• Every minute -- the population increases by 42 people,

   

 

• Total population rose from 495 million (1965) to 936 million (1995) and is projected to increase to 1.32 billion in 2020,

   

 

• The rural population rose from 402 million (1965) to 685 million (1995) of which 78 comprises the agricultural population,

   

   

•  

   

• Some 300 million live below poverty line; and India has the largest concentration of poor people,

   

 

• Silent hunger is a menace, with child undernutrition still as high as 63 percent,

   

 

• Infant mortality high stands at 70 per 1000 births,

   

 

• About half the population lacks access to safe water,

   

 

• Only 16 percent of the population has access to sanitation,

   

 

• Over 141 million hectares are subject to water and wind erosion,

   

 

• Over a million hectares are damaged as a result of shifting cultivation annually,

   

 

• Some 40 million hectares are flood prone.

   

• Every minute -- 48 children are born,

   

Such realities in India and across the world could very easily be interpreted as constituting, once again, a catastrophe scenario. Last year’s temporary increase of the price of wheat, and fears that yield increases of major cereals have reached a plateau, adds to the concerns. Indeed, catastrophe is an ever-present danger, if circumstances are not scientifically assessed and, as necessary, countered.

Agriculture is at the heart of any effective solution to this nexus of problems encompassing population growth, environmental destruction, poverty reduction, and food security. Over 70 percent of the world’s land and water are used for agriculture. Over 75 percent of employment in the poorest countries is based on agriculture. If we do not transform agriculture to be more productive, we will curtail food abundance, which is the basis of food security. If we do not transform agriculture to be sustainable, we will destroy natural resources, the foundation of productivity and human sustenance. If we do not transform it to benefit the poorest and focus especially on women, we will help to perpetuate the very inequities that should be destroyed.

IV. THE CHANGING PARADIGM OF SCIENCE

As we look to the future, therefore, we know that action on a broad front is required to meet the objectives of poverty reduction, food security, and natural resources management.

In the short-run, reducing hunger must focus at the household level with enabling actions by nations. Globally, only adequate supplies and food aid can help. In the medium-term, the emphasis must be more at the national and international levels, focusing on reducing poverty and generating sustained economic development for all. Central to that vision are concerted national and international efforts to generate appropriate agricultural technology to improve the productivity and profitability of millions of farmers in developing countries. In the long-term, global food supplies must increase in sustainable production systems to feed more than 8 billion people, and a fair trading system is vital.

India’s outstanding experience in the green revolution shows us that in the past, government policies compiled with good science and an effective extension service which took the results of science to the farmers were adequate to meet the challenges of the time - provided that the technology package was appropriate.

Today’s problems are more complex. Science can help us to meet them, but the mobilization of science has to be reshaped, as science itself changes. Science must be used in three crucial areas:

 

• Defining the problem,

   

   

• Identifying partnerships and the new role of all partners in the global agricultural research system, and

   

   

• Making decisions on how science is practiced - bringing together all members of the "science family" together in a single constructive enterprise.

   

The world has seen a science explosion. The wonders of science and their potential for further improving the condition of the human family are all around us. We must put that potential to the best possible use, beginning with a concerted effort to define our problems accurately; to get the facts right.

So much of the debate among policymakers, advocacy groups, and in the media is based on partial figures and incomplete or inaccurate information. Sensible discussion and appropriate policies are thereby made elusive. What virtue is there in carrying out an impassioned debate on food production in China when the protagonists use vastly divergent figures of the acreage of Chinese land under cultivation on which the yield figures depend?

India was a pioneer in matching the requirements of agricultural development and information technology through its Satellite Instructional Television Experiment (SITE). Now is the time to be bold again, and to ensure that new breakthroughs in Geographic Information Systems (GIS) and computing will make it possible for more accurate figures to be obtained on the kinds of questions that determine policy. More importantly, such developments will enable the ecological site-specific data and the socioeconomic data to be mapped at the local to the supranational levels, offering for the first time the possibility of substantial relational databases being developed with all the advantages for analysis that such developments entail. Maintaining and making available proper databases thus becomes another major contribution that scientists can make to the better understanding of the issues and the monitoring and evaluation of trends by countless researchers and groups. Beyond using GIS/computing, databases, and scientific interpretation, the international scientific community can state problems accurately, define areas of uncertainty and risk, identify new technologies, and help set the boundaries of debate.

The debate will be wide ranging and through it will emerge an agenda for today and tomorrow. Let me review some of the issues that will have to be confronted.

 

• Favored or less-favored areas
• Traditional versus exotic crops
. This is not an either/or choice. The real question is how much of each receives priority attention by researchers in a period of finite resources. How does one weight poverty reduction for poor subsistence farmers against low food prices for the rural landless and the urban poor? How does one focus on the particular target groups we want to help--the poorest, women, and those who cultivate fragile environments?

 

 

. How can we improve the productivity and the income potential of poor farmers in the semi-arid tropics and arid zones? Should we invest in improving the yields of indigenous crops--millet and sorghum--or should we try to improve the stress resistance of higher yielding nontraditional maize? Should we invest in developing "tropical" wheat or potatoes or improve yams, sweet potatoes, and cassava?

 

 

• Time horizon choices
. What should be the time frame of expected impact? Often, improved agronomic practices such as spacing, seeding time, weed control, and planting depth can have short-term yield impacts, whereas genetic improvement, particularly involving complex characteristics, takes much longer but has higher long-run yield potential. How much should the international system invest in small, incremental improvements (including removing impediments to application of known technologies); how much on the development of radical new technologies such as transgenic techniques for apomixis and plant resistance?

 

 

• Environmental improvement versus yield maximization
. Frequently this is posed as a major tradeoff in priority choices, but it cannot persist as such. Clearly a major challenge to agricultural science is to turn this apparent win-lose situation into a win-win guarantee.

 

 

• The integration of traditional knowledge and new science
. The documentation of traditional knowledge, including identification of wild races, should be undertaken as a matter of urgency before it is lost. It must be integrated in a two-way commerce of ideas with modern science, and the poor farmers who are the custodians of this knowledge should benefit from these efforts. Taxonomies will show us different ways of approaching these problems.

 

 

• The search for integrated farming practices that reflect local specificity’s versus the search for new technologies with very broad applications
• Preserving biodiversity
. Such farming practices would reduce the vulnerability of the smallholder farmer and/or increase her or his income. These require international reach but local adaptation, such as the introduction of multipurpose leguminous trees e.g., sesbania or calliandra, or the introduction of fish ponds for super tilapia, which help with on-farm water management in addition to producing fish. How much attention should be given these types of activities versus the use of cutting-edge technologies such as transgenic biotechnology to attack the problems of the developing world?

 

 

. This is a crucial aspect of the agricultural research process, an area in which many groups need to work together to ensure that we can increase our use of this biodiversity and that our common heritage is protected and preserved for the future.

 

 

• Greater use of biotechnology
. This could be the most exciting contribution that science can make to food security in the next century. Radical and rapid changes in our understanding of molecular biology have spawned a potential biotechnology revolution. The application of biotechnology was pioneered in the medical sciences, but agricultural science has been catching up. There has undoubtedly been concern that the application of biotechnology in agriculture is occurring more slowly than its enthusiasts predicted. Yet today, some fifty plant varieties--from alfalfa to wheat--have been altered through biotechnology since the first success was recorded in gene manipulation in the 1980s. The value of sorrel products from biotechnology in agriculture in the U.S. market alone is US$380 million in sales in 1996, with predicted growth in the market of 20 percent per annum over the next decade.

 

The opportunities for producing transgenic varieties are endless. Plants and animals that use water more efficiently, grow in highly adverse conditions, resist pests and diseases, and use fewer inputs have enormous potential to contribute to the sustainability of agricultural production systems and are representative of the range of possibilities which may develop through biotechnology. Biotechnology also has great potential in livestock and fish production, and in the modification of biological control agents.

Genetically altered varieties, especially those that are sensitively responsive to the specifics of complex smallholder farming systems, can be introduced to less-favored areas offering undreamed of opportunities to the poor. However, the research agenda must also address areas of concern with biotechnology.

The correct balance has to be established on weighing the benefits against the risks of biotechnology. Not everything that is technically feasible is ethically desirable. The technology potential involves science and economics. The ethical issue has many complexities. We cannot accept hunger and poverty as the permanent legacy of the disadvantaged. We cannot accept the notion that deprivation should forever be imprinted on the genes of the poor and destitute - that misery is their inevitable or even karmic destiny - because of fears about the use of biotechnology. Both sets of issues need to be boldly confronted.

Science has created the basis of a new interconnectedness. And yet there is potential for dangerous divisions. Aspects of the application of intellectual property rights could lead to limitations on the free flow of germplasm, thus drastically curtailing agricultural development. The collaborative nature of science and its application run the risk of being transformed into a competitive race -- not by scientific or communications obstacles but by legal requirements.

Indeed, research today is subjected to dual pressure. On the one hand, it must take account of the diversity of natural and human environments and therefore come to terms with location-specific realities. It is equally influenced by globalization factors: the awakening of a planetary conscience against common challenges, the revolution of basic sciences, particularly in biology; the interconnection of communications networks; economic liberalization, and so on. The emergence of a "global system" is manifest.

However, in this area, as in others we must ensure that this "globalization" of research does not translate into a few powers dominating a world where the vast majority are relegated to facing the specter of environmental loss, and seeing the impact of continuing inequities on the poor, there can be no room for divisiveness in the agricultural research effort. "Public assets" and "private assets" each have their own logic. These must be clearly understood, and their differences as well as their complementarities respected.

We need a new paradigm of research. The real challenge is to ensure that all usable assets are deployed for the production of public goods. This principle applies to the protection of intellectual property and in the field of biological research. We need an overall system that promotes interaction to help each actor contribute to the best of its comparative advantages so that the whole is much more than the sum of the parts. When such a system is in place, the synergies in agricultural research will acquire their own momentum, providing more productive links among public and private actors, national and international agencies, rich and poor countries, and formal and informal sector institutions of the civil society.

To address all these issues, what should be the distribution of responsibilities among local, national, regional and international research? Should every country have a full-blown research system? What role should multinational firms play in the global research systems? What are truly public research goods--nationally and internationally? What level of public investment is required for the production of public goods? How can the strengths of the private sector be integrated with public endeavor?

These are difficult issues, but nobody said that development would be simple. Think of the Finance Minister of any small country in the South who, three weeks before Budget Day, has to choose between allocating money for an emergency program to clean out small irrigation reservoirs or an emergency program to build a network of rural dispensaries. The choices of development are rarely easy. But, just as the crises of the fifties and sixties in India brought forth effective responses, I am convinced that today’s challenges are also today’s opportunities. They are opportunities for building partnerships, creating and implementing effective policies, for acting in areas both directly and indirectly connected with food security issues, for reaching out to the weakest among us and helping them to begin their ascent from poverty.

We all recognize that the challenges of tomorrow will require the mobilization of the talents, resources and abilities of all the actors, from the public and the private sectors, local, national and international agencies, the private sector and the civil society. How does one bring them together? How does one find a non-bureaucratic forum to enable them to share ideas and help shape the agenda? To define new partnerships and work out new forms of collaboration? Indeed, steps to do just that have already been taken. A Global Forum, which took place in Washington last October, was the start of this dream of a common commitment by one and all for the better future of humanity and of our planet.

Clearly, the voice of the NARS and their regional fora must be central in helping shape the future programs of this new Global Forum. The single most important challenge facing this Global Forum is that of devising both the priorities of and the modalities for action. But such action must be guided by principles designed to create a truly participatory and inclusive system. Based on this, the emerging global system can have a shared vision in which the programs of each benefit from the successful work of the others. This will give substance to real research partnerships in the battles against poverty, hunger, environmental degradation, and inequity.

The CGIAR sees itself as an active participant in the further development of the global agricultural system, as CGIAR centers continue with the mission of carrying out cutting-edge research. Beyond the content of their work and the manner in which they design and carry out research programs with their partners, these centers of scientific excellence must act as dynamic catalysts, as platforms for the exchange of information and the development of true networks of scientists between the South and the North. In preparation for its deepening involvement in a partnership mode within global agricultural systems, the CGIAR undertook an 18-month program of renewal - which was launched in this city in May 1994. The program was completed on schedule in October of 1995. As a result the CGIAR is today a fully South-North enterprise, its participatory mechanisms have been greatly improved and the mode of operations of some centers have changed or are changing.

ICRISAT, headquartered near Hyderabad, is one such center. It is reducing the size of its staff, orienting itself much more than before to operating through partnership, and is sharply refocusing its research agenda. Utmost care is being taken to cushion the personal impact of the changes underway. Periods of change are hard, nevertheless, and I share the concerns of those who are personally affected. Commiseration is easier than hardship. Many hundred staff are affected; national and international. The CGIAR is profoundly concerned about the personal difficulties that are being experienced. I, personally, have appealed for more resources to prevent current developments, and wish that other courses could have been followed. Those affected will be cared for, to the fullest extent possible. Our thoughts are with them, and we hope that the adjustment process will soon be completed. The plus side of an otherwise negative situation is that programmatic and administrative changes now in progress at several CGIAR centers will enable them to be even more effective partners of national scientists than before. The NARS will have to undergo their own transformation, taking on new responsibilities, and working out effective distributions of tasks among themselves and other components of the global agricultural research system. Let us all do our bit to ensure that the changes will not only be made, but will be part of the new science paradigm.