HIV-1 从培养细胞中的快速解离严重限制了感染性测定,导致归因于进入抑制剂的失活,并掩盖了病毒粒子固有高感染性。
Rapid dissociation of HIV-1 from cultured cells severely limits infectivity assays, causes the inactivation ascribed to entry inhibitors, and masks the inherently high level of infectivity of virions.
机构信息
Department of Biochemistry and Molecular Biology, Oregon Health and Science University, Portland, OR 97239-3098, USA.
出版信息
J Virol. 2010 Mar;84(6):3106-10. doi: 10.1128/JVI.01958-09. Epub 2009 Dec 30.
Abstract
By using immunofluorescence microscopy to observe and analyze freshly made HIV-1 virions adsorbed onto cells, we found that they are inherently highly infectious, rather than predominantly defective as previously suggested. Surprisingly, polycations enhance titers 20- to 30-fold by stabilizing adsorption and preventing a previously undescribed process of rapid dissociation, strongly implying that infectivity assays for many viruses are limited not only by inefficient virus diffusion onto cells but also by a postattachment race between entry and dissociation. This kinetic competition underlies inhibitory effects of CCR5 antagonists and explains why adaptive HIV-1 mutations overcome many cell entry limitations by accelerating entry.
摘要
通过使用免疫荧光显微镜观察和分析新形成的吸附在细胞上的 HIV-1 病毒颗粒,我们发现它们天生具有高度传染性,而不是像之前所认为的那样主要是有缺陷的。令人惊讶的是,多聚阳离子通过稳定吸附并阻止以前未描述的快速解离过程,将滴度提高了 20 到 30 倍,这强烈表明许多病毒的感染性测定不仅受到病毒扩散到细胞上的效率低下的限制,还受到进入和解离之间的附着后竞争的限制。这种动力学竞争是 CCR5 拮抗剂抑制作用的基础,也解释了为什么适应性 HIV-1 突变通过加速进入来克服许多细胞进入限制。
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