Mallory J B, Alfano C, McMacken R
Department of Biochemistry, Johns Hopkins University, School of Hygiene and Public Health, Baltimore, Maryland 21205.
J Biol Chem. 1990 Aug 5;265(22):13297-307.
The bacteriophage lambda P protein promoters replication of the phage chromosome by recruiting a key component of the cellular replication machinery to the viral origin. Specifically, P protein delivers one or more molecules of Escherichia coli DnaB helicase to a nucleoprotein structure formed by the lambda O initiator at the lambda replication origin. Using purified proteins, we have examined the features of the pivotal host virus interaction between P and DnaB. These two proteins interact in vitro to form a P.DnaB protein complex that can be resolved by sedimentation or by chromatography on DEAE-cellulose from the individual free proteins. The sedimentation coefficient of the P.DnaB complex, 13 S, suggests a size larger than that of free DnaB hexamer (Mr = 313,600). The P.DnaB complex isolated by glycerol gradient sedimentation contains approximately three protomers of P/DnaB hexamer, consistent with a molecular weight of 393,000. The isolated P.DnaB complex functions in vitro in the initiation of lambda DNA replication. Interaction of P with DnaB strongly suppressed both the intrinsic DNA-dependent ATPase activity of DnaB, as well as the capacity of DnaB to assist E. coli primase in the general priming reaction. Formation of a P.DnaB protein complex also blocked DnaB from functioning in the initiation of E. coli DNA replication in vitro. The physical and functional properties of lambda P protein suggest that it is a viral analogue of the E. coli DnaC replication protein. Like P, DnaC also binds to DnaB (Wickner, S., and Hurwitz, J. (1975) Proc. Natl. Acad. Sci. U. S. A. 72, 921-925), but unlike P, DnaC stimulates DnaB-mediated general priming. When viral P and bacterial DnaC replication proteins were placed in direct competition with one another for binding to DnaB, the viral protein was clearly predominant. For example, a 5-fold molar excess of DnaC protein only partially reversed the inhibitory effect of P on general priming. Furthermore, when a preformed DnaC.DnaB protein complex was incubated briefly with P protein, it was readily converted into a P.DnaB protein complex and the bulk of the bound DnaC was released as free protein. It is likely that the capacity of the lambda P protein to outcompete the analogous host protein for binding to the bacterial DnaB helicase is the critical molecular event enabling infecting phage to recruit cellular replication proteins required for initiation of DNA synthesis at the viral origin.
噬菌体λ P蛋白通过将细胞复制机制的一个关键组分招募到病毒起源位点来启动噬菌体染色体的复制。具体而言,P蛋白将一个或多个大肠杆菌DnaB解旋酶分子递送至由λ O起始蛋白在λ复制起点形成的核蛋白结构上。利用纯化的蛋白质,我们研究了P蛋白与DnaB之间关键的宿主-病毒相互作用的特征。这两种蛋白质在体外相互作用形成P.DnaB蛋白复合物,该复合物可通过沉降或在DEAE - 纤维素柱上进行色谱分离,与单个游离蛋白区分开来。P.DnaB复合物的沉降系数为13 S,表明其大小大于游离DnaB六聚体(Mr = 313,600)。通过甘油梯度沉降分离得到的P.DnaB复合物包含大约三个P/DnaB六聚体原聚体,分子量约为393,000。分离得到的P.DnaB复合物在体外可启动λ DNA复制。P蛋白与DnaB的相互作用强烈抑制了DnaB固有的依赖DNA的ATP酶活性,以及DnaB在一般引发反应中协助大肠杆菌引发酶的能力。P.DnaB蛋白复合物的形成也阻止了DnaB在体外启动大肠杆菌DNA复制中发挥作用。λ P蛋白的物理和功能特性表明它是大肠杆菌DnaC复制蛋白的病毒类似物。与P蛋白一样,DnaC也与DnaB结合(维克纳,S.,和赫维茨,J.(1975年)美国国家科学院院刊72,921 - 925),但与P蛋白不同的是,DnaC刺激DnaB介导的一般引发反应。当病毒P蛋白和细菌DnaC复制蛋白直接竞争与DnaB的结合时,病毒蛋白明显占优势。例如,5倍摩尔过量的DnaC蛋白只能部分逆转P蛋白对一般引发反应的抑制作用。此外,当预先形成的DnaC.DnaB蛋白复合物与P蛋白短暂孵育时,它很容易转化为P.DnaB蛋白复合物,并且大部分结合的DnaC会以游离蛋白的形式释放出来。λ P蛋白在与类似的宿主蛋白竞争结合细菌DnaB解旋酶方面的能力,很可能是使感染的噬菌体能够招募在病毒起源位点启动DNA合成所需的细胞复制蛋白的关键分子事件。
