Linear dichroism of pigments associated with spherical chromatophores. Models of orientation in polyacrylamide gels

Linear dichroism and orientation of pigments in chromatophores of photosynthetic bacteria Chromatium minutissimum and Rhodospirillum rubrum using a novel method of orientation in polyacrylamide gel was studied. A model is proposed for orientation of spherical membranes of chromatophores or other similar vesicules. The value of linear dichroism is derived for known deformation of the gel and a certain angle between the transition dipole and a unit vector perpendicular to the membrane plane. The analysis of linear dichroism spectra permits calculation of angles between the normal to the membrane and the transition dipoles in Chr. minutissimum 65 degrees +/- 1.5 degrees (890 nm absorption band), 63 degrees +/- 1 degree (860 nm), 63 degrees +/- 1 degree (800 nm), 45.5 degrees +/- 1 degree (590 nm), 50.5 degrees +/- 0.5 degree (450--550 nm) and in Rsp. rubrum: 71 degrees +/- 1.5 degree (890 nm), 66.5 degrees +/- 1 degree (870 nm), 69 degrees +/- 1.5 degree (800 nm), 37 degrees +/- 0.5 degree (590 nm), 49.5 degrees +/- 0.5 degree (450--550 nm). The 860 nm band shift to shorter wave-lengths observed in Chr. minutissimum chromatophores treated with 0.01 M potassium ferricyanide is not related to reorientation of transition dipoles, but rather to certain changes of lipid-protein environment.     

Absorption and structure of an LM unit isolated with sodium dodecyl sulfate from reaction centers of Rhodopseudomonas sphaeroides

Low-temperature absorption, circular dichroism and resonance Raman spectra of the LM units isolated with sodium dodecyl sulfate from wild-type Rhodopseudomonas sphaeroides reaction centers (Agalidis, I. and Reiss-Husson, F. (1983) Biochim. Biophys. Acta 724, 340–351) are described in comparison with those of intact reaction centers. In LM unit, the Q_y absorption band of P-870 at 77 K shifted from 890 nm (in reaction center) to 870 nm and was broadened by about 30%. In contrast, the 800 nm bacteriochlorophyll absorption band including the 810 species remained unmodified. It was concluded that the 810 nm transition is not the higher excitonic component of P-870. The Q_x band of P-870 shifted from 602 nm (in reaction center) to 598 nm in LM, whereas the Q_x band of the other bacteriochlorophylls was the same in reaction center and LM and had two components at about 605 and 598 nm. The Q_xII band of bacteriopheophytin was upshifted to 538 nm and a slight blue shift of the Q_y band of bacteriopheophytin was observed. Resonance Raman spectra of spheroidene in LM showed that its native cis-conformation was preserved. Resonance Raman spectroscopy also demonstrated that in LM the molecular interactions assumed by the conjugated carbonyls of bacteriochlorophyll molecules were altered, but not those assumed by the bacteriopheophytins carbonyls. In particular at least one Keto group of bacteriochlorophyll free in reaction center, becomes intermolecularly bounded in LM (possibly with extraneous water). This group may belong to the primary donor molecules.     

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.     

Transition dipole orientations in the early photolysis intermediates of rhodopsin.

The linear dichroism spectrum of rhodopsin in sonicated bovine disk membranes was measured 30, 60, 170, and 600 ns after room temperature photolysis with a linearly polarized, 7-ns laser pulse (lambda = 355 or 477 nm). A global exponential fitting procedure based on singular value decomposition was used to fit the linear dichroism data to two exponential processes which differed spectrally from one another and whose lifetimes were 42 +/- 7 ns and 225 +/- 40 ns. These results are interpreted in terms of a sequential model where bathorhodopsin (BATHO, lambda max = 543 nm) decays toward equilibrium with a blue shifted intermediate (BSI, lambda max = 478 nm). BSI then decays to lumirhodopsin (LUMI, lambda max = 492 nm). It has been suggested that two bathorhodopsins decay in parallel to their products. However, a Monte Carlo simulation of partial photolysis of solid-state visual pigment samples shows that one mechanism which creates populations of BATHO having different photolysis rates at 77 K may not be responsible for the two decay rates reported here at room temperature. The angle between the cis band and 498-nm band transition dipoles of rhodopsin is determined to be 38 degrees. The angles between both these transition dipoles and those of the long-wave-length bands of BATHO, BSI, and LUMI are also determined. It is shown that when BATHO is formed its transition dipole moves away from the original cis band transition dipole direction. The transition dipole then moves roughly twice as much towards the original cis band direction when BSI appears. Production of LUMI is associated with return of the transition dipole almost to the original orientation relative to the cis band, but with some displacement normal to the plane which contains the previous motions. The correlation between the lambda max of an intermediate and its transition dipole direction is discussed.     

Circular dichroism spectra of oriented photoreaction center from Rhodospirillum rubrum

The circular dichroism spectra of oriented and unoriented photoreaction centers of Rhodospirillum rubrum are compared. Orientation is achieved by pressing photoreaction center suspended in polyacrylamide gel. The biphasic bands at 870 and 810 nm and at 630 and 600 nm undergo a rotatory strength decrease when measured in the direction of the pressure, but not when measured in the direction normal to the pressure. Such a decrease in oriented photoreaction center is consistent with the model according to which these bands are dimer exciton bands of the special pair bacteriochlorophyll.     

Photodichroic studies of the photoreaction center from Rhodospirillum Rubrum. I. Attribution of P870 to two non parallel dipoles

A randomly oriented sample of photoreaction center prepared from Rhodospirillum rubrum was excited at 77 °K by an actinic linearly polarized light of 870 nm. Under such conditions, only those chromophores with components of their absorption dipoles oriented parallel to the polarization of the actinic light are bleached. The change in absorbance at 900 nm of this photoselected sample was observed while varying the angle of polarization of a weak measuring light. The polarization of the absorbance change was thus evaluated as 0.25.

This value is interpreted to mean that P₈₇₀ is attributable to two absorption dipoles forming an angle included between 35.75° and 90°. Comparison with the p value of 0.5 obtained on a similar preparation by polarization of fluorescence (Ebrey, T. G. and Clayton, R. K. (1969) Photochem. Photobiol. 10, 109–117) leads to the conclusion that either these two dipoles emit fluorescence without being coupled by singlet-singlet energy transfer or that only one of them is a fluorescence emitter in the absence of reversible singlet-singlet energy transfer.     

An asymmetric dimer exciton model. Application to the primary electron donor of bacterial photoreaction center

An asymmetric dimer excition theory is developed that takes into account both environmental and vibronic effects on the electronic transition energies. Explicit equations are presented for the transition energies, the dipole moments, the angle between the dipole moments and the dipole and rotational strengths for the electronic transitions in this asymmetric dimer. This model is proposed to describe the structure of the special pair of bacteriochlorophyll a molecules believed to constitute the primary electron donor of bacterial photoreaction center. The model is found to be consistent with most of the spectroscopic properties of the photoreaction center. We used the equations derived from the asymmetric model along with absorption and circular dichroism spectroscopy data to predict a geometrical structure for the primary electron donor.     

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.     

Picosecond photodichroism studies on reaction centers from the green photosynthetic bacterium Chloroflexus aurantiacus

Picosecond photodichroism (photoselection) measurements have been carried out on reaction centers from the facultative green photosynthetic bacterium Chloroflexus aurantiacus using weak 30 ps flashes in the long-wavelength band of the primary electron donor, P. Absorption changes due to the chemical and photochemical oxidation of P and the reduction of quinone also have been examined. Our results on Chloroflexus suggest that the Q_y transition-dipoles of the bacteriopheophytin molecules participating in, or affected by, the primary reactions are oriented essentially perpendicular to the 865 nm transition dipole of P. This is in agreement with previous work on reaction centers from purple bacteria, such as Rhodopseudomonas sphaeroides. The data also suggest that the 812 nm ground-state transition is oriented at an angle of 45–65° with respect to the 865 nm transition. The new band that appears near 800 nm upon oxidation of P is polarized mainly parallel to the 865 nm band. These relative polarizations of the absorption bands are in very good agreement with the results of recent linear dichroism studies (Vasmel, H., Meiburg, R.F., Kramer, H.J.M., De Vos, L.J. and Amesz, J. (1983) Biochim. Biophys. Acta 724, 333–339). Possible origins for the absorption changes and the photodichroism spectra are discussed. The data are consistent with either a monomeric or dimeric structure of P-865.     

Pigment organization in the photosynthetic apparatus of Roseiflexus castenholzii

The light-harvesting-reaction center (LHRC) complex from the chlorosome-lacking filamentous anoxygenic phototroph (FAP), Roseiflexus castenholzii (R. castenholzii) was purified and characterized for overall pigment organization. The LHRC is a single complex that is comprised of light harvesting (LH) and reaction center (RC) polypeptides as well as an attached c-type cytochrome. The dominant carotenoid found in the LHRC is keto-γ-carotene, which transfers excitation to the long wavelength antenna band with 35% efficiency. Linear dichroism and fluorescence polarization measurements indicate that the long wavelength antenna pigments absorbing around 880 nm are perpendicular to the membrane plane, with the corresponding Q_y transition dipoles in the plane of the membrane. The antenna pigments absorbing around 800 nm, as well as the bound carotenoid, are oriented at a large angle with respect to the membrane. The antenna pigments spectroscopically resemble the well-studied LH2 complex from purple bacteria, however the close association with the RC makes the light harvesting component of this complex functionally more like LH1.     

Spectroscopic properties of the reaction center and of the 47 kDa chlorophyll protein of Photosystem II

The D1-D2-cytochrome b-559 reaction center complex and the 47 kDa antenna chlorophyll protein isolated from spinach Photosystem II were characterized by means of low temperature absorption and fluorescence spectroscopy. The low temperature absorption spectrum of the D1-D2-cytochrome b-559 complex showed two bands in the Q_y region located at 670 and 680 nm. On the basis of its absorption maximum and orientation the latter component may be attributed at least in part to P-680, the primary electron donor of Photosystem II. The 47 kDa antenna complex showed absorption bands at 660, 668 and 677 nm and a minor component at 690 nm. The latter transition appeared to be associated with the characteristic low temperature 695 nm fluorescence band of Photosystem II. The 695 nm emission band was absent in the D1-D2 complex, which indicates that it does not originate from the reaction center pheophytin, as earlier proposed. The transition dipole responsible for the main fluorescence at 684 nm from this complex had a parallel orientation with respect to the membrane plane in the native structure. The reaction center preparation contains two spectrally distinct carotenoids with different orientations.     

Linear-dichroic triplet-minus-singlet absorbance difference spectra of reaction centers of the photosynthetic bacteria Chromatium vinosum,Rhodopseudomonas sphaeroides R-26 and Rhodospirillum rubrum S1

For the first time, linear-dichroic triplet-minus-singlet (LD-(T - S)) spectra of reaction centers of the photosynthetic bacteria Chromatium vinosum, Rhodopseudomonas sphaeroides R-26 and Rhodospirillum rubrum S1 have been measured using an extension of the technique of absorbance-detected magnetic resonance (ADMR) of the triplet state. For all bacteria studied the LD-(T - S) spectra exhibit a bleaching of the long-wavelength absorbance band that is either split or has a clear shoulder to longer wavelengths. The components are approximately parallel-polarized, indicating that they do not form an exciton pair. Around 800 nm a band appears with a width of about 7 nm, which does not form part of a band shift and that may be attributed to an appearing monomer band. Small features in the LD-(T - S) spectra at both sides of this band are well explained by band shifts of the two components of the 800 nm reaction center absorption band. The transition moment of the component at about 818 nm in reaction centers of Rps. sphaeroides R-26 is at an angle larger than 55° with both the x and the y triplet spin axes. In none of the bacteria do we find evidence for the bleaching of an exciton component of P-860 near 810 nm.     

Bacteriochlorophyll a-types in chromatophore and subchromatophore preparations from Rhodopseudomonas sphaeroides.

Comparison of absorption and circular dichroism (CD) spectra in the near infrared region was made with chromatophore and subchromatophore preparations obtained from Rhodopseudomonas sphaeroides. The 850 nm absorption band had a positive correlation with the 850 nm and 870 nm CD bands. The 800 nm and 870 nm absorption bands seemed not to correlate with any CD bands. Lipid contents in chromatophores and subchromatophores were measured. Lipids in membranes seemed to contribute to the appearance of the 870 nm absorption band, but not to that of the 800 nm and 850 nm absorption bands. The time courses of absorbance changes were compared at 800, 850, and 870 nm in detergent-treated chromatophores. Relative changes of absorbances differed from one another. The present results suggest that the three absorption bands are due to three different bacteriochlorophyll a-types and the 850 nm absorption band originates from exciton-coupling of bacteriochlorophyll a.     

The carotenoid band shift in reaction centers from Rhodopseudomonas sphaeroides

A specific carotenoid associated with reaction centers purified from Rhodopseudomonas sphaeroides shows an optical absorbance change in response to photochemical activity, at temperatures down to 35 K. The change corresponds to a bathochromic shift of 1 nm of each absorption band. The same change is induced by either chemical oxidation or photo-oxidation of reaction center bacteriochlorophyll (P-870). Reduction of the electron acceptor of the reaction center, either chemically or photochemically, does not cause a carotenoid absorbance change or modify a change already induced by oxidation of P-870. The change of the carotenoid spectrum can therefore be correlated with the appearance of positive charge in the reaction center. In these studies we observed that at 35 K the absorption band of reaction center bacteriochlorophyll near 600 nm exhibits a shoulder at 605 nm. The resolution into two components is more pronounced in the light-dark difference spectrum. This observation is consistent with our earlier finding, that the “special pair” of bacteriochlorophyll molecules that acts as photochemical electron donor has a dimer-like absorption spectrum in the near infrared.     

Orientation of chromophores in reaction centers of Rhodopseudomonas sphaeroides. Evidence for two absorption bands of the dimeric primary electron donor.

Chromatophores from Rhodopseudomonas sphaeroides were oriented by allowing aqueous suspensions to dry on glass plates. Orientation of reaction center pigments was investigated by studying the linear dichroism of chromatophores in which the absorption by antenna bacteriochlorophyll had been attenuated through selective oxidation. Alternatively the light-induced absorbance changes, in the ranges 550-650 and 700-950nm, were studied in untreated chromatophores. The long wave transition moment of reaction center bacteriochlorophyll (P-870) was found to be nearly parallel to the plane of the membrane, whereas the long wave transition moments of bacteriopheophytin are polarized out of this plane. For light-induced changes the linear dichroic ratios, defined as deltaav/deltaah, are nearly the same for untreated and for oxidized chromatophores. Typical values are 1.60 at 870 nm, 0.80 at 810nm, 1.20 at 790 nm, 0.70 at 765 nm, 0.30 at 745 nm , and 0.50 at 600 nm. The different values for the absorbance decrease at 810 nm (0.80) and the increase at 790 nm (1.20) are incompatible with the hypothesis that these changes are due to the blue-shift of a single band. We propose that the decreases at 870 and 810 nm reflect bleaching of the two components of a bacteriochlorophyll dimer, the "special pair" that shares in the photochemical donation of a single electron. The increase at 790 nm then represents the appearance of a monomer band in place of the dimer spectrum, as a result of electron donation. This hypothesis is consistent with available data on circular dichroism. It is confirmed by the presence of a shoulder at 810 nm in the absorption spectrum of reaction centers at low temperature; this band disappears upon photooxidation of the reaction centers. For the changes near 760 nm, associated with bacteriopheophytin, the polarization and the shape of the "light-dark" difference spectrum (identical to the first derivative of the absorption spectrum) show that the 760 nm band undergoes a light-induced shift to greater wavelengths.     

Orientation of chromophores in reaction centers of Rhodopseudomonas sphaeroides. Evidence for two absorption bands of the dimeric primary electron donor

Chromatophores from Rhodopseudomonas sphaeroides were oriented by allowing aqueous suspensions to dry on glass plates. Orientation of reaction center pigments was investigated by studying the linear dichroism of chromatophores in which the absorption by antenna bacteriochlorophyll had been attenuated through selective oxidation. Alternatively the light-induced absorbance changes, in the ranges 550–650 and 700–950 nm, were studied in untreated chromatophores. The long wave transition moment of reaction center bacteriochlorophyll (P-870) was found to be nearly parallel to the plane of the membrane, whereas the long wave transition moments of bacteriopheophytin are polarized out of this plane. For light-induced changes the linear dichroic ratios, defined as Δa_v/Δa_h, are nearly the same for untreated and for oxidized chromatophores. Typical values are 1.60 at 870 nm, 0.80 at 810 nm, 1.20 at 790 nm, 0.70 at 765 nm, 0.30 at 745 nm, and 0.50 at 600 nm. The different values for the absorbance decrease at 810 nm (0.80) and the increase at 790 nm (1.20) are incompatible with the hypothesis that these changes are due to the blue-shift of a single band. We propose that the decreases at 870 and 810 nm reflect bleaching of the two components of a bacteriochlorophyll dimer, the “special pair” that shares in the photochemical donation of a single electron. The increase at 790 nm then represents the appearance of a monomer band in place of the dimer spectrum, as a result of electron donation. This hypothesis is consistent with available data on circular dichroism. It is confirmed by the presence of a shoulder at 810 nm in the absorption spectrum of reaction centers at low temperature; this band disappears upon photooxidation of the reaction centers. For the changes near 760 nm, associated with bacteriopheophytin, the polarization and the shape of the “light-dark” difference spectrum (identical to the first derivative of the absorption spectrum) show that the 760 nm band undergoes a light-induced shift to greater wavelengths.     

Transient and linear dichroism studies on bacteriorhodopsin: determination of the orientation of the 568 nm all-trans retinal chromophore

The orientation of the 568 nm transition dipole moment of the retinal chromophore of bacteriorhodopsin has been determined in purple membranes from Halobacterium halobium and in reconstituted vesicles. The angle between the 568 nm transition dipole moment and the normal to the plane of the membrane was measured in two different ways.In the first method the angle was obtained from transient dichroism measurements on bacteriorhodopsin incorporated into large phosphatidylcholine vesicles. Following flash excitation with linearly polarized light, the anisotropy of the 568 nm ground-state depletion signal first decays but then reaches a time-independent value. This result, obtained above the lipid phase transition, is interpreted as arising from rotational motion of bacteriorhodopsin which is confined to an axis normal to the plane of the membrane. It is shown that the relative amplitude of the time-independent component depends on the orientation of the 568 nm transition dipole moment. From the data an angle of 78 ° ± 3 ° is determined.In the second method the linear dichroism was measured as a function of the angle of tilt between the oriented purple membranes and the direction of the light beam. The results were corrected for the angular distribution of the membranes within the oriented samples, which was determined from the mosaic spread of the first-order lamellar neutron diffraction peak. In substantial agreement with the results of the transient dichroism method, linear dichroism measurements on oriented samples lead to an angle of 71 ° ± 4 °.No significant wavelength dependence of the dichroic ratio across the 568 nm band was observed, implying that the exciton splitting in this band must be substantially smaller than the recently suggested value of 20 nm (Ebrey et al., 1977).The orientation of the 568 nm transition dipole moment, which coincides with the direction of the all-trans polyene chain of retinal, is not only of interest in connection with models for the proton pump, but can also be used to calculate the inter-chromophore distances in the purple membrane.     

Relations between pigments and proteins in the photosynthetic membranes of Rhodopseudomonas spheroides

We have isolated from Rhodopseudomonas spheroides a pigment-protein complex of apparent weight 9 kdaltons that bears more than 60% of the light harvesting bacteriochlorophyll. The isolation procedure involved exposure to 1% lauryl dimethyl amine oxide (LDAO). The purified 9-kdalton fraction showed the light harvesting bacteriochlorophyll components B800 and B850, plus carotenoids. The ratio of bacteriochlorophyll to protein was 17%. This protein is probably the same as the “band 15” protein of Fraker and Kaplan. It may exist in vivo as characteristic aggregates of higher molecular weight. LDAO added to Rps. spheroides chromatophores converted the bacteriochlorophyll component B870 to a form absorbing at 770 nm but had little effect on the “B800 + B850” system, causing only a reversible shift of the 850-nm band to 845 nm. Anti-reaction center serum, added to subcellular fractions from Rps. spheroides with 1% LDAO, precipitated reaction center chromoprotein unaccompanied by light harvesting bacteriocholorophyll. Other antisera precipitated light harvesting components and left the reaction center chromophores in solution. A major protein of apparent weight 45 kdaltons was found in relatively nonpigmented fractions from Rps. spheroides, associated with cell wall fragments. The 45-kdalton protein showed considerable interstrain variability, whereas the 9-kdalton and reaction center proteins appeared constant.     

Rotational mobility of the photoreaction center in chromatophore membranes of Rhodospirillum rubrum

We investigated the rotational mobility of the photoreaction center in chromatophores of Rhodospirillum rubrum by studying the photoinduced linear dichroism of absorption changes at 865 nm. The study was carried out in suspensions of chromatophores treated with ferricyanide in order to bleach their antenna bacteriochlorophyll and thus minimize depolarization by energy transfer. Very little depolarization of the photoinduced absorbance change at 865 nm was observed at room temperature for chromatophores immersed in a highly viscous medium over the time range 0–10 ms following an exciting light flash. In the light of independent evidence for transmembrane arrangement of the photoreaction center, we conclude that the photoreaction center protein is immobilized in the chromatophore membrane for at least 10 ms.