辛德毕斯病毒糖蛋白PE2在培养的脊椎动物和节肢动物细胞中的差异加工。

Differential processing of sindbis virus glycoprotein PE2 in cultured vertebrate and arthropod cells.

作者信息

Heidner H W, Knott T A, Johnston R E

机构信息

Department of Microbiology and Immunology, University of North Carolina, Chapel Hill 27599-7290, USA.

出版信息

J Virol. 1996 Mar;70(3):2069-73. doi: 10.1128/JVI.70.3.2069-2073.1996.

DOI:10.1128/JVI.70.3.2069-2073.1996

PMID:8627739

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC190042/

Abstract

A step in the maturation of Sindbis virus glycoproteins is the cleavage of the precursor glycoprotein PE2 into E3 and E2 by furin or a furin-like host cell protease. The results presented here suggest that PE2 cleavage is an obligatory event for Sindbis virus maturation in C6/36 cells and demonstrate that certain mutants display a cell-specific PE2 cleavage phenotype. We previously have described Sindbis virus variants which fail to cleave PE2 because of incorporation of a signal for N-linked glycosylation immediately adjacent to the PE2 cleavage site but are viable in BHK-21 cells by virtue of an additional mutation at E2 216 or E2 191 (TRSB-NE2G216 and TRSB-NE2T191, respectively) (H. W. Heidner, K. L. McKnight, N. L. Davis, and R. E. Johnston, J. Virol. 68:2683-2692, 1994). Other viable PE2 cleavage-defective mutants were constructed by substituting the parental residue at E2 position 1 (Arg), with Leu or Val (TRSB-E2L1 and TRSB-E2V1, respectively) (H.W. Heidner and R. E. Johnston, J. Virol. 68:8064-8070, 1994). When grown in BHK-21 cells, all four of these viruses replicated normally and incorporated PE2 in place of E2 in released virions. However, growth of TRSB-NE2G216 and TRSB-NE2T191 was severely restricted in cultured arthropod cells (C6/36 cells). Analysis of infected C6/36 cells by flow cytometry demonstrated that the restricted growth of TRSB-NE2G216 and TRSB-NE2T191 was not due to an impaired ability to initiate infection. In addition, TRSB-NE2G216 and TRSB-NE2T191 remained growth restricted in C6/36 cells following introduction of in vitro transcriptions by electroporation. In contrast, the PE2 cleavage defect of TRSB-E2L1 and TRSB-E2V1 was cell type specific. In C6/36 cells, the majority of PE2 was converted to E2, and these viruses replicated normally in C6/36 cells. These results demonstrated a consistent link between expression of a PE2 cleavage defect and restricted growth in C6/36 cells and suggest that cleavage of PE2 is required for maturation of Sindbis virus late in infection of C6/36 cells.

摘要

辛德毕斯病毒糖蛋白成熟过程中的一个步骤是前体糖蛋白PE2被弗林蛋白酶或类弗林蛋白酶宿主细胞蛋白酶切割成E3和E2。本文给出的结果表明，PE2切割是辛德毕斯病毒在C6/36细胞中成熟的一个必需事件，并证明某些突变体表现出细胞特异性的PE2切割表型。我们之前描述过一些辛德毕斯病毒变体，它们由于在紧邻PE2切割位点处掺入了一个N-连接糖基化信号而无法切割PE2，但由于E2 216或E2 191处的额外突变（分别为TRSB-NE2G216和TRSB-NE2T191），在BHK-21细胞中仍可存活（H. W. 海德纳、K. L. 麦克奈特、N. L. 戴维斯和R. E. 约翰斯顿，《病毒学杂志》68:2683 - 2692, 1994年）。通过将E2第1位的亲本残基（精氨酸）分别替换为亮氨酸或缬氨酸构建了其他可存活的PE2切割缺陷突变体（分别为TRSB-E2L1和TRSB-E2V1）（H. W. 海德纳和R. E. 约翰斯顿，《病毒学杂志》68:8064 - 8070, 1994年）。当在BHK-21细胞中生长时，这四种病毒均正常复制，并在释放的病毒粒子中掺入PE2以取代E2。然而，TRSB-NE2G216和TRSB-NE2T191在培养的节肢动物细胞（C6/36细胞）中的生长受到严重限制。通过流式细胞术分析感染的C6/36细胞表明，TRSB-NE2G216和TRSB-NE2T191生长受限并非由于起始感染能力受损。此外，通过电穿孔引入体外转录本后，TRSB-NE2G216和TRSB-NE2T191在C6/36细胞中的生长仍然受限。相比之下，TRSB-E2L1和TRSB-E2V1的PE2切割缺陷具有细胞类型特异性。在C6/36细胞中，大多数PE2转化为E2，并且这些病毒在C6/36细胞中正常复制。这些结果证明了PE2切割缺陷的表达与C6/36细胞中生长受限之间存在一致的联系，并表明PE2切割是辛德毕斯病毒在感染C6/36细胞后期成熟所必需的。

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Differential processing of sindbis virus glycoprotein PE2 in cultured vertebrate and arthropod cells.辛德毕斯病毒糖蛋白PE2在培养的脊椎动物和节肢动物细胞中的差异加工。

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