Nigel Poole, Professor of International Development at SOAS, University of London, writes on The Conversation about the role of cereals in fighting malnutrition. Poole was a Visiting Fellow at the International Maize and Wheat Improvement Center (CIMMYT) in Mexico for a year.
Read more: https://theconversation.com/global-malnutrition-why-cereal-grains-could-provide-an-answer-156786
The key to transforming food production systems globally lies in knowledge management processes, according to a team of researchers from the International Maize and Wheat Improvement Center (CIMMYT).
The challenge is to combine traditional knowledge with state-of-the-art scientific research: to meet regional needs for improvement in farming systems with knowledge networks fostering innovative practices and technologies that increase yields and profits sustainably.
A group of CIMMYT researchers led by Andrea Gardeazábal, Information and Communications Technology for Agriculture Monitoring and Evaluation Manager, recently published a proposal for a new knowledge management framework for agri-food innovation systems: Agricultural Knowledge Management for Innovation (AKM4I).
“We are proposing a knowledge management framework for agricultural innovation that addresses the need for more inclusive and environmentally sustainable food production systems that are able to provide farmers and consumers with affordable and healthy diets within planetary boundaries,” Gardeazábal said.
The AKM4I framework was designed to help agricultural development practitioners understand how farming skills and abilities are developed, tested and disseminated to improve farming systems in real-life conditions.
Following systems theory principles, the model empirically describes how information is created, acquired, stored, analyzed, integrated and shared to advance farming knowledge and produce innovative outcomes that effectively contribute to: collaboratively building local capacities for developing joint problem-solving abilities and integrated-knowledge solutions; empowering farmers with site-specific knowledge; co-creating technology and conducting participatory community-based research; and bridging innovation barriers to drive institutional change.
Knowledge access for systems transformation
The framework builds on CIMMYT’s learnings from MasAgro, a bilateral project with Mexico that relies on participatory research and knowledge and technology development networks for sustainable maize and wheat production systems.
This CIMMYT project was recently acknowledged with the 2020 Innovative Applications in Analytics Award for developing groundbreaking monitoring, evaluation, accountability and learning (MEAL) systems and tools for publicly funded researchers and field technicians who advise more than 150,000 farmers in Mexico.
“Through the outlined principles and processes, the AKM4I framework can assist in closing the cycle of continually re-creating knowledge, evaluating and iterating upon innovations, building coalitions to democratize knowledge access and utilization, and using MEAL to facilitate course-correction of all stages of knowledge management,” concludes the study.
Bram Govaerts, CIMMYT Chief Operating Officer, Deputy Director General for Research and Integrated Development Program Director, believes the AKM4I framework should be the cornerstone of agri-food systems transformation, including the current reformation of CGIAR’s partnerships, knowledge, assets, and global presence.
“The MasAgro hub and knowledge management model will become the operational model of many regional initiatives of CGIAR,” Govaerts said.
Read the study:
Knowledge management for innovation in agri-food systems: a conceptual framework
The overall objective of the 5-year EU-funded DeSIRA action, led by the International Potato Center (CIP), is to improve climate change adaptation of agricultural and food systems in Malawi through research and uptake of integrated technological innovations.
CIMMYT’s role is focused on the following project outputs:
Protected from the harsh midday sun with a hat, Pramila Mondal pushes behind the roaring engine of a two-wheel tractor. She cultivates a small plot of land with her husband in the small village of Bara Kanaibila, in the Rajbari district of Bangladesh, near the capital Dhaka.
Using this machine, she also provides planting services to farmers who need to sow wheat, maize, mungbean, mustard and jute, earning her between $600 and $960 in each planting season.
Mondal and her husband first heard about this technology five years ago, when they attended an event to promote agricultural mechanization, organized by the International Maize and Wheat Improvement Center (CIMMYT). After seeing a demonstration, they were convinced that the power-tiller-operated seeder could form the basis for a business.
Ultimately, Mondal bought the machine. She got training on how to operate and maintain it, as part of the Cereal Systems Initiative for South Asia – Mechanization Irrigation and Mechanization Extension Activity (CSISA-MI and CSISA-MEA) project, supported by USAID through Feed the Future.
Let’s get it started
Mondal became the only woman in her area who could operate a seeder of this type, making her locally famous. After seeing the results of her business, others followed suit.
Eight more women in her area expressed interest in operating power-tiller-operated seeders and also went on to become service providers.
They all faced a similar problem: power tillers are hard to start. Pulling the starting rope or turning the hand crank requires a lot of strength.
The CSISA-MEA project team worked with a local engineering company to introduce a self-starting mechanism for power tiller engines. Since then, starting diesel engines is no longer a problem for women like Mondal.
Glee for the tillerwoman
Almost all of the 11 million hectares of rice planted every year in Bangladesh are transplanted by hand. It is becoming increasingly difficult to find people willing to do this type of backbreaking work. New machines are being introduced that transplant rice mechanically, but they require rice seedling to be raised in seedling mats.
As this new service is required, Mondal jumped at the opportunity. With support from CIMMYT through the CSISA-MEA project, she is now raising seedlings for this new type of rice transplanters.
CIMMYT facilitated training for machinery service providers on mat type seedling production, in partnership with private companies. Mondal and other women who were also trained produced enough seedlings to plant 3.2 hectares of land with a rice transplanter they hired from a local owner.
Mondal and her husband now have big dreams. They intend to buy a rice transplanter and a combine harvester.
“With our effort we can make these changes, but a little support can make big difference, which the CSISA-MEA project did,” she said.
The conservation of plant genetic diversity through germplasm conservation is a key component of global climate-change adaptation efforts. Germplasm banks like the maize and wheat collections at the International Maize and Wheat Improvement Center (CIMMYT) may hold the genetic resources needed for the climate-adaptive crops of today and tomorrow.
But how do we ensure that these important backups are themselves healthy and not potential vectors of pest and disease transmission?
This was the question that animated “Germplasm health in preventing transboundary spread of pests and pathogens,” the second webinar in Unleashing the Potential of Plant Health, a CGIAR webinar series in celebration of the UN-designated International Year of Plant Health.
“Germplasm refers to the source plants of either specific cultivars or of unique genes or traits that can be used by breeders for improved cultivars,” program moderator and head of the Health and Quarantine Unit at the International Potato Center (CIP) Jan Kreuze explained to the event’s 622 participants. “If the source plant is not healthy, whatever you multiply or use it for will be unhealthy.”
According to keynote speaker Saafa Kumari, head of the Germplasm Health Unit at the International Center for Agricultural Research in the Dry Areas (ICARDA), we know of 1.3 thousand pests and pathogens that infect crops, causing approximately $530 billion in damages annually. The most damaging among these tend to be those that are introduced into new environments.
Closing the gap, strengthening the safety net
The CGIAR has an enormous leadership role to play in this area. According to Kumari, approximately 85% of international germplasm distribution is from CGIAR programs. Indeed, in the context of important gaps in the international regulation and standards for germplasm health specifically, the practices and standards of CGIAR’s Germplasm Health Units represent an important starting point.
“Germplasm health approaches are not necessarily the same as seed and plant health approaches generally,” said Ravi Khaterpal, executive secretary for the Asia-Pacific Association of Agricultural Research Institutions (APAARI). “Best practices are needed, such as CGIAR’s GreenPass.”
In addition to stronger and more coherent international coordination and regulation, more research is needed to help source countries test genetic material before it is distributed, according to Francois Petter, assistant director for the European and Mediterranean Plant Protection Organization (EPPO). Head of the CGIAR Genebank Platform Charlotte Lusty also pointed out the needed for better monitoring of accessions in storage. “We need efficient, speedy processes to ensure collections remain healthy,” she said.
Of course, any regulatory and technological strategy must remain sensitive to existing and varied social and gender relations. We must account for cultural processes linked to germplasm movement, said Vivian Polar, Gender and Innovation Senior Specialist with the CGIAR Research Program on Roots, Tubers and Bananas (RTB). Germplasm moves through people, she said, adding that on the ground “women and men move material via different mechanisms.”
“The cultural practices associated with seed have to be understood in depth in order to inform policies and address gender- and culture-related barriers” to strengthening germplasm health, Polar said.
The event was co-organized by researchers at CIP and the International Institute of Tropical Agriculture (IITA).
The overall webinar series is hosted by CIMMYT, CIP, the International Food Policy Research Institute (IFPRI), IITA, and the International Rice Research Institute (IRRI). It is sponsored by the CGIAR Research Program on Agriculture for Nutrition (A4NH), the CGIAR Gender Platform and the CGIAR Research Program on Roots, Tubers and Bananas (RTB).
The third of the four webinars on plant health, which will be hosted by CIMMYT, is scheduled for March 10 and will focus on integrated pest and disease management.
The continuing increase in the number of farming families has led to a growing emphasis on approaches on how to reach more people at a time. Among others, individual, group and mass-media approaches to agricultural extension and advisory services have been used concurrently.
This year, the global COVID-19 pandemic presented yet another challenge to the agriculture sector due to travel restrictions and limited face-to-face interactions. This has obstructed capacity building for farmers as well as development agents to deliver seasonal and intra-seasonal agroclimate advisories for farmers to support farm decisions.
Realizing the importance of mass media in extension, the International Maize and Wheat Improvement Center (CIMMYT) in collaboration with the Ministry of Agriculture, the Ethiopian Institute of Agricultural Research (EIAR) and Climate Change, Agriculture and Food Security (CCAFS)-EA used live show radio program on Sunday mornings to provide climate advisories on the 2020 Kiremt (main cropping) season to farmers and extension workers on a two-weekly basis between June and November. The live show also allows listeners to call in and ask questions and provide feedback. Besides the climate agro-advisories, COVID-19 alerts and precautionary measures were provided to the radio audience.
Extremely low climate induced risk perception
CIMMYT-CASCAID II project baseline assessment indicates that the rural communities in the project intervention areas have an extremely low climate induced risk perception and are also quite resistant to change. The areas are also highly prone to recurring droughts. Erratic rainfall distribution and dry spells are common. Large areas of barren and uncultivable land, water shortage, poor soil quality, soil erosion due to high run off rate are adversely affecting the farming systems. Research shows that simple adaptation actions such as watershed management, changing planting dates and crop varieties could greatly reduce the climate variability and change impacts. However, communities being poorly linked to scientists and policy makers lack information about climate change adaptation options and government schemes related to the same. There are also challenges of communicating scientific research in simplified ways that are appropriate to local stakeholder needs.
In recent years, the use of improved technologies has been increasing due to the progressive national agricultural development policy and strategy that is in place coupled with advisories provided to help farmers to make timely and appropriate farm level decisions and practices.
Agroclimate advisory – the fourth production factor
The provision of agroclimate advisory is considered as the fourth production factor after labor, land, and capital and critical to the agricultural sector as climate and its associated adverse effects can negatively affect agricultural activities and productivities. Thus, ensuring the accessibility of relevant time sensitive forecast based advisory information to farming communities helps improve productivity and yields higher returns.
The advice will also assist smallholder farmers to manage climate risks through informed decisions such as identifying optimum planting time/sowing windows, planting density at the start of the rainy season, while at the same time managing fertilizer application. Moreover, it also benefits farmer decisions and practices on soil water, weeds, diseases, and pest management throughout the growing season. By monitoring weather and crop growth during the season, the same forecast information can assist in predicting crop yields well in advance of crop maturity and to allow farmers to decide whether to sell the product immediately after harvest or store it until it commands better prices later in the year.
Radio for disseminating agroclimate information
In Ethiopia, the use of ICT for the accumulation and dissemination of agroclimate information and other agricultural updates is still low. Radio transmission covers a large percentage of the country with most of the households own a radio. This makes the use of radio programs one of the most cost-effective channels for conveying weather forecast information and agricultural knowledge to rural communities which ultimately facilitate informed decision-making and adoption of new technologies and practices.
In collaboration with its partners, the CIMMYT-CASCADE II project through Fana FM radio implemented a six-month (June-November 2020) live radio program providing seasonal advisories at the start of the main season in June using seasonal forecast from the National Meteorology Agency which was downscaled to Woreda/Kebele level by EIAR, CCAFS-EA and CIMMYT. This was followed by a biweekly or monthly Wereda specific agro-climate advisories which focus on fertilizer application, weeding, crop protection, soil and water management and climate extremes such as flood and droughts.
The program also included experts from the Ministry of Agriculture, EIAR, and CGIAR Centers to provide professional explanations and updates from the perspective of in situational readiness to support issues coming from the radio audience. The program created an opportunity for the federal government to prepare in time on some activities like importing agricultural inputs such as pesticides and fungicides to control the outbreak of pests and diseases (e.g., desert locust infestation and wheat rust outbreak). The platform also provided an opportunity to reach to millions of farmers to convey COVID-19 prevention messages such as physical distancing, use of masks, handwashing and other precautions that need to be taken while working in groups.
The state of Odisha, in the east of India, ranks sixth in rice production in the country. Agriculture in Odisha’s tribal-dominated plateau region, however, is characterized by depleted soils along with low and variable rice yields. During the monsoon season, more than 60,000 hectares of land are left fallow, due to lack of knowledge and to farmers’ low risk tolerance.
In districts like Mayurbhanj, over 50% of the population belongs to tribal groups. Women there are mostly engaged in traditional roles: being at home looking after family, farm and livestock while their men are away as migrant laborers or with menial jobs. Women working on farming used to be considered daily wage laborers, as if they were only supporting their husband or family who were officially the farmers.
The last few years, with the introduction of maize cultivation and its promotion predominantly for women farmers, a significant change in the perception of women’s role is unfolding in the region.
In 2013, the International Maize and Wheat Improvement Center (CIMMYT) began working in the plateau region through the Cereal Systems Initiative for South Asia (CSISA), improving farming systems for higher yields and providing sustainable livelihood options for tribal farmers. Since then, farmers in the region have achieved considerable production of maize in the monsoon season — and women have particularly led this transformation.
Farmers from this region — 28% of which were women — converted 5,400 hectares of fallow lands into successful maize cultivation areas. Not only has this new opportunity helped improve family income, but also women’s identity as resilient and enterprising farmers.
This impact was possible through the applied research efforts of the CSISA project along with partners like Odisha’s State Department of Agriculture, the Odisha Rural Development and Marketing Society (ORMAS), the Integrated Tribal Development Agency (ITDA) and two federations of women’s self-help groups supported by PRADAN.
On International Women’s Day, we share the story of these successful farmers who have made maize cultivation a part of their livelihoods and a tool for socioeconomic development.
Transforming fallow lands into golden maize fields
Women working in the fields used to be considered daily wage laborers, but today they are acknowledged as enterprising farmers who transformed fallow lands into golden maize fields.
In the season 2019/2020 alone, in all four districts where CSISA is actively engaged — Bolangir, Keonjhar, Mayurbhanj and Nuapada — improved maize cultivation was adopted by 7,600 farmers — 28% of which were women — in 5,400 hectares of fallow land, resulting in considerable production of quality maize in the region. Since many of the women in the districts are smallholder farmers or without agriculture land, farming also happens on leased land through self-help groups.
Learning and implementing best maize cultivation practices
CSISA supports the farmers all the way from sowing to crop harvesting, ensuring the produce is shiny and golden. Through self-help groups, farmers have access to fertilizers and machines to weed and earth-up their fields. Researchers have introduced seed cum fertilizer drills for maize sowing, which make fertilizer placement more uniform and crop establishment easier, saving time and helping these women manage both household responsibilities and the farm.
Quality knowledge for quality grain
To strengthen the capacity of farmers, the project team trains them continuously on grain quality parameters like moisture level, foreign matters, infestation rate. Most of the participants are farmers from women collectives and self-help groups. They have gradually advanced in their knowledge journey, going from general awareness to subject-specific training.
Marketing gurus
Even though many large poultry feed mills operate in Odisha, most of their maize comes from outside the state. Women self-help groups are bridging that gap. In collaboration with the State Department of Agriculture and Farmers’ Empowerment, the CSISA project has cultivated a network of market actors including producers, providers of agricultural inputs and development partners. Market access to these value chains will help women, all the way from planting to produce marketing.
Extending the collaboration, in the four districts of Odisha and beyond
A considerable increase in maize production has improved incomes for families across the regions, as well as their food security. It has also created opportunities for women to raise their social and economic standing.
There are opportunities for CSISA and its partners to continue collaborating in the project region and beyond. CIMMYT has worked with Odisha’s State Department of Agriculture, the Odisha Rural Development and Marketing Society (ORMAS), the Integrated Tribal Development Agency (ITDA), women’s self-help groups, farmers’ producer groups, private seed companies and many other collectives.
Weathering the crisis
Women have shouldered the responsibility and led their families out of the COVID-19 crisis. When men were left jobless and stranded as migrant workers during lockdown, many women associated with the CSISA project began generating income by selling green corn. This small income helped ensure food to feed their families and wellbeing in this critical period.
The road ahead
With the purpose of advocating this positive transformation in similar conditions, CSISA is committed to expand maize intensification in the plateau region of Odisha and engaging more farmers. Ongoing research and studies are focusing on improving the outreach, to help women increase their maize area and productivity with better-bet agronomy. This will contribute to secured income in coming years and the sustainability of the initiative.
Global thought leader, philanthropist and one of the International Maize and Wheat Improvement Center (CIMMYT) and CGIAR’s most vocal and generous supporters, Bill Gates, wrote a book about climate change and is now taking it around the world on a virtual book tour to share a message of urgency and hope.
With How to Avoid a Climate Disaster, Gates sets out a holistic and well-researched plan for how the world can get to zero greenhouse gas emissions in time to avoid a climate catastrophe. Part of this plan is to green everything from how we make things, move around, keep cool and stay warm, while also considering how we grow things and what can be done to innovate agriculture to lower its environmental impact.
Interviewed by actor and producer Rashida Jones, Gates explained his passion for action against climate change: “Avoiding a climate disaster will be one of the greatest challenges us humans have taken on. Greater than landing on the moon, greater than eradicating smallpox, even greater than putting a computer on every desk.”
“The world needs many breakthroughs. We need to get from 51 billion tons [of greenhouse gases] to zero while still meeting the planet’s basic needs. That means we need to transform the way we do almost everything.”
Innovations in agriculture
When a book tour event attendee asked about the role of agriculture research in improving farmers’ livelihoods, Gates linked today’s challenge to that of the Green Revolution more than half a century ago. “There’s nothing more impactful to reduce the impacts of climate change than working on help for farmers. What we can do this time is even bigger than that. […] The most unfunded thing in this whole area is the seed research that has so much potential,” he said.
One such innovation and one of Gates’ favorite examples of CGIAR’s work is featured in Chapter 9 of his climate book – “Adapting to a warmer world” – and has been the source of generous funding from the Bill & Melinda Gates Foundation: drought-tolerant maize. “[…] as weather patterns have become more erratic, farmers are at greater risk of having smaller maize harvests, and sometimes no harvest at all. So, 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,” writes Gates.
We at CIMMYT are very proud and humbled by this mention as in collaboration with countless partners, CIMMYT and the International Institute of Tropical Agriculture (IITA) developed and promoted these varieties across 13 countries in sub-Saharan Africa and contributed to lifting millions of people above the poverty line across the continent.
For example, in Zimbabwe, farmers who used drought-tolerant maize varieties in dry years were able to harvest up to 600 kilograms more maize per hectare — enough for nine months for an average family of six — than farmers who sowed conventional varieties.
The world as we know it is over and, finally, humanity’s fight against climate change is becoming more and more mainstream. CIMMYT and its scientists, staff, partners and farmers across the globe are working hard to contribute to a transformation that responds to the climate challenge. We have a unique opportunity to make a difference. It is in this context that CGIAR has launched an ambitious new 10-year strategy that echoes Gates’s hopes for a better environment and food security for the generations to come. Let’s make sure that it ticks the boxes of smallholder farmers’ checklists.
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.
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.
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.”
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.
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.
In a study published in the journal Science Advances, scientists conclude that a switch to canal irrigation will not fully compensate for the expected loss of groundwater in Indian agriculture.
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.
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.
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Since the 1980s, the International Maize and Wheat Improvement Center (CIMMYT) and the International Institute of Tropical Agriculture (IITA) have spearheaded the development and deployment of climate-smart maize in Africa.
This game-changing work has generated massive impacts for smallholder farmers, maize consumers, and seed markets in the region. It also offers a blueprint for CGIAR’s new 2030 Research and Innovation Strategy, which proposes a systems transformation approach for food, land and water systems that puts climate change at the center of its mission.
Over the course of the 10-year run of the first iteration of this collaborative work on climate-adaptive maize, the Drought Tolerant Maize for Africa (DTMA) project, CIMMYT and IITA partnered with dozens of national, regional, and private sector partners throughout sub-Saharan Africa to release around 160 affordable maize varieties. This month, CGIAR recognizes climate-smart maize as one of the standout 50 innovations to have emerged from the institution’s first half-century of work.
Game changer
Maize’s importance as a food crop in sub-Saharan Africa is hard to overstate. So are the climate change-driven challenges it faces.
It accounts for almost one third of the region’s caloric intake. It is grown on over 38 million hectares, primarily under rainfed conditions. Around 40% of this area faces occasional drought stress. Another 25% suffers frequent drought and crop losses reaching 50%.
Drought-tolerant maize stabilized production under drought-stress conditions. Recent studies show that farmers growing drought-tolerant maize varieties in dry years produced over a half ton more maize per hectare than those growing conventional varieties — enough maize to support a family of six for nine months.
Such drastic results fed increased demand for improved, climate-adaptive maize seed in sub-Saharan Africa, thus strengthening local commercial seed markets and helping drought-tolerant maize varieties reach an increasing share of climate-vulnerable farmers.
Today, approximately 8.6 million farmers have benefitted from CIMMYT- and IITA-derived climate-adaptive maize varieties in sub-Saharan Africa. Millions have risen above the poverty line.
In addition to drought-tolerance, CIMMYT- and IITA-derived climate-adaptive maize varieties have been developed to tolerate multiple climate-driven stresses and to provide improved nutritional outcomes through biofortification with essential nutrients such as provitamin A and zinc.
The task ahead
In his recently published book, How to Avoid a Climate Catastrophe, Bill Gates says “no other organization has done more than CGIAR to ensure that families — especially the poorest — have nutritious food to eat. And no other organization is in a better position to create the innovations that will help poor farmers adapt to climate change in the years ahead.”
CGIAR’s new strategic orientation is an important step towards making good on that potential. CIMMYT and IITA’s longstanding work on climate-smart maize offers an important blueprint for the kinds of bold, comprehensive, and collaborative research for development initiatives such a strategy could empower.
As CIMMYT and IITA directors general Martin Kropff and Nteranya Sanginga note in a recent op-ed, “The global battle against climate change and all its interconnected impacts requires a multisectoral approach to formulate comprehensive responses.”
A leader of wheat breeding and later director of CIMMYT’s Global Wheat Program, Sanjaya Rajaram passed away at the age of 78.
Recognized with the World Food Prize in 2014, he personally oversaw the development of more than 480 high-yielding, disease-resistant varieties sown on 58 million hectares in 51 countries, increasing global wheat production by more than 200 million tons during his lifetime in diverse regions across the globe.
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.
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.
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.
As scientists study and learn more about the complicated genetic makeup of the wheat genome, one chromosomal segment has stood out, particularly in efforts to breed high-yielding wheat varieties resistant to devastating and quickly spreading wheat diseases.
Known as the 2NvS translocation, this segment on the wheat genome has been associated with grain yield, tolerance to wheat stems bending over or lodging, and multiple-disease resistance.
Now, thanks to a new multi-institution study led by wheat scientist Liangliang Gao of Kansas State University, we have a clearer picture of the yield advantage and disease resistance conferred by this chromosomal segment for wheat farmers — and more opportunities to capitalize on these benefits for future breeding efforts.
The Aegilops ventricosa 2NvS segment in bread wheat: cytology, genomics and breeding, published in Theoretical and Applied Genetics, summarizes the collaborative effort by scientists from several scientific institutions — including International Maize and Wheat Improvement Center (CIMMYT) head of global wheat improvement Ravi Singh and wheat scientist Philomin Juliana — to conduct the first complete cytological characterization of the 2NvS translocation.
A rich background
The 2NvS translocation segment has been very valuable in disease-resistance wheat breeding since the early 1990s. Originally introduced into wheat cultivar VPM1 by the French cytogeneticist Gerard Doussinault in 1983 by crossing with a wild wheat relative called Aegilops ventricosa, the segment has been conferring resistance to diseases like eye spot (Pch1 gene), leaf rust (Lr37 gene), stem rust (Sr38 gene), stripe rust (Yr17 gene), cereal cyst (Cre5 gene), root knot (Rkn3 gene) and wheat blast.
The high-yielding blast-resistant CIMMYT-derived varieties BARI Gom 33 and WMRI#3 (equivalent to Borlaug100),released in Bangladesh to combat a devastating outbreak of wheat blast in the region, carry the 2NvS translocation segment for blast resistance.
Earlier research by Juliana and others found that the proportion of lines with the 2NvS translocation had increased by 113.8% over seven years in CIMMYT’s international bread wheat screening nurseries: from 44% in 2012 to 94.1% in 2019. It had also increased by 524.3% in the semi-arid wheat screening nurseries: from 15% in 2012 to 93.7% in 2019. This study validates these findings, further demonstrating an increasing frequency of the 2NvS translocation in spring and winter wheat breeding programs over the past two decades.
New discoveries
The authors of this study completed a novel assembly and functional annotation of the genes in the 2NvS translocation using the winter bread wheat cultivar Jagger. They validated it using the spring wheat cultivar CDC Stanley and estimated the actual size of the segment to be approximately 33 mega base pairs.
Their findings substantiate that the 2NvS region is rich in disease resistance genes, with more than 10% of the 535 high-confidence genes annotated in this region belonging to the nucleotide-binding leucine-rich repeat (NLR) gene families known to be associated with disease resistance. This was a higher number of NLRs compared to the wheat segment of the Chinese Spring reference genome that was replaced by this segment, adding further evidence to its multiple-disease resistant nature.
In addition to being an invaluable region for disease resistance, the study makes a strong case that the 2NvS region also confers a yield advantage. The authors performed yield association analyses using yield data on lines from the Kansas State University wheat breeding program, the USDA Regional Performance Nursery —comprising lines from central US winter wheat breeding programs — and the CIMMYT spring bread wheat breeding program, and found a strong association between the presence of the segment and higher yield.
Global benefits
The yield and disease resistance associations of the 2NvS genetic segment have been helping farmers for years, as seen in the high proportion of the segment present in the improved wheat germplasm distributed globally through CIMMYT’s nurseries.
“The high frequency of the valuable 2NvS translocation in CIMMYT’s internationally distributed germplasm demonstrates well how CIMMYT has served as a key disseminator of lines with this translocation globally that would have likely contributed to a large impact on global wheat production,” said study co-author Juliana.
Through CIMMYT’s distribution efforts, it is likely that national breeding programs have also effectively used this translocation, in addition to releasing many 2NvS-carrying varieties selected directly from CIMMYT distributed nurseries.
With this study, we now know more about why the segment is so ubiquitous and have more tools at our disposal to use it more deliberately to raise yield and combat disease for wheat farmers into the future.
The food security and livelihoods of smallholder farming families in sub-Saharan Africa depend on maize production. The region accounts for up to two-thirds of global maize production, but is facing challenges related to extreme weather events, climate-induced stresses, pests and diseases, and deteriorating soil quality. These require swift interventions and innovations to safeguard maize yields and quality.
In this Q&A, we reflect on the results and impact of the long-term collaborative work on drought-tolerant maize innovations spearheaded by two CGIAR Research Centers: the International Maize and Wheat Improvement Center (CIMMYT) and International Institute of Tropical Agriculture (IITA). This innovative work has changed guises over the years, from the early work of the Drought Tolerant Maize for Africa (DTMA) and Drought Tolerant Maize for Africa Seed Scaling (DTMASS) projects through later iterations such as Stress Tolerant Maize for Africa (STMA) and the newest project, Accelerating Genetic Gains in Maize and Wheat (AGG).
In this Q&A, three leaders of this collaborative research reflect on the challenges their work has faced, the innovations and impact it has generated for smallholder farmers, and possible directions for future research. They are: B.M Prasanna, director of CIMMYT’s Global Maize Program and of the CGIAR Research Program on Maize (MAIZE); Abebe Menkir, a maize breeder and maize improvement lead at IITA; and Cosmos Magorokosho, project lead for AGG-Maize at CIMMYT.
Briefly describe the challenges confronting small-scale farmers prior to the introduction of drought-tolerant maize and how CIMMYT and IITA responded to these challenges?
B.M.P.: Maize is grown on over 38 million hectares in sub-Saharan Africa, accounting for 40% of cereal production in the region and providing at least 30% of the population’s total calorie intake. The crop is predominantly grown under rainfed conditions by resource-constrained smallholder farmers who often face erratic rainfall, poor soil fertility, increasing incidence of climatic extremes — especially drought and heat — and the threat of devastating diseases and insect pests.
Around 40% of maize-growing areas in sub-Saharan Africa face occasional drought stress with a yield loss of 10–25%. An additional 25% of the maize crop suffers frequent drought, with yield losses of up to 50%. Climate change is further exacerbating the situation, with devastating effects on the food security and livelihoods of the millions of smallholder farmers and their families who depend on maize in sub-Saharan Africa. Therefore, the improved maize varieties with drought tolerance, disease resistance and other farmer-preferred traits developed and deployed by CIMMYT and IITA over the last ten years in partnership with an array of national partners and seed companies across sub-Saharan Africa are critical in effectively tackling this major challenge.
A.M.: Consumption of maize as food varies considerably across sub-Saharan Africa, exceeding 100 kg per capita per year in many countries in southern Africa. In years when rainfall is adequate, virtually all maize consumed for food is grown in sub-Saharan Africa, with a minimal dependence on imported grain. Maize production, however, is highly variable from year to year due to the occurrence of drought and the dependence of national maize yields on seasonal rainfall. One consequence has been widespread famine occurring every five to ten years in sub-Saharan Africa, accompanied by large volumes of imported maize grain as food aid or direct imports.
This places a significant strain on resources of the World Food Programme and on national foreign exchange. It also disincentivizes local food production and may not prevent or address cyclical famine. It also leaves countries ill-equipped to address famine conditions in the period between the onset of the crisis and the arrival of food aid. Investment in local production, which would strengthen the resilience and self-sufficiency in food production of smallholder farming families, is a far better option to mitigate food shortages than relying on food aid and grain imports.
C.M.: Smallholder farmers in sub-Saharan Africa face innumerable natural and socioeconomic constraints. CIMMYT, in partnership with IITA and national agricultural research system partners, responded by developing and catalyzing the commercialization of new maize varieties that produce reasonable maize yields under unpredictable rainfall-dependent growing season.
Over the life of the partnership, more than 300 new climate-adaptive maize varieties were developed and released in more than 20 countries across sub-Saharan Africa where maize is a major staple food crop. Certified seed of over 100 stress-tolerant improved maize varieties have been produced by seed company partners, reaching more than 110,000 tons in 2019. The seeds of these drought-tolerant maize varieties have benefited more than 8 million households and were estimated to be grown on more than 5 million hectares in eastern, southern and west Africa in 2020.
In what ways did the drought-tolerant maize innovation transform small-scale farmers’ ability to respond to climate-induced risks? Are there any additional impacts on small scale farmers in addition to climate adaptation?
B.M.P.: The elite drought-tolerant maize varieties can not only provide increased yield in drought-stressed crop seasons, they also offer much needed yield stability. This means better performance than non-drought-tolerant varieties in both good years and bad years to a smallholder farmer.
Drought-tolerant maize varieties developed by CIMMYT and IITA demonstrate at least 25-30% grain yield advantage over non-drought-tolerant maize varieties in sub-Saharan Africa under drought stress at flowering. This translates into at least a 1 ton per hectare enhanced grain yield on average, as well as reduced downside risk in terms of lost income, food insecurity and other risks associated with crop yield variability. In addition to climate adaptation, smallholder farmers benefit from these varieties due to improved resistance to major diseases like maize lethal necrosis and parasitic weeds like Striga. We have also developed drought-tolerant maize varieties with enhanced protein quality — such as Quality Protein Maize or QPM — and provitamin A, which improve nutritional outcomes.
We must also note that drought risk in sub-Saharan Africa has multiple and far-reaching consequences. It reduces incentives for smallholder farmers to intensify maize-based systems and for commercial seed companies to invest and evolve due to a limited seed market.
Drought-tolerant maize is, therefore, a game changer as it reduces the downside risk for both farmers and seed companies and increases demand for improved maize seed, thus strengthening the commercial seed market in sub-Saharan Africa. Extensive public-private partnerships around drought-tolerant maize varieties supported the nascent seed sector in sub-Saharan Africa and has enabled maize-based seed companies to significantly grow over the last decade. Seed companies in turn are investing in marketing drought-tolerant maize varieties and taking the products to scale.
A.M.: The DTMA and STMA projects were jointly implemented by CIMMYT and IITA in partnership with diverse national and private sector partners in major maize producing countries in eastern, southern and western Africa to develop and deploy multiple stress-tolerant and productive maize varieties to help farmers adapt to recurrent droughts and other stresses including climate change.
These projects catalyzed the release and commercialization of numerous stress-resilient new maize varieties in target countries across Africa. Increasing the resilience of farming systems means that smallholder farmers need guaranteed access to good quality stress resilient maize seeds. To this end, the two projects worked with public and private sector partners to produce large quantities of certified seeds with a continual supply of breeder seeds from CIMMYT and IITA. The availability of considerable amount of certified seeds of resilient maize varieties has enabled partners to reach farmers producing maize under stressful conditions, thus contributing to the mitigation of food shortages that affect poor people the most in both rural and urban areas.
C.M.: The drought-tolerant maize innovation stabilized maize production under drought stress conditions in sub-Saharan Africa countries. Recent study results showed that households that grew drought-tolerant maize varieties had at least half a ton more maize harvest than the households that did not grow the drought-tolerant maize varieties, thus curbing food insecurity while simultaneously increasing farmers’ economic benefits. Besides the benefit from drought-tolerant innovation, the new maize varieties developed through the partnership also stabilized farmers’ yields under major diseases, Striga infestation, and poor soil fertility prevalent in sub-Saharan Africa.
How is the project addressing emerging challenges in breeding for drought-tolerant maize and what opportunities are available to address these challenges in the future?
B.M.P.: A strong pipeline of elite, multiple-stress-tolerant maize varieties — combining other relevant adaptive and farmer-preferred traits — has been built in sub-Saharan Africa through a strong germplasm base, partnerships with national research partners and small- and medium-sized seed companies, an extensive phenotyping and multi-location testing network, and engagement with farming communities through regional on-farm trials for the identification of relevant farmer-preferred products.
CGIAR maize breeding in sub-Saharan Africa continues to evolve in order to more effectively and efficiently create value for the farmers we serve. We are now intensively working on several areas: (a) increasing genetic gains (both on-station and on-farm) through maize breeding in the stress-prone environments of sub-Saharan Africa by optimizing our breeding pipelines and effectively integrating novel tools, technologies and strategies (e.g., doubled haploids, genomics-assisted breeding, high-throughput and precise phenotyping, improved breeding data management system, etc.); (b) targeted replacement of old or obsolete maize varieties in sub-Saharan Africa with climate-adaptive and new varieties; (c) developing next-generation climate-adaptive maize varieties with traits such as native genetic resistance to fall armyworm, and introgressed nutritional quality traits (e.g., provitamin A, high Zinc) to make a positive impact on the nutritional well-being of consumers; and (d) further strengthening the breeding capacity of national partners and small and medium-sized seed companies in sub-Saharan Africa for a sustainable way forward.
A.M.: The DTMA and STMA projects established effective product pipelines integrating cutting-edge phenotyping and molecular tools to develop stress-resilient maize varieties that are also resistant or tolerant to MLN disease and fall armyworm. These new varieties are awaiting release and commercialization. Increased investment in strengthening public and private sector partnerships is needed to speed up the uptake and commercialization of new multiple stress-resilient maize varieties that can replace the old ones in farmers’ fields and help achieve higher yield gains.
Farmers’ access to new multiple-stress-tolerant maize varieties will have a significant impact on productivity at the farm level. This will largely be due to new varieties’ improved response to fertilizer and favorable growing environments as well as their resilience to stressful production conditions. Studies show that the adoption of drought-tolerant maize varieties increased maize productivity, reduced exposure to farming risk among adopters and led to a decline in poverty among adopters. The availability of enough grain from highly productive and stress-resilient maize varieties can be the cheapest source of food and release land to expand the cultivation of other crops to facilitate increased access to diversified and healthy diets.
C.M.: The project is tackling emerging challenges posed by new diseases and pests by building upon the successful genetic base of drought-tolerant maize. This is being done by breeding new varieties that add tolerance to the emerging disease and pest challenges onto the existing drought-tolerant maize backgrounds. Successes have already been registered in breeding new varieties that have high levels of resistance to MLN disease and the fall armyworm pest.
Opportunities are also available to address new challenges including: pre-emptively breeding for threats to maize production challenges that exist in other regions of the world before these threats reach sub-Saharan Africa; enhancing the capacity of national partners to build strong breeding programs that can address new threats once they emerge in sub-Saharan Africa; and sharing knowledge and novel high-value breeding materials across different geographies to immediately address new threats once they emerge.
Cover photo: Alice Nasiyimu stands in front of a drought-tolerant maize plot at her family farm in Bungoma County, in western Kenya. (Photo: Joshua Masinde/CIMMYT)