Insights into [FeFe]-hydrogenase structure, mechanism, and maturation

Hydrogenases are metalloenzymes that are key to energy metabolism in a variety of microbial communities. Divided into three classes based on their metal content, the [Fe]-, [FeFe]-, and [NiFe]-hydrogenases are evolutionarily unrelated but share similar nonprotein ligand assemblies at their active site metal centers that are not observed elsewhere in biology. These nonprotein ligands are critical in tuning enzyme reactivity, and their synthesis and incorporation into the active site clusters require a number of specific maturation enzymes. The wealth of structural information on different classes and different states of hydrogenase enzymes, biosynthetic intermediates, and maturation enzymes has contributed significantly to understanding the biochemistry of hydrogen metabolism. This review highlights the unique structural features of hydrogenases and emphasizes the recent biochemical and structural work that has created a clearer picture of the [FeFe]-hydrogenase maturation pathway.     

Carbamoylphosphate requirement for synthesis of the active center of [NiFe]-hydrogenases

The iron of the binuclear active center of [NiFe]-hydrogenases carries two CN and one CO ligands which are thought to confer to the metal a low oxidation and/or spin state essential for activity. Based on the observation that one of the seven auxiliary proteins required for the synthesis and insertion of the [NiFe] cluster contains a sequence motif characteristic of O-carbamoyl-transferases it was discovered that carbamoyl phosphate is essential for formation of active [NiFe]-hydrogenases in vivo and is specifically required for metal center synthesis suggesting that it is the source of the CO and CN ligands. A chemical path for conversion of a carbamoyl group into cyano and carbonyl moieties is postulated     

产甲烷古菌铁氢酶研究进展

根据活性中心金属原子的不同,氢酶主要分为镍铁、铁铁、铁氢酶三大类。铁氢酶是发现较晚、存在物种单一且结构较为特殊的一类氢酶。目前,铁氢酶仅发现于氢营养型产甲烷古菌中。该酶直接催化氢气异裂,还原产甲烷代谢途径中一碳载体四氢蝶呤的次甲基转化为亚甲基。与其他两类氢酶相比,铁氢酶不含传递电子的铁硫簇和双金属活性中心,在结构组成上有较大的差异。此外,铁氢酶活性中心的吡啶环被高度取代,活性中心铁原子直接与酰基碳成键,这些奇特的活性分子结构预示着氢酶全新的催化机制,以及古菌细胞在合成特殊结构大分子方面的特殊功能。本文总结了从1990年发现这类新型氢酶以来的相关研究,分别从氢酶的生理功能、结构特征、催化机制、成熟过程及应用研究等方面阐述铁氢酶的研究进展。     

The CO and CN(-) ligands to the active site Fe in [NiFe]-hydrogenase of Escherichia coli have different metabolic origins

The Fe atom in the bimetallic active site of [NiFe]-hydrogenases has one CO and two cyanide ligands. To determine their metabolic origin, [NiFe]-hydrogenase-2 was isolated from Escherichia coli grown in the presence of L-[ureido-(13)C]citrulline, purified and analyzed by infrared spectroscopy. The spectra indicate incorporation of (13)C only into the cyanide ligands and not into the CO, showing that cyanide and CO have different metabolic origins. After growth of E. coli in the presence of (13)CO only the CO ligand was labelled with (13)C. Labelling did not result from an exchange of the intrinsic CO ligand with the exogenous CO.     

The hows and whys of aerobic H2 metabolism

The bacterial [NiFe]-hydrogenases have been classified as either 'standard' or 'O2-tolerant' based on their ability to function in the presence of O2. Typically, these enzymes contain four redox-active metal centers: a Ni-Fe-CO-2CN- active site and three electron-transferring Fe-S clusters. Recent research suggests that, rather than differences at the catalytic active site, it is a novel Fe-S cluster electron transfer (ET) relay that controls how [NiFe]-hydrogenases recover from O2 attack. In light of recent structural data and mutagenic studies this article reviews the molecular mechanism of O2-tolerance in [NiFe]-hydrogenases and discusses the biosynthesis of the unique Fe-S relay.     

Metallocenter assembly of the hydrogenase enzymes

The biosynthesis of the [NiFe]- and [FeFe]-hydrogenase enzymes requires the activities of multiple proteins that assemble the intricate metallocenters on the enzyme precursor proteins in an energy-dependent process. These accessory proteins include enzymes that synthesize the non-protein iron ligands as well as metallochaperones for the delivery of nickel to the [NiFe]-hydrogenase. Over the past few years many of these proteins have been examined in vitro. The biochemical properties, in the context of the earlier genetic studies, provide a basis for assigning function to the individual accessory proteins and mapping out the sequential steps of the metallocenter assembly pathways. This framework will serve as a foundation for detailed mechanistic analysis of these complex biomolecular factories.     

Carbamoylphosphate serves as the source of CN(-), but not of the intrinsic CO in the active site of the regulatory [NiFe]-hydrogenase from Ralstonia eutropha

Within the catalytic centre of [NiFe]-hydrogenases one carbonyl and two cyanide ligands are covalently attached to the iron. To identify the metabolic origins of these ligands, the regulatory [NiFe] hydrogenase in conjunction with the indigenous Hyp maturation proteins of Ralstonia eutropha H16 were heterologously overproduced in E. coli grown in the presence of L-[ureido-(13)C] citrulline and NaH(13)CO(3). Infrared spectroscopy of purified hydrogenase provided direct evidence that only the cyanide ligands, but not the CO ligand, originate from CO(2) and carbamoylphosphate. Incorporation of label from (13)CO exclusively into the carbonyl ligand indicates that free CO is a possible precursor in carbonyl ligand biosynthesis.     

Spectroelectrochemical characterization of the [NiFe] hydrogenase of Desulfovibrio vulgaris Miyazaki F

The active site in the [NiFe] hydrogenase of Desulfovibrio vulgaris Miyazaki F has been investigated by Fourier transform infrared (FTIR) spectroscopy. Analysis of the spectra allowed the three diatomic inorganic ligands to Fe in this enzyme to be identified as one CO molecule and two CN(-) molecules. Furthermore, pH-dependent redox titrations were performed to determine the midpoint potentials as well as the pK value of the respective reactions and revealed that each single-electron redox transition is accompanied by a single-proton transfer step. The comparison of these spectra with those published for other [NiFe] hydrogenases shows that the electronic structure of the active sites of these enzymes and their redox processes are essentially the same. Nevertheless, differences with respect to the frequency of the CO band and the pH dependence of the Ni-R states have been observed. Finally, the frequency shifts of the bands in the IR spectra were interpreted with respect to the electronic configuration of the redox intermediates in the catalytic cycle.     

Isocyanides inhibit [Fe]-hydrogenase with very high affinity

[Fe]-Hydrogenase catalyzes the reversible activation of H₂. CO and CN⁻ inhibit this enzyme with low affinity (K_i ≅ 0.1 mM) by binding to the iron site of the bound iron-guanyrylpyridinol cofactor. We report here that isocyanides, which are formally isoelectronic with CO and CN⁻, strongly inhibit [Fe]-hydrogenase (K_i as low as 1 nM). The [NiFe]- and [FeFe]-hydrogenases tested were not inhibited by isocyanides. UV–Vis and infrared spectra revealed that the isocyanides bind to the iron center of [Fe]-hydrogenase. The inhibition kinetics are in agreement with the proposed catalytic mechanism, including the open/closed conformational change of the enzyme.     

The presence of a SO molecule in [NiFe] hydrogenase from Desulfovibrio vulgaris Miyazaki as detected by mass spectrometry

The active site of [NiFe] hydrogenase is a binuclear metal complex composed of Fe and Ni atoms and is called the Ni–Fe site, where the Fe atom is known to be coordinated to three diatomic ligands. Two mass spectrometric techniques, pyrolysis-MS (pyrolysis-mass spectrometry) and TOF-SIMS (time-of-flight secondary ion mass spectrometry), were applied to several proteins, including native and denatured forms of [NiFe] hydrogenase from Desulfovibrio vulgaris Miyazaki F, [Fe₄S₄]₂-ferredoxin from Clostridium pasteurianum, [Fe₂S₂]-ferredoxin from Spirulina platensis, and porcine pepsin. Pyrolysis-MS revealed that only native hydrogenase liberated SO/SO₂ (ions of m/z 48 and 64 at an equilibrium ratio of SO and SO₂) at relatively low temperatures before the covalent bonds in the polypeptide moiety started to decompose. TOF-SIMS indicated that native Miyazaki hydrogenase released SO/SO₂ (m/z 47.97 and 63.96) as secondary ions when irradiated with a high-energy Ga⁺ beam. Denatured hydrogenase, clostridial ferredoxin, and pepsin did not release SO as a secondary ion. The FT-IR spectrum of the enzyme suggested the presence of CO and CN. These lines of evidence suggest that the three diatomic ligands coordinated to the Fe atom at the Ni–Fe site in Miyazaki hydrogenase are SO, CO, and CN. The role of the SO ligand in helping to cleave H₂ molecules at the active site and stabilizing the Fe atom in the diamagnetic Fe(II) state in the redox cycle of this enzyme is discussed.     

Extending the motif of the [FeFe]-hydrogenase active site models: protonation of Fe2(NR)2(CO)6-xLx species

Studies on diiron dithiolato complexes have proven fruitful for modeling the active site of the [FeFe]-hydrogenases. Here we present a departure from the classical Fe(2)S(2) motif by examining the viability of Fe(2)N(2) butterfly compounds as functional models for the diiron active site of [FeFe]-hydrogenases. Derivatization of Fe(2)(BC)(CO)(6) (1, BC=benzo-[c]-cinnoline) with PMe(3) affords Fe(2)(BC)(CO)(4)(PMe(3))(2), which subsequently undergoes protonation at the Fe-Fe bond. The hydride [(mu-H)Fe(2)(BC)(CO)(4)(PMe(3))(2)]PF(6) was characterized crystallographically as the C(2v) isomer. It represents a rare example of a hydrido diiron complex that exists as observable isomers, depending on the location of the phosphine ligands--diapical and apical-basal. This hydride catalyzes the electrochemical reduction of protons.     

A Universal Scaffold for Synthesis of the Fe(CN)2(CO) Moiety of [NiFe] Hydrogenase

Hydrogen-cycling [NiFe] hydrogenases harbor a dinuclear catalytic center composed of nickel and iron ions, which are coordinated by four cysteine residues. Three unusual diatomic ligands in the form of two cyanides (CN⁻) and one carbon monoxide (CO) are bound to the iron and apparently account for the complexity of the cofactor assembly process, which involves the function of at least six auxiliary proteins, designated HypA, -B, -C, -D, -E, and -F. It has been demonstrated previously that the HypC, -D, -E, and -F proteins participate in cyanide synthesis and transfer. Here, we show by infrared spectroscopic analysis that the purified HypCD complexes from Ralstonia eutropha and Escherichia coli carry in addition to both cyanides the CO ligand. We present experimental evidence that in vivo the attachment of the CN⁻ ligands is a prerequisite for subsequent CO binding. With the aid of genetic engineering and subsequent mutant analysis, the functional role of conserved cysteine residues in HypD from R. eutropha was investigated. Our results demonstrate that the HypCD complex serves as a scaffold for the assembly of the Fe(CN)₂(CO) entity of [NiFe] hydrogenase.     

Probing the origin of the metabolic precursor of the CO ligand in the catalytic center of [NiFe] hydrogenase

The O(2)-tolerant [NiFe] hydrogenases of Ralstonia eutropha are capable of H(2) conversion in the presence of ambient O(2). Oxygen represents not only a challenge for catalysis but also for the complex assembling process of the [NiFe] active site. Apart from nickel and iron, the catalytic center contains unusual diatomic ligands, namely two cyanides (CN(-)) and one carbon monoxide (CO), which are coordinated to the iron. One of the open questions of the maturation process concerns the origin and biosynthesis of the CO group. Isotope labeling in combination with infrared spectroscopy revealed that externally supplied gaseous (13)CO serves as precursor of the carbonyl group of the regulatory [NiFe] hydrogenase in R. eutropha. Corresponding (13)CO titration experiments showed that a concentration 130-fold higher than ambient CO (0.1 ppmv) caused a 50% labeling of the carbonyl ligand in the [NiFe] hydrogenase, leading to the conclusion that the carbonyl ligand originates from an intracellular metabolite. A novel setup allowed us to the study effects of CO depletion on maturation in vivo. Upon induction of CO depletion by addition of the CO scavenger PdCl(2), cells cultivated on H(2), CO(2), and O(2) showed severe growth retardation at low cell concentrations, which was on the basis of partially arrested hydrogenase maturation, leading to reduced hydrogenase activity. This suggests gaseous CO as a metabolic precursor under these conditions. The addition of PdCl(2) to cells cultivated heterotrophically on organic substrates had no effect on hydrogenase maturation. These results indicate at least two different pathways for biosynthesis of the CO ligand of [NiFe] hydrogenase.     

Application of gene-shuffling for the rapid generation of novel [FeFe]-hydrogenase libraries

A gene-shuffling technique was identified, optimized and used to generate diverse libraries of recombinant [FeFe]-hydrogenases. Six native [FeFe]-hydrogenase genes from species of Clostridia were first cloned and separately expressed in Escherichia coli concomitantly with the assembly proteins required for [FeFe]-hydrogenase maturation. All enzymes, with the exception of C. thermocellum HydA, exhibited significant activity when expressed. Single-stranded DNA fragments from genes encoding the two most active [FeFe]-hydrogenases were used to optimize a gene-shuffling protocol and generate recombinant enzyme libraries. Random sampling demonstrates that several shuffled products are active. This represents the first successful application of gene-shuffling using hydrogenases. Moreover, we demonstrate that a single set of [FeFe]-hydrogenase maturation proteins is sufficient for the heterologous assembly of the bioinorganic active site of several native and shuffled [FeFe]-hydrogenases.     

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.     

The cyanobacterium Synechocystis sp. PCC 6803 is able to express an active [FeFe]-hydrogenase without additional maturation proteins

[FeFe]-hydrogenases have been claimed as the most promising catalysts of hydrogen bioproduction and several efforts have been accomplished to express and purify them. However, previous attemps to obtain a functional recombinant [FeFe]-hydrogenase in heterologous systems such as Escherichia coli failed due to the lack of the specific maturation proteins driving the assembly of its complex active site. The unique exception is that of [FeFe]-hydrogenase from Clostridium pasteurianum that has been expressed in active form in the cyanobacterium Synechococcus PCC 7942, which holds a bidirectional [NiFe]-hydrogenase with a well characterized maturation system, suggesting that the latter is flexible enough to drive the synthesis of a [FeFe]-enzyme. However, the capability of cyanobacteria to correctly fold a [FeFe]-hydrogenase in the absence of its auxiliary maturation proteins is a debated question. In this work, we expressed the [FeFe]-hydrogenase from Chlamydomonas reinhardtii as an active enzyme in the cyanobacterium Synechocystis sp. PCC 6803. Our results, using a different experimental system, confirm that cyanobacteria are able to express a functional [FeFe]-hydrogenase even in the absence of additional chaperones.     

Molecular biology of microbial hydrogenases

Hydrogenases (H2ases) are metalloproteins. The great majority of them contain iron-sulfur clusters and two metal atoms at their active center, either a Ni and an Fe atom, the [NiFe]-H2ases, or two Fe atoms, the [FeFe]-H2ases. Enzymes of these two classes catalyze the reversible oxidation of hydrogen gas (H2 <--> 2 H+ + 2 e-) and play a central role in microbial energy metabolism; in addition to their role in fermentation and H2 respiration, H2ases may interact with membrane-bound electron transport systems in order to maintain redox poise, particularly in some photosynthetic microorganisms such as cyanobacteria. Recent work has revealed that some H2ases, by acting as H2-sensors, participate in the regulation of gene expression and that H2-evolving H2ases, thought to be involved in purely fermentative processes, play a role in membrane-linked energy conservation through the generation of a protonmotive force. The Hmd hydrogenases of some methanogenic archaea constitute a third class of H2ases, characterized by the absence of Fe-S cluster and the presence of an iron-containing cofactor with catalytic properties different from those of [NiFe]- and [FeFe]-H2ases. In this review, we emphasise recent advances that have greatly increased our knowledge of microbial H2ases, their diversity, the structure of their active site, how the metallocenters are synthesized and assembled, how they function, how the synthesis of these enzymes is controlled by external signals, and their potential use in biological H2 production.     

Structure of hydrogenase maturation protein HypF with reaction intermediates shows two active sites

[NiFe]-hydrogenases are multimeric proteins. The?large subunit contains the NiFe(CN)(2)CO bimetallic active center and the small subunit contains Fe-S clusters. Biosynthesis and assembly of the NiFe(CN)(2)CO active center requires six Hyp accessory proteins. The synthesis of the CN(-) ligands is?catalyzed by the combined actions of HypF and?HypE using carbamoylphosphate as a substrate.?We report the structure of Escherichia coli HypF(92-750) lacking the N-terminal acylphosphatase domain. HypF(92-750) comprises the novel Zn-finger domain, the nucleotide-binding YrdC-like domain, and the Kae1-like universal domain, also binding a nucleotide and a Zn(2+) ion. The two nucleotide-binding sites are sequestered in an internal cavity, facing each other and separated by ～14??. The YrdC-like domain converts carbamoyl moiety to a carbamoyl adenylate intermediate, which is channeled to the Kae1-like domain. Mutations within either nucleotide-binding site compromise hydrogenase maturation but do not affect the carbamoylphosphate phosphatase activity.     

The role of the maturase HydG in [FeFe]-hydrogenase active site synthesis and assembly

[FeFe]-hydrogenases catalyze the protons/hydrogen interconversion through a unique di-iron active site consisting of three CO and two CN ligands, and a non-protein SCH₂XCH₂S (X = N or O) dithiolate bridge. Site assembly requires two “Radical-S-adenosylmethionine (SAM or AdoMet)” iron-sulfur enzymes, HydE and HydG, and one GTPase, HydF. The sequence homology between HydG and ThiH, a Radical-SAM enzyme which cleaves tyrosine into p-cresol and dehydroglycine, and the finding of a similar cleavage reaction catalyzed by HydG suggests a mechanism for hydrogenase maturation. Here we propose that HydG is specifically involved in the synthesis of the dithiolate ligand, with two tyrosine-derived dehydroglycines as precursors along with an [FeS] cluster of HydG functioning both as electron shuttle and source of the sulfur atoms.     

Unusual FTIR and EPR properties of the H2-activating site of the cytoplasmic NAD-reducing hydrogenase from Ralstonia eutropha

Soluble NAD-reducing [NiFe]-hydrogenase (SH) from Ralstonia eutropha (formerly Alcaligenes eutrophus) has an infrared spectrum with one strong band at 1956 cm(-1) and four weak bands at 2098, 2088, 2081 and 2071 cm(-1) in the 2150-1850 cm(-1) spectral region. Other [NiFe]-hydrogenases only show one strong and two weak bands in this region, attributable to the NiFe(CN)2(CO) active site. The position of these three bands is highly sensitive to redox changes of the active site. In contrast, reduction of the SH resulted in a shift to lower frequencies of the 2098 cm(-1) band only. These and other properties prompted us to propose the presence of a Ni(CN)Fe(CN)3(CO) active site.