Photosynthetic electrogenic events in native membranes ofChloroflexus aurantiacus. Flash-induced charge displacements within the reaction center-cytochromec 554 complex

The thermophilic phototrophChloroflexus aurantiacus possesses a photosynthetic reaction center (RC) containing a pair of menaquinones as primary (Q_A) and secondary (Q_B) electron acceptors and a bacteriochlorophyll dimer (P) as a primary donor. A tetraheme cytochromec ₅₅₄ with two high(H)- and two low(L)-potential hemes operates as an immediate electron donor for P. The following equilibrium E_m,7 values were determined by ESR for the hemes in whole membrane preparations: 280 mV (H1), 150 mV (H2), 95 mV (L1) and 0 mV (L2) (Van Vliet et al. (1991) Eur. J. Biochem. 199: 317–323). Partial electrogenic reactions induced by a laser flash inChl. aurantiacus chromatophores adsorbed to a phospholipid-impregnated collodion film were studied electrometrically at pH 8.3. The photoelectric response included a fast phase of generation ( < 10 ns, phase A). It was ascribed to the charge separation between P⁺ and Q_A ^– as its amplitude decreased both at high and low E_h values (E_m,high=360±10 mV, estimated E_m,low\s-160 mV) in good agreement with E_m values for P/P⁺ and Q_A/Q_A ^– redox couples. A slower kinetic component appeared upon reduction of the cytochromec ₅₅₄ hemes (phase C). With H1 reduced before the flash the amplitude of phase C was equal to 15–20% of that of phase A and its rise time was 1.2–1.3 s: we attribute this phase to the electrogenic electron transfer from H1 to P⁺. Pre-reduction of H2 decreased the value to about 700–800 ns and increased the amplitude of phase C to 30–35% of that of phase A. Pre-reduction of L1 further accelerated phase C (up to of 500 ns) and induced a reverse electrogenic phase with of 12 s and amplitude equal to 10% of phase A. Upon pre-reduction of L2 the rise time of phase C was decreased to about 300 ns and its amplitude decreased by 30%. The acceleration in the onset of phase C is explained by the acceleration of the rate-limiting H1 P electrogenic reaction after reduction of the other hemes due to their electrostatic influence; a P-H1-(L1-L2)-H2 alignment of redox centers with an approximately rhombic arrangement of the cytochromec ₅₅₄ hemes is proposed. The observed reverse phase is ascribed to the post-flash charge redistribution between the hemes. Redox titration of the amplitude of phase C yielded the E_m,8.3 values of H1, H2 and L2 hemes: 340±10 mV for H1, 160±20 mV for H2 and –40±40 mV for L2.     

The influence of electrostatic interactions and intramolecular dynamics on electron transfer from the cytochrome subunit to the cation —radical of the bacteriochlorophyll dimer in reaction centers from Rps. viridis

Interheme electrostatic interaction can explain the acceleration of the electron transfer (ET) rate from the highest potential heme (C38o) to the photooxidized bacteriochlorophyll dimer (P⁺) which takes place after the reduction of neighbouring heme(s) of the cytochrome subunit in the reaction center of Rps. viridis. The electrostatic interaction energies calculated for neighbouring hemes, 7.0 Å apart (edge-to-edge), and for two high potential hemes, 21.5 Å apart are found to be 0.110 eV and 0.040 eV respectively. The reorganisation energy of the C₃₈₀-P⁺ transition of about 0.290±0.030 eV is calculated using the Marcus theory of electron tunneling. An empirical relation for the rate of ET is given. The low temperature restriction of the C₃₈₀-⁺ transition is caused by an energetic inhibition which originates from an opposite shifting of the energy levels of C₃₈₀ and P⁺ due to the freezing of protein dynamics and protein-bound water mobility. The freezing of the protein dynamics is revealed by the Mössbauer effect and correlates with the efficiency of the ET.Abbreviations RC reaction center - P⁺ cation-radical of bacteriochlorophyll dimer - C₃₈₀, C20, C310, C_–60, hemes indexed by the values of their individual redox potentials (in mV) - ET electron transfer     

The primary quinone acceptor and the membrane-bound c-type cytochromes of the halophilic purple nonsulfur bacterium Rhodospirillum salinarum: A spectroscopic and thermodynamic study

The mid-point potential (Em_7.0) of the primary quinone acceptor (Qa) and the biochemical features (Em_7.0 and apparent molecular mass, MM) of the membrane bound c-type cytochromes (cyt) involved in photosynthetic electron transfer of the halophilic phototrophic bacterium Rhodospirillum (Rs.) salinarum were determined. A tetrahemic RC bound cytochrome was found (MM of 39.8 kDa) with Em_7.0 of the hemes equal to +304, +98, +21, –134 (± 8) mV as determined by dark equilibrium redox titrations in the isolated purified form. The highest potential heme (Em_7.0 = +304 mV, band at 556 nm) was able to reduce the photo-oxidized reaction center (P⁺) in a sub-millisecond ( 20 s) time scale reaction, acting most likely as the direct electron donor to P⁺). The midpoint potential of the primary electron donor (Em_7.0 = + 455 mV) was found to be close to that reported for the primary donor of the non-halophilic Rhodospirillum species Rs. rubrum, whereas the quinone primary electron acceptor (Qa) was different showing the spectral features of a menaquinone molecule with Em_7.0 at –128 (± 5) mV. A membrane bound c-type heme with Em_7.0 of 259 (± 1) and MM of 40 kDa was also isolated and referred to an orthodox cytochrome c₁). The present data on the photosynthetic apparatus, along with the previous results on the respiratory system [Moschettini et al. (1997) Arch Microbiol 168: 302-309], suggest that Rs. salinarum is biochemically distinct from Rs. rubrum, the most representative specie of the genus.     

Electron transfer between cytochrome c2 and the tetraheme cytochrome c in Rhodopseudomonas viridis

Kinetics of electron transfer from soluble cytochrome c₂ to the tetraheme cytochrome c have been measured in isolated reaction centers and in membrane fragments of the photosynthetic purple bacterium Rhodopseudomonas viridis by time-resolved flash absorption spectroscopy. Absorbance changes kinetics in the region of cytochrome -bands (540–560 nm) were measured at 21 °C under redox conditions where the two high-potential hemes (c-559 and c-556) of the tetraheme cytochrome were chemically reduced. After flash excitation, the heme c-559 donates an electron to the special pair of bacteriochlorophylls and is then re-reduced by heme c-556. The data show that oxidized heme c-556 is subsequently re-reduced by electron transfer from reduced cytochrome c₂ present in the solution. The rate of this reaction has a non-linear dependence on the concentration of cytochrome c₂, suggesting a (minimal) two-step mechanism involving the f ormation of a complex between cytochrome c₂ and the reaction center, followed by intracomplex electron transfer. To explain the monophasic character of the reaction kinetics, we propose a collisional mechanism where the lifetime of the temporary complex is short compared to electron transfer. The limit of the halftime of the bimolecular process when extrapolated to high concentrations of cytochrome c₂ is 60 ± 20 s. There is a large ionic strength effect on the kinetics of electron transfer from cytochrome c₂ to heme c-556. The pseudofirst-order rate constant decreases from 1.1 × 10⁷ M^-1 s^-1 to 1.3 × 10⁶ M^-1 s^-1 when the ionic strength is increased from 1 to 1000 mM. The maximum rate (1.1 × 10⁷ M^-1 s^-1) was obtained at about 1 mM ionic strength. This dependence of the rate on ionic strength s uggests that attractive electrostatic interactions contribute to the binding of cytochrome c₂ with the tetraheme cytochrome. On the basis of our data and of previous molecular modelling, it is proposed that cytochrome c₂ docks close to the low-potential heme c-554 and reduces heme c-556 via c-554.     

Studies on the protolytic reactions coupled with water cleavage in photosystem II membrane fragments from spinach

The protolytic reactions of PSII membrane fragments were analyzed by measurements of absorption changes of the water soluble indicator dye bromocresol purple induced by a train of 10 s flashes in dark-adapted samples. It was found that: a) in the first flash a rapid H⁺-release takes place followed by a slower H⁺-uptake. The deprotonation is insensitive to DCMU but is completely eliminated by linolenic acid treatment of the samples; b) the extent of the H⁺-uptake in the first flash depends on the redox potential of the suspension. In this time domain no H⁺-uptake is observed in the subsequent flashes; c) the extent of the H⁺-release as a function of the flash number in the sequence exhibits a characteristic oscillation pattern. Multiphasic release kinetics are observed. The oscillation pattern can be satisfactorily described by a 1, 0, 1, 2 stoichiometry for the redox transitions S_i S_i+1 (i=0, 1, 2, 3) in the water oxidizing enzyme system Y. The H⁺-uptake after the first flash is assumed to be a consequence of the very fast reduction of oxidized Q₄₀₀(Fe³⁺) formed due to dark incubation with K₃[Fe(CN)₆]. The possible participation of component Z in the deprotonation reactions at the PSII donor side is discussed.Abbreviations A protonizable group at the PSII acceptor side - BCP Bromocresol Purple - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - FWHM Full Width at Half Maximum - Q_A, Q_B primary and secondary plastoquinone at PSII acceptor side - Q₄₀₀ redox group at PSII-acceptor side (high spin Fe²⁺) - P680 Photoactive chlorophyll of PSII reaction center - S_i redox states of the catalytic site of water oxidation - Z redox component connecting the catalytic site of water oxidation with the reaction center     

Primary photochemical processes in isolated reaction centers of Rhodopseudomonas viridis

Picosecond and nanosecond spectroscopic techniques have been used to study the primary electron transfer processes in reaction centers isolated from the photosynthetic bacterium Rhodopseudomonas viridis. Following flash excitation, the first excited singlet state (P1) of the bacteriochlorophyll complex (P) transfers an electron to an intermediate acceptor (I) in less than 20 ps. The radical pair state (P⁺I^?) subsequently transfers an electron to another acceptor (X) in about 230 ps. There is an additional step of unknown significance exhibiting 35 ps kinetics. P⁺ subsequently extracts an electron from a cytochrome, with a time constant of about 270 ns. At low redox potential (X reduced before the flash), the state P⁺I^? (or P^F) lives approx. 15 ns. It decays, in part, into a longer lived state (P^R), which appears to be a triplet state. State P^R decays with an exponential time of approx. 55 μs. After continuous illumination at low redox potential (I and X both reduced), excitation with an 8-ps flash produces absorption changes reflecting the formation of the first excited singlet state, P1. Most of P1 then decays with a time constant of 20 ps. The spectra of the absorbance changes associated with the conversion of P to P1 or P⁺ support the view that P involves two or more interacting bacteriochlorophylls. The absorbance changes associated with the reduction of I to I^? suggest that I is a bacteriopheophytin interacting strongly with one or more bacteriochlorophylls in the reaction center.     

Delayed fluorescence from Rhodopseudomonas sphaeroides following single flashes

Delayed fluorescence from Rhodopseudomonas sphaeroides chromatophores was studied with the use of short flashes for excitation. Although the delayed fluorescence probably arises from a back-reaction between the oxidized reaction center bacteriochlorophyll complex (P⁺) and the reduced electron acceptor (X^?), the decay of delayed fluorescence after a flash is much faster ($\text{τ}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{≈ 120 μ}\text{s}$) than the decay of P⁺X^?. The rapid decay of delayed fluorescence is not due to the uptake of a proton from the solution, nor to a change in membrane potential. It correlates with small optical absorbance changes at 450 and 770 nm which could reflect a change in the state of X^?.The intensity of the delayed fluorescence is 11–18-fold greater if the excitation flashes are spaced 2 s apart than it is if they are 30 s apart. The enhancement of delayed fluorescence at high flash repetition rates occurs only at redox potentials which are low enough (< + 240 mV) so that electron donors are available to reduce P⁺X^? to PX^? in part of the reaction center population. The enhancement decays between flashes as PX^? is reoxidized to PX, as measured by the recovery of photochemical activity. Evidently, the reduction of P⁺X^? to PX^? leads to the storage of free energy that can be used on a subsequent flash to promote delayed fluorescence. The reduction of P⁺X^? also is associated with a carotenoid spectral shift which decays as PX^? is reoxidized to PX. Although this suggests that the free energy which supports the delayed fluorescence might be stored as a membrane potential, the ionophore gramicidin D only partially inhibits the enhancement of delayed fluorescence. With widely separated flashes, gramicidin has no effect on delayed fluorescence.At redox potentials low enough to keep X fully reduced, delayed fluorescence of the type described above does not occur, but one can detect weak luminescence which probably is due to phosphorescence of a protoporphyrin.     

Charge recombination in photosystem I at low temperatures kinetics of electron tunneling

Absorption changes accompanying light-induced P-700 oxidation and the decay of P-700+ in the dark were measured in the temperature range 294-5 K over a broad time scale (three to four orders of magnitude). Two qualitatively different types of kinetics for the dark decay of P-700⁺ were observed. In the 294-240K region, a usual exponential kinetics is observed with the rate constant κ = 1 · 10¹⁰ · exp(-16 000/RT) s^?1, with R in cal/mol per degree. Below 220 K, a rather unusual logarithmic or near-logarithmic kinetics are observed. These kinetics can be explained quantitatively if one assumes for the various (P-700+ ··· X^-) pairs a broad rectangular or near-rectangular distribution over the values of the rate constant. The following kinetic equation corresponding to this model was obtained: n_t/n_o = [In(κ_max/κ_min)]-1 - [In(1/κ_min)? In t] where no and nt are respectively the initial concentration of P-700⁺ and its concentration at time t, and kmax and kmin the maximum and minimum values of the rate constant, respectively. The decay processes observed can be ascribed to electron tunneling. Distribution over the values of k can be accounted for by different environments or different mutual orientations of P-700⁺ and X^?, or by different distances between them in the various reacting pairs.The corresponding distribution function was reconstructed from the experimentally measured P-700+-decay curves. The rate of tunneling was found to be temperature dependent. In the 160-80-K region, the temperature dependence corresponds to an activation energy of 2.9 kcal/mol. Below 80 K, new modes of P-700+ decay with lower activation energy become operative. The tunneling distance for the majority of the (P-700+ ··· X^?) pairs was estimated from the EPR linewidth of P-700+ to exceed 13.2 A.     

Temperature dependence of cytochrome photooxidation and conformational dynamics of Chromatium reaction center complexes

A temperature dependence of multiheme cytochrome c oxidation induced by a laser pulse was studied in photosynthetic reaction center preparations from Chromatium minutissimum. Absorbance changes and kinetic characteristics of the reaction were measured under redox conditions where one or all of the hemes of the cytochrome subunit are chemically reduced (E _h =+300 mV or E _h =–20 to -60 mV respectively). In the first case photooxidation is inhibited at temperatures lower than 190–200 K with the rate constant of the photooxidation reaction being practically independent on temperature over the range of 300 to 190 K (k=2.2×10⁵ s^-1). Under reductive conditions (E _h =–20 to -60 mV) lowering the temperature to 190–200 K causes the reaction to slow from k=8.3×10⁵ s^-1 to 2.1×10⁴ s^-1. Under further cooling down to the liquid nitrogen temperature, the reaction rate changes negligibly. The absorption amplitude decreases by 30–40% on lowering the temperature. A new physical mechanism of the observed critical effects of temperature on the rate and absorption amplitude of the multiheme cytochrome c oxidation reaction is proposed. The mechanism suggests a close interrelation between conformational mobility of the protein and elementary electron tunneling act. The effect of freezing conformational motion is described in terms of a local diffusion along a random rough potential.     

The pathway of cyclic electron transport in chromatophores of Chromatium vinosum. Evidence for a Q-cycle mechanism

Chromatophores of the purple sulfur bacterium Chromatium vinosum were shown to contain a cytochrome similar to cytochrome c₁ and two b cytochromes. Cytochrome b can be accumulated in the reduced form upon illumination at an ambient redox potential of +415 mV in the presence of the electron transport inhibitors antimycin A or HOQNO. The reductions of cytochrome b, of the high-potential cytochrome c₅₅₅ and of the primary electron donor P-870 are all inhibited by myxothiazol. Dark-adapted C. vinosum chromatophores show little cytochrome b reduction on the first flash. Considerable cytochrome b reduction (1 cytochrome b:8 P-870 present) is observed on the second flash. This observation and the 1:1 stoichiometry observed between cytochrome b reduction and P-870⁺ reduction after the second flash support a Q-cycle model for cyclic electron flow in C. vinosum.     

Effect of isotope substitution and controlled dehydration on the photoinduced electron transport reactions of quinone acceptors and multiheme cytochrome C in bacterial photosynthetic reaction center

Isotope substitution of H₂O by ²H₂O causes an increase in the rate of dark recombination between photooxidized bacteriochlorophyll (P⁺) and reduced primary quinone acceptor in Rhodobacter sphaeroides reaction centers (RC) at room temperature. The isotopic effect declines upon decreasing the temperature. Dehydration of RC complexes of Ectothiorhodospira shaposhnikovii chromatophores containing multiheme cytochrome c causes a decrease in the efficiency of transfer of a photomobilized electron between the primary and secondary quinone acceptors and from cytochrome to P⁺. In the case of H₂O medium these effects are observed at a lower hydration than in ²H₂O-containing medium. In the E. shaposhnikovii chromatophores subjected to dehydration in H₂O, the rate of electron transfer from the nearest high-potential cytochrome heme to P⁺ is virtually independent of hydration within the P/P₀ range from 0.1 to 0.5. In samples hydrated in ²H₂O this rate is approximately 1.5 times lower than in H₂O. However, the isotopic effect of this reaction disappears upon dehydration. The intramolecular electron transfer between two high-potential hemes of cytochrome c in samples with ²H₂O is inhibited within this range of P/P₀, whereas in RC samples with H₂O there is a trend toward gradual inhibition of the interheme electron transfer with dehydration. The experimental results are discussed in terms of the effects of isotope substitution and dehydration on relaxation processes and charge state of RC on implementation of the reactive states of RC providing electron transfer control.     

Fast phases of the generation of the transmembrane electric potential in chromatophores of the photosynthetic bacterium Ectothiorhodospira shaposhnikovii

Ectothiorhodospira shaposhnikovii chromatophores were associated with a collodion film and kinetics of generation of the transmembrane electric potential (Δψ) were investigated in the ‘chromatophore-collodion film’ system, using an electrometric technique with a high resolution time (over 200 ns). A generation of Δψ (the chromatophore interior positive) following a laser flash was observed, the kinetics consisting of three components of the following half-times: less than 200 ns (phase 1); 2–7 μs (phase 2); and 120 μs (phase 3). A redox titration of the kinetic phases was performed. Computer analysis of the results has shown that the midpoint potentials (E_m) of the phase 1 at pH 7.5 are +400 mV and −75 mV, whereas those of the phase 2 are +310 mV and +35 mV. The comparison of the kinetic and potentiometric characteristics of the Δψ generation with analogous characteristics of the electron-transport processes, measured by optical spectroscopy, suggested that phases 1, 2 and 3 are associated with the electron transfer from P-890 to the primary quinone acceptor Q_a, from the high-potential cytochrome C_H to P-890, and with the reduction of secondary acceptor Q_b, respectively. From the amplitude characteristics of the Δψ components, a tentative scheme of the intramembrane localization of the electron carriers is presented.     

Kinetics of oxidation of the bound cytochromes in reaction centers from Rhodopseudomonas viridis

The initial oxidized species in the photochemical charge separation in reaction centers from Rps. viridis is the primary donor, P⁺, a bacteriochlorophyll dimer. Bound c-type cytochromes, two high potential (Cyt c ₅₅₈) and two low potential (Cyt c ₅₅₃), act as secondary electron donors to P⁺. Flash induced absorption changes were measured at moderate redox potential, when the high potential cytochromes were chemically reduced. A fast absorption change was due to the initial oxidation of one of the Cyt c ₅₅₈ by P⁺ with a rate of 3.7×10⁶s^-1 (=270nsec). A slower absorption change was attributable to a transfer, or sharing, of the remaining electron from one high potential heme to the other, with a rate of 2.8×10⁵s^-1 (=3.5 sec). The slow change was measured at a number of wavelengths throughout the visible and near infrared and revealed that the two high potential cytochromes have slightly different differential absorption spectra, with -band maxima at 559 nm (Cyt c ₅₅₉) and 556.5 nm (Cyt c ₅₅₆), and dissimilar electrochromic effects on nearby pigments. The sequence of electron transfers, following a flash, is: Cyt c ₅₅₆Cyt c ₅₅₉P⁺. At lower redox potentials, a low midpoint potential cytochrome, Cyt c ₅₅₃, is preferentially oxidized by P⁺ with a rate of 7×10⁶s^-1 (=140 nsec). The assignment of the low and high potential cytochromes to the four, linearly arranged hemes of the reaction center is discussed. It is concluded that the closest heme to P must be the high potential Cyt c ₅₅₉, and it is suggested that a likely arrangement for the four hemes is: c ₅₅₃ c ₅₅₆ c ₅₅₃ c ₅₅₉P.Abbreviations diaminodurene 2,3,5,6-tetramethyl-p-phenylenediamine - MOPS 3-[N-morpholino]-propane-sulfonic acid - PMS methyl phenazinium methosulfate - PES ethyl phenazinium ethosulfate - TMPD N,N,N,N-tetramethyl-p-phenylenediamine - TX-100 Triton X-100     

Spectral and kinetic characterization of electron acceptor A1 in a Photosystem I core devoid of iron-sulfur centers FX,FB and FA

The kinetic and spectroscopic properties of the secondary electron acceptor A₁ were determined by flash absorption spectroscopy at room and cryogenic temperatures in a Photosystem I (PS I) core devoid of the iron-sulfur clusters F_X, F_B and F_A. It was shown earlier (Warren, P.V., Golbeck, J.H. and Warden, J.T. (1993) Biochemistry 32: 849–857) that the majority of the flash-induced absorbance increase at 820 nm, reflecting formation of P700⁺, decays with a t_1/2 of 10 s due to charge recombination between P700⁺ and A₁ ^–. Following A₁ ^– directly around 380 nm, where absorbance changes due to the formation of P700⁺ are negligible, two major decay components were resolved in this study with t_1/2 of 10 s and 110 s at an amplitude ratio of 2.5:1. The difference spectra between 340 and 490 nm of the two kinetic phases are highly similar, showing absorbance increases from 340 to 400 nm characteristic of the one-electron reduction of the phylloquinone A₁. When measured at 10 K, the flash-induced absorbance changes around 380 nm can be fitted with two decay phases of t_1/2 15 s and 150 s at an amplitude ratio 1:1. The difference spectra of both kinetic phases from 340 to 400 nm are similar to those determined at 298 K and are therefore attributed to charge recombination in the pair P700⁺A₁ ^–. These results indicate that the backreaction between P700⁺ and A₁ ^– is multiphasic when F_X, F_B and F_A are removed, and only slightly temperature dependent in the range of 298 K to 10 K.Abbreviations Chl chlorophyll - D pathlength for the measuring light through the sample - DPIP 2,6-dichlorophenolindophenol - EPR electron paramagnetic resonance - IR infrared - PS I Photosystem I - Tris Tris(hydroxymethyl)aminomethane - UV ultraviolet Published as Journal Series #10890 of the University of Nebraska Agricultural Research Division and supported by a grant from the National Science Foundation (MCB-9205756).     

The voltage-dependent potassium-uptake channel of corn coleoptiles has permeation properties different from other K+ channels

The initial response of coleoptile cells to growth hormones and light is a rapid change in plasma-membrane polarization. We have isolated protoplasts from the cortex of maize (Zea mays L.) coleoptiles to study the electrical properties of their plasma membrane by the patch-clamp techniqueUsing the whole-cell configuration and cell-free membrane patches we could identify an H⁺-ATPase, hyperpolarizing the membrane potential often more negative than -150 mV, and a voltage-dependent, inward-rectifying K⁺ channel (unit conductance 5–7 pS) as the major membrane conductan-ces Potassium currents through this channel named CKC1_in (for Coleoptile K ⁺ Channel inward rectifier) were elicited upon voltage steps negative to -80 mV, characterized by a half-activation potential of -112 mV. The kinetics of activation, well described by a double-exponential process, were strongly dependent on the degree of hyperpolarization and the cytoplasmic Ca²⁺ level. Whereas at nanomolar Ca²⁺ concentrations K⁺ currents increased with a t_1/2=16 ms (at -180 mV), higher calcium levels slowed the activation process about fourto fivefoldUpon changes in the extracellular K⁺ concentration the reversal potential of the K⁺ channel followed the Nernst potential for potassium with a 56-mV shift for a tenfold increaseThe absence of a measurable conductance for Na⁺, Rb⁺, Cs⁺ and a permeability ratio P_{NH 4} ⁺ /P_K+ around 0.25 underlines the high selectivity of CKC1_in for K⁺In contrast to Cs⁺, which at submillimolar concentration blocks the channel in a voltage-dependent manner, Rb⁺, often used as a tracer for K+, does not permeate this type of K⁺ channelThe lack of Rb⁺ permeability is unique with respect to other K⁺ transporters. Therefore, future molecular analysis of CKC1_in, considered as a unique variation of plant inward rectifiers, might help to understand the permeation properties of K⁺ channels in general.Abbreviations CKC1_in Coleoptile K ⁺ Channel inward rectifier - U membrane voltage - I_ss steady-state currents - I_tail tail currents Experiments were conducted in the laboratory of F.G. during the stay of RHas a guest professor sponsored by Special Project RAISA, subproject N2.1, paper N2155.     

Cooperative interaction of high-potential hemes in the cytochrome subunit of the photosynthetic reaction center of bacterium <Emphasis Type="Italic">Ectothiorhodospira shaposhnikovii</Emphasis>

Cooperative interaction of the high-potential hemes (C_h) in the cytochrome subunit of the photosynthesizing bacterium Ectothiorhodospira shaposhnikovii was studied by comparing redox titration curves of the hemes under the conditions of pulse photoactivation inducing single turnover of electron-transport chain and steady-state photoactivation, as well as by analysis of the kinetics of laser-induced oxidation of cytochromes by reaction center (RC). A mathematical model of the processes of electron transfer in cytochrome-containing RC was considered. Theoretical analysis revealed that the reduction of one heme C_h facilitated the reduction of the other heme, which was equivalent to a 60 mV positive shift of the midpoint potential. In addition, reduction of the second heme C_h caused a three-to four-fold acceleration of the electron transfer from the cytochrome subunit to RC. Published in Russian in Biokhimiya, 2007, Vol. 72, No. 11, pp. 1540–1547.     

The interaction of the reaction center secondary quinone with the ubiquinone-cytochrome c2 oxidoreductase in Rhodopseudomonas sphaeroides chromatophores

(1) Two populations of reaction centers in the chromatophore membrane can be distinguished under some conditions of initial redox poise (300 mV < E_h < 400 mV): those which transfer a reducing equivalent after the first flash from the secondary quinone (Q_II) of the reaction center to cytochrome b of the ubiquinone-cytochrome c₂ oxidoreductase; and those which retain the reducing equivalent on Q^?_II until a second flash is given. These two populations do not exchange on a time scale of tens of seconds. (2) At redox potentials higher than 400 mV, Q^?_II generated after the first flash is no longer able to reduce cytochrome b-560 even in those reaction centers associated with an oxidoreductase. Under these conditions, doubly reduced Q_II generated by a second flash is required for cytochrome b reduction, so that the Q_II effectively functions as a two-electron gate into the oxidoreductase at these high potentials. (3) At redox potentials below 300 mV, although the two populations of Q_II are no longer distinguishable, cytochrome b reduction is still dependent on only part of the reaction center population. (4) Proton binding does not oscillate under any condition tested.     

A portable multi-flash kinetic fluorimeter for measurement of donor and acceptor reactions of Photosystem 2 in leaves of intact plants under field conditions

A newly-developed field-portable multi-flash kinetic fluorimeter for measuring the kinetics of the microsecond to millisecond reactions of the oxidizing and reducing sides of photosystem 2 in leaves of intact plants is described and demonstrated. The instrumental technique is a refinement of that employed in the double-flash kinetic fluorimeter (Joliot 1974 Biochim Biophys Acta 357: 439–448) where a low-intensity short-duration light pulse is used to measure the fluorescence yield changes following saturating single-turnover light pulses. The present instrument uses a rapid series of short-duration (2 s) pulses to resolve a complete microsecond to millisecond time-scale kinetic trace of fluorescence yield changes after each actinic flash. Differential optics, using a matrix of optical fibers, allow very high sensitivity (noise levels about 0.05% F_max) thus eliminating the need for signal averaging, and greatly reducing the intensity of light required to make a measurement. Consequently, the measuring pulses have much less actinic effect and an entire multi-point trace (seven points) excites less than 1% of the reaction centers in a leaf. In addition, bu combining the actinic and measuring pulse light in the optical fiber network, the tail of the actinic flash can be compensated for, allowing measurements of events as rapidly as 20 s after the actinic flash. This resolution makes practical the routine measurement of the microsecond turnover kinetics of the oxygen evolving complex in leaves of intact plants in the field. The instrument is demonstrated by observing flash number dependency and inhibitor sensitivity of the induction and decay kinetics of flash-induced fluorescence transients in leaves of intact plants. From these traces the period-two oscillations associated with the turnover of the two-electron gate and the period-four oscillations associated with the turnover of the oxygen evolving complex can be observed. Applications of the instrument to extending our knowledge of chloroplast function to the whole plant, the effects on plants of environmental stress, herbicides, etc, and possible applications to screening of mutants are discussed.Abbreviations DCMU 3-(3,4-Dichlorophenol)-1,1-dimethylurea - PS 2 photosystem 2 - PS 1 photosystem 1 - P₆₈₀ primary electron donor of the PS 2 reaction center - Q_A primary acceptor quinone of PS 2 - Q_B secondary acceptor quinone of PS 2 - CCCP carbonyl cyanide-m-chlorophenylhydrazone - Y_z donor to P₆₈₀ ⁺ - F₀ level of fluorescence with all PS 2 centers open - F_max maximum level of fluorescence with all PS 2 centers closed - P₆₈₀Q_A Open reaction centers with P₆₈₀ reduced and Q_A oxidized (low fluorescence) - P₆₈₀Q_A ^- Closed reaction centers, in which P₆₈₀ is reduced (high fluorescence) - P₆₈₀ ⁺Q_A ^- Closed reaction centers, in which P₆₈₀ is oxidized (low fluorescence)     

Effects of Temperature and ΔG° on Electron Transfer from Cytochrome c2 to the Photosynthetic Reaction Center of the Purple Bacterium Rhodobacter sphaeroides

The kinetics of electron transfer from cytochrome c₂ to the primary donor (P) of the reaction center from the photosynthetic purple bacterium Rhodobacter sphaeroides have been investigated by time-resolved absorption spectroscopy. Rereduction of P⁺ induced by a laser pulse has been measured at temperatures from 300 K to 220 K in a series of specifically mutated reaction centers characterized by altered midpoint redox potentials of P⁺/P varying from 410 mV to 765 mV (as compared to 505 mV for wild type). Rate constants for first-order electron donation within preformed reaction center–cytochrome c₂ complexes and for the bimolecular oxidation of free cytochrome c₂ have been obtained by multiexponential deconvolution of the kinetics. At all temperatures the rate of the fastest intracomplex electron transfer increases by more than two orders of magnitude as the driving force −ΔG° is varied over a range of 350 meV. The temperature and ΔG° dependences of the rate constant fit the Marcus equation well. Global analysis yields a reorganization energy λ = 0.96 ± 0.07 eV and a set of electronic matrix elements, specific for each mutant, ranging from 1.2 10⁻⁴ eV to 2.5 10⁻⁴ eV. Analysis in terms of the Jortner equation indicates that the best fit is obtained in the classical limit and restricts the range of coupled vibrational modes to frequencies lower than ∼200 cm⁻¹. An additional slower kinetic component of P⁺ reduction, attributed to electron transfer from cyt c₂ docked in a nonoptimal configuration of the complex, displays a Marcus type dependence of the rate constant upon ΔG°, characterized by a similar value of λ (0.8 ± 0.1 eV) and by an average electronic matrix element smaller by more than one order of magnitude. In all of the mutants, as the temperature is decreased below 260 K, both intracomplex reactions are abruptly inhibited, their rate being negligible at 220 K. The free energy dependence of the second-order rate constant for oxidation of cyt c₂ in solution suggests that the collisional reaction is partially diffusion controlled, reaching the diffusion limit at exothermicities between 150 and 250 meV over the temperature range investigated.