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EOR-2 是秀丽隐杆线虫中 BTB-zinc finger 蛋白 EOR-1 的必需结合伴侣。

EOR-2 is an obligate binding partner of the BTB-zinc finger protein EOR-1 in Caenorhabditis elegans.

机构信息

Department of Genetics, University of Pennsylvania School of Medicine, Philadelphia, Pennsylvania 19104, USA.

出版信息

Genetics. 2010 Apr;184(4):899-913. doi: 10.1534/genetics.109.111591. Epub 2010 Jan 11.

DOI:10.1534/genetics.109.111591
PMID:20065070
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2865926/
Abstract

BTB-zinc finger transcription factors play many important roles in metazoan development. In these proteins, the BTB domain is critical for dimerization and for recruiting cofactors to target genes. Identification of these cofactors is important for understanding how BTB-zinc finger proteins influence transcription. Here we show that the novel but conserved protein EOR-2 is an obligate binding partner of the BTB-zinc finger protein EOR-1 in Caenorhabditis elegans. EOR-1 and EOR-2 function together to promote multiple Ras/ERK-dependent cell fates during development, and we show that EOR-1 is a robust substrate of ERK in vitro. A point mutation (L81F) in the EOR-1 BTB domain reduces both ERK phosphorylation and EOR-2 binding and eliminates all detectable biological function without affecting EOR-1 expression levels, localization, or dimerization. This point mutation lies near the predicted charged pocket region of the EOR-1 BTB dimer, a region that, in other BTB-zinc finger proteins, has been proposed to interact with corepressors or coactivators. We also show that a conserved zinc finger-like motif in EOR-2 is required for binding to EOR-1, that the interaction between EOR-1 and EOR-2 is direct, and that EOR-2 can bind to the human BTB-zinc finger protein PLZF. We propose that EOR-2 defines a new family of cofactors for BTB-zinc finger transcription factors that may have conserved roles in other organisms.

摘要

BTB 锌指转录因子在后生动物的发育中发挥着许多重要作用。在这些蛋白质中,BTB 结构域对于二聚化和募集靶基因的辅助因子至关重要。鉴定这些辅助因子对于理解 BTB 锌指蛋白如何影响转录非常重要。在这里,我们表明,新型但保守的蛋白 EOR-2 是 Caenorhabditis elegans 中 BTB 锌指蛋白 EOR-1 的必需结合伴侣。EOR-1 和 EOR-2 共同作用以促进发育过程中多个 Ras/ERK 依赖的细胞命运,我们表明 EOR-1 是 ERK 在体外的强底物。BTB 结构域中 EOR-1 的一个点突变(L81F)降低了 ERK 的磷酸化和 EOR-2 的结合,并且消除了所有可检测的生物学功能,而不影响 EOR-1 的表达水平、定位或二聚化。该点突变位于 EOR-1 BTB 二聚体的预测带电口袋区域附近,在其他 BTB 锌指蛋白中,该区域已被提议与核心抑制剂或共激活剂相互作用。我们还表明,EOR-2 中的保守锌指样模体对于与 EOR-1 结合是必需的,EOR-1 和 EOR-2 之间的相互作用是直接的,并且 EOR-2 可以结合到人 BTB 锌指蛋白 PLZF。我们提出 EOR-2 定义了 BTB 锌指转录因子的一个新的辅助因子家族,它可能在其他生物体中具有保守的作用。

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