Phelan Jody, Coll Francesc, McNerney Ruth, Ascher David B, Pires Douglas E V, Furnham Nick, Coeck Nele, Hill-Cawthorne Grant A, Nair Mridul B, Mallard Kim, Ramsay Andrew, Campino Susana, Hibberd Martin L, Pain Arnab, Rigouts Leen, Clark Taane G
Faculty of Infectious and Tropical Diseases, London School of Hygiene & Tropical Medicine, Keppel Street, London, WC1E 7HT, UK.
University of Cape Town Lung Institute, Lung Infection & Immunity Unit, Old Main Building, Groote Schuur Hospital, Observatory, Cape Town, 7925, South Africa.
BMC Med. 2016 Mar 23;14:31. doi: 10.1186/s12916-016-0575-9.
Combating the spread of drug resistant tuberculosis is a global health priority. Whole genome association studies are being applied to identify genetic determinants of resistance to anti-tuberculosis drugs. Protein structure and interaction modelling are used to understand the functional effects of putative mutations and provide insight into the molecular mechanisms leading to resistance.
To investigate the potential utility of these approaches, we analysed the genomes of 144 Mycobacterium tuberculosis clinical isolates from The Special Programme for Research and Training in Tropical Diseases (TDR) collection sourced from 20 countries in four continents. A genome-wide approach was applied to 127 isolates to identify polymorphisms associated with minimum inhibitory concentrations for first-line anti-tuberculosis drugs. In addition, the effect of identified candidate mutations on protein stability and interactions was assessed quantitatively with well-established computational methods.
The analysis revealed that mutations in the genes rpoB (rifampicin), katG (isoniazid), inhA-promoter (isoniazid), rpsL (streptomycin) and embB (ethambutol) were responsible for the majority of resistance observed. A subset of the mutations identified in rpoB and katG were predicted to affect protein stability. Further, a strong direct correlation was observed between the minimum inhibitory concentration values and the distance of the mutated residues in the three-dimensional structures of rpoB and katG to their respective drugs binding sites.
Using the TDR resource, we demonstrate the usefulness of whole genome association and convergent evolution approaches to detect known and potentially novel mutations associated with drug resistance. Further, protein structural modelling could provide a means of predicting the impact of polymorphisms on drug efficacy in the absence of phenotypic data. These approaches could ultimately lead to novel resistance mutations to improve the design of tuberculosis control measures, such as diagnostics, and inform patient management.
抗击耐药结核病的传播是全球卫生工作的重点。全基因组关联研究正被用于识别抗结核药物耐药性的遗传决定因素。蛋白质结构和相互作用建模用于了解假定突变的功能影响,并深入了解导致耐药性的分子机制。
为了研究这些方法的潜在效用,我们分析了来自热带病研究和培训特别规划(TDR)收集的144株结核分枝杆菌临床分离株的基因组,这些分离株来自四大洲的20个国家。对127株分离株采用全基因组方法,以识别与一线抗结核药物最低抑菌浓度相关的多态性。此外,使用成熟的计算方法定量评估已识别的候选突变对蛋白质稳定性和相互作用的影响。
分析表明,rpoB(利福平)、katG(异烟肼)、inhA启动子(异烟肼)、rpsL(链霉素)和embB(乙胺丁醇)基因中的突变是观察到的大部分耐药性的原因。预测rpoB和katG中鉴定出的一部分突变会影响蛋白质稳定性。此外,在rpoB和katG的三维结构中,最低抑菌浓度值与突变残基到各自药物结合位点的距离之间观察到强烈的直接相关性。
利用TDR资源,我们证明了全基因组关联和趋同进化方法在检测与耐药性相关的已知和潜在新突变方面的有用性。此外,在缺乏表型数据的情况下,蛋白质结构建模可以提供一种预测多态性对药物疗效影响的方法。这些方法最终可能会发现新的耐药突变,以改进结核病控制措施(如诊断)的设计,并为患者管理提供信息。
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