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CHIP/LDB转录复合体的模块化调控细胞分化。

Modularity of CHIP/LDB transcription complexes regulates cell differentiation.

作者信息

Bronstein Revital, Segal Daniel

机构信息

Department of Molecular Microbiology and Biotechnology, Tel Aviv University, Tel Aviv, Israel.

出版信息

Fly (Austin). 2011 Jul-Sep;5(3):200-5. doi: 10.4161/fly.5.3.14854. Epub 2011 Jul 1.

DOI:10.4161/fly.5.3.14854
PMID:21406967
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3225763/
Abstract

Transcription is the first step through which the cell operates, via its repertoire of transcription complexes, to direct cellular functions and cellular identity by generating the cell-specific transcriptome. The modularity of the composition of constituents of these complexes allows the cell to delicately regulate its transcriptome. In a recent study we have examined the effects of reducing the levels of specific transcription co-factors on the function of two competing transcription complexes, namely CHIP-AP and CHIP-PNR which regulate development of cells in the thorax of Drosophila. We found that changing the availability of these co-factors can shift the balance between these complexes leading to transition from utilization of CHIP-AP to CHIP-PNR. This is reflected in change in the expression profile of target genes, altering developmental cell fates. We propose that such a mechanism may operate in normal fly development. Transcription complexes analogous to CHIP-AP and CHIP-PNR exist in mammals and we discuss how such a shift in the balance between them may operate in normal mammalian development.

摘要

转录是细胞运作的第一步,细胞通过其转录复合物库,通过生成细胞特异性转录组来指导细胞功能和细胞特性。这些复合物成分的模块化组成使细胞能够精细地调节其转录组。在最近的一项研究中,我们研究了降低特定转录辅因子水平对两种相互竞争的转录复合物功能的影响,这两种复合物分别是CHIP-AP和CHIP-PNR,它们调节果蝇胸部细胞的发育。我们发现,改变这些辅因子的可用性会改变这些复合物之间的平衡,导致从CHIP-AP的利用转向CHIP-PNR的利用。这反映在靶基因表达谱的变化上,改变了发育中的细胞命运。我们提出,这种机制可能在正常果蝇发育中起作用。在哺乳动物中存在类似于CHIP-AP和CHIP-PNR的转录复合物,我们讨论了它们之间平衡的这种变化在正常哺乳动物发育中可能如何起作用。

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