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通过质谱法和一种伯胺选择性试剂鉴定HIV-1逆转录酶与病毒RNA:tRNA复合物的特异性接触。

Identification of specific HIV-1 reverse transcriptase contacts to the viral RNA:tRNA complex by mass spectrometry and a primary amine selective reagent.

作者信息

Kvaratskhelia Mamuka, Miller Jennifer T, Budihas Scott R, Pannell Lewis K, Le Grice Stuart F J

机构信息

HIV Drug Resistance Program, National Cancer Institute, Frederick, MD 21702, USA.

出版信息

Proc Natl Acad Sci U S A. 2002 Dec 10;99(25):15988-93. doi: 10.1073/pnas.252550199. Epub 2002 Dec 2.

DOI:10.1073/pnas.252550199
PMID:12461175
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC138552/
Abstract

We have devised a high-resolution protein footprinting methodology to dissect HIV-1 reverse transcriptase (RT) contacts to the viral RNA:tRNA complex. The experimental strategy included modification of surface-exposed lysines in RT and RT-viral RNA:tRNA complexes by the primary amine selective reagent NHS-biotin, SDSPAGE separation of p66 and p51 polypeptides, in gel proteolysis, and comparative mass spectrometric analysis of peptide fragments. The lysines modified in free RT but protected from biotinylation in the nucleoprotein complex were readily revealed by this approach. Results of a control experiment examining the RT-DNA:DNA complex were in excellent agreement with the crystal structure data on the identical complex. Probing the RT-viral RNA:tRNA complex revealed that a majority of protein contacts are located in the primer-template binding cleft in common with the RT-DNA:DNA and RT-RNA:DNA species. However, our footprinting data indicate that the p66 fingers subdomain makes additional contacts to the viral RNA:tRNA specific for this complex and not detected with DNA:DNA. The protein footprinting method described herein has a generic application for high-resolution solution structural studies of multiprotein-nucleic acid contacts.

摘要

我们设计了一种高分辨率蛋白质足迹法,以剖析HIV-1逆转录酶(RT)与病毒RNA:tRNA复合物的相互作用。实验策略包括用伯胺选择性试剂NHS-生物素修饰RT以及RT-病毒RNA:tRNA复合物中表面暴露的赖氨酸,通过SDS-PAGE分离p66和p51多肽,进行凝胶内蛋白酶解,并对肽片段进行比较质谱分析。通过这种方法很容易揭示在游离RT中被修饰但在核蛋白复合物中免受生物素化的赖氨酸。一项检测RT-DNA:DNA复合物的对照实验结果与相同复合物的晶体结构数据高度一致。对RT-病毒RNA:tRNA复合物进行探测发现,与RT-DNA:DNA和RT-RNA:DNA种类一样,大多数蛋白质相互作用位于引物-模板结合裂隙中。然而,我们的足迹数据表明,p66指状亚结构域与该复合物特有的病毒RNA:tRNA有额外的相互作用,而在DNA:DNA中未检测到。本文所述的蛋白质足迹法在多蛋白-核酸相互作用的高分辨率溶液结构研究中具有广泛应用。

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