Ubiquinone 10 formation in Rhodospirillum rubrum under different culture conditions

The formation of ubiquinone 10 and bacteriochlorophyll (bchl) was determined in Rhodospirillum rubrum grown under different culture conditions. Transfer of chemotrophically grown cultures to photosynthetic conditions leads to the formation of the pigments until cells reach the stationary phase of growth. Bchl-synthesis initially exceeds quinone synthesis. On a cellular protein basis quinone levels first decrease by about a factor of two and subsequently increase by a factor of four. Bchl levels per protein increase until cells reach the stationary phase of growth. Quinone levels per bchl decrease rather rapidly and become constant in the growing culture. When cells were transferred under continuous phototrophic conditions to new culture medium, both pigments are formed concomitantly. While protein synthesis starts immediately, bchl and ubiquinone formation is slightly delayed. This causes a short time decrease in the amount of both pigments per cellular protein followed by an increase to a constant level. Ratios of ubiquinone per bchl are constant. The transfer of phototrophically grown cultures to chemotrophic conditions results in a complete inhibition of bchl formation while quinone synthesis resumes. Quinone cellular levels decrease slightly and then remain constant. Quinone values increase per bchl which is eventually diluted out of the cells.     

Evidence for three distinct hydrogenase activities in Rhodospirillum rubrum

Inducer, inhibitor, and mutant studies on three hydrogenase activities of Rhodospirillum rubrum indicate that they are mediated by three distinct hydrogenase enzymes. Uptake hydrogenase mediates H2 uptake to an unknown physiological acceptor or methylene blue and is maximally synthesized during autotrophic growth in light. Formate-linked hydrogenase is synthesized primarily during growth in darkness or when light becomes limiting, and links formate oxidation to H2 production. Carbon-monoxide-linked hydrogenase is induced whenever CO is present and couples CO oxidation to H2 evolution. The enzymes can be expressed singly or conjointly depending on growth conditions, and the inhibitor or inducer added. All three hydrogenases can use methyl viologen as the mediator for both the H2 evolution and H2 uptake reactions while displaying distinct pH optima, reversibility, and sensitivity to C2H2 gas. Yet, we present evidence that the CO-linked hydrogenase, unlike the uptake hydrogenase, does not link to methylene blue as the electron acceptor. These differences allow conditions to be established to quantitatively assay each hydrogenase independently of the others both in vivo and in vitro.     

Evidence for a ligand CO that is required for catalytic activity of CO dehydrogenase from Rhodospirillum rubrum

Radiolabeling studies support the existence of a nonsubstrate CO ligand (CO(L)) to the Fe atom of the proposed [FeNi] cluster of carbon monoxide dehydrogenase (CODH) from Rhodospirillum rubrum. Purified CODH has variable amounts of CO(L) dissociated depending on the extent of handling of the proteins. This dissociated CO(L) can be restored by incubation of CODH with CO, resulting in a 30-40% increase in initial activity relative to as-isolated purified CODH. A similar amount of CO(L) binding is observed when as-isolated purified CODH is incubated with (14)CO: approximately 0.33 mol of CO binds per 1 mol of CODH. Approximately 1 mol of CO was released from CO-preincubated CODH upon denaturation of the protein. No CO could be detected upon denaturation of CODH that had been incubated with cyanide. CO(L) binds to both Ni-containing and Ni-deficient CODH, indicating that CO(L) is liganded to the Fe atom of the proposed [FeNi] center. Furthermore, the Ni in the CO(L)-deficient CODH can be removed by treatment with a Ni-specific chelator, dimethylglyoxime. CO preincubation protects the dimethylglyoxime-labile Ni, indicating that CO(L) is also involved in the stability of Ni in the proposed [FeNi] center.     

Biosynthesis of Phenylalanine from Phenylacetate by Chromatium and Rhodospirillum rubrum

Cultures of Chromatium strain D and Rhodospirillum rubrum incorporated ¹⁴C from phenylacetate-1-¹⁴C during anaerobic growth. The radioactivity in the protein fraction of cells was mainly in phenylalanine. Phenylalanine from Chromatium cells grown in phenylacetate-1-¹⁴C was labeled at carbon 2. Incorporation of phenylacetate by Chromatium was decreased in the presence of exogenous phenylalanine, and de novo synthesis of phenylalanine from bicarbonate was less in medium containing either phenylalanine or phenylacetate. These organisms, and also certain anaerobic rumen bacteria, apparently carboxylate phenylacetate to synthesize the phenylalanine carbon skeleton. The mechanism of the carboxylation is unknown; however, it appears to be dependent upon anaerobic conditions, since R. rubrum did not synthesize phenylalanine from phenylacetate during aerobic growth in the dark.     

Tam41 Is a CDP-Diacylglycerol Synthase Required for Cardiolipin Biosynthesis in Mitochondria

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Evidence of tyrosine kinase activity in the photosynthetic bacterium Rhodospirillum rubrum

The photosynthetic bacterium Rohodospirillum rubrum evidenced tyrosine protein phosphorylation under photoautotrophic conditions in the presence of [32P]Pi. The stability to alkaline treatment of the [32P] bound to the cell-free extract proteins suggested that tyrosine residues were carrying the labelling. One- and two-dimensional high voltage paper electrophoresis analysis revealed that such extracts do contain [32P]-phosphotyrosine residues. Furthermore, the association of alkali stable [32P] bound to specific proteins of the cell-free extract was confirmed by sodium dodecyl sulfate polyacrylamide gel electrophoresis combined with KOH treatment of the gel. A definite argument in favor of protein kinase(s) phosphorylating tyrosine residues in R.rubrum proteins was obtained by partial purification of a tyrosine kinase activity from cell-free extract capable of phosphorylating synthetic peptides that only contain a single tyrosine residue as phosphate acceptor.     

Ferredoxin-dependent carbon assimilation in Rhodospirillum rubrum

Summary Evidence has been presented that a soluble fraction from R. rubrum cells contains two new primary carboxylation reactions which depend on the reducing power of ferredoxin: (a) pyruvate synthase which brings about a synthesis of pyruvate from acetyl-CoA and CO₂ and (b) -ketoglutarate synthase which brings about a synthesis of -ketoglutarate from succinyl-CoA and CO₂. The soluble fraction of R. rubrum cells contains also a series of other enzymes which, together with the ferredoxin-dependent enzymes, constitutes a reductive carboxylic acid cycle—a new cyclic pathway for CO₂ assimilation that was first found in the photosynthetic bacterium, Chlorobium thiosulfatophilum.Dedicated to C. B. van Niel on the occasion of his 70th birthday.Aided by grants from the National Institute of General Medical Sciences, Office of Naval Research and the National Science Foundation.     

Evidence for monomeric bacteriochlorophyll in P800 of the photoreaction center from Rhodospirillum rubrum.

To find out whether weak or strong coupling exists between the bacteriochlorophyll molecules of the photoreaction center, the relative efficiency of energy transfer to P870 was measured at 795 nm and at 808 nm, at room temperature and at 77 degrees K. At room temperature, both relative efficiencies are close to 100%. However, at 77 degrees K, 795 nm light has a quantum efficiency of 76% and 808 nm light has an efficiency of 87%. These results confirm the fact that P800 is formed of at least one short wavelength component and one long wavelength component. Moreover, the short wavelength component is weakly coupled to both P870 and to the long wavelength component of P800. The conclusion is that the short wavelength component is due to monomeric bacteriochlorophyll. By comparison with other data, all four bacteriochlorophyll molecules of the photoreaction center are inferred to be monomeric.     

Microaerophilic Cooperation of Reductive and Oxidative Pathways Allows Maximal Photosynthetic Membrane Biosynthesis in Rhodospirillum rubrum

The purple nonsulfur bacterium Rhodospirillum rubrum has been employed to study physiological adaptation to limiting oxygen tensions (microaerophilic conditions). R. rubrum produces maximal levels of photosynthetic membranes when grown with both succinate and fructose as carbon sources under microaerophilic conditions in comparison to the level (only about 20% of the maximum) seen in the absence of fructose. Employing a unique partial O₂ pressure (pO₂) control strategy to reliably adjust the oxygen tension to values below 0.5%, we have used bioreactor cultures to investigate the metabolic rationale for this effect. A metabolic profile of the central carbon metabolism of these cultures was obtained by determination of key enzyme activities under microaerophilic as well as aerobic and anaerobic phototrophic conditions. Under aerobic conditions succinate and fructose were consumed simultaneously, whereas oxygen-limiting conditions provoked the preferential breakdown of fructose. Fructose was utilized via the Embden-Meyerhof-Parnas pathway. High levels of pyrophosphate-dependent phosphofructokinase activity were found to be specific for oxygen-limited cultures. No glucose-6-phosphate dehydrogenase activity was detected under any conditions. We demonstrate that NADPH is supplied mainly by the pyridine-nucleotide transhydrogenase under oxygen-limiting conditions. The tricarboxylic acid cycle enzymes are present at significant levels during microaerophilic growth, albeit at lower levels than those seen under fully aerobic growth conditions. Levels of the reductive tricarboxylic acid cycle marker enzyme fumarate reductase were also high under microaerophilic conditions. We propose a model by which the primary “switching” of oxidative and reductive metabolism is performed at the level of the tricarboxylic acid cycle and suggest how this might affect redox signaling and gene expression in R. rubrum.     

Role of Genetic Redundancy in Polyhydroxyalkanoate (PHA) Polymerases in PHA Biosynthesis in Rhodospirillum rubrum

This study investigated the apparent genetic redundancy in the biosynthesis of polyhydroxyalkanoates (PHAs) in the Rhodospirillum rubrum genome revealed by the occurrence of three homologous PHA polymerase genes (phaC1, phaC2, and phaC3). In vitro biochemical assays established that each gene product encodes PHA polymerase. A series of single, double, and triple phaC deletion mutants were characterized with respect to PHA production and growth capabilities on acetate or hexanoate as the sole carbon source. These analyses establish that phaC2 contributes the major capacity to produce PHA, even though the PhaC2 protein is not the most efficient PHA polymerase biocatalyst. In contrast, phaC3 is an insignificant contributor to PHA productivity, and phaC1, the PHA polymerase situated in the PHA biosynthetic operon, plays a minor role in this capability, even though both of these genes encode PHA polymerases that are more efficient enzymes. These observations are consistent with the finding that PhaC1 and PhaC3 occur at undetectable levels, at least 10-fold lower than that of PhaC2. The monomers in the PHA polymer produced by these strains establish that PhaC2 is responsible for the incorporation of the C₅ and C₆ monomers. The in vitro characterizations indicate that heteromeric PHA polymerases composed of mixtures of different PhaC paralogs are more efficient catalysts, suggesting that these proteins form complexes. Finally, the physiological role of PHA accumulation in enhancing the fitness of R. rubrum was indicated by the relationship between PHA content and growth capabilities of the genetically manipulated strains that express different levels of the PHA polymer.