Induction of fragility at the human RNU2 locus by cytosine arabinoside is dependent upon a transcriptionally competent U2 small nuclear RNA gene and the expression of p53.

Somatic Cell and Molecular Genetics Pub Date : 1997-11-01 DOI:10.1007/BF02673748

H L MacArthur, M L Agarwal, S Bacchetti

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引用次数: 6

Abstract

Chromosomal fragile sites are regions that are intrinsically unstable and are susceptible to experimentally induced damage. In most cases, the target and mechanism of induction of fragility are unknown. Using ectopic integration of engineered DNA arrays to create "new" fragile sites, we and others have previously shown that the transcriptionally competent U2 gene is necessary and sufficient for induction of fragility at the RNU2 locus upon infection of human cells with Adenovirus 12. In the present study we have investigated the response of the RNU2 locus to cytosine arabinoside (araC), an inhibitor of DNA polymerases and a common inducer of fragile sites. We demonstrate that the RNU2 locus is sensitive to the drug and that araC-induced fragility is dependent upon a functional U2 gene and on the expression of the cellular p53 protein. Our results identify a novel DNA structure associated with fragile sites and suggest a role for transcription and repair processes in RNU2 fragility.

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阿拉伯糖胞嘧啶诱导人类RNU2位点的易碎性依赖于具有转录能力的U2小核RNA基因和p53的表达。

染色体脆弱位点是本质上不稳定的区域，容易受到实验诱导的损伤。在大多数情况下，脆弱性诱发的目标和机制是未知的。利用工程DNA阵列的异位整合来创建“新的”脆弱位点，我们和其他人之前已经证明，在腺病毒12感染人类细胞时，转录能力强的U2基因是诱导RNU2位点脆弱的必要和充分条件。在本研究中，我们研究了RNU2基因座对阿拉伯糖胞嘧啶(araC)的反应，araC是一种DNA聚合酶抑制剂和脆弱位点的常见诱导剂。我们证明RNU2位点对药物敏感，arac诱导的脆性依赖于功能U2基因和细胞p53蛋白的表达。我们的研究结果确定了一种与脆性位点相关的新型DNA结构，并提出了RNU2脆性中转录和修复过程的作用。

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Somatic Cell and Molecular Genetics

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