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Invite par: Drs F Causeret/ and A Pierani Her work is dedicated to early cortical activity patterns in rodents and humans to understand basic development to propose translational bridges to clinic. Studies are to investigate the cytoskeleton dynamics in axon regeneration. Her researches are devoted to the homeostatic interplay between electrical activity and neuronal apoptosis in the developing neocortex. She recently published a high resolution 3D imaging and analysis of axon regeneration in unsectioned spinal cord with or without tissue clearing (Nat Protoc 2019). Her expertise and skills are covering multiple domains. Plus d'infos... Tags: Neuron Culture, Immunohistochemistry, Apoptosis, Electrophysiology, Cellular Neuroscience, Molecular Cell Biology, Neuron, Patch Clamp, 3D-Imaging, Spinal Cord Injury Annonce publiée le 26-06-2020 Tweet |
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| Institut de Psychiatrie et Neurosciences de Paris VISIOCONFERENCE R04-45, Institut de Psychiatrie et Neurosciences de Paris (IPNP, UMR_S1266 INSERM, Universite de Paris, 102-108 rue de la sante - 75014 Paris, https://ipnp.paris5.inserm.fr// |
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Invite par: Maud Tenaillon
The evolution of selfing from outcrossing is one of the most frequent transitions in flowering plants. Although potentially ecologically successful on the short term, selfing is supposed to be an evolutionary dead-end on the long term because of its negative genetic consequences. Theory predicts that selfing increases genetic drift and genetic linkage, reducing genetic diversity and the efficacy of selection. In addition, selfing species are more prone to extinction/recolonization dynamics, which increases further genetic drift. Selfing species are thus supposed to have a reduced adaptive potential and to accumulate weakly deleterious mutations. In several species, genomic signatures of the negative effects of selfing have been found. However, the pace at which selfing impacts genome evolution and the relative roles of demographic versus linked selection effects remain unclear. To address these questions we sequenced the transcriptome of two to 20 individuals for all 13 diploid species of the Aegilops/Triticum genus (wheat relatives) that presents a wide range of mating systems, from self-incompatible to highly selfing species. Phylogenomic analyses revealed a complex history with past hybridizations and pointed to a self-incompatible ancestor with several evolutions to different degrees of selfing. We found a strong and continuous effect of mating system on patterns of polymorphism and selection efficacy. We also used recombination maps to estimate the effect of linked selection on patterns of polymorphism and try to distinguish it from demographic effects. We found a strong effect of linked selection that is amplified by selfing but our results also point to a role of the specific demography of species able to autonomous selfing. Finally, the comparison of polymorphism and divergence patterns suggested a (very) recent origin of selfing habit, hence a potentially rapid turnover of selfing species, raising the question of the underlying causes of high extinction rates in selfers.
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Annonce publiée le 22-06-2020
Tweet INRAe Le Moulon
Webinaire semIDEEV du GQE-Le Moulon -
In human cells, two meters of DNA sequence are compressed into a nucleus whose linear size is five orders of magnitude smaller. Deciphering how this amazing structural organization is achieved and how DNA functions can ensue in the environment of a cell’s nucleus represent central questions for contemporary biology.
Here, I embrace this challenge by establishing a comprehensive framework of microscopy and sequencing technologies coupled with advanced analytical approaches, aimed at addressing three fundamental highly-interconnected questions: 1) What are the design principles that govern DNA compaction? 2) How does genome structure vary between different cell types as well as among cells of the same type? 3) What is the link between genome structure and function? To this aim, we have devised a powerful method for Genomic loci Positioning by Sequencing (GPSeq), which allows genome-wide measurements of the distance of genomic loci to the nuclear periphery. Using GPSeq, we are generating reproducible maps of radial genome organization in human cells, in order to reveal radial gradients of genetic and epigenetic features as well as gene expression in various cell and tissue types. In parallel, we are developing high-end microscopy tools for simultaneous localization of dozens of genomic locations at high resolution in thousands of single cells.
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Tags: Branches of biology, Biology, Genetic mapping, Genomics, Genome, Life sciences, DNA, Biotechnology, Molecular biology, Elmar Zeitler
Annonce publiée le 07-02-2020
Tweet Institut Curie
Centre de recherche - Paris - Amphitheatre Marie Curie -
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Tags: ESMO, European Society for Medical Oncology, Europe, European Cancer Organisation
Annonce publiée le 21-11-2019
Tweet Institut Gustave Roussy
Madrid, Espagne -
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Tags: Branches of biology, Biology, Life sciences, Stem cells, Developmental biology, Organoid, Tissue engineering, Induced stem cells, Biotechnology, Enteric nervous system, Cerebral organoid, Neural tissue engineering
Annonce publiée le 07-02-2020
Tweet SFR Necker
Institut des maladies genetiques IMAGINE - auditorium, 6eme etage - 24, bd du Montparnasse 75015 Paris