Use of molecular hydrogen as an energy substrate by human pathogenic bacteria.

Molecular hydrogen is produced as a fermentation by-product in the large intestine of animals and its production can be correlated with the digestibility of the carbohydrates consumed. Pathogenic Helicobacter species (Helicobacter pylori and H. hepaticus) have the ability to use H(2) through a respiratory hydrogenase, and it was demonstrated that the gas is present in the tissues colonized by these pathogens (the stomach and the liver respectively of live animals). Mutant strains of H. pylori unable to use H(2) are deficient in colonizing mice compared with the parent strain. On the basis of available annotated gene sequence information, the enteric pathogen Salmonella, like other enteric bacteria, contains three putative membrane-associated H(2)-using hydrogenase enzymes. From the analysis of gene-targeted mutants it is concluded that each of the three membrane-bound hydrogenases of Salmonella enterica serovar Typhimurium are coupled with an H(2)-oxidizing respiratory pathway. From microelectrode probe measurements on live mice, H(2) could be detected at approx. 50 muM levels within the tissues (liver and spleen), which are colonized by Salmonella. The half-saturation affinity of whole cells of these pathogens for H(2) is much less than this, so it is expected that the (H(2)-utilizing) hydrogenase enzymes be saturated with the reducing substrate in vivo. All three enteric NiFe hydrogenase enzymes contribute to virulence of the bacterium in a typhoid fever-mouse model, and the combined removal of all three hydrogenases resulted in a strain that is avirulent and (in contrast with the parent strain) one that is not able to pass the intestinal tract to invade liver or spleen tissue. It is proposed that H(2) utilization and specifically its oxidation, coupled with a respiratory pathway, is required for energy production to permit growth and maintain efficient virulence of a number of pathogenic bacteria during infection of animals. These would be expected to include the Campylobacter jejuni, a bacterium closely related to Helicobacter, as well as many enteric bacteria (Escherichia coli, Shigella and Yersinia species).

Respiratory hydrogen use by Salmonella enterica serovar Typhimurium is essential for virulence.

Based on available annotated gene sequence information, the enteric pathogen salmonella, like other enteric bacteria, contains three putative membrane-associated H2-using hydrogenase enzymes. These enzymes split molecular H2, releasing low-potential electrons that are used to reduce quinone or heme-containing components of the respiratory chain. Here we show that each of the three distinct membrane-associated hydrogenases of Salmonella enterica serovar Typhimurium is coupled to a respiratory pathway that uses oxygen as the terminal electron acceptor. Cells grown in a blood-based medium expressed four times the amount of hydrogenase (H2 oxidation) activity that cells grown on Luria Bertani medium did. Cells suspended in phosphate-buffered saline consumed 2 mol of H2 per mol of O2 used in the H2-O2 respiratory pathway, and the activity was inhibited by the respiration inhibitor cyanide. Molecular hydrogen levels averaging over 40 microM were measured in organs (i.e., livers and spleens) of live mice, and levels within the intestinal tract (the presumed origin of the gas) were four times greater than this. The half-saturation affinity of S. enterica serovar Typhimurium for H2 is only 2.1 microM, so it is expected that H2-utilizing hydrogenase enzymes are saturated with the reducing substrate in vivo. All three hydrogenase enzymes contribute to the virulence of the bacterium in a typhoid fever-mouse model, based on results from strains with mutations in each of the three hydrogenase genes. The introduced mutations are nonpolar, and growth of the mutant strains was like that of the parent strain. The combined removal of all three hydrogenases resulted in a strain that is avirulent and (in contrast to the parent strain) one that is unable to invade liver or spleen tissue. The introduction of one of the hydrogenase genes into the triple mutant strain on a low-copy-number plasmid resulted in a strain that was able to both oxidize H2 and cause morbidity in mice within 11 days of inoculation; therefore, the avirulent phenotype of the triple mutant is not due to an unknown spurious mutation. We conclude that H2 utilization in a respiratory fashion is required for energy production to permit salmonella growth and subsequent virulence during infection.

Superoxide dismutase-deficient mutants of Helicobacter pylori are hypersensitive to oxidative stress and defective in host colonization.

Superoxide dismutase (SOD) is a nearly ubiquitous enzyme among organisms that are exposed to oxic environments. The single SOD of Helicobacter pylori, encoded by the sodB gene, has been suspected to be a virulence factor for this pathogenic microaerophile, but mutations in this gene have not been reported previously. We have isolated mutants with interruptions in the sodB gene and have characterized them with respect to their response to oxidative stress and ability to colonize the mouse stomach. The sodB mutants are devoid of SOD activity, based on activity staining in nondenaturing gels and quantitative assays of cell extracts. Though wild-type H. pylori is microaerophilic, the mutants are even more sensitive to O(2) for both growth and viability. While the wild-type strain is routinely grown at 12% O(2), growth of the mutant strains is severely inhibited at above 5 to 6% O(2). The effect of O(2) on viability was determined by subjecting nongrowing cells to atmospheric levels of O(2) and plating for survivors at 2-h time intervals. Wild-type cell viability dropped by about 1 order of magnitude after 6 h, while viability of the sodB mutant decreased by more than 6 orders of magnitude at the same time point. The mutants are also more sensitive to H(2)O(2), and this sensitivity is exacerbated by increased O(2) concentrations. Since oxidative stress has been correlated with DNA damage, the frequency of spontaneous mutation to rifampin resistance was studied. The frequency of mutagenesis of an sodB mutant strain is about 15-fold greater than that of the wild-type strain. In the mouse colonization model, only 1 out of 23 mice inoculated with an SOD-deficient mutant of a mouse-adapted strain became H. pylori positive, while 15 out of 17 mice inoculated with the wild-type strain were shown to harbor the organism. Therefore, SOD is a virulence factor which affects the ability of this organism to colonize the mouse stomach and is important for the growth and survival of H. pylori under conditions of oxidative stress.

Requirement of nickel metabolism proteins HypA and HypB for full activity of both hydrogenase and urease in Helicobacter pylori.

The nickel-containing enzymes hydrogenase and urease require accessory proteins in order to incorporate properly the nickel atom(s) into the active sites. The Helicobacter pylori genome contains the full complement of both urease and hydrogenase accessory proteins. Two of these, the hydrogenase accessory proteins HypA (encoded by hypA) and HypB (encoded by hypB), are required for the full activity of both the hydrogenase and the urease enzymes in H. pylori. Under normal growth conditions, hydrogenase activity is abolished in strains in which either hypA (HypA:kan) or hypB (HypB:kan) have been interrupted by a kanamycin resistance cassette. Urease activity in these strains is 40 (HypA:kan)- and 200 (HypB:kan)-fold lower than for the wild-type (wt) strain 43504. Nickel supplementation in the growth media restored urease activity to almost wt levels. Hydrogenase activity was restored to a lesser extent, as has been observed for hyp mutants in other (H(2)-oxidizing) bacteria. Expression levels of UreB (the urease large subunit) were not affected by inactivation of either hypA or hypB, as determined by immunoblotting. Urease activity was not affected by lesions in the genes for either the hydrogenase accessory proteins HypD or HypF or the hydrogenase large subunit structural gene, indicating that the urease deficiency was not caused by lack of hydrogenase activity. When crude extracts of wt, HypA:kan and HypB:kan were separated by anion exchange chromatography, the urease-containing fractions of the mutant strains contained about four (HypA:kan)- and five (HypB:kan)-fold less nickel than did the urease from wt, indicating that the lack of urease activity in these strains results from a nickel deficiency in the urease enzyme.

Characterization of the NifU and NifS Fe-S cluster formation proteins essential for viability in Helicobacter pylori.

The Fe-S cluster formation proteins NifU and NifS are essential for viability in the ulcer causing human pathogen Helicobacter pylori. Obtaining viable H. pylori mutants upon mutagenesis of the genes encoding NifU and NifS was unsuccessful even by growing the potential transformants under many different conditions including low O(2) atmosphere and supplementation with both ferric and ferrous iron. When a second copy of nifU was introduced into the chromosome at a unrelated site, creating a mero-diploid strain for nifU, this second copy of the gene could be disrupted at high frequency. This indicates that the procedures used for transformation were capable of nifU mutagenesis, so that the failure to recover mutants is solely due to the requirement of nifU for H. pylori viability. H. pylori NifU and NifS were expressed in Escherichia coli and purified to near homogeneity, and the proteins were characterized. Purified NifU is a red protein that contains approximately 1.5 atoms of iron per monomer. This iron was determined to be in the form of a redox-active [2Fe-2S](2+,+) cluster by characteristic UV-visible, EPR, and MCD spectra. The primary structure of NifU also contains the three conserved cysteine residues which are involved in providing the scaffold for the assembly of a transient Fe-S cluster for insertion into apoprotein. Purified NifS has a yellow color and UV-visible spectra characteristic of a pyridoxal phosphate containing enzyme. NifS is a cysteine desulfurase, releasing sulfur or sulfide (depending on the reducing environment) from L-cysteine, in agreement with its proposed role as a sulfur donor to Fe-S clusters. The results here indicate that the NifU type of Fe-S cluster formation proteins is not specific for maturation of the nitrogenase proteins and, as H. pylori lacks other Fe-S cluster assembly proteins, that the H. pylori NifS and NifU are responsible for the assembly of many (non-nitrogenase) Fe-S clusters.

Role of the Azotobacter vinelandii nitrogenase-protective shethna protein in preventing oxygen-mediated cell death.

Azotobacter vinelandii strains lacking the nitrogenase-protective Shethna protein lost viability upon carbon-substrate deprivation in the presence of oxygen. This viability loss was dependent upon the N(2)-fixing status of cultures (N(2)-fixing cells lost viability, while non-N(2)-fixing cells did not) and on the ambient O(2) level. Supra-atmosheric O(2) tensions (40% partial pressure) decreased the viable cell number of the mutant further, and the mutant had a slightly higher spontaneous mutation frequency than the wild type in the high-O(2) conditions. Iron starvation conditions, which resulted in fourfold-reduced superoxide dismutase levels, were also highly detrimental to the viability of the protective protein mutants, but these conditions did not affect the viability of the wild-type strain. Nitrogenase or other powerful reductants associated with N(2) fixation may be sources of damaging partially reduced oxygen species, and the production of such species are perhaps minimized by the Shethna protein.

Dual roles of Bradyrhizobium japonicum nickelin protein in nickel storage and GTP-dependent Ni mobilization.

The hydrogenase accessory protein HypB, or nickelin, has two functions in the N(2)-fixing, H(2)-oxidizing bacterium Bradyrhizobium japonicum. One function of HypB involves the mobilization of nickel into hydrogenase. HypB also carries out a nickel storage/sequestering function in B. japonicum, binding nine nickel ions per monomer. Here we report that the two roles (nickel mobilization and storage) of HypB can be separated in vitro and in vivo using molecular and biochemical approaches. The role of HypB in hydrogenase maturation is completely dependent on its intrinsic GTPase activity; strains which produce a HypB protein that is severely deficient in GTPase activity but that fully retains nickel-sequestering ability cannot produce active hydrogenase even upon prolonged nickel supplementation. A HypB protein that lacks the nickel-binding polyhistidine region near the N terminus lacks only the nickel storage capacity function; it is still able to bind a single nickel ion and also retains complete GTPase activity.

Mutagenesis studies of the FeSII protein of Azotobacter vinelandii: roles of histidine and lysine residues in the protection of nitrogenase from oxygen damage.

The Azotobacter FeSII protein, also known as the Shethna protein, forms a protective complex with nitrogenase during periods when nitrogenase is exposed to oxygen. One possible mechanism for its action is an oxidation state-dependent conformational interaction with nitrogenase whereby the FeSII protein dissociates from the MoFe and Fe proteins of nitrogenase under reducing conditions. Herein we report the construction and characterization of five site-directed mutants of the FeSII protein (H12Q, H55Q, K14A, K15A, and the double mutant K14A/K15A) which were individually purified after being individually overexpressed in Escherichia coli. These mutant FeSII proteins maintain native-like assembly and orientation of the 2Fe-2S center on the basis of EPR and NMR spectroscopic characterization and their redox midpoint potentials, which are within 25 mV of that of the wild type protein. The abilities of the individual mutant proteins to protect nitrogenase were assessed by determining the remaining nitrogenase activities after adding each pure version back to extracts from an FeSII deletion strain, and then exposing the mixture to oxygen. In these assays, the H12Q mutant functioned as well as the wild type protein. However, mutation of His55, a few residues away from a cluster-liganding cysteine, results in much less efficient protection of nitrogenase. These results are consistent with pH titrations in both oxidation states, which show that His12 is insensitive to 2Fe-2S cluster oxidation state. His55's pK is weakly responsive to oxidation state, and the pK increase of 0. 16 pH unit upon 2Fe-2S cluster oxidation is indicative of ionization of another group between His55 and the 2Fe-2S cluster, which could modulate the FeSII protein's affinity for nitrogenase in a redox state-dependent manner. Both K14A and K15A mutant FeSII proteins partially lost their ability to protect nitrogenase, but the lysine double mutant lost almost all its protective ability. The nitrogenase component proteins in an Azotobacter strain bearing the double lysine mutation (in the chromosome) were degraded much more rapidly in vivo than those in the wild type strain under carbon substrate-limited conditions. These results indicate that the two lysines may have an important role in FeSII function, perhaps in the initial steps of recognizing the nitrogenase component proteins.

The FixK2 protein is involved in regulation of symbiotic hydrogenase expression in Bradyrhizobium japonicum.

The roles of the nitrogen fixation regulatory proteins NifA, FixK1, and FixK2 in the symbiotic regulation of hydrogenase structural gene expression in Bradyrhizobium japonicum have been investigated. Bacteroids from FixJ and FixK2 mutants have little or no hydrogenase activity, and extracts from these mutant bacteroids contain no hydrogenase protein. Bacteroids from a FixK1 mutant exhibit wild-type levels of hydrogenase activity. In beta-galactosidase transcriptional assays with NifA and FixK2 expression plasmids, the FixK2 protein induces transcription from the hup promoter to levels similar to those induced by HoxA, the transcriptional activator of free-living hydrogenase expression. The NifA protein does not activate transcription at the hydrogenase promoter. Therefore, FixK2 is involved in the transcriptional activation of symbiotic hydrogenase expression. By using beta-galactosidase transcriptional fusion constructs containing successive truncations of the hup promoter, the region of the hup promoter required for regulation by FixK2 was determined to be between 29 and 44 bp upstream of the transcription start site.

Cytochrome c terminal oxidase pathways of Azotobacter vinelandii: analysis of cytochrome c4 and c5 mutants and up-regulation of cytochrome c-dependent pathways with N2 fixation.

The Azotobacter vinelandii cytochrome c5 gene (termed cycB) was cloned and sequenced. Mutants in this c-type cytochrome as well as cytochrome c4 mutants (mutations in cycA) and double mutants in both of the c-type respiratory pathways were characterized. Spectral and heme staining experiments on membranes from the mutants were consistent with the anticipated characteristics of all the gene-directed mutants. Membranes of the individual cytochrome c4 or c5 mutants had normal respiratory rates with physiological substrates but respiration significantly lower than the wild-type rate with ascorbate-N,N,N',N',-tetramethyl-p-phenylenediamine (TMPD) as a reductant. The growth rates of the individual cytochrome c4 or c5 mutants were not markedly different from that of the wild-type strain, but the cycA cycB double-mutant strain was noticeably growth retarded at and below 7.5% O2 on both N-containing and N-free media. The double-mutant strain was unable to grow on agar plates at O2 tensions of 2.5% or less on N-free medium. As the wild-type growth was unaffected by varying the O2 tension, the results indicate that the role of the cytochrome c-dependent pathways is to provide respiration at intermediate (5 to 10%) and low (below 5%) O2 tensions. The two c-type cytochrome genes are transcriptionally up-regulated with N2 fixation; N starvation caused 2.8-fold and 7- to 10-fold increases in the promoter activities of cycA and cycB, respectively, but these activities were affected little by the O2 level supplied to the cultures.

The sequences of hypF, hypC and hypD complete the hyp gene cluster required for hydrogenase activity in Bradyrhizobium japonicum.

A region of DNA 6 kb downstream of the hydrogenase (H2ase) structural genes and directly downstream of the hypB gene of Bradyrhizobium japonicum was shown by mutational analysis to be necessary for H2ase synthesis. Sequencing of this region revealed two complete open reading frames, and the 5' fragment of a third ORF. They encode proteins with homologies to the HypF, HypC and the N-terminus of HypD from other H2ase-containing organisms. The hypF of B. japonicum encodes a 753-aa protein with a predicted molecular mass of 80.3 kDa that contains the two zinc-finger motifs characteristic of other HypF proteins. The hypC encodes a 85-aa protein with a predicted molecular mass of 8.4 kDa. The 5' portion of hypD, which encodes the first 35 aa, upon combining with the previously reported C-terminus of HypD, designated HypD' (Van Soom et al. (1993) Mol. Gen. Genet. 239, 235-240) encodes a protein with a predicted molecular mass of 42.4 kDa. Complementation studies on a H2 uptake defective strain of B. japonicum containing a polar mutation in the hyp operon revealed that the products of the hyp F, C, D, E genes are required for H2ase production. Evidence is also presented that the hyp genes are co-transcribed from a large operon together with the downstream genes hupGHIJK, making a polycistronic message of 11 genes.

Roles of HoxX and HoxA in biosynthesis of hydrogenase in Bradyrhizobium japonicum.

In-frame deletion mutagenesis was used to study the roles of two Bradyrhizobium japonicum proteins, HoxX and HoxA, in hydrogenase biosynthesis; based on their sequences, these proteins were previously proposed to be sensor and regulator proteins, respectively, of a two-component regulatory system necessary for hydrogenase transcription. Deletion of the hoxX gene resulted in a strain that expressed only 30 to 40% of wild-type hydrogenase activity. The inactive unprocessed form of the hydrogenase large subunit accumulated in this strain, indicating a role for HoxX in posttranslational processing of the hydrogenase enzyme but not in transcriptional regulation. Strains containing a deletion of the hoxA gene or a double mutation (hoxX and hoxA) did not exhibit any hydrogenase activity under free-living conditions, and extracts from these strains were inactive in gel retardation assays with a 158-bp fragment of the DNA region upstream of the hupSL operon. However, bacteroids from root nodules formed by all three mutant types (hoxX, hoxA, and hoxX hoxA) exhibited hydrogenase activity comparable to that of wild-type bacteroids. Bacteroid extracts from all of these strains, including the wild type, failed to cause a shift of the hydrogenase upstream region used in our assay. It was shown that HoxA is a DNA-binding transcriptional activator of hydrogenase structural gene expression under free-living conditions but not under symbiotic conditions. Although symbiotic hydrogenase expression is still sigma54 dependent, a transcriptional activator other than HoxA functions presumably upstream of the HoxA binding site.

Formation of pH and potential gradients by the reconstituted Azotobacter vinelandii cytochrome bd respiratory protection oxidase.

To directly characterize the bioenergetic properties of the cytochrome bd terminating branch of the Azotobacter vinelandii electron transport chain, the purified cytochrome bd oxidase was reconstituted into a phospholipid environment consisting of phosphatidylethanolamine and phosphatidylglycerol (3:1). The average diameter of the proteoliposomes after extrusion through a polycarbonate membrane was 94 +/- 4 nm. Initiation of respiration upon the addition of 20 microM ubiquinone-1 to proteoliposomes loaded with the pH-sensitive dye pyranine resulted in an immediate alkalization of the vesicle lumen by an average pH change of 0.11 unit. This pH gradient was readily collapsed upon the addition of nigericin, carbonyl cyanide p-(tri-fluoromethoxy) phenyl-hydrazone, gramicidin, Triton X-100, or 2-heptyl-4-hydroxyquinoline N-oxide (HQNO). Proteoliposomal respiration initiated in the presence of the potentiometric membrane dye rhodamine 123 caused the generation of a transmembrane potential; the potential was collapsed upon the addition of either valinomycin or HQNO. The formation of both pH and potential gradients during turnover demonstrates that the A. vinelandii cytochrome bd oxidase is coupled to energy conservation in vivo.

The HypB protein from Bradyrhizobium japonicum can store nickel and is required for the nickel-dependent transcriptional regulation of hydrogenase.

The HypB protein from Bradyrhizobium japonicum is a metal-binding GTPase required for hydrogenase expression. In-frame mutagenesis of hypB resulted in strains that were partially or completely deficient in hydrogenase expression, depending on the degree of disruption of the gene. Complete deletion of the gene yielded a strain (JH delta Eg) which lacked hydrogenase activity under all conditions tested, including the situation as bacteroids from soybean nodules. Mutant strain JH delta 23H lacking only the N-terminal histidine-rich region (38 amino acids deleted, 23 of which are His residues) expressed partial hydrogenase activity. The activity of strain JH delta 23H was low in comparison to the wild type in 10-50 nM nickel levels, but could be cured to nearly wild-type levels by including 50 microM nickel during the derepression incubation. Studies on strains harbouring the hup promoter-lacZ fusion plasmid showed that the complete deletion of hypB nearly abolished hup promoter activity, whereas the histidine deletion mutant had 60% of the wild-type promoter activity in 50 microM NiCl2. Further evidence that HypB is required for hup promoter-binding activity was obtained from gel-shift assays. HypB could not be detected by immunoblotting when the cells were cultured heterotrophically, but when there was a switch to microaerobic conditions (1% partial pressure O2, 10% partial pressure H2) HypB was detected, and its expression preceded hydrogenase synthesis by 3-6 h. 63Ni accumulation by whole cells showed that both of the mutant strains accumulate less nickel than the wild-type strain at all time points tested during the derepression incubation. Wild-type cultures that received nickel during the HypB expression-specific period and were then washed and derepressed for hydrogenase without nickel had activities comparable to those cells that were derepressed for hydrogenase with nickel for the entire time period. In contrast to the wild type, strain JH delta 23H cultures supplied with nickel only during the HypB expression period achieved hydrogenase activities that were 30% of those cultures supplied with nickel for the entire hydrogenase derepression period. These results indicate that the loss of the metal-binding area of HypB causes a decrease in the ability of the cells to sequester and store nickel for later use in one or more hydrogenase expression steps.

Cloning and expression of the gene for a protein disulfide oxidoreductase from Azotobacter vinelandii: complementation of an Escherichia coli dsbA mutant strain.

The gene for a disulfide oxidoreductase was cloned and sequenced from Azotobacter vinelandii and termed the dsbA locus. The deduced amino acid sequence contains 214 residues with a potential 17-residue signaling sequence on the N-terminal end. This gives the mature protein a calculated molecular mass of 21 799 Da. The A. vinelandii DsbA protein contains the well-conserved motif of C-P-H-C, which is found in the catalytic site of other bacterial DsbA enzymes. The A. vinelandii dsbA gene was expressed in Escherichia coli and was found to be able to complement an E. coli dsbA mutant strain by restoring flagellar and alkaline phosphatase activities. A. vinelandii dsbA mutant strains were impossible to characterize because of the extreme deleterious effect of the mutation. Therefore, the in vivo role of A. vinelandii DsbA is unknown, but it may function to form disulfide bonds and/or be involved in cytochrome biogenesis.

The Bradyrhizobium japonicum coxWXYZ gene cluster encodes a bb3-type ubiquinol oxidase.

Bradyrhizobium japonicum, a symbiotic nitrogen-fixing bacterium, has a complex respiratory electron-transport chain, capable of functioning throughout a wide range of oxygen tensions. It does so by synthesizing a number of terminal oxidases, each appropriate for different environmental conditions. We have previously described the cloning of the large catalytic subunit, coxX, from one of the terminal oxidases from B. japonicum [Surpin, M.A., Moshiri, F., Murphy, A.M. and Maier, R.J. (1994) Genetic evidence for a fourth terminal oxidase from Bradyrhizobium japonicum. Gene 143, 73-77]. In this work, we describe the remaining subunits of this terminal oxidase complex, which is encoded by the coxWXYZ operon. The polypeptide encoded by coxW does not contain any amino acid residues that are known to bind the CuA atom of cytochrome c terminal oxidases, but contains residues thought to be involved in ubiquinol binding. Terminal oxidase cyanide inhibition titration pattern comparisons of the wild type with a coxWXYZ insertion mutant indicated the new oxidase is expressed microaerobically. However analysis of hemes extracted from microaerobically incubated cells revealed the absence of heme O in this strain (from both the wild type and the mutant) of B. japonicum. Therefore, coxWXYZ most likely encodes a microaerobically-expressed bb3-type ubiquinol oxidase.

Hydrogen uptake hydrogenase in Helicobacter pylori.

The peptic ulcer-causing bacterium Helicobacter pylori was found to contain an H2-uptake hydrogenase activity coupled to whole cell (aerobic) respiration. The activity was localized to membranes which functioned in the H2-oxidizing direction with a variety of artificial and physiological electron acceptors of positive redox potential. Immunoblotting of H. pylori membrane components with anti (B. japonicum) hydrogenase large and small subunit-specific antisera identified H. pylori hydrogenase peptides of approximately 65 and 26 kDa respectively, and H. pylori genomic DNA fragments hybridizing to the (B. japonicum) hydrogenase structural genes were identified. The membrane-bound activity was subject to anaerobic activation, like many NiFe hydrogenases. Difference absorption spectral studies revealed absorption peaks characteristic of b and c-type cytochromes, as well as of a bd-type terminal oxidase in the H. pylori H2-oxidizing membrane-associated respiratory chain.

The "nitrogenase-protective" FeSII protein of Azotobacter vinelandii: overexpression, characterization, and crystallization.

The Azotobacter vinelandii FeSII protein confers conformational protection to nitrogenase by binding to the MoFe and Fe proteins under periods of oxidative stress to create an inactive but O2-stabilized tripartite complex. In this work the FeSII protein has been overexpressed in Escherichia coli, and the recombinant protein has been purified to homogeneity, crystallized, and characterized in terms of its functional, spectroscopic, and redox properties. The recombinant protein is a homodimer and is expressed as a holoprotein with one [2Fe-2S]2+,+ cluster in each subunit. It is shown to be functional in reconstituting an O2-stable nitrogenase complex in vitro. Spectroscopic studies using the combination of UV-visible absorption, CD, and variable temperature MCD, EPR, and resonance Raman indicate that the [2Fe-2S]2+,+ cluster is coordinated exclusively by cysteine residues. The arrangement of coordinating cysteines in the primary sequence and the EPR properties of the [2Fe-2S]+ cluster (g = 2.04, 1.95, 1.88) are very similar to those of chloroplast ferredoxins. However, the variable-temperature MCD, resonance Raman, and redox properties (Em = -262 +/- 10 mV based on dye-mediated EPR redox titrations) are more characteristic of hydroxylase-type ferredoxins such as adrenodoxin. In contrast to chloroplast-type ferredoxins, the vibrational properties of the [2Fe-2S]2+,+ cluster in the FeSII protein indicate that none of the cysteinyl Fe-S-C-C dihedral angles are close to 180 degrees and that the cluster is not exposed to solvent. Preliminary X-ray diffraction analysis indicates that the protein crystallizes in an orthorhombic space group with unit cell dimensions a = 135 A, b = 135 A, and c = 38 A and that there are at least two dimers per asymmetric unit.

Cloning, sequencing, and mutagenesis of the cytochrome c4 gene from Azotobacter vinelandii: characterization of the mutant strain and a proposed new branch in the respiratory chain.

Azotobacter vinelandii is a free-living, nitrogen-fixing bacterium with a branched electron transport chain terminating with two terminal oxidases, cytochromes d and o. Cytochrome o is thought to receive its electrons from cytochromes c. The gene encoding cytochrome c4 has been cloned and sequenced (termed the cycA locus). The deduced amino acid sequence contains a 20 residue signaling peptide sequence on the N-terminal end. Mutagenesis was performed by inserting a Kmr cassette into the structural gene. The subsequent mutant strains showed reduced amounts of cytochromes c (approximately 60% of wild-type levels) based on difference absorption spectra measurements. Heme staining confirmed the complete loss of cytochrome c4 protein in the mutant strains. These mutants could grow and respire normally, like the wild type, under both diazotrophic or non-diazotrophic conditions. Surprisingly, the cytochrome o terminal oxidase was still turning over in membranes from the cycA mutants as evidenced by substrate-reduced CO difference spectra and inhibition experiments with the use of the cytochrome o inhibitor, chlorpromazine. Still, the levels of oxidation by ascorbate-TMPD were greatly reduced in the cycA mutants. Therefore, it is proposed that cytochrome c4 does not exist in complex with cytochrome o as a multi-component terminal oxidase complex, yet still passes electrons to it in parallel like cytochrome c5, as opposed to in an obligate sequential manner with cytochrome c5. In this pathway the proposed new branch is at the ubiquinone to cytochromes c level.