[The mechanism of acetate assimilation in purple nonsulfur bacteria lacking the glyoxylate pathway: acetate assimilation in Rhodobacter sphaeroides cells].

The mechanism of acetate assimilation in the purple nonsulfur bacterium Rhodobacter sphaeroides, which lacks the glyoxylate pathway, is studied. It is found that the growth of this bacterium in batch and continuous cultures and the assimilation of acetate in cell suspensions are not stimulated by bicarbonate. The consumption of acetate is accompanied by the excretion of glyoxylate and pyruvate into the medium, stimulated by glyoxylate and pyruvate, and inhibited by citramalate. The respiration of cells in the presence of acetate is stimulated by glyoxylate, pyruvate, citramalate, and mesaconate. These data suggest that the citramalate cycle may function in Rba. sphaeroides in the form of an anaplerotic pathway instead of the glyoxylate pathway. At the same time, the low ratio of fixation rates for bicarbonate and acetate exhibited by the Rba. sphaeroides cells (approximately 0.1), as well as the absence of the stimulatory effect of acetate on the fixation of bicarbonate in the presence of the Calvin cycle inhibitor iodoacetate, suggests that pyruvate synthase is not involved in acetate assimilation in the bacterium Rba. sphaeroides.

The dependence of algal H2 production on Photosystem II and O2 consumption activities in sulfur-deprived Chlamydomonas reinhardtii cells.

Chlamydomonas reinhardtii cultures, deprived of inorganic sulfur, undergo dramatic changes during adaptation to the nutrient stress [Biotechnol. Bioeng. 78 (2002) 731]. When the capacity for Photosystem II (PSII) O(2) evolution decreases below that of respiration, the culture becomes anaerobic [Plant Physiol. 122 (2000) 127]. We demonstrate that (a) the photochemical activity of PSII, monitored by in situ fluorescence, also decreases slowly during the aerobic period; (b) at the exact time of anaerobiosis, the remaining PSII activity is rapidly down regulated; and (c) electron transfer from PSII to PSI abruptly decreases at that point. Shortly thereafter, the PSII photochemical activity is partially restored, and H(2) production starts. Hydrogen production, which lasts for 3-4 days, is catalyzed by an anaerobically induced, reversible hydrogenase. While most of the reductants used directly for H(2) gas photoproduction come from water, the remaining electrons must come from endogenous substrate degradation through the NAD(P)H plastoquinone (PQ) oxido-reductase pathway. We propose that the induced hydrogenase activity provides a sink for electrons in the absence of other alternative pathways, and its operation allows the partial oxidation of intermediate photosynthetic carriers, including the PQ pool, between PSII and PSI. We conclude that the reduced state of this pool, which controls PSII photochemical activity, is one of the main factors regulating H(2) production under sulfur-deprived conditions. Residual O(2) evolved under these conditions is probably consumed mostly by the aerobic oxidation of storage products linked to mitochondrial respiratory processes involving both the cytochrome oxidase and the alternative oxidase. These functions maintain the intracellular anaerobic conditions required to keep the hydrogenase enzyme in the active, induced form.

[Role of hydrogenases 1 and 2 in the hydrogen dependent nitrate respiration by Escherichia coli]. / Uchastie gidrogenazy 1 i gidrogenazy 2 v vodorodzavisimom nitratnom dykhanii u Escherichia coli.

The study of Escherichia coli mutants synthesizing either hydrogenase 1 (HDK203) or hydrogenase 2 (HDK103) showed that the nitrate-dependent uptake of hydrogen by E. coli cells can be accomplished through the action of either of these hydrogenases. The capability of the cells for hydrogen-dependent nitrate respiration was found to be dependent on the growth conditions. E. coli cells grown anaerobically without nitrate in the presence of glucose were potentially capable of nitrate-dependent hydrogen consumption. The cells grown anaerobically in the presence of nitrate exhibited a much lower capability for nitrate-dependent hydrogen consumption. The inhibitory effect of nitrate on this capability of bacterial cells was either weak (the mutant HDK203) or almost absent (the mutant HDK103) when the cells were grown in the presence of peptone and hydrogen. Hydrogen stimulated the growth of the wild-type strain and the mutant HDK103 (but not the mutant HDK203) cultivated in the medium with nitrate and peptone. These data suggest that hydrogenase 2 is much more active in catalyzing the nitrate-dependent hydrogen consumption than is hydrogenase 1.

H2 consumption by Escherichia coli coupled via hydrogenase 1 or hydrogenase 2 to different terminal electron acceptors.

Hydrogen uptake in the presence of various terminal electron acceptors was examined in Escherichia coli mutants synthesizing either hydrogenase 1 or hydrogenase 2. Both hydrogenases mediated nitrate-dependent H2 consumption but neither of them was coupled with nitrite. Unlike hydrogenase 2, hydrogenase 1 demonstrated poor activity with electron acceptors of low midpoint redox potential. Oxygen-linked H2 uptake via hydrogenase 1 was observed over a wide range of air concentrations. Hydrogenase 2 catalyzed this reaction only at low air concentrations. Thus, hydrogenase 1 works in cells at higher redox potential, being more tolerant to oxygen than hydrogenase 2.

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.

Effect of O2, H2 and redox potential on the activity and synthesis of hydrogenase 2 in Escherichia coli.

The aim of this work was to study the influence of O2 with special emphasis on low oxygen tension, the effect of H2 under various conditions of oxygen tension and the influence of the redox potential in the growth medium on hydrogenase 2 of Escherichia coli. The hydrogenase activity and the content of the large (HybC) and small (HybO) subunits of hydrogenase 2 were compared during turbidostat cultivation in a wild strain and mutant HDK103 lacking hydrogenases 1 and 3. No hydrogenase 2 activity in the mutant HDK103 was observed under aerobic conditions, but it was maximal under anaerobic conditions and half-maximal at an oxygen tension of approximately 4 mbar as is common for enzymes of anaerobic respiration. The content of hydrogenase 2 in both the strains was maximal under anaerobic conditions. In the wild strain, H2 addition enhanced hydrogenase activity and the HybO content under microaerobic conditions only. Under anaerobic conditions endogenous H2 production hindered this effect. Under aerobic conditions, the 02-related negative effect seemed to dominate over the H2-related positive effect. By contrast, in the mutant HDK103, hydrogen influenced neither hydrogenase 2 activity nor its content. A possible role of hydrogenase I in the response of hydrogenase 2 to hydrogen is discussed. Under conditions of different O2 tension, hydrogenase activity in both strains correlated inversely with the value of the redox potential of the medium. The presence of H2 changed this dependence. Thus, the value of the redox potential itself is not a controlling factor for hydrogenase 2.

The presence of ADP-ribosylated Fe protein of nitrogenase in Rhodobacter capsulatus is correlated with cellular nitrogen status.

The photosynthetic bacterium Rhodobacter capsulatus has been shown to regulate its nitrogenase by covalent modification via the reversible ADP-ribosylation of Fe protein in response to darkness or the addition of external NH4+. Here we demonstrate the presence of ADP-ribosylated Fe protein under a variety of steady-state growth conditions. We examined the modification of Fe protein and nitrogenase activity under three different growth conditions that establish different levels of cellular nitrogen: batch growth with limiting NH4+, where the nitrogen status is externally controlled; batch growth on relatively poor nitrogen sources, where the nitrogen status is internally controlled by assimilatory processes; and continuous culture. When cultures were grown to stationary phase with different limiting concentrations of NH4+, the ADP-ribosylation state of Fe protein was found to correlate with cellular nitrogen status. Additionally, actively growing cultures (grown with N2 or glutamate), which had an intermediate cellular nitrogen status, contained a portion of their Fe protein in the modified state. The correlation between cellular nitrogen status and ADP-ribosylation state was corroborated with continuous cultures grown under various degrees of nitrogen limitation. These results show that in R. capsulatus the modification system that ADP-ribosylates nitrogenase in the short term in response to abrupt changes in the environment is also capable of modifying nitrogenase in accordance with long-term cellular conditions.

Influence of the degree and mode of light limitation on growth characteristics of the Rhodobacter capsulatus continuous cultures.

The influence of the degree and mode of light limitation on growth characteristics of turbidostat cultures of Rhodobacter capsulatus was investigated using mass and energy balance regularities. Light limitation was achieved by increasing the steady-state biomass concentration at constant incident light intensity ( approximately 100 W/m(2)) or by decreasing the incident light intensity at constant steady-state biomass concentration ( approximately 500 mg of dry biomass/L). It was shown that under conditions of light limitation of Rh. capsulatus, the content of P and N in the biomass as well as the biomass degree of reduction were determined by the growth rate of the cultures. The energetic yield of biomass of Rh. capsulatus and total bacteriochlorophyll a content increased when light limitation increased. These parameters were higher in the cultures, in which light limitation was achieved by lowering the incident light intensity at low biomass concentration. This seems to be due to different distribution of light within the photobioreactor when dissimilar modes of light limitation were used.

[Low potential c-type cytochrome of Thiocapsa roseopersicina]. / Nizkopotentsial'nyi tsitokhrom tipa c Thiocapsa roseopersicina.

The low potential c-type cytochrome from the phototrophic purple sulphur bacterium Thiocapsa roseopersicina, strain BBS was isolated in electrophoretically homogeneous state. The bulk of the cytochrome (approximately 90%) after disruption of the cells remained in the membrane fraction. The absorption spectrum of the cytochrome was characterized by the maxima at 420, 523 and 552 nm in the reduced state and at 408 nm in the oxidized one. The cytochrome interacted with CO in the reduced state. The molecular weight of the cytochrome is 50 000. The cytochrome contains great amounts of phenylalanine, leucine, valine, aspartic and glutamic acids and can be reduced by dithionite but not by cysteine, sulfide or ascorbate. Besides, the cytochrome can also be reduced by NAD(P)H in the presence of NAD(P)-reductases of T. roseopersicina, when ferredoxin of Spirulina platensis or benzyl viologen are added to the reaction mixture. The cytochrome can act as an electron donor (acceptor) for T. roseopersicina hydrogenase.

[Comparative study of NADP-reductase properties in two species of purple bacteria]. / Sravnenie svoist' NADP-reduktazy u dvukh vidow purpurnykh bakterii.

Unlike Rhodospirillum rubrum, the highly purified preparations of NADP-reductase Thiocapsa roseopersicina are capable of reduction of cytochrome c though they do not catalyse diaphorase reaction in the presence of methyl viologen or benzyl viologen and NADH. T. roseopersicina reductase has more high temperature optimum (50-65 degrees) and more high thermal stability (65 degrees) and it is capable to catalyse diaphorase and menadione-reductase reactions under more high pH values (11.0-12.0) than NADP-reductase of R. rubrum. NADP-reductase of T. roseopersicina is more stable under storing than the enzyme from R. rubrum: the semi-inactivation period of the enzyme when storing in Ar or the air is about 10 and 4 days, respectively, and it takes about three days for R. rubrum.

[Purification and properties of NADP-reductase of phototropic bacteria Thiocapsa roseopersicina]. / Ochistka i svoistva NADP-reduktazy iz fototrofnoi bakterii Thiocapsa roseoppersicina.

The method of purification up to homogenous states and properties of NADP-reductase of purple bacteria Thiocapsa roseopersicina, strain BBS, are described. The molecular weight of NADP-reductase is about 47 000; it is flavoprotein consisting of two subunits. Atebrim and chloromercury bensoate inhibit the activity of NADP-reductase (34% and 33--60%, respectively). The enzyme is specific to NADPH; it catalyzes menadion-reductase reaction, diaphorase reaction of benzyl viologen reduction, oxidation of reduced benzyl viologen in the presence of NADP, reduction of ferredoxin and cytochrome c in the presence of NADPH, but it is not capable to catalyze transhydrogenase reaction.

[Purification and properties of Rhodospirillum rubrum NADP-reductase]. / Ochistka i svoistva NADP-reduktazy iz Rhodospirillum rubrum

Rhodospirillum rubrum cell extracts have active NADP-reductase capable of catalyzing the diaphorase reaction in the presence of methyl viologene or benzyl viologene and NADPH-generating system. The greater part of NADP-reductase is localized in the soluble fraction of destroyed cells (90-10(3) g; 90 min). The purified preparation of NADP-reductase was found to contain 6 proteins, 4-5 of them possessing diaphorase activity. Partially purified NADP-reductase preparation with a period of half-inactivation of about two days has a molecular weight of 95 000 and absorption spectrum, characterized by two maxima at 410 and 430 nm. NADP-reductase preparation possesses also menadione-reductase activity, but showed no ability for transhydrogenase reaction and reduction of cytochrome c.

[Role of ferredoxin in the metabolism of hydrogen by Rhodospirillum rubrum]. / Rol' ferredoksina v metabolizme vodoroda u Rhodospirillum rubrum

Ferredoxin was purified after isolation from the cells of Rhodospirillum rubrum grown under photoheterotrophic conditions; A385/A280 in the absorption spectrum was not less than 0.53; the molecular weight was ca. 7700; E0' (pH 7.0)--430 mv. Ferredoxin was easily reduced in the presence of dithionite and provided a high rate of NADP reduction by pea chloroplasts. The extracts of R. rubrum containing ferredoxin or the extracts, to which it was added, reduced NAD in the presence of hydrogen and evolved H2 in the presence of NAD(P)H. ATP or light were required for the evolution of H2 from NAD(P)H.