人类小神经胶质细胞系中 HIV-1 脱壳的特性。

Characterization of HIV-1 uncoating in human microglial cell lines.

机构信息

Department of Biomedical Sciences, Missouri State University, Springfield, MO, USA.

出版信息

Virol J. 2020 Mar 6;17(1):31. doi: 10.1186/s12985-020-01301-5.

DOI:10.1186/s12985-020-01301-5

PMID:32143686

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7060623/

Abstract

BACKGROUND

After viral fusion with the cell membrane, the conical capsid of HIV-1 disassembles by a process called uncoating. Previously we have utilized the CsA washout assay, in which TRIM-CypA mediated restriction of viral replication is used to detect the state of the viral capsid, to study the kinetics of HIV-1 uncoating in owl monkey kidney (OMK) and HeLa cells. Here we have extended this analysis to the human microglial cell lines CHME3 and C20 to characterize uncoating in a cell type that is a natural target of HIV infection.

METHODS

The CsA washout was used to characterize uncoating of wildtype and capsid mutant viruses in CHME3 and C20 cells. Viral fusion assays and nevirapine addition assays were performed to relate the kinetics of viral fusion and reverse transcription to uncoating.

RESULTS

We found that uncoating initiated within the first hour after viral fusion and was facilitated by reverse transcription in CHME3 and C20 cells. The capsid mutation A92E did not significantly alter uncoating kinetics. Viruses with capsid mutations N74D and E45A decreased the rate of uncoating in CHME3 cells, but did not alter reverse transcription. Interestingly, the second site suppressor capsid mutation R132T was able to rescue the uncoating kinetics of the E45A mutation, despite having a hyperstable capsid.

CONCLUSIONS

These results are most similar to previously observed characteristics of uncoating in HeLa cells and support the model in which uncoating is initiated by early steps of reverse transcription in the cytoplasm. A comparison of the uncoating kinetics of CA mutant viruses in OMK and CHME3 cells reveals the importance of cellular factors in the process of uncoating. The E45A/R132T mutant virus specifically suggests that disrupted interactions with cellular factors, rather than capsid stability, is responsible for the delayed uncoating kinetics seen in E45A mutant virus. Future studies aimed at identifying these factors will be important for understanding the process of uncoating and the development of interventions to disrupt this process.

摘要

背景

HIV-1 病毒的锥形衣壳通过一种称为脱壳的过程与细胞膜融合。此前，我们利用 CsA 洗脱测定法，利用 TRIM-CypA 介导的病毒复制限制来检测病毒衣壳的状态，研究了 HIV-1 在猫头鹰猴肾 (OMK) 和 HeLa 细胞中的脱壳动力学。在这里，我们将这种分析扩展到人类小胶质细胞系 CHME3 和 C20，以表征 HIV 感染的天然靶细胞中的脱壳。

方法

利用 CsA 洗脱法研究 CHME3 和 C20 细胞中野生型和衣壳突变病毒的脱壳。进行病毒融合测定和奈韦拉平添加测定，以将病毒融合和逆转录的动力学与脱壳相关联。

结果

我们发现脱壳在病毒融合后的第一个小时内开始，并在 CHME3 和 C20 细胞中通过逆转录促进。A92E 衣壳突变没有显著改变脱壳动力学。在 CHME3 细胞中，具有 N74D 和 E45A 衣壳突变的病毒降低了脱壳的速度，但不改变逆转录。有趣的是，第二位点抑制衣壳突变 R132T 能够挽救 E45A 突变的脱壳动力学，尽管其衣壳具有超稳定性。

结论

这些结果与先前在 HeLa 细胞中观察到的脱壳特征最为相似，并支持脱壳由细胞质中逆转录的早期步骤启动的模型。CA 突变病毒在 OMK 和 CHME3 细胞中的脱壳动力学比较表明，细胞因子在脱壳过程中起着重要作用。E45A/R132T 突变病毒特别表明，与细胞因子相互作用中断而不是衣壳稳定性，是导致 E45A 突变病毒脱壳动力学延迟的原因。未来旨在鉴定这些因素的研究对于理解脱壳过程和开发破坏该过程的干预措施将是重要的。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/41d3/7060623/5489c6e406f4/12985_2020_1301_Fig1_HTML.jpg

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人类小神经胶质细胞系中 HIV-1 脱壳的特性。

Characterization of HIV-1 uncoating in human microglial cell lines.

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出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

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结果

结论

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