端粒重复结合因子1是一种二聚体，可使端粒DNA弯曲。

TRF1 is a dimer and bends telomeric DNA.

作者信息

Bianchi A, Smith S, Chong L, Elias P, de Lange T

机构信息

The Rockefeller University, New York, NY 10021, USA.

出版信息

EMBO J. 1997 Apr 1;16(7):1785-94. doi: 10.1093/emboj/16.7.1785.

DOI:10.1093/emboj/16.7.1785

PMID:9130722

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1169781/

Abstract

TRF1 is a mammalian telomeric protein that binds to the duplex array of TTAGGG repeats at chromosome ends. TRF1 has homology to the DNA-binding domain of the Myb family of transcription factors but, unlike most Myb-related proteins, TRF1 carries one rather than multiple Myb-type DNA-binding motifs. Here we show that TRF1 binds DNA as a dimer using a large conserved domain near the N-terminus of the protein for TRF1-TRF1 interactions. Dimerization was observed both in a complex with DNA and in the yeast two-hybrid assay. TRF1 dimers were found to require both Myb repeats for the formation of a stable complex with DNA, indicating a parallel between the DNA-binding mode of TRF1 and other Myb-related proteins. TRF1 was found to have a number of biochemical similarities to Rap1p, a distantly related DNA-binding protein that functions at telomeres in yeast. Rap1p and TRF1 both require two Myb motifs for DNA binding and both factors bind along their cognate telomeric sequences without showing strong cooperative interactions between adjacent proteins. Furthermore, TRF1 was found to bend its telomeric site to an angle of -120 degrees. Since Rap1p similarly distorts telomeric DNA, we propose that DNA bending is important for the function of telomeres in yeast and mammals.

摘要

TRF1是一种哺乳动物端粒蛋白，它与染色体末端TTAGGG重复序列的双链阵列结合。TRF1与转录因子Myb家族的DNA结合结构域具有同源性，但与大多数Myb相关蛋白不同的是，TRF1携带一个而非多个Myb型DNA结合基序。在此我们表明，TRF1以二聚体形式结合DNA，利用该蛋白N端附近一个大的保守结构域进行TRF1-TRF1相互作用。在与DNA形成的复合物以及酵母双杂交试验中均观察到了二聚化现象。发现TRF1二聚体与DNA形成稳定复合物需要两个Myb重复序列，这表明TRF1与其他Myb相关蛋白的DNA结合模式存在相似之处。发现TRF1与Rap1p存在一些生化相似性，Rap1p是一种在酵母端粒发挥作用的远亲DNA结合蛋白。Rap1p和TRF1与DNA结合均需要两个Myb基序，并且这两种因子均沿着其同源端粒序列结合，相邻蛋白之间未表现出强烈的协同相互作用。此外，发现TRF1将其端粒位点弯曲至-120度角。由于Rap1p同样会使端粒DNA发生扭曲，我们提出DNA弯曲对于酵母和哺乳动物中端粒的功能很重要。

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本文引用的文献

Comparison of the human and mouse genes encoding the telomeric protein, TRF1: chromosomal localization, expression and conserved protein domains.编码端粒蛋白TRF1的人类和小鼠基因的比较：染色体定位、表达及保守蛋白结构域

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