Jessica Pellegrino scite author profile

Transcription requires the progression of RNA polymerase II (RNAP II) through a permissive chromatin structure. Recent studies of Saccharomyces cerevisiae have demonstrated that the yeast Sin3 protein contributes to the restoration of the repressed chromatin structure at actively transcribed loci. Yet, the mechanisms underlying the restoration of the repressive chromatin structure at transcribed loci and its significance in gene expression have not been investigated in mammals. We report here the identification of a mammalian complex containing the corepressor Sin3B, the histone deacetylase HDAC1, Mrg15, and the PHD finger-containing Pf1 and show that this complex plays important roles in regulation of transcription. We demonstrate that this complex localizes at discrete loci approximately 1 kb downstream of the transcription start site of transcribed genes, and this localization requires both Pf1's and Mrg15's interaction with chromatin. Inactivation of this mammalian complex promotes increased RNAP II progression within transcribed regions and subsequent increased transcription. Our results define a novel mammalian complex that contributes to the regulation of transcription and point to divergent uses of the Sin3 protein homologues throughout evolution in the modulation of transcription.Regulation of gene expression impacts virtually all cellular processes and relies primarily on accurate regulation of transcription. It has become increasingly clear that transcription itself is regulated not only at the level of initiation, but also during elongation and termination. While the molecular events underlying transcription initiation have been in part elucidated in the recent past, how transcription elongation and transcription termination modulate gene expression in mammals remains largely elusive.In eukaryotes, the presence of nucleosomes interspersed along the chromatin fiber is believed to represent a major barrier for RNA polymerase II (RNAP II) entry and progression (30). To allow the recruitment of the transcription machinery and transcriptional initiation, the transcriptional start sites (TSS) of active genes are, for the most part, devoid of nucleosomes. In contrast, downstream transcribed regions are tightly packed with nucleosomes, which are likely to prevent aberrant entry of the transcription machinery within coding regions, but they can also hinder progression of the polymerase. In order for RNAP II to progress through the transcribed region, the generation of a permissive chromatin structure is needed and involves the removal and redeposition of nucleosomes along transcribed regions. Such a mechanism is believed to be controlled in part by posttranslational modifications of histones, such as by acetylation and methylation, which are actively involved in regulation of transcriptional elongation (2,18,20). Among these modifications, histone acetylation has long been recognized to be associated with transcriptional activation. However, its function in transcription and its regulation have been studied m...

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The Mammalian Sin3 Proteins Are Required for Muscle Development and Sarcomere Specification

Oevelen

Bowman

Pellegrino

et al. 2010

Molecular and Cellular Biology

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The highly related mammalian Sin3A and Sin3B proteins provide a versatile platform for chromatinmodifying activities. Sin3-containing complexes play a role in gene repression through deacetylation of nucleosomes. Here, we explore a role for Sin3 in myogenesis by examining the phenotypes resulting from acute somatic deletion of both isoforms in vivo and from primary myotubes in vitro. Myotubes ablated for Sin3A alone, but not Sin3B, displayed gross defects in sarcomere structure that were considerably enhanced upon simultaneous ablation of both isoforms. Massively parallel sequencing of Sin3A-and Sin3B-bound genomic loci revealed a subset of target genes directly involved in sarcomere function that are positively regulated by Sin3A and Sin3B proteins. Both proteins were coordinately recruited to a substantial number of genes. Interestingly, depletion of Sin3B led to compensatory increases in Sin3A recruitment at certain target loci, but Sin3B was never found to compensate for Sin3A loss. Thus, our analyses describe a novel transcriptional role for Sin3A and Sin3B proteins associated with maintenance of differentiated muscle cells.

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Sin3B Expression Is Required for Cellular Senescence and Is Up-regulated upon Oncogenic Stress

Grandinetti¹,

Jelinic²,

DiMauro³

et al. 2009

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Serial passage of primary mammalian cells or strong mitogenic signals induce a permanent exit from the cell cycle called senescence. A characteristic of senescent cells is the heterochromatinization of loci encoding pro-proliferative genes, leading to their transcriptional silencing. Senescence is thought to represent a defense mechanism against uncontrolled proliferation and cancer. Consequently, genetic alterations that allow senescence bypass are associated with susceptibility to oncogenic transformation. We show that fibroblasts genetically inactivated for the chromatin-associated Sin3B protein are refractory to replicative and oncogene-induced senescence. Conversely, overexpression of Sin3B triggers senescence and the formation of senescence-associated heterochromatic foci. Although Sin3B is strongly up-regulated upon oncogenic stress, decrease in expression of Sin3B is associated with tumor progression in vivo, suggesting that expression of Sin3B may represent a barrier against transformation. Together, these results underscore the contribution of senescence in tumor suppression and suggest that expression of chromatin modifiers is modulated at specific stages of cellular transformation. Consequently, these findings suggest that modulation of Sin3B-associated activities may represent new therapeutic opportunities for treatment of cancers. [Cancer Res 2009;69(16):6430-7]

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Transcriptional Profiling of a Selective CREB Binding Protein Bromodomain Inhibitor Highlights Therapeutic Opportunities

Chekler

Pellegrino

Lanz

et al. 2015

Chemistry & Biology

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Bromodomains are involved in transcriptional regulation through the recognition of acetyl lysine modifications on diverse proteins. Selective pharmacological modulators of bromodomains are lacking, although the largely hydrophobic nature of the pocket makes these modules attractive targets for small-molecule inhibitors. This work describes the structure-based design of a highly selective inhibitor of the CREB binding protein (CBP) bromodomain and its use in cell-based transcriptional profiling experiments. The inhibitor downregulated a number of inflammatory genes in macrophages that were not affected by a selective BET bromodomain inhibitor. In addition, the CBP bromodomain inhibitor modulated the mRNA level of the regulator of G-protein signaling 4 (RGS4) gene in neurons, suggesting a potential therapeutic opportunity for CBP inhibitors in the treatment of neurological disorders.

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Chromatin associated Sin3A is essential for male germ cell lineage in the mouse

Pellegrino

Castrillón

Gourichon

2012

Developmental Biology

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Spermatogenesis is a complex process that requires coordinated proliferation and differentiation of male germ cells. The molecular events that dictate this process are largely unknown, but are likely to involve highly regulated transcriptional control. In this study, we investigate the contribution of chromatin associated Sin3A in mouse germ cell lineage development. Genetic inactivation of Sin3A in the male germline leads to sterility that results from the early and penetrant apoptotic death observed in Sin3A-deleted germ cells, coincident with the reentry in mitosis. Sin3A-deleted testes exhibit a Sertoli-cell only phenotype, consistent with the absolute requirement for Sin3A in germ cells’ development and/or viability. Interestingly, transcripts analysis revealed that the expression program of Sertoli cells is altered upon inactivation of Sin3A in germ cells. These studies identified a central role for the mammalian Sin3-HDAC complex in the germ cell lineage, and point to an exquisite transcriptional crosstalk between germ cells and their niche to support fertility in mammals.

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