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.     

Isoniazid‐resistance conferring mutations in Mycobacterium tuberculosis KatG: Catalase,peroxidase, and INH‐NADH adduct formation activities

Mycobacterium tuberculosis catalase‐peroxidase (KatG) is a bifunctional hemoprotein that has been shown to activate isoniazid (INH), a pro‐drug that is integral to frontline antituberculosis treatments. The activated species, presumed to be an isonicotinoyl radical, couples to NAD⁺/NADH forming an isoniazid‐NADH adduct that ultimately confers anti‐tubercular activity. To better understand the mechanisms of isoniazid activation as well as the origins of KatG‐derived INH‐resistance, we have compared the catalytic properties (including the ability to form the INH‐NADH adduct) of the wild‐type enzyme to 23 KatG mutants which have been associated with isoniazid resistance in clinical M. tuberculosis isolates. Neither catalase nor peroxidase activities, the two inherent enzymatic functions of KatG, were found to correlate with isoniazid resistance. Furthermore, catalase function was lost in mutants which lacked the Met‐Tyr‐Trp crosslink, the biogenic cofactor in KatG which has been previously shown to be integral to this activity. The presence or absence of the crosslink itself, however, was also found to not correlate with INH resistance. The KatG resistance‐conferring mutants were then assayed for their ability to generate the INH‐NADH adduct in the presence of peroxide (t‐BuOOH and H₂O₂), superoxide, and no exogenous oxidant (air‐only background control). The results demonstrate that residue location plays a critical role in determining INH‐resistance mechanisms associated with INH activation; however, different mutations at the same location can produce vastly different reactivities that are oxidant‐specific. Furthermore, the data can be interpreted to suggest the presence of a second mechanism of INH‐resistance that is not correlated with the formation of the INH‐NADH adduct.     

Molecular analysis of type I-A (tyrosinase negative) oculocutaneous albinism

Type I oculocutaneous albinism (OCA) is caused by the reduction in or absence of activity of tyrosinase in melanocytes in skin, hair, and the eyes, the result of mutations of the tyrosinase gene. To date, a total of 22 unique mutations in the coding region of tyrosinase have been described in the literature. In this report we present 5 additional mutations of the tyrosinase gene associated with type I-A OCA in four individuals, including 2 missense, 1 frameshift and 2 nonsense mutations, and review the relevant literature on all published mutations. Analysis of the distribution of all identified missense mutations (n = 17) shows that most cluster in three areas of the gene and involve amino acids conserved between humans and the mouse. Two clusters involve the copper A and copper B binding sites and may disrupt the metal ion-protein interaction necessary for enzyme function. The third cluster in exon I could represent a functional domain important in enzyme function such as the tyrosine or the dihydroxyphenylalanine (DOPA) binding site of the enzyme. Small deletions or insertions resulting in frameshift mutations and nonsense mutations are distributed throughout the coding region and do not appear to cluster.     

A SALL4 zinc finger missense mutation predicted to result in increased DNA binding affinity is associated with cranial midline defects and mild features of Okihiro syndrome

Truncating mutations of the gene SALL4 on chromosome 20q13.13–13.2 cause Okihiro and acro-renal-ocular syndromes. Pathogenic missense mutations within the SALL4 or SALL1 genes have not yet been reported, raising the question which phenotypic features would be associated with them. Here we describe the first missense mutation within the SALL4 gene. The mutation results in an exchange of a highly conserved zinc-coordinating Histidine crucial for zinc finger (ZF) structure within a C2H2 double ZF domain to an Arginine. Molecular modeling predicts that this exchange does not result in a loss of zinc ion binding but leads to an increased DNA-binding affinity of the domain. The index patient shows mild features of Okihiro syndrome, but in addition cranial midline defects (pituitary hypoplasia and single central incisor). This finding illustrates that the phenotypic and functional effects of SALL4 missense mutations are difficult to predict, and that other SALL4 missense mutations might lead to phenotypes not overlapping with Okihiro syndrome. This study has received approval by the institutional review board (Ethics committee) of the Medical Faculty, University of Freiburg, Germany. Jan Miertus and Wiktor Borozdin have equally contributed to this work.     

Iron enhances the susceptibility of pathogenic mycobacteria to isoniazid, an antitubercular drug

The catalase-peroxidase KatG of Mycobacterium tuberculosis plays a central role in the mechanism of action of the anti-tubercular drug isoniazid (INH). Like other bacterial catalases, mycobacterial catalase-peroxidases are dual active enzymes with both catalase and peroxidase activities in the same protein molecule. In our previous study, we showed that iron deprivation resulted in the loss of peroxidase activity in several non-pathogenic mycobacterial species. Here we extended the study to pathogenic mycobacteria and showed that the peroxidase activity, associated with iron-sufficient (4 μg Fe/ml) conditions of growth was responsible for INH activation. Upon iron deprivation (0.02 μg Fe/ml), peroxidase activity was abolished and there was no activation of INH, as demonstrated both by INH-mediated NBT reduction (spectrophotometrically and activity staining in gels) and by viability studies as assayed by the microplate Alamar Blue assay (MABA). In the viability assay, iron-sufficient M. tuberculosis, Mycobacterium bovis and Mycobacterium bovis BCG were susceptible to INH and iron-deficient organisms expressing negligible peroxidase survived high concentrations of the drug. It␣is well known that M. tuberculosis is sensitive to low concentrations of INH while the minimum inhibitory concentration of the drug is quite high for other mycobacteria, especially the non-pathogenic species. We showed this difference to be due to the specificity of the peroxidase for the drug. As withholding of iron is one of the host’s mechanisms of controlling an invading pathogen, the implications of these observations on the efficacy of the anti-tubercular drug INH are discussed with reference to the iron status within the human host.     

Sequence variation in two lignin biosynthesis genes,cinnamoyl CoA reductase (CCR) and cinnamyl alcohol dehydrogenase 2 (CAD2)

Cinnamoyl CoA reductase (CCR) and cinnamyl alcohol dehydrogenase 2 (CAD2) are genes which may influence variation in lignin content and composition within plants. Sequence variation within these genes may be responsible for changes in enzyme activity and/or specificity, which could cause variation in lignin content or composition. This study examines sequence variation within these two genes in Eucalyptus globulus, an important species used in pulp and paper-making. Twenty-one single nucleotide polymorphisms (SNPs) were identified in the exons of CCR, of which nine were neutral mutations and 12 were missense mutations. Six of the missense mutations affected highly conserved amino acids within the protein sequence of CCR. Eight SNPs were identified in the CAD2 exons, six of which were neutral mutations and two which were missense mutations. One of the missense mutations affected a highly conserved amino acid within the protein sequence. In addition, 32 SNPs were identified in the CCR introns along with four insertion/deletions and two polyA length variation regions. Polymorphism affecting highly conserved amino acids may alter enzyme function and this molecular variation may be linked to variation in lignin profiles. Selecting positive alleles which produce favourable lignin profiles would be advantageous in tree breeding programs.     

Genetic analysis of the LexA repressor: Isolation and characterization of LexA(Def) mutant proteins

Summary We report the isolation of LexA mutant proteins with impaired repressor function. These mutant proteins were obtained by transforming a LexA-deficient recA-lacZ indicator strain with a randomly mutagenized plasmid harbouring the lexA gene and subsequent selection on MacConkey-lactose indicator plates. A total of 24 different lexA(Def) missense mutations were identified. All except three mutant proteins are produced in near-normal amounts suggesting that they are fairly resistant to intracellular proteases. All lexA(Def) missense mutations are situated within the first 67 amino acids of the amino-terminal DNA binding domain. The properties of an intragenic deletion mutant suggest that the part of the amino-terminal domain important for DNA recognition or domain folding should extent at least to amino acids 69 or 70. A recent 2D-NMR study (Lamerichs et al. 1989) has identified three a helices in the DNA binding domain of LexA. The relative orientation of two of them (helices 2 and 3) is reminiscent of, but not identical to, the canonical helix-turn-helix motif suggesting nevertheless that helix 3 might be involved in DNA recognition. The distribution of the lexA(Def) missense mutations along the first 67 amino-terminal amino acids indeed shows some clustering within helix 3, since 8 out of the 24 different missense mutations are found in this helix. However one mutation in front of helix 1 and five mutations between amino acids 61 and 67 suggest that elements other than helices 2 and 3 may be important for DNA binding.     

Analysis of Mucolipidosis II/III GNPTAB Missense Mutations Identifies Domains of UDP-GlcNAc:lysosomal Enzyme GlcNAc-1-phosphotransferase Involved in Catalytic Function and Lysosomal Enzyme Recognition

UDP-GlcNAc:lysosomal enzyme GlcNAc-1-phosphotransferase tags newly synthesized lysosomal enzymes with mannose 6-phosphate recognition markers, which are required for their targeting to the endolysosomal system. GNPTAB encodes the α and β subunits of GlcNAc-1-phosphotransferase, and mutations in this gene cause the lysosomal storage disorders mucolipidosis II and III αβ. Prior investigation of missense mutations in GNPTAB uncovered amino acids in the N-terminal region and within the DMAP domain involved in Golgi retention of GlcNAc-1-phosphotransferase and its ability to specifically recognize lysosomal hydrolases, respectively. Here, we undertook a comprehensive analysis of the remaining missense mutations in GNPTAB reported in mucolipidosis II and III αβ patients using cell- and zebrafish-based approaches. We show that the Stealth domain harbors the catalytic site, as some mutations in these regions greatly impaired the activity of the enzyme without affecting its Golgi localization and proteolytic processing. We also demonstrate a role for the Notch repeat 1 in lysosomal hydrolase recognition, as missense mutations in conserved cysteine residues in this domain do not affect the catalytic activity but impair mannose phosphorylation of certain lysosomal hydrolases. Rescue experiments using mRNA bearing Notch repeat 1 mutations in GNPTAB-deficient zebrafish revealed selective effects on hydrolase recognition that differ from the DMAP mutation. Finally, the mutant R587P, located in the spacer between Notch 2 and DMAP, was partially rescued by overexpression of the γ subunit, suggesting a role for this region in γ subunit binding. These studies provide new insight into the functions of the different domains of the α and β subunits.     

Engineering of histidine tail in the N-terminal region of p-hydroxybenzoate hydroxylase from Pseudomonas fluorescens

The pobA of Pseudomonas florescens IFO14160 encoding a p-hydroxybenzoate hydroxylase (PHBH) was cloned, sequenced, and over-expressed in Escherichia coli. To facilitate the purification of PHBH, a fully active, tagged enzyme was constructed by engineering a two-, three-, or six-histidine tail in the N-terminal region (H2-, H3-, or H6-PHBH), or a six-histidine tail in the C-terminal region of the PHBH. The six-histidine tail in the C-terminal region of the enzyme could not be expressed with activity, while the other polyhistidine tails in the N-terminal region of the enzyme were highly active. However, the resulting H6-PHBH could not be purified by Ni-NTA chromatography because the H6-PHBH was so strongly bound to the supports that it could be eluted only after a significant change in conditions. On the other hand, H2-PHBH did not bind tightly to the Ni-chelate support. H3-PHBH was purified from the crude extract in a single step by using the optimized length and location of the polyhistidine tail in the enzyme.     

Heterogeneity of mutations in the uroporphyrinogen III synthase gene in congenital erythropoietic porphyria

Summary Congenital erythropoietic porphyria (CEP) or Günther's disease is an inborn error of heme biosynthesis transmitted as an autosomal recessive trait and characterized by a profound deficiency of uroporphyrinogen III synthase (UROIIIS) activity. We have previously described two missense mutations in the UROIIIS gene, confirming that the primary defect responsible for CEP is a structural alteration of this gene. We have extended our work to 5 additional unrelated families. Two new point mutations, a deletion and an insertion have been found in the messenger RNA. Our study shows that a molecular heterogeneity of the mutations exists in Günther's disease. One mutation (C73R), however, appears to be more frequent than the others. Finally, the different normal and mutated proteins have been expressed in Escherichia coli to determine the consequence of the mutations on the enzyme activity.     

Alterations in tumour suppressor gene p53 in human gliomas from Indian patients

Alterations in the tumour suppressorp53 gene are among the most common defects seen in a variety of human cancers. In order to study the significance of thep53 gene in the genesis and development of human glioma from Indian patients, we checked 44 untreated primary gliomas for mutations in exons 5–9 of thep53 gene by PCR-SSCP and DNA sequencing. Sequencing analysis revealed six missense mutations. The incidence of p53 mutations was 13⋅6% (6 of 44). All the six mutations were found to be located in the central core domain of p53, which carries the sequence-specific DNA-binding domain. These results suggest a rather low incidence but a definite involvement of p53 mutations in the gliomas of Indian patients.     

Heterozygous Germline Mutations in the CBL Tumor-Suppressor Gene Cause a Noonan Syndrome-like Phenotype

RAS signaling plays a key role in controlling appropriate cell responses to extracellular stimuli and participates in early and late developmental processes. Although enhanced flow through this pathway has been established as a major contributor to oncogenesis, recent discoveries have revealed that aberrant RAS activation causes a group of clinically related developmental disorders characterized by facial dysmorphism, a wide spectrum of cardiac disease, reduced growth, variable cognitive deficits, ectodermal and musculoskeletal anomalies, and increased risk for certain malignancies. Here, we report that heterozygous germline mutations in CBL, a tumor-suppressor gene that is mutated in myeloid malignancies and encodes a multivalent adaptor protein with E3 ubiquitin ligase activity, can underlie a phenotype with clinical features fitting or partially overlapping Noonan syndrome (NS), the most common condition of this disease family. Independent CBL mutations were identified in two sporadic cases and two families from among 365 unrelated subjects who had NS or suggestive features and were negative for mutations in previously identified disease genes. Phenotypic heterogeneity and variable expressivity were documented. Mutations were missense changes altering evolutionarily conserved residues located in the RING finger domain or the linker connecting this domain to the N-terminal tyrosine kinase binding domain, a known mutational hot spot in myeloid malignancies. Mutations were shown to affect CBL-mediated receptor ubiquitylation and dysregulate signal flow through RAS. These findings document that germline mutations in CBL alter development to cause a clinically variable condition that resembles NS and that possibly predisposes to malignancies.     

Mutational and functional analysis of the neurofibromatosis type 1 (NF1) gene

Neurofibromatosis type 1 (NF1) is one of the most common autosomal dominant disorders. It is caused by mutations in the NF1 gene which comprises 60 exons and is located on chromosome 17q. The NF1 gene product, neurofibromin, displays partial homology to GTPase-activating protein (GAP). The GAP-related domain (GRD), encoded by exons 20–27a, is the only region of neurofibromin to which a biological function has been ascribed. A total of 320 unrelated NF1 patients were screened for mutations in the GRD-encoding region of the NF1 gene. Sixteen different lesions in the NF1 GRD region were identified in a total of 20 patients. Of these lesions, 14 are novel and together comprise three missense, two nonsense and three splice site mutations plus six deletions of between 1 and 4 bp. The effect of one of the missense mutations (R1391S) was studied by in vitro expression of a site-directed mutant and GAP activity assay. The mutant protein, R1391S, was found to be some 300-fold less active than wild-type NF1 GRD. The mutations reported in this study therefore provide further material for the functional analysis of neurofibromin as well as an insight into the mutational spectrum of the NF1 GRD. Received: 13 July 1996 / Revised: 6 August 1996     

Localised mutagenesis of the fts YEX operon conditionally lethal missense substitutions in the FtsE cell division protein of Escherichia coli are similar to those found in the cystic fibrosis transmembrane conductance regulator protein (CFTR) of human patients

Summary After localised mutagenesis of the 76 min region of the Escherichia coli chromosome, we isolated a number of conditionally lethal mutants. Some of these mutants had a filamentation temperature sensitive (fts) phenotype and were assigned to the cell division genes ftsE of ftsX whereas others were defective in the heat shock regulator gene rpoH. Both missense and amber mutant alleles of these genes were produced. The missense mutant ftsE alleles were cloned and sequenced to determine whether or not the respective mutations mapped to the region of the gene encoding the putative nucleotide binding site. Surprisingly, most of these mutant FtsE proteins had missense substitutions in a different domain of the protein. This region of the FtsE protein is highly conserved in a large family of proteins involved in diverse transport processes in all living cells, from bacteria to man. One of the proteins in this large family of homologues is the human cystic fibrosis transmembrane conductance regulator (CFTR), and the FtsE substitutions were found to be in very closely linked, or identical, amino acid residues to those which are frequently altered in the CFTR of human patients. These results confirm the structural importance of this highly conserved region of FtsE and CFTR and add weight to the current structural model for the human protein.     

The katE gene, which encodes the catalase HPII of Mycobacterium avium

Disseminated Mycobacterium avium-Mycobacterium intracellular disease is a prevalent opportunistic infection in patients with acquired immune deficiency syndrome (AIDS). These pathogens are generally resistant to isoniazid (INH), a powerful antituberculosis drug. It is now generally accepted that the INH susceptibility of Mycobacterium tuberculosis results from the transformation of the drug into a toxic derivative, as a result of the action of the enzyme catalase-peroxidase (HPI), encoded by the katG gene. It has been speculated that the presence of a second catalase (HPII) in some mycobacterial species, but lacking in M. tuberculosis, may impair the action of INH. In this report, the nucleotide sequence of the M. avium katE gene, encoding catalase HPII, is described. This enzyme shows strong similarity to Escherichia coli catalase HPII and eukaryotic catalases. All amino acids previously postulated as participating directly in catalysis by liver catalase and most of the amino acids binding the prosthetic group are conserved in M. avium catalase HPII. The enzyme is expressed in E. coli and is inhibited by 3-amino -l,2,4 triazole (AT). Furthermore, Southern blot hybridizations and polymerase chain reaction experiments demonstrate the distribution of katE gene in several mycobacterial species. To evaluate the potentially antagonistic effect of HPII catalase on INH susceptibility, the katE gene was transformed into M. tuberculosis H37Rv and the minimum inhibitory concentration (MIC) for INH was determined. Despite strong expression of the katEgene, no change in MIC was observed, thus ruling out a possible contribution of this enzyme to the natural resistance of M. avium to the drug. The availability of the gene probe, encoding the second mycobacterial catalase HPII, should open the way for the development of new drugs and diagnostic tests to combat drug-resistant pathogen strains.     

A silent mutation in mabA confers isoniazid resistance on Mycobacterium tuberculosis

Drug resistance in Mycobacterium tuberculosis (Mtb) is caused by mutations in restricted regions of the genome. Mutations in katG, the promoter region of the mabA–inhA operon, and inhA are those most frequently responsible for isoniazid (INH) resistance. Several INH‐resistant (INH^r) Mtb clinical isolates without mutations in these regions have been described, however, indicating that there are as yet undetermined mechanisms of INH resistance. We identified the mabA^g609a silent mutation in a significant number of INH^r Mtb clinical isolates without known INH resistance mutations. A laboratory strain, H37Rv, constructed with mabA^g609a, was resistant to INH. We show here that the mabA^g609a mutation resulted in the upregulation of inhA, a gene encoding a target for INH, converting the region adjacent to the mutation into an alternative promoter for inhA. The mabA^g609a silent mutation results in a novel mechanism of INH resistance, filling in a missing piece of INH resistance in Mtb.     

Mapping disease‐related missense mutations in the immunoglobulin‐like fold domain of lamin A/C reveals novel genotype–phenotype associations for laminopathies

Mutations in A‐type nuclear lamins cause laminopathies. However, genotype–phenotype correlations using the 340 missense mutations within the LMNA gene are unclear: partially due to the limited availability of three‐dimensional structure. The immunoglobulin (Ig)‐like fold domain has been solved, and using bioinformatics tools (including Polyphen‐2, Fold X, Parameter OPtimized Surfaces, and PocketPicker) we characterized 56 missense mutations for position, surface exposure, change in charge and effect on Ig‐like fold stability. We find that 21 of the 27 mutations associated with a skeletal muscle phenotype are distributed throughout the Ig‐like fold, are nonsurface exposed and predicted to disrupt overall stability of the Ig‐like fold domain. Intriguingly, the remaining 6 mutations clustered, had higher surface exposure, and did not affect stability. The majority of 9 lipodystrophy or 10 premature aging syndrome mutations also did not disrupt Ig‐like fold domain stability and were surface exposed and clustered in distinct regions that overlap predicted binding pockets. Although buried, the 10 cardiac mutations had no other consistent properties. Finally, most lipodystrophy and premature aging mutations resulted in a ‐1 net charge change, whereas skeletal muscle mutations caused no consistent net charge changes. Since premature aging, lipodystrophy and the subset of 6 skeletal muscle mutations cluster tightly in distinct, charged regions, they likely affect lamin A/C –protein/DNA/RNA interactions: providing a consistent genotype–phenotype relationship for mutations in this domain. Thus, this subgroup of skeletal muscle laminopathies that we term the ‘Skeletal muscle cluster’, may have a distinct pathological mechanism. These novel associations refine the ability to predict clinical features caused by certain LMNA missense mutations. Proteins 2014; 82:904–915. © 2013 Wiley Periodicals, Inc.     

Effect of precisely identified mutations in the spoIIAC gene of Bacillus subtilis on the toxicity of the sigma-like gene product to Escherichia coli

Summary Yudkin (1986) has shown that the spoIIAC gene of Bacillus subtilis cannot be cloned in Escherichia coli in such an orientation that it is expressed. This toxicity of the gene product has been attributed to its close homology with the sigma subunit of the E. coli RNA polymerase. The effect of six individual mutations in spoIIAC has now been studied. All six mutant genes could be cloned in E. coli in an orientation that does not allow expression. When in the orientation that permits expression, one mutant gene could not be cloned, and a second substantially hampered growth; both mutations lie in the region that is believed to encode the DNA-binding domain of the protein. By contrast, two missense mutations in the region of the gene thought to encode the domain that binds to the core RNA polymerase rendered the protein harmless in E. coli, as did two nonsense mutations.