Regulation of dinitrogen fixation in intact Azotobacter vinelandii

Phosphoribulokinase mediates nitrogenase-induced carbon dioxide fixation gene repression in Rhodobacter sphaeroides

In many organisms there is a balance between carbon and nitrogen metabolism. These observations extend to the nitrogen-fixing, nonsulfur purple bacteria, which have the classic family of P(II) regulators that coordinate signals of carbon and nitrogen status to regulate nitrogen metabolism. Curiously, these organisms also possess a reverse mechanism to regulate carbon metabolism based on cellular nitrogen status. In this work, studies in Rhodobacter sphaeroides firmly established that the activity of the enzyme that catalyses nitrogen fixation, nitrogenase, induces a signal that leads to repression of genes encoding enzymes of the Calvin–Benson–Bassham (CBB) CO₂ fixation pathway. Additionally, genetic and metabolomic experiments revealed that NADH-activated phosphoribulokinase is an intermediate in the signalling pathway. Thus, nitrogenase activity appears to be linked to cbb gene repression through phosphoribulokinase.

Characterization and nucleotide sequence of a novel gene fixW upstream of the fixABC operon in Rhizobium leguminosarum

On the Rhizobium leguminosarum PRE sym plasmid, fixABC and a novel gene fixW were identified upstream of the regulatory gene nifA. The molecular masses of FixABC, 29, 44 and 50 kDa respectively, were estimated by polyacrylamide gel electrophoresis (PAGE) and of FixW, 25 kDa, by PAGE and nucleotide sequencing. Hybridization studies using bacteroid mRNA as a probe showed that fixABC is one operon which can be transcribed independently of fixW. Nucleotide sequencing revealed that both fixW and fixA are preceded by a nif consensus promoter. The fixA promoter partly overlaps the 3'-terminal coding region of fixW, indicating that readthrough from fixW into fixA is possible. Two open reading frames, ORF71 and ORF79, precede fixW and form one operon with fixW. ORF71 contains sequences homologous to the fixA promoter and 5'-terminal coding region. One more duplication of fixA sequences was detected, also located within the sym plasmid nif/fix clusters. One duplication of fixW sequences was found. No fixW homologue could be found in other nitrogen fixing organisms except in a number of R. leguminosarum strains.

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.

Characterization of three different flavodoxins from Azotobacter vinelandii

The flavodoxins from Azotobacter vinelandii cells grown N2-fixing and from cells grown on NH4OAc have been purified and characterized. The purified flavodoxins from these cells are a mixture of three different flavodoxins (Fld I, II, III) with different primary structures. The three proteins were separated by fast protein liquid chromatography; Fld I eluted at 0.38 M KCl, Fld II at 0.43 M KCl and Fld III at 0.45 M KCl. The most striking difference between the three flavodoxins was the midpoint potential (pH 7.0, 25 degrees C) of the semiquinone/hydroquinone couple, which was -320 mV for Fld I and -500 mV for the other two flavodoxins (Fld II and Fld III). All three flavodoxins were present in cells grown on NH4OAc. In cells grown on N2 as N source only Fld I and Fld II were found. The concentration of Fld II was 10-fold higher in N2-fixing cells than in cells grown on NH4OAc. Evidence has been obtained that Fld II is involved in electron transport to nitrogenase. As will be discussed, our observation that preparations of Azotobacter flavodoxin are heterogeneous, has consequences for the published data.

Studies on the mechanism of electron transport to nitrogenase in Azotobacter vinelandii

The involvement of the cytoplasmic membrane in electron transport to nitrogenase has been studied. Evidence shows that nitrogenase activity in Azotobacter vinelandii is coupled to the flux of electrons through the respiratory chain. To obtain information about proteins involved, the changes occurring in A. vinelandii cells transferred to nitrogen-free medium after growth on NH4Cl (depression of nitrogenase activity) were studied. Synthesis of the nitrogenase polypeptides was detectable 5 min after transfer to nitrogen-free medium. No nitrogenase activity could be detected until t = 20 min, whereupon a linear increase of nitrogenase activity with time was observed. Synthesis of nitrogenase was accompanied by synthesis of flavodoxin II and two membrane-bound polypeptides of Mr 29,000 and 30,000. Analysis with respect to changes in membrane-bound NAD(P)H dehydrogenase activities revealed the induction of an NADPH dehydrogenase activity, which was not detectable in membranes isolated from cells grown in the presence of NH4OAc. This induced activity was associated with the appearance of a polypeptide of Mr 29,000 in the NADPH dehydrogenase complex.

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.

Adenine nucleotide levels in Rhodospirillum rubrum during switch-off of whole-cell nitrogenase activity

Adenine nucleotide pools were measured in Rhodospirillum rubrum cultures that contained nitrogenase. The average energy charge [([ATP] + 1/2[ADP])/([ATP] + [ADP] + [AMP])] was found to be 0.66 and 0.62 in glutamate-grown and N-limited cultures respectively. Treatment of glutamate-grown cells with darkness, ammonia, glutamine, carbonyl cyanide m-chlorophenylhydrazone, or phenazine methosulphate resulted in perturbations in the adenine nucleotide pools, and led to loss of whole-cell nitrogenase activity and modification in vivo of the Fe protein. Treatment of N-limited cells resulted in similar changes in adenine nucleotide pools but not enzyme modification. No correlations were found between changes in adenine nucleotide pools or ratios of these pools and switch-off of nitrogenase activity by Fe protein modification in vivo. Phenazine methosulphate inhibited whole-cell activity at low concentrations. The effect on nitrogenase activity was apparently independent of Fe protein modification.

Inhibition of nitrogenase activity by ammonium chloride in Azotobacter vinelandii

In Azotobacter vinelandii cells, the short-term inhibition of nitrogenase activity by NH4Cl was found to depend on several factors. The first factor is the dissolved oxygen concentration during the assay of nitrogenase. When cells are incubated with low concentrations of oxygen, nitrogenase activity is low and ammonia inhibits strongly. With more oxygen, nitrogenase activity increases. Cells incubated with an optimum amount of oxygen have maximum nitrogenase activity, and the extent of inhibition by ammonia is small. With higher amounts of oxygen, the nitrogenase activity of the cells is decreased and strongly inhibited by ammonia. The second factor found to be important for the inhibition of nitrogenase activity by NH4Cl was the pH of the medium. At a low pH, NH4+ inhibits more strongly than at a higher pH. The third factor that influenced the extent of ammonia inhibition was the respiration rate of the cells. When cells are grown with excess oxygen, the respiration rate of the cells is high and inhibition of nitrogenase activity by ammonia is small. Cells grown under oxygen-limited conditions have a low respiration rate and NH4Cl inhibition of nitrogenase activity is strong. Our results explain the contradictory reports described in the literature for the NH4Cl inhibition of nitrogenase in A. vinelandii.

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.

Membrane energization in relation with nitrogen fixation in Azotobacter vinelandii and Rhizobium leguminosarum bacteroids

Nitrogen fixation in A. vinelandii and R. leguminosarum bacteroides shows identical characteristics with respect to the dependence on membrane energization, the sensitivity to uncouplers, the ATP/ADP-ratio, and the dependences on flavodoxinhydroquinone as electrondonor. Although we have been successful in preparing inside-out vesicles which can be energized, attempts to couple these membranes to N2-ase were still unsuccessful. One of the major problems could be the failure to energize these vesicles directly by ATP. Although subject to polymerisation after addition of MgCl2, it could be shown that the actual mol.wt. of the O2-stable N2-ase complex is about 300,000 in agreement with a 1:1:1 stoichiometry of the three constituent proteins, namely, component I, component II and the 2Fe-2S protein.

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

1. The nitrogen-fixing efficiency of freshly prepared suspensions of Rhizobium leguminosarum bacteroids from pea root nodules was considerably enhanced by addition of bovine serum albumin. Evidence was found that during preparation of bacteroids the cell membrane is exposed to the uncoupling effect of free fatty acids and to plant phospholipase D activity. Both effects could be counteracted by bovine serum albumin. 2. A technique was developed by which concentrations of free O2 and nitrogenase activity could be measured simultaneously under conditions of steady-state respiration. By means of this system it could be shown that in contrast to previous claims, high ATP/ADP ratios can be achieved in bacteroids even with a high concentration of O2 in the medium. 3. Nitrogen fixation was found to be controlled by the ATP/ADP ratio, the generation of reducing equivalents and the switch-off phenomenon. It was demonstrated that the generation of reducing equivalents for nitrogenase is regulated by the energized state and the integrity of the bacteroid cell membrane. The data indicate that the process of aerobic nitrogen fixation in R. leguminosarum bacteroids resembles that of Azotobacter vinelandii.

Nitrogenase IX. Effect of the MgATP generator on the catalytic and EPR properties of the enzyme in vitro

Nitrogenase(nitrogen:(acceptor) oxidoreduction, EC 1.7.99.2) of Clostridium pasteuranium is very sensitive to the ratio of MgADP/MgATP in dithionite oxidation assays. Variation of concentration of creatine kinase, an ATP-regenerating enzyme, can be used to control the ratio of ADP/ATP and thereby the dithionite oxidation activity of nitrogenase. The in vitro properties of nitrogenase support the suggestion of Haaker (Haaker, H., deKok, A. and Veeger, C. (1974) Biochim. Biophys. Acta 357, 344-357) that in vivo the nucleotide ratio and not the electron supply normally regulates nitrogenase activity. In EPR experiments it has been shown that the "steady state" varies as a function of the concentration of creatine kinase. The spectral differences are interpreted as being a function of the ratio of MgADP/MgATP obtained in the pseudo steady-state condition, which occurs as a result of variation in relative rates of ATP-utilizing and ATP-generating reactions, that is, the relative nitrogenase and creatine kinase activities. Implications of these finding for interpretation of previously reported kinetic and EPR studies are discussed.

Identification and physiological characterization of the nitrogen fixing bacterium Corynebacterium autotrophicum GZ 29

The coryneform hydrogen bacterium strain GZ 29, assigned to Corynebacterium autotrophicum fixed molecular nitrogen under autotrophic (H2, CO2) as well as under heterotrophic (sucrose) conditions. Physiological parameters of nitrogen fixation were measured under heterotrophic conditions. The optimal dissolved oxygen concentration for cells grown in a fermenter with N2 was rather low (0.14 mg O2/l) compared with cells grown in the presence of NH+4 (4.45 mg O2/l). C. autotrophicum GZ 29 had a doubling time of 3.7 h at 30 degrees C with N2 as N-source and sucrose as carbon source and at optimal pO2. Acetylene reduction reached values of 12 nmoles of ethylene produced/min X mg protein. Although the oxygen concentration in the growing culture was kept constant, the optimal dissolved oxygen tension for the acetylene reduction assay shifted to higher pO2-values. The overall efficiency of nitrogen fixation amounted to 22 mg N fixed/g sucrose consumed; it reached a maximal value of 65 mg N fixed/g sucrose consumed at the beginning of the exponential growth phase. Intact cells reduced acetylene even under anaerobic test conditions; further anaerobic metabolic activity could not be ascertained so far.

Regulation of respiration and nitrogen fixation in different types of Azotobacter vinelandii

The levels of the adenine nucleotides, pyridine nucleotides and the kinetical parameters of the enzymes of the Entner-Doudoroff pathway (glucose-6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase) were determined in Azotobacter vinelandii cells, grown under O2- or N2-limiting conditions. It was concluced that the levels of both the adenine nucleotides and pyridine nucleotides do not limit the rate of sucrose oxidation. Experiments with radioactive pyruvate and sucrose show that the rate of sucrose oxidation of Azotobacter cells is associated with an increase in the rate of sucrose uptake. The sites of oxidative phosphorylation and the composition of the respiratory membranes with respect to cytochromes c4 + c5, b and d differ in cells growth either O2- or N2-limited. It was possible to show that the respiration protection of the nitrogen-fixing system in Azotobacter is mainly independent of the oxidation capacity of the cells. The oxidation capacity intrinsically depends on the type of substrate and can be partly adapted. The maximum activity of the nitrogenase in Azotobacter depends on the type of substrate oxidized. Although the level of energy charge is somewhat dependent on the type of substrate used, no obvious relation can be derived between changes in energy charge and nitrogenase activity. An alternative proposal is given.

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.

Involvement of oxyleghaemoglobin and cytochrome P-450 in an efficient oxidative phosphorylation pathway which supports nitrogen fixation in Rhizobium

Cellular ATP level, ATP/ADP ratio and nitrogenase activity rise when oxyleghaemoglobin is added to respiring suspensions of Rhizobium japonicum bacteroids from soybean root nodules. Increased gaseous O2 tension is much less efficient than oxyleghaemoglobin in stimulation of bacteroid ATP production. Studies with the inhibitor carbonyl cyanide m-chlorophenylhydrazone show this ATP to be generated as a consequence of oxidative phosphorylation. N-Phenylimidazole, a specific cytochrome P-450 inhibitor, also lowers the efficiency of bacteroid oxidative phosphorylation. An approximately linear relationship is observed between ATP/ADP ratio and nitrogenase activity as N-phenylimidazole concentration is lowered. It is suggested that cytochrome P-450 is a component of the leghaemoglobin-facilitated respiration pathway and that it may act as intracellular O2 carrier rather than terminal oxidase. A less efficient oxidase appears to function when cytochrome P-450 is inhibited.