Structure of the B880 holochrome of Rhodospirillum rubrum as studied by the radiation inactivation method

Chromatophores from photoreaction centerless strain F24 of Rhodospirillum rubrum were subjected to different doses of gamma radiation. Target theory was applied to the induced decay of the B880 holochrome pigments as analyzed by absorption spectroscopy of the membranes and of organic solvent extracts. Destruction of bacteriochlorophyll is associated with a target size of 7 kDa. This indicates that each one of the two different 6-kDa holochrome polypeptides binds one molecule of this pigment. The target size of spirilloxanthin, 12 kDa, suggests that both polypeptides contribute to the binding site of this carotenoid. The 880 nm absorption band and the oxidation-induced 1225 nm band have a target size of 14 kDA. Therefore, these bands are due to interaction between two bacteriochlorophyll molecules, each one of which resides on a different polypeptide. This 14-kDa complex decays into a bacteriochlorophyll monomer associated with a target size of 7 kDa. The absolute absorption spectra of the protein-bound bacteriochlorophyll pair and monomer are presented.     

Polarization angle dependence of stark absorption spectra of spirilloxanthin bound to the reconstituted LH1 complexes using LH1-subunits isolated from the purple photosynthetic bacterium Rhodospirillum rubrum

Reconstituted LH1 complexes were prepared using the LH1 subunit-type complexes, isolated from the purple photosynthetic bacterium Rhodospirillum (Rs.) rubrum, and purified all-trans spirilloxanthin. Stark absorption spectra of spirilloxanthin bound to both the native and reconstituted LH1 complexes were compared in different polarization angles (χ) against the external electric field. From the polarization angle dependence of the Stark absorption spectra, two angles were determined in reference to the direction of transition dipole moment (m) of spirilloxanthin: one is the change in polarizability upon photoexcitation (Δα), θ(Δα) and the other is the change in static dipole moment upon photoexcitation (Δμ), θ(Δμ). Despite the symmetric molecular structure of all-trans spirilloxanthin, its Stark absorption spectra show pronounced values of Δμ. This large Δμ values essentially caused by the effect of induced dipole moment through Δα both in the cases for native and reconstituted LH1 complexes. However, slightly different values of θ(Δα) and θ(Δμ) observed for the native LH1 complex suggest that spirilloxanthin is asymmetrically distorted when bound to the native LH1 complex and gives rise to intrinsic Δμ value.     

Plasmidless, photosynthetically incompetent mutants of Rhodospirillum rubrum

Ethyl methanesulfonate rendered a high percentage of Rhodospirillum rubrum cells plasmidless and photosynthetically incompetent (Kuhl et al., J. Bacteriol. 156:737-742, 1983). By probing restriction endonuclease-digested chromosomal DNA from these plasmidless strains with 32P-labeled R. rubrum plasmid DNA, we showed that no homology exists between the plasmid and the chromosomal DNA of the mutant. Loss of the plasmid in all the nonphotosynthetic isolates was accompanied by the synthesis of spirilloxanthin under aerobic growth conditions, resistance to cycloserine and HgCl2, and loss of ability to grow fermentatively on fructose. Changes in both the protein and lipid composition of the membranes and the impaired uptake of 203HgCl2 in the plasmidless strains (compared with the wild type) suggest either that membrane modification occurs as a result of plasmid loss, accounting for several of the acquired phenotype characteristics of the cured strains, or that both membrane modification and plasmid loss are part of the same pleiotropic mutation.     

A carotenoprotein from chromatophoreses of Rhodospirillum rubrum

A carotenoprotein has been obtained by SDS-solubilization of $\text{Rhodospirillum rubrum}$ chromatophores. It was then purified by (NH₄)₂SO₄ precipitation and Sephadex G-200 filtration. SDS-polyacrylamide gel electrophoresis revealed a single protein with a molecular weight of about 12,000. The absorption spectrum of the complex is entirely different from the usual three peaked carotenoid spectrum, it has only a major peak at 370 nm. However, after acetone extraction the spectrum of spirilloxanthin reappears. The fact that the carotenoid associates with a specific protein provides strong evidence that the complex originates from the chromatophores and is not a preparative artefact.     

Vibrational spectra and structure of myelin membranes

Raman and infrared spectroscopy have been simultaneously applied, for the first time, to the study of myelin membranes and their proteolipid protein (PLP) so as to obtain information on the secondary structure of proteins and the ordering of lipid chains. The vibrational spectra were recorded at physiological pH using a non-denaturing detergent (n-octyl--d-glucopyranoside) in phosphate buffer. Neither the buffer nor the detergent interfere spectroscopically with the amide bands from proteins. The spectra reveal that the predominant secondary structure in the polypeptide backbone in myelin is the helix. The proteolipid protein was found to be more disordered than the polypeptide arrangement of the myelin membrane, as deduced from the relative intensities and halfwidths of characteristic infrared amide I bands. -form and turns are also present, the amount of these structures being higher in PLP. The study of the Raman spectra of vC-C and vC-H regions made it possible to obtain information on the lipid chain order.     

Surface-enhanced resonance Raman scattering spectroscopy of bacterial photosynthetic membranes. The carotenoid of Rhodospirillum rubrum

Resonance Raman scattering by the carotenoid, spirilloxanthin (Spx), in a suspension of chromatophores (cytoplasmic side out) isolated from the photosynthetic bacterium, Rhodospirillum rubrum, is greatly enhanced when the membranes are adsorbed onto the surface of an anodized Ag electrode. The phenomenon is the basis for surface-enhanced resonance Raman scattering (SERRS) spectroscopy. The Spx SERRS peaks observed were at 1505-1510, 1150-1155, and 1000-1005 cm-1 with laser excitation wavelengths ranging between 457.9 and 568.2 nm. Similar peaks were not observed with spheroplasts (periplasmic side out) isolated from the same species. The difference in signal detected in chromatophores and spheroplasts is not due to differences in membrane surface charge, presence of residual cell wall on the spheroplast surface, lack of adhesion of spheroplasts to metals, or large differences in pigment content per unit membrane area. Instead, the results indicate an asymmetric distribution of Spx in vivo across the membrane (i.e., it is located on the cytoplasmic side of the membrane). The results also demonstrate that the SERRS effect is extremely distance sensitive, and the thickness of a single bacterial membrane (separating the Ag electrode from the carotenoid) is sufficient to prevent detection of Spx spectra. Studies of chromatophores from the F24 strain (a reaction centerless mutant) have pin-pointed B880 antenna complex as the source of the Spx SERRS spectra, and a schematic model of the minimal structural unit of B880 is presented. This work demonstrates the potential of the SERRS technique as a probe for surface topology of pigmented membranes.     

Spectroscopic characterisation of a tetrameric subunit form of the core antenna protein from Rhodospirillum rubrum

The core light-harvesting complex (LH1) of Rhodospirillum rubrum is constituted of multiple heterodimeric subunits, each containing two transmembrane polypeptides, alpha and beta. The detergent octylglucoside induces the stepwise dissociation of LH1 into B820 (an alphabeta dimer) and B777 (monomeric polypeptides), both of which still retain their bound bacteriochlorophyll molecules. We have investigated the absorption properties of B820 as a function of temperature, whereby a spectral population called 'B851' has been characterised. We show evidence that it is a dimer of the B820 complex. This may represent an intermediate oligomeric form in the process of the LH1 ring formation, as its existence was predicted from global analysis of the absorption spectra of the LH1/B820 equilibrium [Pandit et al. (2001) Biochemistry 40, 12913-12924]. Stabilisation of this dissociated form of LH1 may help in understanding both the electronic properties and the association process of these integral membrane proteins.     

Direct observation of sub-picosecond equilibration of excitation energy in the light-harvesting antenna of Rhodospirillum rubrum.

Excitation energy transfer in the light-harvesting antenna of Rhodospirillum rubrum was studied at room temperature using sub-picosecond transient absorption measurements. Upon excitation of Rs. rubrum membranes with a 200 fs, 600 nm laser flash in the Qx transition of the bacteriochlorophyll-a (BChl-a) absorption, the induced transient absorption changes in the Qy region were monitored. In Rs. rubrum membranes the observed delta OD spectrum exhibits ground state bleaching, excited state absorption and stimulated emission. Fast Qx --> Qy relaxation occurs in approximately 100-200 fs as reflected by the building up of stimulated emission. An important observation is that the zero-crossing of the transient difference absorption (delta OD) spectrum exhibits a dynamic redshift from 863 to 875 nm that can be described with by a single exponential with 325 fs time constant. The shape of the transient difference spectrum observed in a purified subunit of the core light-harvesting antenna, B820, consisting of only a single interacting pair of BChl-as, is similar to the spectrum observed in Rs. rubrum membranes and clearly different from the spectrum of BChl-a in a protein/detergent mixture. In the B820 and monomeric BChl-a preparations the 100-200 fs Qx --> Qy relaxation is still observed, but the dynamic redshift of the delta OD spectrum is absent. The spectral kinetics observed in the Rs. rubrum membranes are interpreted in terms of the dynamics of excitation equilibration among the antenna subunits that constitute the inhomogeneously broadened antenna. A simulation of this process using a set of reasonable physical parameters is consistent with an average hopping time in the core light harvesting of 220-270 fs, resulting in an average single-site excitation lifetime of 50-70 fs. The observed rate of this equilibration process is in reasonable agreement with earlier estimations for the hopping time from more indirect measurements. The implications of the findings for the process of excitation trapping by reaction centers will be discussed.     

Purification of an LHI-RC-complex of Rhodospirillum rubrum by solubilization of chromatophores with a short-chain lecithin

Chromatophores from Rhodospirillum rubrum were solubilized using the detergent 1,2-diheptanoyl-sn-phosphatidylcholine (DHPC). The solubilization curves are sigmoidal reaching a plateau at a detergent/protein ratio of 2–3 mol/mg corresponding to 75–90% solubilized protein. The BChl-binding proteins are stable over a large range of DHPC/protein ratios. A complex of BChl-binding proteins containing both LHI- and RC-polypeptides (LHI-RC-complex) was purified using a two step procedure. RC photochemical activity as well as absorption and near-IR CD spectra showed the complex to be active and stable after purification in presence of DHPC.Abbreviations ATPase adenosine triphosphatase - BChI bacteriochlorophyll - DHPC 1,2-diheptanoyl-sn-phosphatidylcholine - DNAse deoxyribonuclease - INT 2-[4-iodophenyl]-3-[4-nitrophenyl]-5-phenyltetrazolium chloride - LDAO lauryl-N,N-dimethylamine-N-oxide - LHI-complex light harvesting complex - PMSF phenylmethylsulfonyl fluoride - RC-complex reaction center complex - SDS-PAGE sodium dodecyl sulfate polyacrylamide gel electrophoresis - TCA trichloroacetic acid This work is dedicated to the memory of Prof. D. I. Arnon.     

Some observations on the culture,physiology and morphology of some brown-redRhodospirillum-species

Summary From ditch- and canalwater 21 strains of brown-red, photo-synthetically active spirilla were isolated. These spirilla distinguished themselves fromRhodospirillum rubrum by the composition of their pigment complex and by their behaviour towards oxygen (strictly anaerobic). The strains, judged by morphological characteristics, represented three different species. Two of the species could be identified withRhodospirillum fulvum van Niel resp.Rhodospirillum photometricum Molisch. The third species was found to be a new one, for which the nameRhodospirillum Molischianum was proposed.Regarding the isolation, culture, morphological and physiological characteristics of these organisms detailed data were given. Various organic substances can function as H-donors for these spirilla. The absorption spectra of living cells of the three species show a striking conformity, but there is a distinct difference between the absorption spectra of the brown-redRhodospirillum-species and the absorption spectrum ofRhodospirillum rubrum. The results of a chromatographical analysis of the pigment complex of one of the strains ofRhodospirillum pholometricum make it probable that this difference is due to the absence of the carotenoid spirilloxanthin in the brown-red spirilla.     

X-ray diffraction studies on chromatophore membrane from photosynthetic bacteria. III. Basic structure of the photosynthetic unit and its relation to other bacteriochlorophyll forms

We have performed X-ray diffraction studies on photosynthetic units of Rhodospirillum rubrum and solubilized *B800 + B890 complex from chromatophores of Chromatium vinosum, to investigate the homology of their molecular structures. The native chromatophores of Chromatium vinosum, which contain other bacteriochlorophyll forms, were examined by an X-ray diffraction technique, in order to assess the interactions between the complexes as well as the molecular structures of the bacteriochlorophyll forms. The subchromatophore particles, solubilized by Triton X-100 from cells of Chromatium vinosum, exhibit a major absorption maximum at 881 nm and a minor one at 804 nm, consisting of bacteriochlorophyll form *B800 + B890. The near-IR absorption spectrum of the particle is very similar to that of chromatophores of Rhodospirillum rubrum although the major absorption maximum is shifted slightly. The X-ray diffraction pattern of the subchromatophore particles is very similar to that of chromatophores of Rhodospirillum rubrum. Thus, the subchromatophore particles are considered to be the "photoreaction unit" of Rhodospirillum rubrum. Since the bacteriochlorophyll form, *B800 + B890, is common in the purple bacteria, it is strongly suggested that the photoreaction unit is the basic and common structure existing in the photosynthetic units of purple bacteria. Chromatium vinosum cells exhibit different near-IR absorption spectra, depending on the culture media and also on the intensity of the illumination during culture. The chromatophores from these cells give different equatorial X-ray diffraction patterns. These patterns are much broader than that of solubilized subchromatophore particles, though they have common features. Thus, the molecular structures in the photosynthetic units are different, depending on their constituent bacteriochlorophyll forms.(ABSTRACT TRUNCATED AT 250 WORDS)     

Alternative pathways of spirilloxanthin biosynthesis in Rhodospirillum rubrum

Detailed studies of the properties of carotenoids isolated from diphenylamine-inhibited cultures of Rhodospirillum rubrum have revealed a number of novel structures that indicate new features of carotenoid biosynthesis in the photosynthetic bacteria. Both neurosporene and 7,8,11,12-tetrahydrolycopene undergo hydration, methylation and dehydrogenation to yield spheroidene and 11',12'-dihydrospheroidene respectively; all the intermediates in these pathways have been identified. These pathways represent alternative routes of anhydrorhodovibrin and spirilloxanthin biosynthesis.     

Vibrational spectroscopy of excited electronic states in carotenoids in vivo. Picosecond time-resolved resonance Raman scattering.

The vibrational spectroscopy and population dynamics of excited singlet (2(1)Ag), excited triplet (3B u), and the ground (1Ag) electronic states of carotenoids in chromatophores of Chromatium vinosum (mainly spirilloxanthin and rhodopin) and of the same carotenoids in benzene solutions are examined by picosecond time-resolved resonance Raman scattering. Coherent Stokes Raman scattering from the ground states of carotenoids in chromatophores also is observed. Resonance Raman spectra of in vitro rhodopin and spirilloxanthin when compared with in vivo data demonstrate that scattering from spirilloxanthin dominates the in vivo spectrum. Comparisons of the time-dependent intensities of 2(1)Ag and 1Ag resonance Raman bands from both in vitro and in vivo carotenoids suggest that vibrationally excited levels in 1Ag are populated directly by the decay of the 2(1)Ag state and that these levels relax into a thermalized distribution in less than 50 ps. The appearance of asymmetrically broadened, ground-state resonance Raman bands supports this conclusion. Formation of the 3Bu state is observed for carotenoids in chromatophores, but not for in vitro spirilloxanthin indicating that the 3Bu state is formed by fission processes originating from the spatial organization of pigments within chromatophores. The rate at which the intensities of 2(1)Ag resonance Raman bands decay is faster for the carotenoids in vivo than for those in vitro thereby indicating that additional relaxation channels (e.g., energy transfer to bacteriochlorophylls) are present in the chromatophore. The similarity of the in vivo and in vitro 2(1)Ag resonance Raman spectra shows that no significant modifications in the vibronic coupling has been caused by the chromatophore environment.     

Energy transfer and bacteriochlorophyll fluorescence in purple bacteria at low temperature

Emission spectra of bacteriochlorophyll a fluorescence and absorption spectra of various purple bacteria were measured at temperatures between 295 and 4 K. For Rhodospirillum rubrum the relative yield of photochemistry was measured in the same temperature region. In agreement with earlier results, sharpening and shifts of absorption bands were observed upon cooling to 77 K. Below 77 K further sharpening occurred. In all species an absorption band was observed at 751-757 nm. The position of this band and its amplitude relative to the concentration of reaction centers indicate that this band is due to reaction center bacteriopheophytin. The main infrared absorption band of Rhodopseudomonas sphaeroides strain R26 is resolved in two bands at low temperature, which may suggest that there are two pigment-protein complexes in this species. Emission bands, like the absorption bands, shifted and sharpened upon cooling. The fluorescence yield remained constant or even decreased in some species between room temperature and 120 K, but showed an increased below 120 K. This increase was most pronounced in species, such as R. rubrum, which showed single banded emission spectra. In Chromatium vinosum three (835, 893 and 934 nm) and in Rps. sphaeroides two (888 and 909 nm) emission bands were observed at low temperature. The temperature dependence of the amplitudes of the short wavelength bands indicated the absence of a thermal equilibrium for the excitation energy distribution in C. vinosum and Rps. sphaeroides. In all species the increased in the yield was larger when all reaction centers were photochemically active than when the reaction centers were closed. In R. rubrum the increase in the fluorescence yield was accompanied by a decrease of the quantum yield of charge separation upon excitation of the antenna but not of the reaction center chlorophyll. Calculation of the F?rster resonance integral at various temperatures indicated that the increase in fluorescence yield and the decrease in the yield of photochemistry may be due to a decrease in the rate of energy transfer between antenna bacteriochlorophyll molecules. The energy transfer from carotenoids to bacteriochlorophyll was independent of the temperature in all species examined. The results are discussed in terms of existing models for energy transfer in the antenna pigment system.     

Ectothiorhodospira vacuolata sp. nov., a new phototrophic bacterium from soda lakes

A new phototrophic bacterium was isolated from Jordanian and Kenyan alkaline salt lakes. Cells are rod shaped, 1.5 m wide and 2–4 m long, and motile by polar flagella. They divide by binary fission, and possess photosynthetic membranes as lamellar stacks similar to those in the other species of the genus Ectothiorhodospira and the brown colored Rhodospirillum species. The presence of bacteriochlorophyll a and carotenoids of the normal spirilloxanthin series is indicated by the absorption spectra of living cells. Under certain growth conditions the cells form gas vacuoles, may become immotile and float to the top of the culture medium. Sulfide and thiosulfate are used as photosynthetic electron donors. During the oxidation of sulfide to sulfate, elemental sulfur is formed, which is accumulated outside the cells. The organisms are strictly anaerobic, do not require vitamins, are moderately halophilic and need alkaline pH-values for growth. The new species Ectothiorhodospira vacuolata is proposed.     

Carotenoid Profiles in Pigment-Protein Complexes of Rhodospirillum rubrum

Young cells of Rhodospirillum rubrum contain a set of carotenoidsfrom lycopene to spirilloxanthin. During growth, intermediatesare almost completely converted to spirilloxan-thin. The ratioof the different carotenoid precursors vs. spirilloxanthin foundin material of a certain age is the same in cells, chromatophores,light-harvesting complexes and reaction centers. Independentof the carotenoid composition and the age of the cells, thesame detergent treatment can be used for isolation of pigment-proteincomplexes. Light-harvesting complexes of young cells containingmainly precursors of spirilloxanthin, as well as those of oldcells in which spirilloxanthin dominates, both have their absorptionmaximum at 880 nm. It is thus assumed that all carotenoids ofthe spirilloxanthin series interact with bacteriochlorophylla similarly to spirilloxanthin itself. From these results it is concluded that the micro-environmentof these membrane-complexes is not influenced by the type ofcarotenoid present and that the assembly of the pigment-proteincomplexes in a growing membrane takes place before carotenoidbiosynthesis has lead to the final product. (Received October 26, 1988; Accepted March 6, 1989)     

Thermostability of Rhodopseudomonas viridis and Rhodospirillum rubrum chromatophores reflecting physiological conditions

Relationships between growth conditions and thermostability were examined for photosynthetic inner membranes (chromatophores) from Rhodopseudomonas viridis and Rhodospirillum rubrum of which morphology, lipid composition, and protein/lipid rate are rather mutually different. Signals observed by differential scanning calorimetry of the chromatophores were correlated with thermal state transitions of the membrane components by reference to temperature dependencies of circular dichroism and absorption spectra of the purified supramolecule comprising a photoreaction center and surrounding light-harvesting pigment-protein complexes that are the prominent proteins in both membranes. The differential scanning calorimetry curves of those chromatophores exhibited different dependencies on growth stages and environmental temperatures. The obtained result appeared to reflect the differences in the protein/lipid rate and protein-lipid specificity between the two chromatophores.     

Low Temperature Absorption Spectra of Chlorophyll a in Polar and Nonpolar Solvents

Absorption spectra of chlorophyll a were measured in polar and non-polar solvents, as a function of temperature from 298 degrees to 77 degrees K. Both dilute and concentrated solutions were examined. In both types of solvents at room temperature, the absorption spectra of concentrated solutions differ from dilute ones in that the half width of the main red absorption band is greater, and all bands are shifted to longer wavelengths. These differences are largely due to the presence of dimers when the pigment concentration is high. In dilute ethanol solutions, where the chlorophyll is unassociated, cooling causes a red shift in all bands which is due to the increased polarity of the solvent at low temperature. On cooling at high concentrations in ethanol and EPA, a new band appears near 700 nm. This band is attributed to dimers present prior to cooling, but absorbing at shorter wavelengths at room temperature. In nonpolar solvents, a band near 700 nm appears at the solvent freezing point. In these solvents, the "700" nm absorption is attributed to dimers, and/or small polymers, partly formed by cooling. A change in aggregate geometry when the solvent becomes viscous or frozen can account for the appearance of this "700" nm absorption band at low temperature, in polar and nonpolar media.     

The bacteriochlorophyll absorption band shifts linked with the energy state of photosynthetic bacteria membranes

The uncoupler of photophosphorylation FCCP inhibits the light-induced changes in absorbancy forRhodospirillum rubrum, Ectothiorhodospira shaposhnikovii andChromatium minutissimum cells in anaerobic conditions. These changes are associated with the shifts of bacteriochlorophyll absorption bands. The superposition of these spectral shifts and the photobleaching of reaction centers P890 is observed in aerobic conditions.The light-induced shifts of bacteriochlorophyll absorption bands are suggested to be due to the electrochemical transmembrane potential and local electric field arising as a result of the primary separation of opposite charges.Abbreviations FCCP carbonylcyanide-p-trifluoromethoxy phenyl-hydrazone - TMPD tetramethyl-p-phenylenediamine