funder_partner: CGIAR Research Program on Maize (MAIZE)

The CGIAR Research Program on Maize (MAIZE) is an international collaboration between more than 300 partners that seeks to mobilize global resources in maize research and development to achieve a greater strategic impact on maize-based farming systems in Africa, Latin America and South Asia.

Led by the International Maize and Wheat Improvement Center (CIMMYT), with the International Institute of Tropical Agriculture (IITA) as its main CGIAR partner, MAIZE focuses on increasing maize production for the 900 million poor consumers for whom maize is a staple food in Africa, Latin America and South Asia. MAIZE’s overarching goal is to double maize productivity and increase incomes and livelihood opportunities from sustainable maize-based farming systems.

MAIZE receives funding support from CGIAR Trust Fund contributors.

https://maize.org/

MAIZE Flagship Projects (FPs) and Cluster of Activities

FP1: Enhancing MAIZE’s R4D strategy for impact
• Foresight and targeting of R4D strategies
• Learning from M&E, adoption and impacts
• Enhancing gender and social inclusiveness
• Value chain analysis

FP2: Novel diversity and tools for improving genetic gains
• Informatics, database management and decision support tools
• Development of enabling tools for germplasm improvement
• Unlocking genetic diversity through trait exploration and gene discovery
• Pre-breeding: development of germplasm resources

FP3: Stress-tolerant and nutritious maize
• Climate resilient maize with abiotic and biotic stress tolerance
• Tackling emerging trans-boundary disease/pest challenges
• Nutritional quality and end-use traits in elite genetic backgrounds
• Precision phenotyping and mechanization of breeding operations
• Seed production research and recommendations
• Stronger maize seed systems

FP4: Sustainable intensification of maize-based systems
• Multi-scale farming system framework to better integrate and enhance adoption of sustainable intensification options
• Participatory adoption and integration of technological components
• Development and field-testing of crop management technologies
• Partnership and collaborations models for scaling

Ventura Oliveros Garcia holds a photograph of her father, Santos Oliveros, who was one of the maize farmers who donated seed to CIMMYT’s genebank in 1966-67. (Photo: E. Orchardson/CIMMYT)

Tracing maize landraces, 50 years later

Written by Carolyn Cowan on May 22, 2019. Posted in Features. 2 Comments on Tracing maize landraces, 50 years later

Maize is more than a crop in Mexico. While it provides food, feed and raw materials, it is also a bloodline running through the generations, connecting Mexico’s people with their past.

The fascinating diversity of maize in Mexico is rooted in its cultural and biological legacy as the center of origin of maize. Landraces, which are maize varieties that have been cultivated and subjected to selection by farmers for generations, retaining a distinct identity and lacking formal crop improvement, provide the basis of this diversity.

As with any cultural legacy, the cultivation of maize landraces can be lost with the passage of time as farmers adapt to changing markets and generational shifts take place.

Doctoral candidate Denisse McLean-Rodríguez, from the Sant’Anna School of Advanced Studies in Italy, and researchers from the International Maize and Wheat Improvement Center (CIMMYT) have undertaken a new study that traces the conservation and abandonment of maize landraces over the last 50 years in Morelos, Mexico’s second smallest state.

The study is based on a collection of 93 maize landrace samples, collected by Ángel Kato as a research assistant back in 1966-67 and stored in CIMMYT’s Maize Germplasm Bank. Researchers traced the 66 families in Morelos who donated the samples and explored the reasons why they abandoned or conserved their landraces.

Doctoral candidate Denisse McLean-Rodríguez (left) interviews maize farmer Roque Juarez Ramirez at his family home in Morelos to explore his opinions on landrace conservation. (Photo: E. Orchardson/CIMMYT)

Tracing landrace abandonment

In six cases, researchers were able to interview the original farmers who donated the samples to CIMMYT. In other cases, they interviewed their family members, most frequently the sons or daughters, or alternatively their grandchildren, siblings, nephews or widows.

The study reveals that maize landrace cultivation has diminished significantly within the families. Only 13 of the 66 families are still cultivating the same maize seed lots as in 1966-67 and there was consensus that the current social, economic and physical environments are unfavorable for landrace cultivation.

Among the reasons for abandonment are changes in maize cultivation technologies, shifting markets for maize and other crops, policy changes, shifting cultural preferences, urbanization and climate change.

“By finding out about landrace continuity in farmers’ fields and the factors driving change, we were able to better understand the context in which these landraces are currently cultivated,” said McLean-Rodríguez. “Our study also allowed us to evaluate the importance of ex situ conservation in facilities like CIMMYT’s Germplasm Bank.”

Juarez and Oliveros’s grandson shows the family’s heirloom maize: maíz colorado (left) and Ancho maize. (Photo: E. Orchardson/CIMMYT)

Maize biodiversity conservation

Maize landraces can be conserved “in situ” in farmers’ fields and “ex situ” in a protected space such as a germplasm bank or community seed bank.

“These conservation strategies are complementary,” explained McLean-Rodríguez. “Ex situ conservation helps to secure landraces in case of unpredictable conditions that threaten their conservation in the field, while in situ cultivation allows the processes that generated maize’s diversity to continue, allowing the emergence of mutations and the evolution of new potentially beneficial traits.”

The loss of landraces in farmers’ fields over 50 years emphasizes the importance of ex situ conservation. CIMMYT’s Maize Germplasm Bank holds 28,000 samples of maize and its wild relatives from 88 countries, spanning collections dating back to 1943. Safeguarded seed stored in the Germplasm Bank is protected from crises or natural disasters, and is available for breeding and research. Traits found in landraces can be incorporated into new varieties to address some of the world’s most pressing agriculture challenges like changing climates, emerging pests and disease, and malnutrition.

McLean-Rodríguez recalls an aspect of the study that she found particularly rewarding: “Many of the families who had lost their landrace for one reason or another were interested in receiving back samples of their maize from the CIMMYT Germplasm Bank. Some were interested due to personal value, while others were more interested in the productive value. They were very happy to retrieve their maize from the Germplasm Bank, and it would be very interesting to learn whether the repatriated seed is cultivated in the future.”

A family tradition

One of the families to take part in the study was farmer Roque Juarez Ramirez and his wife, Ventura Oliveros Garcia, whose father was one of the donor farmers from Morelos. “I was so happy to hear the name of my father, [Santos Oliveros],” recalls Oliveros, remembering the moment McLean-Rodríguez contacted her. “He had always been a maize farmer, as in his day they didn’t cultivate anything else. He planted on his communal village land [ejido] and he was always able to harvest a lot of maize, many ears. He planted an heirloom variety of maize that we called arribeño, or marceño, because it was always planted in March.”

Juarez senses his responsibility as a maize farmer: “I feel that the importance [of maize farming] is not small, but big. We are not talking about keeping 10 or 20 people alive; we have to feed a whole country of people who eat and drink, apart from providing for our families. We, the farmers, generate the food.”

Filling vessels of champurrado, a Mexican maize-based sweet drink, and presenting samples of the family’s staple maize — maíz colorado and the Ancho landrace — Oliveros describes what maize means to her: “Maize is very important to my family and me because it is our main source of food, for both humans and animals. We use our maize variety to make pozole, tortillas, tamales, atole, quesadillas, picadas and many other foods.”

The Juarez-Oliveros family substituted the Ancho seed lot from Olivero’s father with another seed lot from the Ancho landrace obtained from her husband’s family. The Ancho landrace is used to make pozole, and continues to be widely cultivated in some municipalities of Morelos, including Totolapan, where the family resides. However, researchers found other landraces present in the 1966-67 collection, such as Pepitilla, were harder to trace 50 years later.

Maíz colorado (left), or red maize, is an important part of the family’s diet. The family’s Ancho maize (right) has characteristically wide and flat kernels, and is a key ingredient of the pozole stew. (Photo: E. Orchardson/CIMMYT)

The study shows that landrace abandonment is common when farming passed from one generation to the next. Older farmers were attached to their landraces and continued cultivating them, even in the face of pressing reasons to change or replace them. When the younger generations take over farm management, these landraces are often abandoned.

Nonetheless, young farmers still value the cultural and culinary importance of landraces. “Maize has an important traditional and cultural significance, and is fundamental to our economy,” said Isaac Juarez Oliveros, son of Roque and Ventura. “I have been planting [maize landraces] since I was around 15 to 20 years old. I got my maize seed from my parents. I believe it is important for families to keep planting their maize, as it has become tradition passed down through many generations.”

The family’s son, Isaac Juarez Oliveros, stands outside the maize storage room where they store and dry their harvested maize for sale and consumption. (Photo: E. Orchardson/CIMMYT)

The legacy for future generations

Global food security depends on the maintenance of high genetic biodiversity in such key staple food crops as maize. Understanding the causes of landrace abandonment can help to develop effective landrace conservation strategies. The authors suggest that niches for landrace conservation and even expansion can be supported in the same manner that niches have been created for improved maize and other commercial crops. Meanwhile, management of genetic resources is vital, both in the field and in germplasm banks, especially in developing countries where broader diversity exists.

For Oliveros, it is a matter of family legacy: “It means a lot to me that [my family’s seed] was preserved because it has allowed my family’s maize and my father’s memory to stay alive.”

“Farmers who cultivate landraces are providing an invaluable global public service,” state the authors of the study. “It will be key to encourage maize landrace cultivation in younger farmers. Tapping into the conservation potential of the current generation of farmers is an opportunity we should not miss.”

Read the full study:
The abandonment of maize landraces over the last 50 years in Morelos, Mexico: a tracing study using a multi-level perspective

Funding for this research was provided by the CGIAR Research Program on Maize (MAIZE), the Sant’Anna School of Advanced Studies and Wageningen University.

A special acknowledgement to the families, focus group participants and municipal authorities from the state of Morelos who kindly devoted time to share their experiences with us, on the challenges and rewards of maize landrace conservation.

Winners of the 2019 MAIZE Youth Innovators Awards – Africa receive their awards at the STMA meeting in Lusaka, Zambia. From left to right: Admire Shayanowako, Blessings Likagwa, Ismael Mayanja and Hildegarde Dukunde. Fifth awardee Mila Lokwa Giresse not pictured. (Photo: J.Bossuet/CIMMYT)

Winners of 2019 MAIZE Youth Innovators Awards – Africa announced

Written by Rodrigo Ordóñez on May 16, 2019. Posted in Press releases.

LUSAKA, Zambia (CIMMYT) – The CGIAR Research Program on Maize (MAIZE) officially announced the winners of the 2019 MAIZE Youth Innovators Awards – Africa at an awards ceremony held on May 9, 2019, in Lusaka, Zambia. These awards recognize the contributions of young women and men under 35 to innovation in African maize-based agri-food systems, including research for development, seed systems, agribusiness, and sustainable intensification. The awards, an initiative of MAIZE in collaboration with Young Professionals for Agricultural Research and Development (YPARD), were offered in three categories: farmer, change agent, and researcher.

The MAIZE Youth Innovators Awards aim to identify young innovators who can serve to inspire other young people to get involved in maize-based agri-food systems. This is the second year of the award, which was launched in 2018 with a first cohort of winners from Asia. Part of the vision is to create a global network of young innovators in maize based systems from around the world.

2019 award recipients were invited to attend the Stress Tolerant Maize for Africa (STMA) project meeting in Lusaka, May 7-9, where they had the opportunity to present their work. The project meeting and award ceremony also allowed these young innovators to network and exchange experiences with MAIZE researchers and partners. Looking forward, award recipients may also get the opportunity to collaborate with MAIZE and its partner scientists in Africa on implementing or furthering their innovations.

This year’s five awardees are:

Hildegarde Dukunde (Rwanda) – Category: Change Agent

Dukunde is a graduate in Human Nutrition and serves as a Sales Associate for Agrifood Business Consulting Ltd. She has been at the forefront of preventing aflatoxin contamination in Rwanda by helping smallholder farmers to access low-cost post-harvest equipment, namely DryCard™ and Purdue Improved Crop Storage (PICS) bags. The DryCard™ is an inexpensive device developed by University of California Davis researchers for determining if dried food is dry enough to prevent mold growth and aflatoxin contamination during storage and reducing post-harvest losses.

Mila Lokwa Giresse (Democratic Republic of the Congo) – Category: Change Agent

Giresse is the CEO of Mobile Agribiz. This company develops the Mobile Agribiz App, an innovative tool to enhance the pest and disease diagnostics of fall armyworm in maize. It uses artificial intelligence and machine learning to easily detect the pest across maize crops at any stage of the production cycle. The app aims to assist farmers, extension workers, and agribusinesses in democratic republic of Congo with early detection and accurate diagnosis. Through SMS and smart alert notifications, the Mobile Agribiz App provides farmers with constant reminders and real-time information on how to detect, manage, and address fall armyworm on maize.

Blessings Likagwa (Malawi) – Category: Farmer

Likagwa lives in Mtunthama, Malawi, where he works on his family’s farm. From a young age he has had an interest in farming and for the past eight years he has been involved in growing a variety of crops, especially maize and cassava. In the future he hopes to use his bachelor’s degree in Community Development and his interest in technology to help smallholder farmers in Malawi and Eastern Africa adapt to the challenges of climate change and rapid population growth. Since 2018, in collaboration with UNICEF and Kyoto University, he has investigated how drone technology can improve agricultural performance and benefit Malawi’s smallholders.

Ismael Mayanja (Uganda) – Category: Researcher

Mayanja is a 2019 graduate of Makerere University with a Bachelor of Science degree in Agricultural Engineering. He is currently assisting research at Makerere University to ascertain and quantify post-harvest losses associated with transportation of agricultural produce in the markets of Kampala district, Uganda. His primary research interest lies in post-harvest handling and technology, motivated by the reported 40% post-harvest loss of agricultural produce by farmers in sub-Saharan Africa. He developed a bicycle-powered maize cleaning machine to increase efficiency and reduce time dedicated to cleaning maize at several primary schools in Uganda.

Admire Shayanowako (Republic of South Africa) – Category: Researcher

Shayanowako is a researcher at the African Centre for Crop Improvement (ACCI) – University KwaZulu-Natal. His research focuses on the parasitic weed Striga, also known as witch weed, which causes severe crop losses to millions of small-scale African maize farmers. The goal of the project is to combine breeding for Striga resistance in maize with a soil fungus, Fusarium oxysporum f.sp. strigae (FOS) that is highly specific in its pathogenicity to Striga and acts as a biological control agent. The breeding approach aims to develop at least partial host resistance in open pollinated maize germplasms that are adapted to the semi-arid regions. When partial host resistance is augmented with biological control agent FOS, parasitic effects of Striga decline overwhelmingly. Currently, the breeding component of the research has embarked on identification of quantitative trait locus (QTL) controlling Striga resistance in maize through genomic based approaches.

For further information, contact:

Jennifer Johnson
Communications Officer, CGIAR Research Program on Maize (MAIZE)
Telephone: +52 (55) 5804 2004 ext. 1036
Email: j.a.johnson@cgiar.org

Foliar damage to maize leaves due to adult fall armyworm in Zimbabwe. (Photo: C. Thierfelder/CIMMYT)

New study identifies best agronomic practices to reduce fall armyworm damage

Written by Jennifer Johnson on April 22, 2019. Posted in News.

The fall armyworm, an invasive insect-pest native to the Americas, has caused significant damage to maize crops in sub-Saharan Africa since its arrival to the region in 2016. An integrated approach, including improved agronomic practices, is necessary in order to fight against the invasive caterpillar. However, little is known about the most effective agronomic practices that could control fall armyworm under typical African smallholder conditions. In addition, more information is needed on the impact of fall armyworm on maize yield in Africa, as previous studies have focused on data trials or farmer questionnaires rather than using data from farmer fields. In a new study published by researchers with the International Maize and Wheat Improvement Center (CIMMYT), investigators set out to understand the factors influencing fall armyworm damage and to quantify yield losses due to fall armyworm damage.

The study examined damage in smallholder maize fields in two districts of eastern Zimbabwe. “We estimated the yield losses due to fall armyworm damage at 11.57 percent in the study area. Extrapolated to the whole of Zimbabwe, this would amount to a loss of 200,000 tons of grain, or a value of more than $32 million using the average global price of maize of $163 per ton in 2018,” said Frederic Baudron, cropping systems agronomist at CIMMYT and main author of the study.

Practices such as infrequent weeding or planting on land that had previously been fallow were found to increase fall armyworm damage to maize — most likely because they increased the amount of fall armyworm host plants other than maize. Conversely, practices hypothesized to increase the abundance of natural enemies of fall armyworm — such as minimum and zero tillage or the application of manure and compost — were found to decrease fall armyworm damage. Intercropping with pumpkins was found to increase damage, possibly by offering a shelter to moths or facilitating plant-to-plant migration of the caterpillar. Fall armyworm damage was also higher for some maize varieties over others, pointing to the possibility of selecting for host plant resistance.

“Given the limited coverage of the study in terms of area and season, it would be interesting to replicate it all over the country through the involvement of governmental agricultural departments, so that we get the full picture around the fall armyworm problem at a larger scale,” said Mainassara Zaman-Allah, co-author of the study and abiotic stress phenotyping specialist at CIMMYT.

This study is unique in that it is the first to collect information on agronomic practices that can affect fall armyworm damage using data taken directly from smallholder farmer fields. “Many papers have been written on pest incidence-damage-yield relationships, but with researchers often having control over some of the potential sources of variation,” said Peter Chinwada, TAAT Fall Armyworm Compact Leader at the International Institute of Tropical Agriculture (IITA), another co-author of the study.

“Our study was driven by the desire to determine fall armyworm incidence-damage-yield relationships under typical African smallholder farmer conditions which are characterized by a diversity of cropping systems, planting dates and “pest management practices” that may have been adopted for purposes which have nothing to do with managing pests. Unravelling such relationships therefore requires not only institutional collaboration, but the meeting of minds of scientists from diverse disciplines.”

The results of the study suggest that several practices could be promoted to control fall armyworm in its new home of Africa. “Farmers have already been informed of the results by their extension agents; the NGO GOAL, present in Zimbabwe, shared the findings,” Baudron said. “The next step is to test some of the recommendations suggested in the paper to control fall armyworm such as good weed management, conservation agriculture, use of manure and compost, and stopping pumpkin intercropping. These approaches will need to be refined.”

This work was implemented by the International Maize and Wheat Improvement Center (CIMMYT), GOAL, and the University of Zimbabwe. It was made possible by the generous support of Irish Aid, Bakker Brothers and the CGIAR Research Program on Maize (MAIZE). Any opinions, findings, conclusion, or recommendations expressed in this publication are those of the authors and do not necessarily reflect the view of Irish Aid, Bakker Brothers and MAIZE.

Maize Doubled Haploid Production Services

Written by Rodrigo Ordóñez on March 29, 2019. Posted in Uncategorized.

CIMMYT provides a maize doubled haploid (DH) production service at cost to maize breeding programs in Africa and Latin America at its DH facilities in Kenya and Mexico.

This service reduces the time required to develop homozygous maize lines to just over one year, instead of three to seven years using more traditional inbreeding methods. This technology also results in better-quality maize lines: DH maize lines are 100% homozygous, whereas traditional inbreeding generates lines with only approximately 99.2% homozygosity. These advantages help breeders increase their rate of genetic gain: the rate at which the genetic potential of a crop increases in yield over time.

CIMMYT established centralized DH line production facilities for Africa at KALRO-Kiboko, Kenya. A similar facility is also in operation for Latin America at CIMMYT’s experimental station in Agua Fría, Mexico. Public and private sector organizations involved in maize breeding can access the DH production service by signing a DH service agreement.

Maize Lethal Necrosis Phenotyping Service

Written by Rodrigo Ordóñez on March 29, 2019. Posted in Uncategorized.

The CIMMYT-Kenya Agriculture and Livestock Research Organization (KALRO) Maize Lethal Necrosis (MLN) Screening Facility quarantine site is used to provide an MLN Phenotyping Service at cost to national agricultural research systems and seed companies in Africa.

KALRO and CIMMYT have been screening germplasm against MLN in Kenya since Nov 2012. The dedicated screening facility at KALRO Naivasha was established in 2013. This facility now represents a high quality phenotyping platform, permitting large-scale screening of germplasm from regional public and private partners.

To date, close to 90 percent of materials screened at Naivasha are susceptible under artificial inoculation. However, resistant and tolerant materials have been identified. Four first-generation MLN tolerant and resistant hybrids have been released in East Africa and a further 15-20 second generation hybrids are at advanced stages of testing.

Fall Armyworm Response

Written by Rodrigo Ordóñez on March 29, 2019. Posted in Uncategorized.

Following the recent emergence and rapid spread of the fall armyworm pest in Africa, the Fall Armyworm Response project is bringing together expert partners to develop and disseminate science-based recommendations to manage the pest.

Representatives from CIMMYT and UAS-Bangalore signed the collaboration agreement on February 18, 2019.

CIMMYT and UAS-Bangalore to establish a maize doubled haploid facility in Karnataka, India

Written by on March 20, 2019. Posted in Press releases.

KARNAKATA, India (CIMMYT) — The International Maize and Wheat Improvement Center (CIMMYT) and the University of Agricultural Sciences-Bangalore (UAS-Bangalore) have signed a collaboration agreement for establishing a maize doubled haploid (DH) facility at the Agricultural Research Station in Kunigal (ARS-Kunigal), Tumkur district, Karnataka state, India.

CIMMYT will establish and operate the maize DH facility, including field activities and the associated laboratory. Occupying 12 acres of land, the facility is estimated to produce at least 30,000 DH lines a year. CIMMYT hopes the facility to be operational by the last quarter of 2019.

The maize DH facility, funded by the CGIAR Research Program on Maize (MAIZE), fulfills a very important requirement of the region. It has the potential to accelerate maize breeding and hybrid development and significantly increase genetic gains through maize breeding in Asia. During the 13^th Asian Maize Conference in Ludhiana, India (October 8-10, 2018), several partners — including the Indian Institute of Maize Research (ICAR-IIMR) — emphasized the urgent need for a state-of-the-art maize DH facility that could serve breeding programs across Asia.

“This is indeed a major landmark for maize breeding, especially in the public sector, not only in India, but also in Asia,” said B.M. Prasanna, Director of CIMMYT’s Global Maize Program and the CGIAR Research Program on Maize (MAIZE). “The facility will provide maize DH development services, not only for the maize breeding programs of CIMMYT and UAS-B, but also for national agricultural research system institutions and small and medium-sized seed companies engaged in maize breeding and interested to pursue DH-based advanced maize breeding strategies in Asia. DH technology, in combination with molecular marker-assisted breeding, can significantly increase genetic gains in maize breeding.”

“The maize doubled haploid facility … will be the first of its kind in the public domain in Asia,” said S. Rajendra Prasad, Vice Chancellor of UAS-Bangalore. “The work done at this facility will certainly benefit the farmers of the state, country and the Asian region, by accelerating maize breeding and improving efficiencies.”

The signing of the collaboration agreement took place on February 18, 2019 at UAS-Bangalore’s campus in Bengaluru. CIMMYT was represented by B.M. Prasanna and BS Vivek, Senior Maize Breeder. UAS-Bangalore was represented by S. Rajendra Prasad; Mahabaleshwar Hegde, Registrar, and Y.G. Shadakshari, Director of Research.

The benefits of doubled haploid technology

DH maize lines are highly uniform, genetically pure and stable, and enable significant saving of time and resources in deriving parental lines, which are building blocks of improved maize hybrids.

Over the last 12 years, CIMMYT has worked intensively on optimizing DH technology for the tropics. Researchers released first-generation tropicalized haploid inducers in 2012, and second-generation tropicalized haploid inducers in 2017, in partnership with the University of Hohenheim, Germany. In 2017, CIMMYT developed more than 93,000 maize DH lines from 455 populations, and delivered them to maize breeders in Africa, Asia and Latin America.

INTERVIEW OPPORTUNITIES:

B.M. Prasanna – Director of CIMMYT’s Global Maize Program and the CGIAR Research Program on Maize (MAIZE).

FOR MORE INFORMATION, CONTACT THE MEDIA TEAM:

Jennifer Johnson – Maize Communication Officer, CIMMYT. J.A.JOHNSON@cgiar.org, +52 (55) 5804 2004 ext. 1036.

Maize infected with the fungus Aspergillus flavus, causing ear rot and producing aflatoxins. (Photo: George Mahuku/CIMMYT)

New publications: Biofortification of maize with provitamin A can reduce aflatoxin load

Written by Carolyn Cowan on March 20, 2019. Posted in Publications.

New research evidence could have significant implications for breeding approaches to combat harmful aflatoxin contamination in maize while simultaneously contributing to alleviate vitamin A deficiency. The study “Provitamin A Carotenoids in Grain Reduce Aflatoxin Contamination of Maize While Combating Vitamin A Deficiency” is the first published report to document how biofortification with provitamin A can contribute to reduce aflatoxin contamination in maize.

Aflatoxins are harmful compounds that are produced by the fungus Aspergillus flavus, which can be found in the soil, plants and grain of a variety of legumes and cereals including maize. Toxic to humans and animals, aflatoxins are associated with liver and other types of cancer, as well as with weakened immune systems that result in increased burden of disease, micronutrient deficiencies, and stunting or underweight development in children.

Efforts to breed maize varieties with resistance to aflatoxin contamination have proven difficult and elusive. Contamination of maize grain and products with aflatoxin is especially prevalent in low- and middle-income countries where monitoring and safety standards are inconsistently implemented.

Biofortification also serves to address “hidden hunger,” or micronutrient deficiency. Over two billion people are affected globally — they consume a sufficient amount of calories but lack essential micronutrients such as vitamins and minerals. Vitamin A deficiency specifically compromises the health of millions of maize consumers around the world, including large parts of sub-Saharan Africa.

Provitamin A-enriched maize is developed by increasing the concentration of carotenoids — the precursors of vitamin A — and powerful antioxidants that play important roles in reducing the production of aflatoxin by the fungus Aspergillus flavus. The relative ease of breeding for increased concentrations of carotenoids as compared to breeding for aflatoxin resistance in maize make this finding especially significant as part of a solution to aflatoxin contamination problems.

Breeding of provitamin A-enriched maize varieties is ongoing at the International Maize and Wheat Improvement Center (CIMMYT) and the International Institute of Tropical Agriculture (IITA), with the support of HarvestPlus. Several varieties trialed in sub-Saharan Africa have demonstrated their potential to benefit vitamin-deficient maize consumers.

The researchers highlight the potential in breeding maize with enhanced levels of carotenoids to yield the dual health benefits of reduced aflatoxin concentration in maize and reduced rates of vitamin A deficiency. This result is especially significant for countries where the health burdens of exposure to aflatoxin and prevalence of vitamin A deficiency converge with high rates of maize consumption.

Read the full study here: https://www.frontiersin.org/articles/10.3389/fpls.2019.00030/full

Financial support for this study was partially provided by HarvestPlus, a global alliance of agriculture and nutrition research institutions working to increase the micronutrient density of staple food crops through biofortification. The views expressed do not necessarily reflect those of HarvestPlus. The CGIAR Research Program on Maize (MAIZE) also supported this research.

This research builds on the Ph.D. dissertation of Dr. Pattama Hannok at University of Wisconsin, Madison, WI, United States (Hannok, 2015).

Researchers and friends recall John Mihm, former CIMMYT maize entomologist

Written by Mike Listman on January 29, 2019. Posted in News.

*John Mihm working at CIMMYT in the 1980s.*

The community of the International Maize and Wheat Improvement Center (CIMMYT) joins former colleagues of John A. Mihm, CIMMYT’s maize entomologist during the 1970s-90s, in honoring his memory and valuable work. John passed away on January 25, 2019, at the age of 72.

Special maize populations developed by Mihm and his CIMMYT contemporaries are critical in today’s global quest for new maize varieties to resist the fall armyworm (Spodoptera frugiperda), according to B.M. Prasanna, director of the CIMMYT Global Maize Program and the CGIAR Research Program on Maize.

“The insect-resistant maize germplasm developed by Mihm is proving an invaluable resource in our fight against this pest, underpinning progress in the development of resistant varieties,” said Prasanna.

Crop entomologists were laboriously placing young insect larvae onto plants in greenhouses and in the field until 1976, when Mihm developed the “bazooka.” A plastic tube with a valve that quickly and easily delivered a uniform mixture of corn grits and insect larvae into individual maize plants, the innovation allowed researchers to infest hundreds of plants in a single morning.

Originally from the Americas, fall armyworm has caused major damage to maize crops in Africa since 2016. The pest is now spreading rapidly in Asia, with incidence on maize crops confirmed in India, Bangladesh, Sri Lanka, Myanmar, Thailand, and southern China.

“Without proper controls, fall armyworm could reduce maize grain harvests in Africa alone by an amount worth as much as US$4.6 billion,” Prasanna explained, citing a 2018 report from the Centre for Agriculture and Biosciences International (CABI).

With support from UNDP, Mihm greatly refined CIMMYT practices to rear larvae of maize insect pests and to apply them efficiently so that researchers could identify resistant plants and use them to breed elite, resilient varieties.

After leaving CIMMYT in 1994, Mihm worked for the U.S. company “French Agricultural Research” in studies on sources of resistance in maize to corn rootworm (Diabrotica spp). He eventually retired happily to his farm in Minnesota, according to Florentino Amasende, a former CIMMYT field assistant who was a close friend and colleague of Mihm.

“John was a friend, a mentor and even a father figure for me,” said Amasende, who with support from Mihm for his university studies rose to seed production specialist in leading seed companies. “My family and I are eternally grateful for the opportunities he gave me.”

Call for nominees for the 2019 Maize Youth Innovators Awards – Africa

Written by on January 28, 2019. Posted in News.

Nominations are now open for the 2019 MAIZE Youth Innovators Awards – Africa! These awards are part of the efforts that the CGIAR Research Program on Maize (MAIZE) is undertaking to promote youth participation in maize-based agri-food systems. These awards recognize the contributions of young women and men below 35 years of age who are implementing innovations in African maize-based agri-food systems, including research for development, seed systems, agribusiness, and sustainable intensification.

Young people are the key to ensuring a food-secure future and agricultural sustainability. However, rural youth face many challenges related to unemployment, underemployment and poverty. According to the Food and Agriculture Organization (FAO) of the United Nations, facilitating young people’s participation in agriculture has the potential to drive widespread rural poverty reduction among young people and adults alike. In Africa, where over 300 million smallholder-farming families grow and consume maize as a staple crop, the human population stands at 1.2 billion people, 60 percent of whom are below the age of 25.

The MAIZE Youth Innovators Awards aim to identify young innovators who can serve to inspire other young people to get involved in maize-based agri-food systems. Part of the vision is to create a global network of young innovators in maize-based systems from around the world.

Award recipients will be invited to attend the annual Stress Tolerant Maize for Africa (STMA) project meeting in Lusaka, Zambia, from May 7 to May 9, where they will receive their awards and will be given the opportunity to present their work. The project meeting and award ceremony will also allow these young innovators to network and exchange experiences with MAIZE researchers and partners. Award recipients may also get the opportunity to collaborate with MAIZE and its partner scientists in Africa on implementing or furthering their innovations.

MAIZE invites young innovators to apply and CGIAR researchers and partners to nominate eligible applicants for any of the following three categories:

Researcher: Maize research for development (in any discipline)
Farmer: Maize farming systems in Africa
Change agent: Maize value chains (i.e., extension agents, input and service suppliers, transformation agents, etc.)

We ask nominators/applicants to take into account the following criteria and related questions:

Novelty and innovative spirit: To which specific novel findings or innovation(s) has this young person contributed? (in any of the three categories mentioned above)
Present or potential impact: What is the present or potential benefit or impact of the innovation(s) in maize-based agri-food systems?

Applications should be submitted online through this form by March 15, 2019.

Key dates:

Opening date for nominations: January 21, 2019
Closing date for nominations: March 15, 2019 (Please note: Nominations received after the closing date will not be considered)
Notification of winners: March 22, 2019

Information documents:

A PDF version of this Call for Nominees is available here.
Nomination/Application Guidelines can be found here.
The Application Form can be found here and is also available on the MAIZE and YPARD websites.

For any questions or issues, contact maizecrp@cgiar.org.

This award is sponsored by the CGIAR Research Program on Maize (MAIZE) in collaboration with YPARD (Young Professionals for Agricultural Development).

The itsy bitsy spider can make a big impact in agriculture

Written by on January 15, 2019. Posted in Features.

*Face of an adult male Phidippus audax male jumping spider. (Photo: Opoterser/Wikimedia Commons)*

A new study explores how conservation agriculture in southern Africa supports spider populations and diversity in fields, which could help mitigate pest damage and potentially lead to higher yields for farmers. According to the Food and Agriculture Organization of the United Nations (FAO), herbivorous insects such as aphids, caterpillars and weevils destroy about one fifth of the world’s total crop production each year. Spiders can help keep voracious pests in-check, but conventional farming practices (e.g. tilling, crop residue removal and monoculture) can harm or drastically reduce these beneficial bio-control agents.

There are more than 45,000 identified spider species around the world. From glaciers to tropical rainforests, they inhabit every terrestrial ecosystem on earth. Some can even live in tidal zones, and at least one species inhabits fresh water. While we tend to associate spiders with webs, only about 50 percent of the species catch their prey this way; the rest hunt on plants, on the ground or below it, using a variety of tactics such as stalking, stabbing, crushing – even seduction.

Although spiders have been around for 300 million years, some species are at risk of extinction due to habitat loss and fragmentation. Drastic reductions in vegetation – whether from a new parking lot or a tilled field – removes the food source that attracts their prey. Bare ground exposes their nesting sites and themselves, which makes it harder to hunt and easier to be hunted by birds and small mammals.

At the Chinhoyi University of Technology experimental farm in Zimbabwe, a team of researchers aimed to determine the response of spiders under different agricultural practices. Conventional farmers often prepare their fields for planting by physically breaking up and inverting the top 6-10 inches of soil. This practice of ploughing prepares a fine soil tilth, which makes it easier to plant; it breaks up and buries weeds, and reduces soil compaction to aerate the soil. But tilling also increases topsoil erosion from wind and water. It accelerates soil carbon decomposition, reduces soil water infiltration and disrupts microorganisms living in the soil, including beneficial insects and spiders.

The researchers conducted two experiments over the 2013/2014 and 2014/2015 cropping seasons to see how tilling, crop residue retention (i.e. leaving stalks and post-harvest organic matter in the field), fertilizer application and weeding affected ground- and plant-wandering spider species. They hypothesized that spider abundance and diversity would increase with lower levels of soil disturbance and more plant cover.

The results showed direct seeding into no-till soil increased the abundance of spiders and the diversity of species. Mulching also showed a positive effect. Contrary to their hypotheses and results from temperate regions, the application of fertilizer and intense weeding did not affect the spider community. The researchers attributed this to the difference in climatic conditions (tropical vs. temperate) of this study in southern Africa.

“Often the government’s and farmer’s immediate reaction to a crop pest issue is to apply a pesticide, but we can make use of biological control agents, which may be cheaper and less damaging for the environment,” says Christian Thierfelder, a co-author of the study. Thierfelder is a cropping systems agronomist and conservation agriculture specialist with the International Maize and Wheat Improvement Center (CIMMYT) with long-term experience in sustainable intensification.

“Spiders, ants and beetles all do a really good job with little or no cost to the farmer,” he adds. “For us, it’s quite fascinating to see simple agronomic practices to affect and control crop pests. This also provides new avenues of dealing with the fall armyworm, an invasive species which has devastated crops across the majority of sub-Saharan Africa countries.”

A robust number of studies from Europe, Australia and North America have shown the link between conservation agriculture and biodiversity, but Thierfelder says that research on biodiversity in agronomic systems is relatively new in southern Africa. While the study in Zimbabwe helps fill this gap, more research is needed to show the connection between the abundance of spiders, beetles and ants with the suppression of insect pest activity.

For more information, read Spider community shift in response to farming practices in a sub-humid agroecosystem in southern Africa.

This research was jointly funded by Chinhoyi University of Technology (CUT) and the German Academic Exchange Program (DAAD). The CGIAR Research Program on Maize (MAIZE) supported this study through Christian Thierfelder’s contributions.

Conference participants pose for a group photo at the field visit site during the 13th Asian Maize Conference. (Photo: Manjit Singh/Punjab Agricultural University)

International experts discuss progress and challenges of maize research and development in Asia

Written by Jennifer Johnson on December 17, 2018. Posted in Features.

The importance of maize in Asian cropping systems has grown rapidly in recent years, with several countries registering impressive growth rates in maize production and productivity. However, increasing and competing demands — food, feed, and industry — highlight the continued need to invest in maize research for development in the region. Maize experts from around the world gathered to discuss these challenges and how to solve them at the 13^th Asian Maize Conference and Expert Consultation on Maize for Food, Feed, Nutrition and Environmental Security, held from October 8 to 10, 2018, in Ludhiana, Punjab, India.

More than 280 delegates from 20 countries attended the conference. Technical sessions and panel discussions covered diverse topics such as novel tools and strategies for increasing genetic gains, stress-resilient maize, sustainable intensification of maize-based cropping systems, specialty maize, processing and value addition, and nutritionally enriched maize for Asia.

The international conference was jointly organized by the Indian Council of Agricultural Research (ICAR), the International Maize and Wheat Improvement Center (CIMMYT), the Indian Institute of Maize Research (ICAR-IIMR), Punjab Agricultural University (PAU), the CGIAR Research Program on Maize (MAIZE), and the Borlaug Institute for South Asia (BISA).

In Asia, maize is rapidly growing in its importance, due to high demand. Maize productivity in the region is growing by 5.2 percent annually compared to a global average of 3.5 percent. However, this is not enough. “Asia produces nearly 80 million tons of maize annually, but demand will be double by the year 2050,” said Martin Kropff, CIMMYT director general, in his opening address at the conference. “We need to produce two times more maize in Asia, using two times less inputs, including water and nutrients. Climatic extremes and variability, especially in South and South East Asia, will make this challenge more difficult. Continued funding for maize research is crucial. We need to work together to ensure that appropriate innovations reach the smallholder farmers.”

*Field visit in Ludhiana, India, during the 13th Asian Maize Conference. (Photo: Manjit Singh/Punjab Agricultural University)*

Climate-resilient maize and sustainable intensification

A major theme emphasized at the conference was climate resilience in maize-based systems. South Asia is a hotspot for vulnerability due to climate change and climate variability, which poses great risks to smallholder farmers. “Climate resilience cannot be brought by only a single technology — it has to be through a judicious mix of several approaches,” said B.M. Prasanna, director of CIMMYT’s Global Maize Program and the CGIAR Research Program on Maize.

Great advances have been made in developing climate-resilient maize for Asia since the last Asian Maize Conference, held in 2014. Many new heat- and drought-tolerant maize varieties have been developed through various projects, such as the Heat Stress Tolerant Maize for Asia (HTMA), and Affordable, Accessible, Asian (AAA) maize projects. Through the HTMA project, over 50 CIMMYT-derived elite heat-tolerant maize hybrids have been licensed to public and private sector partners in Asia during the last three years, and nine heat-tolerant maize hybrids have been released so far in Bangladesh, India and Nepal.

Sustainable intensification of maize-based farming systems has also helped farmers to increase yields while reducing environmental impact, through conservation agriculture and scale-appropriate mechanization. Simple technologies are now available to reduce harvest time by up to 80 percent and hired labor costs by up to 60 percent. Researchers across the region are also working to strengthen the maize value chains.

*B.S. Dhillon (center) receives the MAIZE Champion Award for his pioneering work in maize breeding. (Photo: Manjit Singh/Punjab Agricultural University)*

Science and appropriate technologies

CIMMYT has been focusing on developing and deploying new technologies that can enhance the efficiency of maize breeding programs; these include doubled haploid (DH) technology, high-throughput field-based phenotyping, and genomics-assisted breeding. The conference emphasized on the need for Asian institutions to adapt such new tools and technologies in maize breeding programs.

Another topic of interest was the fall armyworm, an invasive insect pest that has spread through 44 countries in Africa and was recently reported in India for the first time. “This pest can migrate very quickly and doesn’t require visas and passports like we do. It will travel, and Asian nations need to be prepared,” Prasanna said. “However, there is no need for alarm. We will be looking at lessons learned from other regions and will work together to control this pest.”

In addition to grain for food and feed, specialty maize varieties can provide beneficial economic alternatives for smallholder maize farmers. Conference participants had the opportunity to hear from Indian farmers Kanwal Singh Chauhan and Yugandar Y, who have effectively adopted specialty maize varieties, such as baby corn, sweet corn and popcorn, into life-changing economic opportunities for farming communities. They hope to inspire other farmers in the region to do the same.

On October 10, conference delegates participated in a maize field day organized at the BISA farm in Ladhowal, Ludhiana. Nearly 100 improved maize varieties developed by CIMMYT, ICAR and public and private sector partners were on display, in addition to scale-appropriate mechanization options, decision support tools, and precision nutrient and water management techniques.

The conference concluded with a ceremony honoring the winners of the 2018 MAIZE-Asia Youth Innovators Award. The awards were launched in collaboration between the CGIAR Research Program on Maize and YPARD (Young Professionals for Agricultural Development) to recognize the contributions of innovative young women and men who can inspire fellow youth to get involved in improving maize-based agri-food systems in Asia. Winners of the first edition of the awards include Dinesh Panday of Nepal, Jie Xu of China, Samjhana Khanal of Nepal, and Vignesh Muthusamy of India.

*Participants listen to a briefing during the field visit of the 13th Asian Maize Conference, in Ludhiana, India. (Photo: Manjit Singh/Punjab Agricultural University)*

Fall armyworm session at 2018 Borlaug Dialogue.

Fall armyworm on the agenda at the 2018 Borlaug Dialogue

Written by Rodrigo Ordóñez on October 25, 2018. Posted in News.

DES MOINES (Iowa) — At the plenary of the 2018 Borlaug Dialogue, a global panel of experts gave an overview of the origins of the fall armyworm, how it is spreading around the world, and how governments, farmers and researchers are fighting against this pest.

Pedro Sanchez, research professor in tropical soils at the University of Florida and 2002 World Food Prize Laureate, shared background information on the history of the fall armyworm and the early attempts to neutralize it, decades ago. He pointed out that once-resistant varieties were eventually affected by this pest.

The Director General of the International Maize and Wheat Improvement Center (CIMMYT), Martin Kropff, shared the most recent developments and explained how organizations are working together to respond to this pest. “We want to have science-based, evidence-based solutions,” Kropff said. “We have to solve the problem based on science, and then to develop and validate and deploy integrated pest management technologies.”

The director general of the Ethiopian Institute of Agriculture, Mandefro Nigussie, reminded that in addition to affecting people and the environment, fall armyworm “is also affecting the future generation,” as children were pulled out of school to pick larvae.

The response against fall armyworm cannot be done by governments alone, panelists agreed. It requires the support of multiple actors: financing the research, producing research, promoting the results of the research and implementing appropriate measures.

Rob Bertram, chief scientist at USAID’s Bureau for Food Security predicted the fall armyworm will continue to be a “serious problem” as it moves and migrates.

The director general and CEO of the Kenya Agricultural & Livestock Research Organization, Eluid Kireger, emphasized the importance of global collaboration. “We need to borrow the technologies that are already working”.

The fall armyworm was also discussed during the Corteva Agriscience Forum side event, on a session on “Crop security for food security”. The Director of CIMMYT’s Global Maize Program and the CGIAR Research Program on Maize, B.M. Prasanna, was optimistic about the efforts to tackle this voracious pest. “I’m 100 percent confident that the pest will be overcome, but it requires very solid synergistic and coordinated actions at the national level, at the regional level and at the continental level.”

CIMMYT is co-leading the Fall Armyworm R4D International Consortium. “Fall armyworm is not going to be the only threat now and forever; there will be more insects, pests and pathogens moving around,” Prasanna said. “Global connectedness is exacerbating this kind of problem, but the solution lies also in global connectedness.”

*See our coverage of the 2018 Borlaug Dialogue and the World Food Prize.*

A fall armyworm on a damaged leaf in Nigeria, 2017. (Photo: G. Goergen/IITA)

New global research alliance joins fight against fall armyworm

Written by on September 26, 2018. Posted in Press releases.

NAIROBI (Kenya) — As the invasion of the voracious fall armyworm threatens to cause US$3-6 billion in annual damage to maize and other African food staples, 35 organizations announced today the formation of a global coalition of research for development (R4D) partners, focused on developing technical solutions and a shared vision of how farmers should fight against this pest. After causing extensive crop damage in Africa, the presence of the fall armyworm was recently confirmed in India.

The new Fall Armyworm R4D International Consortium will serve to develop and implement a unified plan to fight this plant pest on the ground. Focusing on applied research, the consortium joins other global efforts and coordinates with international bodies working against this pest. The Fall Armyworm R4D International Consortium will be co-led by the International Maize and Wheat Improvement Center (CIMMYT) and the International Institute of Tropical Agriculture (IITA).

“This pest caught us all by surprise and it continues eating away at maize and other crops that are important for the food security and livelihoods of African farmers. We can no longer afford to work in isolation,” said the Director General of CIMMYT, Martin Kropff. “Many organizations in the public and private sector are working intensively on different approaches,” he added, “but farmers are not interested in half solutions. They want to have integrated solutions, supported by strong science, which work effectively and sustainably.”

Consortium members will coordinate efforts to pursue a wide range of options for fighting fall armyworm, with a strong emphasis on integrated pest management, which includes host plant resistance, environmentally safer chemical pesticides, biological and cultural control methods, and agronomic management.

The Deputy Director General for Partnerships for Delivery at IITA, Kenton Dashiell, said that efforts are underway to identify and validate biopesticides, or “very safe products that don’t harm the environment or people but kill the pest.” In some areas, Dashiell explained, farmers may need to consider temporarily switching to a food crop that is not susceptible to armyworm.

The Vice President of Program Development and Innovation at the Alliance for a Green Revolution in Africa (AGRA), Joe DeVries, said his organization is serving as a bridge between scientists and farmers. AGRA is developing a network of “village-based advisers” across 15 countries who will be connected to farmers via a “private sector-led” extension system to help farmers deal with fall armyworm infestations. AGRA and its partners already have trained more than 1,000 advisers and expect to add several thousand more who can “quickly bring to farmers the latest knowledge about the best methods of control.”

The Chief Scientist at the Bureau of Food Security of the United States Agency for International Development (USAID), Rob Bertram, expressed his excitement about the formation of the consortium, both for its immediate relevance for fighting fall armyworm and as a forerunner of “more resilient” agriculture systems in Africa, which is likely to see similar threats in the future. CIMMYT and USAID, together with global experts, developed an integrated pest management guide to fight fall armyworm, available in English, French and Portuguese.

The Director General of Development at the Center for Agriculture and Biosciences (CABI), Dennis Rangi, noted that the ability for people to more rapidly travel around the world is also making it easier for plant pests to hop from continent to continent. “Today we are focusing on the fall armyworm, tomorrow it could be something different,” he said.

The members of the Fall Armyworm R4D International Consortium will hold their first face-to-face meeting on October 29-31, 2018, in Addis Ababa, Ethiopia. This international conference will be organized by CIMMYT, IITA, AGRA, CABI, FAO, icipe, FAO, USAID and the African Union Commission.

The technical coordinators of the consortium are B.M. Prasanna, Director of the CGIAR Research Program MAIZE and Global Maize Program at CIMMYT, and May-Guri Saethre, Deputy Director General of Research for Development at IITA.

PARTNERS OF THE FALL ARMYWORM R4D INTERNATIONAL CONSORTIUM

Leads:

International Maize and Wheat Improvement Center (CIMMYT)
International Institute of Tropical Agriculture (IITA)

Members:

African Agricultural Technology Foundation (AATF)
Agricultural Research Service (ARS) of the United States Department of Agriculture (USDA)
Alliance for a Green Revolution in Africa (AGRA)
Bayer
Bill & Melinda Gates Foundation
Biorisk Management Facility (BIMAF)
Brazilian Agricultural Research Corporation (Embrapa)
Center for Agriculture and Biosciences (CABI)
Corteva
CropLife International
Deutsche Gesellschaft für Internationale Zusammenarbeit (GIZ)
Food and Agriculture Organization of the United Nations (FAO)
Forum for Agricultural Research in Africa (FARA)
International Centre of Insect Physiology and Ecology (icipe)
International Crops Research Institute for the Semi-Arid Tropics (ICRISAT)
Lancaster University
Leibniz Institute DSMZ (German Collection of Microorganisms and Cell Cultures)
Michigan State University (MSU)
Mississippi State University (MSU)
North-West University (NWU)
Norwegian Institute of Bioeconomy Research (NIBIO)
Oregon State University (OSU)
Rothamsted Research
Syngenta
UK Department for International Development (DFID)
United States Agency for International Development (USAID)
University of Bonn
University of Florida (UFL)
University of Greenwich
Virginia Polytechnic Institute and State University (Virginia Tech)
Wageningen University and Research (WUR)
West and Central African Council for Agricultural Research (CORAF/WECARD)
World Agroforestry Centre (ICRAF)

MEDIA CONTACTS

For more information, please contact:

Geneviève Renard, Head of Communication, CIMMYT
g.renard@cgiar.org, +52 (55) 5804 2004, ext. 2019.

Katherine Lopez, Head of Communication, IITA
k.lopez@cgiar.org, +234 0700800, ext. 2770

MULTIMEDIA

Photos of the fall armyworm are available here:
https://www.flickr.com/photos/cimmyt/sets/72157677988561403

Winners of the 2018 MAIZE Youth Innovators Awards – Asia announced

Written by Jennifer Johnson on September 20, 2018. Posted in News.

The 2018 MAIZE Youth Innovators Awards – Asia recognize the contributions of young women and men who can inspire fellow young people to get involved in maize-based research, social change and farming. The awards are sponsored by the CGIAR Research Program on Maize (MAIZE) in collaboration with Young Professionals for Agricultural Development (YPARD).

The awardees have been invited to attend the 13^th Asian Maize Conference in Ludhiana, India, where they will present their work and receive their awards.

The winners in the two categories are:

RESEARCHER

Dinesh Panday, Nepal

Focus: Soil fertility and nutrient management

Dinesh Panday’s family has a long history in agriculture, which strongly rooted his passions in the field of soil science. He is a Doctorate Graduate Research Assistant in Soil Fertility and Nutrient Management at the University of Nebraska-Lincoln under the supervision of Bijesh Maharjan and Richard Ferguson.

His research aims to determine the effectiveness of high carbon char in reducing environmental nitrogen loss and improving nitrogen fertilizer use efficiency in fertilized soils in semi-arid regions. Using active and passive sensors to detect maize nitrogen stress, predict grain yield and determine in-season and additional side-dress applications of nitrogen fertilizer it is possible to reduce environmental impacts.

Jie Xu, China

Focus: Drought stress in maize root systems

An associate researcher at Sichuan Agricultural University, China, Jie Xu is interested in how maize roots influence performance under drought stress. By studying maize inbred lines that exhibit different drought tolerance, her research explores their genome and transcriptome variations to understand the genetic basis of plant adaptation to drought. The findings can then be used in breeding drought-tolerant maize.

Jie Xu and her team have developed methods to dissect the genetic and epigenetic mechanisms underlying maize drought stress response. This work involves the identification of non-synonymous SNPs and corresponding candidate genes for drought tolerance using analyses such as common variant and clustering techniques. Her team also revealed the impact smRNAs and histone modifications have in the regulation of maize drought stress response.

Vignesh Muthusamy, India

Focus: Development of biofortified provitamin-A rich QPM maize hybrids

Vignesh Muthusamy is from a farming community in the Namakkal district in Tamil Nadu. A Senior Scientist at the Division of Genetics, ICAR-Indian Agricultural Research Institute, New Delhi, he specializes in maize genetics and breeding. His research demonstrates the use of modern biotechnological tools in crop improvement. He was associated with the development of India’s first provitamin A enriched maize hybrid ‘Pusa Vivek QPM 9 Improved’ and with the development of three quality protein maize hybrids that possess high lysine and tryptophan in protein. These biofortified maize hybrids offer tremendous scope to address widespread human malnutrition. Further research work includes the development of a high-yielding sweet corn hybrid and several novel maize genetic resources for nutritional quality traits.

Muthusamy has received many prestigious awards from different societies and scientific organizations, including Jawaharlal Nehru Award for Outstanding Doctoral Thesis Research in Agricultural and Allied Sciences from Indian Council of Agricultural Research. As Principal Investigator, he is handling projects funded by Department of Biotechnology and Department of Science & Technology, Government of India for development of nutritionally rich maize and specialty corn genotypes. Besides research, he is also actively involved in teaching and guidance of post graduate students of the institute.

CHANGE AGENT

Samjhana Khanal, Nepal

Focus: Social inclusion of young people and site-specific nutrient management (SSNM) using Nutrient Expert®

Samjhana Khanal, an agricultural graduate, has founded and co-founded various social organizations at a local level in Nepal to involve young minds in the development of innovative strategies to work towards sustainable agriculture and zero hunger.

Besides taking part in agricultural trainings, workshops and conferences during her undergraduate degree, Samjhana worked as a R&D Research Assistant at the Eastern Regional Agricultural Directorate in Nepal and has published a number of research papers. Her most recent research involves the productivity and profitability of hybrid maize using the Nutrient Expert® Maize model in eastern Terai, Nepal. Using Nutrient Expert®, a dynamic nutrient management tool based on site-specific nutrient management (SSNM) principles, farm-specific fertilizer recommendations for maize are possible, resulting in higher grain yield and improved productivity and profits for farmers.