Choi Wonyoung, Harshey Rasika M
Section of Molecular Genetics and Microbiology and Institute of Cellular and Molecular Biology, University of Texas at Austin, Austin, TX 78712, USA.
Proc Natl Acad Sci U S A. 2010 Jun 1;107(22):10014-9. doi: 10.1073/pnas.0912615107. Epub 2010 Feb 18.
Phage Mu transposes by two distinct pathways depending on the specific stage of its life cycle. A common strand transfer intermediate is resolved differentially in the two pathways. During lytic growth, the intermediate is resolved by replication of Mu initiated within the flanking target DNA; during integration of infecting Mu, it is resolved without replication, by removal and repair of DNA from a previous host that is still attached to the ends of the incoming Mu genome. We have discovered that the cryptic endonuclease activity reported for the isolated C-terminal domain of the transposase MuA [Wu Z, Chaconas G (1995) A novel DNA binding and nuclease activity in domain III of Mu transposase: Evidence for a catalytic region involved in donor cleavage. EMBO J 14:3835-3843], which is not observed in the full-length protein or in the assembled transpososome in vitro, is required in vivo for removal of the attached host DNA or "5'flap" after the infecting Mu genome has integrated into the E. coli chromosome. Efficient flap removal also requires the host protein ClpX, which is known to interact with the C-terminus of MuA to remodel the transpososome for replication. We hypothesize that ClpX constitutes part of a highly regulated mechanism that unmasks the cryptic nuclease activity of MuA specifically in the repair pathway.
噬菌体Mu根据其生命周期的特定阶段通过两种不同的途径进行转座。一种常见的链转移中间体在这两种途径中以不同方式得到解决。在裂解生长期间,中间体通过在侧翼靶DNA内启动的Mu复制来解决;在感染性Mu整合期间,它通过从仍然附着于进入的Mu基因组末端的先前宿主中去除和修复DNA而在不进行复制的情况下得到解决。我们发现,转座酶MuA的分离的C末端结构域所具有的隐秘核酸内切酶活性[Wu Z, Chaconas G(1995) Mu转座酶结构域III中的一种新型DNA结合和核酸酶活性:参与供体切割的催化区域的证据。《欧洲分子生物学组织杂志》14:3835 - 3843],在全长蛋白或体外组装的转座体中未观察到,但在感染性Mu基因组整合到大肠杆菌染色体后,体内需要它来去除附着的宿主DNA或“5'侧翼序列”。高效去除侧翼序列还需要宿主蛋白ClpX,已知它与MuA的C末端相互作用以重塑转座体进行复制。我们推测,ClpX构成了一种高度调控机制的一部分,该机制专门在修复途径中揭示MuA的隐秘核酸酶活性。