Narain Dhar
Narain Dhar is a research fellow working with CIMMYTâs Global Wheat program and CGIAR Research Program on Wheat (WHEAT). His recent work is on charaterization and evaluation of a unique set of germplasm lines for abiotic stress.
Location: Asia
As a fast growing region with increasing challenges for smallholder farmers, Asia is a key target region for CIMMYT. CIMMYTâs work stretches from Central Asia to southern China and incorporates system-wide approaches to improve wheat and maize productivity and deliver quality seed to areas with high rates of child malnutrition. Activities involve national and regional local organizations to facilitate greater adoption of new technologies by farmers and benefit from close partnerships with farmer associations and agricultural extension agents.
Vijayalaxmi Dundappa Khed
Vijayalaxmi D Khed started her career as a Consultant with the CIMMYT team and later became Associate Scientist in the Sustainable Agrifood Systems (SAS) program. She is involved in various CIMMYT projects like the Cereal Systems Initiative for South Asia (CSISA), Accelerating Genetic Gains in Maize and Wheat (AGG), and Happy Seeder impact assessments.
Her major research interests include technology adoption, impact assessment, gender studies, agriculture development, and farm-household consumption dynamics. Currently, she is working on gender dimensions of norms, caste, decision-making, and workload.
Roshan Kumar Mishra
Roshan Kumar Mishra is a Human Resources Analyst working with CIMMYT.
Pushpender Singh
Pushpender Singh is an Office Auxiliary working with CIMMYT.
Mutasim Billah
Mutasim Billah is a Data Specialist working with CIMMYTâs Sustainable Intensification program.
Jannatul Ferdous Asha
Jannatul Ferdous Asha is a Machinery Development Officer working with CIMMYTâs Sustainable Agrifood Systems (SAS) program in Bangladesh. She joined CIMMYT in 2019.
Asha completed an undergraduate degree in agricultural engineering and a masters degree in farm power and machinery at Bangladesh Agricultural University.
Taming wheat blast
As wheat blast continues to infect crops in countries around the world, researchers are seeking ways to stop its spread. The disease â caused by the Magnaporthe oryzae pathotype Triticum â 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 â including using and promoting resistant varieties, using fungicides, and deploying strategic agricultural practices â 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 fungusâ spores can travel on the wind, it could spread to neighboring countries, such as China, India, Nepal and Pakistan â 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.
âThe 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,â said Pawan Singh, CIMMYTâs 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 worldâs governments. The paper recommends quarantining potentially infected grain and seeds before they enter a new jurisdiction.
Governments can also create wheat âholidaysâ, 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 blastâs airborne and wind-flung spores. In 2017, India banned wheat cultivation within five kilometers of Bangladeshâs border, for instance. The paper also recommends that other crops â such as legumes and oilseed â that cannot be infected by the wheat blast pathogen be grown in these areas instead, to protect the farmersâ 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.
âBut the resistance is still limited. It is still quite narrow, basically one single gene,â 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 blastâs impact.
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 â as well as identifying and deploying more resistant genes within the wheat â 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.
âMultiple approaches need to be taken to manage wheat blast,â he said.
Climate-smart strategy for weed management proves to be extremely effective
Rice-wheat cropping rotations are the major agri-food system of the Indo-Gangetic Plains of South Asia, occupying the region known as the âfood basketâ of India. The continuous rice-wheat farming system is deceptively productive, however, under conventional management practices.
Over-exploitation of resources leaves little doubt that this system is unsustainable, evidenced by the rapid decline in soil and water resources, and environmental quality. Furthermore, continuous cultivation of the same two crops over the last five decades has allowed certain weed species to adapt and proliferate. This adversely affects resource-use efficiency and crop productivity, and has proven to negatively influence wheat production in the Western Indo-Gangetic Plains under conventional wheat management systems.
Studies suggest weed infestations could reduce wheat yields by 50-100% across the South Asian Indo-Gangetic Plains. Globally, yield losses from weeds reach 40%, which is more than the effects of diseases, insects, and pests combined.
Herbicides are not just expensive and environmentally hazardous, but this method of chemical control is becoming less reliable as some weeds become resistant to an increasing number common herbicides. Considering the food security implications of weed overgrowth, weed management is becoming increasingly important in future cropping systems.
How can weeds be managed sustainably?
Climate-smart agriculture-based management practices are becoming a viable and sustainable alternative to conventional rice-wheat cropping systems across South Asia, leading to better resource conservation and yield stability. In addition to zero-tillage and crop residue retention, crop diversification, precise water and nutrient management, and timing of interventions are all important indicators of climate-smart agriculture.
In a recently published 8-year study, scientists observed weed density and diversity under six different management scenarios with varying conditions. Conditions ranged from conventional, tillage-based rice-wheat system with flood irrigation (scenario one), to zero-tillage-based maize-wheat-mung bean systems with subsurface drip irrigation (scenario 6). Each scenario increased in their climate-smart agriculture characteristics all the way to fully climate-smart systems.
At the end of 8 years, scenario six had the lowest weed density, saw the most abundant species decrease dramatically, and seven weed species vanish entirely. Scenario one, with conventional rice-wheat systems with tillage and flooding, experienced the highest weed density and infestation. This study highlights the potential of climate-smart agriculture as a promising solution for weed suppression in northwestern India.
Read the full study: Climate-smart agriculture practices influence weed density and diversity in cereal-based agri-food systems of western Indo-Gangetic plains
Cover image: Farmer weeding in a maize field in India. (Photo: M. Defreese/CIMMYT)
A new tool to strengthen the fight against fall armyworm in Asia
Together with the United States Agency for International Development (USAID) and Feed the Future, the International Maize and Wheat Improvement Center (CIMMYT) and the CGIAR Research Program on Maize (MAIZE) are pleased to announce the release of âFall Armyworm in Asia: A Guide for Integrated Pest Management.â
The publication builds on intensive, science-based responses to fall armyworm in Africa and Asia.
âI have encountered few pests as alarming as the fall armyworm,â wrote USAID Chief Scientist Rob Bertram in the guideâs Foreword. âThis publication … offers to a broad range of public and private stakeholders â including national plant protection, research and extension professionals â evidence-based approaches to sustainably manage fall armyworm,â Bertram adds.
âPartners from a wide array of national and international institutions have contributed to the mammoth task of formulating various chapters in the guide,â said B.M. Prasanna, director of CIMMYTâs Global Maize Program and of MAIZE. âWhile the publication is focused on Asia, it provides an updated understanding of various components of fall armyworm integrated pest management that could also benefit stakeholders in Africa.â
In January 2018, CIMMYT and USAID published a similar guide on integrated pest management of fall armyworm in Africa, which reached a large number of stakeholders globally and is widely cited. Prasanna spearheaded the development and publication of both guides.
The current publication also follows CIMMYTâs announcement of three fall armyworm-tolerant elite maize hybrids for sub-Saharan Africa.
ICAR Organized âState Level Maize Dayâ in Haryana
The Indian Council of Agricultural Research (ICAR), together with CIMMYT and partners, organized a State Level Maize Day in the state of Haryana to discuss sustainable maize production systems for future generations.
Read more: https://krishijagran.com/agriculture-world/icar-organized-state-level-maize-day-in-haryana/
CIMMYT scientists join 60th All India Wheat and Barley Research Workersâ Meet
The International Maize and Wheat Improvement Centerâs (CIMMYT) legacy of work with the Indian Centre for Agricultural Research (ICAR) has once again produced more successful collaborations this year. This solid partnership resulted in the release of new varieties poised to bring new, superior yielding, disease-resistant, high-quality wheat varieties suitable for different production environments to Indian farms.
The National Variety Release Committee announced the release of nine new varieties at the 60th All India Wheat and Barley Research Workersâ Virtual Meet on August 23â24, 2021, hosted by the Indian Institute of Wheat and Barley Research (IIWBR) of ICAR. Of the nine new varieties identified, five were selected by national partners from CIMMYT international trials and nurseries.
At the event, ICAR-IIWBR director Gyanendra Pratap (GP) Singh highlighted the impressive growth trajectory of Indiaâs wheat production, estimated at 109.52 million tons of wheat harvested in 2021, a figure which was 86.53 million tons in 2015 and less than 60 million tons in 1991. Singh highlighted that this success is dependent upon the deployment of superior wheat varieties, bridging yield and information gaps, strengthened seed value chain, supportive government policies and, of course, farmer support to adopt new varieties and technologies.
The CIMMYT-derived varieties announced at the meeting include DBW296, DBW327, DBW332, HUW296 and JKW261. A few days earlier, variety PBW869 was released by the Punjab Agricultural University for growing in Punjab State under conservation agriculture practices.
âAn innovative and powerful feature of ICAR-CIMMYT collaboration has been the introduction of long-term (10-month) rotational involvement of Indian young scientists in CIMMYTs breeding program at Mexico as well as in wheat blast screening in Bolivia,â said Arun Joshi, CIMMYT Regional Representative for Asia and Managing Director, Borlaug Institute for South Asia (BISA). âIn this way, the breeding program of CIMMYT is an excellent example of joint breeding program with national institutions.â
Beyond expectations
In addition to these important new wheat varieties, some CIMMYT-derived wheat varieties that were released in recent years have now been deemed suitable for regions beyond their initial region of cultivation, showing wide adaptation and yield stability.
Wheat variety DBW222, released in 2020 for the northwestern plain zone, has now been deemed suitable for cultivation in the northeastern plain zone. Similarly, DBW187, which was initially released for the northeastern plain zone, and then for northwestern plain zone as well for early sowing, is now also extended for sowing in the central zone, together representing 25 million hectares of the 31 million hectares of wheat grown in India.
âFarmers prefer these types of varieties that give them flexibility during sowing time, and have high, stable yields, and disease resistance,â GP Singh said at the meeting.
A major achievement discussed at this yearâs event was that three of the new varieties â DBW187, DBW303 and DBW222 â achieved record-high demand in Breeders Seed Indent, with first, second and seventh ranks, respectively. This is a reflection and indirect measure of popularity and demand for a variety. IIWBRâs innovative strategy to implement pre-release seed multiplication and create demand for seeds from new varieties has led to a faster turnover of improved varieties.
According to Ravi Singh, Distinguished Scientist and Head of Global Wheat Improvement at CIMMYT, the collaborators are âfurther expanding our partnership through the support from the Accelerating Genetic Gains in Maize and Wheat (AGG) and zinc-mainstreaming projects, to expand testing of larger sets of elite lines in targeted populations of environments of the four South Asian countries where various IIBWR-affiliated institutions shall expand testing in the 2021â22 crop season.â CIMMYT looks forward to continuing ongoing and new collaborations with the ICAR-IIWBR programs to deliver even faster genetic gain for yield and grain zinc levels in new varieties, he explained.
Speaking during the meeting Alison Bentley, Director of CIMMYTâs Global Wheat Program, highlighted the collaborative efforts underway as part of the AGG project to accelerate breeding progress. âInnovations and discoveries in breeding approaches are being rapidly made â with further investment needed â to quickly and equitably accumulate and deploy them to farmers,â she said.
Agricultural scientist Balwinder Singh awarded ‘Alumnus of the Year’ by a prestigious Australian university
The Indian researcher leads CIMMYTâs environmental analytics work in South Asia, combining field experimentation, participatory engagement and cropping systems modelling to address the regionâs productivity and sustainability challenges in cereal systems.
Charles Sturt University (CSU) awarded him with the 2021 Alumnus of the Year title in Professional Achievement (Research) as part of its Foundation Day celebrations on July 21.
Building resilient and sustainable irrigation for food security in Nepal
In Nepal, agriculture contributes to a third of gross domestic product and employs about 80% of the rural labor force. The rural population is comprised mostly of smallholder farmers whose level of income from agricultural production is low by international standards and the country‘s agricultural sector has become vulnerable to erratic monsoon rains. Farmers often experience unreliable rainfall and droughts that threaten their crop yields and are not resilient to climate change and water-induced hazard. This requires a rapid update of the sustainable irrigation development in Nepal. The Cereal Systems Initiative for South Asia (CSISA) Nepal COVID Response and Resilience short-term project puts emphasis on identifying and prioritizing entry points to build more efficient, reliable and flexible water services to farmers by providing a fundamental irrigation development assessment and framework at local, district and provincial levels.
Digital groundwater monitoring system and assessment of water use options
Digital system of groundwater data collection, monitoring and representation will be piloted with the government of Nepal to facilitate multi-stakeholder cooperation to provide enabling environments for inclusive irrigation development and COVID-19 response. When boosting the irrigation development, monitoring is fundamental to ensure sustainability. In addition, spatially targeted, ex-ante assessments of the potential benefits of irrigation interventions provide insights by applying machine-learning analytics and constructing data-driven models for yield and profitability responses to irrigation. Furthermore, a customized set of integrated hydrological modeling and scenario analyses can further strengthen local, district and provincial level assessment of water resources and how to build resilient and sustainable water services most productively from them.
Toward a systemic framework for sustainable scaling of irrigation in Nepal
Through interview and surveys, the project further builds systemic understanding of the technical, socioeconomic and institutional challenges and opportunities in scaling water access and irrigation technologies. This will contribute to the construction of a comprehensive irrigation development framework, achieved by the collective efforts from multiple stakeholders across different line ministries, levels of government and local stakeholders and water users. Together with the technical assessments and monitoring systems, the end goal is to provide policy guidelines and engage prioritized investments that ensure and accelerate the process of sustainable intensification in irrigation in Nepal.
This blog was originally published in Agrilinks.
Indiaâs Groundwater Is In Trouble. And It Could Cause a Food Shortage for Millions By 2025, Study Finds
A recent study of the groundwater in India revealed that, by 2025, large areas of the north-western and southern parts of the country will have âcritically low groundwater availabilityâ, leading to a decrease in cropping that will ultimately cause an imbalance in the food security for millions.
Preventing and protecting against wheat blast
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 countriesâ wheat crops. But the disease spreads quickly, and when the conditions are right thereâs a risk of a large outbreak â 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 â the country where wheat blast was originally discovered in 1985.
The International Maize and Wheat Improvement Center (CIMMYT), the Brazilian Agricultural Research Corporation (EMBRAPA), Â Brazilâs 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.
âIt can be very severe. It can cause a lot of damage,â says MaurĂcio 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 â texts or emails â 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.
âIf the pathogen has already affected the plant, the fungicides will have no effect,â 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 â shortly after its discovery â 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 regionâs wheat production by 85 million tons.
In Brazil, wheat blast outbreaks can have a marked impact on the countryâs 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.
âPeople forget about the disease, then you have an outbreak again,â 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 âhomecomingâ 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.
âFrom 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,â he says.
Read more: Towards an early warning system for wheat blast: epidemiological basis and model development