I. Research Questions

This contribution was guided by the following research questions:

1. 1. What scientific presumptions underlie the UPOV treaty and the PBR regime it establishes?

2. 2. What scientific presumptions underlie the Convention on Biological Diversity (CBD) and the International Treaty on Plant Genetic Resources for Food and Agriculture (ITPGRFA)?

3. 3. What is the scientific and historical basis of the regulatory focus on uniformity or homogeneity and stability? Does this focus correspond with current and emerging scientific understanding of how sustainability can be ensured in agricultural production and innovation?

4. 4. In what way, if at all, does agricultural biodiversity support food security and seed-related innovations?

These questions are explored in this paper with a relatively long-term perspective. The aim is to determine whether a fundamental rethinking of international IP regulations is called for to promote and incentivize what has been previously referred to as “sustainable innovations” in plant varieties.Footnote ¹⁵

II. Arrangement of the Paper

The paper is arranged as follows. Following this introduction, Section B briefly explores the assumptions that underlie the UPOV agreement and the PBR regime it establishes. Specifically, Section B discusses the meaning and scope of the key terms under PBR regimes, giving special attention to the historical scope of the term “variety” and the scientific and commercial basis of the focus on “uniformity” (or homogeneity) and “stability.” Section C explores the assumptions underlying the CBD and the International Treaty on Plant Genetic Resources for Food and Agriculture (the ITPGRFA, also known as the Seed Treaty). Section C specifically discusses the scientific basis of the importance given to “diversity” (contained in landraces and farmers’ varieties) and “traditional knowledge” in the CBD and the Seed Treaty. Section C also looks into current scientific research that highlights the importance of and the inter-relationship between seed and soil (microbial) diversity for the performance of indigenous or heterogenous seeds in marginal environments. A related point is the limited utility of “uniform” seeds in such environments and in the face of climate change.

In Section D, the value of traditional (ecological) knowledge vis-à-vis protection and enhancement of agrobiodiversity (i.e., seed and soil microbial diversity) is explored in the context of the natural farming (NF) movement in India. Section E concludes with exploring recent legislation in Europe that indicates a sort of “return to innocence,” focusing, once again, on the importance of local seed and food diversity in the face of climate change and the ongoing global pandemic. Section E also makes recommendations for further research and highlights the need to urgently redirect international effort toward more diversity, supporting “minimum standards” in IP and associated regulations.

I. (Botanical) Varieties versus (Legal) Varieties

The International Union for the Protection of New Varieties of Plants (UPOV) was established by the International Convention for the Protection of New Varieties of Plants (UPOV Convention). The Convention itself was adopted in Paris in 1961 and was revised in 1972, 1978 and 1991. According to the UPOV website, “UPOV’s mission is to provide and promote an effective system of plant variety protection, with the aim of encouraging the development of new varieties of plants, for the benefit of society.”Footnote ¹⁶

The UPOV focuses on promoting and protecting new “plant varieties.” The term “plant variety” is considered to have neither a scientific nor a botanical origin.Footnote ¹⁷ Its origin as well as rise to popular usage are usually traced to the UPOV Convention of 1962. However, the term “variety” has a legal as well as a botanical origin. In the legal context, the term “variety” was indeed defined, perhaps for the first time, by UPOV,Footnote ¹⁸ under Article 2.2 of its 1962 Act, which states:Footnote ¹⁹ “For the purposes of this Convention, the word ‘variety’ applies to any cultivar, clone, line, stock or hybrid which is capable of cultivation and which satisfies the provisions of subparagraphs (1)(c) and (d) of Article 6.” Article 6(1)(c) and (d) go on to describe the “homogeneity” and “stability” requirement that every “cultivar, clone, line, stock or hybrid” must fulfill to be deemed a “new variety” and to qualify for protection:

In the European Union, the Biotechnology DirectiveFootnote ²⁰ clarifies the meaning of (plant) varieties by stating that “a variety is defined by its whole genome and therefore possesses individuality and is clearly distinguishable from other varieties.”Footnote ²¹ Recital 31 adds that “a plant grouping which is characterized by a particular gene (and not its whole genome) is not a plant variety.”Footnote ²² The 1991 Act of UPOV substantially modified the definition of “variety” and replaced the “homogeneity” requirement with the “uniformity” requirement. UPOV 1991 states:

Thus, under the legal definition, in order to be deemed a “variety,” (i) the plant grouping must exhibit specific characteristics that result from a given genotype, that is, from the “internal environment” of the seed as a whole, or in other words, from its entire genome and not due to the expression of a particular gene; (ii) these characteristics (or at least one of them) should help distinguish it from any other plant grouping; and (iii) the plant grouping must be capable of propagating itself unchanged.

It is in the context of botanical taxons and ranks mentioned in the above legal definition of “variety,” that one can also find the botanical meaning of the term. The International Code of Nomenclature for Algae, Fungi and PlantsFootnote ²³ places the term “variety (varietas)” as the category in the botanical nomenclatural hierarchy that comes between species and form (forma).Footnote ²⁴

This botanical usage of the term “variety” pre-dates the adoption of UPOV and has been defined differently by various notable botanists. The emergence of the term was highly influenced by Darwin’s work on the evolution of species.Footnote ²⁵ One of the earliest definitions of “variety” was by Linnaeus, who in 1753, in the Species Plantarum, defined “variety” as “a plant changed by accidental cause due to the climate, soil, heat, wind, etc. It is consequently reduced to its original form by a change of soil. Further, the kinds of varieties are size, abundance, crispation, colour, taste, smell. Species and genera are regarded as always the work of nature, but varieties are more usually owing to culture.”Footnote ²⁶

The reference to “culture” in the botanical definition of “variety” is significant as it indicates the very localized nature of a “variety” and that various cultural contexts can lead to the evolution, in various geographies, of diverse varieties belonging to the same species (or sub-species). The interpretation of Linnaeus’ work by Fernald (1940) confirms this understanding. Fernald opined that Linnaeus “generally designated as varieties indigenous plants which he considered to be natural (often geographic) variations within the broad limits of his specific concept.” Footnote ²⁷ In later works, botanists have distinguished between “sub-species” and “varieties,” with the former term used to indicate “major morphological variations” or “variations of greater value,” while the latter indicates “minor ones [variations].”Footnote ²⁸

Asa Gray, a leading botanist in nineteenth-century America, however, said in 1836 that “any considerable change in the ordinary state or appearance of a species is termed a variety. These arise for the most part from two causes, viz.: the influence of external circumstances,Footnote ²⁹ and the crossing of races.”Footnote ³⁰ Here we see, therefore, that before the era of genetic engineering rose to prominence, varieties were known to result not just from “crossing” (i.e. breeding activities that seek to change the “internal environment” of the seed) but also by natural environmental factors (i.e. the “external environment” to which a seed is subjected). In other words, it is not just the “internal atmosphere” of a seed, but also its external environment that determines its characteristics.

Indeed, today geneticists confirm that the seed’s external environment – which contributes specific nourishment, inter alia, through soil and manure quality as well as biotic and abiotic stressors – determines which genes will express themselves and which will remain dormant.Footnote ³¹ This principle is particularly relevant when the seed’s internal genetic environment has not been artificially narrowed with the aim of ensuring “uniformity” and “stability” in specific external conditions.

Undoubtedly, the term “variety” is now less frequently used in the field of botany,Footnote ³² with preference given to the more important differences reflected under the taxonomic ranks of “species” and “sub-species”. However, it is important to note that the botanical term “variety,” which reflects “minor” differences, does not presuppose “uniformity” or “stability” either within the same farmland (due to shifting environmental circumstances) or across various geographic, environmental, soil type and other factors. In fact, within specific species and sub-species, a variety (in the botanical sense) can be expected to naturally display different characteristics depending on various external factors and influences. Further, the changes seen in any such botanical “variety” can originate from the work not just of plant breeders but also of farmers, inter alia, based on cultural preferences and environmental expediencies.

It is, therefore, quite interesting that some countries, while following a definition of variety that is very close to the above UPOV definition,Footnote ³³ also recognize a different category – called “farmers’ varieties.” In India, for example, “farmers’ varieties” are defined to include landraces and wild relatives of a variety. To this extent, the Indian law seems to include both the legal and botanical understanding of “variety” within its scope. Section 2(l) of the Indian law states:

Wild relatives and landracesFootnote ³⁴ differ significantly from UPOV’s “varieties” because they can and do change during the course of repeated cycles of propagation. This change occurs as a result of the genetic variability inherent in heterogenous (as opposed to homogenous) propagation materials (such as seeds), and is triggered, inter alia, by external circumstances such as climate change, pest attacks, drought or flood conditions. While genetic variability makes landraces and farmers’ varieties more robust in the face of biotic and abiotic stresses, it is antithetical to “uniformity” and “stability” requirements, which are pre-conditions for the grant of PBR certificates under UPOV.

II. The Scientific (Ir)rationale of the DUS Requirement

The test of distinctness, uniformity, and stability (DUS) is referred to as the “DUS requirement.” The legal concept of uniformity can be traced back to the “homogeneity” requirement under the 1962 UPOV Act, which became “uniformity” in the later Acts. Hence, UPOV 1991 (Article 8) defines a “uniform” variety rather generally: ‘A variety shall be deemed to be uniform if, subject to the variation that may be expected from the particular features of its propagation, it is sufficiently uniform in its relevant characteristics.’

The regulatory focus on uniformity can be traced back to the (re)discovery of Mendelian genetics in the early 1900sFootnote ³⁵ Gregor Johann Mendel published his understanding of the laws of heredity in 1865. However, the dissemination of the findings in the scientific and political community followed only in 1900, rediscovered by K. E. Correns, E. von Tschermak and H. de Vries.Footnote ³⁶ They rejected “breeding methods inspired by Darwin’s evolutionary theory” as “scientifically unsound” and not feasible for practical breedingFootnote ³⁷ and focused instead on Mendel’s theory of heredity based on the stability of genes.Footnote ³⁸

Johannsen emphasized the purity of genetic material;Footnote ³⁹ he considered “the genotype as a whole as the elementary species and the pure line, as the key permanent biological type.”Footnote ⁴⁰ In the early 1900s, with the expanding practice of plant breeding, the understanding that genetic purity is rare and actually leads to instability was increasingly overtaken by the understanding that genetic purity and stability are indicative of quality and replicability.Footnote ⁴¹ Early geneticists considered genetic identity to be independent of environmental influence; that is, gene expression is not influenced by the plant’s environment but is primarily or exclusively influenced by the internal genetic makeup of the plant (i.e. the plant genome).Footnote ⁴² This idea led to a sort of obsession with genetic purity and stability that continues in the plant breeding community to date.Footnote ⁴³ According to Provine (1971), “the climate of biological opinion was favorable to the pure line theory.”Footnote ⁴⁴ Opposing ideas tying genetics closely to its context (e.g. environment) were led by Raphael Weldon but ended prematurely with his death in 1906.Footnote ⁴⁵ When Johannsen presented his pure line theory at a symposium in 1910, most geneticists accepted the theories without adequate proofFootnote ⁴⁶ and Mendelism’s legacy “boomed its way into biology.”Footnote ⁴⁷

There are, indeed, also more economically driven reasons for the continuing importance given to pure and stable genetic materials: pure and stable genetic material leads to uniform and stable plant varieties that can be easily protected by PBR and patents. The existence of property rights permits the charging of monopoly rents and recoupment of the (allegedly) high costs involved in the creation, certification and marketing of new uniform varieties.Footnote ⁴⁸ Further, industrial standardization and quality control regulations have allowed and supported the emergence of the breeding industryFootnote ⁴⁹ and effectively limited competition from the informal seed sector (in Europe). Industrial breeders, therefore, can be said to have considerably contributed to the success of Mendel’s and Johannsen’s theories.Footnote ⁵⁰

Pure (parental) lines, purified for specific traits, are also a prerequisite for the creation of F1 hybrids.Footnote ⁵¹ These F1 hybrids, in turn, help industrial breeders maintain their market monopolies in two ways: (i) once two (or more) parental lines are crossed to create an F1 hybrid, it is difficult to identify (or recreate) the parents. This is because the resulting hybrid out-performs both parents due to a phenomenon known as hybrid vigor or heterosis;Footnote ⁵² (ii) F1 hybrids do not reproduce true to type. This means that farmers who attempt to save seeds from the harvest of their F1 seeds for sowing the next season’s crop are likely to experience lowering of yields due to the segregation of genetic materials in the second generation.Footnote ⁵³

Experts argue that it was perhaps no coincidence that the dissemination of Mendelian theory in the early 1900s coincided with the industry push for property rights for new inventions and discoveries in agriculture.Footnote ⁵⁴ To ensure “quality control,” the purity and stability criteria of plant material became the norm not only for industrial seed production but also in experimental biology, and as a means of ensuring “fairness in social and economic relations.”Footnote ⁵⁵

The standardization of plant breeding and its focus on uniformity and purity caused a divide between landraces, which are preserved and improved over time by farmers in situ, versus cultivars, which result from plant breeders’ labs or from highly regulated and carefully managed agricultural testing lands.Footnote ⁵⁶ Landraces were considered “not suitable for anything,” obsolete, unproductive and were reduced to a mere gene storeFootnote ⁵⁷ – as indicated in the popular term “plant genetic resources”. A resolution in 1907 on conserving landracesFootnote ⁵⁸ by a locally oriented public initiator “soon came under private breeders’ fire” leading to its decline.Footnote ⁵⁹ However, as a paradox of modern breeding, the breeder Baur (1914) warned of their disappearance and the urgent need to preserve landraces.Footnote ⁶⁰

What has resulted since the widespread acceptance of Mendelian genetics and the “pure line” theory is a systematic exclusion of farmers (as seed sellers) from the agricultural seed market, especially in Europe.Footnote ⁶¹ This resulted in a whole array of undesirable consequences, including the erosion of agricultural biodiversity and the rapid conversion to conventional farming, heavily reliant on expensive chemical inputs.Footnote ⁶²

Arguably, therefore, the requirements of “uniformity” and “stability” have been introduced into the legal definition of “plant variety” through a legal fiction because genetic purity, uniformity and stability are important primarily from a legal (and industrial) standpoint, and not from scientific or (marginal) farm-environment perspectives. An expert has stated that “the scientific notion does not necessarily coincide with the legal concept. The law may require certain characteristics for a protected variety that may not be essential for a scientific definition.”Footnote ⁶³

In fact, as stated previously, pure, uniform and stable lines are able to perform well only in carefully managed environments because, contrary to the claims of early geneticists, a plant’s genetic identity is not independent of its environment but is highly influenced by it.Footnote ⁶⁴ More recently, historians of science have attempted to emphasize again the importance of taking environmental influences into account, together with the inherent genetic makeup of seeds, to avoid the “determinism” that results from a focus exclusively on a seed’s “internal” environment.Footnote ⁶⁵ In this context, the following explanation is helpful:Footnote ⁶⁶

This is where we can start to understand the relevance of agrobiodiversity contained in farmers’ varieties and landraces. We discuss this in further detail in the following section.

I. The Scope and Importance of ‘Diversity’ and ‘Traditional Knowledge’

We saw above that UPOV assumes and emphasizes the central importance of “uniformity”, “stability” and related “genetic homogeniety” or “purity”. The CBD and the Seed Treaty, on the other hand, assume and emphasize the importance of (agro)biodiversity. Since its inception, the CBD has underscored the importance of biodiversity within the soil (i.e. the soil microbiome) and on the soil (i.e. seed or plant biodiversity). Equally relevant is the recognition and high status given within the CBD to the valuable role played by traditional knowledge and associated systems, practices, and innovations in maintaining this biodiversity and using it in a sustainable manner (CBD, Articles 8(j), 17). The CBD also mandates the sharing of social and economic benefits (“benefit sharing”) with the people preserving and using this knowledge in situ.Footnote ⁷¹

Equitable benefit sharing is presumed necessary not only to ensure fair compensation for sharing biodiversity and associated know-how, but also to ensure that communities engaged in its protection and in-situ conservation have monetary incentives to continue their important work.Footnote ⁷² Similar to the CBD’s focus on biodiversity generally, the Seed Treaty focuses on agrobiodiversity, especially agricultural seed diversity and mechanisms to conserve, preserve and protect this diversity, while facilitating its equitable use through benefit sharing.

“Conservation” and “preservation,” however, are unfortunate terms in the context of agrobiodiversity.Footnote ⁷³ This is not least because farmers and farmer communities not only conserve this diversity but constantly improve it and innovate with it, with the help of traditional and indigenous know-how and technologies. Indeed, the CBD encourages international “cooperation for the development and use of technologies, including indigenous and traditional technologies, in pursuance of the objectives of the Convention.”Footnote ⁷⁴ The relevance of traditional technologies and associated traditional ecological knowledge (TEK), is, however, context-dependent. To understand the context, it is useful to revisit the development of “high yielding varieties” (HYVs) during the “Green Revolution.” Prior to the development of HYVs by Norman Borlaug, “lodging” was witnessed when traditional (indigenous) wheat seeds were treated with mineral fertilizers: they would grow rapidly and prematurely fill up with grain, the weight of which made them “lodge” and die before they were ready for harvest.Footnote ⁷⁵

The breeding of semi-dwarf “high yielding” wheat and rice seed varieties (HYVs) under the Green Revolution resolved a twofold problem: the problem of traditional varieties being non-responsive to fertilizer-treated soilsFootnote ⁷⁶ and the problem of lodging.Footnote ⁷⁷ The new development paved the way for bumper crops and the promise of economic and social prosperity for all farmers. Indeed, the notion that scientific intervention for the creation of “new varieties” is necessary for high yield and food security was also propelled in the Global South, at least in part, by the demonstrated success of Norman Borlaug’s HYVs.Footnote ⁷⁸

What is not discussed in the success story of the Green Revolution is its impact on indigenous seeds and landraces that were not engineered to withstand the application of mineral fertilizers. The claim that the cultivation of indigenous seeds that incorporate agrobiodiversity and genetic variability is not adequate for food security needs to be considered in this context. Studies that compare the productivity of landraces with that of improved varieties on fertilizer-treated soils can, therefore, be expected to show lower yields for landraces and farmers’ varieties than for seeds whose genetic environment is engineered to perform in such soils.Footnote ⁷⁹ Therefore, the rapid expansion of conventional agriculture involving the regular use of mineral fertilizers and chemical pesticides with “improved” seeds (and the corresponding disappearance of TEK-based farming systems) is also one of the main threats to landraces and in-situ agrobiodiversity conservation.Footnote ⁸⁰

Yet, landraces and indigenous or farmers’ varieties, when cultivated in TEK-based farming systems, have been found to outcompete hybrid varieties in highly variable environments,Footnote ⁸¹ offering a robust local strategy for food security, including coping with climate change.Footnote ⁸² They may also economically benefit (marginal) smallholder farmers by granting them independence from cost-intensive inputs such as breeders’ seeds, mineral fertilizers and pesticides while helping to revive and conserve local traditional knowledge.

In the following sub-sections, we look closer into the current scientific understanding of the importance of diversity and variability contained in landraces and the impact of plant genetic diversity on soil health and the nutrition contained in food.

II. The Relevance of Landraces and Genetic Variability

We saw in the previous section that modern genetics and the science of plant breeding developed under the aegis of Mendel’s theory of heredity, supported by pure line theories proposed by scientists such as Johanssen.Footnote ⁸³ However, as early as 1972, the US report “Genetic Vulnerability of Major Crops” attracted attention in science:Footnote ⁸⁴ it found genetic uniformity to be the source of vulnerability to plant diseases and abiotic or biotic stresses. The report challenged dominant scientific thought and the national policies that relied on it.

However, although scientists take the blame for the focus on uniformity, notably, the markets (and consumers) also demand uniformity (e.g. in the form size, shape, color, texture of vegetables and grains).Footnote ⁸⁵

Not surprisingly, therefore, today the legal fictions and assumptions underlying UPOV continue to unchangeably favor Mendel’s theory of heredity and the pure line theory. Empirical and scientific evidence opposing these theories is, however, accumulating. Various studies find higher variety and variability of plant genetic resources to be more efficient than pure lines. For example, increased within-crop genetic diversity has been found to enhance yield stability and yield reliability while permitting rapid and dynamic response to change (e.g. changes in climatic or biotic stresses).Footnote ⁸⁶

Unlike pure lines and hybrids created in artificial or carefully managed environments, landraces are, by definition, unique to the region where they evolve.Footnote ⁸⁷ Undoubtedly, farming – including farming with landraces or farmers’ varieties – reduces the overall plant or natural biodiversity. However, cultivation with indigenous landraces, rather than with uniform and stable seeds, helps to increase, or at least maintain, agrobiodiversity. In this context, it is useful to revisit the distinction between genetic variation and genetic variability, as discussed in significant detail elsewhere:Footnote ⁸⁸

In other words, the genes of landraces are highly variable due to continuous evolution in the face of unpredictable phenological events. This variability helps landraces adapt to varying biotic and abiotic stresses, such as weather extremes or pest attacks, making them more climate-resilient than improved and uniform varieties.Footnote ⁹² For example, lucerne landraces from five countries learned to cope differently with environmental stress situations, such as drought (Italian landraces) or salt-stress environments (Moroccan landraces).Footnote ⁹³ Lima bean landraces showed high adaptability to drought, temperature stress and competitiveness under such conditions, compared to commercial cultivars.Footnote ⁹⁴ In unfavorable areas of MoroccoFootnote ⁹⁵ and China,Footnote ⁹⁶ landraces are preferably cultivated due to their better adaptability and better yields. Farmers planting a higher diversity of corn in Mexico are better able to mitigate the weather extremes caused by climate change.Footnote ⁹⁷ In Turkey, farmers prefer a local wheat landrace that can be sown twice per year, minimizing the risk of harvest losses.Footnote ⁹⁸ As observed by Kochupillai,Footnote ⁹⁹

However, it is also this genetic variability inherent in landraces and farmers’ varieties that make them heterogenous (rather than homogenous or “uniform”). Landraces and farmers’ varieties are, therefore, unsuitable for protection by PBR, even when a landrace is significantly distinctive from other landraces or farmers’ varieties.

III. Seed–Soil Interactions, Nutrition and Environmental Sustainability

Plant genetic materials co-evolve with their surrounding microorganisms, forming a holobiont.Footnote ¹⁰¹ Plant root secretions and associated soil microorganisms together constitute the root microbiome. The soil surrounding the plant root, which is particularly rich in beneficial microbiological activity, is called the rhizosphere.Footnote ¹⁰² The more diverse the microbial population in the rhizosphere, the better the symbiotic exchange between plants and microorganisms, supporting nutrient exchangeFootnote ¹⁰³ and resulting in higher nutrient content in the plant, vegetable, or crop.Footnote ¹⁰⁴ Intimate associations between the plant root and soil microbes are also critical for the establishment and maintenance of stable relations between plant hosts and rhizobial microorganisms (host-microbial homeostasis),Footnote ¹⁰⁵ which is crucial for plant disease suppression.Footnote ¹⁰⁶

Interestingly, it is not just the quality of the soil that impacts seeds and crops, but the plant genotype, in turn, influences the root microbiomeFootnote ¹⁰⁷ and, consequently, plant–microbe interactions. Evolutionary changes in host genotypes influence the bacterial selection process, determining the richness, diversity, and relative abundances of taxa.Footnote ¹⁰⁸ For example, for barley, the community composition at the root–soil interface significantly declined from wild genetic resources to landraces to uniform plant varieties.Footnote ¹⁰⁹

Plants also co-evolve with microorganisms that are hosted in their cell walls (endophytes).Footnote ¹¹⁰ These microorganisms offer various advantages to host plants, such as the production of phytohormonesFootnote ¹¹¹ or the solubilization of nutrients such as phosphorus.Footnote ¹¹² These microorganisms are also crucial for the germination of seedsFootnote ¹¹³ and for fighting seed-borne diseases.Footnote ¹¹⁴ While a part of these microorganisms (bacteria) are vertically transmitted from parent to progeny seedlings,Footnote ¹¹⁵ at around 45 percent,Footnote ¹¹⁶ other parts are horizontally transmitted and are impacted by environmental characteristics such as the soil microbiome,Footnote ¹¹⁷ climatic conditions, and human practices.Footnote ¹¹⁸

Further, research comparing older landraces of wheat,Footnote ¹¹⁹ breadfruit,Footnote ¹²⁰ soybeans,Footnote ¹²¹ and cornFootnote ¹²² with more modern varieties found the older ancestors benefited more from symbiotic associations with mycorrhizal fungi (mycorrhiza root colonization).Footnote ¹²³ The mycorrhiza root colonization of landraces exceeded that of modern hybrid cultivars by 149 percent, doubling sorghum yields – and also correlating with higher mineral nutrients in sorghum.Footnote ¹²⁴ Heirloom bean landraces have similarly been found to contain higher nutrient contents than modern varieties.Footnote ¹²⁵

Symbiotic associations also result in more resistant plants, particularly in low-fertility soils. For example, heirloom bean landraces from Spain were found to adapt well to dry conditions,Footnote ¹²⁶ and native corn outcompeted hybrid variants in taking up symbiotic and direct phosphorus.Footnote ¹²⁷ However, plant varieties react very individually.Footnote ¹²⁸ Due to mycorrhiza symbiosis, the productivity and sensual quality of in-situ cultivated landraces can be addressed more efficiently and inclusively by agricultural practices that are beneficial for arbuscular mycorrhiza fungi, such as omitting pesticide usage, avoiding soil mechanization, and inoculating the plants with arbuscular mycorrhiza fungi. Interestingly, landraces have been found to react more positively to the inoculation of arbuscular mycorrhizal fungi than genetically modified hybrid corn, which responded negatively.Footnote ¹²⁹

Higher nutrient availability in soils results in less plant–microbial symbiosis.Footnote ¹³⁰ For example, in nutrient-rich environments under the usage of mineral fertilizers, plants downregulate their symbiosisFootnote ¹³¹ and stop interacting with arbuscular mycorrhiza fungi.Footnote ¹³² Over the last centuries, this phenomenon has been found to result in plants losing their ability to form symbioses with beneficial fungi.Footnote ¹³³

To maintain and promote plants forming symbiotic ties with beneficial microorganisms and to enhance plants’ resistance, yields and nutritive values, it is essential to revive TEK-based farming systems and the indigenous heterogenous seeds applied in such systems. In the next section, we look at one such TEK-based farming system, namely, “natural farming” (NF), which conserves both seed and soil (microbial) diversity, leading to enhanced farmers’ profits, improved soil health, and an increase in agrobiodiversity. The rapid adoption of these farming systems and the associated adoption of heterogenous seeds across India (and beyond) calls into question the rationale and assumptions underlying the DUS criteria that have been employed to incentivize the creation of uniform plant varieties.

I. Traditional Ecological Knowledge and Agrobiodiversity

Traditional Ecological Knowledge (TEK) has been defined as a “cumulative body of knowledge, practices, and beliefs, evolving by adaptive processes and handed down through generations by cultural transmission, about the relationship of living beings (including humans) with one another and with their environment.”Footnote ¹³⁴ In TEK-based farming systems, plant genetic material and human knowledge co-evolve in close adaptation to climatic and cultural changes. This essentially means that various TEK-based farming systems have emerged independently across various parts of the globe.Footnote ¹³⁵ Nonetheless, TEK systems do follow certain basic principles, giving significant importance to the autonomy of farmersFootnote ¹³⁶ (local inputs only, on-farm nutrient recycling, saving seeds)Footnote ¹³⁷ and their knowledge, which is verified season after season.Footnote ¹³⁸ Since TEK-based farming systems presuppose and preserve the functioning of self-sustaining ecosystems, they are also described as agroecological farming systems.Footnote ¹³⁹ Unlike conventional farming systems that rely heavily on uniformity and stability, diversity (in seeds, crops, soil microbes etc.) is the lifeblood of agroecological and TEK-based farming systems.

Locally selecting, multiplying, saving, improving and exchanging seeds with desirable traits – such as stress resilience, hardiness, taste and yieldFootnote ¹⁴⁰ – has returned an astounding heterogeneity of planting materials that are genetically non-uniform, variable and diverse.Footnote ¹⁴¹ Such planting materials are characterized by a particularly high within-variety diversity (intra-varietal genetic diversity).Footnote ¹⁴² They adapt year by year to local climatic conditions and soil properties. Saved heterogenous seeds, therefore, lead to more robust plants.Footnote ¹⁴³

Apart from yielding diverse plant genetic material, agroecological practices contribute to stable ecosystems.Footnote ¹⁴⁴ The more diverse the in-soil living organisms, the better functioning are ecosystem services such as the cycling of vital nutrients for plant growth, regulation of water supply and food webs controlling pests.Footnote ¹⁴⁵ Together, seed and soil biodiversity constitute the backbone of TEK-based farming systems. We explore this further in the context of the NF movement in India.

II. TEK and the Natural Farming Movement in India

Natural farming is an agroecological farming system based on the TEK of India.Footnote ¹⁴⁶ Like most TEK-based farming systems, NF considers seed diversity and healthy soil as being fundamental prerequisites for efficient and sustainable crop cultivation.Footnote ¹⁴⁷ Over the last decade, NF methods in India have rapidly gained popularity and momentum due to their positive impact on overall farm resilience, particularly by rehabilitating degraded soilsFootnote ¹⁴⁸ and increasing farmer profits.

As an aftermath of the Green Revolution in India, in the late twentieth century, vast soil resources were significantly degraded from the intensive usage of pesticides, mineral fertilizers and soil mechanization.Footnote ¹⁴⁹ The NF practices support the ecological recovery of soil functions by using farming principles that revive, enhance, and protect the soil’s ecosystem functions, such as better nutrient provision.Footnote ¹⁵⁰ These functions are supported by farmer-made biostimulant preparationsFootnote ¹⁵¹ using local materials and agricultural waste.Footnote ¹⁵² Healthy soils allow farmers to cut dependencies on expensive inputs (e.g. mineral fertilizers, seeds, and pesticides),Footnote ¹⁵³ thereby reducing costs and increasing farmer profits. This scenario inspired the name “zero budget natural farming” (ZBNF).Footnote ¹⁵⁴

Due to their success, NF practices have spread rapidly throughout India and are recognized as the “largest ‘experiment’ in agro-ecology in the world.”Footnote ¹⁵⁵ The UN Food and Agriculture Organization (UN FAO) has defined ZBNF as simultaneously a set of farming methods and as a grassroots peasant movement.Footnote ¹⁵⁶ Natural farming has been adopted by several Indian states such as Andhra Pradesh, Himachal Pradesh, Gujarat, Haryana, Karnataka, and Kerala, with Andhra Pradesh implementing its NF program at a mass scale. According to the Andhra Pradesh government, as of March 2020, roughly 620,000 farmers (10.5 percent of all farmers) were enrolled in the program.Footnote ¹⁵⁷ Himachal Pradesh aimed to convert the entire state to NF by 2022.Footnote ¹⁵⁸ Civil society and several NF movements led by non-government organizations (NGOs) have also spread to states such as Karnataka, Tamil Nadu, and Maharashtra.Footnote ¹⁵⁹

Several NGOs, including the International Association for Human Values (IAHV) and the Art of Living Foundation (AOLF), are also actively engaged in imparting education in NF under the government’s Paramparagat Krishi Vikas Yojna (PKVY) (translated as “scheme for the promotion of traditional agriculture”). In March 2020, the Indian government declared a new sub-mission to specifically promote the adoption of NF under the name Bhartiya Prakritik Krishi Padhati (BPKP) (translated as “Indian natural farming method”’).Footnote ¹⁶⁰ These schemes are sub-components of India’s “Soil Health Management Scheme” under the “National Mission of Sustainable Agriculture,” which “aims to develop sustainable models of organic farming through a mix of traditional wisdom and modern science.”

Although research on the impact of NF on farm yields has not been consistent across states, the overall success and rising popularity of NF results from a combination of factors. These include widespread efforts by various individuals (notably, Subhash Palekar) and NGOs such as the AOLF, the Sri Sri Institute for Agricultural Sciences and Technology Trust (SSIAST), Kheti Virasat Mission, BAIF, IAHV, LiBird, and others to educate – or reeducate – farmers on the benefits of TEK and agrobiodiversity, thus raising farmers’ profits and reducing costs while improving the soil health and the personal health of farming families that have adopted NF in recent years.Footnote ¹⁶¹ Proponents of NF also emphasize its ability to revive and improve local agrobiodiversity, not only in the form of indigenous seeds but also by helping to revive indigenous cattle breeds and preventing their extinction, while enhancing soil microbial diversity.

III. Seed Biodiversity in TEK and Natural Farming

The cultivation of local varieties of indigenous and heterogeneous seeds lies at the heart of NF, serving as the prerequisite for food security and sustainability vis-à-vis the triple bottom line: people, planet and profits. The high adaptability and hardiness exhibited by landraces to their environment over an extended period allow for low-cost and low-input farming.Footnote ¹⁶² Migrating to NF gradually reduces farmers’ dependence on market-purchased “uniform” and “stable” seeds, as farmers rely on (and prefer) indigenous heterogenous seeds that perform better and can also be saved and exchanged without cost. The social practices of seed sharing and exchange further support the diversification of seed material over time,Footnote ¹⁶³ facilitating agrobiodiversity conservation as well as informal (farmer-led) seed innovations.

In addition to conserving knowledge on diversities and traits, NF in India also includes knowledge of how to enhance the germination rate of indigenous seeds for better plant vitality and stress resistance.Footnote ¹⁶⁴ For example, the seed stimulant preparation called Angara or Bheej-Amrut (or Beejamrut) is derived from Indian TEK texts.Footnote ¹⁶⁵ Composed of cow manure, water, limestone and local soil,Footnote ¹⁶⁶ the preparation stimulates plant growth. Farmers report negligible seed mortality rate, improved seedling length and vigor as well as enhanced seed germination rates.Footnote ¹⁶⁷ Bheej-Amrut has been found to contain N-fixing, P-solubilizing bacteria, actinomycetes and beneficial fungi.Footnote ¹⁶⁸

IV. Soil Biodiversity in TEK and Natural Farming

The revival of seed biodiversity in TEK systems is dependent on the diversity of soil organisms, which are protected and promoted by a plethora of farming practices. For example, applying plant residues as mulch provides a nutritious carbon source for soil organisms.Footnote ¹⁶⁹ Particularly under dry conditions, mulching can significantly increase the grain yieldFootnote ¹⁷⁰ and reduce the amount of irrigation needed, thereby also minimizing the risk of high salinity in soils connected to irrigation.Footnote ¹⁷¹ Similarly, low tillage is an effective practice to maintain soil health in TEK-based farming systems.Footnote ¹⁷²

Farm waste-based preparations that act like microbial plant biostimulants are also an integral part of NF. Most plant biostimulant formulations under NF are based on local (cow) manure. Specific fermentation methods transform the manure into a potent biofertilizerFootnote ¹⁷³ that significantly enhances the soil’s biological, physical and chemical properties.Footnote ¹⁷⁴ For example, the formulation called Jeev-Amrut is based on (cow) manure, sugar (e.g. ripe fruits), proteins (e.g. pea flour), minerals (e.g. mineral flour), and local soil. The mix has been found to significantly increase yields,Footnote ¹⁷⁵ effectively control various plant pathogensFootnote ¹⁷⁶ and increase the availability of nutrients, while decreasing the concentration of contaminants such as chloride and sulfate.Footnote ¹⁷⁷

The TEK-based farming systems are growing in popularity partly because of the need to recover degraded soils and to meet the growing demand for healthy, nutritious, and organic food. They are also growing out of social movements seeking to move away from high-input farming, which is considered expensive and highly vulnerable. Recent studies and developments are helping people to better understand, interpret, and improve upon ancient practices for modern application.Footnote ¹⁷⁸ These studies point to the importance of TEK-based farming and formulations in promoting sustainable agriculture that can support the cause of enhanced food and nutritional security.

Despite its recent boom in India, TEK systems are globally endangered.Footnote ¹⁷⁹ They are mostly used by smallholder farmers, who are outcompeted by intensive agricultural systems, or by the loss of habitats, altered lifestyles,Footnote ¹⁸⁰ negative attitudes toward the word “traditional,”Footnote ¹⁸¹ and aggressive introduction of new (“improved”) seed varieties, even though they do not perform consistently in marginal environments.Footnote ¹⁸² Legal and regulatory changes are urgently needed to help revive a diversity of TEK-based farming systems as possible and beneficial substitutes for conventional farming systems, particularly for marginal environments. Corresponding shifts are also needed in the educational curriculums of universities and the training of regional agricultural extension officers.

I. Trends in Europe

The relevance of agrobiodiversity is widely acknowledged, not only in countries of the Global South but also within Europe. In 2018, the European Union adopted Regulation (EU) 2018/848 of 30 May 2018 on organic production and the labeling of organic products (published on June 14, 2018). The regulation, for the first time, permits and encourages, inter alia, the marketing for organic agriculture of “plant reproductive material of organic heterogeneous material.” It defines “organic heterogeneous material” as

Such heterogeneous materials do not need to fulfil the registration and certification requirements under various EU laws.Footnote ¹⁸⁵ The regulation clarifies that “heterogeneous materials,” unlike current proprietary seeds, need not be uniform or stable, and notes that based on “Research in the Union on plant reproductive material that does not fulfil the variety definition… that there could be benefits of using such diverse material… to reduce the spread of diseases, to improve resilience and to increase biodiversity.”

Accordingly, the regulation removes the legal bar on the marketing of “heterogeneous materials” and encourages their sale for organic agriculture, thus clearing the way for the more expansive use of indigenous non-uniform seeds in agriculture. It is expected that “once the delegated [A]cts under the EU regulation are formulated, they will support the creation of markets and marketplaces facilitating trade in heterogeneous seeds, including by small farmers who have, thus far, been left out of the competition in seed markets.”Footnote ¹⁸⁶

Further, in the context of nutrient recycling and organic fertilizers for organic agriculture, the amended recital 5a of the proposed EU regulation (which is a part of the EU Circular Economy (CE) Package) of “CE marked fertilizers” is very relevant. The recital as proposed by the EU Parliament reads: “(5a) To ensure effective use of animal manure and on-farm compost, farmers should use those products which follow the spirit of ‘responsible agriculture’, favoring local distribution channels, good agronomic and environmental practice and in compliance with union environmental law …. The preferential use of fertilizers produced on-site and in neighbouring agricultural undertakings should be encouraged.”Footnote ¹⁸⁷ Despite the crucial role this provision could have played in the revival of TEK-based farming that teaches farmers how to produce biostimulants and organic fertilizers on-farm, the fertilizer regulation (EU 2019/1009) dropped the proposal.Footnote ¹⁸⁸

The importance of locally adapted seeds has, nevertheless, been further emphasized in the Farm to Fork Strategy (2020), which states that “the Commission will take measures to facilitate the registration of seed varieties, including for organic farming, and to ensure easier market access for indigenous and locally-adapted varieties.”Footnote ¹⁸⁹ The strategy also emphasizes the need for more agroecological farming practices in the European Union.

These legal and regulatory trends suggest a small but decisive step in the direction of diversifying the marketplace for agricultural seeds. They are also in line with the emerging scientific understanding of the urgent need to revive seed and soil microbial diversity for the sake of sustainable farming and food security. However, based on past scientific understanding, the European Union has, for decades, strictly regulated the agricultural seeds and inputs sector, outlawing active participation by farmers in the creation of agricultural seeds and associated organic fertilizers produced on-farm. These regulations have resulted in the development of specific practices and mindsets in agriculture, including among small and marginal farmers. Changing laws at the high level of the European Union will not lead immediately to a shift in local practices and mindsets.

In accordance with the principles of translational ethics and order ethics, to ensure compliance with ethically appropriate behavior (including environmentally sustainable behavior), it is necessary to ensure that legal, regulatory and governance structures incentivize the appropriate action. This can be done by, inter alia, removing perverse incentives and ensuring the necessary structural changes within existing institutional frameworks (e.g. by imparting balanced and updated education to farmers, rural agricultural extension officers and university students). This will facilitate the steering of human choices toward accomplishing more sustainable outcomes. Here, the European Union can learn from the NF movement in India, which was steered by NGOs and civil society groups but is now receiving support from the central and state governments.

II. Reviving Agrobiodiversity and Local Food Cultures

The revival of traditional agriculture based on indigenous and heterogenous seeds can also support the revival and nourishment of local agro-food systems (LAFS). These LAFS comprise local identity-based foods emerging from specific “territorial dynamics of agriculture, food and consumption networks.”Footnote ¹⁹⁰ By mobilizing territorial dynamics based on collective action, LAFS revive and encourage local food identity and add value to local resources, including agricultural landscapes and ecosystems, local knowledge, local social networks, food traditions and cultures, and native vegetable varieties and animal breeds.Footnote ¹⁹¹ While recognizing that many of the LAFS in Europe have been lost following the widespread adoption of conventional agriculture,Footnote ¹⁹² LAFS research currently focuses on studying remaining local systems or on using the concept as an approach for analyzing local agriculture and food-specific resources. Researchers are also studying its close connection with and impact on (agro)biodiversity.Footnote ¹⁹³

The ongoing COVID-19 pandemic is a reminder of the urgent need to ensure local self-sustainable food production. Given the vast and diverse agro-climatic zones present in various regions of the world, farmers in all countries can benefit socioeconomically as well as environmentally by adopting farming systems and regulatory policies that encourage the use of local biodiversity in agriculture and incentivize farmer-level innovations with this diversity.

III. Rethinking the DUS Test

In the light of mounting evidence in the form of scientific research as well as on-farm experiences of small and marginal farmers, it is necessary to rethink the DUS test and identify approaches that can incentivize and promote sustainable seed innovations, not in isolation of environmental and soil interactions, but in combination with sustainable farming practices. Such innovations can include seed improvements that go hand in hand with innovative and sustainable soil management practices, manure and farm waste (nutrient) recycling methods, and/or seed storage techniques that are cost-effective and implementable in rural, low income and low-tech environments.

Beyond regulatory efforts, recent research based on extensive consultations with natural farmers in India has also recommended the adoption of technological means such as blockchain or distributed ledger technology to support the transparent and traceable sourcing of materials and know-how from farmer-innovators and ensure benefit sharing with the help of smart contracts.Footnote ¹⁹⁴ Further research as well as funding for research and development, together with concerted international efforts, are needed to conduct more in-depth farmer interviews, build necessary prototypes and test the prototypes in real conditions to determine their acceptability, suitability and sustainability.

This is not to say that uniform varieties and the DUS test need to be done away with altogether. However, it is necessary to recognize that the unidirectional focus under current IP laws and associated regulations that incentivize and protect innovations only by the formal seed sector, or that permit the marketing only of certified uniform materials, is both inequitable and non-sustainable. Diversity in regulatory approaches is necessary to ensure that all potential innovators – in both the formal and informal sectors – can equitably participate in the landscape of seed innovations, while also protecting and enhancing agrobiodiversity for present and future generations.