Electrical potential changes in the surface and the central region of chromatophore membranes of photosynthetic bacteria detected by the absorbance changes of ethidium and carotenoid

(1) Changes of local intramembrane electrical field in the surface and central region of the chromatophore membrane during energization were studied both by the measurement of absorbance changes of ethidium, a monovalent cationic dye, and of carotenoid, the intrinsic probe of electrical field. (2) Binding of ethidium to the chromatophore membrane of Rhodopseudomonas sphaeroides was found to be dependent on the energization of membrane as well as on the ionic condition of the medium. The dye was released from the membrane when salt was added to the suspension, indicating the electrostatic interaction between the positive dye and the net negative membrane surface. The result was explained by the surface-potential dependent distribution of the dye to the membrane surface, as seen with other charged dyes (Masamoto, K., Matsuura, K., Itoh, S. and Nishimura, M. (1981) Biophys. Acta 638, 108–115). (3) Energization of chromatophores by flash-light-induced absorbance change of ethidium showing a similar difference spectrum to that induced by the addition of salts. The release of ethidium by a single turn-over flash of saturating intensity was estimated to be 0.22 ethidium per reaction center. Addition of ethidium (at 200 μM) slightly affected the flash-induced absorbance change of carotenoid which responds to the intramembrane electricalfield change, indicating a low-membrane permeability of the dye. The extent of the absorbance change of ethidium was linear to that of carotenoid, and was abolished in the presence of valinomycin plus K⁺. However, the rise and decay kinetics of the absorbance change of ethidium was different from that of carotenoid. (4) These absorbance changes of ethidium and carotenoid can be explained by a model in which ethidium responds to the potential changes in the surface region and carotenoid in the central hydrophobic region of the chromatophore membrane.     

Membrane-potential- and surface-potential-induced absorbance changes of merocyanine dyes added to chromatophores from Rhodopseudomonas sphaeroides

(1) Three analogs of merocyanine dyes added to suspensions of chromatophore vesicles showed absorbance changes responding to the change in surface potential induced by salt addition and to the change in membrane potential induced by illumination. (2) The extent of the light-induced absorbance changes of the dyes was linearly related, in the presence and absence of uncouplers, to that of carotenoid spectral shift which is an intrinsic probe of the intramembrane electric field. (3) Comparison of the merocyanine absorbance changes induced by salt addition with those induced by illumination indicated that the surface potential change in the outer surface of chromatophore membranes during illumination was very small. (4) Judging from the spectra of these absorbance and from the low permeabilities of the dyes to membrane, the absorbance change are attributed to change in distribution of the dyes between the medium and the outer surface region in chromatophore membranes. The extent of the light-induced absorbance changes of merocyanine dyes depended on the salt concentration of the medium. The types of dependence were different among three merocyanine analogs. This is explained by the mechanism mentioned above assuming appropriate parameters. It is suggested that, under continuous illumination, an equilibrium of the electrochemical potential of H⁺ is reached between the bulk aqueous phase and the outer surface region in the membrane where the merocyanine dyes are distributed.     

The surface and membrane potentials of chromatophores of photosynthetic bacteria as studied by carotenoid absorbance changes

The change in surface potential induced by addition of mono- or divalent cations to a chromatophore suspension was monitored by carotenoid absorbance changes (a probe which is intrinsic to the membrane). The change in carotenoid absorbance elicited by an alteration of the surface potential is strongly dependent on the presence of ionophores; the absorbance changes (due to addition of MgCl₂) in the presence of valinomycin or gramicidin are larger than those in the presence of carbonyl cyanide m-chlorophenylhydrazone or cabonyl cyanide p-trifluoromethoxyphenylhydrazone. These differences in carotenoid absorbance change reflect the degree in which the membrane resistance has been shunted. Gramicidin or high concentrations of valinomycin (10⁻⁶ M) appear to be sufficiently effective as shunt in order that the totality of the change in external surface potential is seen as an intramembrane potential difference as sensed by the carotenoids. It is also shown that the decay of the carotenoid changes induced by the addition of salt to the medium is a measure of the intrinsic permeability of the chromatophore membrane for the added cation.     

Light-induced blue shift of the carotenoid spectrum in chromatophores of Chromatium vinosum strain D

In Chromatium chromatophores, the response of part of the carotenoid complement to a light-induced membrane potential is a shift to the blue of its absorption spectrum, as indicated by the characteristics of the light-minus-dark difference spectrum. The spectrum in the dark of the population of carotenoid which responds to a light-induced membrane potential is located at least 1–2 nm to the red in comparison to the total carotenoid absorption. The results indicate that the proposed permanent electric field affecting the responding population has a polarity with respect to the chromatophore membrane opposite to that in Rhodopseudomonas sphaeroides chromatophores. The carotenoid absorption change interferes seriously with measurements of cytochrome c-555 redox changes at its α band.     

Light-induced absorption spectrum changes of carotenoid in chromatophores of photosynthetic bacterium, Rhodopseudomonas spheroides II. Rapid and slow absorption changes of carotenoid in chromatophores

Time courses of light-induced absorption changes of carotenoid(spheroidene) in chromatophores of the photosynthetic bacterium,Rhodopseudomonas spheroides, consisting of an 8–10 nm-shiftin the carotenoid absorption spectrum towards the longer wavelength,were investigated. The whole time course of absorption changecan be expressed as the sum of two first order reactions; arapid change accomplished in several msec after the onset ofillumination with actinic light (800–900 nm) and a slowchange extending over the whole period (200 msec). The rapidchange required a high light intensity, whereas the slow changewas saturated at relatively low light intensity (ca. 5xl0³ erg/cm²sec). Electron transport inhibitors (HOQNO, piericidin A and o-phenanthroline)and Cl-CCP, at concentrations uncoupling photophosphorylation(10^–M), inhibited slow change but did not affect rapidchange. The rapid change was inhibited by higher concentrationsof Cl-CCP (10–4 M) and by o-phenanthroline in the concomitantpresence of an uncoupling concentration of Cl-CCP. The rapidand slow changes have midpoint potentials of 440 and 420 mv,respectively; as calculated from absorption changes in the presenceof ferri- and ferrocyanide mixtures. Relationships between absorptionspectrum changes and other reactions in the chromatophores wereanalyzed. Slow absorption change is closely related to the highenergy intermediate, or state, of photophosphorylation. Rapidabsorption change, with a midpoint potential of 440 mv, is relatedto the electron flow mediated by P870; although it does notdirectly reflect the state of P870, itself. ¹ This article is the second of a series published under thesame title in this journal, volume 11 (1970) p. 519–530. ² Present address: Department of Biology, Faculty of Science,Toho University, Narashino City, Chiba 275, Japan. (Received October 30, 1970; )     

Effect of Intracellular ATP Levels on the Light-Induced H+ Efflux from Intact Cells of Cyanidium caldarium

The light-induced H⁺ efflux observed at acidic pH in Cyanidiumcells was shown to be an active H⁺ transport depending on theintracellular ATP produced by cyclic photo-phosphorylation.Triton X-100 was found to act as an effective uncoupler in intactCyanidium cells without collapsing the pH gradient across theplasma membrane. Triton X-100 at 0.015% significantly reducedthe intracellular ATP levels, stimulated the p-BQ, Hill reactionand completely inhibited the light-induced H⁺ efflux. Inhibitionof the H⁺ efflux by Triton X-100 correlated well with the depressionof the apparent rale of light-induced ATP synthesis as wellas the decrease in the intracellular ATP level in light. The light-induced H⁺ efflux was completely inhibited by diethylstilbestrol,a specific inhibitor of plasma membrane ATPase, without anychanges in the intracellular ATP level, thereby suggesting theparticipation of the plasma membrane ATPase in the light-inducedH⁺ efflux. ¹The data in this paper are included in the Ph. D. dissertationsubmitted by M. Kura-Hotta to Tokyo Metropolitan University. (Received February 3, 1984; Accepted June 14, 1984)     

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.     

Anion-dependent changes of energy transfer in chloroplasts II. Relationships of the coupling factor to light-induced proton transport and absorbance change at 515 nm

Roles of the coupling factor in light-induced proton transportand 515-nm absorption change were investigated in chloroplastswashed with high concentrations of Tris salts (pH 7.2). Washingthe chloroplasts with Tris-HCl and Tris-HNO₃ buffers diminishedboth the light-induced pH rise and absorbance change at 515-nm,while Tris-H₂SO₄ buffer was much less effective. Inhibited activitiescould be restored by replacement of the coupling factor afterextraction with EDTA. N,N'-dicyclohexylcarbodiimide also restoredboth activities. Effects of various anions on the proton pumpand 515-nm shift were also investigated. The order of effectivenesswas NO₃^–>Cl^–>SO₄^2–. The role of thecoupling factor and its mode of action; the action mechanismsof Tris and anionsn energy transducing processes in chloroplasts,photophosphorylation, proton transport and absorbance changeat 515 nm, are discussed. ¹Present address: Biology Department, College of Science andEngineering, Ryukyu University, Naha, Okinawa, Japan. (Received June 27, 1972; )     

Quantum yield and conformational changes during greening and bleaching of Chlorella protothecoides

Measurements of quantum requirement of oxygen evolution in greeningand bleaching cultures of Chlorella proiothecoides reveal aconstant low-quantum requirement during greening and the firsthours of bleaching. Thereafter the values increase drastically. The light-induced "conformational change," measured as straylight-dependent absorbance change, is biphasic; the second partof die signal is due to the absorbance changes caused by theshrinking of the chloroplast. Its value was used as a measureof photophosphorylation, which follows, after a certain delay,the photosynthetic oxygen evolution during greening and bleachingofthe cells. ¹ Present address: Institute of Applied Microbiology, Universityof Tokyo, 113 Tokyo, Japan. (Received January 27, 1976; )     

Light-induced absorbance change of carotenoid in chromatophores of photosynthetic bacterium, Rhodopseudomonas spheroides

The nature of the light-induced absorbance change of carotenoid,spheroidene, was investigated with the chromatophores of Rhodopseudomonasspheroides. The experimental results indicate that the changedoes not represent an oxidation-reduction reaction of the carotenoid,but is caused by a change in the state of the chromatophoresclosely related to the high energy state of the photophosphorylation.Since the change almost vanishes at liquid nitrogen temperature,it probably does not represent a primary photochemical reactionin the chromatophores. The values of the quantum yield for thechange of carotenoid were above unity ; 2.5 on an avera (Received November 20, 1969; )     

Demonstration of Voltage Dependency of Light-induced Potential Change in Chara

The electromotive force (E_m) of the plasma membrane of the tonoplast-freecell of Chara australis decreased when the electrogenic pumpwas stopped by removing ATP or Mg²⁺ from the cell. Such a cellshowed a rapid light-induced potential change (rLPC). Threefactors were considered to be responsible for the generationof rLPC; removal of Mg-ATP, stoppage of the electrogenic pumpand membrane depolarization per se. Tonoplast-free cells having enough Mg-ATP occasionally showedsmall E_m (–87— –116 mV) due to stoppage ofthe electrogenic pump. Since the rLPC was induced in such cells,removal of Mg-ATP cannot be the factor. Cells having large E_mdue to active pump activity also showed rLPC when the potentialdifference across the plasma membrane (V_m) was depolarized byan outward electric current; evidence that not the stoppageof the pump but membrane depolarization is a necessary conditionfor the generation of rLPC. In the rLPC Vm always changed in the negative direction. However,calculation of E_m revealed the existence of a reversal potential[ (E_m)rev] toward which E_m converged from either more negativeor more positive values. The (E_m)rev approximately coincidedwith the equilibrium potential for K⁺ across the plasma membrane.Intracellular anions occupying lower positions in the lyotropicseries inhibited rLPC. (Received February 9, 1981; Accepted May 16, 1981)     

Energy conversion and changes in physical parameters in chloroplasts and subchloroplast particles II. Energy conversion in chloroplasts and different types of subchloroplast particles

The light-induced absorbance change at 515 nm, light-inducedhydrogen ion uptake and ATP formation were compared in chloroplastsand different types of sonicated subchloroplast particles. Noparallel relationship among the activities for ATP formation,hydrogen ion uptake and the 515-nm change was observed in differenttypes of preparations. NH₄Cl inhibited ATP formation in chloroplastsbut had little effect on subchloroplast particles. In contrast,the light-induced hydrogen ion uptake was inhibited by NH₄Clin a similar manner. Tetraphenylboron (TPB), at 1 µM, inhibited ATP formationby about 30% in both chloroplasts and subchloroplast particles.In the presence of TPB, ATP formation in chloroplasts was stronglyinhibited by NHC₄Cl, but in subchloroplast particles the additionalinhibitory effect of NH₄Cl was small. A synergistic inhibitionof photophosphorylation by valinomycin plus NH₄Cl was much clearer.Although acceleration of the recovery of the 515-nm change byNH₄Cl or valinomycin was moderate, the 515-nm change virtuallydisappeared when NH₄Cl and valinomycin were added simultaneously. Although the membrane potential has a major role as the principaldriving force for ATP formation in subchloroplast particles,the simultaneous abolishment of the pH gradient and membranepotential may be required to uncouple ATP formation. ¹Present address: Fukuoka Women's University, Kasumigaoka, Fukuoka813, Japan. ²Present address: Ryukyu University, Naha, Okinawa 903, Japan. (Received February 5, 1974; )     

Correlation of membrane-potential-sensing carotenoid to pigment-protein complex II in Rhodopseudomonas sphaeroides

The changes in carotenoid absorbance induced by illumination or by a diffusion potential were larger in chromatophores from cells cultured under low light intensity than those in chromatophores from high-light culture in a photosynthetic bacterium, Rhodopseudomonas sphaeroides. The carotenoid molecules which are associated with the pigment-protein complex (with the infrared bacteriochlorophyll peaks at 800 and 850 nm) (complex II) probably respond to the electrical field changes in the chromatophore membrane.     

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.     

Transient light-induced changes in ion channel and proton pump activities in the plasma membrane of tobacco mesophyll protoplasts

Rapid, transient changes of the membrane potential upon lighttransitions are generally observed in microelectrode studies.In a patch-clamp study similar responses to light transitionswere found in current clamp. Corresponding with the changesof membrane potential, light-induced current changes in voltageclamp were observed. This paper evaluates the involvement ofoutward rectifying conductances and plasma membrane bound H⁺-ATpases(proton pump) to these light responses in mesophyll protoplastsof Nicotiana tabacum L. The contribution of K⁺-channels to theseresponses, could be minimized by variation of the holding potentialor addition of the K⁺-channel blocker verapamil. It was concludedthat light transitions modulate both proton pump and K⁺-channelactivity. Effects of light on membrane current were not observedin root cells and chlorophyll-deficient cells, suggesting thatthe response requires photosynthetic activity. However, blockersof photosystems I and II did not affect current changes. Key words: Light, patch-clamp, plasma membrane, tobacco, whole cell     

H+ tolerance of Chara Internodal Cells and Apparent Net Influx of H+ in Weakly Acidic Solutions: Implication of the Net Flux of H+ as a Minor Component among the Total Net Flux of Ions across the Intact Cell Membrane of Chara

Precise measurements of the net flux of protons in Chara internodalcells were made with a recently designed high-resolution pH-meter.Survival of intact Chara internodal cells in artificial pondwater (APW) that contained HC1 at various concentrations wasalso examined. The apparent net flux of H⁺ was inward and muchsmaller than that reported so far. In APW at pH 4.005, a valuehigher than the extracellular pH expected from the values ofH⁺ efflux reported to date, all of the intact Chara internodalcells died within a day. With reference to the data on the circadianflow of ions in the pulvinus of Phaseolus [Kiyosawa (1979) PlantCell Physiol. 20: 1621–1634, Hosokawa and Kiyosawa (1983)Plant Cell Physiol. 24: 1065–1072] and ionic regulationin Chara L-cells [Kiyosawa and Okihara (1988) Plant Cell Physiol.29: 9–19], a discussion is presented of the prossiblyminor contribution of the net flux of H⁺ in the generation ofthe electrical membrane potential. Regulation of the net fluxof H⁺ in weakly acidic APW is also discussed. (Received September 4, 1989; Accepted January 25, 1990)     

Light-induced Changes of the Electrical Potential in Chloroplasts Associated with the Activity of Photosystem I and Photosystem II

The electric potential changes induced by flashing and continuouslight were measured with microcapillary electrodes in isolatedwhole chloroplasts of Peperomia inetallica. In continuous lightthe chloroplast electrical potential rose in two phases. Theinitial rapid phase coincided in extent with the flash-inducedpotential and was insensitive to the electron transfer inhibitorDBMIB. The subsequent phase was relatively slow (20–30ms) and was inhibited by DBMIB. Electron acceptors of photosystemII (p-phenylendiamine, p-benzoquinone) added to DBMIB-treatedchloroplasts produced a suppression of the flash-induced responseand a considerable increase in the steady level of the potentialin the light. The electrical potential associated with the activityof photosystem II rose in continuous light much more slowlythan that associated with the activity of photosystem I aloneor the activities of both photosystems. Illumination of chloroplastswith successive flashes at a repetition rate 5 Hz in the presenceof oxaloacetate, a terminal acceptor of photosystem I, was accompaniedwith a gradual decline of the flash-induced potential. The specificrole of two photosystems in the light-induced H⁺ transport andthe electrogenesis across the chloroplast thylakoid membranesis discussed.     

Effect of pH on the Membrane Potential and Electrical Resistance of Nitella flexilis in the Presence of Calcium

Effects of pH on the membrane potential and electrical resistanceof Nitella were investigated in a bathing medium with or withoutcalcium. The membrane potential became more negative as theexternal pH was raised, at a faster rate in the presence ofcalcium than in its absence. The value then achieved by thepotential could be reversed by restoring the original pH whilstin a Ca-free medium the cell remained ‘hyperpolarized’.Tenfold changes of the external concentration of potassium broughtabout larger modifications of the membrane potential when thepH of the solution was high and calcium concentration low. Theelectrical resistance was lowest in alkaline and calcium-freesolutions. We conclude that calcium prevents the mediation ofsome changes in the membrane structure by lowering the concentrationof external H⁺ ions, and that the permeability of Nitella topotassium increases with rising pH.     

Study of electrogenic electron transfer steps in chromatophore membrane of Chromatium vinosum by the response of merocyanin dye

1. Electrogenic steps in photosynthetic cyclic electron transport in chromatophore membrane of Chromatium vinosum were studied by measuring absorption changes of added merocyanin dye and of intrinsic carotenoid.

2. The change in dye absorbance was linear with the membrane potential change induced either by light excitation or by application of diffusion potential by adding valinomycin in the presence of K⁺ concentration gradient.

3. It was estimated that chromatophore membrane became 40–60 mV and 110–170 mV inside positive upon single and multiple excitations with single-turnover flashes, respectively, from the responses of the dye and the carotenoid.

4. Electron transfers between cytochrome c-555 or c-552 and reaction center bacteriochlorophyll dimer (BChl₂) and between BChl₂ and the primary electron acceptor were concluded to be electrogenic from the redox titration of the dye response.

5. No dye response which corresponded to the change of redox level of cytochrome b was observed in the titration curve. Addition of antimycin A slightly decreased the dye response.

6. The dye response was decreased under phosphorylating conditions.

7. From the results obtained localization of the electron transfer components in chromatophore membrane is discussed.     

Turgor Regulation in a Brackish Charophyte, Lamprothamnium succinctum II. Changes in K$, Na$ and Cl- Concentrations, Membrane Potential and Membrane Resistance during Turgor Regulation

A brackish Characeae, Lamprothamnium succinctum, regulates intracellularosmotic pressure in response to changes in the external salinityand keeps the turgor pressure constant. The osmotic pressureof the vacuole was found to be mostly due to K^$, Na^$ and Cl^–.But in the cytoplasm, the sum of their concentrations was muchlower than the cellular osmotic pressure. Electroneutralitywas maintained among the analyzed inorganic ions in the vacuolebut a strong anion deficiency was detected in the cytoplasm,supporting the existence of organic anions to balance excesspositive charges. During turgor regulation, concentrations of inorganic ions inthe vacuole changed just enough to accommodate the osmotic pressurechange, while those in the cytoplasm remained almost constant.Since the cytoplasmic volume was almost constant during turgorregulation, some organic molecule(s) may have contributed tothe osmoregulation of the cytoplasm. The membrane potential and resistance at steady state underdifferent salinities were almost constant. Hypotonic treatmentcaused a sudden depolarization of the membrane potential anda drastic decrease in membrane resistance. Hypertonic treatmentcaused a slow hyperpolization of membrane potential but didnot significantly affect the membrane resistance. The energeticsof K^$ and Cl^– movements across the plasma membrane isdiscussed based upon the electrochemical potential gradients. (Received November 28, 1983; Accepted March 14, 1984)