Variations in the occurrence of the S315T mutation within the katG gene in isoniazid-resistant clinical Mycobacterium tuberculosis isolates from Kuwait

The worldwide threat of drug-resistant tuberculosis (TB) to human health has led to the development of molecular methods for rapidly determining the resistance of clinical Mycobacterium tuberculosis isolates to the two front-line antituberculous drugs, isoniazid and rifampin. The prevalence of the S315T mutation within the katG gene, which confers clinically significant resistance to isoniazid, was determined in isoniazid-resistant clinical M. tuberculosis isolates recovered from TB patients in Kuwait. A total of 67 isoniazid-resistant and 18 susceptible clinical M. tuberculosis isolates were tested. The mutation S315T was found in 46 (69%) of the 67 resistant strains, whereas none of the susceptible strains contained this mutation. The prevalence of this mutation was highest (32 of 40, 80%) in isolates recovered from patients of South Asian origin and lowest in isolates from patients of Middle Eastern origin (8 of 18, 44%). The genotyping performed on isolates carrying the S315T mutation showed that the isolates belong to several different types as they exhibited unique DNA banding patterns. The results point to a varying prevalence of the S315T mutation within the katG gene in clinical M. tuberculosis isolates recovered from patients of different ethnic groupings within the same country. The results also suggest that detection of the S315T mutation in the katG gene may be used as a rapid screening method for identifying isoniazid-resistant clinical M. tuberculosis isolates recovered from majority of patients in some ethnic groupings.     

PCR-restriction fragment length polymorphism for rapid, low-cost identification of isoniazid-resistant Mycobacterium tuberculosis

PCR-restriction fragment length poymorphism (PCR-RFLP) is a simple, robust technique for the rapid identification of isoniazid-resistant Mycobacterium tuberculosis. One hundred consecutive isolates from a Vietnamese tuberculosis hospital were tested by MspA1I PCR-RFLP for the detection of isoniazid-resistant katG_315 mutants. The test had a sensitivity of 80% and a specificity of 100% against conventional phenotypic drug susceptibility testing. The positive and negative predictive values were 1 and 0.86, respectively. None of the discrepant isolates had mutant katG_315 codons by sequencing. The test is cheap (less than $1.50 per test), specific, and suitable for the rapid identification of isoniazid resistance in regions with a high prevalence of katG_315 mutants among isoniazid-resistant M. tuberculosis isolates.     

Performance of the genotype MTBDR line probe assay for detection of resistance to rifampin and isoniazid in strains of Mycobacterium tuberculosis with low- and high-level resistance

We assessed the performance of the Genotype MTBDR line probe assay that offers the simultaneous identification of Mycobacterium tuberculosis and its resistance to rifampin (RIF) and isoniazid (INH) by detecting the most commonly found mutations in the rpoB and katG genes. One hundred thirteen M. tuberculosis isolates were tested. The nucleotide sequences of the katG and inhA genes and the mabA-inhA promoter region were also determined. The MTBDR assay detected 100% and 67% (n = 64) of the strains resistant to RIF and INH, respectively. Among the latter, 62 strains carried a Ser315Thr mutation in katG, 59 of them displaying a high level of resistance to INH. Two strains with a low level of INH resistance had a Ser315Asn mutation. No mutation was found by the MTBDR assay for 31 INH-resistant strains (33%), of which 24 showed a low level of resistance. By DNA sequencing, we found among them various mutations in the KatG protein for 7 strains, a C-->T mutation in position -15 of the mabA-inhA promoter in 17 strains, and a Ser94Ala mutation in InhA for 7 strains. In conclusion, the MTBDR assay, which fits easily in the workflow of a routine laboratory, enabled the detection of 100% of the RIF-resistant strains and 89% of the INH-resistant strains with a high level of resistance but only 17% of the strains characterized by a low level of INH resistance, indicating that the test can be used as a rapid method to detect in the same experiment the rifampin-resistant and the high-level isoniazid-resistant strains of M. tuberculosis.     

Mutations prevalent among rifampin- and isoniazid-resistant Mycobacterium tuberculosis isolates from a hospital in Vietnam

Vietnam is ranked 13th among the WHO list of 22 high-burden countries, based upon estimated total number of tuberculosis cases. Despite having a model national tuberculosis program, consistently achieving and exceeding WHO targets for detection and cure, drug-resistant and multidrug-resistant tuberculosis cases continue to rise. Rapid multidrug-resistant tests applicable in this setting, coupled with effective treatment regimens, would be a useful tool in reversing this trend, allowing early identification of patients with multidrug-resistant tuberculosis and avoiding resistance-amplifying regimens. Sequencing of consecutive isolates identified by the National Tuberculosis Program showed 89% of isoniazid-resistant isolates could be detected by targeting just 2 codons, katG 315 and -15C-->T in the inhA promoter, while rifampin resistance will be more complex to detect, with many different mutation and insertion events in rpoB. The most prevalent rifampin resistance-conferring mutations, as in other countries, were in rpoB codons 531 (43%), 526 (31%), and 516 (15%). However, a hybridization-based resistance test with probes targeting the 5 most common mutations would only detect 78% of rifampin-resistant isolates. Overall, these data suggest that rifampin resistance may be used as a surrogate marker for multidrug-resistant tuberculosis and that a sensitivity of between 70 to 80% may be possible for rapid molecular detection of multidrug-resistant tuberculosis in this setting.     

Single-nucleotide polymorphism-based differentiation and drug resistance detection in Mycobacterium tuberculosis from isolates or directly from sputum

The rapid technique of pyrosequencing was used to examine 123 samples (in the form of DNA extracts and inactivated sputum) of Mycobacterium spp. Of 99 Mycobacterium tuberculosis samples investigated for single-nucleotide polymorphisms (SNPs), 68% of isoniazid-resistant isolates analysed had an AGC --> ACC mutation in katG at codon 315, resulting in the Ser --> Thr substitution associated previously with isoniazid resistance. Of the rifampicin-resistant isolates, 92% showed SNPs in rpoB at codons 516, 531 or 526. Inactivated sputum samples and DNA extracts could both be analysed by pyrosequencing, and the method was able to differentiate rapidly between the closely related species of the M. tuberculosis complex (M. tuberculosis, Mycobacterium bovis, Mycobacterium africanum, Mycobacterium canetti and Mycobacterium microti), except between M. tuberculosis, M. canetti and one of two M. africanum strains. This low-cost, high-throughput technique could be used as a rapid screen for drug resistance and as a replacement for some of the time-consuming tests used currently for species identification.     

Molecular characterization of isoniazid and rifampin resistance of Mycobacterium tuberculosis clinical isolates from Malatya, Turkey

Molecular characterization of drug resistance of Mycobacterium tuberculosis strains of different origins can generate information useful for developing molecular methods that are widely applicable for rapid drug resistance detection. Using DNA sequencing and allele-specific polymerase chain reaction (AS-PCR), we investigated genetic mutations associated with isoniazid (INH) and rifampin (RIF) resistance among 29 drug-resistant clinical isolates of M. tuberculosis collected from Malatya, Turkey, including 19 multi-drug-resistant (MDR) isolates. Point mutations were detected at codons 531, 516, 526, and 513 of the RNA polymerase beta- subunit gene (rpoB) in 10 (47.6%), five (23.8%), three (14.3%), and three (14.3%) of the 21 RIF-resistant isolates, respectively. Of the five isolates having mutations in codon 516, three also had mutations at codon 527; one had a concurrent mutation at codon 572. Mutations at codon 315 of the catalase-peroxidase-encoding gene (katG) were found in 17 (63.0%) of the 27 INH-resistant isolates. Interestingly, the katG codon 315 mutation was observed at a much higher frequency in MDR isolates than in INH-mono-resistant isolates ( approximately 79% vs. 25%). This study provided the first molecular characterization of INH and RIF resistance of M. tuberculosis clinical isolates from Eastern Turkey, and extended our knowledge of molecular basis of M. tuberculosis drug resistance.     

Significance ofahpC promoter mutations for the prediction of isoniazid resistance inMycobacterium tuberculosis

To determine the value ofahpC promoter mutations for the rapid prediction of isoniazid resistance, this genomic region was characterized in 50 isoniazid-resistant and 12 isoniazid-sensitiveMycobacterium tuberculosis isolates. Of the resistant isolates, 12 hadahpC promoter mutations, but only one possessed both anahpC promoter mutation and akatG codon 315 substitution, although the latter was found in the majority (54%) of the isoniazid-resistant isolates investigated. This investigation presents empirical evidence that the central portion of theahpC promoter is the most valuable genetic locus to complementkatG codon 315 characterizations in order to increase the sensitivity of molecular tests for the prediction of isoniazid resistance.     

Detection of mutation in isoniazid-resistant Mycobacterium tuberculosis isolates from tuberculosis patients in Belarus

The aim of this study was to investigate the frequency, location and type of katG mutations in Mycobacterium tuberculosis strains isolated from patients in Belarus. Forty two isoniazid-resistant isolates were identified from sputum of 163 patients with active pulmonary tuberculosis. Drug susceptibility testing was determined by using CDC standard conventional proportional method and BACTEC system. Standard PCR method for detection of isoniazid resistance associated mutations was performed by katG gene amplification and DNA sequencing. Most mutations were found in katG gene codons 315, 316 and 309. Four types of mutations were identified in codon 315: AGC-->ACC (n=36) 85%, AGC-->AGG (n=1) 2.3%, AGC-->AAC (n=2) 4.7%, AGC-->GGC (n=1) 2.3%. One type of mutation was found in codon 316: GGC-->AGC (n=18) 41.4%, four types of mutations were detected in codon 309: GGT-->GGT (n=7) 16.1%, GGT-->GCT (n=4) 9.2%, GGT-->GTC (n=3)6.9%, GGT-->GGG (n=1) 2.7%. The highest frequency of mutations sharing between primary and secondary infections was found in codon 315.     

Molecular analysis of isoniazid and rifampin resistance in Mycobacterium tuberculosis isolates recovered from Barcelona

We studied the presence of mutations in the whole katG gene and specific regions of the oxyR-ahpC and mabA-inhA regulatory region in 61 Mycobacterium tuberculosis isoniazid-resistant isolates. An 81-bp region of the rpoB gene was also sequenced in 17 rifampin-resistant strains. Alterations in the katG gene were detected in 55% of the isolates. Mutation in codon 315 was the most prevalent (32%). Strains showed a high level of resistance, and most maintained a substantial catalase-peroxidase activity. Three strains with an isoniazid MIC of >or=32 microg/ml lacked catalase-peroxidase activity. Two of them had deletions in the catalytic domain of the KatG protein. One strain with deletion and three strains with mutations in the C-terminal domain showed low-level resistance and conserved the catalase-peroxidase activity. Mutations in the mabA-inhA regulatory region were identified in 32% of the isolates. All had low-level resistance, and the vast majority conserved catalase-peroxidase activity. Seventeen percent of the isoniazid-resistant isolates had no detectable alterations at the studied loci. Resistance to rifampin was associated with mutations in the 81-bp of the rpoB gene in all cases. IS6110 analysis indicated that recent transmission contributed substantially to the emergence of isoniazid- resistant tuberculosis in Barcelona through short transmission chains. A rapid genotypic assay, including the 315-katG codon and the -15 nucleotide of the mabA-inhA regulatory region, may cover 62% of isoniazid- resistant strains in Barcelona. In contrast, the targeting of the 81-bp region of rpoB would detect all our rifampin-resistant isolates.     

Molecular mechanisms of isoniazid resistance in Mycobacterium tuberculosis and Mycobacterium bovis.

Genetic and biochemical studies have suggested a link between reduced catalase activity and resistance to isoniazid in Mycobacterium tuberculosis. In this study, we examined the molecular mechanisms of resistance to isoniazid with six in vitro mutants of the M. tuberculosis complex (Mycobacterium bovis and M. tuberculosis). Five of six mutants resistant to isoniazid were negative by catalase assays. Immunoblot analyses using a polyclonal antibody against the katG gene product (catalase-peroxidase) demonstrated that the enzyme is not produced in four of these isoniazid-resistant strains. A complete deletion of the katG gene was detected in only one of these isoniazid-resistant M. tuberculosis complex strains by Southern blot analyses. In two other resistant strains, partial deletions of the katG gene were identified. A point mutation which resulted in the insertion of a termination codon in the katG coding sequence caused a catalase-negative phenotype in a fourth strain. Of the two resistant strains which produce the enzyme, one was shown to be negative by a catalase assay. Single-stranded conformational polymorphism and DNA sequence analyses identified a mutation in the katG gene of this strain which may contribute to reduced enzymatic activity and subsequent isoniazid resistance. These data demonstrate that genetic alterations to the katG gene other than complete deletions are prevalent and may contribute significantly to the number of cases of isoniazid-resistant tuberculosis.     

Multidrug-resistant tuberculosis: rapid detection of resistance to rifampin and high or low levels of isoniazid in clinical specimens and isolates

The aim of the present study was to evaluate a new improved multiplex polymerase chain reaction (PCR) hybridisation assay to detect multidrug-resistant tuberculosis. The assay, developed to detect rifampin (rpoB) and isoniazid (katG) gene mutations causing Mycobacterium tuberculosis resistance, was recently extended to include inhA gene mutations that code for low-level isoniazid resistance. Interpretable results were obtained in 115 isolates and in all smear-positive clinical specimens. Rifampin resistance was correctly identified in all specimens and in 20 of 21 (95%) multidrug-resistant isolates compared to BACTEC 460TB. Isoniazid resistance correlated in 18 of 22 (82%) specimens, in 31 of 31 (100%) high-level and 24 of 28 (86%) low-level isoniazid-resistant isolates. The assay was rapid, easy to perform and directly applicable in smear-positive specimens. We predict that the assay may be a useful tool to combat and prevent new cases of multi- and extensively drug-resistant tuberculosis.     

Detection of mutations associated with isoniazid and rifampin resistance in Mycobacterium tuberculosis isolates from Samara Region, Russian Federation

High incidence rates of isoniazid-, rifampin-, and multiple-drug-resistant tuberculosis have been reported in countries of the former Soviet Union (FSU). Genotypic (unlike phenotypic) drug resistance assays do not require viable cultures but require accurate knowledge of both the target gene and the mutations associated with resistance. For these assays to be clinically useful, they must be able to detect the range of mutations seen in isolates from the population of tuberculosis patients to which they are applied. Two novel macroarrays were applied to detect mutations associated with rifampin (rpoB) and isoniazid (katG and inhA) resistance. In a sample of 233 isolates from patients in Samara, central Russia, 46.5% of isolates possessed mutations in both the rpoB and the katG (or inhA) genes. Combined results from the macroarrays demonstrated concordance in 95.4 and 90.4% of phenotypically defined rifampin- and isoniazid-resistant isolates, respectively. The contribution of different mutations to resistance was comparable to that reported previously for non-FSU countries, with 90% of rifampin-resistant isolates and 93% of isoniazid resistant isolates due to rpoB531 and katG315 mutations, respectively. The percentage of phenotypically resistant rifampin isolates with no mutations in the rpoB codons 509 to 536 was 4.2%, which was similar to previous reports. Novel macroarrays offer a rapid, accurate, and relatively cheap system for the identification of rifampin-, isoniazid-, and multiple-drug-resistant Mycobacterium tuberculosis isolates.     

Frequency of mutations in rpoB and codons 315 and 463 of katG in rifampin- and/or isoniazid-resistant Mycobacterium tuberculosis isolates from northeast Mexico

A total of 48 isoniazid (INH)- and rifampin (RIF)-resistant Mycobacterium tuberculosis isolates, 19 INH-resistant isolates, and 9 RIF-resistant isolates were randomly selected and tested for detecting mutations at codons 315 and 463 of katG by polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP), and/or for detecting mutations at a 69-bp region of the rpoB gene by the INNO-LiPA Rif TB assay. Of the 67 INH-resistant isolates tested, 36 (53.7%) showed the mutation at codon 315 of katG; however, none of them showed the mutation at codon 463. The majority of the RIF-resistant samples analyzed (49 of 57, 86.0%) reacted positive with one of the four R-type probes. The R5-pattern (S531L mutation) was the most frequently observed (31 of 57, 54.4%), followed by R4a-pattern (H526Y mutation) 13 isolates (22.8%), R4b-pattern (H526D mutation) 4 isolates (7.0%), and R2-pattern (D516V mutation) 1 isolate (1.8%). Overall, there was agreement between the line probe kit and phenotypic RIF-susceptibility test for 56 (98.2%) of 57 RIF-resistant isolates tested. These results show that the mutation analysis at codon 315 of katG could be used as a screening assay prior to standard susceptibility testing, whereas mutations in the rpoB gene could be used successfully as genetic markers to rapidly detect RIF-resistant M. tuberculosis clinical isolates from northeast Mexico.     

Molecular characterization of isoniazid-resistant Mycobacterium tuberculosis isolates from Xi'an, China

The increased prevalence of isoniazid (INH)-resistant tuberculosis (TB) has become a significant challenge for TB control in the last 10 years. It has been reported that INH resistance is most frequently associated with katG 315 and inhA-15 mutations. The relative significance of these mutations in INH-resistant Mycobacterium tuberculosis and their association with the different genotypes of M. tuberculosis in Xi'an, China, was investigated. Eighty-nine INH-resistant isolates were subjected to molecular characterization of hotspot mutations within katG 315 and inhA-15 by Multiplex allele-specific PCR, and results from 10 isolates were confirmed by direct sequencing. Mutations in katG 315 and inhA-15 were detected in 58 and 7 isolates, respectively. These isolates were genotyped by mycobacterial interspersed repetitive unit-variable number of tandem repeats and Spoligotyping. Spoligotyping showed that 79 isolates (89%) belonged to Beijing family. Mycobacterial interspersed repetitive unit-variable number of tandem repeats typing revealed significant differences in clustering level between Beijing and non-Beijing family (56% vs. 9%, p?=?0.002), which indicated the active transmission of Beijing family in INH-resistant isolates. Our results suggested that the katG 315 mutants were predominant in INH-resistant isolates in Xi'an and the hotspot mutations within katG 315 and inhA-15 can be used as genetic markers for detection of INH resistance.     

深圳地区结核分枝杆菌耐药分离株分子特征与表型特征相关性研究

目的 研究深圳地区2007-2008年分离的结核分枝杆菌耐药株分子特征与表型特征的相关性.方法 参照WHO/IUATLD标准,使用L-J药敏培养基,1%比例法药敏试验筛选针对异烟肼、利福平、链霉素、氧氟沙星、卡那霉素5种药物耐药或敏感的临床分离株,通过PCR扩增经筛选菌株的rpoB、katG、rpsL、rrs1、gyrAB、rrs2基因的相关序列,运用DNAStar和BLASTN进行序列分析,应用二倍稀释法测定其表型最低抑菌浓度(MIC)值.结果 筛得实验菌株123株,其中耐药株73株,全敏感株50株.异烟肼耐药株katG基因突变率为84.6%,突变位点全部为S315T或S315N.利福平耐药株rpoB基因突变率为93.6%,突变位点主要集中在S531L(30/44,68.2%)和H526D(9/44,20.5%)或H526R(1/44,2.3%).链霉素耐药株以rpsl基因突变为主,突变位点为K43R(19/27,70.4%)和K88Q(6/27,22.2%);rrs1基因突变较少见,仅491C→T(2/27,7.4%)及513A→C(1/27,3.7%);2个基因突变率合计为65.9%.氧氟沙星耐药株突变率为100%,以gyrA基因突变为主,突变位点包括D94A(2/11,18.2%)、S91P(4/11,36.4%)和A90V(3/11,27.3%),3个突变位点总突变率为81.8%(9/11);S95T存在于所有氧氟沙星耐药株及部分全敏感株gyrA基因中;gyrB未发现突变.卡那霉索耐药株rrs2基因突变率为61.1%;突变位点为1400 A→C(9/11,81.8%)和1483 G→T(2/11,18.2%).其他突变位点在全敏感株中未发现.临床耐药株同一耐药组别所包含耐药类型不同,相关耐药基因的突变位点相同,其MIC值基本一致;相关耐药基因突变位点不同,其MIC值存在明显差异.结论 结核分枝杆菌耐药基因突变存在一定的地域特性,表型特征因耐药基因突变位点不同存在耐药程度差异.     

Evaluation of the Genotype MTBDR assay for rapid detection of rifampin and isoniazid resistance in Mycobacterium tuberculosis isolates

A novel PCR-based reverse hybridization method Genotype MTBDR assay (Hain Lifescience GmbH, Nehren, Germany) was evaluated for rapid detection of rifampin (RIF) and isoniazid (INH) resistance in Turkish Mycobacterium tuberculosis isolates. The Genotype MTBDR assay is designed to detect mutations within the 81-bp hotspot region of rpoB and mutations at katG codon 315. A total of 41 RIF-resistant M. tuberculosis isolates with rpoB mutations that were previously tested by the INNO-LiPA Rif.TB kit and also characterized by DNA sequencing were included in the study. Thirty-seven of these isolates were also resistant to INH. RIF resistance was correctly identified in 39 of 41 isolates (95.1%) with the Genotype MTBDR assay probes specific for these mutations. One isolate with a Gln-490-His mutation and another one with a CGG insertion between codons 514 and 515 were identified as RIF sensitive by the Genotype MTBDR assay. While the INNO-LiPA Rif.TB kit was able to determine the CGG insertion between codons 514 and 515, the Gln-490-His mutation outside the 81-bp hotspot region was not detected by the INNO-LiPA Rif.TB kit. These isolates had MICs of >or=32 microg/ml for RIF. The Genotype MTBDR assay also correctly identified 27 of 37 INH-resistant isolates (73%) with mutations in katG codon 315. In conclusion, the Genotype MTBDR assay may be useful for the rapid diagnosis of the most common mutations found in multidrug-resistant M. tuberculosis strains. However, the test results should always be confirmed with phenotypic methods.     

Identifying isoniazid resistance markers to guide inclusion of high-dose isoniazid in tuberculosis treatment regimens

ObjectivesEffective use of antibiotics is critical to control the global tuberculosis pandemic. High-dose isoniazid (INH) can be effective in the presence of low-level resistance. We performed a systematic literature review to improve our understanding of the differential impact of genomic Mycobacterium tuberculosis (Mtb) variants on the level of INH resistance. The following online databases were searched: PubMed, Web of Science and Embase. Articles reporting on clinical Mtb isolates with linked genotypic and phenotypic data and reporting INH resistance levels were eligible for inclusion.MethodsAll genomic regions reported in the eligible studies were included in the analysis, including: katG, inhA, ahpC, oxyR-ahpC, furA, fabG1, kasA, rv1592c, iniA, iniB, iniC, rv0340, rv2242 and nat. The level of INH resistance was determined by MIC: low-level resistance was defined as 0.1–0.4 μg/mL on liquid and 0.2–1.0 μg/mL on solid media, high-level resistance as >0.4μg/mL on liquid and >1.0 μg/mL on solid media.ResultsA total of 1212 records were retrieved of which 46 were included. These 46 studies reported 1697 isolates of which 21% (n = 362) were INH susceptible, 17% (n = 287) had low-level, and 62% (n = 1048) high-level INH resistance. Overall, 24% (n = 402) of isolates were reported as wild type and 76% (n = 1295) had ≥1 relevant genetic variant. Among 1295 isolates with ≥1 variant, 78% (n = 1011) had a mutation in the katG gene. Of the 867 isolates with a katG mutation in codon 315, 93% (n = 810) had high-level INH resistance. In contrast, only 50% (n = 72) of the 144 isolates with a katG variant not in the 315-position had high-level resistance. Of the 284 isolates with ≥1 relevant genetic variant and wild type katG gene, 40% (n = 114) had high-level INH resistance.ConclusionsPresence of a variant in the katG gene is a good marker of high-level INH resistance only if located in codon 315.     

Molecular characterization of rifampin- and isoniazid-resistant Mycobacterium tuberculosis strains isolated in Poland

A total of 105 rifampin (RMP)- and/or isoniazid (INH)-resistant strains of Mycobacterium tuberculosis isolated from different parts of Poland in 2000 were screened for mutations associated with resistance to these drugs by two molecular methods, namely sequence analysis and real-time PCR technology. Three loci associated with drug resistance were selected for characterization: they were rpoB (RMP), katG, and the regulatory region of inhA (INH). Nineteen different mutations were identified in 64 RMP-resistant strains, and five new alleles were described. The most common point mutations were in codons 531 (41%), 516 (16%), and 526 (9%) of the rpoB gene. Mutations were not found in two (3%) of the isolates. In the case of resistance to INH, six different mutations in the katG gene of 83 resistant strains were detected. Fifty-seven (69%) isolates exhibited nucleotide substitutions at codon 315. One strain harbored a mutation affecting codon 279 (Gly279Thr). Twelve of 26 INH-resistant strains with the wild-type codon 315 (14.5% of all strains tested) had the mutation -15C-->T in the regulatory region of inhA. A full correlation between the DNA sequence analysis and real-time PCR data was obtained. We conclude that the real-time PCR method is fast and reliable for the detection of RMP and INH resistance-associated mutations in M. tuberculosis clinical isolates.     

结核分枝杆菌临床分离株异烟肼耐药相关基因突变的分子特征

目的 阐明结核分枝杆菌异烟肼（INH）耐药相关基因突变特征.方法 对137株结核分枝杆菌临床分离株（耐异烟肼菌株87株,异烟肼敏感菌株90株）的9个结构基因furA、katG、inhA、kasA、Rv0340、iniB、iniA、iniC和efpA以及两个调控区oxyR-ahpC基因间隔区和mabA-inhA启动子进行DNA片段扩增及序列分析.结果 82株（94.3%）INH耐药分离株的katG基因存在突变,其中katGSer315Thr突变占优势（55.2%）.50株INH敏感的分离菌katG的463密码子没有突变.35株（40.2%）INH耐药的分离株katG的463有突变.87株INH耐药株中,20株（23.0%）的katG基因存在两重突变.13株（14.9%）分离菌inhA基因的启动子区存在突变,4.6%的分离菌有inhA结构基因突变,11.5%oxyR-ahpC基因间区存在突变.iniBAC区域和efpA中发现耐药性关联突变.结论 研究证实多个基因突变与异烟肼耐药之间的关系,并且为阐明结核分枝杆菌耐药机制提供线索.     

Association of specific mutations in katG, rpoB, rpsL and rrs genes with spoligotypes of multidrug-resistant Mycobacterium tuberculosis isolates in Russia

Most multidrug-resistant (MDR) Mycobacterium tuberculosis isolates in Russia belong to the Beijing or Latino-American and Mediterranean (LAM) spoligotype families. The objective of this study was to investigate possible associations between genotype and the frequencies of mutations that confer drug resistance in a population that has two large families of circulating strains. Spoligotyping, IS6110 restriction fragment length polymorphism typing, and sequencing of the katG and rpoB genes, were performed for 217 consecutive MDR M. tuberculosis isolates from patients. The rpsL and rrs genes were also sequenced for selected streptomycin-resistant isolates. Of the 217 MDR isolates, 99 (46%) belonged to the LAM family, 92 (42%) to the Beijing family, 21 (10%) to the Haarlem family and four (2%) to the T family. There was one unique spoligotype. Mutations in the katG gene were identified in 207 (95%) isolates, all of which had mutations in codon 315. Mutations in the rpoB gene were identified in 200 (92%) isolates; 75% of LAM isolates carried a mutation in codon 516, whereas 71% of Beijing isolates carried a mutation in codon 531. In the 33 isolates resistant to streptomycin 50 mg/L, the 43AGG rpsL mutation was found in 27% of Haarlem, 75% of Beijing and 0% of LAM isolates, and rrs mutations were found in 17% (516C-->T) of Beijing and 100% (513A-->C) of LAM isolates. Overall, there appeared to be a correlation between the genotype and specific mutations conferring resistance to rifampicin or streptomycin in the Beijing and LAM families. The biological implications of this correlation remain to be explored.