Photosynthetic carbon dioxide assimilation by Rhodospirillum rubrum

Summary Although Rhodospirillum rubrum, grown photoheterotrophically on malate, assimilates carbon dioxide less rapidly than it does when grown autotrophically, the difference is less marked than previously suggested.The rate of photoassimilation of carbon dioxide varies during batch culture on malate, reaching a maximum at about mid-exponential phase. It also varies with density and growth rate in a turbidostat continuous-flow culture on malate and increases with decreasing growth rate in a chemostat continuous-flow culture growing with limiting malate concentrations.The changing rates of carbon dioxide photoassimilation during photoheterotrophic growth under the various conditions are paralleled by changing activities of ribulose diphosphate carboxylase.Under conditions of maximum carbon dioxide fixation the rate by photoheterotrophic cultures approaches that shown by the bacterium growing autotrophically and is assimilated eight to ten times more slowly than is malate in chemostat cultures.The rate of carbon dioxide fixation also increases to that shown by autotrophic cells when photoheterotrophic cultures are deprived of malate, but without subjecting them to the conditions required for autotrophic growth.     

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.     

The Structure of Rhodospirillum rubrum

Cells from serial cultures of R. rubrum, grown anaerobically in the light, were harvested at intervals from ½ to 15 days and sectioned for electron microscopy by conventional methods. Cells of this species possess a multilayered outer envelope, and the external cell surface is differentiated into ridges extending parallel or obliquely to the long axis of the cell. Cells from very young cultures resemble non-photosynthetic bacteria and contain only a granular cytoplasm, scattered high-density particles, and low-density areas corresponding to the chromatin areas observed by light microscopy. They contain neither the chromatophores nor the lamellar systems assumed by previous investigators to be characteristic of this species when grown anaerobically in the light. Chromatophores appear in cells from cultures older than about 12 hours, while systems of paired lamellae appear along with the chromatophores in cells from cultures older than about 8 days. Divergent opinions concerning the occurrence of chromatophores or lamellae in this species can be resolved on the basis of the age of cultures used in previous studies. Other changes occurring in cells from cultures of increasing age include the appearance of granular and reticulate cytoplasmic bodies and vacuoles, extension of the chromatin areas, and the appearance of a single membrane enclosing several chromatophores.     

Substrate and light dependent fixation of molecular nitrogen in Rhodospirillum rubrum

Summary Whole cells of Rhodospirillum rubrum were cultivated in a malate medium lacking bound nitrogen under N₂ and tested for their nitrogenase activity by measuring the disappearance of nitrogen manometrically.Several experimental conditions were relevant in maintaining consistently high activities. These included: a) light intensity, b) substrate concentration, c) concentration of the cell suspension, d) buffer molarity, pH, and e) temperature.Under our optimal experimental conditions about 6 moles of either l-malate, fumarate, succinate or 10 moles of pyruvate were consumed per 1 mole of molecular nitrogen.The amount of gas taken up by the cells agreed quantitatively with the increase of bound nitrogen found in the cells by microkjeldahl determinations.The fixation of molecular nitrogen is suppresed quickly and specifically by very small amounts of ammonia (<5 g ammonia N/ml). The duration of this inhibition depends on the amount of ammonia available to the cells.     

Interrelationship of nitrogen fixation,hydrogen evolution and photoreduction in Rhodospirillum rubrum

Summary Rhodospirillum rubrum was grown: 1. photoheterotrophically on a medium containing dl-malate as the carbon source and ammonium chloride as the nitrogen source (medium No. 1); 2. phototrophically with N₂ and dl-malate (medium No. 2); 3. photoautotrophically with N₂, CO₂ and H₂ (medium No. 3).Resting cells derived from these cultures were tested for their ability to photoreduce CO₂, evolve H₂ and fix N₂. Only cells which were grown in medium No. 2 were able to perform all three gas exchanges. The activity pattern of gas exchanges altered in a characteristic way during the growth cycle of the bacterial culture. Cells newly transferred to medium No. 2 showed an enormous increase in the rate of H₂ evolution, which dropped sharply when all l-malate had been used up. The rate of photoreduction of CO₂ increased steadily and reached a maximum level after 120 h. The nitrogen fixing activity remained constant during the whole growth cycle.The yields of H₂ produced per mole of l-malate added were measured as a function of cell age. Only very young cultures gave appreciable yields, which dropped gradually with increasing age.The function of the carbon source is discussed as a regulating factor for photoreduction and hydrogen evolution.     

Studies in the phototaxis of Rhodospirillum rubrum

Summary The threshold strength-duration relationships were determined for the phototactic excitation of Rhodospirillum rubrum by various pulses and pairs of pulses of change in light intensity. The recovery of excitability after a response was followed, and examples of rhythmic behavior were recorded.Exprimental results were found to be in fair agreement with data for other irritable systems and with the predictions of the theories of Rashevsky and Hill.The hypothesis was considered that all excitable systems might share a common mechanism for irritability, and the phototactic mechanisms of various unicellular organisms were discussed in this connection.     

The NADP$-specific isocitrate dehydrogenase of Rhodospirillum rubrum

The NADP^$-specific isocitrate dehydrogenase was partially purifiedfrom photosynthetically-grown Rhodospirillum rubrum. The pHoptimum is between 7.5 and 9.0 in phosphate buffer. The apparentKm is 3.1x10^–5 M for isocitrate, 5.1x10^–5 M forNADP^$, 1.7x10^–5 M for manganese, 1.5x10^–4 M formagnesium, and 3.5x10^–3 M for inorganic orthophosphate.Arsenate exerts a slight inhibition. The Q₁₀ between 17.5°Cand 40°C is 1.62, and the energy of activation at 25°Cis 9.74 Kcal/mole. Glyoxylate and oxalacetate cause concertedinhibition of the enzyme activity. Various nucleotides inhibitthe activity. The kinetics of inhibition by ATP was found tobe mixed type with respect to NADP^$ and isocitrate, the K_i valuesbeing 1.17x10^–3 M and 1.10x10^–3 M respectively.The inhibition between ATP and orthophosphate is competitivewith a K_i of 10^–4M. Thiol binding reagents are inhibitory;this inhibition is reversed by cysteine or reduced glutathione. (Received October 1, 1971; )     

The early formation of the photosynthetic apparatus in Rhodospirillum rubrum

The time dependent assembly of the photosynthetic apparatus was studied in Rhodospirillum rubrum after transfer of cells growing aerobically in the dark to low aeration. While bacteriochlorophyll (Bchl) cellular levels increase continuously levels of soluble cytochrome c ₂do not change significantly. Absorption spectra of membranes isolated at different times after transfer reveal that incorporation of carotenoids lags behind incorporation of Bchl. However, a carotenoid fraction exhibiting spectral properties of spirilloxanthin isomers was isolated apart from membranes. This carotenoid fraction even was present in homogenates from Bchl-free, aerobically grown cells. Incorporation of U-¹⁴C-proteinhydrolyzate into membrane proteins showed that proteins are mainly formed which are specific for photosynthetic membranes. Although the proportion of reaction center (RC) Bchl per light harvesting (LH) Bchl does not change the proportions of membrane proteins present in RC and LH preparations change initially. But later on the proportions of the different proteins also reach constant values. Concerning proteins characteristic for cytoplasmic membranes a differential incorporation of label can be observed. The data indicate that the photosynthetic apparatus in Rhodospirillum rubrum is assembled through a sequential mechanism.Abbreviations Bchl bacteriochlorophyll - LH light harvesting - RC reaction center - R. Rhodospirillum - R. Rhodopseudomonas