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.     

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.     

Nitrogenase activity in the non-heterocystous cyanobacterium Oscillatoria sp. grown under alternating light-dark cycles

The non-heterocystous cyanobacterium Oscillatoria sp. strain 23 fixes nitrogen under aerobic conditions. If nitrate-grown cultures were transferred to a medium free of combined nitrogen, nitrogenase was induced within about 1 day. The acetylene reduction showed a diurnal variation under conditions of continuous light. Maximum rates of acetylene reduction steadily increased during 8 successive days. When grown under alternating light-dark cycles, Oscillatoria sp. fixes nitrogen preferably in the dark period. For dark periods longer than 8 h, nitrogenase activity is only present during the dark period. For dark periods of 8 h and less, however, nitrogenase activity appears before the beginning of the dark period. This is most pronounced in cultures grown in a 20 h light – 4 h dark cycle. In that case, nitrogenase activity appears 3–4 h before the beginning of the dark period. According to the light-dark regime applied, nitrogenase activity was observed during 8–11 h. Oscillatoria sp. grown under 16 h light and 8 h dark cycle, also induced nitrogenase at the usual point of time, when suddenly transferred to conditions of continuous light. The activity appeared exactly at the point of time where the dark period used to begin. No nitrogenase activity was observed when chloramphenicol was added to the cultures 3 h before the onset of the dark period. This observation indicated that for each cycle, de novo nitrogenase synthesis is necessary.     

Effect of lectins on auxin-induced elongation and wall loosening in oat coleoptile and azuki bean epicotyl segments

A marine unicellular aerobic nitrogen-fixing cyanobacterium Synechococcus sp. strain Miarni BG 043511 was pretreated with different light and dark regimes in order to induce higher growth synchrony. A pretreatment of two dark and light cycles of 16 h each yielded good synchrony for 3 cell division cycles. Longer dark treatments decreased the degree of synchrony and shorter dark treatments caused irregular cell division. Once synchronous culture was established, distinct phases of cellular carbohydrate accumulation and cellular carbohydrate degradation were observed even under continuous illumination. Changes in carbohydrate content were repeated in a cyclic manner with approximately 20 h intervals, the same as the cell division cycle. This change in carbohydrate metabolism provided a good index of growth synchrony under nitrogen-fixing conditions.
Photosynthetic oxygen evolution and nitrogen fixation capabilities and their activities in near, in situ, culture conditions were measured in well synchronized cultures of this strain under continuous illumination. Distinct oscillations of both photosynthetic oxygen evolution and nitrogen fixation capabilities with ca 20-h intervals, similar to the interval of the cell division cycle, were observed for three cycles. However, the activities of photosynthetic oxygen evolution were inversely correlated with those of nitrogen fixation. During the nitrogen fixation period, net oxygen consumption was observed even in the light under conditions approximating in situ culture conditions. The phase of temporal appearance of nitrogenase activity during the cell division cycle coincided with the phase of carbohydrate net degradation. These data indicate that this unicellular cyanobacterium can grow diazotrophically under conditions of continuous illumination by the segregation of photosynthesis and nitrogen fixation within a cell division cycle.     

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.     

Regulation of nitrogenase activity in Rhodobacter capsulatus under dark microoxic conditions

Rhodobacter capsulatus modulates its in vivo nitrogenase activity in the light in response to the addition of NH4+ in a variety of ways: with ADP-ribosylation of the Fe-protein of nitrogenase, with a switch-off response that is independent of ADP-ribosylation, and with a "magnitude response." In the light, these responses are differentially shown by cultures that differ in the degree of their nitrogen limitation. Here we examined the response of these culture types to the addition of NH4+ under dark, microoxic conditions and found that all three responses can be observed under these conditions. However, the magnitude response was much more sensitive to the ammonium concentration, and the ADP-ribosylation response correlated only poorly with activity changes, similar to results obtained in the light. In contrast to previous reports, Fe-protein was not ADP-ribosylated in response to the presence of oxygen.     

Chick pineal serotonin acetyltransferase: a diurnal cycle maintained in vitro and its regulation by light.

We have reproduced in vitro the diurnal cycles in levels of serotonin acetyltransferase activity found in the chick pineal gland in vivo. The more closely the lighting conditions of culture matched those under which the birds were raised, the closer was the similarity between cycles in levels of enzyme activity in vitro and in vivo. Repetitive cycles in levels of acetyltransferase activity persisted in culture for at least 4 days under a diurnal cycle of illumination, and at least 2 days in continuous darkness. When glands were explanted into culture in the light phase of a cycle, short periods of further exposure to light markedly stimulated subsequent increase of acetyltransferase in the dark (after a short lag). Prolonged exposure to light in culture markedly inhibited increase of enzyme activity. Cycles in the levels of enzyme activity in glands cultured under altered light cycles were regulated primarily by changes in illumination. However, the endogenous biological 'clock' remained at least partly entrained to the original light cycle. Increase of acetyltransferase activity in vitro was markedly stimulated by theophylline plus compound Ro. 20.1724 (4-(3-butoxy-4-methoxybenzyl)-2-imidazolidinone) under all lighting conditions. Kinetics (to the time of attaining maximum levels in situ) of the increase under diurnal lighting and in constant darkness were indistinguishable from those in vivo. A high concentration of dl-propranolol markedly stimulated an increase in acetyltransferase activity in glands cultured in constant darkness but had little effect on glands under diurnal lighting or continuous illumination.     

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.     

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.     

Light Dependent Increase of Triosephosphate Dehydrogenase in Pea Leaves

Data from 3 lines of investigation were presented indicating that chlorophyll is not necessary for the increase in the triphosphopyridine nucleotide-requiring triosephosphate dehydrogenase accompanying the illumination of etiolated pea plants. These include A) the kinetics of the development of chlorophyll and enzyme activity, B) the presence of enzyme activity in leaves grown in the dark on normal plants and C) the high specific enzyme activity in leaves of a chlorophyll-less mutant.It was also shown that the light-initiated increase of enzyme activity continues for several days after removal from the light and that illumination with far-red light before the dark period inhibited, but did not abolish, this increase. The ability of green plants to continue to produce the enzyme in the dark was eventually lost with time, for after 7 days in the dark a stimulation in leaf protein formation was not accompanied by an increase in enzyme activity.     

Induction of a nitrogenase activity rhythm inSynechococcus and the protection of its nitrogenase against photosynthetic oxygen

All oxygen levels are detrimental to the nitrogenase activity ofSynechococcus RF-1 cells. In continuous light, cultures maintain a high dissolved oxygen concentration and a continuous but usually low rate of nitrogenase activity.Cultures adapted to a light-dark regimen will reduce acetylene almost exclusively during the dark periods. When switched to continuous light, they continue to exhibit a diurnal rhythm in nitrogenase activity. While in continuous light, each upsurge of nitrogenase activity coincides with a marked drop in the net oxygen production rate; this drop is due largely to a concomitant increase in the dark respiration rate of the culture.The endogenous nitrogenase activity rhythm can be induced in continuous light by periodically lowering the oxygen concentration of the culture by either bubbling nitrogen through it or by treating the culture with 3(3,4-dichlorophenol)-1,1-dimethylurea (DCMU or diuron).     

Response of nitrogenase to altered carbon supply in a Frankia-Alnus incana symbiosis

To study the effect of altered carbon supply on nitrogenase (EC 1.7.99.2), plants of Alnus incana (L.) Moench in symbiosis with the local source of Frankia were exposed to darkness for 2 days, and then returned to normal light/dark conditions. During the dark period nitrogenase activity in vivo (intact plants) and in vitro ( Frankia cells supplied with ATP and reductant), measured as acetylene reduction activity, was almost completely lost. Western blots for both the Fe-protein (dinitrogenase reductase) and the MoFe-protein (dinitrogenase) showed that, in particular, the amount of MoFe-protein was strongly reduced during darkness. Protein stained sodium dodecyl sulphate-polyacrylamide gels of Frankia protein showed that the nitrogenase proteins were the only abundant proteins that clearly decreased during darkness. During recovery, studied for 4 days, nitrogenase activity in vivo recovered to the level before dark treatment but was still only half of control activity, Nitrogenase activity in vitro and the amount of MoFe-protein, both expressed per Frankia protein, recovered and reached similar values in previously dark treated plants and in control plants. The rate of recovery was similar to the increase in activity of control plants, suggesting growth of Frankia in addition to synthesis of nitrogenase proteins during the recovery after carbon starvation.     

Phytochrome mediated induction of nitrate reductase activity in etiolated maize leaves

The effects of red and far-red light on the enhancement of in vitro nitrate reductase activity and on nitrate accumulation in etiolated excised maize leaves were examined. Illumination for 5 min with red light followed by a 4-h dark period caused a marked increase in nitrate reductase activity, whereas a 5-min illumination with far-red light had no effect on the enzyme activity. The effect of red light was completely reversed by a subsequent illumination with the same period of far-red light. Continuous far-red light also enhanced nitrate reductase activity. Both photoreversibility by red and far-red light and the operation of high intensity reaction under continuous far-red light indicated that the induction of nitrate reductase was mediated by phytochrome. Though nitrate accumulation was slightly enhanced by red and continuous far-red light treatments by 17% and 26% respectively, this is unlikely to account for the entire increase of nitrate reductase activity. The far-red light treatments given in water, to leaves preincubated in nitrate, enhanced nitrate reductase activity considerably over the dark control. The presence of a lag phase and inhibition of increase in enzyme activity under continuous far-red light-by tungstate and inhibitors of RNA synthesis and protein synthesis-rules out the possibility of activation of nitrate reductase and suggests de novo synthesis of the enzyme affected by phytochrome.     

Modification of dinitrogenase reductase in the cyanobacterium Anabaena variabilis due to C starvation and ammonia.

In the heterocystous cyanobacterium Anabaena variabilis, a change in nitrogenase activity and concomitant modification of dinitrogenase reductase (the Fe protein of nitrogenase) was induced either by NH4Cl at pH 10 (S. Reich and P. B?ger, FEMS Microbiol. Lett. 58:81-86, 1989) or by cessation of C supply resulting from darkness, CO2 limitation, or inhibition of photosystem II activity. Modification induced by both C limitation and NH4Cl was efficiently prevented by anaerobic conditions. Under air, endogenously stored glycogen and added fructose protected against modification triggered by C limitation but not by NH4Cl. With stored glycogen present, dark modification took place after inhibition of respiration by KCN. Reactivation of inactivated nitrogenase and concomitant demodification of dinitrogenase reductase occurred after restoration of diazotrophic growth conditions. In previously C-limited cultures, reactivation was also observed in the dark after addition of fructose (heterotrophic growth) and under anaerobiosis upon reillumination in the presence of a photosynthesis inhibitor. The results indicate that modification of dinitrogenase reductase develops as a result of decreased carbohydrate-supported reductant supply of the heterocysts caused by C limitation or by increased diversion of carbohydrates towards ammonia assimilation. Apparently, a product of N assimilation such as glutamine is not necessary for modification. The increase of oxygen concentration in the heterocysts is a plausible consequence of all treatments causing Fe protein modification.     

Rhythmic changes in ribonuclease activity in relation to nucleic acid synthesis in cotyledons ofChenopodium rubrum L. and to floral induction of the plants

Ribonuclease (RNAse) activity was investigated in cotyledons ofChenopodium rubrum plants subjected to various conditions of illumination (photoperiodic induction, continuous light, induction cancelled by interrupting the dark period by a light-break). At the end of the dark period of the single inductive cycles RNAse activity of induced plants was inferior to that of plants grown in continuous light. At the end of the first two cycles the activity was lowest after the interruption of the dark period by light. The investigation of the enzyme in 6h intervals showed rhythmic changes in activity to occur in induced plants. Enzyme activity followed a pattern opposed to this of nucleic acid (NA) synthesis in the cotyledons. In plants from continuous light the enzyme activity did not show any rhythm and in plants having obtained a light-break during the inductive period the rhythm was less distinct than in the induced ones. The period length of the endogenous rhythm of NA synthesis in the cotyledons is about half as long as this of flowering and the peaks of flowering coincide with the throughs of NA synthesis.     

Induction and modification of dinitrogenase reductase in the unicellular cyanobacterium Synechocystis BO 8402

Oxygen is an important regulatory factor of nitrogenase induced in a unicellular cyanobacterium, Synechocystis BO 8402, during nitrogen starvation. Synthesis of the enzyme is limited by the efficiency of the cells to remove oxygen by respiration, supported by hydrogenases and, in the light, by inhibition of photosynthesis. With a polyclonal antibody against dinitrogenase reductase (the Fe protein of nitrogenase) a single polypeptide is detected, indicative of an active dimeric enzyme in dense cell suspensions. Inhibition of nitrogenase by addition of oxygen is accompanied by the appearance of a second polypeptide of the Fe protein having a 1.5 kDa higher molecular weight. This disappears upon removal of oxygen from the gas phase while nitrogenase activity is restored. No protein synthesis is required indicating that a fraction of the existing polypeptides is reversibly modified in response to oxygen. After induction of nitrogenase activity in dilute culture suspensions, both forms of the Fe-protein are found in variable amounts possibly due to oxygen contamination during the experiment.Abbreviations CAM chloramphenicol - Chl chlorophyll a - CHO carbohydrates - DCMU 3,4-dichlorophenyl-1,1-dimethylurea (diuron) - kDa kilodalton - SDS sodium dodecylsulphate     

Circadian Rhythms of Enzymes' Activity in Mice Tissues During Exposure to Continuous Illumination

Activity rhythms of enzymes were determined in various tissues of C57BL/6J male mice. The determinations were carried out on mice which were kept in 14 hr light: 10 hr dark regimen, and on day 2, day 5 and day 21 during exposure to continuous illumination. Locomotor activity rhythms were followed in light: dark and up to the seventh day in constant light. All the activities exhibited a significant circadian rhythm in the light: dark regimen. During the exposure to continuous illumination, the locomotor activity exhibit a free running circadian rhythm with a consistent 24 hr and 40 min, major period component. At the same time recording the rhythms of enzyme activity; enzymes exhibited various formats of response which differed from those of the locomotor activity. The results suggest that rhythms of enzyme activity, as well as the desynchronization of the rhythms, are not enzyme specific.     

Glycogen content and nitrogenase activity in Anabaena variabilis

Nitrogenase (=acetylene-reducing activity) was followed during photoautotrophic growth of Anabaena variabilis (ATCC 29413). When cell density increased during growth, (1) inhibition of light-dependent activity by DCMU, an inhibitor of photosynthesis, increased, and (2) nitrogenase activity in the dark decreased. Addition of fructose stabilized dark activity and alleviated the DCMU effect in cultures of high cell density.The resistance of nitrogenase towards oxygen inactivation decreased after transfer of autotrophically grown cells into the dark at subsequent stages of increasing culture density. The inactivation was prevented by addition of fructose. Recovery of acetylene-reducing activity in the light, and in the dark with fructose present, was suppressed by ammonia or chloramphenicol. In the light, also DCMU abolished recovery.To prove whether the observed effects were related to a lack of photosynthetic storage products, glycogen of filaments was extracted and assayed enzymatically. The glycogen content of cells was highest 10 h after inoculation, while light-dependent nitrogenase activity was at its maximum about 24 h after inoculation. Glycogen decreased markedly as growth proceeded and dropped sharply when the cells were transferred to darkness. Thus, when C-supply (by photosynthesis or added fructose) was not effective, the glycogen content of filaments determined the activity of nitrogenase and its stability against oxygen. In cells lacking glycogen, nitrogenase activity recovered only when carbohydrates were supplied by exogenously added fructose or by photosynthesis.Abbreviations Chl chlorophyll a - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea     

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.