Integrated management of organic and inorganic nitrogen sources in high- to low-yield cereal production could bring yearly savings in nitrogen fertilizer of over 1 million tons in India, some 90,000 tons in Ethiopia, and more than 20,000 tons in Malawi, according to a new scientific paper, “Spatially differentiated nitrogen supply is key in a global food-fertilizer price crisis.”
“Global policies and governments should prioritize nitrogen supplies to low-yield, low-fertility cropping systems, such as smallholder maize and rice farms in Malawi, which are representative of the highly N-deficient cereal systems relied upon by over 100 million people in sub-Saharan Africa,” said Sieglinde Snapp, director of the Sustainable Agrifood Systems Program at the International Maize and Wheat Improvement Center (CIMMYT) and first author of the paper. “Those farmers should also ramp up organic nitrogen inputs, such as manure and legume crops.”
In the intensive, high-yield cropping systems of India, farmers generally over-apply N fertilizer on 90% of the rice and wheat crops and more than half of maize crops. Less than half the nitrogen is taken up and used by the crops and the rest is lost into the environment, contaminating water, land, and the atmosphere. “Simply saving the excess fertilizer from over-fertilized areas and shifting it to low-application areas could increase global crop yields by 30%, with huge reductions in greenhouse gas emissions,” said Tek Sapkota, co-author of the paper and climate change leader at CIMMYT.
This study is based on evidence of achievable shifts in nitrogen management over 1-2 years, for a modest proportion of cropped area (10%). “We did not assess interventions with longer time horizons or large investment requirements such as precision agriculture, mechanization, or deep placement of fertilizer,” Snapp explained.
Snapp and her colleagues used evidence from the scientific literature to estimate N-fertilizer savings from the above interventions for maize, wheat, and rice cropping systems in India, Ethiopia, and Malawi. Integrated organic and inorganic nitrogen management was estimated by considering manure and legume N inputs along with N fertilizers. The effect of reallocating public subsidies to more cost-effective, high-N fertilizer was calculated as the extra nitrogen that could be made available through a lower unit cost of nitrogen.
Food production vs healthy environment?
According to Snapp, humanity is caught in a bind. Food crops grown using synthetic nitrogen fertilizer have fed expanding world populations since the 1960s, fertilizer use has increased nearly 10-fold since then, and significantly higher food demands lie ahead to mid-century. At the same time, poor use of N fertilizer is hurting the environment and, most recently, geopolitical conflicts have disrupted N fertilizer supplies and exposed the vulnerabilities of the global fuel-fertilizer-food nexus.
“In regions where cropping systems are highly deficient in nitrogen, investment is needed in policies and extension education to promote the use of organic nitrogen residues and legume crops,” Snapp said.
Extension agencies, she suggests, can extend their reach using digital tools and bi-directional communication approaches that engage local knowledge and farmers, including advisories regarding local soils and crop and fertilization requirements.
Reiterating the commitment to leading agriculture innovation across Africa, Bram Govaerts, director general of the International Maize and Wheat Improvement Center (CIMMYT), took part in the 8th Africa Agribusiness and Science Week (AASW8), June 5-8, 2023, in Durban, South Africa.
Partners discuss how to generate greater impact for farmers through regional partnerships between One CGIAR and African stakeholders (Photo: Liesbet Vannyvel/CIMMYT)
The theme of the AASW8 was linking science, innovation, and agribusiness for resilient food systems.
CGIAR System Board Chair Lindiwe Sibanda called for increased research and innovation to achieve an impact at scale and benefit African farmers at the opening ceremony.
Govaerts moderated a partner panel discussion regarding opportunities to strengthen the collaboration between One CGIAR and African research stakeholders.
Organizations represented on the panel included leaders from Technologies for African Agricultural Transformation, Total Landcare, Lupiya, Chitetezo Farmer Federation, and Green Sahel.
The African Development Bank, the African Union Commission, the Forum for Agricultural Research in Africa, and CGIAR also launched the Action Plan for the Abidjan II Communiqué that aims to build Africa’s resilience to future shocks by bolstering agricultural research and innovation systems to give farmers access to the science and technologies that they need to thrive.
“African countries must systematically review what is needed for the transformation of agrifood systems taking into consideration the present and future needs, and significantly increase investment in agricultural research and development,” said Govaerts.
Local and regional agribusiness is an essential industry playing a significant role in Africa’s prospects for economic growth and ensuring food security of its citizens. Still, challenges include regional harmonization of crop variety releases, surveillance of transboundary pests, and the growing threats of climate change.
“CIMMYT is dedicated to collaborating with local stakeholders to facilitate policies at the national, regional, and continental levels to promote proactive and eco-friendly management of transboundary plant health threats,” said Govaerts.
Honoring a legacy of innovative development in Zambia and looking forward to meeting the nation’s goals for food security, Bram Govaerts, director general of the International Maize and Wheat Improvement Center (CIMMYT), along with CGIAR Board Chair Lindiwe Sibanda, visited facilities and met with southern Africa collaborators of the Southern Africa AID-I Rapid Delivery Hub on June 2 and 3, 2023.
Bram Govaerts visited field experiments with the head of science at Zamseed (Photo: Katebe Mapipo/CIMMYT)
“CIMMYT’s work in Zambia and the region is geared to help national governments build resilience to climate change, diversify maize-based farming systems and improve productivity and production to address reduce hunger and poverty,” said Govaerts.
Southern Africa AID-I Rapid Delivery Hub aims to provide critical support to over 3 million farming households in Malawi, Tanzania and Zambia via targeted interventions for demand driven seed scaling, improved soil health and fertilizer use efficiency, and rapid delivery of critical agricultural advisory services deep into rural communities.
CIMMYT research and innovation supports Zambia’s medium-term goal of “Socio-Economic Transformation for Improved Livelihoods” and its 2030 Vision of becoming “A Prosperous Middle-Income Nation by 2030.”
Govaerts and Sibanda toured Afriseed’s factory in Lusaka and its wheat field trials in Ngwerere. They also attended a field demonstration of Purdue Improved Crop Storage bags in the nearby district of Chongwe organized by the Catholic Relief Services, a local partner promoting low-cost post-harvest technologies for small-scale farmers in Zambia.
The delegation visited private partner Zamseed, a company commercializing and releasing CIMMYT-bred, Fall Armyworm tolerant maize seeds.
Southern Africa AID-I Rapid Delivery Hub has enabled the release of nearly 10,000 metric tons of certified maize and legume seed, which have been harvested by Zambian seed companies and community-based seed organizations, directly benefiting a million semi-subsistence farmers.
Govaerts also hailed Zambia’s commitment to creating a transparent seed system. “Thanks to this conducive policy environment, Zambia is a major hub in sub-Saharan Africa for hybrid maize seed production and export in Africa.”
Kevin Kabunda opened a partner meeting in which Bram Govaerts met AID-I farmers and partners from seed companies, educational institutions, CGIAR centers, and micro-finance and tech companies. (Photo: Katebe Mapipo/CIMMYT)
Besides Southern Africa AID-I Rapid Delivery Hub, CIMMYT and the Zambia Agricultural Research Institute have been collaborating for over two decades along with public and private partners in Zambia through different investments designed to create sustainable interventions that strengthen food systems and directly reach small-scale farmers.
Leading crop simulation models used by a global team of agricultural scientists to simulate wheat production up to 2050 showed large wheat yield reductions due to climate change for Africa and South Asia, where food security is already a problem.
The model predicted average declines in wheat yields of 15% in African countries and 16% in South Asian countries by mid-century, as described in the 2021 paper “Climate impact and adaptation to heat and drought stress of regional and global wheat production,” published in the science journal Environmental Research Letters. Climate change will lower global wheat production by 1.9% by mid-century, with the most negative impacts occurring in Africa and South Asia, according to the research.
“Studies have already shown that wheat yields fell by 5.5% during 1980-2010, due to rising global temperatures,” said Diego N.L. Pequeno, wheat crop modeler at the International Maize and Wheat Improvement Center (CIMMYT) and lead author of the paper. “We chose several models to simulate climate change impacts and also simulated wheat varieties that featured increased heat tolerance, early vigor against late season drought, and late flowering to ensure normal biomass accumulation. Finally, we simulated use of additional nitrogen fertilizer to maximize the expression of these adaptive traits.”
Wheat fields in Ankara, Turkey, where data was used for crop model simulation (Photo: Marta Lopes/CIMMYT)
The wheat simulation models employed — CROPSIM-CERES, CROPSIM, and Nwheat within the Decision Support System for Agrotechnology Transfer, DSSAT v.4.6 — have been widely used to study diverse cropping systems around the world, according to Pequeno.
“The DSSAT models simulated the elevated CO2 stimulus on wheat growth, when N is not limiting,” he said. “Our study is the first to include combined genetic traits for early vigor, heat tolerance, and late flowering in the wheat simulation.”
Several factors, including temperature, water deficit, and water access, have been identified as major causes in recent wheat yield variability worldwide. The DSSAT wheat models simulate the impact of temperature, including heat stress, water balance, drought stress, or nitrogen leaching from heavy rainfall.
“Generally, small and low-volume wheat producers suffered large negative impacts due to future climate changes, indicating that less developed countries may be the most affected,” Pequeno added.
Climate change at high latitudes (France, Germany, and northern China, all large wheat-producing countries/region) positively impacted wheat grain yield, as warming temperatures benefit wheat growth through an extended early spring growing season. But warmer temperatures and insufficient rainfall by mid-century, as projected at the same latitude in Russia and the northwestern United States, will reduce rainfed wheat yields — a finding that contradicts outcomes of some previous studies.
At lower latitudes that are close to the tropics, already warm, and experiencing insufficient rainfall for food crops and therefore depending on irrigation (North India, Pakistan, Bangladesh), rising heat will damage wheat crops and seriously reduce yields. China, the largest wheat producer in the world, is projected to have mixed impacts from climate change but, at a nation-wide scale, the study showed a 1.2% increase in wheat yields.
“Our results showed that the adaptive traits could help alleviate climate change impacts on wheat, but responses would vary widely, depending on the growing environment and management practices used,” according to Pequeno. This implies that wheat breeding for traits associated with climate resilience is a promising climate change adaptation option, but its effect will vary among regions. Its positive impact could be limited by agronomical aspects, particularly under rainfed and low soil N conditions, where water and nitrogen stress limit the benefits from improved cultivars.
Extreme weather events could also become more frequent. Those were possibly underestimated in this study, as projections of heat damage effects considered only changes in daily absolute temperatures but not possible changes in the frequency of occurrence. Another limitation is that most crop models lack functions for simulating excess water (e.g., flooding), an important cause of global wheat yield variability.
This study was supported by the CGIAR Research Program on Wheat agri-food systems (CRP WHEAT; 2012-2021), the CGIAR Platform for Big Data in Agriculture, the International Wheat Yield Partnership (IWYP115 Project), the Bill & Melinda Gates Foundation, the World Bank, the Mexican government through the Sustainable Modernization of Traditional Agriculture (MasAgro) project, and the International Treaty of Plant Genetic Resources for Food and Agriculture and its Benefit-sharing Fund for co-funding the project, with financial support from the European Union.
In December 2022, more than 40 scientists from African National Agricultural Research Institutes (NARI) and Small and Medium Enterprise (SME) seed companies received training on the design and implementation of modern maize breeding programs.
The training, explains Yoseph Beyene, project leader in the Accelerating Genetic Gains (AGG) – Maize project, was designed to improve maize breeders’ knowledge of the most advanced technologies and methodologies in order to increase genetic gains in their respective breeding programs. It was supported by AGG-Maize and the CGIAR Accelerated Breeding Initiative (ABI) and formed part of ongoing efforts to modernize NARI breeding programs under AGG-Maize.
Yoseph Beyene, Accelerating Genetic Gains-Maize Project leader, makes introductory remarks at the start of the Senior Breeders Training in Nairobi, Kenya. (Photo: Susan Otieno/CIMMYT)
Over the course of five days in Nairobi, Kenya, participants from 13 countries where AGG-Maize is implemented worked to develop their skills in the use of new technologies and approaches to improving genetic gains and breeding efficiencies. Topics covered included the prioritization of market segmentation and product profile development, application of quantitative genetics principles in maize breeding, seed production research, improved designs for regional on-farm trials, and much more.
“The training was an eye opener supported by detailed explanations on applications of diverse research methodologies in maize breeding,” said Isiah Aleri, a research assistant for the International Maize and Wheat Improvement Center’s (CIMMYT) Maize Program in Kenya. “I met teams who had different views on some breeding techniques, but later received guided explanations from trainers on why certain standards and requirements are set for effective decision making.”
Veronica Ogugo, a research associate in the same CIMMYT program, agreed saying: “It was very educative and in-depth in all the areas that were covered by the different specialists. The best part was that each of the components complimented one another.” She added that the training also offered a good opportunity for interaction with other experts.
B.M. Prasanna, CIMMYT Global Maize Program director, speaks at the Senior Breeders Training in Nairobi, Kenya. (Photo: Susan Otieno/CIMMYT)
What and whom to breed for
In his opening remarks at the training, B.M. Prasanna, Global Maize Program director at CIMMYT, noted the need for efficient use of limited resources, and encouraged scientists to work smartly, for instance, by leveraging available germplasm across phenotyping networks from other regions to diversify germplasm base for increased genetic gains. He emphasized the importance of clearly determining market segments and developing product profiles that have clear objectives, as well as the key traits to be considered, such as tolerance to drought, heat, and pests and diseases like fall armyworm.
Prasanna highlighted zinc as an example of an important feature to focus on, pointing out the micronutrient’s vital role in mental well-being and its immune boosting properties, especially in children. “Different geographies have different ways of using maize,” he explained. “In general, maize provides 15-56% of total calorie intake in the rain-fed tropics, hence its importance for improving not only smallholder farmer incomes but also food and nutrition security.”
He also outlined how important partnerships with national programs and seed companies are for achieving the fullest impact of CIMMYT’s work. “The strong regional collaborative maize breeding and seed systems is fundamental for impact,” he said. “It is also the reason for arguably the largest public sector maize germplasm testing network in the Global South, in rain-fed stress-prone tropical environments.”
In the Indo-Gangetic Plains of northern India, nearly 70% of the population is involved in agriculture and extension services. Despite the abundantly fertile soil and farmers’ resilience, the adoption of agricultural innovations and productivity in the region has been slow.
This slow progress is often attributed to comparatively low levels of agricultural mechanization in the region and small land holdings of individual farmers, which often makes them risk averse to new technologies. However, times are changing.
Farmer Gangesh Pathak, in his recently harvested field using combine harvester machine, discuss Kharif – summer crops – schedule with CIMMYT Agronomist Ajay K Pundir. (Photo: Vijay K. Srivastava/CIMMYT)
Through the Cereal Systems Initiative for South Asia (CSISA) project, researchers from the International Maize and Wheat Improvement Center (CIMMYT), working closely with the local Krishi Vigyan Kendra (KVK) and partners, have led the transition from traditional farming to sustainable intensification agricultural practices in the region, helping the region slowly but steadily realize its full potential. Over the years, working extensively with progressive farmers, CSISA scientists have helped optimize the cost of inputs and increase productivity through new technology adoption and capacity building for these farmers.
Krishnamohan Pathak, a farmer in his early sixties from the village of Patkhaoli, first learned about conservation agriculture practices when he attended a field event in Nonkhar village in Deoria district, Uttar Pradesh. CSISA researchers invited farmers from Nonkhar and neighbouring villages to attend a field day event, an exposure activity, on zero tillage wheat and direct seeded rice (DSR) technologies. Zero tillage allows farmers to plant directly without plowing or preparing the soil, minimizing soil movement. Pathak was one of the farmers who got to see first-hand the advantages of these sustainable agricultural practices.
Seeing merit in these practices, Pathak continued to engage with CSISA scientists and in 2013-2014, adopted zero tillage, and directly seeded rice in his family-owned fields.
“The CSISA field team encouraged me to buy a rice planter which has helped manage paddy transplantation on time, and wheat after that through zero till,” Pathak said.
Pathak later participated in other agri-technology events and CSISA field trial activities. In 2018, he joined other progressive farmers from the region who attended a training at ISARC (IRRI South Asia Regional Centre) in Varanasi, Uttar Pradesh on direct seeded rice, organized by CSISA researchers to build capacity and raise awareness of the conservation agriculture method.
The next generation leads the way
Today, Pathak is one of the key influential farming members in the region. He has now, however, passed the baton to his 37-year-old son Gangesh Pathak. “I have occupied myself with other local leadership activities after my son has been active in the fields. I am not so skilled at using these machines, their maintenance and their services. The younger generation seems much better at adapting,” he said.
Gangesh has been involved actively in farming ever since he finished his graduation, trying to make it lucrative. He has enjoyed recent success growing wheat and rice through new technology and practices. Standing in the fields recently harvested with the new improved wheat variety DBW 187, grown through early sowing – a method which goes against the traditional practice of planting after November – and zero tillage, he is happy with his 5.5 ton per hectare yield.
He spoke enthusiastically about the farming machinery he has procured to reduce drudgery in his farms and the hiring services provided to smallholder farmers in the region. After his father bought the transplanter in 2014, the family added larger machines such as the Happy Seeder, Super Seeder, Laser Land Leveller, Straw Reaper, and Direct Seeded Rice machine.
Farmer Gangesh Pathak explains the use of machinery that has enabled conservation agriculture practices in his fields and helped improve yields and income. (Photo: Nima Chodon/CIMMYT)
According to Gangesh, this has been possible thanks to the support from the local agriculture authorities and guidance from the CSISA team, who told his father about the various schemes offered by the central and state government to support farmers to adopt more productive and sustainable agricultural technologies.
Ajay Kumar Pundir, CIMMYT agronomist, based in Uttar Pradesh and leading CSISA’s efforts, stressed the importance of access to agricultural mechanization and support.
“Our job just does not end at informing and training farmers about better-bet agricultural practices. Along with other public and private stakeholders, we must support and ensure their availability and access – machines, quality seeds, timely information – for farmers to adopt it,” he said.
Custom hiring center help scale mechanization
With so much farm machinery, the Pathaks soon began extending hiring services. Custom hiring is a promising enterprise opportunity for farmers as they can use the machinery on their farms and earn extra income by extending services to other farmers at a reasonable cost, which helps cover diesel and maintenance costs. Gangesh made about 2.5 lakhs (USD $3,033.76) in profit during the 2022-2023 Rabi (winter crops) through hay machine hiring services, where around 250 farmers used these services.
Once the word spread, demand for hiring services by smallholder farmers, challenged by scarce labor for sowing and harvesting, started growing. Gangesh was encouraged by the good profits and was keen to share the benefits of such hiring services to as many farmers as possible, and he helped establish a Farmer Producer Organization (FPO) with his father, Krishnamohan. FPO is a group made up of farmer-producers who are entitled to a host of benefits, including quality seeds, technical support, market access, under the Department of Agriculture and Farmers Welfare (DA&FW).
The FPO, started by the Pathaks in 2020, with 75 members (farmers) initially, currently boasts of around 300 farmers. Almost all FPO members have availed the custom hiring services for all farming purposes and various crops. Farmers, “particularly smallholders who cannot afford to purchase these machines for less than a few acres of land, are happy with the custom hiring services. It helps reduce their input cost by almost 50% along with other FPO member benefits,” Gangesh said.
Community-based technology demonstrations by CSISA and KVK and partners are ongoing to scale-out proven technologies and practices like early wheat sowing, zero tillage, and direct seeded rice. Gangesh is hopeful that farmers in the region, despite the emerging climate crisis concerns – already being felt in the region – can produce more and improve their income. He reckons that diversifying between rice-wheat cropping systems, mechanizing and system optimization through better advisories, and improved access to technologies as recommended by agronomists, will help farmers stay ahead of the curve.
About CSISA
Established in 2009, the Cereal Systems Initiative for South Asia (CSISA) is a science-driven and impacts-oriented regional initiative for increasing the productivity of cereal-based cropping systems. CSISA works in Bangladesh, India, and Nepal. CSISA activities in India focus on the eastern Indo-Gangetic Plains, dominated by small farm sizes, low incomes, and comparatively low agricultural mechanization, irrigation, and productivity levels. Learn about CSISA (India) Phase 4.0
Staff of the International Soil Borne Pathogens Research and Development Center along with the Minister, deputy ministers, TAGEM’s DG, and high-level officials of the Ministry of Agriculture Forestry. (Photo: TAGEM)
Soil-borne pathogens (SBP) are a serious threat to Turkey’s food security, especially as climate extremes (temperature, precipitations) become more commonplace. SBP are an array of specific adverse effects, such as root rot, wilt, yellowing, and dwarfing caused by fungi, bacteria, viruses, and nematodes. These pathogens can cause 50-75% yield loss in crops.
On May 2, 2023, the International Maize and Wheat Improvement Center (CIMMYT) Country Representative in Turkey, Abdelfattah Dababat, joined the inauguration ceremony of the International Soil-Borne Pathogens Research & Development Center (ISBPRDC).
Vahit Kirişci, Turkish Minister of Agriculture and Forestry, inaugurated the Center, which is the first of its kind in the Central West Asia and North Africa (CWANA) region dedicated to advancing research on SBPs and developing innovative solutions to control and prevent their spread.
The opening ceremony took place at the Directorate of Plant Protection Central Institute working under the General Directorate of Agricultural Research and Policies (TAGEM), and it was attended by deputy ministers, TAGEM’s DG, and high-level officials of the Ministry of Agriculture and Forestry.
Serving under the auspices of the General Directorate of Agricultural Research and Policies (TAGEM), part of the Turkish Minister of Agriculture and Forestry, the ISBPRDC will meet international standards for sanitary conditions.
CGIAR and TAGEM mutually supported the SBP CIMMYT Turkey program by establishing and funding the ISBPRDC.
Bringing partners together
CIMMYT is signing a collaboration agreement with the ISBPRDC to facilitate knowledge exchange and technology transfer between the two institutions, which will support joint research and development activities aimed at improving crop health and productivity.
“The most effective way forward to battle against threats to food security is through cooperation,” said Dababat. “This collaboration is a great opportunity for Turkey’s seed industry to maintain its competitive advantage in foreign markets.”
Professor Vahit Kirişci, Turkish Minister of Agriculture and Forestry, TAGEM’s DG, CIMMYT’s Representative, and high-level officials from the Ministry of Agriculture and Forestry. (Photo: TAGEM)
Thirty-five scientists and technicians will work at the ISBPRDC and the institute will act as an umbrella for all SBP research in Turkey. Bahri Dağdaş International Agricultural Research Institute (BDIARI), the Transitional Zone Agricultural Research Institute (TZARI), and the Plant Protection Central Research Institute (PPCRI) with offices in Konya, Eskisehir, and Ankara, respectively, will support the ISBPRDC center and collaborate with the SBP program at CIMMYT to deliver high-yielding wheat germplasm that is resistant to SBP.
Among new programs at the center are the development of a robust surveillance system to track pathogens, a genebank for germplasm, and screening facilities for resistance against SBP.
AID-I staff inspect germination in Malawi (Photo: CIMMYT)
Accelerated delivery with a difference is underway in Malawi, Tanzania, and Zambia to ensure access to stress-tolerant seeds for underserved farmers in remote areas. Supported by USAID, the Accelerated Innovation Delivery Initiative (AID-I) project brings public-private and civil society together to address the impacts of climate change, pests and diseases, and food shocks on maize and legume systems.
One simple and cost-effective solution to tackle these threats is last mile delivery of stress-tolerant and nutritious seeds. Ensuring that farmers have access to a diverse range of seeds means they can choose the best varieties to suit their needs and their local environment.
Through AID-I, scientists at the International Maize and Wheat Improvement Center (CIMMYT) are working with over 20 global, regional, national, and local partners to strengthen maize and legume seed systems in Malawi, Tanzania, and Zambia.
So far, in 2023, the team has set up over a hundred mega-demonstrations across Malawi and Zambia, to raise awareness and increase seed production by exposing communities to improved, climate-adapted and nutritious crop varieties. As learning centers, the mega-demonstrations give farmers a chance to see for themselves the advantages of improved maize and legume varieties and better farming practices including conservation agriculture and doubled up legumes systems.
Farmers plant mega-demonstration plots in Malawi (Photo: CIMMYT)
Spotlighted were drought-tolerant and nutritious varieties, expected to play a crucial role in the recovery of regional maize production. The Zambian and Malawian governments have also just released maize hybrids tolerant to fall armyworms, which will be scaled through the AID-I. The fall armyworm is an invasive pest that attacks more than 80 different crops but has a particular preference for maize. Without proper control measures, the pest can decimate crops, threatening food security, incomes, and livelihoods.
Alongside maize, the AID-I team is making seed of improved legume varieties, including beans, soybean, pigeon peas, cowpea, and groundnuts available at the last mile. Legumes are nutritious and good for the soil, providing valuable nutrients like nitrogen (N) so farmers can use less fertilizer, save money, and protect soil health.
AID-I supports strengthening of strategically located seed stockists of improved legume varieties and linking seed growers and buyers. These stockists, called agricultural development agents will also receive training in community seed production. Through connection with hundreds of agricultural development agents in the first farming season with seed suppliers, hundreds of thousands of farmers will be able to access a wide variety of improved seed.
Members of the CIMMYT leadership team with representatives from the U.S. Department of State and the U.S. Agency of International Development (USAID) visit AfriSeed in Zambia (Photo: CIMMYT)
Building strong relationships between public and private sector organizations is an integral part of the project. On January 16, 2023, long-term CIMMYT collaborator and AID-I key partner, AfriSeed hosted senior government officials from the United States Department of State (DOS) and U.S. Agency for International Development (USAID). The visitors gained valuable insight into how private seed companies involved in the marketing and distribution of maize and legume seeds operate in Zambia and showed their crucial role in the country’s seed sector.
1000FARMS is an institutional platform of NARES/CGIAR breeding networks whose purpose is to magnify their effectiveness and impact by enabling them to generate sufficient on-farm data and product insights on late-stage maize breeding selection candidates and new releases to ensure they will be high-performing in the hands of farmers, are farmer-preferred and climate-adapted, and can be recommended for scaling by the seed system. The platform achieves this by integrating three primary components:
tricot, or triadic comparison of technology options, a research methodology that helps farmers to identify the most suitable technologies for the local conditions of their farm, engaging them in the testing or validation of new crop varieties and other promising technologies.
ClimMob, a digital public software package developed by the Alliance of Bioversity-CIAT that allows farmers and field agents to record crowdsourced data, such as variety preferences, notes on performance, images, and gender/socio-economic data.
An on-farm trial (OFT) community of practice embedded in the NARES/CGIAR Breeding Networks in Africa.
These tools and methodologies already exist and have been well-tested; the innovation of 1000FARMS is to put all three components together to accelerate the uptake of the OFT approach across CGIAR and NARES breeding networks.
Objectives:
Expand and improve OFT tools to enable streamlined workflows and extract more insights from OFT data.
Implement appropriately scaled on-farm testing programs in partnership with at least 20 NARES/CG crop breeding networks.
Bram Govaerts, Sieg Snapp, Minister Mtolo Phiri and Prassana Boddupalli pose at the conclusion of the high level meeting between CIMMYT and the Government of Zambia. (Photo: Tawanda Hove/CIMMYT)
Senior government officials in Zambia have embraced the rollout of the International Maize and Wheat Improvement Center’s (CIMMYT’s) new innovations which target smallholder farmers and agriculture-based value chain actors in the country.
On January 17, 2023, CIMMYT Director General Bram Govaerts met with Minister of Agriculture Reuben Mtolo Phiri. The Minister reassured Govaerts that the investments made by CIMMYT in the country had the Government’s full support.
Earlier this year, a delegation led by Cary Fowler, the US Special envoy for Global Food Security met the Minister and his team at the Government complex in Lusaka, Zambia’s capital, to deliberate on a variety of agriculture development issues concerning the country.
Govaerts’ visit came off the back of the new Accelerated Innovation Delivery Initiative (AID-I), a CIMMYT-led project funded by the United Stated Agency for International Development (USAID). The project seeks to scale up promising innovations that could transform the maize and legume value chains within the southern African region, with a focus on Zambia, Malawi and Tanzania.
“As the Government of Zambia, we intend to create a private sector driven economy for which agriculture plays a critical role. Having progressive partners like CIMMYT helps us achieve this cause and this new program is received with open arms,” said Phiri.
The aims of the AID-I project include strengthening seed systems, the promotion and adoption of stress-tolerant maize and legume varieties, demonstration of good agriculture practices that respond to the effects of climate change and addressing systemic constraints in maize and legume value chains.
Through AID-I, CIMMYT experts are working with over 20 global, regional, national and local partners including the Alliance for a Green Revolution in Africa (AGRA), Catholic Relief Services (TLC), Total Land Care (TLC), the International Water Management Institution (IMWI) and World Vegetable Center.
Also attending the meeting was AID-I Technical Lead and CIMMYT Scientist Hambulo Ngoma who discussed some of the latest project activities.
“As this project focuses on accelerated delivery, we have set up more than 40 demonstrations in eastern Zambia with the intention of showcasing stress-tolerant varieties for maize and legume under conservation agriculture. In addition, we are showcasing other good agriculture practices such as strip cropping which not only enhances intensified crop production but is a biological control for fall armyworm,” Ngoma said.
Hambulo Ngoma receiving a verbal vote of confidence from Zambian Minister of Agriculture Mtolo Phiri. (Photo: Tawanda Hove/CIMMYT)
The Minister appreciated the rationale of the project and indicated that participatory variety selection for farmers was crucial if they were going to maximize their yields and returns from farming.
Phiri further emphasized that CIMMYT and partners’ investment in legume value chain strengthening came at a welcome time as upscaling soya bean production was a key priority in the Government’s strategic plan for agricultural development because of its export-ready market within the region.
“Markets such as Zimbabwe, Mozambique and Tanzania can readily take up the soya we produce, and we are looking to export legumes such as soya and groundnuts to East Africa. This project therefore fits very well within our strategic road map,” Phiri said.
The demonstration plots set up by CIMMYT experts will help farmers grow the right varieties for their agro ecologies and have greater response capabilities to the export market opportunities the Government is facilitating.
The Minister also indicated that he hoped CIMMYT would assist in strengthening the country’s capacity to deal with fall armyworm. CIMMYT Global Maize Program Director B.M. Prasanna reassured Phiri that through the Zambian Agriculture research Institute (ZARI), CIMMYT had already released three fall armyworm-tolerant varieties. He also discussed how the AID-I project would be instrumental in scaling up their uptake, especially amongst smallholder farmers who have minimal disposable income to buy enough pesticides to control the pest.
Concluding the meeting, Govaerts spoke of CIMMYT’s commitment to supporting Zambia achieve its food security and agricultural export goals.
“As CIMMYT, we want you to recognize us as a listening partner. We are of the conviction that we can only combat climate change and achieve shared prosperity through the strength of convening power, where we leverage on each other’s strength.”
As the project is focused on scaling existing promising technologies and innovations, rapid transformative results are on the horizon for the people of Zambia.
Delegates with other officials in front of the seminar room. (Photo: Biswajit/BWMRI)
Representatives from Australian Centre for International Agricultural Research (ACIAR) and Bangladesh Agricultural Research Council (BARC) paid a visit to Bangladesh to see the valuable work of the Precision Phenotyping Platform (PPP).
PPP was established in response to the devastating wheat blast disease, which was first reported in the country in 2016.
Technical and financial support from the International Maize and Wheat Improvement Center (CIMMYT), the Australian Commission for International Agricultural Research and the Australian Centre for International Agricultural Research, along with other funders, has contributed to the effort to combat the disease.
This is achieved by generating precise data for wheat blast resistance in germplasm in Bangladesh, as well as other wheat growing countries. This PPP has been used to screen elite lines and genetic resources from various countries.
On February 16 and 17, 2023, two groups of national and international delegations visited the BWMRI-CIMMYT collaborative research platform PPP at the BWMRI regional station in Jashore, Bangladesh.
The first group was made up of representatives from both the Australian Commission for International Agricultural Research and the Australian Centre for International Agricultural Research. This included seven commissioners under the direction of Fiona Simson, along with ACIAR senior officials from Australia and India.
The other group was from BARC, which was led by Executive Chairman Shaikh Mohammad Bokhtiar, along with Golam Faruq, Director General of BWMRI, and Andrew Sharpe, Bangabandhu Research Chair, Global Institute of Food Security (GIFS), University of Saskatchewan in Canada.
Both delegations were welcomed by Muhammad Rezaul Kabir, the Senior Wheat Breeder at BWMRI. Kabir gave a brief presentation about the platform and other wheat blast collaborative research programs in the seminar room.
The delegations then went to the PPP field, where BWMRI researchers Kabir and Robiul Islam, as well as CIMMYT researcher Md. Harun-Or-Rashid, explained further information about the BWMRI-CIMMYT collaborative research. Both commissioners and delegates appreciated seeing the work being conducted in person by the national and international collaborations of BWMRI and CIMMYT on wheat blast research.
Visitors observing blast disease symptoms in wheat leaves. (Photo: Muhammad Rezaul Kabir/BWMRI)
“It is important, innovative work, that is affecting not only Bangladesh but many countries around the world that are now starting to be concerned about the impacts of wheat blast,” commissioner Simson said. “This study is very important for Australia and we are pleased to be contributing to it.”
Lindsay Falvey, another commissioner, added, “This is a wonderful experiment, using high-level science and technologies to combat wheat blast in Bangladesh. The experiment is well-planned. Overall, it is an excellent platform.”
ACIAR delegate Eric Huttner added to the praise for the project. “The platform is performing extremely well for the purpose of evaluating lines, resistance to the disease and that’s very useful for Bangladesh and rest of the world,” he said. “This is a gift that Bangladesh is giving to the neighboring countries to protect wheat.”
The delegates pledged to share their expert advice with the Minister of Foreign Affairs in Bangladesh in order to increase investments and improve facilities for agricultural research programs in the country.
Golam Faruq, Director General of BWMRI discussing the PPP with Shaikh Mohammad Bokhtiar, Executive Chairman of BARC (Photo: Md. Harun-Or-Rashid/CIMMYT)
“This is an excellent work,” Executive Chairman of BARC, Bokhtiar said. “We can get more information from screening activities by using bioinformatics tools and training people through the BARC-GIFS program.”
Pawan Kumar Singh, Head of Wheat Pathology at CIMMYT-Mexico and Project Leader, coordinated the visits virtually and expressed his thanks to the delegations for their visit to the platform. This PPP, within a short span of few years, has been highly impactful, characterizing more than 15,000 entries and releasing several resistant varieties in countries vulnerable to wheat blast.
The Wheat Disease Early Warning Advisory System (Wheat DEWAS) project is bringing new analytic and knowledge systems capacity to one of the world’s largest and most advanced crop pathogen surveillance systems. With Wheat DEWAS, researchers are building an open and scalable system capable of preventing disease outbreaks from novel pathogen strains that threaten wheat productivity in food vulnerable areas of East Africa and South Asia.
The system builds from capabilities developed previously by multi-institutional research teams funded through long-term investments in rust pathogen surveillance, modelling, and diagnostics. Once fully operationalized, the project aims to provide near-real-time, model-based risk forecasts for governments. The result: accurate, timely and actionable advice for farmers to respond proactively to migrating wheat diseases.
The Challenge
Farmers growing wheat face pathogen pressures from a range of sources. Two of the most damaging are the fungal diseases known as rust and blast. Rust is a chronic issue for farmers in all parts of the world. A study in 2015 estimated that the three rust diseases — stem, stripe and leaf — destroyed more than 15 million tons of wheat at a cost of nearly $3 billion worldwide. Wheat blast is an increasing threat to wheat production and has been detected in both Bangladesh and Zambia. Each of these diseases can destroy entire harvests without warning, wiping out critical income and food security for resource-poor farmers in vulnerable areas.
The Response
Weather forecasts and early-warning alerts are modern technologies that people rely on for actionable information in the case of severe weather. Now imagine a system that lets farmers know in advance when dangerous conditions will threaten their crop in the field. Wheat DEWAS aims to do just that through a scalable, integrated, and sustainable global surveillance and monitoring system for wheat.
Wheat DEWAS brings together research expertise from 23 research and academic organizations from sub-Saharan Africa, South Asia, Europe, the United States and Mexico.
Together, the researchers are focused on six interlinked work packages:
Work package
Lead
Objectives
Data Management
Aarhus University; Global Rust Reference Center
Maintain, strengthen and expand the functionality of the existing Wheat Rust Toolbox data management system
Create new modules within the Toolbox to include wheat blast and relevant wheat host information
Consolidate and integrate datasets from all the participating wheat rust diagnostic labs
Develop an API for the two-way exchange of data between the Toolbox and the Delphi data stack
Develop an API for direct access to quality-controlled surveillance data as inputs for forecast models
Ensure fair access to data
Epidemiological Models
Cambridge University
Maintain operational deployment and extend geographical range
Productionalize code for long-term sustainability
Multiple input sources (expert, crowd, media)
Continue model validation
Ensure flexibility for management scenario testing
Extend framework for wheat blast
Surveillance (host + pathogen)
CIMMYT
Undertake near-real-time, standardized surveys and sampling in the target regions
Expand the coverage and frequency of field surveillance
Implement fully electronic field surveillance that permits near real-time data gathering
Target surveillance and diagnostic sampling to validate model predictions
Map vulnerability of the host landscape
Diagnostics
John Innes Centre
Strengthen existing diagnostic network in target regions & track changes & movement
Develop & integrate new diagnostic methodology for wheat rusts & blast
Align national diagnostic results to provide a regional & global context
Enhance national capacity for wheat rust & blast diagnostics
Information Dissemination and Visualization Tools
PlantVillage; Penn State
Create a suite of information layers and visualization products that are automatically derived from the quality-controlled data management system and delivered to end users in a timely manner
Deliver near real time for national partners to develop reliable and actionable advisory and alert information to extension workers, farmers and policy makers
National Partner Capacity Building
Cornell University
Strengthening National partner capacity on pathogen surveillance, diagnostics, modeling, data management, early warning assessment, and open science publishing
A section of key speakers at the Drylands Legumes and Cereals Network Meeting in Accra, Ghana in January 2023. (Photo: Eagle Eye Projects)
The formation of regional crop improvement networks took center stage at a meeting held in January 2023 in Accra, Ghana. The meeting convened more than 200 scientists and stakeholders in dryland crops value chains from 28 countries from Africa and across the globe to co-design a network approach.
The meeting followed a series of consultative visits and discussions between three CGIAR research centers — the International Maize and Wheat Improvement Center (CIMMYT), Alliance of Bioversity International and CIAT, and the International Institute of Tropical Agriculture (IITA) — African National Agricultural Research Institutes (NARIs), and other common-visioned partners during 2021 and 2022. These earlier discussions gathered insights, brainstormed, and co-designed approaches to empower national programs to deliver impact through their crop improvement programs.
“The idea is to add value to the existing capacities in National Agricultural Research and Extension Services, through networks where the partners agree on the goals and resources needed to achieve desired outcomes. So, it’s really a collaborative model,” said Harish Gandhi, breeding lead for dryland legumes and cereals at CIMMYT. He added that the teams have been learning from and aiming to add value to existing models such as the Pan-Africa Bean Research Alliance (PABRA), USAID Innovation Labs, and Innovation and plant breeding in West Africa (IAVAO).
Paradigm shift for African National Agricultural Research Institutes
Making the opening remarks, Ghana Council for Scientific and Industrial Research (CSIR) Director General, Paul Bosu said that at the very least, African countries should aim to feed themselves and transition from net importers to net exporters of food. “Dryland legumes and cereals, especially millet and sorghum, are very well adapted to the continent and offer great opportunity towards achieving food security”, said Bosu. He applauded the Bill & Melinda Gates Foundation and other partners for investing in research on these crops.
Representing West and Central African Council for Agricultural Research and Development (CORAF), Ousmane Ndoye noted that research in dryland legumes and cereals is a valid and needed action amidst the COVID-19 pandemic and civil unrest in different parts of the world. He added that the first and crucial step to increasing food production especially in sub-Saharan Africa is the availability of sufficient quantities of seed.
Director General of Uganda’s National Agriculture Research Organization (NARO), Ambrose Agona observed that a paradigm shift should occur for desired transformation in agriculture. He noted that African governments ought to commit adequate budgets to agriculture and that seed funding should serve to complement and amplify existing national budgets for sustainability.
He commended efforts to consult NARIs in Africa and noted that the quality of ideas exchanged at the meeting strengthen the work. “The NARIs feel happier when they are consulted from the very beginning and contribute to joint planning unlike in some cases where the NARIs in Africa are only called upon to make budgets and are excluded from co-designing projects”, said Agona.
Participants following the proceedings at the Drylands Legumes and Cereals Network Meeting in Accra, Ghana in January 2023. (Photo: Eagle Eye Projects)
Challenge to deliver effectively
During his remarks at the meeting, CIMMYT Director General Bram Govaerts noted that the focus legume and cereal crops are key to transforming and driving diversification of food systems in Africa. “It is therefore an honor and a privilege to work together with partners to improve cereal and legume systems. We will put forward our experience in breeding and commit to innovative systems approaches towards achieving impact and leverage what we are already good at, to become even better,” said Govaerts.
Referencing his visit with the United States Special Envoy for Global Food Security Cary Fowler to Southern Africa in January 2023, Govaerts narrated witnessing firsthand a food, energy and fertilizer crisis impacting Zambian and Malawian farmers. He challenged the meeting participants to envision the future impact they would like to see their breeding programs have as they design and strategize at the meeting. He pointed out that farmers are more interested in the qualities and characteristics of varieties released than the institutions responsible for the release.
CIMMYT Global Genetic Resources Director and Deputy Director General, Breeding and Genetics, Kevin Pixley also underscored the need to generate more impact through adoption of improved varieties in Africa. Pixley noted that on average, fewer than 30 percent of farmers are using improved varieties of sorghum, millet, and groundnut across the countries with ongoing work.
The meeting heard One CGIAR’s commitment to deliver resilient, nutritious and market preferred varieties as part of its Genetic Innovation Action Area, alongside improving systems and processes for sustainability from CGIAR Senior Director Plant Breeding and Pre-Breeding, John Derera. Speaking in the capacity of IITA’s Breeding Lead, Derera noted the progress made in IITA cowpea breeding program, including its modernization, owing to strong partnerships, cross learning and germplasm exchange between institutions.
PABRA Director & Leader of the Bean Programme at the Alliance of Bioversity International and CIAT, Jean-Claude Rubyogo, pointed out that despite remarkable achievements, such as those witnessed in the bean research, more effort is needed to tackle the challenges of climate change and also increase understanding of consumers traits.
Commenting on innovative pathways to improve adoption of improved varieties, the Director General of the Institute of Agricultural Research (IAR) in Zaria, Nigeria, Mohammad Ishiyaku observed the tendency for some seed companies to continue selling specific seed varieties for years, even when the productivity of the variety is low. He noted the seed companies always claimed consumer preferences concluding then that amidst investor demands, breeders ought to keenly investigate the expectations of consumers and famers to arrive at the best parameters for breeding choices.
A group photo of over 200 scientists and stakeholders in dryland crops value chains that participated at the Drylands Legumes and Cereals Network Meeting in Accra, Ghana in January 2023. (Photo: Eagle Eye Projects)
International Year of Millets, 2023
The gathering commemorated the International Year of Millets by listening to a keynote address on “Millets for food and nutritional security and mitigating climate change – #IYM2023” by Lake Chad Research Institute, Nigeria, Research Director, Zakari Turaki. The keynote was followed by statements on the importance of millets for various countries and wider Africa from: Sanogo Moussa Daouda, representing Director General of Mali’s Institut d’Économie Rurale (IER); Ibrahima Sarr, Director of Senegal’s Institut Sénégalais de Recherches Agricoles’s Centre National de Recherches Agronomiques; Hamidou Traore, Director of Burkina Faso’s Institut de L’Environnement et de Recherches Agricoles; and Ambrose Agona, Director General of NARO, Uganda.
High-level statements on approaches to gender integration in agricultural research and development were delivered by Scovia Adikini, NARO millet breeder, Geoffrey Mkamillo, Director General of Tanzania’s Agricultural Research Institute (TARI), Francis Kusi of Ghana’s Savanna Agricultural Research Institute (SARI), and Aliou Faye, Director of Senegal’s Regional Center of Excellence on Dry Cereals and Associated Crops (CERAAS).
AVISA Achievements
Finally, this meeting marked the transition from the recently ended Accelerated Varietal Improvement and Seed Systems in Africa (AVISA) project to align with One CGIAR initiatives under the Genetic Innovation Action Area, with specific focus on dryland crops.
Solomon Gyan Ansah, the Director of Crop Services at the Ministry of Food and Agriculture, Ghana, acknowledged the success of AVISA Project and commended the forum’s efforts to build on the gains made by the project in developing the new approach.
“By the end of 2022, AVISA project partners had reached 4.8 million farmers with 30,600 metric tons of seed of improved legume and cereal varieties, covering almost one million hectares of land”, revealed Chris Ojiewo, Strategic Partnerships and Seeds Systems Lead. Other achievements supported by the AVISA Project include upgrading of NARES facilities and building capacities of researchers through short- and long-term trainings.
The meeting was hosted by Ghana Council for Scientific and Industrial Research (CSIR) and Ghana’s Savannah Agricultural Research Institute (SARI), and was organized by CIMMYT, in partnership with IITA and the Alliance of Bioversity and CIAT (ABC).
Crop breeding has the potential to significantly contribute to addressingthe global challenges of poverty, malnutrition, hunger, gender inequality, environmental degradation and climate change.Rapid population growth, climate change and market crises in low-income and middle-income countries mean that crop breeding must be far more agile and professional than ever before. Data-driven, modernized breeding with tools and technologies such as genomic selection, quantitative genetics, high-throughput phenotyping and bioinformatics, are needed toaccelerate and advance improvement in varieties.
Across the CGIAR-NARES(National Agricultural Research and Extension Systems) crop breeding networks, there is huge opportunity to reach the full potential to improve the lives of farmers and consumers: to share innovations to their full potential; reduce costs associated with services such as bioinformatics; de-fragment disparate data and incompatible technologies; apply consistent standards; and improve access to tools, technologies and shared services.
This Initiative aims to improve the genetic, economic, social and environmental performance of breeding programs across the CGIAR-NARES breeding network.
This objective will be achieved through:
Undertaking strategic modernization so that breeding schemes are designed using the most up-to-date methods, namely: quantitative genetics and computer simulation, including modeling of adoption and benefits across the breeding network, and budget forecasting for management of the portfolio and operational improvements.
Delivering cost-effective shared services through coordinating services such as genotyping and data management, leading to efficiency and greater bargaining power in purchasing or contracting equipment, software and services, ultimately enabling the generation and analysis of high-quality and consistent data across the breeding network.
Implementing performance management of consistent, connected operations through a dedicated performance management team supporting breeding programs and data management teams in describing, harmonizing and adopting standard operating protocols, workflow charts and quality controls across the networks.
Making smarter use of data, enabling CGIAR-NARES networks to share standardized data, creating larger and more powerful datasets that can be readily analyzed and interpreted.
Promoting innovation and research exchange through developing and implementing change management plans, and supporting region-specific capacity building to increase global adoption of modernized breeding tools, technologies and shared services across the network.
This Initiative will work with breeding programs serving countries in Sub-Saharan Africa and South Asia, along with Asia and Latin America. High-priority countries for the Initiative include Ghana, Kenya, Nigeria, Senegal, Tanzania, Uganda, Zimbabwe and Zambia in Africa, and Bangladesh and India in South Asia.
Proposed 3-year outcomes include:
Varieties are developed 30% faster for 70% of targeted breeding programs.
Shared services reduce costs by 25% in a majority of target programs, making modernized breeding more accessible across the global CGIAR-NARES networks.
At least 70% of targeted breeding programs make data-driven decisions using genomic, phenotypic and environmental data at more than one major decision point.
At least a 70% improvement of Initiative’s targeted breeding programs in at least 50% of impact area tracking indicators as a result of CGIAR-NARES leadership.
Increased capacity in at least 15 NARES institutions, demonstrated by increased access to tools, technologies and shared services (of more than one type) more than once a year.
A least 70% of the Initiative’s targeted continuous breeding programs increase or add at least one target to their modernization plan.
Standardized protocols shared in a common system.
Harmonized operations enabling consistent data generation.
Adoption of quality management system within facilities.
Establishment of Breeding Pipeline Improvement Monitoring System to support informative performance monitoring that reduces the complexity of breeding activities to the core metrics material for decision-making, as aligned to shared goals.
Establishment of performance monitoring system to track implementation of standardized processes and quality of operations along with modernization progress and the impacts of the resulting breeding program.
To mark International Women’s Day 2023, Nele Verhulst, cropping systems agronomist at the International Maize and Wheat Improvement Center (CIMMYT), shares progress from the Women in Crop Science group and how their work tries to contribute to gender equality in agriculture and science.
Growing up in the nineties in Belgium, I was interested in feminism, but I also assumed that the fight for equal rights for women and men had been fought and won. Studying bioscience engineering in the 2000s, more than half of the students were women, so this demonstrated to me that we were all set (although the large majority of professors were men, it seemed to be just a matter of time for that to be resolved). I have now been working in Latin America as an agronomist and researcher for more than 15 years and have come to realize that there is still a lot of work to do to achieve equal opportunities for female farmers, farm advisors, scientists, and other professionals in agriculture.
At CIMMYT, between 20 and 25 percent of staff in the science career track – careers involving field, lab, data, and socioeconomic work – are female. Because of that, Alison Bentley and I started a group of women in crop science at CIMMYT about one year ago on the International Day of Women and Girls in Science in 2022. In our first meeting, we aimed to connect, discussed how to build a network (we did not even have a list of all women in science at CIMMYT, so it was hard to know who to invite), and decided whether we wanted to commit to additional actions to achieve a more inclusive environment at CIMMYT.
Since that first meeting, we have organized coffee mornings and other events, and have split into smaller working groups to draft action plans on ten topics: gender in the workplace strategy development, advancement for locally recruited staff, mentorship, recruitment processes, microaggressions, harassment policies, work-life balance, family friendly work environment, raising external awareness about women in agriculture, and ensuring internal visibility.
I have enjoyed being able to make some first small changes – who knew sanitary facilities would turn out to be a recurring topic! – but most of all I have loved the opportunities over the past year to connect with women with a shared passion for crop science in all its aspects. That passion and the opportunities it creates to improve the lives of farmers and rural communities is the most important thing we are celebrating today.
Cover photo: Women participate in a public harvest event for timely sown wheat organized by the Cereal Systems Initiative for South Asia (CSISA) project with Krishi Vigyan Kendra (KVK) in in Nagwa village near Patna in Bihar, India. (Photo: Madhulika Singh/CIMMYT)
