The identification, characterization, sequencing and mutagenesis of the genes (hupSL) encoding the small and large subunits of the H2-uptake hydrogenase of Azotobacter chroococcum

Genetic, structural, and functional diversity of low and high-affinity siderophores in strains of nitrogen fixing Azotobacter chroococcum

To increase iron (Fe) bioavailability in surface soils, microbes secrete siderophores, chelators with widely varying Fe affinities. Strains of the soil bacterium Azotobacter chroococcum (AC), plant-growth promoting rhizobacteria used as agricultural inoculants, require high Fe concentrations for aerobic respiration and nitrogen fixation. Recently, A. chroococcum str. NCIMB 8003 was shown to synthesize three siderophore classes: (1) vibrioferrin, a low-affinity α-hydroxy carboxylate (pFe = 18.4), (2) amphibactins, high-affinity tris-hydroxamates, and (3) crochelin A, a high-affinity siderophore with mixed Fe-chelating groups (pFe = 23.9). The relevance and specific functions of these siderophores in AC strains remain unclear. We analyzed the genome and siderophores of a second AC strain, A. chroococcum str. B3, and found that it also produces vibrioferrin and amphibactins, but not crochelin A. Genome comparisons indicate that vibrioferrin production is a vertically inherited, conserved strategy for Fe uptake in A. chroococcum and other species of Azotobacter. Amphibactin and crochelin biosynthesis reflects a more complex evolutionary history, shaped by vertical gene transfer, gene gain and loss through recombination at a genomic hotspot. We found conserved patterns of low vs. high-affinity siderophore production across strains: the low-affinity vibrioferrin was produced by mildly Fe limited cultures. As cells became more severely Fe starved, vibrioferrin production decreased in favor of high-affinity amphibactins (str. B3, NCIMB 8003) and crochelin A (str. NCIMB 8003). Our results show the evolution of low and high-affinity siderophore families and conserved patterns for their production in response to Fe bioavailability in a common soil diazotroph.

Azotobacter vinelandii Nitrogenase Activity, Hydrogen Production, and Response to Oxygen Exposure

Azotobacter vinelandii selectively utilizes three types of nitrogenase (molybdenum, vanadium, and iron only) to fix N₂, with their expression regulated by the presence or absence of different metal cofactors in its environment. Each alternative nitrogenase isoenzyme is predicted to have different electron flux requirements based on in vitro measurements, with the molybdenum nitrogenase requiring the lowest flux and the iron-only nitrogenase requiring the highest. Here, prior characterized strains, derepressed in nitrogenase synthesis and also deficient in uptake hydrogenase, were further modified to generate new mutants lacking the ability to produce poly-β-hydroxybutyrate (PHB). PHB is a storage polymer generated under oxygen-limiting conditions and can represent up to 70% of the cells' dry weight. The absence of such granules facilitated the study of relationships between catalytic biomass and product molar yields across different adaptive respiration conditions. The released hydrogen gas observed during growth, due to the inability of the mutants to recapture hydrogen, allowed for direct monitoring of in vivo nitrogenase activity for each isoenzyme. The data presented here show that increasing oxygen exposure limits equally the in vivo activities of all nitrogenase isoenzymes, while under comparative conditions, the Mo nitrogenase enzyme evolves more hydrogen per unit of biomass than the alternative isoenzymes.IMPORTANCEA. vinelandii has been a focus of intense research for over 100 years. It has been investigated for a variety of functions, including agricultural fertilization and hydrogen production. All of these endeavors are centered around A. vinelandii's ability to fix nitrogen aerobically using three nitrogenase isoenzymes. The majority of research up to this point has targeted in vitro measurements of the molybdenum nitrogenase, and robust data contrasting how oxygen impacts the in vivo activity of each nitrogenase isoenzyme are lacking. This article aims to provide in vivo nitrogenase activity data using a real-time evaluation of hydrogen gas released by derepressed nitrogenase mutants lacking an uptake hydrogenase and PHB accumulation.

Azotobacter Genomes: The Genome of Azotobacter chroococcum NCIMB 8003 (ATCC 4412)

The genome of the soil-dwelling heterotrophic N2-fixing Gram-negative bacterium Azotobacter chroococcum NCIMB 8003 (ATCC 4412) (Ac-8003) has been determined. It consists of 7 circular replicons totalling 5,192,291 bp comprising a circular chromosome of 4,591,803 bp and six plasmids pAcX50a, b, c, d, e, f of 10,435 bp, 13,852, 62,783, 69,713, 132,724, and 311,724 bp respectively. The chromosome has a G+C content of 66.27% and the six plasmids have G+C contents of 58.1, 55.3, 56.7, 59.2, 61.9, and 62.6% respectively. The methylome has also been determined and 5 methylation motifs have been identified. The genome also contains a very high number of transposase/inactivated transposase genes from at least 12 of the 17 recognised insertion sequence families. The Ac-8003 genome has been compared with that of Azotobacter vinelandii ATCC BAA-1303 (Av-DJ), a derivative of strain O, the only other member of the Azotobacteraceae determined so far which has a single chromosome of 5,365,318 bp and no plasmids. The chromosomes show significant stretches of synteny throughout but also reveal a history of many deletion/insertion events. The Ac-8003 genome encodes 4628 predicted protein-encoding genes of which 568 (12.2%) are plasmid borne. 3048 (65%) of these show > 85% identity to the 5050 protein-encoding genes identified in Av-DJ, and of these 99 are plasmid-borne. The core biosynthetic and metabolic pathways and macromolecular architectures and machineries of these organisms appear largely conserved including genes for CO-dehydrogenase, formate dehydrogenase and a soluble NiFe-hydrogenase. The genetic bases for many of the detailed phenotypic differences reported for these organisms have also been identified. Also many other potential phenotypic differences have been uncovered. Properties endowed by the plasmids are described including the presence of an entire aerobic corrin synthesis pathway in pAcX50f and the presence of genes for retro-conjugation in pAcX50c. All these findings are related to the potentially different environmental niches from which these organisms were isolated and to emerging theories about how microbes contribute to their communities.

Distribution of Hydrogenase Genes in Desulfovibrio spp. and Their Use in Identification of Species from the Oil Field Environment

The distribution of genes for [Fe], [NiFe], and [NiFeSe] hydrogenases was determined for 22 Desulfovibrio species. The genes for [NiFe] hydrogenase were present in all species, whereas those for the [Fe] and [NiFeSe] hydrogenases had a more limited distribution. Sulfate-reducing bacteria from 16S rRNA groups other than the genus Desulfovibrio (R. Devereux, M. Delaney, F. Widdel, and D. A. Stahl, J. Bacteriol. 171:6689-6695, 1989) did not react with the [NiFe] hydrogenase gene probe, which could be used to identify different Desulfovibrio species in oil field samples following growth on lactate-sulfate medium.

Genes involved in Sec-independent membrane targeting of hydrogenase in Azotobacter chroococcum

Sec-independent translocation systems have been characterised in Escherichia coli and other bacteria and differ from the Sec-dependent system by transporting fully folded proteins using the transmembrane proton electrochemical gradient. Proteins transported by this system bear a twin-arginine motif (tat) in the N-terminal signal peptide and include several cofactor-containing proteins. Azotobacter chroococcum strain (MCD124) has a soluble hydrogenase, which exhibited low O(2)-dependent H(2) uptake, and a shift in the pH of the culture to a more alkaline range during growth. We show that the DNA region capable of complementing this strain contains the tatABC genes and that mutations in the tatA gene reproduced the soluble hydrogenase and the culture pH shift phenotypes. We also show that insertional mutation in the tatC gene at a position corresponding to its C-terminal region had no effect on hydrogenase activity, but induced the pH shift of the culture. Sequence and mutagenesis analyses of this genomic region suggest that these genes form an operon that does not contain a tatD-like gene. A mutation in hupZ of the main hup gene region, coding for a possible b-type cytochrome also yielded a soluble hydrogenase, but not the pH-shift phenotype.

Unusual organization of the genes coding for HydSL, the stable [NiFe]hydrogenase in the photosynthetic bacterium Thiocapsa roseopersicina BBS

The characterization of a hyd gene cluster encoding the stable, bidirectional [NiFe]hydrogenase 1 enzyme in Thiocapsa roseopersicina BBS, a purple sulfur photosynthetic bacterium belonging to the family Chromatiaceae, is presented. The heterodimeric hydrogenase 1 had been purified to homogeneity and thoroughly characterized (K. L. Kovacs et al., J. Biol. Chem. 266:947-951, 1991; C. Bagyinka et al., J. Am. Chem. Soc. 115:3567-3585, 1993). As an unusual feature, a 1,979-bp intergenic sequence (IS) separates the structural genes hydS and hydL, which encode the small and the large subunits, respectively. This IS harbors two sequential open reading frames (ORFs) which may code for electron transfer proteins ISP1 and ISP2. ISP1 and ISP2 are homologous to ORF5 and ORF6 in the hmc operon, coding for a transmembrane electron transfer complex in Desulfovibrio vulgaris. Other accessory proteins are not found immediately downstream or upstream of hydSL. A hup gene cluster coding for a typical hydrogen uptake [NiFe]hydrogenase in T. roseopersicina was reported earlier (A. Colbeau et al. Gene 140:25-31, 1994). The deduced amino acid sequences of the two small (hupS and hydS) and large subunit (hupL and hydL) sequences share 46 and 58% identity, respectively. The hup and hyd genes differ in the arrangement of accessory genes, and the genes encoding the two enzymes are located at least 15 kb apart on the chromosome. Both hydrogenases are associated with the photosynthetic membrane. A stable and an unstable hydrogenase activity can be detected in cells grown under nitrogen-fixing conditions; the latter activity is missing in cells supplied with ammonia as the nitrogen source. The apparently constitutive and stable activity corresponds to hydrogenase 1, coded by hydSL, and the inducible and unstable second hydrogenase may be the product of the hup gene cluster.

Characterization of the cytochromes C from Desulfovibrio desulfuricans G201

A monoheme cytochrome c553 and a hexadecaheme high molecular weight cytochrome (Hmc) have been isolated and characterized from the sulfate-reducing bacteria Desulfovibrio desulfuricans G201, in addition to the tetraheme cytochrome c3 (Mr 13000) that has been previously described. Both cytochromes are homologous with respect to several biochemical properties to the corresponding cytochromes found in other Desulfovibrio species. However, they are acidic proteins while the corresponding molecules, isolated from other Desulfovibrio species, are relatively more basic. The D. desulfuricans cytochrome content appears identical to that of D. vulgaris Hildenborough. Isolation of these cytochromes from a Desulfovibrio desulfuricans strain is of great interest in order to get more insight on the physiological function of these molecules.

The Alcaligenes eutrophus membrane-bound hydrogenase gene locus encodes functions involved in maturation and electron transport coupling

Alcaligenes eutrophus H16 produces two [NiFe] hydrogenases which catalyze the oxidation of hydrogen and enable the organism to utilize H2 as the sole energy source. The genes (hoxK and hoxG) for the heterodimeric, membrane-bound hydrogenase (MBH) are located adjacent to a series of eight accessory genes (hoxZ, hoxM, hoxL, hoxO, hoxQ, hoxR, hoxT, and hoxV). In the present study, we generated a set of isogenic mutants with in-frame deletions in the two structural genes and in each of the eight accessory genes. The resulting mutants can be grouped into two classes on the basis of the H2-oxidizing activity of the MBH. Class I mutants (hoxKdelta, hoxGdelta, hoxMdelta, hoxOdelta, and hoxQdelta) were totally devoid of MBH-mediated, H2-oxidizing activity. The hoxM deletion strain was the only mutant in our collection which was completely blocked in carboxy-terminal processing of large subunit HoxG, indicating that hoxM encodes a specific protease. Class II mutants (hoxZdelta, hoxLdelta, hoxRdelta, hoxTdelta, and hoxVdelta) contained residual amounts of MBH activity in the membrane fraction of the extracts. Immunochemical analysis and 63Ni incorporation experiments revealed that the mutations affect various steps in MBH maturation. A lesion in hoxZ led to the production of a soluble MBH which was highly active with redox dye.

Molecular biological analysis of a bidirectional hydrogenase from cyanobacteria

An 8.9-kb segment with hydrogenase genes from the cyanobacterium Anabaena variabilis has been cloned and sequenced. The sequences show homology to the methyl-viologen-reducing hydrogenases from archaebacteria and, even more striking, to the NAD(+)-reducing enzymes from Alcaligenes eutrophus and Nocardia opaca as well as to the NADP(+)-dependent protein from Desulfovibrio fructosovorans. The cluster from A. variabilis contains genes coding for both the hydrogenase heterodimer (hoxH and hoxY) and for the diaphorase moiety (hoxU and hoxF) described for the A. eutrophus enzyme. In A. variabilis the gene cluster is split by two open reading frames (between hoxY and hoxH and between hoxU and hoxY, respectively), and a probably non-coding 0.9-kb segment in an unusual way. The hoxH partial sequence from Anabaena 7119 and Anacystis nidulans was amplified by PCR. Using the labeled segment from A. 7119 as probe, Southern analysis revealed homologous gene segments in the cyanobacteria A. 7119, Anabaena cylindrica, Anacystis nidulans and A. variabilis. The bidirectional hydrogenase from A. nidulans was purified and digests were sequenced. The amino acid sequences obtained showed partial identities to the amino acid sequences deduced from the DNA data of the 8.9-kb segment from A. variabilis. Therefore the 8.9-kb segment contains the genes coding for the bidirectional, reversible hydrogenase from cyanobacteria. Crude extracts from A. nidulans perform NAD(P)H-dependent H2 evolution corroborating the molecular biological demonstration of the NAD(P)(+)-dependent hydrogenase in cyanobacteria.

Sequences, organization and analysis of the hupZMNOQRTV genes from the Azotobacter chroococcum hydrogenase gene cluster

Hydrogen-uptake (Hup) activity in Azotobacter chroococcum depends upon a cluster of genes spread over 13,687 bp of the chromosome. Six accessory genes of the cluster, hupABYCDE, begin 4.8 kb downstream of the structural genes, hupSL, and are required for the formation of a functional [NiFe] hydrogenase. The sequencing of the intervening 4.8 kb of hup-specific DNA has now been completed. This revealed eight additional closely linked ORFs, which we designated hupZ, hupM, hupN, hupO, hupQ, hupR, hupT and hupV. These genes potentially encode polypeptides with predicted masses of 27.7, 22.3, 11.4, 16.2, 31.3, 8.1, 16.2 and 36.7 kDa, respectively. All eight genes are transcribed from the same strand as hupSL and hupABYCDE. A chroococcum, therefore, has a total of 16 contiguous genes affecting hydrogenase activity beginning with hupS and ending with hupE. The amino acid sequence deduced from hupZ has the characteristics of a b-type cytochrome. Insertion mutagenesis of hupZ resulted in a mutant incapable of supporting O2-dependent H2 oxidation. The deduced amino acid sequence of hupR shares high homology with bacterial rubredoxins. HupZ and HupR may both be involved in transferring electrons from hydrogenase to the electron transport chain. A mutation in hupV knocked out hydrogenase activity entirely; this gene may be involved in processing the large subunit of hydrogenase. It is now clear that the genes controlling [NiFe] hydrogenase activity in many bacteria including Azotobacter chroococcum, Alcaligenes eutrophus, Rhizobium leguminosarum, Rhodobacter capsulatus and Escherichia coli are highly conserved, organized in much the same manner, and likely derived from a common ancestor.

Organization of the hydrogenase gene cluster from Bradyrhizobium japonicum: sequences and analysis of five more hydrogenase-related genes

Previously, the deletion of a 2.9-kb chromosomal EcoRI fragment of DNA located 2.2 kb downstream from the end of the Bradyrhizobium japonicum hydrogenase structural genes caused lack of normal-sized hydrogenase (Hup) subunits and complete loss of Hup activity. It was suggested that this region encodes one or more genes required for Hup processing. Sequencing of a 3322-bp XcmI fragment of DNA covering this 2.9-kb EcoRI fragment within the hup gene cluster revealed the presence of five open reading frames (ORFs) designated hupG, hupH, hupI, hupJ and hupK, encoding polypeptides with calculated molecular masses of 15.8, 30.7, 7.6, 18.1 and 38 kDa, respectively. Based on deduced amino acid (aa) sequences, all five products of the hupGHIJK genes showed significant homology with other genes' products in several H2-utilizing bacteria. Of particular interest are HupG and HupI. HupG showed 70% similarity (28% identity) to the HyaE of the Escherichia coli hydrogenase-1 operon which was demonstrated to be involved in the processing of hydrogenase-1. HupI showed strong identity to rubredoxin and rubredoxin-like proteins from many other bacteria. The latter proteins contain two 'C-X-X-C' motifs, which may serve as iron ligands for non-heme iron proteins involved as intermediate electron carriers or in the assembly process for Fe-S (or NiFe-S) clusters.

Cloning, sequencing, and mutational analysis of the hyb operon encoding Escherichia coli hydrogenase 2

The genes encoding the two structural subunits of Escherichia coli hydrogenase 2 (HYD2) have been cloned and sequenced. They occur in an operon (hyb) which contains seven open reading frames. An hyb deletion mutant (strain AP3) failed to grown on dihydrogen-fumarate medium and also produced very low levels of HYD1. All seven open reading frames are required for restoration of wild-type levels of active HYD2 in AP3. The hyb operon was mapped at 65 min on the E. coli chromosome.

Carboxy-terminal processing of the large subunit of [NiFe] hydrogenases

Two electrophoretic forms of the large subunit of the soluble periplasmic [NiFe] hydrogenase from Desulfovibrio gigas have been detected by Western analysis. The faster moving form co-migrates with the large subunit from purified, active enzyme. Amino acid sequence and composition of the C-terminal tryptic peptide of the large subunit from purified hydrogenase revealed that it is 15 amino acids shorter than that predicted by the nucleotide sequence. Processing of the nascent large subunit occurs by C-terminal cleavage between His536 and Val537, residues which are highly conserved among [NiFe] hydrogenases. Mutagenesis of the analogous residues, His582 and Val583, in the E. coli hydrogenase-1 (HYD1) large subunit resulted in significant decrease in processing and HYD1 activity.

Intimate relationships of the large and the small subunits of all nickel hydrogenases with two nuclear-encoded subunits of mitochondrial NADH: ubiquinone oxidoreductase

The sequence pattern CxxCxnGxCxxxGxmGCPP, thus far found in the small subunits from 21 different nickel hydrogenases, appears also to be present in the PSST polypeptide from NADH:ubiquinone oxidoreductase (Complex I) of beef-heart mitochondria. There is only one difference: the first cysteine residue is a leucine in the PSST subunit. The large nickel-binding subunit of nickel hydrogenases shows a surprising homology with the 49 kDa subunit of mitochondrial Complex I.

The Azotobacter chroococcum hydrogenase gene cluster: sequences and genetic analysis of four accessory genes, hupA, hupB, hupY and hupC

The Azotobacter chroococcum chromosome contains a region spanning about 14 kb associated with hydrogen-uptake (Hup) activity. The small and large subunits of the hydrogenase are encoded by the structural genes hupS and hupL. Two other genes, hupD and hupE, are located 8.9 kb downstream from hupL and are required for the formation of a catalytically active hydrogenase. In this study, we determined the nucleotide sequence of a 3.8-kb region immediately upstream from hupD. This revealed four additional closely linked ORFs which we designated hupA, hupB, hupY and hupC; these genes potentially encode polypeptides with predicted masses of 12.6, 33.3, 80.4 and 9.0 kDa, respectively. This cluster of genes was shown to be essential for hydrogenase activity by insertion mutagenesis using antibiotic-resistance gene cassettes and a Tn5 derivative carrying a promoterless lacZ gene. A 10.5-kb fragment of DNA beginning 3.4 kb downstream from hupL, and including the sequenced region, was able to complement hupA and hupY mutants, supporting earlier evidence for a promoter downstream from hupSL. The deduced amino acid sequences of hupA, hupB and hupC are homologous to the Escherichia coli hypA, hypB and hypC gene products, respectively. Of particular interest is the fact that there is no homologue of the hupY gene product in the E. coli hyp operon. Mutations in hupY or hupB had little effect on beta-galactosidase activity in a strain also carrying a hupL::lacZ fusion, showing that hupY and hupB are not major factors in regulating the transcription of the hydrogenase structural genes.

Microbial hydrogenases: primary structure, classification, signatures and phylogeny

Thirty sequenced microbial hydrogenases are classified into six classes according to sequence homologies, metal content and physiological function. The first class contains nine H2-uptake membrane-bound NiFe-hydrogenases from eight aerobic, facultative anaerobic and anaerobic bacteria. The second comprises four periplasmic and two membrane-bound H2-uptake NiFe(Se)-hydrogenases from sulphate-reducing bacteria. The third consists of four periplasmic Fe-hydrogenases from strict anaerobic bacteria. The fourth contains eight methyl-viologen- (MV), factor F420- (F420) or NAD-reducing soluble hydrogenases from methanobacteria and Alcaligenes eutrophusH16. The fifth is the H2-producing labile hydrogenase isoenzyme 3 of Escherichia coli. The sixth class contains two soluble tritium-exchange hydrogenases of cyanobacteria. The results of sequence comparison reveal that the 30 hydrogenases have evolved from at least three different ancestors. While those of class I, II, IV and V hydrogenases are homologous, i.e. sharing the same evolutionary origin, both class III and VI hydrogenases are neither related to each other nor to the other classes. Sequence comparison scores, hierarchical cluster structures and phylogenetic trees show that class II falls into two distinct clusters composed of NiFe- and NiFeSe-hydrogenases, respectively. These results also reveal that class IV comprises three distinct clusters: MV-reducing, F420-reducing and NAD-reducing hydrogenases. Specific signatures of the six classes of hydrogenases as well as some subclusters have been detected. Analyses of motif compositions indicate that all hydrogenases, except those of class VI, must contain some common motifs probably participating in the formation of hydrogen activation domains and electron transfer domains. The regions of hydrogen activation domains are highly conserved and can be divided into two categories. One corresponds to the 'nickel active center' of NiFe(Se)-hydrogenases. It consists of two possible specific nickel-binding motifs, RxCGxCxxxH and DPCxxCxxH, located at the N- and C-termini of so-called large subunits in the dimeric hydrogenases, respectively. The other is the H-cluster of the Fe-hydrogenases. It might comprise three motifs on the C-terminal half of the large subunits. However, the motifs corresponding to the putative electron transfer domains, as well as their polypeptides chains, are poorly or even not at all conserved. They are present essentially on the small subunits in NiFe-hydrogenases. Some of these motifs resemble the typical ferredoxin-like Fe-S cluster binding site.(ABSTRACT TRUNCATED AT 400 WORDS)

Organization of the genes necessary for hydrogenase expression in Rhodobacter capsulatus. Sequence analysis and identification of two hyp regulatory mutants

A 25 kbp DNA fragment from the chromosome of Rhodobacter capsulatus B10 carrying hydrogenase (hup) determinants was completely sequenced. Coding regions corresponding to 20 open reading frames were identified. The R. capsulatus hydrogenase-specific gene (hup and hyp) products bear significant structural identity to hydrogenase gene products from Escherichia coli (13), from Rhizobium leguminosarum (16), from Azotobacter vinelandii (10) and from Alcaligenes eutrophus (11). The sequential arrangement of the R. capsulatus genes is: hupR2-hupU-hypF-hupS-hupL-hupM-hu pD-hupF-hupG-hupH-hupJ-hupK-hypA- hypB-hupR1- hypC-hypD-hypE-ORF19-ORF20, all contiguous and transcribed from the same DNA strand. The last two potential genes do not encode products that are related to identified hydrogenase-specific gene products in other species. The sequence of the 12 R. capsulatus genes underlined above is presented. The mutation site in two of the Hup- mutants used in this study, RS13 and RCC12, was identified in the hypF gene (deletion of one G) and in the hypD gene (deletion of 54 bp), respectively. The hypF gene product shares 45% identity with the product of hydA from E. coli and the product of hypF from R. leguminosarum. Those products present at their N-terminus a Cys arrangement typical of zinc-finger proteins. The G deletion in the C-terminal region of hypF in the RS13 mutant prevented the expression of a hupS::lacZ translational fusion from being stimulated by H2 as it is observed in the wild-type strain B10. It is inferred that the HypF protein is a factor involved in H2 stimulation of hydrogenase expression.

A gene complex coding for the membrane-bound hydrogenase of Alcaligenes eutrophus H16

One of the key enzymes in the chemolithoautotrophic metabolism of Alcaligenes eutrophus H16 is a dimeric, membrane-associated hydrogenase. The genetic determinants of this enzyme are located on the endogenous megaplasmid pHG1 (G. Eberz, C. Hogrefe, C. Kortlüke, A. Kamienski, and B. Friedrich, J. Bacteriol. 168:636-641, 1986). Complementation studies showed that the information required for the formation of active membrane-bound hydrogenase occupies more than 7.5 kb of megaplasmid DNA. We cloned and sequenced this region and identified the genes encoding the two hydrogenase subunits (hoxK and hoxG). The nucleotide sequence contains nine additional closely spaced open reading frames. Immunoelectron microscopy showed that the gene product of one of these open reading frames (hoxM) is involved in the process leading to the attachment of hydrogenase to the membrane. Other open reading frames may encode additional processing functions and components of a hydrogenase-linked electron transport chain. Analysis of Tn5-B21-mediated transcriptional fusions provided evidence that the structural genes and accessory functions belong to at least three coordinately regulated transcriptional units.

Carboxyl-terminal processing may be essential for production of active NiFe hydrogenase in Azotobacter vinelandii

The NiFe hydrogenase from Azotobacter vinelandii is a membrane-bound alpha beta heterodimer that can oxidize H2 to protons and electrons and thereby provide energy. Genes encoding the alpha and beta subunits, hoxG and hoxK respectively, followed by thirteen contiguous accessory genes potentially involved in H2 oxidation, have been previously sequenced. Mutations in some of these accessory genes give rise to inactive enzyme containing an alpha subunit with decreased electrophoretic mobility. Mass spectral analysis of the subunits demonstrated that the alpha subunit had a molecular weight 1,663 Da less than that predicted from hoxG. Since the N-terminal sequence of the purified alpha subunit matches the sequence predicted from hoxG we suggest this difference is due to removal of the C-terminus of the alpha subunit which may be an important step linked to metal insertion, localization, and formation of active hydrogenase.

Nucleotide sequences and genetic analysis of hydrogen oxidation (hox) genes in Azotobacter vinelandii

Azotobacter vinelandii contains a heterodimeric, membrane-bound [NiFe]hydrogenase capable of catalyzing the reversible oxidation of H2. The beta and alpha subunits of the enzyme are encoded by the structural genes hoxK and hoxG, respectively, which appear to form part of an operon that contains at least one further potential gene (open reading frame 3 [ORF3]). In this study, determination of the nucleotide sequence of a region of 2,344 bp downstream of ORF3 revealed four additional closely spaced or overlapping ORFs. These ORFs, ORF4 through ORF7, potentially encode polypeptides with predicted masses of 22.8, 11.4, 16.3, and 31 kDa, respectively. Mutagenesis of the chromosome of A. vinelandii in the area sequenced was carried out by introduction of antibiotic resistance gene cassettes. Disruption of hoxK and hoxG by a kanamycin resistance gene abolished whole-cell hydrogenase activity coupled to O2 and led to loss of the hydrogenase alpha subunit. Insertional mutagenesis of ORF3 through ORF7 with a promoterless lacZ-Kmr cassette established that the region is transcriptionally active and involved in H2 oxidation. We propose to call ORF3 through ORF7 hoxZ, hoxM, hoxL, hoxO, and hoxQ, respectively. The predicted hox gene products resemble those encoded by genes from hydrogenase-related operons in other bacteria, including Escherichia coli and Alcaligenes eutrophus.

Identification of six open reading frames from a region of the Azotobacter vinelandii genome likely involved in dihydrogen metabolism

We reported earlier the identification of two Azotobacter vinelandii open reading frames (ORFs), ORF1 and ORF2, downstream from the hydrogenase structural genes (Chen, J.C. and Mortenson, L.E. (1992) Biochim. Biophys. Acta 1131, 122-124). Sequencing of 6008 base pairs of DNA immediately downstream from ORF2 revealed six additional ORFs (ORF3 through ORF8). All six ORFs are transcribed from the same DNA strand as that of the ORF1 and ORF2. Deduced amino acid sequences of ORF3 through ORF5, and those of ORF4, ORF5, ORF7 and ORF8 have strong homology with genes required for dihydrogen (H2) metabolism in Rhodobacter capsulatus and in Escherichia coli, respectively. ORF4, ORF5, ORF6 and ORF8 would encode for polypeptides containing one or more 'Cys-X-X-Cys' motifs. The predicted products of ORF5 and ORF6 each contain a histidine-rich region, and the product of ORF5 also includes a 'Cys-Thr-Val-Cys-Gly-Cys' region near its amino-terminus. Implications of these findings with respect to metal binding, transport and incorporation, to hydrogenase assembly and to H2 metabolism are discussed.

Incorporation of a bacterial membrane-bound hydrogenase into proteoliposomes

Membrane-bound nickel-iron hydrogenases from diverse genera of bacteria have been previously characterized and they are closely related. We report the reconstitution of purified Bradyrhizobium japonicum hydrogenase into proteoliposomes by a detergent dialysis method followed by two or three cycles of freeze-thaw. Sedimentation experiments revealed that more than 60% of the H2-uptake activity was particulate when reconstituted into Escherichia coli phospholipids. Sucrose-gradient centrifugation separated hydrogenase activity into two peaks, the less dense of which was phospholipid-associated and turbid, thereby showing successful incorporation. Purified enzyme did not bind to performed phospholipid vesicles, and 1.0 M NaCl failed to remove incorporated hydrogenase. The optimal micellar detergent:phospholipid ratio (rho) value for hydrogenase incorporation was 2.0. Proteoliposomes containing acidic phospholipids were the most effective for incorporation as well as for activity. The artificial electron acceptor specificity was similar for proteoliposomes and for H2-oxidizing membranes from B. japonicum. Proteoliposomes formed under optimal conditions had a broad size distribution centered around 400 nm diameter. Hydrogenase activity in proteoliposomes was partially protected from inactivation by the protein modification reagent diazobenzene sulfonate (DABS) (inactivation t1/2 = 30 min), whereas DABS rapidly inactivated the purified enzyme (t1/2 = 4 min). The latter result indicates protection of a catalytically important site by the phospholipid bilayer. This experimental system should be useful in addressing questions regarding the in vivo situation of bacterial membrane-bound hydrogenases.

Nucleotide sequence and characterization of four additional genes of the hydrogenase structural operon from Rhizobium leguminosarum bv. viciae

The nucleotide sequence of a 2.5-kbp region following the hydrogenase structural genes (hupSL) in the H2 uptake gene cluster from Rhizobium leguminosarum bv. viciae UPM791 was determined. Four closely linked genes encoding peptides of 27.9 (hupC), 22.1 (hupD), 19.0 (hupE), and 10.4 (hupF) kDa were identified immediately downstream of hupL. Proteins with comparable apparent molecular weights were detected by heterologous expression of these genes in Escherichia coli. The six genes, hupS to hupF, are arranged as an operon, and by mutant complementation analysis, it was shown that genes hupSLCD are cotranscribed. A transcription start site preceded by the -12 to -24 consensus sequence characteristic of NtrA-dependent promoters was identified upstream of hupS. On the basis of the lack of oxygen-dependent H2 uptake activity of a hupC::Tn5 mutant and on structural characteristics of the protein, we postulate that HupC is a b-type cytochrome involved in electron transfer from hydrogenase to oxygen. The product from hupE, which is needed for full hydrogenase activity, exhibited characteristics typical of a membrane protein. The features of HupC and HupE suggest that they form, together with the hydrogenase itself, a membrane-bound protein complex involved in hydrogen oxidation.

The quinone-reactive Ni/Fe-hydrogenase of Wolinella succinogenes

The hydrogenase (Hyd) isolated from the cytoplasmic membrane of Wolinella succinogenes consists of three polypeptides (HydA, HydB and HydC) and contains cytochrome b (6.4 mumol/g protein), which was reduced upon the addition of H2. The enzyme catalyzed the reduction of 2,3-dimethyl-1,4-naphthoquinone with H2, in contrast to an earlier preparation which was made up of HydA and HydB only and did not contain cytochrome b (Unden, G., Böcher, R., Knecht, J. & Kröger, A. (1982) FEBS Lett. 145, 230-234). This suggests that HydC is a cytochrome b which serves as a mediator in the electron transfer from H2 to the quinone. The hydrogenase genes were cloned, sequenced and identified by sequence comparison with the N-termini of the three subunits. The three genes were arranged in the order hydA, hydB, hydC, with the transcription start site in front of hydA, and were present only once on the genome. Separated by an intergene region of 69 nucleotides, hydC was followed by at least two more open reading frames of unknown function. The amino acid sequences derived from hydA, hydB and hydC were similar to those of the membrane Ni-hydrogenases of seven other bacteria. HydA and HydB also showed similarity to the small and the large subunits of periplasmic Ni-hydrogenases. HydC was predicted to contain four hydrophobic segments which might span the bacterial membrane. Two histidine residues located in hydrophobic segments are conserved in the corresponding sequences of the other membrane hydrogenases and might ligate the haem B.

Two open reading frames (ORFs) identified near the hydrogenase structural genes in Azotobacter vinelandii, the first ORF may encode for a polypeptide similar to rubredoxins

Sequencing of 744 base pairs (bp) of a cloned section of DNA from Azotobacter vinelandii reveals two complete, closely-spaced open reading frames (ORF1 and ORF2). Both ORFs are transcribed from the same DNA strand as that of the structural genes for hydrogenase (hoxK and hoxG, Menon, A.L. et al. (1990) Gene 96, 67-74), and are located downstream from the latter genes. The distance between the end of hoxG and the beginning of ORF1 is approx. 3.0 kilobases (kb). Most of the deduced amino acid sequence of ORF1 shares high homology with rubredoxin sequences. Some of the deduced amino acid sequence of ORF2 shares homology with that of a reported partial ORF from Rhodobacter capsulatus, ORF located within a region of DNA required for dihydrogen oxidation in that organism. Implications of these findings with respect to dihydrogen metabolism are discussed.

Purification and properties of a F420-nonreactive, membrane-bound hydrogenase from Methanosarcina strain Gö1

The distribution of the F420-reactive and F420-nonreactive hydrogenases from the methylotrophic Methanosarcina strain Gö1 indicated a membrane association of the F420-nonreactive enzyme. The membrane-bound F420-nonreactive hydrogenase was purified 42-fold to electrophoretic homogeneity with a yield of 26.7%. The enzyme had a specific activity of 359 mumol H2 oxidized.min-1.mg protein-1. The purification procedure involved dispersion of the membrane fraction with the detergent Chaps followed by anion exchange, hydrophobic and hydroxylapatite chromatography. The aerobically prepared enzyme had to be reactivated anaerobically. Maximal activity was observed at 80 degrees C. The molecular mass as determined by native gel electrophoresis and gel filtration was 77,000 and 79,000, respectively. SDS gel electrophoresis revealed two polypeptides with molecular masses of 60,000 and 40,000 indicating a 1:1 stoichiometry. The purified enzyme contained 13.3 mol S2-, 15.1 mol Fe and 0.8 mol Ni/mol enzyme. Flavins were not detected. The amino acid sequence of the N-termini of the subunits showed a higher degree of homology to eubacterial uptake-hydrogenases than to F420-dependent hydrogenases from other methanogenic bacteria. The physiological function of the F420-nonreactive hydrogenase from Methanosarcina strain Göl is discussed.

Structure-function relationships among the nickel-containing hydrogenases

The enzymology of the heterodimeric (NiFe) and (NiFeSe) hydrogenases, the monomeric nickel-containing hydrogenases plus the multimeric F420-(NiFe) and NAD(+)-(NiFe) hydrogenases are summarized and discussed in terms of subunit localization of the redox-active nickel and non-heme iron clusters. It is proposed that nickel is ligated solely by amino acid residues of the large subunit and that the non-heme iron clusters are ligated by other cysteine-rich polypeptides encoded in the hydrogenase operons which are not necessarily homologous in either structure or function. Comparison of the hydrogenase operons or putative operons and their hydrogenase genes indicate that the arrangement, number and types of genes in these operons are not conserved among the various types of hydrogenases except for the gene encoding the large subunit. Thus, the presence of the gene for the large subunit is the sole feature common to all known nickel-containing hydrogenases and unites these hydrogenases into a large but diverse gene family. Although the different genes for the large subunits may possess only nominal general derived amino acid homology, all large subunit genes sequenced to date have the sequence R-X-C-X-X-C fully conserved in the amino terminal region of the polypeptide chain and the sequence of D-P-C-X-X-C fully conserved in the carboxyl terminal region. It is proposed that these conserved motifs of amino acids provide the ligands required for the binding of the redox-active nickel. The existing EXAFS (Extended X-ray Absorption Fine Structure) information is summarized and discussed in terms of the numbers and types of ligands to the nickel and the various redox species of nickel defined by EPR spectroscopy. New information concerning the ligands to nickel is presented based on site-directed mutagenesis of the gene encoding the large subunit of the (NiFe) hydrogenase-1 of Escherichia coli. Based on considerations of the biochemical, molecular and biophysical information, ligand environments of the nickel in different redox states of the (NiFe) hydrogenase are proposed.

Primary structure of hydrogenase I from Clostridium pasteurianum

Peptides obtained by cleavage of Clostridium pasteurianum hydrogenase I have been sequenced. The data allowed design of oligonucleotide probes which were used to clone a 2310-bp Sau3A fragment containing the hydrogenase encoding gene. The latter has been sequenced and was found to translate into a protein composed of 574 amino acids (Mr = 63,836), including 22 cysteines. C. pasteurianum hydrogenase is homologous to, but longer than, the large subunit of Desulfovibrio vulgaris (Hildenborough) [Fe] hydrogenase. It includes an additional N-terminal domain of ca. 110 amino acids which contains eight cysteine residues and which therefore could accommodate two of its postulated four [4Fe-4S] clusters. C. pasteurianum hydrogenase is most similar in length, cysteine positions, and sequence altogether to the translation product of a putative hydrogenase encoding gene from D. vulgaris (Hildenborough). Comparisons of the available [Fe] hydrogenase sequences show that these enzymes constitute a structurally rather homogeneous family. While they differ in the length of their N-termini and in the number of their [4Fe-4S] clusters, they are highly similar in their C-terminal halves, which are postulated to harbor the hydrogen-activating H cluster. Five conserved cysteine residues occurring in this domain are likely ligands of the H cluster. Possible ligation by other residues, and in particular by methionine, is discussed. The comparisons carried out here show that the H clusters most probably possess a common structural framework in all [Fe] hydrogenases. On the basis of the available data on these proteins and on the current developments in iron-sulfur chemistry, the H clusters possibly contain six to eight iron atoms.(ABSTRACT TRUNCATED AT 250 WORDS)

Cloning and nucleotide sequence of the structural genes encoding the formate dehydrogenase of Wolinella succinogenes

The formate dehydrogenase of Wolinella succinogenes is a membraneous molybdo-enzyme which is involved in phosphorylative electron transport. The gene (fdhA) encoding the largest subunit was isolated from a gene bank by immunological screening. The fdhA gene was located in an apparent transcriptional unit (fdhA,B,C,D) together with three more structural genes. The N-terminal sequences of three polypeptides present in the isolated enzyme were found to map within the fdhA, B and C structural genes. A polypeptide corresponding to fdhD was not detected in the enzyme preparation. This suggested that the functional formate dehydrogenase was made up of three or four different subunits. The genes fdhA and C encode larger preproteins which differ from the corresponding mature proteins by N-terminal signal peptides. The N-terminal half of the mature FdhA is homologous to the larger subunits of the formate dehydrogenases of E. coli (formate-hydrogenlyase linked) and Methanobacterium formicicum as well as to three bacterial reductases containing molybdenum. It harbours a conserved cysteine cluster and two more domains which may be involved in binding the molybdenum cofactor. FdhB may represent an iron-sulphur protein, twelve cysteine residues of which are arranged in two clusters which are typical of ligands of the iron-sulfur centers in ferredoxins. FdhC is a hydrophobic protein with four predicted transmembrane segments, which appears to be identical with the cytochrome b present in the isolated formate dehydrogenase. It may form the membrane anchor of the enzyme and react with the bacterial menaquinone.

Mutational analysis and characterization of the Escherichia coli hya operon, which encodes [NiFe] hydrogenase 1

Deletion mutants of Escherichia coli specific for hydrogenase isoenzyme 1 (HYD1) have been constructed and characterized. The hya operon, which contains genes for the two HYD1 structural subunits and four additional genes, was mapped at 22 min on the E. coli chromosome. The total hydrogenase activities of the HYD1-negative mutant and wild-type strains were similar. However, the formate dehydrogenase activity associated with the formate hydrogen lyase pathway was lower in the mutant. The hya mutant (strain AP1), complemented with only the hydrogenase structural genes (hyaAB), produced antigenically identifiable but inactive HYD1 protein. The first five genes of hya (hyaA to hyaE) were required for the synthesis of active HYD1, but wild-type levels of HYD1 activity were restored only when mutant cells were transformed with all six genes of the operon. When AP1 was complemented with hya carried on a high-copy-number plasmid, the HYD1 structural subunits were overexpressed, but the excess protein was unprocessed and localized in the soluble fraction of the cell. The products of hyaDEF are postulated to be involved in the processing of nascent structural subunits (HYAA and HYAB). This processing takes place only after the subunits are inserted into the cell membrane. It is concluded that the biosynthesis of active HYD1 is a complex biochemical process involving the cellular localization and processing of nascent structural subunits, which are in turn dependent on the insertion of nickel into the nascent HYD1 large subunit.

Aerobically purified hydrogenase from Azotobacter vinelandii: activity, activation, and spectral properties

The hydrogenase from Azotobacter vinelandii is typically purified under anaerobic conditions. In this work, the hydrogenase was purified aerobically. The yields were low (about 2%) relative to those of the anaerobic purification (about 20%). The rate of enzyme activity depended upon the history of the enzyme. The enzyme preparations were active as isolated in H2 oxidation, and isotope exchange. The activity increased during the assay to a new maximal level (turnover activation). Treatment with reductants (e.g., H2, dithionite, dithiothreitol, indigo carmine) resulted in greater activation (reductant activation). Activation of the hydrogenase was accompanied by decrease in visible light absorption (300-600 nm) with maximal decreases at 450 and 345 nm which indicated the reduction of iron-sulfur clusters. The aerobically purified hydrogenase was susceptible to irreversible inactivation by cyanide. Pretreatment with acetylene did not influence activation of the hydrogenase. Once activated, the aerobically purified hydrogenase was indistinguishable from the anaerobically purified hydrogenase with respect to the catalytic properties tested.