Electron transfer after flash photolysis of mixed-valence carboxycytochrome c oxidase

The light-induced difference spectra of the fully reduced (a³⁺a²⁺₃-CO) complex and the mixed-valence carboxycytochrome c oxidase (a³⁺a²⁺₃-CO) during steady-state illumination and after flash photolysis showed marked differences. The differences appear to be due to electron transfer between the redox centres in the enzyme. The product of the absorbance coefficient and the quantum yield was found to be equal in both enzyme species, both when determined from the rates of photolysis and from the values of the dissociation constants of the cytochrome a²⁺₃-CO complex. This would confirm that the spectral properties of cytochrome a₃ are not affected by the redox state of cytochrome a and Cu_A. When the absorbance changes after photolysis of cytochrome a²⁺₃-CO with a laser flash were followed on a time scale from 1 μs to 1 s in the fully reduced carboxycytochrome c oxidase, only the CO recombination reaction was observed. However, in the mixed-valence enzyme an additional fast absorbance change (k = 7·10³s^?1) was detected. The kinetic difference spectrum of this fast change showed a peak at 415 nm and a trough at 445 nm, corresponding to oxidation of cytochrome a₃. Concomitantly, a decrease of the 830 nm band was observed due to reduction of Cu_A. This demonstrates that in the partially reduced enzyme a pathway is present between Cu_A and the cytochrome a₃-Cu_B pair, via which electrons are transferred rapidly.     

Properties of photochemical reaction centers purified from Rhodopseudomonas gelatinosa

Reaction centers were isolated from a carotenoidless mutant of Rhodopseudomonas gelatinosa by hydroxyapatite chromatography of purified chromatophores treated with lauryl dimethyl amine oxide. Absorption spectra and spectra of light-induced absorbance changes are similar to those of reaction centers from Rhodopseudomonas sphaeroides. The ratio of absorbance at 280 nm to that at 799 nm was 1.8 in the purest preparations. The extinction coefficient at the 799 nm absorption maximum was estimated to be 305 ± 20 mM^?1 · cm^?1. The molecular weight based on protein and chromophore assays was found to be 1.5 · 10⁵; the reaction center protein accounted for 6% of the total membrane protein. These reaction centers contained no cytochrome and showed just two components of apparent molecular weights 33 000 and 25 000 in polyacrylamide gel electrophoresis. The chromatophores contained 42 molecules of antenna bacteriochlorophyll for each reaction center.     

Photosynthetic electron transport and electrochromic effects at sub-zero temperatures

Spinach chloroplasts, suspended in a liquid medium containing ethyleneglycol, showed reversible absorbance changes near 700 and 518 nm due to P-700 and “P-518” in the region from ?35 to ?50 °C upon illumination. The kinetics were the same at both wavelengths, provided absorbance changes due to Photosystem II were suppressed. At both wavelengths, the decay was slowed down considerably, not only by the System I electron acceptor methyl viologen, but also by silicomolybdate. The effect of the latter compound is probably not due to the oxidation of the reduced acceptor of Photosystem I by silicomolybdate, but to the enhanced accessibility of the acceptor to some other oxidant.In the presence of both an electron donor and acceptor for System I, a strong stimulation of the extent of the light-induced absorbance increase at 518 nm was observed. The most effective donor tested was reduced N-methylphenazonium methosulphate (PMS). The light-induced difference spectrum was similar to spectra obtained earlier at room temperature, and indicated electrochromic band shifts of chlorophylls a and b and carotenoid, due to a large potential over the thylakoid membrane, caused by sustained electron transport. It was estimated that steady-state potentials of up to nearly 500 mV were obtained in this way; the potentials reversed only slowly in the dark, indicating a low conductance of the membrane. This decay was accelerated by gramicidin D. The absorbance changes were linearly proportional to the membrane potential.     

Electron transfer after flash photolysis of mixed-valence carboxycytochrome c oxidase

The light-induced difference spectra of the fully reduced (a2+ a23+-CO) complex and the mixed-valence carboxycytochrome c oxidase (a3+ a23+-CO) during steady-state illumination and after flash photolysis showed marked differences. The differences appear to be due to electron transfer between the redox centres in the enzyme. The product of the absorbance coefficient and the quantum yield was found to be equal in both enzyme species, both when determined from the rates of photolysis and from the values of the dissociation constants of the cytochrome a23+-CO complex. This would confirm that the spectral properties of cytochrome a3 are not affected by the redox state of cytochrome a and CuA. When the absorbance changes after photolysis of cytochrome a23+-CO with a laser flash were followed on a time scale from 1 mus to 1 s in the fully reduced carboxycytochrome c oxidase, only the CO recombination reaction was observed. However, in the mixed-valence enzyme an additional fast absorbance change (k = 7 X 10(3) s-1) was detected. The kinetic difference spectrum of this fast change showed a peak at 415 nm and a trough at 445 nm, corresponding to oxidation of cytochrome a3. Concomitantly, a decrease of the 830 nm band was observed due to reduction of CuA. This demonstrates that in the partially reduced enzyme a pathway is present between CuA and the cytochrome a3-CuB pair, via which electrons are transferred rapidly.     

Modified Light-Induced Absorbance Changes in dim Y Photoresponse Mutants of Trichoderma

A brief pulse of blue light induces the common soil fungus Trichoderma harzianum to sporulate. Photoresponse mutants with higher light requirements than the wild type are available, including one class, dim Y, with modified absorption spectra. We found blue-light-induced absorbance changes in the blue region of the spectrum, in wild-type and dim Y mutant strains. The light-minus-dark difference spectra of the wild type and of several other strains indicate photoreduction of flavins and cytochromes, as reported for other fungi and plants. The difference spectra in strains with normal photoinduced sporulation have a prominent peak at 440 nm. After actinic irradiation, this 440 nanometer difference peak decays rapidly in the dark. In two dim Y photoresponse mutants, the difference spectra were modified; in one of these, LS44, the 440 nanometer peak was undetectable in difference spectra. Detailed study of the dark-decay kinetics in LS44 and the corresponding control indicated that the 440 nanometer difference peak escaped detection in LS44 because it decays faster than in the control. The action spectrum of the 440 nm difference peak is quite different from that of photoinduced sporulation. The light-induced absorbance changes are thus unlikely to be identical to the primary photochemical reaction triggering sporulation. Nevertheless, these results constitute genetic evidence that physiologically relevant pigments participate in these light-induced absorbance changes in Trichoderma.     

Evidence from studies with acifluorfen for participation of a flavin-cytochrome complex in blue light photoreception for phototropism of oat coleoptiles

The diphenyl ether acifluorfen enhances the blue light-induced absorbance change in Triton X100-solubilized crude membrane preparations from etiolated oat (Avena sativa L. cv. Lodi) coleoptiles. Enhancement of the spectral change is correlated with a change in rate of dark reoxidation of a b-type cytochrome. Similar, although smaller, enhancement was obtained with oxyfluorfen, nitrofen, and bifenox. Light-minus-dark difference spectra in the presence and absence of acifluorfen, and the dithionite-reduced-minus oxidized difference spectrum indicate that acifluorfen is acting specifically at a blue light-sensitive cytochrome-flavin complex. Sodium azide, a flavin inhibitor, decreases the light-induced absorbance change significantly, but does not affect the dark reoxidation of the cytochrome. Hence, it is acting on the light reaction, suggesting that the photoreceptor itself is a flavin. Acifluorfen sensitizes phototropism in dark-grown oat seedlings such that the first positive response occurs with blue light fluences as little as one-third of those required to elicit the same response in seedlings grown in the absence of the herbicide. Both this increase in sensitivity to light and the enhancement of the light-induced cytochrome reduction vary with the applied acifluorfen concentration in a similar manner. The herbicide is without effect either on elongation or on the geotropic response of dark-grown oat seedlings, indicating that acifluorfen is acting specifically close to, or at the photoreceptor end of, the stimulus-response chain. It seems likely that the flavin-cytochrome complex serves to transduce the light signal into curvature in phototropism in oats, with the flavin moiety itself serving as the photoreceptor.     

The incorporation of reaction centres into membranes from a bacteriochlorophyll-less mutant of Rhodopseudomonas sphaeroides

Reaction centres purified from a blue-green mutant R-26 of Rhodopseudomonas sphaeroides can be incorporated into bacteriochlorophyll-less membranes purified from an aerobically-grown bacteriochlorophyll-less mutant 01 of R. sphaeroides. This can be accomplished by raising the temperature of the mixture or by addition of the detergent sodium cholate and its subsequent removal by dilution or dialysis. Optimum conditions for the reconstitution are at 4°C in the presence of 1% cholate and soybean phospholipid (2 : 1, w/w, with membrane protein). Isopycnic sucrose density gradient centrifugation of such preparations shows that reaction centres and light-harvesting pigment-protein complex bind to the membranes. Reconstituted membranes exhibit light-induced steady-state cytochrome absorbance changes resembling those observed in chromatophores prepared from the photosynthetically-grown mutant R-26. The effect on these absorbance changes of varying reaction centre content in the membrane has been studied, and the time course of the interaction between 01 membrane cytochrome c₂ and added reaction centre examined.Cytochrome b photoreduction and cytochrome c₂ photo-oxidation were observed in the reconstituted preparation; each increased following the addition of antimycin A, suggesting that a cyclic light-driven system had been reconstituted.     

A Spectroscopic Analysis of a High Fluorescent Mutant of Chlamydomonas Reinhardi

Chloroplast fragments of a high fluorescent mutant of Chlamydomonas reinhardi, hfd 91, were compared against those of Acl⁺, a low chlorophyll variant of the wild type. The chloroplast fragments of the mutant which have a high invariant fluorescence yield lacked photochemical activities associated with photosystem II (PSII) but retained normal photosystem I (PSI) activities. The mutant fragments also lacked the low temperature (-196°C) light-induced absorbance changes due to the photoreduction of C-550 and the photooxidation of cytochrome (cyt) b-559 which are PSII-mediated reactions. A fourth-derivative analysis of the absolute spectra of the chloroplast fragments at different stages of reduction (obtained with ferricyanide, ascorbate, and dithionite) showed both the oxidized and reduced forms of C-550 and the reduced forms of cyt c-553, b-559, and b-564 in wild-type fragments. The mutant fragments lacked C-550 and an ascorbate-reducible cyt b-559 but contained cyt c-553, a dithionite-reducible cyt b-559, and cyt b-564.     

Blue Light-Reducible Cytochromes in Membrane Fractions from Neurospora crassa

We have assayed absorbance changes generated by blue light in plasma membranes, endoplasmic reticulum, and mitochondrial membranes from Neurospora crassa. Light minus dark difference spectra, obtained anaerobically in the presence of ethylenediaminetetraacetate, indicated that b-type cytochromes could be photoreduced in all three membranes. In plasma membranes, a b-type cytochrome with a distinct difference spectrum was photoreducible without addition of exogenous flavin. Addition of riboflavin greatly stimulated the photoreduction of cytochromes in endoplasmic reticulum and mitochondrial membranes. In its spectral characteristics the cytochrome on the endoplasmic reticulum resembled cytochrome b₅ or nitrate reductase, while the cytochrome in mitochondrial membranes had the same spectrum as cytochrome b of the mitochondrial respiratory chain.

Cytochromes in the three membrane fractions reacted differently to blue light in the presence of various inhibitors. Potassium azide inhibited reduction of plasma membrane cytochrome b, with 50% inhibition at 1.0 millimolar. The same concentration of azide stimulated photoreduction of cytochromes in both endoplasmic reticulum and mitochondria. Although photoreduction of cytochromes in all three membranes was inhibited by salicylhydroxamic acid, cytochromes in plasma membranes were more sensitive to this inhibitor than those in endoplasmic reticulum and mitochondria. Cells grown to induce nitrate reductase activity showed an elevated amount of blue light-reducible cytochrome b in the endoplasmic reticulum.

     

Effect of NADP+ on light-induced cytochrome changes in membrane fragments from a blue-green alga

The effect of NADP⁺ on light-induced steady-state redox changes of membrane-bound cytochromes was investigated in membrane fragments prepared from the blue-green algae Nostoc muscorum (Strain 7119) that had high rates of electron transport from water to NADP⁺ and from an artificial electron donor, reduced dichlorophenolindophenol (DCIPH₂) to NADP⁺. The membrane fragments contained very little phycocyanin and had excellent optical properties for spectrophotometric assays. With DCIPH₂ as the electron donor, NADP⁺ had no effect on the light-induced redox changes of cytochromes: with or without NADP⁺, 715- or 664-nm illumination resulted mainly in the oxidation of cytochrome f and of other component(s) which may include a c-type cytochrome with an α peak at 549 nm. With 664 nm illumination and water as the electron donor, NADP⁺ had a pronounced effect on the redox state of cytochromes, causing a shift toward oxidation of a component with a peak at 549 nm (possibly a c-type cytochrome), cytochrome f, and particularly cytochrome b₅₅₉. Cytochrome b₅₅₉ appeared to be a component of the main noncyclic electron transport chain and was photooxidized at physiological temperatures by Photosystem II. This photooxidation was apparent only in the presence of a terminal acceptor (NADP⁺) for the electron flow from water.     

Simulation of chlorophyll fluorescence rise and decay kinetics,and P<Subscript>700</Subscript>-related absorbance changes by using a rule-based kinetic Monte-Carlo method

A model of primary photosynthetic reactions in the thylakoid membrane was developed and its validity was tested by simulating three types of experimental kinetic curves: (1) the light-induced chlorophyll a fluorescence rise (OJIP transients) reflecting the stepwise transition of the photosynthetic electron transport chain from the oxidized to the fully reduced state; (2) the dark relaxation of the flash-induced fluorescence yield attributed to the Q_A^? oxidation kinetics in PSII; and (3) the light-induced absorbance changes near 820 or 705 nm assigned to the redox transitions of P₇₀₀ in PSI. A model was implemented by using a rule-based kinetic Monte-Carlo method and verified by simulating experimental curves under different treatments including photosynthetic inhibitors, heat stress, anaerobic conditions, and very high light intensity.     

Two electrogenic mechanisms contributing to the 560 nm absorption changes in intact Bryopsis chloroplasts

Light -induced absorbance changes at 560 nm in dark-adapted intact chloroplasts of the green alga, Bryopsis maxima were studied in the time range of 200 ms. The initial rise of the 560 nm signals constists of two major components which are both electrochromic absorbance changes of the carotenoids, sipnonein and/or siphonaxanthin, but different in mechanisms of the field formation.The first component (component S) is related to electron transport since it was sensitive to 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) and 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone (DBMIB) and showed a light-intensity dependence similar to that of electron transport in chloroplasts. In the presence of DCMU, component S could be restored on addition of proton-transporting electron donors such as reduced 2,6-dichlorophenol indophenol and phenazine methosulfate, but not on addition of N,N,N′,N′-tetramethyl-p-phenylenediamine which does not carry protons with electrons (Trebst, A. (1974) Annu. Rev. Plant Physiol. 25, 423–458). We propose that component S is due to the electric field set up by the proton translocation across the thylakoid membrane.The second component (component R) was resistant to DCMU and DBMIB. The light-intensity dependency of component R was similar to that of cytochrome f photooxidation which showed saturation at a relatively low light intensity. The magnitude of component R was markedly reduced by phenylmercuric acetate, suggesting the participation of ferredoxin and ferredoxin-NADP oxidoreductase in the mechanism of the field formation responsible for this component. In the presence of DCMU and phenylmercuric acetate, time courses of the 560 nm changes paralleled those of cytochrome f changes. These results indicate that component R is due to the electric field formed between oxidized cytochrome f and other intersystem electron carriers located in the inner part of the thylakoid membrane and reduced electron acceptors of Photosystem I situated on the membrane surface.The complex natures of the 560 nm changes, as well as the contributions of Photosystems I and II to the absorbance changes, are explained in terms of the two electrogenic mechanisms.     

Spectroscopic identification of the catalytic intermediates of cytochrome c oxidase in respiring heart mitochondria

The catalytic cycle of cytochrome c oxidase (COX) couples the reduction of oxygen to the translocation of protons across the inner mitochondrial membrane and involves several intermediate states of the heme a₃-Cu_B binuclear center with distinct absorbance properties. The absorbance maximum close to 605 nm observed during respiration is commonly assigned to the fully reduced species of hemes a or a₃ (R). However, by analyzing the absorbance of isolated enzyme and mitochondria in the Soret (420–450 nm), alpha (560–630 nm) and red (630–700 nm) spectral regions, we demonstrate that the Peroxy (P) and Ferryl (F) intermediates of the binuclear center are observed during respiration, while the R form is only detectable under nearly anoxic conditions in which electrons also accumulate in the higher extinction coefficient low spin a heme. This implies that a large fraction of COX (>50 %) is active, in contrast with assumptions that assign spectral changes only to R and/or reduced heme a. The concentration dependence of the COX chromophores and reduced c-type cytochromes on the transmembrane potential (ΔΨ_m) was determined in isolated mitochondria during substrate or apyrase titration to hydrolyze ATP. The cytochrome c-type redox levels indicated that soluble cytochrome c is out of equilibrium with respect to both Complex III and COX. Thermodynamic analyses confirmed that reactions involving the chromophores we assign as the P and F species of COX are ΔΨ_m-dependent, out of equilibrium, and therefore much slower than the ΔΨ_m-insensitive oxidation of the R intermediate, which is undetectable due to rapid oxygen binding.     

Studies on electron-transport reactions of photosynthesis in plastome mutants of oenothera

Fluorescence characteristics and light-induced absorbance changes of 5 plastome mutants of Oenothera, all having a defect in photosynthesis, were investigated to localize the site of the block in their photosynthetic mechanism and to relate mutational changes in the plastome to specific biochemical events in photosynthesis. In 4 of the mutants examined photosystem 2 was largely, or completely, nonfunctional. Excitation of system 2 did not cause reduction of oxidized cytochrome f in these mutants. The system-2 dependent absorbance change at 518 mμ seen in normal leaves was absent in the mutants. Moreover, the mutants had a high initial fluorescence in the presence and in the absence of 3- (3,4-dichlorophenyl)-1,1-dimethylurea, which did not change during illumination, indicating that the reaction centers of system 2 were affected by the mutations. Photosystem 1 functioned normally.

A fifth mutant had an impaired photosystem 1. Even high intensity far-red light did not lead to an accumulation of oxidized cytochrome f as was seen in normal plants. Photosystem 2 was functioning, as evidenced by the fast reduction of the primary system-2 oxidant, and by the characteristics of the 518-mμ absorbance change.

Because 1 of the 2 photosystems is functional in all mutants, and because they all have the enzymes of the photosynthetic carbon cycle, it appears that the effect of the mutation is specific. The results suggest that the plastome controls reactions within the electron-transport chain of photosynthesis.

     

Light-inducible Cytochrome Reduction in Membrane Preparations from Corn Coleoptiles: I. STABILIZATION AND SPECTRAL CHARACTERIZATION OF THE REACTION

Conditions for obtaining reproducible light-induced reduction of a b-type cytochrome in membrane fractions from coleoptiles of dark-grown Zea mays L. include a glucose-glucose oxidase system that lowers O₂ tension and generates H₂O₂, substrate amounts of ethylenediaminetetraacetic acid which, in some manner, facilitates photoreduction by both added flavin and the endogenous photoreceptor and a sample temperature below 10 C. Cytochrome reduction could be obtained by photoexcitation of either a tightly bound endogenous receptor, which is probably a flavin, or added riboflavin, flavin mononucleotide, or flavin adenine dinucleotide. The latter flavin was the least effective. The endogenous photoreceptor appears to be rather firmly bound to the membranes, suggesting that this association may also exist in vivo. When any of the above four photoreceptors or methylene blue were used to sensitize the reaction, a cytochrome with a reduced α-band near 560 nanometers and a Soret difference peak near 429 nanometers was the electron acceptor. This cytochrome could be clearly distinguished spectrally from other cytochromes that predominated in the membrane preparations.     

Electron Transport Reactions in Grana Preparations from Spinach Chloroplasts

Fraction 2 (grana-stack) particles prepared with the French press showed absorbance changes, at room temperature and with sodium ascorbate and methyl-viologen, that were produced by the oxidation of cytochrome b-559. This oxidation was inhibited by 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) and sensitized by system II of photosynthesis. The oxidation is too slow to account for the rates of the Hill reaction that have been observed with nicotinamide-adenine dinucleotide phosphate (NADP⁺). It appears that this cytochrome is not functioning in the main pathway of electron transport. In the presence of 2,3,5,6-tetramethyl-p-phenylene-diamine (DAD) and ascorbate, light-induced oxidation of cytochrome f took place within 3 msec (or faster) in the grana-stack particles. Treatment with the detergent Triton X-100 disrupted this rapid cytochrome f oxidation as well as the oxidation of cytochrome b-559. Subsequent plastocyanin addition did not restore the rapid oxidation of cytochrome f (nor of cytochrome b-559) but only slow changes of cytochrome f. In view of the fact that these particles contain almost no plastocyanin, it is unlikely that plastocyanin functions in electron transport between cytochrome f and P-700 in the particles derived from the grana-stack regions of the chloroplast.     

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

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

Dichroism of transient absorbance changes in the red spectral region using oriented chloroplasts. I. Field indicating absorbance changes

The light-induced transient absorbance changes which are affected by valinomycin have been studied using magnetically oriented spinach chloroplasts and a polarized measuring beam. The ΔA spectra for the two polarizations parallel and perpendicular to the plane of the photosynthetic membranes have been recorded in the spectral range 630–750 nm. Large polarization effects are found in all the bands of the ΔA spectrum, shifts in the position of the extrema are observed and the two spectra cross each other at various wavelengths. A comparison of these spectral features with available data on the dichroism of the Stark effect on monomolecular films of chlorophyll a and b indicates similarities favoring the already well documented hypothesis of the electrochromic nature of these absorbance changes in vivo.The data on this electrochromic effect can be correlated with the linear dichroism of oriented chloroplasts and the ΔA_∥?ΔA_⊥ spectrum in the 645–655 nm region gives further evidence of the orientation out of the membrane plane of the red transition moment of chlorophyll b.