Farmers worldwide are increasingly adopting conservation agriculture. In the 2015/2016 season, conservation agriculture was practiced on about 180 mega hectares of cropland globally, 69% more than in the 2008/2009 season.
What are the benefits of this method of farming? How did it originate? In this episode, we answer common questions on conservation agriculture and talk to Simon Fonteyne, Research Platforms Coordinator with CIMMYTâs Integrated Development program and conservation agriculture expert.
On December 10, 1970, the former chair of the Nobel Committee, Aase Lionaes, called Norman Borlaug to receive the Nobel Peace Prize arguing, âHe has given us a well-founded hope, an alternative of peace and of life â the Green Revolution.â
From that moment, Borlaug became known as âthe man who saved one billion livesâ from famine and as âthe father of the Green Revolution.â Borlaug started a pivotal process in the 20th century, characterized by the development of high-yielding new wheat and maize varieties from the International Maize and Wheat Improvement Center (CIMMYT).
âFood is the moral right of all who are born into this world,â Borlaug said during his acceptance speech or Nobel Lecture almost 50 years ago. The scientist, credited for coining the phrase âYou canât build peace on empty stomachs,â became the worldâs most acknowledged advocate of the right to food.
The Nobel Peace Center, the government of Mexico â through its Embassy in Oslo, Norway â and CIMMYT remembered Norman Borlaugâs legacy to commemorate the International Day of Peace on September 21. Established in 1981 by the United Nations General Assembly, this day calls to halt all forms of violence for 24 hours and to strengthen the ideals of peace, including Sustainable Development Goal number 2, âzero hunger.â
According to the Nobel Peace Center, âDr. Norman Borlaugâs work is one of the greatest achievements for humankind.â On a similar note, CIMMYTâs director general, Martin Kropff, noted that âPeace lies in the hands of those who cultivate the land. We can build peace through agriculture.â
CIMMYT carries on Borlaugâs legacy by implementing integrated strategic development projects that aim to transform food production units into sustainable, resilient and healthy agri-food systems. For that reason, CIMMYT issued a call to form an international coalition to tackle the current crisis and avert a new food crisis.
âNorman Borlaug led the charge in the war against hunger more than 50 years ago; let us learn from this experience, let us do it again together by listening to the current crisis and by developing a matching transformative answer to overcome todayâs challenges and shortcomings,â said Bram Govaerts, director of CIMMYTâs Integrated Development program and representative for the Americas.
Researchers working on the Seeds of Discovery (SeeD) initiative, which aims to facilitate the effective use of genetic diversity of maize and wheat, have genetically characterized 79,191 samples of wheat from the germplasm banks of the International Maize and Wheat Improvement Center (CIMMYT) and the International Center for Agricultural Research in the Dry Areas (ICARDA).
A new study analyzing the diversity of almost 80,000 wheat accessions reveals consequences and opportunities of selection footprints. (Photo: Keith Ewing)
Researchers working on the Seeds of Discovery (SeeD) initiative, which aims to facilitate the effective use of genetic diversity of maize and wheat, have genetically characterized 79,191 samples of wheat from the germplasm banks of the International Maize and Wheat Improvement Center (CIMMYT) and the International Center for Agricultural Research in the Dry Areas (ICARDA).
The findings of the study published today in Nature Communications are described as âa massive-scale genotyping and diversity analysisâ of the two types of wheat grown globally â bread and pasta wheat â and of 27 known wild species.
Wheat is the most widely grown crop globally, with an annual production exceeding 600 million tons. Approximately 95% of the grain produced corresponds to bread wheat and the remaining 5% to durum or pasta wheat.
The main objective of the study was to characterize the genetic diversity of CIMMYT and ICARDAâs internationally available collections, which are considered the largest in the world. The researchers aimed to understand this diversity by mapping genetic variants to identify useful genes for wheat breeding.
From germplasm bank to breadbasket
The results show distinct biological groupings within bread wheats and suggest that a large proportion of the genetic diversity present in landraces has not been used to develop new high-yielding, resilient and nutritious varieties.
âThe analysis of the bread wheat accessions reveals that relatively little of the diversity available in the landraces has been used in modern breeding, and this offers an opportunity to find untapped valuable variation for the development of new varieties from these landracesâ, said Carolina Sansaloni, high-throughput genotyping and sequencing specialist at CIMMYT, who led the research team.
The study also found that the genetic diversity of pasta wheat is better represented in the modern varieties, with the exception of a subgroup of samples from Ethiopia.
The researchers mapped the genomic data obtained from the genotyping of the wheat samples to pinpoint the physical and genetic positions of molecular markers associated with characteristics that are present in both types of wheat and in the cropâs wild relatives.
According to Sansaloni, on average, 72% of the markers obtained are uniquely placed on three molecular reference maps and around half of these are in interesting regions with genes that control specific characteristics of value to breeders, farmers and consumers, such as heat and drought tolerance, yield potential and protein content.
Open access
The data, analysis and visualization tools of the study are freely available to the scientific community for advancing wheat research and breeding worldwide.
âThese resources should be useful in gene discovery, cloning, marker development, genomic prediction or selection, marker-assisted selection, genome wide association studies and other applications,â Sansaloni said.
The study was part of the SeeD and MasAgro projects and the CGIAR Research Program on Wheat (WHEAT), with the support of Mexico’s Secretariat of Agriculture and Rural Development (SADER), the United Kingdomâs Biotechnology and Biological Sciences Research Council (BBSRC), and CGIAR Trust Fund Contributors. Research and analysis was conducted in collaboration with the National Institute of Agricultural Botany (NIAB) and the James Hutton Institute (JHI).
About CIMMYT:
The International Maize and What Improvement Center (CIMMYT) is the global leader in publicly-funded maize and wheat research and related farming systems. Headquartered near Mexico City, CIMMYT works with hundreds of partners throughout the developing world to sustainably increase the productivity of maize and wheat cropping systems, thus improving global food security and reducing poverty. CIMMYT is a member of the CGIAR System and leads the CGIAR programs on Maize and Wheat and the Excellence in Breeding Platform. The Center receives support from national governments, foundations, development banks and other public and private agencies. For more information visit staging.cimmyt.org.
For smallholder farmers in sub-Saharan Africa, new agricultural technologies such as improved maize varieties offer numerous benefits â increased incomes, lower workloads and better food security, among others. However, when new technologies are introduced, they can denaturalize and expose gender norms and power relations because their adoption inevitably requires women and men to renegotiate the rules of the game. The adoption of new varieties will often be accompanied by a number of related decisions on the allocation of farm labor, the purchase and use of inorganic fertilizers, switching crops between women- and men-managed plots, and the types of benefit household members expect to secure may change.
In an article published this month in Gender, Technology and Development, researchers from the International Maize and Wheat Improvement Center (CIMMYT) explore how women in Nigeria negotiate these new power dynamics to access and secure the benefits of improved maize varieties and, more broadly, to expand their decision-making space.
Using focus group and interview data collected as part of the GENNOVATE project, the authors draw on case studies from four villages â two in the northern states of Kaduna and Plateau; two in the southwestern state of Oyo â to develop an understanding of the relationship between gender norms, womenâs ability and willingness to express their agency, and the uptake of agricultural technologies. âThis is an important step toward improving the capacity of agricultural research for development to design and scale innovations,â say the authors. âAchieving this ambition is highly relevant to maize.â
The results were similar across all four sites. The authors found that women in each area were constrained by powerful gender norms which privilege male agency and largely frown upon womenâs empowerment, thus limiting their ability to maximize the benefits from improved varieties or realize their agency in other domains.
All women respondents remarked that improved maize varieties were easy to adopt, have higher yields and mature quickly, which meant that income flows started earlier and helped them meet household expenditures on time. They prioritized the contribution of improved maize to securing household food security, which helped them meet their ascribed gender roles as food providers.
âAt the same time though, women felt they could not maximize their benefits from improved maize varieties due to menâs dominance in decision-making,â the authors explain. âThis was particularly the case for married women.â
âMen are meant to travel far â not womenâ
Woman selling white maize at Bodija market in Ibadan, Nigeria. (Photo: Adebayo O./IITA)
Embedded gender norms â particularly those relating to mobility â infuse the wider environment and mean that womenâs access to opportunities is considerably more restricted than it is for men.
The findings demonstrate that both women and men farmers secure benefits from improved maize varieties. However, men accrue more benefits and benefit directly, as they have unfettered mobility and opportunity. They can access markets that are further away, and the maize they sell is unprocessed and requires no transformation. Additionally, men do not question their right to devote profits from maize primarily to their own concerns, nor their right to secure a high level of control over the money women make.
On the other hand, women respondents â regardless of age and income cohort â repeatedly stated that while it is hard to earn significant money from local sales of the processed maize products they make, it is also very difficult for them to enter large markets selling unprocessed, improved maize.
The difficulties women face in trying to grow maize businesses may be partly related to a lack of business acumen and experience, but a primary reason is limited personal mobility in all four communities. For example, in Sabon Birni village, Kaduna, women lamented that though the local market is not large enough to accommodate their maize processing and other agri-business ventures, they are not permitted travel to markets further afield where âthere are always people ready to buyâ.
âWomenâs benefits relate to the fact that improved maize varieties increase the absolute size of the âmaize cakeâ,â say the authors. âThey expect to get a larger slice as a consequence. However, the absolute potential of improved varieties for boosting womenâs incomes and other options of importance to women is hampered by gender norms that significantly restrict their agency.â
The implications for maize research and development are that an improved understanding of the complex relational nature of empowerment is essential when introducing new agricultural technologies.
The International Maize and Wheat Improvement Center (CIMMYT) operates 11 hubs â nodes of innovation â in Mexico, supported by a portfolio of projects including MasAgro. These hubs are perfectly defined by the agro-ecological conditions of the territory in which they are located, and their main aim is innovation management focused on sustainable and resilient agri-food systems.
Ortiz HernĂĄndez joined CIMMYT in 2010 as a collaborator in the state of MichoacĂĄn, where he trained and certified technicians, and managed the first modules and platforms of the MasAgro project. That experience allowed him to become the manager of the Yucatan Peninsula Hub, in southeastern Mexico, in 2015. After three years of serving in the state of Guanajuato, he has recently taken a management position at the BajĂo Hub.
Growing up in a rural community of less than a thousand people in the state of Puebla, Ortiz HernĂĄndez was familiar with agriculture from a young age. However, he considers that his decision to pursue a career in agronomy was unplanned. It was when he got into the agronomy-engineering program at the Chapingo Autonomous University â one of the most prestigious institutions in agricultural studies in Mexico â that he realized how drawn he was to plant production, choosing it as his specialty.
“As a Chapingo student, you know that CIMMYT is one of the most relevant research institutions not only in Mexico, but internationally,â says Ortiz HernĂĄndez. âTo be honest, when I graduated, I would never have imagined that I could be part of this great team.â
Tailored sustainability
Currently, he coordinates and manages the operation of different projects at the BajĂo Hub, working with both the public and private sectors. All of them operate under the same objectives: to monitor and address activities in the value chain to improve production systems, produce more with less through conservation agriculture and precision farming practices, and achieve a successful association with the market.
These actions are of utmost importance, since every year the region’s water tables are affected by the excessive use of water. Around 80% of the consumption of this natural resource is used for farming activities.
Ortiz HernĂĄndez explains that the production of 2.2 pounds of wheat in the region can require 1,500 liters of water on average. However, he and his team have shown that water consumption can be reduced by 30-50% by implementing practices that save water without decreasing yields and, ideally, with low production costs.
Ortiz HernĂĄndez in a barley field in Guanajuato where sustainable and climate-smart practices are implemented. (Photo: Francisco AlarcĂłn/CIMMYT)
Linking for success
The BajĂo Hub also manages MasAgro Guanajuato, a collaboration project between the government of state of Guanajuato and CIMMYT. Its aim is to support the technological improvement of conventional agri-food production, in order to implement actions of diagnosis, design, validation, demonstration and induction to the use of sustainable technological innovations.
One of the current situations faced by this program is that farmers in the area either broadcast or leave the fertilizer on the surface, resulting in an inefficient use. The technical team identified this problem and the possibility of mitigating it, by creating collaborative links with leading companies in the manufacture of agricultural machinery in the state, to design and produce a tool that meets this purpose.
“By working on a territorial innovation management approach, we get stakeholders to provide what is needed for farmers to access and adopt appropriate technology,” explains Ortiz HernĂĄndez. âWhat we expect from this type of project is not only to benefit the 500 or 1,000 farmers with whom we work directly, but to scale up and multiply those numbers generating an impact in the region through partnerships and alliances.â
Ortiz HernĂĄndez sees his management role as a strategic one, in which he has the flexibility to innovate by working with his team to generate efficient models, processes and tools. He can also propose and manage activities with different stakeholders in the region, so they can join in or align common objectives.
âThere is no better moment than when farmers are harvesting and you see a smile on their faces due to the good results. When you know you contributed, even a little, you feel good and you come home happy,â says Ortiz HernĂĄndez.
One of his personal goals, and something he tries to incorporate into any project, is to create awareness of farmers’ major role in global food security. “We have to see farmers for what they really are: the people who ensure that food reaches our tables and who guarantee its quantity and quality. It is vital to recognize their daily efforts.â
Farmers in Coahuila are embracing technology by using WhatsApp to exchange experiences and access technical information, especially on sustainable farming practices such as ecological pest management.
MasAgro develops capacities in Mexican producers through the socialization of scientific knowledge and the use of rural knowledge to increase their yields and conserve natural resources.
The COVID-19 pandemic continues to transform the way the world operates, and agricultural production systems are not exempt.
Even in countries that have identified the agricultural sector as an essential one, ongoing restrictions on transport and freedom of movement are causing disruptions across the value chain â with potentially devastating impact on already fragile food systems in Latin America, sub-Saharan Africa and South Asia.
With this in mind, systems agronomists and mechanization specialists at the International Maize and Wheat Improvement Center (CIMMYT), discuss the impact of restrictions on agricultural labor and production, and the role farm mechanization can play in addressing new challenges.
What are the implications of the agricultural labor shortages that are emerging in Africa and Latin America as a result of COVID-19 restrictions?
A woman demonstrates the use of a mini-tiller in Naivasha, Kenya. (Photo: Matt OâLeary/CIMMYT)
Africa is often presented as being dominated by farms which rely mainly on the labor of family members. Therefore, one could expect that Africa would be spared from the consequences of unavailability and/or unaffordability of hired labor. However, a recent CIMMYT study shows that farming systems in Africa are far more dependent on hired labor than commonly thought, and that the quasi total dependence of smallholder farming on family labor is a myth. Depending on the farming system, a complete loss of hired labor could lead to a productivity decrease of up to 20% in Eastern and Southern Africa. Hired labor is also likely to be replaced by child labor.
Because most production on the continent is rainfed during a single season, most farmers only plant and harvest once per year, making the timing of each task critical. A delay in planting because of labor shortages â as will soon occur Ethiopia â could lead to dramatically reduced yields. A delay in harvesting â as is currently experienced in Zimbabwe â means a large fraction of the crop is likely to be spoilt in the field.
Jelle Van Loon: The situation is similar for Mexico and the general Central American corridor, although the main production cycle is only just starting. Proper land preparation and timely sowing are critical, not only in terms of food production and achieving proper yields, but also to ensure that farmers have a stable income at the end of the year. This is especially important now, as financial and food reserves are shrinking at a faster pace due to COVID-19 restrictions that heavily affect demand on informal markets.
An operator demonstrates the use of a reaper in Bangladesh. (Photo: CIMMYT)
Are you seeing a similar situation in South Asia?
Timothy Krupnik: Depending on the country, weâve seen either abrupt interruptions in the movement of agricultural laborers â for example in India where millions of migrant laborers have not been able to travel home during lockdown â or an influx of people from urban areas who fled to their villages when lockdown began.
In the latter case, one might expect this to increase labor availability for farming, but we tended to observe the reverse. People remain largely frightened of coming out of their homes, so even in rural areas which saw an influx of people, labor availability has not necessarily increased. Where laborers are willing to work, our initial scan of the evidence indicates that daily wage labor costs have also increased considerably due to risks of infection spreading. In either situation, smallholder farmers who need to hire labor to assure crucial crop management activities like planting or harvesting are suffering. There are reports emerging also of increased child labor in the region as schools are closed and resource-poor farmers are allocating family members and children to work where they canât afford to hire labor.
M.L. Jat: I would like to cite the specific example of intensive rice-wheat rotation in Indiaâs breadbasket and the Green Revolution corridors in the western Indo-Gangetic plains, which provide the bulk of cereals to the national food basket. An ex-ante analysis on the consequences of the reverse migration of the agricultural workforce and social distancing due to COVID-19 revealed that a delay in the transplanting of rice seedlings by two weeks is likely, which will delay rice harvesting and consequently delay the planting of wheat. This will potentially lead to rice and wheat production losses of 10-25%, worth up to $1.5 billion.
In addition, the shorter turn around between harvesting rice and planting wheat may further increase the incidence of rice residue burning. This is a major problem which creates significant health issues and may exacerbate the threat of COVID-19 by increasing both infection rates and disease severity.
Krupnik: The situation has increased interest and policy to support use of scale-appropriate machinery for operations like harvesting. In Bangladesh, for example, there was a recent and very serious risk of losing much of the rice harvest as the monsoon has started early and flash flooding has been a concern. Without manual laborers to harvest the crop, CIMMYT-led projects like the Cereal Systems Initiative for South Asia â Mechanization and Extension Activity (CSISA-MEA) have played a key role in assisting the movement of combine harvesters and crop reapers to areas at risk of crop losses and helping to assure the rice crop is harvested on time.
An operator demonstrates the use of a starwheel planter in Zimbabwe. (Photo: Frederic Baudron/CIMMYT)
It sounds like these machines were instrumental in avoiding crop losses. Does this mean that mechanization has a key role to play in lessening the impact of these labor shortages?
Krupnik: During the COVID-19 crisis, scale-appropriate machinery has become even more important for mitigating labor shortages. We work to facilitate the availability of scale-appropriate machinery not only so that farmers can buy and use equipment, but also by encouraging those who own machineries to become entrepreneurial service providers who offer efficient and mechanized land preparation, planting, irrigation, harvesting and post-harvesting to other farmers on an affordable fee-for-service basis.
This is a win-win situation for farmers who canât access or afford the escalating costs of labor. In the COVID-19 crisis, these arrangements assist in responding to the labor crunch in locations where resource-poor farmers are most in need, and also allow farmers to get crucial work done while maintaining and encouraging social distancing.
Baudron: Over the past seven years, CIMMYT and its partners have fine-tuned technologies and developed delivery models â based on rural service providers supported by private sector companies â to scale the use of small machines in East and Southern Africa. These are profitable for both farmers and service providers and reduce labor requirements tremendously.
In Zimbabwe, we found that labor requirements were 15 times lower when establishing a maize field with a direct seeder pulled by a two-wheel tractor, and 23 times lower using a similar technology for establishing wheat in Rwanda, compared to the conventional method based on labor and draft power. A ton of maize that would take 12 people a full day to shell manually, can be shelled in one hour using a small double-cob sheller that costs about $300.
Jat: Rapid policy decisions by sub-national and national governments on facilitating more mechanized operations in labor intensive rice-wheat production regions will address labor availability issues while contributing to productivity enhancement of succeeding wheat crop in rotation, as well as overall system sustainability. Our ex-ante analysis on the implications of labor shortages in rice-wheat rotation in the western Indo-Gangetic plains due to COVID-19 indicates that adoption of scale-appropriate farm mechanization has the potential to stabilize the food production as well as reducing the income losses and air pollution surges in northwest India.
Harvesting maize in Mexico. (Photo: CIMMYT)
The situation in the regions each of you have mentioned is unique, but are there any global trends that youâve noticed? And if so, can other regions learn from these localized experiences?
Krupnik: A huge part of what we do as a research and training institute is facilitate exchanges of information across continents and countries. Different types and designs of machinery that can be used in similar circumstances can be shared, as can business models supporting service providers.
Importantly, part of the concept of âscale-appropriate mechanizationâ is also learning when and where machinery makes sense â where labor is not scarce and rural communities are highly dependent on income from labor to sustain their communities, some forms of mechanization may not be appropriate. We work to understand these dynamics and target the right machines in the right time and right places.
Van Loon: In addition to reducing pressure on available labor and alleviating drudgery, modern farm equipment tailored to the needs of smallholders can also increase competitiveness, as it allows for higher precision and efficiency.
In this sense, scale-appropriate mechanization can stimulate rural transformation incentivizing short and efficient value chains while ensuring stable food provision â aspects that have become essential to navigating the present crisis.
Has the current pandemic brought up any new perspectives in terms of how you consider labor and mechanization?
Baudron: We often look at yield and area planted in staple crops to assess the food security situation of a country during a particular year. This pandemic has shown us that we need to pay more attention to labor productivity. In many countries, policy-makers and development agents fear that mechanization will displace labor, but the dependency of staple crops on labor is a threat to food security, as we currently see in Africa and South Asia.
If the production of fruit, vegetables, cash crops, and so on will continue to depend on manual labor, it is essential in my view for critical tasks in the production of staples to be mechanized â particularly planting and harvesting. This will ensure the resilience of national food systems in the case of a future disruption similar to the COVID-19 pandemic.
Cover photo: Establishment of demo trial in Nyanga, Zimbabwe. (Photo: CIMMYT/ZRBF)
Not only is it the origin of maize â one of CIMMYTâs focus crops â it also inspired the birth of its headquarters, which has served as the instituteâs mothership since its establishment in 1966.
CIMMYTâs crop-breeding research begins with its genebank, a remarkable living catalog of genetic diversity comprising over 28,000 unique seed collections of maize and over 150,000 of wheat. The genebank was established at CIMMYTâs headquarters in 1986 and to date is the worldâs largest and most diverse collection of maize and wheat. Like clockwork, every year, more than 1,500 maize and wheat seed shipments leave Mexico to reach as many as 800 recipients in over 100 countries.
In one way or another, the worldâs maize and wheat have a link back to Mexico: be it through pest-resistance trials in the Agua Fria or Tlaltizapan hub or heat-resilient wheat trials in the scorching fields of Obregon. The countryâs diverse ecosystems which allowed for Norman Borlaug’s shuttle breeding in the 1940s remain instrumental for todayâs researchersâ work to develop innovative crops and sustainable farming systems worldwide.
CIMMYT has been working hand in hand with Mexicoâs Secretariat of Agriculture and Rural Development (SADER) on MasAgro, a project that promotes the sustainable production of maize and wheat in Mexico.
In the conversation below, Martin Kropff, Director General of CIMMYT, and Bram Govaerts, CIMMYT Representative for the Americas and Director of the Integrated Development Program, explore topics such as Mexicoâs food security and agriculture while COVID-19 disrupts the nationâs status quo.
Has the COVID-19 pandemic exposed any vulnerabilities in Mexican food security?
Kropff: Albeit Mexico produces a lot of food â in fact, I believe that it currently ranks 11th in food production globally â it still imports food from other countries, particularly staples such as maize, wheat and rice from the U.S. The current pandemic poses a threat to open trade, and Mexico could also be affected by trade restrictions that other countries impose to protect their people and internal markets from food shortages.
Govaerts: At the same time, the pandemic is reducing economic activities everywhere to minimum levels. This poses a threat to food production given that farmers and agricultural workers in Mexico, and most of the northern hemisphere, are just about to begin the growing spring/summer season. Mexicoâs fields need to be prepared for sowing and farmers need certainty as they take risks by investing today for a harvest that will come within several months.
How is CIMMYT helping to reduce these vulnerabilities?
Govaerts: CIMMYT is working with Mexicoâs Agriculture Department (SADER) and the private and social sector to address these threats.
Kropff: In fact, we see that Mexico is already answering to a CIMMYT-endorsed Call to Action For World Leaders, which was published on the Food and Land Use Coalition website. This call to action urges countries to implement three key measures to avert a global food crisis that could increase the number of people suffering from chronic hunger by millions:Â keep the supply of food flowing across the world; scale support to the most vulnerable; and invest in sustainable, resilient food systems.
Seed collection during the harvest at CIMMYTâs experimental station located in Cuidad ObregĂłn, Sonora. (Photo: CIMMYT/Peter Lowe)
What is the role of CIMMYTâs collaboration with Mexican government bodies in this process?
Govaerts: In the fields there is potential to respond and avoid that todayâs health crisis becomes tomorrowâs food crisis. CIMMYT is working with SADER and Mexicoâs National Research System (INIFAP) to contribute to a stable supply of basic grains grown sustainably in Mexico by offering technical advice to the more than 300,000 farmers that participate in MasAgro, CIMMYTâs bilateral collaboration project with Mexico for sustainable maize and wheat production.
Currently, MasAgro technicians and extension agents are working with smallholder farmers in the center and south of the country to prepare soils for sowing, advising on optimal sowing densities and use of high-yielding improved varieties, agro-ecological pest management, fertilization, irrigation, among other activities that are essential to begin the crop production cycle in time.
Mexico and CIMMYT are also working with the agri-food sector to build farmersâ capacities to increase grain production sustainably and to sell the surplus to local and multi-national agri-food companies in Mexico. This is part of wider country plans which are called Maize for Mexico and Wheat for Mexico.
How can we strengthen Mexico as a country of agricultural crops research and design activities?
Kropff: CIMMYT has been instrumental to public policy formulation in Mexico and has been positioned as one of Mexicoâs most trusted partners over the past 10 years.
Govaerts: Exactly, and the numbers speak for themselves. As a result of the collaboration with more than 150 collaborators from the public, private and social sector, MasAgro has had a positive impact in the lives of more than 300 thousand farmers who have adopted conservation agriculture, improved seeds and sustainable farming technologies on more than 1 million hectares across Mexico.
Kropff: It would be great if Mexico continued investing in integrated development projects like MasAgro, and scaled out sustainable farming practices and technologies with innovative approaches like responsible local sourcing, which I mentioned just before while it promotes the replication of the MasAgro model in other countries.
The RodrĂguez family, milpa farmers, in CristĂłbal ColĂłn, Campeche. (Photo: CIMMYT/Peter Lowe)
How can we strengthen farmer’s access to better crops and better farming techniques?
Kropff: It is imperative to CIMMYT to improve farmersâ economic opportunity. This cannot be done without essential ingredients such as access to markets, capacity development, technology, and inputs like seeds and fertilizer. And most importantly, better crops and farming technologies are worthless without the national agricultural research systemsâ buy in and trust.
Govaerts: This is very much at the heart of what we do together with maize farmers in Mexico in MasAgro. CIMMYT breeds maize hybrids with conventional technologies and improves native maize seed in collaborative projects with farmers. Then this improved maize seed is tested in collaboration with the local seed sector that, in turn, commercializes the best adapted materials in Mexicoâs growing regions. These seed companies are small and medium enterprises that generate economic development in the center and south of the country.
Kropff: Similarly, in a project that started in 2019 in eastern and southern Africa, we reach farmers in Malawi, and soon in Rwanda and Tanzania, with our improved seeds through small seed companies which play the key role of âconnectorâ in intricate and complicated markets which often are ignored by large seed companies. Then, CIMMYT researchers undertake varietal trials and track genetic gains in farmersâ fields and share the findings with the broader agricultural community.
What changes can we expect in the nation’s food supply chain management after COVID-19?
Kropff: All crises bring challenges and opportunities. I believe that Mexico could take this opportunity to make its supply and value chains more integrated, resilient and flexible.
Govaerts: Mexico can become the leader of innovation that integrates traditional and scientific knowledge.
What role does CIMMYT want to play in the future?
Kropff: I see CIMMYT working even closer to the farming communities but especially along the whole value chain with science and data towards improved decision-making.
Govaerts: CIMMYT can be a catalyst of integrated programs. We want to keep discovering and helping to implement new solutions for the worldâs poor and food insecure and work toward achieving the Sustainable Development Goals.
A series of coincidences led Sylvanus Odjo to study agronomy. It was only after finishing his first degree that he learned that his namesake, Silvanus, was the Latin deity of forests and fields.
Spurred by a curiosity about the natural world, he spent several years working at the National Institute of Agriculture in his native Benin, before pursuing advanced degrees in Belgium, where he developed his interest in cereals research.
âObviously by that point I knew about the CGIAR centers and the International Maize and Wheat Improvement Center,â he explains. âIf youâre working on maize, youâll know about CIMMYT.â
He joined the organization as a postdoctoral researcher in 2017 and now works as a postharvest specialist. He coordinates a network of platforms which evaluates and validates potential solutions and transfers them to farmers across Mexico and Latin America.
âAll the projects Iâm working on now have the same objective: finding ways to avoid and reduce postharvest losses.â These, Odjo estimates, can be as high as 40% in some parts of Mexico, with dramatic consequences for smallholder farmers whose food security is directly linked to the amount of grain they have. They are also the most likely to be affected by the effects of climate change.
âA lot of people think postharvest just means storage,â he points out, âbut it actually encompasses everything from the moment of harvest and includes processes like drying, shelling, technical and economic activities.â
A drying specialist by training, Odjo now works across the entire postharvest system. There are two central components to his work. The first involves testing postharvest technologies to develop recommendations for farmers, conducting trials under controlled conditions on CIMMYT research stations and with local collaborators across Mexico and assessing how drying and storage technologies fare under different conditions. The second, and perhaps more challenging, is promoting the successful ones, such as hermetic grain storage bags, among farmers and providing training on how to use them appropriately.
âWe see a lot of publications agreeing that we need to promote hermetic technologies, which is true.â The question, Odjo asks, is how to do it. âHow can we succeed in making a solution available to farmers? And once that has happened, how do we convince them to use it? Those are big questions which people were asking 50 years ago but theyâre still being discussed today.â
Odjo demonstrates the use of a handheld grain moisture tester in ComitĂĄn de Dominguez, Chiapas, Mexico. (Photo: Juan Carlos Reynoso)
Finding answers to the big questions
âThe potential solutions sound so simple, but when you actually try to implement these things it can be very complex.â
Odjo can reel off a list of postharvest interventions which seem straightforward initially but fail at the moment of implementation. Farmers might be instructed to harvest their grain at a particular time, which turns out to conflict with the timing of an important traditional ceremony, which cannot be rescheduled. Elsewhere they may be encouraged to avoid reducing moisture levels by purchasing a dryer but lack the resources to do so.
Much of Odjoâs work involves conducting research into the process of technology transfer and the scaling of postharvest technologies, working with a number of projects in Mexico to find the most efficient ways of training farmers and providing them with the tools they need to use improved practices and technologies.
âWhat weâre looking for is the right technology for each farmer,â he explains. âBecause the conditions in the highlands of Guanajuato are not the same as in coastal YucatĂĄn, or any of the other locations we work in.â Hermetic technology has been proven to be effective in most conditions, but the choice to use hermetic silos, hermetic bags, or a cocoon storage container ultimately depends on farmer preferences and the specific conditions in their local area. âWe noticed, for example, that in the highlands pests tend to pose less of a threat to stored grain, so we need to use a different strategy than we would at sea level, where humidity can significantly increase the risk of grain becoming contaminated.â
Odjo and his team have also noted that in Mexico, although many postharvest activities such as shelling are led by women, men are more likely to attend farmer trainings, which makes it harder to ensure that they are reaching their target demographic. âGender has emerged as a key parameter that we need to take into account, so weâre working with an excellent gender specialist at CIMMYT to find ways of making sure we transfer knowledge and technologies efficiently.â
While it can be challenging coordinating with so many different stakeholders, each with their distinct priorities and interests, Odjo is adamant that postharvest research can only be successful when it is fully interdisciplinary and collaborative. Though farmers are their core audience, he and his team make sure they work with extension agents, government actors, researchers and development practitioners to find solutions. âI canât do anything alone so Iâm open to collaboration,â he adds. âWe always need fresh ideas.â
âA lot of people think postharvest just means storage, but it actually encompasses everything from the moment of harvest and includes processes like drying, shelling, technical and economic activities,â Odjo explains. (Photo: Francisco AlarcĂłn/CIMMYT)
Sharing knowledge in 140 characters
Up until quite recently, Odjo was reluctant to join Twitter because he felt that he had nothing to share. It was only when colleagues encouraged him to use social media as a platform for discussing postharvest issues that he discovered the app is an effective way of sharing recommendations directly with farmers and agricultural service providers. âOne of my lecturers used to say that you can understand something if youâre capable of explaining it to a kindergarten-aged child. If you donât succeed, it means you havenât understood.â
âThatâs become a part of my job that I really enjoy: figuring out how to share research and results of investigations with different audiences in a simple manner.â
His newfound social media presence has also proved useful for connecting with researchers on a global level. In late 2019, researchers in Laos interested in learning about postharvest technologies reached out to Odjo, who was able to arrange for colleagues to travel to the country and share practices developed with local extension agents and blacksmiths in Mexico. âAnd do you know how they found me? Through my Twitter account.â
Moving forward, Odjo hopes to extend the scope of his activities beyond Latin America and carry out more knowledge exchange with his peers across the world. âIn research, a lot of people are working on the same topics, but we donât always share the information. Iâm open to sharing my experience, because Iâm sure I can learn a lot from others that will be useful for my job.â
Kenya in particular stands out as a case study he can learn from, where a high incidence of aflatoxins in maize, heavy government intervention and fierce market competition among providers of hermetic bags have allowed for the successful scaling of postharvest technologies. âIt would be great to be able to analyze their scaling process and learn from it. Not to replicate it entirely, because obviously the conditions arenât the same, but there will undoubtedly be lessons we can take and apply here in Mexico and Latin America.â
In crop research fields, it is now a common sight to see drones or other high-tech sensing tools collecting high-resolution data on a wide range of traits â from simple measurement of canopy temperature to complex 3D reconstruction of photosynthetic canopies.
This technological approach to collecting precise plant trait information, known as phenotyping, is becoming ubiquitous, but according to experts at the International Maize and Wheat Improvement Center (CIMMYT) and other research institutions, breeders can profit much more from these tools, when used judiciously.
In a new article in the journal Plant Science, CIMMYT researchers outline the different ways in which phenotyping can assist breeding â from large-scale screening to detailed physiological characterization of key traits â and why this methodology is crucial for crop improvement.
âWhile having been the subject of debate in the past, extra investment for phenotyping is becoming more accepted to capitalize on recent developments in crop genomics and prediction models,â explain the authors.
Their review considers different contexts for phenotyping, including breeding, exploration of genetic resources, parent building and translations research to deliver other new breeding resources, and how these different categories of phenotyping apply to each. Some of the same tools and rules of thumb apply equally well to phenotyping for genetic analysis of complex traits and gene discovery.
The authors make the case for breeders to invest in phenotyping, particularly in light of the imperative to breed crops for warmer and harsher climates. However, wide scale adoption of sophisticated phenotyping methods will only occur if new techniques add efficiency and effectiveness.
In this sense, âbreeder-friendlyâ phenotyping should complement existing breeding approaches by cost-effectively increasing throughput during segregant selection and adding new sources of validated complex traits to crossing blocks. With this in mind, stringent criteria need to be applied before new traits or phenotyping protocols are incorporated into mainstream breeding pipelines.
Some of Mexicoâs favorite dishes are taking on a new hue with blue corn chips, blue tortillas or blue tamales. But should breeders, millers, processors and farmer organizations invest in expanding the production of blue maize and blue maize products? Are consumers really interested, and are they willing to pay more?
CIMMYT markets and value chain specialist Trent Blare explains, in one minute, the results of his study, which gives insight into Mexican consumersâ preferences and demand for blue maize tortillas. Consumers near Mexico City perceived blue maize tortillas to taste better and were willing to pay up to a third more to buy them for special family events or to consume them in a restaurant .
In crop research fields, drones and other high-tech sensing tools are now a common sight. They collect high-resolution data on a wide range of traits â from simple measurement of canopy temperature to complex 3D reconstruction of photosynthetic canopies.
This technological approach to collecting precise plant trait information, known as phenotyping, is becoming ubiquitous. According to experts at the International Maize and Wheat Improvement Center (CIMMYT) and other research institutions, breeders can profit much more from these tools, when used judiciously.
Examples of different classes and applications of breeder friendly phenotyping. (Image: M. Reynolds et al.)
In a new article in the journal Plant Science, CIMMYT Wheat Physiologist Matthew Reynolds and colleagues explain the different ways that phenotyping can assist breeding â from simple to use, âhandyâ approaches for large scale screening, to detailed physiological characterization of key traits to identify new parental sources â and why this methodology is crucial for crop improvement. The authors make the case for breeders to invest in phenotyping, particularly in light of the imperative to breed crops for warmer and harsher climates.
