基因芯片法用于检测长沙地区结核分枝杆菌耐药性研究

目的了解长沙市中心医院2013年1月1日至2014年9月30日临床分离的1 031株结核分枝杆菌对利福平和异烟肼的耐药性。方法将结核分枝杆菌培养阳性,并经鉴定为结核分枝杆菌的1 031株菌株,采用绝对浓度法进行常规药敏检测,同时应用基因芯片技术检测利福平和异烟肼耐药相关的rpoB、katG和inhA基因上的位点突变,并对2种结果进行比较。结果基因芯片法检测利福平耐药性中,其敏感株896株,耐药株135株;检测异烟肼耐药性为敏感株901株,耐药株130株。与绝对浓度法比较,基因芯片检测利福平耐药结果与其一致的菌株共1 011株(包含敏感株894株,耐药株117株),符合率为98.00%;基因芯片检测异烟肼耐药结果与其一致的菌株共1 005株(包含敏感株890株,耐药株115株),符合率为97.48%。与利福平耐药相关的rpoB基因的突变位点最常见的为531TCG→TTG突变,占耐药株的51.11%;其次为526CAC→TAC突变耐药株的10.37%;526CAC→GAC共11株菌株突变,占耐药菌株的8.15%。异烟肼耐药主要是由katG315AGC→ACC位突变引起,占耐药株的83.85%,inhA-15C→T突变仅占12.30%。结论基因芯片法与绝对浓度法结果高度一致,可成为筛查利福平和异烟肼耐药性的快速有效方法,长沙地区结核分枝杆菌利福平和异烟肼耐药以rpoB531,526及katG315突变位点为主。     

艾滋病合并结核病患者结核分枝杆菌耐药基因突变特征分析

目的了解云南省艾滋病合并结核病患者中结核分枝杆菌(MTB)耐利福平RNA聚合酶β亚单位编码基因(rpoB)和耐异烟肼过氧化氢酶-过氧化物酶编码基因(katG)、烯酰基还原酶编码基因(inhA)突变特点。方法采用基因芯片技术,对该省208例艾滋病合并结核病患者标本进行MTB利福平耐药相关基因rpoB和异烟肼耐药相关基因katG、inhA分析。结果 208例标本中共34例(16.3%)耐药,其中单耐利福平6例(2.9%),单耐异烟肼10例(4.8%),二者同时耐药18例(8.7%)。24例利福平耐药MTB的rpoB基因突变位点主要为531(TCG→TTG),占66.7%(16/24);28例异烟肼耐药MTB的基因突变位点主要为katG基因315(AGC→ACC),占78.6%(22/28)。结论云南省艾滋病合并结核病患者中MTB利福平和异烟肼耐药基因突变具有多态性,其中耐利福平rpoB基因的主要突变位点为531(TCG→TTG),耐异烟肼katG、inhA基因的主要突变位点为katG基因315(AGC→ACC)。     

尘肺并发结核患者耐多药结核分枝杆菌L型异烟肼耐药基因katG序列突变特点分析

目的探讨淮南矿区尘肺并发结核患者感染耐多药结核分枝杆菌(multiple drugs resistant Mycobacterium tuberculosis,MDR-MTB)L型异烟肼耐药基因katG突变特点。方法收集114株MTB菌L型临床分离株,用药敏试验鉴定MDR-MTB菌L型;抽提MDR-MTB L型和H37Rv标准菌株DNA,PCR法扩增katG基因,并对katG基因的突变集中区域进行测序分析。结果从114株临床分离株中检出MDR-MTB菌L型31株(27.2%),其katG基因突变率为61.3%(19/31);主要集中在315位点碱基置换突变,以Ser315Thr为主(AGC→ACC)(48.4%,15/31),其次是315位点Ser315Asn(AGC→AAC)突变(9.7%,3/31)以及431位点Ala431Val(GCG→GTG)突变(3.2%,1/31),未发现多位点联合突变,12株(38.7%,12/31)未发现katG基因突变;随机检测的10株异烟肼敏感株未见katG基因单链构象异常。结论淮南矿区尘肺并发结核患者感染的MDR-MTB菌L型异烟肼耐药情况较为严重,高度保守的katG基因突变是导致异烟肼耐药的分子基础,其突变位点呈多样性。     

探针熔解分析法检测结核分枝杆菌异烟肼耐药突变的应用和评价

目的 评价PMA技术检测MTB对INH耐药突变的价值,调查INH耐药突变发生特征.方法 MTB标准株H37Rv来自国家结核病参比实验室,1株INH敏感株和1株katG S315TACC突变株来自厦门市疾病预防控制中心,7株含有已知INH耐药突变的结核耐药株来自深圳慢性病防治中心、河南省疾病预防控制中心、中国人民解放军第309医院和厦门市疾病预防控制中心.707份MTB临床分离株来自厦门市疾病预防控制中心、厦门市第一医院和漳州市疾病预防控制中心,126份MTB涂阳痰标本来自厦门市同安区疾病预防控制中心.MTB标准株H37Rv、7株MTB INH耐药株和833份临床标本均采用厦门致善结核分枝杆菌异烟肼耐药突变检测试剂盒热裂解法提取基因组DNA,1株INH敏感株和1株katG S315T ACC突变株采用AxyPrepTM细菌基因组DNA提取试剂盒提取基因组DNA.熔解曲线分析所检标本与野生型对照在katG315位密码子、inhA启动子区(- 17～-8位点)、ahpC启动子区(-44～-30以及-15 ～3位点)及inhA94位密码子的熔解温度(Tm值)差异判断标本是否发生INH耐药突变.3×105拷贝/反应的野生株和katG S315T ACC突变株以10倍梯度稀释至300拷贝/反应,分析PMA技术的灵敏度.用PMA技术检测7株含有已知INH耐药突变的结核耐药株,评价特异性,并就其中5种耐药突变进行重复性检验.测序验证PMA技术对833份标本INH耐药性的临床检测效能.结果 PMA技术从核酸提取到结果判断可在3小时内完成,在标准96孔实时PCR仪器上可同时检测46份标本.对野生株和katG S315T ACC突变株的灵敏度均为300拷贝/反应,能够同时区分9种INH耐药相关点突变或缺失,5种耐药突变的Tm值标准偏差均在0.5℃之内.检出的162份突变标本与测序验证结果均一致.临床标本验证突变率为19.4％( 162/833),在所检出的14种INH耐药突变katGS315T( AGC →ACC)、inhA启动子区- 15C→T和katG S315N (AGC→AAC)这3种突变占INH耐药突变标本的83.3％(135/162).结论 PMA技术可快速、灵敏、特异检测结核INH耐药突变.     

耐药结核分枝杆菌基因突变分析

目的 探讨结核分枝杆菌耐药表型与基因突变位点之间的相互关系.方法 采用序列特异性引物分别扩增92株结核分枝杆菌利福平耐药基因rpoB,异烟肼耐药基因katG、inhA、ahpC,链霉素耐药基因rrs、rpsL,乙胺丁醇耐药基因embB及喹诺酮耐药基因gyrA,SSCP筛选出突变序列,DNA测序分析突变性质.结果 59株利福平耐药株rpoB基因突变检出率94.9%(56/59),以Ser450Trp突变最多;90株异烟肼耐药株中,katG基因突变检出率38.9%(35/90),以Ser315Thr最多,3株检出inhA基因突变,ahpC基因无突变检出;34株喹诺酮耐药株中gyrA基因突变检出率82.4%(28/34),主要为Asp94Gly,其次为Ala90Val;31株链霉素耐药株中,15株检出rrs突变,最常见为A514C和A1041G,10株发生rpsL Lys88Arg突变,总的链霉素基因突变检出率为77.4%(24/31);31株乙胺丁醇耐药株中embB 基因突变检出率19.4%(6/31),主要为Met306Val.结论 耐药结核分枝杆菌耐药情况较为严重,以DNA测序为基础的基因突变分析能快速有效地检测结核分枝杆菌的rpoB、katG、gyrA、rrs、rpsL、embB 等耐药分子标识,显示了西安地区耐药性结核分枝杆菌的突变特点,为结核病的临床诊断和合理用药提供了实验依据.     

应用多重PCR-单链构象多态性分析同时检测耐异烟肼和利福平的结核分枝杆菌

目的 探讨应用多重PCR-单链构象多态性分析(multiplexpulymerase chain reaction-single strand conformation polymorphism,multi-PCR-SSCP)方法快速、特异地同时快速检测结核分枝杆菌对异烟肼和利福平耐药性的效能.方法 根据结核分枝杆菌的inhA序列、katG序列、rpoB序列,分别设计出3对特异性寡聚核苷酸引物.采用multi-PCR-SSCP技术,一次性检出耐异烟肼和利福平的结核分枝杆菌.新方法的有效性通过116株临床分离株(70株耐异烟肼,66株耐利福平)的验证.结果 名 Multi-PCR-SSCP方法检测临床分离株基因突变的有效性,以细菌培养和药敏试验结果为金标准.116株临床分离株和H37Rv标准株中除了4株katG缺失突变,其余菌株3个基因katG、inhA和rpoB在单基因PCR中都扩增成功.与H37Rv标准株相比,46株katG基因突变,14株inhA基因突变,58株rpoB基因突变.38株katG和rpoB,4株inhA和rpoB,4株inhA和katG同时突变,还有2株3个基因都有突变.multi-PCR-SSCP对于耐异烟肼和利福平的结核分枝杆菌检出的敏感度分别为80%、82%,特异度分别为100%和92%.结论 multi-PCR-SSCP方法敏感、特异,能同时快速有效地检测耐多药结核分枝杆菌,有望成为临床指导用药的好方法,为深入研究耐药基凶检测奠定了良好的基础.     

耐多药结核分枝杆菌耐药相关基因突变特征分析

目的了解中国耐多药结核分枝杆菌耐药相关基因的分子特征。方法对138株耐多药结核分枝杆菌和45株敏感菌的耐药相关基因inhA、katG和oxyR-ahpC间隔区(异烟肼)、rpob(利福平)、gyrA(氧氟沙星)和rrs(卡那霉素)进行序列测定,分析其基因突变特点。结果 138株耐多药结核分枝杆菌中,14.4%的菌株inhA基因发生突变,72.5%菌株的katG基因发生突变,15.9%菌株的oxyR-ahpC基因发生突变,同时考虑这3种基因,异烟肼耐药相关基因突变检出率可达90.6%;94.2%菌株的rpoB基因发生突变,74.5%菌株的gyrA基因发生突变,61.1%菌株的rrs基因发生突变,主要的突变位点为katG315(66.7%),inhA-15(9.4%),oxyR-ahpC-10(5.1%),rpoB516(13.8%),526(26.1%)和531(49.3%),gyrA90(21.6%)和94(51%),rrs1401(61.1%)。结论我国耐多药结核菌异烟肼、利福平、氧氟沙星和卡那霉素耐药相关基因最常见突变为katG315、inhA-15,rpoB531、526和516,gyrA94和90,rrs1401。     

结核分枝杆菌katG、inhA、ahpC等突变与异烟肼耐药关系的研究

目的：了解结核分枝杆菌katG、inhA、ahpC、fabG1、sodA及sodC基因突变的特征及其与耐异烟肼的关系。方法对127例活动性肺结核患者痰标本进行菌型鉴定及结核分枝杆菌药敏试验,提取结核分枝杆菌菌株DNA,应用PCR扩增katG、inhA及ahpC、fabG1、sodA及sodC基因片段,并进行DNA序列分析。结果结核分枝杆菌药物敏感试验显示127株结核分枝杆菌中,其中47株耐异烟肼,80株对异烟肼敏感,耐异烟肼率为37.01%。47株耐异烟肼中,29株存在katG和（或）inhA基因突变,其中22株（46.81%,22/47）存在katG基因单位点突变,3株（6.38%,3/47）存在inhA基因单位点突变,4株（8.51%,4/47）存在katG及inhA基因联合位点突变。22株katG基因单位点突变中,20株为AGC315ACC、AGC315AAC （42.55%,20/47）突变,2株（2.13%,1/47）分别为CTG378CCG（Leu378Pro）、ACG394ATG（Thr394Met）突变,该突变位点及突变形式尚未见文献报道。18株katG及inhA未突变结核分枝杆菌均未检测到ahpC、fabG1、sodA及sodC基因突变。结论结核分枝杆菌对异烟肼耐药主要与katG和inhA基因突变有关。耐异烟肼结核分枝杆菌临床分离株378和394新突变位点的发现为进一步研究耐药机制以及耐药结核病的快速检测提供了依据。     

等位基因特异性PCR法快速检测结核分枝杆菌常见耐药突变基因

摘要：目的：建立一套同步检测结核分枝杆菌(MTB)常见耐药突变基因的等位基因特异性PCR（AS-PCR）检测体系,以间接判断对利福平（RFP）与异烟肼（INH）的耐药性。 方法：用AS-PCR技术同步检测58株MTB临床分离株rpoB基因516位、526位和531位,katG基因315位及inhA基因-15位密码子突变,并与DNA测序结果进行比对。 结果：AS-PCR法对RFP耐药株检出率为95.1%（39/41）,其中rpoB基因531位、526位、516位点突变分别检出28株、10株、2株,包括531位与526位联合点突变1株;未检出突变的2株RFP耐药株经测序验证1株未发生突变、1株发生533位点突变;RFP敏感株均未检测到突变。AS-PCR法对INH耐药株检出率为86.5%（45/52）,其中katG基因315位点突变43株、inhA基因-15位点突变2株,未检出突变的7株INH耐药株经测序验证未见突变;INH敏感株均未检测到突变。 结论：等位基因特异性PCR能够快速检测MTB常见突变基因,具有较高的敏感性与特异性,快速经济、操作简便。     

广西壮族自治区结核分枝杆菌异烟肼与利福平耐药基因联合突变特征分析

  目的   了解广西壮族自治区（广西）结核分枝杆菌异烟肼与利福平耐药基因联合突变特征，为耐多药结核病的分子诊断和治疗提供依据。  方法   2017—2018年从广西30个结核病防治定点机构收集的结核分枝杆菌中选取49株耐多药菌株和459株全敏感菌株进行全基因组测序。  结果   耐多药表型与基因联合突变的符合率为71.43%。 单基因突变率和基因联合突变率在耐多药菌株中均高于全敏感菌株（χ2=5.753，P=0.016; χ2=284.034，P<0.001）。 katG和rpoB的单基因突变率在耐多药菌株中高于全敏感菌株（χ2=7.524，P=0.006; χ2=4.353，P=0.037）。 katG＋rpoB基因联合突变在耐多药菌株中高于全敏感菌株（χ2=279.956，P<0.001）。 在基因联合突变的位点分布中，以katG315＋rpoB450和katG315＋rpoB445位点突变为主，占40.82%（20/49），2种形式的基因位点联合突变率在耐多药菌株中均高于全敏感菌株（χ2=144.232，P<0.001; χ2=19.014，P<0.001）。  结论   对异烟肼和利福平耐药基因联合突变的检测可作为广西耐多药筛查的重要指标。 广西结核分枝杆菌异烟肼和利福平耐药基因突变以katG315、rpoB450和rpoB445位点突变为主，基因联合突变以katG＋rpoB形式为主。 katG315＋rpoB450和katG315＋rpoB445位点突变是广西地区耐多药产生的主要分子机制。     

结核分枝杆菌耐利福平和异烟肼相关基因快速检测的应用研究

目的 利用DNA芯片检测技术直接检测痰标本中结核分枝杆菌耐利福平(RFP)、异烟肼(INH)相关的耐药基因(rpoB、katG/inhA),评价DNA芯片检测技术临床应用的可行性.方法 对586份涂阳痰标本使用L-J培养并用终点法确定其耐药性,同时利用DNA芯片检测技术检测痰标觋本中结核分枝杆菌的rpoB、katG/inhA常见基因突变位点的突变情况,比对两种方法的检测结果,对不符合的菌株测定其相应DNA序列,评估上述试验的准确性.结果 (1)586份涂阳痰标本,其中3(+)163份、2(+)204份、1(+)217份,培养阳性584份.耐药结果显示,对INH、RFP敏感的菌株分别为361株和327株,耐药菌株分别为223株和247株,其中低浓度耐药、高浓度敏感菌株分别为93株和59株,低浓度、高浓度均耐药菌株分别为130株和188株.(2)耐药基因特异性片段扩增阳性标本367份(62.8%)、阴性217份(37.2%).对INH耐药相关基因(katG/inhA)突变检出率是28.4%,突发发生位点集中在katG315位密码子(89.8%);对RFP耐药相关基因(rpoB)突变检出率是55.9%(137/247),突变发生位点主要在rpoB 531和rpoB 526位密码子,发生率分别是68.6%和16.1%.(3)对L-J药敏结果与DNA芯片检测结果不符的菌株进行DNA序列分析,发现有漏检现象.结论 DNA芯片技术直接检测样本中结核分枝杆菌的相关耐药基因存在可行性,如直接应用于临床样本检测,关键要解决样本中DNA的提取效率、PCR的扩增效率和试验的质量控制.     

Molecular characterization of multidrug-resistant Mycobacterium tuberculosis isolated in Nepal

Despite the fact that Nepal is one of the first countries globally to introduce multidrug-resistant tuberculosis (MDR-TB) case management, the number of MDR-TB cases is continuing to rise in Nepal. Rapid molecular tests applicable in this setting to identify resistant organisms would be an effective tool in reversing this trend. To develop such tools, information about the frequency and distribution of mutations that are associated with phenotypic drug resistance in Mycobacterium tuberculosis is required. In the present study, we investigated the prevalence of mutations in rpoB and katG genes and the inhA promoter region in 158 M. tuberculosis isolates (109 phenotypically MDR and 49 non-MDR isolates collected in Nepal) by DNA sequencing. Mutations affecting the 81-bp rifampin (RIF) resistance-determining region (RRDR) of rpoB were identified in 106 of 109 (97.3%) RIF-resistant isolates. Codons 531, 526, and 516 were the most commonly affected, at percentages of 58.7, 15.6, and 15.6%, respectively. Of 113 isoniazid (INH)-resistant isolates, 99 (87.6%) had mutations in the katG gene, with Ser315Thr being the most prevalent (81.4%) substitution. Mutations in the inhA promoter region were detected in 14 (12.4%) INH-resistant isolates. The results from this study provide an overview of the current situation of RIF and INH resistance in M. tuberculosis in Nepal and can serve as a basis for developing or improving rapid molecular tests to monitor drug-resistant strains in this country.     

Molecular characterization of isoniazid-resistant Mycobacterium tuberculosis isolates collected in Australia

Elucidation of the molecular basis of isoniazid (INH) resistance in Mycobacterium tuberculosis has led to the development of different genotypic approaches for the rapid detection of INH resistance in clinical isolates. Mutations in katG, in particular the S315T substitution, are responsible for INH resistance in a large proportion of tuberculosis cases. However, the frequency of the katG S315T substitution varies with population samples. In this study, 52 epidemiologically unrelated clinical INH-resistant M. tuberculosis isolates collected in Australia were screened for mutations at katG codon 315 and the fabG1-inhA regulatory region. Importantly, 52 INH-sensitive isolates, selected to reflect the geographic and genotypic diversity of the isolates, were also included for comparison. The katG S315T substitution and fabG1-inhA -15 C-to-T mutation were identified in 34 and 13 of the 52 INH-resistant isolates, respectively, and none of the INH-sensitive isolates. Three novel katG mutations, D117A, M257I, and G491C, were identified in three INH-resistant strains with a wild-type katG codon 315, fabG1-inhA regulatory region, and inhA structural gene. When analyzed for possible associations between resistance mechanisms, resistance phenotype, and genotypic groups, it was found that neither the katG S315T nor fabG1-inhA -15 C-to-T mutation clustered with any one genotypic group, but that the -15 C-to-T substitution was associated with isolates with intermediate INH resistance and isolates coresistant to ethionamide. In total, 90.4% of unrelated INH-resistant isolates could be identified by analysis of just two loci: katG315 and the fabG1-inhA regulatory region.     

Molecular analysis of isoniazid resistance in Mycobacterium tuberculosis isolates recovered from South Korea

The katG, inhA and ahpC genes, in 71 isoniazid (INH)-resistant and 26 INH-susceptible Mycobacterium tuberculosis isolates, from South Korea were examined by sequencing and MspI restriction enzyme analysis. Mutations in the katG 315 alone, katG 315 plus inhA, katG 315 plus ahpC, katG 309 alone, katG 309 plus inhA, inhA alone, and ahpC alone, were detected in 54.9, 2.8, 1.4, 1.4, 1.4, 19.7, and 5.6% of the 71 INH-resistant isolates, respectively. There was no statistically significant difference (p > 0.05) in the frequencies of these mutations for the INH-monoresistant compared with the multidrug-resistant isolates. Mutations in the katG codon 315 were associated with the high-level of INH resistance (MIC, >1 microg/ml), whereas the mutation in the inhA promoter region was associated with the low-level of INH resistance (MIC, >0.2 to 1 microg/ml). The previously undescribed GGT-->GAT (Gly-->Asp) mutation in the katG codon 309 was found in two rifampin, including-multidrug-resistant isolates, but we cannot assess if this is predictive of INH resistance. The sensitivity and specificity of molecular analysis of the katG codon 315 and/or the inhA promoter region were 80.3 and 100%, respectively. Therefore, mutations in these regions are highly predictive of INH resistance in South Korea.     

Prevalence of and molecular basis for tuberculosis drug resistance in the Republic of Georgia: validation of a QIAplex system for detection of drug resistance-related mutations

We developed a QIAplex system for the simultaneous detection of 24 Mycobacterium tuberculosis gene mutations responsible for resistance to isoniazid (INH), rifampin (RIF), streptomycin (STM), and ethambutol (EMB) in 196 M. tuberculosis isolates recovered in the Republic of Georgia. In comparison to phenotypic susceptibility tests, the QIAplex showed sensitivity and specificity of 85.4% and 96.1% for INH, 94.4% and 99.4% for RIF, 69.6% and 99.2% for STM, 50.0% and 98.8% for EBM, and 86.7% and 100.0% for multidrug resistance, respectively. The dominant resistance mutations revealed were a mutation in katG resulting in S315T (katG S315T), rpsL K43R, and rpoB S531L. Mutations katG S315G and S315T and rpoB S531L were detected with higher frequencies in pretreated patients than in naive patients (P < 0.05). Simultaneous detection of 24 common drug resistance-related mutations provides a molecular tool for studying and monitoring M. tuberculosis resistance mechanism and epidemiology.