Showing papers on "Photosynthetic reaction centre published in 1991"

Structure of the membrane-bound protein photosynthetic reaction center from Rhodobacter sphaeroides

Abstract: The structure of the photosynthetic reaction center (RC) from Rhodobacter sphaeroides was determined at 3.1-A resolution by the molecular replacement method, using the Rhodopseudomonas viridis RC as the search structure. Atomic coordinates were refined with the difference Fourier method and restrained least-squares refinement techniques to a current R factor of 22%. The tertiary structure of the RC complex is stabilized by hydrophobic interactions between the L and M chains, by interactions of the pigments with each other and with the L and M chains, by residues from the L and M chains that coordinate to the Fe2+, by salt bridges that are formed between the L and M chains and the H chain, and possibly by electrostatic forces between the ends of helices. The conserved residues at the N-termini of the L and M chains were identified as recognition sites for the H chain.

Charge separation in a reaction center incorporating bacteriochlorophyll for photoactive bacteriopheophytin.

Abstract: Site-directed mutagenic replacement of M subunit Leu214 by His in the photosynthetic reaction center (RC) from Rhodobacter sphaeroides results in incorporation of a bacteriochlorophyll molecule (BChl) in place of the native bacteriopheophytin (BPh) electron acceptor. Evidence supporting this conclusion includes the ground-state absorption spectrum of the (M)L214H mutant, pigment and metal analyses, and time-resolved optical experiments. The genetically modified RC supports transmembrane charge separation from the photoexcited BChl dimer to the primary quinone through the new BChl molecule, but with a reduced quantum yield of 60 percent (compared to 100 percent in wild-type RCs). These results have important implications for the mechanism of charge separation in the RC, and rationalize the choice of (bacterio)pheophytins as electron acceptors in a variety of photosynthetic systems.

Electron transfer in inorganic, organic, and biological systems.

Abstract: Introduction Basic Electron-Transfer Theory Nuclear and Electronic Factors in Electron Transfer Theoretical Analysis of Energy-Gap Laws of Electron-Transfer Reactions Electron Transfer From Model Compounds to Proteins Ultrafast Laser Photolysis Studies on Photoinduced Charge Separation and Charge Recombination of Transient Ion Pair States Solvent, Temperature, and Bridge Dependence of Photoinduced Intramolecular Electron Transfer Solvent-Dependent Photophysics of Fixed-Distance Chlorophyll-Porphyrin Molecules Manipulation of Electron-Transfer Reaction Rates with Applied Electric Fields Function of Quinones and Quinoids in Green-Plant Photosystem I Reaction Centers Effects of Reaction Free Energy in Biological Electron Transfer in vitro and in vivo Long-Range Electron Transfer in Heme Proteins: Porphyrin-Ruthenium Electronic Couplings in Three Ru(His)Cytochromes Long-Range Electron Transfer in Mixed-Metal Hemoglobin Hybrids: A Status Report Electron Transfer, Energy Transfer, and Excited State Annihilation in Binuclear Compounds of Ruthenium(II) Electron Transfer Across Model Polypeptide and Protein Bridging Ligands: Distance Dependence, Pathways, and Protein Conformational States Solvent Reorganization Energetics and Dynamics in Charge-Transfer Processes of Transition-Metal Complexes Puzzles of Electron Transfer Interaction of Theory and Experiment in Electron Transfer

Functioning of photosystems I and II in pea leaves exposed to heat stress in the presence or absence of light Analysis using in-vivo fluorescence, absorbance, oxygen and photoacoustic measurements

Abstract: Fluorimetric, photoacoustic, polarographic and absorbance techniques were used to measure in situ various functional aspects of the photochemical apparatus of photosynthesis in intact pea leaves (Pisum sativum L.) after short exposures to a high temperature of 40 ° C. The results indicated (i) that the in-vivo responses of the two photosystems to high-temperature pretreatments were markedly different and in some respects opposite, with photosystem (PS) II activity being inhibited (or down-regulated) and PSI function being stimulated; and (ii) that light strongly interacts with the response of the photosystems, acting as an efficient protector of the photochemical activity against its inactivation by heat. When imposed in the dark, heat provoked a drastic inhibition of photosynthetic oxygen evolution and photochemical energy storage, correlated with a marked loss of variable PSII-chlorophyll fluorescence emission. None of the above changes were observed in leaves which were illuminated during heating. This photoprotection was saturated at rather low light fluence rates (around 10 W · m−2). Heat stress in darkness appeared to increase the capacity for cyclic electron flow around PSI, as indicated by the enhanced photochemical energy storage in far-red light and the faster decay of P 700 + (oxidized reaction center of PSI) monitored upon sudded interruption of the far-red light. The presence of light during heat stress reduced somewhat this PSI-driven cyclic electron transport. It was also observed that heat stress in darkness resulted in the progressive closure of the PSI reaction centers in leaves under steady illumination whereas PSII traps remained largely open, possibly reflecting the adjustment of the photochemical efficiency of undamaged PSI to the reduced rate of photochemistry in PSII.

Deletion mutagenesis in Synechocystis sp. PCC6803 indicates that the Mn-stabilizing protein of photosystem II is not essential for O2 evolution.

Abstract: The photosystem II (PSII) reaction center complex coordinates a cluster of Mn atoms that are involved in the accumulation of oxidizing equivalents generated by light-induced charge separations within the intrinsic portion of the PSII complex. A 33-kDa extrinsic protein, termed the Mn-stabilizing protein (MSP), has been implicated in the stabilization of two of the four Mn atoms of the cluster, yet the precise role of this protein in O2 evolution remains to be elucidated. Here we describe the construction of a mutant of the cyanobacterium Synechocystis sp. PCC6803 in which the entire gene encoding MSP has been deleted. Northern and immunoblot analyses indicate that other PSII proteins are expressed and accumulated, despite the absence of MSP. Fluorescence emission spectra at 77 K indicate PSII assembles in the mutant, but that the binding of MSP is required for the normal fluorescence characteristics of the PSII complex, and suggest a specific interaction between MSP and CP47. Fluorescence induction measurements indicate a reduced rate of forward electron transport to the primary electron donor, P680, in the mutant. It is concluded that in contrast to previous reports, MSP is not required for the assembly of active PSII complexes nor is it essential for H2O-splitting activity in vivo.

Lateral redistribution of cytochrome b6/f complexes along thylakoid membranes upon state transitions.

Abstract: The cytochrome b6/f complex operates in photosynthetic electron transfer either in linear electron flow from photosystem II to photosystem I or in cyclic flow around photosystem I. Using membrane fractionation and immunocytochemistry, we show a change in lateral distribution of cytochrome b6/f complexes along the thylakoid membranes during state transitions. This change is seen in maize as well as in the green algae Chlamydomonas reinhardtii. When either of the two organisms were adapted to state II in vivo, the proportion of cytochrome b6/f complexes found in the photosystem I-enriched stroma lamellae regions was significantly larger than after adaptation to state I. A similar observation was made upon state I to state II transitions done in vitro by illuminating, in the presence of ATP, broken maize chloroplasts prepared from dark-adapted leaves. This reorganization of the electron-transfer chain is concurrent with the change in light-energy distribution between the two photosystems, which requires lateral displacement of light-harvesting complex II. That the changes in lateral distribution of both cytochrome b6/f and light-harvesting II complexes seen upon state transition in vitro similarly required addition of exogenous ATP, suggests that the change in cytochrome b6/f organization also depends on kinase activity. The increased concentration of cytochrome b6/f complexes in the vicinity of photosystem I in state II is discussed in terms of an increase in cyclic electron flow, thus favoring ATP production. Because transition to state II can be triggered in vivo by ATP depletion, we conclude that state transitions should be regarded not only as a light-adaptation mechanism but also as a rerouting of photosynthetic electron flow, enabling photosynthetic organisms to adapt to changes in the cell demand for ATP.

Interactions of Herbicides with Photosynthetic Electron Transport

Abstract: The two primary sites of herbicide action in photosynthetic electron transport are the inhibition of photosystem II (PS II) electron transport and diversion of electron flow through photosystem I (PS I). PS II electron transport inhibitors bind to the D1 protein of the PS II reaction center, thus blocking electron transfer to plastoquinone. Inhibition of PS II electron transport prevents the conversion of absorbed light energy into electrochemical energy and results in the production of triplet chlorophyll and singlet oxygen which induce the peroxidation of membrane lipids. PS I electron acceptors probably accept electrons from the iron-sulfur protein, Fa/Fb. The free radical form of the herbicide leads to the production of hydroxyl radicals which cause the peroxidation of lipids. Herbicide-induced lipid peroxidation destroys membrane integrity, leading to cellular disorganization and phototoxicity.

Structures and functions of carotenoid in photosynthetic systems

Abstract: Recent achievements in the investigation of the structures and excited-state properties of carotenoids, in relation to their photoprotective and light-harvesting functions in bacterial photosynthesis, are reviewed. In purple bacteria, natural selection of the carotenoid configurations has been observed. The 15-cis configuration is selected by the reaction centers (RCs), whereas the all-trans configuration is selected by the light-harvesting complexes (LHCs). In the photoprotective function in the RCs, involvement of one of the accessory bacteriochlorophylls in the triplet energy transfer has been demonstrated. The extremely efficient isomerization of the 15-cis T1 carotenoid in vitro, together with indications of isomerization and two forms of carotenoids in vivo, have led to the proposal of a mechanism of energy dissipation in which isomerization of the carotenoid is involved. In the energy transfer function in the LHCS, evidence for the 2Ag (S1) state for carotenoids in vitro and in vivo has been obtained. Its lifetime of approximately 10 ps in vitro and an energy transfer time of 1–10 ps in vivo, determined by picosecond absorption spectroscopy, make the electron-exchange mechanism via the 2Ag state likely. However, the Bu (S2) lifetime of approximately 200 fs in vitro and an energy transfer time of the same order of magnitude in vivo, determined by femtosecond absorption spectroscopy, suggest that the dipole mechanism via the Bu state is also possible.

The iron-quinone electron-acceptor complex of photosystem II

Abstract: The iron quinone-complex of the reaction centers of photosystem II and the purple non-sulphur photosynthetic bacteria contains two quinones, QA and QB connected in series with respect to electron transfer, and separated by a non-heme iron coordinated by amino acid residues. It is the site of inhibition of many of the common photosynthetic herbicides, which act by displacing QB from the center. The complex is responsible for reducing QB to QBH2 in two successive one-electron photo acts. OBH2 dissociates from the center, to be replaced by a new QB molecule and reduces the following membrane-bound electron-transfer complex (cytochrome b6/for b/c1). The energetic, kinetics and mechanism of complex function are reviewed here. Recent crystallographic, spectroscopic and molecular biological evidence has produced a considerable quantity of structural information on this complex. These data have given a less formal and more molecular view of how the complex functions. They have also revealed fundamental differences between the photo system II and bacterial complexes, particularly with respect to the coordination of the iron and its chemistry. The comparative anatomy of the complexes is reviewed and its implications for function discussed.

Two sites of photoinhibition of the electron transfer in oxygen evolving and Tris-treated PS II membrane fragments from spinach.

Abstract: Photoinhibition was analyzed in O2-evolving and in Tris-treated PS II membrane fragments by measuring flash-induced absorption changes at 830 nm reflecting the transient P680+ formation and oxygen evolution. Irradiation by visible light affects the PS II electron transfer at two different sites: a) photoinhibition of site I eliminates the capability to perform a ‘stable’ charge separation between P680+ and QA - within the reaction center (RC) and b) photoinhibition of site II blocks the electron transfer from YZ to P680+. The quantum yield of site I photoinhibition (2–3×10-7 inhibited RC/quantum) is independent of the functional integrity of the water oxidizing system. In contrast, the quantum yield of photoinhibition at site II depends strongly on the oxygen evolution capacity. In O2-evolving samples, the quantum yield of site II photoinhibition is about 10-7 inhibited RC/quantum. After selective elimination of the O2-evolving capacity by Tris-treatment, the quantum yield of photoinhibition at site II depends on the light intensity. At low intensity (<3 W/m2), the quantum yield is 10-4 inhibited RC/quantum (about 1000 times higher than in oxygen evolving samples). Based on these results it is inferred that the dominating deleterious effect of photoinhibition cannot be ascribed to an unique target site or a single mechanism because it depends on different experimental conditions (e.g., light intensity) and the functional status of the PS II complex.

Photoinduced degradation of the D1 polypeptide in isolated reaction centers of photosystem II: evidence for an autoproteolytic process triggered by the oxidizing side of the photosystem.

Abstract: When the isolated D1/D2/cytochrome b559 complex was exposed to bright light, a distinctive pattern of D1 polypeptide fragments was observed under both aerobic and anaerobic conditions. The major degradation product had an apparent molecular mass of 24 kDa, while other fragments were detected at 17, 14, and 10 kDa by immunoblotting. This pattern was observed when the electron acceptors 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone or silicomolybdate were present during illumination. It is known that these conditions stabilize P680+ chlorophyll and bring about the photooxidation and destruction of pigments in the reaction center, particularly chlorophyll absorbing at 670 nm and beta-carotene. When P680+ was not allowed to accumulate, either by omission of an electron acceptor or by addition of both an electron donor (Mn2+) and an acceptor, no breakdown fragments were observed. In the former case, however, some degradation of the D1 and D2 polypeptides did occur. Under conditions that gave rise to the characteristic D1 breakdown pattern, the D2 polypeptide was also degraded to specific fragments detected at about 29 and 21 kDa by immunoblotting. The results indicate that the photoinduced degradation of D1 (and D2) does not involve exogenous proteases but is most likely an autoproteolytic process. Moreover, our data indicate that the photochemical damage giving rise to D1 and D2 degradation occurs on the oxidizing rather than the reducing side of photosystem II and involves photooxidation of the accessory pigments. The results are discussed in terms of D1 and D2 turnover and photoinhibition.

Mechanism of the initial charge separation in bacterial photosynthetic reaction centers.

Abstract: The initial electron transfer in reaction centers from Rhodobacter sphaeroides R26 was studied by a subpicosecond transient pump-probe technique. The measured kinetics at various wavelengths were analyzed and compared with several mechanisms for electron transfer. An unambiguous determination of the initial electron transfer mechanism in reaction centers cannot be made by studying the anion absorption region (640-690 nm), due to the spectral congestion in this region. However, correlations between the stimulated emission decay of the excited state of the special pair, P*, at 926 nm and bleaching of the bacteriopheophytin Qx absorption at 545 nm suggest that the electron transfer at 283 K is dominated by a two-step sequential mechanism, whereas one-step superexchange and the two-step sequential mechanism have about equal contributions at 22 K.

Site directed mutagenesis of the heme axial ligands of cytochrome b559 affects the stability of the photosystem ii complex

Abstract: Cytochrome (cyt) b559, an integral membrane protein, is an essential component of the photosystem II (PSII) complex in the thylakoid membranes of oxygenic photosynthetic organisms. Cyt b559 has two subunits, alpha and beta, each with one predicted membrane spanning alpha-helical domain. The heme cofactor of this cytochrome is coordinated between two histidine residues. Each of the two subunit polypeptides of cyt b559 has one His residue. To investigate the influence of these His residues on the structure of cyt b559 and the PSII complex, we used a site directed mutagenesis approach to replace each His residue with a Leu residue. Introduction of these missense mutations in the transformable unicellular cyanobacterium, Synechocystis 6803, resulted in complete loss of PSII activity. Northern blot analysis showed that these mutations did not affect the stability of the polycistronic mRNA that encompasses both the psbE and the psbF genes, encoding the alpha and the beta subunits, respectively. Moreover, both of the single His mutants showed the presence of the alpha subunit which was 1.5 kd smaller than the same polypeptide in wild type cells. A secondary effect of such a structural change was that D1 and D2, two proteins that form the catalytic core (reaction center) of PSII, were also destabilized. Our results demonstrate that proper axial coordination of the heme cofactor in cyt b559 is important for the structural integrity of the reaction center of PSII.

Modifications to Thylakoid Composition during Development of Maize Leaves at Low Growth Temperatures.

Abstract: The effects of reductions in growth temperature on the development of thylakoids of maize (Zea mays var LG11) leaves are examined. Thylakoids isolated from mesophyll cells of leaves grown at 17 degrees and 14 degrees C, compared with 25 degrees C, exhibited a decreased accumulation of many polypeptides, which was accompanied by a loss of activity of photosystems (PS) I and II. Probing the polypeptide profiles with a range of antibodies specific for thylakoid proteins demonstrated that a number of polypeptides encoded by the chloroplast genome failed to accumulate at low temperatures. Although thylakoid protein synthesis was reduced severely at 14 degrees C compared with 25 degrees C, major synthesis of both chloroplast and nuclear encoded polypeptides was detected. It is suggested that the lack of accumulation of some thylakoid proteins at low temperatures may be due to an inability to stabilize the proteins in the membranes. A number of thylakoid polypeptides were found to appear as the growth temperature was decreased. Analyses of pigments and polypeptides demonstrated that decreases in the photosystem reaction center core complexes occur relative to the light harvesting complex associated with PS II at reduced growth temperatures. Differential effects on the development of PSI and PSII were also observed, with PSII activity being preferentially reduced. Reductions in PSII content and activity occurred in parallel with decreases in the quantum yield and light-saturated rate of CO(2) assimilation. Fractionation of thylakoid pigment-protein complexes showed that the ratio of monomeric:oligomeric form of the light harvesting complex associated with PSII increased at low growth temperature, which is consistent with a chill-induced modification of thylakoid organization. Many, but not all, of the characteristic changes in thylakoid protein metabolism, which were observed when leaves were grown at low temperatures in controlled environments, were identified in leaves of a field maize crop during the early growing season when low temperatures were experienced by the crop. Chill-induced perturbations of thylakoid development can occur in the field in temperate regions and may have implications for the photosynthetic productivity of the crop.

Targeted genetic inactivation of the photosystem I reaction center in the cyanobacterium Synechocystis sp. PCC 6803.

Abstract: We describe the first complete segregation of a targeted inactivation of psaA encoding one of the P700-chlorophyll a apoproteins of photosystem (PS) I. A kanamycin resistance gene was used to interrupt the psaA gene in the unicellular cyanobacterium Synechocystis sp. PCC 6803. Selection of a fully segregated mutant, ADK9, was performed under light-activated heterotrophic growth (LAHG) conditions; complete darkness except for 5 min of light every 24 h and 5 mM glucose. Under these conditions, wild-type cells showed a 4-fold decrease in chlorophyll (chl) per cell, primarily due to a decrease of PS I reaction centers. Evidence for the absence of PS I in ADK9 includes: the lack of EPR (electron paramagnetic resonance) signal I, from P700+; undetectable P700-apoprotein; greatly reduced whole-chain photosynthesis rates; and greatly reduced chl per cell, resulting in a turquoise blue phenotype. The PS I peripheral proteins PSA-C and PSA-D were not detected in this mutant. ADK9 does assemble near wild-type levels of functional PS II per cell, evidenced by: EPR signal II from YD+; high rates of oxygen evolution with 2,6-dichloro-p-benzoquinone (DCBQ), an electron acceptor from PS II; and accumulation of D1, a PS II core polypeptide. The success of this transformation indicates that this cyanobacterium may be utilized for site-directed mutagenesis of the PS I core.

An assessment of the mechanism of initial electron transfer in bacterial reaction centers

Abstract: Subpicosecond time-resolved photodichroism measurements on Rhodobacter sphaeroides R26 reaction centers are reported in the key region between 620 and 740 nm, where the anions of both bacteriopheophytin and bacteriochlorophyll (BChl) have their most diagnostic absorption bands. These measurements fail to resolve clearly the formation of a reduced BChl species. The implications of this for elucidating the role of the accessory BChl in the initial stage of charge separation are discussed.

Investigation into the source of electron transfer asymmetry in bacterial reaction centers.

Abstract: We have investigated the primary photochemistry of two symmetry-related mutants of Rhodobacter sphaeroides in which the histidine residues associated with the central Mg2+ ions of the two bacteriochlorophylls of the dimeric primary electron donor (His-L173 and His-M202) have been changed to leucine, affording bacteriochlorophyll (BChl)/bacteriopheophytin (BPh) heterodimers. Reaction centers (RCs) from the two mutants, (L)H173L and (M)H202L, have remarkably similar spectral and kinetic properties, although they are quite different from those of wild-type RCs. In both mutants, as in wild-type RCs, electron transfer to BPhL and not to BPhM is observed. These results suggest that asymmetry in the charge distribution of the excited BChl dimer (P*) in wild-type RCs (due to differing contributions of the two opposing intradimer charge-transfer states) contributes only modestly to the directionality of electron transfer. The results also suggest that differential orbital overlap of the two BChls of P with the chromophores on the L and M polypeptides does not contribute substantially to preferential electron transfer to BPhL.

Protein secondary structure of the isolated photosystem II reaction center and conformational changes studied by Fourier transform infrared spectroscopy.

Abstract: The secondary structure of the photosystem II (PSII) reaction center isolated from pea chloroplasts has been characterized by Fourier transform infrared (FTIR) spectroscopy. Spectra were recorded in aqueous buffers containing H2O or D2O; the detergent present for most measurements was dodecyl maltoside. The broad amide I and amide II bands were analyzed by using second-derivative and deconvolution procedures. Absorption bands were assigned to the presence of alpha-helices, beta-sheets, turns, or random structure. Quantitative analysis revealed that this complex contained a high proportion of alpha-helices (67%) and some antiparallel beta-sheets (9%) and turns (11%). An irreversible decrease in the intensity of the band associated with the alpha-helices occurs upon exposure of the isolated PSII reaction center to bright illumination. This loss of alpha-helical content gave rise to an increase in other secondary structures, particularly beta-sheets. After similar pretreatment with light, sodium dodecyl sulfate polyacrylamide gel electrophoresis reveals lower mobility and solubility of constituent D1 and D2 polypeptides of the PSII reaction center. Some degradation of these polypeptides also occurs. In contrast, there is no change in the mobility of the two subunits of cytochrome b559. In the absence of illumination, the PSII reaction center exchanged into dodecyl maltoside shows good thermal stability as compared with samples in Triton X-100. Only at a temperature of about 60 degrees C do spectral changes take place that are indicative of denaturation.

Carotenoids in photosynthesis: structure and photochemistry

Abstract: Carotenoids from phototrophic bacteria cany out light-harvesting in antenna proteins via carotenoid-to-bacteriochlorophyll singlet-singlet energy transfer and photoprotection in the reaction center via bacteriochlorophyll-to-carotenoid triplet-triplet energy transfer. Spectroscopic studies have permitted elucidation of the explicit routes of these transfers in pigment-protein complexes obtained from the bacterium Rhodobacter sphaeroides. The molecular details of these mechanisms are presented and discussed in conjunction with studies revealing the structural features of the complexes.