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腺病毒E1A抑制结构域以一种可被TFIIB逆转的方式破坏TATA结合蛋白与TATA框之间的相互作用。

The adenovirus E1A repression domain disrupts the interaction between the TATA binding protein and the TATA box in a manner reversible by TFIIB.

作者信息

Song C Z, Loewenstein P M, Toth K, Tang Q, Nishikawa A, Green M

机构信息

Institute for Molecular Virology, Saint Louis University School of Medicine, Missouri 63110, USA.

出版信息

Mol Cell Biol. 1997 Apr;17(4):2186-93. doi: 10.1128/MCB.17.4.2186.

Abstract

The human adenovirus E1A 243 amino acid oncoprotein possesses a transcription repression function that appears to be linked with its ability to induce cell cycle progression and to inhibit cell differentiation. The molecular mechanism of E1A repression has been poorly understood. Recently, we reported that the TATA binding protein (TBP) is a cellular target of E1A repression. Here we demonstrate that the interaction between TBP and the E1A repression domain is direct and specific. The TBP binding domain within E1A 243R maps to E1A N-terminal residues approximately 1 to 35 and is distinct from the TBP binding domain within conserved region 3 unique to the E1A 289R transactivator. An E1A protein fragment consisting of only the E1A N-terminal 80 amino acids (E1A 1-80) and containing the E1A repression function was found to block the interaction between TBP and the TATA box element as shown by gel mobility and DNase protection analysis. Interestingly, a preformed TBP-TATA box promoter complex can be dissociated by E1A 1-80. Further, TFIIB can prevent E1A disruption of TBP-TATA box interaction. TFIIB, like TBP, can overcome E1A repression of transcription in vitro. The ability of the E1A repression domain to block TBP interaction with the TATA box and the ability of TFIIB to reverse E1A disruption of the TBP-TATA box complex implies a mechanism for E1A repression distinct from those of known cellular repressors that target TBP.

摘要

人腺病毒E1A 243个氨基酸的癌蛋白具有转录抑制功能,这一功能似乎与其诱导细胞周期进程和抑制细胞分化的能力相关。E1A抑制的分子机制一直未被充分理解。最近,我们报道了TATA结合蛋白(TBP)是E1A抑制的细胞靶点。在此我们证明TBP与E1A抑制结构域之间的相互作用是直接且特异的。E1A 243R内的TBP结合结构域定位于E1A N端大约1至35位的残基,并且与E1A 289R反式激活因子特有的保守区域3内的TBP结合结构域不同。凝胶迁移和DNase保护分析表明,一个仅由E1A N端80个氨基酸(E1A 1 - 80)组成且具有E1A抑制功能的E1A蛋白片段能够阻断TBP与TATA盒元件之间的相互作用。有趣的是,预先形成的TBP - TATA盒启动子复合物可被E1A 1 - 80解离。此外,TFIIB能够阻止E1A破坏TBP - TATA盒的相互作用。与TBP一样,TFIIB在体外能够克服E1A对转录的抑制。E1A抑制结构域阻断TBP与TATA盒相互作用的能力以及TFIIB逆转E1A对TBP - TATA盒复合物破坏的能力,暗示了一种与已知靶向TBP的细胞抑制因子不同的E1A抑制机制。

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