Nucleotide sequence of the Mycobacterium leprae katG region.

Synthetic oligonucleotide primers based on the DNA sequence data of the Escherichia coli, Mycobacterium tuberculosis, and Mycobacterium intracellulare katG genes encoding the heme-containing enzyme catalase-peroxidase were used to amplify and analyze the Mycobacterium leprae katG region by PCR. A 1.6-kb DNA fragment, which hybridized to an M. tuberculosis katG probe, was obtained from an M. leprae DNA template. Southern hybridization analysis with a probe derived from the PCR-amplified fragment showed that the M. leprae chromosome contains only one copy of the putative katG sequence in a 3.4-kb EcoRI-BamHI DNA segment. Although the nucleotide sequence of the katG region of M. leprae was approximately 70% identical to that of the M. tuberculosis katG gene, no open reading frame encoding a catalase-peroxidase was detectable in the whole sequence. Moreover, two DNA deletions of approximately 100 and 110 bp were found in the M. leprae katG region, and they seemed to be present in all seven M. leprae isolates tested. These results strongly suggest that M. leprae lacks a functional katG gene and catalase-peroxidase activity.     

Crystal structure of Mycobacterium tuberculosis catalase-peroxidase

The Mycobacterium tuberculosis catalase-peroxidase is a multifunctional heme-dependent enzyme that activates the core anti-tuberculosis drug isoniazid. Numerous studies have been undertaken to elucidate the enzyme-dependent mechanism of isoniazid activation, and it is well documented that mutations that reduce activity or inactivate the catalase-peroxidase lead to increased levels of isoniazid resistance in M. tuberculosis. Interpretation of the catalytic activities and the effects of mutations upon the action of the enzyme to date have been limited due to the lack of a three-dimensional structure for this enzyme. In order to provide a more accurate model of the three-dimensional structure of the M. tuberculosis catalase-peroxidase, we have crystallized the enzyme and now report its crystal structure refined to 2.4-A resolution. The structure reveals new information about dimer assembly and provides information about the location of residues that may play a role in catalysis including candidates for protein-based radical formation. Modeling and computational studies suggest that the binding site for isoniazid is located near the delta-meso heme edge rather than in a surface loop structure as currently proposed. The availability of a crystal structure for the M. tuberculosis catalase-peroxidase also permits structural and functional effects of mutations implicated in causing elevated levels of isoniazid resistance in clinical isolates to be interpreted with improved confidence.     

katGI and katGII encode two different catalases-peroxidases in Mycobacterium fortuitum.

It has been suggested that catalase-peroxidase plays an important role in several aspects of mycobacterial metabolism and is a virulence factor in the main pathogenic mycobacteria. In this investigation, we studied genes encoding for this protein in the fast-growing opportunistic pathogen Mycobacterium fortuitum. Nucleotide sequences of two different catalase-peroxidase genes (katGI and katGII) of M. fortuitum are described. They show only 64% homology at the nucleotide level and 55% identity at the amino acid level, and they are more similar to catalases-peroxidases from different bacteria, including mycobacteria, than to each other. Both proteins were found to be expressed in actively growing M. fortuitum, and both could also be expressed when transformed into Escherichia coli and M. aurum. We detected the presence of a copy of IS6100 in the neighboring region of a katG gene in the M. fortuitum strain in which this element was identified (strain FC1). The influence of each katG gene on isoniazid (isonicotinic acid hydrazide; INH) susceptibility of mycobacteria was checked by using the INH-sensitive M. aurum as the host. Resistance to INH was induced when katGI was transformed into INH-sensitive M. aurum, suggesting that this enzyme contributes to the natural resistance of M. fortuitum to the drug. This is the first report showing two different genes encoding same enzyme activity which are actively expressed within the same mycobacterial strain.     

Detection and purification of a catalase-peroxidase from Mycobacterium sp. Pyr-1

A catalase-peroxidase from Mycobacterium sp. Pyr-1, a strain capable of growth on pyrene, was purified to homogeneity by anion exchange and hydroxyapatite column chromatography. The enzyme, like the M. tuberculosis T-catalase, reduced nitroblue tetrazolium in the presence of isoniazid (INH) and H2O2. It also oxidized 3,3',5,5'-tetramethylbenzidine and other substrates of the catalase-peroxidase of M. tuberculosis in the presence of either tert-butyl hydroperoxide or H2O2. It had a UV/ visible absorption spectrum (Soret peak at 406 nm) similar to that of the catalase-peroxidase of M. tuberculosis (Soret peak at 408 nm) and identical to that of the catalase-peroxidase of M. smegmatis. After electrophoresis on non-denaturing gels the enzyme showed one single protein band with both catalase and peroxidase activity, which were lost after electrophoresis on SDS-PAGE. The enzyme was inhibited by sodium azide, glutathione, 2-mercaptoethanol, and isoniazid, but not by isonicotinic acid. The optimum enzyme activity was obtained at pH 4.5 and at 25 degrees C.     

Binding of the anti-tubercular drug isoniazid to the arylamine N-acetyltransferase protein from Mycobacterium smegmatis

Isoniazid is a frontline drug used in the treatment of tuberculosis (TB). Isoniazid is a prodrug, requiring activation in the mycobacterial cell by the catalase/peroxidase activity of the katG gene product. TB kills two million people every year and the situation is getting worse due to the increase in prevalence of HIV/AIDS and emergence of multidrug-resistant strains of TB. Arylamine N-acetyltransferase (NAT) is a drug-metabolizing enzyme (E.C. 2.1.3.5). NAT can acetylate isoniazid, transferring an acetyl group from acetyl coenzyme A onto the terminal nitrogen of the drug, which in its N-acetylated form is therapeutically inactive. The bacterium responsible for TB, Mycobacterium tuberculosis, contains and expresses the gene encoding the NAT protein. Isoniazid binds to the NAT protein from Salmonella typhimurium and we report here the mode of binding of isoniazid in the NAT enzyme from Mycobacterium smegmatis, closely related to the M. tuberculosis and S. typhimurium NAT enzymes. The mode of binding of isoniazid to M. smegmatis NAT has been determined using data collected from two distinct crystal forms. We can say with confidence that the observed mode of binding of isoniazid is not an artifact of the crystallization conditions used. The NAT enzyme is active in mycobacterial cells and we propose that isoniazid binds to the NAT enzyme in these cells. NAT activity in M. tuberculosis is likely therefore to modulate the degree of activation of isoniazid by other enzymes within the mycobacterial cell. The structure of NAT with isoniazid bound will facilitate rational drug design for anti-tubercular therapy.     

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.     

Encapsulation of DNA in negatively charged liposomes and inhibition of bacterial gene expression with fluid liposome-encapsulated antisense oligonucleotides

The catalase-peroxidase encoded by katG of Mycobacterium tuberculosis is a more effective activator of the antibiotic isoniazid than is the equivalent enzyme from Escherichia coli. The environment of the heme iron was investigated using X-ray absorption spectroscopy to determine if differences in this region were associated with the differences in reactivity. The variation in the distal side Fe-ligand distances between the two enzymes was the same within experimental error indicating that it was not the heme iron environment that produced the differences in reactivity. Analysis of variants of the E. coli catalase-peroxidase containing changes in active site residues Arg102 and His106 revealed small differences in Fe-water ligand distance including a shorter distance for the His106Tyr variant. The Arg102Leu variant was 5-coordinate, but His106Cys and Arg102Cys variants showed no changes within experimental error. These results are compared with those reported for other peroxidases.     

Enzyme-catalyzed mechanism of isoniazid activation in class I and class III peroxidases

There is an urgent need to understand the mechanism of activation of the frontline anti-tuberculosis drug isoniazid by the Mycobacterium tuberculosis catalase-peroxidase. To address this, a combination of NMR spectroscopic, biochemical, and computational methods have been used to obtain a model of the frontline anti-tuberculosis drug isoniazid bound to the active site of the class III peroxidase, horseradish peroxidase C. This information has been used in combination with the new crystal structure of the M. tuberculosis catalase-peroxidase to predict the mode of INH binding across the class I heme peroxidase family. An enzyme-catalyzed mechanism for INH activation is proposed that brings together structural, functional, and spectroscopic data from a variety of sources. Collectively, the information not only provides a molecular basis for understanding INH activation by the M. tuberculosis catalase-peroxidase but also establishes a new conceptual framework for testing hypotheses regarding the enzyme-catalyzed turnover of this compound in a number of heme peroxidases.     

Cloning, expression, and characterization of the katG gene, encoding catalase-peroxidase, from the polycyclic aromatic hydrocarbon-degrading bacterium Mycobacterium sp. strain PYR-1

A 81-kDa protein from Mycobacterium sp. strain PYR-1 was expressed in response to exposure of the strain to the polycyclic aromatic hydrocarbon pyrene and recovered by two-dimensional gel electrophoresis. The N-terminal sequence of the protein indicated that it was similar to catalase-peroxidase. An oligonucleotide probe designed from this sequence was used to screen a genomic library of Mycobacterium sp. strain PYR-1, and a positive clone, containing a part of the gene encoding the 81-kDa protein, was isolated. A gene-walking technique was used to sequence the entire gene, which was identified as katG for catalase-peroxidase. The deduced KatG protein sequence showed significant homology to KatGII of Mycobacterium fortuitum and clustered with catalase-peroxidase proteins from other Mycobacterium species in a phylogenetic tree. The katG gene was expressed in Escherichia coli to produce a protein with catalase-peroxidase activity. Since the induction of this catalase-peroxidase occurred in pyrene-induced cultures and the exposure of these cultures to hydrogen peroxide reduced pyrene metabolism, our data suggest that this enzyme plays a role in polycyclic aromatic hydrocarbon metabolism by strain PYR-1.     

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.     

Characterization of a bifunctional catalase-peroxidase of Burkholderia cenocepacia

Isolates of Burkholderia cenocepacia express a putative haem-binding protein (molecular mass 97 kDa) that displays intrinsic peroxidase activity. Its role has been re-evaluated, and we now show that it is a bifunctional catalase-peroxidase, with activity against tetramethylbenzidine (TMB), o-dianisidine, pyrogallol, and 2,2'-azino-bis(3-ethylbenzthiazoline-6-sulphonic) acid (ABTS). Both peroxidase and catalase activities are optimal at pH 5.5-6.0. The gene encoding this enzyme was cloned and expressed in Escherichia coli. We have named it katG because of its similarity to other katGs, including that from Burkholderia pseudomallei. It is substantially similar to a previously described catalase-peroxidase of B. cenocepacia (katA). MS analysis indicated that the initial katG translation product may be post-translationally modified in B. cenocepacia to give rise to the mature 97-kDa catalase-peroxidase.     

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.     

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.     

Missense mutations in the catalase-peroxidase gene, katG, are associated with isoniazid resistance in Mycobacterium tuberculosis

The toxicity of the powerful anti-tuberculosis drug isoniazid (INH) is believed to be mediated by the haem-containing enzyme catalase-peroxidase, encoded by the katG gene of Mycobacterium tuberculosis. Compelling evidence for this was obtained by studying a panel of INH-resistant clinical isolates using a novel strategy based on the polymerase chain reaction and single-strand-conformation polymorphism analysis (PCR-SSCP) to detect mutations in katG. In most cases INH resistance was associated with missense mutations while in a small number of strains the gene had been completely, or partially, deleted. The missense mutations fell into two groups, the larger of which contained several independent mutations that affected the N-terminal peroxidase domain of the protein, resulting in the production of a catalase peroxidase with strongly reduced enzyme activity and increased heat lability. The effects of these substitutions could be interpreted by means of molecular modelling using the crystal structure of the related enzyme cytochrome c peroxidase from yeast as a template. The second group comprises a frequently occurring amino acid substitution and a single mutation that are both located in the C-terminal domain but do not noticeably alter either enzyme activity or heat stability.     

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.     

Mutations linked with antimicrobial resistance in Mycobacterium tuberculosis isolated from tuberculosis patients in the Samara region

A total of 234 M. tuberculosis isolates were used to demonstrate the leading role of mutations in, respectively, codon 531 of gene rpoB (90.0%) and codon 315 of gene katG (92.9%), in the development of resistance to rifampicin and isoniazid by the methods of reverse hybridization with oligonucleotide probes and the sequencing of gene stretches. The levels of primary resistance of M. tuberculosis to rifampicin, isoniazid and multiresistance, according to the molecular-genetic analysis, were 41.0%, 57.7% and 37.2% respectively. The coincidence of the results of the bacteriological and molecular-genetic analyses of the antimicrobial resistance of the isolates was 90.4% and 95.3% for isoniazid and rifampicin respectively. The prevalence of individual types of mutations, linked with antimicrobial resistance, in the presence of a considerable spread of strains of the family Beijing in the region may be indicative of the limited number of M. tuberculosis clones circulating in the region.