177 IN VITRO MATURATION AND FERTILIZATION OF OVARIAN OOCYTES OF FREE-RANGING GEMSBOK (ORYX GAZELLA)

The gemsbok is a large antelope native to arid regions of southern Africa. Listed by the International Union for Conservation of Nature as a species of least concern, the gemsbok is an excellent model for the development of assisted reproductive techniques for the closely related but critically endangered scimitar-horned oryx (Oryx dammah) and addax (Addax nasomaculatus). Gemsbok were introduced to the White Sands Missile Range by the New Mexico Department of Game and Fish to preserve the habitat by providing big game hunting, which ensures the support and lobby of hunters. Gonads were collected from hunted gemsbok and transported in PBS to the laboratory, where gametes were harvested. Testes were stored at 4°C in PBS until sperm were needed for IVF (18 to 28 h). Ovaries were sliced to release follicular oocytes, which were placed in maturation medium (TCM-199 with FCS, pyruvate, gentamicin and LH, FSH and oestradiol) for 20- to 22-h in vitro maturation culture at 38.8°C in 5% CO2 in air. Oocytes were then washed [Tyrode lactate (TL)-HEPES with BSA, pyruvate and gentamicin] and placed in groups of 5 to 10 in 50-μL drops of IVF-TL medium supplemented with pyruvate, gentamicin and BSA. Sperm were allowed to swim out of sliced epididymides into room temperature IVF-TL medium and then equilibrated for 30 min at 38.8°C. Approximately 2 × 103 motile sperm were added to each oocyte drop and incubated under oil for 21 to 23 h at 38.8°C in 5% CO2 in air. Domestic cattle oocytes were matured in maturation medium at 39°C during shipment to the field site, where they were washed and transferred to IVF medium as described for gemsbok oocytes. Approximately 1.7 × 103 motile gemsbok sperm were added to each drop and oocytes were incubated as described for gemsbok oocytes. At the end of IVF culture, oocytes of both species were stripped of granulosa cells and placed in embryo medium (SOF supplemented with BSA, essential and nonessential amino acids, pyruvate and gentamicin; all media formulations from Applied Reproductive Technologies, Madison, WI, USA) at 38.8°C in 5% CO2 in air. Embryo culture medium was refreshed after 48 h. Embryos were removed from culture after 6 days, examined for cleavage and fixed in PBS:formalin for staining and further analysis. Although gemsbok sperm were capable of fertilizing domestic cow oocytes at the same rate (38.3%) as gemsbok oocytes (37.1%), the antelope oocytes cleaved at a higher rate (29% vs cattle at 15.3%). These results indicate that chilled epididymal gemsbok sperm is capable of fertilizing gemsbok and domestic cattle oocytes and that protocols designed for in vitro maturation and fertilization of cattle oocytes may be successfully used in the field to produce gemsbok embryos (Table 1). Table 1.Fertilization of in vitro-matured gemsbok and cattle oocytes by chilled epididymal gemsbok sperm The authors thank the New Mexico Department of Game and Fish, Troylyn Zimmerly, Dana Powers and the Biology Department of New Mexico Institute of Mining and Technology.

Genetically engineered mutant of the cyanobacterium Synechocystis 6803 lacks the photosystem II chlorophyll-binding protein CP-47

CP-47 is absent in a genetically engineered mutant of cyanobacterium Synechocystis 6803, in which the psbB gene [encoding the chlorophyll-binding photosystem II (PSII) protein CP-47] was interrupted. Another chlorophyll-binding PSII protein, CP-43, is present in the mutant, and functionally inactive PSII-enriched particles can be isolated from mutant thylakoids. We interpret these data as indicating that the PSII core complex of the mutant still assembles in the absence of CP-47. The mutant lacks a 77 K fluorescence emission maximum at 695 nm, suggesting that the PSII reaction center is not functional. The absence of primary photochemistry was indicated by EPR and optical measurements: no chlorophyll triplet originating from charge recombination between P680(+) and Pheo(-) was observed in the mutant, and there were no flash-induced absorption changes at 820 nm attributable to chlorophyll P680 oxidation. These observations lead us to conclude that CP-47 plays an essential role in the activity of the PSII reaction center.

Electron Transfer in the Photosynthetic Membrane: Influence of PH and Surface Potential on the P-680 Reduction Kinetics

The primary electron donor P-680 of the Photosystem-II reaction center was photoxidized by a short flash given after dark adaptation of photosynthetic membranes in which oxygen evolution was inhibited. The P-680(+) reduction rate was measured under different conditions of pH and salt concentration by following the recovery of the absorption change at 820 nm. As previously reported for Tris-washed chloroplasts (Conjeaud, H., and P. Mathis, 1980, Biochim. Biophys. Acta, 590:353-359) a fast phase of P-680(+) reduction slows down as the bulk pH decreases. When salt concentration increases, this fast phase becomes faster for pH above 4.5-5 and slower below. A quantitative interpretation is proposed in which the P-680(+) reduction kinetics by the secondary electron donor Z are controlled by the local pH. This pH, at the membrane level, can be calculated using the Gouy-Chapman theory. A good fit of the results requires to assume that the surface charge density of the inside of the membrane, near the Photosystem-II reaction center, is positive at low pH values and becomes negative as the pH increases, with a local isoelectric point approximately 4.8. These results lead us to propose a functional scheme in which a pH-dependent proton release is coupled to the electron transfer between secondary and primary donors of Photosystem-II. The H(+)/e ratio varies from 1 at low pH to 0 at high pH, with a real pK approximately 6.5 for the protonatable species.

Effect of protein relaxation on electron transfer from the cytochrome subunit to the bacteriochlorophyll dimer in Rps. sulfoviridis reaction centers within mixed adiabatic/nonadiabatic model

The broad set of nonexponential electron transfer (ET) kinetics in reaction centers (RC) from Rhodopseudomonas sulfoviridis in temperature range 297-40 K are described within a mixed adiabatic/nonadiabatic model. The key point of the model is the combination of Sumi-Marcus and Rips-Jortner approaches which can be represented by the separate contributions of temperature-independent vibrational (v) and temperature-dependent diffusive (d) coordinates to the preexponential factor, to the free energy of reaction DeltaG=DeltaG(v)+DeltaG(d)(T) and to the reorganization energy lambda=lambda(v)+lambda(d)(T). The broad distribution of protein dielectric relaxation times along the diffusive coordinate is considered within the Davidson-Cole formalism.

Intraprotein radical transfer during photoactivation of DNA photolyase

Amino-acid radicals play key roles in many enzymatic reactions. Catalysis often involves transfer of a radical character within the protein, as in class I ribonucleotide reductase where radical transfer occurs over 35 A, from a tyrosyl radical to a cysteine. It is currently debated whether this kind of long-range transfer occurs by electron transfer, followed by proton release to create a neutral radical, or by H-atom transfer, that is, simultaneous transfer of electrons and protons. The latter mechanism avoids the energetic cost of charge formation in the low dielectric protein, but it is less robust to structural changes than is electron transfer. Available experimental data do not clearly discriminate between these proposals. We have studied the mechanism of photoactivation (light-induced reduction of the flavin adenine dinucleotide cofactor) of Escherichia coli DNA photolyase using time-resolved absorption spectroscopy. Here we show that the excited flavin adenine dinucleotide radical abstracts an electron from a nearby tryptophan in 30 ps. After subsequent electron transfer along a chain of three tryptophans, the most remote tryptophan (as a cation radical) releases a proton to the solvent in about 300 ns, showing that electron transfer occurs before proton dissociation. A similar process may take place in photolyase-like blue-light receptors.

Uphill electron transfer in the tetraheme cytochrome subunit of the Rhodopseudomonas viridis photosynthetic reaction center: evidence from site-directed mutagenesis

The cytochrome (cyt) subunit of the photosynthetic reaction center from Rhodopseudomonas viridis contains four heme groups in a linear arrangement in the spatial order heme1, heme2, heme4, and heme3. Heme3 is the direct electron donor to the photooxidized primary electron donor (special pair, P(+)). This heme has the highest redox potential (E(m)) among the hemes in the cyt subunit. The E(m) of heme3 has been specifically lowered by site-directed mutagenesis in which the Arg residue at the position of 264 of the cyt was replaced by Lys. The mutation decreases the E(m) of heme3 from +380 to +270 mV, i.e., below that of heme2 (+320 mV). In addition, a blue shift of the alpha-band was found to accompany the mutation. The assignment of the lowered E(m) and the shifted alpha-band to heme3 was confirmed by spectroscopic measurements on RC crystals. The structure of the mutant RC has been determined by X-ray crystallography. No remarkable differences were found in the structure apart from the mutated residue itself. The velocity of the electron transfer (ET) from the tetraheme cyt to P(+) was measured under several redox conditions by following the rereduction of P(+) at 1283 nm after a laser flash. Heme3 donates an electron to P(+) with t(1/2) = 105 ns, i.e., faster than in the wild-type reaction center (t(1/2) = 190 ns), as expected from the larger driving force. The main feature is that a phase with t(1/2) approximately 2 micros dominates when heme3 is oxidized but heme2 is reduced. We conclude that the ET from heme2 to heme3 has a t(1/2) of approximately 2 micros, i.e., the same as in the WT, despite the fact that the reaction is endergonic by 50 meV instead of exergonic by 60 meV. We propose that the reaction kinetics is limited by the very uphill ET from heme2 to heme4, the DeltaG degrees of which is about the same (+230 meV) in both cases. The interpretation is further supported by measurements of the activation energy (216 meV in the wild-type, 236 meV in the mutant) and by approximate calculations of ET rates. Altogether these results demonstrate that the ET from heme2 to heme3 is stepwise, starting with a first very endergonic step from heme2 to heme4.

Intraprotein electron transfer between tyrosine and tryptophan in DNA photolyase from Anacystis nidulans

Light-induced electron transfer reactions leading to the fully reduced, catalytically competent state of the flavin adenine dinucleotide (FAD) cofactor have been studied by flash absorption spectroscopy in DNA photolyase from Anacystis nidulans. The protein, overproduced in Escherichia coli, was devoid of the antenna cofactor, and the FAD chromophore was present in the semireduced form, FADH., which is inactive for DNA repair. We show that after selective excitation of FADH. by a 7-ns laser flash, fully reduced FAD (FADH-) is formed in less than 500 ns by electron abstraction from a tryptophan residue. Subsequently, a tyrosine residue is oxidized by the tryptophanyl radical with t(1)/(2) = 50 microseconds. The amino acid radicals were identified by their characteristic absorption spectra, with maxima at 520 nm for Trp. and 410 nm for TyrO. The newly discovered electron transfer between tyrosine and tryptophan occurred for approximately 40% of the tryptophanyl radicals, whereas 60% decayed by charge recombination with FADH- (t(1)/(2) = 1 ms). The tyrosyl radical can also recombine with FADH- but at a much slower rate (t(1)/(2) = 76 ms) than Trp. In the presence of an external electron donor, however, TyrO. is rereduced efficiently in a bimolecular reaction that leaves FAD in the fully reduced state FADH-. These results show that electron transfer from tyrosine to Trp. is an essential step in the process leading to the active form of photolyase. They provide direct evidence that electron transfer between tyrosine and tryptophan occurs in a native biological reaction.

Effects of temperature and deltaGo 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 -deltaGo is varied over a range of 350 meV. The temperature and deltaGo dependences of the rate constant fit the Marcus equation well. Global analysis yields a reorganization energy lambda = 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 approximately 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 deltaGo, characterized by a similar value of lambda (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.

Membrane-anchored cytochrome cy mediated microsecond time range electron transfer from the cytochrome bc1 complex to the reaction center in Rhodobacter capsulatus

In Rhodobacter capsulatus, the soluble cytochrome (cyt) c2 and membrane-associated cyt cy are the only electron carriers which operate between the photochemical reaction center (RC) and the cyt bc1 complex. In this work, cyt cy mediated microsecond time range electron transfer kinetics were studied by light-activated time-resolved absorption spectroscopy using a mutant strain lacking cyt c2. In intact cells and in isolated chromatophores of this mutant, only approximately 30% of the RCs had their photooxidized primary donor rapidly rereduced by cyt cy. Of these 30%, about half were reduced with a half-time of approximately 5 micros attributed to preformed complexes, and the other half with a half-time of approximately 40 micros attributed to cyt cy having to move from another site. This slower phase was affected by addition of glycerol, indicating its dependence on the viscosity of the medium. Cyt cy, despite its rereduction by ubihydroquinone oxidation in the millisecond time range, remained virtually unable to deliver electrons to other RCs which stayed photooxidized for several seconds. Furthermore, using two flashes separated by a variable time interval, it was shown that the fast electron donating complex was reformed in about 60 micros, a time span probably reflecting electron transfer from cyt c1 to cyt cy. In the absence of the cyt bc1 complex, the steady-state level of cyt cy in the chromatophore membranes obtained using cells grown in minimal medium was decreased to approximately 50%. The remaining cyt cy , however, was able to form the fast electron donating complex with the RC (half-time of approximately 5 micros), whereas the slower phase with a half-time of approximately 40 micros was strongly decelerated. This finding suggests a role for the cyt bc1 complex in stabilizing cyt cy and providing its "other" site, possibly via a close association between these components. Taken together, it is concluded that although cyt cy is present in substoichiometric amount compared to the RCs, it supports efficiently photosynthetic growth of R. capsulatus in the absence of cyt c2 because it can mediate fast electron transfer from the cyt bc1 complex to the RC during multiple turnovers of the cyclic electron flow.

Low-temperature electron transfer from cytochrome to the special pair in Rhodopseudomonas viridis: role of the L162 residue

Electron transfer from the tetraheme cytochrome c to the special pair of bacteriochlorophylls (P) has been studied by flash absorption spectroscopy in reaction centers isolated from seven strains of the photosynthetic purple bacterium Rhodopseudomonas viridis, where the residue L162, located between the proximal heme c-559 and P, is Y (wild type), F, W, G, M, T, or L. Measurements were performed between 294 K and 8 K, under redox conditions in which the two high-potential hemes of the cytochrome were chemically reduced. At room temperature, the kinetics of P+ reduction include two phases in all of the strains: a dominant very fast phase (VF), and a minor fast phase (F). The VF phase has the following t(1/2): 90 ns (M), 130 ns (W), 135 ns (F), 189 ns (Y; wild type), 200 ns (G), 390 ns (L), and 430 ns (T). These data show that electron transfer is fast whatever the nature of the amino acid at position L162. The amplitudes of both phases decrease suddenly around 200 K in Y, F, and W. The effect of temperature on the extent of fast phases is different in mutants G, M, L, and T, in which electron transfer from c-559 to P+ takes place at cryogenic temperatures in a substantial fraction of the reaction centers (T, 48%; G, 38%; L, 23%, at 40 K; and M, 28%, at 60 K), producing a stable charge separated state. In these nonaromatic mutants the rate of VF electron transfer from cytochrome to P+ is nearly temperature-independent between 294 K and 8 K, remaining very fast at very low temperatures (123 ns at 60 K for M; 251 ns at 40 K for L; 190 ns at 8 K for G, and 458 ns at 8 K for T). In all cases, a decrease in amplitudes of the fast phases is paralleled by an increase in very slow reduction of P+, presumably by back-reaction with Q(A)-. The significance of these results is discussed in relation to electron transfer theories and to freezing at low temperatures of cytochrome structural reorganization.

Cross-linked electron transfer complex between cytochrome c2 and the photosynthetic reaction center of Rhodobacter sphaeroides

Electron donation from the soluble cytochrome (cyt) c2 to the photooxidized primary donor, P+, of reaction centers isolated from Rhodobacter sphaeroides was studied by using chemical zero-length cross-linking. This cross-linking stabilizes a 1:1 covalent complex between subunit M of the reaction center and cyt c2. In 80% of the reaction centers, P+ generated by a laser flash is reduced by covalently bound cyt c2. Kinetics of P+ reduction show (i) a fast phase with a half-life of 0.7 micros similar to that observed for electron transfer in the noncovalent proximal complex and (ii) a slow phase (t1/2 = 60 micros) that is attributed to a cyt c2 bound less favorably for electron transfer. Its relationship with similar kinetic phases attributed to a distal conformation of the complex in previous studies is discussed. Both kinetic phases are slightly accelerated upon addition of glycerol. Upon addition of reduced soluble cyt c2 to the cross-linked complex the kinetics of both phases are not affected. The kinetics of P+ reduction following the second flash (20 ms after the first) show that a complex is formed between soluble cyt c2 and the cross-linked complex, in which electron transfer takes place in the millisecond time domain. Cross-linked cyt c2 in complexes which give rise to the two kinetic phases of P+ reduction shows almost pH-independent midpoint redox potentials between pH 6 and 9.5. This behavior is at variance with that of free cyt c2, the midpoint potential of which is affected by at least two protonable groups within this pH range. The cross-linked RC-cyt c2 complex allowed study of the effects of temperature on the electron transfer reaction without a possible disturbance by dissociation of the complex. In the 250-300 K range, Arrhenius behavior is observed showing activation energies of 11.7 and 8.0 kJ/mol for the faster and the slower kinetic phases, respectively, which are remarkably lower than the activation energy of 20.5 kJ/mol for the fast P+ reduction by soluble cyt c2 [Venturoli, G., Mallardi, A., & Mathis, P. (1993) Biochemistry 32, 13245-13253]. Between 250 and 230 K, a fall-off in amplitude is observed for both kinetic phases indicating that intracomplex electron transfer is blocked at low temperatures.

Structure and function of cytochrome c2 in electron transfer complexes with the photosynthetic reaction center of Rhodobacter sphaeroides: optical linear dichroism and EPR

The photosynthetic reaction center (RC) and its secondary electron donor the water-soluble cytochrome (cyt) c2 from the purple bacterium Rhodobacter sphaeroides have been used in cross-linked and non-cross-linked complexes, oriented in compressed gels or partially dried multilayers, to study the respective orientation of the primary donor P (BChl dimer) and of cyt c2. Three methods were used: (i) Polarized optical absorption spectra at 295 and 10 K were measured and the linear dichroism of the two individual transitions (Qx, Qy), which are nearly degenerate within the alpha-band of reduced cyt c2, was determined. Attribution of the polarization directions to the molecular axes within the heme plane yielded the average cyt orientation in the complexes. (ii) Time-resolved flash absorption measurements using polarized light allowed determination of the orientation of cyt c2 in complexes which differ in their kinetics of electron transfer. (iii) EPR spectroscopy of ferricyt c2 in cross-linked RC-cyt c2 complexes was used to determine the angle between the heme and the membrane plane. The results suggest the following structural properties for the docking of cyt c2 to the RC: (i) In cross-linked complexes, the two cytochromes displaying half-lives of 0.7 and 60 micros for electron transfer to P+ are similarly oriented (difference < 10 degrees). (ii) For cross-linked cyt c2 the heme plane is parallel to the symmetry axis of the RC (0 degrees +/- 10 degrees). Moreover, the Qy transition, which is assumed to be polarized within the ring III-ring I direction of the heme plane, makes an angle of 56 degrees +/- 1 degree with the symmetry axis. (iii) The dichroism spectrum for the fast phase (0.7 micros) for the non-cross-linked cyt c2-RC complex suggests an orientation similar to that of cross-linked cyt c2, but the heme plane is tilted about 20 degrees closer to the membrane. An alternative model is that two or more bound states of cyt c2 with heme plane tilt angles between 0 degrees and 30 degrees allow the fast electron transfer. Zero-length cross-linking of cyt c2 may take place in one of these bound states. These orientations of cyt c2 are compared to different structural models of RC-cyt c2 complexes proposed previously. The relation of the two kinetic phases observed in cross-linked cyt c2 complexes to biphasic kinetics of the mobile reaction partners is discussed with respect to the dynamic electrostatic interactions during the formation of a docking complex and its dissociation. A mechanism is proposed in which a pre-orientation of cyt c2 relative to the membrane plane occurs by interaction of its strong electrostatic dipole with the negative surface charges of the RC. The optimal matching of the oppositely charged surfaces of the two proteins necessitates further rotation of the cyt around its dipole axis.

Very fast electron transfer from cytochrome to the bacterial photosynthetic reaction center at low temperature

Electron transfer from the proximal heme c-559 to the primary donor P has been studied in reaction centers of the photosynthetic bacterium Rhodopseudomonas viridis in which the tyrosine residue L162 was replaced by threonine. In the wild type, when the two high-potential hemes of the tetraheme cytochrome are reduced before flash excitation, a rapid electron transfer (t1/2 = 190 ns) observed at ambient temperature disappears below 190 K. In the mutant, the reaction is partly maintained down to 8 K, leading to irreversible charge separation. The reaction rate is nearly temperature-independent between 294 K and 8 K (t1/2 approximately 450 ns). The different behavior of wild type and mutant reaction centers is attributed to differences in a network of water molecules, the freezing of which may block structural reorganizations associated with cytochrome oxidation, in the wild type but not in the mutant.

Temperature dependence of the reorganization energy for charge recombination in the reaction center from Rhodobacter sphaeroides

The rate of charge recombination from the primary quinone to the bacteriochlorophyll dimer of the reaction center from the photosynthetic purple bacterium Rhodobacter sphaeroides has been investigated using time-resolved optical spectroscopy. Measurements were performed at temperatures from 293 to 10 K on reaction centers that have specific mutations that result in a range of 425-780 meV for the free energy difference of charge recombination compared to 520 meV for wild type [Lin, X., Murchison, H. A., Nagarajan, V., Parson, W. W., Allen, J. P., & Williams, J.C. (1994) Proc.Natl.Acad.Sci.U.S.A. 91, 10265-10269]. In all cases, the rate increased as the temperature decreased, although the details of the dependence were different for each mutant. The observed dependence of the rate upon temperature is modeled as arising principally from a several hundred meV change in reorganization energy. The relationships among the rate, temperature, and free energy differences can be well fit by a Marcus surface using two modes centered near 150 and 1600 cm(-1)with a total reorganization energy that decreases from 930 to 650 meV as the temperature decreases from 293 to 10 K. In the inverted region, where the driving force is greater than the reorganization energy, the rate is found to be approximately independent of the free energy difference. This is modeled as due to the additional coupling of high frequency modes to the reaction. An alternative model is also considered in which a 140 meV increase in the reorganization energy is matched by a 140 meV increase in the free energy difference as the temperature decreases. The possible role of solvent dipoles in determining this temperature dependence of the reorganization energy and the implications for other electron transfer reactions are discussed.

Electron transfer from the tetraheme cytochrome to the special pair in the Rhodopseudomonas viridis reaction center: effect of mutations of tyrosine L162

The structure of the photosynthetic reaction center (RC) from Rhodopseudomonas viridis is known to high resolution. It contains a firmly bound tetraheme cytochrome from which electrons are donated to a special pair (P) of bacteriochlorophylls, which is photooxidized upon absorption of light. Tyrosine at position 162 of the L-subunit of the reaction center (L 162 Y) is a highly conserved residue positioned halfway between P and the proximal heme group (c-559) of the cytochrome. By specific mutagenesis this residue was exchanged against the amino acids phenylalanine (F), glycine (G), methionine (M), leucine (L), tryptophan (W), threonine (T), and histidine (H). All mutants were expressed in Rps. viridis using a recently established transformation system [Laussermair & Oesterhelt (1992) EMBO J. 11, 777-783]. They were shown biochemically to synthesize all four subunits of the RC (cytochrome, subunits L, M, and H) and to assemble them correctly into the membrane. The structures of two mutants (L 162 F and L 162 T) were determined and found not to differ significantly from the wild-type structure. All mutants grew photosynthetically. The absorption spectrum of all the mutants is the same as in WT, but the redox potential of P and of c-559 was changed by the mutations. The kinetics of electron transfer from the heme group to the special pair were measured in chromatophores by flash absorption. As found earlier in the wild type (Y) several exponential components were needed to fit the data.(ABSTRACT TRUNCATED AT 250 WORDS)

Relationship between rate and free energy difference for electron transfer from cytochrome c2 to the reaction center in Rhodobacter sphaeroides

The rate of electron transfer from cytochrome c2 to the bacteriochlorophyll dimer of the reaction center from the photosynthetic bacterium Rhodobacter sphaeroides has been investigated using time-resolved optical spectroscopy. Measurements were performed on a series of mutant reaction centers in which the midpoint potentials of the bacteriochlorophyll dimer vary over a range of 350 mV. Dramatic changes in the characteristic time of electron transfer were observed, with the measured values ranging from 7730 to 80 ns compared to 960 ns for wild type. The binding constants (0.15 to 0.25 microM-1) and the second-order rate constants for the slow component (5.5 x 10(8) to 9.4 x 10(8) M-1 s-1) for the mutants are similar to the corresponding values for wild type (0.35 microM-1 and 11 x 10(8) M-1 s-1), indicating that the binding of the cytochrome to the reaction center is not changed in the mutants. In the mutants with the fastest rates, an additional minor component was resolved that is probably due to formation of a reaction center-cytochrome complex in an unfavorable configuration with a binding constant an order of magnitude weaker than the major component. The altered midpoint potentials in the mutants result in values for the free energy difference for this electron transfer reaction ranging from -65 to -420 meV compared to -160 meV for wild type. The relationship between the rate and free energy difference was well fit by a Marcus equation using a reorganization energy of 500 meV.(ABSTRACT TRUNCATED AT 250 WORDS)

Interaction between cytochrome c2 and reaction centers from purple bacteria

The kinetics of electron transfer of cytochrome c2 from Rhodobacter sphaeroides, Rhodobacter capsulatus, and Rhodospirillum centenum to reaction centers from Rb. sphaeroides and Rb. capsulatus have been measured. Observed in the kinetics of decay of the oxidized donor are a rapid first-order rate and one or more slower rates that are due to diffusion-limited complex formation. For reaction centers from Rb. sphaeroides, the fast component had time constants of 1.0 and 0.5 microsecond for cytochrome c2 from Rb. sphaeroides and Rb. capsulatus, respectively, but only a slow component was observed for cytochrome c2 from Rs. centenum. For reaction centers from Rb. capsulatus, the kinetics from all three cytochromes had a fast component with time constants of 1.0, 0.7, and 1.9 microseconds for cytochrome c2 from Rb. sphaeroides, Rb. capsulatus, and Rs. centenum, respectively, although the dissociation constant for cytochrome c2 from Rs. centenum was approximately 20 times larger than that of the other cytochromes. The observation of the fast component for cytochrome c2 from Rs. centenum in reaction centers from Rb. capsulatus but not Rb. sphaeroides demonstrates that the binding interactions for the two reaction centers differ, and the involvement of amino acid residues in the binding is discussed. The kinetics of electron transfer from cytochrome c2 to reaction centers of Rb. sphaeroides from wild type and three mutant strains that have altered carboxyl-terminal regions of the M subunit of the reaction center have also been measured. For cytochrome c2 from Rb. sphaeroides, the kinetics are very similar between the mutants and wild type.(ABSTRACT TRUNCATED AT 250 WORDS)

Interaction between cytochrome c and the photosynthetic reaction center of purple bacteria: behaviour at low temperature

In purple photosynthetic bacteria the electron donor to the special pair, after its oxidation by a light-induced reaction, is a c-type cytochrome: either a soluble monoheme cytochrome which forms a transitory complex with the reaction center, or a tetraheme cytochrome which remains permanently bound to the reaction center. The effects of low temperatures on electron transfer in the complex are presented and discussed. They provide estimates for the reorganization energy. The most prominent effect of low temperature is that a dominant fast phase of electron transfer becomes impossible at a temperature of around 250 K (monoheme cytochrome) or located between 250 K and 80 K according to the redox state (tetraheme cytochrome). This inhibition is attributed to a freezing-like transition of pools of water molecules which blocks structural changes of the protein which are normally associated with the cytochrome oxidation.

Electron transfer from cytochrome c2 to the primary donor of Rhodobacter sphaeroides reaction centers. A temperature dependence study

Kinetics of flash-induced electron transfer from the soluble cytochrome c2 to the primary donor (P) of the reaction center purified from the purple bacterium Rhodobacter sphaeroides R-26 were investigated by time-resolved absorption spectroscopy. Re-reduction of P+ induced by a laser pulse was measured at 1283 nm both in isolated reaction centers and in reconstituted proteoliposomes reproducing the lipid composition of the native membrane. The effects of temperature (230-300 K) and of the cytochrome c2/reaction center stoichiometry were examined. At room temperature, over a wide range of cytochrome c2 to reaction center molar ratios, the biphasic kinetics of cytochrome c2 oxidation in the microsecond-to-millisecond time scale could be accurately described by a minimum reaction scheme which includes a second-order collisional process (k = 1.4 x 10(9) M-1 s-1 and k = 2.4 x 10(9) M-1 s-1 in isolated and reconstituted reaction centers, respectively) and a first-order intracomplex electron donation (t1/2 = 590 +/- 110 ns in isolated reaction centers; t1/2 = 930 +/- 140 ns in proteoliposomes). At cytochrome c2 to reaction center molar ratios exceeding 5, the monomolecular process almost completely accounts for P+ re-reduction. At lower stoichiometries, the relative contribution of the two parallel reaction pathways is modulated by a single binding equilibrium between cytochrome c2 and reaction centers, yielding a binding constant of 3.5 x 10(5) M-1 in both systems.(ABSTRACT TRUNCATED AT 250 WORDS)

Tyrosine 162 of the photosynthetic reaction center L-subunit plays a critical role in the cytochrome c2 mediated rereduction of the photooxidized bacteriochlorophyll dimer in Rhodobacter sphaeroides. 2. Quantitative kinetic analysis

The electron-transfer kinetics from the soluble cytochrome (cyt) c2 to the photooxidized reaction center (RC) was studied with proteins isolated from Rhodobacter (R.) sphaeroides. In addition to wild-type (WT) RC, RCs harboring site-directed mutations at residue L162 (L162F, -M, -L, -S, or -G) wree analyzed. The disappearance of the absorption band of the photooxidized primary donor P+ (at 1250 nm) and the alpha-band of cyt c2 (at 550 nm) were monitored. Under conditions of high equimolar RC and cyt c2 concentrations, the kinetics were very similar to those measured in intact cells (Farchaus et al., 1993). The fast component of the kinetics normally seen in WT was not observed in any of the mutants; the overall rereduction rates for the mutants depended on the amino acid substitution. Light intensity, viscosity, ionic strength, and RC/cyt c2 stoichiometry of the reaction mixture were varied to distinguish the contributions of association, reorientation, and electron-transfer reactions to the observed kinetics. In competition experiments, WTRC (L162Y) and the mutant RCL162L showed similar affinity for cyt c2, with a dissociation constant of kD = 10(-6) M. Mutants with an aliphatic substitution at position L162 displayed slower cyt c2-RC association and dissociation rates. Comparison of the major kinetic component of the P+ rereduction rates for the aliphatic substitutions to the aromatic substitution, L162F, revealed that the former were less affected by ionic strength and viscosity than the latter. The viscosity and ionic strength dependences noted for L162F were comparable to those seen for the slow kinetic component observed for the WT RC. The redox midpoint potential of the P/P+ couple was increased by 30 mV (L162F) to 50 mV (L162L, G) over the WT value, leading to differences in delta G not large enough to account for the drastic kinetic effects. Rather, the results suggested that the state(s) where cyt c2 is nonproductively bound to the RC dominated in the mutants. In the L162F mutant, it appeared that only the distribution between the bound cyt c2 states was affected, whereas for the mutants with aliphatic substitutions, a decreased reorientation rate had to be additionally assumed in order to explain the observations.

Tyrosine 162 of the photosynthetic reaction center L-subunit plays a critical role in the cytochrome c2 mediated rereduction of the photooxidized bacteriochlorophyll dimer in Rhodobacter sphaeroides. 1. Site-directed mutagenesis and initial characterization

Five site-directed mutants were engineered to substitute phenylalanine, serine, leucine, methionine, and glycine for tyrosine residue 162 of the pufL gene in Rhodobacter (R.) sphaeroides. Each of the mutations and the wild-type (WT) genes was expressed in the R. sphaeroides puf deletion strain PUF delta LMX21/3. Initial characterization revealed that all of the mutants were photoheterotrophically competent but that L162G and L162S were impaired. The amounts of mutant reaction centers expressed, the spectral characteristics, and the rates of intraprotein electron transfer and turnover were similar to the values obtained for WT. Kinetic measurements of photooxidized special pair rereduction mediated by the physiological donor cytochrome c2 in intact chemoheterotrophically grown cells revealed that the fast phase was abolished in all mutants and that the overall kinetics of rereduction was drastically slowed. It is concluded that L162Y plays a vital role in facilitating the rapid rereduction of the photooxidized bacteriochlorophyll dimer in R. sphaeroides.

Electron transfer from the tetraheme cytochrome to the special pair in isolated reaction centers of Rhodopseudomonas viridis

Kinetics of electron transfer from the bound tetraheme cytochrome c to the primary donor (P) have been measured in isolated reaction centers of the purple bacterium Rhodopseudomonas viridis by time-resolved flash absorption spectroscopy. The influence of two major parameters has been studied: temperature (7-305 K) and the redox state of the cytochrome. Most experiments were done with one heme (c-559), two hemes (c-559 and c-556), or three hemes (c-559, c-556, and c-552) poised in a reduced state before the flash. Measurements were done at 1283 nm in the absorption band of P+, and in the region of cytochrome alpha-bands. At room temperature, c-559 donates an electron to P+ with a half-time of 115, 190, or 230 ns (with three, two, or one heme reduced, respectively) and is then eventually rereduced by c-556 (t1/2 = 1.7 microseconds) or by c-552 (in less than 40 ns). The kinetics also include a minor microsecond phase of P+ reduction. At decreasing temperatures, the polyphasic character of P+ rereduction is accentuated. Fast phases (115 ns-10 microseconds) are slightly slowed down, following Arrhenius behavior with a weak activation energy (3.6-8.6 kJ.mol-1), until they become temperature-independent. Their extent decreases rather sharply, at temperatures which vary according to the redox poising: 250, 210, or 80 K when one, two, or three hemes are reduced, respectively. In the last case, P+ can still be reduced at low temperature, apparently directly by c-552 (t1/2 = 1.1 ms, nearly temperature-independent).(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of temperature on the kinetics of electron transfer from the tetraheme cytochrome to the primary donor in Rhodopseudomonas viridis

The kinetics of electron transfer from the third highest potential heme (c-552, Em = +20 mV) to the primary donor (P-960) have been measured by flash absorption spectroscopy in isolated reaction centers of Rhodopseudomonas viridis between 300 K and 7 K. The data are analyzed on the basis of three exponential components with a very fast phase (t1/2 = 120 ns) dominating at high temperature and a very slow one (t1/2 = 1.2 ms) at low temperature. This multiphasic behavior is interpreted in terms of the existence of three states with a temperature-dependent population and a very limited effect of the temperature on the kinetics for each state.

Effects of selective destruction of iron-sulfur center B on electron transfer and charge recombination in Photosystem I

Incubation of spinach thylakoids with HgCl2 selectively destroys Fe-S center B (FB). The function of electron acceptors in FB-less PS I particles was studied by following the decay kinetics of P700(+) at room temperature after multiple flash excitation in the absence of a terminal electron acceptor. In untreated particles, the decay kinetics of the signal after the first and the second flashes were very similar (t 1/2∼2.5 ms), and were principally determined by the concentration of the artificial electron donor added. The decay after the third flash was fast (t 1/2∼0.25 ms). In FB-less particles, although the decay after the first flash was slow, fast decay was observed already after the second flash. We conclude that in FB-less particles, electron transfer can proceed normally at room temperature from FX to FA and that the charge recombination between P700(+) and FX (-)/A1 (-) predominated after the second excitation. The rate of this recombination process is not significantly affected by the destruction of FB. Even in the presence of 60% glycerol, FB-less particles can transfer electrons to FA at room temperature as efficiently as untreated particles.

Characterization of four herbicide-resistant mutants of Rhodopseudomonas viridis by genetic analysis, electron paramagnetic resonance, and optical spectroscopy

Herbicides of the triazine class block electron transfer in the photosynthetic reaction centers of purple bacteria and PSII of higher plants. They are thought to act by competing with one of the electron acceptors, the secondary quinone, QB, for its binding site. Several mutants of the purple bacterium Rhodopseudomonas viridis resistant to terbutryn [2-(methylthio)-4-(ethylamino)-6-(tert-butylamino)-s-triazine] have been isolated by their ability to grow photosynthetically in the presence of the herbicide. Sequence analysis of the genes coding for the L and M subunits of the reaction center showed that four different mutants were obtained, two of them being double mutated: T1 (SerL223----Ala and ArgL217----His), T3 (PheL216----Ser and ValM263----Phe), T4 (TyrL222----Phe), and T6 (PheL216----Ser). The residues L223 and L216 are involved in binding of QB, whereas L217 and L222 are not. M263 is part of the binding pocket of the primary quinone, QA. The affinity of the reaction centers for terbutryn and the electron transfer inhibitor o-phenanthroline, determined via the biphasic charge recombination after one flash, is decreased for all mutants. The affinity for ubiquinone 9 is also decreased, except in T1. Characterization by EPR spectroscopy showed that the QB.-Fe2+ signal of T4, having a g = 1.93 peak, is different from the signals obtained with the wild type and the other mutants but very similar to those of Rhodospirillum rubrum and PSII. The results obtained by the combination of these different techniques are discussed with respect to the three-dimensional structure of the wild type and the mode of binding of ubiquinone, terbutryn, and o-phenanthroline as determined by X-ray structure analysis.

EPR and optical changes of the photosystem II reaction center produced by low temperature illumination

Electron paramagnetic resonance (EPR) and absorption spectroscopy have been used to study the low temperature photochemical behavior of the Photosystem II D-1/D-2/ cytochrome b559 reaction center complex. The reaction center displays large triplet state EPR signals which are attenuated after actinic illumination at low temperatures in the presence of sodium dithionite. Concomitant with the triplet attenuation is the buildup of a structured radical signal with an effective g value of 2.0046 and a peak-to-peak width of 11.9 G. The structure in the signal is suggestive of it being comprised in part of the anion radical of pheophytin a. This assignment is corroborated by low temperature optical absorbance measurements carried out after actinic illumination at the low temperatures which show absorption bleachings at 681 nm, 544 nm and 422 nm and an absorbance buildup at 446 nm indicating the formation of reduced pheophytin.

Nanosecond flash studies of the absorption spectrum of the Photosystem I primary acceptor Ao

Photosystem I particles devoid of the secondary electron acceptor A1 were studied by nanosecond flash absorption. The primary radical pair (P-700(+), A0 (-)) decays with a half-time of 35 ns. The difference spectrum was measured (400-870 nm). After subtraction of the P-700(+)/P-700 difference spectrum, the A0 (-)/A0 was obtained. It includes bleachings centered at 690 and 430 nm, and broad positive bands in the near infra-red and the blue-green. This spectrum is consistent with A0 being chlorophyll a absorbing at 690 nm.

[Efficacy of verapamil in mania crises]

The authors review the different studies on the use of calcium antagonists in the treatment of acute mania. They present 7 cases, of which 4 with manic-depressive psychosis and 3 with schizo-affective disorder, during acute mania as defined by DSM III criteria, treated by verapamil at the dose of 320 mg/day. Four patients improved (2 manic-depressive, 2 schizo-affective), of which one that had responded neither to haloperidol nor to clonidine, and another for which all other treatment was contra-indicated due to important side effects. Three of these patients entered into acute depressive state between the 12th and the 15th day of treatment. The two most severe (manic-depressive) cases did not respond. The role of calcium in neuron physiology and the mode of action of calcium antagonists are outlined. The authors discuss the physiopathological hypothesis of Dubovsky.

Functional role of vitamin K in photosystem I of the cyanobacterium Synechocystis 6803

The function of vitamin K1 in the primary electron-transfer processes of photosystem I (PS I) was investigated in the cyanobacterium Synechocystis 6803. A preparation of purified PS I was found to contain two vitamin K1's per reaction center. One vitamin K1 was removed by extraction with hexane, and further extraction using hexane including 0.3% methanol resulted in a preparation devoid of vitamin K1. The hexane-extracted PS I was functional in the photoreduction of NADP+, but the PS I after extraction using hexane-methanol was totally inactive. Activity was restored by using exogenous vitamin K1 plus the hexane extract. Vitamin K3 would not substitute. The room temperature recombination kinetics of the PS I extracted with hexane were not significantly modified. However, following the removal of both vitamin K1's, the 20-ms recombination between P-700+ and P-430- was replaced by a dominant relaxation (t 1/2 = 30 ns) due to recombination of the primary biradical P-700+ A0- and a slower component originating from the P-700 triplet. This kinetic behavior was consistent with an interruption of forward electron transfer to the acceptor A1. Addition of either vitamin K1 or vitamin K3 to such preparations resulted in restoration of the slow kinetic phase (greater than 2 ms), indicating significant competition by the two exogenous quinones for electron transfer from A0-. In the case of vitamin K3, this change in the kinetics induced by vitamin K1, suggesting successful reconstitution of the acceptor site A1. These data support the hypothesis that acceptor A1 is vitamin K1 and is a component of the electron-transfer pathway for NADP+ reduction.

[Plasma amino acid disturbances and depression]

Plasmatic amino acids concentrations were measured in 59 depressive patients and compared with that of a control population. Serine, glutamine, cystine, lysine and arginine have increased levels in the depressed males and females; so are 3 competitors of the tryptophan for the transport through the blood-brain barrier: valine, leucine and isoleucine. The tryptophan ratio is decreased in the depressive males. The sum of the competitors of the tryptophan is increased in the depressive males and females. All these results are discussed in relation with an abnormality of the carrier through the blood-brain barrier in the depressive state, without no proof thereof being however given.

Influence of magnetic fields on the P-870 triplet state in Rps. sphaeroides reaction centers

Magnetic fields influence two properties of the P-870 triplet state observed in Rps. sphaeroides reaction centers: the yield of formation and the kinetics of decay. These effects have been studied in reaction centers which were prepared in three different states: state QA (-), state QA (2-) and state (- QA) (QA depleted). The triplet yields decrease with increasing magnetic fields, with B1/2's of about 140, 41 and 57 Gauss, respectively. The half-time of (3)P-870 decay is not influenced by the field in state QA (-); it increases at increasing fields, in state QA (2-) and state (- QA), with the same B1/2 as the triplet yield. These results are discussed in the framework of current theories of the radical-pair dynamics and of the mechanism of triplet decay.

Stoichiometric determination of pheophytin in photosystem II of oxygenic photosynthesis

Pheophytin and chlorophyll extracted from oxygen-evolving photosystem II particles, chloroplast thylakoids and cyanobacterial cells were separated by column chromatography with DEAE-Toyopearl, and quantitatively determined by spectrophotometry. The molecular ratio of chlorophyll a+b to pheophytin a was about 100 in spinach photosystem II particles and about 140 in spinach thylakoids. Using flash spectrophotometry of P680 and measurement of flash-induced oxygen yield, the molecular ratio of the chlorophyll to the photochemical reaction center II was determined to be about 200 in the photosystem II particles. These findings suggest that the stoichiometry in photosystem II particles is one reaction center II and two pheophytin a molecules per about 200 chlorophyll molecules. The same stoichiometry for pheophytin to the reaction center II was obtained in the cyanobacteria, Anacystis nidulans and Synechocystis PCC 6714. A quantitative determination of pheophytin a and the electron donor P700 in stroma thylakoids from pokeweed suggests that photosystem I does not contain pheophytin.

Photosystem I photochemistry: A new kinetic phase at low temperature

A new phase of charge recombination between the oxidized primary electron donor of photosystem I (P700(+)) and a reduced acceptor has been detected by flash absorption spectroscopy in PS I particles at low temperature. It occurs under highly reducing conditions (the secondary electron acceptors FA and FB and one or possibly two 'more primary' acceptors being prereduced) with a t1/2 of about 20 μs between 10 and 80 K.