Ryan Mayle, William K Holloman, Michael E O'Donnell
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引用次数: 0
摘要
细胞生物学和遗传学研究表明,DNA 双链断裂(DSB)修复可以使用横跨 DNA 断裂位点的 RNA 转录本作为修复模板。这种类型的 DSB 修复需要逆转录酶将 RNA 序列转化为 DNA,以促进断裂的修复,而不是像典型的 DSB 修复那样从 DNA 模板进行复制。转座合成(TLS)DNA 聚合酶(Pol)通常比 DNA Pols 更具杂合性,因此有人认为反转录可以由 TLS Pol 进行。事实上,一些研究已经证明人类 Pol η 具有反转录酶活性,而另一些研究则认为酵母 TLS Pol ζ 也参与其中。在这里,我们纯化了所有七种已知的酿酒酵母核 DNA Pols,并比较了它们的反转录酶活性。比较结果表明,Pol ζ 的反转录酶活性远远超过 Pol η 和其他所有 DNA Pols。我们发现,Pol ζ 的反转录酶活性不受 RPA 或 RFC/PCNA 的影响,并能分布式地使 DNA 与 RNA 模板链互补。与之前在体内进行的 S. cerevisiae 研究一致,我们认为 Pol ζ 是在 RNA 模板 DSB 修复途径中发挥作用的主要 DNA Pol。
DNA polymerase ζ has robust reverse transcriptase activity relative to other cellular DNA polymerases.
Cell biology and genetic studies have demonstrated that DNA double strand break (DSB) repair can be performed using an RNA transcript that spans the site of the DNA break as a template for repair. This type of DSB repair requires a reverse transcriptase to convert an RNA sequence into DNA to facilitate repair of the break, rather than copying from a DNA template as in canonical DSB repair. Translesion synthesis (TLS) DNA polymerases (Pol) are often more promiscuous than DNA Pols, raising the notion that reverse transcription could be performed by a TLS Pol. Indeed, several studies have demonstrated that human Pol η has reverse transcriptase activity, while others have suggested that the yeast TLS Pol ζ is involved. Here, we purify all seven known nuclear DNA Pols of Saccharomyces cerevisiae and compare their reverse transcriptase activities. The comparison shows that Pol ζ far surpasses Pol η and all other DNA Pols in reverse transcriptase activity. We find that Pol ζ reverse transcriptase activity is not affected by RPA or RFC/PCNA and acts distributively to make DNA complementary to an RNA template strand. Consistent with prior S. cerevisiae studies performed in vivo, we propose that Pol ζ is the major DNA Pol that functions in the RNA templated DSB repair pathway.
期刊介绍:
The Journal of Biological Chemistry welcomes high-quality science that seeks to elucidate the molecular and cellular basis of biological processes. Papers published in JBC can therefore fall under the umbrellas of not only biological chemistry, chemical biology, or biochemistry, but also allied disciplines such as biophysics, systems biology, RNA biology, immunology, microbiology, neurobiology, epigenetics, computational biology, ’omics, and many more. The outcome of our focus on papers that contribute novel and important mechanistic insights, rather than on a particular topic area, is that JBC is truly a melting pot for scientists across disciplines. In addition, JBC welcomes papers that describe methods that will help scientists push their biochemical inquiries forward and resources that will be of use to the research community.