Structure-Function Analysis of the Bifunctional CcsBA Heme Exporter and Cytochrome c Synthetase.

Although intracellular heme trafficking must occur for heme protein assembly, only a few heme transporters have been unequivocally discovered and nothing is known about their structure or mechanisms. Cytochrome c biogenesis in prokaryotes requires the transport of heme from inside to outside for stereospecific attachment to cytochrome c via two thioether bonds (at CXXCH). The CcsBA integral membrane protein was shown to transport and attach heme (and thus is a cytochrome c synthetase), but the structure and mechanisms underlying these two activities are poorly understood. We employed a new cysteine/heme crosslinking tool that traps endogenous heme in heme binding sites. We combined these data with a comprehensive imidazole correction approach (for heme ligand interrogation) to map heme binding sites. Results illuminate the process of heme transfer through the membrane to an external binding site (called the WWD domain). Using meta-genomic data (GREMLIN) and Rosetta modeling programs, a structural model of the transmembrane (TM) regions in CcsBA were determined. The heme mapping data were then incorporated to model the TM heme binding site (with TM-His1 and TM-His2 as ligands) and the external heme binding WWD domain (with P-His1 and P-His2 as ligands). Other periplasmic structure/function studies facilitated modeling of the full CcsBA protein as a framework for understanding the mechanisms. Mechanisms are proposed for heme transport from TM-His to WWD/P-His and subsequent stereospecific attachment of heme. A ligand exchange of the P-His1 for histidine of CXXCH at the synthetase active site is suggested.IMPORTANCE The movement or trafficking of heme is critical for cellular functions (e.g., oxygen transport and energy production); however, intracellular heme is tightly regulated due to its inherent cytotoxicity. These factors, combined with the transient nature of transport, have resulted in a lack of direct knowledge on the mechanisms of heme binding and trafficking. Here, we used the cytochrome c biogenesis system II pathway as a model to study heme trafficking. System II is composed of two integral membrane proteins (CcsBA) which function to transport heme across the membrane and stereospecifically position it for covalent attachment to apocytochrome c We mapped two heme binding domains in CcsBA and suggest a path for heme trafficking. These data, in combination with metagenomic coevolution data, are used to determine a structural model of CcsBA, leading to increased understanding of the mechanisms for heme transport and the cytochrome c synthetase function of CcsBA.

Helicobacter hepaticus cholesterol-α-glucosyltransferase is essential for establishing colonization in male A/JCr mice.

BACKGROUND: Helicobacter pylori cholesterol-α-glucosyltransferase (cgt) is essential for survival of H. pylori in mice. Enterohepatic H. hepaticus, the cause of colonic and hepatocellular carcinoma in susceptible mouse strains, contains an ortholog of the H. pylori cgt. However, the role of cgt in the pathogenesis of H. hepaticus has not been investigated. MATERIALS AND METHODS: Two cgt-deficient isogenic mutants of wild-type H. hepaticus (WT) 3B1 were generated and used to inoculate male A/JCr mice. Cecal and hepatic colonization levels of the mutants and WT 3B1 as well as select inflammation-associated cytokines were measured by qPCR at 4 months postinoculation. RESULTS: Both mutants were undetectable in the cecum of any inoculated mice (10 per mutant) but were detected in two livers (one for each mutant); by contrast, 9 and 7 of 10 mice inoculated with WT 3B1 were qPCR positive in the ceca and livers, respectively. The mice inoculated with the mutants developed significantly less severe hepatic inflammation (p < .05) and also produced significantly lower hepatic mRNA levels of proinflammatory cytokines Ifn-γ (p < .01) and Tnf-α (p ≤ .02) as well as anti-inflammatory factors Il10 and Foxp3 compared with the WT 3B1-inoculated mice. Additionally, the WT 3B1-inoculated mice developed significantly higher Th1-associated IgG2a (p < .0001) and Th2-associated IgG1 responses (p < .0001) to H. hepaticus infection than mice dosed with isogenic cgt mutants. CONCLUSION: Our data indicate that the cholesterol-α-glucosyltransferase is required for establishing colonization of the intestine and liver and therefore plays a critical role in the pathogenesis of H. hepaticus.

Inhibitory effect of Lactobacillus acidophilus on Helicobacter hepaticus in vitro.

Helicobacter hepaticus and Helicobacter pylori both belong to Helicobacter species. Strains of Lactobacillus acidophilus, including L4 and L6, have shown significant inhibitory effects on H. pylori. Based on this phenomenon, we aim to investigate the inhibitory effect of L. acidophilus on H. hepaticus. Both standard and isolated H. hepaticus strains were grown under microaerophilic conditions at 37 °C in the presence of L. acidophilus supernatant, or lactic acid. The diameters of the inhibition zones were measured on the solid culture media. In liquid culture, the cell concentrations were measured and the urease activity was determined by phenol red staining. Sixteen strains of L. acidophilus isolated from human feces (named as L1-L16) showed anti-H. hepaticus effects. Two of them (L4 and L6) exhibited the most apparent effects on H. hepaticus inhibition. The L. acidophilus supernatant of L4 and L6 significantly increased the diameters of the inhibition zones compared with that of the lactic acid control (P < 0.05). The inhibitory role of L. acidophilus supernatant was independent of the pH value of solution (P > 0.05). Moreover, in liquid culture, L. acidophilus supernatant significantly reduced the cell growth rate and the urease activity of H. hepaticus cells in a time-dependent pattern (P < 0.05 compared with lactic acid control). No obvious difference was observed between the standard and isolated strain of H. hepaticus (P > 0.05). Our results indicate that L. acidophilus can decrease the viability and urease activity of H. hepaticus in vitro and this inhibition is independent of pH levels. This provides evidence for developing novel approaches for the prevention and treatment of H. hepaticus infection.

Helicobacter hepaticus NikR controls urease and hydrogenase activities via the NikABDE and HH0418 putative nickel import proteins.

Helicobacter hepaticus open reading frame HH0352 was identified as a nickel-responsive regulator NikR. The gene was disrupted by insertion of an erythromycin resistance cassette. The H. hepaticus nikR mutant had five- to sixfold higher urease activity and at least twofold greater hydrogenase activity than the wild-type strain. However, the urease apo-protein levels were similar in both the wild-type and the mutant, suggesting the increase in urease activity in the mutant was due to enhanced Ni-maturation of the urease. Compared with the wild-type strain, the nikR strain had increased cytoplasmic nickel levels. Transcription of nikABDE (putative inner membrane Ni transport system) and hh0418 (putative outer membrane Ni transporter) was nickel- and NikR-repressed. Electrophoretic mobility shift assays (EMSAs) revealed that purified HhNikR could bind to the nikABDE promoter (P(nikA)), but not to the urease or the hydrogenase promoter; NikR-P(nikA) binding was enhanced in the presence of nickel. Also, qRT-PCR and EMSAs indicated that neither nikR nor the exbB-exbD-tonB were under the control of the NikR regulator, in contrast with their Helicobacter pylori homologues. Taken together, our results suggest that HhNikR modulates urease and hydrogenase activities by repressing the nickel transport/nickel internalization systems in H. hepaticus, without direct regulation of the Ni-enzyme genes (the latter is the case for H. pylori). Finally, the nikR strain had a two- to threefold lower growth yield than the parent, suggesting that the regulatory protein might play additional roles in the mouse liver pathogen.

Analysis of epitope regions for autoantibodies in catalase.

Catalase is reported to be one of the target antigens for autoantibodies in various pathologies. To understand the mechanism of autoantibody production, we compared the several properties of autoantigenic epitopes (AE)-1 and -2 of mouse catalase, which reported to react with antibodies from sera of Helicobacter hepaticus-infected mice; AE-3 and -4 of rat catalase, which we found to be susceptible to autoimmunity; and antigenic epitope (E)-1 of H. pylori catalase, which is recognized by monoclonal antibodies produced by immunized mice. Amino acid sequences of AE-1 and -2 were similar among both mammalian and pathogenic microorganism catalases, whereas that of E-1 differed. Amino acid sequences of AE-3 and -4 were similar among mammalian catalases but differed from pathogenic microorganism catalases. Based on local relative rates of evolution, these vertebrate catalases were divided into 5 segments. E-1 included a faster evolving region, whereas AE-1 and -2 included a slowly evolving region; AE-3 and -4 comprised a slowly evolving patch within a faster evolving region. In conclusion, although AE-1 and -2 of catalase have been reported to contribute to autoimmune responses in animals infected with catalase-producing pathogens, AE-3 and -4 appear to have a different mechanism for autoantibody production.

Helicobacter hepaticus urease is not required for intestinal colonization but promotes hepatic inflammation in male A/JCr mice.

Urease activity contributes to bacterial survival in the acidic environment of the stomach and is essential for persistent infection by known gastric helicobacters such as the human pathogen Helicobacter pylori. Several enterohepatic Helicobacter species (EHS) that primarily infect the less acidic intestine also have very active urease enzymes. The importance of urease and its contribution to pathogenesis for these EHS are poorly understood. In this study, we generated a urease-deficient, isogenic mutant (HhureNT9) of Helicobacter hepaticus 3B1 (Hh 3B1), an EHS that possesses a urease gene cluster similar to that of H. pylori. Lack of urease activity did not affect the level of cecal colonization by HhureNT9 compared to Hh 3B1 in male A/JCr mice (P=0.48) at 4 months post-inoculation (MPI). In contrast, there was no HhureNT9 detected in the livers of any infected mice, whereas all livers from the Hh 3B1-infected mice were PCR-positive for Hh 3B1. The mice infected with HhureNT9 developed significantly less severe hepatitis (P=0.017) and also produced significantly lower hepatic mRNA levels of proinflammatory cytokines IFN-gamma (P=0.0007) and TNF-alpha (P<0.0001) compared to the Hh 3B1-infected mice. The Hh 3B1-infected mice developed significantly higher total IgG, Th1-associated IgG2a and Th2-associated IgG1 responses to infection. These results indicate that H. hepaticus urease activity plays a crucial role in hepatic disease but is not required for cecal colonization by H. hepaticus.

Characterization of a Helicobacter hepaticus putA mutant strain in host colonization and oxidative stress.

Helicobacter hepaticus is a gram-negative, spiral-shaped microaerophilic bacterium associated with chronic intestinal infection leading to hepatitis and colonic and hepatic carcinomas in susceptible strains of mice. In the closely related human pathogen Helicobacter pylori, L-proline is a preferred respiratory substrate and is found at significantly high levels in the gastric juice of infected patients. A previous study of the proline catabolic PutA flavoenzymes from H. pylori and H. hepaticus revealed that Helicobacter PutA generates reactive oxygen species during proline oxidation by transferring electrons from reduced flavin to molecular oxygen. We further explored the preference for proline as a respiratory substrate and the potential impact of proline metabolism on the redox environment in Helicobacter species during host infection by disrupting the putA gene in H. hepaticus. The resulting putA knockout mutant strain was characterized by oxidative stress analysis and mouse infection studies. The putA mutant strain of H. hepaticus exhibited increased proline levels and resistance to oxidative stress relative to that of the wild-type strain, consistent with proline's role as an antioxidant. The significant increase in stress resistance was attributed to higher proline content, as no upregulation of antioxidant genes was observed for the putA mutant strain. The wild-type and putA mutant H. hepaticus strains displayed similar levels of infection in mice, but in mice challenged with the putA mutant strain, significantly reduced inflammation was observed, suggesting a role for proline metabolism in H. hepaticus pathogenicity in vivo.

The NADPH quinone reductase MdaB confers oxidative stress resistance to Helicobacter hepaticus.

An mdaB mutant strain in a quinone reductase (MdaB) of Helicobacter hepaticus type strain ATCC51449 was constructed by insertional mutagenesis, and the MdaB protein was purified and compared to the Helicobacter pylori enzyme. While wild type H. hepaticus cells could tolerate 6% O(2) for growth, the mdaB strain was clearly inhibited at this oxygen level. Disruption of the gene downstream of mdaB (HH1473) did not affect the oxidative stress phenotype of the strain. The mdaB mutant was also more sensitive to oxidative stress reagents such as H(2)O(2), cumene hydroperoxide, t-butyl hydroperoxide, and paraquat. All H. hepaticus mdaB strains isolated constitutively up-expressed another oxidative stress-combating enzyme, superoxide dismutase; this is in contrast to H. pylori mdaB strains. H. hepaticus MdaB is a flavoprotein catalyzing quinone reduction using a two-electron transfer mechanism from NAD(P)H to quinone. The H. hepaticus enzyme specific activity was far less than for the H. pylori enzyme purified in the same manner.

Nickel enzyme maturation in Helicobacter hepaticus: roles of accessory proteins in hydrogenase and urease activities.

Helicobacter hepaticus, a causative agent of chronic hepatitis and hepatocellular carcinoma in mice, possesses a hydrogenase and a urease, both of which are nickel-containing enzymes. Analysis of the genome sequence of H. hepaticus revealed a full set of accessory genes which are required for the nickel maturation of each enzyme in other micro-organisms. Erythromycin-resistant mutants were constructed in four of these genes, hypA, hypB, ureE and ureG. Controls for polar effect were provided for hypA or hypB mutants by disrupting each gene located immediately downstream, i.e. hp0809 or hypC, respectively. Urease and hydrogenase activities were determined for each strain with or without supplemented nickel in the medium. As expected, the ureE and the ureG mutants had negligible urease activity, but they retained normal levels of hydrogenase activity. Urease levels could not be increased by the addition of nickel to the medium. The H. hepaticus hypA and hypB strains were deficient in both urease and hydrogenase activities, suggesting that both gene products act in a similar fashion as their counterparts in H. pylori. However, in contrast with the analogous mutants of H. pylori, the addition of nickel into the growth medium failed to restore either urease or hydrogenase enzyme levels in the H. hepaticus hypA or hypB mutants, indicating a probably unique role for these genes in the mouse liver pathogen.

A Helicobacter hepaticus catalase mutant is hypersensitive to oxidative stress and suffers increased DNA damage.

Catalase (KatA) is known to play an important role in oxidative stress resistance in many bacterial species and a homologue exists in Helicobacter hepaticus, a member of the enterohepatic Helicobacter species. Here, a katA mutant was constructed by insertional mutagenesis and its oxidative stress phenotype was investigated. Catalase activity was readily detected [196 units (mg protein crude cell extract)(-1)] in the wild-type, whereas the mutant strain was deficient in, but not devoid of, activity. In contrast, Helicobacter pylori katA strains lack detectable catalase activity and wild-type H. pylori generally contains higher specific activity than H. hepaticus. Wild-type H. hepaticus cells tolerated 6 % O2 for growth, whilst the katA mutant could not survive at this oxygen level. Even at the optimal O2 level, the growth of the H. hepaticus katA strain was severely inhibited, which is also in contrast to H. pylori katA strains. Wild-type H. hepaticus cells withstood exposure to 100 mM H(2)O(2) but the katA mutant cells were killed by the same treatment. Wild-type cells suffered no significant DNA damage by H(2)O(2) treatment (100 mM for 6 min), whilst the same treatment resulted in severe DNA fragmentation in the katA mutant. Thus H. hepaticus KatA plays an important role as an antioxidant protein.

Helicobacter hepaticus catalase shares surface-predicted epitopes with mammalian catalases.

Helicobacter hepaticus colonizes the murine intestine and has been associated with hepatic inflammation and neoplasia in susceptible mouse strains. In this study, the catalase of an enterohepatic Helicobacter was characterized for the first time. H. hepaticus catalase is a highly conserved enzyme that may be important for bacterial survival in the mammalian intestine. Recombinant H. hepaticus catalase was expressed in Escherichia coli in order to verify its enzymic activity in vitro. H. hepaticus catalase comprises 478 amino acids with a highly conserved haem-ligand domain. Three conserved motifs (R-F-Y-D, RERIPER and VVHAKG) in the haem-ligand domain and three surface-predicted motifs were identified in H. hepaticus catalase and are shared among bacterial and mammalian catalases. H. hepaticus catalase is present in the cytoplasmic and periplasmic compartments. Mice infected with H. hepaticus demonstrated immune responses to murine and H. hepaticus catalase, suggesting that Helicobacter catalase contains conserved structural motifs and may contribute to autoimmune responses. Antibodies to H. hepaticus catalase recognized murine hepatocyte catalase in hepatic tissue from infected mice. Antibodies from sera of H. hepaticus-infected mice reacted with peptides comprising two conserved surface-predicted motifs in H. hepaticus catalase. Catalases are highly conserved enzymes in bacteria and mammals that may contribute to autoimmune responses in animals infected with catalase-producing pathogens.

Iron-responsive repression of urease expression in Helicobacter hepaticus is mediated by the transcriptional regulator Fur.

Persistent colonization of mucosal surfaces by bacteria in the mammalian host requires concerted expression of colonization factors, depending on the environmental conditions. Helicobacter hepaticus is a urease-positive pathogen that colonizes the intestinal and hepatobiliary tracts of rodents. Here it is reported that urease expression of H. hepaticus is iron repressed by the transcriptional regulator Fur. Iron restriction of growth medium resulted in a doubling of urease activity in wild-type H. hepaticus strain ATCC 51449 and was accompanied by increased levels of urease subunit proteins and ureA mRNA. Insertional inactivation of the fur gene abolished iron-responsive repression of urease activity, whereas inactivation of the perR gene did not affect iron-responsive regulation of urease activity. The iron-responsive promoter element was identified directly upstream of the H. hepaticus ureA gene. Recombinant H. hepaticus Fur protein bound to this ureA promoter region in a metal-dependent matter, and binding resulted in the protection of a 41-bp, Fur box-containing operator sequence located at positions -35 to -75 upstream of the transcription start site. In conclusion, H. hepaticus Fur controls urease expression at the transcriptional level in response to iron availability. This represents a novel type of urease regulation in ureolytic bacteria and extends the already diverse regulatory repertoire of the Fur protein.

In vitro and in vivo characterization of alkyl hydroperoxide reductase mutant strains of Helicobacter hepaticus.

Mutant strains in the tsaA gene encoding alkyl hydroperoxide reductase were more sensitive to O(2) and to oxidizing agents (paraquat, cumene hydroperoxide and t-butylhydroperoxide) than the wild type, but were markedly more resistant to hydrogen peroxide. The mutant strains resistance phenotype could be attributed to a 4-fold and 3-fold increase in the catalase protein amount and activity, respectively compared to the parent strain. The wild type did not show an increase in catalase expression in response to sequential increases in O(2) exposure or to oxidative stress reagents, so an adaptive compensatory mutation has probably occurred in the mutants. In support of this, chromosomal complementation of tsaA mutants restored alkyl hydroperoxide reductase, but catalase was still up-expressed in all complemented strains. The katA promoter sequence was the same in all mutant strains and the wild type. Like its Helicobacter pylori counterpart strain, a H. hepaticus tsaA mutant contained more lipid hydroperoxides than the wild type strain. Hepatic tissue from mice inoculated with a tsaA mutant had lesions similar to those inoculated with the wild type, and included coagulative necrosis of hepatocytes. The liver and cecum colonizing abilities of the wild type and tsaA mutant were comparable. Up-expression of catalase in the tsaA mutants likely permits the bacterium to compensate (in colonization and virulence attributes) for the loss of an otherwise important oxidative stress-combating enzyme, alkyl hydroperoxide reductase. The use of erythromycin resistance insertion as a facile way to screen for gene-targeted mutants, and the chromosomal complementation of those mutants are new genetic procedures for studying H. hepaticus.

Differential regulation of urease activity in Helicobacter hepaticus and Helicobacter pylori.

Helicobacter hepaticus is a pathogen of rodents, which causes diverse enteric and hepatic inflammatory diseases and malignancies. The urease enzyme is an important colonization factor of gastric Helicobacter species like Helicobacter pylori, but little is known about the role and regulation of urease in enterohepatic Helicobacter species. Here it is reported that urease activity of H. hepaticus does not contribute to acid resistance, and that it is nickel-responsive at the post-translational level. H. hepaticus strain ATCC 51449 did not grow or survive at pH 3.0, and supplementation with urea or NiCl2 did not abrogate this acid sensitivity. Furthermore, urease enzyme activity of H. hepaticus was acid-independent, which contrasts with the acid-induced urease system of H. pylori. Nickel supplementation of Brucella medium resulted in a tenfold increase in urease activity in both H. hepaticus and H. pylori, but the maximum level of urease activity in H. hepaticus was still three- to fivefold lower when compared to H. pylori in the same conditions. The increase in urease activity of H. hepaticus was not associated with elevation of urease mRNA or protein levels. Inhibition of protein synthesis by chloramphenicol did not affect nickel-responsive induction of urease activity in H. hepaticus, and confirmed that nickel induction occurs at the post-translational level, probably by activation of preformed apo-enzyme. In conclusion, both the role of the urease enzyme and the regulation of urease activity differ between the enterohepatic pathogen H. hepaticus and the gastric pathogen H. pylori.

The cytolethal distending toxin B sub-unit of Helicobacter hepaticus is a Ca2+- and Mg2+-dependent neutral nuclease.

The cytolethal distending toxin B (CdtB) of the mouse pathogen Helicobacter hepaticus has cation binding and DNA catalysis residues in common with members of the mammalian deoxyribonuclease I (DNase I) family. The purpose of the present study was to characterize CdtB nuclease. To establish optimal digestion conditions and to evaluate co-factor requirements, a novel and sensitive fluorometric assay that quantitatively determines double stranded DNA digestion was developed. Although the Ca2+- and Mg2+-dependence and neutral properties of CdtB were similar to DNase I, hydrolysis of DNA by CdtB was approximately 100-fold less active than DNase I and was considerably more resistant to inhibition by ZnCl2 and G-actin.

Helicobacter hepaticus hydrogenase mutants are deficient in hydrogen-supported amino acid uptake and in causing liver lesions in A/J mice.

Helicobacter hepaticus, a causative agent of chronic hepatitis and hepatocellular carcinoma in mice, expresses a nickel-containing hydrogen-oxidizing hydrogenase enzyme. Growth of a hyaB gene-targeted mutant was unaffected by the presence of hydrogen, unlike the wild-type strain, which showed an enhanced growth rate when supplied with H(2). Hydrogenase activities in H. hepaticus were constitutive and not dependent on the inclusion of H(2) during growth. Addition of nickel during growth significantly stimulated both urease (for wild-type and hyaB) and hydrogenase (for wild-type) activities. In a 5-h period, the extent of (14)C-labeled amino acid uptake by the wild type was markedly enhanced in the presence of hydrogen and was >5-fold greater than that of the hyaB mutant strain. In the presence of H(2), the short-term whole-cell amino acid uptake V(max) of the parent strain was about 2.2-fold greater than for the mutant, but the half-saturation affinity for amino acid transport was the same for the parent and mutant strain. The liver- and cecum-colonizing abilities of the strains was estimated by real-time PCR quantitation of the H. hepaticus-specific cytolethal distending toxin gene and showed similar animal colonization for the hyaB mutant and the wild type. However, at 21 weeks postinoculation, the livers from mice inoculated with wild type exhibited moderate lobular lymphoplasmacytic hepatitis with hepatocytic coagulative necrosis, but the hydrogenase mutants exhibited no histological evidence of lobular inflammation or necrosis.