Primary structure of hydrogenase I from Clostridium pasteurianum

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

Structural similarities between MutT and the C-terminal domain of MutY

One of the functions of MutY from Escherchia coli is removal of adenine mispaired with 7,8-dihydro-8-oxoguanine (8-oxoG), a common lesion in oxidatively damaged DNA. MutY is composed of two domains: the larger N-terminal domain (p26) contains the catalytic properties of the enzyme while the C-terminal domain (p13) affects substrate recognition and enzyme turnover. On the basis of sequence analyses, it has been recently suggested that the C-terminal domain is distantly related to MutT, a dNTPase which hydrolyzes 8-oxo-dGTP [Noll et al. (1999) Biochemistry 38, 6374-6379]. We have studied the solution structure of the C-terminal domain of MutY by NMR and find striking similarity with the reported solution structure of MutT. Despite low sequence identity between the two proteins, they have similar secondary structure and topology. The C-terminal domain of MutY is composed of two alpha-helices and five beta-strands. The NOESY data indicate that the protein has two beta-sheets. MutT is also a mixed alpha/beta protein with two helices and two beta-sheets composed of five strands. The secondary structure elements are similarly arranged in the two proteins.     

The mechanisms of H2 activation and CO binding by hydrogenase I and hydrogenase II of Clostridium pasteurianum

Hydrogenase I (bidirectional) and hydrogenase II (uptake) of Clostridium pasteurianum have been investigated by electron paramagnetic resonance (EPR) spectroscopy, in the presence and absence of the inhibitor, CO. These hydrogenases contain both a novel type of iron-sulfur cluster (H), which is the proposed site of H2 catalysis, and ferredoxin-type [4Fe-4S] clusters (F). The results show that the H clusters of these two hydrogenases have very different properties. The H cluster of oxidized hydrogenase II (Hox-II) exhibits three distinct EPR signals, two of which are pH-dependent. Hox-II binds CO reversibly to give a single, pH-independent species with a novel, rhombic EPR spectrum. The H cluster of reduced hydrogenase II (Hred-II) does not react with CO. In contrast, the EPR spectrum of Hox-I appears homogeneous and independent of pH. Hox-I has a much lower affinity for CO than Hox-II, and binds CO irreversibly to give an axial EPR signal. Hred-I also binds CO irreversibly. The EPR spectra of Fred-I and Fred-II show little or no change after CO treatment. Prior exposure to CO does not affect the catalytic activity of the reduced or oxidized hydrogenases when assayed in the absence of CO, but both enzymes are irreversibly inactivated if CO is present during catalysis. Mechanisms for H2 activation by hydrogenase I and hydrogenase II are proposed from the determined midpoint potentials (Em, pH 8.0) of H-I and H-II (Em approximately -400 mV, -CO; approximately -360 mV, +CO), F-I (Em = -420 mV, +/- CO), and F-II (Em = -180 mV, +/- CO). These allow one to rationalize the different modes of CO binding to the two hydrogenases and suggest why hydrogenase II preferentially catalyzes H2 oxidation. The results are discussed in light of recent spectroscopic data on the structures of the two H clusters.     

The purification of hydrogenase II (uptake hydrogenase) from the anaerobic N2-fixing bacterium Clostridium pasteurianum

The H₂ uptake activity (units/mg protein) of Clostridium pasteurianum cells with methylene blue as the electron acceptor increases with cell density independent of the growth conditions. The H₂ evolution activity (units/mg protein) of the same cells with reduced methyl viologen as the electron donor remains fairly constant under all growth conditions tested. Cells grown under N₂-fixing conditions have the highest H₂ uptake activity and were used for the purification of hydrogenase II (uptake hydrogenase). Attempts to separate hydrogenase II from hydrogenase I (bidirectional hydrogenase) by a previously published method were unreliable. We report here a new large-scale purification procedure which employs a rapid membrane filtration system to fractionate cell-free extracts. Hydrogenases I and II were easily filtered into the low-molecular-weight fraction (M_r less than 100 000), and from this, hydrogenase II was further purified to a homogeneous state. Hydrogenase II is a monomeric iron-sulfur protein of molecular weight 53 000 containing eight iron atoms and eight acid-labile sulfur atoms per molecule. Hydrogenase II catalyzes both H₂ oxidation and H₂ evolution at rates of 3000 and 5.9 μmol H₂ consumed or evolved/min per mg protein, respectively. The purification procedure for hydrogenase II using the filtration system described greatly facilitates the large-scale purification of hydrogenase I and other enzymes from cell-free extracts of C. pasteurianum.     

Electron paramagnetic resonance studies of the low temperature photolytic behavior of oxidized hydrogenase I from Clostridium pasteurianum

The effects of CO and O2 on the EPR spectrum of oxidized Clostridium pasteurianum hydrogenase I have been investigated both before and after prolonged exposure to white light at 8 K and 30 K. Low concentrations of O2 were found to induce analogous changes in the EPR spectrum as CO, i.e. conversion of the rhombic signal with g approximately 2.10, 2.04, 2.00, a characteristic of the novel H2-activating center in oxidized Fe-hydrogenases, to an axial signal with g approximately 2.07, 2.01, 2.01. The results suggest a common binding site and mode of coordination for CO and O2 and permit rationalization of conflicting reports from different laboratories concerning the EPR properties of oxidized Fe-hydrogenases. The CO- and O2-induced axial EPR signals were found to be light-sensitive at low temperatures. Moreover, they exhibited indistinguishable and unusual photolysis behavior with the dominant photo-product being dependent on the temperature at which illumination was performed. At 8 K, photodissociation of CO or O2 occurs, resulting in an EPR signal identical with that of the oxidized enzyme in the absence of CO or O2. However, at 30 K, the dominant photoproduct is a rhombic EPR signal with g approximately 2.26, 2.12, 1.89. While the origin of this new EPR signal is uncertain, the g-value anisotropy and relaxation characteristics resemble those of a low spin Fe(III) center. These two photoproducts cannot be thermally or photolytically interconverted, but both are quantitatively reconverted to the original axial EPR signal on warming in the dark to 200 K. A tentative working hypothesis for the nature of the H2-activating center of Fe-hydrogenases is presented that is consistent with the available physiochemical data and permits rationalization of the novel photolysis behavior.     

M?ssbauer study of Clostridium pasteurianum hydrogenase II. Evidence for a novel three-iron cluster

Hydrogenase II contains two iron-sulfur clusters, one of the [4Fe-4S] type and one of unknown structure with unusual spectral properties (H-cluster). Using M?ssbauer spectroscopy we have studied the H-cluster under a variety of conditions. In the reduced state the cluster exhibits, in zero magnetic field, spectra with the typical 2:1 quadrupole pattern of reduced [3Fe-4S] clusters. However, whereas the latter are paramagnetic (S = 2) the H-cluster is diamagnetic (S = 0). Upon oxidation and exposure to CO the H-cluster exhibits an S = 1/2 EPR spectrum with g values at 2.03, 2.02, and 2.00. In this state, the M?ssbauer spectra reveal two cluster subsites with magnetic hyperfine coupling constants AI = +26.5 MHz and AII = -30 MHz. ENDOR data obtained by Hoffman and co-workers (Telser, J., Benecky, M. J., Adams, M. W. W., Mortenson, L. E., and Hoffman, B. M. (1986) J. Biol. Chem. 261, 13536-13541) show a 57Fe resonance at AIII approximately equal to 9.5 MHz. Analysis of the M?ssbauer spectra shows that this resonance represents one iron site. Our studies of the reduced and CO-bound oxidized states of hydrogenase II suggest that the H-cluster contains three iron atoms. The data obtained for the oxidized H-cluster suggest a novel type of 3-Fe cluster and bear little resemblance to those reported for oxidized [3Fe-4S] clusters with g = 2.01 EPR signals. In the reduced sample the [4Fe-4S]1+ cluster appears to occur in a mixture of two distinct electronic states.     

Structural basis for thermostability in aporubredoxins from Pyrococcus furiosus and Clostridium pasteurianum

The structures of apo- and holorubredoxins from Pyrococcus furiosus (PfRd) and Clostridium pasteurianum (CpRd) have been investigated and compared using residual dipolar couplings to probe the origin of thermostability. In the native, metal (Fe or Zn) containing form, both proteins can maintain native structure at very high temperatures (>70 degrees C) for extended periods of time. Significant changes in either structure or backbone dynamics between 25 and 70 degrees C are not apparent for either protein. A kinetic difference with respect to metal loss is observed as in previous studies, but the extreme stability of both proteins in the presence of metal makes thermodynamic differences difficult to monitor. In the absence of metal, however, a largely reversible thermal denaturation can be monitored, and a comparison of the two apoproteins can offer insights into the origin of stability. Below denaturation temperatures apo-PfRd is found to have a structure nearly identical to that of the native holo form, except immediately adjacent to the metal binding site. In contrast, apo-CpRd is found to have a structure distinctly different from that of its holo form at low temperatures. This structure is rapidly lost upon heating, unfolding at approximately 40 degrees C. A PfRd mutant with the hydrophobic core mutated to match that of CpRd shows no change in thermostability in the metal-free state. A metal-free chimera with residues 1-15 of CpRd and the remaining 38 residues of PfRd is severely destabilized and is unfolded at 25 degrees C. Hence, the hydrophobic core does not seem to be the key determinant of thermostability; instead, data point to the hydrogen bond network centered on the first 15 residues or the interaction of these 15 residues with other parts of the protein as a possible contributor to the thermostability.     

Formate dehydrogenase of Clostridium pasteurianum

Formate dehydrogenase was purified to electrophoretic homogeneity from N2-fixing cells of Clostridium pasteurianum W5. The purified enzyme has a minimal Mr of 117,000 with two nonidentical subunits with molecular weights of 76,000 and 34,000, respectively. It contains 2 mol of molybdenum, 24 mol of nonheme iron, and 28 mol of acid-labile sulfide per mol of enzyme; no other metal ions were detected. Analysis of its iron-sulfur centers by ligand exchange techniques showed that 20 iron atoms of formate dehydrogenase can be extruded as Fe4S4 centers. Fluorescence analysis of its isolated molybdenum centers suggests it is a molybdopterin. The clostridial formate dehydrogenase has a pH optimum between 8.3 and 8.5 and a temperature optimum of 52 degrees C. The Km for formate is 1.72 mM with a Vmax of 551 mumol of methyl viologen reduced per min per mg of protein. Sodium azide competes competitively with formate (K1 = 3.57 microM), whereas the inactivation by cyanide follows pseudo-first-order kinetics with K = 5 X 10(2) M-1 s-1.     

Vertebrate-type and plant-type ferredoxins: crystal structure comparison and electron transfer pathway modelling

Crystallographic analysis of a fully functional, truncated bovine adrenodoxin, Adx(4-108), has revealed the structure of a vertebrate-type [2Fe-2S] ferredoxin at high resolution. Adrenodoxin is involved in steroid hormone biosythesis in adrenal gland mitochondria by transferring electrons from adrenodoxin reductase to different cytochromes P450. Plant-type [2Fe-2S] ferredoxins interact with photosystem I and a diverse set of reductases.A systematic structural comparison of Adx(4-108) with plant-type ferredoxins which share about 20 % sequence identity yields these results. (1) The ferredoxins of both types are partitioned into a large, strictly conserved core domain bearing the [2Fe-2S] cluster and a smaller interaction domain which is structurally different for both subfamilies. (2) In both types, residues involved in interactions with reductase are located at similar positions on the molecular surface and coupled to the [2Fe-2S] cluster via structurally equivalent hydrogen bonds. (3) The accessibility of the [2Fe-2S] cluster differs between Adx(4-108) and the plant-type ferredoxins where a solvent funnel leads from the surface to the cluster. (4) All ferredoxins are negative monopoles with a clear charge separation into two compartments, and all resulting dipoles but one point into a narrow cone located in between the interaction domain and the [2Fe-2S] cluster, possibly controlling predocking movements during interactions with redox partners. (5) Model calculations suggest that FE1 is the origin of electron transfer pathways to the surface in all analyzed [2Fe-2S] ferredoxins and that additional transfer probability for electrons tunneling from the more buried FE2 to the cysteine residue in position 92 of Adx is present in some.     

Chromatographic separation of extruded iron-sulfur cores from the apoproteins of Clostridium pasteurianum and spinach ferredoxins in aqueous Triton X-100/urea

Iron-sulfur core extrusions from spinach [( 2Fe-2S]) and Clostridium pasteurianum (2[4Fe-4S]) ferredoxins in aqueous Triton X-100/urea containing excess benzenethiol yield quantitatively [FenSn(SPh)4]2- with n = 2 and n = 4, respectively. The iron-sulfur cluster can be separated from the corresponding apoprotein by rapid passage of the extrusion mixture over a small anaerobic column of Whatman DE-52 anion-exchange cellulose. Essentially quantitative recovery of [FenSn (SPh)4]2- is achieved in the eluate. The apoprotein remaining on the column can be eluted with 0.5 M NaCl. Most of the residual Triton X-100 and benzenethiol can be removed by passage of the apoprotein eluate over a small column of Bio-Beads SM-2, a hydrophobic polystyrene adsorbent. Apoprotein recovery is comparable to that obtained by other chromatographic methods. At least with spinach ferredoxin, the apoprotein prepared in this fashion can be reconstituted. The procedures developed in this work are potentially most applicable to selective removal of [2Fe-2S] and [4Fe-4S] centers from a multicenter enzyme without irreversible denaturation.     

An investigation of hydrogenase I and hydrogenase II from Clostridium pasteurianum by resonance Raman spectroscopy. Evidence for a [2Fe-2S] cluster in hydrogenase I

Resonance Raman spectra are reported for hydrogenase I and II from Clostridium pasteurianum. These spectra show overlapping bands with contributions from [4Fe-4S] clusters, known to be present in these enzymes, and from novel FeS centers of hitherto undefined structure. For hydrogenase I there are strong bands at 288 and 394 cm-1, which are seen in [2Fe-2S] proteins and in no other FeS species so far examined. In contrast these bands do not appear for hydrogenase II, whose resonance Raman spectrum is dominated by [4Fe-4S] cluster modes. These results provide the first structural information on the hydrogenase I FeS center involved in H2 activation and demonstrate structural differences between hydrogenase I and hydrogenase II.     

Isolation of mutants of Clostridium pasteurianum

Twenty-nine independent mutants of Clostridium pasteurianum ATCC 6013, including several auxotrophs and UV resistants, have been isolated and characterized. The protoplast formation and regeneration procedure of Minton and Morris (1983) has also been successfully tried with some of these newly obtained mutants. The availability of these mutants together with the possibility of protoplast formation and regeneration will be useful for the development of a genetic exchange system in this species.Abbreviations CFU colony forming unit - DCCP dicyclohexyl carbodiamide - EMS ethylmethane sulfonate - IB isotonic buffer - MNNG N-methyl-N-nitro-N-nitrosoguanidine - PEG polyethylene glycol - UV ultraviolet