Month Flat Week Day
Tuesday, October 16, 2018 10:15 - 11:15
1 Hour
UPSC Cutting-Edge Seminar

Raphaël Mercier
Institut Jean-Pierre Bourgin, INRA Versailles, France

Title: What limits meiotic recombination?

Host: Catherine Bellini


Meiosis is an essential stage in the life cycle of sexually-reproducing organisms. Indeed, meiosis is the specialized cell division that reduces the number of chromosomes from two sets in the parent to one set in gametes, while fertilization restores the original chromosome number. Meiosis is also the stage of development when genetic recombination occurs, thus being the heart of Mendelian heredity. Increasing our knowledge on meiotic mechanisms, in addition to its intrinsic interest, would have also important implications for agriculture and medicine.
Arabidopsis emerged as one of the prominent models in the field of meiosis. Indeed, the meiotic field benefits greatly from a multi-model approach with several kingdoms represented, highlighting both conserved mechanisms and variation around the theme. Arabidopsis emerged as a very good model to study meiosis, notably because of the possibility of large scale genetic studies and the wide range of molecular and cytological tools. Raphaël Mercier and his team aim at deciphering meiotic mechanisms, including recombination, cell cycle and sister chromatid cohesion modifications, and their functional relationships. To achieve this goal, they are conducting various genetic screens and characterizing the key players that they identified.
Apomixis results in progeny that are genetic clones of the maternal parent and thus is of great interest due to its potential revolutionary application in crop improvement. By introducing apomixis into sexual plants, any desired genotype, no matter how complex, could be perpetuated through successive seed generations. However, despite the occurrence of apomixis in over 400 species of angiosperms, very few crop species are apomictic and attempts to introduce this trait by crossing have failed. Raphaël Mercier ‘s projects aim, via a better understanding of sexual reproduction processes, to de novo engineer apomixes in sexual plants