CIMMYT has several offices in the Americas, including global headquarters in Mexico and a regional office in Colombia. Activities are supported by an additional 140 hectares of stations in diverse agro-ecological zones of Mexico. CIMMYT’s genebank in Mexico stores 27,000 maize and 170,000 wheat seed collections – key to preserving the crop genetic diversity of the region. CIMMYT projects range from developing nutritionally enhanced maize to mapping regional climate change hot spots in Central America. The comprehensive MasAgro project aims to increase wheat production in Mexico by 9 million tons and maize production by 350,000 tons by 2030. CIMMYT promotes regional collaboration and facilitates capacity building for scientists, researchers and technicians.
CIMMYT researcher Bram Govaerts participates in the World Food Prize and Borlaug Dialogue.
Expertise, multiple achievements and a significant contribution to sustainable agri-food systems in Mexico and globally, have merited Bram Govaerts, director of the Integrated Development Program and regional representative for the Americas at the International Maize and Wheat Improvement Center (CIMMYT), Cornell University’s appointment as Andrew D. White Professor-at-Large. This is a distinction granted to individuals whose work in science, education, social sciences, literature and creative arts has had great impact and international visibility.
Cornell University launched the Professors-at-Large program to commemorate its centenary and to honor its first president, Andrew D. White. The program secures a connection between the university and its faculty with the world, global issues, great thinkers and outstanding intellectuals. Since then, personalities such as philosopher Jacques Derrida, writer and poet Octavio Paz, geneticist M. S. Swaminathan, and Nobel Peace Prize recipient Norman Borlaug have received this distinction.
“I was honored to learn about my nomination and glad to be interviewed, but I was happily surprised and humbled to learn that I had been chosen to join this group of distinguished thinkers and artists, which has welcomed such outstanding members as Norman Borlaug and Octavio Paz,” said Govaerts.
Professors-at-Large take the responsibility to participate, over a six-year period, in several activities that strengthen the international academic community and are, afterwards, considered distinguished and lifetime members of the university.
Govaerts takes inspiration from the “take it to the farmer” vision, and has been instrumental to the development of CIMMYT’s project portfolio, which integrates innovations in maize and wheat production systems by minimizing their environmental impact.
Govaerts shares this acknowledgement with his team and collaborators who have joined efforts to achieve the objectives set in Colombia, Ethiopia, Guatemala, Mexico and many other countries that have taken the decision to make a difference.
In 2014, Bram Govaerts received from the World Food Prize Foundation the Norman E. Borlaug Award for Field Research and Application, endowed by the Rockefeller Foundation, for leading the MasAgro project and finding innovative ways of applying science to improve the productivity and resilience of small and medium-sized maize and wheat farmers in Mexico.
Expert Mexican scientists and farmer cooperatives have formed a non-profit organization to support small-scale landrace maize farmers who continue to conserve and plant seeds of their own native heirloom varieties. The civil association, known as ProMaíz Nativo, intends to work collaboratively on projects to improve the lives of native maize and milpa farm families. Group members include national and internationally recognized maize experts, ethnobotanists, socioeconomists, food and nutrition scientists, marketing experts, maize farmers and farmer groups.
The civil association has also created a collective trademark, Milpaiz, which can be used by farmers to demonstrate the authenticity of the native maize varieties they grow and sell. This trademark will certify that a farmer’s maize is native to their community and derived from their continuous selection of seed. It will also certify that it is grown by small farmers and that they are selling only the surplus of their crops after feeding their own family. The trademark will also make a transparent effort to connect these farmers to a culinary market which values the quality, rarity and history of their production.
“Mexico is the center of origin of maize, and home to much of its genetic diversity. This initiative will allow us to certify that products are truly landrace maize from smallholder farmers, so that the benefits reach the smallholder farmers that have provided us with this biodiversity,” said Flavio Aragón, a genetic resources researcher with Mexico’s National Institute for Forestry, Agriculture and Livestock Research (INIFAP).
Members of the association gather for a photo at the launch event. (Photo: ProMaíz Nativo)
Researchers like Aragon, members of farmer groups and local chefs attended the official launch of ProMaíz Nativo on June 14, 2019, at the World Trade Center in Mexico City, during restaurant trade fair ExpoRestaurantes.
Edelmira Linares, ethnobotanist at the National Autonomous University of Mexico (UNAM) and member of the association, emphasized that the collective trademark Milpaiz covers all crops grown in the traditional milpa intercrop farming system in Mexico: maize, beans, squash, edible greens, amaranth, pumpkin seeds, and certain vegetables.
“The trademark will make it easier for income to reach the farmers, will allow smallholder farmers to sell their products in supermarkets and to have a legal presence,” said Amanda Galvez, a food chemist at UNAM and president of ProMaíz Nativo.
Traditional milpa products: native maize, beans, squash, chilies and other local fruits and vegetables. (Photo: Martha Willcox/CIMMYT)
Fair and sustainable market growth
Many smallholder farmers continue to plant the same native maize varieties that their parents and grandparents planted, developed in their villages and regions and improved by farmer selection dating back to their ancestors. These varieties are prized by their local communities for their unique flavors, colors, texture and use in special dishes — and the global culinary community is catching on. Native maize, or landraces, have become extremely popular with chefs and consumers in the past few years, drawing attention and imports from across the world. However, increased demand can mean increased vulnerability for farmers.
Many maize experts in Mexico were concerned with how to best support and protect smallholder farmers navigating this increase in demand. Without guidelines and transparency, it is difficult to ensure that farmers are being fairly compensated for their traditional maize, or that they are able to save enough to feed their own families.
In a discerning culinary market, a symbol of certification such as the collective trademark could serve to differentiate the families who have long been the guardians of these native varieties from larger commercial farmers who acquire these heirloom seeds. But there was no pre-existing space for these guidelines to be determined and developed.
Martha Willcox (left) with farmers and their milpa products in Santa María Yavesía, Oaxaca state, México. (Photo: Arturo Silva/CIMMYT)
“There is a depth of expertise on maize in Mexico, but these experts all work at different institutions, making it more difficult for all of them to collaborate on a project like this,” said Martha Willcox, landrace improvement coordinator at the International Maize and Wheat Improvement Center (CIMMYT).
“The formation of this civil association is truly novel in the history of native maize in Mexico, and its strength comes from the expertise of its members, made up entirely of Mexican scientists and Mexican farmer co-ops,” Willcox explained.
She initiated and facilitated the formation of this group of scientists and continues to work closely with them as an advisor. “This association will help provide a space and network where these experts can work together and speak in one voice to support maize and maize farmers.”
CIMMYT does not have a seat in the association but has played a key role in its facilitation and has provided funding to cover logistics and fees related to the formation of the organization, through the CGIAR Research Program on Maize (MAIZE). Mexico’s National Commission for the Knowledge and Use of Biodiversity (CONABIO) has also participated in the logistics and facilitation of the formation of the organization.
Members of the association pose with CIMMYT staff that helped facilitate the creation of the group. (Photo: ProMaíz Nativo)
Demand for wheat is predicted to increase 70% by the year 2050. As demand for wheat is increasing, so are challenges to wheat production. New and more aggressive pests and diseases, diminishing water resources, limited available land, and unstable weather conditions due to climate change present risks for the crop.
Carolina Rivera is working to solve this problem. A wheat physiologist at CIMMYT and data coordinator with the International Wheat Yield Partnership, she works to identify new traits in wheat aiming to boost grain number and yield. Rivera is also one of the recipients of the 2019 Jeanie Borlaug Laube Women in Triticum Early Career Award.
The International Maize and Wheat Improvement Center (CIMMYT) operates five agricultural experiment stations in Mexico. Strategically located across the country to take advantage of different growing conditions — spanning arid northern plains to sub-tropical and temperate climatic zones — the stations offer unique and well-managed testing conditions for a variety of biotic and abiotic stresses.
Heat and drought tolerance in wheat is the focus of study at Ciudad Obregón, while the humid, cool conditions at Toluca are ideal for studying wheat resistance to foliar diseases. The tropical and sub-tropical settings of Agua Fría and Tlaltizapán respectively are suited to maize field trials, while at El Batán researchers carry out a wide variety of maize and wheat trials.
A new video highlights the important and valuable contribution of the five experimental stations in Mexico to CIMMYT’s goal of developing maize and wheat that can cope with demanding environments around the world, helping smallholder farmers in Africa, Asia and Latin America adapt to challenges like climate change, emerging pests and disease, and malnutrition.
Featuring aerial cinematography and interviews with each station’s manager, the video takes viewers on a journey to each experimental station to highlight the research and management practices specific to each location.
In addition to their role in breeding maize and wheat varieties, CIMMYT’s experimental stations host educational events throughout the year that train the next generation of farmers, policymakers and crop scientists. They also provide the canvas on which CIMMYT scientists develop and test farming practices and technologies to help farmers grow more with less.
Some of the stations also hold historical significance. Ciudad Obregón and Toluca are two of the sites where Norman Borlaug set up his shuttle breeding program that provided the foundations of the Green Revolution. It was also in Toluca, while at a trial plot alongside six young scientists from four developing nations, where Borlaug first received news of his 1970 Nobel Peace Prize award.
Nominations are now open for the 2019 MAIZE Youth Innovators Awards – Latin America!
These awards are part of the efforts that the CGIAR Research Program on Maize (MAIZE) is undertaking to promote youth participation in maize agri-food systems. These awards recognize the contributions of young women and men under 35 who are implementing innovations in Latin American maize-based agri-food systems, including research for development, seed systems, agribusiness, and sustainable intensification.
Latin America is the birthplace of maize and home to much of its genetic diversity. Maize is a main staple food across the continent and plays an important role in local culture and gastronomy. However, maize faces many challenges, from climate change-related stresses such as drought and heat to emerging pests and diseases. These challenges cannot be solved without the participation of young people at all levels of the maize value chain, from farmers to researchers and change agents. Over one-fourth of Latin America’s total population is between the ages of 15 and 29 – approximately 156 million people, the largest proportion of young people ever in the region’s history. By encouraging and empowering young people to develop innovative solutions to these challenges we can strengthen maize agri-food systems and improve food security in Latin America and across the world.
The MAIZE Youth Innovators Awards aim to identify young innovators who can serve to inspire other young people to get involved in maize-based agri-food systems. Part of the vision is to create a global network of young innovators in maize-based systems from around the world.
Award recipients will be invited to attend the 23rd Latin American Maize Reunion (XXIII Reunión Latinoamericana del Maíz) in Monteria, Colombia October 7-10 where they will receive their awards and be given the opportunity to present their work. The project meeting and award ceremony will also allow these young innovators to network and exchange experiences with MAIZE researchers and partners. Award recipients may also get the opportunity to collaborate with MAIZE and its partner scientists in Latin America on implementing or furthering their innovations.
MAIZE invites young innovators to apply and CGIAR researchers and partners to nominate eligible applicants for any of the following three categories:
Researcher: Maize research for development (in any discipline)
Farmer: Maize farming systems in Latin America
Change agent: Maize value chains (i.e., extension agents, input and service suppliers, transformation agents).
We ask nominators/applicants to take into account the following criteria and related questions:
Novelty and Innovative Spirit: To which specific novel findings or innovation(s) has this young person contributed? (in any of the three categories mentioned above)
Present/Potential Impact: What is the present/potential benefit or impact of the innovation(s) in maize-based agri-food systems?
To apply:
Applications should be submitted online, through the Application Form by July 22, 2019.
Key dates:
Opening date for nominations: June 19, 2019
Closing date for nominations: July 22, 2019
Notification of winners: August 6, 2019
NOTE: Nominations received after the closing date will not be considered.
Additional information:
A PDF version of this Call for Nominees is available here.
Nomination/Application Guidelines can be found here.
The Application Form can be found here and is also available on the MAIZE and YPARD websites.
Fred Palmer, former CIMMYT maize agronomist, in his office at Egerton University, Kenya, in 1994.
With sorrow we report the passing on June 14 of Anthony F. E. (Fred) Palmer, former maize agronomist and physiologist who contributed notably to the International Maize and Wheat Improvement Center (CIMMYT) networking and capacity building during crucial periods.
A British national, Palmer joined CIMMYT as a post-doctoral fellow in 1968 and retired from the center in 1996. With undergraduate studies in Agronomy at the University of Reading, Palmer completed masters and doctoral degrees in Crop Physiology at Cornell University. His early years at CIMMYT headquarters included work in maize physiology, agronomy and training.
In 1972 Palmer moved to Pakistan, serving as a production agronomist in that key Green Revolution setting until 1978, when he returned to Mexico as a training officer. “Fred was a true gentleman as a researcher and trainer,” said Stephen Waddington, retired CIMMYT maize agronomist who worked with Fred in Africa. “He was a mentor and friend to many junior CIMMYT staff, including myself, and countless trainees and visiting scientists from partner countries.”
Capitalizing on his experience and accomplishments, in 1985 CIMMYT posted Palmer to Nairobi, Kenya, as the team leader of the East African Cereal Project, funded by the Canadian International Development Agency (CIDA). During the project’s third phase, Palmer helped to establish and guide an entry-level crop management training program, in conjunction with the Kenya Agricultural Research Institute (KARI) and Egerton University, targeting maize researchers from eastern and southern Africa. Based at the university’s Njoro campus, the effort included construction of training facilities and guest rooms and Palmer successfully prepared Egerton administrators and faculty to take over the program, according to Joel Ransom, a North Dakota State University professor who served as a CIMMYT maize agronomist in Asia and sub-Saharan Africa.
“Scores of young agronomists mastered the fundamentals of on-farm research through that program,” Ransom said. “Palmer’s mentoring, training, and leadership greatly advanced the professional development of African maize and wheat scientists.”
Matthew Reynolds, CIMMYT distinguished scientist and wheat physiologist, recalls talking to Palmer about the latter’s efforts to apply fledgling tools for measuring photosynthesis in the field, a topic in which he had specialized at Cornell. “Fred was a very kind and unassuming man who treated everyone with respect, qualities that made him a great training officer and a well-regarded colleague,” said Reynolds.
Palmer firmly believed that national partners needed the capacity to train staff, particularly those fresh out of university studies, strengthening both their knowledge and professional linkages.
“By bringing young scientists together and working with them as a multidisciplinary research team,” Palmer wrote in a report on CIMMYT training in eastern and southern Africa, “it is anticipated that these scientists will learn to value each other’s work as essential to successful research.”
The CIMMYT community sends its warmest condolences to the Palmer family.
In 2018, CIMMYT continued to innovate and forge strategic alliances to combat malnutrition, tackle the effects of climate change and respond to emerging threats.
Building on the release of a new wheat genome reference map, our researchers more precisely tagged genes for valuable traits, including disease resistance, heat tolerance, and grain quality, in more than 40,000 CIMMYT wheat lines.
In collaboration with our partners, CIMMYT released 81 maize and 48 wheat varieties. More than 40,000 farmers, scientists and technical workers across the world took part in over 1,500 training and capacity development activities. CIMMYT researchers published 338 journal articles.
As the maize-hungry fall armyworm spreads from Africa to Southeast Asia, CIMMYT joined with more than 40 partners in an international consortium to advance research against the devastating insect pest.
CIMMYT used a scaling approach to extend the benefits of crop research to more farmers and consumers in developing countries in transformative and lasting ways. Smallholder farmers in Mexico, Pakistan and Zimbabwe are benefitting from the use of appropriate machinery and implements for efficient and climate-smart agriculture. A manual developed with the Food and Agriculture Organization (FAO) of the United Nations offers technical and business advice for local entrepreneurs offering mechanized services, such as sowing or threshing, to smallholder farmers.
As part of taste tests in Ethiopia, Kenya, and Tanzania, consumers indicated their willingness to pay a premium for quality protein maize (QPM), which contains enhanced levels of the amino acids needed to synthesize protein.
A CIMMYT-led study on gender has explored the lives and viewpoints of 7,500 men and women from farming communities in 26 countries, providing invaluable information that will lead to better productivity and food security.
2018 showed us that the passion and values of staff and partners help CIMMYT to have major impact on the livelihoods of smallholders and the poor. This Annual Report pays tribute to them.
Francelino Rodrigues prepares an UAV for radiometric calibration for multispectral flight over a maize tar spot complex screening trial at CIMMYT’s Agua Fría experimental station, Mexico. (Photo: Alexander Loladze/CIMMYT)
A new study from researchers at the International Maize and Wheat Improvement Center (CIMMYT) shows that remote sensing can speed up and improve the effectiveness of disease assessment in experimental maize plots, a process known as phenotyping.
The study constitutes the first time that unmanned aerial vehicles (UAVs, commonly known as drones) with cameras that capture non-visible electromagnetic radiation were used to assess tar spot complex on maize.
The interdisciplinary team found among other things that potential yield losses under heavy tar spot complex infections could reach 58% — more than 10% greater than reported in previous studies.
Caused by the interaction of two fungal pathogens that thrive in warm, humid conditions, tar spot complex is diagnosed by the telltale black spots that cover infected plants. (Photo: Alexander Loladze/CIMMYT)
“Plant disease resistance assessment in the field is becoming difficult because breeders’ trials are larger, are conducted at multiple locations, and there is a lack of personnel trained to evaluate diseases,” said Francelino Rodrigues, CIMMYT precision agriculture specialist and co-lead author of the study. “In addition, disease scoring based on visual assessments can vary from person to person.”
A major foliar disease that affects maize throughout Latin America, tar spot complex results from the interaction of two species of fungus that thrive in warm, humid conditions. The disease causes telltale black spots on infected plants, killing leaves, weakening the plant, and impairing ear development.
Phenotyping has traditionally involved breeders walking through crop plots and visually assessing each plant, a labor-intensive and time-consuming process. As remote sensing technologies become more accessible and affordable, scientists are applying them more often to assess experimental plants for desired agronomic or physical traits, according to Rodrigues, who said they can facilitate accurate, high-throughput phenotyping for resistance to foliar diseases in maize and help reduce the cost and time of developing improved maize germplasm.
“To phenotype maize for resistance to foliar diseases, highly trained personnel must spend hours in the field to complete visual crop evaluations, which requires substantial time and resources and may result in biased or inaccurate results between surveyors,” said Rodrigues. “The use of UAVs to gather multispectral and thermal images allows researchers to cut down the time and expenses of evaluations, and perhaps in the future it could also improve accuracy.”
Color-infrared image of maize hybrids in the experimental trials under fungicide treatment (A1) and non-fungicide treatment (A2) of tar spot complex of maize. Image data were extracted from two polygons from the two central rows in each plot (B).
Technology sheds new light on phenotyping
Receptors in the human eye detect a limited range of wavelengths in the electromagnetic spectrum — the area we call visible light — consisting of three bands that our eyes perceive as red, green and blue. The colors we see are the combination of the three bands of visible light that an object reflects.
Remote sensing takes advantage of how the surface of a leaf differentially absorbs, transmits and reflects light or other electromagnetic radiation, depending on its composition and condition. The reflectance of diseased plant tissue is different from that of healthy ones, provided the plants are not stressed by other factors, such as heat, drought or nutrient deficiencies.
In this study, researchers planted 25 tropical and subtropical maize hybrids of known agronomic performance and resistance to tar spot complex at CIMMYT’s experimental station in Agua Fría, central Mexico. They then carried out disease assessments by eye and gathered multispectral and thermal imagery of the plots.
This allowed them to compare remote sensing with traditional phenotyping methods. Calculations revealed a strong relationship between grain yield, canopy temperature, vegetation indices and the visual assessment.
Future applications
“The results of the study suggest that remote sensing could be used as an alternative method for assessment of disease resistance in large-scale maize trials,” said Rodrigues. “It could also be used to calculate potential losses due to tar spot complex.”
Accelerated breeding for agriculturally relevant crop traits is fundamental to the development of improved varieties that can face mounting global agricultural threats. It is likely that remote sensing technologies will have a critical role to play in overcoming these challenges.
“An important future area of research encompasses pre-symptomatic detection of diseases in maize,” explained Rodrigues. “If successful, such early detection would allow appropriate disease management interventions before the development of severe epidemics. Nevertheless, we still have a lot of work to do to fully integrate remote sensing into the breeding process and to transfer the technology into farmers’ fields.”
Funding for this research was provided by the CGIAR Research Program on Maize (MAIZE).
In 2013, Mexico had the fourth highest sales of ultra-processed products worldwide. This is indicative of one of the most important changes in food systems in middle-income countries in recent years: the shift away from meals prepared at home with fresh or minimally processed products towards meals that include ultra-processed foods.
“Typically, these products do not have any wholefood ingredient, are ready to eat, and are high in fat, sodium and sugar but low in fiber, protein and vitamins,” says Ana Gaxiola, a nutritionist consultant working with the International Maize and Wheat Improvement Center (CIMMYT). “The health risks associated with their consumption have important, long-term implications for the health and nutritional status of individuals, families and communities.”
Latin America has a sophisticated maize and wheat processing sector with the potential to segment urban markets according to income, preferences and knowledge. This has important implications for equity in access to food with higher nutritional value.
In 2018, CIMMYT researchers began a new investigative project in collaboration with two CGIAR research programs, Agriculture for Health and Nutrition (A4NH) and WHEAT, seeking to understand how affordability affects diets in different areas of Mexico City. “We want to better understand access to healthier maize- and wheat-based foods across differences in purchasing power,” explains CIMMYT senior economist Jason Donovan. “Part of that involves looking at what processed products are available at what price and in different neighborhoods and the dietary implications of that.”
A researcher captures nutritional information from a packet of tortillas. (Photo: Emma Orchardson/CIMMYT)
This is relatively new territory for those involved. “This kind of research has been done before,” explains Gaxiola, “but only looking at supermarkets in Mexico City and without differentiating between socioeconomic levels.” Previous studies have also failed to include data from abarrotes, the small convenience stores ubiquitous throughout the city.
The study compares Polanco and San Vicente, two neighborhoods in Mexico City chosen to represent high- and low-income areas, respectively. Using economic data in combination with label and packaging information it analyzes the variation in availability of processed and ultra-processed maize and wheat products, taking into account ingredients, nutritional content, portion size, price and other added value. The study will later include a qualitative element, in which the team will conduct interviews with shop managers to find out how they decide which products to stock, and with consumers to discuss the products they buy and the factors influencing their decisions.
“We’re also interested in how the products are being promoted,” says Miriam Perez Luna, a CIMMYT research assistant involved in the study. “Do companies employ celebrity endorsements or cartoons to appeal to children? Do they have any special certifications based on where or how the products were produced? This information goes into our database so we can examine how products are being marketed, whether in stores or online and through social media.”
In a small food shop in San Vicente, a low-income area, snacks high in salt and sugar line the shelves. (Photo: Emma Orchardson/CIMMYT)
Now at the end of the data collection period, Gaxiola and a team of researchers have collected more than 20,000 images of packaging, bar codes and nutritional information for a variety of products including biscuits, breads, cakes, cereals, flours, pastas, soups and tortillas. Once the data has been cleaned, they will begin to analyze each individual product and create an index for how healthy they are. Preliminary results from the study will be made available later in the year, but the team are keen to share some of their initial observations.
They were unsurprised to note that many products were more expensive in the upscale Polanco neighborhood, and smaller convenience stores tended to charge more for certain products than larger supermarkets.
There have however, been some unexpected findings. For example, many of the discussions about lack of access to nutritious food options focus on the diets of the urban poor, but there may be reason to believe that affluent consumers face similar challenges. “You’ll be surprised to hear that a lot of what we found in Polanco was not that healthy, because most of it is heavily processed,” says Gaxiola.
Based on the Pan-American Health Organization’s classification system, a product containing more than one milligram of sodium per calorie, 10% refined sugar and 30% total fat is an unhealthy one. “We still need to carry out the analysis, but I’d say more than 70% of the products we’ve encountered could be deemed unhealthy, based on this classification system.”
In a small supermarket in San Vicente, the research team found nearly 50 different types of biscuits and around 80 savory maize-based snacks like chips and tortillas. (Photo: Emma Orchardson/CIMMYT)
The implications of this are significant for a country like Mexico, which currently faces an epidemic of obesity and overweight. “There’s a lot of advocacy now around nutritional information, but it can be hard to understand sometimes, even for me,” says Gaxiola. “It has to be become something that everyone can understand and use to make healthier choices.”
For this to happen it is important to close the data gap on how urban consumers interact with their food environments. Understanding how they choose among different types of maize- and wheat-based products and how much of this is shaped by socioeconomic disparities is a key first step towards engaging with the private and public sectors on options for promoting healthier processed wheat and maize products in fast-evolving food systems.
This study is being carried out by the International Maize and Wheat Improvement Center (CIMMYT) and supported by the CGIAR Research Program on Agriculture for Nutrition and Health (A4NH) and the CGIAR Research Program on Wheat (WHEAT).
Participants in the scaling workshop stand for a group photo with the trainers. (Photo: CIMMYT)
How to scale up agricultural innovation in a sustainable and responsible manner? Through a workshop from the International Maize and Wheat Improvement Center (CIMMYT), a group from Mexico’s state of Chiapas learnt the basic principles of scaling. This knowledge will allow them to design and implement strategies that live well beyond the end of a project and that take into account the systems in which they operate.
Through presentations, group exercises and discussions, 23 people associated with the MasAgro project in Chiapas — technical advisors, coordinators and collaborators — received training on scaling sustainable and responsible agricultural innovations.
The scaling process is relevant because oftentimes the size of a problem does not match the size of its solutions. To support scaling efforts, all relevant actors and entities must subscribe to a paradigm shift to achieve a positive sustainable impact for the greatest number of people.
Executing innovations in scaling requires a paradigm shift in all relevant actors and entities involved in order to achieve positive, sustainable impact that reaches the greatest number of people.
The workshop was divided into three sections. The first section was focused on basic concepts and the definition of realistic and responsible scaling goals. In the second, the group discovered the “Scaling Scan” tool. The third section was focused on the identification of opportunities and potential actions at the project level and through strategic collaborations.
The workshop “Scaling farming innovations: the what, for what and how” took place on April 24 and 25, 2019, in Tuxtla Gutiérrez, Chiapas. The event was led by Lennart Woltering, international scaling expert at CIMMYT, María Boa, CIMMYT scaling coordinator, and Jorge García, CIMMYT Hub Manager from the MasAgro project in Chiapas.
This training was held under the project for Strengthening Market Access for Small Producers of Maize and Legumes in Oaxaca, Chiapas and Campeche, which is financed by the Walmart Foundation.
The indigenous peoples who lived in central and southern Mexico thousands of years ago developed a resilient intercropping system to domesticate some of the basic grains and vegetables that contribute to a healthy diet.
Today, small farmers in roughly the same areas of Mexico continue to use this flexible system called “milpa” to grow chili, tomatoes, beans, squashes, seasonal fruits and maize, which are essential ingredients of most Mexican dishes.
An analysis of the Mexican diet done in the context of a recent report by the EAT – Lancet Commission found that Mexicans are eating too much animal fat but not enough fruits, vegetables, legumes and wholegrains. As a result, a serious public health issue is affecting Mexico due to the triple burden of malnutrition: obesity, micronutrient deficiency and/or low caloric intake. The study also urges Mexico to increase the availability of basic foodstuffs of higher nutritional value produced locally and sustainably.
Although changing food consumption habits may be hard to achieve, the traditional diet based on the milpa system is widely regarded as a healthy option in Mexico. Although nutritional diversity increases with the number of crops included in the milpa system, its nutritional impact in the consumers will also depend on their availability, number, uses, processing and consumption patterns.
Unfortunately, milpa farmers often practice slash-and-burn agriculture at the expense of soils and tropical rainforests. For that reason, it is also important to address some of the production-side obstacles on the way to a healthier diet, such as soil degradation and post-harvest losses, which have a negative effect on agricultural productivity and human health.
The International Maize and Wheat Improvement Center (CIMMYT) engages in participatory field research and local capacity-building activities with farmers, local partners and authorities to foster innovation and to co-create strategies and procedures that help farmers produce food sustainably.
Francisco Canul Poot in his land. (Photo: CIMMYT)
These efforts led Francisco Canul Poot, a milpa farmer from the Yucatan Peninsula, to adopt conservation agriculture concepts in his milpa and to stop burning soil residues since 2016. As a result, his maize yield grew by 70%, from 430 to 730 kg per hectare, and his income increased by $300 dollars. 15 farmers sharing property rights over communal land have followed his example since.
These outstanding results are encouraging more farmers to adopt sustainable intensification practices across Mexico, an important change considering that falling levels of nitrogen and phosphorus content in Mexican soils may lead to a 70 percent increase in fertilizer use by 2050.
By implementing a sustainable intensification project called MasAgro, CIMMYT contributes, in turn, to expand the use of sustainable milpa practices in more intensive production systems. CIMMYT is also using this approach in the Milpa Sustentable Península de Yucatán project.
At present, more than 500 thousand farmers have adopted sustainable intensification practices — including crop diversification and low tillage — to grow maize, wheat and related crops on more than 1.2 million hectares across Mexico.
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
In November 2015, Jelle Van Loon set off for Zimbabwe, with a cross-section plan in his backpack. He spent two weeks working with a group of blacksmiths, searching Harare for parts and assembling machines in a bid to test whether the construction plans developed by his team were indeed designed to be built anywhere. “We might have had to change a few things, but three working machines were built, proving the accessibility of the construction plans and inherent replicability of the designs.”
From studying agronomic engineering and crop modelling in Belgium to working on supply chain issues in Peru, Jelle Van Loon amassed a range of experience before joining the International Maize and Wheat Improvement Center (CIMMYT) in 2012. Soon after joining, he began shaping up a team to work on mechanization issues.
“First and foremost I’m an agricultural engineer; I just happen to have a high affinity with mechanics,” he says. “I think my advantage is having a broad knowledge, being able to understand agronomy as well as mechanical engineering, and having studied agricultural economics in developing countries.”
This background has served him well in a role where a hands-on, multidisciplinary approach is crucial.
“Mechanization doesn’t necessarily mean building or creating more machines,” Van Loon explains, “but rather introducing technology and farm equipment to farmers to facilitate their work, as well as supporting them on how and when to use it to increase production efficiency.” Many people also assume that mechanization only involves motorized equipment such as tractors, he adds, when in fact any tool, even simple hand tools, which facilitate farmer work and alleviate drudgery fit into this concept.
CIMMYT’s mechanization team carries out research and development on a range of farm equipment. Team members draw and design prototypes, test them in the field and develop protocols for experiments. Combining agronomy and mechanics, they work to create machinery that supports farmers in their day-to-day work at each stage of the crop cycle: from land preparation, planting and fertilization, to harvest and shelling. They also support the generation of new business models which can deliver appropriate machinery to farmers working within resilient agri-food systems.
Welcome to the machine
One of the biggest challenges is changing the way farmers work. Many are resistant to investing in new machinery because they are unsure of how to use it, and simply cannot afford the risk of failure. As such, the team also places an emphasis on extension work. They have set up centers where growers can learn about the equipment and rent out some model machines. They also build the capacity of service providers through training on functional engineering for blacksmiths and manufacturers, and market intelligence for small sector entrepreneurs.
“It’s beyond just designing the machine. It’s really about taking products out to the field, seeing what works well and where, and then thinking about how we can get these products into the hands of farmers.”
Building on the work being carried out in Mexico, Van Loon is always looking at how other regions can also benefit from the mechanization unit and opportunities for collaborating with colleagues and partners in Africa and Asia. Equipment developed for farmers in Africa or Latin America could be adapted for use in South Asia or vice versa, but this requires a solid understanding of each region’s unique opportunities and challenges.
He points to the example of the two-wheel tractor engine, developed in China and popularized in Asia during the 1980s, when famine and the loss of draft animals prompted governments to subsidize that particular piece of equipment at the right time. The tractor is ubiquitous in countries such as Bangladesh, but it is unclear whether the same success is replicable in Africa and Latin America, neither of which has the same conditions, second-hand markets or import facilities. “We’re trying to learn from cross-regional efforts to scale up. Being able to understand different areas helps us find the weakest links and create more enabling environments,” Van Loon explains.
He and his team are continuously developing and evaluating new ideas, trialing ways of embedding mechatronics or sensory-based technology into their machines to help capture data and ease farmer workloads. Finding a way to keep these low-cost and convenient for farmer use may be a challenge, but positive testimonials from farmers keep him excited about the possibilities.
“I think it’s worthwhile to follow through on wild new ideas and see what happens because when it works out, the positive impact and change we help create is all that matters,” Van Loon notes.
“And more so, the cool thing about working in mechanization is we can go as far as our creativity lets us.”
Jelle Van Loon demonstrates machinery for visitors at CIMMYT’s global headquarters in Mexico. (Photo: Gerardo Mejía/CIMMYT)
Maize is more than a crop in Mexico. While it provides food, feed and raw materials, it is also a bloodline running through the generations, connecting Mexico’s people with their past.
The fascinating diversity of maize in Mexico is rooted in its cultural and biological legacy as the center of origin of maize. Landraces, which are maize varieties that have been cultivated and subjected to selection by farmers for generations, retaining a distinct identity and lacking formal crop improvement, provide the basis of this diversity.
As with any cultural legacy, the cultivation of maize landraces can be lost with the passage of time as farmers adapt to changing markets and generational shifts take place.
Doctoral candidate Denisse McLean-Rodríguez, from the Sant’Anna School of Advanced Studies in Italy, and researchers from the International Maize and Wheat Improvement Center (CIMMYT) have undertaken a new study that traces the conservation and abandonment of maize landraces over the last 50 years in Morelos, Mexico’s second smallest state.
The study is based on a collection of 93 maize landrace samples, collected by Ángel Kato as a research assistant back in 1966-67 and stored in CIMMYT’s Maize Germplasm Bank. Researchers traced the 66 families in Morelos who donated the samples and explored the reasons why they abandoned or conserved their landraces.
Doctoral candidate Denisse McLean-Rodríguez (left) interviews maize farmer Roque Juarez Ramirez at his family home in Morelos to explore his opinions on landrace conservation. (Photo: E. Orchardson/CIMMYT)
Tracing landrace abandonment
In six cases, researchers were able to interview the original farmers who donated the samples to CIMMYT. In other cases, they interviewed their family members, most frequently the sons or daughters, or alternatively their grandchildren, siblings, nephews or widows.
The study reveals that maize landrace cultivation has diminished significantly within the families. Only 13 of the 66 families are still cultivating the same maize seed lots as in 1966-67 and there was consensus that the current social, economic and physical environments are unfavorable for landrace cultivation.
Among the reasons for abandonment are changes in maize cultivation technologies, shifting markets for maize and other crops, policy changes, shifting cultural preferences, urbanization and climate change.
“By finding out about landrace continuity in farmers’ fields and the factors driving change, we were able to better understand the context in which these landraces are currently cultivated,” said McLean-Rodríguez. “Our study also allowed us to evaluate the importance of ex situ conservation in facilities like CIMMYT’s Germplasm Bank.”
Juarez and Oliveros’s grandson shows the family’s heirloom maize: maíz colorado (left) and Ancho maize. (Photo: E. Orchardson/CIMMYT)
Maize biodiversity conservation
Maize landraces can be conserved “in situ” in farmers’ fields and “ex situ” in a protected space such as a germplasm bank or community seed bank.
“These conservation strategies are complementary,” explained McLean-Rodríguez. “Ex situ conservation helps to secure landraces in case of unpredictable conditions that threaten their conservation in the field, while in situ cultivation allows the processes that generated maize’s diversity to continue, allowing the emergence of mutations and the evolution of new potentially beneficial traits.”
The loss of landraces in farmers’ fields over 50 years emphasizes the importance of ex situ conservation. CIMMYT’s Maize Germplasm Bank holds 28,000 samples of maize and its wild relatives from 88 countries, spanning collections dating back to 1943. Safeguarded seed stored in the Germplasm Bank is protected from crises or natural disasters, and is available for breeding and research. Traits found in landraces can be incorporated into new varieties to address some of the world’s most pressing agriculture challenges like changing climates, emerging pests and disease, and malnutrition.
McLean-Rodríguez recalls an aspect of the study that she found particularly rewarding: “Many of the families who had lost their landrace for one reason or another were interested in receiving back samples of their maize from the CIMMYT Germplasm Bank. Some were interested due to personal value, while others were more interested in the productive value. They were very happy to retrieve their maize from the Germplasm Bank, and it would be very interesting to learn whether the repatriated seed is cultivated in the future.”
Ventura Oliveros Garcia holds a photograph of her father, Santos Oliveros, who was one of the maize farmers who donated seed to CIMMYT’s germplasm bank in 1966-67. (Photo: E. Orchardson/CIMMYT)
A family tradition
One of the families to take part in the study was farmer Roque Juarez Ramirez and his wife, Ventura Oliveros Garcia, whose father was one of the donor farmers from Morelos. “I was so happy to hear the name of my father, [Santos Oliveros],” recalls Oliveros, remembering the moment McLean-Rodríguez contacted her. “He had always been a maize farmer, as in his day they didn’t cultivate anything else. He planted on his communal village land [ejido] and he was always able to harvest a lot of maize, many ears. He planted an heirloom variety of maize that we called arribeño, or marceño, because it was always planted in March.”
Juarez senses his responsibility as a maize farmer: “I feel that the importance [of maize farming] is not small, but big. We are not talking about keeping 10 or 20 people alive; we have to feed a whole country of people who eat and drink, apart from providing for our families. We, the farmers, generate the food.”
Filling vessels of champurrado, a Mexican maize-based sweet drink, and presenting samples of the family’s staple maize — maíz colorado and the Ancho landrace — Oliveros describes what maize means to her: “Maize is very important to my family and me because it is our main source of food, for both humans and animals. We use our maize variety to make pozole, tortillas, tamales, atole, quesadillas, picadas and many other foods.”
The Juarez-Oliveros family substituted the Ancho seed lot from Olivero’s father with another seed lot from the Ancho landrace obtained from her husband’s family. The Ancho landrace is used to make pozole, and continues to be widely cultivated in some municipalities of Morelos, including Totolapan, where the family resides. However, researchers found other landraces present in the 1966-67 collection, such as Pepitilla, were harder to trace 50 years later.
Maíz colorado (left), or red maize, is an important part of the family’s diet. The family’s Ancho maize (right) has characteristically wide and flat kernels, and is a key ingredient of the pozole stew. (Photo: E. Orchardson/CIMMYT)
The study shows that landrace abandonment is common when farming passed from one generation to the next. Older farmers were attached to their landraces and continued cultivating them, even in the face of pressing reasons to change or replace them. When the younger generations take over farm management, these landraces are often abandoned.
Nonetheless, young farmers still value the cultural and culinary importance of landraces. “Maize has an important traditional and cultural significance, and is fundamental to our economy,” said Isaac Juarez Oliveros, son of Roque and Ventura. “I have been planting [maize landraces] since I was around 15 to 20 years old. I got my maize seed from my parents. I believe it is important for families to keep planting their maize, as it has become tradition passed down through many generations.”
The family’s son, Isaac Juarez Oliveros, stands outside the maize storage room where they store and dry their harvested maize for sale and consumption. (Photo: E. Orchardson/CIMMYT)
The legacy for future generations
Global food security depends on the maintenance of high genetic biodiversity in such key staple food crops as maize. Understanding the causes of landrace abandonment can help to develop effective landrace conservation strategies. The authors suggest that niches for landrace conservation and even expansion can be supported in the same manner that niches have been created for improved maize and other commercial crops. Meanwhile, management of genetic resources is vital, both in the field and in germplasm banks, especially in developing countries where broader diversity exists.
For Oliveros, it is a matter of family legacy: “It means a lot to me that [my family’s seed] was preserved because it has allowed my family’s maize and my father’s memory to stay alive.”
“Farmers who cultivate landraces are providing an invaluable global public service,” state the authors of the study. “It will be key to encourage maize landrace cultivation in younger farmers. Tapping into the conservation potential of the current generation of farmers is an opportunity we should not miss.”
A special acknowledgement to the families, focus group participants and municipal authorities from the state of Morelos who kindly devoted time to share their experiences with us, on the challenges and rewards of maize landrace conservation.
