Activation and deactivation of the membrane-bound hydrogenase from Desulfovibrio desulfuricans, Norway strain

The hydrogenase from D. desulfuricans, when isolated in air, had a low activity in the hydrogen-methyl viologen reductase assay, and no activity in the hydrogen-methylene blue reductase assay. The activity increased markedly during incubation under hydrogen. This process is interpreted in terms of conversion of the enzyme from a relatively inactive Unready state to the Active state. Oxidation by dichloro-indophenol caused conversion to a state in which the hydrogen-uptake activity to methyl viologen was preserved, but hydrogen-methylene blue activity was not. This form is termed the Ready state. This behaviour resembles that of the hydrogenase of Desulfovibrio gigas and thus may be a widespread property of this class of hydrogenases. The electron-spin-resonance spectra of the D. desulfuricans enzyme showed the presence of [3Fe-xS] and [4Fe-4S] clusters. Spectra were also observed in the various states of activation of the enzyme. In these respects, the hydrogenase of D. desulfuricans resembles that from D. gigas, although the latter may have an additional iron-sulphur cluster.     

The presence of multiple intrinsic membrane nickel-containing hydrogenases in Desulfovibrio vulgaris (Hildenborough)

Three intrinsic membrane proteins exhibiting oxygen stable hydrogenase activity have been isolated from D. vulgaris. In contrast to the periplasmic exclusively non-heme iron hydrogenase, all three hydrogenases contain Ni in addition to non-heme iron, have low specific activities and are insensitive to inhibition by CO. None of the three hydrogenases cross react with IgA against the periplasmic hydrogenase of D. vulgaris but two of the new hydrogenases cross react with IgA against the periplasmic nickel containing hydrogenase of D. gigas and the other new hydrogenase cross reacts with IgA against the periplasmic nickel and selenium hydrogenase of D. desulfuricans (Norway -4).     

The three classes of hydrogenases from sulfate-reducing bacteria of the genus Desulfovibrio

Three types of hydrogenases have been isolated from the sulfate-reducing bacteria of the genus Desulfovibrio. They differ in their subunit and metal compositions, physico-chemical characteristics, amino acid sequences, immunological reactivities, gene structures and their catalytic properties. Broadly, the hydrogenases can be considered as 'iron only' hydrogenases and nickel-containing hydrogenases. The iron-sulfur-containing hydrogenase ([Fe] hydrogenase) contains two ferredoxin-type (4Fe-4S) clusters and an atypical iron-sulfur center believed to be involved in the activation of H2. The [Fe] hydrogenase has the highest specific activity in the evolution and consumption of hydrogen and in the proton-deuterium exchange reaction and this enzyme is the most sensitive to CO and NO2-. It is not present in all species of Desulfovibrio. The nickel-(iron-sulfur)-containing hydrogenases [( NiFe] hydrogenases) possess two (4Fe-4S) centers and one (3Fe-xS) cluster in addition to nickel and have been found in all species of Desulfovibrio so far investigated. The redox active nickel is ligated by at least two cysteinyl thiolate residues and the [NiFe] hydrogenases are particularly resistant to inhibitors such as CO and NO2-. The genes encoding the large and small subunits of a periplasmic and a membrane-bound species of the [NiFe] hydrogenase have been cloned in Escherichia (E.) coli and sequenced. Their derived amino acid sequences exhibit a high degree of homology (70%); however, they show no obvious metal-binding sites or homology with the derived amino acid sequence of the [Fe] hydrogenase. The third class is represented by the nickel-(iron-sulfur)-selenium-containing hydrogenases [( NiFe-Se] hydrogenases) which contain nickel and selenium in equimolecular amounts plus (4Fe-4S) centers and are only found in some species of Desulfovibrio. The genes encoding the large and small subunits of the periplasmic hydrogenase from Desulfovibrio (D.) baculatus (DSM 1743) have been cloned in E. coli and sequenced. The derived amino acid sequence exhibits homology (40%) with the sequence of the [NiFe] hydrogenase and the carboxy-terminus of the gene for the large subunit contains a codon (TGA) for selenocysteine in a position homologous to a codon (TGC) for cysteine in the large subunit of the [NiFe] hydrogenase. EXAFS and EPR studies with the 77Se-enriched D. baculatus hydrogenase indicate that selenium is a ligand to nickel and suggest that the redox active nickel is ligated by at least two cysteinyl thiolate and one selenocysteine selenolate residues.(ABSTRACT TRUNCATED AT 400 WORDS)     

Nickel requirement for active hydrogenase formation in Alcaligenes eutrophus.

The nickel-dependent chemolithoautotrophic growth of Alcaligenes eutrophus is apparently due to a requirement of nickel for active hydrogenase formation. Cells grown heterotrophically with fructose and glycerol revealed a specific activity of soluble and membrane-bound hydrogenase which was severalfold higher than the normal autotrophic level. The omission of nickel from the medium did not affect heterotrophic growth, but the soluble hydrogenase activity was reduced significantly. In the presence of ethylenediaminetetraacetic acid (EDTA), almost no hydrogenase activity was detected. The addition of nickel allowed active hydrogenase formation even when EDTA was present. When chloramphenicol was added simultaneously with nickel to an EDTA-containing medium, almost no hydrogenase activity was found. This indicates that nickel ions are involved in a process which requires protein synthesis and not the direct reactivation of a preformed inactive protein. The formation of the membrane-bound hydrogenase also appeared to be nickel dependent. Autotrophic CO2 assimilation did not specifically require nickel ions, since formate was utilized in the presence of EDTA and the activity of ribulosebisphosphate carboxylase was not affected under these conditions.     

Molecular and immunological comparison of membrane-bound, H2-oxidizing hydrogenases of Bradyrhizobium japonicum, Alcaligenes eutrophus, Alcaligenes latus, and Azotobacter vinelandii.

The membrane-bound hydrogenases of Bradyrhizobium japonicum, Alcaligenes eutrophus, Alcaligenes latus, and Azotobacter vinelandii were purified extensively and compared. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of each hydrogenase revealed two prominent protein bands, one near 60 kilodaltons and the other near 30 kilodaltons. The migration distances during nondenaturing polyacrylamide gel electrophoresis were similar for all except A. vinelandii hydrogenase, which migrated further than the other three. The amino acid composition of each hydrogenase was determined, revealing substantial similarity among these enzymes. This was confirmed by calculation of S delta Q values, which ranged from 8.0 to 26.7 S delta Q units. S delta Q is defined as sigma j(Xi,j-Xk,j)2, where i and k identify the proteins compared and Xj is the content (residues per 100) of a given amino acid of type j. The hydrogenases of this study were also compared with an enzyme-linked immunosorbent assay. Antibody raised against B. japonicum hydrogenase cross-reacted with all four hydrogenases, but to various degrees and in the order B. japonicum greater than A. latus greater than A. eutrophus greater than A. vinelandii. Antibody raised against A. eutrophus hydrogenase also cross-reacted with all four hydrogenases, following the pattern of cross-reaction A. eutrophus greater than A. latus = B. japonicum greater than A. vinelandii. Antibody raised against B. japonicum hydrogenase inhibited B. japonicum hydrogenase activity to a greater extent than the A. eutrophus and A. latus activities; no inhibition of A. vinelandii hydrogenase activity was detected. The results of these experiments indicated remarkable homology of the hydrogenases from these four microorganisms.     

The interaction of polymeric viologens with hydrogenases from Desulfovibrio desulfuricans and Clostridium pasteurianum.

The interaction between hydrogenases from either Desulfovibrio desulfuricans or Clostridium pasteurianum and electron donors methyl viologen or polymeric viologens was examined. Extracts from each organism contained a single gel electophoretic band of active hydrogenase. The hydrogenase of D. desulfuricans was much more stable than that of Cl. pasteurianum. With methyl viologen apparent Km and Vm values were 0.5 mM and 0.62 mumole H2/min per milligram protein for the Cl. pasteurianum and 0.7 and 6.2 mumole H2/min per milligram protein, respectively, for the D. desulfuricans enzyme. The hydrogenases bound the polymeric viologens more tightly than methyl viologen, more so for the enzyme of D. desulfuricans than for Cl. pasteurianum. Maximal rate of hydrogen production was less with the polymeric than with methyl viologen. The results suggest that the D. desulfuricans enzyme in conjunction wiion than that from Cl. pasteurianum.     

Comparison of the membrane-bound hydrogenases from Alcaligenes eutrophus H16 and Alcaligenes eutrophus type strain

Whereas the membrane-bound hydrogenase from Alcaligenes eutrophus H16 is an integral membrane protein and can only be solubilized by detergent treatment, the membrane-bound hydrogenase of Alcaligenes eutrophus type strain was found to be present in a soluble form after cell disruption. For the enzyme of A. eutrophus H16 a new, highly effective purification procedure was developed including phase separation with Triton X-114 and triazine dye chromatography on Procion Blue H-ERD-Sepharose. The purification led to an homogeneous hydrogenase preparation with a specific activity of 269 U/mg protein (methylene blue reduction) and a yield of 45%. During purification and storage the enzyme was optimally stabilized by the presence of 0.2 mM MnCl2. The hydrogenase of A. eutrophus type strain was purified from the soluble extract by a similar procedure, however, with less specific activity and activity yield. Comparison of the two purified enzymes revealed no significant differences: They have the same molecular weight, both consist of two different subunits (Mr = 62,000, 31,000) and both have an isoelectric point near pH 7.0. They have the same electron acceptor specificity reacting with similar high rates and similar Km values. The acceptors reduced include viologen dyes, flavins, quinones, cytochrome c, methylene blue, 2,6-dichlorophenolindophenol, phenazine methosulfate and ferricyanide. Ubiquinones and NAD were not reduced. The two hydrogenases were shown to be immunologically identical and both have identical electrophoretic mobility. For the membrane-bound hydrogenase of A. eutrophus H16 it was demonstrated that this type of hydrogenase in its solubilized, purified state is able to catalyze also the reverse reaction, the H2 evolution from reduced methyl viologen.     

Purification of hydrogenases by affinity chromatography on Procion Red-agarose.

The agarose-coupled triazine dye Procion Red HE-3B has been demonstrated to be applicable as an affinity gel for the purification of five diverse hydrogenases, namely the soluble, NAD-specific and the membrane-bound hydrogenase of Alcaligenes eutrophus, the membrane-bound hydrogenase of the N2-fixing Alcaligenes latus, the reversible H2-evolving and the unidirectional H2-oxidizing hydrogenase of Clostridium pasteurianum. In the case of the soluble hydrogenase of A. eutrophus, chromatography on Procion Red-agarose even permitted the separation of inactive from active enzyme, thus yielding a 2-3-fold increase in specific activity. For the homogeneous enzyme preparation obtained after two column steps (Procion Red-agarose, DEAE-Sephacel), a specific activity of 121 mumol of H2 oxidized/min per mg of protein was determined. Kinetic studies with free Procion Red provided evidence that the diverse hydrogenases are competitively inhibited by the dye, each with respect to the electron carrier (NAD, Methylene Blue, Methyl Viologen), indicating a specific interaction between Procion Red and the catalytic centres of the enzymes. For the highly purified preparations of the soluble and the membrane-bound hydrogenase of A. eutrophus, in 50 mM-potassium phosphate, pH 7.0, Ki values for Procion Red of 103 and 19 microM have been determined.     

The membrane-bound hydrogenase of Alcaligenes eutrophus: II. Localization and immunological comparison with other hydrogenase systems

Immunological comparison of the soluble and the membrane-bound hydrogenase of Alcaligenes eutrophus revealed no common antigenic determinants shared by the native proteins, however, a small amount of cross-reacting material was detected after freezing and thawing. Immune precipitation assays supported previous observations indicating the membrane-bound hydrogenase to be localized in the outer surface of the cytoplasmic membrane.The membrane-bound hydrogenases of A. eutrophus and Pseudomonas pseudoflava showed close immunological relationship, and material cross-reacting to both antisera was found in membrane extracts of all hydrogen-oxidizing strains of Pseudomonas, Alcaligenes and Aquaspirillum. Material cross-reacting to the membrane-bound hydrogenase of Xanthobacter autotrophicus GZ 29 was found only in a few hydrogen-oxidizing bacteria. Material cross-reacting to the soluble hydrogenase of A. eutrophus was detected in strains of A. eutrophus and A. ruhlandii only.Comparison of the membrane-bound hydrogenase of A. eutrophus, P. pseudoflava and X. autotrophicus with hydrogenases of other physiological bacterial groups revealed serological relationship to the membrane-bound hydrogenases of the hydrogen bacteria and of Chromatium vinosum only. The results are discussed in terms of physiological, taxonomical, and evolutionary aspects.     

Purification and properties of the soluble hydrogenase from Desulfovibrio desulfuricans (strain Norway 4)

A soluble hydrogenase has been isolated from Desulfovibrio desulfuricans (strain Norway 4) grown on Postgate's medium. The enzyme differs significantly from a membrane-bound hydrogenase previously purified from the same organism grown on Starkey's medium. The enzyme consisted of two subunits of 56 kDa and 29 kDa compared with masses of 60 kDa and 27 kDa for the membrane-bound enzyme. Analysis of preparations of the soluble enzyme by various methods gave values of 5-10 iron atoms, 6 labile sulphur atoms and 0.45-0.8 nickel atom per molecule. The enzyme was unusual in that it contained selenium, in quantities equivalent to nickel. The highly purified active enzyme produced no electron-spin-resonance (ESR) signals in the oxidized state. ESR signals due to a [3Fe-xS] cluster and nickel were observed only in some of the less active fractions of the enzyme, demonstrating that neither of these ESR-detectable components is a prerequisite for hydrogenase activity. Treatment of D. desulfuricans (Norway) cells with EDTA released a minor fraction with hydrogenase activity, which might indicate the presence of a periplasmic enzyme.     

Immunological comparison of subunits isolated from various hydrogenases of aerobic hydrogen bacteria

Polyclonal, monospecific antibodies were produced against the two subunits (Mr 62,000, and Mr 31,000), isolated from the membrane-bound hydrogenase of Alcaligenes eutrophus H16. The antibodies (IgG fractions) were purified from crude sera by Protein A-Sepharose CL-4B chromatography. By double immunodiffusion assays and tandem-crossed immunoelectrophoresis the large and the small subunit were demonstrated not to be immunologically related. Immunological comparison of these subunits with the four non-identical subunits (Mr 63,000, 56,000, 30,000 and 26,000) of the NAD-linked, soluble hydrogenase from A. eutrophus H16 showed that the subunits of the membrane-bound hydrogenase did not cross-react with any of the antibodies raised against the four subunits of the NAD-linked enzyme and that, vice versa, none of these four subunits cross-reacted with antibodies raised against the two subunits of the membrane-bound hydrogenase. This means that A. eutrophus H16 contains altogether six non-identical immunologically unrelated hydrogenase polypeptides. The membrane-bound hydrogenases were isolated and purified from various aerobic H2-oxidizing bacteria: A. eutrophus H16, A. eutrophus type strain, A. eutrophus CH34, A. eutrophus Z1, A. hydrogenophilus, Paracoccus denitrificans and strain Cd2/01. All these proteins resembled each other and each consisted of two non-identical polypeptides. A complete separation of these subunits was achieved at high-yield by preparative FPLC gel filtration on three Superose 12 columns connected in series, using SDS and DTT-containing sodium phosphate buffer (pH 7.0). The small subunits of these enzymes turned out to be immunologically closely related to each other; they were either identical or almost identical. The large subunits were also related, but less pronounced. Only the large subunits from Z1 and type strain reacted fully identical with the H16 subunit. Of the two isolated, homogeneous subunits of the membrane-bound hydrogenase from A. eutrophus H16, the amino acid compositions and the NH2-terminal sequences have been determined. The results confirmed the diversity of the large and the small subunit. Furthermore, for comparison also the NH2-terminal sequences of the two subunits from the hydrogenase of A. eutrophus CH34 have been analysed.     

Structure-function relationships among the nickel-containing hydrogenases.

The enzymology of the heterodimeric (NiFe) and (NiFeSe) hydrogenases, the monomeric nickel-containing hydrogenases plus the multimeric F420-(NiFe) and NAD(+)-(NiFe) hydrogenases are summarized and discussed in terms of subunit localization of the redox-active nickel and non-heme iron clusters. It is proposed that nickel is ligated solely by amino acid residues of the large subunit and that the non-heme iron clusters are ligated by other cysteine-rich polypeptides encoded in the hydrogenase operons which are not necessarily homologous in either structure or function. Comparison of the hydrogenase operons or putative operons and their hydrogenase genes indicate that the arrangement, number and types of genes in these operons are not conserved among the various types of hydrogenases except for the gene encoding the large subunit. Thus, the presence of the gene for the large subunit is the sole feature common to all known nickel-containing hydrogenases and unites these hydrogenases into a large but diverse gene family. Although the different genes for the large subunits may possess only nominal general derived amino acid homology, all large subunit genes sequenced to date have the sequence R-X-C-X-X-C fully conserved in the amino terminal region of the polypeptide chain and the sequence of D-P-C-X-X-C fully conserved in the carboxyl terminal region. It is proposed that these conserved motifs of amino acids provide the ligands required for the binding of the redox-active nickel. The existing EXAFS (Extended X-ray Absorption Fine Structure) information is summarized and discussed in terms of the numbers and types of ligands to the nickel and the various redox species of nickel defined by EPR spectroscopy. New information concerning the ligands to nickel is presented based on site-directed mutagenesis of the gene encoding the large subunit of the (NiFe) hydrogenase-1 of Escherichia coli. Based on considerations of the biochemical, molecular and biophysical information, ligand environments of the nickel in different redox states of the (NiFe) hydrogenase are proposed.     

Characterization of periplasmic hydrogenase from Desulfovibrio vulgaris Miyazaki K

Periplasmic hydrogenase [hydrogen:ferricytochrome c3 oxidoreductase, EC 1.12.2.1] from Desulfovibrio vulgaris Miyazaki K (MK) was purified to homogeneity. Its chemical and immunological properties were examined and compared with those of other Desulfovibrio hydrogenases. The pure enzyme showed a specific activity of 1,000 mumol H2 evolution min-1 (mg protein)-1. The enzyme had a molecular weight of 50,000 as estimated by gel filtration and consisted of a single polypeptide chain. The absorption spectrum of the enzyme was characteristic of an iron-sulfur protein and the extinction coefficients at 400 and 280 nm were 34 and 104 mM-1. cm-1, respectively. It contained 9.4 mol iron and 6.9 mol of acid-labile sulfide per mol. The amino acid composition of the preparation was very similar to the value reported for D. desulfuricans NRC 49001 hydrogenase. Rabbit antisera were prepared against the enzyme of D. vulgaris MK. Ouchterlony double diffusion and immunotitration tests of crude extracts from several strains of Desulfovibrio revealed that the enzyme from MK cells was immunologically identical with those from D. vulgaris Hildenborough and D. desulfuricans NRC 49001, but different from those from D. vulgaris Miyazaki F (MF) and Miyazaki Y, and D. desulfuricans Essex 6 strains. It is concluded that among Desulfovibrio hydrogenases, those from D. vulgaris MK, D. vulgaris Hildenborough and D. desulfuricans NRC 49001 form one group in terms of both subunit structure and antigenicity.     

Cloning and sequencing of a [NiFe] hydrogenase operon from Desulfovibrio vulgaris Miyazaki F

A hydrogenase operon was cloned from chromosomal DNA isolated from Desulfovibrio vulgaris Miyazaki F with the use of probes derived from the genes encoding [NiFe] hydrogenase from Desulfovibrio vulgaris Hildenborough. The nucleic acid sequence of the cloned DNA indicates this hydrogenase to be a two-subunit enzyme: the gene for the small subunit (267 residues; molecular mass = 28763 Da) precedes that for the large subunit (566 residues; molecular mass = 62495 Da), as in other [NiFe] and [NiFeSe] hydrogenase operons. The amino acid sequences of the small and large subunits of the Miyazaki hydrogenase share 80% homology with those of the [NiFe] hydrogenase from Desulfovibrio gigas. Fourteen cysteine residues, ten in the small and four in the large subunit, which are thought to co-ordinate the iron-sulphur clusters and the active-site nickel in [NiFe] hydrogenases, are found to be conserved in the Miyazaki hydrogenase. The subunit molecular masses and amino acid composition derived from the gene sequence are very similar to the data reported for the periplasmic, membrane-bound hydrogenase isolated by Yagi and coworkers, suggesting that this hydrogenase belongs to the general class of [NiFe] hydrogenases, despite its low nickel content and apparently anomalous spectral properties.     

Alcaligenes eutrophus CH34 is a facultative chemolithotroph with plasmid-bound resistance to heavy metals.

Alcaligenes eutrophus strain CH34, which was isolated as a bacterium resistant to cobalt, zinc, and cadmium ions, shares with A. eutrophus strain H16 the ability to grow lithoautotrophically on molecular hydrogen, to form a cytoplasmic NAD-reducing and a membrane-bound hydrogenase, and most metabolic attributes; however, it does not grow on fructose. Strain CH34 contains two plasmids, pMOL28 (163 kilobases) specifying nickel, mercury, and cobalt resistance and pMOL30 (238 kilobases) specifying zinc, cadmium, mercury, and cobalt resistance. The plasmids are self-transmissible in homologous matings, but at low frequencies. The transfer frequency was strongly increased with IncP1 plasmids RP4 and pUZ8 as helper plasmids. The phenotypes of the wild type, cured strains, and transconjugants are characterized by the following MICs (Micromolar) in strains with the indicated phenotypes: Nic+, 2.5; Nic-, 0.6; Cob+A, 5.0; Cob+B, 20.0; Cob-, less than 0.07; Zin+, 12.0; Zin-, 0.6; Cad+, 2.5; and Cad-, 0.6. Plasmid-free cells of strain CH34 are still able to grow lithoautotrophically and to form both hydrogenases, indicating that the hydrogenase genes are located on the chromosome, in contrast to the Hox structural genes of strain H16, which are located on the megaplasmid pHG1 (450 kilobases).     

Nickel-[iron-sulfur]-selenium-containing hydrogenases from Desulfovibrio baculatus (DSM 1743). Redox centers and catalytic properties

The hydrogenase from Desulfovibrio baculatus (DSM 1743) was purified from each of three different fractions: soluble periplasmic (wash), soluble cytoplasmic (cell disruption) and membrane-bound (detergent solubilization). Plasma-emission metal analysis detected in all three fractions the presence of iron plus nickel and selenium in equimolecular amounts. These hydrogenases were shown to be composed of two non-identical subunits and were distinct with respect to their spectroscopic properties. The EPR spectra of the native (as isolated) enzymes showed very weak isotropic signals centered around g approximately 2.0 when observed at low temperature (below 20 K). The periplasmic and membrane-bound enzymes also presented additional EPR signals, observable up to 77 K, with g greater than 2.0 and assigned to nickel(III). The periplasmic hydrogenase exhibited EPR features at 2.20, 2.06 and 2.0. The signals observed in the membrane-bound preparations could be decomposed into two sets with g at 2.34, 2.16 and approximately 2.0 (component I) and at 2.33, 2.24, and approximately 2.0 (component II). In the reduced state, after exposure to an H2 atmosphere, all the hydrogenase fractions gave identical EPR spectra. EPR studies, performed at different temperatures and microwave powers, and in samples partially and fully reduced (under hydrogen or dithionite), allowed the identification of two different iron-sulfur centers: center I (2.03, 1.89 and 1.86) detectable below 10 K, and center II (2.06, 1.95 and 1.88) which was easily saturated at low temperatures. Additional EPR signals due to transient nickel species were detected with g greater than 2.0, and a rhombic EPR signal at 77 K developed at g 2.20, 2.16 and 2.0. This EPR signal is reminiscent of the Ni-signal C (g at 2.19, 2.14 and 2.02) observed in intermediate redox states of the well characterized Desulfovibrio gigas hydrogenase (Teixeira et al. (1985) J. Biol. Chem. 260, 8942]. During the course of a redox titration at pH 7.6 using H2 gas as reductant, this signal attained a maximal intensity around -320 mV. Low-temperature studies of samples at redox states where this rhombic signal develops (10 K or lower) revealed the presence of a fast-relaxing complex EPR signal with g at 2.25, 2.22, 2.15, 2.12, 2.10 and broad components at higher field. The soluble hydrogenase fractions did not show a time-dependent activation but the membrane-bound form required such a step in order to express full activity.(ABSTRACT TRUNCATED AT 400 WORDS)     

Depression of hydrogenase during limitation of electron donors and derepression of ribulosebisphosphate carboxylase during carbon limitation of Alcaligenes eutrophus

Alcaligenes eutrophus did not form the key enzymes of autotrophic metabolism, the soluble and particulate hydrogenases and ribulosebisphosphate carboxylase (RuBPC), during heterotrophic growth on succinate in batch cultures. During succinate-limited growth in a chemostat, high activities of both hydrogenases were observed. With decreasing dilution rate (D) the steady-state hydrogenase activity (H) followed first-order kinetics, expressed as follows: H = Hmax .e-alpha.D. An identical correlation was observed when autotrophic growth in a chemostat was limited by molecular hydrogen. During autotrophic growth under oxygen or carbon dioxide limitation, the activity if the soluble hydrogenase was low. These data suggested that hydrogenase formation depended on the availability of reducing equivalents to the cells. RuBPC activities were not correlated with the hydrogenase activities. During succinate-limited growth, RuBPC appeared at intermediate activities. During autotrophic growth in a carbon dioxide-limited chemostat, RuBPC was highly derepressed. RuBPC activity was not detected in cells that suffered from energy limitation with a surplus of carbon, as in a heterotrophic oxygen-limited chemostat, nor was it detected in cells limited in carbon and energy, as in the case of complete exhaustion of a heterotrophic substrate. From these data I concluded that RuBPC formation in A. eutrophus depends on two conditions, namely, carbon starvation and an excess of reducing equivalents.     

Mutants of Alcaligenes eutrophus defective in autotrophic metabolism

Forty-four mutants of Alcaligenes eutrophus H 16 were isolated which grew poorly or not at all under autotrophic conditions. Four types were characterized with respect to their defects and their physiological properties. One mutant lacked both enzymes specific for autotrophic CO₂ fixation, another one lacked both hydrogenases, and two mutants lacked either the membrane-bound or the soluble hydrogenase. Comparing the results of studies on these mutant types, the following conclusions were drawn: the lack of each hydrogenase enzyme could be partially compensated by the other one; the lack of membrane-bound hydrogenase did not affect autotrophic growth, whereas the lack of the soluble hydrogenase resulted in a decreased autotrophic growth rate. When pyruvate as well as hydrogen were supplied to the wild-type, the cell yield was higher than in the presence of pyruvate alone. Mutant experiments under these conditions indicated that either of both hydrogenases was able to add to the energy supply of the cell. Only the soluble hydrogenase was involved in the control of the rate of hydrogen oxidation by carbon dioxide; the mutant lacking this enzyme did not respond to the presence or absence of CO₂. The suppression of growth on fructose by hydrogen could be mediated by either of both hydrogenases alone.