Despite the development of improved wheat varieties with increased productivity, farming systems in the Global South are still marred by inequitable access based on gender and other social characteristics.
Focusing on Ethiopia and India due to their large wheat economies and challenges with inequality, researchers assessed the barriers preventing male and female smallholders from using modern wheat varieties. Issues covered through evaluation could include wheat varietal trait preferences, adoption of technology, and decision-making and labor-use changes associated with new varieties.
Concluding the paper is the argument that institutional arrangements in research and development (R&D) programs must transform to address gender equity and inclusivity in wheat improvement.
Cover photo: Rural farmers associated with JEEViKa-Bihar attend a public wheat harvest activity organized by the Cereal Systems in South Asia (CSISA) project in Nagwa village, India, to encourage conservation agriculture practices in the region. (Photo: Nima Chodon/CIMMYT)
A wheat field of Bamyan, Afghanistan. (Photo: Nigel Poole/SOAS University of London)
The UN High Commissioner Michelle Bachelet recently said of Afghanistan, “In the wake of years of conflict, and since the takeover by the Taliban in August last year, the country has been plunged into a deep economic, social, humanitarian and human rights crisis” (UN News 2022a). International humanitarian agencies and NGOs have persisted in supporting the population, half of whom are suffering food insecurity, and some of whom are facing unprecedented and catastrophic levels of hunger (UN News 2022b). The conflict in Ukraine is exacerbating the crises in poor import-dependent countries and humanitarian programmes, and Afghanistan will be among the most affected (Bentley and Donovan 2022).
The rural sector underlies Afghanistanâs economic potential, with agriculture as the foundation of the economy. Wheat, both irrigated and rainfed, is the principal agricultural crop, and bread is the major component of the Afghan diet. For decades the country has relied for food security on neighbors such as Kazakhstan and Pakistan and import dependence appears to be a permanent feature of the agricultural economy (Sharma and Nang 2018).
In a recent paper published in Plants, People, Planet, CIMMYT scientists and partners from SOAS University of London, Afghanistan Research and Evaluation Unit, FAO-Afghanistan, The HALO Trust, Afghanaid and the Agricultural Research Institute of Afghanistan call for renewed investment in Afghanistanâs wheat and agricultural sector.
Bread and spread in Bamyan, Afghanistan. (Photo: Nigel Poole/SOAS University of London)
Improved CIMMYT wheat germplasm has supported agricultural development
CIMMYTâs activities in Afghanistan have focused primarily on supporting the national agricultural research system through the provision of elite, widely adapted germplasm with strong disease resistance. Recent estimates of genetic gains over 14 years (2002-2003 to 2015-2016) of testing of CIMMYTâs Elite Spring Wheat Yield Trial material across 11 locations in Afghanistan documents significant grain yield progress of 115 kg/year. Average yields across 11 testing locations ranged from 3.58 to 5.97 t/ha (Sharma et al., 2021). This indicates that yield potential can be increased through introduction and testing of internationally improved germplasm.
But such investment in research has come to a halt. Local public- and private-sector wheat breeding activities have been largely absent in Afghanistan for over a decade. Hence, wheat productivity remains low due to the limited availability of improved varieties, inadequate quality seed production and distribution. Although in the short term, humanitarian interventions are likely to be the major determinant of food security, we propose that strategic rebuilding of the wheat system will lay the foundation for restoring Afghanistanâs agricultural production, food supplies, nutrition and health. Here we signal opportunities for future improvement.
Opportunities to build climate resilience and enhance seed systems
The need for climate-resilient varieties that meet farmersâ varied requirements and consumer preferences is paramount. Afghan farmers need varieties with improved traits such as heat and drought resilience, incorporating functional variation from existing landrace collections. In addition, agronomic interventions such as conservation agriculture will offer substantial benefits in buffering environmental stresses.
The technological pathways for seed (re-)distribution are a critical part of the innovation pathway from plant breeding to production and productivity. Given the particularities of markets in Afghanistan, both the public sector and the private sector often fail to reach farming geographies that are remote, diverse, and unserved by physical and institutional infrastructure. For many years, basic public services and agricultural interventions have been provided by the NGO sector, and this form of delivery continues. Hence, local âinformalâ systems for seed and inputs are important to smallholder farmers.
Investment to support both irrigated and rain-fed wheat production
Rehabilitation of ancient irrigation practices and infrastructure could once again serve local farming in a way that supports stable production, restores Afghan heritage, and rebuilds social cohesion. However, there are no easy solutions to the challenges of increasing irrigation to boost agriculture. Although yields are lower, there is potential to optimize breeding specifically for rain-fed production. We expect rain-fed agriculture to continue given the limitations of water and infrastructure access.
Wheat improvement must be embedded in the wider agricultural environment. There is a renewed need for a deep understanding of social, political, and cultural systems and how they vary between villages, and from districts, provinces, and regions to people groups. We need to re-envision the roles of men and women in agriculture, and investment in skills and capacity building to provide a stable foundation for the eradication of poverty and food insecurity.
A new wheat program for Afghanistan
We highlight the urgent need for:
Resumption of breeding of nutritious and climate-resilient varieties.
Development of a knowledge base on current wheat production systems, gendered agricultural roles, farmer needs for varietal change and consumer preferences for tasty and nutritious wheat-based products.
Development of seed information systems using new technologies to enhance farmer engagement in research.
Expansion of appropriate irrigation systems and development of nature-based solutions to protect soil and to preserve and conserve water.
Investment in capacity building among private, non-governmental, university and public stakeholders in seed systems and delivery of agricultural services.
These foundations will support the wider regeneration of Afghanistanâs agricultural sector and enhance food security, nutrition and health of some of the worldâs most vulnerable populations.
Full paper
Poole, N., Sharma, R., Nemat, O.A., Trenchard, R., Scanlon, A., Davy, C., Ataei, N., Donovan, J. and Bentley, A.R. (in production). Sowing the wheat seeds of Afghanistan’s future. Plants, People, Planet DOI: https://doi.org/10.1002/ppp3.10277
References
Bentley, A. and Donovan, J. (2022). What price wheat? Crisis in Ukraine underscores the need for long-term solutions for global food security. Retrieved 16 June 2022, from https://staging.cimmyt.org/blogs/what-price-wheat/.
Sharma, R.K. and Nang, M. (2018). Afghanistan wheat seed scenario: Status and imperatives. International Journal of Agricultural Policy and Research6(5): 71-75 DOI: https://doi.org/10.15739/IJAPR.18.008
A generalized wiring diagram for wheat, as proposed by the authors. The diagram depicts the traits most commonly associated with the source (left) and sink (right) strengths and others that impact both the sink and source, largely dependent on growth stage (middle). TGW, thousand grain weight.
As crop yields are pushed closer to biophysical limits, achieving yield gains becomes increasingly challenging. Traditionally, scientists have worked on the premise that crop yield is a function of photosynthesis (source), the investment of assimilates into reproductive organs (sinks) and the underlying processes that enable and connect the expression of both. Although the original source-and-sink model remains valid, it must embrace more complexity, as scientific understanding improves.
A group of international researchers are proposing a new wiring diagram to show the interrelationships of the physiological traits that impact wheat yield potential, published on Nature Food. By illustrating these linkages, it shows connections among traits that may not have been apparent, which could serve as a decision support tool for crop scientists. The wiring diagram can inform new research hypotheses and breeding decisions, as well as research investment areas.
The diagram can also serve as a platform onto which new empirical data are routinely mapped and new concepts added, thereby creating an ever-richer common point of reference for refining models in the future.
âIf routinely updated, the wiring diagram could lead to a paradigm change in the way we approach breeding for yield and targeting translational research,â said Matthew Reynolds, Distinguished Scientist and Head of Wheat Physiology at the International Maize and Wheat Improvement Center (CIMMYT) and lead author of the study. âWhile focused on yield potential, the tool can be readily adapted to address climate resilience in a range of crops besides wheat.â
Breeding milestone
The new wiring diagram represents a milestone in deterministic plant breeding. It dovetails simpler models with crop simulation models.
This diagram can be used to illustrate the relative importance of specific connections among traits in their appropriate phenological context and to highlight major gaps in knowledge. This graphical representation can also serve as a roadmap to prioritize research at other levels of integration, such as metabolomic or gene expression studies. The wiring diagram can be deployed to identify ways for improving elite breeding material and to explore untapped genetic resources for unique traits and alleles.
Yield for climate resilience
The wheat scientific community is hard at work seeking new ways to get higher yields more quickly to help the world cope with population growth, climate change, wars and stable supplies of calories and protein.
“To ensure food and nutritional security in the future, raising yields must be an integral component of making crops more climate-resilient. This new tool can serve as a roadmap to design the necessary strategies to achieve these goals,” said Jeff Gwyn, Program Director of the International Wheat Yield Partnership (IWYP).
Matthew Reynolds â Distinguished Scientist and Head of Wheat Physiology at the International Maize and Wheat Improvement Center (CIMMYT)
Gustavo Ariel Slafer â Research Professor at the Catalonian Institution for Research and Advanced Studies (ICREA) and Associate Professor of the University of Lleida
For more information or to arrange interviews, please contact the CIMMYT media team:
The study is an international collaboration of scientists from the International Maize and Wheat Improvement Center (CIMMYT), the Catalonian Institution for Research and Advanced Studies (ICREA), the Center for Research in Agrotechnology (AGROTECNIO), the University of Lleida, the University of Nottingham, the John Innes Centre, Lancaster University, Technische UniversitĂ€t MĂŒnchen, CSIRO Agriculture & Food, and the International Wheat Yield Partnership (IWYP).
ABOUT CIMMYT:
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. CIMMYTâs 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.
The International Wheat Yield Partnership (IWYP) represents a long-term global endeavor that utilizes a collaborative approach to bring together funding from public and private research organizations from a large number of countries. Over the first five years, the growing list of partners aims to invest up to US$100 million.
A new article in the New Yorker praises the cutting-edge technology CIMMYT, CGIAR and other scientists are developing to produce a second Green Revolution that doesn’t repeat the mistakes of the first, putting the experiences and challenges of farmers at the heart of it.
In this op-ed, Harvard Professor Gabriela Soto Laveaga stresses the importance of tackling hunger as more than a technical problem to be addressed through scientific advancement alone, praising CGIAR for its community-centered & inclusive approach to food systems amid the climate crisis.
Written by Bea Ciordia on . Posted in Uncategorized.
Berhanu is a product development breeder for Eastern Africa based in Nairobi, Kenya. He is responsible for identifying competitive hybrids through formation of coded by coded hybrids and testing across multiple optimum and stress environment.
Berhanu organizes and leads the product advancement process for eastern Africa to advance products using the stage gate advancement process.
Prior to joining CIMMYT, Berhanu worked for the Ethiopian Institute of Agricultural Research, where he was the national coordinator for maize research.
Written by Bea Ciordia on . Posted in Uncategorized.
Gustavo Teixeira is an Automation and Mechanization Lead with CIMMYT’s Excellence in Breeding Platform.
As a Breeding Operations and Phenotyping module leader, he provides evaluation of breeding program operations according to continuous improvement and operational excellence methodologies and lead initiatives to improve CGIAR and National Agricultural Research Systems (NARS) breeding operations capacities.
Teixeira is an expert in agriculture engineering, processes, mechanization and automatization. He has over 15 years of experience in the private sector, including as Automation Manager for R&D in Latin America at Syngenta.
As extreme weather conditions increasingly threaten the global wheat supply, CIMMYTÂ head of wheat physiology Matthew Reynolds discusses the importance of developing drought-resistant crops through breeding programs to keep bread on the table.
Alberto Chassaigne has 27 years of experience working in maize seed systems, maize breeding, agronomy and farmer outreach. Since February 2022, he is the Maize Germplasm Bank Curator focusing on the conservation, access to and benefit sharing of the enhanced use of germplasm. As a Maize Seed Systems Specialist, he works focusing primarily on promoting commercial seed production and enhanced adoption of maize hybrids and OPV, developing seed production research, capacity building and scaling production from Breeder Seed to Certified Seed. Since 2013 he has served 73 seed companies and registered 95 CIMMYT varieties in Mexico, and advised the public and private sector in Haiti, Colombia and Peru.Chassaigne holds a PhD in Seed Production from Colegio de Postgraduados, Mexico, a PhD in Agricultural Science and an MSc. in Agronomy from the Central University of Venezuela, and an additional degree in Agricultural Engineer.
Chengetai Kadzere is a field auxiliary with CIMMYT’s Global Maize Program, based in Zimbabwe. His work involves preparation of seed shipments for local and international partners, generation of hybrids, OPVs and parent materials descriptor data, and management of demonstration sites for regional trials.
Beyhan Akin is a senior scientist with CIMMYTâs Global Wheat Program, based in Turkey.
She joined CIMMYT in 1987 and has since worked across different areas of the International Winter Wheat Program (IWWIP), including supporting capacity development for national and regional collaborators and conducting in-service trainings for young researchers from the Central and West Asia and North Africa (CWANA) region. Since 2020, she is leading the International Winter Wheat Improvement Program for CIMMYT and the Spring Wheat Program in Turkey.
Akin obtained her PhD from the Aegean University in Izmir, Turkey, in 2007. She had post-graduate research activities at Washington State University in 2009 on Yellow Rust.
