链霉素耐药结核分支杆菌rpsL基因分析

结核分支杆菌（Mycobacterium tuberculosis.TB)的rpsL基因突变往往与链霉素（Streptomycin.SM)耐药变异有关。选择了77例TB临床分离株,应用BACTEC460快速培养系统进行常规药敏实验,同时针对rpsL基因进行聚合酶链反应（PCR）,对PCR产物进行单链构型多态性（SSCP）分析,MboⅡ酶切后的限制性片段长度分析（RFLP）和序列测定分析。常规药敏实验显示：有20株为SM敏感,57株为耐药。SSCP显示：34株的rpsL基因为野生型,43株为突变型。与常规药敏相比SSCP的特异性与阳性预期值分别为95％和98％。RFLP显示：81.4%的突变类型使其失去MboⅡ酶切位点。序列测定显示：失去MboⅡ酶切位点的突变为rpsL基因43位密码子存有单碱基突变（AAG→AGG）。实验结果表明,TB对SM耐药变异与rpsL基因突变相关,其中第43位密码子的突变是最常见的原因。     

结核分枝杆菌快速检测中的新技术

结核分枝杆菌体外培养生长缓慢的特性和耐多药性给传统的实验室检测和药物敏感试验带来很多麻烦,从而给结核病的诊断和治疗增加困难,随着现代实验技术的发展,分子生物学技术,色谱技术以及计算机等技术在该菌中的研究和应用已显示出极大的优势,不仅能够快速鉴定到其种和株的水平,还能够提供快速的药敏试验的结果和考核抗结核治疗的效果,并可进行耐药基因的分析及分子流行病学调查,为人类最终控制并战胜结核病提供了有效的手段。     

结核分枝杆菌rpoB基因突变的检测(简报)

结核病主要是由结核分枝杆菌(Mycobacterium tuberculosis)引起的一种慢性传染性疾病。利福平是结核病化疗方案中一个关键性的药物,它在结核病的短程化疗中起着重要的作用。但是,在我国结核菌对利福平的耐药发生率呈上升局势,而通过传统的依赖生物生长的药敏试验方法进行结核菌对利福平耐药性检测所需时间较长(4-8周),不能满足临床早期开展有效化疗的需要,所以迫切需要建     

结核分枝杆菌的耐药基因及其相关分子机制

结核分枝杆菌原发性和继发性耐药是当前控帝】和治疗结核病面临的重要问题,随着分子遗传学的发展,已经阐明了结核分枝杆菌耐药的分子基础是染色体的突变,影响了药靶本身或激活了药物前体的细菌酶,造成MTB的耐药。本文主要就MTB对其常用药物的耐药机制展开讨论,以便正确认识MTB对不同药物的耐药机制,建立快速检测耐药结核分枝杆菌基因型的分子生物学方法。     

结核分枝杆菌的耐药基因及其相关分子机制

结核分枝杆菌原发性和继发性耐药是当前控制和治疗结核病面临的重要问题,随着分子遗传学的发展,已经阐明了结核分枝杆菌耐药的分子基础是染色体的突变,影响了药靶本身或激活了药物前体的细菌酶,造成MTB的耐药。本文主要就MTB对其常用药物的耐药机制展开讨论,以便正确认识MTB对不同药物的耐药机制,建立快速检测耐药结核分枝杆菌基因型的分子生物学方法。     

结核分枝杆菌临床株4种耐药基因的检测与分析

结核分枝杆菌Mycobacterium tuberculsis(M.t)4种耐药基因的研究,了解耐药基因突变情况和耐药水平的关系。108例临床痰标本临床分离株均做传统梯度药敏试验和聚合酶链反应多态-单链构象多态性（PCR-SSCP）试验。结果表明耐SM（rpsL）REP(rpoB）INH(katG）EMB（embB）基因突变率分别为78.5%,68.2%,70.5%,48.6%。其中,上海高耐药株基因突变率分别为86.5%,89.3%,84.3%,35.3%。低耐药株分别为28.5%,16.5%,7.1%。EMB在低耐药区无基因突变。M.t的4种耐药基因联合检测的分析,在国内外很少报道。部分M.t的耐药由耐药基因突变所致,M.t耐药基因突变与耐药水平密切相关,且M.t基因突变绝大多数发生在高耐药区中,也有少部分在低耐区株中发生。     

基于PARMS技术的结核分枝杆菌利福平耐药基因rpoB分子标记的开发

文中旨在建立结核分枝杆菌利福平耐药基因rpoB的荧光分子标记,为分子药物敏感性试验提供简便、可靠的基因分型检测方法。对比分析利福平耐药菌株rpoB基因531、526、516、511、513等氨基酸位点的基因突变与敏感菌株中等位基因的序列差异,结合PARMS技术 (Penta-primer amplification refractory mutation system),建立rpoB基因的荧光分子标记。利用其对104例结核分枝杆菌临床分离株进行检测,经Sanger测序验证,正确率100%。并采用比例法药敏试验对这104份样本进行了利福平耐药性鉴定,与分子标记结果相符率为94.23%。结果表明,分子标记有较强可靠性,能检出表型药敏无法测出的低浓度耐药样本 (511/533单位点突变)。建立的11组荧光分子标记能覆盖92%–96%的利福平耐药菌株rpoB基因突变类型,为快速检测结核分枝杆菌利福平耐药提供新思路。     

结核分枝杆菌耐药机制研究进展

结核分枝杆菌为结核病的病原体.最近几年,由于基因突变导致多耐药及广泛耐药结核菌株的出现,以及抗结核病药近几十年来没有换代,使之前基本得到控制的结核痛死灰复燃,成为世界上病死率最高的传染病.为了遏制其进一步的恶化,必须从根本上透彻了解其耐药分子机制.近年来,各国学者采用先进分子生物学技术对结核杆菌耐药机制进行深入研究,定位了结核分枝杆菌耐药基因的位置和基因突变位点,比如耐异烟肼、利福平、乙胺丁醇、链霉素、吡嗪酰胺、喹诺酮类、外排泵等菌株新的基因突变位点引起新的功能改变有新的发现,特别是gidB基因、外排泵基因等有突破性的发现,对研制新一代抗结核病药提供了理论支持及新的方向,但仍有很多耐药机制未阐明,为后续研究者提供些许查考,故笔者就近几年来从分子水平对耐药机制的研究进展做一概述.     

结核分枝杆菌对异烟肼耐药的分子机制

抗结核一线药物异烟肼是应用最广泛的抗结核药物之一,自1952年应用于临床以来,异烟肼就成了治疗结核和潜在感染的基础药物.有报道,我国异烟肼耐药已排在首位.结核分枝杆菌对异烟肼耐药的分子机制十分复杂,涉及katG、inhA、kasA、ndh、axyR等多种基因,本研究仅就此方面的研究作一综述.     

两株超级广泛耐药结核分枝杆菌全基因组比较分析

【目的】结合现有数据,通过对两株临床超级广泛耐药的结核分枝杆菌全基因组的测序和分析,发现其型别相关的突变位点,解释发生广泛耐药的基因组突变机制。【方法】利用Solexa第二代测序技术对两株广泛耐药结核分枝杆菌(FJ05194和GuangZ0019)进行全基因组测序分析。以H37Rv为参考序列得到两株广泛耐药菌株的单核苷酸多态性(SNPs),构建系统发育树鉴定菌株型别,判断突变位点中型别相关和非型别相关的SNPs。定位SNPs所在的基因组区域,对型别相关的突变基因进行KEGG通路的富集分析,对非型别相关的突变基因和间隔区判断是否与耐药相关。【结果】两株广泛耐药菌株分别属于Lineage2和Lineage4型别,两菌株在碱基替换方面存在差异性,Lineage2型别相关的基因功能富集于ABC转运蛋白和核苷酸切除修复的通路。耐药方面,发现了已知的耐药相关基因的突变(rpoB、katG、rpsl、gyrA、gyrB、embB和ethA等),但卷曲霉素和卡那霉素相关的rrs、tlyA和eis启动子区域未发生突变,不足以解释其耐药性的产生。与最新报道的候选耐药基因比较,发现了卷曲霉素和卡那霉素相关的突变(Rv1393c、Rv0265c和narX等)和外排泵相关的pstB、Rv2333c和Rv2687c突变。【结论】结核分枝杆菌Lineage2型别相关的SNPs中含有影响结核分枝杆菌突变率和耐药性的突变。对于两株超级广泛耐药的结核菌,已知的激活药物或药靶相关的单耐药基因突变集合不能完全解释其广泛耐药性,还涉及新候选结核耐药基因、外排泵和补偿等其他潜在机制的相关基因突变。     

At Baltic crossroads: a molecular snapshot of Mycobacterium tuberculosis population diversity in Kaliningrad, Russia

The Kaliningrad region is the westernmost part of the Russian Federation; it includes an enclave on the Baltic Sea inside the European Union separated from mainland Russia by Lithuania and Poland. The incidence of tuberculosis in Kaliningrad has shown a steady and dramatic increase from 83/100 000 in 2000 to 134/100 000 in 2006; the rate of multidrug-resistant tuberculosis (MDR-tuberculosis) in the Kaliningrad region was reported to be 30.5% among newly diagnosed tuberculosis patients. This study presents a first molecular snapshot of the population diversity of Mycobacterium tuberculosis in this region. A total of 90 drug-resistant and susceptible M. tuberculosis strains from Kaliningrad were subjected to spoligotyping, 12-locus MIRU typing and mutation analysis of the drug resistance genes rpoB and katG . A comparison with international databases showed that the M. tuberculosis population in this region shares a joint pool of strains with the European part of Russia, and also exhibits a certain affinity with those of its northern European neighbours, such as Poland and Germany. Comparison of the genotyping and drug resistance data emphasized that the high prevalence of the MDR Beijing genotype strains is a major cause of the adverse epidemiological situation of MDR-tuberculosis in the Kaliningrad region.     

耐药结核分枝杆菌基因组信息挖掘

<正>由于结核分枝杆菌的耐药性问题,使结核病这个古老的传染病死灰复燃,并成为全球性的严重公关问题。从1998年首个结核分枝杆菌(H37Rv)全基因组完成图的获得[1],到近年来采用新一代测序技术对多个菌株进行高通量的基因组测序与分析,对结核分枝杆菌进化及耐药机制的认识不断深入。关于结核分枝杆菌菌株的基因组比较分析有多篇报道,包括对中国12个省来源的161株结核分枝杆菌     

Characterization of rpoB mutations associated with rifampin resistance in Mycobacterium tuberculosis from eastern China

Aims:  The aim of this study was to investigate the features of rpoB gene mutations associated with Rifampin (RIF) resistance in Mycobacterium tuberculosis ( M. tuberculosis ) in eastern China.
Methods and Results:  The mutations of rpoB gene in 56 clinical isolates of M. tuberculosis resisted to one to four first-line drugs (rifampin, isonicotinyl hydrazide, ethambutol and streptomycin) were analysed by polymerase chain reaction single strand conformation polymorphism analysis (PCR-SSCP) and DNA sequencing. The results of PCR-SSCP showed 52 isolates were positive (existing rpoB mutation) including 47 isolates resisted to RIF. Subsequent results of DNA sequencing showed that 54 isolates had rpoB gene mutation including 49 isolates resisted to RIF. The most frequently mutated sites were at codons 526 (73·2%), 513 (10·7%) and 531 (3·5%).
Conclusions:  The rpoB codon 526 was the most frequently mutated site of RIF-resistant M. tuberculosis strains in eastern China and its frequency is significantly higher ( P  < 0·0001) compared with that in other areas of China and in other geographic regions worldwide.
Significance and Impact of the Study:  Our results reveal that geographic variation is responsible for rpoB mutations in M. tuberculosis and the resulting information will be helpful to improve a novel rapid molecular drug resistance screening approach for MDR TB.     

结核分枝杆菌利福平耐药性的研究进展

本旨在阐明结核分枝杆菌耐利福平分离株rpoB基因突变的规律,以及rpoB基因突变与利福平最低抑菌浓度(MIC)的关系。结核分枝杆菌的rpoB基因突变是引起利福平耐药性的主要原因,耐利福平分离株的rpoB基因突变主要集中在507～533位密码子的81bp的区域内,约80％的菌株发生531位或526位密码子突变。不同类型rpoB基因突变的结核分枝杆菌对利福平的耐受性也不同,通常发生531位密码子突变的菌株的MIC≥64μg／ml。     

结核分枝杆菌katG基因突变的研究

探讨编码过氧化氢-过氧化物酶的katG基因突变与结核分枝杆菌异烟肼(INH)耐药性的相关关系。根据结核分枝杆菌GenBank中的katG序列,自行设计特异性寡聚核苷酸引物,采用聚合酶链反应-单链构象多态性(PCR-SSCP)分析和直接测序法(DS)分析结核分枝杆菌中katG基因突变情况。以HR37Rv标准株为对照。所有23株敏感菌均未有SSCP结果异常;35株耐药菌中,有2株(5．7％)katG基因扩增阴性,且发生在高度耐药菌中。进一步分析发现,SSCP法突变检出23株(65．7％),测序法突变检出24株(68．6％),符合率为95．8％(23／24)。参照测序法对耐药菌突变序列的分析结果,PCR—SSCP敏感、特异,可快速检测结核分枝杆菌katG耐药基因突变,有利于耐药结核分枝杆菌耐药性的快速检测。     

A population-based study of first and second-line drug-resistant tuberculosis in a high-burden area of the Mexico/United States border

The resistance of 139 Mycobacterium tuberculosis (MTB) isolates from the city of Monterrey, Northeast Mexico, to first and second-line anti-TB drugs was analysed. A total of 73 isolates were susceptible and 66 were resistant to anti-TB drugs. Monoresistance to streptomycin, isoniazid (INH) and ethambutol was observed in 29 cases. Resistance to INH was found in 52 cases and in 29 cases INH resistance was combined with resistance to two or three drugs. A total of 24 isolates were multidrug-resistant (MDR) resistant to at least INH and rifampicin and 11 MDR cases were resistant to five drugs. The proportion of MDR-TB among new TB cases in our target population was 0.72% (1/139 cases). The proportion of MDR-TB among previously treated cases was 25.18% (35/139 cases). The 13 polyresistant and 24 MDR isolates were assayed against the following seven second-line drugs: amikacin (AMK), kanamycin (KAN), capreomycin (CAP), clofazimine (CLF), ethionamide (ETH), ofloxacin (OFL) and cycloserine (CLS). Resistance to CLF, OFL or CLS was not observed. Resistance was detected to ETH (10.80%) and to AMK (2.70%), KAN (2.70%) and CAP (2.70%). One isolate of MDR with primary resistance was also resistant to three second-line drugs. Monterrey has a high prevalence of MDR-TB among previously treated cases and extensively drug-resistant-MTB strains may soon appear.     

Recent updates on drug resistance in Mycobacterium tuberculosis

Tuberculosis (TB) along with acquired immune deficiency syndrome and malaria rank among the top three fatal infectious diseases which pose threat to global public health, especially in middle and low income countries. TB caused by Mycobacterium tuberculosis (Mtb) is an airborne infectious disease and one-third of the world's population gets infected with TB leading to nearly 1·6 million deaths annually. TB drugs are administered in different combinations of four first-line drugs (rifampicin, isoniazid, pyrazinamide and ethambutol) which form the core of treatment regimens in the initial treatment phase of 6–9 months. Several reasons account for the failure of TB therapy such as (i) late diagnosis, (ii) lack of timely and proper administration of effective drugs, (iii) lower availability of less toxic, inexpensive and effective drugs, (iv) long treatment duration, (v) nonadherence to drug regimen and (vi) evolution of drug-resistant TB strains. Drug-resistant TB poses a significant challenge to TB therapy and control programs. In the background of worldwide emergence of 558 000 new TB cases with resistance to rifampicin in the year 2017 and of them, 82% becoming multidrug-resistant TB (MDR-TB), it is essential to continuously update the knowledge on the mechanisms and molecular basis for evolution of Mtb drug resistance. This narrative and traditional review summarizes the progress on the anti-tubercular agents, their mode of action and drug resistance mechanisms in Mtb. The aim of this review is to provide recent updates on drug resistance mechanisms, newly developed/repurposed anti-TB agents in pipeline and international recommendations to manage MDR-TB. It is based on recent literature and WHO guidelines and aims to facilitate better understanding of drug resistance for effective TB therapy and clinical management.     

Plasmid-based controls to detect rpoB mutations in Mycobacterium tuberculosis by quantitative polymerase chain reaction-high-resolution melting

Quantitative polymerase chain reaction-high-resolution melting (qPCR-HRM) analysis was used to screen for mutations related to drug resistance in Mycobacterium tuberculosis. We detected the C526T and C531T mutations in the rifampicin resistance-determining region (RRDR) of the rpoB gene with qPCR-HRM using plasmid-based controls. A segment of the RRDR region from M. tuberculosis H37Rv and from strains carrying C531T or C526T mutations in the rpoB were cloned into pGEM-T vector and these vectors were used as controls in the qPCR-HRM analysis of 54 M. tuberculosis strains. The results were confirmed by DNA sequencing and showed that recombinant plasmids can replace genomic DNA as controls in the qPCR-HRM assay. Plasmids can be handled outside of biosafety level 3 facilities, reducing the risk of contamination and the cost of the assay. Plasmids have a high stability, are normally maintained in Escherichia coli and can be extracted in large amounts.