21140 January 2000 Promethe n :Science0W Agricultural Biotec nology *i: ORAL RESEARC .~~~ ; - -- ~~~ey w;~~~~~~~~~~~~~JA RESACH Promethean Science Agricultural Biotechnology, the Environment, and the Poor Ismail Serageldin and G. J. Persley t3 CONSULTATIVE GROUP ON INTERNATIONAL AGRICULTURAL RESEARCH ForjohnJ. Doyle, whose vision inspires us still Copyright (C 2000 Secretariat Consultative Group on International Agricultural Research 1818 H Street N.W., Washington, D.C. 20433, USA http://www. cgiar org Citation: Serageldin, Ismail, and GJ. Persley 2000. Promethean Science: Agricultural Biotech- nology, the Environment, and the Poor. Consultative Group on International Agricul- tural Research, Washington, D.C. 48 p. Technical Editor: L. Reginald Maclntyre ELS Contents Authors' Preface v Part 1 The Challenge 1 Global Food Security 1 Poverty in a Time of Plenty: A Paradox 1 World Food Production Challenge 3 Beyond the Green Revolution 4 Doubly Green Revolution 5 Double Shift in the Research Paradigm 5 Challenge of Biotechnology 7 Part 2 Enabling Technologies 12 Evolution of Modern Genetics 12 Gene Transfer Technologies 13 Understanding Plant and Animal Genes 13 Platform Technologies 15 Functional Genomics for Trait Discovery 15 Part 3 Putting Technologies to Work 18 Crop Improvement 18 Characterizing Biodiversity 21 Bioinformatics 23 Livestock Improvement 23 Diagnostics and Therapeutics 27 Part 4 The Way Ahead 31 Food for the Poor 33 Epilogue 36 Glossary of Terms 37 References 39 iii The CGR....... The Consultative Group on International Agricultural Research (CGIAR) is an informal association of 58 public and private sector members supporting 16 international agricultural research centers. The CGIAR's mission is to contribute to food security and poverty eradication in developing countries through re- search, partnership, capacity building, and policy support, pro- moting sustainable agricultural development based on the environmentally sound management of natural resources. The World Bank, Food and Agriculture Organization (FAO), United Nations Development Programme (UNDP), and United Nations Environment Programme (UNEP) serve as cosponsors. The Authors... Ismail Scrageldin, Chair of the CGIAR, is a Vice President of the World Bank for Special Programs. Before focusing on the Bank's special programs, he was Vice President for Environmen- tally and Socially Sustainable Development. He held earlier po- sitions as economist, Division Chief, and Director at the World Bank, dealing primarily with Africa, and the Middle East. He obtained his doctorate at Harvard University, and has published internationally on economic development, human resources issues, and the environment, with an emphasis on poverty alle- viation. GabrielleJ. Persley is an advisor to the CGIAR and the World Bank on biotechnology-related issues. She received her doctor- ate in microbiology at the University of Queensland, and worked for several years as a plant pathologist in Africa and Australia. Her work in recent years has focused on the role of biotechnol- ogy in developing countries. She has published widely, and is editor of a CABI-published series of books on Agricultural Bio- technology. Authors' Preface Prometheus, according to Greek harnessing the new findings in biotech- mythology, was a Titan, responsible nology for the benefit of the poor and the for introducing fire to humans, a re- environment. markable innovation at the time, but hav- It is here that the newly created Global ing benefits and risks, depending on its use. Forum for Agricultural Research must be Promethean has since come to mean dar- seen as an important new vector for bringing ingly original and creative. about the necessary collaboration amongst This book is a companion to the larger farmers, producer and consumer organiza- volume "Agricultural Biotechnology and tions, public and private companies, non- the Poor" which was published in January governmental organizations, national 2000. That volume reported on the inter- agricultural research systems, advanced re- national conference that the CGIAR and search organizations and international ag- the U.S. National Academy of Sciences co- riculture research institutes, including the sponsored with many other interested in- CGIAR centers. stitutions in October 1999. Our thanks are due to Per Pinstrup- There is a double shift in the research Andersen and Rajul Pandya-Lorch for per- paradigm: firstly, the need for greater mission to use material from the International contextualization of research, to be under- Food Policy Research Institute's Focus 2 series taken in the context of the deeper under- of briefs on biotechnology, which were pub- standing of the sustainable management of lished in October 1999 as part of the 2020 the environment and the socioeconomic Vision project. We are especially grateful and gender issues that affect the livelihoods to John Barton, Richard Flavell, Clive of poor people in rural and urban areas. James, Klaus Leisinger, and Ivan Morrison The second shift is the need to mobilize for allowing us to draw on their material. the new revolution in genetics and biotech- We thank also Peter Doherty, Val Giddings, nology to improve the productivity of agro- Declan McKeever, Noel Murphy, and Ana ecological systems and the crops, Sittenfeld for their helpful review of the livestock, fish, trees and other species im- manuscript. portant to poor people and developing The design and desktopping of this book countries. were done by Staci Daddona and Gaudencio Without minimizing in any way the Dizon. We thank them and also Shirley Geer vital importance of the first shift, this andSarwatHussainoftheCGlARSecretariat monograph is devoted to a discussion for their exceptional effort in getting this of the second shift, the challenge of book out in record time. Ismail Serageldin Gabrielle J. Persley v Schematic illustration of regions of origin of the major food crops and the locations of the research centers of the CGIAR ISNAR ICARDA Netherlands Syria IPGRI Italy IFPRI USA W ICRISAT India \. _ X Soyb~~~~~~~~~~~~~~~~ean CIMMYT Mexico ntain Mize, ________ ) IRRI Philippines BensPtt __ICLARM Malaysia CIAT Colombia 6C ssava; ˘V CFRI i Sogu _ _ CIFOR Indonesia CIP Peru - t t / K\ Grunut I$ - \ ,/ - C g - WARDA ILRI IWMI Cote d'lvoire ICRAF Sri Lanka Kenya IITA Nigeria Part 1 The Challenge T hroughout history, innovation has The World Food Summit recognized that driven progress and helped people eradication of poverty is a critical step in address the problems of their Age. improving access to food. Food security This progress has not been achieved with- covers both the availability of food at the out pain and controversy. At times, war, household level as well as access in terms famine, and pestilence thwart our best en- of purchasing power (FAO 1996). Most deavors. Despite setbacks, people the world people who are undernourished either can- over continue to strive to understand the not produce enough food or cannot afford to natural world, to pursue truth and beauty, buy it. Reduction and elimination of pov- and to create a better world for themselves erty is therefore an integral part of the pro- and their children. vision of sustainable global food security. Science has a role to play in all these pursuits. However, the very power of the new discoveries in the biological sciences Poverty in a Time of Plenty: raises fears that these discoveries will not A Paradox be used wisely. Many believe that they will accelerate the destruction of the natural Although the annual world agricultural environment, damage human health, con- growth rate has decreased from 3 percent centrate too much power in the hands of a in the 1960s to 2 percent in the last de- few global companies, and widen the gap cade, projections indicate that, given rea- between the rich and the poor, within and sonable initial assumptions, world food between nations. supply will continue to outpace world The task of the Promethean scholars population growth, at least to 2020 of today is to analyze where modern sci- (Pinstrup-Andersen, Pandya-Lorch, and ence can lead to technical innovations and Rosegrant 1999). Worldwide, per capita how these can be used wisely to improve availability of food is projected to increase agricultural productivity, conserve natural around 7 percent between 1995 and 2020, resources, and create wealth especially for and for developing countries, by 9 percent poor people in developing countries. (Pinstrup-Andersen, Pandya-Lorch, and Rosegrant 1999). The paradox is that despite the increas- Global Food Security ing availability of food, there ar-e about 840 million people, or 13 percent of the global population, wlho are food insecure. These A world of food-secure people is people are among the 4.5 billion inhabit- within our reach, if we take the ants of the developing countries in Asia (48 necessary actions. percent), Africa (35 percent), and Latin America (17 percent). Of these 840 mil- 1 2 PROMETHEAN SCIENCE AND 1 HE POOR lion, at least 200 million are malnourished Figure 1 Urban and rural population children. levels in developing countries, It is also paradoxical that food insecu- 1950-2020 rity is so prevalent at a time when global food prices are generally in decline. World 3.5 cereal production doubled between 1960 3.0 R Rural and 1990, per capita food production in- 2.5 Urban creased 37 percent, calories supplied in- 2.0 creased 35 percent, and real food prices fell by almost 50 percent (McCalla 1998). 1.5 w 1.0 , The basic cause of the paradox is the 0.5 , intrinsic linkage between poverty and 0 food security. Simply put, people's 1950 1960 1970 1980 1990 2000 2010 2020 access tofood depends on income. Source:United Nations, World Urbanizaton Prospects: The 1996 Revision (NewYork: UN, 1996). Poverty is both a rural and an urban phenomenon. Over 1.3 billion people in Food Security developing countries are absolutely poor, with incomes of tJS$1 per day or less per Food security is a complex issue that in- person, while another 2 billion people are volves: only marginally better off (WVorld Bank 1997 Maluttiionkills 40,000 people * Not just production, but also access 1997). Malnutrition kil 000pol Not just output, but also process each dav. Children and women are most I 0~~~~~~~~~ Not just technology, but also policy vulnerable to dietary deficiencies, with 125 million children affected by vitamin A * Not just global, but also national deficiency Many of the poor today live in ' Not JuSt t-oral, but also urbcin * Not just rural, but also urban the low-potential rural areas of the world. * Not just amount, but also content. With increasing urbanization, a higher pro- portion of poor people will be living in the Food production is a necessary but not cities of the developing countries. The rate sufficient condition for food securitv. Fo- of increase of the urban population in the cusing on improving the livelihood of developing countries will be approximately smallholder farmers in developing coun- six-fold that of rural areas (Figure 1). En- tries is key to environmental protection, suring their access to sufficient nutritious poverty reduction, and food security. The food at affordable prices is also an impor- need is to produce differently, not to pro- tant component of global food security duce less. strategies. Agricultural research needs to re- spond to both of these challenges, so as to Global Food Base improve the livelihood of the rural poor and ensure the increased availability of nutri- Humanity has a narrow food base. lwelve tious food at affordable prices for the urban crops accountfor 95 percent of the plantfood poor base. These are banana/plantain, cassava, PART 1 THE CHALLENGE 3 coni (maize), groundnut, millets, oil crops, creased from 71 million tons in 1961 to potato, rice, sorghum, soybean, sweet potato, 226 million tons in 1999. For developing and wheat. countries, it increased from 20 million There is also an increasing demand for tons to 122 million tons over the same milk and meat in the developing countries, period (Delgado and others 1999). as dietary preferences change, with increas- ing urbanization. Indeed, some consider Consumption Patterns that a "livestock revolution" is taking place in global agriculture that has profound im- Demands for food in developing countries plications for human health, livelihoods, are met by both local production and im- and the environment. Population growth, ports. Currently the developing world is a urbanization, and income growth in devel- net importer of 88 million tons of cereals/ oping countries are fueling a massive in- year at a cost of US$14.5 billion. Since the crease in demand for food of animal origin. 1970s the developing countries have be- These changes in the diets of billions of come large net importers of milk and meat people could significantly improve the as demand for livestock products increas- well-being of many rural and urban poor ingly exceeds supply. Net meat imports by (Delgado and others 1999). Although some developing countries will increase eight- of this increase will be met by local range- fold between 1995 and 2020. land production, some also requires in- Forecasts of future demands for plant creased production and/or import of feed and animal products that will drive the pro- grains and more intensive livestock produc- duction/import requirements of the vari- tion. FAO has nominated 14 priority spe- ous regions of the developing world will cies in its global strategy on farm animal need to take into account: (a) changes in genetic resources. The most important of dietary composition of both food and live- these for food production are cattle, sheep, stock products; (b) use of cereals as food goats, pigs, and chickens. Fish are also an and feed; and (c) the balance between pro- increasingly important component of the duction and import of plant and animal diet in developing countries (FAO 1999). commodities. Future Demands World Food Production Challenge IFPRI projects that global demand for ce- Production Trends reals will increase by 40 percent between 1995 and 2020, with most of the increase Yields of maize, wheat, and rice in devel- in demand coming from developing coun- oping countries increased from 1.15 to 2.76 tries. This will include a doubling in de- tons/hectare between 1961 and 1998. In mand for feed grains in the developing Africa, they increased from 0.81 to 1.22 world. Net cereal imports by developing tons/hectare over the same period. This countries will almost double by 2020 to presents a significant opportunity to raise meet the gap between production and de- cereal production in Africa through yield mand (Pinstrup-Andersen, Pandya-Lorch, increases. Globally, meat production in- and Rosegrant 1999) (see Figures 2 and 3). 4 PROMETHEAN SCIENCE AND THIE POOR Figure 2 Share of increase in global demand by region, 1995-2020 Cereals Meat products Sub-Saharan Latin Sub-Saharan Latin Africa America Africa America 10.6% 1.% 50 11.7% 1 Developed West Asia and 5.0% countries North Afric West Asia and .- ~~~~15.9% 5.%Developed West°t1 5.9r e Asia nacOun cuntres North Africa ~~~~~India 15.4% India||_ 12.6Rst of Asia Rest of Asia 14.2%128 China China 24.9% 40.6% World = 690 million ton increase World= 115 million ton increase Roots and tubers Sub-Saharan Africa West Asia 42.8% and North Africa 4.6% South Asia 6.0% Southeast Asia Latin America 6.0% 999% Developed countries East Asia 2.8% 19.9% World increase = 234 million tons Source: IFPRI IMPACT simulations, July 1999. Beyond the Green Revolution in improving agricultural productivity were a prerequisite to initiating the process of The food production increases over the past economic development. These policies 40 years have been achieved by increasing were supported by both the public and productivity of cereals, expanding the area private sectors of the international commu- of arable land, and massive increases in nity. The successful implementation of fertilizer use. these policies led to the Green Revolution. The key element in improving food se- Attention was given to the following issues: curity during 1970-90 was government research and development; technology policies reflecting a belief that investments transfer; human resource development; PART 1 THE CHALLENGE 5 Figure 3 Projected increase in total The international agricultural research demand for food, 1990-2020 centers also undertook the collection and conservation of the germplasm of their Percent mandate crops, established and maintained 160 f Developing countries large ex situ collections of this genetic 140 World material, and undertook its partial pheno- 120 - typic characterization. Some hundreds of 100 0 Developed countries thousands of accessions are now held in 80 trust by the CGIAR Centers, under the 60 auspices of the FAO Commission on Plant 40 Genetic Resources. 20 Cereals Meat Roots and tubers Doubly Green Revolution appropriate provision of credit; supply and To meet the food security needs of the distribution of inputs (seed, water, fertilizer, world's people in the decades ahead and to pesticide); appropriate pricing policies create wealth, there is a need to increase for inputs and outputs; and infrastruc- agricultural productivity on the presently ture. available land while conserving the natu- The scientific basis for the green revo- ral resource base (Conway 1997). Such a lution stems from joint national and inter- revolution would involve: national research programs, which led to the development and distribution of new, ' Increasing productivity of the major high-yielding varieties, primarily of wheat food crops and rice. These varieties gave improved anReducing chemical inputs of fertilizers yields, especially when grown in favorable and pesticides and replacing these with environments with the addition of fertil- biologically based products izer and pesticides. S Integrating soil, water, and nutrient Plant breeding was carried out with management multiple sites worldwide, north and south * Improving the productivity of live- of the equator. These trials were associated stock. with comprehensive production training programs for scientists and technicians Double Shift in the Research from national agricultural research systems. Paradi Informative data on the performance of the gn genetic materials were provided back to the The challenge now is how to use new coordinating center. Local breeding and developments in modern science, selection programs were later initiated by communications technology, and new the national agricultural research systems, ways of managing knowledge to make based on the international breeding mate- complex agricultural systemgs of rials crossed with locally adapted material. smallholderfarmers more productive in This increased the availability of locally a sustainable way adapted varieties for different ecosystems. 6 PROMFTHEAN SCIENCE AND THE POOR These issues make for a complex research decade. They include increasing privati- agenda to improve food security and create zation and competition amongst research wealth. This new research agenda needis to com- providers. These changes are also having a bine traditional wisdom with modern science. significant impact on donor perceptions, There is a double shift in the research policies, and financial support for national paradigm: firstly, the need for greater and international agricultural research. contextualization of research, to be under- There is a trend toward decreasing pub- taken in the context of the deeper under- lic sector investments in research and de- standing of the sustainable management of velopment. This is partially offset by the environment and the socioeconomic and increasing private sector investments gender issues that affect the livelihoods of largely aimed at generating new products poor people in rural and urban areas. This and processes through biotechnological research will need to seek synergies within advances. There is also an increasing use the farming systems of smallholders, who of participatory processes involving farm- integrate crop agriculture, livestock, ers, civil society, and other stakeholders in agroforestry, and aquaculture in complex the financing, planning, and conduct of re- fanning systems. search and technology transfer. These ap- The second shift is the need to mobilize proaches seek to enhance successful the new revolution in genetics and biotech- delivery of useful products and decision- nology to improve the productivity of agro- support systems to farmers and consumers. ecological systems and the crops, livestock, The coming into force of several inter- fish, trees and other species important to poor national treaties and conventions have also people and developing countries. increased the pressure on national govern- Without minimizing in any way the vi- ments to meet international obligations. tal importance of the first shift, this mono- graph is devoted to a discussion of the second New Modalities shift, the challenge of harnessing the new findings in biotechnology for the benefit of New developments in modern biotechnology, the poor and the environment. information technology, and geographic in- formation systems are revolutionizing global Role of Agricultural Research research and development in agriculture and natural resources research. Partnerships The annual rates of return to investment between national agencies and international in agricultural research average 50-80 per- groups may often be the most effective cent. Thus well directed agricultural re- means of developing and delivering new search and development programs remain agricultural research technologies of a pub- a wise investment of public funds (Alston lic goods nature. and others 2000). These programs need to involve vari- There have been several forces that have ous combinations of national agricultural resulted in the restructuring, downsizing, research systems, nongovernmental orga- and refinancing of agricultural and natu- nizations, the private sector, farmer groups, ral resources research systems in industrial advanced research organizations, and the and developing countries over the past international agricultural research centers. PART 1 THE CHALLENGE 7 new revolution in genomics and associated This challenge requires the CGIAR to technologies as aids for genetic improve- work with more partners, in a wider ment. The new technologies will enable array of environments, with a broader greatly increased efficiency of selection for range of commodities, often grown in valuable genes, based on knowledge of the mixed systems, and with concern for biology of the organism, the function of maintaining the physical and genetic specific genes, and their role in regulating resource base. particular traits. This will enable more precise selection of improved strains at The Genetic Imperative the molecular as well as the phenotypic level. Rapid progress is being made in understand- ing the genetic basis of living organisms, and the ability to use that understanding Challenge of Biotechnology to develop new products and processes useful in human and animal health, food Biotechnology (see Box 1) offers both prom- and agriculture, and the environment. ise and perils for the world community. In There is now increasing use of modern human health, it offers new ways to under- molecular genetics for genetic mapping and stand the genetic basis of diseases, and to marker-assisted selection as aids to improve develop improved diagnostics, drugs, and crops, livestock, fish, and tree species. vaccines for their treatment. In agriculture Other biotechnology applications such as and forestry, it promises new ways to har- tissue culture and new diagnostics and ani- ness and improve the biological poten- mal vaccines are being widely adopted. tial of crops, livestock, fish, and trees, and Harnessing the full power of the ge- improved ways to diagnose and control the netic revolution requires going beyond pests and pathogens that damage them. these early applications of modern biotech- The perils lie in the profound ethical nology, and recognizing the power of the issues surrounding the control and use of Box 1 Biotechnology defined The genome contains two copies of each gene, one having been received from each parent. Biotechnology is any technique that uses liv- The collection of traits displayed by any or- ing organisms or parts thereof to make or ganism (phenotype) depends on which modify a product, improve plants or animals, genes are present in its genome (genotype). or develop microorganisms for specific uses. The appearance of any specific phenotype All the characteristics of any given organism trait also will depend on many other fac- are encoded within its genetic material, which tors, including whether the genetic infor- consists of the collection of deoxyriionucleic mation responsible for the trait (or genes) acid (DNA) molecules that exist in each cell associated with it is turned on (expressed) or of the organism. The complete set of DNA off, the specific cells within which the genes molecules in an organism comprises its ge- are expressed, and how the genes, their ex- nome. The genome is divided into a series of pression, and the gene products interact with functional units, called genes. Typical crop environmental factors (genotype x environ- plants contain 20,000 to 25,000 such genes. ment effects). 8 PROMFTHEAN SCIENCE AND THF POOR these powerful new technologies, and the as- diversity of genes, including genes from sessment and management of risks to human distantly related species, into organisms health and the environment associated with than traditional methods of breeding and specific applications. These issues have led selection. Organisms genetically modified to rising public concerns in some countries in this way are called living modified organ- about various applications of biotechnology isms. Concerns exist about the potential The concerns have been stimulated by an ac- risks posed by living modified organisms. tivist campaign against the use of genetically The principles and practices required for improved organisms in food and agriculture assessment of technology-inherent risks are and their release into the environment. well established and draw on the experi- Modern biotechnology raises profound issues, ence of individual countries and regional but it also offers enormous promisefor deal- and international organizations. From an ing with previously intractable problems. ethical perspective, risks disallowed in in- dustrial countries should not be exported Key Issues to developing countries. If genetically en- gineered organisms and biotechnological The key policy issues that will affect the procedures are used in developing coun- application of new developments in mod- tries, state-of-the-art quality management ern biotechnology for the public good are that takes local ecological conditions into ethics, food and environmental safety eco- account must be practiced. Such risk as- nomic concentration, and intellectual prop- sessments allow governments, communi- erty management. ties, and business to make informed decisions about the benefits and risks in- Ethics herent in using a particular technology to solve specific problems. A wealth of scientific and popular discus- Technology-transcending risks ema- sion exists about the benefits and risks of nate from the political and social context genetic engineering and biotechnology in which a technology is used. These risks Confusion surrounds the issue of bio- stem from both the course the global technology's risks and benefits. What are economy takes and country-specific politi- the social and ethical issues surrounding cal and social issues. The most critical fears the use of biotechnology to improve food have to do with the potential aggravation security and alleviate poverty? Current of the prosperity gap between industrial public debate about the "gene revolution'" and developing countries and growing dis- often does not sufficiently differentiate be- parities in the distribution of income and tween risks inherent in a technology and wealth within and between developing those that transcend it. This differentiation countries. The gap in prosperity between is important in any attempt to reason out industrial and developing countries may the social and ethical implications of bio- grow because of the possible substitution technology (Leisinger 2000). of genetically engineered products for Since the early 1970s, recombinant tropical agricultural exports and because DNA technology has enabled scientists to the industrial world may not adequately genetically modify plants, animals, and compensate the developing world for ex- microorganisms and introduce a greater ploiting its indigenous genetic resources. PART 1 THE CHALLFNGE 9 Widespread fear exists that private en- quired, which takes account of public con- terprises and research institutes could gain cerns about genetically improved foods. unremunerated control of the genes of Many consumers in North America, Europe, plants native to the developing world and and China have been eating genetically im- use them to produce superior varieties that proved food over the past several years, with- would then be sold back to developing out any demonstrated adverse effects on countries at high prices. The successful human health. The concept and practice of implementation of the Rio Convention on risk assessment, including consistent ap- Biological Diversity so that it becomes clear proaches to the use of substantial equivalence who should compensate whom for what and the precautionary principle, are valuable and for how much needs unequivocal regu- tools but need to be kept under review. lation. Simple and effective ways need to Food labeling, whether mandatory or be found to establish fair compensation. voluntary, could be used to provide informa- In assessing the potential impact of bio- tion about specific products and enable con- technology on food security and povertty sumers to make informed decisions about alleviation, the interpretation of data is their use. The potential long-term impact of subject to the interests and value judgments genetically improved foods on human health, of a variety of stakeholders. Identical in- worker safety, and the environment is un- formation can lead some to consider agri- known, and requires monitoring and re- cultural biotechnologies to be amongst the search. Methods are available to test most powerful and economically promis- allergenicity and toxicity of novel genetically ing means of ensuring food security, while improved foods in humans. Post-market others perceive them as a threat to devel- monitoring of such foods may be possible in opment in poor countries. Differing reali- some markets but impractical in others. ties and pluralism of opinion exist. The Organization for Economic Coop- Biotechnology involves a number of eco- eration and Development will report in mid nomic, social, and ecological risks. But 2000 to the G8 Summit on key issues, these risks are not a consequence of the including: technology per se. They arise from particu- lar social settings, transcending the nature * Factual points of departure where there of the technology employed within those is agreement and disagreement settings. There are also ethical issues in- * Benefits versus risks, which differ for volved in not pursuing the use of new tech- different countries and environments nologies that may contribute to improving * Management of genetic modification the productivity and sustainability of agri- technologies culture, especially in developing countries * The role of stakeholders (Nuffield Council on Bioethics 1999). All * An international program of activities these issues need to be openly debated, and to inform the public debate and choices made by individuals and nations. policymaking. Food Safety Environmental Risks An open, transparent, and inclusive food When addressing risks posed by the culti- safety policy and regulatory process is re- vation of plants in the environment, six 1 0 PROMETHEAN SCIENCE AND THE POOR safety issues need to be considered (Cook thorize the shipment within a one-year pe- 2000; NRC 2000). These are riod. The Protocol also outlines general pro- cedures for risk assessment. The aim is to * gene transfer to wild relatives ensure that recipient countries have both * weediness the opportunity and the capacity to assess * trait effects any risks to biodiversity involving the prod- * genetic and phenotypic variability ucts of modern biotechnology. Capacity * expression of genetic material from building is also an important component pathogens of the agreement. The Protocol and the * worker safety. World Trade Organization are intended to be mutually supportive. The Protocol is not Review of these issues is inherent in the to affect the rights and obligations of gov- regulatory systems in place today (Doyle ernments under any existing international and Persley 1996). agreements. The Cartagena Protocol on Biosafety To ensure the safe use of biotechnol- was agreed to by 130 governments in ogy in the environment, there is a need for Montreal in January 2000. The Biosafety continuing emphasis on: Protocol is intended to specify obligations for international transfer of living modi- * Efficient and cost-effective regulatory fied organisms that may threaten bio- systems at the institutional and na- diversity. It sets out means of risk tional levels assessment, risk management, advanced in- * Clear guidelines for field tests and com- formed agreement, technology transfer, and mercial releases of living modified or- capacity building. ganisms Under the Protocol, governments will * Informative labeling of novel products signal whether they are willing to accept for consumers imports of living modified organisms in- * Systematic capacity building tended for release into the environment, * International support mechanisms for by communicating their decision via a early warning of good or bad develop- Biosafety Clearing House. Information on ments with living modified organisms living modified organisms that may be * More scientific research on possible contained in shipments of commodities short- and long-term effects of living will also be provided to importing coun- modified organisms on the environ- tries. ment and risks to biodiversity Advanced Informed Agreement proce- dures will apply to the introduction of Economic Concentration seeds, live fish, attenuated vaccines, and other living modified organisms that are to The trend toward intellectual property pro- be intentionally introduced into the envi- tection in biosciences has had several im- ronment and which may threaten portant structural consequences. The biodiversity. In all these cases, the exporter private sector life sciences industry has must provide detailed information to each become increasingly centralized. About six importing country in advance of the first companies dominate what was once an in- shipment, and the importer must then au- dustry in which many more small compa- PART 1 THE CHALLENGE I 1 nies played a major role. The reasons for licly funded agricultural research commu- this are complex. They relate to economic nity must also develop an effective ap- efficiencies in production and marketing, proach to cooperation with the private as well as the desire to access specific re- sector in research and product develop- search and development expertise in ment. The public sector needs to develop smaller companies. Intellectual property a policy toward intellectual property pro- protection has contributed significantly tection for its own discoveries. In doing so to the development of the current bio- it should set the example in terms of ben- technological revolution in agriculture, efit sharing with poor indigenous farmers, and to the institutional restructuring that and also to consider the possibility for the is accompanying that revolution (Barton public sector to obtain intellectual prop- 1999). erty protection to have bargaining chips to negotiate strategic alliances with multina- Intellectual Property Management tional companies. For national governments, it would be New scientific discoveries in biotechnol- desirable to design Trade-Related Aspects ogy may be protected by plant variety pro- of Intellectual Property Rights-compliant tection, patents, and/or trade secrets. legislation in a way that is beneficial to Countries differ in what forms of intellec- their agriculture, maintaining the possi- tual property protection may be applied to bility for a multilateral regime for germ- specific inventions. The 1995 Agreement plasm acquisition and transfer. Legislation on Trade-Related Aspects of Intellectual should be supplemented with improved Property Rights requires all members to capabilities in the courts, the law firms, provide at least a sui generis system of pro- and the law schools, so that the law can be tection for plant varieties. used effectively. There is a real possibility Industrial country moves toward in- that an antitrust code can be negotiated tellectual property protection of the prod- and this is almost certainly beneficial for ucts of biotechnology have led to developing countries. developing country moves to protect the Developing countries could also seek genetic sources. This culminated in the ways to use the intellectual property sys- Convention on Biological Diversity in tem to encourage research for their needs 1992. This agreement made it clear that by giving incentives, such as market pro- nations could enact legislation protecting tection, to encourage private-sector re- theexportofgeneticresources,byarrange- search on products of benefit to the ments to share the benefits should there developing world, in a manner analogous be financial return from the exported ge- to the Orphan Drug legislation. All such netic resources. legislation should be the result of substan- Because the private sector holds many tive public discussion and be adopted in a of the advanced biotechnologies, the pub- transparent fashion. Part 2 Enabling Technologies Evolution of Modern Genetics to obtain viable hybrids from distantly re- lated species. Gregor Mendel, the father of modern ge- The double helix structure of DNA netics, published his work on inheritance (deoxyribonucleic acid), the chemical sub- patterns in pea in 1865, but it took 35 years stance of heredity, was discovered in 1953 for others to grasp their significance. Since by James Watson and Francis Crick. This 1900, there has been steady progress in our triggered rapid progress in every field of understanding of the genetic makeup of all genetics, leading to a rapid transition from living organisms ranging from microbes to Mendelian to molecular genetic applica- humans. A major step was taken in the tions in agriculture, medicine, and indus- 1920s when Muller and Stadler discovered try (see Box 2). that radiation can induce mutations in ani- The most striking differences between mals and plants. In the 1930s and 1940s, the techniques of modern biotechnology several new methods of chromosome and and those that have been used for many gene manipulation were discovered, com- years in the breeding of new strains of crops mercial exploitation of hybrid vigor in and livestock improvement lie in the in- maize commenced, and techniques such as creased precision with which the new tech- tissue culture and embryo rescue were used niques may be used (see Figure 4). Box 2 Recombinant DNA a genetically improved organism or a living modi- technologies fied organism. The offspring of any traditional cross between two organisms also are geneti- In the 1970s, a series of complementary ad- cally improved relative to the genotype of ei- vances in the field of molecular biology pro- ther of the contributing parents. Strains that vided scientists with the ability to identify, have been genetically improved using recom- clone, and move DNA between close and binant DNA technology to introduce a gene i more distantly related organisms. This recom- from either the same or a different species binant DNA technology has reached a stage also are known as transgenic strains and the whereapieceofDNAcontainingoneormore specific gene transferred is known as a specific genes can be taken from nearly any transgene. Not all genetically improved organ- organism, including plants, animals, bacte- isms involve the use of cross-species genetic ria, or viruses, and introduced into any other exchange. Recombinant DNA technology also organism. This process is known as transfor- can be used to transfer a gene between differ- mation. The application of recombinant DNA ent varieties of the same species or to modify technology has been termed genetic modifi- the expression of one or more of a given plant's cation. An organism that has been improved, own genes, such as the ability to amplify the or transformed, using modern techniques of expression of a gene for disease resistance genetic exchange is commonly referred to as (Persley and Siedow 1999). 12 PART 2 ENABLING TFCHNOLOGIES 13 Gene Transfer Technologies Plants known as monocots (grass spe- cies such as maize, wheat, and rice) are not Two primary methods currently exist for readily infected by Agrobacterium so the introducing new transgenic genetic mate- external DNA that is to be transferred into rial into plant genomes in a functional the plant's genome is coated on the surface manner. For plants known as dicots of small tungsten balls and the balls are (broad-leaved plants such as soybean, to- physically shot into plant cells. Some of the mato, and cotton), transformation is usu- DNA comes off the balls and is incorpo- ally brought about by use of the bacterium rated into the DNA of the recipient plant. Agrobacterium tumefacienis. Agrobacterium Those cells can also be identified and naturally infects a wide range of plants by grown via cell culture into a whole plant inserting some of its own DNA directly into that contains added DNA. the DNA of the plant. By taking out the undesirable traits associated with Agro- bacterium infection and inserting a gene of Understanding Plant interest into the Agrobacterium DNA that and Animal Genes will ultimately be incorporated into the plant's DNA, any desired gene can be trans- The 1990s have seen dramatic advances in ferred into a dicot's DNA following bacte- our understanding of how biological or- rial infection. The cells containing the ganisms function at the molecular level, as new gene subsequently can be identified well as in our ability to analyze, under- and grown using plant cell culture tech- stand, and manipulate DNA molecules, the nology into a whole plant that now con- biological material from which the genes tains the new transgene incorporated into in all organisms are made. The entire pro- its DNA (Persley and Siedow 1999). cess has been accelerated by the Human Figure 4 Differences between conventional breeding and genetic engineering Source vanety/species Commercial variety Result Desired gene Conventional , . plant breeding Modern biotechnology ' (Source: Crops, Reed Business Information, U.K.) 1 4 PROMETIIEAN SC1INCE AND THF POOR Genome Project, which has invested sub- This is dramatically enhancing the rate at stantial public and private resources into which an understanding of the function of the development of new technologies to different genes is being achieved. This new work with human genes (Smaglik 2000). knowledge will radically change the future The same technologies are directly appli- of breeding for improved strains of crops, cable to all other organisms, including livestock, fish, and tree species (Box 3). plants, animals, insects, and microbes. The present major technical limitation Thus, the new scientific discipline of on the applications of recombinant DNA genomnics has arisen, which has contributed technology to improving agriculture is in- to powerful new approaches to identify the sufficient understanding of exactly which functions of genes and their application in genes control agriculturally important traits agriculture, medicine, and industry and how they act to do so. This is why new Genomics refers to determining the developments in understanding gene func- DNA sequence and identifying the location tion and linking this new information with and function of all the genes contained in breeding and genetic resources conserva- the genome of an organism. The advent of tion programs is so important. large-scale sequencing of entire genomes Research in plant genome projects, for of organisms as diverse as bacteria, fungi, example, is showing that many traits are plants, and animals, is leading to the iden- conserved (that is, shared) within and even tification of the complete complement of between species. The same gene(s) (DNA genes found in many different organisms. sequences) may confer the same trait in dif- Box 3 New technology developments * The comparison of physical and genetic in genomics maps and DNA sequences across differ- ent organisms will reduce significantly * Rapid developments in DNA sequencing the time frame for the identification and technology have made the acquisition of selection of potentially useful genes. Thus whole genome sequences a reality. Such the gene discovery process becomes data, when interpreted using new ana- shorter through comparative genomics, lytical tools, give a complete listing of all because many genes are conserved (i.e. the genes present in an organism, thus the same) between different organisms. providing a genetic blueprint of it. * The new genomics and new technologi- * Several technologies are being developed cal developments will accelerate the ac- for genome analysis that allow rapid quisition of fundamental knowledge genotyping and gene expression studies. It about biological systems. Genomes will should become possible to scan rapidly the change the approaches used to solve bio- genomes of different organisms and to de- logical problems, which will result in velop a systematic approach for mapping novel uses of biotechnology to develop genetic traits, both complex (controlled by and improve agricultural productivity. multiple genes) and single gene traits. * Marker-assisted selection will link with * Advances in bioinformatics may allow the more efficient gene-assisted selection, prediction of gene function from gene se- and will greatly facilitate and accelerate quence data. Given a listing of the genes the characterization of crop and livestock of an organism, it may become possible genetic resources, so they can be more to build a theoretical framework of the effectively deployed in different ecosys- biology of that organism. tems. PART 2 ENABLING TECHNOLOGIES 1 5 ferent species. Thus, a gene for salt toler- Second, different types of technologies ance in fish may confer salt tolerance if it have been developed for genome analysis, is transferred and expressed in rice. A gene which speed up the process. With the im- for drought tolerance in millet may also mense increase in the amount of DNA se- confer drought tolerance if transferred to quence data available, it is possible to scan maize. These advances in genomics should whole genomes rapidly and to develop a lead to a rapid increase in the identifica- systems approach for mapping genetic tion of useful traits that will be available to traits. enhance crop plants and livestock in the It is also possible to use the new devel- future. In other areas such as animal health, opments in bioinformatics to understand knowledge of the genome of a parasite such the complex genetic interactions involved as Theileria par va should assist in the iden- in growth, development, and environmen- tification of essential proteins of the para- tal interactions. Developments in bio- site against which an immune response can informatics are allowing the prediction of be targeted and hence may accelerate ef- gene function from gene sequence. Thus fective vaccine development when com- from genome sequences of DNA it is pos- bined with the necessary biology and sible to build a theoretical framework of immunology (see Box 4). the biology of an organism. This forms a powerful base for further experimentation. In addition, as the numbers of physical and Platform Technologies genetic maps of different species increase, it becomes possible to compare these across Rapid advances are occurring in three different organisms (comparative major areas: DNA sequencing, genome genomics), be they microbes, plants or analysis, and computational biology (bio- animals, and to significantly reduce the informatics). First, developments in DNA time required to identify important genes. sequencing have made the acquisition of These technologies allow novel approaches whole genome sequences possible. These to addressing biological problems, which data, when interpreted with bioinformatics, are just beginning to be understood. can provide a complete listing of all the genes present in an organism, the so-called genetic blueprint of an organism. Rapid Functional Genomics for Trait progress is being made in the Human Ge- Discovery nome Project, by both public and private laboratories. The first genome sequence of Much of the discussion about molecular an organism more complex than a virus was biology today is focused on the opportu- published in 1996. Already 23 genome se- nity and risks associated with gene trans- quences are available, and some 60 or more fer through transformation and the risks genome sequencing projects of a wide va- to human health and the environment as- riety of organisms, including plants, ani- sociated with the use of such living modi- mals, parasites, and microbes, are under fied organisms. The same science brings way (see The Institute for Genomic Re- new tools to assist plant and animal breed- search web site at http://www.tigr.org/). ers to identify and transfer genes through 1 6 PROMETHFAN SCIENCF AND THE POOR Box 4 Fighting East Coast Fever of disease intervention may arise from study- ing this phenomenon and the molecules that Parasitic diseases of livestock caused by mediate the process. This research may also Theileria species lead to annual losses esti- contribute to human medicine, particularly mated at US$1 billion worldwide. The most in leukemia research, by contributing to a important of this group of parasites in Africa greater understanding of the molecular is Theileria parva. This parasite causes East mechanisms of some human cancers. Coast Fever in cattle, which occurs in 11 The major mechanism of immunity countries of sub-Saharan Africa and kills against T. parva infection is known to be the about 1 million animals annually Farmers action of cytotoxic T cells. Each T cell recog- who own only a few cattle are disproportion- nizes a small fragment of a parasite antigen, a ately affected, because of the high percent- peptide fragment about 9 amino acid residues age mortality in affected herds. Also, they are long, that is displayed on the surface of the less likely either to be able to afford or have infected cells in association with major his- access to present control methods of chemi- tocompatibility antigens. Identifying these cal dips for stock, or the presently available peptide antigens directly is technically very infection/treatment vaccine, which costs ap- demanding. proximately US$25 per dose. As part of its strategy for East Coast Fe- A robust and affordable vaccine to pro- ver vaccine development, the International tect cattle against East Coast Fever in Africa Livestock Research Institute is now collabo- would be of great benefit to small-scale live- rating with The Institute for Genomic Research stock producers. Integrating the new find- to determine the DNA sequence of Theileria ings in genetics, immunology, molecular parva. It is estimated that the genome is about biology, and genomics offer promising new 10Mb and contains 5000-6000 genes (Nene strategies for vaccine development. and others 2000). East Coast Fever has a two-stage infec- From the genome sequence of the para- tive process. One prospective candidate an- site, all the genes encoded within the genome tigen (p67) has been identified by may be able to be identified using bio- International Livestock Research Institute informatics. From these data and the avail- scientists through molecular biology and able knowledge about the types of desirable immunology approaches. It is active at the protein antigens it should be possible to iden- first transient stage of infection and gives par- tify additional candidate vaccine antigens. tial but not sufficient protection to infected Using in vitro screens, it should then also be animals. It seems likely that an effective East possible to identify which ones to take fur- Coast Fever vaccine will need to be effective ther in terms of animal experiments. against both stages of the disease, The two collaborating institutes intend to In the second stage of the infective pro- place the genome sequence data for T parva cess, the parasites invade the host cells and in the public domain, as it becomes available. cause infected cells to behave like cancer In this way, it will be accessible to other re- cells. The parasites induce host cells to pro- search institutes concerned with developing liferate. The parasites attach to the cellular new vaccines for more effective control of T division apparatus and so divide in syn- parva and related parasites, such as T annulata, chrony with host cells, resulting in huge in- Babesia, Eimeria, Plasmodium, and Toxoplasma, creases in parasite numbers. New methods that cause disease in livestock and humans. PART 2 ENABLING TEC11NOLOGIES 1 7 conventional approaches. In many environ- molecular markers to assist the breeding ments, future gains in productivity will process. depend to a large extent upon manipula- Previously, the genetic resources were tion of complex traits, such as drought or provided largely by developing countries, heat tolerance. These are often difficult to and bred in publicly funded crop and live- identify and utilize in a conventional breed- stock breeding programs, the outputs of ing program without the additional help which were publicly available. Now, the of modern science. For future crop im- advent of private investments in research provement, plant genomic projects will be and development and strong intellectual the engine to drive trait discovery and help property protection has radically changed solve intractable problems in crop produc- this relationship. A new compact is re- tion and protection. quired to address the current imbalance. A completely sequenced plant genome The gathering and provision of so such as rice, for example, will provide an much sophisticated genetic information in enormous pool of genetic markers and genes computerized databases, by both the pri- for rice improvement through marker-as- vate and public sectors, and the patenting sisted selection in conventional breeding, of genes and enabling technologies require and/or the introduction of specific genes a new paradigm for using new biotechnolo- through transformation (see Box 5). gies to improve crops and livestock, espe- To fully exploit the wealth of molecu- cially in developing countries where food lar data it is necessary to understand the needs are most urgent. This paradigm re- specific biological functions encoded by quires public and private partnerships DNA sequence through detailed genetic amongst farmers, consumers, genomics and phenotypic analyses. Thus unlike ge- specialists, breeders, and scientists knowl- nome sequencing per se, functional edgeable about the species and the envi- genomics requires diversity of scientific ronments upon which the world depends expertise as well as genetic resources for for food. evaluation. In many important food crops national and international public sector research has a large investment in genetic X .i resources and breeding materials, and a long history of understanding biological function and genotype x environment in- .,.' S . X teractions. These scientific and biologi- g , i cal resources will become increasingly Y important in gaining knowledge about the function of genes and in developing Part 3 Putting Technologies to Work Crop Improvement when linked with new diagnostics, has been especially useful in vegetatively propa- The applications of modern biotechnology gated crops such as sweet potato and ba- to crops are in: nana and for the rapid propagation of tree species. Tissue culture is also a critical step * Improved diagnosis of pests and dis- in the construction of transgenic plants by eases enabling the regeneration of transformed * Tissue culture/micropropagation tech- cells containing a novel gene. niques * The construction of transgenic plants Modern Plant Breeding with improved yields, disease, pest, and stress resistance, and/or nuitritional The application of biotechnology to agri- quality culturally important crop species has tra- * The use of genetic markers, maps, and ditionally involved the use of selective genomic information in marker-as- breeding to bring about an exchange of ge- sisted and gene-assisted selection and netic material between two parent plants breeding. to produce offspring having desired traits such as increased yields, disease resistance, Diagnostics and/or enhanced product quality The ex- change of genetic material through conven- The use of monoclonal antibodies and tional breeding requires that the two plants nucleic acid technologies has improved the being crossed be of the same, or closely specificity, sensitivity, and ease of diagno- related, species. Such active plant breed- sis of plant pests and pathogens. These new ing has led to the development of superior diagnostics have also greatly assisted in the plant varieties far more rapidly than would study of the ecology of pests and diseases, have occurred in the wild due to random their more rapid identification in quaran- mating. tine, and in the propagation of disease-free Traditional methods of gene exchange, planting material. however, are limited to crosses between the same or closely related species. It can take Micropropagation Techniques considerable time to achieve desired re- sults, and frequently, genes conveying de- Tissue culture and other in vitro micro- sirable traits do not exist in any closely propagation technologies provide a practi- related species. Modern biotechnology, cal means of providing disease-free when applied to plant breeding, vastly in- plantlets of current varieties with signifi- creases the precision and reduces the time cantly improved yield gains by the removal with which these changes in plant charac- of pests and pathogens. Micropropagation, teristics can be made, and greatly increases 18 PART 3 PUTTING TECHNOLOGIES TO WORK 19 the potential sources from which desirable how they act to do so. This is the constraint traits can be obtained. that can be addressed through studies of The application of recombinant DNA plant genomes, as an aid to crop improve- technology to facilitate genetic exchange ment. in crops by transformation techniques has The rapid progress being made in several features that complement tradi- genomics should greatly assist conven- tional breeding methods. The exchange is tional plant breeding, as more functions of far more precise because only a single spe- genes are identified and able to be manipu- cific gene that has been identified as pro- lated. This may enable more successful viding a useful trait is being transferred to breeding for complex traits such as drought the recipient plant. There is no inclusion and salt tolerance. This would be of great of ancillary, unwanted traits that need to benefit to those farming in marginal lands be eliminated in subsequent generations, worldwide. Breeding for such complex as often happens with traditional plant traits has had limited success with conven- breeding. There has been some debate over tional breeding in the major staple food the transfer of antibiotic marker genes with crops. the single trait gene, and considerable re- Another important trait of great poten- search has now gone into eliminating the tial benefit to smallholder farmers would antibiotic marker genes from the final prod- be apomixis. This is the ability to propa- ucts prior to commercial use. Better still is gate plants asexually through seed. This to use markers that do not require antibi- would confer the benefits of hybrid vigor otics, such as new sugar-based markers. without the need to purchase new seed each The technical ability to transfer genes season. Research is underway by scientists from any other plant or other organism into at CIMMYT, Mexico, working with other a chosen recipient means that the entire collaborators in France and the USA, to span of genetic capabilities available among identify the genes conferring this trait. all biological organisms has the potential to be genetically transferred or used in any other organism. This markedly expands the Commercial Applications of range of useful traits that ultimately can Genetically Improved Crops be applied to the development of new crop varieties. Substantial commercial cultivation of the The use of genetic markers, maps, and first generation of new genetically im- genomic information will improve both the proved plant varieties commenced in the accuracy and time to commercial use of mid-lO10s. In 1999, approximately 40 mil- single and polygenic traits in plant breed- lion hectares of land were planted world- ing (for example, the use of marker-aided wide with transgenic varieties of over 20 selection in breeding for disease resistance plant species, the most commercially im- in rice is illustrated in Box 5). portant being cotton, corn, soybean, and The present major technical limitation rapeseed (Games 1999). These new crop on the application of recombinant DNA varieties are planted in Argentina, Austra- technology to improving plants is insuffi- lia, Canada, China, France, Mexico, South cient understanding of exactly which genes Africa, Spain, and, predominantly, the control agriculturally important traits and United States. Approximately 15 percent of 20 PROMETHEAN SCIENCE AND THE POOR Box 5 Moleculr breeding: blight problem. First DNA markers~ are used, i h a : f C; ft workSt:: 0 fort: rice:; i:to tag ne0tar all the bti b resistance genes in available genetic stocks. Second, Marker-assisted selection is the application of DNA, markers are used to describe the com- moleclatr lndmarks-usually DNA markers positio of pathogen populations unique to near target genes-to assist the accumulation each region. This parallel analysis of the host of desirble genes in plant varieties. There are and the pathogen has enabled scientists to many reasons why molecular markers are determine the right combination of genes to useful in plant breeding. Improved disease use in each locality resistance in rice is a good example. In Asia, a number of resistance genes Bacterial blight is a widespread disease in (xa4, xa5, Xa7, xal3, Xa2 1), all with molecu- irrigated rice-growing areas f and can cause lar tags, have been introduced in various com- widesprd yield loss.: The incorporation: of binats into locally adapted varieties host-plant resistance through conventional The Asian Rice Biotechnology Network breeding has beenthe most ecnomical means is promoting sharing of these elite lines and of control, and has eliminated the need for gene pyramids from different countries with pesticides. There are now over 20 gnes avail- other countries in Asia. This will allow the able for use in rice improvement, but not all useful marker-assisted selection products to of these genes are equally effective in differ- be rapidly disseminated through collabora- ent environments. The pathogen eventually tive field testing across the region. overcomes the resistant gene. Using conven- Marker-assisted selection has delivered tional approaches the plant breeder must be some of the promises of biotechnology, and continually adding and changing genes just there are other examples of use in rice. The to maintain the same level of resistance. Breed- impact of new selection techniques will con- ing effort spent in "maintenance" is a poten- tinue to be significant, particularly in an in- tial loss to gains in other traits. creasingly intellectual property-conscious A more sustainable system can be devel- environment. Marker technology is based on oped by deploying more than one resistance knowledge of endogenous DNA sequences; gene at a time. The challenge is to find the this has important practical implications, as right combination of genes and put them into the rice genome will be completely sequenced varieties most suitable for local production. by an international effort, led by the Rice When two or more genes are incorporated Genome Research Program of Tsukuba, Japan. into a variety it is called "gene pyramiding." As long as there is a public commitment to Up to four genes for bacterial resistance have maintain all rice sequences in the public do- been pyramided in rice, and there is evidence main, useful genes for marker-assisted selec- that collectively they are more effective than tion should be readily accessible to national would be ascribed to their additive effects. and international rice breeding programs. Beause each gene may mask the presence of Thus, because of their relative simplicity, easy another gene, it is difficult to pyramid more integration into conventionalibreeding, and than two genes by conventional breeding and minimal background intellectual property, selection; but it can be done with molecular DNA marker technology and marker-assisted m}a:rkers. : : :;: :::;i0;::H:0 selection are expecited to be strng driving Over the past several yea, scientists at forces in crto improvement -in the lfure. the International Rice Research Institute and its national partners in the Asian Rice Bio- Ken Fischer, Hei Leung and Gurdev Khush technology Network have applied DNA (International Rice Research Institute, marker technology to address the bacterial Philippines) PART 3 PUTTING TECHNOLOGIES TO WORK 21 the area is in emerging economies. The main a vital source for germplasm improve- value of the global market in transgenic ment. They need to be conserved in seed crops grew from US$75 million in 1995 to banks, and in situ where possible and de- US$1.64 billion in 1998. sirable. Genomics can play a key role in The traits these new varieties contain the characterization and conservation of are most commonly insect resistance (cot- genetic resources. It can be used to deter- ton, maize), herbicide tolerance (soybean), mine which genes and chromosome seg- delayed fruit ripening (tomato) and virus ments are duplicated, which are unique, resistance (potato). The main benefits of and how easy it will be to recreate the vari- these initial varieties are better weed and in- ous combinations of chromosome seg- sect control, higher productivity, and more ments in modern plant breeding programs flexible crop management. These benefits ac- (Flavell 1998). crue primarily to farmers and agribusinesses. Comparative genetics can enhance There are also economic benefits accruing exploitation of genebank collections. The to consumers in terms of maintaining food CGIAR has an opportunity to become an production at low prices. Benefits also ac- important player in the field, by exploit- crue to the environment through reduced ing its own comparative advantages of use of pesticides, and the reduction in car- germplasm management and enhance- cinogenic mycotoxins caused by fungal ment and its international network of re- contamination in food crops. search centers and collaborators. The Otler crop/input trait combinations pres- location of the Centers and their inter- ently being field-tested include virus-resis- national network of collaborators coin- tant melon, papaya, potato, squash, tomato, cide well with the centers of origin of the and sweet pepper; insect-resistant rice, soy- world's major food crops (see Map). bean, and tomato; disease-resistant potato; Jointly, the CGIAR, national programs, and delayed ripening chili pepper. Research and advanced laboratories now have an is aimed at modifying the oil content (rape- historic opportunity to work together to seed), increasing the amount and quality of make optimal use of new developments protein (maize), or increasing vitamin con- in science, for the molecular character- tent (rice) (James and Krattiger 1999). ization of agriculturally important spe- Much greater emphasis is now being cies and their wild relatives amongst given to improving the nutritional value plant, livestock, and microbial genetic re- of foods. There also is work in progress to sources to achieve their goals. use plants such as corn, potato, and ba- The application of comparative stud- nana as bio-factories for the production of ies to enhance the use and management of vaccines and biodegradable plastics. plant germplasm collections was the focus of an international workshop in The Hague in August 1999. It was co-organized by the Characterizing Biodiversity International Rice Research Institute and the International Service for National Ag- Genes and gene combinations selected in ricultural Research through the System- the past in nature and by humans will re- Wide Genetic Resources Program. 2 2 PROMETHEAN SCIENCE AND THE POOR The major finding was that the The initial potential of comparative ge- CGIAR centers must take advantage netics mav best be demonstrated with traits nowof.the-let techies where gene action is simple and well un- geomicresearchto apy derstood, such as resistance to some pests tive genetics to: the gerennpiasmand diseases, submergence tolerance, collections thatO* tehlin trut starch accumulation, nutritional qualities, (s -Wde Geetic Reources pbosphate uptake, resistance to soil toxic- Program 1999 : ity, weed competitiveness, and flowering response. Comparative studies may facili- The principal conclusions from the tate: workshop were that: * The systematic search for useful genes * Comparative genetics can provide the that contain these traits in germplasm most precise, unambiguous and com- accessions without having to discover prehensive tool for germplasm charac- the genes for each crop terization * Identification of genetic resources con- * Cross-species comparisons will allow taining useful genetic combinations identification of the germplasm sources * Understanding of the genetics under- of superior, potentially optimal genetic lying important traits sources for specific traits. Comparative * Better understanding of the structure genetics will provide a multilateral flow of biodiversity that will enhance man- of knowledge between major and mi- agement of germplasm collections. nor crops * CGIAR centers need to take the initia- Comparative genetics provides the po- tive to develop comparative genetics tential for trait extrapolation from a spe- research for several crops, including cies where the genetic control is well cereals, roots/tubers, and legumes understood, and for which there are mo- * Use of comparative genetics will help lecular markers, to a species that has a lim- reposition CGIAR genebanks for the ited amount of information. Rice, for future and enhance use of germplasm example, is regarded as a model for cereal in crop improvement programs genomics because of its small genome. The * The strong comparative advantage of similarity of cereal genomes means that the CGIAR centers to conserve, phenotype, genetic and physical maps of rice can be and use germplasm should be linked used as reference points for the explora- with expertise in comparative genetics tion of the much larger and more difficult existing in many laboratories worldwide. genomes of the other major cereal crops, This will require innovative investment and be applied to the minor cereals. Con- and institutional arrangements versely decades of breeding work and mo- * Additional investment by the CGIAR lecular analysis of maize, wheat, and barley in comparative genetics and bio- can now find direct application in rice im- informatics will ensure that the results provement. These studies are much more and benefits are available as interna- advanced for cereals than for roots/tubers, tional public goods. and legumes. This reflects the large public PART 3 PUTTING TECHNOLOGIES TO WORK 23 and private sector investments in the rice New discoveries in comparative genet- genome project, coordinated byJapan. This ics indicate a high degree of conservation has recently been strengthened by the de- of genetic material across the genomes of cision of Monsanto to donate its knowl- many species. This applies in terms of gene edge on the rice genome to the public sector order and gene structure and has impor- effort. Other investments on the maize and tant implications for the ability to trans- wheat genomes in Europe and North late findings in molecular biology in one America are making rapid progress. species to others. This process will not be The opportunities to apply compara- possible unless the bioinformatics tools are tive genetics now are furthest advanced in also compatible across species. the cereals in which considerable research Numerous research projects worldwide investment has already been made. are collecting genomic data. These are of- Investment in other agriculturally im- ten made available for bioinformatic analy- portant species, especially for tropical crops sis in public databases. The task of linking such as cassava, banana, and food legumes, these data resources, integrating the is limited. Without significant investment CGIAR's own contributions, and analyzing in the immediate future, the research gap the products is too great for any one CGIAR between the CGIAR centers, national center to handle. People with skill and ex- research institutes, and advanced labo- perience in this new and rapidly changing ratories already heavily involved in field are rare and dispersed. comparative genetics will widen. Collabo- The CGIAR centers have a unique role ration with advanced laboratories is essen- to play in the design and deployment of a tial to exploit fully the potential of bioinformatics system for use by the inter- comparative genetics on all the agricultur- national centers and their collaborators. ally important species. CGIAR centers need to work together and with advanced research institutes and NARS partners to develop, deploy, and ex- Bioinformatics tend an integrated bioinformatics system for the major food crops. This will require The CGIAR centers have gathered a huge new investments, new skills, and innova- resource of phenotypic data through the tive organizational arrangements that cut germplasm collections and the crop im- across traditional commodity, discipline, provement and international testing pro- and Center responsibilities. grams conducted over the past 30 years. Research in molecular biology, genome se- quencing, functional genomics, and com- Livestock Improvement parative genetics are producing large amounts of new genomic data. Bio- Constraints to Livestock Productivity informatics is essential for the manage- ment, integration, and analysis of pheno- Three groups of technical constraints need typic and genomic data if the promise of to be overcome to improve livestock pro- molecular biology for genetic improvement ductivity in the developing world. These is to be realized. relate to improvements in genetic potential, 24 PROMETHEAN SCIENCE AND TtiE POOR health, and management practices, includ- tainable method of disease control ing nutrition. In some cases these constraints (Morrison 1999), but technical challenges are specific to tropical and subtropical envi- remain to be resolved. ronments, such as specific diseases and There has been limited success in ex- stresses. In others, the constraints are shared ploiting the genetic potential of indigenous by industrial and developing countries. livestock breeds to resist disease and envi- Infectious diseases of livestock not ronmental stresses and to better utilize the present in the industrial countries, and for available natural feed resources. Further which there are as yet no sustainable means improvements in livestock genotypes now of control, present a formidable barrier to need to relate more to the quality of the increasing the efficiency of livestock pro- final product and the efficiency of its pro- ductivity in developing countries. duction rather than simple increases in quantity Improvements in animal health Disease is one of the major factors are moving from interventions at the level contributing to poor productivity of of the individual animal to interventions livestock in developing countries. In at the herd and flock health level, with a subiSharan Africa, animal losses focus on prevention rather than treatment due to disease are estimated to be and subclinical rather than clinical disease. US$4 billion annually, approximately Vaccines play an important role in disease a quarter of the total value of management by developing herd immunity livestock production. to target diseases Tsetse fly-transmitted trypanosomosis Applications and tick-borne diseases are the most im- portant disease problems in developing The main applications of new biotechnolo- countries. Therapeutic agents are available gies to livestock are in the areas of genetic for some of these diseases, but problems improvement, reproductive technologies, remain. Chemotherapy, based on the use and animal health. These new technologies of trypanocides, has problems due to tox- speed up the reproductive process in ani- icity, residues in milk and meat, and the mals and enable the more efficient selec- excretion of large quantities in feces that tion of breeds with improved productivity are then applied to crops. Some of the Animal genome projects are also shorten- trypanocides are potential carcinogens and ing the gene discovery process and dem- would not be licensed for use in industrial onstrating many potential applications countries. Intensive application is creating where the manipulation of the genome may drug-resistant organisms. be useful in livestock improvement. Current drugs have been in use for over The fundamental differences in repro- 30 years. The problem of drug resistance duction between plants and animals are is becoming acute in some regions, and the reflected in the significant differences in likelihood that new drugs will be devel- the costs and efficiency of effecting pro- oped is low due to development costs and duction increases through breeding pro- lack of return on investment. Vaccination grams. These differences favor investments offers a potentially more effective and sus- in crop rather than livestock breeding and PART 3 PUTTING TECHNOLOGIES TO WORK 25 for short-term rather than long-term fying molecular markers with desirable bio- returns. logical and commercial traits is under way. Phenotypes of commercial livestock The applications of these technologies to fish breeds that are highly productive in tem- are illustrated in Box 6. perate climates and intensive production Another example of the use of molecu- systems do not realize their production lar markers has been in tracing the origins potential in subtropical/tropical production of different cattle breeds. Genomes contain systems. This is due to a number of factors the history of the origin and evolution of including dietary constraints, adaptability the different cattle breeds and modern to local environmental conditions, and molecular techniques have been used to susceptibility to disease. rapidly decipher their story (Bradley and National structures in developing others 1996; Hanotte and others 2000). countries, whether public or private, have The physical location of individual often been unsuccessful in commercially genes on chromosome maps is also well exploiting the production capacities of in- advanced. The rapid development of both digenous livestock, which are adapted to linkage and physical maps of the genomes the local environment and diseases, by se- of domestic livestock is a clear example of lective breeding or some form of cross- how the large investment in basic biology breeding with exotic genotypes. This has (the construction of genetic maps of mouse been due to the need for long-term invest- and humans) can effectively and economi- ment in such breed improvement programs cally be captured to the benefit of domes- and their complexity of management, es- tic livestock improvement. pecially when only small numbers of live- The International Livestock Research stock are present on individual farms. Institute (and previously the International Performance recording schemes are diffi- Laboratory for Research on Animal Dis- cult to initiate and maintain, making breed- eases) has been involved for the past de- ing, selection, and expansion of improved cade in a worldwide collaborative effort to livestock an expensive and inefficient pro- create and improve the genetic maps of the cess (Doyle 1993). bovine genome and to identify markers as- sociated with genetic resistance to trypa- Molecular Breeding nosomosis. The use of such maps will significantly reduce the generation time for Advances have been made in overcoming the developing improved breeds, as compared genotypic constraints to increased produc- to conventional breeding procedures based tion efficiency. Improvements have been solely on phenotype selection. The deter- made both in genetic characterization at the mination of genetic distances, together with molecular level, and in technology to expand genetic maps, also will increase the effec- rapidly the available numbers of improved tiveness of measures for conservation of en- genotypes. In molecular characterization, dangered livestock species by allowing linkage maps of sufficient resolution for use characterization at the genetic rather than in breeding improvement schemes based on phenotypic level. marker-assisted selection are now available The application of comparative for cattle, pigs, poultry, and fish. These maps genomics between breeds and species may are being refined, and the process of identi- mean that such selection strategies in one 26 PROMETHEAN SCIENCF AND THE POOR Box 6 Application ofboehooSex manipulation (for exmple, the pro- in ftsheries and aquaculture duction of all male populaions fish,l es- Pecially tilapia) is also an active area of Th:ere is growing importan or eseartc, designed to avoid the detrimental markers for biodiversity reproduction effects of early maturation and mapping, and trimt selectionin isanote cessation of got.in carp species, how- aquaic oranis. Internationat ps are er,1 alfemale populations are required. It already colaborating on dev is also anticipated Vthat sex reversal will be maps of tilapia, common carp, salm s, used more widely in breedin programs to catfish, zebrafish, and pufferfh. apsfr increase the speed of producton of inbred cm allyi t invete spe ies lines. Haploid fish will be i t for Irincluding shrimp and oysters are being similar reasons. initiated. A wide range of new molecular diag- The0 feasibility of develop an using nostic techniques is being developed for ap- transgenic species of fsh is being explored plications such as disease diagnosis, sexing by several research institutes and companies of juvenile fish, and for assessing progeny in the fisheries and aquaculture sectors on relationships in large populations of fish variousspecies including tilapiaand salmorn. raisedtother to reduce environment-spe- It is antid that there will be an increase cific variations in production. Other tech- in the number of species and strains into niques incllude tissue culture, or other which genes are introgressed, ad the. num- manipulations of embryos or embryonic ber of gene constructs available for trans- cells, for the isolation of viruses, bacteria, genesis (goverming biological functions in and fungi p g to fs. addition to growth) wwillalso be increased. Trainsgenesis maybecomne a costeffective means of enhancing indigenous Species im- Source: Intemational Center for Living Aquatic portant to one or a few countries and not Resources Management. covered by international breeding efforts. species/breed may be more easily adapted This is because of present lack of fund- to that of other species/breeds, when look- ing, the low commercial value of the breeds, ing for similar traits. However, because of lack of effective conventional breeding pro- the high cost, genomics technology is pres- grams in developing countries, and the re- ently being applied more to the lucrative quirements to conduct selection in the markets, breeds, species, and production relevant production environments due to environments of the industrial world than high genotype x environment effects in to the needs of livestock improvement in animal breeding. the developing countries. The applications of biotechnology to fisheries and aquaculture offer the prospect The concerted application of modaen of increasing the efficiency of protein pro- breeding strategies for livestock of duction, and the speed of conversion of relvance to smaliholder production feed to protein. They may also enable eco- in developing countries is unlikely to nomically efficient protein production in occur in the absence or enclosed aquaculture, and reduce prob- sector inititives 000000f000 0lems of effluent disposal (see Box 6 for applications). PART 3 PUTTING TECHNOLOGIES TO WORK 27 Transgenic Livestock Livestock Genetic Resources Technology exists for the creation of There is potential to find genes for disease transgenic livestock including mammals, tolerance and other adaptive traits such as birds, and fish. Practical applications of the heat tolerance in wildlife and transferring technology are presently restricted to pro- these to domestic livestock. In disease re- duction of human biological pharmaceu- sistance, for example, this would have ticals in the milk of sheep. Small herds of greater impact in developing than in in- transgenic animals are likely to be able to dustrial countries. produce sufficient quantities of high-value There are possible opportunities for the biological products, such as pharmaceuti- developing countries, through the analy- cals, in the immediate future. There has also sis of the genomes of their unique animal been work on the creation of transgenic genetic resources, to identify genes encod- lines of virus-resistant poultry, which con- ing traits that may be of benefit to both tain a modified virus gene that confers dis- developing and industrial countries. Al- ease resistance. A similar strategy has though the animal genetic resources in proved useful to introduce virus resistance developing countries are plerntiful, they in plants. have not been tapped to any great extent. In the future, transgenic pigs may be The characterization of these genetic re- used as a source of tissue and organ trans- sources may offer opportunities for devel- plants to humans, provided safety and ethi- oping countries to benefit from their cal concerns are met. The major health appropriate use and agreed benefit sharing issue for review and research at present is (FAO 1999). the possible trans-species movement of vi- ruses from pig tissue to humans. The impact of transgenic animals on Diagnostics and Therapeutics animal breeding and production is pres- ently limited by the dearth of single gene Molecular technologies are also applicable traits in livestock, and the fact that the to the study of livestock parasites and other propagation process of a transgene in an pathogens. They provide effective means animal population is relatively slow for identifying, isolating, characterizing, (Cunningham 1999). There is also a risk and producing molecules that can be used that the desired gene may not be inherited to induce protective responses against the by subsequent generations or may be parasite (Morrison 1999). The new tech- turned off in the offspring from a transgenic nologies can also be used to generate prod- animal. ucts and gene sequences, which can form If desired genes controlling a trait can the basis of improved diagnostics. They be identified and transferred, their expres- also provide effective means of elucidating sion physiologically controlled and the trait the metabolic pathways of pathogens that is heritable, then a quantum leap in im- confer drug resistance or drug sensitivity provements in livestock productivity can on these organisms. Genetic markers are be envisaged. increasingly being used to identify with 28 PROMIETHEAN S(-IFNCL AND l HE POOR greater precision the species, subspecies, exploitation of recombinant DNA technol- and types of pathogenic agents. Recom- ogy requires knowledge of the target patho- binant or genetically modified pathogens gens and the immune responses they also offer new approaches to vaccine de- induce, as well as an understanding of how livery, as does direct injection of DNA into those immune responses can be manipu- animals. lated. Such information was lacking in the Disease, however, is the result of the early 1980s. There has been a series of fun- interactions of two genomes - the patho- damental discoveries in immunology that gen and the host. To exploit the new tech- have led to a detailed understanding of how nologies, particularly for the development the immune system processes and recog- of vaccines and for the exploitation of dis- nizes pathogenic organisms, and the dif- ease resistance traits, it is important to un- ferent ways that infections are controlled derstand the biology of the pathogen as by immune responses. This new knowl- well as the host. edge is directly relevant to all stages of vac- cine development, from identification of Vaccine Development the genes or proteins that need to be in- corporated into a vaccine, to the design of The use of vaccines in disease control has a vaccine delivery system that will induce the advantage of using an already existing a particular type of immune response. domestic animal gene pool. From a man- These advances, coupled with further de- agement/breeding point of view this is lo- velopments in the application of DNA tech- gistically easier to consider as a disease nology, now provide a strong conceptual control strategy than using marker- or framework for the rational development of gene-assisted selection to breed disease-re- new vaccines (Morrison 1999). sistant strains of improved domestic ani- Two main approaches are being pur- mals. Vaccines developed using traditional sued to develop vaccines using recombi- approaches have had a major impact on the nant DNA technology The first of these control of the epidemic viral diseases of involves the deletion of genes that are livestock, such as foot-and-mouth disease known to determine virulence of the patho- and rinderpest. There are many other im- gen, thus producing attenuated organisms portant diseases, notably parasitic diseases, (nonpathogens) that can be used as a live for which vaccines have not been devel- vaccine. This strategy is presently more oped successfully. appropriate for viral and bacterial diseases Rapid advances in biotechnology and than for protozoan parasites. Attenuated immunology over the last two decades have live vaccines have been developed for the created new opportunities to develop vac- herpes viruses that cause pseudorabies in cines for parasitic diseases. Initial optimism pigs and infectious bovine rhinotracheitis in the early 1980s that vaccine products in cattle. would quickly emerge from applications of The second strategy is to identify pro- recombinant DNA technology has not been tein subunits of pathogens that can stimu- fully realized. Subsequent experience has late immunity. This is the preferred demonstrated that, unlike traditional ap- approach to many of the more complex proaches to vaccine development, effective pathogens. It requires knowledge of the PART 3 PUTTING TECIIOLOGIES TO WORK 29 immune responses that mediate immunity, responses they induce are usually more lim- which helps identify the relevant target pro- ited and of shorter duration than with live teins. The strategy can be illustrated by the vaccines. Advances in biotechnology have approach taken by the International Live- provided a number of alternative vaccine stock Research Institute to develop a vac- delivery systems for subunit proteins that cine against Theileria parva, the parasite overcome these shortcomings and offer that causes East Coast Fever of cattle in sub- some of the advantages provided by live Saharan Africa. Studies of immune re- vaccines. Two of the most promising ap- sponses to the parasite have revealed proaches are the use of attenuated organ- antibody responses to the tick-derived in- isms as live vectors and vaccination with fective stage of the parasite, as well as cell- DNA (Morrison 1999). mediated immune responses against the Live-vectored vaccines involve the in- parasite stages that reside within cattle cells. corporation of a gene encoding a subunit A parasite protein recognized by the antibody protein into the genome of an attenuated response and the corresponding parasite gene organism, which itself may be in use as an (p67) have been identified. Protein expressed attenuated vaccine. The protein is then from this gene, when used to vaccinate cattle produced when the organism replicates in under experimental conditions, has been the animal. shown to protect a proportion of animals against the disease. Identification of the para- A vacine containing a rabies virus site proteins recognized by the cell-mediated gene has been used to protect foxes immune responses presents a greater chal- agai"t -rabies and its use has resulted lenge, but a number of recently developed in the eradication of rabiisfrom methodologies for this purpose are now be- northern continentat Europe. ing applied to the problem (McKeever and Morrison 1998). As part of its strategy for The use of DNA for vaccination is the development of a vaccine against East based on the discovery that injection of Coast Fever, the International Livestock Re- genes in the form of plasmid DNA can search Institute is collaborating with The In- stimulate immune responses to the respec- stitute for Genomic Research to map the tive gene products. This occurs as a result genome of T parva (Nene and others 2000) of the genes being taken up and expressed (see Box 4). by cells in the animal following injection. Stimulation of immune responses and par- New Vaccine Delivery Systems tial protection have been reported for a number of pathogen genes in livestock spe- Live attenuated vaccines stimulate immune cies, but none of these has yet led to a fully responses similar to those induced by the effective vaccine. The live vector and DNA parent pathogen, and usually provide vaccination systems are amenable to fur- long-lasting immunity. Vaccines using ther manipulation to enhance the immu- killed organisms require incorporation of nity-conferring characteristics of the gene adjuvants (agents that enhance immunity- products. Experimental studies have dem- giving characteristics), and the immune onstrated that these systems have enor- 30 PROMETHEAN SCIENCE AND THE POOR mous potential for development of vaccines identification of genes essential for caus- that induce appropriate and enduring im- ing infection and disease and thus the iden- mune responses. tification of targets for vaccine development. New vaccines are likely to be produced Vaccine development for domestic live- against some or all of the major animal dis- stock could benefit from technology eases, given the necessary scientific and fi- spillovers from vaccine development for nancial resources. The complexity of the humans because the same research con- problems that are being addressed should cepts and approaches can be applied, albeit not be underestimated. The opportunities to different pathogens. Public-private sector presented by advances in biotechnology cooperation emerging in the eradication of can only be exploited effectively if there is polio, and in the search for a malaria vac- a thorough understanding of the biology cine, may yield innovative research coop- of the target pathogens and the diseases eration models and knowledge that could they produce. The new technologies allow be applied to vaccine development and detailed studies on the two interacting delivery for the benefit of smallholder live- genomes, the pathogen and the host, the stock producers in the developing world. Part 4 The Way Ahead T he Human Genome Project is pro- at traits of interest to producers and con- viding a major impetus to under- sumers in industrial countries. The current standing the genetic basis of life. It debate over the value of these new prod- is, for example, resulting in the early iden- ucts is also largely dominated by the per- tification of predisposition to genetic dis- spectives of civil society in industrial eases, such as cystic fibrosis and breast countries. The potential value of modern cancer, leading to earlier detection and bet- science in producing food for the poor will ter treatments. The applications of mod- not be realized without major additional ern science are strongest in health care efforts involving all stakeholders, includ- where they offer new hope to patients with ing civil society small-scale farmers, urban AIDS, genetically inherited diseases, dia- consumers, and governments in develop- betes, influenza, and some forms of can- ing countries. cer. Biotechnology-based processes are now used routinely in the production of many The need to produce sufficient food new medicines, diagnostics, and medical for the worldt population is urgent, therapies. compelling, and complementary to These new developments are underpin- improving human health. ning important new international health initiatives, such as the the children's vac- About 73 million people will be added cine initiative. This will be the basis of fur- to the world's population every year from ther international health initiatives as new now until 2020. Much of this population order vaccines and therapeutics are devel- growth will occur in the cities of the de- oped. The important initiatives in the health veloping world. Meeting world food needs sector, such as the "Roll Back Malaria Cam- requires increases in production and pro- paign," are being sponsored by the World ductivity, and matching these to dietary Health Organization, the World Bank. and changes, including the rapidly increasing private foundations. These initiatives are demands for livestock and fish as sources mobilizing expertise and financial re- of protein. Demand for meat in the devel- sources of governments, international oping world is projected to double between agencies, private foundations, and the phar- 1995 and 2020. maceutical industry They are expected to World grain production will need to lead to major improvements in human increase by 40 percent by 2020, while the health over the next decades. increases in crop yields have been plateau- Modern science offers the potential for ing. Neither meat nor cereals production similar major contributions to improving in the developing world is keeping pace food security and nutrition of the poor. with demand, and imports are increasing However, the large private sector invest- (Pinstrup-Andersen, Pandya-Lorch, and ments in modern bioscience are directed Rosegrant 1999). 31 32 PROMETHE-AN SCIENCE AND THE POOR Under this scenario, food insecurity Kenya, and South Africa, amongst others and malnutrition will persist to 2020 and (Persley and Lantin 2000). beyond. The International Food Policy Re- However. the major research and de- search Institute predicts that, without sig- velopment efforts of the private sector in nificant new developments in increasing biotechnology have been directed at op- productivity, 135 million children under 5 portunities for introducing traits useful to years of age will be malnourished in 2020, producers and consumers in the markets a decrease of only 15 percent on 1995. in industrial countries. This is where bio- Approximately 77 percent of these children science companies hope to recoup their will live in Africa and South Asia. investments. Initial research and develop- The most promising approaches to in- ment has concentrated on production traits creasing productivity on small-scale farms such as insect resistance. More recent em- are agro-ecological approaches, albeit phasis is on products with improved nu- recognizing the potential role of modern tritional qualities. biotechnology, and the use of modern It is the responsibility of civil society information technology and precision and governments, at the national and in- farming. It wvill require the successful inte- ternational level, to ensure that develop- gration of these three approaches to achieve ing countries consider the benefits and the full potential of modern science and risks of the use of modern science. All ensure the necessary increases in produc- stakeholders need to assess the potential tion while conserving the natural resource benefits and risks of new technologies to base. reduce food insecurity and poverty. This The initial applications of modern bio- will require communicating about the role technology to commercial agriculture have of science in development. It will require resulted in new genetically improved vari- also mobilizing the expertise and resources eties of maize, cotton, rapeseed, soybean, of both the public and private sector na- and potato. These were grown on 40 mil- tionally and internationally to address the lion hectares worldwide in 1999, increas- specific problems that damage human ing from 1.5 million hectares in 1996. health, constrain agricultural productivity Fifteen percent of the area is in emerging and threaten the environment. New ap- economies of Argentina, China, Mexico proaches that mobilize both public and and South Africa. There are also applica- private resources and involve nongovern- tions to livestock and fish, largely related mental bodies are needed if poor people to the production of more productive are not to be bypassed by the revolutions strains of commercially important species in science and information technology and the development of useful diagnostics This strategy of using modern science and vaccines. as a component of the overall policy to fos- Several emerging economies are mak- ter sustainable economic development, ing major investments of human and finan- reduce inequities, and improve the liveli- cial resources in biotechnology with the hoods and well being of the poor, will re- aim of using these new developments in quire good governance and political skills science to improve food security and and leadership of a high order, and new reduce poverty. They include Argentina. polices and actions by governments Brazil, Mexico, China, India, Thailand. (Persley 1999; wvwv.ifpri.org). PART 4 THE WAY AHFAD 33 Food for the Poor increase the productivity of major food crops and livestock in the tropics, and en- To achieve the required productivity in- hance their ability to be more productive creases in crop and livestock production in difficult environments. to keep pace with population growth, there is a need for a major global effort on Food 3. Conserve and Characterize Genetic for the Poor. Its purpose would be: Resources: Maintain and characterize the farm animal and plant genetic resources of the world's major agricultural species. The Tosmobilice andtehenewodlogypretse i largest in vitro collections of plant genetic sciene anoductivitf techne tor ireae resources are held in trust for the interna- the productivity of the world's twelve toa omnt yteCIRcnes major food crops,five species of A recent review commissioned by the livestock, andfish, that provideArentevwcomsiedbth lvestckend of tha provide CGIAR Technical Advisory Committee sug- 95dperelopintgof thoorld. mgests that it will require US$70 million to upgrade the present plant collections, and thereafter US$8 million per year to main- Several actions are urgently required to tain them. Additional investments are re- accomplish this, the most important of quired to collect, characterize, and conserve which are: farm animal genetic resources (see FAO 1999). The in vitro and in vivo collections 1. Plant and Aniinal Genomes: Ensure of plant and animal genetic resources, and that the descriptions of genomes of the ag- the biological information pertaining to riculturally important species are mapped them, are a vast but underutilized resource and that this information is put in the pub- for genetic studies and the identification lic domain, able to be used by scientists of useful traits. worldwide to generate improved crop va- rieties and livestock breeds adapted to lo- 4. Access Enabling Technologies: Obtain- cal ecosystems, and useful biological ing access to key enabling technologies in products. The species are: banana, cassava, agricultural biotechnology, many of which maize (corn), groundnut, millets, oil crops, are proprietary technologies held by the potato, rice, sorghum, soybean, sweet po- private sector, is key to the successful tato, wheat; cattle, sheep, goats, pigs, chick- applications of biotechnology in the devel- ens; and fish species. oping world. It will enable the character- ization and application of useful genetic 2. Identify Traits for the Poor: Identify information for crop and livestock im- the genes conferring traits that are impor- provement and the control of the pests, tant to poor producers in marginal envi- parasites, and pathogens that affect them. ronments. It is likely that research will The economic concentration of agricul- show that some of these are governed by tural biotechnology is a real issue that genes that are conserved (shared) across affects the potential beneficial use of new species (for example drought tolerance in biotechnologies on the problems of poor cereals). This knowledge would greatly farmers and consumers in developing accelerate breeding for these difficult traits, countries. 34 PROMETHEAN SCIENCE AND THE POOR 5. Establish Alliances of the Caring: A businesses in developing countries, as a concerted international effort is needed to source of technology, job creation, and establish a new compact between the pub- wealth. lic and private sectors of the industrial and developing countries, so that the new de- 8. Mobilize the Global Scien1tific Com- velopments in genetics and biotechnology munity to Address the Problems of Foodfor are able to be used more effectively to in- the Poor: The CGIAR centers presently crease agricultural productivity in a sus- spend about US$25-35 million each year tainable way. This could, for example, on agricultural biotechnology, out of a to- involve a Food for the Poor initiative, tal budget for all the CGIAR centers of whiereby a trusL funid is created with pub- US$340 mnillion. These investments are lic and private donations, to conserve and impressive but insufficient by themselves. characterize phenotypically and genetically tlhe CGIAR{ centers are also the custodi- the genetic resources of the world's major ans of the world's largest in vitro collec- agriculture species in perpetuity. tions of plant genetic resources. The New and nontraditional partnerships CGIAR centers and the national agricul- amongst public and private sector organi- tural research systems are the repository of zations are needed to make best use of all a vast array of knowledge of the biology of available resources, involving farmers' as- the world's major food crops, livestock, sociations, nongovernmental organiza- fish, and tree species, and their associated tions, governments, and private sector pests and pathogens. The CGIAR centers organizations. Some alliances could be for- operate long-standing crop improvement malized into specific research consortia that programs and international testing pro- address specific constrairnts and are fi- grams, located tlhrouglhout the world's ma- nanced to achieve agreed outputs. jor ecosystems. In combination, these scientific, biological, and financial re- 6. Increase Investments in Agriculture: sources are a powverful platform. However, Significant additional investments by the the agricultural research efforts in the de- public and the private sectors are required veloping world now need to be mobilized if agricultural productivity is to increase with the global scientific community in in the developing world in an environmen- new and imaginative ways, if a quantum tally sustainable way leap is to be made in producing food for the poor by 2020. 7. Provide Incentives for Private Sector It is here that the newly created Global Participetion: Incentives are needed to en- Forum for Agricultural Rcscarch must be courage the national and international pri- seen as an important new vector for bring- vate sector to address the problems of ing about the necessary collaboration agriculture in developing countries. These amongst farmers, producer and consumer incentives may include improving the en- organizations, public and private compa- abling environment for agribusiness in nies, nongovernmental organizations, na- developing countries, providing financial tional agricultural research systems, incentives for research and development advanced research organizations and inter- on orphan commodities, and incentives national agricultural research institutes, in- for entrepreneurs to establish bio-based cluding the CGIAR centers. PART 4 THE W.Ay AHEAD 35 9. Identify Desi red Outptuts: Innova- Development of these outputs will re- tions that will be required to contribute quire m-iarshalling and directing financial and to improved food security and to create scientific resources in new ways, both nation- wealth in the poorer regions of the world ally and internationally. This will have pro- include: found implications for the CGIAR if it is to recognize and respond to these challenges * Improved genotypes and better agri- with the appropriate strategy and tactics. cultural practices to ensure sustain- Note, however, that whatever research and able increases in productivity of the development work is being advocated on world's agriculturally important com- the genetic side must be seen, along with modities. other crop, livestock and fish productivity * New biological products, such as vac- work, within the context of improved cines, biocontrol agents, and diagnos- agroecological, socioeconomic and gender- tics, for the control of major endemic sensitive approaches. diseases of crops and livestock. Illus- trative priority species, constraints, and 10. Challenge to the CGIAR: The CGIAR targets on which additional research is has a challenge to invest in and mobilize urgently needed are shown in Box 7. the necessary human, financial, and bio- Box 7 Illustrative exarnples of some priority constraints able to be addressed through biotechnology Commodity Constraint Regions Crops Banana/plantain Black Sigatoka disease Global Cassava Cassava mosaic virus Africa Maize Apomixis (all cereals) Global Quality protein maize Drought Millets Blast resistance Africa/South Asia Photoperiod response Global Sorghum Drought, heat tolerance Africa/South Asia Rice Blast, submergence Global Vitamin A content Yield potential Wheat Heat tolerance Africa/Asia Livestock Drought/salinity tolerance Cattle Trypanosomosis Global East coast fever Africa Sheep Heat tolerance, helminths Global Goats Helminths Global Chicken Newcastle virus Global Pigs Viral diseases Global 36 PROMETHEAN SCIENCE AND 1HE POOR logical resources to address the production that the early benefits of biotechnology are and sustainability problems of agriculture accruing. It is also where the debate as to in new and exciting ways. This will require the wisdom of using modern biotechnol- the CGIAR to: ogy at all is fiercest. Modern biotechnology offers prom- * Invest more, and with a greater sense ise to increase the productivity of the agri- of urgency, in science to solve prob- culturally important species in developing lems, marshalling the new in-depth countries. However this is unlikely to understanding of the agroecological happen in time if present trends con- issues with the new opportunities of tinue. The development of relevant and modern genetics and biotechnology appropriately fine-tuned applications in * Build on traditional strengths in breed- developing countries will be hampered ing, biology, and genetic resources by a lack of access to the necessary sci- * Analyze, interpret, and make more ac- entific and financial resources. This cessible its wealth of biological data, means that the potential of the human and using new tools in biotechnology and natural resources of the developing coun- information technology tries will not be fully realized and the world * Access new skills in the global scien- will be a poorer place. tific community to achieve new goals The present economic concentration of * Form new strategic (in addition to investment, science, and infrastructure in project-specific) alliances to achieve industrial countries and the lack of access common objectives to the resulting technologies are major im- * Create more flexible and innovative pediments to the successful applications of institutional arrangements that cut modern biotechnology to the global prob- across traditional Center boundaries lems of the Age, namely the need to guar- e Provide financial incentives for inno- antee food security to all people and to vation and reward success. create wealth for the presently poor people and countries. Creativity in finding solutions to these Epilogue policy and institutional impediments to innovation are as important and challeng- Prometheus changed the world forever ing as new scientific discoveries, if the when he unleashed the forces of innova- promises of Promethean science are to be tion and creativity. The Promethean schol- realized. Even more, the ability to link the ars of today seek to use the new discoveries findings and techniques of the new bio- in molecular biology and genetics to un- logical and genetic sciences within a frame- derstand and protect the natural world and work that respects the agro-ecology of to improve the productivity of agricultural smallholder farming systems, and integrat- systems. These developments are being ing all of that with the wisdom of the farm- driven by the scientific and industrial ers themselves is the key to where a better wealth of the industrial world. It is here future for all lies. Glossary of Terms Aponixis: reproduction (e.g. parthenogen- trix. This matrix can be a solid sup- esis) involving specialized generative port such as glass. If a sample contain- tissues but not dependent on fertiliza- ing DNA or RNA is added, those tion. molecules that are complementary in sequence will hybridize. By making the Bioinformatics: the assembly of data from added molecules fluorescent, it is pos- genomic analysis into accessible forms. sible to detect whether the sample con- It involves the application of informa- tains DNA or RNA of the respective tion technology to analyze and man- genetic sequence initially mounted on age large data sets resulting from gene the matrix. sequencing or related techniques. Genomics: the molecular characterization Diagnostics: more accurate and quicker of all the genes in a species. identification of pathogens using new diagnostics based on molecular char- High throughput (HTP) screening makes acterization of the pathogens. use of techniques that allow for a fast and simple test on the presence or ab- Functional genomics is the knowledge that sence of a desirable structure, such as converts the molecular information a specific DNA sequence and the ex- represented by DNA into an under- pression patterns of genes in response standing of gene functions and effects: to different stimuli. HTP screening how and why genes behave in certain often uses DNA chips or microarrays species and under specific conditions. and automated data processing for To address gene function and expres- large-scale screening, for example to sion specifically, the recovery and iden- identify new targets for drug develop- tification of mutant and over-expressed ment. phenotypes can be employed. Func- tional genomics also entails research on Insertion mutants are mutants of genes that the protein function (proteomics) or, are obtained by inserting DNA, for in- even more broadly, the whole metabo- stance through mobile DNA sequences, lism (metabolomics) of an organism. transposons. In plant research, the ca- pacity of the bacterium Agrobacterium Gene chips (also called DNA chips) or to introduce DNA into the plant ge- microarrays. Identified expressed gene nome is employed to induce mutants. sequences of an organism can, as ex- In both cases, mutations lead to lack- pressed sequence tags or synthesized ing or changing gene functions that are oligonucleotides, be placed on a ma- revealed by aberrant phenotypes. In- 37 38 PROMETIEAN SCIFNCF AND THF POOR sertion mutant isolation, and subse- and leads to rapid sequencing informa- quent identification and analysis are tion, but it is less precise than a sys- employed in model plants such as tematic sequencing approach. Arabidopsis and in crop plants such as maize and rice. Single nucleotide polymorphisms (SNPs) are the most common type of genetic varia- Molecular breeding: identification and tion. SNPs are stable mutations con evaluation of useful traits using sisting of a change at a single base in a marker-assisted selection. DNA molecule. SNPs can be detected by HTP analyses, for instance with Parthenogenesis: reproduction by develop- DNA chips, and they are then mapped ment of an unfertilized (usually female) by DNA sequencing. gamete that occurs especially among lower plants and invertebrate animals. Transformation: introduction of single genes conferring potentially useful Shotgun genome sequencing is a sequencing traits. strategy for which parts of DNA are randomly sequenced. The sequences Vaccine technology: using modern immu- obtained have a considerable overlap nology to develop recombinant DNA and by using appropriate computer vaccines for improved control of ani- software it is possible to compare se- mal and fish disease. quences and align them to build larger units of genetic information. This se- (Source: Biotechnology and Development quencing strategy can be automated Monitor 1999) References Alston, J.M., M.C. Marra, P.G. Pardey, and Delgado, C., M. Rosegrant, H. Steinfeld, S. T.G. Wyatt. 2000. 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