TNPO3 耗竭抑制 HIV-1 感染，这由衣壳决定，并且在病毒 cDNA 进入细胞核后即可检测到。

Inhibition of HIV-1 infection by TNPO3 depletion is determined by capsid and detectable after viral cDNA enters the nucleus.

机构信息

Department of Microbiology and Molecular Medicine, University of Geneva, 1 Rue Michel Servet, CH-1211 Geneva, Switzerland.

出版信息

Retrovirology. 2011 Dec 6;8:98. doi: 10.1186/1742-4690-8-98.

DOI:10.1186/1742-4690-8-98

PMID:22145813

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3267670/

Abstract

BACKGROUND

HIV-1 infects non-dividing cells. This implies that the virus traverses the nuclear pore before it integrates into chromosomal DNA. Recent studies demonstrated that TNPO3 is required for full infectivity of HIV-1. The fact that TNPO3 is a karyopherin suggests that it acts by directly promoting nuclear entry of HIV-1. Some studies support this hypothesis, while others have failed to do so. Additionally, some studies suggest that TNPO3 acts via HIV-1 Integrase (IN), and others indicate that it acts via capsid (CA).

RESULTS

To shed light on the mechanism by which TNPO3 contributes to HIV-1 infection we engineered a panel of twenty-seven single-cycle HIV-1 vectors each bearing a different CA mutation and characterized them for the ability to transduce cells in which TNPO3 had been knocked down (KD). Fourteen CA mutants were relatively TNPO3-independent, as compared to wild-type (WT) HIV-1. Two mutants were more TNPO3-dependent than the WT, and eleven mutants were actually inhibited by TNPO3. The efficiency of the synthesis of viral cDNA, 2-LTR circles, and proviral DNA was then assessed for WT HIV-1 and three select CA mutants. Controls included rescue of TNPO3 KD with non-targetable coding sequence, RT- and IN- mutant viruses, and pharmacologic inhibitors of RT and IN. TNPO3 KD blocked transduction and establishment of proviral DNA by wild-type HIV-1 with no significant effect on the level of 2-LTR circles. PCR results were confirmed by achieving TNPO3 KD using two different methodologies (lentiviral vector and siRNA oligonucleotide transfection); by challenging three different cell types; by using two different challenge viruses, each necessitating different sets of PCR primers; and by pseudotyping virus with VSV G or using HIV-1 Env.

CONCLUSION

TNPO3 promotes HIV-1 infectivity at a step in the virus life cycle that is detectable after the preintegration complex arrives in the nucleus and CA is the viral determinant for TNPO3 dependence.

摘要

背景

HIV-1 感染非分裂细胞。这意味着病毒在整合到染色体 DNA 之前必须穿过核孔。最近的研究表明，TNPO3 是 HIV-1 完全感染性所必需的。TNPO3 是一种核转运蛋白这一事实表明，它通过直接促进 HIV-1 的核进入而起作用。一些研究支持这一假设，而另一些研究则没有。此外，一些研究表明，TNPO3 通过 HIV-1 整合酶（IN）起作用，而其他研究则表明它通过衣壳（CA）起作用。

结果

为了阐明 TNPO3 促进 HIV-1 感染的机制，我们设计了一组 27 种单循环 HIV-1 载体，每种载体都带有不同的 CA 突变，并对其在 TNPO3 被敲低（KD）的细胞中转导的能力进行了表征。与野生型（WT）HIV-1 相比，有 14 种 CA 突变体相对不依赖于 TNPO3。两种突变体比 WT 更依赖于 TNPO3，而 11 种突变体实际上被 TNPO3 抑制。然后评估了 WT HIV-1 和三种选择的 CA 突变体的病毒 cDNA、2-LTR 环和前病毒 DNA 的合成效率。对照包括非靶向编码序列、RT 和 IN 突变病毒对 TNPO3 KD 的挽救，以及 RT 和 IN 的药理抑制剂。TNPO3 KD 阻断了 WT HIV-1 的转导和前病毒 DNA 的建立，但对 2-LTR 环的水平没有显著影响。PCR 结果通过使用两种不同的方法（慢病毒载体和 siRNA 寡核苷酸转染）、挑战三种不同的细胞类型、使用两种不同的挑战病毒（每种病毒都需要不同的 PCR 引物）以及用 VSV G 或 HIV-1 Env 对病毒进行假型化来证实 TNPO3 KD。

结论

TNPO3 在病毒生命周期中检测到的一个步骤中促进 HIV-1 感染性，该步骤发生在预整合复合物到达细胞核并且 CA 是 TNPO3 依赖性的病毒决定因素之后。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3fb2/3267670/39d22306104f/1742-4690-8-98-1.jpg

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TNPO3 耗竭抑制 HIV-1 感染，这由衣壳决定，并且在病毒 cDNA 进入细胞核后即可检测到。

Inhibition of HIV-1 infection by TNPO3 depletion is determined by capsid and detectable after viral cDNA enters the nucleus.

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSION

背景

结果

结论

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