Distribution of rhodopin and spirilloxanthin between LH1 and LH2 complexes when incorporating carotenoid mixture into the membrane of purple sulfur bacterium <Emphasis Type="Italic">Allochromatium minutissimum</Emphasis> in vitro

Carotenoid mixture enriched by rhodopin and spirilloxanthin was incorporated in LH2 and LH1 complexes from Allochromatium (Alc.) minutissimum in vitro. The maximum incorporating level was ~95%. Rhodopin (56.4%) and spirilloxanthin (13.8%) were incorporated into the LH1 complex, in contrast to the control complex, which contained primarily spirilloxanthin (66.8%). After incorporating, the LH2 complex contained rhodopin (66.7%) and didehydrorhodopin (14.6%), which was close to their content in the control (67.4 and 20.5%, respectively). Thus, it was shown that carotenoids from the total pool are not selectively incorporated into LH2 and LH1 complexes in vitro in the proportion corresponding to the carotenoid content in the complexes in vivo.     

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.     

Triplet excited state spectra and dynamics of carotenoids from the thermophilic purple photosynthetic bacterium <Emphasis Type="Italic">Thermochromatium tepidum</Emphasis>

Light-harvesting complex 2 from the anoxygenic phototrophic purple bacterium Thermochromatium tepidum was purified and studied by steady-state absorption, fluorescence and flash photolysis spectroscopy. Steady-state absorption and fluorescence measurements show that carotenoids play a negligible role as supportive energy donors and transfer excitation to bacteriochlorophyll-a with low energy transfer efficiency of ~30%. HPLC analysis determined that the dominant carotenoids in the complex are rhodopin and spirilloxanthin. Carotenoid excited triplet state formation upon direct (carotenoid) or indirect (bacteriochlorophyll-a Q_x band) excitation shows that carotenoid triplets are mostly localized on spirilloxanthin. In addition, no triplet excitation transfer between carotenoids was observed. Such specific carotenoid composition and spectroscopic results strongly suggest that this organism optimized carotenoid composition in the light-harvesting complex 2 in order to maximize photoprotective capabilities of carotenoids but subsequently drastically suppressed their supporting role in light-harvesting process.     

Carotenoids in Rhodoplanes Species: Variation of Compositions and Substrate Specificity of Predicted Carotenogenesis Enzymes

Phototrophic bacteria necessarily contain carotenoids for photosynthesis, and accumulate unusual carotenoids in some cases. The carotenoids in all established species of Rhodoplanes (Rpl.), a representative of phototrophic genera, were identified using spectroscopic methods. The major carotenoid was spirilloxanthin in Rpl. roseus and Rpl. serenus, and rhodopin in "Rpl. cryptolactis". Rpl. elegans contained rhodopin, anhydrorhodovibrin, and spirilloxanthin. Rpl. pokkaliisoli contained not only rhodopin but also 1,1'-dihydroxylycopene and 3,4,3',4'-tetrahydrospirilloxanthin. These variations in carotenoid composition suggested that Rpl. roseus and Rpl. serenus had normal substrate specificity of the carotenogenesis enzymes of CrtC (acyclic carotene 1,2-hydratase), CrtD (acyclic carotenoid 3,4-desaturase), and CrtF (acyclic 1-hydroxycarotenoid methyltransferase). On the other hand, CrtC of Rpl. elegans, CrtD of "Rpl. cryptolactis", and CrtC, CrtD, and CrtF of Rpl. pokkaliisoli might have different characteristics from the usual activity of these normal enzymes in the normal spirilloxanthin pathway. These results suggest that the variation of carotenoids among the species of Rhodoplanes results from modified substrate specificity of the carotenogenesis enzymes involved.     

The resonance Raman spectrum of carotenoids as an intrinsic probe for membrane potential. Oscillatory changes in the spectrum of neurosporene in the chromatophores of Rhodopseudomonas sphaeroides.

The resonance Raman spectrum of the carotenoid neurosporene is shown to be a sensitive monitor of absorption shifts, and thus changes in membrane potential, in chromatophores of the GlC mutant of Rhodopseudomonas sphaeroides. For a Raman excitation wavelength at 472.7 nm, the intensities of the two most prominent resonance Raman features (v1 and v2) respond very differently to small shifts in the absorption maxima. Thus, the ratio intensity v1/intensity v2 is a sensitive probe for absorption shifts. Changes in this ratio of approximately 20% were observed during a valinomycin induced diffusion potential. At 5 degrees C changes in the average intensity ratio of +6, -4 and -14% were brought about by oligomycin, FCCP and sodium deoxycholate, respectively. The changes in intensity ratio were temperature dependent and, in addition, effects due to the laser beam acting as an actinic light could be detected. Oscillatory changes were observed in absolute Raman and Rayleigh scattering intensities for chromatophores at 5 degrees C and for intact cells under growing conditions.     

Resonance Raman scattering by bacterial spores

Abstract The laser Raman spectra of lyophilized spores of 5 species (6 strains) of Bacillus were examined. Under the experimental conditions employed, only Bacillus megaterium species showed 3 intense Raman bands at 1515, 1157 and 1007 cm⁻¹. Spores of other species, despite their high content of dipicolinic acid, did not show distinct Raman signals.
The strong, scattering bands at 1515 and 1157 cm⁻¹ in the spectra of spores of B. megaterium may be attributable to conjugated double-bond systems, probably of membrane-associated carotenoids. Their high intensities are due to resonance enhancement.     

Spirilloxanthin incorporation into the LH2 and LH1-RC pigment-protein complexes from a purple sulfur bacterium <Emphasis Type="Italic">Allochromatium minutissimum</Emphasis>

Incorporation of spirilloxanthin into carotenoidless LH2 and LH1-RC complexes from a purple sulfur bacterium Allochromatium (Alc.) minutissimum was studied. Carotenoidless cells of Alc. minutissimum were obtained using diphenylamine, a carotenoid biosynthesis inhibitor. In the course of incorporation of the carotenoid mixture, the composition of which corresponded to that of Alc. minutissimum control photosynthetic membranes, no selective incorporation of spirilloxanthin into the LH1-RC complex was detected. It is assumed that in vivo carotenoids are not incorporated into the LH2 and LH1-RC complexes from a common pool. Pure spirilloxanthin destroys both the LH2 and LH1-RC complexes. Within the concentration range of spirilloxanthin in the incorporated mixture from 27% to 52%, it was found to be incorporated into the LH2 and LH1-RC complexes with the efficiency of 13% and 33%, respectively. The possible existence of different sites of assembly for the LH2 and LH1-RC complexes is discussed, as well as of two fractions of LH2 complexes, in one of which rhodopin may be integrated, and in the other (minor) one, spirilloxanthin.     

Carotenoid composition in the genus Ectothiorhodospira pelsh

Summary The three species of the genus Ectothiorhodospira have been found to contain the carotenoids of the normal spirilloxanthin series, spirilloxanthin itself being the major component. While the carotenoid composition of E. mobilis and E. shaposhnikovii is not sufficiently different to allow interspecific differentiation, that of E. halophila differs from the two former species by its lack of rhodopin, and its higher amount of spirilloxanthin.     

On the state of carotenoids bound to reaction centers of photosynthetic bacteria: a resonance Raman study.

The carotenoids bound to reaction centers of wild, Ga and GIC strains of Rhodopseudomonas spheroides, of Rhodospirrillum rubrum, strain S1 and of Rhodopseudomonas viridis, yield very similar, but unusual resonance Raman spectra. Through a comparison with resonance Raman spectra of 15,15'-cis-beta-carotene, these carotenoids are shown to assume cis conformations, while the corresponding chromatophores contain all-trans forms only. These cis conformations likely are identical for all the carotenoids studied. They remain unaffected by variations of temperature from 20 to 300 K as well as by the redox state of P-870. They are unstable, being rapidly isomerised towards the all-trans forms when extracted from the reaction centers. The possible nature of these conformers is discussed on the basis of their electronic and vibrational spectra.     

Femtosecond stimulated Raman spectroscopy of the dark S1 excited state of carotenoid in photosynthetic light harvesting complex

Vibrational dynamics of the excited state in the light-harvesting complex (LH1) have been investigated by femtosecond stimulated Raman spectroscopy (FSRS). The native and reconstituted LH1 complexes have same dynamics. The ν(1) (C=C stretching) vibrational mode of spirilloxanthin in LH1 shows ultrafast high-frequency shift in the S(1) excited state with a time constant of 0.3 ps. It is assigned to the vibrational relaxation of the S(1) state following the internal conversion from the photoexcited S(2) state.     

The resonance Raman spectrum of carotenoids as an intrinsic probe for membrane potential Oscillatory changes in the spectrum of neurosporene in the chromatophores of Rhodopseudomonas sphaeroides

The resonance Raman spectrum of the carotenoid neurosporene is shown to be a sensitive monitor of absorption shifts, and thus changes in membrane potential, in chromatophores of the GlC mutant of Rhodopseudomonas sphaeroides. For a Raman excitation wavelength at 472.7 nm, the intensities of the two most prominent resonance Raman features (v₁ and v₂) respond very differently to small shifts in the absorption maxima. Thus, the ratio intensity v₁/intensity v₂ is a sensitive probe for absorption shifts. Changes in this ratio of ～20% were observed during a valinomycin induced diffusion potential. At 5°C changes in the average intensity ratio of +6, ?4 and ?14% were brought about by oligomycin, FCCP and sodium deoxycholate, respectively. The changes in intensity ratio were temperature dependent and, in addition, effects due to the laser beam acting as an actinic light could be detected. Oscillatory changes were observed in absolute Raman and Rayleigh scattering intensities for chromatophores at 5°C and for intact cells under growing conditions.     

Properties of a pigment system consisting of carotenoids and reaction centre pigments in chromatophores of Rhodospirillum rubrum

A pigment system containing carotenoids and oxidised reaction centre pigments is present in chromatophores of Rhodospirillum rubrum and this pigment system may cause fluorescence quenching when a still unidentified chromatophore component is in its oxidised state. Besides by its action spectrum, this pigment system is characterised by the time course and level of light saturation of the effect. The quenching of bacteriochlorophyll fluorescence is abolished when the permeability of the chromatophore membranes is affected. The quenching effect is correlated with a reversible absorption decrease of B 880. A possible function for this pigment system is discussed.     

Microspectrophotometric analysis of intact chromatophores of the Japanese medaka, Oryzias latipes

To investigate the possible photoprotective role of chromatophores in fish, the absorbances of four types of intact chromatophores in adult and larval Japanese medaka were analyzed using microspectrophotometric techniques. The absorbance spectrum of each chromatophore class was obtained from 300 to 550 nm. The absorbance spectra of intact leucophores, melanophores and xanthophores were very similar to the published absorbance spectra of the isolated pure pigments contained in each chromatophore type, pteridines, melanin and carotenoids or pteridines, respectively. Based on these absorbance spectra, leucophores and melanophores should provide the most ultraviolet (UV) photoprotection to fish since the compounds they contain, pteridines and melanin, correspondingly, have strong absorbances in the UV region of the spectrum. Xanthophores containing carotenoids are not likely to provide much protection to fish from UV-induced damage since carotenoids have low absorbances in the UV range. Xanthophores containing colored pteridines, however, may provide somewhat greater UV protection to fish, since pteridines absorb more light than carotenoids in the UV portion of the spectrum. The relative frequency, coverage and thickness of these two types of xanthophores should determine how much protection xanthophores as a chromatophore type would provide against UV-induced damage.     

The study of microviscosity of plasma membranes of Nitella cells during rest and excitation

Changes in the microviscosity of excitable membranes was investigated using resonance Raman spectroscopy of carotenoids. The Raman resonance spectra of carotenoids in Nitella cells were excited by 514.5 nm line of an argon ion laser. The bands at 1525 cm-1, 1160 cm-1 and 1008 cm-1 were observed and they were assigned to C=C, C-C and C-CH vibrations, respectively. The rhythmic excitation of cell reduced the intensity and increased the ratios of intensity of major carotenoid bands with no noticeable shift in the position of peaks. The Arrhenius plot of relative intensity ratios of 1525 cm-1 and 1160 cm-1 bands versus reciprocal temperature showed a change of the slope in the range of 13-18 degrees C. This indicates a membrane phase transitions in which a reorientation of carotenoids species takes place. The interpretation was supported by parallel microcalorimetric and EPR measurements. The decrease of microviscosity with increasing temperature is probably caused by changes in polyene chain conformation. It is suggested that membrane microviscosity during NH4(+)-stimulated rhythmic excitation of algal cells increases, and membrane-associated carotenoids act as microviscosity-sensitive "potential sensor" for the channel.     

Study of the orientational ordering of carotenoids in lipid bilayers by resonance-Raman spectroscopy

The orientational ordering of beta-carotene and crocetin embedded in lamellar model membranes has been investigated by angle-resolved resonance Raman scattering at a temperature well above the phase transition of the lipid chains. It is shown that the ordering of the carotenoids is dependent on the chemical composition of the lipid bilayers. The orientational distribution functions found clearly show that beta-carotene is oriented parallel to the bilayer plane (dioleoyl lecithin) or perpendicular to it (soybean lecithin). For dimyristoyl lecithin at 40 degrees C, egg-lecithin, and digalactosyl diacylglycerol two maxima were found in the orientational distribution: one parallel and one perpendicular to the bilayer surface. Crocetin embedded in soybean lecithin bilayers yields a similar bimodal distribution function. Because of rapid photodegradation no results could be obtained for spirilloxanthin.     

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)     

Structure and function of carotenoids in the photoreaction center from Rhodospirillum rubrum

The bacteriochlorophyll (P-800 and P-870) of the carotenoidless photoreaction center isolated from Rhodospirillum rubrum (strain G9) is bleached irreversibly when the preparations are exposed to intense near infrared light in the presence of oxygen. This effect is much smaller in preparations, extracted from the wild type, which contain, as shown earlier, 1 mol of spirilloxanthin per mol of P-870. This photodynamic effec is shown to be due to singlet O₂. The oxidation of adrenaline in the presence of superoxide dismutase and the oxidation of 1,3-diphenylisobenzofuran are used as reporter reactions. Singlet oxygen is presumably generated by the triplet-triplet energy transfer ³bacteriochlorophyll → O₂ (³Σ).Four purified bacterial carotenoids, spirilloxanthin, sphaeroidene, sphaeroidenone and chloroxanthin were attached onto the carotenoidless photoreaction center from strain G9 in nearly 1 : 1 mol ratios with respect to P-870. Once fixed, these carotenoids confer protection against the photodynamic bleaching of bacteriochlorophyll. The relative photoprotection efficiency was 1.0 for spirilloxanthin and sphaeroidene, 0.4 for chloroxanthin and 0.2 for sphaeroidenone. The fixed carotenoids display optical activity and their molar ellipticity appears to be correlated with their relative photoprotection efficiency. The efficiency of energy transfer to P-870 is 0.90 for sphaeroidene, 0.35 for sphaeroidenone, 0.30 for chloroxanthin and 0.20 for spirilloxanthin. The energy transfer efficiency from the carotenoids to bacteriochlorophyll is suggested to be governed by the rate of the internal conversion processes of the excited singlet state of the carotenoids.A study of the difference absorption and CD spectra of the reconstituted minus carotenoidless preparations leads to the interpretation that the fixed carotenoids are in a central monocis conformation.     

Spectroscopic studies of the low-lying singlet excited electronic states and photochemical properties of carotenoids

Investigations of the singlet excited state properties of carotenoids using steady-state fluorescence, transient absorption pump-probe, two-photon excitation, and resonance Raman excitation spectroscopies are described. The application of these experimental techniques to the specific problem of determining the S1 excited energies of carotenoids is discussed in detail, and the recent literature pertaining to the assignment of charge transfer states in carotenoids and states described as having particular pseudoparity elements is reviewed. Hypothetical schemes for how these states may account for some of the dynamic and photochemical behavior of carotenoids are presented.     

Enhancement of carotenoid-to-chlorophyll singlet energy transfer by carotenoid-carotenoid interaction.

The apparent quantum yield of singlet-singlet spirilloxanthin-to-bacteriochlorophyll a energy transfer increases linearly with the residual spirilloxanthin content in Rhodospirillum rubrum membrane vesicles from which this carotenoid has been partially removed. Since it has been previously shown that carotenoid-carotenoid interaction is a linear function of the residual spirilloxanthin level in the major pigment-protein complex of those vesicles (Zurdo, J., R. M. Lozano, C. Fernandez-Cabrera, and J. M. Ramirez. 1991. Biochem. J. 274:881-884), it appears that such degenerate interaction enhances singlet energy transfer. Part of the enhancement may be explained if the energy donor is the spirilloxanthin 1Bu----1Ag (S2----S0) transition, because exciton coupling probably brings its energy closer to that of the Qx (S2----S0) transition of bacteriochlorophyll. In contrast, it seems that the possible stabilization of the spirilloxanthin 2Ag (S1) state would hardly improve energy transfer, because this hidden state probably lies below the S1 bacteriochlorophyll state. In any case, the stabilizing effects of carotenoid-carotenoid interactions seem insufficient to explain the enhancement of energy transfer. Direct or indirect effects of carotenoid dimerization on the three-dimensional structure of the pigment cluster appear to be required to account for such enhancement.