Written by mcallejas on . Posted in Uncategorized.
The Intercropping project aims to identify options for smallholder farmers to sustainably intensify wide-row crop production through the addition of short-duration, high-value intercrop species and to help farmers increase their productivity, profitability and nutrition security while mitigating against climate change.
The focus is on intensification of wide-row planted crops: dry (rabi) season maize in Bangladesh, eastern India (Bihar and West Bengal states) and Bhutan, and sugarcane in central north India (Uttar Pradesh state). The primary focus is to sustainably improve cropping system productivity, however, the effects of wide-row, additive intercropping at the smallholder farm level will be considered, including potential food and nutrition benefits for the household.
There are many potential benefits of wide-row, additive intercropping, beyond increased cropping system productivity and profitability: water-, labor- and energy-use efficiencies; improved nutrition and food security for rural households; empowerment for women; and (over the longer term) increased soil health.
Little research has been conducted to date into wide-row, additive intercropping (as distinct from traditional replacement intercropping) in South Asian agroecologies. To successfully and sustainably integrate wide-row, additive intercropping into farmers’ cropping systems a range of challenges must be resolved, including optimal agronomic management and crop geometry, household- and farm-scale implications, and potential off-farm bottlenecks.
This project aims to identify practical methods to overcome these challenges for farming households in Bangladesh, Bhutan and India. Focusing on existing wide-row field crop production systems, the project aims to enable farmers to increase their cropping system productivity sustainably and in a manner that requires relatively few additional inputs.
Project activities and expected outcomes:
Evaluating farming households’ initial perspectives on wide-row, additive intercropping.
Conducting on station replicated field trials into wide-row, additive intercropping, focusing on those aspects of agronomic research difficult or unethical to undertake on farms.
Conducting on farm replicated field trials into wide-row, additive intercropping.
Determining how wide-row, additive intercropping could empower women. Quantify the long-term benefits, risks and trade-offs of wide-row, additive intercropping.
Describing key value/supply chains for wide-row, additive intercropping. Determine pathways to scale research to maximize impact.
Quantifying changes in household dry season nutrition for households representative of key typologies in each agroecological zone.
Bangladesh’s agricultural landscape is evolving rapidly, with initiatives focused on modernization, sustainability, and innovation. Projects supported by the United States Agency for International Development (USAID) are working to advance the country’s agriculture through stakeholder collaboration, enhancing productivity, improving mechanization, and embedding sustainable practices.
To explore the impact of this work, USAID officials and senior staff from CIMMYT embarked on a comprehensive tour across multiple project sites on 14 – 19 April 2024. The USAID delegation featured Zachary P. Stewart, production systems specialist from the Bureau for Resilience, Environment, and Food Security, and John Laborde and Muhammad Nuruzzaman from the USAID Bangladesh Mission. From CIMMYT, the team included Sieglinde Snapp, program director from the Sustainable Agrifood Systems Program, Timothy J. Krupnik, country representative for Bangladesh, and Owen Calvert, project leader for the Cereal Systems Initiative for South Asia-Mechanization Extension Activity (CSISA-MEA).
Visitors at Bangladesh Wheat and Maize Research Institute (BWMRI) lab, Dinajpur, Bangladesh. (Photo: Masud Rana/CIMMYT Bangladesh)
Pioneering agricultural technology
The team visited Dinajpur, Bangladesh to observe the progress of the Transforming Agrifood Systems in South Asia (TAFSSA) CGIAR Initiative, including creative efforts to raise agricultural output, support sustainable practices, and boost the area’s nutrition levels. The integrated strategy of TAFSSA, which combines inclusive community participation with socio-agronomic research, has enabled local farmers to increase revenue, diversify their crop production, and enhance yields. From the premium quality rice (PQR) value chain at the Bengal Auto Rice Mill to the sustainable intensification of mixed farming systems, the visit demonstrated TAFSSA’s dedication to building agricultural resilience and improving lives throughout Bangladesh.
In Faridpur, the team observed CSISA-MEA, a five-year project dedicated to supporting smart mechanization in Bangladesh. This included displays of innovative agricultural machinery, such as onion storage blowers, jute fiber separators, axial flow pumps, and combine harvester spare parts. Stakeholders from various sectors shared insights on how to improve machine service providers’ capacity to manage their businesses effectively.
Sholakundu, a village in Kanaipur Union, Faridpur Sadar, has embraced modern agricultural practices and diversified crop cultivation. This site showcased the impact of mechanized rice transplantation and integrated pest management (IPM) techniques, with the opportunity to observe a live demonstration of mat-type seedling raising for mechanized rice transplantation. Discussions revolved around the benefits of mechanization, IPM activities, and the village’s commitment to enhancing agricultural sustainability and productivity.
Climate-specific farming
The southern coastal region of Bangladesh has long suffered from problems including salinity, drought, waterlogging, and unpredictable weather. Addressing these issues is the USAID-funded Sustainable Intensification Innovation Lab–Asian Mega Delta (SIIL-AMD) project, which encourages climate-resilient farming and better water management.
The initiative engages approximately 400 farmers in trials of improved agronomic techniques through the use of 14 Learning Hubs and the Cluster Farmer Field School (CFFS), aiming to increase output and assist local people in adjusting to the special conditions of the coastal polder zone.
“Bangladesh’s women farmers, especially those in this area and the coastal regions, are incredibly hardworking,” stated Zachary P. Stewart. “Even in the face of adverse weather conditions, their dedication has led to excellent crop yields. If provided with further training and allocated more time, these industrious women could take the lead in driving Bangladesh’s agricultural progress forward.”
Visitors at local machine manufacturing workshop in Jashore, Bangladesh. (Photo: Masud Rana/CIMMYT Bangladesh)
Systemic self-sufficiency
For reasons of development and sustainability, Bangladesh’s agriculture industry is focused on using locally made machinery and spare parts. As USAID personnel visited the SMR Agro Engineering Workshop and Foundry, situated in Jashore Sadar, they witnessed how support by CSISA-MEA has improved the agricultural mechanization market system. SMR Agro Engineering produces high-quality agricultural machinery and spare parts, increasing farmers’ productivity and decreasing labor intensity.
CSISA-MEA’s support has been significant in preparing new industrial layouts, raising labor skill levels, providing technical guidance, and facilitating financing. Moreover, through the development of business partnerships with lead companies, agriculture-based light engineering enterprises (ABLEs), and dealers, CSISA-MEA ensures a strong network that supports the widespread use of mechanized services. This collaborative effort marks a significant step towards enhancing rural livelihoods and achieving sustainable agricultural practices in Bangladesh.
Global research partnerships
In addition to visiting farmers’ fields, the team also attended the Bangladesh Agricultural Research Institute (BARI), the nation’s largest agricultural research center which focuses on improving crop yields, food security, and employment. The visitors explored the work in mechanization, IPM, and farm machinery, with a tour of BARI’s IPM and toxicology laboratories highlighting the organizations’ sustainable approach to pest management.
The final visit was to Ispahani Agro Limited (IAL), a leading bio-pesticide producer in Gazipur. IAL is at the forefront of bio-rational pest management, creating environmentally friendly, non-toxic inputs. CIMMYT’s assistance has been crucial for the company’s growth, with the tour covering production units, laboratories, and discussions on IAL’s business development.
Overall, the experience offered a comprehensive overview of collaborative activities between USAID, CIMMYT, and Bangladeshi stakeholders. From research and mechanization to bio-rational pest management, the combined efforts boost output and encourage sustainability and responsible environmental behavior.
As Bangladesh continues to embrace modern farming practices, partnerships and projects will play a pivotal role in defining how the country’s agricultural industry evolves into one that is economically viable and sustainable.
Researchers and experts from 15 countries convened in Zambia, between 4-15 March 2024, for an international training on wheat blast disease screening, surveillance, and management.
Wheat blast, caused by pathogen Magnaporthe oryzae pathotype triticum, is threatening global wheat production especially in warmer and humid regions. The disease was first observed in Parana state of Brazil in 1985 and subsequently spread to Bolivia, Paraguay, and Argentina. Outside of South America, wheat blast incidences were recorded for the first time in Bangladesh in 2016 and in Zambian wheat fields in 2018.
To mitigate the impact of this potential plant pandemic, the Zambia Agriculture Research Institute (ZARI), in collaboration with CIMMYT and other partners, organized a comprehensive training for building research capacity and raising awareness within the local and international community, especially in at-risk countries.
“This collaborative effort, supported by various international partners and funders, underscores the importance of global cooperation in addressing agricultural challenges such as wheat blast. The objective of the training was to empower researchers with knowledge and tools for enhanced wheat production resilience in regions vulnerable to this destructive disease,” said Pawan Kumar Singh, principal scientist and project leader at CIMMYT. Singh collaborated with Batiseba Tembo, wheat breeder at ZARI-Zambia, to coordinate and lead the training program.
Thirty-eight wheat scientists, researchers, professors, policymakers, and extension agents from countries including Bangladesh, Brazil, Ethiopia, India, Kenya, Mexico, Nepal, South Africa, Sweden, Tanzania, United Kingdom, Uruguay, Zambia, and Zimbabwe convened at the Mt. Makulu Central Research Station in Chilanga, Zambia.
“Wheat blast is a devastating disease that requires concerted efforts to effectively manage it and halt further spread. The disease is new to Africa, so developing capacity amongst country partners before the disease spreads more widely is critical,” said Tembo.
Participants at the International Training on Wheat Blast Screening and Surveillance. (Photo: CIMMYT)
Highlights from the training: discussions, lab exercises, and field visits
During the training, participants engaged in lectures, laboratory exercises, and field visits. There were insightful discussions on key topics including the fundamentals of wheat blast epidemiology, disease identification, molecular detection of the wheat blast pathogen, isolation and preservation techniques for the pathogen, disease scoring methods, disease management strategies, and field surveillance and monitoring.
The course also provided practical experience in disease evaluation at the Precision Phenotyping Platform (PPP) screening nursery located in Chilanga research station. This involved characterization of a diverse range of wheat germplasm with the aim of releasing resistant varieties in countries vulnerable to wheat blast. Additionally, participants undertook field visits to farmers’ fields, conducting surveillance of wheat blast-infected areas. They collected samples and recorded survey data using electronic open data kit (ODK) capture tools.
Participants listen to a lecture by B.N. Verma, director of Zambia Seed Co., on the history of wheat production in Zambia. (Photo: CIMMYT)
“The killer disease needs to be understood and managed utilizing multi-faceted approaches to limit the expansion and damages it can cause to global wheat production. The Bangladesh Wheat and Maize Research Institute (BWMRI) is willing to share all the strategies it deployed to mitigate the effect of wheat blast,” said Golam Faruq, BWMRI’s director general.
Participants visited seed farms to gain practical insights into seed production processes and quality assurance measures. These visits provided first-hand knowledge of seed selection, breeding techniques, and management practices crucial for developing resistant wheat varieties. Participants also visited research sites and laboratories to observe advanced research methodologies and technologies related to wheat blast management. These visits exposed them to cutting-edge techniques in disease diagnosis, molecular analysis, and germplasm screening, enhancing their understanding of effective disease surveillance and control strategies.
Field visit. (Photo: CIMMYT)
“The training and knowledge sharing event was a significant first step in developing understanding and capacity to deal with wheat blast for partners from several African countries. It was wonderful to see the efforts made to ensure gender diversity among participants,” said Professor Diane Saunders from the John Innes Centre, UK.
One of the world’s largest crop pathogen surveillance systems is set to expand its analytic and knowledge systems capacity to protect wheat productivity in food vulnerable areas of East Africa and South Asia.
Researchers announced the Wheat Disease Early Warning Advisory System (Wheat DEWAS), funded through a $7.3 million grant from the Bill & Melinda Gates Foundation and the United Kingdom’s Foreign, Commonwealth & Development Office, to enhance crop resilience to wheat diseases.
The project is led by David Hodson, principal scientist at CIMMYT, and Maricelis Acevedo, research professor of global development and plant pathology at Cornell University’s College of Agriculture and Life Sciences. This initiative brings together research expertise from 23 research and academic organizations from sub-Saharan Africa, South Asia, Europe, the United States and Mexico.
Wheat DEWAS aims to be an open and scalable system capable of tracking important pathogen strains. The system builds on existing capabilities developed by the research team to provide near-real-time model-based risk forecasts and resulting in accurate, timely and actionable advice to farmers. As plant pathogens continue to evolve and threaten global food production, the system strengthens the capacity of countries to respond in a proactive manner to transboundary wheat diseases.
The system focuses on the two major fungal pathogens of wheat known as rust and blast diseases. Rust diseases, named for a rust-like appearance on infected plants, are hyper-variable and can significantly reduce crop yields when they attack. The fungus releases trillions of spores that can ride wind currents across national borders and continents and spread devastating epidemics quickly over vast areas.
Wheat blast, caused by the fungus Magnaporte oryzae Tritici, is an increasing threat to wheat production, following detection in both Bangladesh and Zambia. The fungus spreads over short distances and through the planting of infected seeds. Grains of infected plants shrivel within a week of first symptoms, providing little time for farmers to take preventative actions. Most wheat grown in the world has limited resistance to wheat blast.
“New wheat pathogen variants are constantly evolving and are spreading rapidly on a global scale,” said Hodson, principal investigator for Wheat DEWAS. “Complete crop losses in some of the most food vulnerable areas of the world are possible under favorable epidemiological conditions. Vigilance coupled with pathogen-informed breeding strategies are essential to prevent wheat disease epidemics. Improved monitoring, early warning and advisory approaches are an important component for safeguarding food supplies.”
Previous long-term investments in rust pathogen surveillance, modelling, and diagnostics built one of the largest operational global surveillance and monitoring system for any crop disease. The research permitted the development of functioning prototypes of advanced early warning advisory systems (EWAS) in East Africa and South Asia. Wheat DEWAS seeks to improve on that foundation to build a scalable, integrated, and sustainable solution that can provide improved advanced timely warning of vulnerability to emerging and migrating wheat diseases.
“The impact of these diseases is greatest on small-scale producers, negatively affecting livelihoods, income, and food security,” Acevedo said. “Ultimately, with this project we aim to maximize opportunities for smallholder farmers to benefit from hyper-local analytic and knowledge systems to protect wheat productivity.”
The system has already proven successful, contributing to prevention of a potential rust outbreak in Ethiopia in 2021. At that time, the early warning and global monitoring detected a new yellow rust strain with high epidemic potential. Risk mapping and real-time early forecasting identified the risk and allowed a timely and effective response by farmers and officials. That growing season ended up being a production record-breaker for Ethiopian wheat farmers.
While wheat is the major focus of the system, pathogens with similar biology and dispersal modes exist for all major crops. Discoveries made in the wheat system could provide essential infrastructure, methods for data collection and analysis to aid interventions that will be relevant to other crops.
The Transforming Agrifood Systems in South Asia (TAFSSA) Initiative held its Evaluation and Planning Workshop in Dinajpur, Bangladesh, from June 6 to 8, 2023. The purpose of this interactive workshop was to bring together people from diverse sectors to assess the progress and challenges and adjust future implementation of the Initiative’s activities, which aim to improve South Asian agrifood systems to promote sustainable and nutritious foods for all. All three government partners participated in the three-day event: the Bangladesh Institute of Research and Training on Applied Nutrition (BIRTAN), Bangladesh Agricultural Research Institute – On-Farm Research Division (BARI-OFRD), and the Bangladesh Wheat and Maize Research Institute (BWMRI).
Participants visited the research platform trial hosted by BWMRI in Dinajpur, Bangladesh (Photo: Nur-A-Mahajabin Khan/CIMMYT)
The primary goal of the first day was to visit the locations of TAFSSA’s experiments and to interact with the farmers hosting the trials while they were taking place. Participants were divided into groups and visited several on-farm sites, viewing the trials and engaging in meaningful discussions with the farmers. These visits provided useful firsthand insights on the problems farmers confront while attempting to diversify their crops and improve their livelihoods. For example, visiting the research platform trial hosted by the BWMRI at its research station in Dinajpur allowed the participants to compare results from a broader set of diversified cropping patterns.
“More crops mean more money,” said Mohammad Ali, one of the farmers. “I am delighted to produce a variety of crops and witness the increase in my earnings. By cultivating four crops in a single year, I have experienced firsthand the positive impact on my income. Crop diversification has opened doors to new opportunities and has brought greater satisfaction to my farming endeavors.”
During the second day of the workshop, presentations were held to provide an overview of results from the activities TAFSSA implemented during the first seasons of the Initiative, including research platform trials, training sessions on nutrition, and on-farm activities carried out across the divisions of Rangpur and Rajshahi. These presentations emphasized TAFSSA’s progress, obstacles, and preliminary results and were followed by a question-and-answer session to discuss the outcomes and efforts. This interactive workshop promoted information exchange and sparked more debate. Participants underlined the significance of market links between farmers and consumers, emphasizing the need to develop sustainable and lucrative value chains.
Panelists engaged in a discussion about TAFSSA’s progress, challenges, and path forward (Photo: Nur-A-Mahajabin Khan/CIMMYT)
Future adjustments and improvements were discussed, which encouraged collaboration and problem-solving as a group. The method was inclusive and participative, ensuring that all opinions were heard and considered. The day ended with a dinner, during which participants were free to network and discuss ideas further with one another.
The third and final day began with a discussion on TAFSSA’s beneficiaries, particularly those involved in altering agrifood systems in South Asia to promote sustainable and healthy diets for all in the region. Participants looked at the gender aspect of the Initiative and whether it was effectively reaching all of its target beneficiaries, including men, women, and other marginalized groups.
The workshop provided a forum for participants to share their experiences, address issues and collaborate together to reform South Asian agrifood systems. The evaluation and planning exercises aimed to create equal access to nutritious diets, boost livelihoods and resilience among farmers, and safeguard land, air and groundwater resources.
Participants evaluated field production results during the field visit (Photo: Nur-A-Mahajabin Khan/CIMMYT)
“It’s crucial to acknowledge the lack of technical knowledge among farmers,” said Dr. Mazharul Anwar, from the BARI. “Providing targeted training programs for specific crops like tomato, carrot, sorghum, and others can help bridge this knowledge gap and enhance farmers’ capabilities in achieving better yields and sustainable practices.”
Through its work in South Asia, TAFSSA can contribute to change in the region and continue its objective to develop more sustainable and equitable agrifood systems by obtaining useful information from field trials, interactive visits with farmers, presentations, and conversations. To that end, the workshop has set the stage for the Initiative to achieve its goals thanks to the collaborative efforts and collective passion of all the participants.
The devastating disease wheat blast is a threat to crop production in many South Asian countries. In Bangladesh, it was first identified in seven southern and southwestern districts in 2016, and later spread to 27 others causing significant damage. The International Maize and Wheat Improvement Center (CIMMYT) is working with the Bangladesh Wheat and Maize Research Institute (BWMRI) and other national partners to conduct research and extension activities to mitigate the ongoing threat.
From March 1-10, 2023, a group of 46 wheat researchers, government extension agents, and policy makers from ten countries — Bangladesh, Brazil, China, Ethiopia, India, Japan, Mexico, Nepal, Sweden, and Zambia — gathered in Jashore, Bangladesh to learn about and exchange experiences regarding various wheat diseases, particularly wheat blast. Following the COVID-19 pandemic, this was the first in-person international wheat blast training held in Bangladesh. It focused on the practical application of key and tricky elements of disease surveillance and management strategies, such as resistance breeding and integrated disease management.
Training participants get hands-on practice using a field microscope, Bangladesh. (Photo: Ridoy/CIMMYT)
“This is an excellent training program,” said Shaikh Mohammad Bokhtiar, executive chairman of the Bangladesh Agriculture Research Council (BARC), during the opening session. “Participants will learn how to reduce the severity of the blast disease, develop and expand blast resistant varieties to farmers, increase production, and reduce imports.”
This sentiment was echoed by Golam Faruq, director general of BWMRI. “This program helps in the identification of blast-resistant lines from across the globe,” he said. “From this training, participants will learn to manage the devastating blast disease in their own countries and include these learnings into their national programs.”
Hands-on training
The training was divided into three sections: lectures by national and international scientists; laboratory and field experiment visits; and trips to farmers’ fields. Through the lecture series, participants learned about a variety of topics including disease identification, molecular detection, host-pathogen interaction, epidemiology and integrated disease management.
Hands-on activities were linked to working on the Precision Phenotyping Platform (PPP), which involves the characterization of more than 4,000 wheat germplasm and releasing several resistant varieties in countries vulnerable to wheat blast. Participants practiced taking heading notes, identifying field disease symptoms, tagging, and scoring disease. They conducted disease surveillance in farmers’ fields in Meherpur and Faridpur districts — both of which are extremely prone to wheat blast — observing the disease, collecting samples and GPS coordinates, and completing surveillance forms.
Muhammad Rezaul Kabir, senior wheat breeder at BWMRI, explains the Precision Phenotyping Platform, Bangladesh. (Photo: Md. Harun-Or-Rashid/CIMMYT)
Participants learned how to use cutting-edge technology to recognize blast lesions in leaves using field microscopes. They went to a pre-installed spore trapping system in a farmer’s field to learn about the equipment and steps for collecting spore samples, observing them under a compound microscope, and counting spores. They also visited the certified seed production fields of Shawdesh Seed, a local company which has played an important role in promoting wheat blast resistant varieties BARI Gom 33 and BWMRI Gom 3 regionally, and Bangabandhu Sheikh Mujibur Rahman Agricultural University (BSMRAU) in Gazipur to see current wheat blast research in action.
Blast-resistance in Bangladesh
“I am so happy to see the excellent infrastructure and work ethics of staff that has made possible good science and impactful research come out of the PPP,” said Aakash Chawade, associate professor in Plant Breeding at the Swedish University of Agricultural Sciences. “Rapid development of blast-resistant varieties and their dissemination will help Bangladesh mitigate the effects of wheat blast, not only inside the country but by supporting neighboring ones as well.”
Training participants scout and score disease in a blast-infected wheat field, Bangladesh. (Photo: Md. Harun-Or-Rashid/CIMMYT)
“Besides the biotic and abiotic challenges faced in wheat production, climate change and the Russia-Ukraine crisis are further creating limitations to wheat production and marketing,” said Pawan Kumar Singh, head of Wheat Pathology at CIMMYT and lead organizer of the training. “Due to the development of blast-resistant wheat varieties and its commercial production under integrated disease management practices, the domestic production of wheat in Bangladesh has increased and there is increased interest from farmers in wheat.”
Dave Hodson, a principal scientist at CIMMYT and one of the training’s resource speakers, added: “This is a remarkable success that researchers developed two blast resistant varieties in Bangladesh urgently. It was only achievable because of the correct measures taken by the researchers and support of Government policies.”
However, there are still some barriers to widespread adoption of these varieties. As such, in parallel to other activities, a team from Bangladesh Agricultural University (BAU) joined the field trip to meet local farmers and conduct research into the socio-economic factors influencing the adoption and scaling of relevant wheat varieties.
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
Md. Sayedul Islam inaugurated the greenhouse complex along with Golam Faruq and Md. Benojir Alam. (Credit: Timothy J. Krupnik/CIMMYT)
A new greenhouse complex, built with financial support from the International Maize and Wheat Improvement Center (CIMMYT), at the Bangladesh Wheat and Maize Research Institute (BWMRI) was inaugurated on 13 August 2022. The greenhouse was built at BWMRI’s headquarters in Dinajpur, Bangladesh.
This complex has a room for generator, a sample preparation room and space for a small laboratory. These upgrades will add new momentum for greenhouse activities and BWMRI and CIMMYT scientists designed the facility to accommodate wheat scientists from Bangladesh and other countries.
The BWMRI has been working to combat wheat blast disease since 2016, with financial and technical support from CIMMYT and other investors. CIMMYT has also assisted the Government of Bangladesh in developing an early warning system for wheat blast.
Because of the challenging phenology of synthetic wheat and introductions from winter and facultative wheat zones, field condition evaluation of these germplasm is difficult and the greenhouse will help ease this hurdle. Additionally, several pathological experiments investigating the biology of wheat blast will now be able to be performed in the new greenhouse facility.
Supplementary activities at the greenhouse include disease screening and research into unlocking the genetics of host resistance. The installation of a diesel generator will keep the greenhouse running in case of power outages.
Visitors to the newly constructed greenhouse at the Bangladesh Wheat and Maize Research Institute. (Credit: Rezaul Kabir/BWMRI)
Md. Sayedul Islam, Secretary of the Ministry of Agriculture, inaugurated the greenhouse complex. Additional attendees at the opening included Shaikh Mohammad Bokhtiar, Executive Chairman of the Bangladesh Agricultural Research Council (BARC), Golam Faruq, Director General of BWMRI, Mirza Mofazzal Islam, Director General of the Bangladesh Institute of Nuclear Agriculture (BINA), Debasish Sarker, Director General of the Bangladesh Agricultural Research Institute (BARI), Md. Benojir Alam, Director General of the Department of Agricultural Extension (DAE), and Md. Abdul Wadud, Executive Director and Additional Secretary at the Bangladesh Institute of Research and Training on Applied Nutrition (BIRTAN). Timothy J. Krupnik, country representative of CIMMYT in Bangladesh, was also present.
Written by Bea Ciordia on . Posted in Uncategorized.
The Managing Wheat Blast in Bangladesh: Identification and Introgression of Wheat Blast Resistance for Rapid Varietal Development and Dissemination project aims to characterize novel sources of wheat blast resistance, identification, and molecular mapping of resistance loci/gene(s) and their introgression into varietal development pipelines for rapid dissemination of resistant varieties in Bangladesh.
Objectives
Validate the effects of genes Rmg1, Rmg8 and RmgGR119 in field experiments
Identify novel wheat blast resistant sources and generating the corresponding genetic materials for investigating the resistance Quantitative Trait Loci (QTL)/genes
Monitor the adoption of resistant varieties BARI Gom 33 and WMRI Gom 3 by women and men farmers to learn the drivers and obstacles that are involved in the process, to inform the design of a farmer-preferred product profile, and factors in impact pathway
Build the capacity of the Bangladesh Wheat and Maize Research Institute (BWMRI) to operate major infrastructure in Jashore and Dinajpur at the individual and institutional levels
Enhance collaboration between Bangladesh and other countries showing interest on wheat blast
Train young wheat researchers and breeders in Jashore Precision Phenotyping Platform (PPP)
Genomic selection identifies individual plants based on the information from molecular markers, DNA signposts for genes of interest, that are distributed densely throughout the wheat genome. For wheat blast, the results can help predict which wheat lines hold promise as providers of blast resistance for future crosses and those that can be advanced to the next generation after selection.
In this study, scientists from the International Maize and Wheat Improvement Center (CIMMYT) and partners evaluated genomic selection by combining genotypic data with extensive and precise field data on wheat blast responses for three sets of genetically diverse wheat lines and varieties, more than 700 in all, grown by partners at locations in Bangladesh and Bolivia over several crop cycles.
The study also compared the use of a small number of molecular markers linked to the 2NS translocation, a chromosome segment from the grass species Aegilops ventricosa that was introduced into wheat in the 1980s and is a strong and stable source of blast resistance, with predictions using thousands of genome-wide markers. The outcome confirms that, in environments where wheat blast resistance is determined by the 2NS translocation, genotyping using one-to-few markers tagging the translocation is enough to predict the blast response of wheat lines.
Finally, the authors found that selection based on a few wheat blast-associated molecular markers retained 89% of lines that were also selected using field performance data, and discarded 92% of those that were discarded based on field performance data. Thus, both marker-assisted selection and genomic selection offer viable alternatives to the slower and more expensive field screening of many thousands of wheat lines in hot-spot locations for the disease, particularly at early stages of breeding, and can speed the development of blast-resistant wheat varieties.
The research was conducted by scientists from the International Maize and Wheat Improvement Center (CIMMYT), the Bangladesh Wheat and Maize Research Institute (BWMRI), the Instituto Nacional de Innovación Agropecuaria y Forestal (INIAF) of Bolivia, the Borlaug Institute for South Asia (BISA) and the Indian Council of Agricultural Research (ICAR) in India, the Swedish University of Agricultural Sciences (Alnarp), and Kansas State University in the USA. Funding for the study was provided by the Bill & Melinda Gates Foundation, the Foreign and Commonwealth Development Office of the United Kingdom, the U.S. Agency for International Development (USAID), the CGIAR Research Program on Wheat (WHEAT), the Indian Council of Agricultural Research (ICAR), the Swedish Research Council, and the Australian Centre for International Agricultural Research (ACIAR).
Cover photo: A researcher from Bangladesh shows blast infected wheat spikes and explains how the disease directly attacks the grain. (Photo: Chris Knight/Cornell University)
As wheat blast continues to infect crops in countries around the world, researchers are seeking ways to stop its spread. The disease — caused by the Magnaporthe oryzae pathotype Triticum — can dramatically reduce crop yields, and hinder food and economic security in the regions in which it has taken hold.
Researchers from the International Maize and Wheat Improvement Center (CIMMYT) and other international institutions looked into the potential for wheat blast to spread, and surveys existing tactics used to combat it. According to them, a combination of methods — including using and promoting resistant varieties, using fungicides, and deploying strategic agricultural practices — has the best chance to stem the disease.
The disease was originally identified in Brazil in 1985. Since then, it has spread to several other countries in South America, including Argentina, Bolivia and Paraguay. During the 1990s, wheat blast impacted as many as three million hectares in the region. It continues to pose a threat.
Through international grain trade, wheat blast was introduced to Bangladesh in 2016. The disease has impacted around 15,000 hectares of land in the country and reduced average yields by as much as 51% in infected fields.
Because the fungus’ spores can travel on the wind, it could spread to neighboring countries, such as China, India, Nepal and Pakistan — countries in which wheat provides food and jobs for billions of people. The disease can also spread to other locales via international trade, as was the case in Bangladesh.
“The disease, in the first three decades, was spreading slowly, but in the last four or five years its pace has picked up and made two intercontinental jumps,” said Pawan Singh, CIMMYT’s head of wheat pathology, and one of the authors of the recent paper.
In the last four decades, wheat blast has appeared in South America, Asia an Africa. (Video: Alfonso Cortés/CIMMYT)
The good fight
Infected seeds are the most likely vector when it comes to the disease spreading over long distances, like onto other continents. As such, one of the key wheat blast mitigation strategies is in the hands of the world’s governments. The paper recommends quarantining potentially infected grain and seeds before they enter a new jurisdiction.
Governments can also create wheat “holidays”, which functionally ban cultivation of wheat in farms near regions where the disease has taken hold. Ideally, this would keep infectable crops out of the reach of wheat blast’s airborne and wind-flung spores. In 2017, India banned wheat cultivation within five kilometers of Bangladesh’s border, for instance. The paper also recommends that other crops — such as legumes and oilseed — that cannot be infected by the wheat blast pathogen be grown in these areas instead, to protect the farmers’ livelihoods.
Other tactics involve partnerships between researchers and agricultural workers. For instance, early warning systems for wheat blast prediction have been developed and are being implemented in Bangladesh and Brazil. Using weather data, these systems alert farmers when the conditions are ideal for a wheat blast outbreak.
Researchers are also hunting for wheat varieties that are resistant to the disease. Currently, no varieties are fully immune, but a few do show promise and can partially resist the ailment depending upon the disease pressure. Many of these resistant varieties have the CIMMYT genotype Milan in their pedigree.
“But the resistance is still limited. It is still quite narrow, basically one single gene,” Xinyao He, one of the co-authors of the paper said, adding that identifying new resistant genes and incorporating them into breeding programs could help reduce wheat blast’s impact.
Wheat spikes damaged by wheat blast. (Photo: Xinyao He/CIMMYT)
The more the merrier
Other methods outlined in the paper directly involve farmers. However, some of these might be more economically or practically feasible than others, particularly for small-scale farmers in developing countries. Wheat blast thrives in warm, humid climates, so farmers can adjust their planting date so the wheat flowers when the weather is drier and cooler. This method is relatively easy and low-cost.
The research also recommends that farmers rotate crops, alternating between wheat and other plants wheat blast cannot infect, so the disease will not carry over from one year to the next. Farmers should also destroy or remove crop residues, which may contain wheat blast spores. Adding various minerals to the soil, such as silicon, magnesium, and calcium, can also help the plants fend off the fungus. Another option is induced resistance, applying chemicals to the plants such as jasmonic acid and ethylene that trigger its natural resistance, much like a vaccine, Singh said.
Currently, fungicide use, including the treatment of seeds with the compounds, is common practice to protect crops from wheat blast. While this has proven to be somewhat effective, it adds additional costs which can be hard for small-scale farmers to swallow. Furthermore, the pathogen evolves to survive these fungicides. As the fungus changes, it can also gain the ability to overcome resistant crop varieties. The paper notes that rotating fungicides or developing new ones — as well as identifying and deploying more resistant genes within the wheat — can help address this issue.
However, combining some of these efforts in tandem could have a marked benefit in the fight against wheat blast. For instance, according to Singh, using resistant wheat varieties, fungicides, and quarantine measures together could be a time-, labor-, and cost-effective way for small-scale farmers in developing nations to safeguard their crops and livelihoods.
“Multiple approaches need to be taken to manage wheat blast,” he said.
A blast-blighted stalk of wheat. (Photo: Chris Knight/Cornell)
Every year, the spores of the wheat blast fungus lie in wait on farms in South America, Bangladesh, and beyond. In most years, the pathogen has only a small impact on the countries’ wheat crops. But the disease spreads quickly, and when the conditions are right there’s a risk of a large outbreak — which can pose a serious threat to the food security and livelihood of farmers in a specific year.
To minimize this risk, an international partnership of researchers and organizations have created the wheat blast Early Warning System (EWS), a digital platform that notifies farmers and officials when weather conditions are ideal for the fungus to spread. The team, which began its work in Bangladesh, is now introducing the technology to Brazil — the country where wheat blast was originally discovered in 1985.
The International Maize and Wheat Improvement Center (CIMMYT), the Brazilian Agricultural Research Corporation (EMBRAPA), Brazil’s University of Passo Fundo (UPF) and others developed the tool with support from USAID under the Cereal Systems Initiative for South Asia (CSISA) project.
Although first developed with the help of Brazilian scientists for Bangladesh, the EWS has now come full circle and is endorsed and being used by agriculture workers in Brazil. The team hopes that the system will give farmers time to take preventative measures against the disease.
Outbreaks can massively reduce crop yields, if no preventative actions are taken.
“It can be very severe. It can cause a lot of damage,” says Maurício Fernandes, a plant epidemiologist with EMBRAPA.
Striking first
In order to expand into a full outbreak, wheat blast requires specific temperature and humidity conditions. So, Fernandes and his team developed a digital platform that runs weather data through an algorithm to determine the times and places in which outbreaks are likely to occur.
If the system sees a region is going to grow hot and humid enough for the fungus to thrive, it sends an automated message to the agriculture workers in the area. These messages — texts or emails — alert them to take preemptive measures against the disease.
More than 6,000 extension agents in Bangladesh have already signed up for disease early warnings.
In Brazil, Fernandes and his peers are connecting with farmer cooperatives. These groups, which count a majority of Brazilian farmers as members, can send weather data to help inform the EWS, and can spread alerts through their websites or in-house applications.
Wheat blast can attack a plant quickly, shriveling and deforming the grain in less than a week from the first symptoms. Advance warnings are essential to mitigate losses. The alerts sent out will recommend that farmers apply fungicide, which only works when applied before infection.
“If the pathogen has already affected the plant, the fungicides will have no effect,” Fernandes says.
A blast from the past
Because wheat had not previously been exposed to Magnaporthe oryzae, most wheat cultivars at the time had no natural resistance to Magnaporthe oryzae, according to Fernandes. Some newer varieties are moderately resistant to the disease, but the availability of sufficient seed for farmers remains limited.
The pathogen can spread through leftover infected seeds and crop residue. But its spores can also travel vast distances through the air.
If the fungus spreads and infects enough plants, it can wreak havoc over large areas. In the 1990s — shortly after its discovery — wheat blast impacted around three million hectares of wheat in South America. Back in 2016, the disease appeared in Bangladesh and South Asia for the first time, and the resulting outbreak covered around 15,000 hectares of land. CGIAR estimates that the disease has the potential to reduce the region’s wheat production by 85 million tons.
In Brazil, wheat blast outbreaks can have a marked impact on the country’s agricultural output. During a major outbreak in 2009, the disease affected as many as three million hectares of crops in South America. As such, the EWS is an invaluable tool to support food security and farmer livelihoods. Fernandes notes that affected regions can go multiple years between large outbreaks, but the threat remains.
“People forget about the disease, then you have an outbreak again,” he says.
Essential partnerships
The EWS has its roots in Brazil. In 2017 Fernandes and his peers published a piece of research proposing the model. After that, Tim Krupnik, a senior scientist and country representative with CIMMYT in Bangladesh, along with a group of researchers and organizations, launched a pilot project in Bangladesh.
There, agriculture extension officers received an automated email or text message when weather conditions were ideal for wheat blast to thrive and spread. The team used this proof of concept to bring it back to Brazil.
According to Krupnik, the Brazil platform is something of a “homecoming” for this work. He also notes that cooperation between the researchers, organizations and agriculture workers in Brazil and Bangladesh was instrumental in creating the system.
“From this, we’re able to have a partnership that I think will have a significant outcome in Brazil, from a relatively small investment in research supplied in Bangladesh. That shows you the power of partnerships and how solutions can be found to pressing agricultural problems through collaborative science, across continents,” he says.
On November 13, 2020, researchers from the International Maize and Wheat Improvement Center (CIMMYT) and the Bangladesh Wheat and Maize Research Institute (BWMRI) held a virtual meeting to update Bangladesh’s Minister for Agriculture Md Abdur Razzaque on their organizations’ ongoing research activities regarding the development of sustainable, cereal-based farming systems.
The purpose of this event was to inform influential stakeholders of the implications of the impending transition to One CGIAR for collaborative research activities in Bangladesh and how CIMMYT will continue its support to the its partners in the country, including the government and other CGIAR centers. The event was chaired by CIMMYT’s Director General Martin Kropff, who called-in from CIMMYT’s headquarters in Mexico, and Razzaque, who attended the event as a special guest. Around 21 participants from various government offices including the Department of Agricultural Extension (DAE) and the Bangladesh Agricultural Research Council (BARC) were in attendance.
Speaking at the event, Razzaque thanked CIMMYT for its support in increasing maize and wheat production in Bangladesh — as the main source of germplasm for these two crops — which has been crucial for assuring food and income security and helping the country reach towards the Sustainable Development Goals. He expressed his gratitude for CIMMYT’s help in mitigating the threats posed by pests and diseases, and supporting climate information services which have enabled farmers to avoid crop losses in mung bean, and he requested that CIMMYT to intensify its research on cropping systems, heat- and disease-tolerant wheat varieties, and the introduction of technologies and farming practices to sustainably increase production and reduce wheat imports.
Martin Kropff gives an overview of CIMMYT research in Bangladesh during a virtual meeting with stakeholders. (Photo: CIMMYT)
Timothy J. Krupnik, CIMMYT’s country representative for Bangladesh, guided participants through the history of CIMMYT’s engagement in Bangladesh from the 1960s to the present and outlined the organization’s plan for future collaboration with the government. In addition developing wheat blast-resistant varieties, exchanging germplasm and seed multiplication programs for disease-resistant varieties, Krupnik described collaborative efforts to fight back against fall armyworm, research in systems agronomy to boost crop intensity and the use of advanced simulation models and remote sensing to assist in increasing production while reducing farm drudgery, expensive inputs, water and fuel use, and mitigating greenhouse gas emissions.
He also highlighted efforts to create a skilled work force, pointing to CIMMYT’s collaboration with the Bangladesh Agricultural Research Institute (BARI) on appropriate agricultural mechanization and USAID-supported work with over 50 machinery manufacturers across the country.
“This historical legacy, alongside world-class scientists and committed staff, germplasm collection, global impact in farmer’s fields, next generation research and global network of partners have made CIMMYT unique,” explained Kropff during his closing remarks, which focused on the organization’s research and collaboration on climate-smart and conservation agriculture, high-yielding, stress- and disease-tolerant maize and wheat variety development, value chain enhancement, market development, precision agronomy and farm mechanization in Bangladesh.
He expressed his gratitude towards the Government of Bangladesh for supporting CIMMYT as an international public organization in the country, thus enabling it to continue delivering impact, and for recognizing the benefits of the transition to a more integrated network of international research centers through One CGIAR, under which CIMMYT and other centers will strengthen their support to the government to help Bangladesh achieve zero hunger.
To the first-time observer, the aftermath of a fall armyworm infestation must be terrifying. The larvae can cause significant damage to an entire field in a single night, leaving once-healthy leaves looking like tattered rags.
A new instructional video, which will air in Bangladesh, aims to combat both the pest and the distress its appearance can cause with detailed, actionable information for farmers. The video describes how to identify the pest, its lifecycle and the kind of damage it can do to maize — among other crops — and provides techniques for identifying, assessing, and combating an infestation.
This video was developed by the International Maize and Wheat Improvement Center (CIMMYT) with support from the Department of Agricultural Extension (DAE) and the Bangladesh Wheat and Maize Research Institute (BWMRI), as part of the project Fighting back against fall armyworm in Bangladesh. Supported by USAID’s Feed the Future Initiative and Michigan State University, this CIMMYT-led project works in synergy with the Cereal Systems Initiative for South Asia (CSISA), and with national partners to mitigate the impact of this invasive pest on smallholder farmers’ livelihoods.
The video is available in Bangla with English captions.
