Agricultural biodiversity

Unusual strains of maize are collected to increase the crop diversity when selectively breeding domestic corn.

Agricultural biodiversity is a sub-set of general biodiversity. It includes all forms of life directly relevant to agriculture: rare seed varieties and animal breeds (farm biodiversity), but also many other organisms such as soil fauna, weeds, pests, predators, and all of the native plants and animals (wild biodiversity) existing on and flowing through the farm. However, most attention in this field is given to crop varieties and to crop wild relatives. Cultivated varieties can be broadly classified into “modern varieties” and “farmer’s or traditional varieties”. Modern varieties are the outcome of formal breeding and are often characterized as 'high yielding'. For example, the short straw wheat and rice varieties of the Green Revolution. In contrast, farmer’s varieties (also known as landraces) are the product of (breeding and) selection carried out by farmers. Together, these varieties represent high levels of genetic diversity and are therefore the focus of most crop genetic resources conservation efforts. Agricultural biodiversity will also be absolutely essential to cope with the predicted impacts of climate change, not simply as a source of traits but as the underpinnings of more resilient farm ecosystems.[1] Agricultural biodiversity is the basis of our agricultural food chain, developed and safeguarded by farmers, livestock breeders, forest workers, fishermen and indigenous peoples throughout the world. The use of agricultural biodiversity (as opposed to non diverse production methods) can contribute to food security and livelihood security.

Scope

Although the term agricultural biodiversity is relatively new - it has come into wide use in recent years as evidenced by bibliographic references - the concept itself is quite old. It is the result of the careful selection and inventive developments of farmers, herders and fishers over millennia. Agricultural biodiversity is a vital sub-set of biodiversity. It is a use of life, i.e. ancillary biotechnologies, by Mankind whose food and livelihood security depend on the sustained management of those diverse biological resources that are important for food and agriculture.[2] As for everything, agricultural biodiversity can be used, not used, misused and even abused. Agricultural biodiversity includes:

However, agricultural biodiversity, sometimes called Agrobiodiversity, "encompasses the variety and variability of animals, plants and micro-organisms which are necessary to sustain key functions of the agroecosystem, its structure and processes for, and in support of, food production and food security".[3] It further "comprises genetic, population, species, community, ecosystem, and landscape components and human interactions with all these."[4]

Aquatic diversity is also an important component of agricultural biodiversity. The conservation and sustainable use of local aquatic ecosystems, ponds, rivers, coastal commons by artisanal fisherfolk and smallholder farmers is important to the survival of both humans and the environment. Since aquatic organisms, including fish, provide much of our food supply as well as underpinning the income of coastal peoples, it is critical that fisherfolk and smallholder farmers have genetic reserves and sustainable ecosystems to draw upon as aquaculture and marine fisheries management continue to evolve.

Genetic erosion in agricultural and livestock biodiversity

Genetic erosion in agricultural and livestock biodiversity is the loss of genetic diversity, including the loss of individual genes, and the loss of particular combinations of genes (or gene complexes) such as those manifested in locally adapted landraces or breeds. The term genetic erosion is sometimes used in a narrow sense, such as for the loss of alleles or genes, as well as more broadly, referring to the loss of varieties or even species. The major driving forces behind genetic erosion in crops are: variety replacement, land clearing, overexploitation of species, population pressure, environmental degradation, overgrazing, policy and changing agricultural systems.[5]

The main factor, however, is the replacement of local varieties by high yielding or exotic varieties or species. A large number of varieties can also often be dramatically reduced when commercial varieties (including GMOs) are introduced into traditional farming systems. Many researchers believe that the main problem related to agro-ecosystem management is the general tendency towards genetic and ecological uniformity imposed by the development of modern agriculture.[6][7] Pressures for that ecological uniformity on farmers and breeders is caused by the food industry demand for more and more raw materials consistency.

In the case of Animal Genetic Resources for Food and Agriculture, major causes of genetic erosion are reported to include indiscriminate cross-breeding, increased use of exotic breeds, weak policies and institutions in animal genetic resources management, neglect of certain breeds because of a lack of profitability or competitiveness, the intensification of production systems, the effects of diseases and disease management, loss of pastures or other elements of the production environment, and poor control of inbreeding.[8]

Genetic vulnerability

In plant breeding, a population of plants is considered genetically vulnerable if there is little genetic diversity within the population, and this lack of diversity makes the population as a whole particularly vulnerable to disease, pests, or other factors. The problem of genetic vulnerability often arises with modern crop varieties, which are uniform by design.[9][10]

An example of the consequences of genetic vulnerability occurred in 1970 when corn blight struck the US corn belt, destroying 15% of the harvest. A particular plant cell characteristic known as Texas male sterile cytoplasm conferred vulnerability to the blight - a subsequent study by the National Academy of Sciences found that 90% of American maize plants carried this trait.[11]

Change in agricultural biodiversity in human diets

Since 1961, human diets across the world have become more diverse in the consumption of major commodity staple crops, with a corollary decline in consumption of local or regionally important crops, and thus have become more homogeneous globally.[12] The differences between the foods eaten in different countries were reduced by 68% between 1961 and 2009. The modern "global standard"[12] diet contains an increasingly large percentage of a relatively small number of major staple commodity crops, which have increased substantially in the share of the total food energy (calories), protein, fat, and food weight that they provide to the world's human population, including wheat, rice, sugar, maize, soybean (by +284%[13]), palm oil (by +173%[13]), and sunflower (by +246%[13]). Whereas nations used to consume greater proportions of locally or regionally important crops, wheat has become a staple in over 97% of countries, with the other global staples showing similar dominance worldwide. Other crops have declined sharply over the same period, including rye, yam, sweet potato (by -45%[13]), cassava (by -38%[13]), coconut, sorghum (by -52%[13]) and millets (by -45%[13]).[12][13][14]

Human dependency

Agricultural biodiversity is not only the result of human activity but human life is dependent on it not just for the immediate provision of food and other natural resources based goods, but for the maintenance of areas of land and waters that will sustain production and maintain agroecosystems and the wider biological and environmental services (biosphere).

Agricultural Biodiversity provides:

Research supporting these findings addresses multifunctional agriculture in Europe, home gardens from around the world,[16] smallholder farms in the tropics,[17] among others.

Comparisons of Cropping Systems

The general trend noticed by the analysis of biodiversity present in different cropping systems (e.g., industrial agriculture and organic farming) was that a greater the diversity of crops (temporally and spacially) resulted in a greater overall biodiversity of the agroecosystem, though this is not always the case. A meta-analysis of studies comparing biodiversity noted that, when compared to organic cropping systems, conventional systems had significantly lower species richness and abundance (30% greater richness and 50% greater abundance in organic systems, on average), though 16% of studies did find a greater level of species richness in conventional systems.[18] Another study found that cropping systems that required heavy use of chemical amendments (e.g., the widespread broadcasting of pesticides and glyphosate, a practice ubiquitously found throughout the United States and Canada) had significantly greater levels of pollination deficits, whereas organic fields of the same crop (Canola) witnessed no pollination deficits.[19] Other cropping systems like permaculture have undergone little study to determine relative levels of biodiversity compared to other cropping systems, but because they continue to reinforce the goals of increasing overall crop biodiversity, it can be extrapolated that an even greater level of biodiversity would be observed.

Agroecosystems vs natural ecosystems

Agricultural biodiversity has spatial, temporal and scale dimensions especially at agroecosystem levels. These agroecosystems - ecosystems that are used for agriculture - are determined by three sets of factors: the genetic resources (biodiversity), the physical environment and the human management practices. There are not many ecosystems in the world that are "natural" in the sense of having escaped human influence. Most ecosystems have been to some extent modified or cultivated by human activity for the production of food and income and for livelihood security. However, most agricultural areas can be returned to their natural landscape after subsequent generations.

International negotiations

See also

Notes and references

  1. Frison, E.A.; Cherfas, J.; Hodgkin, T. Agricultural Biodiversity Is Essential for a Sustainable Improvement in Food and Nutrition Security. Sustainability 2011, 3, 238-253.
  2. FAO, (1996). Global Plan of Action for the Conservation and Sustainable Utilization of Plant Genetic Resources for Food and Agriculture. Food and Agriculture Organization of the United Nations, "Archived copy". Archived from the original on 2008-09-20. Retrieved 2008-09-05.
  3. FAO : SD Dimensions : Environment : Environmental conventions and agreements Archived December 13, 2004, at the Wayback Machine.
  4. Jackson, L., Bawa, K., Pascual, U., and Perrings, C. (2005).agroBIODIVERSITY: A new science agenda for biodiversity in support of sustainable agroecosystems. DIVERSITAS Report N°4. 40 pp. "Archived copy" (PDF). Archived from the original (PDF) on 2011-07-24. Retrieved 2010-02-27.
  5. FAO, (1997). The State of the World’s Plant Genetic Resources for Food and Agriculture. Food and Agriculture Organization of the United Nations, "Archived copy" (PDF). Archived from the original (PDF) on 2006-10-27. Retrieved 2008-09-05.
  6. Gao, L.Z., (2003). The conservation of rice biodiversity in China: significance, genetic erosion, ethnobotany and prospect. Genetic Resources and Crop Evolution, 50: 17-32.
  7. Guarino, L., (1995). Assessing the threat of genetic erosion. In: Collecting Plant Genetic Diversity: Technical Guidelines (eds. Guarino L, Rao VR, Reid R) pp. 67-74. CAB International, Wallingford.
  8. FAO. 2015. The Second Report on the State of the World’s Animal Genetic Resources for Food and Agriculture. Rome.
  9. Virchow, Detlef. Conservation of genetic resources: Costs and implications for a sustainable utilization of plant genetic resources for food and agriculture Springer, 1999. p22
  10. Eric Elsner. "Genetic Resources and Genetic Diversity". Retrieved 29 October 2014.
  11. Kloppenburg, Jack Ralph Jr. "First the Seed: The political economy of plant biotechnology, 2nd edition" University of Wisconsin Press 2004. 163
  12. 1 2 3 Khoury, C.K.; Bjorkman, A.D.; Dempewolf, H.; Ramirez-Villegas, J.; Guarino, L.; Jarvis, A.; Rieseberg, L.H.; Struik, P.C. (2014). "Increasing homogeneity in global food supplies and the implications for food security". PNAS. 111 (11): 4001–4006. doi:10.1073/pnas.1313490111.
  13. 1 2 3 4 5 6 7 8 Kinver, Mark. "Crop diversity decline 'threatens food security'". BBC. Retrieved 13 June 2016.
  14. Fischetti, Mark. "Diets around the world are becoming more similar". Scientific American. p. 72. Retrieved 13 June 2016.
  15. Thrupp, L. A. (2000) 'Linking agricultural biodiversity and food security: the valuable role of agrobiodiversity for sustainable agriculture', International Affairs, 76(2): 265-281.pdf
  16. Galluzi, G., Eyzaguirre, P. and Negri, V. (2010) 'Home gardens: neglected hotspots of agro-biodiversity and cultural diversity', Biodiversity and Conservation, 19: 3635-3654.
  17. Kull, C. A., Carriere, S. M., Moreau, S., Rakoto Ramiarantsoa, H., Blanc-Pamard, C. and Tassin, J. (2013) 'Melting pots of biodiversity: tropical smallholder farm landscapes as guarantors of sustainability', Environment, 55(2): 6-15.
  18. Bengtsoon, J., et al. (2005). The effects of organic agriculture on biodiversity and abundance: a metaanalysis. Journal of Applied Ecology, 42: 261–269.
  19. Morandin, Lora A., and Mark L. Winston. (2005). WILD BEE ABUNDANCE AND SEED PRODUCTION IN CONVENTIONAL, ORGANIC, AND GENETICALLY MODIFIED CANOLA. Ecological Applications, 15:871–881.

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