Liberation of ammonia during nitrogen fixation by a facultatively heterotrophic cyanobacterium

Nitrogen fixation (acetylene reduction) and ammonia liberation were studied in a facultatively heterotrophic cyanobacterium. Autotrophically grown cells lost acetylene reduction activity when incubated under anaerobic conditions; the activity was maintained in the presence of methionine sulfoximine; or by pretreatment of the cells with a carbon supply. Heterotrophically grown cells maintained acetylene reduction activity anaerobically in the absence of methionine sulfoximine. Both cell types required light for maintenance of activity. The data indicate that methionine sulfoximine preserves the intracellular pool of reductant needed for nitrogenase. Autotrophs and heterotrophs both liberated ammonia when treated with methionine sulfoximine under nitrogen-fixing conditions. However, on treatment with methionine sulfoximine under anaerobiosis, heterotrophs also accumulated large amounts of intracellular ammonia in a pool which was diminished by the Photosystem II inhibitor, 3(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU). DCMU enhanced ammonia liberation without affecting acetylene reduction activity, and hence changed the ratio of acetylene reduced to ammonia formed by the heterotrophs. These data suggest a role for Photosystem II in ammonia liberation by the cyanobacteria.     

Role of metabolism in the chemotactic response of Rhodobacter sphaeroides to ammonia.

Rhodobacter sphaeroides only showed chemotaxis towards ammonia if grown under nitrogen-limited conditions. This chemotactic response was completely inhibited by the addition of methionine sulfoximine. There was no effect of methionine sulfoximine treatment on motility or taxis towards propionate, demonstrating that the effect is specific to ammonia taxis. It is known that methionine sulfoximine inhibits glutamine synthetase and hence blocks ammonia assimilation. Methionine sulfoximine does not inhibit ammonia transport in R. sphaeroides; therefore, these results suggest that limited metabolism via a specific pathway is required subsequent to transport to elicit a chemotactic response to ammonia. Bacteria grown on high ammonia show transport but no chemotactic response to ammonia, suggesting that the pathway of assimilation is important in eliciting a chemotactic response.     

Ca2+ and Mg2+-binding and a putative calmodulin type Ca2+-binding site in Synechococcus Photosystem II

Thylakoids and Photosystem II particles prepared from the cyanobacterium Synechococcus PCC 7942 washed with a HEPES/glycerol buffer exhibited low rates of light-induced oxygen evolution. Addition of either Ca²⁺ or Mg²⁺ to both thylakoids and Photosystem II particles increased oxygen evolution independently, maximal rates being obtained by addition of both ions. If either preparation was washed with NaCl, light induced O₂ evolution was completely inhibited, but re-activated in the same manner by Ca²⁺ and Mg²⁺ but to a lower level. In the presence of Mg²⁺, the reactivation of O₂ evolution by Ca²⁺ allowed sigmoid kinetics, implying co-operative binding. The results are interpreted as indicating that not only Ca²⁺, but also Mg²⁺, is essential for light-induced oxygen evolution in thylakoids and Photosystem II particles from Synechococcus PC 7942. The significance of the reactivation kinetics is discussed. Reactivation by Ca²⁺ was inhibited by antibodies to mammalian calmodulin, indicating that the binding site in Photosystem II may be analogous to that of this protein.Abbreviation HEPES n-2-Hydroxyethylpiperazine--2-ethane sulphonic acid     

Regulation by amino acids of photorespiratory ammonia and glycolate release from ankistrodesmus in the presence of methionine sulfoximine

Methionine sulfoximine induced release of ammonia from illuminated cells of Ankistrodesmus braunii (Naegeli) Brunnth, in normal air, but less in air enriched to 3% CO₂. In normal air, methionine sulfoximine also induced glycolate release. Addition of either glutamate, glycine, or serine suppressed glycolate release, whereas glutamate and glycine at the same time stimulated ammonia release. The results indicate that inhibition of glutamine synthetase and thereby inhibition of photorespiratory nitrogen cycling restricts the sink capacity for glycolate in the photorespiratory carbon cycle. An external supply of glutamate, glycine, or serine seems to stimulate glyoxylate transamination and thus partly restores the sink capacity. Calculations of total glycolate formation rates in air from glycolate and ammonia release rates in the presence of methionine sulfoximine and glutamate revealed values of approximately 20 micromoles glycolate per milligram chlorophyll per hour on the average. Similar calculations led to an estimated rate of photorespiratory ammonia release in air, in the absence of methionine sulfoximine, of about 10 micromoles per milligram chlorophyll per hour on the average, a value comparable to the primary nitrogen assimilation rate of 8 micromoles per milligram chlorophyll per hour.     

Interaction between ribulose 1,5-bisphosphate carboxylase/oxygenase activity and the ammonia assimilatory system of Rhodobacter sphaeroides.

The levels of form I and form II ribulose 1,5-bisphosphate carboxylase/oxygenase (RubisCO) from Rhodobacter sphaeroides were found to depend on the concentration of ammonia supplied to photolithoautotrophically grown cultures. Under conditions in which the cells rapidly depleted the available ammonia, the level of in situ RubisCO activity decreased to less than 5% maximum activity; even at its maximum level under these conditions, the RubisCO activity was only 5% of the activity obtained from cultures supplied with saturating levels of ammonia. When cells were incubated with somewhat higher but not saturating amounts of ammonia, in situ RubisCO activity decreased immediately after the cells depleted the cultures of ammonia. The decrease in activity was not due to any detectable degradation of RubisCO protein, indicative of some mechanism to regulate the activity of the enzyme in response to the intracellular levels of assimilated ammonia. Furthermore, under conditions optimum for RubisCO inactivation, in situ RubisCO activity in permeabilized whole cells greatly exceeded the levels of enzymatic activity determined in vitro in cell extracts. Blockage of ammonia assimilation by inhibition of glutamine synthetase with methionine sulfoximine prevented the recovery of form I RubisCO from pyruvate-mediated inactivation, suggesting the presence of regulatory mechanisms common to both CO2 fixation and ammonia assimilation.     

Regulation of nitrogen fixation by nitrite and glutamine in Derxia gummosa

Abstract Nitrogenase activity of cells of Derxia gummosa (30 h growth in cultures without combined nitrogen) was not inhibited on adding nitrate. However, on adding either azaserine or methionine sulfoximine (MSX) with nitrate to these cells, nitrogenase (C₂H₂ reduction) was inhibited because nitrite accumulated in the reaction mixtures. Nitrite inhibition of the in vivo C₂H₂ reduction had a K _i value of 16 μM. Both ammonia and glutamine inhibited N₂ fixation (C₂H₂ reduction) in intact cells and in those treated with toluene. This inhibition by ammonia was relieved by methionine sulfoximine but not by glutamine. Azaserine enhanced the inhibition of nitrogenase produced by either ammonia or glutamine, since these treatments resulted in an accumulation of glutamine.     

In Vivo Nitrogenase Regulation by Ammonium and Methylamine and the Effect of MSX on Ammonium Transport in Anabaena flos-aquae

Ammonium suppresses nitrogenase activity in Anabaena flos-aquae (Lyng) Breb. at all pH values tested. l-Methionine-dl-sulfoximine at 1 millimolar totally inhibited glutamine synthetase, and 10 micromolar partially inhibited. Both concentrations protected nitrogenase activity from ammonium-induced suppression at pH 7.1 and 8.1. At pH 9.3 and 10.2, methionine sulfoximine did not alleviate the suppression of nitrogenase by ammonium. This pH-dependent protection of nitrogenase activity is a result of the noncompetitive inhibition of the ammonium transporter by methionine sulfoximine. At pH 7.1 and 8.2, ammonium is protonated and methionine sulfoximine inhibits its entry into the cell. At pH 9.3 and 10.2, unprotonated ammonia is abundant and may enter the cell independent of the transport system. The effects of ammonium are closely mimicked by the ammonium analog methylamine. These results suggest that ammonium per se is an important in vivo regulator of nitrogen fixation and its function can be mimicked by methylamine. Previous studies employing methionine sulfoximine may have to be re-evaluated in light of the inhibitory effects of methionine sulfoximine on the ammonium transporter.     

Ammonium generation by nitrogen-starved cultures of Chlamydomonas reinhardii

Ammonium (NH ₄ ⁺ ) assimilation by Chlamydomonas reinhardii was inhibited when cultures were incubated with methionine sulphoximine (MSO). Methionine sulphoximine inhibited glutamine synthetase acitvity in vitro in extracts from wild-type (2192) and mutant (CC419) cultures. Mutant cultures were insensitive to MSO inhibition in vivo. Nitrogen-starved, wild-type cultures excreted ammonium when they were incubated with MSO in light or in darkness. Ammonium generation was stimulated by glutamine, inhibited by CO₂ and stoichiometrically related to loss of protein. Notrogen replete cultures treated with MSO excreted ammonium in light but little was excreted in darkness. Ammonium excretion in darkness, in the presence of MSO, was enhanced by either a period of nitrogen deprivation or by the addition of acetate. Nitrogen deprivation also diminished the lag before ammonium excretion commenced.Abbreviation MSO methionine sulphoximine     

Environmental stress inhibits the synthesis de novo of proteins involved in the photodamage-repair cycle of Photosystem II in Synechocystis sp. PCC 6803

The Photosystem II complex (PSII) is susceptible to inactivation by strong light, and the inactivation caused by strong light is referred to as photoinactivation or photoinhibition. In photosynthetic organisms, photoinactivated PSII is rapidly repaired and the extent of photoinactivation reflects the balance between the light-induced damage (photodamage) to PSII and the repair of PSII. In this study, we examined these two processes separately and quantitatively under stress conditions in the cyanobacterium Synechocystis sp. PCC 6803. The rate of photodamage was proportional to light intensity over a range of light intensities from 0 to 2000 μE m⁻² s⁻¹, and this relationship was not affected by environmental factors, such as salt stress, oxidative stress due to H₂O₂, and low temperature. The rate of repair also depended on light intensity. It was high under weak light and reached a maximum of 0.1 min⁻¹ at 300 μE m⁻² s⁻¹. By contrast to the rate of photodamage, the rate of repair was significantly reduced by the above-mentioned environmental factors. Pulse-labeling experiments with radiolabeled methionine revealed that these environmental factors inhibited the synthesis de novo of proteins. Such proteins included the D1 protein which plays an important role in the photodamage-repair cycle. These observations suggest that the repair of PSII under environmental stress might be the critical step that determines the outcome of the photodamage-repair cycle.     

Excitation energy transfer to Photosystem I in filaments and heterocysts of Nostoc punctiforme

Cyanobacteria adapt to varying light conditions by controlling the amount of excitation energy to the photosystems. On the minute time scale this leads to redirection of the excitation energy, usually referred to as state transitions, which involves movement of the phycobilisomes. We have studied short-term light adaptation in isolated heterocysts and intact filaments from the cyanobacterium Nostoc punctiforme ATCC 29133. In N.punctiforme vegetative cells differentiate into heterocysts where nitrogen fixation takes place. Photosystem II is inactivated in the heterocysts, and the abundancy of Photosystem I is increased relative to the vegetative cells. To study light-induced changes in energy transfer to Photosystem I, pre-illumination was made to dark adapted isolated heterocysts. Illumination wavelengths were chosen to excite Photosystem I (708 nm) or phycobilisomes (560 nm) specifically. In heterocysts that were pre-illuminated at 708 nm, fluorescence from the phycobilisome terminal emitter was observed in the 77 K emission spectrum. However, illumination with 560 nm light caused quenching of the emission from the terminal emitter, with a simultaneous increase in the emission at 750 nm, indicating that the 560 nm pre-illumination caused trimerization of Photosystem I. Excitation spectra showed that 560 nm pre-illumination led to an increase in excitation transfer from the phycobilisomes to trimeric Photosystem I. Illumination at 708 nm did not lead to increased energy transfer from the phycobilisome to Photosystem I compared to dark adapted samples. The measurements were repeated using intact filaments containing vegetative cells, and found to give very similar results as the heterocysts. This demonstrates that molecular events leading to increased excitation energy transfer to Photosystem I, including trimerization, are independent of Photosystem II activity.     

PROTEIN TURNOVER AND HETEROCYST DIFFERENTIATION IN THE CYANOBACTERIUM ANABAENA VARIABILIS1

Under conditions of starvation for fixed nitrogen, cells of the filamentous cyanobacterium Anabaena variabilis Kütz, degrade much of their protein prior to heterocyst differentiation. Cells starved for a source of fixed nitrogen initially degraded about 2% of their protein per hour; by 24 h after nitrogen stepdown about 40% of the protein was degraded. Most of the acid-soluble radiolabeled material was excreted into the medium. Proteolysis was completely inhibited by chloramphenicol, by cyanide, or in the dark, hut was only partially inhibited in the presence of dichlorophenyl dimethylurea. Methionine sulfoximine (MSX) (an inhibitor of glutamine synthetase) in the presence of ammonia caused heterocysts to form. MSX treated cells degraded protein; however, the amount of protein degraded was much less than in cells starved for ammonia. Glutamine, which can serve as a nitrogen source for this strain, did not prevent starvation-induced proteolysis and did not prevent the differentiation of heterocysts.     

Amino Acid Metabolism of Lemna minor L. : I. Responses to Methionine Sulfoximine

When Lemna minor L. is supplied with the potent inhibitor of glutamine synthetase, methionine sulfoximine, rapid changes in free amino acid levels occur. Glutamine, glutamate, asparagine, aspartate, alanine, and serine levels decline concomitantly with ammonia accumulation. However, not all free amino acid pools deplete in response to this inhibitor. Several free amino acids including proline, valine, leucine, isoleucine, threonine, lysine, phenylalanine, tyrosine, histidine, and methionine exhibit severalfold accumulations within 24 hours of methionine sulfoximine treatment. To investigate whether these latter amino acid accumulations result from de novo synthesis via a methionine sulfoximine insensitive pathway of ammonia assimilation (e.g. glutamate dehydrogenase) or from protein turnover, fronds of Lemna minor were prelabeled with [¹⁵N]H₄⁺ prior to supplying the inhibitor. Analyses of the ¹⁵N abundance of free amino acids suggest that protein turnover is the major source of these methionine sulfoximine induced amino acid accumulations. Thus, the pools of valine, leucine, isoleucine, proline, and threonine accumulated in response to the inhibitor in the presence of [¹⁵N]H₄⁺, are ¹⁴N enriched and are not apparently derived from ¹⁵N-labeled precursors. To account for the selective accumulation of amino acids, such as valine, leucine, isoleucine, proline, and threonine, it is necessary to envisage that these free amino acids are relatively poorly catabolized in vivo. The amino acids which deplete in response to methionine sulfoximine (i.e. glutamate, glutamine, alanine, aspartate, asparagine, and serine) are all presumably rapidly catabolized to ammonia, either in the photorespiratory pathway or by alternative routes.     

Turnover of the D1 protein and of Photosystem II in a Synechocystis 6803 mutant lacking Tyrz

The Photosystem II reaction center is rapidly inactivated by light, particularly at higher light intensity. One of the possible factors causing this phenomenon is the oxidized primary donor, P680⁺, which may be harmful to Photosystem II because of its highly oxidizing nature. However, no direct evidence specificially implicating P680⁺ in photoinhibition has been obtained yet. To investigate whether P680⁺ is harmful to Photosystem II, turnover of the D1 protein and of the Photosystem II reaction center complex were measured in vivo in a mutant of the cyanobacterium Synechocystis sp. PCC 6803, in which the physiological donor to P680⁺, Tyr_z, was genetically deleted. In this mutant, D1 degradation in the light is an order of magnitude faster than in wild type. The most straightforward explanation of this phenomenon is that accumulation of P680⁺ leads to an increased rate of turnover of the Photosystem II reaction center complex, which is compatible with the hypothesis of destructive oxidation by P680⁺ that is damaging to the Photosystem II complex.     

A study of the role of glutamate dehydrogenase in the nitrogen metabolism of Arabidopsis thaliana

Glutamate-dehydrogenase (GDH, EC 1.4.1.2) activity and isoenzyme patterns were investigated in Arabidopsis thaliana plantlets, and parallel studies were carried out on glutamine synthetase (GS, EC 6.3.1.2). Both NADH-GDH and NAD-GDH activities increased during plant development whereas GS activity declined. Leaves deprived of light showed a considerable enhancement of NADH-GDH activity. In roots, both GDH activities were induced by ammonia whereas in leaves nitrogen assimilation was less important. It was demonstrated that the increase in GDH activity was the result of de-novo protein synthesis. High nitrogen levels were first assimilated by NADH-GDH, while GS was actively involved in nitrogen metabolism only when the enzyme was stimulated by a supply of energy, generated by NAD-GDH or by feeding sucrose. When methionine sulfoximine, an inhibitor of GS, was added to the feeding solution, NADH-GDH activity remained unaffected in leaves whereas NAD-GDH was induced. In roots, however, there was a marked activation of GDH and no inactivation of GS. It was concluded that NADH-GDH was involved in the detoxification of high nitrogen levels while NAD-GDH was mainly responsible for the supply of energy to the cell during active assimilation. Glutamine synthetase, on the other hand was involved in the assimilation of physiological amounts of nitrogen. A study of the isoenzyme pattern of GDH indicated that a good correlation existed between the relative activity of the isoenzymes and the ratio of aminating to deaminating enzyme activities. The NADH-GDH activity corresponded to the more anodal isoenzymes while the NAD-GDH activity corresponded to the cathodal ones. The results indicate that the two genes involved in the formation of GDH control the expression of enzymes with different metabolic functions.Abbreviations GDH glutamate dehydrogenase - GS glutamine synthetase - MSO methionine sulfoximine     

Amino Acid metabolism in pea leaves : utilization of nitrogen from amide and amino groups of [N]asparagine

The flow of nitrogen from the amino and amide groups of asparagine has been followed in young pea (Pisum sativum CV Little Marvel) leaves, supplied through the xylem with ¹⁵N-labeled asparagine. The results confirm that there are two main routes for asparagine metabolism: deamidation and transamination.

Nitrogen from the amide group is found predominantly in 2-hydroxy-succinamic acid (derived from transamination of asparagine) and in the amide group of glutamine. The amide nitrogen is also found in glutamate and dispersed through a range of amino acids. Transfer to glutamineamide results from assimilation of ammonia produced by deamidation of both asparagine and its transamination products: this assimilation is blocked by methionine sulfoximine. The release of amide nitrogen as ammonia is greatly reduced by aminooxyacetate, suggesting that, for much of the metabolized asparagine, transamination precedes deamidation.

The amino group of asparagine is widely distributed in amino acids, especially aspartate, glutamate, alanine, and homoserine. For homoserine, a comparison of N and C labeling, and use of a transaminase inhibitor, suggests that it is not produced from the main pool of aspartate, and transamination may play a role in the accumulation of homoserine in peas.

     

A polarographic study of glutamate synthase activity in isolated chloroplasts

Illuminated pea (Pisum sativum) chloroplasts actively catalyzed (glutamine plus alpha-ketoglutarate)-dependent O(2) evolution (average of 12 preparations 10.6 mumole mg chlorophyll per hour). The reaction was specific for glutamine and alpha-ketoglutarate; concentrations of 0.2 mm alpha-ketoglutarate and 0.6 mm glutamine, respectively, effected half-maximum rates of O(2) evolution. The reaction was inhibited by 3-(3,4-dichlorophenyl)-1-1-dimethylurea and did not occur in the dark. After osmotic shock chloroplasts did not catalyze O(2) evolution. The reaction was inhibited by azaserine and glutamate but not by 10 mm ammonia, 2.5 mm methionine sulfoximine, or 5 mm amino-oxyacetate; addition of amino-oxyacetate together with aspartate inhibited O(2) evolution. Arsenate (3 mm) enhanced O(2) evolution. The highest molar ratio for O(2) evolved per mole of alpha-ketoglutarate supplied was 0.40; the corresponding values for glutamine in the absence and presence of 3 mm arsenate were 0.20 and 0.24, respectively. The (glutamine plus alpha-ketoglutarate)-dependent O(2) evolution is attributed to photosynthetically coupled glutamate synthase activity and the activity is sufficient to account for the assimilation of inorganic nitrogen. The low molar ratio for glutamine is discussed.Chloroplasts also catalyzed (aspartate plus alpha-ketoglutarate)-dependent O(2) evolution but this reaction was inhibited by 5 mm amino-oxyacetate and it was insensitive to azaserine and methionine sulfoximine. This reaction was attributed to transaminase and photosynthetically coupled malate dehydrogenase activities.     

Ammonia assimilation and metabolism byBeggiatoa alba

Beggiatoa alba B18LD was investigated for its pathways of ammonia assimilation. The increase in growth yields ofB. alba with excess acetate was linear from 0.1 to 2.0 mM ammonia.B. alba had strong glutamine synthetase (GS) and glutamate synthase (GOGAT) activities, irrespective of the ammonia concentration in the medium. Glutamate dehydrogenase activity was not found, and alanine dehydrogenase (aminating) was observed only whenB. alba was grown at high (2.0 mM) ammonia. Methionine sulfoximine, an inhibitor of GS, inhibited growth ofB. alba irrespective of the ammonia concentration in the medium. Thus it appears the primary pathway for ammonia assimilation inB. alba is via the GS-GOGAT pathway at both low and high ammonia concentrations. Preliminary experiments were unable to discern if theB. alba GS is modified by covalent modification.Non-standard abbreviations GS Glutamine synthetase - GOGAT glutamate-oxoglutarate aminotransferase - GDH glutamate dehydrogenase - ADH alanine dehydrogenase - MSX methionine sulfoximine - GOT glutamate-oxaloacetate aminotransferase - GPT glutamate-pyruvate aminotransferase     

Nitrogen starvation-induced chlorosis in Synechococcus PCC 7942. Low-level photosynthesis as a mechanism of long-term survival

Cells of the non-diazotrophic cyanobacterium Synechococcus sp. strain PCC 7942 acclimate to nitrogen deprivation by differentiating into non-pigmented resting cells, which are able to survive prolonged periods of starvation. In this study, the physiological properties of the long-term nitrogen-starved cells are investigated in an attempt to elucidate the mechanisms of maintenance of viability. Preservation of energetic homeostasis is based on a low level of residual photosynthesis; activities of photosystem II and photosystem I were approximately 0.1% of activities of vegetatively growing cells. The low levels of photosystem I activity were measured by a novel colorimetric assay developed from the activity staining of ferredoxin:NADP+ oxidoreductase. Photosystem II reaction centers, as determined by chlorophyll fluorescence measurements, exhibited normal properties, although the efficiency of light harvesting was significantly reduced compared with that of control cells. Long-term chlorotic cells carried out protein synthesis at a very low, but detectable level, as revealed by in vivo [35S]methionine labeling and two-dimensional gel electrophoresis. In conjunction with the very low levels of total cellular protein contents, this implies a continuous protein turnover during chlorosis. Synthesis of components of the photosynthetic apparatus could be detected, whereas factors of the translational machinery were stringently down-regulated. Beyond the massive loss of protein during acclimation to nitrogen deprivation, two proteins that were identified as SomA and SomB accumulated due to an induced expression following nitrogen reduction.     

Genomic investigation of the system for selenocysteine incorporation in the bacterial domain

The Photosystem II complex (PSII) is susceptible to inactivation by strong light, and the inactivation caused by strong light is referred to as photoinactivation or photoinhibition. In photosynthetic organisms, photoinactivated PSII is rapidly repaired and the extent of photoinactivation reflects the balance between the light-induced damage (photodamage) to PSII and the repair of PSII. In this study, we examined these two processes separately and quantitatively under stress conditions in the cyanobacterium Synechocystis sp. PCC 6803. The rate of photodamage was proportional to light intensity over a range of light intensities from 0 to 2000 microE m(-2) s(-1), and this relationship was not affected by environmental factors, such as salt stress, oxidative stress due to H2O2, and low temperature. The rate of repair also depended on light intensity. It was high under weak light and reached a maximum of 0.1 min(-1) at 300 microE m(-2) s(-1). By contrast to the rate of photodamage, the rate of repair was significantly reduced by the above-mentioned environmental factors. Pulse-labeling experiments with radiolabeled methionine revealed that these environmental factors inhibited the synthesis de novo of proteins. Such proteins included the D1 protein which plays an important role in the photodamage-repair cycle. These observations suggest that the repair of PSII under environmental stress might be the critical step that determines the outcome of the photodamage-repair cycle.     

Oxidation and reduction of plastoquinone by photosynthetic and respiratory electron transport in a cyanobacterium Synechococcus sp.

The I-D dip, an early transient of the fluorescence induction, was examined as a means to monitor redox changes of plastoquinone in cells of a cyanobacterium, Synechococcus sp. That the occurrence of the dip depends upon the reduced state of the plastoquinone pool was indicated by observations that 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone and 3-(3,4-dichlorophenyl)-1,1-dimethylurea did not affect the initial rise to I but abolished the subsequent decline from I to D and that illumination of the cells with light 1, prior to fluorescence measurements, eliminated the transient. The I-D dip was prominent in freshly harvested cells containing abundant endogenous substrates, disappeared slowly as the cells were starved by aeration but reappeared on addition of fructose to the starved cells in the dark. The dip that had been induced by a brief illumination of the starved cells with light 2 was rapidly diminished in the dark and KCN inhibited the dark decay of the transient. The results indicate that plastoquinone is reduced with endogenous as well as exogenous substrates and oxidized by a KCN-sensitive oxidase in the dark, thus providing strong support for the view that plastoquinone of photosynthetic electron transport also functions in respiration. In addition, the occurrence of a cyclic pathway of electrons from Photosystem I to plastoquinone, possibly via ferredoxin or NADP, was suggested. Several lines of evidence indicate that, under a strong light 2, Photosystem I-dependent oxidation of plastoquinone predominates over Photosystem II-dependent reduction of the quinone in the cyanobacterium which contains Photosystem I more abundantly than Photosystem II.