Nitrogenase Activity and Amounts of Nitrogenase Proteins in a Frankia-Alnus incana Symbiosis Subjected to Darkness

Effects of prolonged darkness on nitrogenase activity in vivo, nitrogenase activity in vitro, and the amounts of nitrogenase proteins were studied in symbiotic Frankia. Plants of Alnus incana (L.) Moench in symbiosis with a local source of Frankia were grown for 9 to 10 weeks in an 18/6 hour light/darkness cycle. After 12 hours of a light period, the plants were exposed to darkness for up to 40 hours. Nitrogenase activity (acetylene reduction activity) of intact plants was measured repeatedly. Frankia vesicle clusters were prepared from the nodules with an anaerobic homogenization and filtration technique and were used for measurements of in vitro nitrogenase activity and for measurements of the amounts of nitrogenase proteins on Western blots. Antisera made against dinitrogenase reductase (Fe-protein) of Rhodospirillum rubrum and against dinitrogenase (MoFe-protein) of Azotobacter vinelandii were used. Western blots were made transparent and nitrogenase proteins were quantified spectrophotometrically. Nitrogenase activity both in vivo and in vitro decreased after about 23 hours of darkness and continued to decrease to about 25% and 16% of initial activity, respectively, after 40 hours. The amount of Fe-protein and MoFe-protein in Frankia of the same plants decreased to 60% and 35%, respectively, after 40 hours of darkness. Loss of nitrogenase activity thus appeared to be largely explained by loss of MoFe-protein.     

Nitrogenase activity decay and energy supply in Frankia after addition of ammonium to the host plant Alnus incana

A clone of Alnus incana (L.) Moench was grown in symbiosis with a local source of Frankia or with Frankia Ar14. Seven to 9-week-old plants were given 20 m M NH₄Cl (20 m M KCl = control) for 3 days. Nitrogenase activity of intact plants decreased gradually within the 3 days of treatment to about 10% of the initial rates. Hydrogen evolution in air and total nitrogenase activity responded similarly to the treatment. Relative efficiency of nitrogenase thus remained the same throughout the study period. Control plants were not affected. Measurements of nitrogenase activity in root nodule homogenates (in vitro measurements) indicated loss of active nitrogenase rather than shortage of energy for nitrogenase activity in Frankia from ammonium-treated plants. Shoots were exposed to ¹⁴CO₂ and translocation of ¹⁴C to Frankia vesicle clusters prepared from root nodules was studied. Frankia vesicle clusters from ammonium-treated plants contained about half as much ¹⁴C as those of control plants during all 3 days studied. One explanation for the observed effects is that a reduced supply of carbon to Frankia vesicles in the root nodules caused a reduced metabolic rate, including reduced protein synthesis and synthesis of nitrogenase.     

Immunolocalization and Western Blot Analysis of Nitrogenase in Oscillatoria limosa During a Light-dark Cycle

Nitrogenase of the non-heterocystous nitrogen-fixing cyanobacterium Oscillatoria limosa was subjected to western blot analysis and immunogold electron microscopy using antisera raised against dinitrogenase (MoFe-protein, Component I) and dinitrogenase reductase (Fe-protein, Component II). O. limosa was grown diazotrophically under an alternating light-dark cycle (16–8h light-dark). Although nitrogenase activity (acetylene reduction) was found predominantly during the dark phase, being absent during most of the light period, immunogold electron microscopy revealed label of both subunits of nitrogenase in samples taken throughout the light-dark cycle. It was also shown that the nitrogenase label was distributed homogeneously in the cell and that it was present in every cell of every trichome whether fixing nitrogen or not. On average, 34 (± 6) gold particles μm^?2 thin section were detected. Nitrate-grown cells did not contain nitrogenase label. Western blot analysis of the Fe-protein in samples taken during the light phase, revealed a single band with an apparent molecular weight of 37 kDa. At the end of the light period, and during the dark phase when high nitrogenase activities were observed, an additional band of 36 kDa was found. The anti-MoFe-protein antiserum revealed a single band of 56 kDa which was present throughout the light-dark cycle. Nitrate-grown cells were not recognized by either antiserum. It is concluded that nitrogenase enzyme is present in O. limosa throughout the light-dark cycle but that the Fe-protein is modified (inactive form) during the light period when nitrogenase activity is absent.     

Respiratory capacity,nitrogenase activity and structural changes ofFrankia,in symbiosis withAlnus incana,in response to prolonged darkness

Plants ofAlnus incana (L.) Moench in symbiosis with a local source ofFrankia were exposed to prolonged darkness under controlled climate conditions.Frankia vesicle clusters were prepared from the root nodules, and the condition ofFrankia was measured as respiratory capacity by supplying the preparation with saturating amounts of four different substrates. During darkness, nitrogenase (EC 1.7.99.2) activity decreased in intact plants and in the vesicle-cluster preparations. The respiratory capacity ofFrankia also decreased. After 4 d in darkness most respiration was lost, though all nitrogenase activity was already lost after 3 d. When the dark treatment was ended after 2 d and normal light/dark conditions restored, nitrogenase activity immediately started to recover. The respiratory capacity continued to decrease and no recovery was observed until the third day after the end of the dark treatment. Whole-plant nitrogenase activity slowly increased at a rate similar to the rate of increase observed in untreated plants. Transmission electron micrographs of the root nodules showed that the cytoplasm of infected host cells and the cells ofFrankia were structurally degraded in response to dark treatment, while young vesicles were frequent during recovery. Growth and differentiation ofFrankia cells were apparently important for recovery of the enzyme activities studied.     

Diurnal Nitrogenase Modification in the Cyanobacterium Anabaena variabilis*

The nitrogen-fixing cyanobacterium Anabaena variabilis (ATCC 29413) was cultivated as continuous culture under a 12 h: 12 h light-dark cycle. In the light, photosynthetic activity resulted in a continuous increase in cellular glycogen content, followed by an almost complete dissimilation of the polysaccharide during the dark period. Nitrogenase activity, assayed by the acetylene reduction technique, was low at the end of the dark period and increased quickly upon illumination to reach a maximum after 4 to 6 h of light. The activity rapidly declined after darkening the culture. Increase and decrease of activity were accompanied by a change in the electrophoretic mobility of the Fe-protein of nitrogenase (dinitrogenase reductase) indicative of enzyme modification being involved in the diurnal control of nitrogenase activity. Modification and demodification of the Fe-protein were not coupled to the cell cycle since they followed darkening and illumination when the light or dark periods were changed. Addition of fructose increased nitrogenase activity even in darkness and caused demodification of the Fe-protein. Ammonium chloride supplied at the onset of illumination slowed down the increase of nitrogenase activity. A delayed inhibition of the enzyme was accompanied by partial Feprotein modification only. The reaction was completed after transfer to darkness. The function of enzyme modification in maintaining a constant C: N ratio is discussed and a dominating role of carbohydrate supply in this regulation is indicated by the reported findings.     

Loss and recovery of nitrogenase in Abuts incana nodules exposed to low oxygen and low temperature

The possibility that respiration limits oxygen access to nitrogenase was tested by artificially upsetting the balance between oxygen consumption (respiration) and oxygen influx (diffusion). Argon treatment of the nodulated root system on intact plants stopped in vivo nitrogenase activity almost completely. Upon return to air, nitrogenase activity was very low and recovered gradually to full activity after about 5 h. In vitro measurements on nodule homogenates indicated that active nitrogenase was lost upon the shift from low (argon) to normal (air) oxygen. Maintenance of nodulated root systems at low temperature (2°C) inhibited both respiration and in vivo nitrogenase activity. Upon return to normal temperature (22°C), oxygen uptake recovered very rapidly, but nitrogenase activity recovered only gradually to full activity after about 5 to 6 h. Again, loss of active nitrogenase could, at least partly, explain the reduced in vivo nitrogenase activity. The effects from a temporarily impaired balance between oxygen consumption and oxygen influx thus point to the importance of respiration for limiting oxygen access to nitrogenase.     

Regulation of nitrogenase in the photosynthetic bacterium Rhodobacter sphaeroides containing draTG and nifHDK genes from Rhodobacter capsulatus

The photosynthetic bacteria Rhodobacter capsulatus and Rhodospirillum rubrum regulate their nitrogenase activity by the reversible ADP-ribosylation of nitrogenase Fe-protein in response to ammonium addition or darkness. This regulation is mediated by two enzymes, dinitrogenase reductase ADP-ribosyl transferase (DRAT) and dinitrogenase reductase activating glycohydrolase (DRAG). Recently, we demonstrated that another photosynthetic bacterium, Rhodobacter sphaeroides, appears to have no draTG genes, and no evidence of Fe-protein ADP-ribosylation was found in this bacterium under a variety of growth and incubation conditions. Here we show that four different strains of Rba. sphaeroides are incapable of modifying Fe-protein, whereas four out of five Rba. capsulatus strains possess this ability. Introduction of Rba. capsulatus draTG and nifHDK (structural genes for nitrogenase proteins) into Rba. sphaeroides had no effect on in vivo nitrogenase activity and on nitrogenase switch-off by ammonium. However, transfer of draTG from Rba. capsulatus was sufficient to confer on Rba. sphaeroides the ability to reversibly modify the nitrogenase Fe-protein in response to either ammonium addition or darkness. These data suggest that Rba. sphaeroides, which lacks DRAT and DRAG, possesses all the elements necessary for the transduction of signals generated by ammonium or darkness to these proteins.     

The regulation of nodulation,nitrogen fixation and ammonium assimilation under a carbohydrate shortage stress in the Discaria trinervis-Frankia symbiosis

N₂-fixation is sensitive to limitation in the availability of newly synthesised carbohydrates for the nodules. We decided to explore the response of the D. trinervis - Frankia symbiosis to a transient decrease in carbohydrate supply to nodules. Feedback inhibition of nodulation as well as nodule growth was not released by a 6-day dark stress in D. trinervis nodulated plants. However, nitrogen fixation and assimilation were affected by the imposed stress. Nitrogenase activity was totally inhibited after 4 days of darkness although high levels of nitrogenase components were still detected at this time. Degradation of FeMo and Fe nitrogenase subunits – both at similar rates – was observed after 6 days of dark stress, revealing the need for inactivation to precede enhancement of protein turnover. Glutamine synthetase (GS), malate dehydrogenase (MDH) and asparagine synthetase (AS) polypeptides were also degraded during the dark stress, although at a lower rate than nitrogenase. ARA and nitrogenase were totally recovered 8 days after resuming normal illumination. It seems that current nitrogenase activity and ammonium assimilation are not, or are only weakly linked with the feedback control of nodulation in D. trinervis. These observations give support to the persistence of an autoregulatory signal in mature nodules that is not sensitive to transient shortages of carbon supply and sustains the inhibition of nodulation in the transient absence of N₂ fixation.     

Presence of a second mechanism for the posttranslational regulation of nitrogenase activity in Azospirillum brasilense in response to ammonium.

Although ADP-ribosylation of dinitrogenase reductase plays a significant role in the regulation of nitrogenase activity in Azospirillum brasilense, it is not the only mechanism of that regulation. The replacement of an arginine residue at position 101 in the dinitrogenase reductase eliminated this ADP-ribosylation and revealed another regulatory system. While the constructed mutants had a low nitrogenase activity, NH4+ still partially inhibited their nitrogenase activity, independent of the dinitrogenase reductase ADP-ribosyltransferase/dinitrogenase reductase activating glycohydrolase (DRAT/DRAG) system. These mutated dinitrogenase reductases also were expressed in a Rhodospirillum rubrum strain that lacked its endogenous dinitrogenase reductase, and they supported high nitrogenase activity. These strains neither lost nitrogenase activity nor modified dinitrogenase reductase in response to darkness and NH4+, suggesting that the ADP-ribosylation of dinitrogenase reductase is probably the only mechanism for posttranslational regulation of nitrogenase activity in R. rubrum under these conditions.     

thiK and thiL loci of Escherichia coli.

Nitrogenase proteins were isolated from cultures of the photosynthetic bacterium Rhodopseudomonas capsulata grown on a limiting amount of ammonia. Under these conditions, the nitrogenase N2ase A was active in vivo, and nitrogenase activity in vitro was not dependent upon manganese and the activating factor. The nitrogenase proteins were also isolated from nitrogen-limited cultures in which the in vivo nitrogenase activity had been stopped by an ammonia shock. This nitrogenase activity, N2ase R, showed an in vitro requirement for manganese and the activating factor for maximal activity. The Mo-Fe protein (dinitrogenase) was composed of two dissimilar subunits with molecular weights of 55,000 and 59,500; the Fe protein (dinitrogenase reductase), from either type of culture, was composed of a single subunit (molecular weight), 33,500). The metal and acid labile sulfur contents of both nitrogenase proteins were similar to those found for previously isolated nitrogenases. The Fe proteins from both N2ase A and N2ase R contained phosphate and ribose, 2 mol of each per mol of N2ase R Fe protein and about 1 mol of each per mol of N2ase A Fe protein. The greatest difference between the two types of Fe protein was that the N2ase R Fe protein contained about 1 mol per mol of an adenine-like molecule, whereas the N2ase A Fe protein content of this compound was insignificant. These results are compared with various models previously presented for the short-term regulation of nitrogenase activity in the photosynthetic bacteria.     

Nitrogenase activity and root nodule metabolism in response to O2 and short-term N2 deprivation in dark-treated Frankia-Alnus incana plants

Inhibition of nitrogenase (EC 1.18.6.1) activity by O₂ has been suggested to be an early response to disturbance in carbon supply to root nodules in the Frankia‐Alnus incana symbiosis. Intact nodulated root systems of plants kept in prolonged darkness of 22 h were used to test responses to O₂ and short‐term N₂ deprivation (1 h in Ar:O₂). By using a Frankia lacking uptake hydrogenase it was possible to follow nitrogenase activity over time as H₂ evolution in a gas exchange system. Respiration was simultaneously recorded as CO₂ evolution. Dark‐treated plants had lower initial nitrogenase activity in N₂:O₂ (68% of controls), which declined further during a 1‐h period in the assay system in N₂:O₂ at 21 and 17% O₂, but not at 13% O₂. When dark‐treated plants were deprived of N₂ at 21 and 17% O₂ nitrogenase activity declined rapidly to 61 and 74%, respectively, after 20 min, compared with control plants continuously kept in their normal light regime. In contrast, there was no decline in dark‐treated plants at 13% O₂, and only a smaller and temporary decline in control plants at 21% O₂. When dark‐treated plants were kept at 21% O₂ during 45 min prior to N₂ deprivation at 17% O₂ the decline was abolished. This supports the idea that the decline in nitrogenase activity observed in N₂:O₂ at 21% O₂ and during N₂ deprivation was caused by O₂, which affected a sensitive nodule fraction. Nodule contents of the amino acids Gln and Cit decreased during N₂ deprivation, suggesting decreased assimilation of NH₄⁺. Contents of ATP and ADP in nodules were not affected by short‐term N₂ deprivation. ATP/ADP ratios were about 5 indicating a highly aerobic metabolism in the root nodule. We conclude that nitrogenase activity of Alnus plants exposed to prolonged darkness becomes more sensitive to inactivation by O₂. It seemed that dark‐treated plants could not adjust their nodule metabolism at higher perceived pO₂ and during cessation of NH₄⁺ production.     

Posttranslational modification of dinitrogenase reductase in <Emphasis Type="Italic">Rhodospirillum rubrum</Emphasis> treated with fluoroacetate

Nitrogen fixation is one of the major biogeochemical contributions carried out by diazotrophic microorganisms. The goal of this research is study of posttranslational modification of dinitrogenase reductase (Fe protein), the involvement of malate and pyruvate in generation of reductant in Rhodospirillum rubrum. A procedure for the isolation of the Fe protein from cell extracts was developed and used to monitor the modification of the Fe protein in vivo. The subunit pattern of the isolated the Fe protein after sodium dodecyl sulfate–polyacrylamide gel electrophoresis was assayed by Western blot analysis. Whole-cell nitrogenase activity was also monitored during the Fe protein modification by gas chromatograpy, using the acetylene reduction assay. It has been shown, that the addition of fluoroacetate, ammonia and darkness resulted in the loss of whole-cell nitrogenase activity and the in vivo modification of the Fe protein. For fluoroacetate, ammonia and darkness, the rate of loss of nitrogenase activity was similar to that for the Fe protein modification. The addition of NADH and reillumination of a culture incubated in the dark resulted in the rapid restoration of nitrogenase activity and the demodification of the Fe protein. Fluoroacetate inhibited the nitrogenase activity of R. rubrum and resulted in the modification of the Fe protein in cells, grown on pyruvate or malate as the endogeneous electron source. The nitrogenase activity in draTG mutant (lacking DRAT/DRAG system) decreased after the addition of fluoroacetate, but the Fe protein remained completely unmodified. The results showed that the reduced state of cell, posttranslational modifications of the Fe protein and the DRAT/DRAG system are important for nitrogenase activity and the regulation of nitrogen fixation.     

Nitrogen fixation and biomass production in symbioses between Alnus incana and Frankia strains with different hydrogen metabolism

Three different strains of Frankia , the pure cultures AvcI1 and CpI1 and a local strain (crushed nodule inoculum), were compared in symbiosis with one clone of Alnus incana (L.) Moench. Hydrogen metabolism, nitrogenase (EC 1.7.99.2) activity and relative efficiency of nitrogenase were studied as well as growth and nitrogen content of the plants. The local Frankia strain showed no measurable hydrogen uptake but high H₂-evolution. No H₂-evolution was detected in Frankia AvcI1 because of its hydrogenase activity. CpI1 also had hydrogenase, although only a very small H₂-evolution was detected at the end of the growth period. Hydrogenase activity was detected both in pure cultures and nodule homogenates of CpI1 and AvcI1. Growth, biomass production and nitrogen content were highest in alders inoculated with Frankia AvcI1 while the lowest values were found for alders living in symbiosis with the local Frankia strain. The presence of hydrogenase in Frankia seemed to be benefical for growth and biomass production in the alders. However, the strains also differed with respect to spore formation. The local strain, but not AvcI1 and CpI1, formed spores in the root nodules.     

Nitrate reductase activity, nitrogenase activity and photosynthesis of black alder exposed to chilling temperatures

Actinorhizal ( Frankia -nodulated) black alder [ Alnus glutinosa (L.) Gaertn.] seedlings fertilized with 0.36 m M nitrate (low nitrate fertilizer treatment) or 7.14 m M nitrate (high nitrate fertilizer treatment) and acclimated in a growth chamber for 2 weeks were exposed to 2.5 h of night-time chilling temperatures of −1 to 4°C. Cold treatment decreased nitrogenase activity (acetylene reduction activity) 33% for low nitrate fertilized plants and 41% for high nitrate fertilized plants. Recovery of nitrogenase activity occurred within 7 days after chilling treatment. In contrast, in vivo nitrate reductase (NR) activities of leaves and fine roots increased immediately after chilling then decreased as nitrogenase activities recovered. Fine roots of alder seedlings exhibited NR activities proportional to the amounts of nitrate in the rooting medium. In contrast, the NR activities of leaves were independent of substrate and tissue nitrate levels and corresponded to nitrogenase activity in the root nodules. In a separate experiment, net photosynthesis (PS) of similarly treated black alder seedlings was measured before and after chilling treatments. Net PS declined in response to chilling by 17% for plants receiving low nitrate fertilizer and 19% for plants receiving high nitrate fertilizer. After chilling, stomatal conductance (g_s) decreased by 39% and internal CO₂ concentration (c_i) decreased by 5% in plants receiving the high nitrate fertilizer, whereas plants receiving the low nitrate fertilizer showed no change in g_s and a 13% increase in c_i. Results indicate that chilling stimulates stomatal closure only at the high nitrate level and that interference with biochemical functions is probably the major impact of chilling on PS.     

Calcium and magnesium effects on symbiotic nitrogen fixation in the alfalfa (M. sativa) –Rhizobium meliloti system

An investigation of the roles of calcium and magnesium ions in symbiotic nitrogen fixation by legumes has shown that alfalfa plants ( Medicago sativa L. cv. Saranac and Apollo) deficient in either cation were poorly nodulated and retarded in growth on nitrogen-free media. This effect was reversed by supplementation with normal levels of these cations. After recovery, the calcium deficient seedlings showed continuing effects of early mineral deficiencies but recovered to 75% of the nitrogenase activity and had nearly the same yield as control plants. Magnesium deficient plants recovered nitrogenase activity to the same degree but grew to only about 50% of the weight of controls. Supplementation of non-deficient seedlings grown on N-free media with varying amounts of Ca²⁺ and Mg²⁺ resulted in the identification of an optimal ratio of calcium and magnesium near 2 when neither cation was growth limiting. A highly significant positive correlation was obtained between yield of dry matter and the fraction of total expressed nitrogenase activity that was actually available for dinitrogen reduction (nitrogen reducing equivalent). Bacteroids isolated from root nodules and freed of plant cytoplasmic components required high magnesium levels for maximal utilization of externally supplied ATP and dithionite. Ca⁺ was antagonistic to this activity but complemented Mg²⁺ in stimulating the respiration-supported nitrogenase activity of intact bacteroids which had been treated with a chelating agent. The effects of calcium and magnesium on the nitrogenase system of intact bacteroids may be due to binding of the Ca²⁺ ions to the bacteroid membrane.     

Relation between nitrogenase synthesis and activity in a marine unicellular diazotrophic strain, Gloeothece sp. 68DGA (Cyanophyte), grown under different light/dark regimens

The relationship between the abundance of nitrogenase and its activity was studied in the marine unicellular cyanobacterium Gloeothece sp. 68DGA cultured under different light/dark regimens. The Fe‐ and MoFe‐protein of nitrogenase and nitrogen (N₂)‐fixing (acetylene reduction) activity were detected only during the dark phase when the cells were grown under a 12 h light/12 h dark cycle (12L/12D). Nitrogenase activity appeared about 4 h after entering the dark phase. Maximum nitrogenase activity occurred at around the middle of the dark phase, and the activity rapidly decreased to zero before the start of the light phase. The rapid decrease of nitrogenase activity and the Fe‐protein of nitrogenase near the end of the dark phase in 12L/12D were partly recovered by the addition of l ‐methionine‐sulfoximine, an inhibitor of glutamine synthetase. Diurnal oscillation of the abundance of nitrogenase was maintained in the first subjective dark phase (i.e. the period corresponding to the dark phase) after the cells were transferred from 12L/12D to continuous illumination. However, enzyme activity was detected only when photosynthetic oxygen (O₂) evolution was completely suppressed by reducing the light intensity or by the addition of 3‐(3,4‐dichlorophenyl)‐1,1‐dimethylurea. Nitrogenase always appeared in the cells about 16 h after starting the light phase, even when the 12L/12D cycle was modified by the addition or subtraction of a single 6 h period of light or dark. These results suggest the following: (i) N₂‐fixation by Gloeothece sp. 68DGA is primarily regulated by an endogenous circadian oscillator at the level of nitrogenase synthesis. (ii) The endogenous circadian rhythm resets on a shift of the timing of the light phase. (iii) Nitrogenase activity is not always reflected in the presence of nitrogenase. (iv) The activity of nitrogenase is negatively regulated by fixed nitrogen and the concentration of ambient O₂.     

Posttranslational regulation of nitrogenase in Rhodospirillum rubrum strains overexpressing the regulatory enzymes dinitrogenase reductase ADP-ribosyltransferase and dinitrogenase reductase activating glycohydrolase.

Rhodospirillum rubrum strains that overexpress the enzymes involved in posttranslational nitrogenase regulation, dinitrogenase reductase ADP-ribosyltransferase (DRAT) and dinitrogenase reductase activating glycohydrolase (DRAG), were constructed, and the effect of this overexpression on in vivo DRAT and DRAG regulation was investigated. Broad-host-range plasmid constructs containing a fusion of the R. rubrum nifH promoter and translation initiation sequences to the second codon of draT, the first gene of the dra operon, were constructed. Overexpression plasmid constructs which overexpressed (i) only functional DRAT, (ii) only functional DRAG and presumably the putative downstream open reading frame (ORF)-encoded protein, or (iii) all three proteins were generated and introduced into wild-type R. rubrum. Overexpression of DRAT still allowed proper regulation of nitrogenase activity, with ADP-ribosylation of dinitrogenase reductase by DRAT occurring only upon dark or ammonium stimuli, suggesting that DRAT is still regulated upon overexpression. However, overexpression of DRAG and the downstream ORF altered nitrogenase regulation such that dinitrogenase reductase did not accumulate in the ADP-ribosylated form under inactivation conditions, suggesting that DRAG was constitutively active and that therefore DRAG regulation is altered upon overexpression. Proper DRAG regulation was observed in a strain overexpressing DRAT, DRAG, and the downstream ORF, suggesting that a proper balance of DRAT and DRAG levels is required for proper DRAG regulation.     

Changes in the EPR signal of dinitrogenase from Azotobacter vinelandii during the lag period before hydrogen evolution begins.

During the lag period before H2 is evolved by the nitrogenase system, the EPR signal of dinitrogenase decreases steadily, indicating transfer of electrons into dinitrogenase. The rate constant for the decrease in amplitude of the EPR signal, the steady state rate of H2 evolution from nitrogenase, and the length of the lag period have been measured. The data suggest that H2 is evolved only after dinitrogenase has been reduced by 2 electrons/molybdenum. The electrons that have been transfered into dinitrogenase during the lag period are not evolved as H2 upon denaturation of dinitrogenase. The existence of a lag indicates that the two nitrogenase proteins dissociate after every electron transfer. The lag occurs and the nitrogenase proteins dissociate under a variety of conditions of pH and temperature.     

Effect of ammonia, darkness, and phenazine methosulfate on whole-cell nitrogenase activity and Fe protein modification in Rhodospirillum rubrum.

A procedure for the immunoprecipitation of Fe protein from cell extracts was developed and used to monitor the modification of Fe protein in vivo. The subunit pattern of the isolated Fe protein after sodium dodecyl sulfate-polyacrylamide gel electrophoresis was assayed by Coomassie brilliant blue protein staining and autoradiographic 32P detection of the modifying group. Whole-cell nitrogenase activity was also monitored during Fe protein modification. The addition of ammonia, darkness, oxygen, carbonyl cyanide m-chlorophenylhydrazone, and phenazine methosulfate each resulted in a loss of whole-cell nitrogenase activity and the in vivo modification of Fe protein. For ammonia and darkness, the rate of loss of nitrogenase activity was similar to that for Fe protein modification. The reillumination of a culture incubated in the dark brought about a rapid recovery of nitrogenase activity and the demodification of Fe protein. Cyclic dark-light treatments resulted in matching cycles of nitrogenase activity and Fe protein modification. Carbonyl cyanide m-chlorophenylhydrazone and phenazine methosulfate treatments caused an immediate loss of nitrogenase activity, whereas Fe protein modification occurred at a slower rate. Oxygen treatment resulted in a rapid loss of activity but only an incomplete modification of the Fe protein.