Senior representatives from CIMMYT visited the John Innes Centre to strengthen their strategic partnership focused on advancing global wheat research. Key collaborative efforts include the Wheat Disease Early Warning Advisory System (DEWAS) and research on genetic resistance to wheat blast. CIMMYT’s Director General, Dr. Bram Govaerts, emphasized the long-standing partnership’s global impact, noting that around 70% of the world’s wheat is linked to CIMMYT’s network. Dr. Sarah Hearne, Chief Science and Innovation Officer, highlighted the shared commitment to providing sustainable solutions that enhance farmers’ resilience and productivity worldwide.
The Zambia Agricultural Research Institute (ZARI) has undergone a significant transformation, fueled by a strategic subgrant from the Bill & Melinda Gates Foundation through the Africa Dryland Crop Improvement Network (ADCIN). Established in August 2023 and convened by CIMMYT through its Dryland Crops Program (DCP), ADCIN is a collaborative network aimed at uniting over 200 scientists from more than 17 countries across sub-Saharan Africa. Its mission is to create a dynamic and sustainable network to develop and deliver improved varieties of dryland crops in the region. By leveraging the collective expertise of its multidisciplinary members, ADCIN strives to accelerate the access of enhanced crop varieties to smallholder farmers.
This support has led to the modernization of ZARI’s research facilities, improved irrigation systems, and enhanced data management capabilities, positioning the institute as a leader in climate-smart crop research. Key advances include speed breeding and controlled drought research, which have led to higher crop yields and better adaptation to climate challenges. These improvements have not only strengthened Zambia’s agricultural research capacity but also fostered regional collaboration and knowledge sharing, benefiting farmers, scientists, and institutions across Southern Africa. The institute’s improved infrastructure, including expanded water storage and solar power, has ensured uninterrupted research, even during power outages. As a model for other NARES institutions, ZARI’s transformation highlights the critical role of strategic investment in agricultural research to address the growing challenges of climate change and food security across Africa.
We caught up with Dr. Loyd Mbulwe, the Ag. Chief Agriculture Research Officer at ZARI, to get more insight into the upgrade.
Q: What were some of the challenges ZARI faced before the upgrades?
A: ZARI faced several research-related challenges that hampered its potential for innovation. These included limited access to essential research equipment, inadequate funding for critical projects, and insufficient capacity for data management and analysis. Collaboration and knowledge sharing with regional and international partners were also limited.
In terms of infrastructure, ZARI struggled with outdated laboratory facilities, inefficient greenhouse and irrigation systems, and limited storage space for seeds and plant materials. The institution’s ICT infrastructure was inadequate to support modern agricultural research needs. Operational efficiency was hampered by manual data collection, inefficient research protocols, and inadequate standard operating procedures.
Q: How has the upgrade helped ZARI overcome these challenges, and how has it improved the quality and quantity of research coming out of ZARI?
A: Recent upgrades at ZARI have significantly improved its research capabilities. New equipment and increased funding have supported larger projects, while improved data management systems have streamlined data handling and fostered greater collaboration with regional and international partners. The addition of a modern greenhouse and upgraded irrigation systems has improved water management and allowed for more controlled experiments. Expanded seed storage capacity now ensures the secure preservation of critical plant material for future research.
Automated data collection systems have reduced errors and increased efficiency, while standardized research procedures have improved the quality and reproducibility of results. Improved research documentation and targeted staff training programs have further enhanced research skills, enabling the team to produce more impactful results.
The newly constructed greenhouse facility enhances crop breeding and genetics research, enabling efficient off-season studies. (Photo: ZARI/Zambia)
Q: How has ZARI’s research capacity improved with the upgraded facilities and new equipment?
A: ZARI has undergone significant upgrades to improve its research capacity. The new greenhouse facility has improved crop breeding and genetics research, allowing for more efficient off-season research. Speed breeding, a technique that accelerates crop generation turnover by two to five times through controlled environmental conditions, has been a game changer. The greenhouse also enables controlled drought research, providing insights into the development of climate-resilient crops. The ZAMGRO project has increased ZARI’s water storage capacity from 45 m² to 3.6 million m², enabling year-round farming and improved water management. The subgrant also enabled the installation of solar power, addressing the electricity challenges caused by recent droughts. The move to Starlink internet connectivity has also improved ZARI’s online capabilities, providing reliable, uninterrupted internet access, even in remote research sites.
An aerial view of the installed solar panels, that has resolved electricity challenges and mitigating power outages. (Photo: ZARI/Zambia)
Q: Looking ahead, what are ZARI’s future plans? Are there any further upgrades or expansions planned for the future?
A: ZARI’s future plans focus on increasing its research impact through strategic partnerships and innovation. The institute aims to establish a center of excellence for climate-smart agriculture and develop a biotechnology laboratory to advance genetic improvement and crop resilience. Expanding greenhouse and irrigation systems and improving digital infrastructure for data management are also priorities. ZARI also plans to strengthen collaborations with international research institutions and pursue public-private partnerships to transfer technology from research to practical applications. In addition, ZARI is committed to human resource development through targeted training, fellowships, and mentorship programs to nurture future researchers.
Q: What steps is ZARI taking to ensure the long-term sustainability of the upgraded facilities and research programs?
A: ZARI has implemented a comprehensive plan to ensure the long-term sustainability of its upgraded facilities and research programs. Key areas include maintenance of facilities, continuation of research programs, capacity building, partnerships, and knowledge sharing. ZARI has secured funding from partners and donors, diversified its income streams, and developed sustainable research funding models. Staff training, mentoring programs, and collaboration with international experts are key to ensuring that the research team stays abreast of new technologies. Strategic partnerships with private sector companies, joint research initiatives, and technology transfer agreements have further strengthened ZARI’s research capabilities. Regular impact assessments and collaborations with universities, research institutes, and government agencies further strengthen ZARI’s research capabilities and ensure that programs remain relevant and impactful.
An aerial view of the water storage system during installation. This has increased the capacity to support year-round farming and improved water management. (Photo: ZARI/Zambia)
Q: In what ways can this facility upgrade serve as a model or inspiration for other NARES facilities in the region? Are there any best practices that ZARI would recommend for similar projects?
A: The ZARI facility upgrade serves as a model for other NARES institutions in several significant ways. First, it highlights the importance of strategic partnerships, demonstrating how collaboration with regional and international organizations can lead to meaningful progress. Second, it emphasizes capacity building, with a focus on investing in staff training and development to improve institutional performance.
There are also several inspirational aspects to ZARI’s transformation. It demonstrates the transformative impact that research modernization can have on NARES breeding programs and shows the potential for improving agricultural research capacity. In addition, the upgrade is highly regionally relevant, addressing pressing regional challenges.
Finally, ZARI’s best practices provide valuable lessons for other institutions. The irrigation upgrade is an outstanding example, tailored to address the unique challenges posed by climate change in the region.
Unboxing the Starlink hardware: Transitioning to Starlink ensures reliable and uninterrupted internet access, even in remote research sites. (Photo: ZARI/Zambia)
Q: What was ADCIN’s role in facilitating this strategic investment, and how does it fit into the broader vision of strengthening NARES institutions across Africa?
A: ADCIN plays a key role in supporting the development and modernization of NARES institutions across Africa. Its contributions can be seen in three key areas. First, ADCIN provides technical assistance by offering expertise in research infrastructure development. Second, it provides financial support by mobilizing the resources needed to upgrade facilities. Third, ADCIN provides strategic guidance, ensuring that investments are aligned with regional research priorities and agendas.
This support fits into the broader vision of strengthening NARES institutions across the continent. ADCIN’s efforts focus on improving research capacity through upgrading facilities and equipment, fostering collaboration by promoting regional and international partnerships, and improving research quality through stronger research management and governance. As a result of ADCIN’s support, NARES institutions such as ZARI have seen significant improvements. Research output and impact have increased, regional collaboration has been strengthened, and institutions now have better access to international funding. By supporting ZARI’s strategic investments, ADCIN reaffirms its commitment to strengthening NARES institutions and promoting excellence in agricultural research across Africa.
Science without policy is just academia; policy without science is just guesswork. Through a blend of robust field research and policy advocacy, CIMMYT aims to bridge the gap between policy and practice in promoting sustainable agricultural practices through crop diversification in South Asia.
Taking Bangladesh as an example, CIMMYT’s work in the country highlights the critical need to link research with policy to achieve sustainable agricultural practices, enhance food security, and improve farmer livelihoods.
The power of research-informed policy
Bangladesh’s agriculture is highly rice-centric; although rational, this is risky and arguably unsustainable. This means there needs to be a focus on crop diversification, which is one of the approaches toward sustainable agriculture that can address socioeconomic and environmental challenges.
Recognizing these challenges, CIMMYT has been at the forefront of developing solutions by conducting extensive multi-location on-site and on-farm trials that consider the socioeconomic and pedoclimatic dimensions of farm households.
Additionally, CIMMYT analyzes historical policies and initiatives that have been implemented by the Bangladeshi government and international partners to promote crop diversification. Several opportunities for improvement were identified in past policies and project implementation; addressing these challenges requires bridging the gap between policies and research to scale up crop diversification efforts.
Through the RUPANTAR and CGIAR Transforming Agrifood Systems in South Asia (TAFSSA) projects, CIMMYT-Bangladesh has developed an analytical tool to understand the political economy of crop diversification policies and practices. When applied to agriculture policy research, this tool can be tailored to any country and policy context in South Asia.
For example, while the government recognizes crop diversification in its agriculture policies starting with the Fifth Five-Year Plan, substantial funding for crop diversification efforts was only recently allocated. Integration of crop diversification into the government’s annual funding systems is essential to mainstream crop diversification in agriculture.
Many crop diversification policies and projects primarily focus on production, neglecting market systems development for new crops. Similarly, research suggests insufficient attention is paid to cold storage and other infrastructure needed to support diversification.
Most initiatives appear to have been project-driven, resulting in short-lived action without long-lasting impact. Insufficient coordination and support from government agencies appears to have affected projects led by both governments and development partners.
Stakeholder engagement spreads awareness
Without translating research into policy, we leave innovation on the shelf. CIMMYT-Bangladesh disseminates research findings to policymakers through the country Priority Investment Plan for the crop sector at the Bangladesh Agricultural Research Council (BARC), and South Asian Association for Regional Cooperation (SAARC) member countries through regional consultation workshops on accelerating the transformation process for sustainable and nutrition-sensitive food systems.
Looking ahead, CIMMYT’s efforts in South Asia remain dedicated to bridging the gap between research and policy. Ongoing projects aim to generate robust evidence, advocate for informed policy decisions, and foster partnerships across sectors. By continuing to lead in this space, CIMMYT strives to contribute to a more resilient agrifood system for South Asia.
Distinguished Scientist and Head of Wheat Physiology at CIMMYT, Matthew Reynolds, received the Research.com Plant Science and Agronomy in Mexico Leader Award 2024 for placing 53rd in the world and 1st in Mexico in the Research.com ranking of Best Plant Science and Agronomy Scientists 2023.
“Being recognized with this award highlights the far-reaching influence of the wheat science taking place in Mexico and its impact on the development of agronomy around the world,” said Reynolds. “Sharing outputs as international public goods with scientists globally has positive benefits for smallholder farmers and their communities. Widening genetic diversity for key traits helps to improve yield and climate resilience -including resistance to biotic and abiotic stresses, providing reliable harvests and food security.”
Specializing in technologies to increase the productivity of wheat cropping systems around the world, Reynolds has helped to create a new generation of advanced lines at CIMMYT through physiological breeding approaches that widen the genepool, increasing understanding of yield potential and adapting wheat to drought and heat, developing high throughput phenotyping methodologies, and training other researchers.
Reynolds developed and led the Heat and Drought Wheat Improvement Consortium (https://hedwic.org/) and initiated a global academic network that led to the International Wheat Yield Partnership (https://iwyp.org/), where he champions collaboration that brings together plant science expertise from around the globe to boost yield and climate resilience.
Other CIMMYT scientists in the top 100 world rankings include Distinguished Scientist and former Head of Global Bread Wheat Improvement Ravi P. Singh in 57th place globally and 2nd in Mexico, and Distinguished Scientist in the Biometrics and Statistics Unit, José Crossa, who ranked 59th globally and 3rd in Mexico.
This is the third edition of Research.com positioning scholars based on their research output in plant science and agronomy. Rankings are allocated based on a detailed study of 166,880 scientists in bibliometric data sources, with up to 10,700 people analyzed for this field of work.
SAS Program Director Sieg Snapp and GESI researchers gather in New Delhi from across CIMMYT – Asia, Africa, and Latin America. (Photo: Adeeth Cariappa/CIMMYT)
“As we look towards 2030, CIMMYT is focused on building inclusive value chains, advancing mechanization, and confronting seed system challenges. We are championing demand-driven technologies and improved agricultural needs,” said Sieglinde Snapp, program director of CIMMYT’s Sustainable Agrifood Systems (SAS) program, highlighting during the discussions the importance of integrating gender perspectives in research. “We are committed to integrating gender perspectives in all these initiatives, recognizing the vital role of women in agriculture and ensuring equitable access to resources and opportunities for all genders,” she added.
Farah Deba Keya presents her study analyzing constraints for women farmers’ active participation in mixed farming systems in Bangladesh. (Photo: CIMMYT)
The one-day meeting on October 13, 2023, in New Delhi, India, hosted under CIMMYT’s SAS program, brought together diverse groups of participants—totaling over ten senior gender researchers working in Africa, Asia, and Latin America, namely Sieg Snapp, Vijesh Krishna, Moti Jaleta, Michael Euler, Angela Meentzen, Monica Fisher—along with a cadre of junior and senior researchers and students collaborating with CIMMYT on gender research. The coming together of these GESI researchers provided a valuable opportunity for collaboration, sharing insights, and strategizing enhanced gender and socially inclusive research-for-development approaches within CIMMYT’s programs.
Monica Fisher, a senior researcher working in Africa, emphasized CIMMYT’s dedication to making gender equality and social inclusion more visible and relevant in agriculture globally. She said, “The significance of GESI research, particularly in bridging the gap between the Global South and the Global North, cannot be overstated. Our objective is to deepen our engagement in these areas.”
The day-long meeting covered various topics, including the dynamics of technology adoption, gender roles in agriculture, and the feminization of Indian agriculture. Discussions underscored the need for increased financial support for GESI research, the importance of addressing disparities in research focus, and the crucial role of intersectionality in agricultural contexts.
A notable segment of the meeting was dedicated to presentations by students on their ongoing research in gender-related topics. These young researchers brought fresh perspectives and innovative ideas, highlighting the evolving nature of gender roles in agriculture and the impact of technology on gender dynamics in various regions. Their contributions underscored the importance of fostering a new generation of researchers committed to gender equity and social inclusion in agricultural development. Hari Krishnan K. S., a student working with CIMMYT opined, “My study, supervised by CIMMYT’s gender researchers, revealed that the concept of masculinities transcends gender, focusing instead on effective farming practices. It highlighted the diverse influences on agricultural decision-making and the varied reactions to technology adoption in Punjab’s agriculture. This reflects the critical role of CIMMYT’s gender-focused research in shaping my approach and understanding as a student in this field.”
Contributing his perspective, Vijesh Krishna, lead researcher working in India, highlighted the need for innovation in research approach. According to him, “To revolutionize GESI research, a shift towards longitudinal data analysis and cross-country data utilization is needed. Building evidence and documenting changes in gender dynamics due to policy and social transformations are essential.” He further encouraged the fostering of in-house capacities to mainstream gender considerations across disciplines, enhancing collaboration, and developing skills for the effective communication of research findings to stakeholders.
Snapp believes that the meeting was not just a gathering of minds but a milestone in CIMMYT’s ongoing journey towards agrifood systems development. “It reaffirms the organization’s commitment to impactful research that acknowledges and addresses the nuances of gender and social dynamics in agriculture, paving the way for a more inclusive and sustainable future in the sector.”
Sieglinde Snapp explains initiatives to support urgent and relevant GESI research and efforts within CIMMYT’s programs (Photo: CIMMYT)
As the meeting concluded, Snapp spoke of the resolve to make GESI efforts urgent and relevant. She proposed three initiatives: firstly, renaming the SAS gender team the “Paula Kantor Gender and Development Centre” to reflect a broader scope and purpose; secondly, establishing a mentorship program to offer career guidance, networking opportunities, and professional development support; and finally, the introduction of a prestigious “Research Excellence in the Field” award in Paula Kantor’s honor.
“These initiatives aim to enhance the impact and recognition of the organization’s gender-focused efforts, promote professional growth, and honor excellence in the field, embodying CIMMYT’s commitment to gender-focused efforts,” she explained.
On January 10, 2024, Vijesh V. Krishna, Principal Scientist / Lead Economist of CIMMYT visited the Foundation for Agrarian Studies in Bengaluru, sparking collaborative discussions on future research. This meeting, enhanced by online participation, laid the groundwork for potential joint research efforts in the future.
Like other crops, wheat – which makes up 20 percent of the human diet – is affected by threats to the global food system from persistent population growth and economic and climate pressures. These challenges are further exacerbated by the fallout from the COVID-19 pandemic and the war in Ukraine. There is an urgent need to prioritize climate resilient wheat varieties to protect this food staple.
Some five years after HeDWIC was launched in 2014 to incorporate the most advanced research technologies into improving heat and drought tolerance of wheat, the Intergovernmental Panel on Climate Change reported that climate change was having an impact on food security through increasing temperatures, changing precipitation patterns and greater frequency of extreme weather events in its Special Report on Climate Change and Land.
“While some areas are becoming more conducive to wheat growing, crop yields are suffering in other regions around the world traditionally known as bread baskets,” said wheat physiologist Matthew Reynolds, who leads HeDWIC at the International Maize and Wheat Improvement Center (CIMMYT).
“Wheat is one of our fundamental crops, and we must spare no effort in protecting it from current and future challenges,” said Saharah Moon Chapotin, FFAR executive director. “Global collaborations are necessary to address global concerns, and these grants are bringing together international teams to share and build the science and research that will ensure the stability of this crop.”
To boost new ideas in “climate-proofing” crops, HeDWIC conducts virtual meetings that include all awarded research teams to take advantage of the collective global expertise in heat and drought resilience, leading to cross-pollination of ideas and further leverage of resources and capabilities.
In March, Reynolds led in-person discussions with some of the collaborating researchers at CIMMYT’s experimental research station on the outskirts of Ciudad Obregon, a city in Mexico’s Sonoran Desert, during CIMMYT’s annual Visitors’ Week.
Projects awarded in 2022
Exploring the potential of chlorophyll fluorescence for the early detection of drought and heat stress in wheat (FluoSense4Wheat)
“The HeDWIC mini proposal allows us to explore the potential of chlorophyll fluorescence for the early detection of drought and heat stress in wheat. The controlled irrigation conditions for wheat grown in Obregon give us the opportunity to quantify photosynthesis by fluorescence while drought develops. Detecting a drought-specific fluorescence response and/or the interaction between active and passive fluorescence is relevant for breeding selecting purposes as well as large spatial scale detection of drought by monitoring the plant.” – Onno Muller, Forschungszentrum Jülich, Institute of Bio- and Geosciences, Germany
Physiological basis of amelioration of heat stress through nitrogen management in wheat
“Heat stress during grain filling can restrict the availability of carbohydrates needed for grain development. India has been experiencing sudden spikes in both minimum and maximum temperatures by 3 to 5 degrees above normal from late-February onwards, which is an important time for wheat grain-filling and has resulted in declining wheat productivity. Our team is examining the ability of pre-flowering nitrogen applications to support biomass accumulation and overcome the grain-filling source (carbohydrate) limitation during heat spikes. If successful, the results could have broad-reaching benefits given that farmers are familiar with and well-skilled in using nitrogen applications regimes in crop management.” – Renu Pandey, Division of Plant Physiology, Indian Agricultural Research Institute
Can reproductive development be protected from heat stress by the trehalose 6-phosphate pathway?
“The HeDWIC funding provides a unique opportunity to test how the regulatory sugar, trehalose 6-phosphate (T6P) can protect wheat yields against increasingly common chronic and acute heat stress events. We have already shown that T6P spray increases wheat yields significantly in field conditions under a range of rainfall in wet and dry years. With increasing likelihood of heat stress events in the years ahead, in unique facilities at CIMMYT, we will test the potential of T6P to protect reproductive development from catastrophic yield loss due to chronic and acute heat.” – Matthew Paul, Rothamsted Research, UK
Investigating tolerance of heat resilient wheat germplasm to drought
“Over the last decade, we have developed heat tolerant wheat germplasm at the University of Sydney that maintains yield under terminal heat stress. In our new HeDWIC project, this material will be tested under combined drought and heat stress under field conditions. This will provide plant breeders with highly valuable information on field tested germplasm for use in accelerated breeding programs targeting combined heat and drought tolerance. The work is critical for future food security considering the inextricable link between temperature and plant water demand, and the increased frequency and intensity of heat and drought events under projected climate change.” – William Salter, University of Sydney, Australia
Novel wheat architecture alleles to optimize biomass under drought
“Wheat Rht-1 dwarfing genes were an essential component that led to spectacular increases in grain yields during the Green Revolution. Although Rht1 and Rht2 are still used widely in wheat breeding 50 years after they were introduced, they are suboptimal under drought conditions and are often associated with a yield penalty. Using a more extensive range of Rht-1 dwarfing alleles that were developed at Rothamsted, we will introduce them into CIMMYT germplasm to optimize biomass and ultimately increase grain yields under drought stress.” – Steve Thomas, Rothamsted Research, UK
Additional comments from 2021 awardees
“This opportunity has enabled the collection of significant amounts of data that will contribute to the advancement of knowledge in crop physiology and root biology. It has also provided early career researchers with opportunities to gain hands-on experience, develop important skills, and grow their networks. Additionally, this initiative has stimulated further ideas and collaborations among researchers, fostering a culture of innovation and cooperation that is essential for progress.” – Hannah Schneider, Wageningen University & Research, Netherlands
“The project is a unique opportunity for research groups from around the world to coordinate efforts on identifying ways to improve heat tolerance of wheat.” – Owen Atkin, Australian National University, Australia
“It is important to understand how high temperature limits crop growth and yield and to identify genetic variation that can be used for breeding climate resilient crops. This project has already begun to develop new methods for rapidly screening growth and physiological processes in genetically diverse panels which we hope will be invaluable to researchers and breeders.” – Erik Murchie, University of Nottingham, UK
“This project will provide novel phenotyping screens and germplasm to breeders and lay the groundwork for genetic analysis and marker development.” – John Foulkes, University of Nottingham, UK
The International Maize and Wheat Improvement Center (CIMMYT) is an international organization focused on non-profit agricultural research and training that empowers farmers through science and innovation to nourish the world in the midst of a climate crisis. Applying high-quality science and strong partnerships, CIMMYT works to achieve a world with healthier and more prosperous people, free from global food crises and with more resilient agri-food systems. CIMMYT’s research brings enhanced productivity and better profits to farmers, mitigates the effects of the climate crisis, and reduces the environmental impact of agriculture.
CIMMYT is a member of CGIAR, a global research partnership for a food secure future dedicated to reducing poverty, enhancing food and nutrition security, and improving natural resources.
Research for development organizations generate a wealth of knowledge. However, due to time and resource restraints, this knowledge has not been systematically analyzed, and the dynamics of how research is shared online have not been fully understood.
Today, technical advances in text mining, network analysis and hyperlink analysis have made it possible to capture conversations around research outcomes mentioned almost anywhere on the web. New digital research methodologies have emerged offering comprehensive approaches to leverage data across the web and to synthesize it in ways that would be impossible to carry out using traditional approaches.
In a study published in Nature Scientific Reports, scientists from the International Maize and Wheat Improvement Center (CIMMYT) teamed up with researchers from the University of Coimbra and University of Molise to investigate how CIMMYT research in climate change and climate sensitive agriculture is developing and the extent to which the center is exchanging knowledge with communities around the world.
Using text mining, social network analysis and hyperlink analysis to uncover trends, narratives and relationships in digital spaces such as research databases, institutional repositories, and Twitter, the team found that CIMMYT has steadily increased its focus on climate change research and is effectively sharing this knowledge around the world. The authors also found that CIMMYT’s climate research was centered on three main countries: Mexico, India, and Ethiopia.
The novel analytical framework developed by the team will help scientists track where their research is being shared and discussed on the web, from traditional scientific journal databases to social media.
“The web analytics framework proposed in this paper could be a useful tool for many research for development organizations to assess the extent of their knowledge production, dissemination, and influence from an integrated perspective that maps both the scientific landscape and public engagement,” said Bia Carneiro, first author of the paper.
The results of the study showed that sharing of CIMMYT’s climate science research was strongest on academic and research platforms but was also reflected in social media and government and international organization websites from across the Global North and South.
The findings from the study are important for the decolonization of science and the democratization of scientific debate. They show that CIMMYT is decolonizing climate science by sharing, creating, and co-creating knowledge with communities across the globe, particularly in Latin America, South Asia and Africa. On Twitter, the team noted that almost all countries were mentioned in CIMMYT’s Twitter conversations.
The study also shows that CIMMYT is bringing climate science and climate-sensitive agriculture into public debate, particularly through social media platforms, though they note there is potential to share more knowledge through these channels.
According to CIMMYT Agricultural Systems and Climate Change Scientist and coordinator of the study, Tek Sapkota, these types of analyses help research for development organizations to understand how people around the world view their expertise on subject matter, identify their comparative advantage and develop the value proposition of their work going forward.
Cover photo: Twitter mentions network for the International Maize and Wheat Improvement Center official account (@CIMMYT). (Credit: Nature Scientific Reports)
To test solutions that could mitigate the impacts of drought, the study used randomized control trials to test the impact of combining drought-resistant seeds and index insurance in Mozambique and Tanzania.
Results show that combining these two technologies expands their benefits: using the improved seeds reduces insurance costs, and having insurance to begin with counteracts the risk of adopting the seeds. Farmers who use both technologies have greater resilience to drought in the short- and long-term.
Demonstrating the benefits to farmers and informing the scaling-up of the solution-bundling approach was also found to be important.
Over the next 10 years, maize is due to become the most widely grown and traded crop globally and is already the cereal with the highest production volume. Its versatility offers multiple purposes – as a livestock feed in both developed and developing economies, as a key component of human diets in several low- and middle-income countries in sub-Saharan Africa, Latin America and Asia, and for an array of non-food uses worldwide.
The study primarily focused on the Global South, where intensive work is being done to transform the agrifood systems in which maize plays a key role. Through scientific advancements over time, maize yields have increased, although heterogeneously, while the area under cultivation of maize has also expanded due to sharply growing demand.
Research determined that this transformation offers opportunities for investment in maize research and development (R&D) to determine ways that production and productivity can be significantly improved without expanding maize area or creating negative impacts on the environment.
Ten years ago, a foundation was laid on the principles of Norman Borlaug to translate agrarian challenges into opportunities through collaboration between the International Maize and Wheat Improvement Centre (CIMMYT) and the Indian Council of Agricultural Research (ICAR). This major step toward sustainable food and nutrition security was taken through the establishment of the Borlaug Institute for South Asia (BISA) as an independent, non-profit research organization.
Today, BISA is a global name in agriculture research with a vision to promote food security, nutrition, stable livelihoods, and eco-friendly practices in South Asia. Given the prominent challenges of climate change in these economically fragile agroecosystems, the partnership between BISA, ICAR, and CIMMYT plays a pivotal role in developing improved wheat and maize varieties with climate-smart and conservation agriculture-based practices.
A decade of impact
One of the most significant outcomes of BISA’s work has been its contribution to building a vast, solid network for evaluating and disseminating new high-yielding and climate-resilient wheat varieties for India and other South Asian countries in close partnership with ICAR and CIMMYT. BISA’s transformative solutions and science-led research are critical to targeting stressed resources and attaining global food security.
With support from ICAR and CIMMYT, BISA has developed state-of-the-art research facilities at its three strategically selected research stations, having 1,200 acres of land that the Government of India, jointly with the respective state governments, generously granted to the project. Located in three disparate agro-climatic and socioeconomic environments, these sites are model research farms supporting agriculture research in South Asia. The learning labs at BISA emphasize that scaling climate-smart villages also strengthen climate-resilient agriculture, primarily through addressing challenges such as residue burning. BISA’s collaborative and inclusive approach is more relevant today when the world is grappling with various food and nutrition insecurity challenges.
Time for expansion
BISA envisages attracting countries from south Asia, the Bay of Bengal Initiative for Multi-Sectoral Technical and Economic Cooperation (BIMSTEC) and the South Asian Association for Regional Cooperation (SAARC), as well as National Agricultural Research Systems (NARS), national research institutes, private sector companies, and civil society organizations as active partners for expanding reach in the region. To this end, BISA has completed extensive work in Nepal and Bangladesh and has extended its services to Bhutan and Sri Lanka.
Still, more needs to be done in South Asian countries. Therefore, there is an urgent need for a strong commitment to harnessing the best of international scientific discoveries with local efforts. Collective action is to be garnered to provide trusted and effective mechanisms for developing and sharing cutting-edge agricultural technologies in the South Asian region.
Himanshu Pathak, Director General of ICAR, with Bram Govaerts, Director General of CIMMYT, discuss how BISA’s work can create food security in South Asia. (Photo: BISA)
To this end, a BISA High-Level Meeting was organized on September 1 and 2 in Delhi, with senior government representatives from the NARS in Bhutan, Sri Lanka, Pakistan, Nepal, Bangladesh, and India. The meeting provided a forum to identify opportunities to co-create and deploy innovative, multidisciplinary solutions to effectively address the transboundary challenges related to food, nutrition, and environmental security faced by farming communities in South Asia. This platform strives to unite the scientific community and thought leaders to support research and development across the agriculture domain.
Delegates from these countries felt that there is a need for a robust program of germplasm exchange within the region, which is essential to strengthening agriculture’s resilience. All countries expressed a significant need to raise their capacity of young researchers in advanced research techniques related to genomics, phenotyping, climate-smart agriculture, precision agriculture, and digital technologies. Delegates also discussed BISA’s role as a research and innovation regional catalyst, innovation hub, and integrated research platform to build resilient agrifood systems and achieve long-term sustainability and resilience for food security in South Asia.
BISA’s farm-ready research, from setting up climate-resilient villages and developing viable alternatives to rice residue burning to facilitating an open exchange of elite germplasm and cutting-edge technologies, reflects not only the vision of CIMMYT but also the philosophy of our mutual inspiration, Borlaug, who believed strongly in sharing knowledge and “taking it to the farmer”.
Cover photo: Delegates from Bhutan, Sri Lanka, Nepal, Pakistan, Bangladesh, and India meet to deliberate on the significant issues in South Asia’s agriculture sector. (Photo: BISA)
The existing model of funding for agricultural research and development (R&D) is not equipped for the challenges it needs to meet, according to an opinion piece for MarketWatch, penned by Bram Govaerts, Director General of the International Maize and Wheat Improvement Center (CIMMYT) and Elizabeth Cousens, President and Chief Executive Officer of the United Nations Foundation.
To tackle climate change, address hunger and malnutrition, and revive rural livelihoods, Cousens and Govaerts call for increased and more balanced investment in R&D for agri-food systems, using a participatory model to take advantage of knowledge sharing.
Co-designed projects, such as MasAgro, which involve local communities and value chain actors, can be vital in bridging the R&D gap.
“In Afghanistan, wheat is synonymous with food,” says Rajiv K. Sharma, formerly a senior scientist at the International Maize and Wheat Improvement Center (CIMMYT). Standing at about 250kg per year, the country’s per capita consumption of the crop is among the highest in the world. However, Afghanistan does not have a robust wheat research and development system. The majority of wheat varieties have been introduced from outside the country and the national wheat seed replacement rate is one of the lowest in the world at around 5%.
In a bid to strengthen research and development and boost crop productivity in the country, CIMMYT scientists have collaborated with Michigan State University and USAID to design a new, illustrated manual for wheat researchers, intended to aid them during experiments and facilitate smooth and timely data collection. As applied wheat research requires the monitoring and measurement of both qualitative and quantitative traits by different researchers across multiple locations, consistency of approach is crucial.
As well as providing descriptions of characteristics like glaucousness (the presence or absence of leaf waxes) and advice on measuring leaf area, the manual provides several different scales for determining the extent to which a wheat plant is affected by frost damage, cereal rusts or foliar diseases like Septoria and powdery mildew. Covering everything from leaf angle to chlorophyll content, this resource ensures that scientists throughout Afghanistan are supported to follow the same observation and measurement protocols while recording trial data, ensuring a standardized approach, thus bolstering the country’s wheat research sector and ensuring the data is also aligned to international projects.
The manual has since been distributed to National Agricultural Research System (NARS) researchers and other stakeholders across the country, accompanied by a number of CIMMYT-led trainings on how best to use the resource.
Published in Nature Scientific Reports, a new study describes an innovative method to assess the reach and impacts of knowledge and partnerships created as part of the work of research-for-development organizations.
It uses text mining and the analysis of social networks and hyperlinks to draw inferences from publicly available digital sources, including institutional repositories, scientific databases, and social media.
“The method can uncover narratives, dynamics, and relationships that are hidden from traditional bibliometric analyses,” said Tek Sapkota, a cropping systems and climate change specialist at the International Maize and Wheat improvement Center (CIMMYT) and co-author or the study, which also involved the University of Coimbra, Portugal, and the University of Molise, Italy.
“Nearly 90 percent of CIMMYT’s research is related to climate change and its impact on food systems and vice-versa, so we assessed that to illustrate our new, web-based analytical framework. This novel approach can help research-for-development organizations to leverage online data and measure their impact.”
Cover photo: Twitter mentions network for the International Maize and Wheat Improvement Center official account (@CIMMYT). (Credit: Nature Scientific Reports)
Alison Bentley presents at a joint seminar between CIMMYT and WorldFish. (Photo: Sarah McLaughlin/CIMMYT)
“Now more than ever, we need to build greater resilience across our global food system,” said Alison Bentley, Director of Global Wheat Program at the International Maize and Wheat Improvement Center (CIMMYT), to introduce her part of a joint seminar between CIMMYT and WorldFish. The two CGIAR research centers may appear to have different focuses, but the pairing draws attention to many opportunities for intra-CGIAR collaboration to address the looming global food crisis.
Beginning with Ahmed Nasr-Allah, Country Director (Egypt) at WorldFish, the presentation explored Integrated Agriculture and Aquaculture (IAA) systems for food security. Over the coming decades, population growth and increased scarcity of water pose a challenge for food production and agriculture, so water efficiency needs to be maximized.
Nasr-Allah explained that wheat nutrients improve soil quality, which in turn positively impacts fish quality when using water running off growing crops. He gave an example of a farmer who allocated more space on his farm to irrigate and store water and fish, which enabled him to produce higher crop yields. Further research between WorldFish and CIMMYT in this area could be examining nutrient flow from the fish system to the crop system.
Second to present was Bentley, looking at shock-proofing wheat to build future resilience. “It’s important we understand where the risks lie in our global system so we can respond to shocks,” she explained, citing data on global import dependency on Ukrainian and Russian wheat. She went on to describe potential solutions to combat the predicted yield decrease in wheat in the Global South, including substituting a proportion of wheat flour with other under-utilized crops in products, without impacting flour quality or consumer evaluation.
Linking to WorldFish’s work, Bentley highlighted the need to use water more effectively by combining new varieties with enhanced mechanization options to improve crop management, and the potential of optimizing individual components in fish and wheat rotations that could then be combined for greater impact.
The third session was with WorldFish Scientist Sarah Freed, who discussed designing integrated production practices to meet diverse needs. She invited event attendees to consider whether the lessons learnt from challenges in rice growing areas, such as climate change, poverty, food and nutrition insecurity, and increased demand, could be applicable solutions to problems in wheat growing areas.
Using biophysical and sociocultural insights from rice-fish innovations as an example, she listed five recommendations for design: identify objectives; identify a range of production options; use a co-design process; implement fit-for-purpose design and evaluation; and enable adaptation. Of particular interest was the co-design process with people who are involved at all levels, from landowners to rice farmers to laborers, so that the design benefits a variety of stakeholders. Freed also noted that decisions taken for economic reasons, such as extending the shrimp season, can lead to increased soil salinity, which means the ground can no longer incorporate diverse crops.
All three speakers concluded the event by acknowledging the potential in combining their research areas to determine and implement food security solutions.
