Location: South Sudan

Ten years later: CIMMYT facilities in East Africa continue to make a difference

Written by Julian Bañuelos-Uribe on November 30, 2023. Posted in News.

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.”

SPG Coalition: CIMMYT is a leading organization for climate-smart agriculture, nutrient-use efficiency, and pest and fertilizer management

Written by Julian Bañuelos-Uribe on August 21, 2023. Posted in Blogs.

The Coalition on Sustainable Productivity Growth for Food Security and Resource Conservation (SPG Coalition) brings together researchers, non-governmental organizations, and private sector partners to advance a world with greater access to nutritious food and affordable diets. The Coalition recognizes that increasing the productivity of natural resources through climate adaptation and mitigation is instrumental to reaching this goal.

In a recent report, the SPG Coalition provides a path forward for NGOs, research institutions, and government agencies to strengthen agrifood and climate policies. The report contains real-life, evidence-based examples to further the sustainable production and conservation of natural resources, detailing the potential impacts on social, economic, and environmental conditions.

CIMMYT features prominently in the report as a leading organization focused on 4 main areas: climate-smart agriculture, nutrient-use efficiency (NUE), and pest and fertilizer management.

Nutrient-use efficiency and fertilizer management

While chemical fertilizers increase crop yields, excessive or improper use of fertilizers contributes to greenhouse gas emissions (GHG) and increases labor costs for smallholders. Efficient NUE is central to nutrient management and climate change mitigation and adaptation.

Women using spreader for fertilizer application. (Photo: Wasim Iftikar/CSISA)

In India, CIMMYT, along with the Borlaug Institute for South Asia (BISA), CGIAR Research Centers, and regional partners, tested digital tools like the Nutrient Expert (NE) decision support tool which measures proper fertilizer use for optimized yields and provides nutrient recommendations based on local soil conditions.

The majority of smallholders who applied the NE tool reported higher yields while emitting less GHG emissions by 12-20% in wheat and by around 2.5% in rice as compared with conventional fertilization practices. Farmers also recorded double economic gains: increased yields and reduced fertilizer costs. Wider government scaling of NE could enhance regional food security and mitigate GHG emissions.

The Feed the Future Nepal Seed and Fertilizer (NSAF) project, led by CIMMYT and USAID, advocates for climate-smart agriculture by linking smallholders with improved seed, providing capacity-building programs, and promoting efficient fertilizer use. With a vast network established with the support from the Government of Nepal, NSAF successfully provides smallholders with expanded market access and nutritious and climate-resilient crop varieties.

Climate-smart maize breeding

Since its arrival to sub-Saharan Africa (SSA) in 2016, fall armyworm (FAW) has devastated maize harvests for countless smallholders on the continent. Economic uncertainty caused by unstable yields and climate stressors like drought coupled with this endemic pest risk aggravating food insecurity.

Fall armyworm. (Photo: Jennifer Johnson/CIMMYT)

CIMMYT and NARES Partner Institutions in Eastern and Southern Africa are spearheading a robust pest management project to develop, screen, and introduce genetically resistant elite maize hybrids across SSA. South Sudan, Zambia, Kenya, and Malawi have already deployed resistant maize varieties, and eight other countries in the region are projected to release their own in 2023. These countries are also conducting National Performance Trials (NPTs) to increase awareness of host plant resistance for the sustainable control of FAW and to sensitize policymakers on accelerating the delivery of FAW-tolerant maize varieties.

The establishment of FAW screening facilities in Africa permits more rapid detection and breeding of maize varieties with native genetic resistance to FAW, facilitating increased deployment of these varieties across Africa. The sustainable control of FAW demands a rapid-response effort, overseen by research organizations and governments, to further develop and validate genetic resistance to fall armyworms. Achieving greater impact for maize smallholders is critical to ensuring improved income and food security in Africa. It is also paramount for biodiversity conservation and removing labor burden on farmers applying additional synthetic pesticides to prevent further losses by the pest.

“The SPG Coalition report emphasizes the power of partnership to enhance financial and food security for smallholder communities in the Global South. This is fully in line with the recently launched CIMMYT 2030 strategy. It’s also an important reminder to assess our strong points and where more investment and collaboration is needed,” said Bram Govaerts, CIMMYT director general.

AGG-Maize project registers impressive progress

Written by Susan Otieno on October 4, 2022. Posted in News.

Participants of the AGG Maize Mid-Term Review and Planning Meeting at CIMMYT’s Maize Lethal Necrosis Screening Facility in Naivasha, Kenya. (Photo: Dokta Jonte Photography)

The Accelerating Genetic Gains in Maize and Wheat (AGG) Project, which is halfway through its implementation, continues to register impressive achievements. At a meeting focusing on the project’s Maize component, held in Nairobi during July 25-28, B.M. Prasanna, Director of the Global Maize Program at the International Maize and Wheat Improvement Center (CIMMYT), highlighted the project’s major achievements in the opening session.

“One of the most important achievements of this project is increasing use of powerful tools and technologies to increase genetic gains in maize breeding pipelines in Africa,” said Prasanna. He noted that the AGG partners are showing keen interest in doubled haploid-based maize breeding. Prasanna pointed out that currently work is ongoing to produce third-generation tropicalized haploid inducers which, in combination with molecular markers, will support accelerated development of improved maize germplasm, a key objective of the AGG Project.

Prasanna also pointed out a significant increase in adoption of stress-tolerant maize in Africa – from less than half a million hectares cultivated under stress tolerant maize varieties in 2010, to 7.2 million hectares currently in 13 African countries, benefitting 44.5 million people. He explained that drought-tolerant maize is not only a productivity enhancing tool but also an innovation for improving the welfare of farmers. “It reduces the probability of crop failure by 30 percent and provides an extra income to farmers at a rate of approximately $240 USD per hectare, equivalent to about nine months of food for a family at no additional cost,” he said, adding that the essence of research is taking improved genetics to farmers and impacting their lives.

He noted there is remarkable progress in maize varietal turnover in sub-Saharan Africa, pointing out particularly efforts in Ethiopia, Uganda, Zambia and Zimbabwe, where old maize varieties, some dating as far back as 1988, have been replaced with newer climate-resilient varieties. Prasanna highlighted the need to engage with policy makers to put in place appropriate legislation that can accelerate replacement of old or obsolete varieties with improved genetics.

Prasanna stressed on the importance of rapid response to transboundary diseases and insect-pests. CIMMYT has established fall armyworm (FAW) screening facility at Kiboko, Kenya, and that more than 10,000 maize germplasm entries have been screened over the last three years. He applauded South Sudan for being the first country in sub-Saharan Africa to recently release three CIMMYT-developed FAW-tolerant hybrids. He said CIMMYT’s FAW-tolerant inbred lines have been shared with 92 institutions, both public and private, in 34 countries globally since 2018.

Kevin Pixley, CIMMYT Global Genetic Resources Director and Deputy Director General, Breeding and Genetics, encouraged the participants to continuously reflect on making innovative contributions through the AGG project, to serve smallholder farmers and other stakeholders, and to offer sustainable solutions to the food crisis that plagues the world.

B.M. Prasanna addresses partners at the KALRO Kiboko Research station in Kenya during an AGG field visit. (Photo: Dokta Jonte Photography)

Synergies across crops and teams

Pixley pointed out that though the meeting’s focus was on maize, the AGG Project has both maize and wheat components, and the potential for learning between the maize and wheat teams would benefit many, especially with the innovative strides in research from both teams.

Pixley referenced a recent meeting in Ethiopia with colleagues from the International Institute of Tropical Agriculture (IITA), the International Center for Tropical Agriculture (CIAT) and CIMMYT, where discussions explored collaboration among CGIAR centers and other stakeholders in strengthening work on cowpea, chickpea, beans, sorghum, millet and groundnut crops. He noted that maize, wheat and the aforementioned crops are all critical in achieving the mission of CGIAR.

“CIMMYT has been requested, since August of last year, by CGIAR to initiate research projects on sorghum, millet and groundnut because these crops are critical to the success of achieving the mission of CGIAR,” said Pixley. “So, we have recently initiated work on the Accelerated Varietal Improvement and Seed Systems in Africa (AVISA) project together with partners. This is the first step towards OneCGIAR. It’s about synergies across crops and teams.”

Collaborative research commended

The meeting’s Chief Guest, Felister Makini, Deputy Director General – Crops of the Kenya Agricultural and Livestock Research Organisation (KALRO), commended the collaborative research undertaken by CIMMYT and other CGIAR partners. She noted that the partnerships continue to build on synergies that strengthen institutional financial, physical and human resources. She attested that collaboration between KALRO and CGIAR dates back to the 1980s, beginning with training in maize breeding, and then subsequent collaboration on developing climate-adaptive improved maize varieties and training of KALRO technicians in maize lethal necrosis (MLN) screening and management among other areas.

Maize and wheat are staple food sources in Kenya and sub-Saharan Africa and as the population increases, new methods and approaches must be found to accelerate development and deployment of improved maize and wheat varieties. She challenged the partners to intensify research and come out with high-yielding varieties that are resistant or tolerant to a wide range of biotic and abiotic stresses.

The Inaugural Session also featured remarks from the representatives of the AGG funders – Gary Atlin from the Bill & Melinda Gates Foundation, Jonna Davis from the Foundation for Food and Agriculture Research (FFAR), and John Derera from IITA, an AGG project partner.

A total of 116 participants, including representatives from National Agricultural Research Systems (NARS) in 13 AGG-Maize partner countries in Africa and seed companies, participated in the meeting. Participants also visited the KALRO-CIMMYT MLN Screening Facility at Naivasha, and KALRO-CIMMYT maize experiments at Kiboko, Kenya, including the work being done at the maize doubled haploid and FAW facilities.

Farmers at a demonstration farm field day organized by East African Seed Company. (Photo: Courtesy)

Fighting the stress

Written by Rodrigo Ordóñez on March 23, 2021. Posted in Features.

East African Seed Company has a rich history of nearly 50 years, serving farmers with improved climate-resilient seed varieties. Established in 1972, the company produces and sells improved seed, through a wide distribution network in at least 15 countries in sub-Saharan Africa. It also markets agrochemicals and other farm inputs, and has ambitions of expanding to the rest of Africa, trading as Agriscope Africa Limited.

Smallholder farmers in sub-Saharan Africa continue to face multiple biotic and abiotic stresses as they try to improve their farms’ productivity and their livelihoods. Maize seed that guarantees high yield is a key trait, coupled with other key attributes such as drought tolerance, disease and pest resistance, early seedling vigor as well as suitability for food and animal feed.

With the varieties serving both small- and large-scale commercial farmers, challenges such as the fall armyworm, diminishing soil fertility and erratic rains have persisted in recent years and remain as key farming obstacles. “Such challenges diminish crop production and the grain quality thereby, lessening farmers’ profitability,” says Rogers Mugambi, Chief Operating Officer of East African Seed Company.

Scientists at the International Maize and Wheat Improvement Center (CIMMYT), in collaboration with partners in the national agriculture research systems and the commercial seed sector, continue to develop seed varieties that can guarantee decent yield even in times of climatic, disease and pest stress.

General view of the East African Seed warehouse. (Photo: Jerome Bossuet/CIMMYT)

Top-notch research trickles down to farmers

Over the years, East African Seed has inked partnerships with CIMMYT, national research institutes and other agencies in the countries where it operates. Such partnerships have been the driving force to its success and the impacts within the farming communities in sub-Saharan Africa.

“Our collaboration with CIMMYT began in 2008 with germplasm acquisition. The cooperation has expanded to include testing networks for new hybrids, early-generation seed production and marketing. The overall beneficiary is the smallholder farmer who can access quality seeds and produce more with climate-smart products,” Mugambi says.

Apart from the multi-stress-tolerant varieties developed and released over time by the national agricultural research programs, CIMMYT recently announced a breakthrough: fall armyworm-tolerant elite maize hybrids for eastern and southern Africa. This success followed three years of rigorous research and experiments conducted in Kenya and signified a key milestone in the fight against fall armyworm.

As part of the partnership in the Drought Tolerant Maize for Africa (DTMA) and Stress Tolerant Maize for Africa (STMA) projects, East African Seed Company (Agriscope Africa Limited) established demonstration farms and conducted field days in Kenya, reaching thousands of farmers as a result. It was also able to produce early generation seed, which supported production of 2,000 metric tons of certified seed. This partnership now continues in the Accelerating Genetic Gains in Maize and Wheat (AGG) project.

The company has contracted large- and small-scale growers across the country to meet its seed production targets.

“Most of our small-scale growers are clustered in groups of up to 30 farmers with less than five acres of farmland. The large growers have advanced irrigation facilities such as the pivot system and seed processing plants. The seed from the fields is pre-cleaned and dried in the out-grower facilities before delivery to our factory for further cleaning and processing,” Mugambi explains.

A handful of improved maize seed from the drought-tolerant variety TAN 250, developed and registered for sale in Tanzania through CIMMYT's Drought Tolerant Maize for Africa (DTMA) project. (Photo: Anne Wangalachi/CIMMYT) — A handful of improved maize seed from the drought-tolerant variety TAN 250, developed and registered for sale in Tanzania through CIMMYT’s Drought Tolerant Maize for Africa (DTMA) project. (Photo: Anne Wangalachi/CIMMYT)

Out with the drought

Currently, of the 1,300 metric tons of drought-tolerant hybrid seeds it produces yearly, 500 metric tons constitute those derived from the partnership in the STMA project. Two notable hybrids, HODARI (MH501) and TOSHEKA (MH401), were derived during the DTMA and STMA projects. Released in 2014 and accepted for regional certification through the Common Market for Eastern and Southern Africa (COMESA)’s regional catalogue, the MH501 is a mid-altitude adapted and medium maturing three-way cross hybrid. The yield advantage of 15% over the local commercial checks triggered widespread adoption by the farmers, according to Mugambi. In Kenya, it was used as a commercial check during national performance trials, from 2017 to 2019.

The MH401, an early maturing hybrid with moderate drought tolerance, has been adopted in lowland and mid-altitude dry ecologies of Kenya and Tanzania. It has a 20% yield advantage over the local commercial checks.

As part of its varietal replacement, East African Seed Company looks to steadily retire older varieties such as KH600-15A and WE1101 and promote new ones including TAJIRI (EASH1220), TAJI (MH502) and FARAJA (MH503).

To promote new varieties and successfully reach smallholders, the company conducts field days, farm-level varietal demonstrations, road shows and radio programs. It also disseminates information on the benefits of new varieties while also dispensing promotional materials such as branded t-shirts and caps.

“Additionally, we organize annual field days at our research farm in Thika, where key and influential farmers and other stakeholders are invited from across Kenya and neighboring countries to learn about our new agricultural technologies,” Mugambi says.

Alice Nasiyimu stands in front of a drought-tolerant maize plot at her family farm in Bungoma County, in western Kenya. (Photo: Joshua Masinde/CIMMYT)

Q&A: A decade of improved and climate-smart maize through collaborative research and innovation

Written by Shiela Chikulo on February 23, 2021. Posted in Features.

The food security and livelihoods of smallholder farming families in sub-Saharan Africa depend on maize production. The region accounts for up to two-thirds of global maize production, but is facing challenges related to extreme weather events, climate-induced stresses, pests and diseases, and deteriorating soil quality. These require swift interventions and innovations to safeguard maize yields and quality.

In this Q&A, we reflect on the results and impact of the long-term collaborative work on drought-tolerant maize innovations spearheaded by two CGIAR Research Centers: the International Maize and Wheat Improvement Center (CIMMYT) and International Institute of Tropical Agriculture (IITA). This innovative work has changed guises over the years, from the early work of the Drought Tolerant Maize for Africa (DTMA) and Drought Tolerant Maize for Africa Seed Scaling (DTMASS) projects through later iterations such as Stress Tolerant Maize for Africa (STMA) and the newest project, Accelerating Genetic Gains in Maize and Wheat (AGG).

In this Q&A, three leaders of this collaborative research reflect on the challenges their work has faced, the innovations and impact it has generated for smallholder farmers, and possible directions for future research. They are: B.M Prasanna, director of CIMMYT’s Global Maize Program and of the CGIAR Research Program on Maize (MAIZE); Abebe Menkir, a maize breeder and maize improvement lead at IITA; and Cosmos Magorokosho, project lead for AGG-Maize at CIMMYT.

Briefly describe the challenges confronting small-scale farmers prior to the introduction of drought-tolerant maize and how CIMMYT and IITA responded to these challenges?

B.M.P.: Maize is grown on over 38 million hectares in sub-Saharan Africa, accounting for 40% of cereal production in the region and providing at least 30% of the population’s total calorie intake. The crop is predominantly grown under rainfed conditions by resource-constrained smallholder farmers who often face erratic rainfall, poor soil fertility, increasing incidence of climatic extremes — especially drought and heat — and the threat of devastating diseases and insect pests.

Around 40% of maize-growing areas in sub-Saharan Africa face occasional drought stress with a yield loss of 10–25%. An additional 25% of the maize crop suffers frequent drought, with yield losses of up to 50%. Climate change is further exacerbating the situation, with devastating effects on the food security and livelihoods of the millions of smallholder farmers and their families who depend on maize in sub-Saharan Africa. Therefore, the improved maize varieties with drought tolerance, disease resistance and other farmer-preferred traits developed and deployed by CIMMYT and IITA over the last ten years in partnership with an array of national partners and seed companies across sub-Saharan Africa are critical in effectively tackling this major challenge.

A.M.: Consumption of maize as food varies considerably across sub-Saharan Africa, exceeding 100 kg per capita per year in many countries in southern Africa. In years when rainfall is adequate, virtually all maize consumed for food is grown in sub-Saharan Africa, with a minimal dependence on imported grain. Maize production, however, is highly variable from year to year due to the occurrence of drought and the dependence of national maize yields on seasonal rainfall. One consequence has been widespread famine occurring every five to ten years in sub-Saharan Africa, accompanied by large volumes of imported maize grain as food aid or direct imports.

This places a significant strain on resources of the World Food Programme and on national foreign exchange. It also disincentivizes local food production and may not prevent or address cyclical famine. It also leaves countries ill-equipped to address famine conditions in the period between the onset of the crisis and the arrival of food aid. Investment in local production, which would strengthen the resilience and self-sufficiency in food production of smallholder farming families, is a far better option to mitigate food shortages than relying on food aid and grain imports.

C.M.: Smallholder farmers in sub-Saharan Africa face innumerable natural and socioeconomic constraints. CIMMYT, in partnership with IITA and national agricultural research system partners, responded by developing and catalyzing the commercialization of new maize varieties that produce reasonable maize yields under unpredictable rainfall-dependent growing season.

Over the life of the partnership, more than 300 new climate-adaptive maize varieties were developed and released in more than 20 countries across sub-Saharan Africa where maize is a major staple food crop. Certified seed of over 100 stress-tolerant improved maize varieties have been produced by seed company partners, reaching more than 110,000 tons in 2019. The seeds of these drought-tolerant maize varieties have benefited more than 8 million households and were estimated to be grown on more than 5 million hectares in eastern, southern and west Africa in 2020.

A farmer in Mozambique stands for a photograph next to her drought-tolerant maize harvest. (Photo: CIMMYT)

In what ways did the drought-tolerant maize innovation transform small-scale farmers’ ability to respond to climate-induced risks? Are there any additional impacts on small scale farmers in addition to climate adaptation?

B.M.P.: The elite drought-tolerant maize varieties can not only provide increased yield in drought-stressed crop seasons, they also offer much needed yield stability. This means better performance than non-drought-tolerant varieties in both good years and bad years to a smallholder farmer.

Drought-tolerant maize varieties developed by CIMMYT and IITA demonstrate at least 25-30% grain yield advantage over non-drought-tolerant maize varieties in sub-Saharan Africa under drought stress at flowering. This translates into at least a 1 ton per hectare enhanced grain yield on average, as well as reduced downside risk in terms of lost income, food insecurity and other risks associated with crop yield variability. In addition to climate adaptation, smallholder farmers benefit from these varieties due to improved resistance to major diseases like maize lethal necrosis and parasitic weeds like Striga. We have also developed drought-tolerant maize varieties with enhanced protein quality — such as Quality Protein Maize or QPM — and provitamin A, which improve nutritional outcomes.

We must also note that drought risk in sub-Saharan Africa has multiple and far-reaching consequences. It reduces incentives for smallholder farmers to intensify maize-based systems and for commercial seed companies to invest and evolve due to a limited seed market.

Drought-tolerant maize is, therefore, a game changer as it reduces the downside risk for both farmers and seed companies and increases demand for improved maize seed, thus strengthening the commercial seed market in sub-Saharan Africa. Extensive public-private partnerships around drought-tolerant maize varieties supported the nascent seed sector in sub-Saharan Africa and has enabled maize-based seed companies to significantly grow over the last decade. Seed companies in turn are investing in marketing drought-tolerant maize varieties and taking the products to scale.

A.M.: The DTMA and STMA projects were jointly implemented by CIMMYT and IITA in partnership with diverse national and private sector partners in major maize producing countries in eastern, southern and western Africa to develop and deploy multiple stress-tolerant and productive maize varieties to help farmers adapt to recurrent droughts and other stresses including climate change.

These projects catalyzed the release and commercialization of numerous stress-resilient new maize varieties in target countries across Africa. Increasing the resilience of farming systems means that smallholder farmers need guaranteed access to good quality stress resilient maize seeds. To this end, the two projects worked with public and private sector partners to produce large quantities of certified seeds with a continual supply of breeder seeds from CIMMYT and IITA. The availability of considerable amount of certified seeds of resilient maize varieties has enabled partners to reach farmers producing maize under stressful conditions, thus contributing to the mitigation of food shortages that affect poor people the most in both rural and urban areas.

C.M.: The drought-tolerant maize innovation stabilized maize production under drought stress conditions in sub-Saharan Africa countries. Recent study results showed that households that grew drought-tolerant maize varieties had at least half a ton more maize harvest than the households that did not grow the drought-tolerant maize varieties, thus curbing food insecurity while simultaneously increasing farmers’ economic benefits. Besides the benefit from drought-tolerant innovation, the new maize varieties developed through the partnership also stabilized farmers’ yields under major diseases, Striga infestation, and poor soil fertility prevalent in sub-Saharan Africa.

How is the project addressing emerging challenges in breeding for drought-tolerant maize and what opportunities are available to address these challenges in the future?

Margaret holds an improved ear of drought-tolerant maize. Margaret’s grandmother participated in an on-farm trial in Murewa district, 75 kilometers northeast of Zimbabwe’s capital Harare. (Photo: Jill Cairns/CIMMYT)

B.M.P.: A strong pipeline of elite, multiple-stress-tolerant maize varieties — combining other relevant adaptive and farmer-preferred traits — has been built in sub-Saharan Africa through a strong germplasm base, partnerships with national research partners and small- and medium-sized seed companies, an extensive phenotyping and multi-location testing network, and engagement with farming communities through regional on-farm trials for the identification of relevant farmer-preferred products.

CGIAR maize breeding in sub-Saharan Africa continues to evolve in order to more effectively and efficiently create value for the farmers we serve. We are now intensively working on several areas: (a) increasing genetic gains (both on-station and on-farm) through maize breeding in the stress-prone environments of sub-Saharan Africa by optimizing our breeding pipelines and effectively integrating novel tools, technologies and strategies (e.g., doubled haploids, genomics-assisted breeding, high-throughput and precise phenotyping, improved breeding data management system, etc.); (b) targeted replacement of old or obsolete maize varieties in sub-Saharan Africa with climate-adaptive and new varieties; (c) developing next-generation climate-adaptive maize varieties with traits such as native genetic resistance to fall armyworm, and introgressed nutritional quality traits (e.g., provitamin A, high Zinc) to make a positive impact on the nutritional well-being of consumers; and (d) further strengthening the breeding capacity of national partners and small and medium-sized seed companies in sub-Saharan Africa for a sustainable way forward.

A.M.: The DTMA and STMA projects established effective product pipelines integrating cutting-edge phenotyping and molecular tools to develop stress-resilient maize varieties that are also resistant or tolerant to MLN disease and fall armyworm. These new varieties are awaiting release and commercialization. Increased investment in strengthening public and private sector partnerships is needed to speed up the uptake and commercialization of new multiple stress-resilient maize varieties that can replace the old ones in farmers’ fields and help achieve higher yield gains.

Farmers’ access to new multiple-stress-tolerant maize varieties will have a significant impact on productivity at the farm level. This will largely be due to new varieties’ improved response to fertilizer and favorable growing environments as well as their resilience to stressful production conditions. Studies show that the adoption of drought-tolerant maize varieties increased maize productivity, reduced exposure to farming risk among adopters and led to a decline in poverty among adopters. The availability of enough grain from highly productive and stress-resilient maize varieties can be the cheapest source of food and release land to expand the cultivation of other crops to facilitate increased access to diversified and healthy diets.

C.M.: The project is tackling emerging challenges posed by new diseases and pests by building upon the successful genetic base of drought-tolerant maize. This is being done by breeding new varieties that add tolerance to the emerging disease and pest challenges onto the existing drought-tolerant maize backgrounds. Successes have already been registered in breeding new varieties that have high levels of resistance to MLN disease and the fall armyworm pest.

Opportunities are also available to address new challenges including: pre-emptively breeding for threats to maize production challenges that exist in other regions of the world before these threats reach sub-Saharan Africa; enhancing the capacity of national partners to build strong breeding programs that can address new threats once they emerge in sub-Saharan Africa; and sharing knowledge and novel high-value breeding materials across different geographies to immediately address new threats once they emerge.

Cover photo: Alice Nasiyimu stands in front of a drought-tolerant maize plot at her family farm in Bungoma County, in western Kenya. (Photo: Joshua Masinde/CIMMYT)

Godfrey Asea (R) and Daniel Bomet (L) from Uganda’s National Agricultural Research Organization (NARO) admire maize cobs on a farm in Uganda. (Photo: Joshua Masinde/CIMMYT)

Building networks and capacity

Written by Shiela Chikulo on November 30, 2020. Posted in News.

The active involvement of partners in the co-design of project and capacity building activities is key to the success of the Accelerating Genetic Gains in Maize and Wheat for Improved Livelihoods (AGG) project, led by the International Maize and Wheat Improvement Center (CIMMYT). To that end, the AGG Regional Collaborative Breeding and Testing Networks launched with virtual meetings on September 14 and 15 for southern African partners, and October 28 and November 2 for eastern African partners.

In addition, the AGG team collaborated with researchers from the Excellence in Breeding (EiB) Platform on a number of capacity development webinars in October and November, on topics including Continuous Improvement for breeding processes, programs and products, enhancing and measuring genetic gain in crop breeding, and a three-webinar series on statistical analysis for plant breeders with CIMMYT’s Biometrics and Statistics Unit.

These training events and regional meetings provided opportunities for well over 100 breeders from CIMMYT, national agricultural research systems (NARS) and seed companies to refresh their capacities to improve genetic gains, and to collectively review and discuss upcoming project activities, current issues of interest, and broader project objectives within their current regional context.

Several themes of importance to partners emerged during the network virtual meetings, for attention in future AGG activities and capacity development work.

Gender inclusion and the impact of COVID-19

Ugandan partners, including Godfrey Asea, director of the National Crops Resources Research Institute at Uganda’s National Agricultural Research Organization, and Josephine Okot, founder and managing director of Victoria Seeds, applauded the project’s emphasis on inclusion of women’s knowledge and preferences in breeding programs.

“We notice that this time there is a lot of focus on gender-inclusiveness,” remarked Asea. “I can tell you there is need for enhanced capacity building for both the private sector and research in proper gender inclusion.”

They also noted the importance of building local capacity, not just for food security but also for other value chain items like raw materials. “COVID-19 has demonstrated to all policy-makers that we cannot depend on the global supply chains,” said Okot. “How can we leverage this project if, for instance, some private sector actors want to [know] the appropriate protein-content maize for, say, animal feed?”

Demand for knowledge

NARS members in Tanzania requested increased support on how to measure or assess genetic gains, especially at the national level, to allow them to establish a baseline upon which genetic gains would be pegged for the project lifecycle.

With statistics an essential element to plant breeding — from analyzing yield trials to ranking varieties — the webinar series in Statistical Analysis for Plant Breeders was a first step towards meeting these capacity development needs.

“The idea of this webinar series was to share insights on how we can improve the breeding plans using statistical methods in an effective way,” said Juan Burgueño, the head of CIMMYT’s Biometrics and Statistics Unit. “The training offered both theory and hands-on experience using open-access software.”

Reaching farmers

Looking beyond breeding, meeting participants also discussed how to improve access and adoption of improved varieties among farmers.

“For a large country such as Tanzania, it is at times very hard to reach the farmers,” said Zabron Mbwaga, managing director of the Tanzania-based Beula Seed Company and Consultancy Limited. “We may have a lot of seed in the store, but how to get the farmers to adopt the newer varieties is quite difficult. This is more so when farmers tend to stick to varieties which they know well and are always reluctant to adopt the new varieties,” he explained.

“We need to put in a lot of effort to set up demonstration farms and enhance other awareness-raising activities such as radio programs so that farmers can know about the new varieties.”

This interest in working with smallholder farmers along the entire value chain was echoed by partners in southern Africa.

“Through this project, we would like to explore ways of collaborating along the whole value chain — as the Agriculture Research Council, other partners and small to medium enterprises — to make it an effective chain,” said Kingstone Mashingaidze, senior research manager at the South Africa Agricultural Research Council. “By planning together, we can identify best-fits for all activities in the value chain and ultimately benefit the smallholder farmers.”

About the AGG Regional Collaborative Breeding and Testing Networks

The AGG Regional Collaborative Breeding and Testing Networks aim to improve breeding efficiencies among partners by enabling the use of modern tools and approaches and enriching the existing network of research organizations, public and private seed companies, farmers’ organizations, non-governmental organizations and community-based organizations. It is expected that these networks will lead to increased efficiency and communications across the partnership network and within countries, improved sharing of best practices and protocols, and increased collective ownership of products for accelerated variety development and turnover.

The virtual meetings for the Regional Collaborative Breeding and Testing Network for southern Africa convened participants from Malawi, Mozambique, South Africa, Zambia and Zimbabwe, while meetings for eastern Africa had participants from Ethiopia, Kenya, Tanzania and Uganda.

AGG communications staff Joshua Masinde and Shiela Chikulo contributed to this story.

The search is on for nontoxic solutions to fall armyworm across Africa

Written by Mary Donovan on September 29, 2020. Posted in In the media.

Last year, AgBiTech launched a partnership between the United States Agency for International Development, FAO, International Maize and Wheat Improvement Center, and Centre for Agriculture and Bioscience International in South Sudan to train farmers in using Fawlingen. These farmers have shown a 63% increase in yield compared to untreated plots and the pilot is being scaled to reach thousands of farmers this season.

Spraying locusts before they can fly key for effective control

Written by Alison Doody on February 27, 2020. Posted in News. 2 Comments on Spraying locusts before they can fly key for effective control

The locust invasion is the biggest in Ethiopia and Somalia in 25 years, and the biggest in Kenya in 70 years, according to the FAO. Photo: Ben Curtis/AP

East African countries are battling the worst desert locust invasion in decades. The locusts are devouring crops and pasture leaving in their wake a region that is staring at a potential food crisis. The swarms have swept across Djibouti, Eritrea, Ethiopia, Kenya, South Sudan, Somalia, Sudan, Tanzania and Uganda, with some of these countries reporting the worst outbreak in 70 years.

Experts have warned of a second round of the flare-up, as the eggs laid along the locust path hatch. Both aerial and ground spraying with insecticides continue but such interventions have not yielded much success.

Stephen Njoka, Director of the Desert Locust Control Organization for Eastern Africa (DLCO-EA) and Hugo De Groote, Agricultural Economist at the International Maize and Wheat Improvement Center (CIMMYT) share some insights on the outbreak, effective control measures and what can be done to mitigate the damage currently and in potential future outbreaks.

Q: What is your opinion on the locust invasion across the eastern Africa region?

A: The current locust invasion in the eastern Africa region is one of the most serious occurrences in decades. For Ethiopia and Kenya, this is the worst outbreak in over 25 years and 70 years respectively. The locusts have caused significant damage in pastoral regions, where they have devoured pasture and tree leaves. They are now reaching some of the major maize growing areas where they are likely to cause a lot of damage to the crops.

Q: Why are they called desert locusts?

A: They breed in the wet desert sands. In west Africa for instance, they would breed in the border areas between the Sahel and the Sahara Desert. They go through six stages; five of which are the non-flying phases. Once they reach adult stage, they start flying, mating and laying eggs, and the cycle continues.

They are usually solitary in nature, but occasionally move into their gregarious state, in which they alter their behavior and physical appearance, form swarms and migrate over long distances following the winds. This is what differentiates locusts from grasshoppers. When they land at a particular location, they cause a lot of damage in that specific area. Apart from that local destruction, however, they may not cause much harm on a national scale.

Q: How serious of a problem is this invasion to the food security status of countries like South Sudan that are just recovering from decades of conflict and a recent drought?

A: The invasion could pose a serious food security challenge in some areas as these insects consume their own weight in a day (one insect weighs 2 grams and a swarm can contain over 50 million insects).

For countries like South Sudan and Somalia where conflicts can hamper locust control efforts, the food insecurity situation gets compounded. Pastures are the worst hit as locusts tend to prefer hotter climates where livestock keeping is the main source of livelihood.

Q: In your experience, what is the best way to deal with such an invasion? What are the most effective control measures?

A: The best way to deal with such an invasion is to conduct aerial spraying using Ultra Low Volume (ULV) chemical or biological pesticides at the early stages for effective control. It is important to identify the egg-laying sites early on so that the emerging hoppers are sprayed before they can fly.

Q: We understand that this is the worst invasion in Kenya in about 70 years and the worst in 25 years in some neighboring countries such as Ethiopia. Should we expect another infestation a few years from now?

A: It is unlikely that we can expect another invasion of this magnitude in the near future. The current invasion may have been driven by climatic changes in the breeding areas of the Red Sea coast, war-torn Yemen and Somalia.

Q: How can we be better prepared given that such invasions are cyclical in nature and may happen again after some years or decades?

A: Continued monitoring and forecasting of the locust population in the traditional breeding sites should be a priority. Countries in the invasion areas should establish Locust Control Units under the appropriate ministries. These units should frequently get updates from the FAO Desert Locust Information Service (DLIS) in Rome and take precautionary steps as advised.

As the eastern Africa region, member countries of DLCO-EA should step up their support for the organization by acquiring modern aircrafts, which can conduct aerial spraying more effectively and efficiently.

Q: What monitoring measures are in place for the surveillance and recommended remedial measures, especially in periods of low densities just before they become gregarious? Who does the monitoring and how frequently is the monitoring done?

A: Locust scouting teams in the breeding areas are charged with monitoring and surveillance of these pests. The exercise is continuous and largely supported by FAO DLIS using appropriate equipment like elOCUST 3, a data recording and transmission system for crop pest monitoring, currently used as a detection and early warning tool for desert locusts.

Q: Are mitigation measures such as compensation for affected farmers an option?

A: Where farmers are seriously hit, government, intergovernmental agencies or non-governmental organizations may consider easing the farmers’ losses by offering food and/or financial support.

Q: We have seen efforts such as aerial or ground spraying of the pests. How effective are these interventions? What implications does this control measure have on the environment and people’s health?

A: The safe use of pesticides remains the best choice for control of insects occurring in such big numbers. It is important to use environmentally safe products which cause minimum harm to non-targets. Spray teams should be well trained on how to handle the pesticides.

People living in the invaded areas should also be alerted on keeping themselves and their livestock safe by not getting into the sprayed areas as advised. One effective biological control is the use of the Metarhizium, which the International Institute of Tropical Agriculture (IITA) developed out of the locust skin fungus.

Nevertheless, some chemicals may cause more harm to the environment, especially when aerial spraying is applied on swarms in flight. The pesticides can contaminate the environment, water, crops and can cause skin rashes or respiratory, neurological or eye problems. They can also cause harm to animals and aquatic species.

In times of locust outbreaks, like now, there is a tendency to procure large quantities of pesticides. However, once the locusts are gone, stockpiles of the unused pesticides remain. This brings about a new challenge of destroying or safely disposing of the old or obsolete pesticide stock.

Q: Can the locusts be eaten?

A: Many communities in the world eat locusts and other insects. It is, however, important to caution against eating sprayed locusts. Additionally, locust swarms can contain billions of locusts, so catching them for food may not have a significant effect in reducing their population.

Book launch: Lead farmers in eastern and southern Africa

Written by Carolyn Cowan on May 8, 2019. Posted in News. 1 Comment on Book launch: Lead farmers in eastern and southern Africa

Tackling the challenges of climate change and increasing scarcity of resources like arable land and water requires that farming and food systems around the world undergo fundamental shifts in thinking and practices. A new book draws on experiences of men and women farmers across eastern and southern Africa who have been associated with the Sustainable Intensification of Maize-Legume Systems for Food Security in Eastern and Southern Africa (SIMLESA) project. The inspiring and moving accounts tell the story of how these farmers have bravely embraced change to improve their farming methods and consequently the lives and livelihoods of their families.

The maize-growing regions of southern and eastern Africa face many challenges, including lower than average yields, crop susceptibility to pests and diseases, and abiotic stresses such as droughts that can be frequent and severe. There is also widespread lack of access to high-yielding stress resilient improved seed and other farming innovations, presenting a need for scalable technologies, adapted to farmers’ growing conditions.

Maize is the most important staple crop in the region, feeding more than 200-300 million people across Africa and providing food and income security to millions of smallholder farmers. Prioritization of cost reducing, yield enhancing and resource conserving farming methods is vital to catalyze a shift towards sustainable and resilient maize agri-food systems. Conservation agriculture (CA) is one promising approach.

Launched in 2010, SIMLESA is led by the International Maize and Wheat Improvement Center (CIMMYT) and funded by the Australian Center for International Agricultural Research (ACIAR). The project supports farmers and partner organizations to achieve increased food production while minimizing pressure on the environment by using smallholder farmers’ resources more efficiently through CA approaches. SIMLESA is implemented by national agricultural research systems, agribusinesses and farmers in partner countries including, Ethiopia, Kenya, Malawi, Mozambique, Rwanda, Tanzania and Uganda.

The farmers’ words in this book drive home the core philosophy of SIMLESA: that critical paradigm shifts in smallholder farming are possible and can lead to positive and potentially lasting impacts.

The candid accounts of the benefits yielded from adopting new practices like CA are a testimony to this idea: “Now we have seen with our own eyes these new methods are beneficial, and we want to continue what we are doing….my field is a school where others can learn,” said Maria Gorete, a farmer in Mozambique.

Policy makers and scientists from eastern and southern Africa met in Uganda at a regional forum convened by the Association for Strengthening Agricultural Research in Eastern and Central Africa (ASARECA), on 3-4 May 2019. The forum discussed ways to scale up the learnings of SIMLESA and a joint communique recommending policy actions was signed by the Ministers of Agriculture of the Republic of Burundi, the Republic of the Congo, the Democratic Republic of Congo, the State of Eritrea, the Federal Democratic Republic of Ethiopia, the Republic of Kenya, the Republic of Madagascar, the Republic of Rwanda, the Republic of South Sudan, the Republic of the Sudan, the United Republic of Tanzania, the Republic of Uganda, the Republic of Malawi and the Republic of Mozambique of the high level Ministerial Panel on Sustainable Intensification of Maize-Legume Cropping Systems for Food Security in Eastern and Southern Africa (SIMLESA).

Sustainable Intensification of Maize-Legume Systems for Food Security in Eastern and Southern Africa (SIMLESA)

Written by Rodrigo Ordóñez on March 28, 2019. Posted in Uncategorized.

The Sustainable Intensification of Maize-Legume Systems for Food Security in Eastern and Southern Africa (SIMLESA) program aims to improve maize and legume productivity by 30 percent and to reduce the expected downside yield risk by 30 percent on approximately on approximately 650,000 farm households by 2023. Launched in 2010, the focal countries of program research are Australia, Botswana, Burundi, Ethiopia, Kenya, Malawi, Mozambique, Tanzania, South Sudan, Uganda, Rwanda, Zambia and Zimbabwe.

The main thrust of the SIMLESA program is increasing farm-level food security, productivity and incomes through promotion of maize-legume intercropping systems in the context of reduced climate risk and change.

The program has also laid the foundation for developing conservation agriculture based sustainable intensification options, including integration of improved maize and legume varieties identified for their compatibility with CA-based practices; promoting technology adoption by both female and male farmers; capacity building for national agricultural research systems of partner countries; creating enhanced partnerships and collaboration with established innovation platforms for coordinated scaling-out of SIMLESA-generated options and practices.

Funding Institutions: Australian Centre for International Agricultural Research (ACIAR)

Partners: National agricultural systems of Ethiopia, Kenya, Malawi, Mozambique and Tanzania, as well as international and local research centers, extension agencies, non-governmental organizations, universities and agribusinesses along the value chain.

Read the final report of the SIMLESA project

African ambassadors to Zimbabwe support improved agriculture technologies

Written by on May 30, 2016. Posted in News.

HARARE — Several African nation ambassadors to Zimbabwe pledged to step up support for improved agriculture technologies during a visit to The International Maize and Wheat Improvement Center’s (CIMMYT) Southern Africa Regional Office (CIMMYT-SARO) in Harare, Zimbabwe, in April.

The special field day and meeting, held as part of CIMMYT 50 celebrations, gave ambassadors from 12 African countries (Algeria, Botswana, Democratic Republic of Congo, Ethiopia, Namibia, Nigeria, Sudan, South Sudan, Tanzania, Uganda, South Africa and Zambia) the opportunity to learn about CIMMYT projects that are helping to strengthen food systems in sub-Saharan Africa and discuss future initiatives.

During the visit, the need to develop policies that promote smallholder farmers’ access to technologies that enable them to increase yields and improve crop resilience in the face of challenges such as droughts, as well as policies to address poverty, food security and economic growth surfaced as main priorities for the countries represented.

African ambassadors learned about CIMMYT-promoted agricultural technologies while visiting the CIMMYT-Southern Africa Regional Office (CIMMYT-SARO) in Harare, Zimbabwe. Photo: Johnson Siamachira/CIMMYT

In his welcome address, Mulugetta Mekuria, CIMMYT-SARO regional representative, pointed out, “Sub-Saharan Africa’s food security faces numerous challenges, but drought is the most devastating because our farmers rely on rainfed agriculture. As you will see, CIMMYT’s work has created high-level impacts. But a host of challenges still hamper socioeconomic growth, such as reduced funding of agricultural research.”

According to Mekuria, CIMMYT’s work in sub-Saharan Africa aims to ensure farmers can access improved maize seed with drought tolerance and other relevant traits that contribute to higher, more stable yields, as well as technologies such as optimal fertilizer application. He noted that farmers in sub-Saharan African countries lag behind other regions in fertilizer application, applying, on average, less than 10 kg per hectare, which is 10 percent of the world average.

Another issue brought up was the lack of funding of agricultural research for development by most bilateral agencies on which African governments depend. The diplomats pledged to advise their governments of the need to increase support for improved agricultural technologies. They agreed that funding agricultural research work in line with the 2006 Abuja Declaration to allocate at least 1 percent of the donor country’s gross domestic product to agricultural research is of the utmost importance. Enhancing access to markets, extension services and inputs and supporting women and youth in agriculture were also identified as fundamental policy issues that need to be urgently addressed. Strong partnerships and collaborative efforts between various African governments, CIMMYT and the private sector were also called for.

The ambassadors were briefed on CIMMYT’s achievements in the region, and how, in partnership with national agricultural research systems and private seed companies, they have released more than 200 drought-tolerant maize varieties that perform significantly better under moderate drought conditions than varieties already on the market, while yielding the same – or better – in a normal season. More than 6 million farmers in sub-Saharan Africa grow improved drought tolerant maize varieties developed by CIMMYT and partners.

A wide range of CIMMYT-SARO technologies were also showcased, including sustainable intensification strategies based on the principles of conservation agriculture. Compared to conventional cropping practices, conservation agriculture increases yields after two to five cropping seasons due to the combined benefits of minimum soil disturbance, crop residue retention and crop rotation. Conservation agriculture has been successfully promoted in Malawi, Mozambique, Zambia and Zimbabwe for the past 10 years. For example, yield increases of 20-60 percent were recorded in trials in farmers’ fields in Malawi, while in Zambia and Zimbabwe, yields increased by almost 60% using animal traction innovation agriculture technologies.

Other technologies demonstrated were pro-vitamin A maize and quality protein maize. The diplomats learned that CIMMYT had released eight pro-vitamin A hybrids with 28% more vitamin A content in Zambia (4), Malawi (3) and Zimbabwe (1). On improved varieties, CIMMYT sent 823 seed shipments (1.3 million envelopes) to 835 institutions worldwide over the last four years.

“The success of our projects goes beyond the breeding work. Through the value chain approach, our work now is to ensure that seed companies and, ultimately, maize farmers benefit from the seed that is developed with their needs in mind. Getting drought-tolerant maize and other improved seeds to the markets and farmers is a critical next step,” said James Gethi, CIMMYT seed systems specialist.

MLN diagnostics and management in Africa through multi-institutional synergies

Written by on May 9, 2015. Posted in News.

Maize Lethal Necrosis (MLN) disease has continued to wreak havoc on maize production in East Africa since it was first reported in Kenya in 2011, and since then reported in the Democratic Republic of the Congo, Ethiopia, Rwanda, Tanzania, South Sudan and Uganda. The disease, caused by a combination of the Maize Chlorotic Mottle Virus (MCMV) and Sugarcane Mosaic Virus (SCMV), causes irreversible damage that kills maize plants before they can grow and yield grain. MLN pathogens can be transmitted not only by insect vectors but also through contaminated seed. The epidemic is exacerbated by lack of MLN-resistant maize varieties and year round cultivation of maize in many areas in eastern Africa, enabling the build-up of virus inoculum and allowing transmission via insect vectors. For this reason, CIMMYT scientists Monica Mezzalama, Biswanath Das, and B.M. Prasanna have developed a brochure “MLN Pathogen Diagnosis, MLN-free Seed Production and Safe Exchange to Non-Endemic Countries” for providing important information on these key areas to stakeholders, especially seed companies and regulatory agencies operating in both MLN-affected as well as MLN non-endemic countries.

“MLN is an increasing regional threat to food security in sub-Saharan Africa, and must be tackled with concerted effort from all actors in order to safeguard the maize seed sector and protect the livelihoods of smallholder farmers,” said Prasanna. The brochure proposes several key steps to curb the spread of MLN, through MLN diagnostics, production of MLN-free seed, and safe exchange to MLN-endemic countries. The brochure also advises on appropriate agronomic practices that can prevent disease incidence in seed production fields.

An International Conference on “MLN Diagnostics and Management in Africa” will be organized jointly by AGRA (Alliance for Green Revolution in Africa) and CIMMYT during 12-14 May in Nairobi, Kenya, in order to review the present status of MLN incidence and impacts in sub-Saharan Africa (SSA), controlling seed transmission of MLN, managing seed production in MLN-endemic countries, creating awareness about MLN diagnostic protocols, and identifying ways to strengthen MLN diagnostics capacity in SSA, among other topics.

Maize lethal necrosis: a serious threat to food security in eastern Africa and beyond

Written by on May 7, 2015. Posted in Features.

MLN_WS_participants_w — Participants are shown how to inspect maize fields for MLN symptoms and how to collect samples for laboratory analysis.

Maize lethal necrosis (MLN) has rapidly emerged as one of the deadliest maize diseases in eastern Africa capable of causing complete yield loss under heavy disease pressure. This means that Kenya and neighboring countries which largely depend on maize as their main staple food and source of income are on the verge of a looming food and economic crisis.

The disease is difficult to control for two reasons: firstly, it is caused by a combination of viruses; secondly, it can be spread through seed and by insect vectors that may be carried by wind over long distances. Affected crops suffer various symptoms such as severe stunting, tassel abnormality, small ears with poor seed set, chlorotic leaf mottling, leaf necrosis and premature plant death.

Much more than CIMMYT and East Africa

Sixty phytosanitary regulators and seed industry scientists from 11 countries in eastern and southern Africa attended an MLN diagnostics and screening workshop from March 17–19, 2015, in Naivasha, Kenya. The objective of the workshop was to train scientists on the latest MLN diagnostics and screening methods and to share knowledge on how to control the spread of MLN. Besides DR Congo, Ethiopia, Kenya, Rwanda and Tanzania where the disease has been reported, other participants were from South Sudan and southern Africa (Malawi, Mozambique, South Africa, Zambia and Zimbabwe) that have no confirmed cases of MLN, but where maize is an important crop.

CIMMYT organized the workshop in response to the high demand for development of appropriate diagnostics methods and harmonization of regional protocols. Hence, facilitation by agencies like the Food and Agricultural Organization provided a much-needed regional overview of the MLN threat, in addition to perspectives from the International Centre of Insect Physiology Ecology and the Kenya Plant Health Inspectorate Services (KEPHIS) on MLN insect vectors and diagnostics methods respectively.

The workshop was conducted at the MLN screening facility in Naivasha, the largest of its kind established in response to the MLN outbreak in eastern Africa in 2013. It supports countries in the sub-Saharan region to screen seeds under artificial inoculation. The facility is managed jointly by the Kenya Agricultural and Livestock Research Organization (KALRO) and CIMMYT, and was established with support from the Bill & Melinda Gates Foundation and the Sygenta Foundation for Sustainable Agriculture. Biswanath Das, a maize breeder at CIMMYT, noted that “the site has evaluated more than 20,000 accessions since its inception in 2013 from over 15 multinational and national seed companies and national research programs.” This, he added, “has become a primary resource in the fight against MLN regionally.”

Collective pre-emptive actions for prevention: seeds of hope
Participants received hands-on training to identify symptoms of MLN-causing viruses and how to score disease severity by screening germplasm at the site. For some participants, this was a first. “This is my first time to see an MLN-infected plant. Now I understand the impact of MLN on maize production and the need to set up a seed regulatory facility. South Sudan has no laboratory to test planting materials. My first step will be to talk to my counterparts in the ministry to set up one,” said Taban James, a regulator from the Ministry of Agriculture in South Sudan.

CIMMYT staff demonstrate DAS–ELISA method used for detecting MLN-causing viruses.

The tragic reality is that almost all commercial maize varieties in East Africa are highly susceptible to MLN, based on evaluations done at the screening facility. Therefore, stronger diagnostic and sampling capacity at common border-points was agreed to be a key step towards controlling inadvertent introduction of MLN through contaminated seeds. This was particularly important for participants from southern Africa countries who noted an urgent need for surveillance at seed import ports and border areas to contain the spread.

Currently, Kenya, Uganda and Zimbabwe are the only countries that require imported seed to be certified as free of MLN-causing viruses. KEPHIS and CIMMYT have worked closely to restrict movement of germplasm from Kenya to countries in East Africa with reported MLN cases. Seed production fields are inspected thrice by KEPHIS, in addition to analysis of final seed lots. Plans are underway for CIMMYT in collaboration with the ministries of agriculture in Mexico and Zimbabwe to establish quarantine sites to ease germplasm movement in and out of these countries. Speaking on KEPHIS’ role, Francis Mwatuni, the officer-in-charge of Plant Quarantine and Biosecurity Station said, “We ensure all seed fields are inspected and samples tested for MLN resistance including local and imported seed lots from seed companies, to ensure that farmers get MLN-free seeds.”

The latest trends and options for diagnostics on MLN-causing viruses were covered as well, giving participants hands-on training using ELISA diagnostics systems. They were also briefed on polymerase chain reaction based diagnostics and the latest lateral flow diagnostic kits that are under development that will enable researchers to obtain diagnostic results in the field in minutes.

What next for MLN?
The rapid multiplication of the disease coupled with uncertainties over its spread is the biggest hurdle that scientists and other stakeholders are grappling with. KALRO Chief Researcher, Anne Wangai, who played a key role in discovering the disease in Kenya in 2011 observes that “The uncertainties over the transmission of MLN is a worrying phenomenon that requires stakeholders to urgently find a control point to manage and ensure seeds being given to farmers are MLN-free.”

Breeding remains a key component in the search for long-term solution for MLN, and several milestones have been covered to develop MLN-resistant varieties in East Africa. “CIMMYT has developed five hybrids with good MLN tolerance under artificial inoculation, which have either been released or recommended for release in Kenya, Uganda and Tanzania. Thirteen hybrids are currently under national performance trials in the three countries,” noted Mosisa Regasa, a maize seed system specialist at CIMMYT. He further added that it is critical for the MLN-tolerant hybrids to also have other traits important to farmers, so farmers accept these new hybrids.

Open information sharing forums like the diagnostics workshop are an important step to raise awareness and seek solutions to manage the disease. Sharing best practice and lessons learnt in managing the disease are major steps towards curbing MLN. In pursuit of this end, a major international conference on MLN opens next week.

Links: Slides from the workshop | Workshop announcement |Open call for MLN screening – May 2015

Scientists from SIMLESA Spillover countries visit Kenya

Written by on August 14, 2012. Posted in News.

A delegation of scientists from South Sudan, Rwanda, and Uganda —the spillover countries of the Sustainable Intensification of Maize-Legume Systems for Food Security in Eastern and Southern Africa (SIMLESA) initiative— visited Embu, Kenya, during 18-20 July 2012, to gain hands-on experience in implementing the program and to learn about its impact on livelihoods of smallholder farmers.

The delegation comprised Leonidas Dusengemungu, Albert Ruhakana, and Alphonse Nyobanyire from Rwanda; Luka Atwok, Anna Itwari, and Cirino Oketayoyt from South Sudan; and Drake N. Mubiru, William Nanyenya, and Godfrey Otim from Uganda. The scientists found the visit very educative and informative. They learned about the implementation of SIMLESA in Kenya and the role of national agricultural research institutions, the Kenya Agricultural Research Institute (KARI) in particular, in the process. They also gained insights into the innovation platform establishment and arising challenges, maize-beans intercropping and timing, challenges and coping strategies for the implementation of SIMLESA, and the level of adaptation of SIMLESA technologies in Kenya.

In his introductory remarks, Stephen Njoka, KARI-Embu Center Director, explained the Center’s mandate, activities, opportunities, and challenges in conducting agricultural research in Kenya. He noted that research programs at KARI-Embu range from food crops and crop health, natural resource management, horticultural and industrial crops, animal production and health research, outreach and partnerships, to cross-cutting programs, such as socioeconomics and applied statistics. The Center also offers advisory services, such as technical support for partners and capacity development for other service providers, including extension service providers and NGOs. Alfred Micheni, KARI Agronomist and SIMLESA Site Coordinator for eastern Kenya, explained that the western and eastern sites in Kenya had been selected because of their potential for the highest impact. This was determined by their agricultural production constraints: low soil fertility, erratic rainfall, high cost of farm inputs, high incidences of pests and diseases, high cost of credit, and small land sizes.

The scientists had a chance to interact with farmers participating in SIMLESA during a farmers’ field day in Kyeni Division, Embu County, on 20 July 2012. The field day was hosted by the Kyeni Innovation Platform and showcased various treatments under conservation agriculture (CA): maize-legume intercrop, minimum tillage, furrows and ridges, use of herbicides, residue retention, and variety selection. The scientists also had the opportunity to compare the robust crops under CA with those under conventional agricultural practices which were unable to cope with the prolonged drought in the region.

Charles Nkonge, SIMLESA National Coordinator, stressed the importance of the innovation platforms used by the program to evaluate and scale out maizelegume intensification technologies and knowledge in a participatory manner. Other strategies for scaling out include farmer exchange visits and participatory exploratory demonstrations. Nkonge stressed the importance of the participatory nature of the evaluations; through cooperation between the farmers and other collaborators, experimental designs of some of the treatments were adjusted to achieve more efficiency. For instance, the design of maize-pigeon pea intercropping trial was changed from intercropping of one pigeon-pea row between two rows of maize, giving one crop of maize and pigeon pea per season, to five rows of maize between two rows of pigeon pea and one row of common beans between two rows of maize. With the new design, two crops of maize, two crops of beans, and one crop of pigeon pea are harvested every year. This demonstration of successful practices allowed the representatives from SIMLESA Spillover countries to leave Kenya feeling optimistic about the new partnership.

SIMLESA spills over into South Sudan

Written by on June 22, 2012. Posted in News.

South Sudan, Africa’s newest country, is set to benefit from the project “Sustainable Intensification of Maize-Legume Cropping Systems in Eastern and Southern Africa” (SIMLESA), following fruitful discussions between project representatives and South Sudan’s Ministry of Agriculture and Forestry (MoAF). Project coordinator Mulugetta Mekuria and agronomist Fred Kanampiu met with George Leju, Director General of Research, Training, and Extension Services, Cirino Oketayot, Executive Director of Research, and Luka Atwok, maize breeder, in Juba on 6 June 2012. Mekuria gave an overview of the project’s vision, focus, and accomplishments to date and explained how SIMLESA’s experiences can reach and benefit South Sudan. The opportunity for collaboration was first discussed in Rwanda in October 2011 and since then Atwok has attended a series of SIMLESA-organized trainings and workshops.

Leju welcomed the proposal and thanked CIMMYT and the Australian Center for International Agricultural Research (ACIAR, which funds the project) for considering South Sudan as a beneficiary of the work. “SIMLESA resonates well with the MoAF strategic plan as it addresses the core challenges of the country, which has emerged from war,” said Leju. Oketayot highlighted South Sudan’s research structure, current priorities, challenges, and areas that need support, including an urgent need for capacity building. He also emphasized the importance of maize and legumes in the country’s farming systems and the potential impact of SIMLESA on these systems.

“ACIAR has availed initial funding for spillover activities,” said Mekuria. “The idea is to ensure that SIMLESA research results are quickly scaled out to countries like South Sudan and improve food security there.”

South Sudan scientists will join SIMLESA capacity building activities, attending core country and regional training events. “The project will also facilitate their travel to target country sites for activities like field days, so they get first-hand experience,” said Kanampiu. The first such capacity building initiative is planned for August this year, when CIMMYT will hold a workshop on basic agricultural research design and implementation. In addition to a very productive meeting, Leju and Oketayot were also delighted to receive an information pack full of background on SIMLESA, as well as shirts and baseball caps.