A lysR-type regulator is involved in the negative regulation of genes encoding selenium-free hydrogenases in the archaeon Methanococcus voltae

The archaeon Methanococcus voltae encodes two pairs of NiFe-hydrogenase isoenzymes. One hydrogenase of each pair contains selenium in the active site, whereas the other one is selenium-free. The gene groups for the selenium-free hydrogenases, called vhc and frc, are linked by a common intergenic region. They are only transcribed under selenium limitation. A protein binding to a negative regulatory element involved in the regulation of the two operons was purified by DNA-affinity chromatography. Through the identification of the corresponding gene the protein was found to be a LysR-type regulator. It was named HrsM (hydrogenase gene regulator, selenium dependent in M. voltae). hrsM knockout mutants constitutively transcribed the vhc and frc operons in the presence of selenium. A putative HrsM binding site was also detected in the intergenic region in front of the hrsM gene. Northern blot analysis indicated that the hrsM gene might be autoregulated.     

Construction of an integration vector for use in the archaebacterium Methanococcus voltae and expression of a eubacterial resistance gene

Summary An integration vector for use in Methanococcus voltae was constructed, based on the Escherichia coli vector pUC18. It carries the structural gene for puromycin transacetylase from Streptomyces alboniger, which is flanked by expression signals of M. voltae structural genes and hisA gene sequences of this bacterium. Transformed M. voltae cells are puromycin resistant. Several types of integration of the vector into the chromosome were found. Only one case was due to nonhomologous recombination. The integrated sequences were stable under selective pressure but were slowly lost in some cases in the absence of the selective drug. The vector could be excised from M. voltae chromosomal DNA, recircularized and transformed back into E. coli.The order of the other authors is not indicative of the relative importance of their experimental contributions which are considered to be equivalentWe mourn the loss of our colleague and friend Lionel Sibold, who died while this work was still in progress     

A pseudo-SECIS element in <Emphasis Type="Italic">Methanococcus voltae</Emphasis> documents evolution of a selenoprotein into a sulphur-containing homologue

Methanococcus maripaludis possesses two sets of F₄₂₀-non-reducing hydrogenases which are differentially expressed in response to the selenium content of the medium. One of the subunits of the selenium-containing hydrogenase, VhuD, contains two selenocysteine residues, whereas the homologue of M. voltae possesses cysteine residues in the equivalent positions. Analysis of the 3 non-translated region of the M. voltae vhuD mRNA revealed the existence of a structure resembling the consensus of archaeal SECIS elements but with deviations rendering it non-functional in determining selenocysteine insertion. The presence of a pseudo-SECIS element in the 3 non-translated region of the vhuD mRNA from M. voltae suggests that VhuD from this organism has developed from a selenocysteine-containing ancestor. The 3 non-translated region from the VhcD homologues neither contained a SECIS nor a pseudo SECIS element.     

Localization of the F420-reducing hydrogenase in Methanococcus voltae cells by immuno-gold technique

The F₄₂₀-reducing hydrogenase of Methanococcus voltae, which takes part in the terminal reduction step of methanogenesis, was localized in situ in ultrathin sections. This result was obtained by the immuno-gold technique using a high titer antiserum raised against the purified enzyme. Its specifity for the hydrogenase was shown by Western blot analysis. The hydrogenase of M. voltae was found to be membrane-associated.Abbreviations ELISA Enzyme linked immuno sorbent assay - F₄₂₀ 8-hydroxy-5-deazaflavin     

hoxX (hypX) is a functional member of the Alcaligenes eutrophus hyp gene cluster

The role of HoxX in hydrogenase biosynthesis of Alcaligenes eutrophus H16 was re-examined. The previously characterized hoxX deletion mutant HF344 and a newly constructed second hoxX mutant carrying a smaller in-frame deletion were studied. The second mutant was impaired in the activity of both the soluble and the membrane-bound hydrogenase. The two hydrogenase activities were reduced by approximately 50% due to delayed processing of the active-site-containing large subunits, while hydrogenase gene expression was not affected. We conclude that the mutation in mutant HF344 causes polarity resulting in the observed regulatory phenotype of this mutant. The data presented in this report point to an enhancing function of HoxX in the conversion of the soluble hydrogenase and of the membrane-bound hydrogenase large-subunit precursor. Thus, hoxX encodes a member of the Hyp proteins that are required for the formation of active hydrogenase and was accordingly renamed hypX. Received: 15 June 1998 / Accepted: 5 August 1998     

VhuD Facilitates Electron Flow from H2 or Formate to Heterodisulfide Reductase in Methanococcus maripaludis

Flavin-based electron bifurcation has recently been characterized as an essential energy conservation mechanism that is utilized by hydrogenotrophic methanogenic Archaea to generate low-potential electrons in an ATP-independent manner. Electron bifurcation likely takes place at the flavin associated with the α subunit of heterodisulfide reductase (HdrA). In Methanococcus maripaludis the electrons for this reaction come from either formate or H₂ via formate dehydrogenase (Fdh) or Hdr-associated hydrogenase (Vhu). However, how these enzymes bind to HdrA to deliver electrons is unknown. Here, we present evidence that the δ subunit of hydrogenase (VhuD) is central to the interaction of both enzymes with HdrA. When M. maripaludis is grown under conditions where both Fdh and Vhu are expressed, these enzymes compete for binding to VhuD, which in turn binds to HdrA. Under these conditions, both enzymes are fully functional and are bound to VhuD in substoichiometric quantities. We also show that Fdh copurifies specifically with VhuD in the absence of other hydrogenase subunits. Surprisingly, in the absence of Vhu, growth on hydrogen still occurs; we show that this involves F₄₂₀-reducing hydrogenase. The data presented here represent an initial characterization of specific protein interactions centered on Hdr in a hydrogenotrophic methanogen that utilizes multiple electron donors for growth.     

Membrane-bound F420H2-dependent heterodisulfide reduction in Methanococcus voltae

Washed membranes prepared from H₂+CO₂- or formate-grown cells of Methanococcus voltae catalyzed the oxidation of coenzyme F₄₂₀H₂ and the reduction of the heterodisulfide (CoB–S–S–CoM) of 2-mercaptoethanesulfonate and 7-mercaptoheptanoylthreonine phosphate, which is the terminal electron acceptor of the methanogenic pathway. The reaction followed a 1:1 stoichiometry according to the equation: F₄₂₀H₂ + COB–S–S–CoM → F₄₂₀ + CoM–SH + CoB–SH. These findings indicate that the reaction depends on a membrane-bound F₄₂₀H₂-oxidizing enzyme and on the heterodisulfide reductase, which remains partly membrane-bound after cell lysis. To elucidate the nature of the F₄₂₀H₂-oxidizing protein, washed membranes were solubilized with detergent, and the enzyme was purified by sucrose density centrifugation, anion-exchange chromatography, and gel filtration. Several lines of evidence indicate that F₄₂₀H₂ oxidation is catalyzed by a membrane-associated F₄₂₀-reducing hydrogenase. The purified protein catalyzed the H₂-dependent reduction of methyl viologen and F₄₂₀. The apparent molecular mass and the subunit composition (43, 37, and 27 kDa) are almost identical to those of the F₄₂₀-reducing hydrogenase that has already been purified from Mc. voltae. Moreover, the N-terminus of the 37-kDa subunit is identical to the amino acid sequence deduced from the fruG gene of the operon encoding the selenium-containing F₄₂₀-reducing hydrogenase from Mc. voltae. A distinct F₄₂₀H₂ dehydrogenase, which is present in methylotrophic methanogens, was not found in this organism. Received: 18 September 1998 / Accepted: 2 November 1998     

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 (JHΔEg) which lacked hydrogenase activity under all conditions tested, including the situation as bacteroids from soybean nodules. Mutant strain JHΔ23H 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 JHΔ23H 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 μM 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 μM 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 JHΔ23H 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.     

Flagellin genes of Methanococcus vannielii : amplification by the Polymerase Chain Reaction, demonstration of signal peptides and identification of major components of the flagellar filament

The highly conserved nature of the 5′-termini of all archaeal flagellin genes was exploited by polymerase chain reaction (PCR) techniques to amplify the sequence of a portion of a flagellin gene family from the archaeon Methanococcus vannielii. Subsequent inverse PCR experiments generated fragments that permitted the sequencing of a total of three flagellin genes, which, by comparison with flagellin genes that have been sequenced, from other archaea appear to be equivalent to flaB1, flaB2, and flaB3 of M. voltae. Analysis of purified M. vannielii flagellar filaments by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) revealed two major flagellins (M_r= 30 800 and 28 600), whose N-terminal sequences identified them as the products of the flaB1 and flaB2 genes, respectively. The gene product of flaB3 could not be detected in flagellar filaments by SDS-PAGE. The protein sequence data, coupled with the DNA sequences, demonstrated that both FlaB1 and FlaB2 flagellins are translated with a 12-amino acid signal peptide which is absent from the mature protein incorporated into the flagellar filament. These data suggest that archaeal flagellin export differs significantly from that of bacterial flagellins. Received: 27 November 1997 / Accepted: 19 March 1998     

Cloning and characterization of archaeal type I signal peptidase from Methanococcus voltae

Archaeal protein trafficking is a poorly characterized process. While putative type I signal peptidase genes have been identified in sequenced genomes for many archaea, no biochemical data have been presented to confirm that the gene product possesses signal peptidase activity. In this study, the putative type I signal peptidase gene in Methanococcus voltae was cloned and overexpressed in Escherichia coli, the membranes of which were used as the enzyme source in an in vitro peptidase assay. A truncated, His-tagged form of the M. voltae S-layer protein was generated for use as the substrate to monitor the signal peptidase activity. With M. voltae membranes as the enzyme source, signal peptidase activity in vitro was optimal between 30 and 40°C; it was dependent on a low concentration of KCl or NaCl but was effective over a broad concentration range up to 1 M. Processing of the M. voltae S-layer protein at the predicted cleavage site (confirmed by N-terminal sequencing) was demonstrated with the overexpressed archaeal gene product. Although E. coli signal peptidase was able to correctly process the signal peptide during overexpression of the M. voltae S-layer protein in vivo, the contribution of the E. coli signal peptidase to cleavage of the substrate in the in vitro assay was minimal since E. coli membranes alone did not show significant activity towards the S-layer substrate in in vitro assays. In addition, when the peptidase assays were performed in 1 M NaCl (a previously reported inhibitory condition for E. coli signal peptidase I), efficient processing of the substrate was observed only when the E. coli membranes contained overexpressed M. voltae signal peptidase. This is the first proof of expressed type I signal peptidase activity from a specific archaeal gene product.     

Paucity of the Sau3AI recognition sequence (GATC) in the genome of Methanococcus voltae

Summary High molecular weight genomic DNA isolated from the archaebacterium Methanococcus voltae by alkaline-SDS lysis was not effectively digested with the restriction enzyme Sau3AI, which recognizes the base sequence GATC. Mc. voltae DNA was also resistant to digestion by MboI and BamHI which recognize sites containing the same GATC sequence. Examination of a Mc. voltae genomic library prepared in Escherichia coli JM83 with a pUC vector revealed that the 5–10 kb inserts were still resistant to Sau3AI digestion, indicating a likely lack of the GATC sequence in Mc. voltae DNA.     

AglC and AglK are involved in biosynthesis and attachment of diacetylated glucuronic acid to the N-glycan in Methanococcus voltae

Recent advances in the field of prokaryotic N-glycosylation have established a foundation for the pathways and proteins involved in this important posttranslational protein modification process. To continue the study of the Methanococcus voltae N-glycosylation pathway, characteristics of known eukaryotic, bacterial, and archaeal proteins involved in the N-glycosylation process were examined and used to select candidate M. voltae genes for investigation as potential glycosyl transferase and flippase components. The targeted genes were knocked out via linear gene replacement, and the resulting effects on N-glycan assembly were identified through flagellin and surface (S) layer protein glycosylation defects. This study reports the finding that deletion of two putative M. voltae glycosyl transferase genes, designated aglC (for archaeal glycosylation) and aglK, interfered with proper N-glycosylation. This resulted in flagellin and S-layer proteins with significantly reduced apparent molecular masses, loss of flagellar assembly, and absence of glycan attachment. Given previous knowledge of both the N-glycosylation pathway in M. voltae and the general characteristics of N-glycosylation components, it appears that AglC and AglK are involved in the biosynthesis or transfer of diacetylated glucuronic acid within the glycan structure. In addition, a knockout of the putative flippase candidate gene (Mv891) had no effect on N-glycosylation but did result in the production of giant cells with diameters three to four times that of wild-type cells.     

Degradation of trichloroethylene by a growth-arrestedPseudomonas putida

A toluene-oxidizing strain ofPseudomonas mendocina KR1 containing toluene-4-mono-oxygenase (TMO) completely degrades TCE with the addition of toluene as a co-substrate in aerobic condition. In order to constructin situ bioremediation system for TCE degradation without any growth-stimulating nutrients or toxic inducers such as toluene, we used the carbon-starvation promoter ofPseudomonas putida MK1 (Kim, Y.et al., J. bacteriol., 1995). Upon entry into the stationary phase due to the deprivation of nutrients, this promoter is strongly induced without further cell growth. The TMO gene cluster (4.5 kb) was spliced downstream of the carbon starvation promoter ofPseudomona putida MK1, already cloned in pUC19. TMO under the carbon starvation promoter was not expressed inE. coli cells either in stationary phase or exponential phase. For TMO expression inPseudomonas strains,tmo and carbon starvation promoter region were recloned into a modified broad-host range vector pMMB67HES which was made from pMMB67HE (8.9 kb) by deletion oftac promoter andlacI ^q (about 1.5 kb). Indigo was produced by TMO under the carbon starvation promoter in aPseudomonas strain of post-exponential phase on M9 (0.2% glucose and 1mM indole) or LB. 18% of TCE was degraded in 14 hours after entering the stationary phase at the initial concentration of 6.6μ M in liquid phase.     

Cloning and characterization of hydrogenase genes from Azotobacter chroococcum

Summary Genomic DNA from Azotobacter chroococcum was shown by DNA hybridization to contain sequences homologous to Rhizobium japonicum H₂-uptake (hup) hydrogenase genes carried on the plasmid pHU1. Two recombinant cosmid clones, pACD101 and pACD102, were isolated from a gene library of A. chroococcum by colony hybridization and physically mapped. Each contained approximately 42 kb of insert DNA with approximately 27 kb of overlapping DNA. Further hybridization studies using three fragments from pHU1 (6 kb HindIII, 6.4 kb BglII and 5 kb EcoRI) showed that the hup-specific regions of R. japonicum and A. chroococcum are probably highly conserved. Weak homology to the hydrogenase structural genes from Desulfovibrio vulgaris (Hildenborough) was also observed. A 24 kb BamHI fragment from pACD102 subcloned into a broad host-range vector restored hydrogenase activity to several Hup^- mutants of A. chroococcum.