King A J, Teertstra W R, van der Vliet P C
Laboratory for Physiological Chemistry, University of Utrecht, 3508 TA Utrecht, The Netherlands.
J Biol Chem. 1997 Sep 26;272(39):24617-23. doi: 10.1074/jbc.272.39.24617.
Initiation of adenovirus DNA replication occurs by a jumping back mechanism in which the precursor terminal priming protein (pTP) forms a pTP.trinucleotide complex (pTP.CAT) catalyzed by the viral DNA polymerase (pol). This covalent complex subsequently jumps back 3 bases to permit the start of chain elongation. Before initiation, pTP and pol form a tight heterodimer. We investigated the fate of this pTP.pol complex during the various steps in replication. Employing in vitro initiation and elongation on both natural viral templates and synthetic oligonucleotides followed by glycerol gradient separation of the reaction products, we established that pTP and pol are separated during elongation. Whereas pTP.C and pTP. CA were still bound to the polymerase, after the formation of pTP. CAT 60% of the pTP.pol complex had dissociated. Dissociation coincides with a change in sensitivity to inhibitors and in Km for dNTPs, suggesting a conformational change in the polymerase, both in the active site and in the pTP interaction domain. In agreement with this, the polymerase becomes a more efficient enzyme after release of the pTP primer. We also investigated whether the synthesis of a pTP initiation intermediate is confined to three nucleotides. Employing synthetic oligonucleotide templates with a sequence repeat of two nucleotides (GAGAGAGA ... instead of the natural GTAGTA ... ) we show that G5 rather than G3 is used to start, leading to a pTP. tetranucleotide (CTCT) intermediate that subsequently jumps back. This indicates flexibility in the use of the start site with a preference for the synthesis of three or four nucleotides during initiation rather than two.
腺病毒DNA复制的起始通过一种回跳机制发生,其中前体末端引发蛋白(pTP)形成由病毒DNA聚合酶(pol)催化的pTP.三核苷酸复合物(pTP.CAT)。这种共价复合物随后回跳3个碱基以允许链延伸的开始。在起始之前,pTP和pol形成紧密的异二聚体。我们研究了这种pTP.pol复合物在复制的各个步骤中的命运。利用天然病毒模板和合成寡核苷酸进行体外起始和延伸,随后通过甘油梯度分离反应产物,我们确定pTP和pol在延伸过程中分离。虽然pTP.C和pTP.CA仍与聚合酶结合,但在pTP.CAT形成后,60%的pTP.pol复合物已经解离。解离与对抑制剂的敏感性变化和dNTPs的Km变化一致,这表明聚合酶在活性位点和pTP相互作用结构域都发生了构象变化。与此一致的是,在释放pTP引物后,聚合酶成为一种更高效的酶。我们还研究了pTP起始中间体的合成是否局限于三个核苷酸。利用具有两个核苷酸序列重复(GAGAGAGA...而不是天然的GTAGTA...)的合成寡核苷酸模板,我们表明使用G5而不是G3开始,导致形成pTP.四核苷酸(CTCT)中间体,随后该中间体回跳。这表明起始位点的使用具有灵活性,在起始过程中更倾向于合成三个或四个核苷酸而不是两个。
