Mutants of Rhizobium japonicum with Increased Hydrogenase Activity.

Some strains of Rhizobium japonicum can use hydrogen as an energy source for growth under microaerophilic conditions. Mutant strains have been selected that use hydrogen in the presence of high partial pressures of oxygen. The mutants contain more hydrogenase than the parent strain, both as free-living cells and as bacteroids in nitrogen-fixing soybean root nodules.

Mutant Strains of Rhizobium japonicum with Increased Ability to Fix Nitrogen for Soybean.

A strain of Rhizobium japonicum used in commercial inoculants was mutagenized and screened by a rapid effectiveness assay with soybean plants. Two mutant strains nodulated the roots earlier than the wild type and also expressed greater symbiotic nitrogen-fixing activity than the wild type in the presence and absence of fixed nitrogen. In addition, one of the mutants formed more root nodules than the wild type. Plants inoculated with these strains had increased dry weights ( approximately 60 percent) and nitrogen content ( approximately 100 percent) when grown in growth chambers.

Intergeneric transfer of genes involved in the Rhizobium-legume symbiosis.

Genes that seem to be involved in the initial steps of infection of a legume by Rhizobium have been transferred, by transformation, to mutant strains of Azotobacter vinelandii that are unable to fix nitrogen. These genes code for a surface antigen that binds specifically to a protein from the host plant.

Hydrogenase in Rhizobium japonicum Increases Nitrogen Fixation by Nodulated Soybeans.

Some Rhizobium strains synthesize a unidirectional hydrogenase system in legume nodule bacteroids; this system participates in the recycling of hydrogen that otherwise would be lost as a by-product of the nitrogen fixation process. Soybeans inoculated with Rhizobium japonicum strains that synthesized the hydrogenase system fixed significantly more nitrogen and produced greater yields than plants inoculated with strains lacking hydrogen-uptake capacity. Rhizobium strains used as inocula for legumes should have the capability to synthesize the hydrogenase system as one of their desirable characteristics.

Chlorpromazine inhibition of electron transport in Azotobacter vinelandii membranes.

Chlorpromazine was a potent inhibitor of O2-dependent malate oxidation, but not of H2 oxidation in Azotobacter vinelandii membranes. However, chlorpromazine did not significantly affect the activity of malate reductase or the reduction of cytochromes c and d. In the presence of chlorpromazine, cytochrome o failed to form a complex with CO. The site of action of chlorpromazine seems to be in the cytochromes c to cytochrome o branch, the pathway utilized by malate, succinate and NADH, but not by H2.

Nucleotide sequences of two hydrogenase-related genes (hypA and hypB) from Bradyrhizobium japonicum, one of which (hypB) encodes an extremely histidine-rich region and guanine nucleotide-binding domains.

Sequencing of a 1359-bp (NruI-AccI) DNA fragment located approximately 5.2 kb downstream from the end of the hydrogenase structural genes of Bradyrhizobium japonicum revealed two open reading frames designated hypA and hypB, encoding polypeptides with predicted molecular masses of 12.3 and 32.8 kDa, respectively. Both hypA and hypB showed strong homology with other genes in hydrogenase-containing bacteria. Two 'C-X-X-C' motifs were contained in the deduced amino acid sequence of hypA, a motif that is present in all known products homologous to HypA. The deduced product of hypB contains an area remarkably rich in histidine residues at the N-terminus (24 histidines within a 39 amino acid stretch). The deduced HypB also contains GTP-binding domains. We postulate that the product of hypB is involved in nickel binding and accumulation, and may utilize energy (GTP) to mobilize nickel for its subsequent incorporation into hydrogenase.

Purification and characterization of an O2-utilizing cytochrome-c oxidase complex from Bradyrhizobium japonicum bacteroid membranes.

A cytochrome-c (cyt c) oxidase supercomplex consisting of 7-8 subunits and possessing a mass of 358-425 kDa was purified from Bradyrhizobium japonicum bacteroid membranes. At least two subunits possess c-type heme as a prosthetic group. One of the c-heme-containing components was detected in bacteroid membranes, but not in free-living cells. The complex also contains b-heme, and both b-type and c-type heme proteins were spectrophotometrically shown to form complexes with carbon monoxide. A CO difference spectrum showed an absorption minimum (trough) at 551.7 nm, possibly corresponding to a previously described cyt c-552 in bacteroid membranes. 1 mM quinacrine (Atebrin) had no effect on O2 uptake by the cytochrome-c oxidase complex, but 10 mM inhibited O2 uptake by 90%. Cytochromes b and c1 of the cytochrome bc1 respiratory complex were identified as two of the components of the bacteroid complex based upon immunoreaction with antibodies against these two proteins from B. japonicum. The oxidase complex oxidized exogenously added horse heart ferrocytochrome c concomitant with the uptake of oxygen. It could also oxidize the artificial electron donor N,N,N',N'-tetramethyl-p-phenylenediamine in the absence of added cytochrome c. Oxygen uptake activity was completely inhibited by 10 microM NaCN and 38% by 0.1 microM NaCN. The oxidase complex was not able to oxidize a ubiquinol homolog possessing a single isoprenoid unit side chain. Solubilization of bacteroid membranes in the presence of 1.0 mM EDTA resulted in complete loss of cytochrome-c oxidase activity. Leghemoglobin deoxygenation data indicated that the oxidase complex can efficiently function at free oxygen concentrations well below 1.0 microM, even though attempts to determine the oxidase's specific affinity oxygen were unsuccessful due to the formation of oxidized leghemoglobin derivatives.

Bradhyrhizobium japonicum hydrogen-ubiquinone oxidoreductase activity: quinone specificity, inhibition by quinone analogs, and evidence for separate sites of electron acceptor reactivity.

The purified H2-uptake hydrogenase of Bradyrhizobium japonicum, containing no cytochrome b, catalyzed efficient H2-ubiquinone oxidoreductase activity. Hydrogen-oxidizing membranes also catalyzed H2-ubiquinone oxidoreductase activity, and the site of ubiquinone reduction was localized to the He-quinone oxidoreductase complex based on comparative antimycin A and HQNO titrations of both H2-ubiquinone-1 oxidoreductase and ubiquinol-1 oxidase activities. A variety of quinones could function as electron acceptors of both pure or membrane-bound hydrogenase, including ubiquinone-0 (Q0), ubiquinone-1 (Q1), duroquinone and menadione, indicating relatively loose substrate specificity with regard to the quinone head group. Both the redox potential and the quinone structure determined the efficiency of hydrogenase turnover. Among short-chain ubiquinones, the isoprenoid chain length had a profound affect on Kin, with each additional isoprenoid unit resulting in the K m of the membrane-bound enzyme to decrease more than an order of magnitude. For pure enzyme, the K m values for Q0, Q1 and Q2 were 1.97 mM, 68.8 /xM and 3.1 /~M, respectively. Vma x was also influenced by the substrate isoprenoid chain length for the pure enzyme. The inhibition patterns of H2-dependent Q1 versus MB reduction by the quinone analogs (2-n-heptyl-4-hydroxyquinoline N-oxide and Antimycin A) were significantly different, and clear differences in pH optima for the two activities were observed. In addition, the two hydrogen-dependent electron acceptor activities (Q1 and MB) exhibited different time-dependent inactivation patterns by the chemical modification reagent diazobenzene sulfonate. Ubiquinone and MB therefore react by different mechanisms (perhaps at different sites) within the hydrogenase complex in situ. The inhibition pattern of hydrogen-ubiquinone oxidoreductase activity by antimycin A was clearly different than antimycin A inhibition of ubiquinol oxidation at the bc1 complex. This is, to our knowledge, the first report of antimycin A inhibition of a hydrogenase complex, and also of a quinone reducing site of a primary dehydrogenase. When pure hydrogenase is assayed in the absence of dithionite, a delay (lag phase) is observed prior to attainment of full activity. The length of this lag period (in minutes) was inversely dependent on ubiquinone concentration, and was greatly reduced (but not eliminated) at saturating ubiquinone levels. These effects were obtained with both Q1 and MB as electron acceptor, and the lag phases with Q1 were significantly longer than with MB. Electron acceptor binding to hydrogenase is thus required for reductive activation of hydrogenase during turnover.

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.

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.

Sequence and characterization of three genes within the hydrogenase gene cluster of Bradyrhizobium japonicum.

A 2.0-kb DNA fragment downstream from the hydrogenase-encoding structural genes within the hydrogenase gene cluster of Bradyrhizobium japonicum was sequenced. Analysis of the nucleotide (nt) sequence revealed three open reading frames (ORFs), designated hupC, hupD and hupF, which encode polypeptides of 28, 21 and 10.7 kDa, respectively. Based on analysis of the nt sequence and physiological studies, hupSL (hydrogenase structural genes) and hupCDF are organized as a single transcriptional unit. Plasmid pRY12 carrying hupSL genes did not complement (restore) hydrogenase activity of the hupSL deletion mutant strain (JHCS2), whereas the activity of the mutant was considerably restored by pLD22 harboring the entire hydrogenase operon (hupSLCDF genes). Western blots revealed a very low level of hydrogenase protein in JHCS2 containing pRY12. The results suggest that the products of the hupCDF genes may be involved in either stabilizing the hydrogenase peptides (i.e., from degradation) or in post-translational regulation of hydrogenase production. The products of hupC and hupD were successfully expressed in Escherichia coli by a phage T7 promoter system, although the apparent sizes of the gene products were slightly larger than those calculated from the deduced amino-acid sequences.

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.

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.

Genetic evidence for a fourth terminal oxidase in Bradyrhizobium japonicum.

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. Several genes encoding terminal oxidases from B. japonicum have been cloned, but it is unknown what roles these individual oxidases play. In this paper, we describe the cloning and sequencing of the coxX gene encoding the large catalytic subunit for a fourth terminal oxidase from B. japonicum. The coxX gene encodes a 666-amino-acid (aa) protein (M(r) 74,527) that exhibits a high degree of homology to terminal oxidase proteins from a number of prokaryotic and eukaryotic species. This new oxidase exhibits greater homology to the Escherichia coli cytochrome o subunit I than any of the previously reported B. japonicum terminal oxidase genes.

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.

Hydrogen-ubiquinone oxidoreductase activity by the Bradyrhizobium japonicum membrane-bound hydrogenase.

The Bradyrhizobium japonicum heterodimeric nickel-iron hydrogenase efficiently catalyzed H2-ubiquinone-1 oxidoreductase activity at rates up to 47% of the maximal rates obtained using the artificial electron acceptor methylene blue. Gel filtration chromatography and SDS-polyacrylamide gel electrophoresis experiments demonstrated that the purified enzyme was a heterodimer containing only the 65 kDa and 33 kDa subunits. Reduced minus oxidized absorption difference spectra demonstrated the absence of detectable cytochromes. The H2-ubiquinone-1 oxidoreductase activity of both the purified heterodimeric hydrogenase and membranes was significantly inhibited by 2-n-heptyl-4-hydroxyquinoline-N-oxide and antimycin A, inhibitors known to act in the quinone region of electron transport chains. Our results are the first report of H2-ubiquinone oxidoreductase activity by a purified hydrogenase.

Rapid and efficient selection of recombinant site-directed mutants of Bradyrhizobium japonicum by colony hybridization.

Due to the high incidence of spontaneous antibiotic resistance and slow growth of Bradyrhizobium japonicum strains, screening for site-directed mutants is cumbersome and time-consuming. A rapid method for selection of recombinant site-directed mutants of B. japonicum was developed. A kanamycin (Km) and a spectinomycin (Sp) cassette were each used to replace DNA fragments in the chromosome by homologous recombination. The primary new features of this method involve a simple plate selection for the antibiotic (Km or Sp) resistant mutants, then colony streaking, and lysis for DNA hybridization on a nitrocellulose filter enabling direct identification of the recombinant site-directed mutants. This method has permitted us to quickly and easily identify a large number of positive recombinant mutants from a large number of individual colonies. The procedure eliminates the need to first isolate genomic DNA from each mutant for Southern hybridization. All of the tested site-directed mutants from this method were confirmed to exhibit the expected mutant phenotype.

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.