Downregulation of katG expression is associated with isoniazid resistance in Mycobacterium tuberculosis

Isoniazid (INH) is a key agent in the treatment of tuberculosis. In Mycobacterium tuberculosis, INH is converted to its active form by KatG, a catalase-peroxidase, and attacks InhA, which is essential for the synthesis of mycolic acids. We sequenced furA-katG and fabG1-inhA in 108 INH-resistant (INH(r) ) and 51 INH-susceptible (INH(s) ) isolates, and found three mutations in the furA-katG intergenic region (Int(g-7a) , Int(a-10c) and Int(g-12a) ) in four of 108 INH(r) isolates (4%), and the furA(c41t) mutation with an amino acid substitution in 18 INH(r) isolates (17%). These mutations were not found in any of 51 INH(s) isolates tested. We reconstructed these mutations in isogenic strains to determine whether they conferred INH resistance. We found that the Int(g-7a) , Int(a-10c) and Int(g-12a) single mutations in the furA-katG intergenic region decreased katG expression and conferred INH resistance. In contrast, the furA(c41t) mutation was not sufficient to confer INH resistance. These results suggested that downregulation of katG is a mechanism of INH resistance in M. tuberculosis and that mutations in the furA-katG intergenic region play a role in this resistance mechanism.     

Characterization of ndh gene of isoniazid resistant and susceptible Mycobacterium tuberculosis isolates from Brazil

Resistance in Mycobacterium tuberculosis to isoniazid (INH) is caused by mutations in the catalase-peroxidase gene (katG), and within the inhA promoter and/or in structural gene. A small percentage (approximately 10%) of INH-resistant strains do not present mutations in both of these loci. Other genes have been associated with INH resistance including the gene encoding for NADH dehydrogenase (ndh). Here we report the detection of two ndh locus mutations (CGT to TGT change in codon 13 and GTG to GCG change in codon 18) by analyzing 23 INH-resistant and in none of 13 susceptible isolates from Brazilian tuberculosis patients. We also detected two isolates without a mutation in ndh, or any of the other INH resistance-associated loci examined, suggesting the existence of additional, as yet to be described, INH resistance mechanisms.     

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。     

Molecular characterization of mutation associated with rifampicin and isoniazid resistance in Mycobacterium tuberculosis isolates

Nucleotide changes in catalase peroxidase (Kat G) gene and gene encoding the beta subunit of RNA polymerase (rpo B), responsible for isoniazid and rifampicin drug resistance were determined in the clinical isolates of Mycobacterium tuberculosis by PCR-RFLP, Line probe assay and DNA sequencing. PCR-RFLP test was performed by HapII cleavage of an amplified fragment of Kat G gene to detect the transversion 315AGC-->ACC(Ser-->Thr) which is associated with INH drug resistance. The Line probe assay kit was evaluated to detect the mutation in 81bp RMP resistance determining region of rpo B gene associated with RMP drug resistance. These results were validated by DNA sequencing and drug susceptibility test. Kat G S 315 T mutation was found in 74.19% strains of M. tuberculosis from Delhi. This mutation was not found in any of the susceptible strains tested. The line probe assay kit and DNA sequencing identified 18 isolates as RMP resistant with specific mutation, while one of the RMP resistant strain was identified as RMP susceptible, with a concordance of 94.73% with the phenotypic drug susceptibility result. Majority (8 of 19, 42.1%) of resistant isolates involved base changes at codon 531 of rpo B gene. Both PCR-RFLP and Line probe assay test can be used in many of the clinical microbiology laboratories for early detection of isoniazid and rifampicin drug resistance in clinical isolates of M. tuberculosis.     

The use of macroarrays for the identification of MDR Mycobacterium tuberculosis

The emergence of Mycobacterium tuberculosis (Mtb), resistant to both isoniazid (INH) and rifampicin (RIF) (MDR-TB), is an increasing threat to tuberculosis control programs. Susceptibility testing of Mtb complex isolates by phenotypic methods requires a minimum of 14 days from a primary specimen. This can be reduced significantly if molecular analysis is used. Low density oligonucleotide arrays (macroarrays) have been used successfully for the detection of RIF resistance in Mtb. We describe the use of macroarray technology to identify Mtb complex isolates resistant to INH and/or RIF. The macroarray MDR-Mtb screen has been designed to detect mutations in the RIF resistance determining region (RRDR) of Mtb rpoB and loci in katG and mabA-inhA associated with INH resistance. A panel of Mtb isolates containing 38 different RRDR genotypes, 4 different genotypes within codon 315 of katG and 2 genotypes at mabA-inhA was used to validate the macroarray. The wild type (WT) genotype was correctly identified at all three loci. Of the 37 mutant rpoB genotypes, 36 were correctly detected; the single mutant not detected contained a 9 base insertion. All mutations within katG and mabA-inhA were correctly identified. We conclude that this low cost, rapid system can usefully detect the mutations associated with the vast majority of MDR-Mtb.     

Genotypic and phenotypic characteristics of tunisian isoniazid-resistant <Emphasis Type="Italic">Mycobacterium tuberculosis</Emphasis> strains

Forty three isoniazid (INH)-resistant Mycobacterium tuberculosis isolates were characterized on the basis of the most common INH associated mutations, katG315 and mabA −15C→T, and phenotypic properties (i.e. MIC of INH, resistance associated pattern, and catalase activity). Typing for resistance mutations was performed by Multiplex Allele-Specific PCR and sequencing reaction. Mutations at either codon were detected in 67.5% of isolates: katG315 in 37.2, mabA −15C→T in 27.9 and both of them in 2.4%, respectively. katG sequencing showed a G insertion at codon 325 detected in 2 strains and leading to amino acid change T326D which has not been previously reported. Distribution of each mutation, among the investigated strains, showed that katG S315T was associated with multiple-drug profile, high-level INH resistance and loss or decreased catalase activity; whereas the mabA −15C→T was more prevalent in mono-INH resistant isolates, but it was not only associated with a low-level INH resistance. It seems that determination of catalase activity aids in the detection of isolates for which MICs are high and could, in conjunction with molecular methods, provide rapid detection of most clinical INH-resistant strains.     

Conformational differences in Mycobacterium tuberculosis catalase-peroxidase KatG and its S315T mutant revealed by resonance Raman spectroscopy

KatG from Mycobacterium tuberculosis is a heme-containing catalase-peroxidase, which belongs to the class I peroxidases and is important for activation of the prodrug isoniazid (INH), a front-line antituberculosis drug. In many clinical isolates, resistance to INH has been linked to mutations on the katG gene, and the most prevalent mutation, S315T, suggests that modification of the heme pocket has occurred. Electronic absorption and resonance Raman spectra of ferric wild-type (WT) KatG and its INH-resistant mutant KatG(S315T) at different pH values and their complexes with INH and benzohydroxamic acid (BHA) are reported. At neutral pH, a quantum mechanically mixed spin state (QS) is revealed, which coexists with five-coordinate and six-coordinate high-spin hemes in WT KatG. The QS heme is the major species in KatG(S315T). Addition of either INH or BHA to KatG induces only minor changes in the resonance Raman spectra, indicating that both compounds do not directly interact with the heme iron. New vibrational modes are observed at 430, 473, and 521 cm(-1), and these modes are indicative of a change in conformation in the KatG heme pocket. The intensity of these modes and the relative population of the QS heme are stable in KatG(S315T) but not in the WT enzyme. This indicates that there are differences in heme pocket stability between WT KatG and KatG(S315T). We will discuss the stabilization of the QS heme and propose a model for the inhibition of INH oxidation by KatG(S315T).     

Detection of mutations associated with multidrug-resistant Mycobacterium tuberculosis clinical isolates

Antimicrobial resistance was studied in 100 Mycobacterium tuberculosis strains selected randomly from sputum cultures of newly diagnosed tuberculosis patients. Resistance of the isolates to rifampicin, isoniazid, and ethambutol was tested by both drug susceptibility testing (DST) and allele-specific PCR (AS-PCR). A total of 19 (19%) isolates were found resistant to at least one of the antituberculosis drugs investigated by PCR compared with 14 (14%) resistant isolates detected by DST. Eleven mutations were detected by AS-PCR in the rpoB gene (codons 516, 526, and 531), associated with rifampicin resistance, a marker of multidrug-resistant tuberculosis (MDR-TB), 14 mutations in the katG gene codon 315 that confers resistance to isoniazid, and nine mutations in the embB gene codon 306 that confers resistance to ethambutol. Mutations in the six multidrug-resistant isolates were confirmed by DNA sequencing. Results were compared with phenotypic DST data. Nineteen different mutation types to at least one of the drugs were found; six isolates (6%) were classified as MDR-TB, defined as resistance to at least rifampicin and isoniazid. The rates of concordance of the PCR with the phenotypic susceptibility test were 71.4, 54.5, and 44.4 for isoniazid, rifampicin, and ethambutol, respectively. These results highlight the importance of molecular epidemiology studies of tuberculosis in understudied regions with a tuberculosis burden to uncover the true prevalence of the MDR-TB.     

Characterization of mutations causing rifampicin and isoniazid resistance of Mycobacterium tuberculosis in Syria

In order to characterize mutations causing rifampicin and isoniazid resistance of M. tuberculosis in Syria, 69 rifampicin resistant (Rif(r)) and 72 isoniazid resistant (Inh(r)) isolates were screened for point mutations in hot spots of the rpoB, katG and inhA genes by DNA sequencing and real time PCR. Of 69 Rif(r) isolates, 62 (90%) had mutations in the rifampin resistance determining region (RRDR) of the rpoB gene, with codons 531 (61%), 526 (13%), and 516 (8.7%) being the most commonly mutated. We found two new mutations (Asp516Thr and Ser531Gly) described for the first time in the rpoB-RRDR in association with rifampicin resistance. Only one mutation (Ile572Phe) was found outside the rpoB-RRDR. Of 72 Inh(r) strains, 30 (41.6%) had a mutation in katGcodon315 (with Ser315Thr being the predominant alteration), and 23 (32%) harbored the inhA(-15C-->T) mutation. While the general pattern of rpoB-RRDR and katG mutations reflected those found worldwide, the prevalence of the inhA(-15C-->T mutation was above the value found in most other countries, emphasizing the great importance of testing the inhA(-15C-->T) mutation for prediction of isoniazid resistance in Syria. Sensitivity of a rapid test using real time PCR and 3'-Minor groove binder (MGB) probes in detecting Rif(r) and Inh(r) isolates was 90% and 69.4%, respectively. This demonstrates that a small set of MGB-probes can be used in real time PCR in order to detect most mutations causing resistance to rifampicin and isoniazid.     

Evaluation of reasons of the MDR M. tuberculosis strains dissemination by analysis of the rifampicin and/or isoniazid resistant isolates

During the last years in Novosibirsk region of Russia the rate of TB patients infected by MDR strains of M. tuberculosis has been constantly increasing. This increase may occur as a result of the spontaneously mutated mycobacterium selection during treatment of patients or as a result of primary infection by the resistant M. tuberculosis, or also, as a result of both reasons in combination. If the main reason of MDR strain dissemination is selection of resistant bacterium during patient treatment, the equal apportionment of the dominated mutation into the mycobacterium genotypes would be observed. If the main reason is the primary infection by resistant M. tuberculosis, the unequal apportionment would be revealed. For deeper understanding of the main reasons of the fast MDR strains spreading in the region, the distribution of the main mutations over genotypes of strains in Novosibirsk (170 isolates) and Tomsk prison (51 isolates) was investigated. Mutations in rpoB gene associated with the rifampicin resistance and in katG (isoniazid resistance) were detected by biochips. M. tuberculosis genotypings were carried out by IS6110 PCR typing or MIRU typing, in the last method the twelve loci (MIRU 2, 4, 10, 16, 20, 23, 24, 26, 27, 31, 39, 40) have been used. The most frequent mutation in the rpoB gene was Ser531-->Leu (60-70% of the rifampicin resistant strains) and Ser315-->Thr in gene katG (80% of the isoniazid resistant M. tuberculosis). Both in Novosibirsk and in Tomsk prison the rates of clustered cases transmissions were high (69 and 63% respectively). Analysis of the distribution of the dominated mutations Ser531-->Leu (rpoB) and Ser315-->Thr (katG) revealed that all of them were detected in each clusters, but in Novosibirsk there were only two clusters, in which the percentage of strains, containing mutation Ser531-->Leu (rpoB) were higher (85.7% and 77.7% respectively, P < 0.05), then in others. Among the Tomsk prison's clusters it was revealed one in which the proportion of the Ser3 15-->Thr mutation in katGwas higher (96.4%, P < 0.05). The nonuniform distribution of the dominated mutations highlighted that the epidemic spread of drug-resistant strains of M. tuberculosis in region resulted from the selection of them during patient treatment and the subsequent transmission by TB patients.     

A novel genotypic test for rapid detection of multidrug-resistant Mycobacterium tuberculosis isolates by a multiplex probe array

AIMS: To develop and evaluate a novel genotypic test for rapid detection of rifampicin and isoniazid resistance of multidrug-resistant (MDR) Mycobacterium tuberculosis isolates by a multiplex probe array. METHODS AND RESULTS: A multiplex probe array was designed for genotypic test to simultaneously screen the mutations of rpoB, katG, inhA and ahpC genes, associated with rifampin and isoniazid resistance in M. tuberculosis, with a probe detecting one of the recently confirmed genetic markers of isoniazid resistance ahpC-6 and -9 locus added. By using the genotypic test developed, 52 MDR isolates were identified, among which 46 isolates had mutations in rpoB (88.5%) and 45 at codon 315 of katG, regulatory region of inhA and oxyR-ahpC intergenic region (86.5%), whereas all 35 susceptible isolates identified showed a wild-type hybridization pattern. The sensitivity and specificity were 88.5% and 100% for rifampicin resistance, and 86.5% and 100% for isoniazid resistance, respectively. CONCLUSION: A rapid and simultaneous detection of rifampicin and isoniazid resistance caused by the mutations of rpoB, katG, inhA and ahpC genes in M. tuberculosis isolates could be achieved by a multiplex probe array developed. SIGNIFICANCE AND IMPACT OF THE STUDY: This genotypic test protocol has the potential to be developed on clinical application for the rapid detection of drug resistant M. tuberculosis isolates before an efficient chemotherapy is initiated.     

Catalase-peroxidase of Mycobacterium bovis BCG converts isoniazid to isonicotinamide, but not to isonicotinic acid: differentiation parameter between enzymes of Mycobacterium bovis BCG and Mycobacterium tuberculosis

Isonicotinic acid hydrazide (Isoniazid, INH) is one of the major drugs worldwide used in the chemotherapy of tuberculosis. Many investigators have emphasized that INH activation is associated with mycobacterial catalase-peroxidase (katG). However, INH activation mechanism is not completely understood. In this study, katG of M. bovis BCG was separated and purified into two katGs, katG I (named as relatively higher molecular weight than katG II) and katG II, indicating that there is some difference in protein structure between two katGs. The molecular weight of the enzymes of katG I and katG II was estimated to be approximately 150,000 Da by gel filtration, and its subunit was 75,000 Da as determined by SDS-PAGE, indicating that purified enzyme was composed of two identical subunits. The specific activity of the purified enzyme katG I was 991.1 (units/mg). The enzymes were then investigated in INH activation by using gas chromatography mass spectrometry (GC-MS). The analysis of GC-MS showed that the katG I from M. bovis BCG directly converted INH (Mr, 137) to isonicotinamide (Mr, 122), not to isonicotinic acid (Mr, 123), in the presence or absence of H2O2. Therefore, this is the first report that katG I, one of two katGs with almost same molecular weight existed in M. bovis BCG, converts INH to isonicotinamide and this study may give us important new light on the activation mechanism of INH by KatG between M. bovis BCG and M. tuberculosis.     

Antimicrobial susceptibility determined by the E test, Löwenstein-Jensen proportion, and DNA sequencing methods among Mycobacterium tuberculosis isolates discrepancies, preliminary results

Mycobacterium tuberculosis strains resistant to streptomycin (SM), isoniazid (INH), and/or rifampin (RIF) as determined by the conventional L?wenstein-Jensen proportion method (LJPM) were compared with the E test, a minimum inhibitory concentration susceptibility method. Discrepant isolates were further evaluated by BACTEC and by DNA sequence analyses for mutations in genes most often associated with resistance to these drugs (rpsL, katG, inhA, and rpoB). Preliminary discordant E test results were seen in 75% of isolates resistant to SM and in 11% to INH. Discordance improved for these two drugs (63%) for SM and none for INH when isolates were re-tested but worsened for RIF (30%). Despite good agreement between phenotypic results and sequencing analyses, wild type profiles were detected on resistant strains mainly for SM and INH. It should be aware that susceptible isolates according to molecular methods might contain other mechanisms of resistance. Although reproducibility of the LJPM susceptibility method has been established, variable E test results for some M. tuberculosis isolates poses questions regarding its reproducibility particularly the impact of E test performance which may vary among laboratories despite adherence to recommended protocols. Further studies must be done to enlarge the evaluated samples and looked possible mutations outside of the hot spot sequenced gene among discrepant strains.     

Microarray and allele specific PCR detection of point mutations in Mycobacterium tuberculosis genes associated with drug resistance

Global public health is threatened by the emergence of potentially dangerous antibiotic drug-resistant strains of Mycobacterium tuberculosis. Point mutations in certain M. tuberculosis genes are associated with the resistance of M. tuberculosis strains to antibiotic drugs. The purpose of this study was to develop a suitable microarray-based protocol for the detection of point mutations in M. tuberculosis genes associated with drug resistance. We initially developed a conventional, oligonucleotide microarray protocol and used it to detect and identify on a single microarray slide a number of point mutation-containing rpoB and katG gene target sequences. However, the occurrence of some non-specific hybridization led us to the development of an improved protocol based on allele specific PCR combined with tags/anti-tags and microarrays. This protocol was evaluated by detecting point mutations in M. tuberculosis katG and rpoB gene templates produced by recombinant PCR. The methodology allowed sequences containing single point mutations to be readily distinguished from wild type sequences. The data obtained with the improved protocol had strong and specific signals and relatively low amounts of non-specific hybridization. We successfully used this protocol to detect and identify (<8 h) a number of clinically relevant point mutations in the rpoB, katG and rpsL genes of M. tuberculosis clinical isolates. Our allele specific PCR/tags and anti-tags/microarray protocol has several advantages over our conventional oligonucleotide microarray protocol, and it may have broad applications for point mutation detection.     

Genotypic detection of rifampicin and isoniazid resistant Mycobacterium tuberculosis strains by DNA sequencing: a randomized trial

Background

Tuberculosis is a growing international health concern. It is the biggest killer among the infectious diseases in the world today. Early detection of drug resistance allows starting of an appropriate treatment. Resistance to drugs is due to particular genomic mutations in specific genes of Mycobacterium tuberculosis(MTB). The aim of this study was to identify the presence of Isoniazid (INH) and Rifampicin(RIF) drug resistance in new and previously treated tuberculosis (TB) cases using DNA sequencing.

Methods

This study was carried out on 153 tuberculous patients with positive Bactec 460 culture for acid fast bacilli.

Results

Of the 153 patients, 105 (68.6%) were new cases and 48 (31.4%) were previously treated cases. Drug susceptibility testing on Bactec revealed 50 resistant cases for one or more of the first line antituberculous. Genotypic analysis was done only for rifampicin resistant specimens (23 cases) and INH resistant specimens (26 cases) to detect mutations responsible for drug resistance by PCR amplification of rpoB gene for rifampicin resistant cases and KatG gene for isoniazid resistant cases. Finally, DNA sequencing was done for detection of mutation within rpoB and KatG genes. Genotypic analysis of RIF resistant cases revealed that 20/23 cases (86.9%) of RIF resistance were having rpoB gene mutation versus 3 cases (13.1%) having no mutation with a high statistical significant difference between them (P < 0.001). Direct sequencing of Kat G gene revealed point mutation in 24/26 (92.3%) and the remaining 2/26 (7.7%) had wild type KatG i.e. no evidence of mutation with a high statistical significant difference between them (P < 0.001).

Conclusion

We can conclude that rifampicin resistance could be used as a useful surrogate marker for estimation of multidrug resistance. In addition, Genotypic method was superior to that of the traditional phenotypic method which is time-consuming taking several weeks or longer.     

Site-directed mutagenesis and virulence assessment of the katG gene of Mycobacterium intracellulare

Mycobacterial catalases have been suggested as acting as virulence factors by protecting intracellular mycobacteria from reactive oxidative metabolites produced by host phagocytes. Mycobacterium intracellulare , like many other mycobacteria, produces two proteins with catalase activity: a heat-stable catalase (KatE) and an inducible, heat-labile catalase peroxidase (KatG). The M. intracellulare katG gene was cloned, and a plasmid derivative with a 4 bp insertion in the katG coding sequence was constructed and used for site-directed mutagenesis of M. intracellulare 1403 (ATCC 35761). The resulting katG mutant was highly resistant to isoniazid (INH), showed an increased sensitivity to H₂O₂ and had lost peroxidase and heat-sensitive catalase activity but retained heat-stable catalase activity. The plasmid carrying the katG frameshift allele was also used for mutagenesis of the mouse virulent M. intracellulare isolate D673. After intravenous injection into BALB/c mice, D673 and the isogenic katG mutant showed the same growth kinetics in the spleen, liver and lungs of the infected mice. Our results demonstrate that the KatG catalase peroxidase mediates resistance to H₂O₂ and susceptibility to INH but is not an essential virulence factor for the survival and growth of M. intracellulare in the mouse.     

Site-directed mutagenesis of the katG gene of Mycobacterium tuberculosis: effects on catalase–peroxidase activities and isoniazid resistance

Recent studies examining the molecular mechanisms of isoniazid (INH) resistance in Mycobacterium tuberculosis have demonstrated that a significant percentage of drug-resistant strains are mutated in the katG gene which encodes a catalase–peroxidase, and the majority of these alterations are missense mutations which result in the substitution of a single amino acid. In previous reports, residues which may be critical for enzymatic activity and the drug-resistant phenotype have been identified by evaluating INH-resistant clinical isolates and in vitro mutants. In this study, site-directed mutagenesis techniques were utilized to alter the wild-type katG gene from M. tuberculosis at 13 of these codons. The effects of these mutations were determined using complementation assays in katG -defective, INH-resistant strains of Mycobacterium smegmatis and Mycobacterium bovis BCG. This mutational analysis revealed that point mutations in the katG gene at nine of the 13 codons can cause drug resistance, and that enzymatic activity and resistance to INH are inversely related. In addition, mutations in the mycobacterial catalase–peroxidase which reduce catalase activity also decrease peroxidase activity.     

Purification and characterization of Mycobacterium tuberculosis KatG, KatG(S315T), and Mycobacterium bovis KatG(R463L)

Isoniazid, a first-line antibiotic used for the treatment of tuberculosis, is a prodrug that requires activation by the Mycobacterium tuberculosis enzyme KatG. The KatG(S315T) mutation causes isoniazid resistance while the KatG(R463L) variation is thought to be a polymorphism. Much of the work to date focused on isoniazid activation by KatG has utilized recombinant enzyme overexpressed in Escherichia coli. In this work, native KatG and KatG(S315T) were purified from M. tuberculosis, and KatG(R463L) was purified from Mycobacterium bovis. The native molecular weight, enzymatic activity, optical, resonance Raman, and EPR spectra, K(D) for isoniazid binding, and isoniazid oxidation rates were measured and compared for each native enzyme. Further, the properties of the native enzymes were compared and contrasted with those reported for recombinant KatG, KatG(S315T), and KatG(R463L) in order to assess the ability of the recombinant enzymes to act as good models for the native enzymes.