四膜虫端粒酶p65中一个新的RNA结合结构域启动端粒酶全酶的分级组装。
A novel RNA binding domain in tetrahymena telomerase p65 initiates hierarchical assembly of telomerase holoenzyme.
作者信息
O'Connor Catherine M, Collins Kathleen
机构信息
Department of Molecular and Cell Biology, University of California at Berkeley, Berkeley, CA 94720-3204, USA.
出版信息
Mol Cell Biol. 2006 Mar;26(6):2029-36. doi: 10.1128/MCB.26.6.2029-2036.2006.
Abstract
Telomerase reverse transcriptase (TERT) and telomerase RNA (TER) assemble as part of a holoenzyme that synthesizes telomeric repeats at chromosome ends. Genetic approaches have identified proteins that are required for in vivo association of TERT and TER, including the Tetrahymena telomerase holoenzyme protein p65. Here, we use quantitative assays to define the mechanisms underlying p65 function in holoenzyme biogenesis. We demonstrate that four modules of p65 contribute affinity for TER, including a C-terminal domain that recognizes the conserved dinucleotide bulge of central stem IV. This C-terminal domain is necessary and sufficient for p65's function in enhancing the recruitment of TERT to TER. Finally, we show that p65 and TERT assemble on TER with hierarchical rather than cooperative binding. These findings elucidate an extensive network of p65-TER recognition specificity and define a novel p65 RNA binding domain that initiates telomerase holoenyzme biogenesis.
摘要
端粒酶逆转录酶(TERT)和端粒酶RNA(TER)作为全酶的一部分组装在一起,该全酶在染色体末端合成端粒重复序列。遗传学方法已鉴定出TERT和TER在体内缔合所需的蛋白质,包括嗜热四膜虫端粒酶全酶蛋白p65。在这里,我们使用定量分析来确定p65在全酶生物合成中发挥功能的潜在机制。我们证明p65的四个模块对TER具有亲和力,包括一个识别中央茎IV保守二核苷酸凸起的C末端结构域。该C末端结构域对于p65增强TERT募集到TER的功能是必需且充分的。最后,我们表明p65和TERT以分级而非协同结合的方式组装在TER上。这些发现阐明了p65-TER识别特异性的广泛网络,并定义了一个启动端粒酶全酶生物合成的新型p65 RNA结合结构域。
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