Department of Microbiology and Immunology, Laboratory Clinical and Evolutionary Virology, Rega Institute for Medical Research, KU Leuven, Leuven, Belgium
Department of Microbiology and Immunology, Laboratory Clinical and Evolutionary Virology, Rega Institute for Medical Research, KU Leuven, Leuven, Belgium.
Antimicrob Agents Chemother. 2019 Jul 25;63(8). doi: 10.1128/AAC.00539-19. Print 2019 Aug.
Viral pathogens causing global disease burdens are often characterized by high rates of evolutionary changes. The extensive viral diversity at baseline can shorten the time to escape from therapeutic or immune selective pressure and alter mutational pathways. The impact of genotypic background on the barrier to resistance can be difficult to capture, particularly for agents in experimental stages or that are recently approved or expanded into new patient populations. We developed an evolutionary model-based counting method to quickly quantify the population genetic potential to resistance and assess population differences. We demonstrate its applicability to HIV-1 integrase inhibitors, as their increasing use globally contrasts with limited availability of non-B subtype resistant sequence data and corresponding knowledge gap. A large sequence data set encompassing most prevailing HIV-1 subtypes and resistance-associated mutations of currently approved integrase inhibitors was investigated. A complex interplay between codon predominance, polymorphisms, and associated evolutionary costs resulted in a subtype-dependent varied genetic potential for 15 resistance mutations against integrase inhibitors. While we confirm the lower genetic barrier of subtype B for G140S, we convincingly discard a similar effect previously suggested for G140C. A supplementary analysis for HIV-1 reverse transcriptase inhibitors identified a lower genetic barrier for K65R in subtype C through differential codon usage not reported before. To aid evolutionary interpretations of genomic differences for antiviral strategies, we advanced existing counting methods with increased sensitivity to identify subtype dependencies of resistance emergence. Future applications include novel HIV-1 drug classes or vaccines, as well as other viral pathogens.
引起全球疾病负担的病毒病原体通常具有高进化变化率的特征。基线时广泛的病毒多样性可以缩短逃避治疗或免疫选择压力的时间,并改变突变途径。基因型背景对耐药性障碍的影响可能难以捕捉,特别是对于处于实验阶段或最近批准或扩展到新患者群体的药物。我们开发了一种基于进化模型的计数方法,用于快速量化对耐药性的群体遗传潜力并评估群体差异。我们证明了它在 HIV-1 整合酶抑制剂中的适用性,因为它们在全球的使用越来越多,而 B 亚型耐药序列数据和相应的知识差距有限。研究了一个包含大多数流行的 HIV-1 亚型和当前批准的整合酶抑制剂的耐药相关突变的大型序列数据集。密码子优势、多态性和相关进化成本之间的复杂相互作用导致对整合酶抑制剂的 15 种耐药突变具有依赖于亚型的不同遗传潜力。虽然我们确认了 G140S 对亚型 B 的遗传障碍较低,但我们令人信服地否定了先前对 G140C 提出的类似影响。对 HIV-1 逆转录酶抑制剂的补充分析表明,通过以前未报道的不同密码子使用,在 C 亚型中 K65R 的遗传障碍较低。为了帮助对抗病毒策略的基因组差异进行进化解释,我们改进了现有的计数方法,以提高对耐药性出现的亚型依赖性的敏感性。未来的应用包括新型 HIV-1 药物类别或疫苗以及其他病毒病原体。