Involvement of the cytoplasmic membrane in nitrogen fixation by Rhizobium leguminosarum bacteroids

Respiratory control determines respiration and nitrogenase activity of Rhizobium leguminosarum bacteroids

The relationship between the O2 input rate into a suspension of Rhizobium leguminosarum bacteroids, the cellular ATP and ADP pools, and the whole-cell nitrogenase activity during L-malate oxidation has been studied. It was observed that inhibition of nitrogenase by excess O2 coincided with an increase of the cellular ATP/ADP ratio. When under this condition the protonophore carbonyl cyanide m-chlorophenylhydrazone (CCCP) was added, the cellular ATP/ADP ratio was lowered while nitrogenase regained activity. To explain these observations, the effects of nitrogenase activity and CCCP on the O2 consumption rate of R. leguminosarum bacteroids were determined. From 100 to 5 microM O2, a decline in the O2 consumption rate was observed to 50 to 70% of the maximal O2 consumption rate. A determination of the redox state of the cytochromes during an O2 consumption experiment indicated that at O2 concentrations above 5 microM, electron transport to the cytochromes was rate-limiting oxidation and not the reaction of reduced cytochromes with oxygen. The kinetic properties of the respiratory chain were determined from the deoxygenation of oxyglobins. In intact cells the maximal deoxygenation activity was stimulated by nitrogenase activity or CCCP. In isolated cytoplasmic membranes NADH oxidation was inhibited by respiratory control. The dehydrogenase activities of the respiratory chain were rate-limiting oxidation at O2 concentrations (if >300 nM. Below 300 nM the terminal oxidase system followed Michaelis-Menten kinetics (Km of 45 +/- 8 nM). We conclude that (i) respiration in R. leguminosarum bacteroids takes place via a respiratory chain terminating at a high-affinity oxidase system, (ii) the activity of the respiratory chain is inhibited by the proton motive force, and (iii) ATP hydrolysis by nitrogenase can partly relieve the inhibition of respiration by the proton motive force and thus stimulate respiration at nanomolar concentrations of O2.

Identification and Characterization of a Bacteroid-Specific Dehydrogenase Complex in Rhizobium leguminosarum PRE

In membranes of Rhizobium leguminosarum bacteroids isolated from nitrogen-fixing pea root nodules, two different protein complexes with NADH dehydrogenase activity were detected. One of these complexes, with a molecular mass of 110 kilodaltons, was also found in membranes of free-living rhizobia, but the other, with a molecular mass of 550 kilodaltons, appeared to be present only in bacteroids. The bacteroid-specific complex, referred to as DH1, probably consists of at least four different subunits. Using antibodies raised against the separate polypeptides, we found that a 35,000-molecular-weight polypeptide (35K polypeptide) in the DH1 complex is bacteroid specific, while the other proposed subunits were also detectable in cytoplasmic membranes of free-living bacteria. Dehydrogenase complex DH1 is also present in bacteroids of a R. leguminosarum nifA mutant, indicating that the synthesis of the dehydrogenase is not dependent on the gene product of this nif -regulatory gene. A possible involvement of the bacteroid-specific DH1 complex in electron transport to nitrogenase is discussed.

In vivo interaction between nitrogenase molybdenum-iron protein and membrane in Azotobacter vinelandii and Rhodospirillum rubrum

Oriented whole cell multilayers of Azotobacter vinelandii and Rhodospirillum rubrum were analyzed by electron spin resonance (ESR) spectroscopy to detect possible structural associations between nitrogenase molybdenum-iron (MoFe) protein and cytoplasmic or intracytoplasmic membrane. Initially, protocols were designed to obtain strong molybdenum-iron protein ESR signals in whole cell samples of each organism. Then, two-dimensional orientation of whole cell membranes was demonstrated in whole cell multilayers using doxyl stearate spin label in A. vinelandii and the bacteriochlorophyll a dimer triplet signal, (BCHl a)T2, from the intracytoplasmic membrane-bound photosynthetic apparatus of R. rubrum. Subsequent analysis of the low-field signals, g = 4.3 and g = 3.6, of molybdenum-iron protein in whole cell multilayers of each organism showed orientation-dependent characteristics, although the properties of each were different. Specifically, as the normal to the membrane plane was rotated from perpendicular to parallel with the ESR magnetic field, the amplitude of the g = 3.6 signal decreased from maximum to about 37% of maximum in A. vinelandii and from maximum to about 88% of maximum in R. rubrum. The angular dependence of the g = 4.3 peak during rotation varied in A. vinelandii, but decreased from maximum to about 63% of maximum in R. rubrum. These data suggest that the molybdenum-iron protein of nitrogenase was oriented in response to the physical orientation of cellular membranes and that a structural association may exist between this nitrogenase component and membrane in these organisms.

Electron allocation to H+ and N2 by nitrogenase in Rhizobium leguminosarum bacteroids

Electron allocation to H+ and N2 by nitrogenase in intact Rhizobium leguminosarum bacteroids has been studied. Nitrogenase activity was measured in intact cells with succinate and oxygen substrates. When whole cell nitrogenase activity was inhibited by oxygen-limitation or by the addition of the H+-conducting ionophore carbonylcyanide m-chlorophenylhydrazone, both inducing a low intracellular ATP/ADP ratio, the electron allocation to H+ was favoured over that to N2. When whole cell nitrogenase activity was inhibited by excess oxygen or by the addition of the K+-conducting ionophore valinomycin, both inhibiting electron transport to nitrogenase without affecting the intracellular ATP/ADP ratio, no effect upon the electron allocation to H+ and N2 was observed. The whole cell experiments could be confirmed by experiments with bacteroids treated with hexadecyltrimethylammonium bromide. Nitrogenase is highly active in these preparations with Na2S2O4 and MgATP as substrates. No effect was observed upon electron allocation to H+ and N2 when nitrogenase was inhibited by limitation of reductant (Na2S2O4) or MgATP. Only when nitrogenase was inhibited by MgADP, electron allocation to H+ was favoured. The amount of nitrogenase component 1 and 2 in bacteroids was estimated with protein blotting, followed by an immunological detection. It was found that 17% +/- 3% of total bacteroid protein is component 1 and 12% +/- 2% is component 2. The specific nitrogenase activity of bacteroids treated with hexadecyltrimethylammonium bromide is 178 +/- 62 nmol C2H4 formed X min-1 X mg total protein-1. Despite the high protein concentrations, nitrogenase is not inhibited. With cell-free extracts or with purified nitrogenase components isolated from R. leguminosarum bacteroids, electron allocation to H+ was favoured over that to N2, independently of the mechanism of inhibition. The discrepancies between the whole cell studies and those with isolated enzyme will be discussed with respect to the present mechanism of action of nitrogenase.

Symbiotic properties of C4-dicarboxylic acid transport mutants of Rhizobium leguminosarum

The transport of succinate was studied in bacteroids of an effective, streptomycin-resistant strain (GF160) of Rhizobium leguminosarum. High levels of succinate transport occurred, and the kinetics, specificity, and sensitivity to metabolic inhibitors were similar to those previously described for free-living cells. The symbiotic properties of two transposon (Tn5)-mediated C4-dicarboxylate transport mutants (strains GF31 and GF252) were determined. Strain GF31 formed ineffective nodules, and bacteroids from these nodules showed no succinate transport activity. Strain GF252 formed partially effective nodules, and bacteroids from these nodules showed about 50% of the succinate transport activity of the parent bacteroids. Another dicarboxylic acid transport mutant (Dct-), strain GFS5, isolated after N-methyl-N'-nitro-N-nitrosoguanidine mutagenesis, formed ineffective nodules. The ability to form ineffective nodules in strains GF31 and GFS5 was shown to correlate with the Dct- phenotype. The data indicate that the presence of a functional C4-dicarboxylic acid transport system is essential for N2 fixation to occur in pea nodules.

Short-term regulation of the nitrogenase activity in Rhodopseudomonas sphaeroides

The nitrogenase activity in whole cells of Rhodopseudomonas sphaeroides could be inhibited by lowering the electrical potential across the cytoplasmic membrane. The membrane potential was partly dissipated either by lowering the light intensity or by the addition of a lipophilic cation, tetraphenylphosphonium. Under these circumstances, it was shown that the intracellular ATP/ADP ratio was not affected and that the inhibition of the whole cell nitrogenase activity was not due to an inactivation of the nitrogenase enzyme. From these results it is concluded that electron transport to nitrogenase in Rps. sphaeroides is dependent on a high membrane potential. The nitrogenase enzyme in whole cells could be inactivated by lowering the membrane potential across the cytoplasmic membrane by incubating the cells in the dark or in the light in the presence of uncouplers. Nitrogenase could be reactivated in the light in the absence of uncouplers. Some possible mechanisms of action of NH+4 inhibition of whole cell nitrogenase activity could be excluded. Inhibition by NH4Cl of whole cell nitrogenase activity in Rps. sphaeroides could neither be explained by a rapid inactivation of the nitrogenase enzyme, nor by an effect on the intracellular ATP/ADP ratio or the membrane potential. NH+4 inhibits whole cell nitrogenase activity not directly but probably after being assimilated by glutamine synthetase. The role of glutamine, glutamate and 2-oxoglutarate on the regulation of electron transport to nitrogenase will be discussed.

Nitrogenase activity and membrane electrogenesis in the cyanobacterium Plectonema boryanum

The relationships between nitrogenase activity (acetylene reduction) and the transplasmalemma proton electrochemical potential gradient (delta muH+) have been investigated using the non-heterocystous filamentous cyanobacterium Plectonema boryanum. By selectively modifying the chemical (delta pH) and electrical (delta psi) components of delta muH+ under conditions in which the size of the ATP pool remained unaffected, nitrogenase activity was found to be dependent on, or regulated by delta psi. When the ATP pool decreased, concomitant with a decreased internal pH (pHi) the requirement for delta psi was modified. The observed reduction in the intracellular ATP pool and the decreased ATP:ADP ratio also correlated with an inhibition of nitrogenase activity. The data are consistent with a model in vivo in which reductant supply to nitrogenase is regulated by, or dependent on an energised plasmalemma and where there is a fine balance between the supply of reductant and ATP for nitrogenase activity. The correlation observed between delta psi and nitrogenase activity extends our previous observations using the heterocystous cyanobacterium Anabaena variabilis.

Mechanism of regulation of glucose transport in Rhizobium leguminosarum

Multiple glucose transport systems were distinguished in Rhizobium leguminosarum. We found nonlinear Lineweaver-Burk plots for the uptake of glucose, 2-deoxy-D-glucose, and alpha-methyl-D-glucoside, and this implied the existence of at least two uptake mechanisms. Different patterns of inhibition of 2-deoxy-D-glucose uptake and alpha-methyl-D-glucoside uptake at 0.1 mM by various carbohydrates revealed differences in the stereospecificities of the transport systems. Osmotic shock treatment abolished transport activities, and two independent glucose-binding activities were detected in the supernatants. Induction of glucose transport was repressed strongly by L-malate, even in the presence of excess D-glucose. Rhizobium bacteroids showed no significant glucose uptake activity at different oxygen concentrations. These results suggested that glucose transport is repressed by dicarboxylic acids during R. leguminosarum symbiosis.

Nitrogenase activity and membrane electrogenesis in the cyanobacterium Anabaena variabilis Kütz

Relationships between nitrogenase activity and individual components of the proton electrochemical potential gradient (delta microH+) in Anabaena variabilis have been investigated. The ionophore nigericin was found to collapse delta pH in favour of the membrane potential (delta psi); hyperpolarization of delta psi was correlated with an increase in nitrogenase activity. A positive relationship between nitrogenase activity and membrane potential was also observed using the ionophore valinomycin and the uncoupler carbonylcyanide m-chlorophenylhydrazone. Furthermore, using the energy transfer inhibitor N,N'-dicyclohexylcarbodiimide, nitrogenase activity appeared to be limited by the supply of reductant rather than ATP. The data suggest, for intact filaments and isolated heterocysts, that delta psi may be important in regulating nitrogenase activity in vivo.

In vivo energetics and control of nitrogen fixation: changes in the adenylate energy charge and adenosine 5'-diphosphate/adenosine 5'-triphosphate ratio of cells during growth on dinitrogen versus growth on ammonia

The effects of the intracellular energy balance and adenylate pool composition on N2 fixation were examined by determining changes in the energy charge (EC) and the ADP/ATP (D/T) ratio of cells in chemostat and batch cultures of Clostridium pasteurianum, Klebsiella pneumoniae, and Azotobacter vinelandii. When cells of C. pasteurianum, K. pneumoniae, and A. vinelandii in sucrose-limited chemostats were examined, in all cases the EC increased greater than or equal to 15% when the nitrogen source was switched from N2 to NH3 and decreased greater than or equal to 15% when the nitrogen source was switched from NH3 to N2. The D/T ratio of the same cultures decreased greater than or equal to 70% when they were switched from N2 to NH3. In such cultures the adenylate pools remained constant when the cells were grown on either NH3 or N2. In nitrogen (NH3)-limited cultures, the adenylate pool was two- to threefold higher than the adenylate pool in sucrose-limited cultures, and the nitrogenase content of such cells was two- to threefold greater than the nitrogenase content of sucrose-limited N2-fixing cells. The EC and D/T ratio of cells from batch cultures of C. pasteurianum growing on NH3 in the presence of N2 were 0.82 and 0.83, respectively, but when the NH3 was consumed and the cells were switched to a nitrogen-fixing metabolism, the EC and D/T ratio changed to 0.70 and 0.90, respectively. Conversely, when NH3 was added to N2-fixing cultures the EC and D/T ratio changed within 1.5 h the EC and D/T ratio of NH3-grown cells. The nitrogen content of N2-fixing cells to which NH3 was added decreased at a rate greater could be accounted for by cell growth in the absence of further synthesis. This decay of nitrogenase activity (with a half-life about 1.2 to 1.4 h) suggests that some type of inactivation of nitrogenase occurs during repression. The nitrogenase of whole cells was estimated to be operating at about 32% of its theoretical maximum activity during steady-state N2-fixing conditions. Similarities in the data from chemostat and batch cultures of both aerobic and anaerobic N2-fixing organisms suggest that low EC and high D/T ratio are normal manifestations of an N2-fixing physiology.

Properties of the hydrogenase of Megasphaera elsdenii

The catalytic activities of Megasphaera elsdenii hydrogenase are stimulated by salts. The stimulation is due to the anion: the more chaotropic the anion, the greater the effect. Dithionite-reduced and dye-oxidised preparations of hydrogenase are inactivated by reaction with oxygen. The inactivation of the reduced enzyme by excess oxygen follows pseudo-first-order kinetics; the reaction order for the oxidised enzyme has not been established. The rate of oxygen-inactivation is decreased by bovine serum albumin. The hydrogen production activity decreases in the presence of dimethylsulphoxide and ethylene glycol. The hydrogen oxidation activity is stimulated by dimethylsulphoxide, and the activity remains linear with time at concentrations up to 50% (v/v). Above 70% dimethylsulphoxide the steady-state activity of hydrogenase is abolished for both types of activity. The enzyme is more stable in a hydrogen atmosphere than in an argon atmosphere, and the oxidized enzyme is more stable than the reduced enzyme. The enzyme is isolated in the presence of dithionite and it is therefore reduced. When the enzyme is oxidized by treatment with 2,6-dichloroindophenol or with (bi)sulphite, its activity increases by up to 65%; this activation is not reversed when the enzyme is re-reduced. The increase in activity is associated with a change of the redox potential of the incubation medium to a less negative value; half of the maximum activation occurs at -0.41 V. The electron paramagnetic resonance spectrum of the dithionite-reduced hydrogenase resembles that of a reduced ferredoxin-type of spectrum with two 4Fe-4S clusters. The spectrum of the oxidized enzyme is similar to that of Chromatium high-potential iron-sulphur protein. No redox potentials can be ascribed to these spectra since the redox system changes upon freezing to liquid helium temperatures.