Spelling suggestions: "subject:"epigenetic information"" "subject:"spigenetic information""
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Genome-wide nucleosome map and cytosine methylation levels of an ancient human genome.Pedersen, J.S., Valen, E., Velazquez, A.M.V., Parker, B.J., Lindgreen, S., Lilje, B., Tobin, Desmond J., Kelly, T.K., Vang, S., Andersson, R., Jones, P.A., Hoover, C.A., Prokhortchouk, E., Rubin, E.M., Sandelin, A., Gilbert, M.T.P., Krogh, A., Willerslev, E. January 2014 (has links)
Yes / Epigenetic information is available from contemporary organisms, but is difficult to track back in evolutionary time.
Here, we show that genome-wide epigenetic information can be gathered directly from next-generation sequence reads of
DNA isolated from ancient remains. Using the genome sequence data generated from hair shafts of a 4000-yr-old Paleo-
Eskimo belonging to the Saqqaq culture, we generate the first ancient nucleosome map coupled with a genome-wide
survey of cytosine methylation levels. The validity of both nucleosome map and methylation levels were confirmed by the
recovery of the expected signals at promoter regions, exon/intron boundaries, and CTCF sites. The top-scoring nucleosome
calls revealed distinct DNA positioning biases, attesting to nucleotide-level accuracy. The ancient methylation
levels exhibited high conservation over time, clustering closely with modern hair tissues. Using ancient methylation
information, we estimated the age at death of the Saqqaq individual and illustrate how epigenetic information can be used
to infer ancient gene expression. Similar epigenetic signatures were found in other fossil material, such as 110,000- to
130,000-yr-old bones, supporting the contention that ancient epigenomic information can be reconstructed from a deep
past. Our findings lay the foundation for extracting epigenomic information from ancient samples, allowing shifts in
epialleles to be tracked through evolutionary time, as well as providing an original window into modern epigenomics.
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Dynamique des variants de l'histone H3 en réponse aux dommages de l'ADN induits par les UVC dans les cellules humaines / Histone H3 variant dynamics in response to UVC damage in human cellsAdam, Salomé 15 June 2015 (has links)
Dans les cellules eucaryotes, la réponse aux lésions de l'ADN s'accompagne d'une réorganisation de la chromatine. Cette structure, associant l'ADN aux protéines histones, est porteuse de l'information épigénétique, qui définit l'identité cellulaire. Cependant, nos connaissances concernant les mécanismes impliqués dans la réorganisation de la chromatine dont l'intégrité structurale et fonctionnelle a été menacée par un stress génotoxique sont encore limitées, en particulier dans les cellules humaines. Au cours de ma thèse, je me suis donc intéressée à cette thématique en me concentrant sur l'étude de la dynamique des variants de l'histone H3 et de leurs chaperons associés après dommages UVC. En combinant une technologie innovante de suivi spécifique des histones parentales ou néo-synthétisées à des techniques de pointe d'induction de dommages locaux dans l'ADN, j'ai ainsi mis en évidence que le chaperon HIRA (Histone Regulator A) est recruté tôt aux sites de lésions où il stimule l'incorporation locale de nouveaux variants H3.3 et assure la reprise de la transcription après réparation des dommages UVC. Nous avons aussi démontré que les anciennes histones sont initialement redistribuées dans la chromatine autour des sites de lésions par un mécanisme faisant appel au facteur de détection des dommages DDB2 (DNA Damage Binding protein 2). A plus long terme, des histones parentales " reviennent " dans les régions de chromatine en cours de réparation où elles se mélangent aux nouvelles histones incorporées. Le " retour " d'histones préexistantes contribuerait ainsi au maintien de l'intégrité de l'information épigénétique véhiculée par la chromatine avant stress génotoxique. / In eukaryotic cells, the DNA damage response involves a reorganization of chromatin structure. This structure, in which DNA is associated with histone proteins, conveys the epigenetic information, which is critical for cell identity. However, we are still far from understanding the mechanisms underlying chromatin dynamics in response to DNA damage, which challenges both the structural and functional integrity of chromatin architecture. During my PhD, I thus decided to explore this issue in human cells, by deciphering the dynamics of histone H3 variants and their dedicated chaperones in response to UVC lesions. By combining local UVC irradiation with an innovative technology that allows specific tracking of parental and newly synthesized histones, I revealed that the histone chaperone HIRA (Histone Regulator A) is recruited early to UVC-damaged chromatin regions, where it promotes local deposition of new histone H3.3 variant and facilitates transcription recovery upon repair completion. We also demonstrated that old H3 histones are initially redistributed around the damaged chromatin zone, this conservative redistribution requiring the UVC damage sensor DDB2 (DNA Damage Binding protein 2). Later in the repair process, most parental histones recover and mix with newly deposited histones in repairing chromatin regions. The recovery of pre-existing histones may contribute to preserve the integrity of the epigenetic information conveyed by chromatin before genotoxic stress.
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