Westaway E G, Khromykh A A, Mackenzie J M
Sir Albert Sakzewski Virus Research Centre, Royal Children's Hospital, Herston, 4029, Australia.
Virology. 1999 May 25;258(1):108-17. doi: 10.1006/viro.1999.9683.
Incorporation of bromouridine (BrU) into viral RNA in Kunjin virus-infected Vero cells treated with actinomycin D was monitored in situ by immunofluorescence using antibodies reactive with Br-RNA. The results showed unequivocally that nascent viral RNA was located focally in the same subcellular site as dsRNA, the putative template for flavivirus RNA synthesis. When cells were labeled with BrU for 15 min, the estimated cycle period for RNA synthesis, the nascent Br-RNA was not digested in permeabilized cells by RNase A under high-salt conditions, in accord with our original model of flavivirus RNA synthesis (Chu, P. W. G., and Westaway, E. G., Virology 140, 68-79, 1985). The model assumes that there is on average only one nascent strand per template, which remains bound until displaced during the next cycle of RNA synthesis. The replicase complex located by BrU incorporation in the identified foci was stable, remaining active in incorporating BrU or [32P]orthophosphate in viral RNA after complete inhibition of protein synthesis in cycloheximide-treated cells. These results are in accord with our proposal that dsRNA detected in foci previously located by immunofluorescence or by immunogold labeling of induced vesicle packets is functioning as the true replicative intermediate (Westaway et al., J. Virol. 71, 6650-6661, 1997; Mackenzie et al., Virology 245, 203-215, 1998). Implications are that the replicase complex is able to recycle in the same membrane site in the absence of continuing protein synthesis and that possibly apart from uncleaved NS3-NS4A, it has no requirement for a polyprotein precursor late in infection.
在经放线菌素 D 处理的感染昆津病毒的 Vero 细胞中,利用与 Br-RNA 反应的抗体通过免疫荧光原位监测溴尿苷(BrU)掺入病毒 RNA 的情况。结果明确显示,新生病毒 RNA 集中位于与双链 RNA(黄病毒 RNA 合成的假定模板)相同的亚细胞位点。当细胞用 BrU 标记 15 分钟(这是估计的 RNA 合成周期时长)时,在高盐条件下,通透处理的细胞中的新生 Br-RNA 不会被 RNase A 消化,这与我们最初的黄病毒 RNA 合成模型相符(Chu, P. W. G., and Westaway, E. G., Virology 140, 68 - 79, 198)。该模型假定每个模板平均只有一条新生链,这条链会一直结合,直到在下一轮 RNA 合成中被取代。通过 BrU 掺入在确定的位点定位的复制酶复合物是稳定的,在环己酰亚胺处理的细胞中蛋白质合成完全被抑制后,它仍能在病毒 RNA 中持续掺入 BrU 或[32P]正磷酸盐。这些结果与我们的提议一致,即在先前通过免疫荧光或诱导囊泡包的免疫金标记定位的位点中检测到的双链 RNA 作为真正的复制中间体发挥作用(Westaway 等人,J. Virol. 71, 6650 - 6661, 1997;Mackenzie 等人,Virology 2)。这意味着复制酶复合物能够在没有持续蛋白质合成的情况下在同一膜位点循环利用,并且可能除了未切割的 NS3 - NS4A 之外,在感染后期它不需要多蛋白前体。
