The activity of two forms of nitrogenase from Rhodopseudomonas capsulata in the presence of different electron donors

Abstract The active form of Rhodopseudomonas capsulata nitrogenase is active in vitro when dithionite or ferredoxins from this bacterium are used as electron donors. The presence of the activating nitrogenase enzyme and Mn²⁺ ions is needed for functioning of the inactive form of Rh. capsulata nitrogenase in vitro with the use of dithionite as an electron donor. The use of Rh. capsulata ferredoxins as electron donors in vitro makes the inactive form of nitrogenase fully active as is the case in vivo.     

Electron transport to nitrogenase in Rhodospirillum rubrum: Role of energization of the chromatophore membrane

Nitrogen fixation is dependent on a source of ATP and the generation of a reductant at low enough red-ox potential to transfer electrons to nitrogenase. In Rhodospirillum rubrum, grown photoheterotrophically, ATP is produced by photophosphorylation, a process studied in great detail, but the source of reductant for nitrogenase is as yet unidentified. In this report we have studied the effect on nitrogen fixation when the energization of the chromatophore membranes was changed, by decreasing the light intensity or by addition of uncouplers. When the light intensity was lowered a pronounced decrease in nitrogenase activity was observed although there was no decrease in the ATP/ADP ratio. The inhibition observed was not due to ADP-ribosylation, as the same effect was observed in a mutant devoid of the enzymes in the metabolic regulatory cascade operating in R. rubrum and some other diazotrophs. Even at low concentrations of the uncouplers used, a drastic decrease in the ATP/ADP ratio was observed. However, this decrease in the ATP/ADP ratio did not cause a decrease in nitrogenase activity. At higher concentrations of uncouplers, nitrogenase activity decreased but the ATP/ADP ratio remained essentially at a constant low level. These results support a model in which reduction of the electron donor(s) to nitrogenase in R. rubrum is coupled to the energization of the chromatophore membranes.     

The electron transport to nitrogenase in Mycobacterium flavum

1. Two ferredoxin-type iron-sulfur proteins have been isolated from Mycobacterium flavum 301 grown under nitrogen-fixing, iron-sufficient conditions. No flavodoxin was observed. 2. These ferredoxins are apparently soluble: they were present in the supernatant fraction after disrupting by decompression. Only small amounts were present in particulate fractions. 3. The two ferredoxins were separated by chromatography on DEAE-cellulose, Sephadex or electrophoresis. 4. Both ferredoxins mediated the transfer of electrons from illuminated spinach chloroplasts to a nitrogenase preparation to reduce acetylene. Ferredoxin II was specifically about five times more active than ferredoxin I. Ferredoxin II was also active in the photosynthetic NADP+-reduction whereas ferredoxin I was not. 5. Both ferredoxins were reversibly reduced by either sodium dithionite, illuminated spinach chloroplasts or hydrogen plus hydrogenase from Clostridium pasteurianum. 6. Attempts to determine the primary electron donor for nitrogen fixation in Mycobacterium flavum were unsuccessful. Acetylene reduction in Mycobacterium extracts was obtained only with sodium dithionite or illuminated spinach chloroplasts as electron donors. The reduction of the electron carrier (e.g. ferredoxin) rather than the transfer of electrons from the reduced carrier to nitrogenase was rate-limiting.     

The nitrogen fixation system of photosynthetic bacteria II. Chromatium nitrogenase activity linked to photochemically generated assimilatory power

The nitrogenase activity (measured by N₂ or acetylene reduction) of cell-free extracts of the photosynthetic bacterium Chromatium was coupled to photochemically generated ATP and reductant. The ATP was formed through cyclic photophosphorylation by bacterial chromatophores. The reductant (reduced ferredoxin) was generated by a heated preparation (incapable of O₂ and ATP production) of spinach chloroplasts. The nitrogenase activity of Chromatium extracts was supported by reduced Chromatium or Clostridium pasteurianum ferredoxin but not by that of spinach chloroplasts.     

Two Forms of Nitrogenase from the Photosynthetic Bacterium Rhodospirillum rubrum

Acetylene reduction by nitrogenase from Rhodospirillum rubrum, unlike that by other nitrogenases, was recently found by other investigators to require an activation of the iron protein of nitrogenase by an activating system comprising a chromatophore membrane component, adenosine 5'-triphosphate (ATP), and divalent metal ions. In an extension of this work, we observed that the same activating system was also required for nitrogenase-linked H(2) evolution. However, we found that, depending on their nitrogen nutrition regime, R. rubrum cells produced two forms of nitrogenase that differed in their Fe protein components. Cells whose nitrogen supply was totally exhausted before harvest yielded predominantly a form of nitrogenase (A) whose enzymatic activity was not governed by the activating system, whereas cells supplied up to harvest time with N(2) or glutamate yielded predominantly a form of nitrogenase (R) whose enzymatic activity was regulated by the activating system. An unexpected finding was the rapid (less than 10 min in some cases) intracellular conversion of nitrogenase A to nitrogenase R brought about by the addition to nitrogen-starved cells of glutamine, asparagine, or, particularly, ammonia. This finding suggests that mechanisms other than de novo protein synthesis were involved in the conversion of nitrogenase A to the R form. The molecular weights of the Fe protein and Mo-Fe protein components from nitrogenases A and R were the same. However, nitrogenase A appeared to be larger in size, because it had more Fe protein units per Mo-Fe protein than did nitrogenase R. A distinguishing property of the Fe protein from nitrogenase R was its ATP requirement. When combined with the Mo-Fe protein (from either nitrogenase A or nitrogenase R), the R form of Fe protein required a lower ATP concentration but bound or utilized more ATP molecules during acetylene reduction than did the A form of Fe protein. No differences between the Fe proteins from the two forms of nitrogenase were found in the electron paramagnetic resonance spectrum, midpoint oxidation-reduction potential, or sensitivity to iron chelators.     

Regulation of nitrogen fixation in Rhodospirillum rubrum grown under dark, fermentative conditions.

Rhodospirillum rubrum was shown to grow fermentatively on fructose with N2 as a nitrogen source. The nitrogenase activity of these cells was regulated by the NH4+ switch-off/switch-on mechanism in a manner identical to that for photosynthetically grown cells. In vitro, the inactive nitrogenase Fe protein from fermenting cells was reactivated by an endogenous membrane-bound, Mn2+-dependent activating enzyme that was interchangeable with the activating enzyme isolated from photosynthetic membranes.     

Purification and Mn2+ activation of Rhodospirillum rubrum nitrogenase activating enzyme.

The Fe protein activating enzyme for Rhodospirillum rubrum nitrogenase was purified to approximately 90% homogeneity, using DE52-cellulose chromatography and sucrose density gradient centrifugation. Activating enzyme consists of a single polypeptide of molecular weight approximately 24,000. ATP was required for catalytic activity, but was relatively ineffective in the absence of Mg2+. When the concentration of MgATP2- was held in excess, there was an additional requirement for a free divalent metal ion (Mn2+) for enzyme activity. Kinetic experiments showed that the presence of Mg2+ influenced the apparent binding of Mn2+ by the enzyme, resulting in a lowering of the concentration of Mn2+ required to give half-maximum activity (K alpha) as the free Mg2+ concentration was increased. A low concentration of Mn2+ had a sparing effect on the requirement for free Mg2+. There is apparently a single metal-binding site on activating enzyme which preferentially binds Mn2+ as a positive effector, and free Mg2+ can compete for this site.     

The path of electron transfer to nitrogenase in a phototrophic alpha‐proteobacterium

The phototrophic alpha‐proteobacterium, Rhodopseudomonas palustris, is a model for studies of regulatory and physiological parameters that control the activity of nitrogenase. This enzyme produces the energy‐rich compound H₂, in addition to converting N₂ gas to NH₃. Nitrogenase is an ATP‐requiring enzyme that uses large amounts of reducing power, but the electron transfer pathway to nitrogenase in R. palustris was incompletely known. Here, we show that the ferredoxin, Fer1, is the primary but not sole electron carrier protein encoded by R. palustris that serves as an electron donor to nitrogenase. A flavodoxin, FldA, is also an important electron donor, especially under iron limitation. We present a model where the electron bifurcating complex, FixABCX, can reduce both ferredoxin and flavodoxin to transfer electrons to nitrogenase, and we present bioinformatic evidence that FixABCX and Fer1 form a conserved electron transfer pathway to nitrogenase in nitrogen‐fixing proteobacteria. These results may be useful in the design of strategies to reroute electrons generated during metabolism of organic compounds to nitrogenase to achieve maximal activity.     

Nitrogenase Activity in Cell-Free Extracts of the Blue-Green Alga, Anabaena cylindrica

Cell-free extracts with high nitrogenase activity were prepared by sonic oscillation and French press treatment from the blue-gree alga Anabaena cylindrica. Extracts were prepared from cells grown on a 95% N(2)-5% CO(2) gas mixture followed by a period of nitrogen starvation under an atmosphere of 95% argon-5% CO(2). No increase in the specific activity of extracts was achieved by breaking heterocysts. Activity (assayed by acetylene reduction) was found to be dependent on adenosine triphosphate (ATP), an ATP-generating system, and a low-potential reductant. Na(2)S(2)O(2) employed as reductant supports higher rates of nitrogenase activity than reduced ferredoxin. The activity is associated with a small-particle fraction that can be sedimented by ultracentrifugation. In contrast to the particulate nitrogenase of Azotobacter, which is stable in air, the A. cylindrica nitrogenase is an oxygen sensitive as nitrogenase prepared from anaerobic bacteria.     

Manganese, an Essential Trace Element for N2 Fixation by Rhodospirillum rubrum and Rhodopseudomonas capsulata: Role in Nitrogenase Regulation

Nitrogenase (N(2)ase) from the photosynthetic bacterium Rhodospirillum rubrum can exist in two forms, an unregulated form (N(2)ase A) and a regulatory form (N(2)ase R), the latter being identified in vitro by its need for activation by a Mn(2+)-dependent N(2)ase activating system. The physiological significance of this Mn(2+)-dependent N(2)ase activating system was suggested here by observations that growth of R. rubrum and Rhodopseudomonas capsulata on N(2) gas (a condition that produces active N(2)ase R) required Mn(2+), but growth on ammonia or glutamate did not. Manganese could not be shown to be required for the biosynthesis of either nitrogenase or glutamine synthetase or for glutamine synthetase turnover, but it was required for the in vitro activation of N(2)ases from N(2) and glutamate-grown R. rubrum and R. capsulata cells. Chromatium N(2)ase, in contrast, was always fully active and did not require Mn(2+) activation, suggesting that only the purple nonsulfur bacteria are capable of controlling their N(2)ase activity by this new type of regulatory system. Although R. rubrum could not substitute Fe(2+) for Mn(2+) in the in vivo N(2) fixation process, Fe(2+) and, to a lesser extent, Co(2+) could substitute for Mn(2+) in the in vitro activation of N(2)ase. Electron paramagnetic resonance spectroscopy of buffer-washed R. rubrum chromatophores showed lines characteristic of Mn(2+). Removal of the Mn(2+)-dependent N(2)ase activating factor by a salt wash of the chromatophores removed 90% of the Mn(2+), which suggested a specific coupling of this metal to the activating factor. The data presented here all indicate that Mn(2+) plays an important physiological role in regulating the N(2) fixation process by these photosynthetic bacteria.     

Inhibition of nitrogenase by nitrite and nitric oxide in Rhodopseudomonas sphaeroides f. sp. denitrificans

In cells of Rhodopseudomonas sphaeroides f. sp. denitrificans nitrite and nitric oxide, the products of denitrification, inhibit activity of nitrogenase enzyme.Ferredoxin-linked CO₂ fixation, with H₂ as a reductant, was also inhibited by nitrite and NO in denitrifying cells.EPR spectroscopy of cell preparations treated with NO showed that it reacts with non-haem iron-sulphur proteins to form iron-nitrosyl complexes. Nitrite also reacts with these iron-sulphur proteins, but the formation of ironnitrosyl complexes was dependent on the presence of dithionite. Since nitrite is reduced to NO by dithionite it is likely that nitrogenase and CO₂ fixation reactions are inhibited not only by nitrite itself, but also by nitric oxide.Abbreviation DPPH 1,1-diphenyl-2-picrylhydrazyl     

Two pathways of electron transport to nitrogenase in Rhodospirillum rubrum: the major pathway is dependent on the fix gene products

In the photosynthetic bacterium Rhodospirillum rubrum, as in many other diazotrophs, electron transport to nitrogenase has not been characterized in great detail. In this study, we show that there are two pathways operating in R. rubrum. The products of the fix genes constitute the major pathway operating under heterotrophic conditions, whereas a pyruvate:ferredoxin oxidoreductase, encoded by the nifJ gene, may play a central role under anaerobic conditions in the dark. In both systems, ferredoxin N is the main direct electron donor to dinitrogenase reductase. Furthermore, we suggest from studying mutants lacking components in one or both systems under different conditions, that the Fix system operates most efficiently under conditions when a proton motive force is generated. A model for our current view of the electron transfer pathways in R. rubrum is presented.     

Electron transport to nitrogenase in Rhodospirillum rubrum: the role of NAD(P)H as electron donor and the effect of fluoroacetate on nitrogenase activity

The role of the reactions of the TCA cycle in the generation of reductant for nitrogenase in Rhodospirillum rubrum has been investigated. Addition of fluoroacetate inhibited nitrogenase activity almost completely when pyruvate or endogenous sources were used as electron donors, whereas the inhibition was incomplete when malate, succinate or fumarate were used. Addition of NAD(P)H to cells supported nitrogenase activity, both with and without prior addition of fluoroacetate. We suggest that the role of the TCA cycle in nitrogen fixation in R. rubrum is to generate reduced pyridine nucleotides which are oxidized by the components of the electron transport pathway to nitrogenase.     

Effect of light intensity and inhibitors of nitrogen assimilation on NH4+ inhibition of nitrogenase activity in Rhodospirillum rubrum and Anabaena sp

Nitrogenase activity in Rhodospirillum rubrum was inhibited by NH4+ more rapidly in low light than in high light. Furthermore, the nitrogenase of cells exposed to phosphorylation uncouplers was inhibited by NH4+ more rapidly than was the nitrogenase of controls without an uncoupler. These observations suggest that high levels of photosynthate inhibit the nitrogenase inactivation system. L-Methionine-DL-sulfoximine, a glutamine synthetase inhibitor, prevented NH4+ from inhibiting nitrogenase activity, which suggests that NH4+ must be processed at least to glutamine for inhibition to occur. An inhibitor of glutamate synthase activity, 6-diazo-5-oxo-L-norleucine, inhibited nitrogenase activity in the absence of NH4+, but only in cells exposed to low light. The mechanism of 6-diazo-5-oxo-L-norleucine inhibition appeared to be the same as that induced by NH4+, because nitrogenase activity could be restored in vitro by activating enzyme and Mn2+. The inhibitor data suggest that the glutamine pool or a molecule that responds to it activates the Fe protein-modifying (or protein-inactivating) system and that the accumulation of this (unidentified) molecule is retarded when the cells are exposed to high light. It was confirmed here that Anabaena nitrogenase is also inhibited by NH4+, but only when the cells are incubated under low light. This inhibition, however, unlike that in R. rubrum, could be completely reversed in high light, suggesting that the mechanisms of nitrogenase inhibition by NH4+ in these two phototrophs are different.     

Autotrophic synthesis of activated acetic acid from two CO2 inMethanobacterium thermoautotrophicum

A cell-free preparation of heterocysts from Anabaena variabilis showed high nitrogenase activities with several physiological electron donors, dependent on addition of an ATP-generating system. Light-induced acetylene reduction with the artificial electron donor to photosystem I, diaminodurol, exhibited the same light saturation as with hydrogen as donor. Inhibitors of electron flow through plastoquinone affected light-induced, hydrogen- or NADH-dependent nitrogenase activity in a similar way. Several uncoupling agents were without effect, indicating that energized membranes are not a prerequisite for nitrogen fixation. We conclude that NADH or hydrogen deliver electrons to nitrogenase via photosystem I and ferredoxin, feeding in at the plastoquinone site.In the light, addition of NADP induced a lag in H₂- or NADH-supported acetylene reduction apparently by competing with nitrogenase for electrons at the reducing side of photosystem I. Time reversal of this inibition reflects a regulation of photosystem I-dependent nitrogenase activity by the NADPH/NADP ratio in the cell. This was directly demonstrated by differently adjusted NADPH/NADP ratios.NADPH donates electrons to nitrogenase in the dark and in the light, the light reaction being DBMIB-sensitive. NADPH-supported acetylene reduction was inhibited by NADP. This inhibition was not reversed with time, pointing to an involvement of ferredoxin: NADP oxidoreductase (EC 1.18.1.2) in this pathway. Apparently, in the dark, this enzyme is able to directly reduce ferredoxin, whereas in the light electrons from NADPH first have to pass through photosystem I before reducing ferredoxin, hence nitrogenase.Intermediates of glycolysis, like glucose-6-phosphate, fructose-1,6-bisphosphate, and dihydroxyacetone phosphate supported nitrogenase activity in the dark, each with catalytic amounts of both NAD and NADP as equally effective cofactors.We conclude that in heterocysts electrons for nitrogen fixation are essentially supplied by dark reactions, mainly by glycolysis. NADH (and hydrogen) contribute electrons via photosystem I in the light, whereas the NADPH/NADP ratio regulates linear and cyclic electron flow at the reducing side of photosystem I to provide a ratio of ATP/electrons most effective for nitrogenase.Abbvreviations ATCC American Type Culture Collection - Diaminodurol (DAD) 2,3,5,6-tetramethyl-p-phenylenediamine dihydrochloride - DBMIB 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone - DNP-INT 2,4-dinitrophenyl ether of 2-iodo-4-nitrothymol - E Einstein (mol photons) - FNR ferredoxin - NADP oxidoreductase (EC 1.18.1.2) - HEPES N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid - Metronidazole 1-(2-hydroxyethyl)-2-methyl-5-nitroimidazole     

The purification and properties of nitrite reductase from higher plants, and its dependence on ferredoxin

1. NADPH-dependent nitrite reductase from the leaves of higher plants was purified at least 70-fold and separated into two enzyme fractions. The first enzyme, a diaphorase with ferredoxin-NADP-reductase activity, is required only to transfer electrons from NADPH to a suitable electron acceptor, which then donates electrons to nitrite reductase proper. 2. Purified nitrite reductase accepted electrons from ferredoxin (the natural donor) or from reduced dyes. Ferredoxin was reduced by illuminated chloroplasts or dithionite, or by NADPH when diaphorase was present. The purified enzyme did not accept electrons directly from NADPH. 3. Ferredoxins purified from maize, spinach or Clostridium were interchangeable in the nitrite-reductase system. 4. Nitrite reductase had K(m) 0.15mm for nitrite. The pH optimum varied with plant and method of assay. The preparation had low sulphite-reductase activity. Ammonia was the product of nitrite reduction. 5. For some plants, the assay of crude preparations with NADPH was limited by diaphorase and the addition of diaphorase gave a better estimate of nitrite-reductase activity. A simple method of assay is described that uses dithionite with benzyl viologen as electron donor.     

Purification and properties of hydrogenase from Megasphaera elsdenii

A hydrogenase has been purified to homogeneity from the soluble fraction of the rumen bacterium Megasphaera elsdenii, the overall purification is 200 times with a yield of 14%. The pure enzyme consists of a single polypeptide chain with Mr approximately 50 000 which contains 12 atoms of non-haem iron and 12 atoms of acid-labile sulphide. The enzyme is rapidly inactivated by O2 and it is therefore purified under nitrogen and in the presence of sodium dithionite. The optical spectrum of the enzyme, after removal of the dithionite with air, shows a peak at 275 nm (epsilon 275 nm = 143 mM-1 cm-1) and a shoulder between 350 nm and 400 nm (epsilon 400 nm = 46 mM-1 cm-1). The enzyme catalyses hydrogen production from sodium dithionite at a low rate. The rate is greatly enhanced by addition of the electron donors flavodoxin, ferredoxin and methyl viologen. The kinetic data with these three electron donors suggest co-operativity, but no indication of self-association of the enzyme was obtained. Sodium chloride enhances the rate of hydrogen production with methyl viologen semiquinone and changes the kinetic behaviour of the enzyme with this electron donor, but causes inhibition of the reactions mediated by ferredoxin and flavodoxin. Two kinetic models were developed which are consistent with the kinetic data of the three electron donors tested. The apparent co-operativity for the hydrogen production can be fitted with the mathematical form of those models. The identical kinetic behaviour of the hydrogenase with the one-electron donors flavodoxin and methyl viologen semiquinone monomer and the two-electron donor ferredoxin indicates that the hydrogenase accepts two electrons in two separate, independent steps and further indicates that the two (4Fe-4S) clusters of the donor ferredoxin are independent. The interpretation of the kinetic data with methyl viologen semiquinone is complicated by the fact that the semiquinone dimerises, and that the formation of the dimer is enhanced by salt. Taking into account the association of this donor, the activity of the enzyme with methyl viologen semiquinone can be described by the sum of the activities of the enzyme with methyl viologen monomer and methyl viologen dimer. The enzyme catalyses the oxidation of hydrogen gas with methyl and benzyl viologen as electron acceptors to their semiquinone forms; both electron acceptors show Michaelis-Menten kinetics. The hydrogen oxidation activity with both electron acceptors is stimulated by addition of sodium chloride. The kinetic data of the oxidation of hydrogen with the two-electron acceptors used are consistent with the porposed models, if it is assumed that the pathway followed is compulsory. At this moment no choice can be made between the models proposed.     

Reversible membrane association of dinitrogenase reductase activating glycohydrolase in the regulation of nitrogenase activity in Rhodospirillum rubrum; dependence on GlnJ and AmtB1

In the photosynthetic bacterium Rhodospirillum rubrum nitrogenase activity is regulated by reversible ADP-ribosylation of dinitrogenase reductase in response to external so called "switch-off" effectors. Activation of the modified, inactive form is catalyzed by dinitrogenase reductase activating glycohydrolase (DRAG) which removes the ADP-ribose moiety. This study addresses the signal transduction between external effectors and DRAG. R. rubrum, wild-type and P(II) mutant strains, were studied with respect to DRAG localization. We conclude that GlnJ clearly has an effect on the association of DRAG to the membrane in agreement with the effect on regulation of nitrogenase activity. Furthermore, we have generated a R. rubrum mutant lacking the putative ammonium transporter AmtB1 which was shown not to respond to "switch-off" effectors; no loss of nitrogenase activity and no ADP-ribosylation. Interestingly, DRAG was mainly localized to the cytosol in this mutant. Overall the results support our model in which association to the membrane is part of the mechanism regulating DRAG activity.     

Relationships in hydrogen metabolism between hydrogenase and nitrogenase in phototrophic bacteria.

Purple bacteria Rhodospirillum rubrum and Thiocapsa roseopersicina form two enzymes, hydrogenase and nitrogenase, which participate in hydrogen metabolism. H2 photoproduction in these bacteria is associated mainly or completely with the action of nitrogenase. The soluble and membrane-bound hydrogenases of T. roseopersicina have similar physicochemical properties (mol. weight, subunit composition, N-terminal amino acids, Fe2+ and S2- content, pl. Eo'). In comparison with other hydrogenases the enzyme from R. rubrum and T. roseopersicina evolve H2 with high rate from reduced cytochrome c3, but not from ferredoxins. H2 production and N2 fixation take place in the presence of NAD(P)H. NADP-reductase, ferredoxin and cytochrome c3 participate in this reaction. Possible relationships between hydrogenase-nitrogenase in the metabolism of molecular hydrogen are discussed.     

Posttranslational regulatory system for nitrogenase activity in Azospirillum spp.

The mechanism for "NH4+ switch-off/on" of nitrogenase activity in Azospirillum brasilense and A. lipoferum was investigated. A correlation was established between the in vivo regulation of nitrogenase activity by NH4Cl or glutamine and the reversible covalent modification of dinitrogenase reductase. Dinitrogenase reductase ADP-ribosyltransferase (DRAT) activity was detected in extracts of A. brasilense with NAD as the donor molecule. Dinitrogenase reductase-activating glycohydrolase (DRAG) activity was present in extracts of both A. brasilense and A. lipoferum. The DRAG activity in A. lipoferum was membrane associated, and it catalyzed the activation of inactive nitrogenase (by covalent modification of dinitrogenase reductase) from both A. lipoferum and Rhodospirillum rubrum. A region homologous to R. rubrum draT and draG was identified in the genomic DNA of A. brasilense as a 12-kilobase EcoRI fragment and in A. lipoferum as a 7-kilobase EcoRI fragment. It is concluded that a posttranslational regulatory system for nitrogenase activity is present in A. brasilense and A. lipoferum and that it operates via ADP-ribosylation of dinitrogenase reductase as it does in R. rubrum.