Studies of pigments and growth in Chloroflexus aurantiacus, a phototrophic filamentous bacterium

Light and oxygen regulation of the synthesis of bacteriochlorophylls a and c in Chloroflexus aurantiacus

Control of the synthesis of bacteriochlorophylls (Bchls) a and c by light and oxygen was studied in Chloroflexus aurantiacus grown in batch or chemostat culture with serine as the growth-limiting substrate. For comparison, inhibition by gabaculine of the formation of selected tetrapyrroles was studied. The inhibitory effect of gabaculine decreased in the following order of tetrapyrrole formation: coproporphyrin greater than Bchl c greater than Bchl a. Not only did addition of 5-aminolevulinate (ALA) reverse the inhibition by gabaculine, it also caused an increase in Bchl c content when the cultures grew at high concentrations of ALA. Inhibition of Bchl a, Bchl c, and coproporphyrin formation by oxygen was similar to inhibition by gabaculine. Addition of ALA to aerated cultures led to significant accumulation of coproporphyrin. These results suggest that oxygen inhibits tetrapyrrole formation at a site before ALA formation. Control by light was studied with chemostat cultures transferred from 5 klx to 25 klx. This resulted in only a transient increase of the protein level of the culture, while specific contents of Bchls c and a and the ratio Bchl c/Bchl a decreased to lower steady states. However, the specific content of coproporphyrin increased. Addition of ALA to chemostat cultures adapted to 50 klx increased specific coproporphyrin and Bchl c contents by factors of about 20 and 4, respectively, while the specific Bchl a content was only slightly increased and protein levels were unaffected. Increasing the serine concentration caused an initial increase in the specific Bchl c content, which returned to the original value as soon as the protein content had attained its maximal level. These results suggest that light does not control ALA formation as strictly as oxygen and that competition of biomass formation and tetrapyrrole synthesis for common precursors may be influenced by light.

Origin and early evolution of photosynthesis

Photosynthesis was well-established on the earth at least 3.5 thousand million years ago, and it is widely believed that these ancient organisms had similar metabolic capabilities to modern cyanobacteria. This requires that development of two photosystems and the oxygen evolution capability occurred very early in the earth's history, and that a presumed phase of evolution involving non-oxygen evolving photosynthetic organisms took place even earlier. The evolutionary relationships of the reaction center complexes found in all the classes of currently existing organisms have been analyzed using sequence analysis and biophysical measurements. The results indicate that all reaction centers fall into two basic groups, those with pheophytin and a pair of quinones as early acceptors, and those with iron sulfur clusters as early acceptors. No simple linear branching evolutionary scheme can account for the distribution patterns of reaction centers in existing photosynthetic organisms, and lateral transfer of genetic information is considered as a likely possibility. Possible scenarios for the development of primitive reaction centers into the heterodimeric protein structures found in existing reaction centers and for the development of organisms with two linked photosystems are presented.

Bacteriochlorophyll c formation via the C5 pathway of 5-aminolevulinic acid synthesis in Chloroflexus aurantiacus

Biosynthesis of 5-aminolevulinic acid (ALA) in Chloroflexus aurantiacus, a thermophilic bacterium forming bacteriochlorophyll c, is shown to proceed via the C5 pathway by demonstrating (1) the specific labeling of its chlorin ring with [1 - 13C]glutamate and (2) the enzyme activity to produce ALA from glutamate in a cell-free extract. From the phylogenetic distribution it is suggested that ALA synthetase distributed in some aerobic eubacteria could be monophyletic in origin.

Gene encoding the 5.7-kilodalton chlorosome protein of Chloroflexus aurantiacus: regulated message levels and a predicted carboxy-terminal protein extension

The major light-harvesting pigment of the green filamentous bacterium Chloroflexus aurantiacus is bacteriochlorophyll (Bchl) c, localized in chlorosomes attached to the inner surface of the cytoplasmic membrane. Chlorosomes consist of four polypeptides and associated pigments and lipids. Previous studies of the inducible assembly of the photosynthetic apparatus had indicated that the major chlorosomal polypeptides are present as high-molecular-weight aggregates before the appearance of mature chlorosomes, and a mechanism for posttranslational processing of a polyprotein had been proposed. We have isolated the gene (csmA) encoding the 5.7-kilodalton chlorosomal polypeptide from C. aurantiacus in order to determine whether this protein is synthesized as part of a polyprotein. Analysis of the nucleotide sequence of csmA indicates that the gene is not large enough to encode more than one known chlorosome polypeptide. Transcriptional analysis indicates that csmA is transcribed as a small message whose abundance is regulated in response to oxygen, so that no csmA message is detectable in cells grown aerobically in the dark. Comparison of the sequence predicted by csmA with the peptide sequence of the Bchl c binding protein purified from chlorosomes indicates that this protein is synthesized with a carboxy-terminal extension of 27 amino acids. We discuss possible roles for this carboxy-terminal extension in the assembly of chlorosomes.

Distribution of delta-aminolevulinic acid biosynthetic pathways among phototrophic bacterial groups

Two biosynthetic pathways are known for the universal tetrapyrrole precursor, delta-aminolevulinic acid (ALA). In the ALA synthase pathway which was first described in animal and some bacterial cells, the pyridoxal phosphate-dependent enzyme ALA synthase catalyzes condensation of glycine and succinyl-CoA to form ALA with the loss of C-1 of glycine as CO2. In the five-carbon pathway which was first described in plant and algal cells, the carbon skeleton of glutamate is converted intact to ALA in a proposed reaction sequence that requires three enzymes, tRNA(Glu), ATP, Mg2+, NADPH, and pyridoxal phosphate. We have examined the distribution of the two ALA biosynthetic pathways among various genera, using cell-free extracts obtained from representative organisms. Evidence for the operation of the five-carbon pathway was obtained by the measurement of RNase-sensitive label incorporation from glutamate into ALA, using 3,4-[3H]glutamate or 1-[14C]glutamate as substrate. ALA synthase activity was indicated by RNase-insensitive incorporation of label from 2-[14C]glycine into ALA. The distribution of the two pathways among the bacteria tested was in general agreement with their previously established phylogenetic relationships and clearly indicates that the five-carbon pathway is the more ancient process, whereas the pathway utilizing ALA synthase probably evolved much later. The five-carbon pathway is apparently the more widely utilized one among bacteria, while the ALA synthase pathway seems to be limited to the alpha subgroup of purple bacteria.

Bacterial zonation, photosynthesis, and spectral light distribution in hot spring microbial mats of Iceland

The zonation and structure of phototrophic microbial mats were studied along two thermal gradients in sulfide-rich hot springs of southwest Iceland. The green, filamentous bacteriumChloroflexus and the unicellular, "high-temperature form" (HTF) ofMastigocladus formed mats growing up to a temperature limit of 62-66°C. The dominant phototrophs wereChloroflexus sp.,Mastigocladus laminosus, andPhormidium laminosum, respectively, at the three temperature intervals: >60°C, 60°C to 55-50°C, and <55-50°C. AChloroflexus mat growing at 60°C under 60μM H2S was anoxic in the light with the exception of a 0.5 mm thick band of HTFMastigocladus which produced oxygen. The oxygenic photosynthesis of these H2S-sensitive cyanobacteria was probably dependent on a preceding sulfide depletion by the anoxygenicChloroflexus. Measurements of spectral radiance gradients with a fiberoptic microprobe showed maximum light attenuation by carotenoids and bacteriochlorophyllC. AM. laminosus mat growing at 52°C was oxic throughout and showed maximum light attenuation by carotenoids, chlorophyllA, and phycocyanin, but no detectable phycoerythrocyanin absorption.

13C NMR evidence for bacteriochlorophyll c formation by the C5 pathway in green sulfur bacterium, Prosthecochloris

The 13C NMR spectra of the pheophorbide of bacteriochlorophyll c, formed in the presence of L-[1-13C]glutamate and [2-13C]glycine and [13C]bicarbonate in Prosthecochloris aestaurii, were analysed. The isotope in the glutamate was specifically incorporated into the eight carbon atoms in the tetrapyrrole macrocycle derived from the C-5 of 5-aminolevulinic acid, while no specific enrichment of these eight carbon atoms was observed in the spectrum of the pigment formed in the presence of [2-13C]glycine. These labelling patterns provide evidence for the operation of the C5 pathway of 5-aminolevulinic acid synthesis for bacteriochlorophyll c formation in the bacterium. The labelling of bacteriochlorophyll c by [13C]bicarbonate is consistent with its formation from 5-[1,4,5-13C]aminolevulinic acid formed by the C5 pathway from [1,2,5-13C]glutamic acid. It is proposed that this glutamate is the transamination product of 2-[1,2,5-13C]oxoglutaric acid, arising by carboxylation of [1,4-13C]succinyl-CoA with 13CO2 catalysed by 2-oxoglutaric acid synthase activity, and that the labelled succinyl-CoA is, in turn, derived by the fixation of 13CO2 by the reductive tricarboxylic acid cycle. The 13C chemical shifts of two sp2 quaternary carbons of bacteriopheophorbide c methyl ester (C-2 and C-4) were reassigned.

Oxygen regulation of development of the photosynthetic membrane system in Chloroflexus aurantiacus

Oxygen levels which control induction of the assembly of the pigment-protein photosynthetic polypeptides in dark-grown Chloroflexus aurantiacus were determined. The induction signal by low-oxygen tension is not directly related to the respiratory competence of these photosynthetic cells. Cytochrome c554, the primary electron donor to P865+ of the reaction center, is not present in dark-grown respiratory cells but is induced in parallel with bacteriochlorophylls a and c and at similar oxygen partial pressure. The development of these components of the photosynthetic apparatus and its electron transport chain is completely independent of the presence of any detectable light or bacteriochlorophyll c or a pigments in C. aurantiacus.

Electron transport in green photosynthetic bacteria

Green bacteria make up two of the four families of anoxygenic photosynthetic prokaryotes. The two families have similar pigment compositions and membrane fine structure, and both contain a specialized antenna structure known as a chlorosome. The primary photochemistry and electron transport pathways of the two groups are, however, quite distinct. The anaerobic green bacteria (Chlorobiaceae) contain low-potential iron-sulfur proteins as early electron acceptors and can directly reduce NAD(+) in a manner reminiscent of Photosystem I of oxygenic organisms. The facultatively aerobic green bacteria (Chloroflexaceae) contain quinone-type acceptors and have an overall pattern of electron transport very similar to that found in purple bacteria. Many aspects of energy storage in green bacteria, especially photophosphorylation and the role of cytochrome b/c complexes in electron transport, remain poorly understood.

A Novel Photosynthetic Purple Bacterium Isolated from a Yellowstone Hot Spring

A thermophilic photosynthetic purple bacterium was isolated from the waters of a hot spring in Yellowstone National Park, Wyoming. The organism differs from all known purple bacteria in that it grows optimally at a temperature of about 50 degrees C. The isolate contains bacteriochlorophyll a and grows autotrophically, oxidizing sulfide to elemental sulfur which is then stored as globules inside the cell. These properties indicate that the phototroph is a member of the Chromatiaceae (purple sulfur bacteria).

Isolation of pigmentation mutants of the green filamentous photosynthetic bacterium Chloroflexus aurantiacus

Mutants deficient in the production of bacteriochlorophyll c (Bchl c) and one mutant lacking colored carotenoids were isolated from the filamentous gliding bacterium Chloroflexus aurantiacus. Mutagenesis was achieved by using UV radiation or N-methyl-N'-nitro-N-nitrosoguanidine. Several clones were isolated that were deficient in Bchl c synthesis. All reverted. One double mutant deficient both in Bchl c synthesis and in the synthesis of colored carotenoids under anaerobic conditions was isolated. Isolation of a revertant in Bchl c synthesis from this double mutant produced a mutant strain of Chloroflexus that grew photosynthetically under anaerobic conditions and lacked colored carotenoids. Analysis of pigment contents and growth rates of the mutants revealed a positive association between growth rate and content of Bchl c under light-limiting conditions.

Chloroherpeton thalassium gen. nov. et spec. nov., a non-filamentous, flexing and gliding green sulfur bacterium

A flexing and gliding green sulfur bacterium has been isolated from marine sources off the North East coast of the USA. Chloroherpeton thalassium is an obligate phototroph, and requires CO2 and S2 for growth; some organic acids can contribute to cell carbon, and N2 may be fixed. The cells contain typical chlorosomes, and gas vesicles may be present. Bacteriochlorophyll c is the main light harvesting pigment, and a small quantity of bacteriochlorophyll a is also present. Over 80% of the carotenoid is gamma-carotene. DNA base composition of the isolates ranges from 45.0-48.2 mol% G + C.

Physiological Ecology of a Gliding Bacterium Containing Bacteriochlorophyll a

A filamentous, gliding, thermophilic bacterium, found growing abundantly as a surface mat in a limited number of alkaline hot springs in Oregon, is described and designated F-1. The bacteria were studied in the field and in coculture with an aerobic chemoheterotroph. The bacteria are phototrophic and contain bacteriochlorophyll a and several carotenoid pigments. Unlike the other gliding phototrophic bacteria, members of the family Chloroflexaceae , F-1 does not contain chlorosomes or bacteriochlorophyll c or d . The light-dependent uptake of simple organic compounds (acetate and glucose) was demonstrated in field populations. Near-infrared radiation sustained this uptake, which occurred equally well under aerobic or anaerobic conditions and was insensitive to 3-(3,4-dichlorophenyl)-1,1-dimethylurea. The bacteria formed conspicuous dominant mats from about 35 to 56°C, and they covered mats of cyanobacteria in the spring, summer, and autumn months. It appears that they depend on high light intensities to maintain a dense population.

Temperature dependence of growth and membrane-bound activities of Chloroflexus aurantiacus energy metabolism

The temperature dependence of various activities related to the energy metabolism of isolated membranes and whole cells of the thermophilic bacterium Chloroflexus aurantiacus was determined after phototrophic growth at either 40, 50, or 60 degrees C. The data obtained were expressed by use of Arrhenius plots. Maximum activities were determined at about 65 degrees C for succinate 2,4-dichlorophenol-indophenol reductase as well as NADH oxidase and at about 70 degrees C for Mg-ATPase and for light-induced proton extrusion by cells. Activation energies for Mg-ATPase and light-induced proton extrusion were about 40 kJ mol-1 from 30 degrees C to about 50 degrees C and they increased significantly at higher temperatures. Essentially the same dependency was detectable with NADH oxidase, except for an increase in activation energy below 41 degrees C. All of these responses were independent of growth temperature. Succinate-2,4-dichlorophenol-indophenol reductase showed a change in activation energy around 41 degrees C only with cells grown at 60 degrees C. Differences in the responses of cells grown at different temperatures were identified on the basis of changes from sigmoidal to hyperbolic kinetics for light saturation of proton extrusion. Moreover, the thermostability of proton extrusion was maximal when assayed at the corresponding growth temperatures. In any case, thermostability was lowest at the 65 and 68 degrees C assay temperatures. Differential scanning calorimetry with membranes revealed irreversible heat uptake from about 60 to 72 degrees C. The results are discussed in light of the activation energy for the specific growth rate, which is lowest at temperatures from 40 degrees C to the optimum at 60 degrees C.

Primary photochemistry in the facultative green photosynthetic bacterium Chloroflexus aurantiacus

The mechanism of primary photochemistry has been investigated in purified cytoplasmic membranes and isolated reaction centers of Chloroflexus aurantiacus. Redox titrations on the cytoplasmic membranes indicate that the midpoint redox potential of P870, the primary electron donor bacteriochlorophyll, is +362 mV. An early electron acceptor, presumably menaquinone has Em 8.1 = -50 mV, and a tightly bound photooxidizable cytochrome c554 has Em 8.1 = +245 mV. The isolated reaction center has a bacteriochlorophyll to bacteriopheophytin ratio of 0.94:1. A two-quinone acceptor system is present, and is inhibited by o-phenanthroline. Picosecond transient absorption and kinetic measurements indicate the bacteriopheophytin and bacteriochlorophyll form an earlier electron acceptor complex.

Isolation and characterization of cytoplasmic membranes and chlorosomes from the green bacterium Chloroflexus aurantiacus

A method was developed which allows the isolation and purification of cytoplasmic membranes and chlorosomes from cells of Chloroflexus aurantiacus grown under different light conditions. The dipolar ionic detergent Deriphat (0.08%) and a sodium iodide gradient centrifugation were used in isolating cytoplasmic membranes. Chlorosomes were prepared with 0.16% of the dipolar ionic detergent Miranol and purified by a sucrose gradient centrifugation. Cytoplasmic membrane fractions prepared from either high- (3,000 W m-2), medium-(200 W m-2) or low- (7 W m-2) light-grown cells had near infrared absorption bands at 866, 808, and 755 nm in a constant characteristic absorbance ratio of 6:3.8:1. In all cytoplasmic membrane preparations, the amount of bacteriochlorophyll a (Bchl a) per cytochrome, the amount of Bchl a per reaction center, and reaction center per milligram of cytoplasmic membrane protein was found to be constant. No Bchl c was present. Five respiratory enzyme activities have been measured in the cytoplasmic membrane fraction. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of denatured cytoplasmic membrane showed many bands, but a major polypeptide with an apparent molecular weight of 8,000. In contrast, sodium dodecyl sulfate-polyacrylamide gel electrophoresis of purified chlorosomes did not contain the 8,000-molecular-weight band but revealed only three distinct protein bands with molecular weights of 15,000, 12,000, and 6,000. Isolated chlorosomes contained Bchl c and a small, yet constant, amount of Bchl a (absorbing at 790 nm) in a molar ratio of 25:1. The data indicated that the components of the photosynthetic apparatus in the cytoplasmic membrane of Chloroflexus aurantiacus remained constant and only the amount of antenna Bchl c varied with light conditions.

Isolation and development of chlorosomes in the green bacterium Chloroflexus aurantiacus

Freeze-fracture electron microscopy was used to study further the changes in chlorosome structure during the development of the photosynthetic apparatus in Chloroflexus aurantiacus J-10-fl. During development, in response to decreased light intensity or lower oxygen tension, the number of chlorosomes per cell increased. The same conditions also led to a general thickening of chlorosomes but did not affect their length or width. The thickening of the chlorosomes paralleled increases in the bacteriochlorophyll c/bacteriochlorophyll a ratio. Semiaerobic induction of the photosynthetic apparatus did not produce a synchronous assembly of chlorosomes in all cells of a given culture. Even adjacent cells of a single filament showed great variations in the rate and extent of response. Parallel appearance of (i) approximately 5-nm particles (in a lattice configuration) in the membrane attachment site, (ii) the crystalline baseplate material (with a periodicity of approximately 6 nm) adjacent to the membrane attachment site, and (iii) the chlorosome envelope layer preceded addition of longitudinally oriented, rodlike elements (diameter, congruent to 6 m) to the chlorosome core. It is estimated that each chlorosome can funnel energy into approximately 100 reaction centers. Chlorosomes could be isolated by a simple density gradient procedure only from cells grown at low light intensity. A bacteriochlorophyll a species absorbing at 790 nm was associated with isolated chlorosomes. Lithium dodecyl sulfate-polyacrylamide gel electrophoresis of chlorosomes showed only a few low-molecular-weight polypeptides (less than 15,000).

Semiaerobic induction of bacteriochlorophyll synthesis in the green bacterium Chloroflexus aurantiacus

Comparison of Chloroflexus aurantiacus J-10-fl cells by freeze-fracture electron microscopy showed that cell shape and dimensions did not depend on oxygen tension or light intensity during growth. The major morphological difference between cells cultured anaerobically in the light and aerobically in the dark was the absence of chlorosomes in aerobically grown cells. C. aurantiacus cells cultured aerobically in the dark began bacteriochlorophyll synthesis immediately when shifted to either phototrophic or semiaerobic conditions. Cells adapting to phototrophic conditions grew to the same density and synthesized as much bacteriochlorophyll as nonadapting phototrophic cultures grown at the same light intensity. Cells adapting to reduced oxygen tension (semiaerobic conditions) in the dark entered an 8- to 12-h growth lag during which the bacteriochlorophyll content increased significantly. Despite variations in the initial bacteriochlorophyll content and in the length of the growth lag, the amounts of bacteriochlorophyll a and c were constant at the end of the semiaerobic growth lag. At later times during adaptation to semiaerobic conditions, after growth resumed, variations in the ratio of bacteriochlorophyll c/bacteriochlorophyll a were observed and suggested independent regulation of the two bacteriochlorophylls.

Chlorophyll organization in green photosynthetic bacteria

Light-harvesting BChl c, d or e is thought to be located inside the rod elements which fill the chlorosome appressed to the inside of tbe cytoplasmic membrane of green photosynthetic bacteria. BChl a is known to be a part of BChl a-protein which forms a crystal-line baseplate between the rod elements in the chlorosome and the inside of the cytoplasmic membrane. Reaction-center complexes are most probably buried under the baseplate inside the membrane. Energy transfer is from BChl c, d or e in the rod elements to BChl a in the baseplate and then to BChl a in the reaction-center complexes. The rod elements in green sulfur bacteria are thought to be composed of approx. 15-kdalton protein subunits, each associated with 12-14 BChl c, d or e molecules. Six subunits would be required to form a 10-nm ring, and about 35 rings would be necessary to form a 100-nm rod element. The baseplate appears to be a two-dimensional crystal (trigonal space group P31) of BChl a-protein trimers with the 3(1) screw axis tilted 25 degrees out of the plane membrane. The reaction-center complex is thought to be made up of a 100-kdalton carotenoid reaction-center core and five 50-kdalton subunits, each containing seven BChl a molecules. Each reaction-center complex is apparently linked directly to two BChl a-protein trimers in the baseplate. The reaction centers in green sulfur bacteria may be of one type (containing P-840), or of two types (containing P-830 or P-842). In filamentous gliding bacteria the reaction centers appear to contain only P-865. The number of BChl a molecules in these reaction centers is not known, but is assumed to be at least two.