Agriculture is largely feminized in Nepal, where over 80% of women are employed in the sector. As a result of the skills gap caused by male out-migration, many women farmers are now making conscious efforts to learn techniques that can help improve yields and generate greater income — such as balanced fertilizer application — with support from the International Maize and Wheat Improvement Center (CIMMYT).
Studies have shown that many farmers lack knowledge of fertilizer management, but balanced fertilizer application using the right ratio of nutrients is key to helping crops thrive Through the Nepal Seed and Fertilizer (NSAF) project, CIMMYT researchers are working towards promoting precision nutrient management through multiple trials and demonstrations in farmers’ fields.
Through this initiative, Dharma Devi Chaudhary, a smallholder farmer from Kailali district, has been able to increase her annual earnings by adopting balanced fertilizer application in cauliflower cultivation — a key cash crop for the winter season in Nepal’s Terai region.
Her inspiration to use micronutrients such as boron came from the results she witnessed during a CIMMYT-supported demonstration conducted on her land in 2018. During the demonstration, Chaudhary learned the principles of the four ‘Rs’ of nutrient stewardship: the right rate, the right time, the right source and the right placement of fertilizers. She became familiar with different types of fertilizer and the amount to be used, as well as the appropriate time and place to apply urea top-dressing, diammonium phosphate (DAP) and muriate of potash (MoP) for optimal utilization by the plant.
Chaudhary also learned how boron application can increase crop yields while helping prevent plant diseases, especially in cauliflower, where boron deficiency can lead to a disorder known as ‘dead heart’ and cause significant yield loss. This is particularly useful knowledge for farmers in Nepal, where the boron content in soil is generally low.
A digital soil map developed by researchers on the NSAF project shows medium-to-high boron deficiency in Kailali district. (Map: CIMMYT)
Benefitting from best practices
Cauliflower is cultivated on 615 hectares of land across Kailali and produces a yield of 15 tons per hectare — far less than the potential yield of 35-40 tons. As a standard practice, farmers in the area have been applying nitrogen, phosphorous and potassium (NPK) at a ratio of 27: 27.6: 9 kilograms per hectare and three tons of farmyard manure per hectare. During a CIMMYT-led demonstration on a small parcel of land, Chaudhary observed that balanced fertilizer application yielded about 64% more than when using her traditional practices, fetching her an income of $180 that season compared to her usual $109.
Following this demonstration, Chaudhary decided to independently cultivate cauliflower on a plot of 500 square meters, where she applied farmyard manure two weeks before transplantation and then used DAP, MOP, boron and zinc as a basal application during transplanting. She also applied urea in split doses, first at 25 days and then 50 days after transplantation. Using this technique, Chaudhary was able to yield 46 tons of cauliflower per hectare, nearly twice as much as was yielded by farmers using traditional practices. As a result, she was able to generate an income increase of $800 for her household, compared to the previous season’s earnings.
“I was able to buy education resources, clothing and more food supplies for my children with the additional income I earned from selling cauliflower last year,” said Chaudhary. “Learning about the benefits of using micronutrients is essential for smallholder farmers like me who are looking for ways to improve their farming business.”
Smallholder farmers tend to be risk averse, which can make technology adoption difficult. However, on-farm demonstrations help reduce the risks farmers perceive and facilitate new technology adoption easily by exhibiting encouraging results.
Chaudhary now serves as a lead farmer at Janasewa Krishak Multi-purpose Cooperative and supports the organization by disseminating knowledge on balanced fertilizer management practices to hundreds of farmers in her community. After seeing the impact of adopting the recommended techniques, the use of balanced fertilizer is reaping benefits for other farmers in her district, helping them achieve better income from higher crop yields and maintain soil fertility in their area.
Dharma Devi Chaudhary (right) stands next to her flourishing cauliflower crop in Kailali, Nepal. (Photo: Uttam Kunwar/CIMMYT)
Agricultural production in Bangladesh is heavily dependent on machines for land preparation, irrigation, pest control, harvesting and transport. Small enterprises that make up the light engineering sector in Bangladesh are responsible for the creation, maintenance and repair of these machines. Without a functioning light engineering sector, agricultural production would quickly grind to a halt.
As with other industries in the country, most light engineering workshops closed at the beginning of the COVID-19 pandemic. However, as restrictions on movement eased and in response to demand from agricultural machinery operators, the machinery manufacturing and repair workshops have started to open again.
Worker washes hands in agricultural machinery workshop with water tank provided through the Cereal Systems Initiative for South Asia Mechanization Extension Activity, funded by the United States Agency for International Development Feed the Future initiative. (Photo: Rashed/CIMMYT)
Ensuring COVID-19-free workshops
To ensure a safe and hygienic return to work, the Cereal Systems Initiative for South Asia Mechanization Extension Activity (CSISA-MEA) provided water tanks with handwashing points and knapsack sprayers to 50 workshops employing 1,624 staff in Bogura and Jashore to disinfect the workshops and tools. To create awareness on COVID-19 prevention and guide staff on using the handwashing points and sprayer, the CSISA-MEA team distributed low text graphics-based user guides and WHO designed flyers. The flyers also show staff the precautions they should take at home to prevent COVID-19 infection.
Since behavior change is a complex process, the use of more than one approach is often needed. Therefore, workshop owners and workers were sent SMS messages weekly, reminding them of the need to wash hands, disinfect the workspaces and practice other COVID-19 mitigation actions such as maintaining social distance and wearing face masks.
Staff disinfect the machines each day before working. (Photo: Rashed/CIMMYT)
Ahsan Habib, a workshop owner in Bogura, said, “This equipment is a blessing for my workers and me. I have 35 workers and before, they had to use the small tank for handwashing, which was not adequate for many people. Now I can ensure their safety. At the same time, we disinfect the machines with the sprayer before we start working.”
The relatively small investments in equipment and provision of information provided through this USAID-supported activity has helped 50 small companies operate safely in the pandemic. The new equipment and practices allow them to make and repair the machinery that keeps agricultural production running in Bangladesh and contributes to ensuring national food security.
Rural women in Nepal significantly contribute to food security, and when they are empowered, they can create avenues for agricultural growth. As seed producers are often disadvantaged in terms of accessing advanced agricultural knowledge and seed production skills, one opportunity for growth is strengthening the capacity of women seed producers.
“In more than 80% of households in Sindhupalchowk district, women have the final say on the selection of maize variety,” said D.B. Bhandari, managing director of Hairyali Community Seed Company (HCSC). “This urged me to engage women in seed production of preferred maize varieties for the mid-hills.”
HCSC, a partner company of the Nepal Seed and Fertilizer (NSAF) project implemented by the International Maize and Wheat Improvement Center (CIMMYT), is working to improve the business literacy of rural women to support their involvement in seed production and marketing of maize, wheat and rice seeds in Sindhupalchowk district, Bagmati province, Nepal.
Seed producers attend an orientation on the production and marketing of hybrid seed. (Photo: Dharma Dawadi/CIMMYT)
A path to empowerment and income
Access to agricultural inputs such as seed and fertilizer is challenging in Thulosirubari village due to its rural location and absence of agrodealers or nearby markets. Progressive farmers Parbati Gautam and Kamala Gautam, who grew up in the village in a family that has cultivated maize for generations and now grow maize, rice, millet and vegetables, found a solution. They decided to establish a cooperative —Thulosirubari Mahila Krishi Sahakari Sanstha — that not only eases the supply of seed for farmers in their village but also engages in seed production. The cooperative has 45 female members so far.
In coordination with HCSC and the Government of Nepal’s Prime Minister Agriculture Modernization Project (PMAMP), orientation programs and women-only trainings were designed and organized by the NSAF project so farmers could boost their seed production efficiency and profitability at the grassroots level. The partnership between CIMMYT, HCSC and PMAMP provided technical and financial support to these groups, improved their entrepreneurship skills and business literacy, and created marketing linkages between the farmers and buyers. Thirty-five women were trained in the use of good agricultural practices in quality seed production and marketing of hybrid maize, rice and tomato seeds. HCSC supported the women with male and female lines of hybrid maize — Khumal hybrid-2 — to produce first generation seeds and build their skills on estimating ratios for sowing seeds, balanced fertilizer application, weeding, rouging and detasseling.
“I am so happy to learn about the importance of having different male and female lines and how to maintain their quality for crossing to produce first generation of hybrid maize seeds,” Kamala Gautam said.
After getting the required training and technical support, seven farmers from the cooperative, including Kamala and Parbati, collectively produced 1.1 mt of Khumal hybrid-2 with the value of $2,514, which was sold to HCSC in 2019. As the cooperative is a contract seed producer for HCSC, the women have market assurance and do not worry where and how to sell their seed.
“My husband and I are not educated,” Parbati Gautam explained. “However, I was able to sell the hybrid maize seed then use the money to buy decent clothes and offer a better education to my two daughters and son.”
A woman stands in her rice seed production field in Nepal. (Photo: Mohan Mahato/CIMMYT)
Women empowering women
Parbati Gautam has served as chairperson at the cooperative for eight years, where she has mentored other seed producers. Based on her experience, women who have access to information and seed production technologies tend to have better crop yields and make informed decisions to increase their incomes and livelihoods.
According to Bhandari, farmers’ preferences are gradually shifting from local to hybrid varieties which offer better yields, early maturity and resilience to the effects of climate change. Parbati and Kamala Gautam confirm this, sharing that hybrid seed production provides 4-5 times more monetary value per kilogram of seed than that of grain.
“Although the cost of parent lines is expensive for seed production, improved farming technology ensures better quality seeds, higher yields and attractive farm business opportunities,” Parbati Gautam explained.
Since 2017, NSAF project researchers have been working to establish linkages with partner seed companies for seed marketing. Altogether, about 300 mt of maize and rice seed was produced by women farmers engaged in the project with the value of $112,000, and 80 percent of this seed was sold to three private seed companies including HCSC. In 2019, the NSAF project team established partnerships with an additional three cooperatives in Banke, Dang and Sindhupalchowk districts, where over 800 women are members.
The project’s engagement of women’s seed producer groups is an example of an inclusive seed business model where farmers decide what to grow and how to sell. This intervention can be piloted in other parts of Nepal where women account for over 60 percent of the rural farming community. Targeted and sustained interventions to increase women’s business agility, technical capacity in quality seed production, and market linkages will help boost productivity at household level and the country at large.
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.
Masuriya, a rural village in Nepal’s Gauriganga municipality, was one of the villages affected during the country’s civil war which ran from 1996-2006. Since 2012, Bandana Joshi, chairperson of a local cooperative, has been encouraging women in her village to optimize fertilizer application to maximize plant growth and profitability, and improve livelihoods. However, her journey to this day was not an easy one.
In the years of the civil war, women in the villages like Masuriya faced the burden to make ends meet for their children and elderly family members, as most men fled in fear of war or migrated to earn income. It was during this time that Joshi and a group of 24 women who were operating a savings and credit firm realized that more women in their village needed monetary support to carry out their livelihood activities. They decided to expand their services and formed a cooperative to empower rural women and make finance available in the village. Their cooperative, Sana Kisan Sahakari Sanstha Limited, now has 1,186 women members, more than half of whom belong to marginalized communities – 514 Janajatis and 154 Dalits.
Many of the members are small commercial farmers, owning about 1.4 ha of land for farming as their sole source of income. Most have traditionally grown cereals such as rice and wheat alongside a few vegetables and had limited knowledge on cash crop farming and soil fertility management. They would produce and sell their surplus rice and wheat when they needed cash to buy groceries or pay household bills.
Cooperative member prepares cauliflower for marketing. (Photo: Uttam Kunwar/CIMMYT)
In October 2016, researchers from the International Maize and Wheat Improvement Center’s (CIMMYT) Nepal Seed and Fertilizer (NSAF) project and the International Fertilizer Development Center (IFDC), launched an integrated soil fertility management (ISFM) program and worked alongside the cooperative to disseminate and encourage the use of ISFM technologies among its members. The purpose was to show farmers the benefits of ISFM – an integration of organic inputs and inorganic fertilizers with improved seeds – for rice, wheat and cauliflower cultivation, that includes balanced fertilizer application to increase yield. The project team conducted research trials and on-farm demonstrations on these crops as part of the initiative and built capacity through farmer field days and trainings on best management practices.
As a strategic entry point, the cooperative in coordination with female community volunteers helped implement the ISFM program. Women received training on the right source and amount of fertilizer that matches crop needs, and the right time and place to apply these fertilizers to maximize nutrient uptake and improve crop yields. NSAF researchers engaged with lead farmers and the cooperative’s leadership to influence their acceptance of the new fertilizer application practices, and they in turn motivated the members to use balanced fertilizer application. In 2020, these activities have been critical in building awareness on balanced fertilizer application for more than 800 farmers on over 700 ha of land, with each household able to raise their crop productivity by at least 50% for vegetables and 25% for cereals.
Better soil, better harvest
So far, the use of balanced fertilizer application has benefited more than a hundred members of the cooperative by gaining an average income of $219 in a season from cultivating cauliflower – a cash crop in Nepal’s Terai region. This additional return has helped farmers to adequately feed an average family of 4.5 people for the entire year.
Dutrani Chaudhary, a cooperative member, said that she was able to raise cauliflower production by 64% by applying balanced fertilizers that supplied all the essential nutrients – nitrogen, phosphorus, potash and micro-nutrient boron. She earned about $238 from 0.033 ha of land, which is a much larger gain for any farmer from a single season. As well as boosting her pride and confidence, she can now contribute for her children’s school fees and household expenditures.
After witnessing positive results, many other farmers in the village started applying major nutrients using urea, DAP (Di-ammonium Phosphate) and MoP (Muriate of Potash) to increase crop productivity. In 2017, Joshi and her members noticed a sharp rise in fertilizer procurement from the cooperative among farmers resulting in almost double the sales compared to 2015. Prior to the project’s agronomic literacy programs on soil fertility management, she sold merely 15 tons urea and 10 tons of DAP. Thereafter, fertilizer sales increased to 32.6 tons and 27.9 tons, for urea and DAP respectively, in just two years.
“For the first time in 2018 we sold 500 kilograms of MoP since the cooperative established,” explained Joshi. MoP was never considered a priority by the farmers before and they rarely purchased it from the cooperative.
Women participating in farmer field day of cauliflower in Masuriya. (Photo: Uttam Kunwar/CIMMYT)
On the rise
Now more organized and well-equipped, the cooperative has started organizing programs this year on off-seasonal and seasonal vegetable cultivation on crops such as tomato, cauliflower and cucurbits that have aided around 150 member households. “We have prioritized balanced fertilizer application in our vegetable production program,” says Madhuri Chaudhary, manager of the cooperative.
The woman-led rural institution has achieved remarkable success over the years by learning and adopting best agronomic practices including fertilizer application, planting and cultivation methods that helped increase crop productivity and household income. Having seen the benefits, male family members now encourage them to participate in agronomic literacy programs to acquire advanced knowledge and skills.
Joshi and her team of visionary women have been successful in setting up an inclusive new movement in Masuriya village, which has led to their active participation in development activities and decision-making roles not only at the household level but also in societal issues around women’s rights. Passionate to learn new skills and grow financially independent, these rural women are confident in making their own decisions for themselves, their family and for the wider society. Although it started small, the cooperative has now boomed towards improving rural women’s economic empowerment and sparking better livelihood opportunities in the area.
Cover photo: Balanced nutrient management helps farmer Dharma Devi generate better household income from cauliflower cultivation. (Photo: Uttam Kunwar/CIMMYT)
It is a general perception, globally and in Bangladesh, that women do not have a role in the agricultural mechanization sector. However, a deeper look into the sector shows a different reality. Women in Bangladesh are owners and managers in businesses supported by the Cereal Systems Initiative for South Asia Mechanization Extension Activity (CSISA-MEA), funded by the United States Agency for International Development (USAID) Feed the Future initiative.
Professions have no gender
Poly Rani married her husband, Poritosh Kumar Malo, when she was 15. He is an engineer who established his own machine manufacturing business, RK Metal Ltd of Faridpur. As the business expanded Rani began to help her husband with office administration work, leaving him time to supervise the manufacturing side.
“After my marriage, my husband asked me to spend some time in his shop, as he was busy with his job. I never thought I would work in a mechanical workshop where everything is related to machines and male-dominated. Eventually, I started to like it, and now it is my passion. I know every machine and their functions very well. Therefore, when customers arrive, I can explain things,” Rani said.
With support of CSISA-MEA, their business has expanded quickly, now employing 15 staff and manufacturing 38 types of small machines such as rice threshers, corn shellers and fodder choppers. They sell up to 400 machines a year. As the couple expanded the business, Rani’s administrative role became more important and diverse. She now manages the finances and takes orders for machines, using Facebook and YouTube.
“I wish I was a bit more educated and knew better these technical things. I have a dream that one of my daughters will become an engineer and join our workshop, because professions have no gender — we put gender identity with professions. I can cook, raise children and manage a business as well.”
Poly Rani uses machinery at her workshop. (Photo: Poritosh Malo)
Seedlings of change
It is rare for women in Bangladesh to run businesses that provide farmers with mechanization services. One exception is a group of nine women from Baliakandi Upazila in Rajbari District. They have owned and provided planting services for four years using a power tiller operated seeder (PTOS), which annually earns them approximately $500 each. However, this machine cannot transplant rice.
Rice transplanting is a major labor-consuming activity in Bangladesh, where workers manually transplant 11 million hectares of rice each year. A new machine, called the rice transplanter, is being introduced to Bangladesh. However, to transplant rice seedlings with this machine, the seedlings have to be raised on plastic sheets so they have a mat of roots that allows the machine to pick them up and plant them. With the growing popularity of these machines, the women’s group saw raising these seedlings as a good business opportunity. After learning the seedling raising technology from CSISA-MEA, they have produced and sold seedlings sufficient for 10 hectares. The next step is to buy a rice transplanter!
Women’s group works in the field. (Photo: Sourov Dey)
Gender gap
Jorina Begum is the sole breadwinner of her family at 25, caring for her mother, four-year-old son and two disabled siblings in Ramnagor, Sadar, Jashore. After her father’s death when she was ten years old, Begum had to abandon school and start working as a foundry cleaner. She married at an early age and quickly became a mother, but immediately after her son’s birth, her husband left her.
She now works in a foundry where she paints machine parts. “My wage is 75% less than the male workers,” said Begum. “I get only 200 taka [$2] per hour. I work the same hours as the men do but I am paid less, because I cannot do the heavy work and I do not have training.”
In foundries and machinery workshops, women are considered less productive than men. “If I could receive some training, I could perform better and earn more, which will benefit my employer and my family,” said Begum.
To respond to this need, CSISA-MEA is working to raise women’s capacity to work in the agricultural mechanization sector and manage machinery-based businesses through technical and business training. Through these opportunities, more women like Rani and Begum will be able to contribute to the development of this sector.
Cover photo: Jorina Begum works in the foundry workshop. (Photo: Touhidur Rahman)
When we talk about the impact of agricultural research we often rely on numerical metrics: percent increase in yield, percent decrease in crop loss, adoption rates, etcetera. For farmers on the ground, however, the impact can be much harder to boil down to a few numbers. Hiding behind every statistical table are real stories of dreams dashed or fulfilled, of everyday people trying to survive and flourish.
A new educational video powerfully dramatizes this point through the story of Jamal Mia and his daughter Rupa. Jamal’s dreams to own a house and see Rupa enroll in college are threatened when his maize crop is attacked by fall armyworm. An encounter with an agricultural extension officer puts Jamal on track to tackle the infestation, save his crop and secure his family’s wellbeing.
The video was developed by CIMMYT with support from Bangladesh’s Department of Agricultural Extension and the Bangladesh Wheat and Maize Research Institute (BWMRI), as part of a project titled “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 was filmed in Dinajpur district, Bangladesh, and is available in Bangla with English captions.
Wheat blast damages wheat spikes. (Photo: Xinyao He / CIMMYT)
In an article published in Nature Scientific Reports, a team of scientists led by wheat breeder Philomin Juliana from the International Wheat and Maize Improvement Center (CIMMYT) conducted a large genome-wide association study to look for genomic regions that could also be associated with resistance to wheat blast.
Juliana and fellow scientists found 36 significant markers on chromosome 2AS, 3BL, 4AL and 7BL that appeared to be consistently associated with blast resistance across different environments. Among these, 20 markers were found to be in the position of the 2NS translocation, a chromosomal segment transferred to wheat from a wild relative, Aegilops ventricosa, that has very strong and effective resistance to wheat blast.
The team also gained excellent insights into the blast resistance of the globally-distributed CIMMYT germplasm by genomic fingerprinting a panel over 4,000 wheat lines for the presence of the 2NS translocation, and found that it was present in 94.1% of lines from International Bread Wheat Screening Nurseries (IBWSNs) and 93.7% of lines from Semi-Arid Wheat Screening Nurseries (SAWSNs). Although it is reassuring that such a high percentage of CIMMYT wheat lines already have the 2NS translocation and implied blast resistance, finding other novel resistance genes will be instrumental in building widespread, global resilience to wheat blast outbreaks in the long-term.
The researchers used data collected over the last two years from CIMMYT’s IBWSNs and SAWSNs by collaborators at the Bangladesh Wheat and Maize Research Institute (BWMRI) and Bolivia’s Instituto Nacional de Innovación Agropecuaria y Forestal (INIAF).
Devastating fungal disease
Wheat blast, caused by the fungus Magnaporthe oryzae pathotype Triticum, was first identified in 1985 in South America, but has been seen in Bangladesh in recent years. The expansion of the disease is a great concern for regions of similar environmental conditions in South Asia, and other regions globally.
Although management of the disease using fungicide is possible, it is not completely effective for multiple reasons, including inefficiency during high disease pressure, resistance of the fungal populations to some classes of fungicides, and the affordability of fungicide to resource-poor farmers. Scientists see the development and deployment of wheat with genetic resistance to blast as the most sustainable and farmer-friendly approach to preventing devastating outbreaks around the world.
This work was made possible by the generous support of the Delivering Genetic Gains in Wheat (DGGW) project funded by the Bill & Melinda Gates Foundation, the U.K. Foreign, Commonwealth & Development Office (FCDO) and managed by Cornell University, the U.S. Agency for International Development’s Feed the Future initiative, the CGIAR Research Program on Wheat (WHEAT), the Indian Council of Agricultural Research (ICAR), The Swedish Research Council (Vetenskapsråd), and the Australian Centre for International Agricultural Research (ACIAR).
The process for breeding for grain yield in bread wheat at the International Maize and Wheat Improvement Center (CIMMYT) involves three-stage testing at an experimental station in the desert environment of Ciudad Obregón, in Mexico’s Yaqui Valley. Because the conditions in Obregón are extremely favorable, CIMMYT wheat breeders are able to replicate growing environments all over the world and test the yield potential and climate-resilience of wheat varieties for every major global wheat growing area. These replicated test areas in Obregón are known as selection environments (SEs).
This process has its roots in the innovative work of wheat breeder and Nobel Prize winner Norman Borlaug, more than 50 years ago. Wheat scientists at CIMMYT, led by wheat breeder Philomin Juliana, wanted to see if it remained effective.
The scientists conducted a large quantitative genetics study comparing the grain yield performance of lines in the Obregón SEs with that of lines in target growing sites throughout the world. They based their comparison on data from two major wheat trials: the South Asia Bread Wheat Genomic Prediction Yield Trials in India, Pakistan and Bangladesh initiated by the U.S. Agency for International Development Feed the Future initiative and the global testing environments of the Elite Spring Wheat Yield Trials.
The authors found higher average heritabilities, or trait variations due to genetic differences, for grain yield in the Obregón SEs than in the target sites (44.2 and 92.3% higher for the South Asia and global trials, respectively), indicating greater precision in the SE trials than those in the target sites. They also observed significant genetic correlations between one or more SEs in Obregón and all five South Asian sites, as well as with the majority (65.1%) of the Elite Spring Wheat Yield Trial sites. Lastly, they found a high ratio of selection response by selecting for grain yield in the SEs of Obregón than directly in the target sites.
“The results of this study make it evident that the rigorous multi-year yield testing in Obregón environments has helped to develop wheat lines that have wide-adaptability across diverse geographical locations and resilience to environmental variations,” said Philomin Juliana, CIMMYT associate scientist and lead author of the article.
“This is particularly important for smallholder farmers in developing countries growing wheat on less than 2 hectares who cannot afford crop losses due to year-to-year environmental changes.”
In addition to these comparisons, the scientists conducted genomic prediction for grain yield in the target sites, based on the performance of the same lines in the SEs of Obregón. They found high year-to-year variations in grain yield predictabilities, highlighting the importance of multi-environment testing across time and space to stave off the environment-induced uncertainties in wheat yields.
“While our results demonstrate the challenges involved in genomic prediction of grain yield in future unknown environments, it also opens up new horizons for further exciting research on designing genomic selection-driven breeding for wheat grain yield,” said Juliana.
This type of quantitative genetics analysis using multi-year and multi-site grain yield data is one of the first steps to assessing the effectiveness of CIMMYT’s current grain yield testing and making recommendations for improvement—a key objective of the new Accelerating Genetic Gains in Maize and Wheat for Improved Livelihoods (AGG) project, which aims to accelerate the breeding progress by optimizing current breeding schemes.
This work was made possible by the generous support of the Delivering Genetic Gain in Wheat (DGGW) project funded by the Bill & Melinda Gates Foundation and the UK Foreign, Commonwealth & Development Office (FCDO) and managed by Cornell University; the U.S. Agency for International Development’s Feed the Future initiative; and several collaborating national partners who generated the grain yield data.
Striga, an invasive parasitic weed with purple-colored flowers, looks striking and harmless. But, beyond that mark of beauty, is a nutrient-sucking monster that stunts crops such as maize and sorghum, leaving affected farmers counting losses.
Witchweed thrives in poor soils with low rainfall conditions. It is prevalent in farming systems with poor crop management practices and in communities where farmers use minimal or no fertilizer. Once maize begins germinating in Striga-prevalent soil, it stimulates Striga seeds to germinate. Striga then attaches to the roots of the host plant, sapping nutrients from the plant, leading to stunting. The potential yield loss can reach up to 100%. Some farmers attempt to uproot it once they notice it germinating alongside their maize plantation, but this is often too late because damage is done as soon as the parasite attaches to the maize roots. When mature, the weed deposits tens of thousands of tiny seeds into the soil. This makes it very difficult for farmers to get rid of it.
To tackle this challenge, farmers need to apply inorganic fertilizer, which is not always affordable, or animal manure to enrich the soil before planting. They are also advised by researchers and extensionists to practice crop rotation or intercropping with legumes such as beans, soybean or groundnuts that restrict Striga’s germination. In the Assessment of Management Options on Striga Infestation and Maize Grain Yield in Kenya, for example, researchers recommend that Striga control measures include a combination of herbicide-resistant or maize varieties with native genetic resistance intercropped with legumes.
Nevertheless, while a few control measures have been moderately successful, the problem still persists, especially in western Kenya, eastern Uganda and lake zone of Tanzania, where farmers have frequently voiced their frustrations at the ubiquity of this invasive weed.
“While crop rotation with crops such as soybean or beans may break the cycle of Striga, its seed can stay in the soil and remain viable for up to 10 years,” says Dan Makumbi, a maize breeder with the International Maize and Wheat Improvement Center (CIMMYT), who is leading research efforts against the witchweed.
A sorghum field infested with Striga in Siaya County. (Photo: Joshua Masinde/CIMMYT)
Norah Kayugi on a Striga-infested farm in Siaya County. (Photo: Joshua Masinde/CIMMYT)
Norah Kayugi holds a bunch of Striga weeds she has uprooted on a farm she works as a casual laborer in Siaya. (Photo: Joshua Masinde/CIMMYT)
A blow to optimal yield potential
Maize is a staple crop that is predominantly cultivated by smallholder farmers in western Kenya and the lake region. It is an important source of food security and livelihoods of millions of people in the region, but constraints such as Striga prevent farmers from obtaining the crop’s ideal potential.
“The yield loss would have been adequate to cover my family’s food requirements for a year,” Naliaka said. “From two farming seasons, I could harvest a sufficient quantity of maize and sell some surplus to pay my children’s school fees. With the Striga menace, all that is but a dream.”
Just like Naliaka, Norah Kayugi, a 40-year-old widowed mother of six children from Siaya County in Kenya, has seen her maize production fall to less than 8 bags of 90kgs per acre. In normal circumstances, they would obtain at least 16 bags of maize per acre. The significant yield loss sets back many affected households in a big way, as they experience food shortage only a few months after harvest. Some divert their reduced incomes for food purchases, possibly leaving other priorities such as health and education of their children unattended.
Kayugi, who has been a farmer since 1997, now takes on casual jobs to supplement her farming in order to support her family, being the sole breadwinner following her husband’s demise years ago. “I plant vegetables, beans and maize to sustain my family. My one-acre farm yields about 10 bags of 90ks each. But I know for sure that were it not for this weed, the yield potential could reach 30 bags of 90kgs each per acre.”
A young, yet-to-flower Striga weed at the CIMMYT-KALRO Kibos Research Station in Kisumu. (Photo: Joshua Masinde/CIMMYT)
Standing up to multiple farming stresses
These smallholders, like their counterparts elsewhere in sub-Saharan Africa, already face other farming challenges, including climate change-induced droughts, pests such as the fall armyworm, diseases like maize lethal necrosis (MLN), and declining soil fertility, among others. While CIMMYT has registered breakthroughs in developing maize varieties that tolerate such stresses, on-going efforts against Striga are also taking shape, challenges notwithstanding.
The development and deployment of the imazapyr-resistant (IR) maize has been one such instance of effective Striga control. With this method, herbicide-resistant maize seeds are coated with herbicide. The seed germinates and absorbs some of the herbicide used to coat it. The germinating maize stimulates Striga to germinate and as it attaches to the maize root, it is killed before it can cause any damage. Despite its effectiveness, sustaining this technology presented a major challenge to seed companies.
“It was costly for seed companies, as they needed to establish and sustain the operation of separate seed treatment units dedicated to production of the herbicide-coated maize seed. Once you establish a line to dress the seed with the chemical, you cannot use it to treat any other seeds as the chemical will destroy them,” said Makumbi.
Seed companies — like NASECO in Uganda, Kenya Seed Company in Kenya, Western Seed Company and FreshCo in Kenya, and Meru Agro in Tanzania — obtained financial and technical support from a partnership initiative coordinated by African Agricultural Technology Foundation (AATF) and backed by CIMMYT to scale commercialisation of StrigAwayTM maize in East Africa. The initiative was funded by USAID’s Feed the Future Partnering for Innovation program through Fintrac and it supported the seed companies to establish seed treatment facilities to handle herbicide resistant maize. This allowed each of the companies to have a fully dedicated facility for herbicide resistant maize seed processing. “Right now, herbicide resistant maize hybrid seed is available on the market in Kenya, Tanzania and Uganda,” Makumbi said.
CIMMYT field technician Carolyne Adhiambo at a maize field experiment showing promise of Striga tolerance or resistance the Kibos Research station in Kisumu. (Photo: Joshua Masinde/CIMMYT)
Native hope
In the past few years, Makumbi and his team, in collaboration with the International Institute for Tropical Agriculture (IITA) and the Kenya Agricultural and Livestock Research Organization (KALRO), have redirected their efforts towards breeding for native genetic resistance to Striga. This means developing seeds which are naturally resistant to Striga, reducing the need for herbicides. The early indication is that there are several parental lines showing potential to tolerate or resist Striga, and these are being used to develop hybrids. The hybrids, which offer multiple benefits for farmers, are under wide scale testing in Kenya.
“In our tests, we are not only looking at Striga resistance alone but also other important traits such as good yield under optimal conditions, drought stress and low soil fertility, resistance to major foliar diseases including gray leaf spot, Turcicum leaf blight, maize streak virus and ear rots,” Makumbi noted.
As these breeding efforts continue, there is light at the end of the tunnel. The hope of farmers taking back full control of their maize farms from Striga’s “bewitching ways” in the near future remains alive.
The agricultural market has been suffering since the government of Nepal imposed a lockdown from March 23, 2020 to limit the spread of COVID-19 in the country. A month after the lockdown, the International Maize and Wheat Improvement Center (CIMMYT) conducted a rapid assessment survey to gauge the extent of disruptions of the lockdown on households from farming communities and agribusinesses.
As part of the Nepal Seed and Fertilizer (NSAF) project, CIMMYT researchers surveyed over 200 key stakeholders by phone from 26 project districts. These included 103 agrovet owners and 105 cooperative managers who regularly interact with farming communities and provide agricultural inputs to farmers. The respondents served more than 300,000 households.
The researchers targeted maize growing communities for the survey since the survey period coincided with the primary maize season.
Seed company staff harvesting maize during the lockdown. (Photo: Darbin Joshi/CIMMYT)
Key insights from the survey
The survey showed that access to maize seed was a major problem that farmers experienced since the majority of agrovets were not open for business and those that were partially open — around 23% — did not have much customer flow due to mobility restrictions during the lockdown.
The stock of hybrid seed was found to be less than open pollinated varieties (OPVs) in most of the domains. Due to restrictions on movement during the entire maize-planting season, many farmers must have planted OPVs or saved seeds.
Access to fertilizers such as urea, DAP and MOP was another major problem for farmers since more than half of the cooperatives and agrovets reported absence of fertilizer stock in their area. The stock of recommended pesticides to control pests such as fall armyworm was reported to be limited or out of stock at the cooperatives and agrovets.
Labor availability and use of agricultural machineries was not seen as a huge problem during the lockdown in the surveyed districts.
It was evident that food has been a priority for all household expenses. More than half of the total households mentioned that they would face food shortages if the lockdown continues beyond a month.
During the survey, around 36% of households specified cash shortages to purchase agricultural inputs, given that a month had already passed since the lockdown began in the country. The majority of the respondents reported that the farm households were managing their cash requirements by borrowing from friends and relatives, local cooperatives or selling household assets such as livestock and agricultural produces.
Most of the households said that they received food rations from local units called Palikas, while a small number of Palikas also provided subsidized seeds and facilitated transport of agricultural produce to market during the lockdown. Meanwhile, the type of support preferred by farming communities to help cope with the COVID-19 disruptions — ranging from food rations, free or subsidized seed, transportation of fertilizers and agricultural produce, and provision of credit — varied across the different domains.
The survey also assessed the effect of lockdown on agribusinesses like agrovets who are major suppliers of seed, and in a few circumstances sell fertilizer to farmers in Nepal. As the lockdown enforced restrictions on movement, farmers could not purchase inputs from agrovets even when the agrovets had some stock available in their area. About 86% of agrovets spoke of the difficulty to obtain supplies from their suppliers due to the blockage of transportation and product unavailability, thereby causing a 50-90% dip in their agribusinesses.
Seed company staff harvesting maize during the lockdown. (Photo: Darbin Joshi/CIMMYT)
Immediate actions to consider
Major takeaways from this survey are as follows:
Currently, food access is a priority and households are spending more money on food. However, as and when the lockdown eases, the need for cash to buy agricultural inputs and services is likely to emerge and may require attention.
Accessing maize seed and fertilizer was a problem in many communities during the maize season. Similarly, a shortage of rice seed, particularly hybrids, can be an issue for farmers unless efforts are made right away.
To help cope with the COVID-19 disruptions, a one-size-fits-all relief package would not be effective for farming communities living in different domains. Major support should be on facilitating transport and distribution of seed and fertilizers, access to food supplies through the local government’s schemes, and provision of soft loans.
Agrovets have an important contribution as the last mile service providers and they were hit hard by the lockdown. Therefore, facilitating agrovet businesses to operate and transport seeds, fertilizers, and pesticides from suppliers to agrovet business points will be essential to restore businesses and deliver agri-inputs to farmers.
The survey findings were presented and shared with the government, private sector, development partner organizations and project staff over a virtual meeting. This report will serve as a resource for the project and various stakeholders to design their COVID-19 response and recovery strategy development and planning.
Farmers in the Bale area, in Ethiopia’s Oromia region, mainly produce wheat and barley. Temam Mama was no different — but some six years ago, the introduction of the two-wheel tractor offered him additional opportunities. This was part of an initiative of the International Maize and Wheat Improvement Center (CIMMYT) and the Africa RISING project.
Selected as one of the two farmers in the region to test the technology, Temam took a five-day training course to understand the technology and the basics behind operating calibrating and maintaining the equipment.
The two-wheel tractor is multipurpose. By attaching various implements to a single engine, farmers can use it for ploughing, planting, water pumping, transportation, harvesting and threshing. For Temam, who had always relied on a rainfed agricultural system, the technology has high importance — he will be able to use the nearby river as a source of water for irrigation purposes.
To start off, Temam allocated 0.25 hectare from his four hectares of land for irrigation and planted potatoes for the first time. He was delighted with his harvest and the income he collected afterwards.
“From the first harvest, I was able to collect 112 quintals of potato and made roughly $1,529 in total,” said Temam.
Temam Mama checks his crops. (Photo: Simret Yasabu/CIMMYT)
Eternal returns
His productive journey had just started. This income allowed Temam to keep growing his business. He bought a horse and cart for $550 and taking the advice from the project team, he constructed a Diffused Light Storage (DLS) system to store his potatoes for longer.
To diversify his income, Temam occasionally provides transport services to other farmers. Over time, Temam’s financial capital has continued to grow, bringing new ideas and a desire to change. He went from a wooden fence to a corrugated iron sheet, to an additional three rooms by the side of his house for rentals.
He is fortunate for having access to the river and the road, he explains. He also sees new opportunities emerging as the demand for potato in the market continues to grow. The price for one quintal of potato sometimes reaches $76 and matching the demand is unthinkable without the two-wheel tractor, he says.
In addition to the two-wheel tractor, he has also bought a water pump to enable him to increase the area that he can grow irrigated potato, garlic and pepper on. His target is to have two hectares irrigated soon.
Temam Mama drives a two-wheel tractor to the irrigation area. (Photo: Simret Yasabu/CIMMYT)
The future is bright
With his wife and four children, Temam is now living a well-deserved, healthy and exemplary life. Tomato, chilli and onion now grow on his farm ensuring a healthy diet, as well as diversified and nutritious food for the family. His economic status is also enabling him to support his community in times of need. “As part of my social responsibility, I have contributed around $152 for road and school constructions in our area,” noted Temam.
Under the Africa RISING project, Temam has proven that irrigation of high-value crops using two-wheel tractor pumping really works, and that it increases production and the profitability of farming. He has now stepped into a new journey with a bright future ahead of him.
“I plan to sell my indigenous cows to buy improved breeds and, in two to three years’ time, if I am called for refreshment training in Addis Ababa, I will arrive driving my own car,” concluded Temam.
Cover photo: Temam Mama’s family eats healthy and nutritious food produced through irrigation. (Photo: Simret Yasabu/CIMMYT)
A woman sells maize at the market in Sidameika Tura, Arsi Negele, Ethiopia. (Photo: Peter Lowe/CIMMYT)
Disclaimer: The views and opinions expressed in this article are those of the authors and do not necessarily reflect the official views or position of the International Maize and Wheat Improvement Center (CIMMYT).
While all eyes are on Lombardy, Madrid, New York and Wuhan, what do we know about the impact of COVID-19 on the rural poor and on food security in developing countries? How can the impact of the crisis be moderated? What positive breakthroughs could be provoked by this shock to move us into a better “new normal”? What can donors and implementing organizations do to support low- and middle-income countries during and beyond this crisis?
Members of the Agriculture and Rural Development working group of the international Scaling Up community of practice held a virtual meeting to discuss these questions and how scaling-up innovations could help to recover from the current crisis and mitigate future ones.
Poor rural communities are particularly vulnerable
When it comes to a highly contagious disease, being in a rural area sounds better than being in a busy city, but that is a deceptive impression. Smallholder farmers often are older than average and hence more vulnerable to the virus, and they have less access to health services.
They also depend on field laborers that are not able to travel from surrounding villages to help with planting, weeding and harvesting. To process crops, smallholder farmers need to transport crops to processing centers, which may be closed, as are the markets where they obtain agricultural inputs or sell farm products. Large international agrobusiness firms, which supply inputs and purchase local famers’ products may withdraw, at least temporarily, from the rural economies. There are already reports of farmers feeding cattle strawberries and broccoli in India, as they are unable to get their goods to the market.
Most farmers also depend on non-farm and off-farm activities for their livelihoods, as they may be field laborers for other farmers, work in the processing industry or work in construction. Interrupted transportation and closures pose serious challenges to maintain safe business continuity throughout the rural economy. The risk is not only that immediate rural production, food deliveries, exports, employment and incomes will collapse, but also that planting for next year’s crops will be disrupted.
It is key to differentiate between global and local supply chains, which will suffer in different ways. For example, in Uganda, supermarkets are open but small, informal markets are closed. In past crises, governments have focused on the survival of global value chains over local ones. Small, rural businesses are more likely to close permanently than large international ones.
Globally, international support for agriculture and rural development has been lagging in recent years. Today, the international support from aid agencies and NGOs is interrupted, as travels are restricted and community meetings are prohibited. With increased donor attention to a domestic and international health crisis, aid for rural communities may drop precipitously.
Men transport wheat straw on donkey karts in Ethiopia’s Dodula district. (Photo: Peter Lowe/CIMMYT)
Opportunities for an improved “new normal” as we respond to the crisis
The short-term response to help minimize the impact of the COVID-19 crisis on the rural poor is critical, but we also need to support the shaping of a “new normal” where rural food systems are resilient, profitable and inclusive for poor rural communities. Members of the Scaling Up community of practice explored various ideas.
First, the COVID-19 pandemic could present opportunities to break silos and show how closely health and agriculture are related.
“COVID-19 cuts across sectors and jurisdictions in ways that single organizations and established governance structures are ill-equipped to accommodate,” said Larry Cooley, Scaling Expert and Founder and President Emeritus of Management Systems International (MSI)
For example, rural agricultural extension networks could be used to disseminate information on health awareness and education around COVID-19 and collect data on local impacts. This may cause and provide relief in the short term, but may also provide opportunities for collaboration in the long run.
“Our agricultural networks go deep into the rural areas and we are training our agri-entrepreneurs in India to disseminate health messages, products and services to help address COVID-19,” said Simon Winter, Executive Director of the Syngenta Foundation.
“At the African Development Bank we are providing emergency relief finance and re-purposing funding to have a link with COVID-19,” said Atsuko Toda, the bank’s Director of Agricultural Finance and Rural Development.
Second, a “new normal” could also mean an even stronger independence from externally funded projects, experts and solutions to more local ownership and expertise in rural areas, something that the community of practice has been promoting strongly. We could help to support more autonomy of the farmer, a strong local market and scale-up local value chains. Strengthening the capacity of small and medium enterprises linking farmers to urban markets could help ensure stability in future economic shocks.
“Governments and donor ‘projects’ looked too much at export and global value chains. I see great opportunities to scale up local and regional input and output value chains that benefit local farmers and small and medium enterprises,” said Margret Will, expert on value chains.
Third, the COVID-19 pandemic presents an opportunity to accelerate the scaling of innovations.
“Lack of access to labor could be disrupting harvesting and planting in our Feed the Future countries, accelerating an already predominant trend of migration, especially among the young, to urban areas. We see a looming need for mechanization of farms at scale, using mini-tillers, planters, harvesters and other time- and labor-saving equipment,” said Mark Huisenga, Senior Program Manager for the USAID Bureau for Resilience and Food Security.
Masimba Mawire collects bare maize cobs after removing the grain using a mechanized maize sheller in Zimbabwe. (Photo: Matthew O’Leary/CIMMYT)
Rural communities that use more ecological intensive practices, such as conservation agriculture and push-pull farming or safe storage practices are less dependent on external inputs and labor.
The current crisis forces us to use digital communication systems, replace human work with digital tools where possible and use technology to help target interventions. Both the public and private sector could build on this opportunity to invest in increased access to internet, electricity and other digital resources, including in impoverished areas. All these technological innovations can help farmers to better cope with the constraints of COVID-19 and any future crises or stresses to the food system, while also making agriculture more productive and more attractive to the young.
“The pandemic creates an opportunity to accelerate the use of digital technologies in smallholder agriculture, not only for extension advice but to crowdsource information about COVID-19 impacts,” said Julie Howard, Senior Advisor for the Center for Strategic and International Studies (CSIS).
Finally, COVID-19 will change our global governance system, and the agriculture, research and development sector has a role to play in this transformation. A systems change must focus on dietary diversity and food safety and security, paying attention to the rural poor in low- and middle-income countries. We can work together to scale cross-sector platforms to build solid networks and scale-up innovations to strengthen sustainable and resilient food systems.
Systems change beyond the agricultural sector, sustainability through local ownership and uptake of innovations that support profitable and resilient agricultural and related rural activities are key components of how the Scaling Up Community of Practice approaches scaling. A systems change is imminent, and it is important to support a transformation in a direction where local markets, rural labor and regional economies come out stronger in the long term. This requires vision, expertise, mobilization of resources, information sharing and crowdsourced leadership, and the network of scaling experts can contribute to this.
The Agriculture and Rural Development working group of the international Scaling Up community of practice is made up of individuals from more than 100 official donors, foundations, think tanks, research and development organizations united by their interest in scaling the impact of innovations on food security and rural poverty. Areas of particular interest for the group include designing for scale, using scaling frameworks, learning about scaling, responsible scaling, sustainability and system thinking. Members of the working group include professionals with vast experience from the field, and the group explicitly tries to learn from the application of complex concepts such as sustainability, systems change and scaling in real world settings by local actors. In addition to quarterly virtual meetings, the working group encourages and supports exchanges among its members on a variety of subjects. Participation in, and management of, the Agriculture and Rural Development working group is done on a purely voluntary basis.
About the Authors:
Lennart Woltering — Scaling catalyst at CIMMYT and chair of the Agriculture and Rural Development working group.
Johannes Linn — Non-resident Senior Fellow at Brookings and former Vice President of the World Bank.
Maria Boa — Scaling coordinator at CIMMYT and secretary of the Agriculture and Rural Development working group
Mary Donovan — Communications Consultant at CIMMYT.
Three years ago, farmers in the country were combatting the threats of a destructive tomato pest, Tuta Absoluta, and are now battling their way to manage the attack of fall armyworm on maize fields across the country. Since the government’s Plant Quarantine and Pest Management Centre (PQPMC) declared the arrival of fall armyworm on August 2019, this pest is reported to have infested almost half the districts of Nepal and continues to spread further.
“I wasn’t able to gather even half the yields I used to get from my maize field following the fall armyworm outbreak last year,” said Pavitra, a farmer from Sindhupalchowk district, Nepal.
The level of incidence and damage varies from place to place, but farmers have reported up to 80% crop loss in extreme cases. In Nepal, the fall armyworm has the potential to cause maize yield losses of 20-25%, which translates to the loss of more than half a million tons of the annual maize production — estimated at around $200 million. If the pest is left unrestrained, its impact will be huge for farmers and the economy.
This calls for a collective effort and broad mobilization to effectively manage fall armyworm and limit its spread across the country. Since the pest was expected to reach Nepal, partners have conducted workshops and community mobilization initiatives.
Experts at the International Maize and Wheat Improvement Center (CIMMYT) have been working with public and private partners before and after the arrival of the invasive pest in Nepal. The shared efforts have focused on creating awareness, disseminating appropriate technologies and management techniques, and strengthening the capacity of communities, institutions and governments.
The Ministry of Agriculture and Livestock Development has established a national taskforce to fight the pest. Most provinces have established similar taskforces that include researchers, agriculture extension agents, farmers and entrepreneur associations.
Training participants examine a fall armyworm on a maize leaf. (Photo: Bandana Pradhan/CIMMYT)
Fall armyworms are found on leaves in a maize field in Nepal. (Photo: Shailaja Thapa/CIMMYT)
A pheromone trap is installed next to a maize field in Nepal. (Photo: Bandana Pradhan/CIMMYT)
Participants in one of the trainings learn how to scout and collect data on fall armyworm in a maize field. (Photo: Bandana Pradhan/CIMMYT)
Training participants imitate the fall armyworm’s white inverted Y mark visible on the front of the head of the larva. (Photo: Bandana Pradhan/CIMMYT)
Gearing up to fight the very hungry caterpillar
In collaboration with national and provincial governments, CIMMYT has trained 426 agricultural professionals, including lead farmers, on how to identify and manage fall armyworm.
In February 2020, CIMMYT partnered with agricultural development directorates in two provinces to train 130 people on how to scout for fall armyworm and recommended solutions, based on integrated pest management principles.
In late 2019, CIMMYT engaged with the public and private sector through training workshops to disseminate proven practices to control the pest.
“Before, I was unable to recognize the pest that had destroyed my maize field. The hands-on training has been very informative,” said Urmila Banjgayu, a lead farmer who participated in one of the trainings. “I am certain to share the knowledge and practices that I learned with other farmers in my locality. They need to know what to do and what not to.”
Through the Nepal Seed and Fertilizer (NSAF) project, CIMMYT staff is working closely with the Ministry of Agriculture and Livestock Development, the Nepal Agricultural Research Council (NARC), the PQPMC, provincial governments, and other USAID-funded projects and development partners in Nepal. Together, they have developed integrated pest management packages, informative factsheets and surveillance guidelines. CIMMYT researchers have shared experiences on pest management, surveillance and scouting techniques from other countries in Asia and Africa. They have also demonstrated digital tools that will help map the spread of the pest and build accurate interpretation for better management.
Outreach workers use an auto-rickshaw equipped with a sound system and infographics to disseminate information about armyworm in Nepal’s Banke district. (Photo: Darbin Joshi/CIMMYT.)
Farmers listen to information about fall armyworm displayed on an auto-rickshaw in Nepal’s Banke district. (Photo: Darbin Joshi/CIMMYT)
Fall armyworm awareness campaign
Farmers must learn how to identify and manage this pest. Bijaya Ghimire, a lead farmer from Kanchanpur district, had heard about fall armyworm from a nearby seed company and a few of his friends. He informed the Agriculture Knowledge Center about the symptoms he observed in his maize field, and verification of the larvae and damage confirmed the presence of fall armyworm. Luckily, Ghimire was able to control the pest before severe damage was done.
CIMMYT researchers collaborated with the Prime Minister Agricultural Modernization Project (PMAMP) to implement outreach campaigns in Banke district. This included a mobile information booth, local dissemination of audio messages, and distribution of posters and fact sheets about fall armyworm. The two-day campaign successfully raised awareness about the pest, reaching more than 1,000 farmers from four villages in maize growing areas.
Researchers also worked with Scientific Animations Without Borders (SAWBO) and adapted an educational video on how to identify and scout for fall armyworm in a field into Nepali. In collaboration with the PQPMC, the video was broadcast 42 times on three local TV channels, to an estimated audience of more than one million viewers in June 2019. The video has also received over 2,000 online views. The animated video is being shown to farmers using mobile phones and displayed on big screens during community events and workshops.
“Seamless collaboration is required among the major stakeholders in the country to collectively fight the pest,” said AbduRahman Beshir, CIMMYT seed systems lead for the NSAF project and member of the national fall armyworm taskforce. “The potential impact of fall armyworm poses a fundamental challenge for smallholder farmers in Nepal. If unattended, it is going to be a food security issue and an equally daunting task to safeguard livelihoods.”
Nepal’s National Seed Vision 2013-2025 identified the critical skills and knowledge gaps in the seed sector, across the value chain. Seed companies often struggle to find skilled human resources in hybrid product development, improved seed production technology and seed business management. One of the reasons is that graduates from agricultural universities might be missing on recent advancements in seed science and technology, required by the seed industry.
Researchers from the International Maize and Wheat Improvement Center (CIMMYT) have been collaborating with Agriculture and Forestry University (AFU) to review and update the existing curriculum on seed science and technology, for both undergraduate and postgraduate students. This work is part of the Nepal Seed and Fertilizer (NSAF) project, funded by the United States Agency for International Development (USAID) through the Feed the Future initiative.
Realizing the need to increase trained human resources in improved seed technologies, CIMMYT researchers held discussions with representatives from the Department of Agronomy at AFU, to begin revising the curriculum on seed science and technology. Developed four years ago, the current curriculum does not encompass emerging developments in the seed industry. These include, for example, research and product development initiated by local private seed companies engaged in hybrid seed production of various crops, who want to be more competitive in the existing market.
Each year, approximately 200 bachelor’s and 10 master’s students graduate from AFU. In collaboration with CIMMYT, the university identified critical areas that need to be included in the existing curriculum and drafted new courses for endorsement by the academic council. AFU also developed short-term certificate and diploma courses in the subject of seed science and technology.
AbduRahman Beshir, CIMMYT, discusses the importance of linking academic courses with the emerging trends of the seed industry. (Photo: Bandana Pradhan/CIMMYT)
Shared knowledge
On November 20, 2019, CIMMYT, AFU and Catholic Relief Services (CRS) organized a consultation workshop with seed stakeholders from the public and private sectors, civil society and academia. Participants discussed emerging needs within Nepal’s seed industry and charted out how higher education can support demand, through a dynamic and responsive program.
Sabry G. Elias, professor at Oregon State University (OSU), discussed recent advances in seed science and technology, and how to improve productivity of smallholder farmers in Nepal. He is supporting the curriculum revision by taking relevant lessons from OSU and adapting them to Nepal’s context. Sabry shared the courses that are to be included in the new program and outlined the importance of linking graduate research with the challenges of the industry. He also stressed the importance of building innovation and the continuous evolution of academic programs.
Sabry Elias, Oregon State University, talks about the importance of critical thinking to bring innovations to the seed sector. (Photo: Bandana Pradhan/CIMMYT)
Professors from AFU, Nepal Polytechnic Institute, Tribhuvan University, and several private colleges introduced the current courses in seed science and technology at their institutions. Santosh Marahatta, head of the Department of Agronomy at AFU, discussed the limitations of the current master’s and doctoral degree programs, and proposed a draft curriculum with integrated courses across the seed value chain. J.P. Dutta, dean of the Faculty of Agriculture at AFU, shared plans to create a curriculum that would reflect advanced practices and experiences in seed science and technology.
Scientists and researchers from Nepal Agricultural Research Council (NARC) presented their activities and suggested key areas to address some of the challenges in the country’s seed sector.
“Our aim is to strengthen local capacity to produce, multiply and manage adequate quality seeds that will help improve domestic seed production and seed self-sufficiency,” said Mitraraj Dawadi, a representative from the Seed Entrepreneurs Association of Nepal (SEAN). “Therefore, we encourage all graduates to get hands-on experience with private companies and become competent future scientists and researchers.”
AbduRahmann Beshir, Seed Systems Lead for the NSAF project at CIMMYT, shared this sentiment. According to him, most current graduates lack practical experience on hybrid seed development, inbred line maintenance and knowledge on the general requirements of a robust seed industry. “It is important that universities can link their students to private seed companies and work together towards a common goal,” he explained. “This human resource development drive is part of CIMMYT’s efforts to help Nepal on its journey to self-reliance.”
Organizers of the stakeholder consultation workshop to enhance the role of higher learning institutions in the Nepal seed sector at AFU, Chitwan. (Photo: Bandana Pradhan/CIMMYT)
