In vivo and in vitro nickel-dependent processing of the [NiFe] hydrogenase in Azotobacter vinelandii

In vitro maturation of NiSOD reveals a role for cytoplasmic histidine in processing and metalation

The importance of cellular low molecular weight ligands in metalloenzyme maturation is largely unexplored. Maturation of NiSOD requires post-translational N-terminal processing of the proenzyme, SodN, by its cognate protease, SodX. Here we provide evidence for the participation of L-histidine in the protease-dependent maturation of nickel-dependent superoxide dismutase (NiSOD) from Streptomyces coelicolor. In vitro studies using purified proteins cloned from S. coelicolor and overexpressed in E. coli support a model where a ternary complex formed between the substrate (SodN), the protease (SodX) and L-Histidine creates a novel Ni-binding site that is capable of the N-terminal processing of SodN and specifically incorporates Ni into the apo-NiSOD product. Thus, L-Histidine serves many of the functions associated with a metallochaperone or, conversely, eliminates the need for a metallochaperone in NiSOD maturation.

Azotobacter vinelandii: the source of 100 years of discoveries and many more to come

Azotobacter vinelandii has been studied for over 100 years since its discovery as an aerobic nitrogen-fixing organism. This species has proved useful for the study of many different biological systems, including enzyme kinetics and the genetic code. It has been especially useful in working out the structures and mechanisms of different nitrogenase enzymes, how they can function in oxic environments and the interactions of nitrogen fixation with other aspects of metabolism. Interest in studying A. vinelandii has waned in recent decades, but this bacterium still possesses great potential for new discoveries in many fields and commercial applications. The species is of interest for research because of its genetic pliability and natural competence. Its features of particular interest to industry are its ability to produce multiple valuable polymers - bioplastic and alginate in particular; its nitrogen-fixing prowess, which could reduce the need for synthetic fertilizer in agriculture and industrial fermentations, via coculture; its production of potentially useful enzymes and metabolic pathways; and even its biofuel production abilities. This review summarizes the history and potential for future research using this versatile microbe.

Crystal structure of a [NiFe] hydrogenase maturation protease HybD from Thermococcus kodakarensis KOD1

A [NiFe] hydrogenase maturation protease HybD from Thermococcus kodakarensis KOD1 (TkHybD) is involved in the cleavage of the C-terminal residues of [NiFe] hydrogenase large subunits by Ni recognition. Here, we report the crystal structure of TkHybD at 1.82 Å resolution to better understand this process. TkHybD exhibits an α/β/α sandwich fold with conserved residues responsible for the Ni recognition. Comparisons of TkHybD with homologous proteins also reveal that they share a common overall architecture, suggesting that they have similar catalytic functions. Our results including metal binding site prediction provide insight into the substrate recognition and catalysis mechanism of TkHybD. Proteins 2016; 84:1321-1327. © 2016 Wiley Periodicals, Inc.

[NiFe]-Hydrogenase Maturation

[NiFe]-hydrogenases catalyze the reversible conversion of hydrogen gas into protons and electrons and are vital metabolic components of many species of bacteria and archaea. At the core of this enzyme is a sophisticated catalytic center comprising nickel and iron, as well as cyanide and carbon monoxide ligands, which is anchored to the large hydrogenase subunit through cysteine residues. The production of this multicomponent active site is accomplished by a collection of accessory proteins and can be divided into discrete stages. The iron component is fashioned by the proteins HypC, HypD, HypE, and HypF, which functionalize iron with cyanide and carbon monoxide. Insertion of the iron center signals to the metallochaperones HypA, HypB, and SlyD to selectively deliver the nickel to the active site. A specific protease recognizes the completed metal cluster and then cleaves the C-terminus of the large subunit, resulting in a conformational change that locks the active site in place. Finally, the large subunit associates with the small subunit, and the complete holoenzyme translocates to its final cellular position. Beyond this broad overview of the [NiFe]-hydrogenase maturation process, biochemical and structural studies are revealing the fundamental underlying molecular mechanisms. Here, we review recent work illuminating how the accessory proteins contribute to the maturation of [NiFe]-hydrogenase and discuss some of the outstanding questions that remain to be resolved.

Coordination of Synthesis and Assembly of a Modular Membrane-Associated [NiFe]-Hydrogenase Is Determined by Cleavage of the C-Terminal Peptide

During biosynthesis of [NiFe]-hydrogenase 2 (Hyd-2) of Escherichia coli, a 15-amino-acid C-terminal peptide is cleaved from the catalytic large subunit precursor, pro-HybC. This peptide is removed only after NiFe(CN)2CO cofactor insertion by the Hyp accessory protein machinery has been completed, suggesting that it has a regulatory function during enzyme maturation. We show here that in hyp mutants that fail to synthesize and insert the NiFe cofactor, and therefore retain the peptide, the Tat (twin-arginine translocon) signal peptide on the small subunit HybO is not removed and the subunit is degraded. In a mutant lacking the large subunit, the Tat signal peptide was also not removed from pre-HybO, indicating that the mature large subunit must actively engage the small subunit to elicit Tat transport. We validated the proposed regulatory role of the C-terminal peptide in controlling enzyme assembly by genetically removing it from the precursor of HybC, which allowed assembly and Tat-dependent membrane association of a HybC-HybO heterodimer lacking the NiFe(CN)2CO cofactor. Finally, genetic transfer of the C-terminal peptide from pro-HyaB, the large subunit of Hyd-1, onto HybC did not influence its dependence on the accessory protein HybG, a HypC paralog, or the specific protease HybD. This indicates that the C-terminal peptide per se is not required for interaction with the Hyp machinery but rather suggests a role of the peptide in maintaining a conformation of the protein suitable for cofactor insertion. Together, our results demonstrate that the C-terminal peptide on the catalytic subunit controls biosynthesis, assembly, and membrane association of Hyd-2.

IMPORTANCE

[NiFe]-hydrogenases are multisubunit enzymes with a catalytic subunit containing a NiFe(CN)2CO cofactor. Results of previous studies suggested that after synthesis and insertion of the cofactor by the Hyp accessory proteins, this large subunit changes conformation upon proteolytic removal of a short peptide from its C terminus. We show that removal of this peptide is necessary to allow the cleavage of the Tat signal peptide from the small subunit with concomitant membrane association of the heterodimer to occur. Genetic removal of the C-terminal peptide from the large subunit allowed productive interaction with the small subunit and Tat-dependent membrane insertion of a NiFe cofactor-free enzyme. Results based on swapping of C-terminal peptides between hydrogenases suggest that this peptide governs enzyme assembly via a conformational switch.

Synechococcus sp. strain PCC 7002 nifJ mutant lacking pyruvate:ferredoxin oxidoreductase

The nifJ gene codes for pyruvate:ferredoxin oxidoreductase (PFOR), which reduces ferredoxin during fermentative catabolism of pyruvate to acetyl-coenzyme A (acetyl-CoA). A nifJ knockout mutant was constructed that lacks one of two pathways for the oxidation of pyruvate in the cyanobacterium Synechococcus sp. strain PCC 7002. Remarkably, the photoautotrophic growth rate of this mutant increased by 20% relative to the wild-type (WT) rate under conditions of light-dark cycling. This result is attributed to an increase in the quantum yield of photosystem II (PSII) charge separation as measured by photosynthetic electron turnover efficiency determined using fast-repetition-rate fluorometry (F(v)/F(m)). During autofermentation, the excretion of acetate and lactate products by nifJ mutant cells decreased 2-fold and 1.2-fold, respectively. Although nifJ cells displayed higher in vitro hydrogenase activity than WT cells, H(2) production in vivo was 1.3-fold lower than the WT level. Inhibition of acetate-CoA ligase and pyruvate dehydrogenase complex by glycerol eliminated acetate production, with a resulting loss of reductant and a 3-fold decrease in H(2) production by nifJ cells compared to WT cells. Continuous electrochemical detection of dissolved H(2) revealed two temporally resolved phases of H(2) production during autofermentation, a minor first phase and a major second phase. The first phase was attributed to reduction of ferredoxin, because its level decreased 2-fold in nifJ cells. The second phase was attributed to glycolytic NADH production and decreased 20% in nifJ cells. Measurement of the intracellular NADH/NAD(+) ratio revealed that the reductant generated by PFOR contributing to the first phase of H(2) production was not in equilibrium with bulk NADH/NAD(+) and that the second phase corresponded to the equilibrium NADH-mediated process.

Structure and Function of [NiFe]-Hydrogenases

[NiFe(Se)]-hydrogenases are hetero-dimeric enzymes present in many microorganisms where they catalyze the oxidation of molecular hydrogen or the reduction of protons. Like the other two types of hydrogen-metabolizing enzymes, the [FeFe]- and [Fe]-hydrogenases, [NiFe]-hydrogenases have a Fe(CO)x unit in their active sites that is most likely involved in hydride binding. Because of their complexity, hydrogenases require a maturation machinery that involves several gene products. They include nickel and iron transport, synthesis of CN− (and maybe CO), formation and insertion of a FeCO(CN−)2 unit in the apo form, insertion of nickel and proteolytic cleavage of a C-terminal stretch, a step that ends the maturation process. Because the active site is buried in the structure, electron and proton transfer are required between this site and the molecular surface. The former is mediated by either three or one Fe/S cluster(s) depending on the enzyme. When exposed to oxidizing conditions, such as the presence of O2, [NiFe]-hydrogenases are inactivated. Depending on the redox state of the enzyme, exposure to oxygen results in either a partially reduced oxo species probably a (hydro)peroxo ligand between nickel and iron or a more reduced OH– ligand instead. Under some conditions the thiolates that coordinate the NiFe center can be modified to sulfenates. Understanding this process is of biotechnological interest for H2 production by photosynthetic organisms.

Solution Structure and Backbone Dynamics of an Endopeptidase HycI from scherichia coli

[NiFe] hydrogenases are metalloenzymes involved in many biological processes concerning the metabolism of hydrogen. The maturation of the large subunit of these hydrogenases requires the cleavage of a peptide at the C terminus by an endopeptidase before the final formation of the [NiFe] metallocenter. HycI is an endopeptidase of the M52 family and responsible for the C-terminal cleavage of the large subunit of hydrogenase 3 in Escherichia coli. Although extensive studies were performed, the molecular mechanism of recognition and cleavage of hydrogenase 3 remains elusive. Herein, we report the solution structure of E. coli HycI determined by high resolution nuclear magnetic resonance spectroscopy. This is the first solution structure of the apo form of endopeptidase of the M52 family reported thus far. The overall structure is similar to the crystal structure of holo-HybD in the same family. However, significant diversity was observed between the two structures. Especially, HycI shows an open conformation at the putative nickel-binding site, whereas HybD adopts a closed conformation. In addition, we performed backbone dynamic studies to probe the motional properties of the apo form of HycI. Furthermore, the metal ion titration experiments provide insightful information on the substrate recognition and cleavage processes. Taken together, our current structural, biochemical, and dynamic studies extend the knowledge of the M52 family proteins and provide novel insights into the biological function of HycI.

Maturation of hydrogenases

Enzymes possessing the capacity to oxidize molecular hydrogen have developed convergently three class of enzymes leading to: [FeFe]-, [NiFe]-, and [FeS]-cluster-free hydrogenases. They differ in the composition and the structure of the active site metal centre and the sequence of the constituent structural polypeptides but they show one unifying feature, namely the existence of CN and/or CO ligands at the active site Fe. Recent developments in the analysis of the maturation of [FeFe]- and [NiFe]- hydrogenases have revealed a remarkably complex pattern of mostly novel biochemical reactions. Maturation of [FeFe]-hydrogenases requires a minimum of three auxiliary proteins, two of which belong to the class of Radical-SAM enzymes and other to the family of GTPases. They are sufficient to generate active enzyme when their genes are co-expressed with the structural genes in a heterologous host, otherwise deficient in [FeFe]-hydrogenase expression. Maturation of the large subunit of [NiFe]-hydrogenases depends on the activity of at least seven core proteins that catalyse the synthesis of the CN ligand, have a function in the coordination of the active site iron, the insertion of nickel and the proteolytic maturation of the large subunit. Whereas this core maturation machinery is sufficient to generate active hydrogenase in the cytoplasm, like that of hydrogenase 3 from Escherichia coli, additional proteins are involved in the export of the ready-assembled heterodimeric enzyme to the periplasm via the twin-arginine translocation system in the case of membrane-bound hydrogenases. A series of other gene products with intriguing putative functions indicate that the minimal pathway established for E. coli [NiFe]-hydrogenase maturation may possess even higher complexity in other organisms.

HybF, a zinc-containing protein involved in NiFe hydrogenase maturation

HypA and HypB are maturation proteins required for incorporation of nickel into the hydrogenase large subunit. To examine the functions of these proteins in nickel insertion, the hybF gene, which is a homolog of hypA essential for maturation of hydrogenases 1 and 2 from Escherichia coli, was overexpressed, and the product was purified. This protein behaves like a monomer in gel filtration and contains stoichiometric amounts of zinc but insignificant or undetectable amounts of nickel and iron. In filter binding assays radioactively labeled nickel binds to HybF with a K(D) of 1.87 microM and in a stoichiometric ratio. To identify amino acid residues of HybF involved in nickel and/or zinc binding, variants in which conserved residues were replaced were studied. An H2Q replacement eliminated both in vivo activity and in vitro binding of nickel. The purified protein, however, contained zinc at the level characteristic of the wild-type protein. When E3 was replaced by Q, activity was retained, but an E3L exchange was detrimental. Replacement of each of the four conserved cysteine residues of a zinc finger motif reduced the cellular amount of HybF protein without a loss of in vivo activity, indicating that these residues play a purely structural role. A triple mutant deficient in the synthesis or activity of HypA, HybF, and HypB was constructed, and it exhibited the same responsiveness for phenotypic complementation by high nickel as mutants with a single lesion in one of the genes exhibited. The results are interpreted in terms of a concerted action of HypB and HybF in nickel insertion in which HybF (as well as its homolog, HypA) functions as a metallochaperone and HypB functions as a regulator that controls the interaction of HybF with the target protein.

Maturation of [NiFe]-hydrogenases in Escherichia coli: the HypC cycle

Carbamoyl phosphate (CP) has been implicated as an educt for the synthesis of the CO and CN ligands of the metal centre of [NiFe]-hydrogenases in Escherichia coli, since CP synthetase mutants (carAB) are unable to generate active hydrogenases due to a block in enzyme maturation. Citrulline, when added to the growth medium in high concentrations, compensated for the phenotype of the mutants. It is now shown that overexpression of the argI gene lowered the effective concentration of citrulline, thus proving that the amino acid serves as a source for CP. The DeltaCarAB mutant accumulated a complex consisting of the hydrogenase maturation proteins HypC and HypD. This complex was resolved upon citrulline addition and followed-up by the appearance of a complex between HypC and the precursor of the large subunit of hydrogenase 3, preHycE. In the absence of the hycE gene, the HypC-HypD complex did not disappear upon addition of citrulline but developed into a form migrating slower in a non-denaturing polyacrylamide gel, providing strong evidence for the notion that the HypC-HypD complex is the intermediate in hydrogenase maturation where CP or its products are added to the iron atom of the metal centre. This step precedes nickel insertion, since extracts of carAB cells that had been cultivated in the absence of citrulline are unable to process preHycE after the addition of nickel. Complex formation between HypC and HypD, and between HypC and preHycE display dependence on identical primary structure elements of HypC. On the basis of the results, a cycle of HypC activity is proposed whose function is to transfer the iron atom that has been liganded at the HypC-HypD complex to the precursor of the large hydrogenase subunit.

Engineering the Rhizobium leguminosarum bv. viciae hydrogenase system for expression in free-living microaerobic cells and increased symbiotic hydrogenase activity

Rhizobium leguminosarum bv. viciae UPM791 induces hydrogenase activity in pea (Pisum sativum L.) bacteroids but not in free-living cells. The symbiotic induction of hydrogenase structural genes (hupSL) is mediated by NifA, the general regulator of the nitrogen fixation process. So far, no culture conditions have been found to induce NifA-dependent promoters in vegetative cells of this bacterium. This hampers the study of the R. leguminosarum hydrogenase system. We have replaced the native NifA-dependent hupSL promoter with the FnrN-dependent fixN promoter, generating strain SPF25, which expresses the hup system in microaerobic free-living cells. SPF25 reaches levels of hydrogenase activity in microaerobiosis similar to those induced in UPM791 bacteroids. A sixfold increase in hydrogenase activity was detected in merodiploid strain SPF25(pALPF1). A time course induction of hydrogenase activity in microaerobic free-living cells of SPF25(pALPF1) shows that hydrogenase activity is detected after 3 h of microaerobic incubation. Maximal hydrogen uptake activity was observed after 10 h of microaerobiosis. Immunoblot analysis of microaerobically induced SPF25(pALPF1) cell fractions indicated that the HupL active form is located in the membrane, whereas the unprocessed protein remains in the soluble fraction. Symbiotic hydrogenase activity of strain SPF25 was not impaired by the promoter replacement. Moreover, bacteroids from pea plants grown in low-nickel concentrations induced higher levels of hydrogenase activity than the wild-type strain and were able to recycle all hydrogen evolved by nodules. This constitutes a new strategy to improve hydrogenase activity in symbiosis.

Breaking the singleton of germination protease

Germination protease (GPR) plays an important role in the germination of spores of Bacillus and Clostridium species. A few very similar GPRs form a singleton group without significant sequence similarities to any other proteins. Their active site locations and catalytic mechanisms are unclear, despite the recent 3-D structure determination of Bacillus megaterium GPR. Using structural comparison and sequence analysis, we show that GPR is homologous to bacterial hydrogenase maturation protease (HybD). HybD's activity relies on the recognition and binding of metal ions in Ni-Fe hydrogenase, its substrate. Two highly conserved motifs are shared among GPRs, hydrogenase maturation proteases, and another group of hypothetical proteins. Conservation of two acidic residues in all these homologs indicates that metal binding is important for their function. Our analysis helps localize the active site of GPRs and provides insight into the catalytic mechanisms of a superfamily of putative metal-regulated proteases.

Fidelity of metal insertion into hydrogenases

The fidelity of metal incorporation into the active center of hydrogenase 3 from Escherichia coli was studied by analyzing the inhibition of the maturation pathway by zinc and other transition metals. Hydrogenase maturation of wild-type cells was significantly affected only by concentrations of zinc or cadmium higher than 200 microM, whereas a mutant with a lesion in the nickel uptake system displayed a total blockade of the proteolytic processing of the precursor form into the mature form of the large subunit after growth in the presence of 10 microM Zn(2+). The precursor could not be processed in vitro by the maturation endopeptidase even in the presence of an excess of nickel ions. Evidence is presented that zinc does not interfere with the incorporation of iron into the metal center. Precursor of the large subunit accumulated in nickel proficient cells formed a transient substrate complex with the cognate endoprotease HycI whereas that of zinc-supplemented cells did not. The results show that zinc can intrude the nickel-dependent maturation pathway only when nickel uptake is blocked. Under this condition zinc appears to be incorporated at the nickel site of the large subunit and delivers a precursor not amenable to proteolytic processing since the interaction with the endoprotease is blocked.

Hydrogenase in Frankia KB5: expression of and relation to nitrogenase

The localization and expression of the hydrogenase in free-living Frankia KB5 was investigated immunologically and by monitoring activity, focusing on its relationships with nitrogenase and H2. Immunological studies revealed that the large subunit of the hydrogenase in Frankia KB5 was modified post-translationally, and transferred into the membrane after processing. The large subunit was constitutively expressed and no correlation was found between hydrogenase activity and synthesis. Although H2 was not needed for induction of hydrogenase synthesis, exogenously added H2 triggered hydrogen uptake in medium containing nitrogen, i.e., in the hyphae. A correlation between nitrogenase activity and hydrogen uptake was found in cultures grown in media without nitrogen, but interestingly the two enzymes showed no co-regulation.

Dissection of the maturation reactions of the [NiFe] hydrogenase 3 from Escherichia coli taking place after nickel incorporation

The steps in the maturation of the precursor of the large subunit (pre-HycE) of hydrogenase 3 from Escherichia coli taking place after incorporation of both iron and nickel were investigated. Pre-HycE could be matured and processed in the absence of the small subunit but association with the cytoplasmic membrane required heterodimer formation between the two subunits. Pre-HycE formed a complex with the chaperone-like protein HypC in the absence of the small subunit and, in this complex, also incorporated nickel. For the C-terminal processing, HypC had to leave the complex since only a HypC-free, nickel-containing form of pre-HycE was a substrate for the maturation endopeptidase.

Nickel serves as a substrate recognition motif for the endopeptidase involved in hydrogenase maturation

The interaction of the hydrogenase maturation endopeptidase HycI with its substrate, the precursor of the large subunit, was studied. Replacement of conserved amino-acid residues in HycI, which have been shown to bind a cadmium ion from the crystallization buffer in crystals of HybD (endopeptidase for hydrogenase 2), abolished or strongly reduced processing activity. Atomic absorption spectroscopy of purified HycI and HybD proteins showed the absence of nickel. In vitro processing assays showed that the reaction requires nickel to be bound to the precursor and the protease does not have a function in nickel delivery to the substrate. Radioactive labelling of cells with 63Ni, devoid of endopeptidase, resolved several forms of the precursor which are possibly intermediates in the maturation pathway. It is concluded that the endopeptidase uses the metal in the large subunit of [NiFe]-hydrogenases as a recognition motif.

Crystal structure of the hydrogenase maturating endopeptidase HYBD from Escherichia coli

The maturation of [NiFe] hydrogenases includes formation of the nickel metallocenter, proteolytic processing of the metal center carrying large subunit, and its assembling with other hydrogenase subunits. The hydrogenase maturating enzyme HYBD from Escherichia coli, a protease of molecular mass 17.5 kDa, specifically cleaves off a 15 amino acid peptide from the C terminus of the precursor of the large subunit of hydrogenase 2 in a nickel-dependent manner. Here we report the crystal structure of HYBD at 2.2 A resolution. It consists of a twisted five-stranded beta-sheet surrounded by four and three helices, respectively, on each side. A cadmium ion from the crystallization buffer binds to the proposed nickel-binding site and is penta-coordinated by Glu16, Asp62, His93, and a water molecule in a pseudo-tetragonal arrangement. HYBD is topologically related to members of the metzincins superfamily of zinc endoproteinases, sharing the central beta-sheet and three helices. In contrast to the metzincins, the metal-binding site of HYBD is localized at the C-terminal end of the beta-sheet. Three helical insertions unique to HYBD pack against one side of the sheet, build up the active site cleft, and provide His93 as ligand to the metal. From this structure, we derive molecular clues into how the protease HYBD is involved in the hydrogenase maturation process.

Structure/function relationships in nickel metallobiochemistry

Among the many highlights of nickel metallobiochemistry in 1998 were the discoveries that Escherichia coli glyoxalase I is the first example of a nickel isomerase, and that the superoxide dismutase isolated from Streptomyces seoulensis is a new structural class of superoxide dismutase that features thiolate ligation.

Transcriptional and post-transcriptional regulation by nickel of sodN gene encoding nickel-containing superoxide dismutase from Streptomyces coelicolor Müller

A novel type of superoxide dismutase containing nickel as a cofactor (NiSOD) has been discovered in several Streptomyces spp. The gene for NiSOD (sodN) was cloned from S. coelicolor Müller using degenerate oligonucleotide probes designed from the N-terminal peptide sequence of the purified enzyme. It encodes a polypeptide of 131 amino acids (14703 Da), without any apparent sequence similarity to other known proteins. The N-terminus of the purified NiSOD was located 14 amino acids downstream from the initiation codon of the deduced open reading frame (ORF), indicating the involvement of protein processing. The molecular mass of the processed polypeptide was predicted to be 13201 Da, in close agreement with that of the purified NiSOD (13.4 kDa). The transcription start site of the sodN gene was determined by S1 mapping and primer extension analysis. Ni2+ regulates the synthesis of NiSOD polypeptide. S1 mapping of both 5' and 3' ends of sodN mRNA revealed that Ni2+ increased the level of monocistronic sodN mRNA by more than ninefold without changing its half-life, thus demonstrating that Ni2+ regulates transcription. Both precursor and processed NiSOD polypeptides with little SOD activity were produced from the cloned sodN gene in S. lividans in the absence of sufficient Ni2+; however, on addition of Ni2+, active NiSOD consisting of only processed polypeptide was formed. Expression of the full-length sodN gene in E. coli produced NiSOD polypeptide without any SOD activity even in the presence of Ni2+. However, deletion of nucleotides encoding the N-terminal 14 amino acids from the sodN gene allowed the production of active NiSOD in E. coli, indicating that N-terminal processing is required to produce active NiSOD. These results reveal the unique role of nickel as a multifaceted regulator in S. coelicolor controlling sodN transcription and protein processing, as well as acting as a catalytic cofactor.

Functional and structural role of the cytochrome b subunit of the membrane-bound hydrogenase complex of Alcaligenes eutrophus H16

This study shows that the product of the hoxZ gene of Alcaligenes eutrophus H16 is a b-type cytochrome (cytochrome b(z)), which is essential for anchoring the membrane-bound hydrogenase (MBH) complex to the periplasmic side of the membrane and for H2-coupled respiration. The hoxZ product is not required for MBH translocation and H2-dependent reduction of the redox dye, 2,3,5-triphenyl-2-tetrazolium chloride. The lack of cytochrome b(z) does not affect the electron-transport activities linked to oxidation of succinate and NADH, although it enhances the electron-flow rate through the cytochrome-c oxidase pathway in hoxZdelta membranes. We show that the hoxZ product is a dihaem cytochrome b (haems with E(m7.0) of +10 mV and +166 mV) involved in H2-dependent electron transfer. We conclude that cytochrome b(z) of the A. eutrophus MBH complex is the link necessary for transfer of electrons from H2 to the ubiquinone pool and that it is required for attachment of MBH to the membrane.

The hupTUV operon is involved in negative control of hydrogenase synthesis in Rhodobacter capsulatus

The hupT, hupU, and hupV genes, which are located upstream from the hupSLC and hypF genes in the chromosome of Rhodobacter capsulatus, form the hupTUV operon expressed from the hupT promoter. The hupU and hupV genes, previously thought to belong to a single open reading frame, encode HupU, of 34.5 kDa (332 amino acids), and HupV, of 50.4 kDa (476 amino acids), which are >/= 50% identical to the homologous Bradyrhizobium japonicum HupU and HupV proteins and Rhodobacter sphaeroides HupU1 and HupU2 proteins, respectively; they also have 20 and 29% similarity with the small subunit (HupS) and the large subunit (HupL), respectively, of R. capsulatus [NiFe]hydrogenase. HupU lacks the signal peptide of HupS and HupV lacks the C-terminal sequence of HupL, which are cleaved during hydrogenase processing. Inactivation of hupV by insertional mutagenesis or of hupUV by in-frame deletion led to HupV- and Hup(UV)- mutants derepressed for hydrogenase synthesis, particularly in the presence of oxygen. These mutants were complemented in trans by plasmid-borne hupTUV but not by hupT or by hupUV, except when expressed from the inducible fru promoter. Complementation of the HupV- and Hup(UV)- mutants brought about a decrease in hydrogenase activity up to 10-fold, to the level of the wild-type strain B10, indicating that HupU and HupV participate in negative regulation of hydrogenase expression in concert with HupT, a sensor histidine kinase involved in the repression process. Plasmid-borne gene fusions used to monitor hupTUV expression indicated that the operon is expressed at a low level (50- to 100-fold lower than hupS).

Requirement for nickel of the transmembrane translocation of NiFe-hydrogenase 2 in Escherichia coli

The cellular location of membrane-bound NiFe-hydrogenase 2 (HYD2) from Escherichia coli was studied by immunoblot analysis and by activity staining. Treatment of spheroplasts with trypsin was able to release active HYD2 into the soluble fraction, indicating that HYD2 is attached to the periplasmic side of the cytoplasmic membrane and that HYD2 undergoes a trans-membrane translocation during its biosynthesis. By using a nik mutant deficient in the high affinity specific nickel transport system, we show that the intracellular availability of nickel is essential for the processing of the large subunit and for the transmembrane translocation of HYD2. We also demonstrate that the processing of the precursor, which is related with nickel incorporation, can occur in the membrane-depleted soluble fraction and that it is associated with the increase in resistance to proteolysis of the processed form of the large subunit. The mechanism of the transmembrane translocation of HYD2 is discussed.

Involvement of the GroE chaperonins in the nickel-dependent anaerobic biosynthesis of NiFe-hydrogenases of Escherichia coli

We analyzed the involvement of chaperonins GroES and GroEL in the biosynthesis of the three hydrogenase isoenzymes, HYD1, HYD2, and HYD3, of Escherichia coli. These hydrogenases are NiFe-containing, membrane-bound enzymes composed of small and large subunits, each of which is proteolytically processed during biosynthesis. Total hydrogenase activity was found to be reduced by up to 60% in groES and groEL thermosensitive mutant strains. This effect was specific because it was not seen for another oligomeric, membrane-bound metalloenzyme, i.e., nitrate reductase. Analyses of the single hydrogenase isoenzymes revealed that a temperature shift during the growth of groE mutants led to an absence of HYD1 activity and to an accumulation of the precursor of the large subunit of HYD3, whereas only marginal effects on the processing of HYD2 and its activity were observed under these conditions. A decrease in total hydrogenase activity, together with accumulation of the precursors of the large subunits of HYD2 and HYD3, was also found to occur in a nickel uptake mutant (nik). The phenotype of this nik mutant was suppressed by supplementation of the growth medium with nickel ions. On the contrary, Ni2+ no longer restored hydrogenase activity and processing of the large subunit of HYD3 when the nik and groE mutations were combined in one strain. This finding suggests the involvement of these chaperonins in the biosynthesis of a functional HYD3 isoenzyme via the incorporation of nickel. In agreement with these in vivo results, we demonstrated a specific binding of GroEL to the precursor of the large subunit of HYD3 in vitro. Collectively, our results are consistent with chaperonin-dependent incorporation of nickel into the precursor of the large subunit of HYD3 as a prerequisite of its proteolytic processing and the acquisition of enzymatic activity.

Characterization of the CO-induced, CO-tolerant hydrogenase from Rhodospirillum rubrum and the gene encoding the large subunit of the enzyme

In the presence of carbon monoxide, the photosynthetic bacterium Rhodospirillum rubrum induces expression of proteins which allow the organism to metabolize carbon monoxide in the net reaction CO + H2O --> CO2 + H2. These proteins include the enzymes carbon monoxide dehydrogenase (CODH) and a CO-tolerant hydrogenase. In this paper, we present the complete amino acid sequence for the large subunit of this hydrogenase and describe the properties of the crude enzyme in relation to other known hydrogenases. The amino acid sequence deduced from the CO-induced hydrogenase large-subunit gene (cooH) shows significant similarity to large subunits of other Ni-Fe hydrogenases. The closest similarity is with HycE (58% similarity and 37% identity) from Escherichia coli, which is the large subunit of an Ni-Fe hydrogenase (isoenzyme 3). The properties of the CO-induced hydrogenase are unique. It is exceptionally resistant to inhibition by carbon monoxide. It also exhibits a very high ratio of H2 evolution to H2 uptake activity compared with other known hydrogenases. The CO-induced hydrogenase is tightly membrane bound, and its inhibition by nonionic detergents is described. Finally, the presence of nickel in the hydrogenase is addressed. Analysis of wild-type R. rubrum grown on nickel-depleted medium indicates a requirement for nickel for hydrogenase activity. However, analysis of strain UR294 (cooC insertion mutant defective in nickel insertion into CODH) shows that independent nickel insertion mechanisms are utilized by hydrogenase and CODH. CooH lacks the C-terminal peptide that is found in other Ni-Fe hydrogenases; in other systems, this peptide is cleaved during Ni processing.

hyp gene products in Alcaligenes eutrophus are part of a hydrogenase-maturation system

In Alcaligenes eutrophus H16 the hyp gene complex consists of six open reading frames hypA1, B1, F1, C, D and E whose products are involved in maturation of the two NiFe hydrogenases: an NAD-reducing cytoplasmic enzyme (SH) and a membrane-bound electron-transport-coupled protein (MBH). hypB1 and hypF1 were originally considered to form a single open reading frame designated hypB [Dernedde, J., Eitinger, M. & Friedrich, B. (1993) Arch. Microbiol. 159, 545-553]. Re-examination of the relevant sequence identified hypB1 and hypF1 as two distinct genes. Non-polar in-frame deletions in the individual hyp genes were constructed in vitro and transferred via gene replacement to the wild-type strain. The resulting mutants fall into two classes. Deletions in hypC, D and E (class I) gave a clear negative phenotype, while hypA1, B1 and F1 deletion mutants (class II) were not impaired in hydrogen metabolism. Class I mutants were unable to grow on hydrogen under autotrophic conditions. The enzymatic activities of SH and MBH were disrupted in all three class I mutants. Immunoblot analysis showed the presence of the H2-activating SH subunit (HoxH) at levels comparable to those observed in the wild-type strain whereas the other three subunits (HoxF, U and Y) were only detectable in trace amounts, probably due to proteolytic degradation. Likewise, MBH was less stable in hypC, D and E deletion mutants and was not attached to the cytoplasmic membrane. In the wild-type strain, HoxH and the MBH large subunit (HoxG) undergo C-terminal proteolytic processing before attaining enzymatic activity. In class I mutants this maturation was blocked. 63Ni-incorporation experiments identified both hydrogenases as nickel-free apoproteins in these mutants. Although class II mutants bearing deletions in hypA1, B1 and F1 showed no alteration of the wild-type phenotype, a role for these genes in the incorporation of nickel and hence hydrogenase maturation cannot be excluded, since there is experimental evidence that this set of genes is duplicated in A. eutrophus.

Characterisation of a protease from Escherichia coli involved in hydrogenase maturation

The large subunits of nickel-containing hydrogenases are synthesised in a precursor form which, after nickel incorporation, is processed by proteolytic cleavage at the C-terminal end. The protease involved in processing of HycE, the large subunit of hydrogenase 3 from Escherichia coli, was purified by three chromatographic steps to apparent homogeneity. Its gene was identified by using a hybridisation probe generated by PCR with oligonucleotide primers the sequence of which was derived from the N-terminal and internal amino acid sequences. Determination of the nucleotide sequence showed that the gene is located distally and as a hitherto uncharacterised gene within the hyc operon, coding for hydrogenase 3 components. It was designated hycI. The HycI protease has a molecular mass of 17 kDa and is a monomer. Its cleavage reaction is not inhibited by conventional inhibitors of serine and metalloproteases, which correlates with the fact that the sequence does not contain signature motifs characteristic of serine-, metallo-, cysteine- or acid proteases. Homologous genes are present in other transcriptional units coding for hydrogenases.

Nickel availability to pea (Pisum sativum L.) plants limits hydrogenase activity of Rhizobium leguminosarum bv. viciae bacteroids by affecting the processing of the hydrogenase structural subunits

Rhizobium leguminosarum bv. viciae UPM791 induces the synthesis of an [NiFe] hydrogenase in pea (Pisum sativum L.) bacteroids which oxidizes the H2 generated by the nitrogenase complex inside the root nodules. The synthesis of this hydrogenase requires the genes for the small and large hydrogenase subunits (hupS and hupL, respectively) and 15 accessory genes clustered in a complex locus in the symbiotic plasmid. We show here that the bacteroid hydrogenase activity is limited by the availability of nickel to pea plants. Addition of Ni2+ to plant nutrient solutions (up to 10 mg/liter) resulted in sharp increases (up to 15-fold) in hydrogenase activity. This effect was not detected when other divalent cations (Zn2+, Co2+, Fe2+, and Mn2+) were added at the same concentrations. Determinations of the steady-state levels of hupSL-specific mRNA indicated that this increase in hydrogenase activity was not due to stimulation of transcription of structural genes. Immunoblot analysis with antibodies raised against the large and small subunits of the hydrogenase enzyme demonstrated that in the low-nickel situation, both subunits are mainly present in slow-migrating, unprocessed forms. Supplementation of the plant nutrient solution with increasing nickel concentrations caused the conversion of the slow-migrating forms of both subunits into fast-moving, mature forms. This nickel-dependent maturation process of the hydrogenase subunits is mediated by accessory gene products, since bacteroids from H2 uptake-deficient mutants carrying Tn5 insertions in hupG and hupK and in hypB and hypE accumulated the immature forms of both hydrogenase subunits even in the presence of high nickel levels.