funder_partner: CGIAR Research Program on Wheat (WHEAT)
Joining advanced science with field-level research and extension in lower- and middle-income countries, the CGIAR Research Program on Wheat (WHEAT) works with public and private organizations worldwide to raise the productivity, production and affordable availability of wheat for 2.5 billion resource-poor producers and consumers who depend on the crop as a staple food.
WHEAT is led by the International Maize and Wheat Improvement Center (CIMMYT), with the International Center for Agricultural Research in the Dry Areas (ICARDA) as a primary research partner.
Funding for WHEAT comes from CGIAR and national governments, foundations, development banks and other public and private agencies, in particular the Australian Centre for International Agricultural Research (ACIAR), the UK Department for International Development (DFID) and the United States Agency for International Development (USAID).
Wheat blast damages wheat spikes. (Photo: Xinyao He / CIMMYT)
In an article published in Nature Scientific Reports, a team of scientists led by wheat breeder Philomin Juliana from the International Wheat and Maize Improvement Center (CIMMYT) conducted a large genome-wide association study to look for genomic regions that could also be associated with resistance to wheat blast.
Juliana and fellow scientists found 36 significant markers on chromosome 2AS, 3BL, 4AL and 7BL that appeared to be consistently associated with blast resistance across different environments. Among these, 20 markers were found to be in the position of the 2NS translocation, a chromosomal segment transferred to wheat from a wild relative, Aegilops ventricosa, that has very strong and effective resistance to wheat blast.
The team also gained excellent insights into the blast resistance of the globally-distributed CIMMYT germplasm by genomic fingerprinting a panel over 4,000 wheat lines for the presence of the 2NS translocation, and found that it was present in 94.1% of lines from International Bread Wheat Screening Nurseries (IBWSNs) and 93.7% of lines from Semi-Arid Wheat Screening Nurseries (SAWSNs). Although it is reassuring that such a high percentage of CIMMYT wheat lines already have the 2NS translocation and implied blast resistance, finding other novel resistance genes will be instrumental in building widespread, global resilience to wheat blast outbreaks in the long-term.
The researchers used data collected over the last two years from CIMMYTâs IBWSNs and SAWSNs by collaborators at the Bangladesh Wheat and Maize Research Institute (BWMRI) and Bolivia’s Instituto Nacional de InnovaciĂłn Agropecuaria y Forestal (INIAF).
Devastating fungal disease
Wheat blast, caused by the fungus Magnaporthe oryzae pathotype Triticum, was first identified in 1985 in South America, but has been seen in Bangladesh in recent years. The expansion of the disease is a great concern for regions of similar environmental conditions in South Asia, and other regions globally.
Although management of the disease using fungicide is possible, it is not completely effective for multiple reasons, including inefficiency during high disease pressure, resistance of the fungal populations to some classes of fungicides, and the affordability of fungicide to resource-poor farmers. Scientists see the development and deployment of wheat with genetic resistance to blast as the most sustainable and farmer-friendly approach to preventing devastating outbreaks around the world.
This work was made possible by the generous support of the Delivering Genetic Gains in Wheat (DGGW) project funded by the Bill & Melinda Gates Foundation, the U.K. Foreign, Commonwealth & Development Office (FCDO) and managed by Cornell University, the U.S. Agency for International Developmentâs Feed the Future initiative, the CGIAR Research Program on Wheat (WHEAT), the Indian Council of Agricultural Research (ICAR), The Swedish Research Council (VetenskapsrĂ„d), and the Australian Centre for International Agricultural Research (ACIAR).
Seed banks may be another resource for securing Indigenous seed, although these banks have other missions as well. The International Maize and Wheat Improvement Center (CIMMYT), maintains seed banks and programs to preserve seeds native to specific regions. The group also leads the CGIAR Research Programs on Maize and Wheat and the Excellence in Breeding Platform to characterize genetic diversity so it can be used in conventional breeding programs to develop wheat and maize varieties that can address climate change, pest and disease resistance and yield to help manage food security.
âAbout 100 seed banks exist worldwide with seed used for cultural or heritage purposes and for production. CIMMYT has varieties that have been cultivated, conserved and cherished as grain and food crops for thousands of years,â says Tom Payne, head of the non-profit organizationâs wheat germplasm collections and International Wheat Improvement Network. âOur seed bank conserves varieties that can be a source for finding old genes that will solve new problems. We have to have that diversity to address changing production environments.â
Wheat blast, a fast-acting and devastating fungal disease, has been reported for the first time on the African continent. In an article published in the scientific journal PLoS One, a team of scientists confirmed that symptoms of wheat blast first appeared in Zambia during the 2018 rainy season, in experimental plots and small-scale farms in the Mpika district, Muchinga province.
Researchers from the International Maize and Wheat Improvement Center (CIMMYT), the US Department of Agriculture â Foreign Disease Weed Science Research Unit (USDA-ARS) and the Zambian Agricultural Research Institute (ZARI) participated in this study.
Wheat blast poses a serious threat to rain-fed wheat production in Zambia and raises the alarm for surrounding regions and countries on the African continent with similar environmental conditions. Worldwide, 2.5 billion consumers depend on wheat as a staple food and, in recent years, several African countries have been actively working towards reducing dependence on wheat imports.
âThis presents yet another challenging biotic constraint to rain-fed wheat production in Zambia,â said Batiseba Tembo, wheat breeder at ZARI and lead scientist on the study.
A difficult diagnosis
Researchers from ZARI check for wheat blast in experimental plots. (Photo: Batiseba Tembo/ZARI)
âThe first occurrence of the disease was very distressing. This happened at the spike stage, and caused significant losses,â Tembo said. âNothing of this nature has happened before in Zambia.â
Researchers were initially confused when symptoms of the disease were first reported in the fields of Mpika. Zambia has unique agro-climatic conditions, particularly in the rainfed wheat production system, and diseases such as spot blotch and Fusarium head blight are common.
âThe crop had silvery white spikes and a green canopy, resulting in shriveled grains or no grains at all⊠Within the span of seven days, a whole field can be attacked,â Tembo explained. Samples were collected and analyzed in the ZARI laboratory, and suspicions grew among researchers that this may be a new disease entirely.
Tembo participated in the Basic Wheat Improvement Course at CIMMYTâs global headquarters in Mexico, where she discussed the new disease with Pawan Singh, head of Wheat Pathology at CIMMYT. Singh worked with Tembo to provide guidance and the molecular markers needed for the sample analysis in Zambia, and coordinated the analysis of the wheat disease samples at the USDA-ARS facility in Fort Detrick, Maryland, United States.
All experiments confirmed the presence of the fungus Magnaporthe oryzae pathotype Triticum (MoT), which causes the disease.
âThis is a disaster which needs immediate attention,â Tembo said. âOtherwise, wheat blast has the potential to marginalize the growth of rain-fed wheat production in Zambia and may threaten wheat production in neighboring countries as well.â
Wheat blast spreads through infected seeds and crop residues, as well as by spores that can travel long distances in the air. The spread of blast within Zambia is indicated by both mechanisms of expansion.
Wheat blast has expanded rapidly since it was initially discovered in Brazil in 1985. (Map: Kai Sonder/CIMMYT)
A cause for innovation and collaboration
CIMMYT and the CGIAR Research Program on Wheat (WHEAT) are taking action on several fronts to combat wheat blast. Trainings and international courses invite participants to gain new technical skills and knowledge in blast diagnostics, treatment and mitigation strategies. WHEAT scientists and partners are also studying the genetic factors that increase resistance to the disease and developing early warning systems.
âA set of research outcomes, including the development of resistant varieties, identification of effective fungicides, agronomic measures, and new findings in the epidemiology of disease development will be helpful in mitigating wheat blast in Zambia,â Singh said.
âIt is imperative that the regional and global scientific communities join hands to determine effective measures to halt further spread of this worrisome disease in Zambia and beyond,â Tembo expressed.
Financial support for this research was provided by the Zambia Agriculture Research Institute (ZARI), the CGIAR Research Program on Wheat (WHEAT), the Australian Centre for International Agricultural Research (ACIAR), and the US Department of Agricultureâs Agricultural Research Service (USDA-ARS).Â
The Basic Wheat Training Program and Wheat Blast Training is made possible by support from investors including the Australian Centre for International Agricultural Research (ACIAR), WHEAT, the Indian Council of Agricultural Research (ICAR), Krishi Gobeshona Foundation (KGF), the Swedish Research Council (SRC) and the United States Agency for International Development (USAID).
The Accelerating Genetic Gains in Maize and Wheat (AGG) project is funded by the Bill & Melinda Gates Foundation, the UK Foreign, Commonwealth & Development Office, the United States Agency for International Development and the Foundation for Food and Agricultural Research (FFAR).
About CIMMYT
The International Maize and What Improvement Center (CIMMYT) is the global leader in publicly-funded maize and wheat research and related farming systems. Headquartered near Mexico City, CIMMYT works with hundreds of partners throughout the developing world to sustainably increase the productivity of maize and wheat cropping systems, thus improving global food security and reducing poverty. CIMMYT is a member of the CGIAR System and leads the CGIAR programs on Maize and Wheat and the Excellence in Breeding Platform. The Center receives support from national governments, foundations, development banks and other public and private agencies. For more information visit staging.cimmyt.org.
The CGIAR Research Program on Wheat (WHEAT) has âa track record of delivering local solutions with a global perspective â and is well positioned to continue this trajectory in the next decade.â
This was a key finding of a recent review of the program aimed to assess WHEATâs 2017-2019 delivery of quality science and effectiveness, as well as to provide insights and lessons to inform the programâs future.
âWheat as a crop is bound to be central to global food security in the foreseeable future,â the reviewers stated.
The crop currently contributes 20% of the world populationâs calories and protein â and global demand is estimated to increase by 44% between 2005-07 and 2050.
WHEAT â led by the International Maize and Wheat Improvement Center (CIMMYT) with the International Center for Agricultural Research in the Dry Areas (ICARDA) as a key research partner â has two pillars that are essential to meeting this demand: raising potential yield through breeding and closing the yield gap through sustainable intensification at field, farm and landscape scales.
Key recommendations included supporting strategic investment in research partner network development and maintenance and continuing WHEATâs trajectory towards modernizing breeding processes and integrating sustainable intensification approaches, including mechanization.
The reviewers warned of challenges for the way ahead, pointing out that partnerships â and WHEATâs reputation as a reliable partner â are vulnerable to funding volatility. The review also raised concerns about the potential fragmentation of the global breeding program, restrictions to the international exchange of germplasm and ideas, âmisguidedâ emphasis on minor crops, and CGIARâs âfocus on process at the expense of results.â
âThis review cuts to the core of whatâs so critical â and at risk â not only with our program but wheat research in general,â said Hans Braun, director of CIMMYT’s Global Wheat Program and the CGIAR Research Program on Wheat. âGlobal collaboration and the exchange of improved seeds, data, and especially information.â
âThe reviewers rightly point out that limited resources will lead to competition and dampen this collaboration â even between scientists in the same program. We must address this potential risk to improve integration and continue our life saving work,â Braun explained.
âIn most of the developing world, the alliance of public sector and CGIAR wheat breeding programs, as well as some national public breeding programs on their own, will remain dominant providers of wheat varieties, until either functioning seed royalty collection systems are established and/or hybrid wheat becomes a reality,â he said.
WHEATâs strength is its robust global network of research for development partners and scientists linked to global breeding in a âwide adaptationâ approach,â said Victor Kommerell, program manager for the CGIAR Research Programs on Maize and Wheat.
âThis review underscores that breaking up the breeding program could cause lasting damage to this network,â Kommerell said.
More key findings of the review include:
WHEAT is effective and well-managed: In 2017-2019, WHEAT mainly achieved its planned outputs and outcomes and in addition achieved unplanned outcomes. For the three years reviewed, WHEAT did not drop any research line.
WHEATâs strength is its partnerships: WHEAT has catalyzed a global network of research and development (R&D) that has delivered and continues to deliver a disproportionate wealth of outputs in relation to investment.
WHEAT creates, and thrives on, collaboration: The predominantly public nature of wheat R&D (In the period 1994-2014, the public sector accounted for 63% of global wheat varietal releases and more than 95% of releases in developing countries) favors collaboration, compared with other industries.
WHEAT facilitates shared success: The long history of collaboration between CIMMYT, ICARDA and national partners has fostered a sense of belonging to the International Wheat Improvement Network that permits free exchange of information and germplasm, allowing the best varieties to be released, irrespective of origin. International nursery testing delivers elite lines for national program use; data shared by national programs informs WHEATâs next crossing cycle.
The CGIAR Research Program on Wheat (WHEAT) is proud to release its 2019 Annual Report, celebrating shared achievements through partnerships around the world for the seventh year of the program.
In this yearâs report, we highlight cutting-edge work by researchers and partners â particularly our primary research partner, the International Center for Agricultural Research in the Dry Areas (ICARDA) â to help farmers grow wheat that is nutritious, resilient, and high-yielding, while decreasing environmental impact.
DNA fingerprinting, a smartphone-powered warning system, no-till innovations and the joint release of 50 new CGIAR-derived wheat varieties are just a few markers of success in a busy, challenging, and exciting year.
The threat of the current global pandemic highlights the crucial role wheat plays in the health and livelihoods of millions. We look forward to continued productive collaborations as we transition with our partners into an integrated, inclusive One CGIAR designed to meet the UN Sustainable Development Goals.
Researchers working on the Seeds of Discovery (SeeD) initiative, which aims to facilitate the effective use of genetic diversity of maize and wheat, have genetically characterized 79,191 samples of wheat from the germplasm banks of the International Maize and Wheat Improvement Center (CIMMYT) and the International Center for Agricultural Research in the Dry Areas (ICARDA).
Globally, the COVID-19 pandemic and associated lockdowns have created bottlenecks across the agricultural value chain, including disrupting the supply of fertilizer. This could negatively impact the already low yields in smallholders’ fields in the Global South. Livelihoods of these resource-poor farmers and food security of those they feed call for innovations or smarter application of existing knowledge to avoid increasing food insecurity.
In a recent study, a team of scientists from the International Maize and Wheat Improvement Center (CIMMYT) and Plant Production Systems, Wageningen University, found that there are clever ways to mix and match maize and wheat varieties with mineral fertilizers in tree-crop systems for greater nutrient use efficiency. The study explored the impact of different combinations of nitrogen (N) and phosphorus (P) fertilizers on crop yield in tree crop systems. It also identified mineral fertilizer-tree combinations that maximize agronomic nutrient use efficiencies under different contexts.
Tree-crop-fertilizer interactions for wheat growing under Faidherbia albida and maize growing under Acacia tortilis and Grevillea robusta through omission trials of N and P were explored in open fields and fields under tree canopy, using a split plot design. The experiments were conducted under different agroecologies in Ethiopia (Meki and Mojo) and Rwanda, where retaining scattered trees in fields has been practiced for centuries. The trials were replicated four times and over two seasons. Trees with approximately similar ages, crown structures and pruning history were used for a researcher-led and farmer-managed on-farm experiment.
The results demonstrated that different on-farm tree species interact uniquely with crops, resulting in different responses to N and P fertilization. Except for F. albida, perhaps the most ‘ideal’ agroforestry species, the other two tree species under the current study raised the question of tree-crop compatibility for optimum productivity. F. albida significantly improved N and P use efficiencies, leading to significantly higher grain yields in wheat. The P use efficiency of wheat under F.albida was double that of wheat grown in an open field. By contrast, G. robusta and A. tortilis trees lowered nutrient use efficiencies in maize, leading to significantly less maize grain yields compared with open fields receiving the same fertilization. The case study also identified probabilities of critically low crop yields and crop failure to be significantly greater for maize growing under the canopy of these species.
A tree-crop system in Ethiopia. (Photo: Tesfaye Shiferaw /CIMMYT)
In conclusion, the study demonstrated that tree-crop interactions are mediated by the application of N and P fertilizers in tree-crop systems. In F. albida-wheat agroforestry systems, N fertilizers could be saved, with localized application of P fertilizers close to tree crowns. Such adaptable application may help smallholder farmers cope with COVID-19-imposed fertilizer limitations. In G.robusta-maize and A.tortilis-maize agroforestry systems, maize did not respond to N and P fertilizers applied at recommended rates, although the application of these nutrients compensated for competition. This implies mineral fertilizers can offset the effect of competition, while they fail to provide the yield advantages like mono-cropping situations.
The researchers underlined the fact that fertilizer recommendations need to be adapted to agroforestry systems. However, in order to quantify the exact magnitude and nature of fertilizer-tree interaction in agroforestry systems accurately, factorial application of higher and lower rates of mineral fertilizer is needed. They also called for further research to identify fertilization rates that minimize tree-crop competition for G. robusta-maize and A. tortilis-maize systems, while additional studies are needed to identify the rates and timing of application that optimize F. albida-wheat facilitation.
This work was carried out by the International Maize and Wheat Improvement Center (CIMMYT) and Plant Production Systems, Wageningen University
A new study analyzing the diversity of almost 80,000 wheat accessions reveals consequences and opportunities of selection footprints. (Photo: Keith Ewing)
Researchers working on the Seeds of Discovery (SeeD) initiative, which aims to facilitate the effective use of genetic diversity of maize and wheat, have genetically characterized 79,191 samples of wheat from the germplasm banks of the International Maize and Wheat Improvement Center (CIMMYT) and the International Center for Agricultural Research in the Dry Areas (ICARDA).
The findings of the study published today in Nature Communications are described as âa massive-scale genotyping and diversity analysisâ of the two types of wheat grown globally â bread and pasta wheat â and of 27 known wild species.
Wheat is the most widely grown crop globally, with an annual production exceeding 600 million tons. Approximately 95% of the grain produced corresponds to bread wheat and the remaining 5% to durum or pasta wheat.
The main objective of the study was to characterize the genetic diversity of CIMMYT and ICARDAâs internationally available collections, which are considered the largest in the world. The researchers aimed to understand this diversity by mapping genetic variants to identify useful genes for wheat breeding.
From germplasm bank to breadbasket
The results show distinct biological groupings within bread wheats and suggest that a large proportion of the genetic diversity present in landraces has not been used to develop new high-yielding, resilient and nutritious varieties.
âThe analysis of the bread wheat accessions reveals that relatively little of the diversity available in the landraces has been used in modern breeding, and this offers an opportunity to find untapped valuable variation for the development of new varieties from these landracesâ, said Carolina Sansaloni, high-throughput genotyping and sequencing specialist at CIMMYT, who led the research team.
The study also found that the genetic diversity of pasta wheat is better represented in the modern varieties, with the exception of a subgroup of samples from Ethiopia.
The researchers mapped the genomic data obtained from the genotyping of the wheat samples to pinpoint the physical and genetic positions of molecular markers associated with characteristics that are present in both types of wheat and in the cropâs wild relatives.
According to Sansaloni, on average, 72% of the markers obtained are uniquely placed on three molecular reference maps and around half of these are in interesting regions with genes that control specific characteristics of value to breeders, farmers and consumers, such as heat and drought tolerance, yield potential and protein content.
Open access
The data, analysis and visualization tools of the study are freely available to the scientific community for advancing wheat research and breeding worldwide.
âThese resources should be useful in gene discovery, cloning, marker development, genomic prediction or selection, marker-assisted selection, genome wide association studies and other applications,â Sansaloni said.
The study was part of the SeeD and MasAgro projects and the CGIAR Research Program on Wheat (WHEAT), with the support of Mexico’s Secretariat of Agriculture and Rural Development (SADER), the United Kingdomâs Biotechnology and Biological Sciences Research Council (BBSRC), and CGIAR Trust Fund Contributors. Research and analysis was conducted in collaboration with the National Institute of Agricultural Botany (NIAB) and the James Hutton Institute (JHI).
About CIMMYT:
The International Maize and What Improvement Center (CIMMYT) is the global leader in publicly-funded maize and wheat research and related farming systems. Headquartered near Mexico City, CIMMYT works with hundreds of partners throughout the developing world to sustainably increase the productivity of maize and wheat cropping systems, thus improving global food security and reducing poverty. CIMMYT is a member of the CGIAR System and leads the CGIAR programs on Maize and Wheat and the Excellence in Breeding Platform. The Center receives support from national governments, foundations, development banks and other public and private agencies. For more information visit staging.cimmyt.org.
Alison Bentley (right) and Martin Jones inspect wheat in a glasshouse. (Photo: Toby Smith/Gloknos)
In November 2020, Alison Bentley will be joining the International Maize and Wheat Improvement Center (CIMMYT) as the new program director of the Global Wheat Program. She will be succeeding Hans Braun, who has steered the program for the last 16 years.
Bentley is thrilled to join CIMMYT and excited about the opportunity to harness science and breeding to improve livelihoods. She believes in a collective vision for equitable food supply and in science-led solutions to deliver impact.
âIt really is an exciting time for wheat research: the international community has worked together to produce sequence and genomic resources, new biological and physiological insights, a wealth of germplasm and tools for accelerating breeding. This provides an unparalleled foundation for accelerating genetic gains and connecting ideas to determine how we can practically apply these tools and technologies with partners to deliver value-added outputs,â she said.
Bentley has worked on wheat â wheat genetics, wheat genetic resources and wheat pre-breeding â her entire career. She is the UKâs representative on the International Wheat Initiative Scientific Committee, and is a committee member for the Genetics Society, the UK Plant Sciences Federation, the Society of Experimental Botany, and the Editorial Board of Heredity.
Bentley obtained her PhD from the University of Sydney, Australia, in 2007. She then joined the National Institute of Agricultural Botany (NIAB) in the UK, where she progressed from Senior Research Scientist (2007) to Program Leader for Trait Genetics (2013), and Director of Genetics and Breeding (since 2016).
Currently, Bentley is involved in international research projects in Ethiopia, The Gambia, Ghana, India and Pakistan. She leads a number of UK-India projects with partners including Punjab Agricultural University, the Indian National Institute of Plant Genome Research and the University of Cambridge, studying variation and developing wheat and other cereal germplasm with enhanced resource use efficiency.
âWe have demonstrated that small-scale mechanization is a pathway to sustainable intensification and rural transformation, and can have positive gender outcomes as well,â he explained.
Here are some of the key lessons learned along the way, according to the people involved.
1. Appropriate mechanization is essential
With many farms in Africa measuring no more than two hectares, FACASI focused on bringing two-wheel tractors to regions where smallholdings dominate, especially in Zimbabwe and Ethiopia. For most small farmers, conventional farm machinery is out of reach due to its size, costs, and the skills needed to operate it. The typical path to mechanization would be for farmers to consolidate their farms, which could lead to social and environmental upheaval. Instead, the FACASI team scaled-down the equipment to suit the local context.
FACASI has obtained evidence to dispel commonly held myths about farm power in smallholder farming systems,â said Eric Huttner, research program manager for crops at the Australian Centre for International Agricultural Research (ACIAR).
2. Test, develop and adapt technologies⊠togetherÂ
âWe gained many valuable insights by continuously refining technologies in the context of efficiency, farmer preference and needs,â said Bisrat Getnet, FACASI national project coordinator in Ethiopia, and director of the Agricultural Engineering Research Department in the Ethiopian Institute of Agricultural Research (EIAR).
Jane Mautsa and her husband operating the sheller. (Photo: Shiela Chikulo/CIMMYT)
3. Make it usefulÂ
The basic two-wheel tractor is a highly flexible and adaptable technology, which can be used to mechanize a range of on-farm tasks throughout the seasons. With the right attachments, the tractor makes short work of sowing, weeding, harvesting, shelling, water pumping, threshing and transportation.
âThis multi-functional feature helps to ensure the tractor is useful at all stages of the annual farming cycle, and helps make it profitable, offsetting costs,â said Raymond Nazare, FACASI national project coordinator in Zimbabwe and lecturer at the Soil and Engineering Department of the University of Zimbabwe.
4. Less pain, more profit
Reducing the unnecessary drudgery of smallholder farming can be financially rewarding and open new doors. Mechanization can save farmers the costs of hiring additional labor, and vastly reduce the time and effort of many post-harvest tasks â often done by women â such as transport, shelling and grinding. FACASI researchers demonstrated the potential for mechanization to reduce this onerous labor, allowing women to channel their time and energy into other activities.
âThe project demonstrated that small mechanization can create profitable employment,â said Tirivangani Koza, of Zimbabweâs Ministry of Lands, Agriculture, Water and Rural Resettlement.
âWomen and youth are using small mechanization to grow profitable businesses,â said Alice Woodhead in Australia.
âThey have advanced from dependent family members to financially independent entrepreneurs. Their new skills, such as servicing the tractors, marketing and shelling, have increased their familyâs income. FACASI has also inspired community members to launch aligned businesses such as shelling services, inventing new two-wheel tractor implements for the growing customer base, or becoming artisan mechanics. In some districts, the two-wheel tractors are starting to create a cycle of innovation, business development, food diversification and sustainable economic growth,â she said.
6. Respond to farmer demands
Although the FACASI team set out to promote mechanization as a way to help farmers take up conservation agriculture techniques such as direct seeding, they opened the Pandoraâs box for other beneficial uses. By the projectâs end, it was clear that transport and mechanization of post-harvest tasks like shelling and threshing, had become far more popular among farmers than mechanization of crop production. This result is a sign of the teamâs success in demonstrating the value of small-scale mechanization, and adapting technologies to respond to farmersâ needs.
7. Embrace new research models
Agricultural research for development has long forgotten about labour and mechanization issues; the FACASI team helped put these front and center by involving engineers, business enterprises, agriculturalists, and partners from across the supply chain.
âFACASI demonstrates an important change in how to do agricultural research to achieve meaningful impacts,â Woodhead said.
âRather than focus only on the farm environment and on extension services, they worked from the outset with partners across the food, agriculture and manufacturing sectors, as well as with the public institutions that can sustain long-term change. The projectâs results are exciting because they indicate that sustainable growth can be achieved by aligning conservation agriculture goals, institutions and a communityâs business value propositions,â she explained.
Whatâs next?
Demonstration of a minitiller, Naivasha, Kenya. (Photo: Matt O’ Leary/CIMMYT)
Although the project has ended, its insights and lessons will carry on.
âWe now need to move from piloting to scaling. This does not mean leaving all the work to development partners; research still has a big role to play in generating evidence and making sure this knowledge can be used by local manufacturers, engineers, local dealers and financial institutions,â he said.
As an international research organization, CIMMYT is strategically placed to provide critical answers to farming communities and the diversity of actors in the mechanization value chain.
âACIAR provided us generous and visionary support, at a time when very few resources were going to mechanization research in Africa,â Baudron acknowledged. âThis allowed CIMMYT and its partners from the national research system and the private sector to develop unique expertise on scale-appropriate mechanization. The legacy of FACASI will be long-lived in the region,â he concluded.
June marks the start of the rice growing season in Indiaâs breadbasket but on the quiet fields of Haryana and Punjab you wouldnât know it.
Usually the northwestern Indian states are teeming with migrant laborers working to transplant rice paddies. However, the governmentâs swift COVID-19 lockdown measures in late March triggered reverse migration, with an estimated 1 million laborers returning to their home states.
The lack of migrant workers has raised alarms for the labor-dependent rice-wheat farms that feed the nation. Healthy harvests are driven by timely transplanting of rice and, consequently, by the timely sowing of the succeeding wheat crop in rotation.
Without political support for alternative farming practices, crop losses from COVID-19 labor disruptions could reach $1.5 billion and significantly diminish the country’s grain reserves, researchers from the International Maize and Wheat Improvement Center (CIMMYT) warned.
Researchers also fear delayed rice transplanting could encourage unsustainable residue burning as farmers rush to clear land in the short window between rice harvest and wheat sowing. Increased burning in the fall will exacerbate the COVID-19 health risk by contributing to the blanket of thick air pollution that covers much of northwest India, including the densely populated capital region of New Delhi.
The burning of crop residue, or stubble, across millions of hectares of cropland between planting seasons is a visible contributor to air pollution in both rural and urban areas. (Photo: Dakshinamurthy Vedachalam/CIMMYT)
Both farmers and politicians are showing increased interest in farm mechanization and crop diversification as they respond to COVID-19 disruptions, said M.L. Jat, a CIMMYT scientist who coordinates sustainable intensification programs in northwestern India.
âFarmers know the time of planting wheat is extremely important for productivity. To avoid production losses and smog-inducing residue burning, alternative farm practices and technologies must be scaled up now,â Jat said.
The time it takes to manually transplant rice paddies is a particular worry. Manual transplanting accounts for 95% of rice grown in the northwestern regions. Rice seedlings grown in a nursery are pulled and transplanted into puddled and leveled fields â a process that takes up to 30 person-days per hectare, making it highly dependent on the availability of migrant laborers.
Even before COVID-19, a lack of labor was costing rice-wheat productivity and encouraging burning practices that contribute to Indiaâs air pollution crisis, said CIMMYT scientist Balwinder Singh.
âMechanized sowing and harvesting has been growing in recent years. The COVID-19 labor shortage presents a unique opportunity for policymakers to prioritize productive and environmentally-friendly farming practices as long term solutions,â Singh said.
Sustainable practices to cope with labor bottlenecks
CIMMYT researchers are working with national and state governments to get information and technologies to farmers, however, there are significant challenges to bringing solutions to scale in the very near term, Singh explained.
There is no silver bullet in the short term. However, researchers have outlined immediate and mid-term strategies to ensure crop productivity while avoiding residue burning:
Delayed or staggered nursery sowing of rice:Â By delaying nursery sowing to match delays in transplanting, yield potential can be conserved for rice. Any delay in transplanting rice due to labor shortage can reduce the productivity of seedlings. Seedling age at transplanting is an important factor for optimum growth and yield.
âMatching nursery sowing to meet delayed transplanting dates is an immediate action that farmers can take to ensure crop productivity in the short term. However, itâs important policymakers prioritize technologies, such as direct seeders, that contribute to long term solutions,â Singh said.
Direct drilling of wheat using the Happy Seeder: Direct seeding of wheat into rice residues using the Happy Seeder, a mechanized harvesting combine, can reduce the turnaround time between rice harvest and wheat sowing, potentially eliminating the temptation to burn residues.
âIdentifying the areas with delayed transplanting well in advance should be a priority for effectively targeting the direct drilling of wheat using Happy Seeders,â said Jat. The average farmer who uses the Happy Seeder can generate up to 20% more profits than those who burn their fields, he explained. âIncentivizing farmers through a direct benefit transfer payment to adopt âno burnâ practices may help accelerate transitions.â
Directly sown rice: Timely planting of rice can also be achieved by adopting dry direct seeding of rice using mechanized seed-cum-fertilizer planters. In addition to reducing the labor requirement for crop establishment, dry direct seeding allows earlier rice planting due to its lower water requirement for establishment. Direct-seeded rice also matures earlier than puddled transplanted rice. Thus, earlier harvesting improves the chance to sow wheat on time.
âCIMMYT researchers are working with the local mechanical engineers on rolling out simple tweaks to enable the Happy Seeder to be used for direct rice seeding. The existing availability of Happy Seeders in the region will improve the speed direct rice sowing can be adopted,â Jat said.
Crop diversification with maize: Replacing rice with maize in the monsoon season is another option to alleviate the potential shortage of agricultural labor due to COVID-19, as the practice of establishing maize by machine is already common.
âResearch evidence generated over the past decade demonstrates that maize along with modern agronomic management practices can provide a profitable and sustainable alternative to rice,â Jat explained. âThe diversification of rice with maize can potentially contribute to sustainability that includes conserving groundwater, improving soil health and reducing air pollution through eliminating residue burning.â
A combine harvester equipped with the Super SMS (left) harvests rice while a tractor equipped with the Happy Seeder is used for direct seeding of wheat. (Photo: Sonalika Tractors)
Getting innovations into farmersâ fields
Rapid policy decisions by national and state governments on facilitating more mechanized operations in labor-intensive rice-wheat production regions will address labor availability issues while contributing to productivity enhancement of succeeding wheat crop in rotation, as well as overall system sustainability, said ICARâs deputy director general for agricultural extension, AK Singh.
The government is providing advisories to farmers through multiple levels of communications, including extension services, messaging services and farmer collectives to raise awareness and encourage adoption.
Moving toward mechanization and crop diversity should not be viewed as a quick fix to COVID-19 related labor shortages, but as the foundation for long-term policies that help India in achieving the UN Sustainable Development Goals, said ICARâs deputy director general for Natural Research Management, SK Chaudhari.
âPolicies encouraging farming practices that save resources and protect the environment will improve long term productivity of the nation,â he said.
Northwestern India is home to millions of smallholder farmers making it a breadbasket for grain staples. Since giving birth to the Green Revolution, the region has continued to increase its food production through rice and wheat farming providing bulk of food to the country.
This high production has not come without shortfalls, different problems like a lowering water table, scarcity of labor during peak periods, deteriorating soil health, and air pollution from crop residue burning demands some alternative methods to sustain productivity as well as natural resources.
Cover photo:Â A farmer uses a tractor fitted with a Happy Seeder. (Photo: Dakshinamurthy Vedachalam/CIMMYT)
In 2019, CIMMYT continued to perform groundbreaking crop research and forge powerful partnerships to combat hunger and climate change, preserve maize and wheat biodiversity, and respond to emerging pests and diseases. Â
Bill Gates spoke about the âessential role of CGIAR research centers in feeding our futureâ and together with other stakeholders urged us to âdo even better.â In his Gates Notes blog, he highlighted the great example of CIMMYTâs drought-tolerant maize, which helps resource-poor farmers withstand increasing climate risks.Â
Over the course of the year, we supported our national partners to release 82 maize and 50 wheat varieties. More than 14,000 farmers, scientists, and technical workers across the world took part in over 900 training and capacity development activities. CIMMYT researchers published 386 peer-reviewed journal articles.Â
In 2019, CIMMYT also marked the end of a decade of achievements in seed security. CIMMYT celebrated being the largest depositor at the Svalbard Global Seed Vault with 173,779 accessions from 131 countries. The most recent deposit included 15,231 samples of wheat and 332 samples of maize.Â
Innovative solutions like DNA fingerprinting â a method used to identify individual plants by looking at unique patterns in their genome â brought state of the art research into farmerâs fields, providing valuable insights into the diversity of wheat varieties grown in Afghanistan and Ethiopia.  Â
CIMMYT also continued to play a key role in the battle against fall armyworm, coordinating a global research-for–development consortium to build an evidence-based response against the pest in both Africa and Asia.Â
Through the Cereal Systems Initiative for South Asia (CSISA), CIMMYT helped women find business opportunities and empowered female entrepreneurship with the help of mechanization solutions.Â
The year 2019 showed us that while CIMMYTâs work may begin with seeds, our innovations support farmers at all stages of the value chain. The year ahead will be a challenging one as we continue to adjust to the ânew normalâ of life under COVID-19. We hope you enjoy this Annual Report as we look back on the exciting year that was 2019.  Â
Smallholder farmers in Zimbabwe and Ethiopia have embraced small-scale mechanization thanks to an innovative CIMMYT-led project, which is now drawing to a close. Since 2013, the Farm Mechanization and Conservation Agriculture for Sustainable Intensification (FACASI) project has helped farmers access and use two-wheel tractors that significantly reduce the time and labor needed to grow, harvest and process their crops. To ensure long-term sustainability, the project and its partners helped support and develop local enterprises which could supply, service and operate the machines, and encouraged the development of supportive government policies. The project was funded by the Australian Centre for International Agricultural Research (ACIAR), as well as the CGIAR Research Programs on Maize and Wheat.
âMechanization is a system not a technologyâ
From its inception, FACASI went beyond simply providing machinery to farmers, and instead envisioned mechanization as a way out of poverty. âMechanization is a system, not only a technology,â said Bisrat Getnet, the projectâs national coordinator in Ethiopia and director of the Agricultural Engineering Research Department at the Ethiopian Institute of Agricultural Research. âMechanization needs infrastructure such as roads, fuel stations, spare part dealerships, maintenance centers, training centers and appropriate policies. This project assessed which measures are needed to sustain a new technology and addressed these with direct interventions,â he explained.
The FACASI project worked to introduce and develop new small-scale machines, including two-wheel tractors, small shellers and threshers, and small pumps, in African rural settings, collaborating with local engineers, farmers and manufacturers. This included adapting a range of attachments that could be used to mechanize on-farm tasks such as planting, harvesting, transporting and shelling. In parallel, the project developed local business opportunities around the supply, maintenance and use of the machines, to ensure that users could access affordable services and equipment in their communities.
The project initially worked in four countries: Ethiopia, Kenya, Tanzania and Zimbabwe. Researchers saw significant potential for mechanization to reduce the labor intensity associated with smallholder farming, while encouraging application of conservation agriculture techniques and developing rural service provision businesses. In its second phase, which began in 2017, the project focused on strengthening its efforts in Zimbabwe and Ethiopia.
âIn my view the most innovative aspect enabling FACASIâs success was the concept of combining engineering and business modelling, with an understanding of the political, legislative and policy situations in the four countries,â said Professor John Blackwell, an Adjunct Professor at Charles Sturt University who reviewed FACASI and also invented and helped commercialize several successful machines in South Asia, including the famous Happy Seeder.
Conservation agriculture planter manufacturing in Arusha, Tanzania. (Photo: CIMMYT)
Benefits to local communities
During its course, the project improved the efficiency and productivity of smallholder farming, reducing labor requirements and creating new pathways for rural women and youth.
The reduction in the labor and drudgery of farming tasks has opened many doors. Farmers can save the costs of hiring additional labor and reinvest that money into their enterprises or households. With a small double-cob sheller producing one ton of kernels in an hour compared to up to 12 days by hand, women can do something else valuable with their time and energy. Entrepreneurs offering mechanization services â often young people who embrace new technologies â can earn a good income while boosting the productivity of local farms.
Mechanization has shown to sustainably improve yields. In Ethiopia, farmers using two-wheel tractors were able to reduce the time needed to establish a wheat crop from about 100 hours per hectare to fewer than 10 hours. In trials, maize and wheat respectively yielded 29% and 22% more on average, compared with using conventional crop establishment methods.
Local female artisan, Hawassa, Ethiopia. (Photo: CIMMYT)
Impacts now and into the future
According to its national partners, FACASI has laid the groundwork for cheap and practical two-wheel tractors to proliferate. In Ethiopia, there are currently 88 service providers whose skills has been directly developed through FACASI project interventions. âThis has been a flagship project,â said Ethiopia national coordinator Bisrat Getnet. âIt tested and validated the potential for small-scale mechanization and conservation agriculture, it proved that new business models could be profitable, and it opened new pathways for Ethiopian agriculture policy,â he said.
In Zimbabwe, the project has also set the wheels of change in motion. âFACASI demonstrated an opportunity for creating employment and business opportunities through small-scale mechanization,â said Tirivangani Koza, of Zimbabweâs Ministry of Lands, Agriculture, Water and Rural Resettlement. âWith the right funding and policies, there is a very wide and promising scope to scale-up this initiative,â he said.
Using data from 12 communities across four Indian states, an international team of researchers has shed new light on how women are gradually innovating and influencing decision-making in wheat-based systems.
The study, published this month in The European Journal of Development Research, challenges stereotypes of men being the sole decision-makers in wheat-based systems and performing all the work. The authors, which include researchers from the CGIAR Research Program on Wheat (WHEAT)-funded GENNOVATE initiative, show that women adopt specific strategies to further their interests in the context of wheat-based livelihoods.
In parts of India, agriculture has become increasingly feminized in response to rising migration of men from rural areas to cities. An increasing proportion of women, relative to men, are working in the fields. However, little is known about whether these women are actually taking key decisions.
The authors distinguish between high gender gap communities â identified as economically vibrant and highly male-dominant â and low gender gap communities, which are also economically vibrant but where women have a stronger say and more room to maneuver.
The study highlights six strategies women adopt to participate actively in decision-making. These range from less openly challenging strategies that the authors term acquiescence, murmuring, and quiet co-performance (typical of high gender gap communities), to more assertive ones like active consultation, women managing, and finally, women deciding (low gender gap communities).
In acquiescence, for example, women are fully conscious that men do not expect them to take part in agricultural decision-making, but do not articulate any overt forms of resistance.
In quiet co-performance, some middle-income women in high gender gap communities begin to quietly support men’s ability to innovate, for example by helping to finance the innovation, and through carefully nuanced ‘suggestions’ or âadvice.’ They donât openly question that men take decisions in wheat production. Rather, they appear to use male agency to support their personal and household level goals.
In the final strategy, women take all decisions in relation to farming and innovation. Their husbands recognize this process is happening and support it.
A wheat farmer in India. (Photo: J. Cumes/CIMMYT)
âOne important factor in stronger womenâs decision-making capacity is male outmigration. This is a reality in several of the low gender gap villages studiedâand it is a reality in many other communities in India. Another is educationâmany women and their daughters talked about how empowering this is,â said gender researcher and lead-author Cathy Farnworth.
In some communities, the study shows, women and men are adapting by promoting womenâs âmanagerialâ decision-making. However, the study also shows that in most locations the extension services have failed to recognize the new reality of male absence and women decision-makers. This seriously hampers women, and is restricting agricultural progress.
Progressive village heads are critical to progress, too. In some communities, they are inclusive of women but in others, they marginalize women. Input suppliers â including machinery providers â also have a vested interest in supporting women farm managers. Unsurprisingly, without the support of extension services, village heads, and other important local actors, womenâs ability to take effective decisions is reduced.
âThe co-authors, partners at Glasgow Caledonian University and in India, were very important to both obtaining the fieldwork data, and the development of the typologyâ said Lone Badstue, researcher at the International Maize and Wheat Improvement Center (CIMMYT) and another co-author of the paper.
The new typology will allow researchers and development partners to better understand empowerment dynamics and womenâs agency in agriculture. The authors argue that development partners should support these strategies but must ultimately leave them in the hands of women themselves to manage.
âItâs an exciting study because the typology can be used by anyone to distinguish between the ways women (and men) express their ideas and get to where they wantâ, concluded Farnworth.
The COVID-19 pandemic continues to transform the way the world operates, and agricultural production systems are not exempt.
Even in countries that have identified the agricultural sector as an essential one, ongoing restrictions on transport and freedom of movement are causing disruptions across the value chain â with potentially devastating impact on already fragile food systems in Latin America, sub-Saharan Africa and South Asia.
With this in mind, systems agronomists and mechanization specialists at the International Maize and Wheat Improvement Center (CIMMYT), discuss the impact of restrictions on agricultural labor and production, and the role farm mechanization can play in addressing new challenges.
What are the implications of the agricultural labor shortages that are emerging in Africa and Latin America as a result of COVID-19 restrictions?
A woman demonstrates the use of a mini-tiller in Naivasha, Kenya. (Photo: Matt OâLeary/CIMMYT)
Africa is often presented as being dominated by farms which rely mainly on the labor of family members. Therefore, one could expect that Africa would be spared from the consequences of unavailability and/or unaffordability of hired labor. However, a recent CIMMYT study shows that farming systems in Africa are far more dependent on hired labor than commonly thought, and that the quasi total dependence of smallholder farming on family labor is a myth. Depending on the farming system, a complete loss of hired labor could lead to a productivity decrease of up to 20% in Eastern and Southern Africa. Hired labor is also likely to be replaced by child labor.
Because most production on the continent is rainfed during a single season, most farmers only plant and harvest once per year, making the timing of each task critical. A delay in planting because of labor shortages â as will soon occur Ethiopia â could lead to dramatically reduced yields. A delay in harvesting â as is currently experienced in Zimbabwe â means a large fraction of the crop is likely to be spoilt in the field.
Jelle Van Loon: The situation is similar for Mexico and the general Central American corridor, although the main production cycle is only just starting. Proper land preparation and timely sowing are critical, not only in terms of food production and achieving proper yields, but also to ensure that farmers have a stable income at the end of the year. This is especially important now, as financial and food reserves are shrinking at a faster pace due to COVID-19 restrictions that heavily affect demand on informal markets.
An operator demonstrates the use of a reaper in Bangladesh. (Photo: CIMMYT)
Are you seeing a similar situation in South Asia?
Timothy Krupnik: Depending on the country, weâve seen either abrupt interruptions in the movement of agricultural laborers â for example in India where millions of migrant laborers have not been able to travel home during lockdown â or an influx of people from urban areas who fled to their villages when lockdown began.
In the latter case, one might expect this to increase labor availability for farming, but we tended to observe the reverse. People remain largely frightened of coming out of their homes, so even in rural areas which saw an influx of people, labor availability has not necessarily increased. Where laborers are willing to work, our initial scan of the evidence indicates that daily wage labor costs have also increased considerably due to risks of infection spreading. In either situation, smallholder farmers who need to hire labor to assure crucial crop management activities like planting or harvesting are suffering. There are reports emerging also of increased child labor in the region as schools are closed and resource-poor farmers are allocating family members and children to work where they canât afford to hire labor.
M.L. Jat: I would like to cite the specific example of intensive rice-wheat rotation in Indiaâs breadbasket and the Green Revolution corridors in the western Indo-Gangetic plains, which provide the bulk of cereals to the national food basket. An ex-ante analysis on the consequences of the reverse migration of the agricultural workforce and social distancing due to COVID-19 revealed that a delay in the transplanting of rice seedlings by two weeks is likely, which will delay rice harvesting and consequently delay the planting of wheat. This will potentially lead to rice and wheat production losses of 10-25%, worth up to $1.5 billion.
In addition, the shorter turn around between harvesting rice and planting wheat may further increase the incidence of rice residue burning. This is a major problem which creates significant health issues and may exacerbate the threat of COVID-19 by increasing both infection rates and disease severity.
Krupnik: The situation has increased interest and policy to support use of scale-appropriate machinery for operations like harvesting. In Bangladesh, for example, there was a recent and very serious risk of losing much of the rice harvest as the monsoon has started early and flash flooding has been a concern. Without manual laborers to harvest the crop, CIMMYT-led projects like the Cereal Systems Initiative for South Asia â Mechanization and Extension Activity (CSISA-MEA) have played a key role in assisting the movement of combine harvesters and crop reapers to areas at risk of crop losses and helping to assure the rice crop is harvested on time.
An operator demonstrates the use of a starwheel planter in Zimbabwe. (Photo: Frederic Baudron/CIMMYT)
It sounds like these machines were instrumental in avoiding crop losses. Does this mean that mechanization has a key role to play in lessening the impact of these labor shortages?
Krupnik: During the COVID-19 crisis, scale-appropriate machinery has become even more important for mitigating labor shortages. We work to facilitate the availability of scale-appropriate machinery not only so that farmers can buy and use equipment, but also by encouraging those who own machineries to become entrepreneurial service providers who offer efficient and mechanized land preparation, planting, irrigation, harvesting and post-harvesting to other farmers on an affordable fee-for-service basis.
This is a win-win situation for farmers who canât access or afford the escalating costs of labor. In the COVID-19 crisis, these arrangements assist in responding to the labor crunch in locations where resource-poor farmers are most in need, and also allow farmers to get crucial work done while maintaining and encouraging social distancing.
Baudron: Over the past seven years, CIMMYT and its partners have fine-tuned technologies and developed delivery models â based on rural service providers supported by private sector companies â to scale the use of small machines in East and Southern Africa. These are profitable for both farmers and service providers and reduce labor requirements tremendously.
In Zimbabwe, we found that labor requirements were 15 times lower when establishing a maize field with a direct seeder pulled by a two-wheel tractor, and 23 times lower using a similar technology for establishing wheat in Rwanda, compared to the conventional method based on labor and draft power. A ton of maize that would take 12 people a full day to shell manually, can be shelled in one hour using a small double-cob sheller that costs about $300.
Jat: Rapid policy decisions by sub-national and national governments on facilitating more mechanized operations in labor intensive rice-wheat production regions will address labor availability issues while contributing to productivity enhancement of succeeding wheat crop in rotation, as well as overall system sustainability. Our ex-ante analysis on the implications of labor shortages in rice-wheat rotation in the western Indo-Gangetic plains due to COVID-19 indicates that adoption of scale-appropriate farm mechanization has the potential to stabilize the food production as well as reducing the income losses and air pollution surges in northwest India.
Harvesting maize in Mexico. (Photo: CIMMYT)
The situation in the regions each of you have mentioned is unique, but are there any global trends that youâve noticed? And if so, can other regions learn from these localized experiences?
Krupnik: A huge part of what we do as a research and training institute is facilitate exchanges of information across continents and countries. Different types and designs of machinery that can be used in similar circumstances can be shared, as can business models supporting service providers.
Importantly, part of the concept of âscale-appropriate mechanizationâ is also learning when and where machinery makes sense â where labor is not scarce and rural communities are highly dependent on income from labor to sustain their communities, some forms of mechanization may not be appropriate. We work to understand these dynamics and target the right machines in the right time and right places.
Van Loon: In addition to reducing pressure on available labor and alleviating drudgery, modern farm equipment tailored to the needs of smallholders can also increase competitiveness, as it allows for higher precision and efficiency.
In this sense, scale-appropriate mechanization can stimulate rural transformation incentivizing short and efficient value chains while ensuring stable food provision â aspects that have become essential to navigating the present crisis.
Has the current pandemic brought up any new perspectives in terms of how you consider labor and mechanization?
Baudron: We often look at yield and area planted in staple crops to assess the food security situation of a country during a particular year. This pandemic has shown us that we need to pay more attention to labor productivity. In many countries, policy-makers and development agents fear that mechanization will displace labor, but the dependency of staple crops on labor is a threat to food security, as we currently see in Africa and South Asia.
If the production of fruit, vegetables, cash crops, and so on will continue to depend on manual labor, it is essential in my view for critical tasks in the production of staples to be mechanized â particularly planting and harvesting. This will ensure the resilience of national food systems in the case of a future disruption similar to the COVID-19 pandemic.
Cover photo: Establishment of demo trial in Nyanga, Zimbabwe. (Photo: CIMMYT/ZRBF)
