线粒体 DNA 远端重链启动子的转录要求。

Transcriptional requirements of the distal heavy-strand promoter of mtDNA.

机构信息

Division of Child Rehabilitation, The Children's Hospital of Philadelphia, Philadelphia, PA 19104, USA.

出版信息

Proc Natl Acad Sci U S A. 2012 Apr 24;109(17):6508-12. doi: 10.1073/pnas.1118594109. Epub 2012 Mar 27.

DOI:10.1073/pnas.1118594109

PMID:22454497

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3340101/

Abstract

The heavy strand of mtDNA contains two promoters with nonoverlapping functions. The role of the minor heavy-strand promoter (HSP2) is controversial, because the promoter has been difficult to activate in an in vitro system. We have isolated HSP2 by excluding its interaction with the more powerful HSP1 promoter, and we find that it is transcribed efficiently by recombinant mtRNA polymerase and mitochondrial transcription factor B2. The mitochondrial transcription factor A is not required for initiation, but it has the ability to alternatively activate and repress the HSP2 transcriptional unit depending on the ratio between mitochondrial transcription factor A and other transcription factors. The positioning of transcriptional initiation agrees with our current understanding of HSP2 activity in vivo. Serial deletion of HSP2 shows that only proximal sequences are required. Several mutations, including the disruption of a polycytosine track upstream of the HSP2 initiation site, influence transcriptional activity. Transcription from HSP2 is also observed when HeLa cell mitochondrial extract is used as the source of mitochondrial polymerase, and this transcription is maintained when HSP2 is provided in proper spacing and context to the HSP1 promoter. Studies of the linked heavy-strand promoters show that they are differentially regulated by ATP dosage. We conclude that HSP2 is transcribed and has features that allow it to regulate mitochondrial mRNA synthesis.

摘要

重链 mtDNA 含有两个具有非重叠功能的启动子。次要重链启动子 (HSP2) 的作用存在争议，因为该启动子在体外系统中难以激活。我们通过排除其与更强大的 HSP1 启动子的相互作用来分离 HSP2，并发现它可以由重组 mtRNA 聚合酶和线粒体转录因子 B2 有效地转录。线粒体转录因子 A 不需要起始，但它能够根据线粒体转录因子 A 和其他转录因子的比例，选择性地激活和抑制 HSP2 转录单元。转录起始的定位与我们对 HSP2 在体内活性的现有理解一致。HSP2 的连续缺失表明仅近端序列是必需的。几个突变，包括破坏 HSP2 起始位点上游的聚胞嘧啶序列，会影响转录活性。当使用 HeLa 细胞线粒体提取物作为线粒体聚合酶的来源时，也可以观察到 HSP2 的转录，并且当 HSP2 以适当的间隔和上下文提供给 HSP1 启动子时，这种转录得以维持。对连接的重链启动子的研究表明，它们受 ATP 剂量的差异调节。我们得出结论，HSP2 被转录，并具有允许其调节线粒体 mRNA 合成的特征。

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