As a fast growing region with increasing challenges for smallholder farmers, Asia is a key target region for CIMMYT. CIMMYT’s work stretches from Central Asia to southern China and incorporates system-wide approaches to improve wheat and maize productivity and deliver quality seed to areas with high rates of child malnutrition. Activities involve national and regional local organizations to facilitate greater adoption of new technologies by farmers and benefit from close partnerships with farmer associations and agricultural extension agents.
The use of field-specific fertiliser in the Indo-Gangetic Plains (IGP) can increase grain yield, reduce greenhouse gas emissions compared to traditional farmer fertilization practices (FFP), and lead to reduced costs and increased incomes for farmers.
These were the findings of a study conducted between 2013 and 2017 by the International Maize and Wheat Improvement Centre (CIMMYT) and published in Nature Scientific Report in January 2021.
Sanjaya Rajaram, a University of Sydney alumnus recognized with the World Food Prize, was a world-renowned wheat breeder and scientist. One of the world’s leading food scientists, he died on February 17 from COVID-19 in Ciudad Obregon, Mexico.
A shop attendant displays drought-tolerant maize seed at the Dryland Seed Company shop in Machakos, Kenya. (Photo: Florence Sipalla/CIMMYT)
For several decades, the International Maize and Wheat Improvement Center (CIMMYT) has worked with partners and farmers to improve maize and wheat varieties. Packed with “upgrades” such as tolerance to environmental stresses, tolerance to diseases and pests, boosted nutrient content, higher yield potential and storage capabilities, and improved efficiency in using water and fertilizers, these seeds are rolled out by CIMMYT and its partners to create new opportunities for easier and better lives for farmers.
Together with national research partners, farmers, local governments and seed companies, CIMMYT’s work in seed systems has reaped results. Its experts are eager to put this experience into further action as CGIAR embarks on the next ten years of its journey to transform food, land, and water systems in a climate crisis. And rightly so: investments in CGIAR research — mainly through their contributions to enhancing yields of staple food crops — have returned ten-fold benefits and payoffs for poor people in terms of greater food abundance, lower prices of food, reduced food insecurity and poverty and reduced geographical footprint of agriculture. A large part of this impact is the result of CIMMYT’s day to day efforts to create a better world.
A Bangladeshi woman cuts up feed for her family’s livestock. They did not previously have animals, but were able to buy them after her husband, Gopal Mohanta, attended a farmer training from CIMMYT and its partners, which gave him access to better seed, technologies, and practices. Mohanta planted a wider range of crops, and in 2005 he planted maize for the first time, using improved seed based on CIMMYT materials. (Photo: S. Mojumder/Drik/CIMMYT)
Replacing old varieties, not as easy as it sounds
Slow variety turnover — that of more than ten years — makes farmers vulnerable to risks such as climate change and emerging biotic threats. On the other hand, planting improved varieties that match farmers’ needs and the geography they work in, can increase productivity gains and improve the nutritional status of smallholders and their families. This, in turn, contributes to increased household incomes. Indirectly, the benefits can reach the surrounding community by providing increased employment opportunities, wage increases and affordable access to food.
Despite its tremendous benefits, varietal turnover is no small feat.
When it comes to seeds, detailed multi-disciplinary research is behind every new variety and its deployment to farmers. Just as the production of a new snack, beverage or a car requires an in-depth study of what the customer wants, seed systems also must be demand-driven.
Socioeconomists have to work hand-in-hand with breeders and seed system specialists to understand the drivers and bottlenecks for improved varietal adoption, market needs, and gender and social inclusion in seed delivery. Bottlenecks include the lack of access by farmers — especially for resource-poor, socially-excluded ones — to reliable information about the advantages of new varieties. Even if farmers are aware of new varieties, seeds might not be available for sale where they live or they might be too expensive.
Possibly the most complex reason for slow variety turnover is risk vulnerability: some farmers simply can’t afford to take the risk of investing in something that might be good but could also disappoint. At the same time, seed companies also perceive a certain risk: they might not be interested in taking on an improved variety that trumps the seeds from older but more popular varieties they have on stock. For them, building and marketing a new brand of seeds requires significant investments.
Agricultural seed on sale by a vendor near Islamabad, Pakistan. For improved crop varieties to reach farmers, they usually must first reach local vendors like these, who form an essential link in the chain between researchers, seed producers and farmers. (Photo: M. DeFreese/CIMMYT)
New approaches are yielding results
Despite the complexity of the challenge, CIMMYT has been making progress, especially in Africa where slow variety turnover is creating roadblocks for increased food security and poverty alleviation.
Recent analysis of the weighted average age of CIMMYT-related improved maize varieties in 8 countries across eastern and southern Africa reveals that the overall weighted average age has decreased from 14.6 years in 2013 to 10.2 years in 2020. The remarkable progress in accelerating the rate of variety turnover and deploying the improved genetics — with climate resilience, nutritional-enhancement and grain yield — are benefiting more than eight million smallholders in Africa.
In Ethiopia, CIMMYT, EIAR and ICARDA’s work led to the adoption of improved rust-resistant varieties, corresponding productivity gains and economic benefits that, besides the urgent need to fight against the damaging rust epidemic, depended on a combination of enabling factors: pre-release seed multiplication, pro-active policies and rust awareness campaigns. The estimated income gain that farmers enjoyed due to adopting post-2010 varieties in 2016/2017 reached $48 million. For the country itself, the adoption of these varieties could save $65 million that otherwise would be spent on wheat imports.
Bill Gates echoes this in Chapter 9 of his new climate book, How to Avoid a Climate Disaster, as he describes CIMMYT and IITA’s drought-tolerant maize work: “[…] experts at CGIAR developed dozens of new maize varieties that could withstand drought conditions, each adapted to grow in specific regions of Africa. At first, many smallholder farmers were afraid to try new crop varieties. Understandably so. If you’re eking out a living, you won’t be eager to take a risk on seeds you’ve never planted before, because if they die, you have nothing to fall back on. But as experts worked with local farmers and seed dealers to explain the benefits of these new varieties, more and more people adopted them.”
Bidasem director general María Ester Rivas (center) stands for a photo with her seed processing team. Bidasem is a small seed company based in the city of Celaya in the central Mexican plains region known as the Bajío. Despite their small size, Bidasem and similar companies play an important role in reaching small farmers with improved seed that offers them better livelihoods. (Photo: X. Fonseca/CIMMYT)
Holistic action needed if we are to reach farmers with genetic innovations
Now more than ever, with increased frequency and intensification of erratic weather events on top of the complications of the COVID-19 pandemic, successful seed systems require the right investments, partnerships, efforts across disciplines, and enabling policies.
Varietal release and dissemination systems rely greatly on appropriate government policies and adoption of progressive seed laws and regulations. CGIAR’s commitment to farmers and the success of national seed systems is described in the recently launched 10-year strategy: “CGIAR will support effective seed systems by helping national governments and private sector companies and regulators build their capacities to play their roles successfully. New initiatives will be jointly designed along the seed distribution chain, including for regional seed registration, import and export procedures, efficient in-country trialing, registration and release of new varieties, and seed quality promotion through fit-for-purpose certification.”
In line with CGIAR’s ambitious goals, to provide farmers with a better service, small- and medium-size seed companies need to also be strengthened to become more market-oriented and dynamic. According to SPIA, helping local private seed dealers learn about new technology increases farm-level adoption by over 50% compared to the more commonly used approach, where public sector agricultural extension agents provide information about new seed to selected contact farmers.
CIMMYT socioeconomics and market experts are putting this in practice through working with agrodealers to develop retail strategies, such as targeted marketing materials, provision of in-store seed decision support and price incentives, to help both female and male farmers get the inputs that work best.
Within the new CGIAR, CIMMYT scientists will continue to work with partners to strongly improve the performance of wheat and maize in smallholder farmers’ fields. Concerted efforts from all actors conforming the entire seed system are essential to achieve our vision: to transform food systems for affordable, sufficient and healthy diets produced within planetary boundaries. Wheat and maize seed systems will form the basis to fulfill that vision and provide a tried and tested roadmap for other crops, including legumes, vegetables and fruits. Together, we can keep a finger on the pulse of farmers’ needs and build healthy diets for a better tomorrow from the ground up.
Water pumped from a deep irrigation well, called a tube well, at a wheat farm in west India’s Gujarat state. (Photo: Meha Jain)
India is the world’s second-largest producer of wheat and rice and is home to more than 600 million farmers. The country has achieved impressive food-production gains since the 1960s, due in part to an increased reliance on irrigation wells, which allowed Indian farmers to expand production into the mostly dry winter and summer seasons.
But those gains have come at a cost: The country that produces 10% of the world’s crops is now the world’s largest consumer of groundwater, and aquifers are rapidly becoming depleted across much of India. Indian government officials have suggested that switching from groundwater-depleting wells to irrigation canals, which divert surface water from lakes and rivers, is one way to overcome projected shortfalls.
The authors estimate that if Indian farmers lose all access to groundwater in overexploited regions, and if that irrigation water is not replaced with water from other sources, then winter cropped acreage could be reduced by up to 20% nationwide. However, that scenario seems highly unlikely and was included in the study only as an upper-bound estimate.
It seems more likely that any future groundwater shortfalls would be at least partially offset by increases in canal irrigation. But even if all Indian regions currently using depleted groundwater switch to canal irrigation, winter cropped acreage could still decline by 7% nationwide and by 24% in the most severely affected locations, according to the researchers.
Water alternatives needed
“Our results highlight the critical importance of groundwater for Indian agriculture and rural livelihoods, and we were able to show that simply providing canal irrigation as a substitute irrigation source will likely not be enough to maintain current production levels in the face of groundwater depletion,” said study lead author Meha Jain, an assistant professor at the University of Michigan’s School for Environment and Sustainability.
“We need coordinated efforts to solve this water availability and food security issue, which should be supported by science-led policy decisions on what strategies and technology solutions to scale out to improve irrigation efficiency,” said co-author Balwinder Singh, a Cropping Systems Simulation Modeler at the International Maize and Wheat Improvement Center (CIMMYT).
The study analyzed high-resolution satellite imagery and village-level census data and focused on winter cropped acreage. While nearly all Indian farmers plant crops during the monsoon to take advantage of seasonal rains, winter agriculture is mainly reliant on groundwater irrigation and now accounts for 44% of the country’s annual cropped acreage for food grains.
“These findings suggest that other adaptation strategies, in addition to canal expansion, are needed to cope with ongoing groundwater losses,” Jain said.
The possibilities include switching from winter rice to less water-intensive cereals, increased adoption of sprinklers and drip irrigation to conserve water in the fields, and policies to increase the efficiency of irrigation canals.
While groundwater depletion is becoming a global threat to food security, and the extent of current and projected groundwater depletion are well documented, the potential impacts on food production remain poorly quantified. The study is the first to use high-resolution empirical data, including census data about the irrigation methods used in more than 500,000 Indian villages, to estimate the crop production losses that may occur when overexploited groundwater is lost.
“Understanding the complex relationship between food security and water availability is crucial as we prepare for future rainfall variability due to global climate change,” said co-author Gillian Galford of the University of Vermont.
The proliferation of deep (>30 meters) irrigation wells called tube wells since the 1960s has enabled Indian farmers to increase the number of seasons when crops are planted in a given year. This increase in “cropping intensity” is credited for much of the country’s food-production gains.
Maps showing state-by-state Indian winter cropped area loss estimates due to groundwater depletion in coming decades, with and without replacement by canals. Darker shades of pink and red indicate greater projected losses. The map on the left (A) shows projected winter cropped acreage losses if all critically depleted groundwater is lost, with no replacement. The map on the right (B) shows projected winter cropped acreage losses if groundwater irrigation is replaced with canals, using national-level regression coefficients. (Graph: Jain et al. in Science Advances 2021)
Big data for food security
The researchers used satellite data to measure Indian winter cropped area, a key determinant of cropping intensity. They then linked the satellite data to census information about the three main types of irrigation infrastructure in India: shallow “dug wells,” deeper tube wells and canals that divert surface water.
Linking the two datasets allowed them to determine the relative efficacy of each irrigation method. That, in turn, enabled them to estimate potential future acreage losses and the ability of canal expansion to fill the gap.
The study’s worst-case scenario found that winter cropped area could decrease by up to 20% nationwide and by 68% in the most severely affected regions, if farmers lose all access to groundwater and if that irrigation water is not replaced from another source. The expected losses would largely occur in northwest and central India, according to the study.
The researchers also found that increased distance from existing irrigation canals is strongly associated with decreased acreage planted with winter crops. In the future, a greater reliance on canals could increase inequities related to irrigation access, according to the authors.
“This suggests that while canals may be a viable form of irrigation for those who live near canals, they may lead to more unequal access to irrigation across villages compared to wells, with negative impacts for those who live farther from canals,” the authors wrote.
In addition, the lakes and rivers that feed irrigation canals rise and fall in response to rainfall variability, unlike deep groundwater wells. So, a greater reliance on canal irrigation in the future would result in increased sensitivity to year-to-year precipitation fluctuations, as well as any long-term trends due to human-caused climate change.
The authors of the Science Advances study, in addition to Jain and Galford, are Ram Fishman of Tel Aviv University; Pinki Mondal of the University of Delaware; Nishan Bhattarai of the U-M School for Environment and Sustainability; Shahid Naeem, Upmanu Lall and Ruth DeFries of Columbia University; and Balwinder Singh of the International Maize and Wheat Improvement Center (CIMMYT).
The work was funded by a NASA New Investigator Award to Jain and two NASA Land Cover and Land Use Change grants, one awarded to R.S. DeFries and one to Jain.
Agricultural market systems play a pivotal role in food security, livelihood development and economic growth. However, the agricultural sector in Nepal is constrained by a lack of spatially-explicit technologies and practices related to improved seed and fertilizer. Embracing these challenges, Dyutiman Choudhary, a scientist in market development with the International Maize and Wheat Improvement Center (CIMMYT), works to strengthen the seed and fertilizer market systems and value chains, with the ultimate goal to ensure demand-driven, inclusive and market-oriented cereal production.
Nepal’s agricultural sector is dominated by smallholder farmers. As farming is mostly semi-commercial and subsistence in nature, many smallholder farmers are isolated from markets and lack knowledge about the latest farming technologies and inputs. They are unable to upgrade their farms to increase productivity for generating marketable surplus to make profitable income. Agribusiness entities in Nepal — such as seed companies, agrodealers and importers — face market development challenges and lack the commercial and business orientation to develop and deliver new technologies to farmers. Output market linkages are weak and loosely integrated, leading to poor coordination, weak information flow and lower return to actors.
This is where Choudhary’s expertise in agribusiness management fits in to make a difference.
Born and raised in Shillong, a hill station in northeastern India with a distinctive charm, he was enrolled as an engineering student. However, his interest took a sudden turn when he got drawn towards biological sciences and ultimately decided to leave the engineering course by stepping into agribusiness management. “I realized I was walking in the right direction as I was fascinated to learn about the livelihood benefits of agroforestry and the scope of agribusiness in fostering overall economic growth.”
He joined CIMMYT in 2017 as an expert in market development, but his roles and responsibilities transitioned to working as a Lead for the Nepal Seed and Fertilizer (NSAF) project within four months of his appointment. His role involves leading an interdisciplinary team of scientists, partners and experts to develop a synergistic market system. The NSAF team fosters public private partnerships, improves access to support services and strengthens inclusive value chains in a supportive policy environment.
Choudhary’s research focuses on assessing crops, seed and fertilizer value chains; developing commercial and inclusive upgrading strategies with businesses and stakeholders; assessing competitiveness of seed companies; lobbying for policies to foster the growth of seed and fertilizer business; and building pathways for public and private sector services to market actors and smallholder farmers.
Dyutiman Choudhary (seventh from left) with seed producers during a field visit. (Photo: Dipak Kafle)
A roadmap to innovative market systems
Choudhary introduced the vision of a market system approach and put together a strategic roadmap in collaboration with a team from CIMMYT researchers from the Global Maize program, the Sustainable Intensification program and the Socioeconomics program. The roadmap addressed the concerns of low crop productivity, poor private sector growth and a less supportive policy environment inhibiting agricultural innovations in Nepal.
“Seed and fertilizer market systems in Nepal are uncompetitive and lack influx of new knowledge and innovations that restricts agriculture growth,” Choudhary explained.
Having prior experience as a regional lead for high-value products and value chains for South Asia and an inclusive market-oriented development expert in Eastern and Southern Africa, Choudhary carries unique capabilities for putting together a winning team and working with diverse partners to bring about a change in farming practices and build a strong agribusiness sector in Nepal.
Under his leadership, Nepalese seed companies are implementing innovative and competitive marketing approaches to develop newly acquired hybrid varieties under their brands. The companies are upgrading to build business models that cater to the growth of seed business, meet market demands and offer innovative services to smallholder farmers to build a sustainable national market. Facilitating financing opportunities has enabled these enterprises to produce strategic business plans to leverage $2 million to finance seed business. Improved value chain coordination mechanisms are increasing demand of seed company’s products and enhancing smallholder farmers’ access to output markets.
There is a renewed interest and confidence beaming from the private sector to invest in fertilizer business due to improved knowledge, communication and collaborative methods. The government committed to support balanced soil fertility management and allocated $2.4 million in 2019 to initiate fertilizer blending in Nepal.
Dyutiman Choudhary (left) welcomes the Feed the Future team leader to the CIMMYT office in Nepal. (Photo: Bandana Pradhan/CIMMYT)
Dyutiman Choudhary shows a demonstration plot during a field visit with USAID and project partners in Nepal. (Photo: Darbin Joshi)
Dyutiman Choudhary (left) receives a token of appreciation at an International Seed Conference organized in Nepal. (Photo: Bandana Pradhan/CIMMYT)
Competitiveness fosters productivity
The results of Choudhary’s work have the potential to transform Nepalese agriculture by unleashing new investments, changes in policies and practices, and innovative business management practices. “Despite a huge change in my TOR and the challenges to deliver impactful outcomes, I was able to successfully steer the project to produce exciting results that made the donor to declare it as their flagship project in Nepal,” he explained. “At the end of the day, reflecting upon the work achieved with my team and the stakeholders in co-creating solutions for complex issues brings me immense satisfaction.”
An amiable individual, he feels close to natural science and loves interacting with farmers. “I’ve always enjoyed traveling to biodiversity-rich locations, to understand local cultures and livelihood practices, so as to gauge the drivers of innovation and adaptation to change among diverse rural populations.”
“Keeping up the momentum, I want to continue to support growth in agribusiness management in less favorable regions, helping stakeholders in the farm-to-fork continuum to leverage the potential of innovations in research, development and delivery.”
A seed vendor near Islamabad, Pakistan. For improved crop varieties to reach the farmers who need them, they usually must first reach local vendors, who form an essential link in the chain between researchers, seed producers and farmers. (Photo: M. DeFreese/CIMMYT)
Wheat is not just an essential part of the Pakistani diet, but also absolutely critical to the country’s economy and to the farmers who cultivate it. The government of Pakistan’s goal to achieve self-sufficiency in wheat production just became more attainable with the release of five new wheat varieties. These new seeds could help the country’s 8.8 million hectares of wheat-farmed area become more productive, climate-resilient and disease-resistant — a welcome development in a region where new climate change scenarios threaten sustained wheat production.
With multiple years of on-station and on-farm testing, the Wheat Research Institute (WRI) in Faisalabad, the Arid Zone Research Institute (AZRI) in Bhakhar, and the Barani Agricultural Research Institute in Chakwal released five varieties: Subhani 2021, MH-2021, Dilkash-2021, Bhakkar-20 and MA-2020.
The varieties, drawn from germplasm from the International Maize and Wheat Improvement Center (CIMMYT), were developed for different production environments in the Punjab province of Pakistan.
Dilkash-2021 was developed by WRI from a cross with a locally developed wheat line and a CIMMYT wheat line. MH-2021 and MA-2020 were selected from the CIMMYT wheat breeding germplasm through international trials and nurseries.
Subhani-21 and MA-2020 were selected from special trials assembled by CIMMYT for expanded testing, early access and genomic selection under the USAID-funded Feed the Future Innovation Lab for Applied Wheat Genomics at Kansas State University, in partnership with Cornell University and four South Asian countries (Bangladesh, India, Nepal and Pakistan).
Over the course of multiple years and locations, the new varieties exhibited a yield potential that is 5 to 20% higher than current popular varieties such as Faisalabad 2008, in addition to good grain quality and attainable yields of over 7 tons per hectare. They also showed an impressive resistance to leaf and yellow rusts, compatibility with wheat-rice and wheat-cotton farming systems, and resilience to stresses.
“It is exciting to see new varieties coming out of these collaborative projects between the Pakistani breeding programs, CIMMYT and the university teams,” said Jesse Poland, associate professor at Kansas State University and director of the Wheat Genomics Innovation Lab.
Wheat breeder and WRI director Javed Ahmad (center, wearing a white cap) explains the performance of a new variety and its positive traits to visitors. (Photo: Muhammad Shahbaz Rafiq)
Closing the yield gap between research fields and smallholder fields
Despite all of these encouraging traits, releasing a new variety is just half of the battle. The other half is getting these new, quality seeds to markets quickly so that wheat growers can realize the benefits. A fast-track seed multiplication program for each of these varieties has been designed and implemented.
“Pakistan has started to multiply early-generation seeds of rust-resistant varieties. These will be available to seed companies for multiplication and provision to farmers in the shortest possible time,” agreed wheat breeder and WRI Director Javed Ahmad and the National Wheat Coordinator Atiq Rattu.
Wheat breeder and WRI director Javed Ahmad (left) discusses performance of the new varieties with a colleague. (Photo: Muhammad Shahbaz Rafiq)
However, the current seed replacement rate is still low, mainly because new, quality seeds are rarely available at the right time, location, quantity, and price for smallholders. Strengthening and diversifying seed production of newly released varieties can be done by decentralizing seed marketing and distribution systems and engaging both public and private sector actors. Additionally, marketing and training efforts need to be improved for women, who are mostly responsible for household-level seed production and seed care.
In 2020, Pakistan harvested 25.7 million tons of wheat, up from 23.3 million tons a decade ago in 2010, which roughly matches its annual consumption of the crop. Pakistan is coming close to its goal of self-sufficiency, as outlined in the Pakistan Vision 2025, Food Security Policy 2018 and Vision for Agriculture 2030. Research shows that the public sector cannot extensively disseminate seeds alone; new policies must create an attractive environment to private sector partners, so that entrepreneurs are also attracted to the seed business. With continued efforts and a bold distribution and training effort, new releases like these will contribute to narrowing the yield gap between research stations and farmers’ fields.
USAID has started the implementation of a $21.4 million project led by CIMMYT, the International Development Enterprises (iDE), and the Georgia Institute of Technology to support the mechanization of agriculture in Bangladesh.
The challenges facing our food system are growing, both in size and in complexity. In order to tackle these issues and meet the needs of our changing world, the International Maize and Wheat Improvement Center (CIMMYT) understands the importance of assembling a workforce that is diverse, creative and representative. In addition to encouraging STEM careers and hiring more women in scientific positions, we must also foster a more encouraging scientific community for women whose careers are just sparking.
Whether it is through a school field trip, a first internship or a PhD thesis project, CIMMYT is committed to encouraging young women to step into the lab and the fields, and up to the challenge, as we strive to create a more equitable community. On the International Day of Women and Girls in Science, we are inspired by the words of some of the many brilliant women whose scientific careers are just beginning, lighting the pathway to a more equitable future.
The International Day of Women and Girls in Science is particularly meaningful to CIMMYT’s new Global Wheat Program (GWP) Director, Alison Bentley. Listen and watch as she tells her story, from her first lightbulb moment on a high school field trip, to a leadership position in the wheat research world.
In celebration of the International Day of Women and Girls in Science, CIMMYT is participating in a unique marathon event, carrying a global conversation with CGIAR women scientists that are leading change and creating solutions to some of the world’s biggest challenges.
Powered by Women in Research and Science (WIRES), a new employee-led resource group at CGIAR, the event will showcase the many ways women scientists are transforming the way we look at our food, land and water systems around the world. In addition to learning about cutting-edge science, you’ll be able to engage with inspiring speakers in 13 different countries.
Join CIMMYT’s discussion on February 11, 2021, at 1:00 p.m. CST, and learn about the journeys of the 2020 Bänziger Award recipients, an engaging Q&A with four CIMMYT scientists, and our vision for a more equitable workforce. Register for the event.
Australia’s High Commissioner to India, Barry O’ Farrell (left), observes the use of drone technology at the BISA experimental station in Ludhiana, India. (Photo: Uttam Kumar/CIMMYT).
Australia’s High Commissioner to India, Barry O’Farrell, visited the Borlaug Institute for South Asia (BISA) in Ludhiana, India, on January 20, 2021 along with his delegation.
O’Farrell acknowledged the historic role of the International Maize and Wheat Improvement Center (CIMMYT) sharing the seeds of the most recent, climate-resilient, high-yielding, and disease-resistant wheat genotypes. He also appreciated that this work is being continued with even greater vigor by BISA for the benefit of India and the whole of South Asia.
The High Commissioner was happy to note that wheat germplasm is freely shared with public and private sector national partners under constant guidance and collaboration with the Indian Council of Agricultural Research (ICAR) and the Department of Agriculture Research and Education (DARE).
O’Farrell emphasized the strong collaboration between Indian and Australian research institutes. He called for even more cross-learning between scientists and other stakeholders for research, policy and capacity development in the areas of land, water, climatic resilience, environmental sustainability and germplasm enhancement for the benefit of farmers of both countries.
Witnessing science in action
Arun Kumar Joshi, CIMMYT Regional Representative for Asia and Managing Director of BISA, welcomed the group and briefed the visitors on CIMMYT and BISA’s collaboration with ICAR and DARE.
H.S. Sidhu, Principal Research Engineer at BISA, and M.L. Jat, Principal Scientist and Systems Agronomist at CIMMYT, presented the major challenges and research outputs related to climate change, the food-energy-water nexus and the overall agricultural sustainability challenges faced by India.
One of the successful examples of collaboration between Australia and India is the Happy Seeder, which addresses these challenges through conservation agriculture and sustainable intensification. O’Farrell saw the expansive wheat fields sown with the Happy Seeder and was impressed by the technology.
The group also discussed the evidence-based policy changes that have taken place, as well as future strategies for accelerated impact through new approaches, like carbon farming. A detailed discussion took place on climate-smart agriculture research, with a focus on precision water and nutrient management using digital agriculture technologies and their complementarity for boosting Happy Seeder uptake.
The High Commissioner and his delegation also visited the wheat breeding program, where CIMMYT researcher Uttam Kumar explained the development of wheat genotypes — in collaboration with ICAR-DARE and the national agriculture research system — for a range of environments, management conditions, and against various stresses, with the ultimate objective of serving the needs of smallholder farmers.
O’Farrell also appreciated the BISA-designed Phenocart for high-throughput precision phenotyping in wheat improvement. O’Farrell highlighted and appreciated that this season, BISA is conducting the largest wheat breeding trial in South Asia: currently more than 60,000 plots are planted at the BISA station in Ludhiana alone.
Researchers from the International Maize and Wheat Improvement Center (CIMMYT) and the International Livestock Research Institute (ILRI) have identified new genomic regions associated with maize stover quality, an important by-product of maize which can be used in animal feed.
The results of the study, published this month in Nature Scientific Reports, will allow maize breeders to select for stover quality traits more quickly and cost-effectively, and to develop new dual purpose maize varieties without sacrificing grain yield.
The researchers screened diverse Asia-adapted CIMMYT maize lines from breeders’ working germplasm for animal feed quality traits. They then used these as a reference set to predict the breeding values of over a thousand doubled haploid lines derived from abiotic stress breeding programs based on genetic information. Based on these breeding values, the scientists further selected 100 of these double haploid lines and validated the performance of stover quality traits through field-based phenotyping.
The results demonstrate the feasibility of incorporating genomic prediction as a tool to improve stover traits, circumventing the need for field or lab-based phenotyping. The findings significantly reduce the need for additional testing resources — a major hindrance in breeding dual-purpose maize varieties.
Interestingly, the researchers found that increased animal feed quality in maize stover had no impact on grain yield, a concern raised by scientists in the past.
“The main purpose of this study and overall purpose of this CIMMYT and ILRI collaboration was to optimize the potential of maize crops for farm families, increase income, improve livelihoods and sustainably manage the crop livestock system, within limited resources,” said P.H. Zaidi, a maize physiologist at CIMMYT and co-author of the study.
“More than 70% of the farmers in the tropics are smallholders so they don’t have a lot of land to grow crops for grain purposes and separate stover for animal feed, so this is a very sustainable model if they grow dual purpose maize.”
By growing maize simultaneously for both human consumption and animal feed, farmers can get the most out of their crops and conserve natural resources like land and water.
A farmer works in a maize field close to the Pusa site of the Borlaug Institute for South Asia (BISA), in the Indian state of Bihar. (Photo: M. DeFreese/CIMMYT)
Fodder for thought
The findings from this study also validate the use of genomic prediction as an important breeding tool to accelerate the development and improvement of dual-purpose maize varieties, according to CIMMYT Maize Breeder and first author of the study, M.T. Vinayan.
With the demand for animal feed increasing around the world, crop scientists and breeders have been exploring more efficient ways to improve animal feed quality in cereals without compromising grain yields for human consumption.
“Not all maize varieties have good stover quality, which is what we realized when we started working on this project. However, we discovered that there are a few which offer just as good quality as sorghum stover — a major source of livestock fodder particularly in countries such as India,” said Zaidi.
The publication of the study is a fitting tribute to the late Michael Blummel, who was a principal scientist and deputy program leader in the feed and forage development program at ILRI and co-author of this study.
“A couple of years back Dr Blummel relocated from the Hyderabad office at ILRI to its headquarters at Addis Ababa, but he used to frequently visit Hyderabad, and without fail met with us on each visit to discuss updates, especially about dual-purpose maize work. He was very passionate about dual-purpose maize research with a strong belief that the additional income from maize stover at no additional cost will significantly improve the income of maize farmers,” Zaidi said. “Michael was following this publication very closely because it was the first of its kind in terms of molecular breeding for dual purpose maize. He would have been very excited to see this published.”
The President of India, Ram Nath Kovind (left) and the Minister of External Affairs, Subrahmanyam Jaishankar (right) announce the award to Ravi Singh. (Photo: Ministry of External Affairs, India)
Ravi Singh, Distinguished Scientist and Head of Global Wheat Improvement at the International Maize and Wheat Improvement Center (CIMMYT), has received the highest honor conferred by the Government of India to non-resident Indians.
The Pravasi Bharatiya Samman Award recognizes outstanding achievements by non-resident Indians, persons of Indian origin, or organizations or institutions run by them either in India or abroad. Awardees are selected for their support to India’s causes and concerns by a committee led by the Vice President and the Minister of External Affairs of India. The awardees, according to the awards website, “represent the vibrant excellence achieved by our diaspora in various fields.” The online award announcement ceremony took place on January 9, 2021, with India’s President Ram Nath Kovind as a chief guest.
Ravi Singh, whose career at CIMMYT spans 37 years, was recognized for his invaluable contributions to wheat research and the development and training of scientists that have increased food production and nutritional security in Mexico, India and numerous other countries in Africa, Asia and Latin America.
“The award recognizes and values many years of wheat breeding at CIMMYT, where I had the opportunity, privilege and satisfaction to have contributed and made impacts through our invaluable partners in India and many other countries,” Singh said. “By continuously providing superior varieties, we increased wheat production and incomes of millions of smallholder farming families.”
Singh’s nomination cited his contribution to the development, release and cultivation by national partners worldwide of over 550 wheat varieties over the past three decades. These national partners include the Indian Council of Agricultural Research (ICAR) and its affiliated institutions in India. These varieties, sown annually on over 40 million hectares by as many farmers, add over $1 billion annually to farmers’ incomes through increased productivity and built-in disease resistance, thus reducing chemical dependence to a negligible level.
Ravi Singh (left, in striped shirt) shows students how to score the seed of freshly-harvested wheat lines at CIMMYT’s experimental station near Ciudad Obregón, Mexico, during the international Wheat Improvement Course in 2007. (Photo: CIMMYT)
“Great teamwork leads to breakthroughs — and is the only way to achieve a common goal. Dr. Ravi Singh’s work alleviating hunger is a great service to mankind,” said Gyanendra Pratap Singh, director of the ICAR Indian Institute of Wheat and Barley Research (ICAR-IIWBR). “We are proud to have him on our team.”
“This award recognizes Dr. Ravi Singh’s important contribution to CIMMYT wheat breeding, delivering major impacts to wheat production and smallholder livelihoods in India, and around the world,” said Alison Bentley, director of CIMMYT’s Global Wheat Program.
Over his career, Singh has nourished and further expanded an already strong partnership between CIMMYT, ICAR and various agricultural universities in India by developing and sharing each year new, diverse wheat varieties possessing increased grain and straw yields, resistance to diseases such as rusts, spot blotch and blast, climate resilience, and processing and nutritional quality.
Over the past decade, Singh’s team developed about half of the wheat varieties released in India through the ICAR network. These include the country’s first high-yielding biofortified varieties, WB-2 and PBW1-Zn, released in 2017 to benefit India’s zinc-deficient population.
Millions of farmers in India continue to grow CIMMYT wheat varieties or their derivatives developed by Indian institutions, to ensure safe and abundant harvests and better nutrition.
Ravi Singh’s numerous recognitions include membership as a Fellow of the American Association for the Advancement of Science (AAAS), the American Phytopathological Society (APS), the Crop Science Society of America (CSSA), the American Society of Agronomy (ASA) and India’s National Academy of Agricultural Science (NAAS). His awards include the Outstanding CGIAR Scientist Award, the CSSA Crop Science Research Award, the University of Minnesota E.C. Stakman Award, and the China State Council’s Friendship Award, among others. He has been included among the top 1% of highly cited researchers according to Clarivate Analytics-Web of Science every year since 2017. Singh also serves as Adjunct Professor at Cornell University and Kansas State University.
A farmer in the Ara district, in India’s Bihar state, applies NPK fertilizer, composed primarily of nitrogen, phosphorus and potassium. (Photo: Dakshinamurthy Vedachalam/CIMMYT)
An international team of scientists, led by the International Maize and Wheat Improvement Center (CIMMYT), has demonstrated how better nutrient management using digital tools, such as the Nutrient Expert decision support tool, can boost rice and wheat productivity and increase farmers’ income while reducing chemical fertilizer use and greenhouse gas emissions.
Reported today in Nature Scientific Reports, the results show how the farmer-friendly digital nutrient management tool can play a key role in fighting climate change while closing the yield gap and boosting farmers’ profits.
The researchers tested the Nutrient Expert decision tool against typical farmer fertilization practices extensively using approximately 1600 side-by side comparison trials in rice and wheat fields across the Indo-Gangetic Plains of India.
The study found that Nutrient Expert-based recommendations lowered global warming potential by 12-20% in wheat and by around 2.5% in rice, compared to conventional farmers’ fertilization practices. Over 80% of farmers were also able to increase their crop yields and incomes using the tool.
Agriculture is the second largest contributor of greenhouse gas emissions in India. To tackle these emissions, crop scientists have been working on new ways to make farming more nutrient- and energy-efficient. Of the many technologies available, improving nutrient-use-efficiency through balanced fertilizer application — which in turn reduces excess fertilizer application — is key to ensuring food security while at the same time contributing to the UN’s Sustainable Development Goals on climate change.
The work was carried out by CIMMYT in collaboration with farmers, and funded by the CGIAR Research Program on Climate Change, Agriculture and Food Security (CCAFS), the CGIAR Research Program on Wheat (WHEAT), and the Indian Council of Agricultural Research (ICAR). Scientists from the Borlaug Institute for South Asia (BISA), the International Rice Research Institute (IRRI), the Alliance of Bioversity International and CIAT, and the former International Plant Nutrition Institute (IPNI) also contributed to this study.
Researchers tested the Nutrient Expert decision tool against typical farmer fertilization practices extensively using approximately 1600 side-by side comparison trials in rice and wheat fields across the Indo-Gangetic Plains of India (Graphic: CIMMYT).
Precise recommendations
Nutrient Expert, which was launched back in 2013, works by analysing growing conditions, natural nutrients in the soil, and even leftover nutrients from previous crops to provide tailored fertilizer recommendations directly to farmers phones. The tool also complements the Government of India’s Soil Health Cards for balanced and precise nutrient recommendations in smallholder farmers’ fields.
Each farmer’s field is different, which is why blanket fertilizer recommendations aren’t always effective in producing better yields. By using nutrient management tools such as Nutrient Expert, farmers can obtain fertilizer recommendations specific to the conditions of their field as well as their economic resources and thus avoid under-fertilizing or over-fertilizing their fields.
“While efficient nutrient management in croplands is widely recognized as one of the solutions to addressing the global challenge of supporting food security in a growing global population while safeguarding planetary health, Nutrient Expert could be an important tool to implement such efficient nutrient management digitally under smallholder production systems,” said Tek Sapkota, CIMMYT climate scientist and first author of the study.
Sapkota also argues that adoption of the Nutrient Expert tool in rice-wheat systems of India alone could provide almost 14 million tonnes (Mt) of extra grain with 1.4 Mt less nitrogen fertilizer use, and a reduction of 5.3 Mt of carbon (CO2) emissions per year over current practices.
However, technological innovation alone will not achieve these positive outcomes.
“Given the magnitude of potential implications in terms of increasing yield, reducing fertilizer consumption and greenhouse gas emissions, governments need to scale-out Nutrient Expert-based fertilizer management through proper policy and institutional arrangements, especially for making efficient use of the nearly 200 million Soil Health Cards that were issued to farmers as part of the Soil Health mission of the Government of India,” said ML Jat, CIMMYT principal scientist and co-author of the study.
Ravi Singh, Distinguished Scientist and Head of Global Wheat Improvement at the International Maize and Wheat Improvement Center (CIMMYT), received the highest honor conferred by the Government of India to non-resident Indians.
Singh, whose career at CIMMYT spans 37 years, was recognized for his invaluable contributions to wheat research and the development and training of scientists that have increased food production and nutritional security in Mexico, India and numerous other countries in Africa, Asia and Latin America.
Surender Prasad stands next to his Happy Seeder-mounted tractor in Uttar Pradesh, India. (Photo: Ajay K Pundir/CIMMYT)
The agricultural sector is possibly the largest livelihood provider in India, with the smallholder farming community in the vast Indo-Gangetic Plains making the bulk of it. They are the community responsible for growing the food available on our table. In celebration of India’s National Farmer’s Day on December 23 — known in Hindi as Kisan Diwas — we share the story of a farmer-turned-entrepreneur from eastern Uttar Pradesh, where the International Maize and Wheat Improvement Center (CIMMYT) and its partners have invested in supporting smallholder farmers to implement best farming practices and improve yields through sustainable intensification.
“I am a farmer and I am hopeful of a future for my children in the farming sector,” says Surender Prasad, a 52-year-old farmer from Umila village in Santkabir Nagar district, Uttar Pradesh. Prasad is one of the innovative farmers in and around the district who has time and again strived to introduce new implements and technologies on his farm — often a big risk for smallholders like him.
In 2014, Prasad met researchers from CIMMYT’s Cereal Systems Initiative for South Asia (CSISA) project while visiting the village Lazar Mahadeva during an inter-district traveling seminar. After seeing the farmer demonstration plots for himself — which, incidentally, is one of the best ways of raising farmer awareness in the region — Prasad was convinced of the efficiency of transplanting rice by machine and using zero tillage in wheat production.
Through his continued association with the project, Prasad has now adopted both practices, in addition to direct seeded rice (DSR) and Laser Land Levelling. With a single 35 horsepower tractor, cultivator and harrow, Prasad was able to improve his wheat grain yield by one ton per hectare during the 2014-15 cropping season, and secure improved profit margins as a result.
Encouraged by these results, in 2018 Prasad purchased a 55 horsepower New Holland Tractor, a Happy Seeder, a tractor-mounted sprayer and other machinery for custom hire under the state government’s machinery bank scheme. His aspiration for entrepreneurship grew in the months following these purchases and he has since established himself as a local service provider, alongside his role as a farmer. According to Prasad, his continued association with CSISA and its network of partners helped him gain better technical knowledge and skills as well as confidence with using conservation agriculture-based machinery, thanks to trainings provided by the project team.
Surender Prasad stands in his field, where wheat grows under rice-crop residue. (Photo: Ajay K Pundir/CIMMYT)
A budding entrepreneur
Today Prasad is an important entrepreneur in the region, providing custom hiring services for Happy Seeder and DSR and promoting agricultural mechanization in his community. Going forward, scale-appropriate farm mechanization will help farmers in the area to intensify their cropping system at a lower cost, supported by use of the conservation agriculture approaches encouraged by the CSISA project team, which have been shown to improve yields, reduce farmer costs and preserve natural resources. For example, using these best management practices Prasad was able to harvest an additional 1.1 tons of wheat from the 10 acres of land owned by him and his brother, and most farmers in his village now follow his crop management advice.
He is quick to adopt new ideas and has become something of an influencer in the area, earning him friends among the farming community and helping the CSISA team reach more farmers with new innovations.
This year the opportunity for hiring out mechanization services has been immense, largely due to the impact of the COVID-19 pandemic, which has created difficulties for farmers engaged in rice transplanting. As a result, Prasad managed to sow 90 acres of DSR on his own farm and in the nearby village, as well as seeding 105 acres of wheat in the fall 2020 season. “Thanks to mechanization we were far less affected by the COVID-19 disruptions and managed to plant rice and then wheat without much delay,” he explains. Prasad also provided tractor-mounted sprayer services for applying herbicides and insecticide on 90 acres of rice crop. Considering these successes, he has now planned to offer year-round extension services.
“I feel overwhelmed after serving my own community as a service provider,” says Prasad. “I feel proud of myself when other farmers come asking for my assistance.” Endorsing his contribution as an innovative farmer, the Department of Agriculture for the Government of Uttar Pradesh recognized him with awards in 2015 and 2019. He attributes his success to his exposure to CSISA interventions and support and believes that CSISA acted as a facilitator, encouraging him to use his ideas for his own benefit and for the benefit of the larger agrarian community around him.
Surender Prasad drives his Happy Seeder-mounted tractor in Uttar Pradesh, India. (Photo: Ajay K Pundir/CIMMYT)
Gokul Paudel is an agricultural economist working to streamline farming practices in South Asia. He seeks to understand, learn from and improve the efficiency of on-farm management practices in a vast variety of ways. Although he joined the International Improvement Center for Wheat and Maize (CIMMYT) right after university, Paudel’s on-farm education started long before his formal courses.
“I was born in a rural village in Baglung district, in the mid-hills of Nepal. My parents worked on a small farm, holding less than half a hectare of land,” he says. “When I was a kid, I remember hearing that even though Nepal is an agricultural country, we still have a lot of food insecurity, malnutrition and children who suffer from stunting.”
“I would ask: How is Nepal an agricultural country, yet we suffer from food insecurity and food-related problems? This question is what inspired me to go to an agricultural university.”
Paudel attended Tribhuvan University in Nepal, and through his coursework, he learned about plant breeding, genetic improvement and how Norman Borlaug brought the first Green Revolution to South Asia. “After completing my undergraduate and post-graduate studies, I realized that CIMMYT is the one organization that contributes the most to improving food security and crop productivity in developing countries, where farmers livelihoods are always dependent on agriculture,” he explains.
Approaching the paradox
Paudel is right about the agriculture and food paradox of his home country. Almost two thirds of Nepal’s population is engaged in agricultural production, yet the country still has shockingly high numbers in terms of food insecurity and nutritional deficiency. Furthermore, widespread dissemination of unsustainable agronomic practices, like the use of heavy-tilling machinery, present similar consequences across South Asia.
If research and data support the claim that conservation agriculture substantially improves crop yields, then why is the adoption of these practices so low? That is exactly what Paudel seeks to understand. “I want to help improve the food security of the country,” he explains. “That’s why I joined the agricultural sector.”
Paudel joined CIMMYT in 2011 to work with the Socioeconomics Program (SEP) and the Cereal Systems Initiative for South Asia (CSISA), providing regional support across Bangladesh, India and Nepal.
His work is diverse. Paudel goes beyond finding out which technological innovations increase on-farm yield and profit, because success on research plots does not always translate to success on smallholder fields. He works closely with farmers and policy makers, using surveys and high-tech analytical tools such as machine learning and data mining to learn about what actually happens on farmers’ plots to impact productivity.
Gokul Paudel holds up two bags of wheat crop-cuts in a farmer’s field. (Photo: CIMMYT)
A growing future for conservation agriculture
Over the last two decades, the development of environmentally sustainable and financially appealing farming technologies through conservation agriculture has become a key topic of agronomic research in South Asia.
“Conservation agriculture is based on three principles: minimum disturbance of the soil structure, cover crop and crop rotation, especially with legumes,” Paudel explains.
Leaving the soil undisturbed through zero-till farming increases water infiltration, holds soil moisture and helps to prevent topsoil erosion. Namely, zero-till farming has been identified as one of the most transformative innovations in conservation agriculture, showing the potential to improve farming communities’ ability to mitigate the challenges of climate change while also improving crop yields.
Can farm mechanization ease South Asia’s labor shortage?
In South Asia, understanding local contexts is crucial to streamlining farm mechanization. In recent years, many men have left their agricultural jobs in search of better opportunities in the Gulf countries and this recent phenomenon of labor out-migration has left women to take up more farming tasks.
“Women are responsible for taking care of the farm, household and raising their children,” says Paudel. “Since rural out-migration has increased, they have been burdened by the added responsibility of farm work and labor scarcity. This means that on-farm labor wages are rising, exacerbating the cost of production.”
The introduction of farm machinery, such as reapers and mini-tillers, can ease the physical and financial burden of the labor shortage. “Gender-responsive farm mechanization would not only save [women’s] time and efforts, but also empower them through skills enhancement and farm management,” says Paudel. However, he explains, measures must be taken to ensure that women actually feel comfortable adopting these technologies, which have traditionally been held in the male domain.
Gokul Paudel records the total above-ground biomass of maize and other maize yield attributes in a farmer’s field in Kanchunpur, Nepal. (Photo: Ashok Rai/CIMMYT)
From farm-tech to high-tech
Right now, amidst the global lockdown due to COVID-19, Paudel’s field activities are highly restricted. However, he is capitalizing on an opportunity to assess years’ worth of data on on-farm crop production practices, collected from across Bangladesh, India and Nepal.
“We are analyzing this data-set using novel approaches, like machine learning, to understand what drives productivity in farmers’ fields and what to prioritize, for our efforts and for the farmers,” he explains.
Although there are many different aspects of his work, from data collection and synthesis to analysis, Paudel’s favorite part of the job is when his team finds the right, long-lasting solution to farmers’ production-related problems.
“There’s a multidimensional aspect to it, but all of these solutions affect the farmer’s livelihood directly. Productivity is directly related to their food security, income and rural livelihoods.”
A changing landscape
About 160 km away from where he lives now, Paudel’s parents still own the farm he grew up on — though they no longer work on it themselves. They are proud to hear that his work has a direct impact on communities like theirs throughout the country.
“Every day, new problems are appearing due to climate change — problems of drought, flooding and disease outbreak. Though it’s not good news, it motivates me to continue the work that I’m doing,” says Paudel. “The most fascinating thing about working at CIMMYT is that we have a team of multidisciplinary scientists working together with the common goal of sustainably intensifying the agricultural systems in the developing world.”
