Item 1. Business.
Overview
We, a corporation formed in 2002, are an agricultural biotechnology trait company engaged in the development of traits that improve food, feed and fiber crops and enhance the value of the resulting agricultural products. Our customers include seed companies who incorporate these traits into their elite varieties to increase the value of a crop for farmers, as well as food and feed companies who make products that increase the choices and nutritional value of foods for consumers. We are focused on two distinct areas of the agricultural supply chain:
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Improvement of crop yield
by mitigating the impacts of abiotic stresses such as drought, heat, nutrient deficiency, water scarcity, and soil salinity. These stresses are prevalent in most agricultural environments with varying degrees of severity and often have material consequences on crop production, quality, and farmer incomes. Our traits have been introgressed into several crops, including rice, wheat, and soybeans, and we have demonstrated significant yield improvements in multiple years of field testing. In addition to improving the efficiency of agricultural productions, these traits also have the potential of reducing the impact of agriculture on the environment by lowering water requirements and reducing the occurrence of excess nitrogen runoff from intensive farming.
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Enhancement of the nutritional quality of crops
by changing the compositional quality of oilseeds and grains. We currently produce and market the SONOVA
®
brand of oil containing
Gamma Linolenic Acid
(GLA),
an omega-6 fatty acid
derived from safflower. We recently received GRAS notification (generally recognized as safe) from the FDA for use of SONOVA GLA safflower oil in medical foods and nutritional beverages, which we expect will expand the market for this product. In addition, we are in late stage development of Resistant Starch (RS) wheat, a product with twice as much fiber content as conventional wheat. This and other wheat quality products in our pipeline are being developed using our non-transgenic TILLING technology platform.
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Our business model is to access trait technologies that have already achieved proof of concept whether in a public research program or with commercial partners. We further develop these technologies by optimizing their function and validating their performance through intensive field trial testing in multiple crops under varying growth conditions, thereby better establishing commercial viability for resulting products. We then license our technologies to major seed and consumer product companies who perform additional testing and product development and, where needed, generate the requisite data to support regulatory submissions and approvals. License agreements with our partners may include financial and non-financial milestones. When products containing our traits are commercialized we will receive a share of the revenue. In select instances, we also work with our commercial partners to make the regulatory filings required to support commercial launch of the traits in order to increase our share of the revenue.
We use both genetically modified, or GM, and non-GM technologies to develop our traits. This approach allows us to select the most appropriate technology for development of a particular trait, crop and market. However, a key component of the development cycle of GM traits is that U.S., or in some instances, global deregulation of the trait by one or more regulatory agencies may be required. As there continues to be a significant debate about the role of GM traits in agricultural crops, we have seen this issue begin to impact some regulatory agencies which exercise control over the pace of deregulation of products, thereby allowing commercialization. We have recently experienced delays in the review of many of our high value traits principally due to inaction from these government regulatory authorities. For example, in India, where regulators have not approved field trials for testing of GM traits for the last two years, we estimate the impact to trait development and crop commercialization timelines of our license partner in India, Maharashtra Hybrid Seeds Company Ltd. (“Mahyco”), could be at least two to three year delay.
As a result of these challenges, and as we continue working closely with our partners to closely monitor the progress of deregulation activities affecting our GM traits, we are realigning our core capabilities and evolving our business model to accelerate the development and commercialization of near-term, non-GM nutrition and quality traits. According to the estimates of the Nutrition Business Journal report, the global nutrition and supplements
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market stood at $96 billion as of 2012. In 2016, it was approximately $140 billion globally. In 2015 alone, investment in agriculture and food
technology startups totaled $4.6 billion, while the USDA’s Agriculture and Food Initiative (AFRI) budget for the fiscal year 2017 is estimated to be about $700 million or double the fiscal year 2016 level.
Our highest near-term priorities include the expansion of the market for our SONOVA GLA products, bringing our non-GM traits in wheat quality and wheat yield to market, and working closely with our strategic partners to advance our yield trait in corn and soybeans. In the U.S, we have partnered with Dow AgroSciences and Becks Hybrids for the development of yield traits in corn. In South America, we formed Verdeca, a joint venture with Bioceres, a leading agricultural biotechnology company in Argentina, to develop, deregulate and commercialize stress-tolerant soybeans. Verdeca received its first regulatory approval in Argentina in 2015 and submitted regulatory applications in the U.S to Food and Drug Administration (FDA) and in China to the Ministry of Agriculture (MOA) in 2016.
Our Strengths
We believe we are well positioned among our peers to capitalize on the need to increase crop yields and quality of agricultural products globally through a combination of technological innovation, assets and experience that is unique for a small company engaged in trait development. Our competitive strengths include:
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World-class research capabilities.
Our in-house scientific and product development expertise coupled with our advanced Targeting Induced Local Lesions in Genomes, or TILLING, know-how have resulted in the discovery and development of several traits in our commercialization pipeline. Our TILLING platform enables us to discover and develop value-added traits that are considered non-GM. This platform leverages high-throughput screening of induced genetic diversity in plant populations in major crops. Our TILLING populations currently include wheat, rice, soybean, and canola. These populations include numerous native and induced gene function alterations, which can be exploited rapidly at low cost and with minimal regulatory requirements. While the TILLING approach is also practiced elsewhere, we believe that the combination of our history and specialized background in the technology, highly refined skills in developing and screening genetic diversity in plant populations, and proprietary TILLING know-how make us a leader in commercial applications of TILLING.
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Industry leading early phase trait development.
Since the inception of the Company we have successfully
advanced, and continue to advance, several potentially high value traits from the proof of concept stage to advanced field testing. More recently, in the case of HB4 stress tolerant soybeans we have, through our Verdeca joint venture, advanced the trait beyond field testing and into the regulatory phase. By licensing our traits at a later stage of development, we shorten their development cycle, and reduce the risk and expense associated with bringing products to market.
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A broad intellectual property portfolio.
Arcadia’s patent portfolio includes 137 issued patents with 45 pending applications worldwide, relating to our trait technologies and business methods that are either owned or exclusively controlled by us. Our ability to secure exclusive patent rights to our technologies is a key strength for the Company and one that preserves our competitive position.
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Expert regulatory affairs capability.
Our regulatory team has the proven experience and demonstrated capability to manage regulatory submissions and approvals, including regulatory studies, field trials, regulatory submission, regulatory approvals and commercial launch. Our ability to bring traits through the regulatory process quickly and cost-effectively is a key differentiating factor and a capability we have deployed for our own internal development efforts, as well as in collaboration with our development and commercialization partners.
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We have a diverse portfolio of products and partners.
Our product portfolio consists of a wide variety of traits that are applicable to major crops in key geographic markets and address agricultural yield and product quality. The applicability of our product portfolio to these major crops provides us access to multiple large end markets that we believe have demonstrated or have the potential for high growth, such as soybeans in North and South America and wheat and rice globally.
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Our Growth Strategy
We believe there are significant opportunities to grow our business by executing the following elements of our strategy:
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Accelerate the commercialization of our nutrition and yield trait portfolio.
One of our highest priorities is to broaden the market for our SONOVA GLA product and to accelerate the commercialization of our non-GM ingredient and yield traits, including Resistant Starch wheat, wheat quality and wheat yield. We believe these products can be launched into the market over the next three to five years, and we are working with collaborators who are actively advancing the technical and commercial potential of these products.
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Advance commercialization of GM traits in regions where regulatory processes are predictable.
Our Verdeca joint venture continues to advance the HB4 Drought Tolerance trait in soybeans towards commercialization in the Americas, with Argentina being the first launch country. Regulatory submissions were made in 2016 for import approval of HB4 soybeans into China. We plan to submit for production approval in Brazil in 2017 and import approval in the European Union in 2018. In the US we have partnered with Dow AgroSciences for the development of yield traits in corn. This program is currently in field testing in multiple locations in the Midwest.
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Actively support our licensees’ product development, deregulation and commercialization efforts.
Critical to our longer term strategy is unlocking the commercial potential of our key agricultural yield traits, such as Nitrogen Use Efficiency (NUE), Water Use Efficiency (WUE), and Salt Tolerance, in key food crops like rice and wheat. While the ongoing debate about GM crops has delayed regulatory advancements in our most important markets for these traits, we and our partners continue to believe that the value these traits bring to farmers and the impact they will have on food security provide sufficient incentive for all stakeholders to find a way to bring these traits to market. We are actively engaged with our partners to determine and execute optimal strategies to advance these traits through deregulation in these territories
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Leverage our core capabilities in regulatory, greenhouse and field testing to provide services to the industry.
We will deploy the full spectrum of our regulatory services, controlled growth operations and trait evaluation expertise to provide contracted services engagements to drive near-term revenue and support core resources as we build momentum on our trait commercialization pathways.
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Continue to invest in our human resources and commercialization capabilities.
As we expand our GLA business and introduce our non-GM traits to the nutrition and food quality markets, greater knowledge and industry experience will be required to support those commercial efforts. We will continue to invest in acquisition, development and retention of the requisite management and industry experience that will enable us to continue advancing our position in the agricultural biotechnology marketplace.
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Our Products and Product Development Pipeline
In the second half of 2016, the Company completed a comprehensive strategic review of its technology programs, product pipeline, partner progress, competitive landscape and market conditions in order to prioritize and appropriately resource its most promising products and opportunities. As a result of this exercise, management undertook a series of initiatives to rationalize program expenses and Company resources against a set of near, mid-term and long-term priorities and expected outcomes. Some programs were terminated or placed on hold, while investments in other programs were accelerated with the aim of generating the highest potential value for the enterprise. The following table summarizes our current product pipeline inclusive of the decisions made by management in the fourth quarter of 2016.
Program Crop Collaborator(s) Phase Key Markets D 1 2 3 4 5 PRODUCTIVITY TRAITS Nitrogen Use Efficiency (NUE) Wheat Limagrain, Mahyco, CSIRO, ACPFG Global Rice Mahyco, AATF Asia Soybeans Verdeca Americas, Asia Corn Dow AgroSciences Global Cotton Mahyco Americas, Asia Sugarcane US Sugar, SASRI, Mahyco Americas, Asia Turf Scotts N. America Tree Crops Arborgen, Futuragene Brazil, N. America Vegetables Mahyco Asia Water Use Efficiency (WUE) Drought Tolerance (DT) Wheat (WUE) Limagrain Global Wheat (DT) Bioceres Global Rice (WUE) Mahyco Asia Soybeans (DT) Verdeca Americas, Asia Corn (WUE) Genective Global Corn (DT) Dow AgroSciences Global Cotton (WUE) Mahyco Americas, Asia Sugarcane (WUE) US Sugar, Mahyco Americas, Asia Sugarbeets (WUE) SES Vanderhave N. America Tree Crops (WUE) Arborgen, Futuragene Brazil, N. America Vegetables (WUE) Mahcyo Asia Salinity Tolerance (ST) Wheat Mahyco Global Rice Mahyco Asia Cotton Mahyco Americas, Asia Africa Sugarcane Mahyco S. America, Asia Vegetables Mahyco Asia Herbicide Tolerance* Wheat Confidential Global Heat Tolerance Wheat USAID, CIMMYT Global Yield* Soybeans Verdeca Global Trait Stacks NUE/WUE/ST Rice AATF Asia NUE/DT Wheat Bioceres Global NUE/WUE Wheat Limagrain Global NUE Corn Dow AgroSciences Global PRODUCT QUALITY TRAITS GLA Oil Safflower Abbott N. America, Asia Resistant Starch* Wheat NIH Global Post Harvest Quality* Tomato Bioseed Asia, N. America ARA Oil Safflower Abbott, DuPont Pioneer N. America, Asia Grain Quality* Wheat Ardent Mills Global Reduced Gluten* Wheat NIH Global Oil Quality* Soybeans Verdeca Global Phase: D=Discovery; 1=Proof of Concept; 2=Greenhouse / Early Field Trials;
3=Additional Field Trials / Product Development; 4=Regulatory / Pre-Commercial; 5=Commercialized * Non
Productivity Traits, the Yield and Stress Pipeline
Arcadia is a recognized leader in the area of yield and abiotic stress and our business was built on the premise that mitigating the impact of environmental stresses, whether chronic or transient, would generate meaningful yield gains in the most important crops in the world. We believe our yield and stress pipeline holds significant promise, as evidenced by our internal data and data generated by our partners in rice, wheat, soy, corn and cotton varieties. The
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commercial value of these types of t
raits will be fully unlocked as the traits are introgressed into elite germplasm by breeding partners and tested broadly in the field under different environments and agricultural practices. Therefore, while it is our view that the Arcadia pipeline is fair
ly advanced, significant development and testing has yet to be completed on several of our products as referenced in Phase 3 and Phase 4 of development
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Nitrogen Use Efficiency (NUE)
Our NUE technology enables plants to utilize nitrogen fertilizer much more efficiently than conventional plants. This allows crops to achieve significantly higher yields under normally applied levels of nitrogen fertilizer, or to achieve the same yields as conventional crops while using 30 to 50% less nitrogen fertilizer.
Nitrogen fertilizer is a primary plant nutrient and key driver of crop yield. Nitrogen fertilizer is also a significant component of crop production cost. Plant Biotechnology Journal reported that only 30% to 50% of added nitrogen fertilizer is taken up by agricultural crops, with the remainder left unutilized and potentially becoming a significant environmental pollutant.
Our NUE technology platform was initially based on a trait discovered at the University of Alberta (Canada), and we hold an exclusive, global license to the technology for use in all crops, with unlimited sublicense rights. Efficacy of this NUE technology has recently been demonstrated in field-grown rice, wheat, and canola by multiple groups. While we had planned to test NUE cotton lines in the U.S. in 2016, those lines will instead be field tested by our partner, Mahyco.
We are collaborating with Dow AgroSciences on development of NUE in corn from technology originating at Dow Agrosciences. Dow AgroSciences is currently evaluating this technology by means of multiple-location U.S. field efficacy tests in hybrid corn.
Positive field test results for our Dow AgroSciences corn collaboration will also help our research team determine whether to apply this separate NUE technology to additional crops like wheat and soybean. We plan to use a combination of NUE technologies in trait stacks to help us maintain and extend our technical and commercial advantage for this important trait area.
The target crops and markets for NUE include all major agricultural crops and markets. Our NUE technology has now been incorporated, or is under evaluation by our commercial partners, in major global crops, including rice, wheat, cotton, sugarcane, and multiple forestry species. Field trial data to date in multiple major commodity crops has shown yield improvements greater than 10% attributable to our NUE trait. Additionally,
NUE rice tests conducted by independent entities in multiple countries over multiple years have demonstrated that NUE rice lines produced significantly higher grain yield than controls at various nitrogen fertilizer rates. In the paddy low-land production environment, NUE rice lines showed an increase in grain yield of 29.5% at full nitrogen application rates when compared to the parental line. In the rainfed up-land production environment, the NUE rice lines demonstrated 33.8% grain increase at 50% nitrogen application rate.
Water Use Efficiency and Drought Tolerance
Our Water Use Efficiency (WUE) trait enables plants to better tolerate two distinct types of stress: reduced or inconsistent water availability, and severe drought. The WUE trait has been demonstrated to improve crop yield under conditions of episodic water stress and to help crops recover from severe drought conditions. A related but distinct technology, Drought Tolerance, helps plants maintain yields under conditions of prolonged water stress.
Modern agriculture is highly water intensive, using approximately 70% of world water withdrawals, according to the United Nations Educational, Scientific, and Cultural Organization, or UNESCO. UNESCO also estimates that future global agricultural water consumption will increase by about 19% by 2050 and could be even higher if the efficiency of agricultural production does not improve dramatically. The irregular availability of suitable water is one the leading causes of reduced crop yield globally. Loss due to drought in the United States, as reported to the USDA Risk Management Agency, averaged $4.1 billion per year from 2012 through 2016.
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Water-limiting conditions can result from prolonged drought, leading to severe reductions in crop yields, or can result from periodic dry conditions, leading to reduced crop yields. Whenever water limitations occur, economic losses and impairment of the food supply result.
Our WUE trait technology was jointly discovered by researchers at the University of California, Davis and Technion—Israel Institute of Technology. We hold an exclusive, global license to the technology, with sublicense rights, for use in all crops. Greenhouse and field trials of our WUE traits have been completed in agronomic crops such as rice, wheat, cotton, peanuts and alfalfa. We are currently working with collaborators in rice, potato, sugarcane, cotton and multiple tree species.
Our Drought Tolerance (DT) technology was discovered by researchers at National Scientific and Technical Research Council (Argentina), and further developed by Bioceres, S.A. Verdeca, our joint venture with Bioceres, Inc., holds exclusive global rights and is developing and commercializing this technology in soybeans.
Our Drought Tolerance technology is most advanced in soybeans. Multiple seasons of field trials under yield reducing conditions that represent the average yield of soybean production in North and South America have shown significant yield improvements relative to controls with no decrease in yield under optimal conditions. The Early Food Safety Evaluation process has been completed by the U.S. Food and Drug Administration (FDA) for the plant protein responsible for our Drought Tolerance trait. The trait has full approval for food safety and international commerce in Argentina. Regulatory approval application was submitted in 2016 to the FDA and remains under review. Additionally, regulatory approval applications have been submitted in Uruguay and are pending final approval. Regulatory submissions were made in 2016 for import approval of Drought Tolerant HB4 soybeans into China. We plan to submit for commercial release in 2017 with the U.S. Department of Agriculture. Further, we plan to submit for production approval in Brazil in 2017 and import approval in the European Union in 2018.
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alinity Tolerance
Our Salinity Tolerance trait allows plants to maintain yields under conditions of elevated salinity and is applicable to a wide range of crops, including wheat, rice, soybean, and cotton. Our salt-tolerant plants have also been demonstrated to bind excess salt from the soil into the plant, potentially providing the benefit of rehabilitating salinized land over time.
The global cost of lost crop yield to salt-induced land degradation is estimated to be $27.3 billion per year according to the United Nations Natural Resources Forum. Of the current 230 million hectares of irrigated land, 45 million hectares, or about 20%, are salt-affected. Crops grown under salt-affected conditions may be inhibited in two ways. First, the presence of salt in the soil reduces the ability of the plant to take up water, leading to reductions in growth rate. Second, if excessive amounts of salt enter the plant, there can be injury to the cells, which may cause further reductions in growth. Modern agriculture is highly water intensive and the ability to manage crops in saline environments will reduce agricultural demand on critical fresh water supplies.
Our most advanced Salinity Tolerance trait technology is based on technology from the University of Toronto, the University of California, Davis, and the National Institute of Agrobiological Sciences (Japan), all of which have granted us exclusive licenses for all crops. In addition, we are conducting research on additional salinity tolerance genes under a funded research agreement with the United States Agency for International Development, or USAID.
Target markets for the Salinity Tolerance trait are areas where water or soil salinity decrease crop yield. Such areas occur globally where irrigation is prevalent, where ground water supplies are salinized due to seawater intrusion and where soils are salinized due to mineral deposits. These conditions are common in North America, India, China, additional countries in Asia, Australia, and other major crop production countries. Our Salinity Tolerance trait has been licensed to partners in rice, wheat, cotton, and oilseeds.
Crops with tolerance to soil and water salinity are in various phases of development with our primary licensee and partner for the Salinity Tolerance trait technology. Our partner previously tested the most promising rice lines
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with our trait in a field in which controlled amounts of salt were applied to the replicated plots. In 2015, a field trial was executed on naturally high saline farmlands in India, where grain yields typic
ally are very low, and we saw results similar to those in prior trials. Our partner has developed wheat lines that show significant salinity tolerance under greenhouse conditions, with some lines outperforming the controls by more than 30%, and additional
wheat lines are in development to expand the scope of our partner’s first greenhouse evaluations. For salt tolerant cotton, our partner is preparing to conduct outdoor field trials in India.
Yield
Through our Dow AgroSciences collaboration we are evaluating several yield traits in corn through multiple-location U.S. field efficacy tests in hybrid corn. Positive field test results for our Dow AgroSciences corn collaboration will also help our research team determine whether to apply these yield technologies to additional crops like wheat and soybean. We plan to use a combination of these yield traits in stacks to help us develop a competitive technical and commercial advantage for this important trait area.
Our non-transgenic wheat yield program, supported by USDA SBIR, aims to increase yield in wheat using TILLING, a non-GM reverse genetics tool, to identify novel alleles of candidate wheat yield genes in tetraploid and hexaploid wheat. These alleles are being evaluated for the ability to alter wheat architecture and improve yield in the field. As a non-GM technology, products from TILLING can rapidly advance to commercialization and do not face market or regulatory restrictions. With a conservative 5% increase in yield, the yearly value creation to the U.S. farmer is estimated at over $30 per hectare. In addition, the value of higher yielding wheat varieties to a seed company arising from this research in the U.S. alone is more than $40 million annually. By incorporating favorable alleles of plant architecture genes into a commercial wheat breeding program, we believe we can make a significant contribution to improving yield in this vital food crop.
Herbicide Tolerance
Our Herbicide Tolerance program is currently focused on wheat. We have developed a non-GM source of tolerance to glyphosate, a widely used non-selective herbicide. We believe that the discoveries under this program are applicable to other chemistries and are likely to result in similar opportunities in other major crops.
According to the International Service for the Acquisition of Agri-biotech Applications, or ISAAA, from 1996 to 2013, herbicide tolerant crops consistently occupied the largest planting area of biotech crops. In 2013 alone, herbicide tolerant crops occupied 99.4 million hectares, or 57%, of the 175.2 million hectares of biotech crops planted globally. For the first 17 years of commercialization (1996 to 2012), benefits from herbicide tolerant crops were valued at $47.7 billion, which accounted for 41% of global biotech crop value. For 2012 alone, herbicide tolerant crops were valued at $6.6 billion or 35% of global biotech crop value.
Our Herbicide Tolerance technology is in Phase 3 of development and was developed using our non-GM TILLING platform. This work is fully funded by a collaborator who has the option to obtain a non-exclusive commercial license to this trait in certain countries. We retain the right to further license this technology to additional collaborators in major wheat markets.
Testing results have shown tolerance in multiple alleles to levels of glyphosate herbicide, which may be sufficient to control many weed species in wheat production in certain markets. Individual glyphosate tolerant wheat lines are being combined via plant breeding to combine additional sources of tolerance and create products with increasing levels of tolerance.
Heat Tolerance
Our Heat Tolerance technology program is carrying out discovery research funded by USAID in collaboration with the International Maize and Wheat Improvement Center, or CIMMYT, and the Indian National Bureau of Plant Genetic Resources, or NBPGR. Our work targets metabolic approaches to reduce the heat sensitivity of starch synthesis in wheat and increase membrane thermostability. With CIMMYT, we are investigating identified natural
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genetic diversity that affects membrane thermostability and induced genetic diversity in starch synthesis, developed by us, in order to improve wheat heat adaptation in a fundamental way.
Among major staple crops, global wheat yields may be the most impacted by climate change, according to a number of climate change models. And while wheat is the most drought-adapted of major crops, improving heat adaptation would make wheat a climate resilient staple. Developing countries are both significant producers and importers of wheat. According to CIMMYT, demand for wheat will increase by 60% by 2050 in developing countries. As we saw with the global food price crisis in 2008, poor yields in major wheat exporting countries such as Australia can have a significant impact on global prices.
Agronomic Trait Stacks
Trait stacks are combinations of multiple individual traits. Trait stacks can be made by using conventional plant breeding to cross plants with different traits, and can also be made by combining multiple traits in a molecular stack that is then inserted into a target crop. Our collaborators are generally allowed to combine multiple traits of ours either by breeding or molecular stacks. Deep portfolios of agronomic stress tolerance traits are rare in the industry, and the ability to pyramid multiples of such traits is even rarer. In order to validate the efficacy of particular trait stacks, we perform our own research and field trials.
We are advancing two molecular yield and stress trait stacks and have field-tested them in example crops. Efficacy of a trait stack in one crop suggests the probability that the stack will also work in other key crops. The history of single traits functioning in multiple crops, along with the evidence of stacked traits working in more than one crop, suggests that stacked traits are likely to function in multiple crops.
Our most advanced and tested trait stack—the combination of NUE, WUE, and Salinity Tolerance—has been field tested in rice over multiple seasons. We have tested this trait stack under varying levels of nitrogen, water availability, and salinity. Rice plants with this stack out-yielded control plants by 5% to 22% under different levels of nitrogen fertilizer, by 19% to 32% under different types of water stress, and by 27% to 42% under high salinity conditions.
In order to provide a compelling package of trait stacks to corn growers we entered into a strategic collaboration with Dow AgroSciences. Under the collaboration, Arcadia and Dow AgroSciences will jointly develop yield and stress traits, including several traits that have already completed advanced field trials in corn. These traits would then be combined with Dow AgroSciences’ crop protection traits such herbicide tolerance, insect resistance and disease resistance, to create highly competitive trait stacks for commercialization. As part of the agreement, Arcadia can also use the agronomic trait data that we jointly develop in corn to develop and commercialize yield and stress trait stacks in other crops.
Agricultural Product Quality Traits
Gamma Linolenic Acid (GLA) Oil
Under a license agreement we have with Abbott, we developed a new source of vegetable oil with very high levels of gamma linolenic acid, or GLA, an omega-6 fatty acid. To our knowledge, our GLA safflower oil product has the highest concentration of GLA available in any plant oil at 65%; conventional plant oils range from 10 to 22% GLA. We sell the oil in the United States and Canada to manufacturers of nutritional supplements, medical foods, and other products. Our key customers include significant participants in those markets, such as GNC, Lindora Nutrition, and others.
GLA has multiple clinically-demonstrated nutritional and medical benefits, including anti-inflammation effects, improved skin condition and healthy weight management. Multiple parties have expressed commercial interest in incorporating an enhanced GLA oil into their foods, dietary supplements, or medical products where conventional sources of GLA are not sufficiently concentrated to deliver amounts that are cost- and performance-effective.
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Against a commercial target of 40% GLA concentration, we developed, deregulated and commercialized GLA safflower oil containing up to 65% GLA concentration in fewer than
six years. This is significantly fewer than the 13 years it takes, on average, to commercialize a seed using advanced breeding or biotechnology, according to Phillips McDougall. We produce GLA safflower oil by contracting with farmers in Idaho and process
the seed under contract with a manufacturer in California to make refined oil. We sell GLA safflower oil under the brand name, SONOVA, with multiple concentrations and formulations.
In January, 2017 we received notification from the FDA that our GRAS petition (generally recognized as safe) for the use of SONOVA GLA in medical foods and nutritional beverages had been accepted, which means that we can now market and sell this product in a new market segment. We also filed a petition with the FDA’s Center for Veterinary Medicine for the use of SONOVA GLA in dog food. That petition is currently pending and we expect approval in the first quarter of 2017. We anticipate the pet food approval to generate additional revenue opportunities for our GLA business.
Arachidonic Acid (ARA) Oil
Arachidonic Acid (ARA) Oil has high levels of the fatty acid ARA, which is a key ingredient in more than 90% of U.S. infant nutrition products. ARA contributes to benefits such as fostering infant eye and brain development. We estimate the global market for ARA at $160 million and believe that our ARA product will cost significantly less than currently available sources of ARA.
Our ARA Oil is being developed under agreements with Abbott and DuPont Pioneer, each of which licensed intellectual property to us for this program. In exchange for licenses to intellectual property, these agreements provide product access rights to Abbott and DuPont Pioneer, as well as certain royalty payments on product sales to third parties.
We have multiple safflower lines with oil compositions that have the potential of being direct replacements for current sources of ARA in infant nutrition products. We are evaluating near term market distribution opportunities in 2017 with our downstream partners.
Enhanced Quality Grains
We have multiple programs aimed at developing wheat and other small grains with improved nutritional qualities. One such program generated bread and pasta wheat lines with high levels of amylose, a type of resistant starch. Resistant starch increases the total dietary fiber content of wheat and reduces its glycemic index, which are both desirable nutritional qualities that are important in the management of diabetes and healthy blood glucose levels.
In 2016 the FDA approved the use of qualified health claims for corn-based resistant starch in the risk reduction of type 2 diabetes, thus establishing a key precedent for the health benefits associated with this fiber.
In 2012, the average American consumed 40% of the recommended level of daily dietary fiber, with whole grain consumption representing only 15% of targeted fiber intake and 80% of teenagers eating no whole grains. Grain products make up the largest fiber source in US adults, and thus are the ideal vehicle to deliver improved health benefits to a wide population.
A second program aims at improving the flavor profile and shelf-life of whole wheat flour, and is funded by Ardent Mills, which combines the operations of ConAgra Mills and Horizon Milling, a Cargill-CHS joint venture. A third program, funded by the National Institutes of Health, or NIH, is aimed at reducing gluten in wheat and other grains. All three of these programs utilize our TILLING platform, and the resulting products are non-GM.
Resistant Starch Wheat.
Our Resistant Starch (RS) wheat provides a source of wheat with inherently high levels of resistant starch, increasing the total dietary fiber content of food products without the need for fiber additives from other sources such as corn, potato, green banana and cassava. Resistant starch is a key product in two market segments: dietary fiber additives and modified starch additives. According to MarketsandMarkets, the global dietary fibers market is projected to reach $4.31 billion by 2020 and the modified starch market is projected to $11.1 billion in 2020, with food and beverage applications accounting for approximately 50% of this market. Major
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growth in these markets is being driven by the convenience health food sector and functional food sector. Flour from ou
r RS wheat lines has resistant starch levels that are 12 to 20 times higher than the control wheat, and total dietary fiber, or TDF, which is more than eight times higher than the control. RS wheat flour has been tested in applications in bread, where loaf
quality was comparable to bread made with conventional wheat flour, and pasta, where it had the highest consumer preference rankings in tests carried out by a major consumer products company.
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Resistant Starch & TDF Content Levels by Wheat Line Refined Flour Resistant Starch Content (% by wt) Whole Grain Flour Total Dietary Fiber Content (% by wt) 0% 5% 10% 15% 20% 25% 30% 35% 15.1% 37.8% 16.0% 29.0% 33.0% 0% 5% 10% 15% 20% 25% 30% 35% 40% Parent RS14 RS83 RD100 Refined Flour Resistant Starch Whole Grain Flour TDF
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Parent ID 2014 RS 14 CA 2013 RS 14 ID 2014 RS 18 CA 2013 Bread made with 50% RS Bread Wheat
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Resistant Starch & TDF Content Levels by Wheat Line Refined Flour Resistant Starch Content (% by wt) 35% 30% 25% 20% 15% 10% 5% 0% 37.8% 15.1% 16.0% 29.0% 33.0% 40% 35% 30% 25% 20% 15% 10% 5% 0% Parent RS14 RS83 RS100 Whole Grain Flour Total Dietary Fiber Content (% by wt) Refined Flour Resistant Starch Whole Grain Flour TDF Parent ID 2014 RS14 CA 2013 RS 14 ID 2014 RS18 CA 2013 Bread made with 50% RS Bread Wheat
RS wheat flour is currently being tested in a range of additional bakery, ready-to-eat cereals and pasta products with industrial partners. We have several RS wheat lines that are being evaluated for optimal quality and agronomic characteristics.
Improving Shelf Life of Whole Grain Flour.
The USDA recommends that “at least one serving of grains per day must be whole grain-rich” due to evidence that a diet containing whole grains provides a multitude of benefits, including lower risk of obesity, cardiovascular disease, and type-2 diabetes. Despite these health benefits, consumption of whole grain products is negatively affected by the bitter and rancid flavors and odors that accumulate in whole wheat flour after milling. Our improved stability and flavor wheat lines greatly reduced the production of rancid and bitter compounds in aged whole grain flour. Whole wheat flour from these lines is being tested further for sensory characteristics and improved shelf life stability. These new traits, singly and in combination, could help improve the shelf life and flavor profile of whole grain products, thus reducing formulation costs and increasing consumer preference and palatability for whole grains.
Accelerated Aging Study of Whole Grain Flour Production of Rancid Product (ppm) 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 0 week 6week 8 week 16 week Control Accelerated Aging Original Line0 week 6week 8 week 16 week Control Accelerated Aging Arcadia Line
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Post Harvest Quality
Our post harvest quality program for tomatoes has resulted in tomato lines with significantly increased post-harvest storage life. These tomato lines were developed using our TILLING platform and are non-GM. Our early research program was funded by the U.S. Department of Defense, due to their interest in being able to procure quantities of fresh fruit with extended storage life for deployment on board ships and submarines and for overseas missions. The global market for fresh tomatoes is estimated by the Food and Agriculture Organization of the United Nation, or FAO, at $84.5 billion per year. Our initial collaborator for this product is Bioseed, a vegetable seed company based in India, and the product is in Phase 4 of development. Additional collaborations in North America are in development.
Our Product Development Capabilities
The diagram below illustrates the key steps in our technology identification and product development process.
Tilling Create Population (non-GM) ID Target Genes Transform Crop (GM) Plant Transformation Grow Out Controlled Growth Operations Initial Selection Field Trials Data & Analysis Product Selection Regulatory (GM) ASRS Regulatory Management Trait Evaluation & Development and Agricultural Operations Program Team Management Plan Information Management Systems (PIMS)
Identification of New Technology Programs
Our development strategy has been to leverage upstream investment in basic research to expand our product development pipeline and then collaborate with external partners for the early-stage exploration and identification of promising plant technologies, particularly those related to abiotic stress tolerance in plants. Some of these key early-stage collaborations include programs with the ARC Centre of Excellence in Plant Cell Walls (Australia), the University of Adelaide (Australia), CIMMYT (Mexico), the University of California, Davis (United States), Tulane University (United States), the International Center for Research in Semi-Arid Tropics (India), the International Rice Research Institute (the Philippines), the Bangladesh Rice Research Institute (Bangladesh), and ICABIOGRAD (Indonesia). Many of these collaborative programs are funded by U.S. government grants that we have secured either ourselves or in connection with our collaboration partners, including grants by USAID, the NIH, the National Science Foundation, and the USDA. Other early-stage technologies have been introduced to us by commercial entities engaged in basic research who may be seeking to partner with us to advance their discoveries to further validation and product development.
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We have a formal process for evaluating new technology opportunities. We have historically accepted less than 10% of the potential opportunities we have
evaluated. Once a promising new trait technology has been accepted, we negotiate an agreement with the technology provider that, at a minimum, enables us to further evaluate the technology for a suitable period of time, or, in some cases, secures rights th
at enable full research and commercial exploitation of the technology.
Technology Evaluation
Our technology program teams include scientists who are leaders in their respective fields. These teams contribute to the initial evaluation of new opportunities and are responsible for development of technologies brought onboard or developed in-house. Each of our technology programs involves multiple gene, trait and crop targets, and our process focuses on rapid development of the most promising combinations. In the development of any particular trait, we carry out a series of steps including the direct evaluation of target gene function and the specific evaluation of results in key representative crop species. While common core scientific services are provided by functional groups, the technology program team manages overall progress and remains directly involved throughout the development cycle, internally as well as externally with our collaborators.
GM and Non-GM Product Development Platforms
Targeting Induced Local Lesions in Genomes (TILLING)—Non-GM Traits.
Our TILLING platform enables us to develop value-added crops without the use of GM methods. The TILLING platform is managed by a dedicated team of scientists able to apply TILLING to multiple crops with complex genomes. TILLING technology was originally invented by a member of our science team and utilizes specialized laboratory equipment to carry out high-throughput allele screening of DNA samples from genetic diversity populations created in major crops. Our populations include wheat, rice, soybean, and canola. These populations include numerous native and induced gene function alterations, which can be discovered and evaluated rapidly at low cost and with minimal regulatory requirements. While the TILLING approach is also practiced elsewhere, we believe that the combination of our background in the technology as the first to apply TILLING to crop plants such as wheat and tomato, and our highly refined skills in developing and screening genetic diversity in plant populations makes us a leader in commercial applications of TILLING.
Transformation—GM Traits
. For projects involving GM traits, the genetic construct for insertion into plants is designed and built by our relevant program team, and then the gene transfer step is accomplished by our plant transformation functional group. This group has developed a complete physical and methodological infrastructure at our laboratory facility in Davis, California to efficiently transfer genetic materials into key crop species. Our team has demonstrated transformation capabilities in all primary and some secondary agricultural crops, including rice (japonica, indica and NERICA types), wheat, corn, canola, safflower, barley, sorghum, alfalfa, tomato, potato, tobacco and grapes.
Controlled Growth Operations
. Our controlled growth operations group manages our growth chamber facilities, where plants are grown under precisely controlled conditions, and our greenhouse facility, consisting of approximately 26,000 square feet of high quality greenhouse space, which are both at our headquarters in Davis, California. The controlled growth operations group uses these facilities to manage plant experiments and grow-outs under rigorously controlled conditions. They also carry out the initial seed increases and first stages of plant breeding for some projects. For certain projects, such as those relating to oil quality and Resistant Starch wheat, this group also manages crop pre-breeding programs to develop plant varieties for the production of commercial products.
Field Trials and Commercial Production
. Our trait evaluation and development group is based in Davis, California and manages remote field operations in American Falls, Idaho and Brawley, California. The group conducts field trials throughout the United States with specialized contractors, and elsewhere globally with our collaborators and joint venture partners. The trait evaluation and development group has extensive field and specialized statistical analytical capabilities that we deploy to support their field trial execution and data analysis internally and with our collaborators.
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Our agricultural operations group manages efficacy and regulatory field trials and, in the case of GLA safflower, commercial crop production. La
te-stage field trials are intended to develop extensive data on a limited number of potential commercial plant varieties. These trials may be used to test new varieties developed by our collaborators containing our traits, and to test our own commercial va
rieties for oil quality and grain quality programs. Similarly, regulatory trials develop data for use in submissions for regulatory review and may involve plant varieties developed by our collaborators or our own oil quality and grain quality programs.
Regulatory Data Generation
. Our Analytical Services and Regulatory Science, or ASRS, group is located in Davis, California and provides automated DNA preparations, genomic blot analyses, lipid profiling, metabolomics and protein purification services and develops data for use in product selection and validation, certification of SONOVA product specifications, and regulatory submissions. These data support regulatory submissions and provide core trait regulatory packages to our collaborators for use in their crop-specific regulatory applications.
Biological Materials Inventory and Tracking
. Our proprietary Pedigree and Inventory Management System, or PIMS, tracks the genetic, phenotypic and location information for all our plant materials. PIMS encompasses genetic elements such as genes and promoters, GM seeds and plant material received by us, as well as seeds and plants developed by us and used in trait development. The performance of our plant materials is recorded through a variety of laboratory and field observations, and the data are stored within PIMS. The location of all plant materials is tracked throughout the plant life cycle. This includes specific seeds planted within a specific plot of a specific field trial, harvest, seed storage location and use by, or distribution of plant material to, our collaborators or elsewhere. PIMS interfaces with our Biotechnology Quality Management System, or BQMS, to manage all movement and release of regulated GM plant materials. This ensures that all of our plant materials are accounted for, tracked and inventoried, which enables us to maintain control over and documentation of all plant materials.
Regulatory Compliance and Stewardship
Our regulatory management team provides regulatory services for all of product development programs, as well as joint ventures and selected collaborations. These services include establishing standard operating procedures and best practices, completing regulatory permits and monitoring regulatory and stewardship compliance for all products at all stages. Our regulatory team includes key employees who are directly responsible for leading all global regulatory agency interactions and providing tactical and strategic regulatory direction. Our team collectively has more than 30 years of direct involvement in the development and approvals of GM crops. The key member of our regulatory team was responsible for completing the first FDA and USDA deregulation of a GM whole food. The interactions and processes associated with these first USDA and FDA processes established benchmarks for the regulation of GM products that remain applicable today.
Our regulatory management and compliance activities encompass three broad categories: deregulation, stewardship, and authorization. In the United States, these activities are regulated by various government agencies, including the USDA, the FDA and the U.S. Environmental Protection Agency (EPA). Our regulatory team has completed significant regulatory activities (new dietary ingredient review, food additive regulation and GRAS notice) with the FDA Division of Dietary Supplement Programs, with the FDA Center for Food Safety and Applied Nutrition, with the FDA Center for Veterinary Medicine and with the Health Canada Natural Health Products Directorate.
Deregulation
Our business is subject to regulations related to agriculture, food and the environment. Plant products produced using GM technology are subject to laws and regulations in countries where the plants are grown and in countries where the GM plant-derived food and feed are consumed by humans or animals. Commodity products utilizing our GM traits may require approvals in multiple countries prior to commercialization.
U.S. Regulatory Agencies
:
U.S. Department of Agriculture.
We must obtain USDA authorizations and permits in order to conduct the field releases of regulated materials that are necessary to advance the development of GM crops. Obtaining such
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authorizations and permits is generally routine and delays impacting the planned movement or release of GM
material are uncommon. The USDA provides detailed regulations and guidance for obtaining a
“Determination of Deregulated Status,”
which authorizes the commercial and uncontained growing of GM plants. For regulated GM plants, the USDA requires that a compa
ny petition the agency to demonstrate that the product is unlikely to pose a risk. Based on the information provided, the USDA prepares an Environmental Assessment (EA) and/or an Environmental Impact Statement (EIS) in order to make its determination. Thes
e procedures afford the public an opportunity to submit written comments on the draft EA or EIS for consideration by the USDA before the final version of the EA or EIS is published. For any GM plant product, there may be delays or requests for additional i
nformation based on the USDA’s review or the public comments. As of January 2017, USDA has reached 125 Determinations of Nonregulated Status. Submissions received by the USDA from all applicants prior to 2011 averaged more than 3 years for approval. Since
then, the USDA has significantly shortened the time to approval.
U.S. Food and Drug Administration.
The FDA is responsible for food safety under the Federal Food, Drug and Cosmetic Act. The FDA recommended in its 1992
Statement of Policy: Foods Derived from New Plant Varieties
that developers of GM plant products consult with the agency about the safety of GM products under development. In 1996, the FDA provided additional guidance to the industry on procedures for these consultations. These procedures require a developer intending to commercialize a food or feed product derived from a GM plant to first meet with the agency to identify and discuss relevant safety, nutritional and other regulatory issues regarding the product. Subsequently, the developer submits to the FDA a scientific and regulatory assessment supporting proposed product safety. The FDA evaluates the submission and engages with the developer to resolve any questions, requests for additional data or other informational requirements. Once the FDA has determined that all requirements have been satisfied, the FDA concludes the consultation process by issuing a letter to the developer acknowledging completion of the consultation process with the addition of the product to the list of completed consultations on the FDA website. The completed consultation acknowledges product safety for use as food and feed. To date, over 150 GM products have completed this process. This process may have delays if the FDA requires additional data and information for its consultation and to resolve any questions the FDA may have. The FDA completed 16 consultations in 2015 and 2016, with consultation time periods in 2016 ranging from 9 to 22 months and averaging 14 months from first submission to conclusion.
Environmental Protection Agency.
Certain products may also be regulated by the EPA, including plants that contain a plant-incorporated protectant, such as a pesticides or herbicide, or plants engineered to be treated with industrial chemicals.
International Deregulation:
When products from GM crops are expected to be exported from the United States, commercialization of such crops in the United States will require approvals in those countries into which the crops or derivative products, such as grain, oil or meal, will be exported. The laws and regulations for GM plant products are well defined in most commercially significant countries, including Australia, South American countries, India, China, several African countries and the European Union. Typically, our collaborators are responsible for obtaining all regulatory permits and approvals relevant to product development and commercialization in their licensed countries and for generating crop and transformation event-specific data required by their countries of interest. We provide basic safety data on trait expression products in accordance with generally accepted standards. In addition, we may serve as a regulatory consultant and participate in the design of regulatory protocols, data generation and development of detailed regulatory submissions. In certain countries, we may develop strategic business relationships or employ independent consultants with country-specific knowledge and expertise to support and obtain required approvals.
Stewardship
Stewardship, or the careful and responsible management of assets, forms the foundation of our regulatory compliance programs associated with GM plants. Our stewardship framework for GM plants is defined by government regulations and related internal policies and practices. In previous years, Arcadia’s Biotechnology Quality Management System (now identified as ABQMS) was developed by us and then audited/certified by the USDA Animal and Plant Health Inspection Service, Biotechnology Regulatory Service (APHIS BRS). Recently, USDA updated its BQMS program renaming it the Biotechnology Quality Management Support Program, discontinuing the mandatory auditing/certification standard.
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Our ABQMS program was developed to address all conditions required under USDA authority to ensure conta
inment of regulated plant material. The ABQMS includes standard operating procedures, or SOPs, recording and reporting forms, instructions for managing all compliance related activities, and training requirements for all individuals handling GM plant mater
ials. SOPs are highly detailed and consider all elements of each relevant activity or process. Each field trial site is accompanied by a Field Compliance Guide and Record (GUIDE) containing multiple SOPs and associated forms for each activity. For example,
a GM wheat trial requires 19 SOPs and associated verification forms. A GUIDE is completed for each regulated field trial and serves as a completed record to support compliance with government regulations. Example copies of the GUIDE have been provided to
our collaborators for use in other countries where they conduct GM field trials.
Our ABQMS is audited annually by our compliance manager and previously by an independent auditor trained and supervised by the USDA. Since our ABQMS program was first recognized by the USDA in 2011, each annual independent audit conducted by USDA until discontinuation of their audit program confirmed that our program was functioning as intended. Our ABQMS manager has attended USDA BQMS training programs at the request of the USDA to assist in training personnel at other companies and organizations and to share our experience and the SOPs that form the basis of our program.
Compliance with the specific parameters of regulatory requirements is only one element of stewardship. Additional activities within each functional group throughout the company are integral to the overall stewardship program. Each of our employees is trained on, and must comply with, relevant stewardship guidelines as defined and described in our ABQMS.
Authorization
The USDA APHIS Biotechnology Regulatory Service (BRS) has legal and regulatory authority over the movement and release of GM plants and seeds. “Movement” includes movement of regulated GM plant material between states and the importation of regulated GM plant material into the United States. “Release” includes field trials of any size and any other use of regulated GM plant material outside of contained greenhouses.
We have obtained more than 200 authorizations from the BRS for the movement, importation or release of GM plants under development. General and specific conditions to maintain containment during all activities associated with the movement or release are a requirement of each authorization. These conditions are defined, applied and recorded in the GUIDE following our ABQMS program.
Intellectual Property
We rely on patents and other proprietary right protections, including trade secrets and contractual protection of our proprietary know-how and confidential information, to preserve our competitive position.
As of December 31, 2016, we owned or exclusively controlled 137 issued patents and 45 pending patent applications worldwide. As of this date, we owned 11 and exclusively in-licensed 18 U.S. patents and we owned seven and exclusively in-licensed one pending non-provisional U.S. patent applications relating to our trait technologies and business methods. Also, as of this date, we owned 11 and exclusively in-licensed 97 foreign patents and owned 22 and exclusively in-licensed 15 pending foreign patent applications. With respect to all of the foregoing patent assets, our exclusive licenses afford us control over the prosecution and maintenance of the licensed patents and patent applications. These numbers do not include in-licensed patents for which we either do not have exclusive rights (such as certain enabling technology licenses), or for which we have exclusive rights only in a limited field of use or do not control prosecution and maintenance of the licensed patents.
As of December 31, 2016, we had eight registered trademarks in the United States. As of this date, we also had eight registered trademarks in various other countries.
We also have entered into in-license agreements enabling the use and commercialization of our traits, including NUE, WUE and Salinity Tolerance, and certain products that we have commercialized or are under development, including GLA safflower oil and ARA safflower oil. Under these licensing arrangements, we are
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obligated to pay royalty fees on sublicense re
venue and net product sales ranging between low single digit percentages and percentages in the mid-teens, subject in certain cases to aggregate dollar caps. The exclusivity and royalty provisions of these agreements are generally tied to the expiration of
underlying patents. After the termination of these provisions, we and our collaborators may continue to produce and sell products utilizing the technology under the expired patents. While third parties thereafter may develop products using the technology
under the expired patents, in many cases, we have incremental patent rights covering our most important technologies, which we believe mitigate the impact of the expiration of these patents, or the related exclusivity provisions, on our business. We also h
ave numerous in-licenses relating to enabling technologies utilized in our development programs, such as transformation methods (e.g., Japan Tobacco, DuPont Pioneer), genome editing tools (e.g., Dow AgroSciences), promoters (e.g., Dow AgroSciences, Louisia
na State University) and selectable marker technologies (e.g., Bayer). These in-licenses are non-exclusive and include some combination of upfront and annual license fees, milestone fees, and commercial royalty obligations consisting of low percentages or
a low dollar per acre fee.
Below is a summary of those in-license agreements that we believe are most significant for our more advanced product development programs.
University of Alberta.
We hold an exclusive license from University of Alberta to the patent portfolio that formed the basis of our NUE program, which began in 2002. In exchange for an upfront license fee and royalties on sublicense revenues and net product sales (which are capped at an aggregate amount in the mid-seven figures), and subject to the University’s right to perform academic research using the technology, we exclusively control all research, development, commercialization, and sublicensing of the patented technology globally for all crops.
Blue Horse Labs.
In conjunction with a sponsored research and development agreement entered into in 2003, we obtained an exclusive license from Blue Horse Labs, an affiliate entity of our majority stockholder, Moral Compass Corporation, for technology related to several of our development programs. Under the sponsored research and development agreement, Blue Horse Labs has an ownership right in patents covering technology that was developed using Blue Horse Labs funds, including certain NUE and GLA safflower patents. In the corresponding license agreement, in exchange for a single-digit royalty on net revenues and management of all aspects of the patent portfolio, we exclusively control all research, development, commercialization, and sublicensing of the patented technology globally for all crops.
University of California, Davis.
Our WUE technology was developed under an exclusive option agreement with the University of California, Davis, pursuant to which we exercised our right to secure an exclusive license in 2010. We also hold an exclusive license from University of California, Davis, to the patent portfolio that forms the basis of our Salinity Tolerance program. In exchange for an upfront license fee, license maintenance fees, and royalties on sublicense revenues and net product sales, we exclusively control all for-profit research, development, commercialization, and sublicensing of the patented technology globally for all crops.
University of Toronto.
We hold an exclusive license from University of Toronto to the patent portfolio that forms the basis of our Salinity Tolerance program. In exchange for an upfront license fee, a royalty on revenues, and payment of all costs associated with the patent portfolio, and subject to the University’s right to use the technology for research and teaching purposes, we exclusively control all for-profit research, development, commercialization and sublicensing of the patented technology globally for all crops.
Abbott.
We entered into a license and development agreement with Abbott in 2003 under which we have been granted limited exclusive rights to Abbott’s portfolio of U.S. and foreign patents relating to the development of plant-based sources of GLA, ARA and essential fatty acids. Under this agreement, we provide Abbott with preferential access to commercial products from our GLA and ARA safflower programs, as well as the right to receive royalty payments on product sales to third parties, in exchange for the licenses to Abbott’s intellectual property rights.
Dow AgroSciences
. In December 2015, we announced the entry into a strategic collaboration with Dow AgroSciences to develop and commercialize new yield traits and trait stacks in corn. The collaboration leverages our platform of abiotic stress traits with Dow AgroSciences’ enabling technology platforms, input traits, regulatory
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capabilities and commercial channels. As part of the strategic partnership, we negotiated non-exclusive access to Dow AgroSciences’ EXZACT™ Precision Technology Platform to enhance and accelerate the development of trait stacks. Dow A
groSciences has developed the EXZACT™ Precision Technology Platform under an exclusive license and collaboration agreement in plants with Sangamo BioSciences, Inc.
Key Collaborations
Since our founding in 2002, we have established numerous trait collaborations and have developed deep relationships with industry-leading seed and consumer product companies. Our partnerships with global strategic seed and consumer product players enable us to further participate in the development and commercialization of innovative products that promise to play significant roles in improving global crop efficiency and enhancing human health. The results of these collaborations directly feed innovation and drive the progress of our ongoing programs. Moreover, the expertise and opportunities created by the collaborations represent important assets to our business. While our collaboration-focused business model has resulted in numerous strategically significant relationships, below is a summary of selected collaborative partnerships that we view as key to the achievement of our near-term and mid-term business objectives.
Mahyco
We have multiple agreements with Mahyco covering more than 15 programs, using our most advanced traits in multiple major crops, and have been working with Mahyco as a key partner since 2007. Our collaborations in NUE rice and salt tolerant rice are in advanced stages of development.
Under our various agreements relating to our NUE, WUE, and Salinity Tolerance traits, Mahyco has exclusive research and commercial rights in all licensed geographies and must timely meet certain diligence milestones in order to maintain their exclusivity. Each of our collaboration agreements with Mahyco includes an upfront technology access fee, technical and regulatory milestone fees, and, once products utilizing our traits are commercialized, we are entitled to receive a portion of the commercial value of seeds sold by Mahyco incorporating our traits. Rights to new intellectual property developed under a collaboration agreement are owned by the inventing party or parties.
Vilmorin & Cie (Limagrain)
We selected Limagrain as our strategic partner and collaborator in wheat—the world’s largest crop by area grown and the third most valuable at $186.4 billion annual value—due to their position as the leading global breeder and marketer of wheat seeds. In 2009, we executed an agreement with Limagrain under which we partnered to develop and commercialize NUE wheat in all countries of the world except Australia, India, Pakistan, Bangladesh and Sri Lanka. Under our agreement, Limagrain has exclusive research and commercial rights in all licensed geographies except North America and South America, in which we retained co-exclusive rights, and Limagrain must timely meet diligence milestones to maintain exclusivity. Our agreement with Limagrain includes an upfront technology access fee, annual maintenance fees, and technical and regulatory milestone fees, and once an NUE wheat product is commercialized, we are entitled to receive a portion of the commercial value of the trait in the marketplace. We and Limagrain have since coordinated with collaborators in Australia to align development efforts in NUE wheat on a global basis.
In 2010, we further expanded our relationship with Limagrain from collaborator to stockholder and joint venture partner. Contemporaneously with Limagrain’s $25.0 million equity investment in our company, we formed Limagrain Cereal Seeds LLC, a joint venture company focused on the development and commercialization of improved wheat seed in North America, of which a U.S. wholly owned subsidiary of Limagrain owns 65% and we own 35%.
We are currently discussing a proposal with Limagrain whereby Limagrain would exchange its ownership interest in Arcadia for Arcadia’s ownership interest in Limagrain Cereal Seeds. After collaborative discussion with Limagrain, we believe the Company can achieve its business goal of bringing high value yield and quality traits to the wheat market without having to incur the additional expense of operating a wheat seed business. Both Arcadia
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and Limagrain remain committed to a partnership in wheat and are diligently working to determine the optimal
structure for our strategic collaboration. Although there can be no assurances that the exchange will be consummated, we expect to complete the cashless exchange in late March 2017.
Bioceres
In 2012, we partnered with Bioceres, an Argentina-based technology company, to form Verdeca LLC, a U.S.-based joint venture company engaged in the development and deregulation of soybean traits, of which we own 50%. We selected Bioceres as our partner in soybeans—the world’s fourth largest crop by area grown and the fourth most valuable at $119.0 billion annual value—due to their desirable trait portfolio, their presence in key South American markets, and the significant presence of large soybean growers in their ownership structure.
Our joint venture agreement provides for each of the joint venture partners to license its trait technologies to Verdeca for use in soybeans, with product development and regulatory efforts equitably divided and managed by us and Bioceres under stand-alone service agreements that are executed annually. The first product in the Verdeca pipeline is a drought and abiotic stress tolerance trait that has already completed extensive validation trials and is now in the regulatory phase of development. This trait has been demonstrated to confer as high as a 14% yield advantage over conventional soybeans grown under the same suboptimal conditions. In April 2015, Verdeca received the first regulatory approval of its stress tolerance trait in soybeans in Argentina. This is the world’s first regulatory approval of an abiotic stress tolerance trait in soybeans, which we believe is an important initial step in pursuing additional regulatory approvals that Verdeca intends to seek in multiple geographies globally. Verdeca has successfully negotiated favorable market access in South America through established players and is working on adding market channel partners in the United States, India, and China.
In addition to those agreements with Bioceres directly associated with Verdeca, we also have negotiated exclusive access to Bioceres’ drought and abiotic stress tolerance trait for use globally, outside of South America, in wheat. Our agreement with Bioceres provides for sharing of trait value once a product is commercialized.
In April 2015, we entered into a collaboration agreement with Dow AgroSciences and Bioceres under which our Verdeca joint venture will collaborate with Dow AgroSciences on the development and deregulation of soybean traits on a global basis.
Dow AgroSciences
In December 2015, we announced the entry into a strategic collaboration with Dow AgroSciences to develop and commercialize new yield traits and trait stacks in corn. The collaboration leverages our platform of abiotic stress traits with Dow AgroSciences’ enabling technology platforms, input traits, regulatory capabilities, and commercial channels.
Under the collaboration, we and Dow AgroSciences will jointly fund, develop and commercialize agronomic yield traits, such as nutrient efficiency and water use efficiency, including several traits that already are in advanced field trials in corn. These traits would then be combined with Dow AgroSciences’ input traits to create highly competitive trait stacks that maximize farmer revenue and efficiency.
Scientific Advisory Board
We maintain a scientific advisory board consisting of the members identified below. Our scientific advisory board meets on a quarterly basis and is comprised of industry and academic experts that have extensive experience in the analysis, research and development, and commercialization of biotech plants, including experience relating to discovery, transformation, and field trials. We consult with our scientific advisory board on a variety of matters pertaining to our current and future pipeline of products in development, including, for example, trait selection and development, transformation and TILLING methodologies, field trials, regulatory matters, and intellectual property evaluation.
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We currently have a scientific advisory board that c
onsists of five members as follows:
Eduardo Blumwald, Ph.D.
is a professor at the University of California, Davis. Dr. Blumwald’s research program is multidisciplinary in nature, combining physiology, biochemistry, molecular biology, genomics, and proteomics. The general objectives of his work are: (i) the cellular and molecular mechanisms that regulate ion homeostasis in plants; (ii) the cellular and molecular mechanisms mediating the responses of plants to abiotic stress (e.g., salt, drought, and heat); (iii) the biochemical and molecular basis of sugar and acid accumulation in fruits; and (iv) the development of genomic and proteomic resources for the improvement of fruit quality. Dr. Blumwald has worked closely with our scientists from the time of his former position with the University of Toronto.
Vicki Chandler, Ph.D.
is Dean of Natural Sciences at Minerva Schools at Keck Graduate Institute, a new undergraduate liberal arts college. Prior to joining Minerva, she was Chief Program Officer, Science at the Gordon and Betty Moore Foundation. She studied biochemistry for her undergraduate and doctoral degrees at the University of California, Berkeley, and the University of California, San Francisco, respectively. She then pursued postdoctoral research at Stanford University in maize genetics and was on the faculty at the University of Oregon and the University of Arizona. Dr. Chandler’s research on paramutation, an epigenetic process, has implications not only for maize, which she used for the majority of her research, but also for animal and human genetics and genetic diseases. Dr. Chandler has been President of the Genetics Society of America, a member of the National Academy of Sciences, and a member of the National Science Board. Her many honors include the Presidential Young Investigator Award, Searle Scholar Award, and American Association for the Advancement of Science Fellow. She has served on advisory boards and panels for the National Research Council, National Science Foundation, Department of Energy, and National Institutes of Health. Dr. Chandler has chaired numerous conferences and served on the editorial boards of several journals, including
Genetics
,
Plant Physiology, PNAS,
and
Science
.
Luca Comai, Ph.D.
is a professor of plant biology at the University of California, Davis Genome Center. Dr. Comai’s lab is involved in two areas pertinent to breeding. In the first, they study genome regulation, hybridization, and heterosis responses in chromosome copy number variants and interspecific hybridization. In the second, they develop methods and resources for functional genomic discovery, including TILLING, which allows targeted inactivation of genes in crop plants. The research combines plant genetics and genomics with the use of next-generation sequencing, bioinformatics and genome editing to identify genes responsible for traits of interest as well as to discover and use natural and induced variation. Dr. Comai is known for his pioneering work creating glyphosate tolerant crops, and as a founding scientist in Calgene Pacific, Targeted Growth, Inc. and Tilligen. He is a Fellow of the American Association for the Advancement of Science.
Georges Freyssinet, Ph.D.
is recently retired after many years in the plant biotechnology industry in France. He is the former CEO of RhoBio, a joint venture between Rhône-Poulenc Agro and Biogemma, and served as the Scientific Advisor for Life Sciences for the RP Group. Dr. Freyssinet is the former Director of Plant Genomics for Aventis, which was later acquired by BayerCropScience. He joined Biogemma in 2003 to lead their genomic and bioinformatics platform, and in 2006 he joined the scientific direction of Groupe Limagrain, serving as Scientific Director from 2008-2011. Dr. Freyssinet is the founder and former CEO of LemnaGene, a biomanufacturing company, and the former CEO of Genective, a joint venture between Groupe Limagrain and KWS. Retired since 2014, he continues his independent consulting activities in plant biotechnology.
Peter Quail, Ph.D.
is a professor of plant and microbial biology at the University of California, Berkeley where he also serves as Research Director of the Plant Gene Expression Center (U.S. Department of Agriculture/Albany, California). Dr. Quail has been a pioneer in the study of phytochromes, photoreceptor proteins that play a major regulatory role in plant growth and development. Dr. Quail was elected to the National Academy of Sciences in 2004, as a Fellow of the American Association of Science in 2004, and was the recipient of the Stephen Hales Prize, American Society of Plant Biologists, 2008. He received a B.S. and Ph.D. from the University of Sydney, Australia.
Competition
The markets for seed traits and agricultural biotechnology products are highly competitive, and we face significant direct and indirect competition in several aspects of our business. Competition for improving plant genetics comes from conventional and advanced plant breeding techniques, as well as from the development of
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advanced biotechnology traits. Other potentially comp
etitive sources of improvement in crop yields include improvements in crop protection chemicals, fertilizer formulations, farm mechanization, other biotechnology, and information management. Programs to improve genetics and chemistry are generally concentr
ated within a relatively small number of large companies, while non-genetic approaches are underway with broader set of companies.
In general, we believe that our competitors generally fall into the following categories:
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•
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Large Agricultural Biotechnology, Seed, and Chemical Companies:
According to Phillips McDougall, the leading 11 seed and trait companies as a group invested $4.1 billion in seed and trait research and development in 2013. This includes conventional and advanced plant breeding, as well as biotechnology trait development. According to Phillips McDougall, only a limited number of companies have been actively involved in new trait discovery, development, and commercialization: Monsanto, DuPont Pioneer, Syngenta, BASF, Bayer, Dow, KWS, and Genective (a joint venture between KWS and Limagrain). Many of these companies have substantially larger budgets for gene discovery, research, development, and product commercialization than we do. Some of these companies also have substantial resources and experience managing the regulatory process for new GM seed traits. Each of Monsanto, DuPont Pioneer, Syngenta, Dow, and Bayer, which accounted for 85% of the 2013 seed trait research and development spend noted above, also have significant chemical crop protection background and businesses. The trait pipelines of these companies are heavily weighted toward biotic stress traits, although they also have significant programs aimed at development of abiotic stress traits. While these companies have internal programs that may compete with our own, they also seek new traits externally and, as such, some of them either currently are, or may in the future be, our collaborators. In addition, some of these companies are currently among our sources for new trait technologies.
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Trait Research and Development Companies:
There are a number of companies that specialize in research and development of agricultural yield and product quality traits, and we believe that a dozen or more companies, including Evogene and Keygene, among others, are competitors in our field. We believe that these companies typically focus on a limited number of traits, and do not generally have the product development and regulatory infrastructure necessary to bring traits to market. Therefore, they typically license trait technologies to large industry players with in-house development and regulatory capabilities at a relatively early stage of development.
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Companies Focused on the Development and Commercialization of Microbial Crop Enhancements:
The use of microbial products to enhance crop performance via application to soil, seed, or to crops directly is an area where increased research and development activity has been underway for the past decade or more. We believe that there are more than 20 companies of varying size working in this space. There have been a number of acquisitions, including Becker Underwood by BASF, and joint collaborations in this space, but multiple independent companies remain, including Verdesian, Marrone Bioinnovations, Biagro and Bioconsortia. While these companies could be considered to compete with us as their products seek to improve crop yields, we believe that such products and our traits may be additive, or synergistic, to our future products in terms of increasing crop yields.
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Companies Focused on Farming Data Management, or Precision Agriculture:
Within the past several years there has been a rapid increase in technologies and companies focused on acquiring, analyzing, and acting upon data in ways that may improve farm economics via increased crop yield and more efficient management of crop production inputs. Technical approaches include weather prediction and monitoring, high-density field and crop imaging systems, precision field soil and yield mapping, and others. Companies focusing on this space include Climate Corporation (acquired by Monsanto), Farmers Business Network, Farmers Edge, Trimble, Planet Labs, Ceres Imaging, Blue River Technologies, and others. While these products are potentially competitive with us for increasing crop yields, we believe that certain of these products could also be additive or synergistic with our traits.
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Agricultural Research Universities and Institutions:
Given the global importance of agriculture, numerous agricultural research universities and institutions around the world focus on basic and applied research aimed at increasing crop yield. According to the Agricultural Science and Technology Indicators, global public spending on agricultural research and development in 2008 totaled $31.7 billion, having increased by 22% during the years from 2000 to 2008. Spending in 2008 in high income
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countries accounted for approximately 51% of the total, while spending in low and middle income countries accounted for 49% of the total. The United State
s was the largest contributor of public agriculture funding in 2008 with a total investment of $4.8 billion. Most of this publicly funded research is focused on basic research. Many public research programs aim to understand basic biological processes and
do not necessarily engage in further development and commercialization of discovered traits. While these programs are potentially competitive with us, we view them primarily as sources of innovation that fit with our business model. We have an established
track record of working closely and effectively with public research programs, including a number from the U.S., Canada, Japan, Australia, Spain, Ireland, and elsewhere.
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We believe that we are uniquely positioned at the nexus of basic research and commercial product development. Unlike many companies in our space, we generally do not compete in the area of basic research. Our focus is on development and validation and, therefore, we provide a value-added link by which basic research can be brought to market. While internal programs at the largest seed and technology companies are competitive with ours in some cases, we are technology providers to some of these companies, and we have numerous collaborations with many of them. To remain competitive, we plan to pursue multiple strategies, including further building our non-GM pipeline of new technologies from basic research programs, increasing the scope and range of our field testing activities, and continuing to protect our intellectual property rights in key jurisdictions globally.
Research and Development
As of December 31, 2016, we had 30 full-time employees dedicated to research and development, six of whom are development and field personnel focused on demonstration and research field trials. Our research and development team has technical expertise in molecular biology, biochemistry, genetics and genetic engineering, analytical chemistry, plant physiology, plant virology, molecular pathogenesis, and soil and water science. Our research and development activities are conducted principally at our Davis, California facility, with ongoing field trials conducted in American Falls, Idaho; Brawley, California, Yuma, Arizona; and numerous other locations throughout the United States, as well as locations managed by our collaborators worldwide. We have made, and will continue to make, substantial investments in research and development. Our research and development expenses were $8.7 million and $9.0 million in the years ended December 31, 2016 and 2015, respectively.
Employees
As of December 31, 2016, we had 57 full-time employees, of whom 8 hold Ph.D. degrees. Approximately 30 employees are engaged in research and development activities, three in business development, two in regulatory management, and 22 in management, operations, accounting/finance, legal and administration. We consider our employee relations to be good. None of our employees is represented by a labor union or collective bargaining agreement.
Facilities
Our corporate headquarters are located in Davis, California, in a facility consisting of approximately 20,775 square feet of office, laboratory and growth chamber space under a lease that expires on June 30, 2018, pursuant to which we have an option to renew the lease for an additional three-year term. This facility accommodates research and development, operations, analytical services, regulatory and administrative activities. In December 2016, in connection with our organizational streamlining, we committed to consolidate our research facilities and began to wind down our Seattle research location, which is operating on a month-to-month lease, effective January 1, 2017. We expect the transfer of equipment and skills from our Seattle facility to be completed by March 2017. Our administrative offices in Phoenix, Arizona, consist of 2,976 square feet under a lease that expires on June 30, 2018 and accommodate our finance, legal and other administrative activities, as well as sales and marketing activities for our SONOVA products. We lease greenhouse space and farm land for agricultural use in Northern California as well as farmland in Idaho. We also lease grain bin and office space in Idaho under a lease that expires on March 3, 2019.
We believe that our leased facilities are adequate to meet our current needs and that, if needed, suitable additional or alternative space will be available to accommodate our operations.
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Segment
Refer to Note 14 – Segment and Geographic Information.
Item 1A. Risk Factors.
You should carefully consider the following risk factors, in addition to the other information contained in this report on Form 10K, including the section of this report titled “Management’s Discussion and Analysis of Financial Condition and Results of Operations” and our financial statements and related notes. If any of the events described in the following risk factors and the risks described elsewhere in this report occurs, our business, operating results and financial condition could be seriously harmed. This report on Form 10K also contains forward-looking statements that involve risks and uncertainties. Our actual results could differ materially from those anticipated in the forwardlooking statements as a result of factors that are described below and elsewhere in this report.
Risks Related to Our Business and Our Industry
We or our collaborators may not be successful in developing commercial products that incorporate our traits.
Our future growth depends on our ability to identify genes that will improve selected crop traits and license these genes to our collaborators to develop and commercialize seeds that contain the genes. Our long-term growth strategy is based on our expectation that revenues related to the sale of seeds containing our traits will comprise a significant portion of our future revenues. Pursuant to our collaboration agreements, we are entitled to share in the revenues from the sale of products that integrate our trait. We expect it will take several years before the first seeds integrating our agricultural yield traits complete the development process and become commercially available for sale, resulting in revenues for us. However, the development process could take longer than we anticipate or could ultimately fail to succeed in commercialization for any of the following reasons:
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our traits may not be successfully validated in one or more target crops;
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our traits may not have the desired effect sought by our collaborators in the relevant crop or geography, or under certain environmental conditions;
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relevant milestones under our agreements with collaborators may not be achieved; and
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we or our collaborators may be unable to complete the regulatory process for the products containing our traits.
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If products containing our traits are never commercialized, or are commercialized on a slower timeline than we anticipate, our ability to generate revenues and become profitable, as well as our long-term growth strategy, would be materially and adversely affected. For example, the development processes for several of our key agricultural yield traits have experienced delays related to regulatory matters, particularly in India, and we expect that these development processes may continue to face delays, which have negatively impacted the commercialization timelines for products containing such traits.
Even if we or our collaborators are successful in developing commercial products that incorporate our traits, such products may not achieve commercial success.
Our long-term growth strategy is dependent upon our or our collaborators’ ability to incorporate our traits into a wide range of crops with global scope. Even if we or our collaborators are able to develop commercial products that incorporate our traits, any such products may not achieve commercial success as quickly as we project, or at all, for one or more of the following reasons, among others:
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products may fail to be effective in particular crops, geographies or circumstances, limiting their commercialization potential;
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our competitors may launch competing or more effective traits or products;
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the market for abiotic seed traits is evolving and not well established, and the market opportunities for any product we or our collaborators develop may be smaller than we or our collaborators believe;
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as we do not have a sales or marketing infrastructure for our agricultural yield traits, we depend entirely on our collaborators to commercialize our products, and they may fail to devote the necessary resources and attention to sell, market and dis
tribute our current or any future products effectively;
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significant fluctuations in market prices for agricultural inputs and crops could have an adverse effect on the value of our traits;
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farmers are generally cautious in their adoption of new products and technologies, with conservative initial purchases and proof of product required prior to widespread deployment, and accordingly, it may take several growing seasons for farmers to adopt our or our collaborators’ products on a large scale;
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farmers may reuse certain non-hybrid GM seeds from prior growing seasons in violation of applicable seed license agreements;
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our collaborators may not be able to produce high-quality seeds in sufficient amounts to meet demand; and
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our collaborators may decide, for whatever reason, not to commercialize products containing our traits.
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Our financial condition and results of operations could be materially and adversely affected if any of the above were to occur.
Our product development cycle is lengthy and uncertain, and we may never earn revenues from the sale of products containing our traits.
Research and development in the seed, agricultural biotechnology, and larger agriculture industries is expensive, prolonged, and entails considerable uncertainty. We and our collaborators may spend many years and dedicate significant financial and other resources, developing traits that will never be commercialized. The process of discovering, developing, and commercializing a seed trait through either genetic modification or advanced breeding involves multiple phases, and it may require from six to thirteen years or more from discovery to commercialization. The length of the process may vary depending on one or more of the complexity of the trait, the particular crop, and the intended geographical market involved. This long product development cycle is in large part attributable to the nature-driven breeding period for a commercial product, as well as a lengthy regulatory process.
There are currently multiple products in development incorporating our traits, each of which consists of the application of a specific seed trait to a specific crop. Although our SONOVA products are on the market currently, we expect that it will take at least several years before the first products containing our agricultural yield traits complete the development process and become commercially available. However, we have little to no certainty as to which, if any, of these products will eventually reach commercialization in this timeframe or at all. Because of the long product development cycle and the complexities and uncertainties associated with agricultural biotechnology research, there is significant uncertainty as to whether we will ever generate revenues from the sale of products containing one of our traits and, even if such products reach commercialization, any resulting revenues may come at a later time than we currently anticipate.
We have a history of significant losses, which we expect to continue, and we may never achieve or maintain profitability.
We have incurred significant net losses since our formation in 2002 and expect to continue to incur net losses for the foreseeable future. We incurred net losses of $19.6 million, and $18.0 million for the years ended December 31, 2016 and 2015, respectively. As of December 31, 2016, we had an accumulated deficit of $151.6 million. We expect to continue to incur losses until we begin generating revenues from our collaborators’ sale of products containing traits we are currently developing, which we expect will not occur for several years, if at all. Because we have incurred and will continue to incur significant costs and expenses for these efforts before we obtain any incremental revenues from the sale of seeds incorporating our traits, our losses in future periods could be even more significant. In addition, we may find our development efforts are more expensive than we anticipate or that they do not generate revenues in the time period we anticipate, which would further increase our losses. If we are unable to adequately control the costs associated with operating our business, including costs of development and commercialization of our traits, our business, financial condition, operating results, and prospects will suffer.
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In addition, our abili
ty to generate meaningful revenues and achieve and maintain profitability depends on our ability, alone or with strategic collaborators, to successfully complete the development of and complete the regulatory process to commercialize our traits. Most of ou
r revenues since inception have consisted of upfront and milestone payments associated with our contract research and license agreements. Additional revenues from these agreements are largely dependent on successful development of our traits by us or our c
ollaborators. To date, we have not generated any significant revenues from product sales other than from our SONOVA products, and we do not otherwise anticipate generating revenues from product sales other than from sales of our SONOVA products for the nex
t several years. If products containing our traits fail to achieve market acceptance or generate significant revenues, we may never become profitable.
We may require additional financing in the future and may not be able to obtain such financing on favorable terms, if at all, which could force us to delay, reduce, or eliminate our research and development activities.
We will continue to need capital to fund our research and development projects and to provide working capital to fund other aspects of our business. If our capital resources are insufficient to meet our capital requirements, we will have to raise additional funds. If future financings involve the issuance of equity securities, our existing stockholders would suffer dilution. If we are able to raise additional debt financing, which will require the consent of our current debt holder, we may be subject to additional restrictive covenants that limit our operating flexibility. We may not be able to raise sufficient additional funds on terms that are favorable to us, if at all. If we fail to raise sufficient funds and continue to incur losses, our ability to fund our operations, take advantage of strategic opportunities, develop and commercialize products or technologies, or otherwise respond to competitive pressures could be significantly limited. If this happens, we may be forced to delay or terminate research and development programs or the commercialization of products, or curtail operations. If adequate funds are not available, we will not be able to successfully execute on our business strategy or continue our business.
If ongoing or future field trials by us or our collaborators are unsuccessful, we may be unable to complete the regulatory process for, or commercialize, our products in development on a timely basis.
The successful completion of field trials in United States and foreign locations is critical to the success of product development and marketing efforts for products containing our traits. If our ongoing or future field trials, or those of our collaborators, are unsuccessful or produce inconsistent results or unanticipated adverse effects on crops or on non-target organisms, or if we or our collaborators are unable to collect reliable data, regulatory review of products in development containing our traits could be delayed or commercialization of products in development containing our traits may not be possible. In addition, more than one growing season may be required to collect sufficient data to develop or market a product containing our traits, and it may be necessary to collect data from different geographies to prove performance for customer adoption. Even in cases where field trials are successful, we cannot be certain that additional field trials conducted on a greater number of acres, or in different crops or geographies, will be successful. Generally, our collaborators conduct these field trials or we pay third parties, such as farmers, consultants, contractors, and universities, to conduct field trials on our behalf. Poor trial execution or data collection, failure to follow required agronomic practices, regulatory requirements, or mishandling of products in development by our collaborators or these third parties could impair the success of these field trials.
Many factors that may adversely affect the success of our field trials are beyond our control, including weather and climatic variations, such as drought or floods, severe heat or frost, hail, tornadoes and hurricanes, uncommon pests and diseases, or acts of protest or vandalism. For example, if there was prolonged or permanent disruption to the electricity, climate control, or water supply operating systems in our greenhouses or laboratories, the crops in which we or our collaborators are testing our traits and the samples we or our collaborators store in freezers, both of which are essential to our research and development activities, could be severely damaged or destroyed, adversely affecting these activities and thereby our business and results of operations. Unfavorable weather conditions can also reduce both acreage planted and incidence, or timing of, certain crop diseases or pest infestations, each of which may halt or delay our field trials. We have also experienced crop failures in the past for then-unknown reasons, causing delays in our achievement of milestones and delivery of results and necessitating that we repeat the impacted field trials. Any field test failure we may experience may not be covered by insurance and, therefore, could result in increased cost for the field trials and development of our traits, which may negatively impact our business and results of operations. Additionally, we are subject to U.S. Department of Agriculture, or USDA, regulations, which may require us to abandon a field trial or to purchase and destroy neighboring crops that
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are planted after our field trials have commenced. For example, while conducting early field trials for GLA safflower oil, we were forced to purchase and destroy an adjacent safflower crop when the placement of bee
hives by a third party altered the required isolation distance between our crop and the neighboring crop, requiring us to either purchase and destroy the adjacent crop or abandon our field trial. In order to prevent the significant delays that would resul
t from terminating our field trial, we decided to purchase and destroy the neighboring crop at a cost of approximately $30,000. Similar factors outside of our control can create substantial volatility relating to our business and results of operations.
Competition in traits and seeds is intense and requires continuous technological development, and, if we are unable to compete effectively, our financial results will suffer.
We face significant competition in the markets in which we operate. The markets for traits and agricultural biotechnology products are intensely competitive and rapidly changing. In most segments of the seed and agricultural biotechnology market, the number of products available to consumers is steadily increasing as new products are introduced. At the same time, the expiration of patents covering existing products reduces the barriers to entry for competitors. We may be unable to compete successfully against our current and future competitors, which may result in price reductions, reduced margins and the inability to achieve market acceptance for products containing our traits. In addition, several of our competitors have substantially greater financial, marketing, sales, distribution, research and development, and technical resources than us, and some of our collaborators have more experience in research and development, regulatory matters, manufacturing, and marketing. We anticipate increased competition in the future as new companies enter the market and new technologies become available. Our technologies may be rendered obsolete or uneconomical by technological advances or entirely different approaches developed by one or more of our competitors, which will prevent or limit our ability to generate revenues from the commercialization of our traits being developed.
We derive a significant portion of our current revenues from government agencies, which may not continue in the future and which may expose us to government audits and potential penalties.
We historically have derived a significant portion of our revenues from grants from U.S. government agencies. Our ability to obtain grants is subject to the availability of funds under applicable government programs and approval of our applications to participate in such programs. The application process for these grants is highly competitive. We may not be successful in obtaining any additional grants. Once we successfully obtain a grant, the awarding U.S. government agency has the right to decrease or discontinue funding on such a grant at any time. The recent political focus on reducing spending at the U.S. federal and state levels may reduce the scope and amount of funds dedicated to seed and agricultural biotechnology innovations, if such funds continue to be available at all. To the extent that we are unsuccessful in obtaining any additional government grants in the future or if funding is discontinued on an existing grant, we would lose a significant source of our current revenues.
To the extent that we do not comply with the specific requirements of a grant, amounts we invoice may not be paid and any of our existing grants or new grants that we may obtain in the future may be terminated or modified. In addition, our activities funded by our government grants are subject to audits by U.S. government agencies. As part of an audit, these agencies may review our performance, cost structures and compliance with applicable laws, regulations and standards, and the terms and conditions of the grant. An audit could result in a material adjustment to our results of operations and financial condition. Moreover, if an audit uncovers improper or illegal activities, we may also be subject to civil and criminal penalties and administrative sanctions, including termination of contracts, forfeiture of profits, suspension of payments, or fines, and we may be suspended or prohibited from doing business with the government. In addition, serious reputational harm or significant adverse financial effects could occur if allegations of impropriety are made against us, even if we are ultimately found to have done no wrong.
A significant portion of our revenues to date are from a limited number of strategic collaborations, and the termination of these collaborations would have a material adverse effect on our results of operations.
We derive a substantial amount of our revenues from a limited number of strategic collaborations, under which we generate revenues through licensing arrangements such as research and development payments, up-front payments, milestone payments, and, once a product is commercialized, a portion of the commercial value of the trait. A small number of commercial partners are expected to continue to account for a substantial amount of our
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revenues for the next several years, most notably among them
, Mahyco. Our agreements with Mahyco are terminable by Mahyco at will upon 90 days’ notice. The termination or non-renewal of our arrangements with Mahyco or our other commercial partners would have a material adverse effect on our business, financial cond
ition, results of operations, and prospects.
We expect to derive a substantial portion of our future revenues from commercial products sold outside the United States, which subjects us to additional business risks.
A significant number of our research and collaboration agreements include products under development for markets outside the United States. Our collaborators’ operations in these regions are subject to a variety of risks, including different regulatory requirements, uncertainty of contract and intellectual property rights, unstable political and regulatory environments, economic and fiscal instability, tariffs and other import and trade restrictions, restrictions on the ability to repatriate funds, business cultures accepting of various levels of corruption, and the impact of anti-corruption laws. These risks could result in additional cost, loss of materials, and delays in our commercialization timeline in international markets and have a negative effect on our operating results.
Revenues generated outside the United States could also be subject to increased difficulty in collecting delinquent or unpaid accounts receivables, adverse tax consequences, currency and exchange rate fluctuations, relatively high inflation, exchange control regulations, and governmental pricing directives. Acts of terror or war may impair our ability to operate in particular countries or regions and may impede the flow of goods and services between countries. Customers in these and other markets may be unable to purchase our products if their economies deteriorate, or it could become more expensive for them to purchase imported products in their local currency or sell their commodities at prevailing international prices, and we may be unable to collect receivables from such customers. If any of these risks materialize, our results of operations and profitability could be harmed.
We or our collaborators may fail to perform our respective obligations under contract research and collaboration agreements.
We are obligated under certain contract research agreements to perform research activities over a particular period of time. If we fail to perform our obligations under these agreements, in some cases our collaborators may terminate our agreements with them and in other cases our collaborators’ obligations may be reduced and, as a result, our anticipated revenues may decrease. In addition, any of our collaborators may fail to perform their obligations under the diligence timelines in our collaboration agreements, which may delay development and commercialization of products containing our traits and materially and adversely affect our future results of operations.
Furthermore, the various payments we receive from our collaborators are a significant source of our current revenues and are expected to be the largest source of our revenues in the future. If our collaborators do not make these payments, either due to financial hardship, disagreement as to whether such payments are owed under the relevant collaboration agreement, or for any other reason, our results of operations and business could be materially and adversely affected. If disagreements with a collaborator arise, any dispute with such collaborator may negatively affect our relationship with one or more of our other collaborators and may hinder our ability to enter into future collaboration agreements, each of which could negatively impact our business and results of operations.
Our prospects for successful development and commercialization of our products are dependent upon the research, development, commercialization, and marketing efforts of our collaborators.
We primarily rely on third parties for research, development, commercialization, and marketing of our products and products in development. Other than as provided for in our collaboration agreements, we have no control over the resources, time and effort that our collaborators may devote to the development of products incorporating our traits, and have limited access to information regarding or resulting from such programs. We are dependent on our third party collaborators to fund and conduct the research and development of product candidates, to complete the regulatory process, and for the successful marketing and commercialization of one or more of such products or products in development. Such success will be subject to significant uncertainty.
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Our ability to recognize revenues from successful collaborations may be impaired by multiple factors including:
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a collaborator may shift its priorities and resources away from our programs due to a change in business strategies, or a merger, acquisition, sale, or downsizing of its company or business unit;
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a collaborator may cease development in a specific crop area that is the subject of a collaboration agreement;
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a collaborator may change the success criteria for a particular program or product in development, thereby delaying or ceasing development of such program or product in development;
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a significant delay in initiation of certain development activities by a collaborator will also delay payment of milestones tied to such activities, thereby impacting our ability to fund our own activities;
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a collaborator could develop or acquire a product that competes, either directly or indirectly, with our current products or any future products;
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a collaborator with commercialization obligations may not commit sufficient financial or human resources to the marketing, distribution, or sale of a product;
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a collaborator with manufacturing responsibilities may encounter regulatory, resource, or quality issues and be unable to meet demand requirements;
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a collaborator may exercise its rights under the agreement to terminate our collaboration;
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a dispute may arise between us and a collaborator concerning the development and commercialization of a product in development, resulting in a delay in milestones, royalty payments, or termination of a program and possibly resulting in costly litigation or arbitration that may divert management attention and resources;
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a collaborator may not adequately protect the intellectual property rights associated with a product or product in development; and
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a collaborator may use our proprietary information or intellectual property in such a way as to expose us to litigation from a third party.
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If our collaborators do not perform in the manner we expect or fulfill their responsibilities in a timely manner, or at all, the development, regulatory, and commercialization process could be delayed, terminated, or otherwise unsuccessful. Conflicts between us and our collaborators may arise. In the event of termination of one or more of our collaboration agreements, it may become necessary for us to assume the responsibility for any terminated products or products in development at our own expense or seek new collaborators. In that event, we likely would be required to limit the size and scope of one or more of our independent programs or increase our expenditures and seek additional funding, which may not be available on acceptable terms or at all, and our business may be materially and adversely affected.
We rely on third parties to conduct, monitor, support, and oversee field trials and, in some cases, to maintain regulatory files for those products in development, and any performance issues by third parties, or our inability to engage third parties on acceptable terms, may impact our or our collaborators’ ability to complete the regulatory process for or commercialize such products.
We rely on third parties, including farmers, to conduct, monitor, support, and oversee field trials. As a result, we have less control over the timing and cost of these trials than if we conducted these trials with our own personnel. If we are unable to maintain or enter into agreements with these third parties on acceptable terms, or if any such engagement is terminated prematurely, we may be unable to conduct and complete our trials in the manner we anticipate. In addition, there is no guarantee that these third parties will devote adequate time and resources to our studies or perform as required by our contract or in accordance with regulatory requirements, including maintenance of field trial information regarding our products in development. If these third parties fail to meet expected deadlines, fail to transfer to us any regulatory information in a timely manner, fail to adhere to protocols, or fail to act in accordance with regulatory requirements or our agreements with them, or if they otherwise perform
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in a substandard manner or in a way that compromises the quality or accuracy of their
activities or the data they obtain, then field trials of our products in development may be extended or delayed with additional costs incurred, or our data may be rejected by the USDA, the U.S. Food and Drug Administration, or FDA, the U.S. Environmental
Protection Agency, or EPA, or other regulatory agencies. Ultimately, we are responsible for ensuring that each of our field trials is conducted in accordance with the applicable protocol, legal, regulatory and scientific standards, and our reliance on thir
d parties does not relieve us of our responsibilities.
If our relationship with any of these third parties is terminated, we may be unable to enter into arrangements with alternative parties on commercially reasonable terms, or at all. Switching or adding farmers or other suppliers can involve substantial cost and require extensive management time and focus. In addition, there is a natural transition period when a new farmer or other third party commences work. As a result, delays may occur, which can materially impact our ability to meet our desired development timelines. If we are required to seek alternative supply arrangements, the resulting delays and potential inability to find a suitable replacement could materially and adversely impact our business.
In addition, recently there has been an increasing trend towards consolidation in the agricultural biotechnology industry. For example, in April 2015, DuPont acquired Taxon Biosciences. Other potential transactions, such as Syngenta’s proposed takeover by ChemChina, the proposed merger of Dow and DuPont, and the proposed acquisition of Monsanto by Bayer, would further consolidate our industry if consummated. Consolidation among our competitors and third parties upon whom we rely could lead to a changing competitive landscape, capabilities, and market share allocations, which could have an adverse effect on our business and operations.
Most of our collaborators have significant resources and development capabilities and may develop their own products that compete with or negatively impact the advancement or sale of products containing our traits.
Most of our collaborators are significantly larger than us and may have substantially greater resources and development capabilities. As a result, we are subject to competition from many of our collaborators, who could develop or pursue competing products and traits that may ultimately prove more commercially viable than our traits. In addition, former collaborators, by virtue of having had access to our proprietary technology, may utilize this insight for their own development efforts, despite the fact that our collaboration agreements prohibit such use. The development or launch of a competing product by a collaborator may adversely affect the advancement and commercialization of any traits we develop and any associated research and development and milestone payments and value-sharing payments we receive from the sale of products containing our traits.
Our joint venture agreements could present a number of challenges that may have a material adverse effect on our business, financial condition, and results of operations.
We currently participate in two joint ventures, Limagrain Cereal Seeds LLC, which focuses on the development and commercialization of improved wheat seeds, and Verdeca LLC, which focuses on the development and deregulation of soybean traits, and we may enter into additional joint ventures in the future. Our joint venture arrangements may present financial, managerial, and operational challenges, including potential disputes, liabilities, or contingencies and may involve risks not otherwise present when operating independently, including:
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our joint venture partners may have business interests, goals or cultures that are or become inconsistent with our business interests, goals or culture;
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our joint venture partners may share certain approval rights, or in some cases, as with Limagrain Cereal Seeds LLC, have control over major decisions;
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our joint venture partners may not pay their share of the joint venture’s obligations, potentially leaving us liable for their share of such obligations, or we may be unable to pay our share of the joint venture’s obligations, which may result in a reduction of our ownership interest;
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we may incur liabilities or losses as a result of an action taken by the joint venture or our joint venture partners;
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our joint venture partners may take action contrary to our instructions, requests, policies or objectives, which could reduce our return on investment, harm our reputation or
restrict our ability to run our business; and
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disputes between us and our joint venture partners may result in delays, litigation or operational impasses.
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The risks described above or the failure to continue any joint venture or joint development arrangement or to resolve disagreements with our current or future joint venture partners could materially and adversely affect our ability to transact the business that is the subject of such joint venture, which would in turn negatively affect our financial condition and results of operations.
We and our collaborators may disagree over our right to receive payments under our collaboration agreements, potentially resulting in costly litigation and loss of reputation.
Our ability to receive payments under our collaboration agreements depends on our ability to clearly delineate our rights under those agreements. We typically license our intellectual property to our collaborators, who then develop and commercialize seeds with improved traits. However, a collaborator may use our intellectual property without our permission, dispute our ownership of certain intellectual property rights, or argue that our intellectual property does not cover, or add value to, their marketed product. If a dispute arises, it may result in costly patent office procedures and litigation, and our collaborator may refuse to pay us while the dispute is ongoing. Furthermore, regardless of any resort to legal action, a dispute with a collaborator over intellectual property rights may damage our relationship with that collaborator and may also harm our reputation in the industry.
Even if we are entitled to payments from our collaborators, we may not actually receive these payments, or we may experience difficulties in collecting the payments to which we believe we are entitled. After our collaborators launch commercial products containing our licensed traits, we will need to rely on the good faith of our collaborators to report to us the sales they earn from these products and to accurately calculate the payments we are entitled to, a process that will involve complicated and difficult calculations. Although we seek to address these concerns in our collaboration agreements by reserving our right to audit financial records, such provisions may not be effective.
Our business is subject to various government regulations and if we or our collaborators are unable to timely complete the regulatory process for our products in development, our or our collaborators’ ability to market our traits could be delayed, prevented or limited.
Our business is generally subject to two types of regulations: regulations that apply to how we and our collaborators operate and regulations that apply to products containing our traits. We apply for and maintain the regulatory permits necessary for our operations, particularly those covering our field trials, while we or our collaborators apply for and maintain regulatory approvals necessary for the commercialization of products containing our seed traits. The large-scale field trials that our collaborators conduct during advanced stages of product development are subject to regulations similar to those to which we are subject. Even if we and our collaborators make timely and appropriate applications for regulatory permits for our field trials, government delays in issuing such permits can significantly affect the development timelines for our products, particularly if the planting period for a crop growing season expires before the necessary permits are obtained. For example, our collaborator in India has encountered and continues to encounter delays in obtaining necessary regulatory permits for field trials, and these delays have had a negative impact on the commercialization timelines for certain of our products and may have additional future negative impacts. Pursuant to our collaboration agreements, our collaborators also apply for the requisite regulatory approvals prior to commercialization of products containing our traits. In most of our key target markets, regulatory approvals must be received prior to the importation of genetically modified products. These regulatory processes may be complex; for example, the U.S. federal government’s regulation of biotechnology is divided among the EPA, which regulates activity related to the use of plant pesticides and herbicides, the USDA, which regulates the import, field testing, interstate movement, and environmental release of specific technologies that may be used in the creation of genetically modified plants, and the FDA, which regulates foods derived from new plant varieties.
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In addition to regulation by the U.S. government, products containing our biotech traits may be subject to regulation in each country in which such products are tested or sold. International regulations may vary
from country to country and from those of the United States. The difference in regulations under U.S. law and the laws of foreign countries may be significant and, in order to comply with the laws of foreign countries, we may have to implement global chang
es to our products or business practices. Such changes may result in additional expense to us and either reduce or delay product development or sales. Additionally, we or our collaborators may be required to obtain certifications or approvals by foreign go
vernments to test and sell the products in foreign countries.
The regulatory process is expensive and time-consuming, and the time required to complete the process is difficult to predict and depends upon numerous factors, including the substantial discretion of the regulatory authorities. Other than for our SONOVA products, neither we nor our collaborators have completed all phases of the regulatory process for any of our products in development. Our traits could require a significantly longer time to complete the regulatory process than expected, or may never gain approval, even if we and our collaborators expend substantial time and resources seeking such approval. A delay or denial of regulatory approval could delay or prevent our ability to generate revenues and to achieve profitability. For example, we are currently awaiting completion of the regulatory process for one of our SONOVA products to be used in pet food, which has taken longer than expected. Changes in regulatory review policies during the development period of any of our traits, changes in, or the enactment of, additional regulations or statutes, or changes in regulatory review practices for a submitted product application may cause a delay in obtaining approval or result in the rejection of an application for regulatory approval. Regulatory approval, if obtained, may be made subject to limitations on the indicated uses for which we or our collaborators may market a product. These limitations could adversely affect our potential revenues. Failure to comply with applicable regulatory requirements may, among other things, result in fines, suspensions of regulatory approvals, product recalls, product seizures, operating restrictions, and criminal prosecution. We have on certain occasions notified the USDA of instances of noncompliance with regulations. Although these occasions did not result in any enforcement actions, we may have occasions of noncompliance in the future that result in USDA or other governmental agency enforcement action.
Consumer resistance to genetically modified organisms may negatively affect our public image and reduce sales of seeds containing our traits.
We are active in the field of agricultural biotechnology research and development in seeds and crop protection, including GM seeds. Foods made from such seeds are not accepted by many consumers due to concerns over such products’ effects on food safety and the environment. The high public profile of biotechnology in food production and lack of consumer acceptance of products to which we have devoted substantial resources could negatively affect our public image and results of operations. The current resistance from consumer groups, particularly in Europe, to GM crops not only limits our access to such markets, but also has the potential to spread to and influence the acceptance of products developed through biotechnology in other regions of the world. For example, we temporarily suspended certain initiatives in response to legislative requirements in Vermont related to labeling of food products containing GM ingredients until it was determined that there would be clarity and uniformity in nationwide food labeling requirements. Certain labeling-related initiatives have heightened consumer awareness of GM crops generally and may make consumers less likely to purchase food products containing GM ingredients, which could have a negative impact on the commercial success of products that incorporate our traits and materially and adversely affect our financial condition and results of operations.
Governmental restrictions on the testing, production, and importation of GM crops may negatively affect our business and results of operations.
The production of certain GM crops is effectively prohibited in certain countries, including throughout the European Union, which limits our commercial opportunities and may influence regulators in other countries to limit or ban the testing, production, or importation of GM crops and products of GM crops. Our GM crops are grown principally in North America, South America, India and Australia, where there are fewer restrictions on the production of GM crops. If these or other countries where our GM crops are grown enact laws or regulations that ban the production of such crops or make regulations more stringent, we could experience a longer product development cycle for our products, encounter difficulty obtaining intellectual property protection, and may even have to abandon projects related to certain crops or geographies, any of which would negatively affect our business and results of operations. Furthermore, any changes in such laws and regulations or consumer acceptance of our GM
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crops and products made from these crops could negatively impact our collaborators, who in turn might terminate or r
educe the scope of their collaborations with us or seek to alter the financial terms of our agreements with them.
Changes in laws and regulations to which we are subject, or to which we may become subject in the future, may materially increase our costs of operation, decrease our operating revenues, and disrupt our business.
Laws and regulatory standards and procedures that impact our business are continuously changing. Responding to these changes and meeting existing and new requirements may be costly and burdensome. Changes in laws and regulations could:
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impair or eliminate our ability, or increase our cost, to develop our traits, including validating our products in development through field trials;
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increase our compliance and other costs of doing business through increases in the cost to patent or otherwise protect our intellectual property or increases in the cost to our collaborators to complete the regulatory process to commercialize and market the products we develop with them;
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render any products less profitable, obsolete, or less attractive compared to competing products;
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affect our collaborators’ willingness to do business with us;
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reduce the amount of revenues we receive from our collaborators; and
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discourage our collaborators from offering, and consumers from purchasing, products that incorporate our traits.
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Any of these events could have a material adverse effect on our business, results of operations, and financial condition. Legislators and regulators have increased their focus on plant biotechnology in recent years, with particular attention paid to GM crops.
Our future growth relies on the ability of our collaborators to commercialize and market our products in development, and any restrictions on such activities could materially and adversely impact our business and results of operations. Any changes in regulations in countries where GM crops are grown or imported could result in our collaborators being unable or unwilling to develop, commercialize, or sell products that incorporate our traits. Any changes to these existing laws and regulations may also materially increase our costs of operation, decrease our operating revenues, and disrupt our business.
The unintended presence of our traits in other products or plants may negatively affect us.
Trace amounts of our traits may unintentionally be found outside our containment area in the products of third parties, which may result in negative publicity and claims of liability brought by such third parties against us. Furthermore, in the event of an unintended dissemination of our genetically engineered materials to the environment or the presence of unintended but unavoidable trace amounts, sometimes called “adventitious presence,” of our traits in conventional seed, or in the grain or products produced from conventional or organic crops, we could be subject to claims by multiple parties, including environmental advocacy groups, as well as governmental actions such as mandated crop destruction, product recalls, or additional stewardship practices and environmental cleanup or monitoring.
Loss of or damage to our germplasm collection would significantly slow our product development efforts.
We have developed and maintain a comprehensive collection of germplasm through strategic collaborations with leading institutions, which we utilize in our non-GM programs. Germplasm comprises collections of genetic resources covering the diversity of a crop, the attributes of which are inherited from generation to generation. Germplasm is a key strategic asset since it forms the basis of seed development programs. To the extent that we lose access to such germplasm because of the termination or breach of our collaboration agreements, our product development capabilities would be severely limited. In addition, loss of or damage to these germplasm collections would significantly impair our research and development activities. Although we restrict access to our germplasm at our research facilities to protect this valuable resource, we cannot guarantee that our efforts to protect our
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germplasm collection will be successful. The destruction or theft of a significant portion of our germplasm collection would adversely affect our business and results of operations.
We depend on our key personnel and, if we are not able to attract and retain qualified scientific and business personnel, we may not be able to grow our business or develop and commercialize our products.
Our future performance depends on the continued services and contributions of our management team and other key employees, the loss of whose services might significantly delay or prevent the achievement of our scientific or business objectives. The replacement of any member of our management team involves significant time and costs and such loss could significantly delay or prevent the achievement of our business objectives. A member of our executive team who has been our employee for many years and therefore has significant experience and understanding of our business that would be difficult to replace.
Additionally, the vast majority of our workforce is involved in research, development, and regulatory activities. Our business is therefore dependent on our ability to recruit and maintain a highly skilled and educated workforce with expertise in a range of disciplines, including molecular biology, biochemistry, plant genetics, agronomics, mathematics, agribusiness, and other subjects relevant to our operations. All of our current employees are at-will employees, and the failure to retain or hire skilled and highly educated personnel could limit our growth and hinder our research and development efforts.
Our business is subject to the risks of earthquakes, fire, flood, and other catastrophic natural events, and security breaches, including cybersecurity incidents.
Our headquarters, certain research and development operations and our seed storage warehouse are located in Davis, California. The safflower grain used in the production of our SONOVA products is grown in several locations throughout Idaho and is stored in a single facility in Idaho. Our production of our SONOVA products takes place at a single facility in Northern California, and the inventory is stored in a single cold storage facility in Northern California. We take precautions to safeguard our facilities, including insurance, health and safety protocols, and off-site storage of critical research results and computer data. However, a natural disaster, such as a fire, flood, or earthquake, could cause substantial delays in our operations, damage or destroy our equipment, inventory, or development projects, and cause us to incur additional expenses. The insurance we maintain against natural disasters may not be adequate to cover our losses in any particular case.
We utilize and critically rely upon information technology systems in all aspects of our business, including increasingly large amounts of data to support our products and advance our research and development. Failure to effectively prevent, detect, and recover from the increasing number and sophistication of information security threats could result in theft, misuse, modification, and destruction of information, including trade secrets and confidential business information, and cause business disruptions, delays in research and development, and reputational damage, which could significantly affect our results of operations and financial condition.
Disruption to our IT system could adversely affect our reputation and have a material adverse effect on our business and results of operations.
Our technologies rely on our IT system to collect and analyze our genomic data, including TILLING and other experimental data, and manage our plant inventory system, which tracks every plant that we have ever produced. We can provide no assurance that our current IT system is fully protected against third-party intrusions, viruses, hacker attacks, information, or data theft, or other similar threats. Furthermore, we store significant amounts of data and, though we are developing back-up storage for our stored data, we cannot assure you that our back-up storage arrangements will be effective if it becomes necessary to rely on them.
If our IT system does not function properly or proves incompatible with new technologies, we could experience interruptions in data transmissions and slow response times, preventing us from completing routine research and business activities. Furthermore, disruption or failure of our IT system due to technical reasons, natural disaster, or other unanticipated catastrophic events, including power interruptions, storms, fires, floods, earthquakes, terrorist attacks, and wars could significantly impair our ability to deliver data related to our projects to our
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collaborators on schedule and materially and adversely affect the outcome of our collabor
ations, our relationships with our collaborators, our business, and our results of operations.
Our use of hazardous materials exposes us to potential liabilities.
Certain of our operations involve the storage and controlled use of hazardous materials, including laboratory chemicals, herbicides, and pesticides. This requires us to conduct our operations in compliance with applicable environmental and safety standards, and we cannot completely eliminate the risk of accidental contamination from hazardous materials. In the event of such contamination, we may be held liable for significant damages or fines, which could have a material adverse effect on our business and operating results.
Most of the licenses we grant to our collaborators to use our proprietary genes in certain crops are exclusive within certain jurisdictions, which limits our licensing opportunities.
Most of the licenses we grant our collaborators to use our proprietary genes in certain crops are exclusive within specified jurisdictions, so long as our collaborators comply with certain diligence requirements. That means that once genes are licensed to a collaborator in a specified crop or crops, we are generally prohibited from licensing those genes to any third party. The limitations imposed by these exclusive licenses could prevent us from expanding our business and increasing our product development initiatives with new collaborators, both of which could adversely affect our business and results of operations.
Our business model for discovery of genes is dependent on licensing patent rights from third parties, and any disruption of this licensing process could adversely affect our competitive position and business prospects.
Our business model involves acquiring technologies that have achieved proof of concept through rigorous development and testing by third-party basic researchers in order to avoid the significant risks and high costs associated with basic research. Only a small number of the genes we evaluate for acquisition are likely to provide viable commercial candidates and an even more limited number, if any, are likely to be commercialized by us or our collaborators. A failure by us to continue identifying genes that improve specific crop traits could make it difficult to grow our business. If we are unable to identify additional genes, we may be unable to develop new traits, which may negatively impact our ability to generate revenues.
If we are unable to enter into licensing arrangements to acquire rights to these potentially viable genes on favorable terms in the future, it may adversely affect our business. In addition, if the owners of the patents we license do not properly maintain or enforce the patents underlying such licenses, our competitive position and business prospects could be harmed. Without protection for the intellectual property we license, other companies might be able to offer substantially similar or identical products for sale, which could adversely affect our competitive business position and harm our business prospects.
If we fail to comply with our obligations under license agreements, our counterparties may have the right to terminate these agreements, in which event we may not be able to develop, manufacture, register, or market, or may be forced to cease developing, manufacturing, registering, or marketing, any product that is covered by these agreements or may face other penalties under such agreements. Such an occurrence could materially adversely affect the value of the applicable products to us and have an adverse effect on our business and result of operations.
Our success depends on our ability to protect our intellectual property and our proprietary technologies.
Our commercial success depends, in part, on our ability to obtain and maintain patent and trade secret protection for our proprietary technologies, our traits, and their uses, as well as our ability to operate without infringing upon the proprietary rights of others. If we do not adequately protect our intellectual property, competitors may be able to use our technologies and erode or negate any competitive advantage we may have, which could harm our business and ability to achieve profitability.
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If we are unable to protect the confidentiality of our trade secrets, the value of our technology coul
d be materially and adversely affected and our business could be harmed.
We treat our proprietary technologies, including unpatented know-how and other proprietary information, as trade secrets. We seek to protect these trade secrets, in part, by entering into non-disclosure and confidentiality agreements with any third parties who have access to them, such as our consultants, independent contractors, advisors, corporate collaborators, and outside scientific collaborators. We also enter into confidentiality and invention or patent assignment agreements with employees and certain consultants. Any party with whom we have executed such an agreement could breach that agreement and disclose our proprietary information, including our trade secrets, and we may not be able to obtain adequate remedies for such breaches. Enforcing a claim that a party illegally disclosed or misappropriated a trade secret is difficult, expensive, and time consuming, and the outcome is unpredictable. In addition, if any of our trade secrets were to be lawfully obtained or independently developed by a competitor, we would have no right to prevent such third party, or those to whom they communicate such technology or information, from using that technology or information to compete with us. If any of our trade secrets were to be disclosed to or independently developed by a competitor, or if we otherwise lose protection for our trade secrets or proprietary know-how, the value of this information may be greatly reduced and our business and competitive position could be harmed.
Changes in U.S. patent law could diminish the value of patents in general, thereby impairing our ability to protect our products in development.
As an agricultural biotechnology company, our success is heavily dependent on intellectual property, particularly patents. Obtaining and enforcing patents involves technological and legal complexity, and is costly, time consuming, and inherently uncertain. In addition, the U.S. Supreme Court has ruled on several patent cases in recent years, either narrowing the scope of patent protection available in certain circumstances or weakening the rights of patent owners in certain situations. In addition to increasing uncertainty with regard to our ability to obtain patents in the future, this combination of events has created uncertainty with respect to the value of patents once obtained. Depending on decisions by the U.S. Congress, the federal courts, and the U.S. Patent and Trademark Office, the laws and regulations governing patents could change in unpredictable ways that may weaken or undermine our ability to obtain new patents or to enforce our existing patents and patents we might obtain in the future.
We may not be able to protect our intellectual property rights throughout the world.
Filing, prosecuting, maintaining, and defending patents on products in development in all countries throughout the world would be prohibitively expensive, and our intellectual property rights in some countries outside the United States are less extensive than those in the United States. In addition, the laws of some foreign countries do not protect intellectual property rights to the same extent as federal and state laws in the United States. For example, several countries outside the United States prohibit patents on plants and seeds entirely. In addition, we may at times license third-party technologies for which limited international patent protection exists and for which the time period for filing international patent applications has passed. Consequently, we are unable to prevent third parties from using intellectual property we develop or license in all countries outside the United States, or from selling or importing products made using our intellectual property in and into the jurisdictions in which we do not have patent protection. Competitors may use our technologies in jurisdictions where we have not obtained patent protection to develop their own products, and we may be unable to prevent such competitors from importing those infringing products into territories where we have patent protection, but where enforcement is not as strong as in the United States. These products may compete with our products in development and our patents and other intellectual property rights may not be effective or sufficient to prevent them from competing in those jurisdictions. Moreover, farmers or others in the chain of commerce may raise legal challenges to our intellectual property rights or may infringe upon our intellectual property rights, including through means that may be difficult to prevent or detect, and local regulators may choose to not enforce our intellectual property rights.
Many companies have encountered significant problems in protecting and defending intellectual property rights in foreign jurisdictions where we have filed patent applications. The legal systems of certain countries have not historically favored the enforcement of patents or other intellectual property rights, which could hinder us from preventing the infringement of our patents or other intellectual property rights and result in substantial risks to us. Proceedings to enforce our patent rights in the United States or foreign jurisdictions could result in substantial costs
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and divert our efforts and attention from other aspects of
our business, could put our patents at risk of being invalidated or interpreted narrowly and our patent applications at risk of not issuing and could provoke third parties to assert patent infringement or other claims against us. We may not prevail in any
lawsuits that we initiate and the damages or other remedies awarded, if any, may not be commercially meaningful or even cover our associated legal costs. Accordingly, our efforts to enforce our intellectual property rights around the world may be inadequat
e to obtain a significant commercial advantage from the intellectual property that we develop or license from third parties.
If we or one of our collaborators are sued for infringing the intellectual property rights of a third party, such litigation could be costly and time consuming and could prevent us or our collaborators from developing or commercializing our products.
Our ability to generate significant revenues from our products depends on our and our collaborators’ ability to develop, market and sell our products and utilize our proprietary technology without infringing the intellectual property and other rights of any third parties. In the United States and abroad there are numerous third-party patents and patent applications that may be applied toward our proprietary technology, business processes, or developed traits, some of which may be construed as containing claims that cover the subject matter of our products or intellectual property. Because of the rapid pace of technological change, the confidentiality of patent applications in some jurisdictions (including U.S. provisional patent applications), and the fact that patent applications can take many years to issue, there may be currently pending applications that are unknown to us that may later result in issued patents upon which our products in development or proprietary technologies infringe. Similarly, there may be issued patents relevant to our products in development of which we are not aware. These patents could reduce the value of the traits we develop or the genetically modified plants containing our traits or, to the extent they cover key technologies on which we have unknowingly relied, require that we seek to obtain licenses or cease using the technology, no matter how valuable to our business. We may not be able to obtain such a license on commercially reasonable terms. If any third party patent or patent application covers our intellectual property or proprietary rights and we are not able to obtain a license to it, we and our collaborators may be prevented from commercializing products containing our traits.
As the agricultural biotechnology industry continues to develop, we may become party to, or threatened with, litigation or other adverse proceedings regarding intellectual property or proprietary rights in our technology, processes, or developed traits. Third parties may assert claims based on existing or future intellectual property rights and the outcome of any proceedings is subject to uncertainties that cannot be adequately quantified in advance. Any litigation proceedings could be costly and time consuming, and negative outcomes could result in liability for monetary damages, including treble damages and attorneys’ fees, if we are found to have willfully infringed a patent. There is also no guarantee that we would be able to obtain a license under such infringed intellectual property on commercially reasonable terms or at all. A finding of infringement could prevent us or our collaborators from developing, marketing or selling a product or force us to cease some or all of our business operations. Even if we are successful in these proceedings, we may incur substantial costs and the time and attention of our management and scientific personnel may be diverted as a result of these proceedings, which could have a material adverse effect on us. Claims that we have misappropriated the confidential information or trade secrets of third parties could similarly have a negative impact on our business.
Our results of operations will be affected by the level of royalty payments that we are required to pay to third parties.
We are a party to license agreements that require us to remit royalty payments and other payments related to in-licensed intellectual property. Under our in-license agreements, we may pay up-front fees and milestone payments and be subject to future royalties. We cannot precisely predict the amount, if any, of royalties we will owe in the future, and if our calculations of royalty payments are incorrect, we may owe additional royalties, which could negatively affect our results of operations. As our product sales increase, we may, from time to time, disagree with our third-party collaborators as to the appropriate royalties owed and the resolution of such disputes may be costly and may consume management’s time. Furthermore, we may enter into additional license agreements in the future, which may also include royalty, milestone and other payments.
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We are subject to governmental export and import controls that could impair our a
bility to compete in international markets due to licensing requirements and subject us to liability if we are not in compliance with applicable laws.
Our products and products in development are subject to export control and import laws and regulations, including the U.S. Export Administration Regulations, U.S. Customs regulations, and various economic and trade sanctions regulations administered by the U.S. Treasury Department’s Office of Foreign Assets Controls. Exports of our products and technology must be made in compliance with these laws and regulations. If we fail to comply with these laws and regulations, we and certain of our employees could be subject to substantial civil or criminal penalties, including the possible loss of export or import privileges; fines, which may be imposed on us and responsible employees or managers; and, in extreme cases, the incarceration of responsible employees or managers.
In addition, changes in our products or solutions or changes in applicable export or import laws and regulations may create delays in the introduction and sale of our products and solutions in international markets, prevent our customers from deploying our products and solutions or, in some cases, prevent the export or import of our products and solutions to certain countries, governments or persons altogether. Any change in export or import laws and regulations, shift in the enforcement or scope of existing laws and regulations, or change in the countries, governments, persons or technologies targeted by such laws and regulations, could also result in decreased use of our products and solutions, or in our decreased ability to export or sell our products and solutions to existing or potential customers. Any decreased use of our products and solutions or limitation on our ability to export or sell our products and solutions would likely adversely affect our business, financial condition and results of operations.
We are subject to anti-corruption and anti-money laundering laws with respect to both our domestic and international operations, and non-compliance with such laws can subject us to criminal and civil liability and harm our business.
We are subject to the U.S. Foreign Corrupt Practices Act of 1977, as amended, the U.S. domestic bribery statute contained in 18 U.S.C. § 201, the U.S. Travel Act, the USA PATRIOT Act, and possibly other anti-bribery and anti-money laundering laws in countries in which we conduct activities. Anti-corruption laws are interpreted broadly and prohibit us and our collaborators from authorizing, offering, or directly or indirectly providing improper payments or benefits to recipients in the public or private sector. We or our collaborators may have direct and indirect interactions with government agencies and state-affiliated entities and universities in the course of our business. We may also have certain matters come before public international organizations such as the United Nations. We use third-party collaborators, joint venture and strategic partners, law firms, and other representatives for regulatory compliance, patent registration, lobbying, deregulation advocacy, field testing, and other purposes in a variety of countries, including those that are known to present a high corruption risk such as India, China, and Latin American countries. We can be held liable for the corrupt or other illegal activities of these third-party collaborators, our employees, representatives, contractors, partners, and agents, even if we do not explicitly authorize such activities. In addition, although we have implemented policies and procedures to ensure compliance with anti-corruption and related laws, there can be no assurance that all of our employees, representatives, contractors, partners, or agents will comply with these laws at all times. Noncompliance with these laws could subject us to whistleblower complaints, investigations, sanctions, settlements, prosecution, other enforcement actions, disgorgement of profits, significant fines, damages, other civil and criminal penalties or injunctions, suspension and debarment from contracting with certain governments or other persons, the loss of export privileges, reputational harm, adverse media coverage, and other collateral consequences. If any subpoenas or investigations are launched, or governmental or other sanctions are imposed, or if we do not prevail in any possible civil or criminal litigation, our business, results of operations, and financial condition could be materially harmed. In addition, responding to any action will likely result in a materially significant diversion of management’s attention and resources and significant defense costs and other professional fees. Enforcement actions and sanctions could further harm our business, results of operations, and financial condition.
Adverse outcomes in future legal proceedings could subject us to substantial damages and adversely affect our results of operations and profitability.
We may become party to legal proceedings, including matters involving personnel and employment issues, personal injury, environmental matters, and other proceedings. Some of these potential proceedings could result in
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substantial damages or payment awards that exceed our insurance coverage. We will estimate our exposure to any future legal proceedings and e
stablish provisions for the estimated liabilities where it is reasonably possible to estimate and where an adverse outcome is probable. Assessing and predicting the outcome of these matters will involve substantial uncertainties. Furthermore, even if the o
utcome is ultimately in our favor, our costs associated with such litigation may be material. Adverse outcomes in future legal proceedings or the costs and expenses associated therewith could have an adverse effect on our results of operations.
We may be required to pay substantial damages as a result of product liability claims for which insurance coverage is not available.
We are subject to product liability claims with respect to our SONOVA products, and as additional products integrating our traits reach commercialization, product liability claims will increasingly be a commercial risk for our business, particularly as we are involved in the supply of biotechnological products, some of which may be harmful to humans and the environment. Product liability claims against us or our collaborators selling products that contain our traits, or allegations of product liability relating to seeds containing traits developed by us, could damage our reputation, harm our relationships with our collaborators, and materially and adversely affect our business, results of operations, financial condition, and prospects. Furthermore, while our collaboration agreements typically require that our collaborators indemnify us for the cost of product liability claims brought against us as a result of our collaborator’s misconduct, such indemnification provisions may not always be enforced, and we may receive no indemnification if our own misconduct contributed to the claims.
We may seek to expand through acquisitions of and investments in other brands, businesses, and assets. These acquisition activities may be unsuccessful or divert management’s attention.
We may consider strategic and complementary acquisitions of and investments in other agricultural biotechnology brands, businesses or other assets, and such acquisitions or investments are subject to risks that could affect our business, including risks related to:
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the necessity of coordinating geographically disparate organizations;
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implementing common systems and controls;
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integrating personnel with diverse business and cultural backgrounds;
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integrating acquired manufacturing and production facilities, technology and products;
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combining different corporate cultures and legal systems;
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unanticipated expenses related to integration, including technical and operational integration;
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increased costs and unanticipated liabilities, including with respect to registration, environmental, health and safety matters, that may affect sales and operating results;
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retaining key employees;
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obtaining required government and third-party approvals;
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legal limitations in new jurisdictions;
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installing effective internal controls and audit procedures;
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issuing common stock that could dilute the interests of our existing stockholders;
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spending cash and incurring debt;
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assuming contingent liabilities; and
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creating additional expenses.
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We may not be able to identify opportunities or complete transactions on commercially reasonable terms, or at all, or actually realize any anticipated benefits from such acquisitions or investments. Similarly, we may not be able to obtain financing for acquisitions or investments on attractive terms. In addition, the success of any acquisitions or
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investments also will depend, in part, on our ability to integrate the acquisition
or investment with our existing operations.
We have recently experienced changes in our management team, which may cause transition problems in our business.
We recently have had significant changes in executive leadership, and more could occur. Vic C. Knauf served as our Chief Scientific Officer until his retirement in December 2016. Wendy Neal served as our Vice President and Chief Legal Officer until her termination in February 2017. The Company plans to hire a Vice President of Research and & Development and a General Counsel to fill their respective roles. In addition, Roger Salameh was appointed Chief Operating Officer in May 2016 and served in the position until his termination in February 2017. The Company has no plans to fill the Chief Operating Officer role, and his duties have been assumed by existing staff. Disruption to our organization as a result of executive management transition could have a material adverse effect on our business, financial condition and results of operations.
We incur significant costs and devote substantial management time as a result of operating as a public company, and our management team has limited experience managing a public company.
As a public company, we incur significant legal, accounting, and other expenses that we did not incur as a private company. For example, we are subject to the reporting requirements of the Securities Exchange Act of 1934, as amended, or the Exchange Act, and are required to comply with the applicable requirements of the Sarbanes-Oxley Act and the Dodd-Frank Wall Street Reform and Consumer Protection Act, as well as rules and regulations subsequently implemented by the SEC and The Nasdaq Stock Market, including the establishment and maintenance of effective disclosure and financial controls and corporate governance practices. Compliance with these requirements has increased and will continue to increase our legal and financial compliance costs and has made and will continue to make some activities more time consuming and costly. Our management and other personnel has had to and will continue to divert attention from operational and other business matters to devote substantial time to these public company requirements, which could adversely affect our business, financial condition, and operating results.
Most members of our management team have limited experience managing a publicly-traded company, interacting with public company investors, and complying with the increasingly complex laws pertaining to public companies. Our management team’s inexperience in dealing with these complex laws could be a significant disadvantage to us, because it is likely that an increasing amount of their time will be devoted to these activities, which may result in them spending less time on the management and growth of our company. In addition, our management team may not successfully or efficiently manage being a public company subject to significant regulatory oversight and reporting obligations under the federal securities laws and the continuous scrutiny of securities analysts and investors, which could adversely affect our business, financial condition, and operating results.
As a result of being a public company, we are obligated to develop and maintain proper and effective internal control over financial reporting. We may not complete our analysis of our internal control over financial reporting in a timely manner, or these internal controls may not be determined to be effective, which may adversely affect investor confidence in our company and, as a result, the value of our common stock.
Pursuant to Section 404 of the Sarbanes-Oxley Act and the related rules adopted by the SEC and the Public Company Accounting Oversight Board, starting with the second annual report that we file with the SEC after the consummation of our public offering, our management will be required to report on the effectiveness of our internal control over financial reporting. In addition, once we no longer qualify as an emerging growth company under the JOBS Act and lose the ability to rely on the exemptions related thereto, our independent registered public accounting firm will also need to attest to the effectiveness of our internal control over financial reporting under Section 404. We are starting the process of determining whether our existing internal controls over financial reporting systems are compliant with Section 404. This process will require the investment of substantial time and resources, including by members of our senior management. As a result, this process may divert internal resources and take a significant amount of time and effort to complete. In addition, we cannot predict the outcome of this
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determination and whether we will need to implement remedial actions in order to implement effective internal control ove
r financial reporting.
Our recent executive management changes (described above) and the short time interval in which they have occurred could add to the risk of control failures, including a failure in the effective operation of our internal control over financial reporting or our disclosure controls and procedures. Additionally, as we hire new executives, it might take the newly constituted management team some time to become sufficiently familiar with our business and each other to effectively develop and implement our business strategies.
In connection with the preparation of our financial statements for the years ended December 31, 2016 and 2015, we identified certain internal control deficiencies that did not rise to the level of a significant deficiency or material weakness, on an individual basis or in the aggregate. We are continuously improving our internal control environment. As a result, we may experience higher than anticipated operating expenses, as well as higher auditor fees during and after the implementation of these changes. If we are unable to implement any of the required changes to our internal control over financial reporting effectively or efficiently or are required to do so earlier than anticipated, it could adversely affect our operations, financial reporting, and results of operations and could result in an adverse opinion on internal controls from our independent registered public accounting firm.
Our ability to use our net operating loss carryforwards to offset future taxable income may be subject to certain limitations.
Under Section 382 of the Internal Revenue Code of 1986, as amended, or the Code, a corporation that undergoes an “ownership change” is subject to limitations on its ability to utilize its NOLs to offset future taxable income. Our existing NOLs may be subject to limitations arising from previous ownership changes, and if we undergo an ownership change in the future, our ability to utilize NOLs could be further limited by Section 382 of the Code. Future changes in our stock ownership, some of which are outside of our control, could result in an ownership change under Section 382 of the Code. Furthermore, our ability to utilize NOLs of companies that we may acquire in the future may be subject to limitations. There is also a risk that, due to regulatory changes, such as suspensions on the use of NOLs, or other unforeseen reasons, our existing NOLs could expire or otherwise be unavailable to offset future income tax liabilities. For these reasons, we may not be able to realize a tax benefit from the use of our NOLs, whether or not we obtain profitability.
Risks Related to Ownership of Our Common Stock
Sales of a substantial number of shares of our common stock in the public market, or the perception that these sales might occur, could cause our stock price to decline.
Sales of a substantial number of our common stock in the public market, or the perception that these sales might occur, could cause the market price of our common stock to decline and could impair our ability to raise capital through the sale of additional equity securities. As of December 31, 2016, there were 44,487,678 shares of our common stock outstanding, of which approximately 7,300,000 shares were held by non-affiliates. All of our common stock is freely transferable, except shares held by our “affiliates,” as defined in Rule 144 under the Securities Act.
We may also issue common stock or options to purchase shares of our common stock that under our 2015 Omnibus Equity Incentive Plan and our 2015 Employee Stock Purchase Plan. Securities issued under these plans will be registered under a Form S-8 and are freely tradable upon issuance.
There were 2,804,796 options exercisable as of December 31, 2016 at a weighted average exercise price of $3.65.
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Our st
ock price has been and may continue to be volatile, and you could lose all or part of your investment.
The market price of our common stock since our initial public offering has been and may continue to be volatile. Since shares of our common stock were sold in our initial public offering in May 2015 at a price of $8.00 per share, our stock price has ranged from $0.86 to $8.80, through December 31, 2016. The market price of our common stock is subject to wide fluctuations in response to various risk factors, some of which are beyond our control and may not be related to our operating performance, including:
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addition or loss of significant customers, collaborators or distributors;
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changes in laws or regulations applicable to our industry or traits;
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additions or departures of key personnel;
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the failure of securities analysts to cover our common stock after this offering;
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actual or anticipated changes in expectations regarding our performance by investors or securities analysts;
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price and volume fluctuations in the overall stock market;
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volatility in the market price and trading volume of companies in our industry or companies that investors consider comparable;
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share price and volume fluctuations attributable to inconsistent trading volume levels of our shares;
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our ability to protect our intellectual property and other proprietary rights;
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sales of our common stock by us or our stockholders;
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the expiration of contractual lock-up agreements;
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litigation involving us, our industry, or both;
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major catastrophic events; and
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general economic and market conditions and trends.
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Further, the stock markets have experienced extreme price and volume fluctuations that have affected and continue to affect the market prices of equity securities of many companies. These fluctuations often have been unrelated or disproportionate to the operating performance of those companies. In addition, the stock prices of many seed and agricultural biotechnology companies have experienced wide fluctuations that have often been unrelated to the operating performance of those companies. These broad market and industry fluctuations, as well as general economic, political, and market conditions such as recessions, interest rate changes, or international currency fluctuations, may cause the market price of our common stock to decline. If the market price of our common stock fluctuates or declines, you may not realize any return on your investment and may lose some or all of your investment.
Insiders have substantial control over us, which could limit your ability to influence the outcome of key transactions, including a change of control.
Our executive officers, directors, and two largest stockholders, in the aggregate, beneficially own approximately 71% of the outstanding shares of our common stock as of December 31, 2016. As a result, these stockholders, if acting together, would be able to influence or control matters requiring approval by our stockholders, including the election of directors and the approval of mergers, acquisitions or other extraordinary transactions. They may have interests that differ from yours and may vote in a way with which you disagree and that may be adverse to your interests. This concentration of ownership may have the effect of delaying, preventing or deterring a change of control of our company, could deprive our stockholders of an opportunity to receive a premium for their common stock as part of a sale of our company and might affect the market price of our common stock.
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As of December 31, 2016, Moral Compass Corporation,
our largest stockholder, beneficially owns approximately 51% of our outstanding common stock, and Moral Compass Corporation and Mandala Capital together beneficially own approximately 71% of our outstanding common stock. For so long as Moral Compass Corpo
ration continues to own a significant percentage of our outstanding shares, they may be able to significantly influence the composition of our board of directors and the approval of actions requiring stockholder approval. Accordingly, for such period of ti
me, Moral Compass Corporation may be able to exercise control over our management, business plans, and policies, including the appointment and removal of our officers, and may be able to cause or prevent a change of control of our company or a change in th
e composition of our board of directors and could preclude any unsolicited acquisition of our company. This concentration of ownership could deprive you of an opportunity to receive a premium for your shares as part of a sale of our company and ultimately
might affect the market price of our common stock.
We expect our operating results to vary significantly from quarter to quarter, which may cause our stock price to fluctuate widely.
We expect our quarterly operating results to fluctuate widely and unpredictably for the following reasons, among others:
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our significant customer concentration;
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our uncertain ability to obtain government grant funding, which affects the timing and amounts of our payments from the U.S. government;
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the variable timing, stage, and results of our and our collaborators’ research, development, and regulatory activities;
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the impact of seasonality in agricultural operations on our field trials and sales of products that incorporate our seed traits;
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supplier, manufacturing, or quality problems; and
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variance in the timing of customer and distributor orders for our SONOVA products.
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Further, a large proportion of our costs are fixed, due in part to our significant research and development costs and general and administrative expenses. Thus, even a small decline in revenues could disproportionately affect our quarterly operating results and could cause such results to differ materially from expectations. Any unanticipated change in revenues or operating results is likely to cause our stock price to fluctuate since such changes reflect new information available to investors and analysts.
Provisions in our amended and restated certificate of incorporation and amended and restated bylaws might discourage, delay or prevent a change of control of our company or changes in our management and, therefore, depress the trading price of our common stock.
Our amended and restated certificate of incorporation and amended and restated bylaws contain provisions that could depress the trading price of our common stock by discouraging, delaying or preventing a change of control of our company or changes in our management that the stockholders of our company may believe advantageous. These provisions include:
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establishing a classified board of directors so that not all members of our board of directors are elected at one time;
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authorizing “blank check” preferred stock that our board of directors could issue to increase the number of outstanding shares to discourage a takeover attempt;
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eliminating the ability of stockholders to call a special stockholder meeting;
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eliminating the ability of stockholders to act by written consent;
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the requirement that, to the fullest extent permitted by law and unless we consent to an alternate form, certain proceedings against or invo
lving us or our directors, officers, or employees be brought exclusively in the Court of Chancery in the State of Delaware;
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providing that the board of directors is expressly authorized to make, alter, or repeal our bylaws; and
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establishing advance notice requirements for nominations for elections to our board of directors or for proposing matters that can be acted upon by stockholders at stockholder meetings.
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If securities or industry analysts do not publish or cease publishing research or reports about us, our business, or our market, or if they change their recommendations regarding our stock adversely, our stock price and trading volume could decline.
The trading market for our common stock is influenced by the research and reports that industry or securities analysts may publish about us, our business, our market or our competitors. If any of the analysts who may cover us make adverse changes to their recommendation regarding our stock, or provide more favorable relative recommendations about our competitors, our stock price would likely decline. If any analyst who may cover us were to cease coverage of our company or fail to regularly publish reports on us, we could lose visibility in the financial markets, which in turn could cause our stock price or trading volume to decline.
As an emerging growth company within the meaning of the Securities Act, we utilize certain modified disclosure requirements, and we cannot be certain if these reduced requirements will make our common stock less attractive to investors.
We are an emerging growth company within the meaning of the rules under the Securities Act and we plan in future filings with the SEC to utilize, the modified disclosure requirements available to emerging growth companies, including reduced disclosure about our executive compensation and omission of compensation discussion and analysis, and an exemption from the requirement of holding a nonbinding advisory vote on executive compensation. In addition, we are not subject to certain requirements of Section 404 of the Sarbanes-Oxley Act, including the additional testing of our internal control over financial reporting as may occur when outside auditors attest as to our internal control over financial reporting. As a result, our stockholders may not have access to certain information they may deem important. We cannot predict if investors will find our common stock less attractive because we rely on these exemptions. If some investors find our common stock less attractive as a result, there may be a less active trading market for our common stock and our stock price may be more volatile.
We could remain an emerging growth company for up to five years, or until the earliest of (i) the last day of the first fiscal year in which our annual gross revenues exceed $1.0 billion, (ii) the date that we become a large accelerated filer as defined in Rule 12b-2 under the Exchange Act, which would occur if the market value of our common stock that is held by non-affiliates exceeds $700 million as of the last business day of our most recently completed second fiscal quarter, or (iii) the date on which we have issued more than $1.0 billion in non-convertible debt during the preceding three-year period.
Because we do not expect to pay any dividends for the foreseeable future, investors may be forced to sell their stock to realize a return on their investment.
We do not anticipate that we will pay any dividends to holders of our common stock for the foreseeable future. Any payment of cash dividends will be at the discretion of our board of directors and will depend on, among other things, our results of operations, cash requirements, financial condition, contractual restrictions including compliance with covenants under our debt agreements, and other factors that our board of directors may deem relevant. Our ability to pay dividends might be restricted by the terms of any indebtedness that we incur in the future. In addition, certain of our current outstanding debt agreements prohibit us from paying cash dividends on our common stock. Consequently, you should not rely on dividends to receive a return on your investment.
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Our common stock may be delisted from The Nasdaq Global Market if we are unable to maintain compliance with Nasdaq’s continued listing standards.
As a company traded on The Nasdaq Global Market, we are subject to compliance with The Nasdaq Stock Market’s rules and requirements, which require, among other things, that our minimum bid price be $1.00 or higher. Should it drop below the listing criteria for 30 consecutive days, Nasdaq will send a “deficiency notice” to inform the company that it will be delisted after 180 calendar days unless it meets the required minimum bid price for at least 10 consecutive trading days during the 180-day cure period. On February 14, 2017, we received a letter from Nasdaq notifying us that we were not in compliance with the minimum closing bid requirement set forth in Nasdaq Listing Rule 5405. In accordance with Nasdaq Listing Rule 5450(a)(1), we are provided with a cure period to regain compliance until August 14, 2017.
Additionally, our board of directors is to be comprised of a majority of independent directors. Due to the resignation of two of our independent directors in July 2016, from July 2016 to October 2016 our Board of Directors was not comprised of a majority of independent directors. On July 21, 2016, we received a letter from Nasdaq notifying us that we were not in compliance with the independent director requirements set forth in Nasdaq Listing Rule 5605. In accordance with Nasdaq Listing Rule 5605(b)(1)(A), we were provided with a cure period to regain compliance until the earlier of our next annual stockholder meeting or July 9, 2017. On October 30, 2016, Kevin Comcowich was appointed to our board of directors, and our board of directors determined that Mr. Comcowich is an independent director under The Nasdaq Stock Market’s rules and regulations. With the addition of Mr. Comcowich, our board of directors is again comprised of a majority of independent directors. We obtained a letter from Nasdaq dated November 9, 2016 confirming the Company’s compliance with the Rule 5605 and that the matter is now closed. If we had been unable to regain compliance with Nasdaq’s independent director requirements prior to the end of the cure period, our common stock could have been delisted from The Nasdaq Global Market. If we had been unable to regain compliance with Nasdaq’s independent director requirements prior to the end of the cure period, our common stock could have been delisted from The Nasdaq Global Market.
Any delisting of our common stock could adversely affect the market liquidity of our common stock and the market price of our common stock could decrease and/or become more volatile. Furthermore, if our common stock were delisted, it could adversely affect our ability to obtain additional financing and/or result in the loss of confidence by investors, collaborators and other third parties, customers, and employees.