Thermodynamic properties of the reaction center of Rhodopseudomonas viridis. In vivo measurement of the reaction center bacteriochlorophyll-primary acceptor intermediary electron carrier.

The thermodynamic properties of redox components associated with the reaction center of Rhodopseudomonas viridis have been characterized with respect to their midpoint potentials and relationship with protons. In particular a midpoint potential for the intermediary electron carrier acting between the reaction center bacteriochlorophyll and the primary acceptor has been determined. The rationale for this measurement was that the light-induced triplet/biradical EPR signal would not be observed if this intermediate was chemically reduced before activation. The midpoint potential of the intermediary at pH 10.8 is about --400 mV (n=1).     

Effect of reduction of the reaction center intermediate upon the picosecond oxidation reaction of the bacteriochlorophyll dimer in Chromatium vinosum and Rhodopseudomonas viridis

The photo-oxidation of the reaction center bacteriochlorophyll dimer or special pair was monitored at 1235 nm in Chromatium vinosum and at 1301 nm in Rhodopseudomonas viridis. In both species, the photo-oxidation was apparently complete within 10 ps after light excitation and proceeded unimpeded at low temperatures regardless of the prior state of reduction of the traditional primary electron acceptor, a quinone-iron complex. Thus the requirement for an intermediary electron carrier (I), previously established by picosecond measurements in Rps. sphaeroides (see ref. 4), is clearly a more general phenomenon.

The intermediary carrier, which involves bacteriopheophytin, was examined from the standpoint of its role as the direct electron acceptor from the photo-excited reaction center bacteriochlorophyll dimer. To accomplish this, the extent of light induced bacteriochlorophyll dimer oxidation was measured directly by the picosecond response of the infrared bands and indirectly by EPR assay of the triplet/biradical, as a function of the state of reduction of the I/I couple (measured by EPR) prior to activation. Two independent methods of obtaining I in a stably reduced form were used: chemical equilibrium reduction, and photochemical reduction. In both cases, the results demonstrated that the intermediary carrier, which we designate I, alone governs the capability for reaction center bacteriochlorophyll photooxidation, and as such I appears to be the immediate and sole electron acceptor from the light excited reaction center bacteriochlorophyll dimer.     

Extraction of oxidized bacteriochlorophyll from illuminated photosynthetic reaction center particles

Illuminated and dark-adapted reaction center particles from Rhodopseudomonas spheroides were extracted with methanol, and the spectra of the extracts were compared. Spectra of extracts of illuminated reaction center particles showed less absorption due to bacteriochlorophyll than did spectra of extracts of dark-adapted reaction center particles. The lost absorption in extracts of illuminated reaction center particles was restored by the addition of ascorbate. This showed that these extracts contained oxidized bacteriochlorophyll which could be rereduced in vitro. The spectrum of the restored absorption was different from that of the original bacteriochlorophyll, indicating that an alteration of the oxidized bacteriochlorophyll had taken place. This apparent alteration may have been due to the presence of the detergent lauryl-dimethylamine oxide in the extracts. However, equilibration of the protein with this detergent may have been a requirement for the extraction of photooxidized bacteriochlorophyll.     

Purification and characterization of the photochemical reaction center of the thermophilic purple sulfur bacterium Chromatium tepidum

Pure reaction center preparations from the thermophilic species Chromatium tepidum have been obtained by lauryldimethylamine N-oxide treatment of chromatophores. The light-induced difference spectrum in presence of 10 mM sodium ascorbate revealed the presence of two high-potential cytochrome c hemes (-band, 555 nm; γ-band, 422 nm). The dithionite-minus-oxidized difference spectrum in the -band suggests the presence of additional hemes of low potential. These hemes are associated with a single polypeptide (M_r = 36 000). The reaction center pigments, probably four bacteriochorophyll a and two bacteriopheophytin a molecules, are associated with three polypeptides of apparent molecular weights equal to 33 000, 30 000 and 22 000. A carotenoid molecule is also bound to the reaction center. The three main absorption bands of this molecule are located at 480, 510 and 530 nm at liquid helium temperature. Photochemical activity is found to be stable, even after heating for 10 min at temperatures higher than 60 °C in intact chromatophore membranes. On the other hand, isolated reaction centers or chromatophores treated with 1% lauryldimethylamine N-oxide are fully inactivated after heating at temperatures higher than 50 °C. From these results, we propose that lipid-protein interactions are of prime importance in the thermal stabilization of Chromatium tepidum reaction centers.     

Structural and functional characterization of the unusual triheme cytochrome bound to the reaction center of Rhodovulum sulfidophilum

The cytochrome bound to the photosynthetic reaction center of Rhodovulum sulfidophilum presents two unusual characteristics with respect to the well characterized tetraheme cytochromes. This cytochrome contains only three hemes because it lacks the peptide motif CXXCH, which binds the most distal fourth heme. In addition, we show that the sixth axial ligand of the third heme is a cysteine (Cys-148) instead of the usual methionine ligand. This ligand exchange results in a very low midpoint potential (-160 +/- 10 mV). The influence of the unusual cysteine ligand on the midpoint potential of this distal heme was further investigated by site-directed mutagenesis. The midpoint potential of this heme is upshifted to +310 mV when cysteine 148 is replaced by methionine, in agreement with the typical redox properties of a His/Met coordinated heme. Because of the large increase in the midpoint potential of the distal heme in the mutant, both the native and modified high potential hemes are photooxidized at a redox poise where only the former is photooxidizable in the wild type. The relative orientation of the three hemes, determined by EPR measurements, is shown different from tetraheme cytochromes. The evolutionary basis of the concomitant loss of the fourth heme and the down-conversion of the third heme is discussed in light of phylogenetic relationships of the Rhodovulum species triheme cytochromes to other reaction center-associated tetraheme cytochromes.     

Physiological electron donors to the photochemical reaction center of Rhodobacter capsulatus

The nature and number of physiological electron donors to the photochemical reaction center of Rhodobacter capsulatus have been probed by deleting the genes for cytochromes c₁ and b of the cytochrome bc₁ complex, alone or in combination with deletion of the gene for cytochrome c₂. Deletion of cytochrome c₁ renders the organism incapable of photosynthetic growth, regardless of the presence or absence of cytochrome c₂, because in the absence of the bc₁ complex there is no cyclic electron transfer, nor any alternative source of electrons to rereduce the photochemically oxidized reaction center. While cytochrome c₂ is capable of reducing the reaction center, there appears no alternative route for its rereduction other than the bc₁ complex. The deletion of cytochromes c₁ and c₂ reveals previously unrecognized membrane-bound and soluble high potential c-type cytochromes, with E_m7 = + 312 mV and E_m6.5 = +316 mV, respectively. These cytochromes do not donate electrons to the reaction center, and their roles are unknown.     

Thermodynamic properties of the photochemical reaction center of Heliobacterium chlorum

The thermodynamic and spectral properties of the photochemical reaction center components of Heliobacterium chlorum have been examined. The primary electron donor bacteriochlorophyll has E_m,7 = +225 mV, and the ‘primary acceptor’ E_m,10 = −510 mV. The former has an EPR signal in its oxidised form near G = 2.0025, ΔH = 0.95 mT, reminiscent of the properties of the primary donor in bacteria containing bacteriochlorophyll a. The ‘primary acceptor’ has properties similar to those of the iron-sulfur cluster acceptors of green sulfur bacteria. H. chlorum contains a c-type cytochrome (E_m,7 = +170 mV) that donates electrons to the photooxidised primary donor with . The reaction center of H. chlorum is thus very similar to that found in representative green sulfur bacteria, but the cellular architecture and photopigments of this group are quite distinct from those of H. chlorum.     

P+HA- charge recombination reaction rate constant in Rhodobacter sphaeroides reaction centers is independent of the P/P+ midpoint potential.

The kinetics of the P+HA- (oxidized donor, reduced bacteriopheophytin acceptor) recombination reaction was measured in a series of reaction center mutants of Rhodobacter sphaeroides with altered P/P+ midpoint potentials between 410 and 765 mV. The time constant for P+HA- recombination was found to range between 14 and 26 ns and was essentially independent of P/P+ midpoint potential. Previous work has shown that the time constant for initial electron transfer in these mutants at room temperature is also only weakly dependent on the P/P+ midpoint potential, ranging from about 2.5 ps to about 50 ps. These results, taken together, imply that heterogeneity in the P/P+ midpoint potential within the reaction center population is not likely the dominant cause of the substantial kinetic complexity observed in the decay of the excited singlet state of P on the picosecond to nanosecond time scale. In addition, the pathway of P+HA- decay appears to be direct or via P+BA- rather than proceeding back through P, even in the highest-potential mutant, as is evident from the fact that the rate of P+HA- recombination is unaltered by pushing P+HA- much closer to P in energy. Finally, the midpoint potential independence of the P+HA- recombination rate constant suggests that the slow rate of P+HA- recombination arises from an inherent limitation in the maximum rate of this process rather than because it occurs in the inverted region of a classical Marcus rate vs free energy curve.     

Energy trapping and detrapping in reaction center mutants from Rhodobacter sphaeroides

Time-resolved fluorescence of chromatophores isolated from strains of Rhodobacter sphaeroides containing light harvesting complex I (LHI) and reaction center (RC) (no light harvesting complex II) was measured at several temperatures between 295 K and 10 K. Measurements were performed to investigate energy trapping from LHI to the RC in RC mutants that have a P/P(+) midpoint potential either above or below wild-type (WT). Six different strains were investigated: WT + LHI, four mutants with altered RC P/P(+) midpoint potentials, and an LHI-only strain. In the mutants with the highest P/P(+) midpoint potentials, the electron transfer rate decreases significantly, and at low temperatures it is possible to directly observe energy transfer from LHI to the RC by detecting the fluorescence kinetics from both complexes. In all mutants, fluorescence kinetics are multiexponential. To explain this, RC + LHI fluorescence kinetics were analyzed using target analysis in which specific kinetic models were compared. The kinetics at all temperatures can be well described with a model which accounts for the energy transfer between LHI and the RC and also includes the relaxation of the charge separated state P(+)H(A)(-), created in the RC as a result of the primary charge separation.     

Analysis by exciton theory of the optical properties of the Chloroflexus aurantiacus reaction center

The optical properties of the reaction center of the filamentous green bacterium Chloroflexus aurantiacus, that contains three bacteriochlorophyll (BChl) a and three bacteriopheophytin (BPh) a molecules, were analyzed in the near-infrared region with the aid of exciton theory. The coordinates obtained from the X-ray analysis of the reaction center of Rhodopseudomonas viridis (Deisenhofer, J., Epp, O., Miki, K., Huber, R. and Michel, H. (1984) J. Mol. Biol. 180, 385–398) were used for the geometry of the reaction center of C. aurantiacus, with the replacement of one of the ‘accessory’ BChl molecules by BPh. The results were found to be in good agreement with experimental low-temperature absorption spectra, linear and circular dichroism and fluorescence polarization spectra and lead to the following conclusions. The allowed, low-energy exciton transition of the primary electron donor (P-865) is located at 887 nm and carries the dipole strength of approx. two BChl a monomers; the high-energy exciton transition, around 790 nm, is mixed with wave functions of other pigments, which explains its relatively small angle with respect to the 887 nm transition. The optical transition of the accessory BChl a molecule near 812 nm has some contribution of the BChls that constitute P-865. This can account for the experimentally observed reorientation and shift of this transition upon oxidation of P-865. Two of the BPh molecules are located on the same (probably the M) polypeptide subunit and show a clear splitting of absorption bands (11 nm) due to exciton coupling; the single BPh on the opposite branch shows hardly any exciton shift. Similar calculations for reaction centers of purple bacteria that contain four BChl a and two BPh a molecules resulted in a very low dipole strength for the high-energy transition of the primary donor due to antisymmetric mixing with both accessory BChl a wave functions and gave very little splitting of the absorption bands of BPh a. Our results indicate that the arrangement of the chromophores in reaction centers of C. aurantiacus is very similar to that in purple bacteria. The functional L-chains of the reaction centers of purple and filamentous green bacteria consist of pigments of the same type in a probably very similar arrangement.     

Effects of dibromothymoquinone on oxidation-reduction reactions and the midpoint potential of the Rieske iron-sulfur center in photosynthetic electron transport of Synechococcus Sp.

The effects of 2,5-dibromo-3-methyl-p-benzoquinone (DBMIB) on the reduction kinetics of flash-oxidized P-700 and cytochrome c-553 were studied in the thermophilic cyanobacterium Synechococcus sp. (1) The reduction kinetics of P-700 showed two exponential phases with half-times of 0.2 and 2 ms at the recording time used (Nanba, M. and Katoh, S. (1983) Biochim. Biophys. Acta 725, 272–279). DBMIB strongly slowed down the 2 ms reduction phase but not the 0.2 ms phase. (2) The content of an electron donor which transfers its electrons to P-700 with the half time of 0.2 ms was estimated to be comparable to that of cytochrome f. (3) The magnitudes of the 0.2 ms reduction phase and cytochrome c-553 oxidation decreased as the flash interval was shortened below 2 s in the poisoned cells. Assuming a rapid equilibrium of electrons in the electron donor pool of Photosystem I, the midpoint potential of the 0.2 ms donor was estimated as 280 mV by comparing its percent reduction with that of cytochrome c-553 at three different flash intervals. (4) A similar value was obtained for the midpoint potential of the 0.2 ms donor in the cells in which the plastoquinone pool had been oxidized by dark starvation. It is concluded that the 0.2 ms reduction phase of P-700 is due to the electron donation from the Rieske iron-sulfur center and that DBMIB inhibits strongly but incompletely the reduction of the iron-sulfur center with electrons from the plastoquinone pool, whereas the inhibitor has no effect on the midpoint potential and Photosystem-I-dependent oxidation of the iron-sulfur center.     

Properties of the reaction center of the thermophilic purple photosynthetic bacterium Chromatium tepidum

Reaction centers were purified from the thermophilic purple sulfur photosynthetic bacterium Chromatium tepidum. The reaction center consists of four polypeptides L, M, H and C, whose apparent molecular masses were determined to be 25, 30, 34 and 44 kDa, respectively, by polyacrylamide gel electrophoresis. The heaviest peptide corresponds to tightly bound cytochrome. The tightly bound cytochrome c contains two types of heme, high-potential c-556 and low-potential c-553. The low-potential heme is able to be photooxidized at 77 K. The reaction center exhibits laser-flash-induced absorption changes and circular dichroism spectra similar to those observed in other purple photosynthetic bacteria. Whole cells contain both ubiquinone and menaquinone. Reaction centers contain only a single active quinone; chemical analysis showed this to be menaquinone. Reaction center complexes without the tightly bound cytochrome were also prepared. The near-infrared pigment absorption bands are red-shifted in reaction centers with cytochrome compared to those without cytochrome.     

Exciton interaction among chlorophyll molecules in bacteriochlorophyll a proteins and bacteriochlorophyll a reaction center complexes from green bacteria

Absorption and CD spectra of bacteriochlorophyll a proteins and bacteriochlorophyll a reaction center complexes from two strains of Chlorobium limicola were recorded at 77 °K. Visual inspection showed that the Q_y-band of chlorophyll in either protein was split into at least five components. Analysis of the spectra in terms of asymmetric Gaussian component pairs by means of computer program GAMET showed that six components are necessary to fit the spectra from strain 2K. These six components are ascribed to an exciton interaction between the seven bacteriochlorophyll a molecules in each subunit. The clear difference between the exciton splitting in the two bacteriochlorophyll a proteins shows that the arrangement of the chlorophyll molecules in each subunit must be slightly different.

The spectra for the bacteriochlorophyll a reaction center complexes have a component at 834 nm (absorption) and 832 nm (CD) which does not appear in the spectra of the bacteriochlorophyll a proteins. The new component is ascribed to a reaction center complex which is combined with bacteriochlorophyll a proteins to form the bacteriochlorophyll a reaction center complex. The complete absorption (or CD) spectrum for a given bacteriochlorophyll a reaction center complex can be described to a first approximation in terms of the absorption (or CD) spectrum for the corresponding bacteriochlorophyll a protein plus the new component ascribed to the reaction center complex.     

Characterization of a Rhodobacter capsulatus reaction center mutant that enhances the distinction between spectral forms of the initial electron donor

A large scale mutation of the Rhodobacter capsulatus reaction center M-subunit gene, sym2-1, has been constructed in which amino acid residues M205-M210 have been changed to the corresponding L subunit amino acids. Two interconvertable spectral forms of the initial electron donor are observed in isolated reaction centers from this mutant. Which conformation dominates depends on ionic strength, the nature of the detergent used, and the temperature. Reaction centers from this mutant have a ground-state absorbance spectrum that is very similar to wild-type when measured immediately after purification in the presence of high salt. However, upon subsequent dialysis against a low ionic strength buffer or the addition of positively charged detergents, the near-infrared spectral band of P (the initial electron donor) in sym2-1 reaction centers is shifted by over 30 nm to the blue, from 852 to 820 nm. Systematically varying either the ionic strength or the amount of charged detergent reveals an isobestic point in the absorbance spectrum at 845 nm. The wild-type spectrum also shifts with ionic strength or detergent with an isobestic point at 860 nm. The large spectral separation between the two dominant conformational forms of the sym2-1 reaction center makes detailed measurements of each state possible. Both of the spectral forms of P bleach in the presence of light. Electrochemical measurements of the P/P+ midpoint potential of sym2-1 reaction centers show an increase of about 30 mV upon conversion from the long-wavelength form to the short-wavelength form of the mutant. The rate constant of initial electron transfer in both forms of the mutant reaction centers is essentially the same, suggesting that the spectral characteristics of P are not critical for charge separation. The short-wavelength form of P in this mutant also converts to the long-wavelength form as a function of temperature between room temperature and 130 K, again giving rise to an isobestic point, in this case at 838 nm for the mutant. A similar, though considerably less pronounced spectral change with temperature occurs in wild-type reaction centers, with an isobestic point at about 855 nm, close to that found by titrating with ionic strength or detergent. Fitting the temperature dependence of the sym2-1 reaction center spectrum to a thermodynamic model resulted in a value for the enthalpy of the conformational interconversion between the short- and long-wavelength forms of about -6 kJ/mol and an entropy of interconversion of about -35 J/(K mol). Similar values of enthapy and entropy changes can be used to model the temperature dependence in wild-type. Thus, much of the temperature dependence of the reaction center special pair near-infrared absorbance band can be described as an equilibrium shift between two spectrally distinct conformations of the reaction center.     

EPR properties of the reaction center of Rhodopseudomas gelatinosa in situ and in a detergent-solubilized form.

The photochemical reaction centers from a variety of purple photosynthetic bacteria are composed of a trimer of protein subunits. However, the recently isolated reaction center from Rhodopseudomonas gelatinosa appears to have only two subunits. In this paper we examine the EPR characteristics of the primary photochemical reactants in this species, and compare them with those of other species. Despite of the differences in protein composition, no dramatic differences in EPR properties are seen in vivo, although some interesting effects are seen upon solubilization of the reaction center, which may be related to the unusual lability of the isolated preparation. Perhaps the most noteworthy phenomenon seen in Rps. gelatinosa is the apparent ability of electrons on the reduced intermediary electron carrier to tunnel at low temperatures to the oxidized c-type cytochrome, which has not been seen in other species studied to date.     

Energy equilibration and primary charge separation in chlorophyll d-based photosystem I reaction center isolated from Acaryochloris marina

Primary photochemistry in photosystem I (PS I) reaction center complex from Acaryochloris marina that uses chlorophyll d instead of chlorophyll a has been studied with a femtosecond spectroscopy. Upon excitation at 630 nm, almost full excitation equilibration among antenna chlorophylls and 40% of the excitation quenching by the reaction center are completed with time constants of 0.6(±0.1) and 4.9(±0.6) ps, respectively. The rise and decay of the primary charge-separated state proceed with apparent time constants of 7.2(±0.9) and 50(±10) ps, suggesting the reduction of the primary electron acceptor chlorophyll (A₀) and its reoxidation by phylloquinone (A₁), respectively.     

Pumping capacity of bacterial reaction centers and backpressure regulation of energy transduction.

Transduction of free-energy by Rhodobacter sphaeroides reaction-center-light-harvesting-complex-1 (RCLH1) was quantified. RCLH1 complexes were reconstituted into liposomal membranes. The capacity of the RCLH1 complex to build up a proton motive force was examined at a range of incident light intensities, and induced proton permeabilities, in the presence of artificial electron donors and acceptors. Experiments were also performed with RCLH1 complexes in which the midpoint potential of the reaction center primary donor was modified over an 85-mV range by replacement of the tyrosine residue at the M210 position of the reaction center protein by histidine, phenylalanine, leucine or tryptophan. The intrinsic driving force with which the reaction center pumped protons tended to decrease as the midpoint potential of the primary donor was increased. This observation is discussed in terms of the control of the energetics of the first steps in light-driven electron transfer on the thermodynamic efficiency of the bacterial photosynthetic process. The light intensity at which half of the maximal proton motive force was generated, increased with increasing proton permeability of the membrane. This presents the first direct evidence for so-called backpressure control exerted by the proton motive force on steady-state cyclic electron transfer through and coupled proton pumping by the bacterial reaction center.     

Preferential binding of equine ferricytochrome c to the bacterial photosynthetic reaction center from Rhodobacter sphaeroides

Redox titration of horse heart cytochrome c (cyt c), in the presence of varying concentrations of detergent-solubilized photosynthetic reaction center (RC) from Rhodobacter sphaeroides, revealed an RC concentration-dependent decrease in the measured cyt c midpoint potential that is indicative of a 3.6 +/- 0.2-fold stronger binding affinity of oxidized cytochrome to a single binding site. This effect was correlated with preferential binding in the functional complex by redox titration of the fraction of RCs exhibiting microsecond, first-order, special pair reduction by cytochrome. A binding affinity ratio of 3.1 +/- 0.4 was determined by this second technique, confirming the result. Redox titration of flash-induced intracomplex electron transfer also showed the association in the electron transfer-active complex to be strong, with a dissociation constant of 0.17 +/- 0.03 microM. The tight binding is associated with a slow off-rate which, in the case of the oxidized form, can influence the kinetics of P(+) reduction. The pitfalls of the common use of xenon flashlamps to photoexcite fast electron-transfer reactions are discussed with relation to the first electron transfer from primary to secondary RC quinone acceptors. The results shed some light on the diversity of kinetic behavior reported for the cytochrome to RC electron-transfer reaction.     

EPR properties of the reaction center of Rhodopseudomas gelatinosa in situ and in a detergent-solubilized form

The photochemical reaction centers from a variety of purple photosynthetic bacteria are composed of a trimer of protein subunits. However, the recently isolated reaction center from Rhodopseudomonas gelatinosa appears to have only two subunits. In this paper we examine the EPR characteristics of the primary photochemical reactants in this species, and compare them with those of other species. Despite of the differences in protein composition, no dramatic differences in EPR properties are seen in vivo, although some interesting effects are seen upon solubilization of the reaction center, which may be related to the unusual lability of the isolated preparation. Perhaps the most noteworthy phenomenon seen in Rps. gelatinosa is the apparent ability of electrons on the reduced intermediary electron carrier to tunnel at low temperatures to the oxidized c-type cytochrome, which has not been seen in other species studied to date.     

Absorbance and fluorescence properties of the bacteriochlorophyll a reaction center complex and bacteriochlorophyll a protein in green bacteria

Absorbance, emission and excitation spectra were measured at both room and liquid-nitrogen temperatures for a photochemically active bacteriochlorophyll a reaction center complex and a bacteriochlorophyll a protein isolated from Chlorobium limicola and Chlorobium thiosulfatophilum. The low-temperature absorbance spectrum for the complex has a band centered at 833 nm, which is not seen in the spectrum of the bacteriochlorophyll a protein. We attribute this difference to a modification of the bacteriochlorophyll a protein in the active complex. The room-temperature fluorescence spectra for the bacteriochlorophyll a protein and the complex are similar, as are those measured at low temperatures. The 833-nm component of the low-temperature absorbance spectrum of the complex is relatively nonfluorescent.