Cytochrome function in the cyclic electron transport pathway of chloroplasts.

Flash excitation of isolated intact chloroplasts promoted absorbance transients corresponding to the electrochromic effect (P-518) and the alpha-bands of cytochrome b6 and cytochrome f. Under conditions supporting coupled cyclic electron flow, the oxidation of cytochrome b6 and the reduction of cytochrome f had relaxation half-times of 15 and 17 ms, respectively. Optimal poising of cyclic electron flow, achieved by addition of 0.1 microM 3-(3,4-dichlorophenyl)-1,1-dimethylurea, increased phosphorylation of endogenous ADP and prolonged these relaxation times. The presence of NH4Cl, or monensin plus NaCl, decreased the half-times for cytochrome relaxation to approximately 2 ms. Uncouplers also revealed the presence of a slow rise component in the electrochromic absorption shift with formation half-time of about 2 ms. Ths inhibitors of cyclic phosphorylation antimycin and 2,5-dibromo-3-methyl-6-isoprophy-p-benzoquinone abolished the slow rise in the electrochromic shift and prolonged the uncoupled relaxation times of cytochromes b6 and f by factors of ten or more. These observations indicate that cytochrome b6, plastoquinone and cytochrome f participated in a coupled electron transport process responsible for cyclic phosphorylation in intact chloroplasts. Estimations of cyclic phosphorylation rates from 40 to 120 mumol ATP/mg chlorophyll per h suggest that this process can provide a substantial fraction of the ATP needed for CO2 fixation.     

Cytochrome function in the cyclic electron transport pathway of chloroplasts

Flash excitation of isolated intact chloroplasts promoted absorbance transients corresponding to the electrochromic effect (P-518) and the α-bands of cytochrome b₆ and cytochrome f. Under conditions supporting coupled cyclic electron flow, the oxidation of cytochrome b₆ and the reduction of cytochrome f had relaxation half-times of 15 and 17 ms, respectively. Optimal poising of cyclic electron flow, achieved by addition of 0.1 μM 3-(3,4-dichlorophenyl)-1,1-dimethylurea, increased phosphorylation of endogenous ADP and prolonged these relaxation times. The presence of NH₄Cl, or monensin plus NaCl, decreased the half-times for cytochrome relaxation to approximately 2 ms. Uncouplers also revealed the presence of a slow rise component in the electrochromic absorption shift, with formation half-time of about 2 ms. The inhibitors of cyclic phosphorylation antimycin and 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone abolished the slow rise in the electrochromic shift and prolonged the uncoupled relaxation times of cytochromes b₆ and f by factors of ten or more.These observations indicate that cytochrome b₆, plastoquinone and cytochrome f participate in a coupled electron transport process responsible for cyclic phosphorylation in intact chloroplasts. Estimations of cyclic phosphorylation rates from 40 to 120 μmol ATP/mg chlorophyll per h suggest that this process can provide a substantial fraction of the ATP needed for CO₂ fixation.     

The site of manganese function in photosynthetic electron transport system

The effects of Mn²⁺ on aerobic photobleaching of carotenoids, on photoreduction of 2,6-dichlorophenolindophenol (DCIP) and on fluorescence above 600 mμ of spinach chloroplasts washed with 0.8 M Tris-HC1 buffer were investigated. Carotenoids (mostly carotenes, lutein and violaxanthin) in the Tris-washed chloroplasts were irreversibly bleached by illumination with red light, while carotenoids in normal chloroplasts prepared with a low concentration of Tris-HC1 underwent no bleaching upon illumination. The photobleaching of carotenoids observed with Tris-washed chloroplasts was inhibited by Mn²⁺ (MnCl₂ or MnSO₄) as well as by some inhibitors of the Hill reaction such as dichlorophenyl-1,1-dimethylurea (DCMU), methylthio-4,6-bis-isopropylamino-s-triazine and o-phenanthroline or by reducing agents such as ascorbate plus tetramethyl-p-phenylene diamine (TMPD). DCIP photoreduction, which was deactivated by Tris, was reactivated to 50–80% of the rate for normal chloroplasts upon addition of Mn²⁺. The restored photoreduction of DCIP was inhibited by DCMU and carbonylcyanide m-chlorophenylhydrazone (CCCP). The steady-state fluorescence yield of normal chloroplasts measured at room temperature was lowered by Tris treatment, and the decreased yield was restored by adding Mn²⁺ as well as ascorbate plus TMPD. CCCP also lowered the yield; the yield was recovered by adding ascorbate plus TMPD. Determination of manganese in normal and Tris-washed chloroplasts showed that 30% of the manganese in chloroplast was removed with Tris. It was postulated that Mn²⁺ functions in the electron transport on the oxidizing side of Photosystem II at a site between water and an electron carrier (Y). CCCP as well as Tris inhibits the reduction of Y⁺ by Mn²⁺, and carotenoids are oxidized by Y⁺ which is reduced by ascorbate plus TMPD.     

Regulation of photosynthetic electron transport

The photosynthetic electron transport chain consists of photosystem II, the cytochrome b(6)f complex, photosystem I, and the free electron carriers plastoquinone and plastocyanin. Light-driven charge separation events occur at the level of photosystem II and photosystem I, which are associated at one end of the chain with the oxidation of water followed by electron flow along the electron transport chain and concomitant pumping of protons into the thylakoid lumen, which is used by the ATP synthase to generate ATP. At the other end of the chain reducing power is generated, which together with ATP is used for CO(2) assimilation. A remarkable feature of the photosynthetic apparatus is its ability to adapt to changes in environmental conditions by sensing light quality and quantity, CO(2) levels, temperature, and nutrient availability. These acclimation responses involve a complex signaling network in the chloroplasts comprising the thylakoid protein kinases Stt7/STN7 and Stl1/STN7 and the phosphatase PPH1/TAP38, which play important roles in state transitions and in the regulation of electron flow as well as in thylakoid membrane folding. The activity of some of these enzymes is closely connected to the redox state of the plastoquinone pool, and they appear to be involved both in short-term and long-term acclimation. This article is part of a Special Issue entitled "Regulation of Electron Transport in Chloroplasts".     

Regulation of proton-to-electron stoichiometry in photosynthetic electron transport: physiological function in photoprotection

The primary stable products of photosynthetic electron flow are NADPH and ATP. Stoichiometry of their production depends on the ratio of protons pumped across the thylakoid membrane to electrons passed through the electron transport pathway (H(+)/e(-) ratio). Flexible requirements of the ATP/NADPH ratio by various assimilatory reactions in chloroplasts must be fulfilled by the H(+)/e(-) ratio during the electron flow. In addition to the well-known role of Delta pH during ATP synthesis, Delta pH also functions as a trigger of the down-regulation of photosystem II (PSII) photochemistry. Excessive light energy is safely dissipated as heat by this regulatory process to suppress the generation of toxic reactive oxygen species. Thus, regulation of the H(+)/e(-) ratio may function in the photoprotection, as well as in the regulation of the ATP/NADPH production ratio. It has long been the consensus that the H(+)/e(-) ratio can be controlled by regulating the proton-transporting Q-cycle in the cytochrome b(6)f complex and by the cyclic electron flow around photosystem I (PSI). Despite the possible physiological importance and the long history of interest, the molecular identity of Q-cycle regulation and the cyclic electron flow around PSI have been remained unclear. The recent improvements in research tools, including the genetic approach using chlorophyll fluorescence imaging and establishment of the chloroplast transformation technique, are providing new insights into classical topics. In this review, we focus on regulation of the H(+)/e(-) ratio especially from the view of photosynthetic regulation.     

Regulation of proton-to-electron stoichiometry in photosynthetic electron transport: physiological function in photoprotection

The primary stable products of photosynthetic electron flow are NADPH and ATP. Stoichiometry of their production depends on the ratio of protons pumped across the thylakoid membrane to electrons passed through the electron transport pathway (H⁺/e⁻ ratio). Flexible requirements of the ATP/NADPH ratio by various assimilatory reactions in chloroplasts must be fulfilled by the H⁺/e⁻ ratio during the electron flow. In addition to the well-known role of ΔpH during ATP synthesis, ΔpH also functions as a trigger of the down-regulation of photosystem II (PSII) photochemistry. Excessive light energy is safely dissipated as heat by this regulatory process to suppress the generation of toxic reactive oxygen species. Thus, regulation of the H⁺/e⁻ ratio may function in the photoprotection, as well as in the regulation of the ATP/NADPH production ratio. It has long been the consensus that the H⁺/e⁻ ratio can be controlled by regulating the proton-transporting Q-cycle in the cytochrome b ₆ f complex and by the cyclic electron flow around photosystem I (PSI). Despite the possible physiological importance and the long history of interest, the molecular identity of Q-cycle regulation and the cyclic electron flow around PSI have been remained unclear. The recent improvements in research tools, including the genetic approach using chlorophyll fluorescence imaging and establishment of the chloroplast transformation technique, are providing new insights into classical topics. In this review, we focus on regulation of the H⁺/e⁻ ratio especially from the view of photosynthetic regulation. Received: August 2, 2001 / Accepted: October 1, 2001     

Plastoquinol diffusion in linear photosynthetic electron transport

The diffusion of plastoquinol and its binding to the cytochrome bf complex, which occurs during linear photosynthetic electron transport and is analogous to reaction sequences found in most energy-converting membranes, has been studied in intact thylakoid membranes. The flash-induced electron transfer between the laterally separated photosystems II and photosystems I was measured by following the sigmoidal reduction kinetics of P-700⁺ after previous oxidation of the intersystem electron carriers. The amount of flash-induced plastoquinol produced at photosystem II was (a) reduced by inhibition with dichlorophenyl-dimethylurea and (b) increased by giving a second saturating flash. These signals were simulated by a new model which combines a deterministic simulation of reaction kinetics with a Monte Carlo approach to the diffusion of plastoquinol, taking into account the known structural features of the thylakoid membrane. The plastoquinol molecules were assumed to be oxidized by either a diffusion-limited or a nondiffusion-limited step in a collisional mechanism or after binding to the cytochrome bf complex. The model was able to account for the experimental observations with a nondiffusion-limited collisional mechanism or with a binding mechanism, giving minimum values for the diffusion coefficient of plastoquinol of 2 × 10^-8 cm²s^-1 and 3 × 10^-7 cm²s^-1, respectively.     

The mechanism of quinonediimine acceptor activity in photosynthetic electron transport.

The rates of electron flow catalyzed by a variety of unsubstituted and C- or N-methylated quinonediimine electron acceptors in a reaction requiring photosystem II in KCN-inhibited chloroplasts vary according to the structure of acceptor used. Quinonediimine, but not quinone, electron acceptor activities are inhibited by a variety of uncouplers. Kinetic analysis of this inhibition shows that it is competitive. Low concentrations of aniline also inhibit the activity of C-methylated quinonediimines, but this appears to be due to a chemical reaction between the acceptor and aniline at low pH inside the chloroplast. Light-induced uptake of a quinonediimine, p-phenylenediimine, was shown to occur in a DCMU-sensitive reaction. Methylamine uncoupling inhibits this uptake to the same extent as it inhibits electron flow. Experiments with a lipophobic acceptor, N,N,N',N'-tetramethyl-p-phenylenediimine, indicate that it catalyzes electron flow by the same mechanism as other quinonediimines. A model is proposed to account for quinonediimine-catalyzed electron flow.     

Photoresponses in Rhodobacter sphaeroides: role of photosynthetic electron transport.

Rhodobacter sphaeroides responds to a decrease in light intensity by a transient stop followed by adaptation. There is no measurable response to increases in light intensity. We confirmed that photosynthetic electron transport is essential for a photoresponse, as (i) inhibitors of photosynthetic electron transport inhibit photoresponses, (ii) electron transport to oxidases in the presence of oxygen reduces the photoresponse, and (iii) the magnitude of the response is dependent on the photopigment content of the cells. The photoresponses of cells grown in high light, which have lower concentrations of light-harvesting photopigment and reaction centers, saturated at much higher light intensities than the photoresponses of cells grown in low light, which have high concentrations of light-harvesting pigments and reaction centers. We examined whether the primary sensory signal from the photosynthetic electron transport chain was a change in the electrochemical proton gradient or a change in the rate of electron transport itself (probably reflecting redox sensing). R. sphaeroides showed no response to the addition of the proton ionophore carbonyl cyanide 4-trifluoromethoxyphenylhydrazone, which decreased the electrochemical proton gradient, although a behavioral response was seen to a reduction in light intensity that caused an equivalent reduction in proton gradient. These results strongly suggest that (i) the photosynthetic apparatus is the primary photoreceptor, (ii) the primary signal is generated by a change in the rate of electron transport, (iii) the change in the electrochemical proton gradient is not the primary photosensory signal, and (iv) stimuli affecting electron transport rates integrate via the electron transport chain.     

Development of photosynthetic electron transport in Pinus silvestris

Photosynthetic electron transport activity has been measured in chloroplasts isolated from dark-grown seedlings of Pinus silvestris L. and in chloroplasts isolated from seedlings subjected to illumination for periods of up to 48 h. Activities of photosystem 2, photosystem 1 and photosystem 2 plus 1 have been measured. Chloroplasts isolated from dark-grown seedlings showed significant electron transport activity through both photosystems and through the entire electron transport chain from water to NADP. Illumination of the seedlings for only 5 min markedly promoted photosystem 2 activity. The artificial electron donor, diphenylcarbazide. promoted activity in chloroplasts from dark-grown seedlings and in chloroplasts from seedlings illuminated for up to 30 min. In comparison to photosystem 2 and overall electron transport from water to NADP, photosystem 1 activity increased only slightly during illumination. Measurements of electron transport and fluorescence kinetics have confirmed that photosynthetic electron transport capacity is limited on the water splitting side of photosystem 2 in dark-grown seedlings, whereas the primary and secondary electron acceptors of photosystem 2 are fully synthesized and functioning in darkness. Polyethylene glycol must be used as a protective agent when isolating photoactive chloroplasts from secondary needles of conifers. However, the presence of polyethylene glycol, when isolating chloroplasts from dark-grown pine cotyledons, caused a total inhibition of the activity of photosystem 2. The failure of others to show a substantial electron transport activity in chloroplasts from dark-grown Pinus silvestris might depend on their use of polyethylene glycol in the preparation medium and/or on their use of suboptimal reaction conditions for the electron transport measurements.     

Effect of phloridzin on photosynthetic electron transport

Phloridzin (2',4',6',4-tetraoxyhydrochalcon-2'-glucoside) was used to study the localization of synthesis of ATP in the electrontransporting chain of photosynthesis. It was shown that phloridzin inhibits the rate of photoreduction of NADP+ by isolated pea chloroplasts by 40%, electron transport via cytochrome f by 100% and via plastocyanin--by 50%. The "crossover" experiments demonstrated that phloridzin inhibits ADP-induced photoreduction of cytochrome f, having no effect on plastocyanin under identical conditions. It is assumed that the site of ATP synthesis is localized on the reduced site of cytochrome f, while the carrier itself is located in the electron transporting chain coupled to phosphorylation. It is possible that only part of the plastocyanin molecules are located in the phosphorylating pathway of electron transport.     

Regulation of the photosynthetic electron transport chain

The regulation of electron transport between photosystems II and I was investigated in the plant Silene dioica L. by means of measurement of the kinetics of reduction of P₇₀₀ following a light-to-dark transition. It was found that, in this species, the rate constant for P₇₀₀ reduction is sensitive to light intensity and to the availability of CO₂. The results indicated that at 25 °C the rate of electron transport is down-regulated by approximately 40–50% relative to the maximum rate achievable in saturating CO₂ and that this down-regulation can be explained by regulation of the electron transport chain itself. Measurements of the temperature sensitivity of this rate constant indicated that there is a switch in the rate-limiting step that controls electron transport at around 20 °C: at higher temperatures, CO₂ availability is limiting; at lower temperatures some other process regulates electron transport, possibly a diffusion step within the electron transport chain itself. Regulation of electron transport also occurred in response to drought stress and sucrose feeding. Measurements of non-photochemical quenching of chlorophyll fluorescence did not support the idea that electron transport is regulated by the pH gradient across the thylakoid membrane, and the possibility is discussed that the redox potential of a stromal component may regulate electron transport. Received: 4 March 1999 / Accepted: 25 May 1999     

Cytochrome bc 1 and b 6 f complexes of photosynthetic membranes

All photosynthetic membranes contain a cytochrome bc ₁ or b ₆ f complex that catalyzes the oxidation of quinols and the reduction of a high-potential electron carrier, such as cytochrome c ₂ or plastocyanin. The cytochrome complex also functions in the translocation of protons across the membrane and as a consequence, establishes the proton motive force that is used for the synthesis of ATP. The structure and function of the cytochrome complexes are first reviewed in this chapter. Amino acid sequence information for almost all of the protein subunits of these complexes is now available, and these allow for a detailed consideration of functional domains in the protein subunits and for a further discussion of the evolution of the cytochrome complex in photosynthetic organisms.     

Modeling of the photosynthetic electron transport regulation in cyanobacteria

In this work we have performed a computer analysis of electron and proton transport in cyanobacterial cells using a mathematical model of light-dependent stages of photosynthesis taking into account the key stages of pH-dependent regulation of electron transport on both acceptor and donor sides of photosystem 1 (PS1). Comparison of theoretical and experimental data shows that the model adequately describes the multiphase kinetics of photoinduced redox transformations of P₇₀₀ (the primary electron donor in PS1). Our computer simulation describes the effect of variations of atmospheric gases (CO₂ and O₂) on the induction events in cyanobacteria (P₇₀₀ photooxidation, generation of transmembrane ΔpH), which strongly depends on the preillumination conditions (aerobic or anaerobic atmosphere). It has been shown that the variations of CO₂ concentration in the cell interior may noticeably affect the kinetics of electron transport, acidification of lumen, and ATP synthesis. The contributions of alternative pathways of electron transport (cyclic electron transport around PS1 and electron outflow to O₂) to the function of cyanobacterial photosynthetic apparatus have been analyzed. At the initial stage of induction period, cyclic electron flows around PS1 (“short” and “long” pathways) substantially contribute to photosynthetic electron transport. These flows, however, attenuate with the light-induced activation of the Calvin-Benson cycle reactions. In the meantime, the outflow of electrons from PS1 to O₂ (or to other metabolic chains) increases with oxygen accumulation in the medium. The effects of ferredoxin oxidation by hydrogenase catalyzing the H₂ formation on the kinetics of P700 photooxidation and distribution of electron flows on the acceptor side of PS1 have been modeled.     

Functional sits of plastoquinone in photosynthetic electron transport system

Mild extraction of lyophilized chloroplasts with hexane eliminatedHill activity with 2,6-dichlorophenolindophenol (DCIP) as anelectron acceptor, and most of the activity was restored byreconstitution with plastoquinone A. The same extraction didnot affect the activity of Photosystem II, determined by thephotoreduction of DCIP supported with an artificial electrondoneor, 1,5-diphenylcarbazied. The fluorescence yield changesof extracted chloroplasts indicated that the electron transportchain between Photosystems I and II was also blocked. The resultssuggest that plastoquinone functions at both sides of PhotosystemII; at the reductive side it acts as an electron carrier, andat the oxidative side as a structural element of the thylakoidmembrance necessary for a component to be active in the oxygen-evolutionsystem. (Received August 22, 1973; )