All eukaryotic cells divide a finite number of times, although the mechanistic basis of this replicative aging remains unclear. Replicative aging is accompanied by a reduction in histone protein levels, and this is a cause of aging in budding yeast. Here we show that nucleosome occupancy decreased by 50% across the whole genome during replicative aging using spike-in controlled micrococcal nuclease digestion followed by sequencing. Furthermore, nucleosomes became less well positioned or moved to sequences predicted to better accommodate histone octamers. The loss of histones during aging led to transcriptional induction of all yeast genes. Genes that are normally repressed by promoter nucleosomes were most induced, accompanied by preferential nucleosome loss from their promoters. We also found elevated levels of DNA strand breaks, mitochondrial DNA transfer to the nuclear genome, large-scale chromosomal alterations, translocations, and retrotransposition during aging.
Je tiens à exprimer mes sincères remerciements à :Monsieur le Professeur Éric Deutsch, de m'avoir fait l'honneur de présider cette thèse. Monsieur le Professeur Ahmed Idbaih et Monsieur le Professeur Keith Ligon, d'avoir pris le temps de diriger et encadrer cette thèse. Monsieur le Docteur Franck Bourdeaut, Madame la Professeure Magali Svrcek, et Monsieur le Professeur Alex Duval, d'avoir pris le temps de juger ce travail. Monsieur le Docteur Franck Bielle, et Monsieur le Professeur Marc Sanson, pour leur participation à ces travaux. Une partie importante de ces travaux a été réalisée au Dana-Farber Cancer Institute et je tiens à remercier ici très sincèrement mes collègues de Boston pour leur amitié et leurs efforts déterminants dans l'obtention de ces résultats, en particulier Keith Ligon pour son accueil au sein de son laboratoire, ses conseils et ses encouragements.
We present the complete 2,843,201-bp genome sequence of Treponema denticola (ATCC 35405) an oral spirochete associated with periodontal disease. Analysis of the T. denticola genome reveals factors mediating coaggregation, cell signaling, stress protection, and other competitive and cooperative measures, consistent with its pathogenic nature and lifestyle within the mixed-species environment of subgingival dental plaque. Comparisons with previously sequenced spirochete genomes revealed specific factors contributing to differences and similarities in spirochete physiology as well as pathogenic potential. The T. denticola genome is considerably larger in size than the genome of the related syphiliscausing spirochete Treponema pallidum. The differences in gene content appear to be attributable to a combination of three phenomena: genome reduction, lineage-specific expansions, and horizontal gene transfer. Genes lost due to reductive evolution appear to be largely involved in metabolism and transport, whereas some of the genes that have arisen due to lineage-specific expansions are implicated in various pathogenic interactions, and genes acquired via horizontal gene transfer are largely phagerelated or of unknown function.
Cas9 is commonly introduced into cell lines to enable CRISPR/Cas9-mediated genome editing. Here we studied the genetic and transcriptional consequences of Cas9 expression
per se
. Gene expression profiling of 165 pairs of human cancer cell lines and their Cas9-expressing derivatives revealed upregulation of the p53 pathway upon Cas9 introduction, specifically in
TP53
-WT cell lines. This was confirmed at the mRNA and protein levels. Moreover, elevated levels of DNA repair were observed in Cas9-expressing cell lines. Genetic characterization of 42 cell line pairs showed that Cas9 introduction can lead to the emergence and expansion of p53-inactivating mutations. This was confirmed by competition experiments in isogenic
TP53
-WT/
TP53
-null cell lines. Lastly, Cas9 was less active in
TP53
-WT than in
TP53
-mutant cell lines, and Cas9-induced p53 pathway activation affected cellular sensitivity to both genetic and chemical perturbations. These findings may have broad implications for the proper use of CRISPR/Cas9-mediated genome editing.
We report a set of oligonucleotide primers and amplification conditions for the polymerase chain reaction to detect the ctx operon of Vibrio cholerae. The results of this assay on strains of V. cholerae and related organisms were identical with those obtained by the DNA colony hybridization test with the polynucleotide probe. The detection limit of this system was 1 pg of chromosomal DNA or broth culture containing three viable cells. The polymerase chain reaction method could directly detect the ctx operon sequences in rice-water stool samples from patients with cholera.
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