description
- In the global warming era, heat stress is a major threat for both yield stability and yield increase. Plants have evolved a variety of sophisticated mechanisms to adapt to challenging environments. Epigenetic regulations allow them to dynamically reprogram their transcription machinery to adapt to an ever-changing environment. Both histone marks and the 3D organization of the chromatin are instrumental for this coordinated regulation of gene expression according to environmental cues. Yet, the overwhelming majority of available data on chromatin dynamics in response to stress has been obtained in Arabidopsis, and cannot be directly transferred to crops. Due to the expansion of NGS technologies, we are currently facing a change of paradigm, empowering the development of genome-wide approaches on crops. In this project we focus on wheat. Wheat is the 1st cereal worldwide for trade, and the demand is expected to increase by 60% by 2050. My main objective is a thorough understanding of the priming for heat stress resistance in wheat. To this end, I propose to develop a new tri-dimensional (D) functional genomics approach, integrating epigenomic (1D), transcriptomic (2D) and chromatin architecture (3D) data to elucidate the molecular basis for priming in wheat. Moreover, this project will go beyond addressing the challenge of deciphering epigenetic regulatory processes underlying priming. It also includes the development of innovative tools for novel breeding strategies that will harness epigenetic variability in addition to genetic diversity. We propose to generate a new generation of molecular markers that do not rely on DNA sequence polymorphisms, and that can be readily used in traditional breeding programs as such, or as complementary tools for efficient QTL introgression. Such markers will be used to tag new traits, to follow a new generation of alleles as well as to unveil new types of genetic diversity in existing collections of germplasms.