Growth of Escherichia coli in iron-enriched medium increases HPI catalase activity

Escherichia coli has two catalases, HPI and HPII. HPI is induced during logarithmic growth in response to low concentrations of hydrogen peroxide. This induction is OxyR-dependent. On the other hand, HPII is not peroxide-inducible but is induced in entry to the stationary phase. We demonstrate here that E. coli displayed higher HPI catalase activity when compared to the cultures that were grown in a normal medium, if grown in a medium supplemented with iron-citrate. Iron supplementation had no effect on HPII catalase. This increase of HPI activity was OxyR-independent and not observed in a Deltafur mutant. The physiological significance of the increase of HPI activity is unclear, but it appears that the katG gene that codes for HPI catalase is among the genes that are regulated by Fur.     

pH-dependency of Escherichia coli catalase activity under modified culture conditions

In the previous work we have found two peaks of catalase activity at acid and neutral pH in partially destroyed bacteria E. coli K12 KS400. The present study indicates that catalase activity with two pH-optimums is sensitive to pH of cultivation medium. The relative catalase activity of frozen-thawed bacteria preparations measured at pH 3.5 increased two-fold and activity measured at pH 7.0 didn't change by shift of medium pH from value 5.5 to 7.0. In analogical preparations of bacteria grown in slightly alkaline media activity with acid maximum was not observed, but activity with neutral maximum rose to 130% in comparison with the intact cells was revealed. Two peaks of activity differed in their sensitivity to bacteria destruction, heating, inhibition by NaN3 and AMT, oxidative stress. The analysis of recent literature information and experimental data leads us to conclude that the activity with neutral pH-optimum consists of two known catalase forms HPI and HPII in E. coli. The ratio of HPI and HPII is 70 and 30%, respectively what was concluded from inhibition of catalase activity with neutral pH-optimum by AMT. Properties of catalase activity with acid pH-optimum didn't corresponding to any known enzyme forms. It is suggested the activity measured at pH 3.5 is results of some unstable activator which acts in acid pH range. It is possible that the described activity with acid pH-optimum is specific for the used E. coli strain. Investigation of another strain of E. coli K12 AB1157 confirmed this idea where the activity peak with acid pH-optimum was not detected.     

RpoS- and OxyR-independent induction of HPI catalase at stationary phase in Escherichia coli and identification of rpoS mutations in common laboratory strains.

A rapid spectrophotometric assay to determine the activities of HPI and HPII catalases in Escherichia coli extracts has been developed. This assay is based upon the differential heat stabilities of the two enzymes and offers significant advantages over previous methods for quantitation of their activities. Measurement of catalase activities in extracts of various mutant strains confirmed the ability of this method to accurately distinguish the two activities. Contrary to previously published results, HPI catalase activity was observed to increase at stationary phase in strains lacking the stationary-phase sigma factor sigma(s) (RpoS). This increase was independent of OxyR and also occurred in a strain lacking the HPII structural gene, katE. These results suggest a potential novel pathway for HPI induction in response to increased oxidative stress in the absence of HPII. Measurement of HPII activity in strains carrying mutations in pcm (encoding the L-isoaspartyl protein methyltransferase) and surE led to the finding that these strains also have an amber mutation in rpoS; sequencing demonstrated the presence of this mutation in several commonly used laboratory strains of E. coli, including AB1157, W1485, and JC7623.     

Catalases HPI and HPII in Escherichia coli are induced independently

Three strains of Escherichia coli differing only in the catalase locus mutated by transposon Tn10 were constructed. These strains produced only catalase HPI (katE::Tn10 and katF::Tn10 strains) or catalase HPII (katG::Tn10). HPI levels increased gradually about twofold during logarithmic growth but did not increase during growth into stationary phase in rich medium. HPII levels, which were initially threefold lower than HPI levels, did not change during logarithmic growth but did increase tenfold during growth into stationary phase. HPI levels increased in response to ascorbate or H2O2 being added to the medium but HPII levels did not. In minimal medium, any carbon source derived from the tricarboxylic acid cycle caused five- to tenfold higher HPII levels during logarithmic growth but had very little effect on HPI levels. Active electron transport did not affect either HPI or HPII levels.     

The active site structure of E. coli HPII catalase. Evidence favoring coordination of a tyrosinate proximal ligand to the chlorin iron.

E. coli produces 2 catalases known as HPI and HPII. While the heme prosthetic group of the HPII catalase has been established to be a dihydroporphyrin or chlorin, the identity of the proximal ligand to the iron has not been addressed. The magnetic circular dichroism (MCD) spectrum of native ferric HPII catalase is very similar to those of a 5-coordinate phenolate-ligated ferric chlorin complex, a model for tyrosinate proximal ligation, as well as of chlorin-reconstituted ferric horseradish peroxidase, a model for 5-coordinate histidine ligation. However, further MCD comparisons of chlorin-reconstituted myoglobin with parallel ligand-bound adducts of the catalase clearly rule out histidine ligation in the latter, leaving tyrosinate as the best candidate for the proximal ligand.     

Escherichia coli deltafur mutant displays low HPII catalase activity in stationary phase

Iron is among the most important micronutrients used by bacteria. As a partner of the Fenton reaction, however, iron potentiates oxygen toxicity. Strict regulation of iron metabolism, and its coupling with regulation of defenses against oxidative stress, is an essential factor for life in the presence of oxygen. In Escherichia coli, iron metabolism is regulated by the Fur protein. A Fur-deficient mutant, in stationary phase, displayed about 30y-fold lower HPII activity than the respective, Fur-proficient parental strain. Deletion of fur seems to affect HPII catalase specifically, since the mutant was capable of inducing HPI catalase when challenged with H(2)O(2). Low HPII catalase activity appears to be among the reasons for hydrogen peroxide hypersensitivity of the deltafur mutant.     

Purification and characterization of catalase HPII from Escherichia coli K12

Catalase (hydroperoxidase II or HPII) of Escherichia coli K12 has been purified using a protocol that also allows the purification of the second catalase HPI in large amounts. The purified HPII was found to have equal amounts of two subunits with molecular weights of 90,000 and 92,000. Only a single 92,000 subunit was present in the immunoprecipitate created when HPII antiserum was added directly to a crude extract, suggesting that proteolysis was responsible for the smaller subunit. The apparent native molecular weight was determined to be 532,000, suggesting a hexamer structure for the enzyme, an unusual structure for a catalase. HPII was very stable, remaining maximally active over the pH range 4-11 and retaining activity even in a solution of 0.1% sodium dodecyl sulfate and 7 M urea. The heme cofactor associated with HPII was also unusual for a catalase, in resembling heme d (a2) both spectrally and in terms of solubility. On the basis of heme-associated iron, six heme groups were associated with each molecule of enzyme or one per subunit.     

Genetic mapping of katF, a locus that with katE affects the synthesis of a second catalase species in Escherichia coli

A class of catalase-deficient mutants that was unlinked to katE was localized between mutS and cys at 59.0 min on the Escherichia coli genome. This locus was named katF. Transposon Tn10 insertions were isolated that mapped in both katE and katF loci. The catalase species present in katE+ and katF+ recombinants was found to be different from the main catalase activities, HPI and HPII, in several respects. It did not have an associated peroxidase activity; it was electrophoretically slower on native polyacrylamide gels; it eluted from DEAE-Sephadex A50 at a higher salt concentration; its Km for H2O2 was 30.9 mM as compared with 3.7 mM for HPI and HPII; its synthesis was not induced by ascorbate; and it did not cross react with HPI-HPII antisera. This new catalase was labeled HPIII.     

Increasing the oxidative stress response allows Escherichia coli to overcome inhibitory effects of condensed tannins

Tannins are plant-derived polyphenols with antimicrobial effects. The mechanism of tannin toxicity towards Escherichia coli was determined by using an extract from Acacia mearnsii (Black wattle) as a source of condensed tannins (proanthocyanidins). E. coli growth was inhibited by tannins only when tannins were exposed to oxygen. Tannins auto-oxidize, and substantial hydrogen peroxide was generated when they were added to aerobic media. The addition of exogenous catalase permitted growth in tannin medium. E. coli mutants that lacked HPI, the major catalase, were especially sensitive to tannins, while oxyR mutants that constitutively overexpress antioxidant enzymes were resistant. A tannin-resistant mutant was isolated in which a promoter-region point mutation increased the level of HPI by 10-fold. Our results indicate that wattle condensed tannins are toxic to E. coli in aerobic medium primarily because they generate H(2)O(2). The oxidative stress response helps E. coli strains to overcome their inhibitory effect.     

Homology among bacterial catalase genes

Catalase activities in crude extracts of exponential and stationary phase cultures of various bacteria were visualized following gel electrophoresis for comparison with the enzymes from Escherichia coli. Citrobacter freundii, Edwardsiella tarda, Enterobacter aerogenes, Klebsiella pneumoniae, and Salmonella typhimurium exhibited patterns of catalase activity similar to E. coli, including bifunctional HPI-like bands and a monofunctional HPII-like band. Proteus mirabilis, Erwinia carotovora, and Serratia marcescens contained a single band of monofunctional catalase with a mobility intermediate between the HPI-like and HPII-like bands. The cloned genes for catalases HPI (katG) and HPII (katE) from E. coli were used as probes in Southern hybridization analyses for homologous sequences in genomic DNA of the same bacteria. katG was found to hybridize with fragments from C. freudii, Ent. aerogenes, Sal. typhimurium, and K. pneumoniae but not at all with Ed. tarda, P. mirabilis, S. marcesens, or Er. carotovora. katE hybridized with C. freundii and K. pneumoniae DNAs and not with the other bacterial DNAs.     

The catalase-peroxidase of Mycobacterium intracellulare: nucleotide sequence analysis and expression in Escherichia coli.

The activation of catalase genes in response to oxidative stress may contribute to the intracellular survival of mycobacteria. In this report, the nucleotide sequence of a mycobacterial catalase gene is described. The deduced protein sequence of this Mycobacterium intracellulare gene (MI85) was 60% identical to the Escherichia coli hydroperoxidase I (HPI) protein, 59% identical to the Salmonella typhimurium (HPI) catalase, and 47% identical to a Bacillus stearothermophilus peroxidase. The MI85 protein, expressed in E. coli, has also been shown to have peroxidase and catalase activities. Furthermore, Southern blot hybridizations, which demonstrated that a MI85 gene probe hybridizes with chromosomal DNA from thirteen different strains of mycobacteria, suggest that this catalase-peroxidase gene is prevalent in the mycobacterial genus. The availability of catalase gene probes should permit an evaluation, at the molecular level, of the role of catalase in mycobacterial pathogenesis.     

Catalase HPII from Escherichia coli exhibits enhanced resistance to denaturation

Catalase HPII from Escherichia coli is a homotetramer of 753 residue subunits. The multimer displays a number of unusual structural features, including interwoven subunits and a covalent bond between Tyr415 and His392, that would contribute to its rigidity and stability. As the temperature of a solution of HPII in 50 mM potassium phosphate buffer (pH 7) is raised from 50 to 92 degrees C, the enzyme begins to lose activity at 78 degrees C and 50% inactivation has occurred at 83 degrees C. The inactivation is accompanied by absorbance changes at 280 and 407 nm and by changes in the CD spectrum consistent with small changes in secondary structure. The subunits in the dimer structure remain associated at 95 degrees C and show a significant level of dissociation only at 100 degrees C. The exceptional stability of the dimer association is consistent with the interwoven nature of the subunits and provides an explanation for the resistance to inactivation of the enzyme. For comparison, catalase-peroxidase HPI of E. coli and bovine liver catalase are 50% inactivated at 53 and 56 degrees C, respectively. In 5.6 M urea, HPII exhibits a coincidence of inactivation, CD spectral change, and dissociation of the dimer structure with a midpoint of 65 degrees C. The inactive mutant variants of HPII which fold poorly during synthesis and which lack the Tyr-His covalent bond undergo spectral changes in the 78 to 84 degrees C range, revealing that the extra covalent linkage is not important in the enhanced resistance to denaturation and that problems in the folding pathway do not affect the ultimate stability of the folded structure.     

Role of the antioxidant system in response of Escherichia coli bacteria to cold stress

The response of aerobically grown Escherichia coli cells to the cold shock induced by the rapid lowering of growth temperature from 37 to 20 degrees C was found to be basically the same as the oxidative stress response. The enhanced sensitivity of cells deficient in two superoxide dismutases, Mn-SOD and Fe-SOD, and the increased expression of the Mn-SOD gene, sodA, in response to cold stress were interpreted as both oxidative and cold stresses are due to a rise in the intracellular level of superoxide anion. The long-term cultivation of E. coli at 20 degrees C was also accompanied by the typical oxidative stress response reactions--an enhanced expression of the Mn-SOD and catalase HPI genes and a decrease in the intracellular level of reduced glutathione (GSH) and in the GSH/GSSG ratio.     

Lex marks the spot: the virulent side of SOS and a closer look at the LexA regulon

The SOS response that responds to DNA damage induces many genes that are under LexA repression. A detailed examination of LexA regulons using genome-wide techniques has recently been undertaken in both Escherichia coli and Bacillus subtilis. These extensive and elegant studies have now charted the extent of the LexA regulons, uncovered many new genes, and exposed a limited overlap in the LexA regulon between the two bacteria. As more bacterial genomes are analysed, more curiosities in LexA regulons arise. Several notable examples include the discovery of a LexA-like protein, HdiR, in Lactococcus lactis, organisms with two lexA genes, and small DNA damage-inducible cassettes under LexA control. In the cyanobacterium Synechocystis, genetic and microarray studies demonstrated that a LexA paralogue exerts control over an entirely different set of carbon-controlled genes and is crucial to cells facing carbon starvation. An examination of SOS induction evoked by common therapeutic drugs has shed new light on unsuspected consequences of drug exposure. Certain antibiotics, most notably fluoroquinolones such as ciprofloxacin, can induce an SOS response and can modulate the spread of virulence factors and drug resistance. SOS induction by beta-lactams in E. coli triggers a novel form of antibiotic defence that involves cell wall stress and signal transduction by the DpiAB two-component system. In this review, we provide an overview of these new directions in SOS and LexA research with emphasis on a few themes: identification of genes under LexA control, the identification of new endogenous triggers, and antibiotic-induced SOS response and its consequences.     

Regulation ofEscherichia coli catalases by anaerobiosis and catabolite repression

Escherichia coli has two forms of catalases, HPI and HPII. Both enzymes, but mainly HPII, are induced in cells reaching the stationary growth phase or under anaerobic conditions and are repressed in the presence of glucose. The induction at the stationary phase is dependent onfnr, a gene that regulates the expression of anaerobically induced proteins. The inhibition by glucose is not affected by cyclic AMP (cAMP) but is reduced in acrp mutant. The results show that HPII belongs to the group of genes controlled by the Fnr protein and is catabolically repressed in a manner that is independent of cAMP.     

The C-terminal domain of HPII catalase is a member of the type I glutamine amidotransferase superfamily

Discovering distant evolutionary relationships between proteins requires detecting subtle similarities. Here we use a combination of sequence and structure analysis to show that the C-terminal domain of Escherichia coli HPII catalase with available spatial structure is a divergent member of the type I glutamine amidotransferase (GAT) superfamily. GAT-containing proteins include many biosynthetic enzymes such as E. coli carbamoyl phosphate synthetase and anthranilate synthase. Typical GAT domains have Rossmann fold-like topology and possess a catalytic triad similar to that of proteases. The C-terminal domain of HPII catalase has the GAT Rossmann fold but lacks the triad and therefore loses enzymatic activity. In addition, we detect significant sequence similarity between thiJ domains, some of which are known to have protease activity, and typical GAT proteins. Evolutionary tree analysis of the entire GAT superfamily indicates that the HPII catalase is more closely related to thiJ domains than to classical GAT domains and is likely to have evolved from a thiJ-like protein. This work illustrates the strength of sequence-based profile analysis techniques coupled with structural superpositions in developing an evolutionarily relevant classification of protein structures. Proteins 2001;42:230-236.     

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.