Effect of light nitrogenase function and synthesis in Rhodopseudomonas capsulata.

The metabolic versatility of the purple nonsulfur photosynethetic bacterial permits the expression of either a phototrophic or a dark aerobic mode of growth. These organism also possess nitrogenase activity which may function under semiaerboic conditions. On the basis of these important properties, the light dependence of nitrogenase function and synthesis in Rhodopseudomonas capsulata was investigated. Nitrogenase activity was strictly dependent on light; no activity was observed in the dark, even when energy (ATP) was supplied by oxidative phosphorylation. It was concluded that the low-potential reducing agent required by the nitrogenase-catalyzed reaction could only be generated by a photochemical reaction. Nitrogenase biosynthesis was also largely dependent on light; however, a small amount of synthesis was observed in resting cells incubated in the dark. Resting cells prepared from dark-grown cultures synthesized nitrogenase at high rates upon illumination. The highest stability of nitrogenase in these resting cells was observed when suspensions were exposed to a diurnal pattern of illumination rather than continuous light. Although nitrogenase function and synthesis are closely coupled to photosynthetic activity, the biosyntheses of bacteriochorophyll and nitrogenase are independent of each other and are most probably subject to different regulatory mechanisms by light.     

Regulation of nitrogenase gene expression in anaerobic cultures of Anabaena variabilis.

Derepression of nitrogenase gene expression was studied at the mRNA and enzyme activity levels in anaerobic cultures of Anabaena variabilis 29413. Cells, previously grown with ammonium chloride, were incubated in the absence of fixed nitrogen compounds under an Ar atmosphere with dichlorophenyldimethyl-urea present to inhibit oxygen evolution. The appearance of nitrogenase mRNA (measured by dot blot hybridization analysis) and nitrogenase activity (measured as acetylene-reducing activity) was followed, and the cells were also observed by phase-contrast microscopy. Nitrogenase mRNA could be detected after 1.5 to 2.0 h of nitrogen starvation; enzyme activity appeared about 1 h later. Although enzyme activity increased for many hours, mRNA levels reached a steady state rapidly. Neither heterocysts nor proheterocysts formed under these conditions; however, the cells were observed to shrink and become chlorotic. When anaerobic, derepressed cultures were exposed to oxygen, nitrogenase mRNA levels decreased very rapidly.     

The dependence on iron availability of allocation of iron to nitrogenase components in Klebsiella pneumoniae and Escherichia coli.

Nitrogenase contains approximately 38 iron ions/complete unit. Therefore, we sought to identify steps and genes involved in nitrogenase production that are responsive to iron availability. We have characterized nitrogenase production in Klebsiella pneumoniae grown in a range of different iron concentrations. We find significant accumulation (50-75%) and normal synthesis rates of the structural polypeptides, even under conditions in which the observed nitrogenase activities are only 14-28% of those observed in iron-sufficient conditions. Thus, maturation instead of synthesis of the structural polypeptides is primarily responsible for the iron dependence of nitrogenase activity. We have also used a binary plasmid system in Escherichia coli to investigate the contributions of various nitrogen fixation (nif) genes to the iron dependence of nitrogenase production. At least one of the nif genes DKTYENXUSVW can modulate synthesis of the structural polypeptide NIF H in response to iron availability. We speculate that an iron-deficient complex of the product(s) of at least one of these genes may repress structural polypeptide synthesis in iron-depleted K. pneumoniae. Such a system would compensate for the inactivity of NIF L in iron-depleted cultures and ensure balanced production of the structural polypeptides of nitrogenase in accordance with the iron available for their maturation.     

Role of ammona in regulation of nitrogenase synthesis and activity in Anabaena cylindrica

The regulation of nitrogenase biosynthesis and activity by ammonia was studied in the heterocystous cyanobacterium Anabaena cylindrica. Nitrogenase synthesis was measured by in vivo acetylene reduction assays and in vitro by an activity-independent, immunoelectrophoretic measurement of the Fe-Mo protein (Component I). When ammonia was added to differentiating cultures after a point when heterocyst differentiation became irreversible, FeMo protein synthesis was also insensitive to ammonia. Treating log-phase batch cultures with 100% O₂ for 30 min resulted in a loss of 90% of nitrogenase activity and a 50% loss of the FeMo protein. Recovery was inhibited by chloramphenicol but not by ammonia or urea. The addition of ammonia to log-phase cultures resulted in a decrease in specific levels of nitrogenase activity and FeMo protein that occurred at the same rate as algal growth and was independent of O₂ tension of the culture media. However, in light-limited linear-phase cultures, ammonia effected a dramatic inhibition of nitrogenase activity. These results indicate that nitrogenase biosynthesis becomes insensitive to repression by ammonia as heterocysts mature and that ammonia or its metabolites act to regulate nitrogen fixation by inhibiting heterocyst differentiation and by inhibiting nitrogenase activity through competition with nitrogenase for reductant and/or ATP, but not by directly regulating nitrogenase biosynthesis in heterocysts.     

Control of nitrogenase recovery from oxygen inactivation by ammonia in the cyanobacterium Anabaena sp. strain CA (ATCC 33047).

The control of nitrogenase recovery from inactivation by oxygen was studied in Anabaena sp. strain CA (ATCC 33047). Nitrogenase activity (acetylene reduction) in cultures grown in 1% CO2 in air was inhibited by exposure to 1% CO2-99% O2 and allowed to recover in the presence of high oxygen tensions. Cultures exposed to hyperbaric levels of oxygen in the presence of 10 mM NH4NO3 were incapable of regaining nitrogenase activity, whereas control cultures returned to 65 to 80% of their original activity within about 3 h after exposure to high oxygen tension. In contrast to the regulation of heterocyst differentiation and nitrogenase synthesis, recovery from oxygen inactivation in this organism was shown to be under the control of NH4+ rather than NO3-.     

Effect of ammonia on the synthesis and function of the N 2 -fixing enzyme system in Clostridium pasteurianum

The N(2)-fixing system of Clostridium pasteurianum operates under regulatory controls; no activity is found in cultures growing on excess NH(3). The conditions which are necessary for the synthesis and function of this system were studied in whole cells by using acetylene reduction as a sensitive assay for the presence of the N(2)-fixing system. Nitrogenase of N(2)-fixing cultures normally can fix twice as much N(2) as is needed to maintain the growth rate. When cultures that have grown for four or more generations on NH(3) exhaust NH(3) from the medium, a diauxic lag of about 90 min ensues before growth is resumed on N(2). Neither N(2)-fixing nor acetylene reduction activity can be detected before growth is resumed on N(2). N(2) is not a necessary requirement for this synthesis since under argon that contains less than 10(-8)m N(2), the N(2)-fixing system is made. If NH(3) is added to N(2)-dependent cultures, synthesis of the enzyme system is abruptly stopped, but the enzyme already present remains stable and functional for at least 6 hr (over three generations). Cultures grown under argon in a chemostat controlled by limiting ammonia have derepressed nitrogenase synthesis. If the argon is removed and replaced by N(2), partial repression of nitrogenase occurs.     

Oxygen inactivation and recovery of nitrogenase activity in cyanobacteria.

Exposure of nitrogen-fixing cultures of Anabaena spp. to 100% oxygen resulted in the rapid decline of nitrogenase activity. When oxygen-treated cells were transferred to 100% argon, nitrogenase activity was quickly restored in a process that required protein synthesis. Anaerobiosis was not essential for the recovery process; in fact, cells of Anabaena sp. strains CA and 1F will recover nitrogenase activity after prolonged incubation in 100% oxygen. Oxygen treatment acted directly on the intracellular nitrogenase and did not affect other metabolic processes. Examination of crude extracts of oxygen-treated Anabaena sp. strain CA indicated that both components of nitrogenase are inactivated. However, several lines of evidence suggest that oxygen treatment does not result in irreversible denaturation of nitrogenase, but rather results in a reversible inactivation which may serve as a protection mechanism. Nitrogenase present in crude extracts from cells of Anabaena sp. strain 1F which had been incubated for a prolonged period in 100% oxygen was less sensitive to oxygen in vitro than was nitrogenase of a crude extract of untreated cells.     

Boron Protection for O(2) Diffusion in Heterocysts of Anabaena sp. PCC 7119

The effect of boron on nitrogenase activity has been studied. When cells were dependent on N₂ fixation, the lack of boron inhibited nitrogenase activity. However, under anaerobic conditions or in the presence of Na-dithionite this effect was not observed. Nitrogenase synthesis was not affected by boron deficiency. Similarly, the heterocyst number was not altered. Examination of boron-deficient cultures showed, however, some dramatic changes in heterocyst morphology. The increased activity of those enzymes related to the maintaining of the low intracellular level of toxic oxygen species (superoxide dismutase, catalase, and peroxidase) support our hypothesis of the role of boron in heterocyst envelope stabilization.     

Characteristics of N2 fixation in Mo-limited batch and continuous cultures of Azotobacter vinelandii.

Steady-state chemostat cultures of Azotobacter vinelandii were established in a simple defined medium that had been chemically purified to minimize Mo and that contained no utilizable combined N source. Growth was dependent on N2 fixation, the limiting nutrient being the Mo contaminating the system. The Mo content of the organisms was at least 100-fold lower than that of Mo-sufficient cultures, and they lacked the characteristic g = 3.7 e.p.r. feature of the MoFe-protein of nitrogenase. A characteristic of nitrogenase activity in vivo in Mo-limited populations was a disproportionately low activity for acetylene reduction, which was 0.3 to 0.1 of that expected from the rate of N2 reduction. Acetylene was also a poor substrate in comparison with protons as a substrate for nitrogenase, and did not markedly inhibit H2 evolution, in contrast with Mo-sufficient populations. In batch cultures in similar medium or 'spent' chemostat medium inoculated with Mo-limited organisms, the addition of Mo elicited a biphasic increased growth response at concentrations as low as 2.5 nM, provided that sufficient Fe was supplied. In this system V did not substitute for Mo, and Mo-deficient cultures ceased growth at a 25-fold lower population density compared with cultures supplemented with Mo. Nitrogenase component proteins could not be unequivocally detected by visual inspection of fractionated crude extracts of Mo-limited organisms. 35SO42-pulse-labelling studies also showed that the rate of synthesis of the MoFe-protein component of nitrogenase was too low to be quantified. However, the Fe-protein of nitrogenase was apparently synthesized at high rates. The discussion includes an evaluation of the possibility that A. vinelandii possesses an Mo-independent N2-fixation system.     

A mutant of Anabaena sp. CA with oxygen-sensitive nitrogenase activity.

Studies on the O₂ protection mechanism for nitrogenase in a mutant (PM10) of $\text{Anabaena}$ sp. CA indicated that the ability to protect nitrogenase from O₂ was functionally impaired. Growth rates of PM10 were substantially improved when cells were cultured under microaerobic conditions. Nitrogenase activity was totally inhibited by exposure to O₂ for 30 min; partial restoration of activity was attained when cell suspensions were subsequently made microaerobic. Experiments in which induction of nitrogenase activity was followed indicated that the synthesis of the O₂ protection mechanism was temporally separated from synthesis of heterocysts and nitrogenase.     

Nitrogen fixation by Anabaena cylindrica

Summary Blending Anabaena cylindrica cultures results in a loss of nitrogenase activity which is correlated with the breakage of the filaments at the junctions between heterocysts and vegetative cells. Oxygen inhibition of nitrogen fixation was significant only above atmospheric concentrations. Nitrogen-fixation activities in the dark were up to 50% of those observed in the light and were dependent on oxygen (10 to 20% was optimal). Nitrogenase activity was lost in about 3 h when cells were incubated aerobically in the dark. Re-exposure to light resulted in recovery of nitrogenase activity within 2 h. Blending, oxygen, or dark pre-incubation had similar effects upon cultures grown under air or nitrogen and did not inhibit light-dependent CO₂ fixation. We conclude that heterocysts are the sites of nitrogenase activity and propose a model for nitrogen fixation by Anabaena cylindrica.     

Cellular differentiation and nitrogenase activity in the cyanobacteriumAnabaena

Nitrogenase activity at periods of differentiation of heterocysts and akinetes was assayed by the acetylene reduction technique. There was no nitrogenase activity in ammoniumgrown, non-heterocystousAnabaena sp.; the activity appeared only after a lag-phase of about 17 – 21 h after the ammonium-grown culture had been transferred to medium free of combined nitrogen. This activity started appearing as the proheterocysts were developing to mature heterocysts. Maximum nitrogenase activity was attained with exponential phase of culture and mature heterocysts. This activity gradually decreased with the differentiation of akinetes. Only insignificant nitrogenase activity was observed in old cultures in which most cells had matured into akinetes.     

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.     

浑球红假单胞菌及其谷氨酸合成酶突变株氢酶活性和合成

浑球红假单胞菌野生型菌株的氢酶表达被有机碳、氮底物所抑制。在光照和黑暗时,氧浓度变化对氢酶的作用不同,但高氧浓度都阻遏氢酶的表达。微量Ni~(2+)能专一性地促进氢酶活性,固氮酶的产氢也可以调节氢酶的表达水平。该野生菌株的GOGAT突变株缺乏固氮酶和氢酶活性,在加入谷氨酰胺合成酶抑制剂MSX后,固氮酶和氢酶以相关联的方式合成出来,固氮酶产生的氢看来诱导了氢酶的合成。然而在固氮酶不表达的情况下,外源氢也可诱导氢酶的合成。     

Dependence of oxygen-tolerant nitrogenase activity on divalent cations in Azotobacter vinelandii.

Nitrogenase activity of washed Azotobacter vinelandii cells was enhanced by the addition of Ca2+ and Mg2+, and the enhancement increased with the O2 concentration. In assays provided with a level of O2 that was initially supraoptimal and inhibitory to nitrogenase activity, the addition of Ca2+ or Mg2+ affected both the maximum respiration rate (Vmax) of the cells and the apparent affinity [KS(O2)] of cell respiration for O2. Changes in these parameters correlated with changes in nitrogenase activity. Aeration-dependent increases in Vmax and KS(O2) were inhibited by rifampin and chloramphenicol and were also observed in ammonium-grown cultures.     

Photoproduction of ammonium ion from N2 in Rhodospirillum rubrum.

NH+4 excretion was undetectable in N2-fixing cultures of Rhodospirillum rubrum (S-1) and nitrogenase activity in these cultures was repressed by the addition of 10 mM NH+4 to the medium. The glutamate analog, L-methionine-DL-sulfoximine (MSX), derepressed N2 fixation even in the presence of 10 mM extracellular NH+4. When 10 mg MSX/ml was added to cultures just prior to nitrogenase induction they developed nitrogenase activity (20% of the control activities) and excreted most of their fixed N2 as NH+4. Nitrogenase activities and NH+4 production from fixed N2 were increased considerably when a combined nitrogen source, NH+4 (greater than 40 mumoles NH+4/mg cell protein in 6 days) or L-glutamate (greater than 60 mumoles NH+4/ mg cell protein in 6 days) was added to the cultures together with MSX. Biochemical analysis revealed that R. rubrum produced glutamine synthetase and glutamate synthase (NADP-dependent) but no detectable NADP-dependent glutamate dehydrogenase. The specific activity of glutamine synthetase was observed to be maximal when nitrogenase activity was also maximal. Nitrogenase and glutamine synthetase activities were repressed by NH+4 as well as by glutamate. The results demonstrate that utilization of solar energy to photoproduce large quantities of NH+4 from N2 is possible with photosynthetic bacteria by interfering with their regulatory control of N2 fixation.     

Biochemical Changes in Nodules of Vigna mungo (L.) During Vegetative and Reproductive Stages of Plant Growth in the Field

Nitrogenase activity in root nodules of Vigna mungo L. attaineda peak at the flowering stage and declined thereafter. Levelsof soluble proteins, particularly leghaemoglobin, and ratesof protein and RNA synthesis declined with nitrogenase. Activitiesof protease and RNase increased with the ageing or nodules.Carbohydrate utilization, sugar levels and ATP were maximumat the early pod stage and gradually declined with age. Theseinterrelated changes point to a loss of nitrogenase activityas the first indicator of nodule senescence that is linked withflowering. Later, losses of proteins, total sugar and ATP wererelated to increased RNase and protease activity and decreasedhexokinase and to a loss in capacity to incorporate amino acidinto protein.Copyright 1993, 1999 Academic Press Vigna mungo (L.), senescene, nitrogenase, leghaemoglobin, field experiments     

Synthesis of nitrogenase and heterocysts by Anabaena sp. CA in the presence of high levels of ammonia.

Anabaena sp. CA fails to synthesize heterocysts and nitrogenase when grown with KNO3 as the nitrogen source. By contrast, both heterocysts and proheterocysts are synthesized in NH4Cl-containing media to a level nearly commensurate with cells grown in the absence of combined nitrogen. The growth rate of the organism in NH4Cl-containing media was similar to that obtained with KNO3 as the nitrogen source and was independent of the presence of N2 in the atmosphere. Thus, our results indicate that the organism assimilated nitrate and ammonium nitrogen equally well to meet the nitrogen requirements for growth. Moreover, in contrast to previous studies with other cyanobacteria, the repressor singal for heterocyst differentiation in Anabaena sp. CA is not derived from the metabolism of ammonia but appears to be involved with nitrate metabolism. Nitrogenase activity was partially expressed in NH4Cl-grown cultures. Increasing the level of nitrogenase activity to a value representative of a N2-grown culture required both the inhibition of ammonia assimilation and de novo protein synthesis. An increase in the number of mature heterocysts was not required. The fact that high levels of exogenous ammonia only partially repress the synthesis of proteins required for the maximum expression of nitrogenase activity in Anabaena sp. CA has important implications.     

Influence of nitrogen source on growth and nitrogenase activity inAzotobacter vinelandii

Growth and nitrogenase activity were studied in cultures ofAzotobacter vinelandii growing with dinitrogen, ammonium sulfate, aspartic acid or yeast extract. Nitrogenase activity was measured by means of the C₂H₂ reduction test.In the presence of ammonium sulfate nitrogenase is completely repressed. After exhaustion of ammonia its activity is restored following a diauxic lag period of 30 min. With aspartic acid nitrogenase activity is partially repressed, and growth yield is higher than in the culture growing with N₂ only. This is due to simultaneous use of dinitrogen and aspartate. Fluctuations of nitrogenase activity occurring during exponential growth and the mechanism of their regulation are discussed.Abbreviations NA nitrogenase activity - BNF Burk's nitrogen free medium