Breeding is a vital part of the global agrifood system, enabling scientists to adapt crops to developing environmental factors, support improved crop management, and inform policy interventions on global food production. The challenge to crop breeding increases every year, as farmers experience more of the effects of climate change, while the population and food demand continue to rise.
The study found that climate change necessitates a faster breeding cycle and must drive changes in breeding objectives by putting climate resilience as the top priority.
“The risk of multiple crop failure due to climate change is very real. Breeding must become more deterministic in terms of adaption if we are to avert food price-hikes, hunger, and social unrest,” said Matthew Reynolds, Distinguished Scientist and Head of Wheat Physiology at CIMMYT.
Challenges in developing climate-ready crops originate from the paradox between urgent breeding requirements prompted by climate change and the limited understanding of how different genotypes interact with the climates. Integrating multiple disciplines and technologies including genotyping, phenotyping, and envirotyping can contribute to the development and delivery of climate-adapted crops in a shorter timeframe.
Shelves filled with maize seed samples make up the maize active collection in the Wellhausen-Anderson Plant Genetic Resources Center at CIMMYT’s El Batán headquarters, Mexico. (Photo: Xochiquetzal Fonseca/CIMMYT)
Fast Tracking Climate Solutions from CGIAR Genebank Collections is expanding CGIAR’s and other organizations’ crop improvement research. This initiative is key to developing new crop varieties adapted to the stresses of climate change, including disruptions caused by drought, heat and flooding. Through this ambitious research program, scientists have already developed critical traits using the genebanks, strengthening the identification of high-value genetic diversity from germplasm collections and more efficiently leveraging this diversity to develop new varieties of climate-resilient crops.
Join virtually to learn more about this program’s pioneering research, the value of collaboration in this research and opportunities to engage further.
WHEN: November 11, 2022, from 11 a.m. to 12 p.m. EST
RSVP: Please register for the webinar to receive call-in information. This event is free and open to the public.
AIM for Climate is a joint initiative by the United States and United Arab Emirates seeking to address climate change and global hunger. The initiative brings together partners to increase investment in climate-smart agriculture and food systems innovation. Specifically, AIM for Climate is advancing research through Innovation Sprints. As an AIM for Climate Knowledge Partner and an Innovation Sprint Partner, FFAR has two other Innovation Sprints in addition to the genebanking project: AgMission and the Greener Cattle Initiative.
For more information, contact Jamie Nickel, communications & legislative affairs associate, at jnickel@foundationfar.org.
About the Foundation for Food & Agriculture Research
The Foundation for Food & Agriculture Research (FFAR) builds public-private partnerships to fund bold research addressing big food and agriculture challenges. FFAR was established in the 2014 Farm Bill to increase public agriculture research investments, fill knowledge gaps and complement USDA’s research agenda. FFAR’s model matches federal funding from Congress with private funding, delivering a powerful return on taxpayer investment. Through collaboration and partnerships, FFAR advances actionable science benefiting farmers, consumers and the environment.
Cover photo: Shelves filled with maize seed samples make up the maize active collection in the Wellhausen-Anderson Plant Genetic Resources Center at CIMMYT’s El Batán headquarters, Mexico. (Photo: Xochiquetzal Fonseca/CIMMYT)
AGG is a collaborative project led by the International Maize and Wheat Improvement Center (CIMMYT) bringing together global partners to advance the development of higher-yielding varieties.
This field day was organized by the Crops Research Institute at Ghana’s Council for Scientific and Industrial Research (CSIR-SARI), the International Institute of Tropical Agriculture (IITA) and the department of agriculture.
During the event, researchers aimed to encourage farmer adoption by familiarizing them with the stress-tolerant hybrids and emphasizing the high and stable grain yields.
How does CIMMYT’s improved maize get to the farmer?
CIMMYT is happy to announce four new, improved tropical maize hybrids that are now available for uptake by public and private sector partners, especially those interested in marketing or disseminating hybrid maize seed across Latin America and similar agro-ecological zones. Public- and private-sector organizations are hereby invited to apply for licenses to pursue national release and /or scale-up seed production and deliver these maize hybrids to farming communities.
The deadline to submit applications to be considered during the first round of allocations is 25 November 2022. Applications received after that deadline will be considered during subsequent rounds of product allocations.
The newly available CIMMYT maize hybrids, CIM20LAPP1C-9, CIM20LAPP1C-10, CIM20LAPP1A-11 and CIM20LAPP1A-12, were identified through rigorous trialing and a stage-gate advancement process which culminated in the 2020 and 2021 CIMMYT Latin America Stage 4 and Stage 5 Trials. The products were found to meet the stringent performance criteria for CIMMYT’s LA-PP1A and LA-PP1C breeding pipelines. While there is variation between different products coming from the same pipeline, the LA-PP1A and LA-PP1C pipelines are designed around the target product profiles described below:
Product Profile
Basic traits
Nice-to-have / Emerging traits
Target agroecologies
LatAM-PP1A
(Tropical Lowland White)
Intermediate maturing, white, high yielding, drought tolerant, and resistant to TSC, MLB, and ear rots
GLS, Fusarium Stalk Rot
Latin-American lowland tropics and similar agroecologies.
LatAM-PP1C
(Tropical Lowland Yellow)
Intermediate maturing, yellow, high yielding, drought tolerant, and resistant to MLB and ear rots
GLS, Fusarium Stalk Rot
Latin-American lowland tropics and similar agroecologies.
The Fast Tracking Climate Solutions from CGIAR Germplasm Banks project, led by the International Maize and Wheat Improvement Center (CIMMYT), is expanding the use of common bean and maize biodiversity, held in trust for humanity in the genebanks of CGIAR, to develop the raw ingredients of new climate-smart crop varieties for small-scale farmers in the Northern Triangle: Guatemala, Honduras and El Salvador.
Aligned with, and building upon the Mining Useful Alleles for Climate Change Adaptation from CGIAR Genebanks project, this project aims to identify common bean accessions in genebanks that contain alleles, or gene variations, responsible for characteristics such as heat, drought or salt tolerance, and to facilitate their use in breeding climate-resilient crop varieties. Additionally, within the maize work, the project focuses on transferring valuable novel genetic variation identified from landraces under the aligned project into breeding materials suitable for variety development in the Northern Triangle.
Through this project, breeders will learn how to use genebank materials more effectively and efficiently to develop climate-smart versions of important food crops.
Building on ten years of support to CIMMYT from the Mexican government, CGIAR Trust Fund contributors, the UK Biotechnology and Biological Sciences Research Council, and the ongoing Mining Useful Alleles for Climate Change Adaptation from CGIAR Genebanks project, this project combines the use of cutting-edge technologies and approaches, high-performance computing, GIS mapping, and new plant breeding methods to identify and use accessions with high value for climate-adaptive breeding of varieties needed by farmers and consumers.
Objectives:
Support faster and more cost-effective discovery and deployment of climate-adaptive alleles from the world’s germplasm collections.
Test integrated approaches for the rapid and cost-effective discovery and deployment of climate-adaptive alleles.
Participants of the AGG Maize Mid-Term Review and Planning Meeting at CIMMYT’s Maize Lethal Necrosis Screening Facility in Naivasha, Kenya. (Photo: Dokta Jonte Photography)
The Accelerating Genetic Gains in Maize and Wheat (AGG) Project, which is halfway through its implementation, continues to register impressive achievements. At a meeting focusing on the project’s Maize component, held in Nairobi during July 25-28, B.M. Prasanna, Director of the Global Maize Program at the International Maize and Wheat Improvement Center (CIMMYT), highlighted the project’s major achievements in the opening session.
“One of the most important achievements of this project is increasing use of powerful tools and technologies to increase genetic gains in maize breeding pipelines in Africa,” said Prasanna. He noted that the AGG partners are showing keen interest in doubled haploid-based maize breeding. Prasanna pointed out that currently work is ongoing to produce third-generation tropicalized haploid inducers which, in combination with molecular markers, will support accelerated development of improved maize germplasm, a key objective of the AGG Project.
Prasanna also pointed out a significant increase in adoption of stress-tolerant maize in Africa – from less than half a million hectares cultivated under stress tolerant maize varieties in 2010, to 7.2 million hectares currently in 13 African countries, benefitting 44.5 million people. He explained that drought-tolerant maize is not only a productivity enhancing tool but also an innovation for improving the welfare of farmers. “It reduces the probability of crop failure by 30 percent and provides an extra income to farmers at a rate of approximately $240 USD per hectare, equivalent to about nine months of food for a family at no additional cost,” he said, adding that the essence of research is taking improved genetics to farmers and impacting their lives.
He noted there is remarkable progress in maize varietal turnover in sub-Saharan Africa, pointing out particularly efforts in Ethiopia, Uganda, Zambia and Zimbabwe, where old maize varieties, some dating as far back as 1988, have been replaced with newer climate-resilient varieties. Prasanna highlighted the need to engage with policy makers to put in place appropriate legislation that can accelerate replacement of old or obsolete varieties with improved genetics.
Prasanna stressed on the importance of rapid response to transboundary diseases and insect-pests. CIMMYT has established fall armyworm (FAW) screening facility at Kiboko, Kenya, and that more than 10,000 maize germplasm entries have been screened over the last three years. He applauded South Sudan for being the first country in sub-Saharan Africa to recently release three CIMMYT-developed FAW-tolerant hybrids. He said CIMMYT’s FAW-tolerant inbred lines have been shared with 92 institutions, both public and private, in 34 countries globally since 2018.
Kevin Pixley, CIMMYT Global Genetic Resources Director and Deputy Director General, Breeding and Genetics, encouraged the participants to continuously reflect on making innovative contributions through the AGG project, to serve smallholder farmers and other stakeholders, and to offer sustainable solutions to the food crisis that plagues the world.
B.M. Prasanna addresses partners at the KALRO Kiboko Research station in Kenya during an AGG field visit. (Photo: Dokta Jonte Photography)
Synergies across crops and teams
Pixley pointed out that though the meeting’s focus was on maize, the AGG Project has both maize and wheat components, and the potential for learning between the maize and wheat teams would benefit many, especially with the innovative strides in research from both teams.
Pixley referenced a recent meeting in Ethiopia with colleagues from the International Institute of Tropical Agriculture (IITA), the International Center for Tropical Agriculture (CIAT) and CIMMYT, where discussions explored collaboration among CGIAR centers and other stakeholders in strengthening work on cowpea, chickpea, beans, sorghum, millet and groundnut crops. He noted that maize, wheat and the aforementioned crops are all critical in achieving the mission of CGIAR.
“CIMMYT has been requested, since August of last year, by CGIAR to initiate research projects on sorghum, millet and groundnut because these crops are critical to the success of achieving the mission of CGIAR,” said Pixley. “So, we have recently initiated work on the Accelerated Varietal Improvement and Seed Systems in Africa (AVISA) project together with partners. This is the first step towards OneCGIAR. It’s about synergies across crops and teams.”
Collaborative research commended
The meeting’s Chief Guest, Felister Makini, Deputy Director General – Crops of the Kenya Agricultural and Livestock Research Organisation (KALRO), commended the collaborative research undertaken by CIMMYT and other CGIAR partners. She noted that the partnerships continue to build on synergies that strengthen institutional financial, physical and human resources. She attested that collaboration between KALRO and CGIAR dates back to the 1980s, beginning with training in maize breeding, and then subsequent collaboration on developing climate-adaptive improved maize varieties and training of KALRO technicians in maize lethal necrosis (MLN) screening and management among other areas.
Maize and wheat are staple food sources in Kenya and sub-Saharan Africa and as the population increases, new methods and approaches must be found to accelerate development and deployment of improved maize and wheat varieties. She challenged the partners to intensify research and come out with high-yielding varieties that are resistant or tolerant to a wide range of biotic and abiotic stresses.
The Inaugural Session also featured remarks from the representatives of the AGG funders – Gary Atlin from the Bill & Melinda Gates Foundation, Jonna Davis from the Foundation for Food and Agriculture Research (FFAR), and John Derera from IITA, an AGG project partner.
A total of 116 participants, including representatives from National Agricultural Research Systems (NARS) in 13 AGG-Maize partner countries in Africa and seed companies, participated in the meeting. Participants also visited the KALRO-CIMMYT MLN Screening Facility at Naivasha, and KALRO-CIMMYT maize experiments at Kiboko, Kenya, including the work being done at the maize doubled haploid and FAW facilities.
Ravi Singh delivers a lecture during the 61st All India Wheat and Barley Research Workers’ Meet celebrating the fruitful partnership of CIMMYT and ICAR. (Credit: SAWBAR)
Ravi Singh, head of wheat improvement and rust research at the International Maize and Wheat Improvement Center (CIMMYT), received the Sh. VS Mathur Memorial Award 2022 for outstanding contribution in the field of wheat crop improvement from the Society for Advancement of Wheat and Barley Research (SAWBAR).
As recipient of the award, Singh delivered a lecture during the 61st All India Wheat and Barley Research Workers’ Meet in Gwalior, India, on August 29. He highlighted and praised the partnership between India and CIMMYT as essential for accelerating gains in wheat yield despite the stresses of climate change thanks to improved resilience in new varieties and earlier sowing.
“The ICAR-CIMMYT wheat improvement partnership remains crucial for delivering new varieties with higher rates of genetic gain in farmers’ fields to enhance productivity, climate resilience, disease resistance and nutrition while meeting market needs,” he said.
Successes of the partnership include integrated breeding with a common agenda, commercialized varieties that are adapted to flexible sowing dates including early sowing, diverse and durable resistance to rust diseases, adoption of wheat blast resistant varieties in large areas, biofortified and high-quality varieties, and the move towards mainstreaming of zinc (Zn) biofortification.
Singh also paid homage to the award’s namesake, as VS Mathur’s “wheat varieties once occupied fields of many millions of farmers and provided food and nutrition to many more millions throughout India and beyond”.
Singh, a CIMMYT scientist, receives the Sh. VS Mathur Memorial Award for his outstanding contribution in the field of wheat crop improvement. (Credit: SAWBAR)
About SAWBAR:
SAWBAR was founded in 2007 and is housed at ICAR-Indian Institute of Wheat and Barley Research Karnal (Haryana) India. The Society presently has 300 life members and more than 320 annual and student members. SAWBAR is playing a significant role in bringing wheat and barley researchers on one platform for the exchange of innovative research and dissemination of knowledge related to the latest research happenings in the area of wheat and barley improvement. Annually, SAWBAR gives awards to pioneer cereal workers in various award categories.
About the Sh. VS Mathur Mathur Memorial Award:
The Sh. VS Mathur Memorial Awardwas constituted in year 2018 in the memory of eminent wheat worker Sh. VS Mathur. Mathur was one of the pioneer wheat workers who worked tirelessly with MS Swaminathan and HK Jain and developed a large number of high-yielding wheat varieties viz. Heera, Moti, Janak (HD 1982), Arjun (HD 2009), HD 2177, HD 2182, HD 2204, HD 2236, HD 2278, HD 2281, HD 2285, HD 2329, HD 2307 and HD 2327 for various regions of India.
Rust pathogens are the most ubiquitous fungal pathogens that continue to pose a serious threat to wheat production. The preferred strategy to combat these diseases is through breeding wheat varieties with genetic resistance.
Landraces are a treasure trove of trait diversity, offer an excellent choice for the incorporation of new traits into breeding germplasm, and serve as a reservoir of genetic variations that can be used to mitigate current and future food challenges. Improving selection efficiency can be achieved through broadening the genetic base through using germplasm pool with trait diversity derived from landraces.
In a recent study, researchers from the International Maize and Wheat Improvement Center (CIMMYT) used Afghan landrace KU3067 to unravel the genetic basis of resistance against Mexican races of leaf rust and stripe rust. The findings of this study not only showcase new genomic regions for rust resistance, but also are the first report of Lr67/Yr46 in landraces. This adult plant resistance (APR) gene confirms multi-pathogenic resistance to three rust diseases and to powdery mildew.
Using genotype sequencing and phenotyping, the authors also report an all-stage resistance gene for stripe rust on chromosome 7BL, temporarily designated as YrKU. The genetic dissection identified a total of six quantitative trait locus (QTL) conferring APR to leaf rust, and a further four QTL for stripe rust resistance.
Although use of landraces in wheat breeding has been practiced for a long time, it has been on a limited scale. This study represents a significant impact in breeding for biotic stresses, particularly in pest and disease resistance.
How does CIMMYT’s improved maize get to the farmer?
CIMMYT is happy to announce a new, improved tropical maize hybrid that is now available for uptake by public and private sector partners, especially those interested in marketing or disseminating hybrid maize seed across rainfed tropics of South Asia and similar agro-ecologies. NARS and seed companies are hereby invited to apply for licenses to pursue national release and /or scale-up seed production and deliver these maize hybrids to farming communities.
The deadline to submit applications to be considered during the first round of allocations is 26 Aug 2022. Applications received after that deadline will be considered during subsequent rounds of product allocations.
The newly available CIMMYT maize hybrid, CIM19SADT-01, was identified through rigorous trialing and a stage-gate advancement process which started in 2019 and culminated in the 2020 and 2021 South Asia Regional On-Farm Trials for our South Asian Drought Tolerance (SADT) and Drought + Waterlogging Tolerance (SAWLDT) maize breeding pipelines. The product was found to meet the stringent performance criteria for CIMMYT’s SADT pipeline. While there is variation between different products coming from the same pipeline, the SADT pipeline is designed around the product concept described below:
Product Profile
Basic traits
Nice-to-have / Emerging traits
Target agroecologies
SADT (South Asian Drought Tolerance)
Medium maturing, yellow, high yielding, drought tolerant, and resistant to TLB and FSR
FER, BLSB, FAW
Semi-arid, rainfed, lowland tropics of South Asia, and similar agroecologies
CIMMYT enumerators hold booklets with vignettes before their interaction with family farmers Kiran Devi (second from left) and Rishikesh Ram (third from left). (Photo: Nima Chodon /CIMMYT)
Researchers from the International Maize and Wheat Improvement Center (CIMMYT) are conducting a study in the state of Bihar, India, to improve our understanding of women’s and men’s contributions to decision-making around wheat crop management. The results will help reach women with new varieties that meet their needs and priorities.
The study seeks to overcome a big challenge for research organizations and national policymakers: to design a better framework for faster turnover of improved varieties and increased access to women and marginalized farmers.
Wheat is the second-largest crop grown in Bihar after rice, with a production of 5-6 million tonnes of it every year. Despite women’s contributions to farming activities, from sowing to harvesting, traditional gender norms can undermine their access to productive resources and influence household decisions. Additionally, women’s workload in wheat agriculture is increasing, due to men’s departure to non-agricultural jobs, but women are still not necessarily recognized as capable farmers.
Gender exclusion in agriculture
Given social norms and household-and-farm labor division based on gender, women are often confined to specific roles in the agricultural production system. In smallholder farming communities of South Asia like Bangladesh, India, and Nepal, men’s increasing involvement in non-agricultural activities has increased women’s workloads in every sphere of agricultural production. However, these long-held assumptions of their role can lead to exclusion from decision-making, limiting their control over what, how, and how much a crop is produced, their economic wellbeing, including household food security.
The CIMMYT study on “Intra-household gender dynamics in decision-making for wheat crop management in India (Bihar)” investigates women’s and men’s roles in production decisions. Led by Hom Gartaula, Gender, and Social Inclusion Specialist at CIMMYT, it covers eight villages — four in Darbhanga and four in Madhepura district — with 25 houses considered in each village.
As part of the Accelerating Genetic Gains in Maize and Wheat for improved livelihoods in Asia and Africa (AGG) project, the research study will help gain deeper insights into the intra-household gender dynamics. It will also help in untangling who does what, how wheat cultivation and management decisions are organized within the households and the perceptions of the male and female farmers around why decisions are made in such a way.
Farmer Devi points at the vignette that aligns with her household decision-making process. (Photo: Nima Chodon /CIMMYT)
Storytelling through household decision-making scenarios
In traditional rural societies, survey-based data collection might not be the best way to evaluate women’s agency, as the deeply rooted cultural restrictions might not allow them to talk openly about sensitive issues, like their relationship with a spouse. This study uses an innovative storytelling approach to data collection: using vignettes, farmers are given short stories to relate to their household circumstances. Stories are also easier to remember and help build a connection with the characters quickly.
The vignettes approach was first applied in the context of smallholder maize production in Kenya under the AGG project. According to Rachel Voss, the leader of the Kenyan study, “Using vignettes to explore decision-making in both East Africa and South Asia allows us to learn and compare across these regions and across crops. Gender relations in Indian wheat and Kenyan maize production might look similar in some ways, but very different in other ways, and our research and programming will need to respond to those differences.”
In this study, five vignettes with fictitious husband and wife characters are presented to participants to represent the different ways production and consumption decisions are made in the household. These vignettes describe how they engage in key decisions like seed procurement, labor hired, and harvest used for consumption or sale. With guidance from evaluators, respondents identify which scenario best aligns with the decision-making process in their household.
Researchers feel this qualitative data, gathered through a storytelling approach, could guide the reach of gender interventions in a more effective way. Gartaula and the team explained that the participants can build connections to a character in the story without biases, expressing their experiences in household decision-making through vignettes. They also observed that sometimes what the participant shared is the opposite of their assumption of women being excluded from decisions.
Rethinking gender roles
Traditional gender roles are deeply entrenched in the region. In the farming communities of rural Bihar, one might assume that who does what in wheat-rice cultivation is obvious, and it has been well studied in the past. However, investigating the stereotypes around gender to understand practices within households is an innovative aspect of this study.
For example, landless couple Pappu Paswan and Kamini Devi of village Kamtaul in Darbhanga district have been cultivating wheat on leased farm plots for many years. Devi is engaged in every aspect of decision-making. “We cultivate in leased plots of different sizes, spread across, requiring more effort and time in attending to them. We discuss additional labor during harvest and if there is money enough to pay them,” said Devi pointing her finger at the vignette illustrating ‘cooperation’ in household decision-making. They produce enough for their consumption, but when possible, “I advise my husband to sell some for income,” she added.
Despite contributing to decisions jointly with Pappu when it comes to farm labor and household finances, Devi has little or no knowledge of seed varieties and access. Her husband informs that it was UP262 (wheat seed variety) they have been cultivating for the last two years.
In Rishikesh Ram’s household, land ownership and livelihood specialization were factors in decision-making. He owns the land and makes all farming decisions, including how much will be saved for consumption at home. His wife, Kiran Devi, a nurse at the village primary health center, is hardly involved in any farming work. “As the income from her job contributes to expenses at home, decisions about loans or payment for labors on the farm are joint decisions,” Ram said.
“In these two households of the diverse decision-making process, different approaches to messaging and relevant extension services must be explored to address the issues of exclusion, access, and knowledge gaps in these households,” Gartaula observed.
Bridging the gender gap in agri-food systems
With the feminization of agriculture in the region, women’s contribution to agricultural production is likely to increase. Policy and research interventions must recognize this growing population and support their full economic and social contributions as cultivators, entrepreneurs, and laborers. However, whether women’s growing role in wheat production leads to increased decision-making authority and empowerment is still unknown. But hope is that AGG-supported gender research in South Asia and East Africa will help guide actions on gender and social inclusion in agri-food systems and support cross-learning between the regions.
This open-access textbook provides a comprehensive, up-to-date guide for students and practitioners wishing to access the key disciplines and principles of wheat breeding. Edited by Matthew Paul Reynolds, head of Wheat Physiology at CIMMYT, and Hans-Joachim Braun, former Director of CIMMYT’s Global Wheat Program, it covers all aspects of wheat improvement, from utilizing genetic resources to breeding and selection methods, data analysis, biotic and abiotic stress tolerance, yield potential, genomics, quality nutrition and processing, physiological pre-breeding, and seed production.
It will give readers a balanced perspective on proven breeding methods and emerging technologies. The content is rich in didactic material that considers the background to wheat improvement, current mainstream breeding approaches, translational research, and avant-garde technologies that enable breakthroughs in science to impact productivity, facilitating learning.
While the volume provides an overview for professionals interested in wheat, many of the ideas and methods presented are equally relevant to small grain cereals and crop improvement in general.
All chapter authors are world-class researchers and breeders whose expertise spans cutting-edge academic science to impacts in farmers’ fields.
Given the challenges currently faced by academia, industry, and national wheat programs to produce higher crop yields, often with fewer inputs and under increasingly harsher climates, this volume is a timely addition to their toolkit.
How does CIMMYT’s improved maize get to the farmer?
CIMMYT is proud to announce a new improved subtropical maize hybrid that is now available for uptake by public and private sector partners, especially those interested in marketing or disseminating hybrid maize seed across mid-altitudes of Mexico and similar agro-ecologies. National agricultural research systems (NARS) and seed companies are invited to apply for a license to commercialize this new hybrid to bring the benefits of the improved seed to farming communities.
The deadline to submit applications is 15 August 2022. Applications received after that date will be considered during the following round of product allocations.
The newly available CIMMYT maize hybrid, CIM20LAPP2B-2, was identified through rigorous trialing and a stage-gate advancement process that culminated in the 2020 Stage 5 trials for CIMMYT’s Latin American tropical mid-altitude maize breeding pipeline (LA-PP2B). While individual products will vary, the LA-PP2B pipeline aims to develop maize hybrids fitting the product profile described in the following table:
Product Profile
Basic traits
Nice-to-have / Emerging traits
Latin America Product Profile 2B (LA-PP2B)
Intermediate-maturing, yellow kernel, high-yielding, drought tolerant, resistant to FSR, GLS, and ear rots
TSC, TLB
Information about the newly available CIMMYT maize hybrid from the Latin America breeding program, application instructions, and other relevant material is available in the CIMMYT Maize Product Catalog and the links provided below.
Spot blotch, a major biotic stress challenging bread wheat production is caused by the fungus Bipolaris sorokiniana. In a new study, scientists from the International Maize and Wheat Improvement Center (CIMMYT) evaluate genomic and index-based selection to select for spot blotch resistance quickly and accurately in wheat lines. The former approach facilitates selecting for spot blotch resistance, and the latter for spot blotch resistance, heading and plant height.
Genomic selection
The authors leveraged genotyping data and extensive spot blotch phenotyping data from Mexico and collaborating partners in Bangladesh and India to evaluate genomic selection, which is a promising genomic breeding strategy for spot blotch resistance. Using genomic selection for selecting lines that have not been phenotyped can reduce the breeding cycle time and cost, increase the selection intensity, and subsequently increase the rate of genetic gain.
Two scenarios were tested for predicting spot blotch: fixed effects model (less than 100 molecular markers associated with spot blotch) and genomic prediction (over 7,000 markers across the wheat genome). The clear winner was genomic prediction which was on average 177.6% more accurate than the fixed effects model, as spot blotch resistance in advanced CIMMYT wheat breeding lines is controlled by many genes of small effects.
“This finding applies to other spot blotch resistant loci too, as very few of them have shown big effects, and the advantage of genomic prediction over the fixed effects model is tremendous”, confirmed Xinyao He, Wheat Pathologist and Geneticist at CIMMYT.
The authors have also evaluated genomic prediction in different populations, including breeding lines and sister lines that share one or two parents.
Spot blotch susceptible wheat lines (left) and resistant lines. (Photo: Xinyao He and Pawan Singh/CIMMYT)
Index selection
One of the key problems faced by wheat breeders in selecting for spot blotch resistance is identifying lines that are genetically resistant to spot blotch versus those that escape and exhibit less disease by being late and tall. “The latter, unfortunately, is often the case in South Asia”, explained Pawan Singh, Head of Wheat Pathology at CIMMYT.
A potential solution to this problem is the use of selection indices that can make it easier for breeders to select individuals based on their ranking or predicted net genetic merit for multiple traits. Hence, this study reports the first successful evaluation of the linear phenotypic selection index and Eigen selection index method to simultaneously select for spot blotch resistance using the phenotype and genomic-estimated breeding values, heading and height.
This study demonstrates the prospects of integrating genomic selection and index-based selection with field based phenotypic selection for resistance in spot blotch in breeding programs.
Spot blotch, caused by the fungus Biopolaris sorokiniana poses a serious threat to bread wheat production in warm and humid wheat-growing regions globally, affecting more than 25 million hectares and resulting in huge yield losses.
Chemical control approaches, including seed treatment and fungicides, have provided acceptable spot blotch control. However, their use is unaffordable to resource-poor farmers and poses a hazard to health and the environment. In addition, “abiotic stresses like heat and drought that are widely prevalent in South Asia compound the problem, making varietal genetic resistance the last resort of farmers to combat this disease,” according to Pawan Singh, Head of Wheat Pathology at the International Maize and Wheat Improvement Center (CIMMYT). Therefore, one of CIMMYT’s wheat research focus areas is developing wheat varieties that carry genetic resistance to the disease.
Signs of spot blotch on wheat. (Photo: Philomin Juliana/CIMMYT)
The study’s results are positive and confirmed that:
Many advanced CIMMYT breeding lines have moderate to high resistance to spot blotch.
Resistance to the disease is conferred quantitatively by several minor genomic regions that act together in an additive manner to confer resistance.
There is an association of the 2NS translocation from the wild species Aegilops ventricosa with spot blotch resistance.
There is also an association of the spot blotch favorable alleles at the 2NS translocation, and two markers on the telomeric end of chromosome 3BS with grain yield evaluated in multiple environments, implying that selection for favorable alleles at these markers could help obtain higher grain yield and spot blotch resistance.
“Considering the persistent threat of spot blotch to resource-poor farmers in South Asia, further research and breeding efforts to improve genetic resistance to the disease, identify novel sources of resistance by screening different germplasm, and selecting for genomic regions with minor effects using selection tools like genomic selection is essential,” explained Philomin Juliana, Molecular Breeder and Quantitative Geneticist at CIMMYT.
Cover photo: Researchers evaluate wheat for spot blotch at CIMMYT’s experimental station in Agua Fría, Jiutepec, Morelos state, Mexico. (Photo: Xinyao He and Pawan Singh/CIMMYT)
How does CIMMYT’s improved maize get to the farmer?
CIMMYT is proud to announce a new, improved highland maize hybrid that is now available for uptake by public- and private-sector partners, especially those interested in marketing or disseminating hybrid maize seed across upper altitudes of Eastern Africa and similar agro-ecologies. National agricultural research system (NARS) and seed companies are hereby invited to apply for licenses to pursue national release, scale-up seed production, and deliver these maize hybrids to farming communities.
The deadline to submit applications to be considered during the first round of allocations is 8 April 2022. Applications received after that deadline will be considered during subsequent rounds of product allocations.
The newly available CIMMYT maize hybrid, CIM20EAPP3-01-47, was identified through rigorous trialing and a stage-gate advancement process that culminated in the 2021 Eastern Africa Regional On-Farm Trials for CIMMYT’s eastern Africa highland maize breeding pipeline (EA-PP3). While individual products will vary, the EA-PP3 pipeline aims to develop maize hybrids fitting the product profile described in the following table:
Product profile
Basic traits
Nice-to-have / Emerging traits
Eastern Africa Product Profile 3 (EA-PP3)
Late -maturing, white, high yielding, drought tolerant, NUE, and resistant to GLS, TLB, Ear rots, and rust
MLN, fall armyworm, cold tolerance
Application instructions, and other relevant material is available via the CIMMYT Maize Product Catalog and in the links provided below.
The Fast Tracking Climate Solutions from CGIAR Germplasm Banks project, led by the International Maize and Wheat Improvement Center (CIMMYT), is expanding the use of common bean and maize biodiversity, held in trust for humanity in the genebanks of CGIAR, to develop the raw ingredients of new climate-smart crop varieties for small-scale farmers in the Northern Triangle: Guatemala, Honduras and El Salvador.
