Light-induced red shift of the Qx absorption band of light-harvesting bacteriochlorophyll in Rhodopseudomonas capsulata and Rhodopseudomonas sphaeroides

In chromatophores from Rhodopseudomonas sphaeroides and Rhodopseudomonas capsulata, the Q_x band(s) of the light-harvesting bacteriochlorophyll (BChl) (λ_max ~590 nm) shifts to the red in response to a light-induced membrane potential, as indicated by the characteristics of the light-minus-dark difference spectrum. In green strains, containing light-harvesting complexes I and II, and one or more of neurosporene, methoxyneurosporene, and hydroxyneurosporene as carotenoids, the absorption changes due to the BChl and carotenoid responses to membrane potential in the spectral region 540–610 nm are comparable in magnitude and overlap with cytochrome and reaction center absorption changes in coupled chromatophores. In strains lacking carotenoid and light-harvesting complex II, the BChl shift absorption change is relatively smaller, due in part to the lower BChl/reaction center ratio.In the carotenoid-containing strains, the peak-to-trough absorption change in the BChl difference spectrum is 5–8% of the peak-to-trough change due to the shift of the longest-wavelength carotenoid band, although the absorption of the BChl band is 25–40% of that of the carotenoid band. The responding BChl band(s) does not appear to be significantly red-shifted in the dark in comparison to the total BChl Q_x band absorption.     

Identification of the carotenoid present in the B-800–850 antenna complex from Rhodopseudomonas capsulata as that which responds electrochromically to transmembrane electric fields

Mild proteolysis of Rhodopseudomonas capsulata chromatophores results in a parallel loss of the 800 nm bacteriochlorophyll absorption band and a blue shift in the carotenoid absorption bands associated with the B-800–850 light-harvesting complex. Both the light-induced and the salt-induced electrochromic carotenoid band shift disappear in parallel to the loss of the 800 nm bacteriochlorophyll absorption upon pronase treatment of chromatophores. During the time required for the loss of the 800 nm bacteriochlorophyll absorption and the loss of the electrochromic carotenoid band shift photochemistry is not inhibited and the ionic conductance of the membrane remains very low. We conclude that the carotenoid associated with the B-800–850 light-harvesting complex is the one that responds electrochromically to the transmembrane electric field. Analysis of the pigment content of Rps. capsulata chromatophores indicates that all of the carotenoid may be accounted for in the well defined pigment-protein complexes.     

The energy-linked carotenoid band-shift in Chromatium vinosum.

Chromatium vinosum chromatophores contain an energy-linked pyrophosphatase that is insensitive to oligomycin and dicyclohexylcarbodiimide. Pyrophosphate hydrolysis produces a carotenoid band-shift similar to that resulting from illumination. The carotenoid band-shift can also be produced by a K⁺ diffusion potential (interior positive) and the magnitude of the band shift is proportional to the membrane potential over at least a 100-fold variation in K⁺ concentration. The light-induced carotenoid band-shift in whole cells is identical to that seen in chromatophores but K⁺ diffusion potentials (interior positive) produce a mirror image of the light-induced band-shift. These results are interpreted in terms of chromatophores being inside-out vesicles.     

The kinetics of carotenoid absorption changes in intact cells of photosynthetic bacteria

The kinetics of carotenoid absorption changes have been measured in intact cells of Rhodopseudomonas capsulata after short flash excitation. The observed changes were consistent with the thesis that they indicate the development and dissipation of membrane potential. In the generation of the absorption changes in anaerobic cells, fast (complete in 0.5 ms) and slow (half-time 3 ms) components can be distinguished. The slow component corresponds kinetically to the rate of cytochrome c re-reduction and is similarly antimycin sensitive. These data are similar to those observed in isolated chromatophores which have been artifically poised with redox mediators. In aerobic intact cells the kinetic profile is altered, mainly because the decay of the carotenoid change is much faster. Inhibition of respiration with KCN leads to flash-induced changes similar to those in anaerobic cells. At least two components can be distinguished in the decay of the carotenoid absorption changes in anaerobic intact cells. Only the faster decay component was inhibited by venturicidin which suggests that it corresponds to H⁺ flux through the F₀F₁-ATPase during ATP synthesis. The contribution of the venturicidin-sensitive decay to the total decay was dependent upon the initial amplitude of the carotenoid absorption change produced by the flash group. This suggests that there is an apparent threshold of membrane potential for ATP synthesis. Supporting evidence was provided by the finding that venturicidin stimulated the steady-state light-induced carotenoid absorption change at high but not at low light intensities. The entire decay of the carotenoid absorption changes was stimulated by carbonyl cyanide p-trifluoromethoxyphenylhydrazone in a manner that can be interpreted as an ionophore catalysing the dissipation of membrane potential.     

Oxonol dyes as monitors of membrane potential. Their behavior in photosynthetic bacteria

The responses of oxonol dyes to single and multiple single turnovers of the photosynthetic apparatus of photosynthetic bacteria have been studied, and compared with the responses of the endogenous carotenoid pigments. The absorbance changes of the oxonols can be conveniently measured at 587 nm, because this is an isosbestic point in the ‘light-minus-dark’ difference spectrum of the chromatophores.The oxonols appear to respond to the light-induced ‘energization’ by shifting their absorption maxima. In the presence of K⁺, valinomycin abolished and nigericin enhanced such shifts, suggesting that the dyes respond to the light-induced membrane potential. Since the dyes are anions at neutral pH values, they probably distribute across the membrane in accordance with the potential, which is positive inside the chromatophores. The accumulation of dye, which is indicated by a decrease in the carotenoid bandshift, poises the dye-membrane equilibrium in favor of increased dye binding and this might be the cause of the spectral shift.The dye response has an apparent second-order rate constant of approx. 2 · 10⁶ M^?1 · s^?1 and so is always slower than the carotenoid bandshift. Thus the dyes cannot be used to monitor membrane potential on submillisecond timescales. Nevertheless, on a timescale of seconds the logarithm of the absorbance change at 587 nm is linear with respect to the membrane potential calibrated with the carotenoid bandshift. This suggests that under appropriate conditions the dyes can be used with confidence as indicators of membrane potential in energy-transducing membranes that do not posses intrinsic probes of potential.     

Light- and diffusion-potential-induced shift of carotenoid spectrum in reconstituted vesicles of Rhodopseudomonas sphaeroides

Proteoliposomes were reconstituted from detergent-solubilized pigment · protein complexes of chromatophores of Rhodopseudomonas sphaeroides and soybean phospholipids. The reconstituted vesicles showed a photooxidation of reaction center bacteriochlorophyll and a light-induced spectral shift of carotenoid to longer wavelengths. The red shift similar to that in intact cells or chromatophores, indicates the generation of local fields in the membrane of proteoliposomes. When inside-positive membrane potential was induced by adding valinomycin and potassium salt, a shift of carotenoid spectrum to shorter wavelengths was observed. Therefore, the reconstituted vesicles, at least in the major part of population, produced the light-induced local field in the same direction as in intact cells, which is inside negative. Sidedness of the membrane structure and the direction of electric field formation in reconstituted vesicles were opposite to those in chromatophores (inside-out vesicles).     

Electrochromic absorbance changes of photosynthetic pigments in Rhodopseudomonas sphaeroides II. Analysis of the band shifts of carotenoid and bacteriochlorophyll

An analysis was made of the changes of pigment absorption upon illumination of chromatophores of Rhodopseudomonas sphaeroides at ?35 °C, described in the preceding paper (de Grooth, B. G. and Amesz, J. (1977) Biochim. Biophys. Acta 462, 237–246). Comparison of the light-induced difference spectra in the carotenoid region obtained without additions, and in the presence of N-methylphenazonium methosulphate and ascorbate as donor-acceptor system showed that the latter spectrum was not only about 10 times larger in amplitude, but also red-shifted with respect to the first one. Together with the shape of the difference spectrum, this indicated that the spectrum obtained in the presence of a donor-acceptor system is due to an electrochromic shift of the absorption spectrum of a carotenoid by a few nm towards longer wavelength, caused by a delocalized potential across the chromatophore membrane. The results of an analysis of the kinetics of the absorbance changes near the zero points of the spectrum were in quantitative agreement with the extent of the red shift and indicated a shift of 0.25 nm for a single electron transfer per reaction center, and shifts of up to 4 nm when the electron transport is stimulated by a donor-acceptor system. For bacteriochlorophyll B-850 the shift is three times smaller.Analysis of the overall absorption spectrum showed that there are at least two pools of carotenoid. The carotenoid that shows electrochromism has absorption bands at 452, 481 and 515 nm, and comprises about one-third of the total carotenoid present; the remaining pool absorbs at about 7 nm shorter wavelength and does not show an electrochromic response to illumination. Both pools presumably consist of spheroidene; the differences in band location may be explained by the assumption that only the first pool is subjected to a local electric field which induces an electric dipole even at zero membrane potential. Similar results were obtained at room temperature and with a mutant of Rps. sphaeroides (G1C)-containing neurosporene.     

Light- and diffusion-potential-induced shift of carotenoid spectrum in reconstituted vesicles of Rhodopseudomonas sphaeroides.

Proteoliposomes were reconstituted from detergent-solubilized pigment.protein complexes of chromatophores of Rhodopseudomonas sphaeroides and soybean phospholipids. The reconstituted vesicles showed a photooxidation of reaction center bacteriochlorophyll and a light-induced spectral shift of carotenoid to longer wave-lengths. The red shift similar to that in intact cells or chromatophores, indicates the generation of local fields in the membrane of proteoliposomes. When inside-positive membrane potential was induced by adding valinomycin and potassium salt, a shift of carotenoid spectrum to shorter wavelengths was observed. Therefore, the reconstituted vesicles, at least in the major part of population, produced the light-induced local field in the same direction as in intact cells, which is inside negative. Sidedness of the membrane structure and the direction of electric field formation in reconstituted vesicles were opposite to those in chromatophores (inside-out vesicles.     

Sidedness of membrane structures in Rhodopseudomonas sphaeroides. Electrochemical titration of the spectrum changes of carotenoid in spheroplasts,spheroplast membrane vesicles and chromatophores

The shift of the carotenoid absorption spectrum induced by illumination and valinomycin-K⁺ addition was investigated in membrane structures with different characteristics and opposite sidednesses isolated from Rhodopseudomonas sphaeroides. Right-side-out membrane structures were prepared by isotonic lysozyme-EDTA treatment of the cells (spheroplasts) and by hypotonic treatment of spheroplasts (spheroplast membrane vesicles). Inside-out membrane structures (“chromatophores”) were obtained by treating spheroplast membrane vesicles by French press or sonication.The membrane structures with either sidedness showed the same light-induced change of the “red shift” type. However, the absorbance change by K⁺ addition in the presence of valinomycin in the right-side-out membrane structures were opposite to that in the inverted vesicles, “blue shift” in the former and “red shift” in the latter. The carotenoid absorbance change was linear to membrane potential, calculated from the concentration of KCl added, with a reference on the cytoplasmic side, through positive and negative ranges.     

Oxonol dyes as monitors of membrane potential. Their behavior in photosynthetic bacteria.

The reponses of oxonol dyes to single and multiple single turnovers of the photosynthetic apparatus of photosynthetic bacteria have been studied, and compared with the responses of the endogenous carotenoid pigments. The absorbance changes of the oxonols can be conveniently measured at 587 nm, because this is an isosbestic point in the 'light-minus-dark' difference spectrum of the chromatophores. The oxonols appear to respond to the light-induced 'energization' by shifting their absorption maxima. In the presence of K+, valinomycin abolished and nigericin enhanced such shifts, suggesting that the dyes, respond to the light-induced membrane potential. Since the dyes are anions at neutral pH values, they probably distribute across the membrane in accordance with the potential, which is positive inside the chromatophores. The accumulation of dye, which is indicated by a decrease in the carotenoid bandshift, poises the dye-membrane equilibrium in favor of increased dye binding and this might be the cause of the spectral shift. The dye response has an apparent second-order rate constant of approx. 2 . 10(6) M-1 . s-1 and so is always slower than the carotenoid bandshift. Thus the dyes cannot be used to monitor membrane potential on submillisecond timescales. Nevertheless, on a timescale of seconds the logarithm of the absorbance change at 587 nm is linear with respect to the membrane potential calibrated with the carotenoid bandshift. This suggests that under appropriate conditions the dyes can be used with confidence as indicators of membrane potential in energy-transducing membranes that do not possess intrinsic probes of potential.     

The light-induced carotenoid absorbance changes in Rhodopseudomonas sphaeroides: an analysis and interpretation of the band shifts.

An analysis has been made of the spectrum of the carotenoid absorption band shift generated by continuous illumination of chromatophores of the GlC-mutant of Rhodopseudomonas sphaeroides at room temperature by means of three computer programs. There appears to be at least two pools of the same carotenoid, only one of which, comprising about 20% of the total carotenoid content, is responsible for the light-induced absorbance changes. The 'remaining' pool absorbs at wavelengths which were about 5 nm lower than those at which the 'changing' pool absorbs. This difference in absorption wavelength could indicate that the two pools are influenced differently by permanent local electric fields. The electrochromic origin of the absorbance changes has been demonstrated directly; the isosbestic points of the absorption difference spectrum move to shorter wavelengths upon lowering of the light-induced electric field. Band shifts up to 1.7 nm were observed. A comparison of the light-induced absorbance changes with a KCl-valinomycin-induced diffusion potential has been used to calibrate the electrochromic shifts. The calibration value appeared to be 137 +/- 6 mV per nm shift.     

The light-induced carotenoid absorbance changes in Rhodopseudomonas sphaeroides. An analysis and interpretation of the band shifts

An analysis has been made of the spectrum of the carotenoid absorption band shift generated by continuous illumination of chromatophores of the GlC-mutant of Rhodopseudomonas sphaeroides at room temperature by means of three computer programs. There appears to be at least two pools of the same carotenoid, only one of which, comprising about 20 % of the total carotenoid content, is responsible for the light-induced absorbance changes. The ‘remaining’ pool absorbs at wavelengths which were about 5 nm lower than those at which the ‘changing’ pool absorbs. This difference in absorption wavelength could indicate that the two pools are influenced differently by permanent local electric fields.

The electrochromic origin of the absorbance changes has been demonstrated directly; the isosbestic points of the absorption difference spectrum move to shorter wavelengths upon lowering of the light-induced electric field. Band shifts up to 1.7 nm were observed. A comparison of the light-induced absorbance changes with a KCl-valinomycin-induced diffusion potential has been used to calibrate the electrochromic shifts. The calibration value appeared to be 137 ± 6 mV per nm shift.     

Surface potential on the periplasmic side of the photosynthetic membrane of Rhodopseudomonas sphaeroides

Membrane surface potential on the periplasmic side of the photosynthetic membrane was estimated in cells, spheroplasts and chromatophores of Rhodopseudomonas sphaeroides. When the membrane potential (potential difference between bulk aqueous phases) was kept constant in the presence of carbonylcyanide m-chlorophenylhydrazone, addition of salt to a suspension of cells or spheroplasts induced a red shift in the carotenoid absorption spectrum which indicated a change in the intramembrane electrical field. The spectral shift is explained by a rise in electrical potential at the outside surface of the photosynthetic membrane due to a decrease in extent of the negative surface potential.The spectral shift occurred in the direction opposite to that in chromatophores, indicating that the sidedness of the membrane of cells or spheroplasts is opposite to that of chromatophores. The dependences of the extent of the potential change on concentration and valence of cations of salts agreed with the Gouy-Chapman relationship on the electrical diffuse double layer. The charge density on the periplasmic surface of the photosynthetic membrane was estimated to be ?2.9 · 10^?3 elementary charge per Ų, while that on the cytoplasmic side surface was calculated as ?1.9 · 10^?3 elementary charge per Ų (Matsuura, K., Masamoto, K., Itoh, S. and Nishimura, M. (1979) Biochim. Biophys. Acta 547, 91–102). Surface potential on the periplasmic side of the photosynthetic membrane was estimated to be about ?50 mV at pH 7.8 in the presence of 0.1 M monovalent salt.     

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.     

Sidedness of membrane structures in Rhodopseudomonas sphaeroides. Electrochemical titration of the spectrum changes of carotenoid in spheroplasts, spheroplast membrane vesicles and chromatophores.

The shift of the carotenoid absorption spectrum induced by illumination and valinomycin-K+ addition was investigated in membrane structures with different characteristics and opposite sidednesses isolated from Rhodopseudomonas sphaeroides. Right-side-out membrane structures were prepared by isotonic lysozyme-EDTA treatment of the cells (spheroplasts) and by hypotonic treatment of spheroplasts (spheroplast membrane vesicles). Inside-out membrane structures ("chromatophores") were obtained by treating spheroplast membrane vesicles by French press or sonication. The membrane structures with either sidedness showed the same light-induced change of the "red shift" type. However, the absorbance change by K+ addition in the presence of valinomycin in the right-side-out membrane structures were opposite to that in the inverted vesicles, "blue shift" in the former and "red shift" in the latter. The carotenoid absorbance change was linear to membrane potential, calculated from the concentration of KCl added, with a reference on the cytoplasmic side, through positive and negative ranges.     

Ionophore-sensitive spectral shift of carotenoid induced by ferricyanide in chromatophores from Rhodopseudomonas sphaeroides

In chromatophores from Rhodopseudomonas sphaeroides, ferricyanideinduced a change in the absorption spectrum of carotenoid. Theionophore-sensitive part of the ferri-cyanide-induced changewas similar to that induced by light or by diffusion potential.The ferricyanide-induced change is explained by the electrochromicshift of the carotenoid spectrum by the inside-positive electricalfield change which is probably caused by the electrogenic electronflow from a membrane redox component to ferricyanide in theouter aqueous phase. The ionophore-insensitive part is probablythe response of the carotenoid in another pool to the localfield change by oxidation of bacteriochlorophyll [Okada, M.and A. Takamiya (1970) Plant & Cell Physiol. 11: 713–721]. (Received January 21, 1980; )     

Fusion of chromatophores derived from Rhodopseudomonas sphaeroides

Fusion of chromatophores, the photosynthetic membrane vesicles isolated from the intracytoplasmic membranes of Rhodopseudomonas sphaeroides, was achieved by the use of poly(ethylene glycol) 6000 as fusogen. Ultracentrifugation, electron microscopy, intrinsic density and isotope labeling were used to demonstrate chromatophore fusion. Although studies of the flash-induced shift in the carotenoid absorbance spectrum indicated that the membrane was rendered leaky to ions by either the fusion procedure or the increased size of the fused products, the orientation and integrity of fused chromatophores were otherwise demonstrated to be identical to control chromatophores by freeze-fracture electron microscopy, proteolytic enzyme digestion, enzymatic radioiodination, and transfer of chromatophore phospholipids mediated by phospholipid exchange protein extracted from Rps. sphaeroides.     

Ferricyanide-induced absorbance change of carotenoid in chromatophores of Rhodopseudomonas spheroides correlated to the oxidation of bacteriochlorophyll 885

Addition of high concentrations (e.g., 1–100 mM) of ferricyanideto a chromatophorc suspension of Rhodopseudomonas spheroidescaused a change in the absorption spectrum of carotenoid (spheroidene),which was completely reversed by adding reducing reagents suchas ferrocyanide and ascorbate. The spectral change is representedby a shift in the absorption spectrum of carotenoid by 2 to2.5 nm towards the longer wavelength side. The presence of piericidinA, o-phenanthroline or Cl-CCP in the reaction mixture did notaffect the ferricyanide-induced absorbance change. Triton X-100markedly suppressed the magnitude of the change. The additionof ferricyanide also caused simultaneous absorbance changeswith maxima at 590 and 885 nm. These are ascribed to oxidationof the (bulk) bacteriochlorophyll, BChl 885. There was no absorptionchange at other peaks of bacteriochlorophyll in the infraredregion (i.e., 800 and 855 nm). Therefore, the ferricyanide-inducedabsorbance change of carotenoid did not represent an oxidation-reductionreaction of carotenoid but was intimately correlated with oxidationof BChl 885 in the chromatophores, as judged from similaritiesobserved with respect to the time course patterns, midpointpotential (545–555 mv) in the ferriferrocyanide reactionsystem, as well as behavior towards various reagents and inhibitorsadded. A similar change of carotenoid (i.e., 2–2.5 nmshift of absorption spectrum) was caused by addition of MgCl₂to the chromatophores, but this did not induce any change inthe absorption spectrum of bacteriochlorophyll. The nature ofthe spectral change of carotenoid in chromatophores is discussed. (Received April 16, 1970; )     

A study on the membrane potential and pH gradient in chromatophores and intact cells of photosynthetic bacteria

Generation of membrane potential (Δψ) and transmembrane pH difference (ΔpH) was studied in PP_i-energized chromatophores of Rhodospirillum rubrum by means of measurements of carotenoid and bacteriochlorophyll absorption changes, atebrin and 8-anilinonaphthalene-1-sulphonate fluorescence responses, and phenyldicarbaundecaborane transport.The data obtained are consistent with the suggestion that carotenoid, bacteriochlorophyll and phenyldicarbaundecaborane responses are indicators of Δψ, while an atebrin response is an indicator of ΔpH. The fluorescence of 8-anilinonaphthalene-1-sulphonate is affected both by Δψ and ΔpH.     

Generation of membrane potential during photosynthetic electron flow in chromatophores from Rhodopseudomonas capsulata

1. When cytochrome c₂ is available for oxidation by the photosynthetic reaction centre, the decay of the carotenoid absorption band shift generated by a short flash excitation of Rhodopseudomonas capsulata chromatophores is very slow (half-time approximately 10 s). Otherwise the decay is fast (half-time approximately 1 s in the absence and 0.05 s in the presence of 1,10-ortho-phenanthroline) and coincides with the photosynthetic back reaction.2. In each of these situations the carotenoid shift decay, but not electron transport, may be accelerated by ioniophores. The ionophore concentration dependence suggests that in each case the carotenoid response is due to a delocalised membrane potential which may be dissipated either by the electronic back reaction or by electrophoretic ion flux.3. At high redox potentials, where cytochrome c₂ is unavailable for photo-oxidation, electron transport is believed to proceed only across part of the membrane dielectric. Under such conditions it is shown that the driving force for carbonyl cyanide trifluoromethoxyphenyl hydrazone-mediated H⁺ efflux is nevertheless decreased by valinomycin/K⁺; demonstrating that the [BChl]₂ → Q electron transfer generates a delocalised membrane potential.