research: Maize

Preserving native maize and culture in Mexico

Written by Matthew O'Leary on May 21, 2018. Posted in Features.

Felipa Martinez shows off some of her family’s maize from last year’s harvest. Photo: Matthew O’Leary

Felipa Martinez, an indigenous Mexican grandmother, grins as she shows off a bag bulging with maize cobs saved from last harvest season. With her family, she managed to farm enough maize for the year despite the increasing pressure brought by climate change.

Felipa’s grin shows satisfaction. Her main concern is her family, the healthy harvest lets her feed them without worry and sell the little left over to cover utilities.

“When our crops produce a good harvest I am happy because we don’t have to spend our money on food. We can make our own tortillas and tostadas,” she said.

Her family belongs to the Chatino indigenous community and lives in the small town of Santiago Yaitepec in humid southern Oaxaca. They are from one of eleven marginalized indigenous communities throughout the state involved in a participatory breeding project with the International Maize and Wheat Improvement Center (CIMMYT) to naturally improve the quality and preserve the biodiversity of native maize.

These indigenous farmers are custodians of maize biodiversity, growing seeds passed down over generations. Their maize varieties represent a portion of the diversity found in the 59 native Mexican races of maize, or landraces, which first developed from wild grasses at the hands of their ancestors. These different types of maize diversified through generations of selective breeding, adapting to the environment, climate and cultural needs of the different communities.

In recent years, a good harvest has become increasingly unreliable, as the impacts of climate change, such as erratic rainfall and the proliferation of pests and disease, have begun to challenge native maize varieties. Rural poor and smallholder farmers, like Martinez and her family, are among the hardest hit by the mounting impacts of climate change, according to the Food and Agriculture Organization of the United Nations.

These farmers and their ancestors have thousands of years of experience selecting and breeding maize to meet their environment. However, climate change is at times outpacing their selection methods, said CIMMYT landrace improvement coordinator Martha Willcox, who works with the community and coordinates the participatory breeding project. Through the initiative, the indigenous communities work together with professional maize breeders to continuously improve and conserve their native maize.

Despite numerous challenges, farmers in the region are unwilling to give up their maize for other varieties. “The native maize, my maize grows best here, it yields well in our environment. The maize is sweeter, it is heavier,” said Don Modesto Suarez, Felipa’s husband. “This maize has been grown by our grandfathers and this is why I will not change it.”

Una mujer de la comunidad Chatino prepara tortillas muy grandes de maíz criollo que son muy apreciadas en los mercados locales. Foto: Matthew O’Leary

This is because a community’s native maize varieties are adapted to their specific microclimate, such as elevation and weather patterns, and therefore may perform better or be more resistant to local pests and diseases than other maize varieties. They may also have specific characteristics prized for local culinary traditions — for example, in Santiago Yaitepec the native maize varieties have a specific type of starch that allows for the creation of extra-large tortillas and tostadas that are in high demand in local markets.

Other varieties may not meet farmers’ specific needs or climate, and many families do not want to give up their cultural attachment to native maize, said Flavio Aragon, a genetic resources researcher at the Mexican National Institute for Forestry, Agriculture and Livestock Research (INIFAP) who collaborates with Willcox.

CIMMYT and INIFAP launched the four-year participatory plant breeding project to understand marginalized communities’ unique makeup and needs – including maize type, local climates, farming practices, diseases and culture – and include farmers in breeding maize to suit these needs.

“Our aim is to get the most out of the unique traits in the native maize found in the farmer’s fields. To preserve and use it to build resistance and strength without losing the authenticity,” said Aragon.

“When we involve farmers in the process of selection, they are watching what we are doing and they are learning techniques,” he said. “Not only about the process of genetic selection in breeding but also sustainable farming practices and this makes it easier for farmers to adopt the maize that they have worked alongside breeders to improve through the project.”

Suarez said he appreciates the help, “We are learning how to improve our maize and identify diseases. I hope more farmers in the community join in and grow with us,” he said.

When disease strikes

Chatino men stand in a maize field in Santiago Yaitepec, Oaxaca, Mexico. Tar spot complex threatened harvests, but work in participatory breeding with CIMMYT has helped local communities to improve their native maize without loosing preferred traits. (Photo: Matthew O'Leary) — Chatino men stand in a maize field in Santiago Yaitepec, Oaxaca, Mexico. Tar spot complex threatened harvests, but work in participatory breeding with CIMMYT has helped local communities to improve their native maize without loosing preferred traits. (Photo: Matthew O’Leary)

Changes in weather patterns due to climate change are making it hard for farmers to know when to plant their crops to avoid serious disease. Now, a fungal disease known as tar spot complex, or TSC, is increasingly taking hold of maize crops, destroying harvests and threatening local food security, said Willcox. TSC resistance is one key trait farmers want to include in the participatory breeding.

Named for the black spots that cover infected plants, TSC causes leaves to die prematurely, weakening the plant and preventing the ears from developing fully, cutting yields by up to 50 percent or more in extreme cases.

Caused by a combination of three fungal infections, the disease occurs most often in cool and humid areas across southern Mexico, Central America and into South America. The disease is beginning to spread, possibly due to climate change, evolving pathogens and introduction of susceptible maize varieties.

“Our maize used to grow very well here, but then this disease came and now our maize doesn’t grow as well,” said Suarez. “For this reason we started to look for maize that we could exchange with our neighbors.”

A traditional breeding method for indigenous farmers is to see what works in fields of neighboring farmers and test it in their own, Willcox said.

Taking the search to the next level, Willcox turned to the CIMMYT Maize Germplasm Bank, which holds over 7000 native maize seed types collected from indigenous farmers. She tested nearly a thousand accessions in search of TSC resistance. A tedious task that saw her rate the different varieties on how they handled the disease in the field. However, the effort paid off with her team discovering two varieties that stood up to the disease. One variety, Oaxaca 280, originated from just a few hours north of where the Suarez family lives.

Farmer Modesto Suarez (left) and neighbors were originally cautious to plant Oaxaca 280 in their fields, but were pleased with the results. (Photo: Matthew O’Leary)

After testing Oaxaca 280 in their fields the farmers were impressed with the results and have now begun to include the variety in their breeding.

“Oaxaca 280 is a landrace – something from Mexico – and crossing this with the community’s maize gives 100 percent unimproved material that is from Oaxaca very close to their own,” said Willcox. “It is really a farmer to farmer exchange of resistance from another area of Oaxaca to this landrace here.”

“The goal is to make it as close as it can be to what the farmer currently has and to conserve the characteristics valued by farmers while improving specific problems that the farmers request help with, so that it is still similar to their native varieties and they accept it,” Aragon said.

Expanding for impact

Willcox and colleagues throughout Mexico seek to expand the participatory breeding project nationwide in a bid to preserve maize biodiversity and support rural communities.

“If you take away their native maize you take away a huge portion of the culture that holds these communities together,” said Willcox. Participatory breeding in marginalized communities preserves maize diversity and builds rural opportunities in areas that are hotbeds for migration to the United States.

“A lack of opportunities leads to migration out of Mexico to find work in other places, a strong agricultural sector means strong rural opportunities,” she said.

To further economic opportunities in the communities, these researchers have been connecting farmers with restaurant owners in Mexico City and the United States to export surplus grain and support livelihoods. A taste for high-quality Mexican food has created a small but growing market for the native maize varieties.

The next generation: The granddaughter of Felipa Martinez and Modesto Suarez stands in her grandparent's maize field. (Photo: Matthew O'Leary) — The next generation: The granddaughter of Felipa Martinez and Modesto Suarez stands in her grandparent’s maize field. (Photo: Matthew O’Leary)

Native maize hold the building blocks for climate-smart crops

Native maize varieties show remarkable diversity and climate resilience that grow in a range from arid to humid environments, said Willcox. The genetic traits found in this diversity are the building blocks that can be used to develop varieties suitable for the changing crop environments predicted for 2050.

“There is a lot of reasoning that goes into the way that these farmers farm the land, the way they decide on what they select for,” said Willcox. “This has been going on for years and has been passed down through generations. For this reason, they have maize of such high quality with resistance to local challenges, genetic traits that now can be used to create strong varieties to help farmers in Mexico and around the world.”

It is key to analyze the genetic variability of native maize, and support the family farmers who conserve it in their fields, she added. This biodiversity still sown and selected throughout diverse microclimates of Mexico holds the traits we need to protect our food supplies.

To watch a video on CIMMYT’s work in this community, please click here.

This work has been conducted as part of the CIMMYT-led MasAgro project in collaboration with INIFAP, and supported by Mexico’s Department of Agriculture, Livestock, Rural Development, Fisheries and Food (SAGARPA) and the CGIAR Research Program MAIZE.

First zinc-enriched maize in Guatemala to combat malnutrition

Written by Jennifer Johnson on May 21, 2018. Posted in News.

Tortillas made of zinc-enriched biofortified maize. Photo: HarvestPlus.

The first zinc-enriched maize varieties developed specifically for farmers in Guatemala were released this month as part of efforts to improve food and nutrition security in a country where over 46 percent of children under five suffer from chronic malnutrition.

More than 40 percent of Guatemala’s rural population have been found to be deficient in zinc, an essential micronutrient that plays a crucial role in pre-natal and post-natal development, and is key to maintaining a healthy immune system.

The new varieties, known as ICTA HB-18 and ICTA B-15, were developed by the International Maize and Wheat Improvement Center (CIMMYT), the CGIAR Research Programs (CRPs) on Maize (MAIZE) and Agriculture for Nutrition and Health (A4NH), and Guatemala’s Institute for Agricultural Science and Technology (ICTA), with support from HarvestPlus. The varieties will be commercialized by Semilla Nueva and Atescatel cooperative with the support of the Plataforma BioFORT, a network created to promote biofortification activities in the country formed by 30 public and private institutions. The official launch was held in Jutiapa, Guatemala, on May 4 with an event attended by over 100 Guatemalan maize producers.

Felix San Vicente, second from left, at the launch event. Photo: HarvestPlus.

“There are not many countries working with zinc maize right now, and that makes us pioneers in this area,” said Felix San Vicente, CIMMYT maize breeder. “Guatemala is the first country to release a zinc maize hybrid and Colombia will be the second. This means that we can also breed high zinc maize hybrids for producers who prefer hybrids over open pollinated varieties.”

These biofortified varieties were developed using conventional breeding methods. Farmers expressed interest in the varieties due to their high yield quality protein content, high zinc levels, early maturity and large kernel size.

Maize is a staple crop in Guatemala, and the base of many traditional foods such as tortillas, tamales, fresh roasted maize ears and other products. Tortillas made with ICTA B-15 contain up to 60 percent more zinc than regular tortillas. ICTA HB-18, a zinc maize hybrid, contains 15 percent more zinc compared to commercial maize. Just 100 grams of tortilla made of these varieties can provide 2.5 milligrams of zinc, 50 percent of the daily recommended zinc intake for children, making zinc-enriched biofortified maize an excellent tool in the fight against malnutrition and hidden hunger.

One hundred and thirteen tons of seed will be produced and delivered to producers by the end of 2018.

Farmers in Ethiopia willing to pay more for quality protein maize

Written by on April 18, 2018. Posted in News.

A blindfolded woman panelist performing a triangular test to differentiate dabbo samples made from different maize varieties. Photo: CIMMYT

In Ethiopia, 44 percent of children under the age of five are stunted, or experience impaired growth due to poor nutrition, and 29 percent are underweight, according to the United States Agency for International Development. Quality protein maize (QPM) – a biofortified crop that increases lysine and tryptophan, two amino acids necessary for protein synthesis in humans – helps combat stunting and boosts nutrition in children who survive on a maize-dominated diet.

As maize is Ethiopia’s most consumed cereal, QPM could be especially beneficial to rural communities in the country, which consume more maize and suffer even higher rates of malnutrition than urban areas.

Until recently, farmers have been hesitant to adopt QPM over traditional varieties because the up-front cost is higher, and they have doubted the marketability due to the novelty of the variety. There is strong competition in productivity between QPM and conventional maize varieties and farmers tend to only plant newest or the best yielding varieties, where they feel sure they will get the highest return for their investment.

A study in Ethiopia found that farmers are willing to pay almost 50 percent more for quality protein maize (QPM) over conventionally grown maize, due to rising consumer preference for QPM varieties.

The major objective of the study was to know whether farmers as consumers have a preference for the QPM and if that would translate to a willingness to pay more for its attributes. As QPM is still a widely unknown variety, many farmers in the study had preconceived notions that it would be sour, would not taste good in traditional foods, or would be visually unappealing.

The study, conducted at CIMMYT as part of a MSc thesis, found that traditional food products made from QPM were correctly identified by most consumers, and were actually preferred over foods made from conventional maize. Farmers repeatedly expressed their preference for dabo, a local type of bread, made from QPM for its aroma, taste and texture. Mothers and children also consistently preferred genfo, a stiff maize-based porridge, made from QPM.

A slice of traditional bread called dabbo made from yellow QPM served for sensory evaluation. Photo: CIMMYT

Although traditional foods made from white grain/flour are usually preferred in Ethiopia, yellow QPM received higher preference than the white, signifying the trait responsible to its yellowness seems to contribute to its taste and functional property.

Based only on this taste difference, farmers were willing to pay as much as 48 percent more for QPM in some communities. On average, farmers were willing to pay 37 percent more for yellow QPM, but only five percent more for white QPM, due to the variability of sensory qualities between the white and yellow QPM varieties.

When given information about the increased nutritional benefit of QPM, farmer willingness to pay more for white QPM shot up to be roughly on par with yellow QPM, and reduced the amount that farmers said they would be willing to pay for conventional maize.

This suggests that the taste preference between white and yellow QPM is small and that education is a particularly powerful tool to increase its uptake among farmers.

Based on this study, QPM has an advantage in Ethiopia’s maize market not only because of its nutritional benefits but also aroma, taste, and texture, which is significant for women who are responsible for household diet.

QPM requires a special value chain that considers its nutritional advantage and taste, and strong extension communication is vital for the adoption of QPM as nutritional information reinforces the market share, specifically for white QPM. Extension agents could use the reported sensory preference for yellow QPM to begin large-market dissemination of QPM, alongside information about its nutritional advantages.

Consumer willingness to pay more for QPM grain should encourage maize farmers, seed suppliers and other stakeholders to invest in the variety. Market acceptability of QPM means more profits for stakeholders, facilitating adoption, and in this case, contributing to the fight against malnutrition.

Read the full study “Sensory acceptance of quality protein maize dishes and willingness to pay for its grain in districts around Gilgel Gibe hydro-electricity dam: Omo Nada district” here, and learn more about CIMMYT’s work with QPM here.

The Nutritious Maize for Ethiopia Project is funded by the Government of Canada.

Adefris Teklewold Chere

Written by on April 17, 2018. Posted in Uncategorized.

Adefris Teklewold is a senior scientist and leads the Nutritious Maize for Ethiopia Project (NuME). He is also involved in breeding quality protein maize varieties and seed system development.

NuME fights malnutrition and food insecurity for resource-poor smallholder farmers in Ethiopia, especially among women and young children, through the widespread adoption, production and utilization of quality protein maize. The project is implemented in drought-prone, moist mid-altitude and highland areas of maize growing agroecologies in focal districts of four major maize producing and consuming regions of Ethiopia. NuME was started in 2012 and will conclude in March 2019.

Led by CIMMYT and funded by Global Affairs Canada, NuME is implemented in collaboration with Ethiopian research institutions, international non-governmental organizations, universities, farmer unions and public and private seed companies operating throughout the country.

Jill Cairns

Written by on April 17, 2018. Posted in Uncategorized.

Jill Cairns is a physiologist whose current research is largely focused on the development, validation and deployment of new phenotyping tools to increase maize breeding efficiency. She is also part of a team validating new seed production technologies for Africa.

These technologies are critical to increasing genetic gain within breeding programs, which is essential to meet future food security. Low cost, high-throughput phenotyping tools can increase the accuracy of traits currently measured visually within breeding programs and the development of cheaper tools to measure key traits will allow breeders to divert more resources towards the generation and management of a larger population, thereby increasing selection intensity.

Cairns currently leads a component of the Stress Tolerant Maize for Africa project on innovative breeding tools and techniques to increase the rate of genetic gain in the maize breeding pipeline, and is the cluster of activities leader for Climate Resilient Maize for Africa under MAIZE, a CGIAR Research Program.

Felix San Vicente

Written by on April 17, 2018. Posted in Uncategorized.

Felix is a maize breeder with broad experience in the study of quantitative genetics and heterosis in tropical maize. He has more than 30 years developing and adapting breeding methods for increasing genetic gains in tropical maize. During his time at CIMMYT, he has developed more than 20 hybrids and 8 open pollinated varieties which are grown commercially in about 500,000 has in 10 countries in Latin America. He has also been part of a team that has released 15 CIMMYT maize lines; elite germplasm used in hybrids by maize breeding programs in at least 25 different countries worldwide.

Currently, Felix coordinates maize breeding activities for Latin America, including Mexico’s and Colombia’s main breeding hubs, targeting lowland tropics, subtropics and highlands. In addition, he leads CIMMYT’s lowland tropical breeding program in intensive collaboration with local and regional partners.

B.M. Prasanna

Written by on April 17, 2018. Posted in Uncategorized.

B.M. Prasanna is a Distinguished Scientist and Regional Director for Asia at CIMMYT.

Since 2010, Prasanna, as the Global Maize Program Director, has provided technical oversight for a wide range of multi-institutional projects focused on the development and deployment of elite, stress-resilient, and nutritionally enriched maize varieties across the tropics of sub-Saharan Africa, Asia, and Latin America. He has also spearheaded the application of innovative tools and technologies aimed at enhancing genetic gains and improving breeding efficiency.

Prasanna led the CGIAR Research Program MAIZE from 2015 till 2021, an alliance of over 300 research and development institutions globally. He has been at the forefront in tackling the challenges of maize lethal necrosis (MLN) disease in eastern Africa (since 2011), and the Fall Armyworm in Africa and Asia (since 2016 and 2018, respectively).

Together with an array of partners globally, Prasanna and the wider CGIAR team have formulated the OneCGIAR Plant Health Initiative in 2021. Prasanna is currently also serving as the Leader of the Plant Health Initiative, involving 10 CGIAR centers and over 80 national and international partners.

Recipient of several awards and recognitions, Prasanna has published over 200 research articles in various international journals of repute, and has a Scopus h-index of 46, and a Google Scholar h-index of 61.

AbduRahman Beshir

Written by on April 17, 2018. Posted in Uncategorized.

AbduRahman Beshir has more than two decades of experience of getting better seeds and varieties to farmers. He works towards boosting farmer uptake of improved crop varieties by identifying ideal crop traits and strengthening seed systems.

Currently, he is working to strengthen seed systems across South Asia in close collaboration with government, national agricultural research systems, non-governmental organizations, donors, seed companies and other seed value chain actors. He primarily focuses on Nepal and Pakistan.

Beshir works with partners fast track the development and deployment of market-ready products and scale up quality seed production of key crops in the region like maize, rice and selected legumes and vegetables. He integrates farmers, researchers and seed companies for the development of improved crops varieties and their subsequent adoption through robust and inclusive seed delivery pathways.

Global maize experts discuss biofortification for nutrition and health

Written by Jennifer Johnson on April 5, 2018. Posted in News.

Over two billion people across the world suffer from hidden hunger, the consumption of a sufficient number of calories, but still lacking essential nutrients such as vitamin A, iron or zinc. This can cause severe damage to health, blindness, or even death.

At the 4^th annual Latin American Cereals Conference (LACC) in Mexico City from 11 to 14 March, presenters discussed global malnutrition and how biofortification of staple crops can be used to improve nutrition for farming families and consumers.

Wolfgang Pfeiffer of HarvestPlus presents on malnutrition and stunting. Photo: Jennifer Johnson/CIMMYT.

“A stunted child will never live up to its full potential,” said Wolfgang Pfeiffer, director of research and development at HarvestPlus, as he showed a slide comparing the brain of a healthy infant versus a stunted one.

Hidden hunger and stunting, or impaired development, are typically associated with poverty and diets high in staple crops such as rice or maize. Biofortification of essential nutrients into these staple crops has the potential to reduce malnutrition and micronutrient deficiencies around the world.

“Maize is a staple crop for over 900 million poor consumers, including 120-140 million poor families. Around 73% of farmland dedicated to maize production worldwide is located in the developing world,” said B.M. Prasanna, director of the CGIAR Research Program on Maize (MAIZE) at LACC.

The important role of maize in global diets and the rich genetic diversity of the crop has allowed for important breakthroughs in biofortifcation. The International Maize and Wheat Improvement Center (CIMMYT) has over 40 years of experience in maize breeding for biofortification, beginning with quality protein maize (QPM), which has enhanced levels of lysine and tryptophan, essential amino acids, which can help reduce malnutrition in children.

B.M. Prasanna discusses the history of maize biofortification at the LACC conference. Photo: Mike Listman/CIMMYT.

“Over 50 QPM varieties have been adopted in Latin America and the Caribbean and sub-Saharan Africa, and three new QPM hybrids were released in India in 2017 using marker assisted breeding,” said Prasanna.

In more recent years, CIMMYT has worked with MAIZE and HarvestPlus to develop provitamin A maize to reduce vitamin A deficiency, the leading cause of preventable blindness in children, affecting 5.2 million preschool-age children globally, according to the World Health Organization. This partnership launched their first zinc-enriched maize varieties in Honduras in 2017 and Colombia in 2018, with releases of new varieties planned in Guatemala and Nicaragua later this year. Zinc deficiency can lead to impaired growth and development, respiratory infections, diarrheal disease and a general weakening of the immune system.

“There is a huge deficiency of vitamin A, iron and zinc around the world,” said Natalia Palacios, maize nutritional quality specialist at CIMMYT. “The beauty of maize is its huge genetic diversity that has allowed us to develop these biofortified varieties using conventional breeding methods. The best way to take advantage of maize nutritional benefits is through biofortification, processing and functional food,” she said.

Natalia Palacios discusses the development of biofortified varieties such as provitamin A and zinc-enriched maize. Photo: Mike Listman/CIMMYT.

The effects of these varieties are already beginning to show. Recent studies have shown that vitamin A maize improves vitamin A status and night vision of 4-8 year old rural children in Zambia.

“Biofortified crops are in testing in over 60 countries, 7.5 million households are growing biofortified crops, and over 35 million household members are consuming them,” said Pfeiffer. “It is critical to involve farmers in the development of biofortified crop varieties before they are released, through participatory variety selection.”

Overall, the conference presenters agreed that ending hidden hunger will require cooperation and partnerships from multiple sectors and disciplines. “Partnerships with seed companies are crucial for biofortified maize to make an impact. This is not just about technological advances and developing new products, this is about enabling policies, stimulating demand, and increasing awareness about the benefits of these varieties,” said Prasanna.

Scientists seek key to boost yields, ensure future food supply

Written by on March 23, 2018. Posted in Features.

We must improve the productivity of our key crops if we are to feed the world's growing population, say scientists. — Reducing the length of time it takes to naturally breed more productive crop varieties is key to feed the world’s growing population, say scientists. Photo: CIMMYT archives

EL BATAN, Mexico (CIMMYT) — Crop genetic gains remain too low, and international scientists are making a concerted effort to determine how best to increase yields to ensure there is enough food to feed everyone on the planet by 2050.

The complex task of increasing genetic gains – the amount of increase in performance achieved per unit time through artificial selection – involves considering many variables, including genotypes and phenotypes – selecting crop varieties with desired gene traits and considering how well they perform in a given environment.

Two new research papers by scientists at the International Maize and Wheat Improvement Center (CIMMYT) and partners at Australia’s University of Queensland and Spain’s University of Barcelona published in “Trends in Plant Science” highlight some of the best available tools and strategies for meeting the challenge.

Currently, crop breeding methods and agronomic management put annual productivity increases at 1.2 percent a year, but to ensure food security for future generations, productivity should be at 2.4 percent a year.

By 2050, the United Nations projects that the current global population of 7.6 billion will grow to more than 9.8 billion, making yield increases vital.

The results of grain yield increases each year are a function of the length of the breeding process, the accuracy of which breeders can estimate the potential of new germplasm, the size of the breeding program, the intensity of selection, and the genetic variation for the trait of interest.

“Reducing the length of the breeding process is the fastest way for breeders to increase their gains in grain yield per year,” said HuiHui Li, quantitative geneticist based at CIMMYT Beijing.

Speed breeding and other new techniques have the potential to double gains made by breeders some crops. Speed breeding protocols enable six generations of crops to be generated within a single year, compared to just two generations using traditional protocols.

Pioneered by scientist Lee Hickey at University of Queensland, speed breeding relies on continuous light to trick plants into growing faster, which means speed breeding can only be undertaken in a controlled environment.

Tapping into larger populations increases the probability of identifying superior offspring, but breeding is an expensive and time consuming process due to the variables involved.

One challenge scientists face is high-throughput field phenotyping, which involves characterising hundreds of plants a day to identify the best genetic variation for making new varieties. New phenotyping tools can estimate key traits such as senescence, reducing the time of data collection from a day or more to less than an hour.

“If breeders could reduce the cost of phenotyping, they can reallocate resources towards growing larger populations,” said Mainassara Zaman-Allah, a senior scientist at CIMMYT-Zimbabwe and a key contributor to the paper “Translating High Throughput Phenotyping into Genetic Gain.”

“Limitations on phenotyping efficiency are considered a key constraint to genetic advance in breeding programs,” said Mike Olsen, maize upstream trait pipeline coordinator with CIMMYT, based in Nairobi. “New phenotyping tools to more efficiently measure required traits will play an important role in increasing gains.”

New tools and techniques can only help contribute to food security if they are easily available and adopted. The CGIAR Excellence in Breeding Platform, launched in 2017, will play a pivotal role in ensuring these new tools reach breeding programs targeting the developing world.

Translating high-throughput phenotyping into genetic gain

Fast-forwarding genetic gain

Breaking ground: Mike Olsen uses new technology to improve farmer’s yields

Written by Jennifer Johnson on March 12, 2018. Posted in Features.

EL BATAN, Mexico (CIMMYT) — Global challenges to agriculture such as climate change, crop diseases and pests mean that the International Maize and Wheat Improvement Center (CIMMYT) is constantly working to develop new, improved, resistant varieties for farmers.

However, crop breeding is expensive, time-consuming work, meaning that it takes several years for farmers to get seed solutions to the challenges they are facing today.

Mike Olsen, upstream research coordinator for CIMMYT maize program, works with scientists to use new technologies to increase breeding program efficiency and genetic gain — developing improved maize varieties with the traits smallholder farmers’ need, such as disease resistance or drought tolerance, using less time and resources than ever before.

“Our whole team is trying to improve genetic gain for various traits, and to deliver more genetic gain with fewer resources, through the application of phenotyping innovation, genomics and molecular markers for crop improvement,” Olsen said. “Our work at CIMMYT assists our breeding teams to be more effective in developing improved products for farmers.”

Originally from the United States, Olsen grew up on a small farm in Wisconsin and would go on to study plant breeding and genetics at the University of Minnesota. “During my undergrad years I had the chance to visit South Africa and saw rural poverty for the first time. At the time, I was taking classes in plant biology and genetics and I was inspired by the idea of using agricultural improvement as a method for poverty eradication—it’s a big part of why I went into plant breeding,” he said. “As a graduate student, I became very interested in the mission of CIMMYT. I was studying at Norman Borlaug’s alma mater — working in Borlaug Hall, in fact — which inspired me to pursue a career at a CGIAR center. CIMMYT was a perfect fit that allowed me to do something I’ve wanted to do since I was 19 years old.”

The farmers he has met around the world inspire Olsen to come into work every day. “Knowing that the outcome of our work is providing income and food security to millions of vulnerable people is what’s so exciting about what we do. Being able to serve as a conduit for bringing advanced technology for crop improvement for resource poor farmers and consumers is incredible,” he said.

Beyond the day-to-day activities of conference calls, travel and airports, the big picture work of what Olsen does is to lead a global team of talented scientists, help with grant writing and project oversight, with a focus on breeding program optimization. “I have been very involved with the Genomics and Open Source Breeding informatics initiative (GOBii), which helps breeding programs efficiently use genetic information, and I’m currently working on a collaboration with DuPont Pioneer on seed production in Africa to deliver higher quality seed to smallholder farmers,” Olsen said. “What I most enjoy about my work is the people. I have to be honest, coming to CIMMYT I was moving out of a hands-on science role into working with people, and the collaborative nature of this job has been really energizing for me. I’ve had the opportunity to mentor some of our talented young scientists into greater leadership roles, and it has been really exciting seeing their professional growth. It’s the CIMMYT mission that gets us all out of bed in the morning, but I really enjoy the people I work and collaborate with.”

Science can reverse “new normal” of climate change-related disasters

Written by on March 9, 2018. Posted in News.

Naivasha, Kenya 2017. Photo: CIMMYT/ P.Lowe

In the last decade, the climate of Africa has been changing in dramatic ways. Many regions face unpredictable levels of rainfall, which can lead both droughts and severe flooding. Sub-Saharan Africa is the only region in the world with over 30 percent of children under five facing stunting – severe malnutrition, and is the only region where the rate of undernourished people has consistently increased.

The Sustainable Intensiﬁcation of Maize-Legume Cropping Systems for Food Security in Eastern and Southern Africa (SIMLESA) program, launched in 2010, works to improve maize and legume productivity and reduce yield risk for over 650,000 farm households in sub-Saharan Africa.

Maize is a vital staple cash and sustenance crop in most of Africa, and legumes provide nutrition, income and improve soil fertility. However, farmers’ yields are suffering due to declining soil fertility, drought and poor access to improved technologies.

Over the last eight years, SIMLESA has developed productive, resilient and sustainable smallholder maize-legume cropping systems. SIMLESA focuses on improving maize-legume cropping systems by encouraging the adoption of sustainable agriculture systems through conservation agriculture practices such as crop residue retention, crop rotation and intercropping practices to simultaneously maintain and boost yields, increase proﬁts and protect the environment.

Recently, Elliud Kireger, director general of the Kenya Agricultural and Livestock Research Organization (KALRO), Mulugetta Mekuria Asfaw, SIMLESA project leader and Daniel Rodriguez, associate professor, Queensland Alliance for Agriculture and Food Innovation (QAAFI) The University of Queensland, wrote a joint opinion piece “Africa: Science Can Reverse ‘New Normal’ of Hunger and Climate Disaster” in All Africa on the impacts of SIMLESA, read it here.

The Sustainable Intensiﬁcation of Maize-Legume Cropping Systems for Food Security in Eastern and Southern Africa (SIMLESA) program is funded by the Australian Centre for International Agricultural Research (ACIAR).

Women farmers, researchers, and local agencies fight to unlock the potential of maize in eastern India

Written by Mike Listman on March 7, 2018. Posted in News.

A women dries maize grain after shelling. Photo: CIMMYT/ Wasim Iftikar

Unforeseen market effects, particularly rising land values and falling maize prices, have blocked the headway of women’s groups in eastern India who had begun profiting from maize farming on fallow land.

Leveraging the region’s favorable rainfall and soils and leasing fallow land from mostly male landholders, women’s groups had been growing improved maize, including hybrids, in Badbil Village, Mayurbhanj District, on the north-central plateau of Odisha State, a populous area on India’s East Coast.

In conjunction with the Odisha State Department of Agriculture in 2016, the Cereal Systems Initiative for South Asia (CSISA), led by the International Maize and Wheat Improvement Center (CIMMYT), provided technical training on improved maize production practices including mechanized line sowing using a seed drill, the safe application of pre-emergence herbicides, weed control using a power weeder, precision fertilizer management, and the marketing of dry grain.

Across Mayurbhanj, CSISA supported the cultivation of more than 1,800 hectares of hybrid maize. The women’s groups in Badbil grew more than 32 hectares and obtained an average yield of 5.6 tons per hectare. CSISA facilitated the purchase by poultry feed mills from neighboring districts of around 100 tons of dry grain at $240 per ton, generating net gains of from $700 to $783 per hectare. The farmers also harvested surplus green cobs for family consumption.

Women farmers ready to bag up maize grain for storage. Photo: CIMMYT/ Wasim Iftikar

The success of maize cultivation in Badbil received attention in leading Odia-language newspapers, became a regional example for turning fallows into cash, and even featured in a report of the CGIAR Research Program on Maize.

But seeing that maize cultivation could yield profits, landowners declined to lease their fields in 2017. Fewer women farmers were able to grow maize and difficulties in sustaining linkages with millers due to the low output led many of the women to sell their crop as green cob at a lower price.

Worse yet, maize market prices plunged in Odisha in 2017. Farmers in Nuapada and Bolangir districts ended up selling at $167 per ton, against a declared minimum support price of $226 and as compared to $190 in 2016, demonstrating farmers’ vulnerability to price volatility.

Women farmers in Badbil wish to continue growing maize, despite the obstacles, and are encouraging male farmers to produce hybrid maize to keep supplying millers and thus maintain that market connection.

Anita Lohar, a progressive woman farmer, said, “The introduction of mechanization has helped the self-help groups to come forward to adopt maize and earn money from fallow land. We had one acre of maize in 2014 and now we cultivate maize on more than 80 acres. Maize farming has changed a lot from traditional practices, which were time consuming, labor intensive and less profitable, and now has asserted women’s fundamental role in agriculture.”

CSISA is working with the Odisha State Department of Agriculture and Farmers’ Empowerment, the Bill & Melinda Gates Foundation, and the National Commodity & Derivatives Exchange Limited to convene a maize marketing forum. On the agenda are improved infrastructure and aggregation and connectivity with nearby markets, such as poultry mills. CSISA also believes that better coordination among agencies involved in production, post-harvest management, storage, warehousing, and e-trading can unlock the potential for maize to generate significant incomes for smallholders, especially women, in the Odisha plateau.

Women are adopting mechanization and using seed drills. Photo: CIMMYT/ Wasim Iftikar

The Cereal Systems Initiative for South Asia is led by the International Maize and Wheat Improvement Center and implemented jointly with the International Food Policy Research Institute and the International Rice Research Institute

New zinc-biofortified maize variety BIO-MZn01. (Photo: CIMMYT)

First zinc maize variety launched to reduce malnutrition in Colombia

Written by Jennifer Johnson on February 28, 2018. Posted in News.

Left to right: Miguel Lengua, director general of Maxi Semillas S.A.S; Bram Govaerts, Latin America regional director at CIMMYT; Martin Kropff, CIMMYT director general; Howdy Bouis, interim HarvestPlus CEO; and Felix San Vicente, CIMMYT maize breeder; at the launch of new biofortified zinc maize. (Photo: Jennifer Johnson/CIMMYT)

Cali, Colombia (CIMMYT) — A new zinc-enriched maize variety was released in Colombia on February 23 to help combat malnutrition in South America.

Zinc is an essential mineral that plays an important role in human development but is not naturally produced by humans. Zinc deficiency can lead to impaired growth and development, respiratory infections, diarrheal disease and a general weakening of the immune system. In Colombia, an average of 22 percent of the population is affected by zinc deficiency. However, in certain regions, such as the pacific coast and Amazonia, up to 65 percent of the population is deficient in zinc.

The new variety, known as BIO-MZN01, was developed by the International Maize and Wheat Improvement Center (CIMMYT) with the support of HarvestPlus in collaboration with the International Center for Tropical Agriculture (CIAT), the CGIAR Research Program on Maize (MAIZE) and the CGIAR Research Program on Agriculture for Nutrition and Health (A4NH).

CIMMYT Director General Martin Kropff speaks at the launch of zinc-enriched maize. (Photo: Jennifer Johnson/CIMMYT)

“The support that CIMMYT and CIAT have received from HarvestPlus has been fundamental in allowing our researchers to develop crops with enhanced vitamin and mineral content,” said Martin Kropff, CIMMYT director general. “The improved maize that we present today is an important example of the impact we can have when we work together in partnership.”

The minimum daily requirement for zinc is 15mg, but not everyone has access to foods with naturally occurring quantities of zinc, which makes this zinc-enriched maize variety a boost for nutrition in a region where maize is a staple food.

BIO-MZN01 contains 36 percent more zinc on average than other maize varieties, meaning that arepas (a common maize-based Colombian dish) made of this new variety offer consumers up to five times more zinc than those made with traditional varieties. Additionally, BIO-MZN01 can yield up to 6 to 8 tons per hectare(t/ha), nearly double the national average in Colombia of 3.7 t/ha and is tolerant to several maize diseases that are common in the region, including rust, turcicum leaf blight, and gray leaf spot. Another advantage is it can be grown between 0 and 1400 meters above sea level during both cropping seasons in the country.

The official launch of BIO-MZN01 was held at CIAT in Palmira, Colombia, and was attended by local farmers, seed companies, and government officials as well as CIMMYT, HarvestPlus and CIAT staff. As part of the launch, visitors and staff were invited into the field to see the variety firsthand and learn more about its properties and the history of its development.

“The conservation and utilization of genetic diversity have been crucial for the development of this new biofortified variety, as well as other CIMMYT varieties with improved nutrition or resistance to climate change,” said Natalia Palacios, maize nutritional quality specialist at CIMMYT. “This has been an inter-institutional and interdisciplinary effort at all levels of the maize value chain.”

Other products of the CIMMYT/HarvestPlus partnership include zinc-enriched wheat and biofortified provitamin A maize, which helps to prevent blindness in children.

“We have been working with CIMMYT since HarvestPlus began,” said Marilia Nutti, the regional director for Latin America and the Caribbean at HarvestPlus. “The greatest advantage of working with CIMMYT is their quality research—CIMMYT has all of the knowledge of maize and wheat, and maize is a big part of the diet in Latin America. Meanwhile, HarvestPlus and CIAT already had the partnerships on the ground in Colombia to ensure that this improved zinc maize could get to farmers and consumers. This has truly been a win-win partnership to improve nutrition.”

A farmer examines a zinc-enriched maize plant. (Photo: CIMMYT)

The scientific work conducted at CIMMYT, HarvestPlus and CIAT reaches the hands of farmers through local seed companies such as Maxi Semillas S.A.S., a partner of CIMMYT Colombia for the past 40 years that will be commercializing the new variety. “These varieties are the product of an incredibly long and costly investigation that we do not have the resources to conduct ourselves. In turn we work to ensure that the variety can reach the hands of the farmers and consumers that need it most,” said Miguel Lengua, director general of Maxi Semillas S.A.S.

The variety will be sold at a similar price to currently available maize varieties in Colombia, and certified seed will be available beginning in August.

BIO-MZN01 will also form part of a new initiative in Colombia called “Semillas para la Paz,” or Seeds for Peace, which seeks to provide improved seed varieties as an alternative to illicit crops. The program, organized by the Colombian government and the Colombian Agricultural Research Corporation (CORPOICA), will promote the cultivation of nine different crops, including maize and beans. Over 20 tons of this new zinc-enriched maize variety will be produced by Maxi Semillas for this program, along with an iron-enriched biofortified bean variety developed by CIAT with HarvestPlus.

Seed savers celebrate “Doomsday Vault” tenth anniversary

Written by on February 22, 2018. Posted in News.

CIMMYT’s Maize Germplasm Bank has its entire collection backed up in the Svalbard Global Seed Vault. Photo: CIMMYT archives

EL BATAN, Mexico (CIMMYT) — The “Doomsday Vault,” that safeguards fall-back collections of key food crop seeds in the arctic cold of Longyearbyen, Norway, marks its tenth anniversary this year. To celebrate, leaders in the conservation of crop genetic resources are gathering next week to discuss best practices and to encourage sustainable use of the resources.

The Svalbard Global Seed Vault sits 1,300 kilometers north of the Arctic Circle; the farthest north commercial flights will take you. It is described as the world’s largest secure seed storage and was established by the Norwegian Government in February 2008. Repurposing an abandoned coal mine, the global seed vault is set deep into the natural permafrost of the Norwegian island of Svalbard.

Over the last decade, seed-preserving institutions worldwide have shipped backup collections of seed and other plant parts for storage in the vault, which now holds nearly 900,000 varieties of essential crops, representing over 4,000 plant species, which could be drawn upon to restart agriculture in case of a catastrophe.

The International Maize and Wheat Improvement Center (CIMMYT) is the top contributor to the vault, with over 150,000 unique collections containing a total of nearly 50 million seeds and representing roughly 85 percent of the entire CIMMYT germplasm bank collection.

The target is to have 90 percent of the CIMMYT entire collection backed up at Svalbard within two years, according to Thomas Payne, head of CIMMYT’s Wheat Germplasm Bank, which is located in Mexico. CIMMYT’s Maize Germplasm Bank, led by Denise Costich, has already reached that goal.

“We send seeds every other year, accumulating packets until we have a critical mass and sending them in a large, single shipment,” Payne said.

Preparing and shipping the seed involves intricate coordination and painstaking work. For starters, seed must be sent in the winter to avoid it sitting on hot airport tarmacs. Additionally, the Svalbard vault opens for new deposits only a few times a year, so shipping logistics need to match up those dates.

The CIMMYT Wheat Germplasm Bank aims to have 90 percent of its collection backed up at Svalbard within two years. Photo: CIMMYT archives. — CIMMYT’s Wheat Germplasm Bank aims to have 90 percent of its collection backed up at Svalbard within two years. Photo: CIMMYT archives.

Only seed of the highest quality is sent to Svalbard, in part to ensure that the stored seed retains as long as possible its ability to germinate.

CIMMYT Germplasm Bank seed collections are regularly tested for germination capacity by placing a batch of seeds in a wet paper towel for 7-10 days. When less than 85 percent of a unique collection is viable, then the entire collection is replaced with fresh seed grown from the viable portion.

“There are seed collections at CIMMYT that still meet the minimum viability standard after more than 50 years under storage,” Payne said, noting that the center’s long-term collections are kept at minus 18 degrees Centigrade and in low humidity.

Payne said the center keeps duplicate collections in Mexico of all the seed it sends to Svalbard and monitors those Mexico back-ups to keep tabs on the viability of its Svalbard deposits.

Payne explained “To check seed viability, we have to take seeds out of storage, representing a loss of several hundred seeds. It’s almost a self-defeating process, balancing viability testing with sufficient quantities of seed to test and distribute.”

Payne said scientists are seeking new, non-invasive ways to test seed viability, potentially by checking seed respiration rates or rapid germination imaging technologies.

The government of Norway and the Global Crop Diversity Trust cover the cost of storage and upkeep of the Svalbard Global Seed Vault, coordinating shipments in conjunction with the Nordic Genetic Resource Center. Established in 2006, the Crop Trust supports the conservation and availability of crop diversity for food security worldwide and helps to fund CIMMYT’s work to collect and conserve maize and wheat genetic resources. The CGIAR Genebank Platform also supports CIMMYT’s maize and wheat germplasm bank.

CIMMYT's Germplasm Bank staff preparing a seed shipment to send to Svalbard. Photo: Alfonso Cortés/ CIMMYT — CIMMYT’s Germplasm Bank staff prepare a seed shipment set for Svalbard. Photo: Alfonso Cortés/ CIMMYT

Learn more about the activities of the Maize Germplasm Bank here, and about the Wheat Germplasm Bank here.

The Maize and Wheat Germplasm banks at the International Maize and Wheat Improvement Center are funded by Global Crop Diversity Trust, the CGIAR Genebank Platform and Germany’s development agency.