作为对抗病毒药物逃逸的资产而研究的共同致死性：HIV 蛋白酶案例。

Co-lethality studied as an asset against viral drug escape: the HIV protease case.

机构信息

Atelier de Bio Informatique, F-75005, Paris, France.

出版信息

Biol Direct. 2010 Jun 17;5:40. doi: 10.1186/1745-6150-5-40.

DOI:10.1186/1745-6150-5-40

PMID:20565756

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2898770/

Abstract

BACKGROUND

Co-lethality, or synthetic lethality is the documented genetic situation where two, separately non-lethal mutations, become lethal when combined in one genome. Each mutation is called a "synthetic lethal" (SL) or a co-lethal. Like invariant positions, SL sets (SL linked couples) are choice targets for drug design against fast-escaping RNA viruses: mutational viral escape by loss of affinity to the drug may induce (synthetic) lethality.

RESULTS

From an amino acid sequence alignment of the HIV protease, we detected the potential SL couples, potential SL sets, and invariant positions. From the 3D structure of the same protein we focused on the ones that were close to each other and accessible on the protein surface, to possibly bind putative drugs. We aligned 24,155 HIV protease amino acid sequences and identified 290 potential SL couples and 25 invariant positions. After applying the distance and accessibility filter, three candidate drug design targets of respectively 7 (under the flap), 4 (in the cantilever) and 5 (in the fulcrum) amino acid positions were found.

CONCLUSIONS

These three replication-critical targets, located outside of the active site, are key to our anti-escape strategy. Indeed, biological evidence shows that 2/3 of those target positions perform essential biological functions. Their mutational variations to escape antiviral medication could be lethal, thus limiting the apparition of drug-resistant strains.

REVIEWERS

This article was reviewed by Arcady Mushegian, Shamil Sunyaev and Claus Wilke.

摘要

背景

共致死性或合成致死性是指两个单独非致死性突变在一个基因组中组合时成为致死性的已记录遗传情况。每个突变都称为“合成致死”（SL）或共致死。与不变位置一样，SL 集（SL 连锁对）是针对快速逃逸 RNA 病毒的药物设计的首选目标：病毒通过失去与药物的亲和力而发生突变逃逸可能会诱导（合成）致死。

结果

从 HIV 蛋白酶的氨基酸序列比对中，我们检测到了潜在的 SL 对、潜在的 SL 集和不变位置。从相同蛋白质的 3D 结构中，我们专注于彼此靠近且可在蛋白质表面上结合潜在药物的位置。我们对齐了 24155 个 HIV 蛋白酶氨基酸序列，鉴定出 290 对潜在的 SL 对和 25 个不变位置。在应用距离和可及性筛选后，发现了 3 个候选药物设计靶点，分别位于 7 个（在瓣下）、4 个（在悬臂上）和 5 个（在枢轴上）氨基酸位置。

结论

这三个位于活性部位之外的复制关键靶标是我们抗逃逸策略的关键。事实上，生物学证据表明，这些靶标位置中的 2/3 执行着重要的生物学功能。它们的突变变异以逃避抗病毒药物治疗可能是致命的，从而限制了耐药株的出现。

评论者

本文由 Arcady Mushegian、Shamil Sunyaev 和 Claus Wilke 进行了评论。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/25cd/2898770/6dcaf6653d47/1745-6150-5-40-1.jpg

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作为对抗病毒药物逃逸的资产而研究的共同致死性：HIV 蛋白酶案例。

Co-lethality studied as an asset against viral drug escape: the HIV protease case.

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

REVIEWERS

背景

结果

结论

评论者

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