The International Wheat Genome Sequencing Consortium (IWGSC) is starting a two-year project, with funding from the U.S. National Science Foundation (NSF), to mine an untapped genetic resource for wheat improvement by sequencing the genomes of ancient varieties representing the worldwide diversity of bread wheat.
In this project – called the "Wheat Diversity Project" – the IWGSC and collaborators in France will sequence 12 landrace genomes and update the IWGSC Chinese Spring reference sequence (IWGSC CS RefSeq), which is the primary genome reference for bread wheat research.
Landraces are wheat varieties adapted to local environmental conditions and management practices. They were traditionally farmed across Northern Africa, Europe, and Asia for thousands of years until their replacement by modern agriculture's cultivars with higher yields and farming qualities. This resulted in a substantial reduction of genetic diversity in cultivated wheat.
Landraces are reservoirs of key agronomic and adaptive traits for crop improvement. They are genetically very diverse and contain genes associated with disease resistance, grain-traits, nitrogen-use efficiency, and tolerance to environmental stresses such as drought, heat, and salt, as well as genes coding for proteins involved in flour quality and dietary sensitivity.
Wheat – one of the most cultivated and consumed crops worldwide – is a key food security crop, providing about 20 percent of dietary calories and proteins. "Development of the initial IWGSC CS RefSeq in 2018 served as a springboard for genetics, evolution, breeding and biotechnology advancements in wheat," said Kellye Eversole, IWGSC Executive Director and lead Principal Investigator (PI) on the Wheat Diversity Project. "Updating this resource and providing new landrace genomes will enable further advancements in wheat research and breeding."
The genome sequencing of 12 strategically selected landraces, along with the updated IWGSC CS RefSeq, will provide a crucial step forward in world-wide efforts to improve wheat by identifying the genomic diversity that underlies adaptive traits. This will allow for the development of hardier and improved wheat varieties to meet future demands of climate change, population growth, and sustainability of natural resources."
Joshua Stein, IWGSC Wheat Diversity Project Manager and co-PI on the project
The genome sequences will be generated by applying recent advances in long-read sequencing, optical maps, and chromosome conformation capture sequencing. All genomes will be annotated using established pipelines and accession-derived transcriptome data to inform gene models across the panel. Existing annotations in the IWGSC CS RefSeq, including thousands of community-contributed and manually curated gene models, will be preserved in the new RefSeq version.
To make these resources immediately applicable to advance wheat breeding, project co-PI Robin Buell at the University of Georgia College of Agricultural and Environmental Sciences (US) will develop a practical haplotype graph – a powerful tool that can be used for both genomics and breeding research to accelerate future innovations. The graph will be publicly available and accessible to the entire wheat community via the IWGSC Data Repository at INRAE-URGI and via the USDA data repository GrainGenes.
Additionally, the Wheat Diversity Project team will conduct education and outreach activities in the US to raise public scientific literacy by engaging in urban after-school STEM programs, training educators and providing paid summer internships for talented minority students to gain training in laboratory and bioinformatics skills in plant sciences.
The NSF grant will support sequencing of the updated IWGSC CS RefSeq and eight landraces, the practical haplotype graph development, and the outreach and education segment of the project. Collaborators in France from INRAE and the University of Paris-Saclay will provide the project seeds, sequence four landraces, annotate all genomes, and add the data to the INRAE-URGI data repository, with funding from the European Research Council (project 3Dwheat #101044399) and INRAE Plant Biology and Breeding department.
Officially called "TRTech-PGR: Unlocking bread wheat genome diversity: Foundational genome sequences and resources to advance breeding and biotechnological improvement of a global food security crop" the NSF-funded project (grant #2322957) will operate from January 2024 to December 2025.