Working with smallholders to understand their needs and build on their knowledge, CIMMYT brings the right seeds and inputs to local markets, raises awareness of more productive cropping practices, and works to bring local mechanization and irrigation services based on conservation agriculture practices. CIMMYT helps scale up farmers’ own innovations, and embraces remote sensing, mobile phones and other information technology. These interventions are gender-inclusive, to ensure equitable impacts for all.
CIMMYT is happy to announce three new, improved tropical maize hybrids that are now available for uptake by public and private sector partners, especially those interested in marketing or disseminating hybrid maize seed across southern Africa and similar agroecologies in other regions. NARES and seed companies are hereby invited to apply for licenses to pursue national release, scale-up seed production and deliver these maize hybrids to farming communities.
The deadline to submit applications to be considered during the first round of allocations is January 26, 2024. Applications received after that deadline will be considered during subsequent rounds of product allocations.
The newly available CIMMYT maize hybrids were identified through rigorous, years-long trialing and a stage-gate advancement process which culminated in the southern Africa Stage 5 On Farm Trials. The products were found to meet the stringent performance and farmer acceptance criteria for CIMMYT’s breeding pipelines that are designed to generate products tailored for smallholder farmers in stress-prone agroecologies of southern Africa.
The Nepal Agricultural Research Council (NARC) and CIMMYT are partnering to advance actions to revolutionize agriculture in Nepal. The collaboration, announced at a planning meeting between the two organizations on October 16, 2023, aims to enhance food security and improve the livelihoods of farmers in the country. With their combined expertise, NARC and CIMMYT will chart a new course in agricultural development, bringing hope and prosperity to Nepal’s farming communities.
CIMMYT scientists with NARC scientists. (Photo: Nabin Maharjan/CIMMYT)
Previous collaborative efforts developing new crop varieties have helped to strengthen Nepal’s national research framework. In a recent statement, Sreemat Shrestha, NERC chief at the NARC, highlighted CIMMYT’s significant contributions. Shrestha emphasized CIMMYT’s role in introducing revolutionary advancements, such as digital file mapping, market segmentation and advanced agricultural land use technologies.
CIMMYT Country Representative in Nepal, Dyutiman Choudhary, gave the presentation and led the meeting. During the event, he presented a comprehensive explanation of the vast relationship that exists between CIMMYT and NARC. He emphasized the historical significance of this partnership and discussed the various aspects that contribute to the strength of their combined efforts.
NARC expanding global influence and enhancing research impact
In an effort to strengthen its position on the global stage, NARC has set forth a clear mission to enhance capacity development, broaden its influence worldwide and establish a coalition of highly trained scientists to elevate the quality and impact of research.
“With this ambitious agenda, NARC is poised to make significant strides in scientific advancement, and CIMMYT will be a valued partner with us the entire time,” said Shrestha.
Sieglinde Snapp, director of Sustainable Agrifood Systems (SAS) at CIMMYT, while acknowledging the challenges the world is facing, such as air and water quality issues, rising food prices, emphasized the importance of agriculture in addressing these challenges and further innovations like new genetic research, molecular biology and AI.
Sieglinde and Sreshtha discuss the CIMMYT-NARC collaboration. (Photo: Nabin Maharjan/CIMMYT)
“I am excited about the progress CIMMYT and NARC have already achieved in Nepal,” said Snapp. “I encourage all of us to continue our efforts together, because collective action is necessary for meaningful change.”
Snapp highlights the need for technology adoption and mentions the transformation of wheat value chains, particularly in reducing women’s labor through introducing machines and spare parts. She praises the commitment to balance input and output and cites an example of helping farmers during a fertilizer crisis.
CIMMYT’s new focus at play in Nepal
Timothy Krupnik, CIMMYT regional director for SAS, provided insights into the organization’s growth and global influence in over 80 countries. Krupnik highlighted CIMMYT’s transition from its primary focus on breeding and genomics to its engagement to include other factors, such as agronomy, on-farm participatory research, socioeconomic studies and comprehensive agrifood systems.
“This shift in focus enhances CIMMYT’s understanding of the broader agricultural landscape and contributes to more comprehensive solutions,” said Krupnik. “Remarkable progress has been achieved in hybrid maize development and seed production, and we look forward to continuing to work with our Nepali partners.”
The meeting discussed various agricultural technology and innovation topics, including machinery, remote sensing, GIS toolsand greenhouse gas emission reduction strategies. NARC officials stressed the significance of enhancing capacity, especially in digital agriculture, to prepare Nepal for present and future climate challenges. Specific focus was on utilizing predictive crop modeling and simulation techniques to ensure crop resilience in the face of changing climate scenarios.
Nepal and CIMMYT have signed a 10-year collaboration to strengthen agriculture. The partnership, formalized by Secretary Govinda Prasad Sharma and CIMMYT director general Bram Govaerts, focuses on improving agricultural production and market systems in Nepal.
Global concerns are escalating as population growth, climate challenges and regional conflicts contribute to a food crisis. CIMMYT, in collaboration with 13 countries, is registering 160 drought-tolerant maize varieties to address changing climatic conditions, underscoring the need for unified efforts in global agricultural organizations.
The Government of Nepal and CIMMYT have signed a Memorandum of Understanding (MoU) outlining a ten-year collaboration to improve agricultural production and market systems in the country.
A recent meta-analysis by Leonard Rusinamhodzi a systems agronomist at CIMMYT and Sigrun Dahlin from the Swedish University of Agricultural Sciences provides an overview of how many agroecological practices are not widely adopted because of their high labor requirements.
Latest advances in sensor technology and data processing allow early detection, mapping and monitoring of crop infestation, helping prevent large-scale outbreaks.
A recent study published in Nature Scientific Reports, assesses the capability of very high-resolution satellite (VHRS) imagery and high-resolution unmanned aerial vehicles (UAVs) imagery for high-throughput phenotyping and detecting impacts of wheat rusts in earlier crop growth stages. UAVs and VHRS offer high potential for nonintrusive, extensive, rapid and flexible measurements of plant biophysical properties at very high spatial and temporal scales.
The study—led by CIMMYT in partnership with the Ethiopian Institute of Agricultural Research (EIAR) and Lincoln Agritech Ltd from New Zealand—establishes that these advanced sensor technologies are emerging as gamechangers in crop health management. They save time, complement traditional disease scoring methods and field surveys, and are cost-effective.
Further, the study establishes that multispectral VHRS sensors can pave the way for the upscaling of disease severity assessment from plot to regional scales at early growth stages.
Wheat rust is a global challenge
Globally, crop infections are an increasing threat to crop production and food security. Increased cross-border trade and travel, coupled with a changing climate are resulting in increased frequency and severity of crop disease outbreaks. Of all the diseases that affect wheat, wheat rusts are among the most damaging, capable of causing epidemics on a vast scale with significant economic and production losses. As of date, global losses from wheat rusts equate to 15 million tonnes per year (USD $2.9 billion). In Ethiopia, a major stripe/yellow-rust epidemic in 2010 affected an estimated 600,000 hectares, resulting in production losses of 15–20% and causing economic losses of USD $250 million. Similarly, a stem/black rust (SR) epidemic from 2013-2014 infected approximately 40,000 hectares. SR, which can cause 100% crop loss within weeks, is re-emerging as a major concern to wheat production.
Early detection, monitoring and timely intervention is key
Rapid early-season detection, monitoring and timely control of wheat rusts in susceptible varieties are critical to avoid large-scale outbreaks, especially in countries where fungicides are scarcely available or too costly for smallholders. UAV-based high-throughput phenotyping (HTP) has been recently investigated to support wheat improvement breeding, in particular, to assess plant growth development, canopy architecture, physiology, reaction to abiotic stress, crop disease and insect pest response, and wheat yield.
Figure 1
Spectral and thermal measurements at the plant and canopy levels allow for monitoring the interactions between plant germplasm and environmental (abiotic and biotic) factors. The current study identifies several spectral features from UAV and VHRS multispectral imagery that have strong assessment power for the detection of combined wheat rust diseases at early crop growth stages.
During a randomized trial conducted in Ethiopia, six bread wheat varieties with differing rust resistance were monitored using UAV and VHRS. In total, 18 spectral features were tested to assess stem and yellow rust disease progression and associated yield loss. Spectral properties of the wheat canopy (e.g., pigmentation, moisture, and biomass) are altered under rust disease stress. Using multispectral images and derived vegetation indices, it is possible to determine crop susceptibility to diseases and consequently can be used for detection and monitoring of wheat rusts.
Figure 2
Recent research on wheat, maize and dry bean demonstrated strong and significant correlations between vegetation indices extracted from UAV and VHRS imagery, confirming the feasibility of VHRS-HTP targeting biomass and yield; however, such satellite applications for plant breeding programs are still scarce.
Looking ahead to upscaling
This study provides valuable insight into the upscaling capability of multispectral sensors for disease detection from UAV imagery at 5 cm per pixel to pan-sharpened satellite imagery at 50 cm per pixel, demonstrating a first step towards upscaling disease detection from plot to regional scales. Further work will expand and improve current methodology to examine the VHRS detection capability towards machine and deep learning techniques (e.g., convolutional neural network) to allow for continuous monitoring systems, focusing on both single and mixed rust diseases under different treatments (e.g., variable fungicide rates, irrigation rates).
The early detection of diseases through spectral analysis and the integration of machine learning algorithms offers invaluable tools to mitigate the spread of infections and implement prompt disease management strategies.
Figures (1-2):
Field trial captured at varying spatial resolutions:
(a) SkySat false color composite (NIR-R-G) at 50 cm pixels (booting stage; 2020-10-17)
(b) UAV false color composite (NIR-R-G) at 5 cm pixels (heading stage; 2020-10-29)
Jared Crain, a research assistant professor of plant pathology, collaborates with CIMMYT on wheat genomics. Leading the Feed the Future Innovation Lab for Applied Wheat Genomics at K-State, Crain and his team annually analyze DNA from 19,000 plants.
Across all production environments in Kenya, early-maturity products demonstrate strong sales. This was revealed in a recent study by the CGIAR Initiative on Market Intelligence. During the long-rains season, farmers in higher rainfall production environments—wet, mid and high altitudes—purchased early-maturity seed products despite potentially lower yields. Also, the short-rains season, which represents almost one-fourth of total maize seed sales, was dominated by early-maturity products.
These insights were obtained through a panel of maize-seed sales data from 722 agrodealers in Kenya during two short-rains seasons and three long-rains seasons in 2020–2022. The study also offers insights into the extent the maturity level of seed products, purchased by farmers in Kenya, aligns with the production environment where they were sold. Market Intelligence applies eight criteria to identify seed product market segments (SPMSs) for CGIAR crop breeding. In the application of these criteria to maize in East Africa, two conditions distinguish the segments: production environment and maturity level. The other criteria do not vary. A key indicator for prioritizing breeding investments across segments is the relative size of SPMSs. In the case of maize, and other crops, teams generally use geospatial data to identify the area of production environments, with the assumption that farmers in each production environment would use the seed product with the maturity level designed for that environment.
The paper contends that a stronger focus on using sales data to inform breeding decisions in maize, and potentially other crops where retailers play an important role in seed distribution, should become a priority for market intelligence. Future work will engage stakeholders in maize seed systems in other countries of East Africa about the changes in demand for earlier-maturing products and the implications for segmentation.
The CGIAR Initiative on Market Intelligence (‘Market Intelligence’ for brevity) represents a new effort to engage social scientists, crop-breeding teams, and others to work together toward the design and implementation of a demand-led breeding approach. In 2022, the Market Intelligence Brief (MIB) series was created as a valuable communication tool to support informed decision making by crop breeders, seed-system specialists, and donors on future priorities and investments by CGIAR, NARS, the private sector, and non-governmental organizations (NGOs).
The author would like to thank all funders who supported this research through their contributions to the CGIAR Trust Fund. This project received funding from the Accelerating Genetic Gains in Maize and Wheat project (AGG) [INV-003439], funded by Bill & Melinda Gates Foundation; Foundation for Food & Agriculture Research (FFAR); United States Agency for International Development (USAID); and United Kingdom’s Foreign, Commonwealth & Development Office (FCDO).
Fall armyworm (Spodoptera frugiperda J.E. Smith) has emerged as a major threat to farming communities across Africa, including Zimbabwe. This destructive pest feeds on a wide range of crops, including maize, posing a significant challenge to food security. To combat this pest, the project “Evaluating Agro-ecological Management Options for Fall Armyworm in Zimbabwe” was initiated in October 2018 with support from USAID. It aims to address research gaps on fall armyworm management and cultural control in sustainable agriculture systems.
The project has implemented research trials in ten (10) districts across Zimbabwe, with work reaching close to 9,000 beneficiaries in target areas being exposed and applying new control practices that reduce the damage of FAW without heavily relying on chemical pesticides. This has been supported by a strong focus on agronomy trainings, field days, documentation, education through technical videos, knowledge sharing, and developing farmer manuals. In addition, the project supports Farmer Field Schools involving all relevant players in the farming communities to mainstream cultural practices in fall armyworm management.
Key objectives
The overall objective is to explore climate-adapted push pull systems and low-cost cultural control options for smallholder farmers in Zimbabwe. This project focused on research trials in Murehwa (Mashonaland East) and Mhondoro Ngezi (Mashonaland West), where the proof of concept was developed. After the inception phase it expanded to establishing demonstration sites and Farmer Field Schools in the Manicaland province, conducting trainings with farmers, and promoting knowledge sharing with Agritex officers and engaging with all relevant players in the target localities. Through continuous research and collaborative efforts, this project aims to develop sustainable and eco-friendly strategies to manage all armyworm infestations.
Wheat DEWAS, funded by the Bill & Melinda Gates Foundation and the UK’s Foreign, Commonwealth & Development Office, is expanding to strengthen wheat resilience in East Africa and South Asia. The collaborative effort is led by CIMMYT and Cornell University, which includes 23 organizations across continents.
Nigerian wheat scientists and millers recently recognized and thanked CIMMYT for its contributions to four new wheat varieties released to farmers, citing the varieties’ exceptional performance in field trials and farmers’ fields across national wheat-growing regions.
“The release of these four wheat varieties, uniquely tailored to suit our local conditions, has marked a significant milestone in enhancing food security and farmer livelihoods,” said Ahamed T. Abdullahi, agronomist for wheat value chains at the Flour Milling Association of Nigeria (FMAN), in a recent message to CIMMYT’s Global Wheat program. “The improved characteristics, such as higher yield potential, enhanced disease resistance, and adaptability to local climatic conditions, have significantly boosted wheat productivity. Moreover, the quality profiles of these varieties, as expressed in Nigeria, comply fully with the standards required by the local industry.”
Two of the varieties are bread wheat and yield up to 7 tons of grain per hectare, according to a recent Nigeria Tribunearticle. The other two are durum wheat, a species grown to make pasta and foods such as couscous and tabbouleh. One of those, given the name LACRIWHIT 14D in Nigeria, was from a CIMMYT wheat line selected for its novel genetic resistance to leaf rust and high-yield potential under irrigated conditions. It was also released in Mexico under the name CIRNO C2008 and is the country’s number-one durum wheat variety, according to Karim Ammar, a wheat breeder at CIMMYT.
Four new bread and durum wheat varieties based on CIMMYT breeding lines are well adapted to local conditions and offer excellent yields and grain quality. (Photo: FMAN)
“Aside from its high yield potential, it has considerable grain size and an aggressive grain fill that is expressed even under extreme heat,” explained Ammar. “These characteristics have certainly helped its identification as outstanding for Nigerian conditions.”
Writing on behalf of FMAN and the Lake Chad Research Institute (LCRI) of Nigeria’s Federal Ministry of Agriculture and Rural Development, Abdullahi said, “We deeply appreciate the expertise and support provided by CIMMYT throughout the development and release process. Your team’s technical guidance on the access to germplasm has played a crucial role in equipping our farmers and extension agents with the necessary skills and resources for successful wheat cultivation.”
Nigeria has a fast-growing population which, coupled with increasing per capita demand for wheat, has made increasing wheat production a national priority, according to Kevin Pixley, director of the Dryland Crops and Global Wheat programs at CIMMYT.
“Until recently, Nigeria produced only 2% of the wheat it consumes, but potential exists to double the current average yield and expand wheat production by perhaps 10-times its current area,” said Pixley. “New wheat varieties will be essential and must be grown using sustainable production practices that improve farmers’ livelihoods while safeguarding long-term food security and natural resources.”
Abdullahi said the release of the varieties demonstrated the power of collaborative research and highlighted the potential for future collaborations. “We look forward to continued collaborations and success in the pursuit of sustainable food systems.”
During his visit to the CIMMYT, Governor Little initiated conversations between the center, the University of Idaho College of Agriculture and Life Sciences, and various Idaho commodity groups. These discussions aim to explore potential collaborations in wheat breeding, sustainability initiatives, and the advancement of bean seed development.
In Zimbabwe, CIMMYT is studying the long-term effectiveness of integrated farming practices, including tillage, no-tillage, mulching with maize residues, and cowpea rotation. This experiment in a distinct agricultural context provides insights into sustainable strategies and soil carbon stocks.
CIMMYT and partners in Kenya recently marked the 10th anniversary of two major facilities that have been crucial for maize breeding in sub-Saharan Africa. The Maize Doubled-Haploid (DH) facility and the Maize Lethal Necrosis (MLN) screening facility at the Kenya Agriculture and Livestock Research Organization (KALRO) centers in Naivasha and Kiboko, respectively, have made immense contributions to the rapid development of higher-yielding, climate-resilient and disease-resistant maize varieties for smallholder farmers across the continent.
An aerial photo of the Naivasha Research Center. (Photo: CIMMYT)
“These two facilities have been instrumental in furthering KALRO’s mission to utilize technology in the service of Kenya’s smallholder farmers,” said KALRO Director General/CEO, Eliud Kireger. “They also exhibit the spirit of cooperation and collaboration that is necessary for us to meet all the challenges to our food systems.”
“Deploying a higher yielding maize variety may not be impactful in eastern Africa if that variety does not have resistance to a devastating disease like MLN,” said CIMMYT’s Director General Bram Govaerts. “These two facilities demonstrate the holistic methods which are key to working towards a more productive, inclusive and resilient agrifood system.”
Maize DH facility
Hybrid maize varieties have much higher yields than open-pollinated varieties and are key to unlocking the agricultural potential of maize producing countries. The doubled haploid process is an innovative technology producing within a year genetically true-to-type maize lines that serve as building blocks for improved maize hybrids.
Unlike conventional breeding, which takes at least 7 to 8 generations or crop seasons to develop parental lines, DH lines are generated within two seasons, saving significant time, labor and other resources. DH maize lines are highly uniform, genetically stable, and are more amenable to the application of modern molecular tools, making them perfect resources for breeding elite maize hybrids.
Workers in the Kiboko Double Haploid facility. (Photo: CIMMYT)
The aim of CIMMYT’s maize DH facility is to empower the breeding programs throughout the low-and middle-income countries in Africa by offering a competitive, accessible, not-for-profit DH production service that will accelerate their rate of genetic gain and fast-track development of improved maize varieties for farming communities.
Since 2017, the DH facility has delivered 280,000 DH lines from 1,840 populations of which 20% were delivered to public and private sector partners. CIMMYT maize breeding programs and partner organizations have embraced the use of DH technology, with many of the newest maize hybrids released in Africa being derived from DH lines. The facility has also served as a training ground so far for over 60 scientists and hundreds of undergraduate students in modern breeding technologies.
“Before 2013, DH technology was mainly employed by private, multinational corporations in North America, Europe, Asia and Latin America,” said CIMMYT’s DH Facility Manager, Vijay Chaikam. “But the DH facility operated by CIMMYT at the KALRO Kiboko research station is specifically targeted at strengthening the maize breeding programs by the public sector institutions as well as small-and medium-size enterprise seed companies in Africa.”
The maize DH facility at Kiboko, Kenya, was established with funding support from the Bill & Melinda Gates Foundation and inaugurated in September 2013. The facility includes an administrative building, seed quality laboratory, training resources, artificial seed dyer, a cold-storage seed room, a chromosome doubling laboratory, greenhouse and a state-of-the-art irrigation system to support year-round DH production in the 17-hectare nursery.
MLN screening facility
MLN is a devastating viral disease that can decimate farmers’ fields, causing premature plant death and unfilled, poorly formed maize ears, and can lead to up to 100 percent yield loss in farmers’ fields. Though known in other parts of the world for decades, the disease was first identified in eastern Africa in 2011. By 2015, MLN had rapidly spread across eastern Africa, including Kenya, Uganda, Tanzania, South Sudan, Rwanda, Democratic Republic of Congo and Ethiopia. CIMMYT scientists quickly discovered that almost all the commercial maize cultivars in eastern Africa were highly susceptible to the disease.
Against this backdrop, CIMMYT and KALRO recognized the urgent need for establishing a screening facility to provide MLN phenotyping service and effectively manage the risk of MLN on maize production through screening of germplasm and identifying MLN-resistant sources. The facility was built with funding support from the Bill & Melinda Gates Foundation and the Syngenta Foundation for Sustainable Agriculture, and inaugurated in September 2013.
Resistant and susceptible line at the Maize Lethal Necrosis facility. (Photo: CIMMYT)
“The MLN screening facility is a key regional resource in breeding for resistance to a devastating viral disease. The facility is indeed one of the key factors behind successful management of MLN and helping stem the tide of losses in eastern Africa,” said Director of the Global Maize Program at CIMMYT and One CGIAR Plant Health Initiative, B.M. Prasanna. “Fighting diseases like MLN, which do not respect political boundaries, requires strong regional and local collaboration. The successes achieved through the MLN Screening facility in the past 10 years embody that spirit of collaboration.” Indeed, farmers in the region now have access to over twenty genetically diverse, MLN-tolerant/resistant maize hybrids released in eastern and southern Africa.
The facility is the largest dedicated MLN screening facility in Africa and has evaluated over 230,000 accessions (over 330,000 rows of maize) from CIMMYT and partners, including over 15 national research programs, national and multinational seed companies. The facility covers 20 hectares, of which 17 hectares are used for field screening of germplasm. Dedicated laboratories and screen houses cover the remaining 3 hectares.
“MLN phenotyping service is conducted under stringent quarantine standards and the high-quality data is shared with all the CGIAR and public and private partners. The MLN screening service has helped breeding programs across the continent, aided in undertaking epidemiological research activities, and supported capacity building of students from diverse institutions, and regional stakeholders regarding MLN diagnosis and best management practices,” said CIMMYT’s Maize Pathologist in Africa, L.M. Suresh.
“The output of MLN resistant lines and hybrids has been remarkable,” said Director of Phytosanitary and Biosecurity at the Kenya Plant Health Inspectorate Service (KEPHIS), Isaac Macharia. “And the facility has strictly adhered to quarantine regulations.”
In Uganda, the MLN facility was crucial in the “release of the first-generation MLN tolerant hybrids and dissemination of MLN knowledge products that minimized the economic impact of MLN,” said the Director of Research of the National Crops Resources Research Institute, Godfrey Asea.
Peter Mbogo, maize breeder with Seed Co Group, said, “This is the only quarantine facility in the world where you can screen against MLN under artificial inoculation. It has been an excellent return on investment.”
