Hsu M Y, Eagle S G, Inouye M, Inouye S
Department of Biochemistry, Robert Wood Johnson Medical School, University of Medicine and Dentistry of New Jersey, Piscataway 08854.
J Biol Chem. 1992 Jul 15;267(20):13823-9.
msDNA-Ec67 is produced in a clinical strain of Escherichia coli and composed of a 67-base single-stranded DNA, which is linked to the 2'-OH group of the 15th rG residue of a 58-base RNA molecule by a 2',5'-phosphodiester linkage (Lampson, B. C., Sun, J., Hsu, M.-Y., Vallejo-Ramirez, J., Inouye, S., and Inouye, M. (1989) Science 243, 1033-1038). The production of msDNA-Ec67 is dependent upon retron-Ec67, which consists of the msr-msd region and the gene for reverse transcriptase (RT). These two elements were separately cloned into plasmids; p67-BHO.6 contained the msr-msd region and pRT-67 contained the RT gene under the lpp-lac promoter-operator. msDNA-Ec67 was produced only when cells were transformed with both plasmids. In addition, msDNA-Ec67 was synthesized in a cell-free system using total RNA prepared from cells harboring plasmid p67-BHO.6 and purified Ec67-RT. Using this cell-free system, the priming reaction, during initiation of DNA synthesis, was demonstrated to be a specific template-directed event; only dTTP was incorporated into a 132-base precursor RNA yielding a 133-base compound. This specific dT addition could be altered to dA or dC by simply substituting the 118th A residue of the putative msr-msd transcript with a T or G residue. The priming reaction was blocked when A was substituted for G at the 15th residue of the precursor RNA transcript, which corresponds to the branched rG residue in msDNA. DNA chain elongation could be terminated by adding ddNTP in the cell-free system, forming a sequence ladder. The DNA sequence determined from this ladder completely agreed with the msDNA sequence. The RT extension reaction was completely blocked when the RNA preparation was treated with RNase A but not when the preparation was treated with DNase. This clearly demonstrates that RNA but not DNA is responsible for the msDNA production. A part of the fully extended cell-free product contained a 13-base RNA strand resistant to RNase A, which is consistent with the previously proposed model. In this model, the 5'-end sequence of the msr-msd transcript (a2; bases 1-13) forms a duplex with the 3'-end sequence (a1) of the same transcript, thus serving as a primer, as well as a template for msDNA synthesis by RT. Our results are inconsistent with a model recently proposed by Lease and Yee (Lease, R. A., and Yee, T. (1991) J. Biol. Chem. 266, 14497-14503).
msDNA - Ec67由大肠杆菌的一个临床菌株产生,由一条67个碱基的单链DNA组成,该单链DNA通过2',5'-磷酸二酯键与一个58个碱基的RNA分子的第15个rG残基的2'-OH基团相连(兰普森,B.C.,孙,J.,许,M.-Y.,瓦列霍 - 拉米雷斯,J.,井上,S.,和井上,M.(1989年)《科学》243卷,1033 - 1038页)。msDNA - Ec67的产生依赖于反转录子 - Ec67,它由msr - msd区域和逆转录酶(RT)基因组成。这两个元件被分别克隆到质粒中;p67 - BHO.6含有msr - msd区域,pRT - 67在lpp - lac启动子 - 操纵子下含有RT基因。只有当细胞同时用这两个质粒转化时才产生msDNA - Ec67。此外,使用从携带质粒p67 - BHO.6的细胞中制备的总RNA和纯化的Ec67 - RT在无细胞系统中合成了msDNA - Ec67。利用这个无细胞系统,在DNA合成起始过程中的引发反应被证明是一个特定的模板导向事件;只有dTTP被掺入到一个132个碱基的前体RNA中,产生一个133个碱基的化合物。通过简单地将假定的msr - msd转录本的第118个A残基替换为T或G残基,这种特定的dT添加可以改变为dA或dC。当前体RNA转录本的第15个残基处的G被A替换时,引发反应被阻断,该残基对应于msDNA中的分支rG残基。在无细胞系统中通过添加ddNTP可以终止DNA链延伸,形成一个序列梯。从这个梯确定的DNA序列与msDNA序列完全一致。当RNA制剂用RNase A处理时,RT延伸反应完全被阻断,但当制剂用DNase处理时则不然。这清楚地表明是RNA而不是DNA负责msDNA的产生。完全延伸的无细胞产物的一部分包含一条对RNase A有抗性的13个碱基的RNA链,这与先前提出的模型一致。在这个模型中,msr - msd转录本的5'-末端序列(a2;碱基1 - 13)与同一转录本的3'-末端序列(a1)形成双链体,因此作为引物以及RT合成msDNA的模板。我们的结果与利兹和伊最近提出的模型不一致(利兹,R.A.,和伊,T.(1991年)《生物化学杂志》266卷,14497 - 14503页)。
