Velu Govindan will always remember his father telling him not to waste his food. “He used to say that rice and wheat are very expensive commodities, which most people could only afford to eat once a week during his youth,” recalls the wheat breeder, who works at the International Maize and Wheat Improvement Center (CIMMYT).
As in many parts of the world, the Green Revolution had a radical impact on agricultural production and diets in southern India, where Govindan’s father grew up, and by the late 1960s all farmers in the area had heard of “the scientist” from the USA. “Borlaug’s influence in India is so great because those new high-yielding varieties fed millions of people — including me.”
But feeding millions was only half the battle.
Today, at least two billion people around the world currently suffer from micronutrient deficiency, characterized by iron-deficiency anemia, lack of vitamin A and zinc deficiency.
Govindan works in collaboration with HarvestPlus to improve nutritional quality in cereals in addition to core traits like yield potential, disease resistance and climate tolerance. His area of focus is South Asia, where wheat is an important staple and many smallholder farmers don’t have access to a diversified diet including fruit, vegetables or animal products which are high in micronutrients like iron and zinc.
“It’s important that people not only have access to food, but also have a healthy diet,” says Govindan. “The idea is to improve major staples like rice, maize and wheat so that people who consume these biofortified varieties get extra benefits, satisfying their daily dietary needs as well as combatting hidden hunger.”
The challenge, he explains, is that breeding for nutritional quality is often done at the expense of yield. But varieties need high yield potential to be successful on the market because farmers in developing countries will not get a premium price simply for having a high micronutrient content in their grain.
Fast evolving wheat diseases are another issue to contend with. “If you release a disease-resistant variety today, in as little as three or four years’ time it will already be susceptible because rust strains keep mutating. It’s a continuous battle, but that’s plant breeding.”
Velu Govindan speaks at International Wheat Conference in 2015. (Photo: Julie Mollins/CIMMYT)
Mainstreaming zinc
When it comes to improvement, breeding is only the first part of the process, Govindan explains. “We can do a good job here in the lab, but if our varieties are not being taken up by farmers it’s no use.”
Govindan and his team work in collaboration with a number of public and private sector organizations to promote new varieties, partnering with national agricultural research systems and advanced research institutes to reach farmers in India, Nepal and Pakistan. As a result, additional high-zinc varieties have been successfully marketed and distributed across South Asia, as well as new biofortified lines which are currently being tested in sub-Saharan Africa for potential release and cultivation by farmers.
Their efforts paid off with the development and release of more than half dozen competitive high-zinc varieties including Zinc-Shakthi, whose grain holds 40% more zinc than conventional varieties and yields well, has good resistance to rust diseases, and matures a week earlier than other popular varieties, allowing farmers to increase their cropping intensity. To date, these biofortified high-zinc wheat varieties have reached nearly a million households in target regions of South Asia and are expected to spread more widely in coming years.
The next step will be to support the mainstreaming of zinc, so that it becomes an integral part of breeding programs as opposed to an optional addition. “Hopefully in ten years’ time, most of the wheat we eat will have those extra benefits.”
There may be a long way to go, but Govindan remains optimistic about the task ahead.
Velu Govindan examines wheat in the field.
Born into a farming family, he has fond memories of a childhood spent helping his father in the fields, with afternoons and school holidays dedicated to growing rice, cotton and a number of other crops on the family plot.
The region has undergone significant changes since then, and farmers now contend with both rising temperatures and unpredictable rainfall. It was a motivation to help poor farmers adapt to climate change and improve food production that led Govindan into plant breeding.
He has spent nearly ten years working on CIMMYT’s Spring Wheat Program and still feels honored to be part of a program with such a significant legacy. “Norman Borlaug, Sanjay Rajaram and my supervisor Ravi Singh — these people are legendary,” he explains. “So luckily we’re not starting from scratch. These people made life easy, and we just need to keep moving towards achieving continuous genetic gains for improved food and nutrition security.”
Experimental harvest of provitamin A-enriched orange maize, Zambia. (Photo: CIMMYT)
In just over a decade there will be around 8.5 billion people on earth, and almost 10 billion by 2050, according to the United Nations World Population Prospects 2019: Highlights.
The report said the newcomers will be concentrated in regions already facing grave food insecurity, rising temperatures, scarce water and erratic rainfall, such as sub-Saharan Africa and South Asia.
Even now, hungry persons worldwide exceed 850 million and an estimated 2 billion suffer micronutrient malnutrition, with costly health and social impacts.
By mid-century 7 of every 10 people will live in cities, according to United Nations data. With more mouths to feed and fewer farmers, food systems will be hard-pressed to grow and supply enough nutritious fare at affordable prices, while mitigating environmental damage.
Facing the challenges
As the examples below show, applied science and partnerships can help address these complex issues.
Decades of research and application by scientists, extension workers, machinery specialists, and farmers are refining and spreading practices that conserve soil and water resources, improve yields under hotter and drier conditions, and reduce the greenhouse gas emissions and pollution associated with maize and wheat farming in Africa, Asia, and Latin America.
A farmer tends a long-term on-farm conservation agriculture trial for a rice-wheat-mungbean cropping system in Rajshahi district, Bangladesh. (Photo: CIMMYT)
The sustained support of funders and policymakers will help ensure that CIMMYT staff and partners are able to continue improving the livelihoods and food security of smallholder farmers and resource-poor consumers, as world population density increases.
A community health worker in Rwanda talks to people on hygiene and the importance of a balanced diet, as part of the SUSTAIN project. (Photo: CIP)
STOCKHOLM, Sweden — Millions of families in Africa and South Asia have improved their diet with a special variety of sweet potato designed to tackle vitamin A deficiency, according to a report published today.
A six-year project, launched in 2013, used a double-edged approach of providing farming families with sweet potato cuttings as well as nutritional education on the benefits of orange-fleshed sweet potato.
The Scaling Up Sweetpotato through Agriculture and Nutrition (SUSTAIN) project, led by the International Potato Center (CIP) and more than 20 partners, reached more than 2.3 million households with children under five with planting material.
The project, which was rolled out in Kenya, Malawi, Mozambique and Rwanda as well as Bangladesh and Tanzania, resulted in 1.3 million women and children regularly eating orange-fleshed sweet potato when available.
“Vitamin A deficiency (VAD) is one of the most pernicious forms of undernourishment and can limit growth, weaken immunity, lead to blindness, and increase mortality in children,” said Barbara Wells, director general of CIP. “Globally, 165 million children under five suffer from VAD, mostly in Africa and Asia.”
“The results of the SUSTAIN project show that agriculture and nutrition interventions can reinforce each other to inspire behavior change towards healthier diets in smallholder households.”
Over the past decade, CIP and partners have developed dozens of biofortified varieties of orange-fleshed sweet potato in Africa and Asia. These varieties contain high levels of beta-carotene, which the body converts into vitamin A.
Just 125g of fresh orange-fleshed sweet potato provides the daily vitamin A needs of a pre-school child, as well as providing high levels of vitamins B6 and C, manganese and potassium.
Under the SUSTAIN project, families in target communities received nutritional education at rural health centers as well as cuttings that they could then plant and grow.
For every household directly reached with planting material, an additional 4.2 households were reached on average through farmer-to-farmer interactions or partner activities using technologies or materials developed by SUSTAIN.
The project also promoted commercial opportunities for smallholder farmers with annual sales of orange-fleshed sweet potato puree-based products estimated at more than $890,000 as a result of the project.
Two women sort orange-fleshed sweet potato in Faridpur district, Bangladesh. (Photo: Sara Quinn/CIP)
Perspectives from the Global South
The results of the initiative were published during the EAT Forum in Stockholm, where CGIAR scientists discussed the recommendations of the EAT-Lancet report from the perspective of developing countries.
“The SUSTAIN project showed the enormous potential for achieving both healthy and sustainable diets in developing countries using improved varieties of crops that are already widely grown,” said Simon Heck, program leader, CIP.
“Sweet potato should be included as the basis for a sustainable diet in many developing countries because it provides more calories per hectare and per growing month than all the major grain crops, while tackling a major nutrition-related health issue.”
At an EAT Forum side event, scientists highlighted that most food is grown by small-scale producers in low- and middle-income countries, where hunger and undernutrition are prevalent and where some of the largest opportunities exist for food system and dietary transformation.
“There are almost 500 million small farms that comprise close to half the world’s farmland and are home to many of the world’s most vulnerable populations,” said Martin Kropff, director general of the International Maize and Wheat Improvement Center (CIMMYT).
“Without access to appropriate technologies and support to sustainably intensify production, small farmers — the backbone of our global food system — will not be able to actively contribute a global food transformation.”
Matthew Morell, director general of the International Rice Research Institute (IRRI), added: “If the EAT-Lancet planetary health diet guidelines are to be truly global, they will need to be adapted to developing-world realities — such as addressing Vitamin A deficiency through bio-fortification of a range of staple crops.
“This creative approach is a strong example of how to address a devastating and persistent nutrition gap in South Asia and Africa.”
The International Potato Center (CIP) was founded in 1971 as a research-for-development organization with a focus on potato, sweet potato and Andean roots and tubers. It delivers innovative science-based solutions to enhance access to affordable nutritious food, foster inclusive sustainable business and employment growth, and drive the climate resilience of root and tuber agri-food systems. Headquartered in Lima, Peru, CIP has a research presence in more than 20 countries in Africa, Asia and Latin America. CIP is a CGIAR research center. www.cipotato.org
CGIAR is a global research partnership for a food-secure future. CGIAR science is dedicated to reducing poverty, enhancing food and nutrition security, and improving natural resources and ecosystem services. Its research is carried out by 15 CGIAR centers in close collaboration with hundreds of partners, including national and regional research institutes, civil society organizations, academia, development organizations and the private sector. www.cgiar.org
TEXCOCO, Mexico (CIMMYT) — More nutritious crop varieties developed and spread through a unique global science partnership are offering enhanced nutrition for hundreds of millions of people whose diets depend heavily on staple crops such as maize and wheat, according to a new studyin the science journal Cereal Foods World.
From work begun in the late 1990s and supported by numerous national research organizations and scaling partners, more than 60 maize and wheat varieties whose grain features enhanced levels of zinc or provitamin A have been released to farmers and consumers in 19 countries of Africa, Asia, and Latin America over the last 7 years. All were developed using conventional cross-breeding.
Farmer and consumer interest has grown for some 60 maize and wheat varieties whose grain features enhanced levels of the essential micronutrients zinc and provitamin A, developed and promoted through collaborations of CIMMYT, HarvestPlus, and partners in 19 countries (Map: Sam Storr/CIMMYT).
“The varieties are spreading among smallholder farmers and households in areas where diets often lack these essential micronutrients, because people cannot afford diverse foods and depend heavily on dishes made from staple crops,” said Natalia Palacios, maize nutrition quality specialist at the International Maize and Wheat Improvement Center (CIMMYT) and co-author of the study.
More than 2 billion people worldwide suffer from “hidden hunger,” wherein they fail to obtain enough of such micronutrients from the foods they eat and suffer serious ailments including poor vision, vomiting, and diarrhea, especially in children, according to Wolfgang Pfeiffer, co-author of the study and head of research, development, delivery, and commercialization of biofortified crops at the CGIAR program known as “HarvestPlus.”
“Biofortification — the development of micronutrient-dense staple crops using traditional breeding and modern biotechnology — is a promising approach to improve nutrition, as part of an integrated, food systems strategy,” said Pfeiffer, noting that HarvestPlus, CIMMYT, and the International Institute of Tropical Agriculture (IITA) are catalyzing the creation and global spread of biofortified maize and wheat.
“Eating provitamin A maize has been shown to be as effective as taking Vitamin A supplements,” he explained, “and a 2018 study in India found that using zinc-biofortified wheat to prepare traditional foods can significantly improve children’s health.”
Six biofortified wheat varieties released in India and Pakistan feature grain with 6–12 parts per million more zinc than is found traditional wheat, as well as drought tolerance and resistance to locally important wheat diseases, said Velu Govindan, a breeder who leads CIMMYT’s work on biofortified wheat and co-authored the study.
“Through dozens of public–private partnerships and farmer participatory trials, we’re testing and promoting high-zinc wheat varieties in Afghanistan, Ethiopia, Nepal, Rwanda, and Zimbabwe,” Govindan said. “CIMMYT is also seeking funding to make high-zinc grain a core trait in all its breeding lines.”
Pfeiffer said that partners in this effort are promoting the full integration of biofortified maize and wheat varieties into research, policy, and food value chains. “Communications and raising awareness about biofortified crops are key to our work.”
For more information or interviews, contact:
Mike Listman Communications Consultant
International Maize and Wheat Improvement Center (CIMMYT)
m.listman@cgiar.org, +52 (1595) 957 3490
While increasing yields will be necessary to feed the 9.8 billion people expected by 2050, Natalia Palacios — head of the maize nutritional quality laboratory at CIMMYT — says that’s only part of the challenge. She argues we must also strive for higher-quality, more nutritious crops. According to the United Nations Food and Agriculture Organization, over 800 million people are considered undernourished. That’s about one out of every nine people in the world. Find out how Palacios’ research helps CIMMYT and its partners close the gap and support better health and nutrition.
For more information on Palacios’ research linking provitamin A orange maize and reduced aflatoxin contamination, read the publication here.
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.
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).
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 lead to severe health damage, blindness, or even death, particularly among children under the age of five. Furthermore, a recent FAO report estimates the number of undernourished people worldwide at over 800 million, with severe food insecurity and undernourishment increasing in almost all sub-regions of Africa, as well as across South America.
In recognition of World Food Day and the focus of the 2018 World Food Prize on nutrition, the CGIAR Research Centers and Programs reflect on the significance and global impact of biofortification and climate resilient crops – key components in achieving Sustainable Development Goals 2: Zero Hunger and 3: Good Health and Wellbeing by 2030.
Biofortification enables scientists to fortify staple crops with micronutrients to address hidden hunger. There are now 290 new varieties of 12 biofortified crops – including maize, wheat and potatoes – being grown in 60 countries, reaching an estimated 10 million farming households.
The first biofortified maize variety was quality protein maize (QPM), developed by International Maize and Wheat Improvement Center (CIMMYT) scientists Evangelina Villegas and Surinder Vasal. QPM features enhanced levels of lysine and tryptophan, essential amino acids, which can help reduce malnutrition in children. Villegas and Vasal would later go on to win the World Food Prize in 2000 for this groundbreaking work, and genetic variation found in QPM would serve as the baseline for developing further biofortified products, such as zinc-enriched maize and vitamin A orange maize.
Biofortified, provitamin A enriched maize at an experimental plot in Zambia. Photo: CIMMYT
Several key factors have contributed to the success of biofortification. One is partnership. The CGIAR Centers work with hundreds of partners around the world, from national governments and research institutes through to non-governmental organizations and farmers on the ground. Other factors include the ability to build evidence and conduct thorough monitoring and evaluation, the maintenance of a clear vision on how research will have impact, and coordinated investment.
In considering the future role of biofortification in our evolving agricultural landscape, the article highlights the need to tie up with meeting global goals on sustainable development in terms of food security and improved nutrition, and the importance of ‘future proofing’ new varieties in the face of climate change.
In further support of biofortification, the UK’s Department for International Development (DFID) recognized the importance of CGIAR’s world-renowned agricultural research in the fight to end global hunger. Support from DFID has been crucial to biofortification work in Africa as well as in the development of drought-tolerant maize by CIMMYT and the CGIAR Research Program on Maize (MAIZE), which has increased farmers’ yields by up to 30 per cent, benefitting 20 million people in 13 African countries. Over 300 drought tolerant maize varieties were released by CIMMYT under the Drought Tolerant Maize for Africa (DTMA) project, which ran from 2006 to 2015, and continue to be scaled out and provide benefits to smallholder farmers in the region today. DFID also highlighted the impact of their support to CIMMYT and the CGIAR Research Program on Wheat (WHEAT) in the development of disease resistant wheat varieties that help avoid food shortages and exacerbated hunger worldwide.
After a prolonged decline in global hunger, findings pointing to a recent increase are alarming. Coupled with uncertainties surrounding food supply due to challenges like changing climates and ever-present crop pests and diseases, the challenges we face are significant. The development and deployment of crops biofortified with nourishing micronutrients and equipped to cope with abiotic and biotic stresses is of fundamental importance. The work of the CGIAR Centers and Research Programs is vital to improve the livelihoods of smallholder farmers and to fuel the fight towards zero hunger by 2030.
On World Food Day, October 16, the International Maize and Wheat Improvement Center (CIMMYT) joins the Food and Agriculture Organization of the United Nations and partners around the world in their call to realize Sustainable Development Goal 2: Zero Hunger by 2030. Learn how CIMMYT, HarvestPlus and Semilla Nueva are working together to use biofortified zinc-enriched maize to reduce malnutrition in Guatemala, an important component of Goal 2.
Over 46 percent of children under five in Guatemala suffer from chronic malnutrition. More than 40 percent of the country’s rural population is 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. CIMMYT, HarvestPlus and Semilla Nueva are working together to change this, through the development and deployment of the world’s first biofortified zinc-enriched maize.
“In Latin America, Guatemala is among the top 3 countries with the highest rates of zinc and iron deficiencies, and it is characterized by a high production and consumption of staple foods such as maize and beans. This made Guatemala, along with Haiti, the top prioritized countries for biofortification in the region, according to the Biofortification Priority Index (BPI) for Latin America,” said Salomón Pérez, the HarvestPlus country coordinator for Guatemala. HarvestPlus developed the BPI in 2013 to select the countries, crops and micronutrients in which to focus their efforts in Latin America. The BPI combines three sub-indexes: production, consumption and micronutrient deficiency level. “As maize is a staple food in Guatemala, with high levels of consumption and production, the development of biofortified maize with enhanced zinc was prioritized for the country,” he said.
Biofortified maize is a unique and efficient way of improving nutrition. As the nutrients occur naturally in the plant, consumers do not have to make any behavioral changes to get results. Rather than having to import supplements or fortify food, seeds and crops are sourced within the country, which makes this option more sustainable and accessible even in remote rural areas. It tastes the same as non-biofortified maize varieties and requires no special preparation methods. This made biofortification the obvious choice for improving zinc deficiency in Guatemala, and CIMMYT the obvious partner.
“CIMMYT has over 50 years of experience in tropical maize breeding for different traits,” said Félix San Vicente, one of the CIMMYT maize breeders leading the project. “Throughout our history we have developed elite materials with important agronomic and nutritional traits, such as Quality Protein Maize (QPM).”
The long lineage of zinc maize
Developed by CIMMYT scientists Evangelina Villegas and Surinder Vasal, QPM has enhanced levels of lysine and tryptophan, essential amino acids, which can help reduce malnutrition in children. Villegas and Vasal would later go on to win the World Food Prize in 2000 for this groundbreaking work, and genetic variation found in QPM would serve as the baseline for developing zinc-enriched maize.
A maize plot of the Fortaleza F3 variety in Guatemala. Photo: Sarah Caroline Mueller.
After years of breeding work and research, the world’s first biofortified zinc maize hybrid, ICTA HB-18, was released in Guatemala in May 2018. It was developed by CIMMYT, the CGIAR Research Programs on Maize (MAIZE) and Agriculture for Nutrition and Health (A4NH), and Guatemala’s Institute for Agricultural Science and Technology (ICTA) with support from HarvestPlus. Commercialized by Semilla Nueva under the name Fortaleza F3, the biofortified zinc maize hybrid contains 6-12ppm more zinc and 2.5 times more quality protein compared to conventional maize varieties. An open pollinated variety, ICTA B-15, was also released.
Just 100 grams of tortilla made of either of these varieties can provide 2.5 milligrams of zinc, 50 percent of the daily recommended intake for children, making zinc-enriched biofortified maize an excellent tool in the fight against malnutrition and hidden hunger.
As CIMMYT is a breeding organization, it depends on national partners to get seeds to the farmers. That is where Semilla Nueva comes in. This non-profit social enterprise is working to get high yielding biofortified seeds to farmers in Guatemala.
Rómulo González’s daughter holds a corncob. Photo: Sarah Caroline Mueller.
The last mile
“We need to be able to impact farmers with our improved germplasm,” said San Vicente. “Semilla Nueva takes us to the last mile, to the farmers, which alone we could not do, so that our breeding work can achieve impact in farmers’ fields and lives.”
Semilla Nueva targets commercial farmers in Guatemala, as they are the main source of maize consumed in the country. Typically, a quarter of their harvest is consumed at home and surplus is sold in local markets, meaning that the zinc maize not only provides increased income to farmers, but also improves nutrition in their families, communities and country at large.
“CIMMYT, along with partners like HarvestPlus, have provided the technologies and support to allow us to come up with new ways to improve farmers’ lives. Tapping into decades of research from qualified scientists is the only way that an organization of our size can have hope of making an impact in the lives of millions of farmers. That’s what makes the partnership so incredible,” said Curt Bowen, executive director and cofounder of Semilla Nueva. “We provide the innovative way to get technologies to farmers through our social enterprise model. CIMMYT and HarvestPlus come up with the technologies that we never could have come up with on our own. Together, we help thousands of families make huge changes in their lives and take on malnutrition, which is one of the world’s biggest challenges to ending global poverty.”
Semilla Nueva plans to produce 5,000 bags of Fortaleza F3 next year, which will represent 5 percent of the Guatemalan hybrid seed market.
Farmer Rómulo González on his maize plot.Photo: Sarah Caroline Mueller.
“Farmers have responded very positively to Fortaleza F3. They are convinced of its performance, especially during the dry season,” said Angela Bastidas, senior operations director at Semilla Nueva. “The way we approach farmers is not different than other seed companies; through farm visits, meetings, or field days. We are not reinventing the wheel. The difference with us has been offering farmers exactly what they need in terms of maize performance and price. Additionally, they find that our maize produces soft tortillas that taste better!” she explained.
In the end, the results speak for themselves. Fortaleza F3 increases yields by 13 percent and profits by $164 per bag compared to other mid-priced seeds, which goes a long way in improving farming families’ livelihoods, food security and nutrition.
“With Fortaleza F3, I pay less for the seed compared to other mid-priced competitors that I used to plant. F3 also yields more, giving me a greater profit,” said Rómulo González, a farmer from the southern coast of Guatemala. “With the extra income I’ve gotten since switching to F3, I’ve been paying for my daughter to go to school. Fortaleza F3 not only gave me a good harvest, but also the ability to support my daughter’s education.”
Natalia Palacios, CIMMYT maize quality specialist, spearheads the center’s work to raise the nutritional value of maize-based foods.
Exposure to more frequent and intense climate extremes is threatening to reverse progress towards ending hunger and malnutrition. New evidence points to rising world hunger. A recent FAO report estimated the number of undernourished people worldwide at over 800 million. Severe food insecurity and undernourishment are increasing in almost all sub-regions of Africa, as well as across South America.
“It’s very important to ensure food security,” says CIMMYT maize quality specialist Natalia Palacios. “But we also have to focus on food nutrition, because increasing yields doesn’t always mean that we’re improving food quality.” Food quality, she explained, is affected not only by genetics, but also by crop and postharvest management practices. As head of CIMMYT’s maize nutritional quality laboratory, Palacios’ work combines research on all three.
What role can CIMMYT play in addressing global nutrition challenges?
Nutrition is an interdisciplinary issue, so there are several ways for CIMMYT to engage. In breeding, there’s a lot we can do in biofortification—which means to increase grain nutrient content. The CIMMYT germplasm bank, with its more than 175,000 unique collections of maize and wheat seed, is an invaluable source of genetic traits to develop new nutritious and competitive crops.
CIMMYT also addresses household nutrition challenges, including food availability, proper storage, and consumer behavior and choice. In cropping systems, the Center studies and promotes diversification, agroforestry, and improved soil health and farming practices, and at the landscape level it examines the role of agricultural practices. Gender research and foresight allow us to identify our role in the evolving setting of agri-food systems and rural transformation. We are prioritizing areas where CIMMYT can play a key role to address global nutrition challenges and partner effectively with leading nutrition groups worldwide.
How does the biofortification of staple crops like maize and wheat help to improve nutrition?
CIMMYT biofortification research has focused on micronutrients such as provitamin A in maize and zinc in both maize and wheat, to benefit consumers whose diets depend on those crops and may lack diversity. Biofortification must be complemented by enhanced dietary diversification and education for better nutrition.
How important are processing and post-harvest storage in terms of ensuring high-nutritional quality?
Research on post-harvest processing and storage is key to our work. A critical topic in maize is monitoring, understanding, and controlling aflatoxins—poisonous toxins produced by molds on the grain. CIMMYT has worked mainly to develop aflatoxin-tolerant maize, but recent funding from the Mexican food industry has enabled us to launch a small, more broadly-focused study.
In the past, aflatoxins showed up every three or four years in Mexico, and even then at fairly low levels. Aflatoxin incidence has lately become more frequent, appearing almost every year or two, as climate changes expose crops to higher temperatures and fungi are more likely to develop in the field or storage, especially when storage conditions are poor.
What are the implications of high aflatoxin incidence for health and nutrition?
The implications for health and nutrition are huge. High consumption can affect the immune system and lead to pancreatic and liver cancers, among other grave illnesses.
How easy is it to tell if a kernel is contaminated?
It’s impossible to tell whether grain is contaminated without doing tests. The chemical structure of the toxin includes a lactone ring that fluoresces under UV-light, but this method only tells you whether or not the toxin is present, and results depend contamination levels and kernel placement under the lamp.
We’re spreading the lamp method among farmers so they can detect contamination in their crops, as well as making other of our other methods more accessible and less expensive, for use by farmers and food processors.
Ashley Muzhange eats sadza with her family in rural Zimabwe. Her sadza is made with vitamin A orange maize, a variety improving the nutrition of children and families in the nation. Photo: Matthew O’Leary/ CIMMYT
In the rural Chiweshe Communal Area, about two hours north of Zimbabwe’s capital Harare, 18-month-old Ashley Muzhange tucks into a bowl of vitamin A orange maize sadza. Sadza, a thickened porridge made from finely ground maize grain with a side of stewed vegetables, is the staple dish for rural families.
Ashley’s sadza is made from biofortified maize, conventionally bred by researchers at the International Maize and Wheat Improvement Center (CIMMYT) under the work of HarvestPlus to contain a higher amount of nutritious vitamin A.
Recent prolonged drought pushed malnutrition to levels not seen in over 15 years, with almost 33,000 children in need of urgent treatment for severe acute malnutrition, according to the United Nations Children’s Fund (UNICEF). Many experience micronutrient deficiencies, since their diets lack the vitamins and minerals required for growth and development.
Ashley’s mother, Lilian Muzhange, prepares fritas made with vitamin A orange maize grown on their family farm. Photo: Matthew O’Leary/ CIMMYT
According to the World Health Organization, 35.8 percent of preschool aged children suffer from vitamin A deficiency. The leading cause of preventable blindness in children, it compromises the immune system increasing the risk of death from diseases like measles, diarrhea and respiratory infections.
Biofortification increases the density of vitamins and minerals in a crop through conventional plant breeding or agronomic practices. When consumed regularly, biofortified crops generate measurable improvements in health and nutrition. The process develops crops rich in nutrients for consumers as well as the agronomic characteristics like drought and disease resistance valued by farmers. It is considered a sustainable way to bring micronutrients to populations with limited access to diverse diets.
Even though baby Ashley is unaware her sadza not only fills her stomach, but also provides her with a dose of vitamin A, her family is conscious of the benefits.
“This orange maize assures me that my daughter gets a nutritious meal and means we don’t only rely on the supplements provided by the government,” said Lilian Muzhange, her mother.
Orange the color of health
The farming family first began trialing the biofortified vitamin A orange maize in 2015 and are now growing it in place of traditional white maize. The nutritious variety contains high levels of beta-carotene, a vitamin A precursor that produces the rich orange color and once ingested is converted into the micronutrient, acting as an antioxidant to protect cells.
“Our family now prefers the new vitamin A orange maize over the white maize, as it has great health benefits for my children and granddaughter and the taste is delicious. The sadza truly is better,” said Ashley’s grandfather Musonza Musiiwa. “I was also pleased the variety is drought tolerant. Despite a dry spell in January my maize was able to yield a good harvest.”
Orange maize conventionally bred to contain high amounts of vitamin A is fighting child malnutrition in Zimbabwe. (Photo: Matthew O’Leary/ CIMMYT)
Rural diets mainly consist of what farming families can grow, which is predominantly maize, said CIMMYT maize breeder Thokozile Ndhlela. The majority of rural households do not meet minimum dietary diversity, reliant on a cereal-based diet where meat is a rarity, the Zimbabwe Food and Nutrition Council finds.
“White maize traditionally used for the staple sadza is predominantly starch and very low in nutritional value,” said Ndhlela, who leads CIMMYT’s biofortified breeding efforts in Zimbabwe. “Biofortifying this staple crop ensures consumers have access to nutritious food season after season as farmers continue to grow it.”
Musiiwa not only sees the health and agronomic benefits of vitamin A orange maize, but has also identified its economic opportunity. The farmer is planning to increase the amount he grows to capitalize on the market he believes is set to grow.
Getting vitamin A maize into farmers’ fields and onto plates
Sakile Kudita, HarvestPlus researcher, explains the benefits of of vitamin A orange maize to seed company and government representatives. Photo: Matthew O’Leary/ CIMMYT
For the new biofortified maize to be part of the food system it must be commercialized creating a full value chain, said Sakile Kudita, a demand creation researcher with HarvestPlus, a program improving nutrition and public health by developing and promoting biofortified food crops.
“Vitamin A orange maize needs to be a product millers take up and processed foods are made of, so that seed companies have an incentive to keep producing seed and farmers have an incentive to grow more than just for consumption but also sale in order to generate income,” she said.
The efforts of HarvestPlus and CIMMYT to engage government, food processors and seed companies at field days, where they learn about the nutritional and agronomic benefits and taste the orange maize have yielded success, said Kudita. Working with the government, four biofortified varieties have been commercialized since 2015.
Prime Seed Co, a subsidiary of the regional certified seed company Seed Co, was the first company commissioned by the government to commercialize vitamin A orange maize in Zimbabwe and now sells the variety Musiiwa uses in his field.
Prime Seed Co worked with CIMMYT, HarvestPlus and the Zimbabwe government to release the first vitamin A orange maize variety onto the market. Photo: Thoko Ndhlela/ CIMMYT
“Through our partnership with CIMMYT and HarvestPlus we are developing a market for vitamin A orange maize in Zimbabwe,” said Masimba Kanyepi, a sales manager at Prime Seed Co. “We have seen our sales improve since launching the first variety and expect an increase.”
Kanyepi is confident the market will grow following a new government regulation requiring all processed maize products to contain added micronutrients, including vitamin A, through fortification.
Food industry representatives taste-test foods made with vitamin A orange maize at an open day. Photo: Matthew O’Leary/ CIMMYT
“Adding vitamin A to maize at the processing stage is expensive for food companies due to the cost of importing the vitamin from overseas,” said Kanyepi. “Buying vitamin A orange maize grown by local farmers already biofortified at the same price as the white variety makes economic sense.”
Food companies see the saving with Zimbabwe manufacturer, Cairns Foods, confirming it’s taking steps to include biofortified maize in its cereals and biofortified beans in its canned products.
With food processors and millers buying vitamin A orange maize there is demand for farming families like the Musiiwas to grow more, ensuring not only a boost to their health but also their livelihood, said Kudita.
Breeding for a more nutritious future
Vitamin A orange maize in a farmer’s field. Photo: Matthew O’Leary/ CIMMYT
The crop diversity found in the maize species is key to nutritional gain. The plant grows in distinct environments and has developed a diverse range of valuable traits including nutritional properties.
Following a lengthy analysis of thousands of samples in the CIMMYT Maize Germplasm Bank researchers discovered native landraces and varieties from South and Central America containing increased levels of beta-carotene, explained Ndhlela. These were included in breeding programs in Africa and crossed with local varieties to ensure they were fit for the subtropical climate and were tolerant to local biotic and abiotic stresses.
Working alongside Zimbabwe’s national breeding program Ndhlela continually monitors, improves and combines dozens of characteristics, which include high yield potential, nitrogen use efficiency, and tolerance to drought, into new varieties that meet farmers’ preferences.
The most recent biofortified varieties contain about 39 percent more vitamin A compared to the first, she said.
“CIMMYT’s support through free access to maize germplasm and breeding expertise has allowed us to continue developing this nutritious maize,” said Prince Matova, a maize breeder with the Zimbabwe Ministry of Agriculture. “In the next few years we expect to release two more varieties.”
At the end of the day, farming is a business and farmers value varieties with high yield, adapted to stress conditions. The breeders are currently trialing new vitamin A maize varieties with the hope of identifying those with the potential to yield as much as the traditional white varieties and are already garnering positive feedback from farmers.
CIMMYT maize breeder Thoko Ndhlela shows food industry representatives the agronomic benefits of vitamin A orange maize in the field. Photo: Matthew O’Leary/ CIMMYT
CIMMYT’s biofortified vitamin A maize breeding is supported by HarvestPlus. HarvestPlus improves nutrition and public health by developing and promoting biofortified food crops that are rich in vitamins and minerals, and providing global leadership on biofortification evidence and technology. HarvestPlus is part of the CGIAR Research Program on Agriculture for Nutrition and Health (A4NH). CGIAR is a global agriculture research partnership for a food secure future. Its science is carried out by its 15 research centers in collaboration with hundreds of partner organizations. The HarvestPlus program is coordinated by two of these centers, the International Center for Tropical Agriculture (CIAT) and the International Food Policy Research Institute (IFPRI).
HarvestPlus’ principal donors are the UK Government; the Bill & Melinda Gates Foundation; the US Government’s Feed the Future initiative; the European Commission; and donors to the CGIAR Research Program on Agriculture for Nutrition and Health. HarvestPlus is also supported by the John D. and Catherine T. MacArthur Foundation.
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.
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.
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 4th 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.
Wheat fields at the Campo Experimental Norman E. Borlaug (CENEB) near Ciudad Obregón, Sonora, Mexico. Photo: M. Ellis/CIMMYT.
MEXICO CITY (CIMMYT) — Malnutrition is rising again and becoming more complex, according to the head of the world’s leading public maize and wheat research center.
“Those people suffer from calorie malnutrition and go to bed hungry at night, which is a terrible thing,” Kropff added. “But the diets of 2 billion persons worldwide lack essential micronutrients — Vitamin A, iron, or zinc — and this especially affects the health and development of children under 5 years old.”
Kropff noted that some 650 million people are obese, and the number is increasing. “All these nutrition issues are interconnected, and are driven by rising population, global conflicts, and — for obesity — increasing prosperity, in developed and emerging economies.”
“The solution? Good, healthy diets,” said Kropff, “which in turn depend on having enough food available, but also diverse crops and food types and consumer education on healthy eating.”
The world’s quickly-rising population needs not only more food but healthier, more nutritious food, according to Julie Miller Jones, Professor Emerita at St. Catherine University, and Carlos Guzmán, who leads wheat quality research at CIMMYT.
Held in Mexico City during 11-14 March and co-organized by CIMMYT and the International Association for Cereal Science and Technology (ICC), the 4th Latin American Cereals Conference has drawn more than 220 participants from 46 countries, including professionals in agricultural science and production, the food industry, regulatory agencies, and trade associations.
“We are dedicated to spreading information about cereal science and technology, processing, and the health benefits of cereals,” said Hamit Köksel, president of the ICC and professor at Hacettepe University, Turkey, to open the event. “Regarding the latter, we should increase our whole grain consumption.”
Köksel added that ICC has more than 10,000 subscribers in 85 countries.
Breeding micronutrient-dense cereals
One way to improve the nutrition and health of the poor who cannot afford dietary supplements or diverse foods is through “biofortification” of the staple crops that comprise much of their diets.
Drawing upon landraces and diverse other sources in maize and wheat’s genetic pools and applying innovative breeding, CIMMYT has developed high-yielding maize and wheat lines and varieties that feature enhanced levels of grain zinc and are being used in breeding programs worldwide.
“In the last four years, the national research programs of Bangladesh, India, and Pakistan have released six zinc-biofortified wheat varieties derived from CIMMYT research,” said Hans Braun, director of the center’s global wheat program. “Zinc-Shakthi, an early-maturing wheat variety released in India in 2014 whose grain features 40 percent more zinc than conventional varieties, is already grown by more than 50,000 smallholder farmers in the Northeastern Gangetic Plains of India.”
New zinc biofortified maize variety BIO-MZN01, recently released in Colombia. Photo: CIMMYT archives
CIMMYT is focusing on enhancing the levels of provitamin A and zinc in the maize germplasm adapted to sub-Saharan Africa, Asia, and Latin America. Improved quality protein maize (QPM) varieties, whose grain features enhanced levels of two essential amino acids, lysine and tryptophan, is another major biofortified maize that is grown worldwide, according to Prasanna Boddupalli, director of CIMMYT’s global maize program.
“Quality protein maize varieties are grown by farmers on 1.2 million hectares in Africa, Asia, and Latin America,” said Prasanna, in his presentation, adding that provitamin-A-enriched maize varieties have also been released in several countries in Africa, besides Asia.
“Biofortified crops have been released in 60 countries,” said Wolfgang Pfeiffer, HarvestPlus global director for product development and commercialization, speaking at the conference. “The pressing need now is to ‘mainstream’ biofortification, making it a standard component of breeding programs and food systems.”
Whole grains are good for you
A central issue on the conference agenda is promoting awareness about the importance of healthy diets and the role of whole grains.
“Participants will discuss the large body of published studies showing that whole grain foods, including processed ones, are associated with a significantly reduced risk of chronic diseases and obesity,” said Carlos Guzmán, who leads wheat quality research at CIMMYT and helped organize the conference. “There is a global movement to promote the consumption of whole grains and the food industry worldwide is responding to rising consumer demand for whole grain products.”
Guzmán also thanked the conference sponsors: Bimbo, Bastak Instruments, Brabender, Foss, Chopin Technologies, Perten, Stable Micro Systems Scientific Instruments, Cereal Partners Worldwide Nestlé and General Mills, Stern Ingredients-Mexico, World Grain, the CGIAR Research Program on Wheat, and Megazyme.
To learn more about the Latin American Cereals Conference and the International Gluten Workshop, click here.
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.
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.
New zinc-biofortified maize variety BIO-MZn01. (Photo: CIMMYT)
“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.
