chlorophyll-a and 2-6-dichlorobenzoquinone

Photosystems II and I (PSII, PSI) are the reaction centre-containing complexes driving the light reactions of photosynthesis; PSII performs light-driven water oxidation and PSI further photo-energizes harvested electrons. The impressive efficiencies of the photosystems have motivated extensive biological, artificial and biohybrid approaches to 're-wire' photosynthesis for higher biomass-conversion efficiencies and new reaction pathways, such as H

Topics: Carbon Cycle; Carbon Dioxide; Chlorophyll; Cyanobacteria; Electrons; Hydrogen; Oxidation-Reduction; Photosynthesis; Photosystem I Protein Complex; Photosystem II Protein Complex; Thermodynamics; Time Factors

Oxygen consumption in Mn-depleted photosystem II (PSII) preparations under continuous and pulsed illumination is investigated. It is shown that removal of manganese from the water-oxidizing complex (WOC) by high pH treatment leads to a 6-fold increase in the rate of O(2) photoconsumption. The use of exogenous electron acceptors and donors to PSII shows that in Mn-depleted PSII preparations along with the well-known effect of O(2) photoreduction on the acceptor side of PSII, there is light-induced O(2) consumption on the donor side of PSII (nearly 30% and 70%, respectively). It is suggested that the light-induced O(2) uptake on the donor side of PSII is related to interaction of O(2) with radicals produced by photooxidation of organic molecules. The study of flash-induced O(2) uptake finds that removal of Mn from the WOC leads to O(2) photoconsumption with maximum in the first flash, and its yield is comparable with the yield of O(2) evolution on the third flash measured in the PSII samples before Mn removal. The flash-induced O(2) uptake is drastically (by a factor of 1.8) activated by catalytic concentration (5-10microM, corresponding to 2-4 Mn per RC) of Mn(2+), while at higher concentrations (>100microM) Mn(2+) inhibits the O(2) photoconsumption (like other electron donors: ferrocyanide and diphenylcarbazide). Inhibitory pre-illumination of the Mn-depleted PSII preparations (resulting in the loss of electron donation from Mn(2+)) leads to both suppression of flash-induced O(2) uptake and disappearance of the Mn-induced activation of the O(2) photoconsumption. We assume that the light-induced O(2) uptake in Mn-depleted PSII preparations may reflect not only the negative processes leading to photoinhibition but also possible participation of O(2) or its reactive forms in the formation of the inorganic core of the WOC.

Topics: Benzoquinones; Chlorophyll; Electron Transport; Fluorescence; Fluorometry; Kinetics; Light; Manganese; Models, Chemical; Oxygen; Photosystem II Protein Complex; Polarography; Thylakoids

The assembly of Mn(2+) ions into the H(2)O oxidation complex (WOC) of the photosystem II (PSII) reaction center is a light-driven process, termed photoactivation. According to the "two-quantum" model, photoactivation involves two light-driven charge separations coupled to the photooxidation of Mn(2+) in order to form the first stable intermediate in a process that culminates in the oxidative assembly of four Mn(2+) ions and one Ca(2+) ion to form the active, higher valence (Mn(4)-Ca) center of the WOC. To better define the kinetics of the dark rearrangement and to gain some understanding of the basis for the very low quantum yield of the overall process, photoactivation experiments, involving different flash patterns, were conducted with Synechocystis sp. PCC6803. It was found that even the so-called first stable intermediate is readily lost during protracted (1-10 s) dark periods during photoactivation of Synechocystis cells. Low concentrations of the electron acceptor, DCBQ, improved the stability of the dark intermediates. The unstable photoactivation intermediates formed early in the photoactivation process were not, however, stabilized by the addition of Ca(2+), although the overall yield of photoactivation is enhanced by the additional Ca(2+). Measurements of the kinetics of fluorescence yield verify that Q(A)(-) to Q(B) electron transfer rates change during the course of photoactivation as the high potential form of Q(A)(-) is converted to the low potential form and show that DCBQ acts as an efficient electron acceptor from Q(A)(-) even while in its high potential form. In addition the approximately 150 ms phase corresponding to the originally described dark rearrangement of photoactivation, repetitive, double flash experiments, with a 10 s intervening dark period, reveals a faster, 15 ms phase that is accentuated by DCBQ.

Topics: Benzoquinones; Calcium; Chlorophyll; Darkness; Fluorometry; Hydroxylamine; Kinetics; Manganese; Oxidation-Reduction; Photolysis; Photosystem II Protein Complex; Quantum Theory; Synechocystis; Water

Light modulation of the ability of three artificial quinones, 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone (DBMIB), 2,6-dichloro-p-benzoquinone (DCBQ), and tetramethyl-p-benzoquinone (duroquinone), to quench chlorophyll (Chl) fluorescence photochemically or non-photochemically was studied to simulate the functions of endogenous plastoquinones during the thermal phase of fast Chl fluorescence induction kinetics. DBMIB was found to suppress by severalfold the basal level of Chl fluorescence (F(o)) and to markedly retard the light-induced rise of variable fluorescence (F(v)). After irradiation with actinic light, Chl fluorescence rapidly dropped down to the level corresponding to F(o) level in untreated thylakoids and then slowly declined to the initial level. DBMIB was found to be an efficient photochemical quencher of energy in Photosystem II (PSII) in the dark, but not after prolonged irradiation. Those events were owing to DBMIB reduction under light and its oxidation in the dark. At high concentrations, DCBQ exhibited quenching behaviours similar to those of DBMIB. In contrast, duroquinone demonstrated the ability to quench F(v) at low concentration, while F(o) was declined only at high concentrations of this artificial quinone. Unlike for DBMIB and DCBQ, quenched F(o) level was attained rapidly after actinic light had been turned off in the presence of high duroquinone concentrations. That finding evidenced that the capacity of duroquinone to non-photochemically quench excitation energy in PSII was maintained during irradiation, which is likely owing to the rapid electron transfer from duroquinol to Photosystem I (PSI). It was suggested that DBMIB and DCBQ at high concentration, on the one hand, and duroquinone, on the other hand, mimic the properties of plastoquinones as photochemical and non-photochemical quenchers of energy in PSII under different conditions. The first model corresponds to the conditions under which the plastoquinone pool can be largely reduced (weak electron release from PSII to PSI compared to PSII-driven electron flow from water under strong light and weak PSI photochemical capacity because of inactive electron transport on its reducing side), while the second one mimics the behaviour of the plastoquinone pool when it cannot be filled up with electrons (weak or moderate light and high photochemical competence of PSI).

Topics: Benzoquinones; Chlorophyll; Chloroplasts; Darkness; Dibromothymoquinone; Energy Metabolism; Fluorescence; Intracellular Membranes; Kinetics; Light; Light-Harvesting Protein Complexes; Photochemistry; Photosynthetic Reaction Center Complex Proteins; Photosystem I Protein Complex; Photosystem II Protein Complex; Plastoquinone; Quinones

Chlorophyll fluorescence induction (Chl-F) was investigated in Photosystem II (PSII)-enriched membranes, which predominantly include active (QB reducing) PSII reaction centres (RCs) and lack Photosystem I (PSI). The Chl-F curve of these preparations show a polyphasic rise from F0, the minimal fluorescence, to FP, the maximal fluorescence, with several intermediate transitions. Analyses of these transitions revealed three exponential rise components with lifetimes of 18 ms, 400 ms and 800 ms. The 18 ms component was assigned to the photoaccumulation of reduced QA. The two slowest components, of 400 ms and 800 ms, were assigned to QB reduction (QB- and QB =) and further QB= protonation (till QBH2), respectively. These assignments were based on the observation of specific quenching of the phases by DCMU or by different oxidized, reduced and protonated quinones. The work is done in low light conditions which are saturating to avoid photoinhibition or PSII inactivation effects. The results suggest that the Chl-F curve observed in PSII-enriched membranes can be attributed to the sequential steps till the photoaccumulation (reduction and protonation) of plastoquinone (PQ) by PSII. These results are in good agreement with the molecular models that show a correspondence between Chl-F and PQ reduction steps, like the models that propose and explain the O-J-I-P transients.

Topics: Benzoquinones; Chlorophyll; Fluorescence; Light; Light-Harvesting Protein Complexes; Oxidation-Reduction; Photosystem II Protein Complex; Plastoquinone; Protons

A highly active oxygen-evolving photosystem II (PSII) complex was purified from the HT-3 strain of the widely used cyanobacterium Synechocystis sp. PCC 6803, in which the CP47 polypeptide has been genetically engineered to contain a polyhistidine tag at its carboxyl terminus [Bricker, T. M., Morvant, J., Masri, N., Sutton, H. M., and Frankel, L. K. (1998) Biochim. Biophys. Acta 1409, 50-57]. These purified PSII centers had four manganese atoms, one calcium atom, and two cytochrome b(559) hemes each. Optical absorption and fluorescence emission spectroscopy as well as western immunoblot analysis demonstrated that the purified PSII preparation was devoid of any contamination with photosystem I and phycobiliproteins. A comprehensive proteomic analysis using a system designed to enhance resolution of low-molecular-weight polypeptides, followed by MALDI mass spectrometry and N-terminal amino acid sequencing, identified 31 distinct polypeptides in this PSII preparation. We propose a new nomenclature for the polypeptide components of PSII identified after PsbZ, which proceeds sequentially from Psb27. During this study, the polypeptides PsbJ, PsbM, PsbX, PsbY, PsbZ, Psb27, and Psb28 proteins were detected for the first time in a purified PSII complex from Synechocystis 6803. Five novel polypeptides were also identified in this preparation. They included the Sll1638 protein, which shares significant sequence similarity to PsbQ, a peripheral protein of PSII that was previously thought to be present only in chloroplasts. This work describes newly identified proteins in a highly purified cyanobacterial PSII preparation that is being widely used to investigate the structure, function, and biogenesis of this photosystem.

Topics: Arabidopsis Proteins; Bacterial Proteins; Benzoquinones; beta Carotene; Calcium; Chlorophyll; Cyanobacteria; Cytochrome b Group; Cytochrome c Group; Iron; Light-Harvesting Protein Complexes; Manganese; Molecular Weight; Oxygen; Peptide Fragments; Pheophytins; Photosynthetic Reaction Center Complex Proteins; Photosystem I Protein Complex; Photosystem II Protein Complex; Phycobilisomes; Plastoquinone; Proteins; Proteome; Spectrometry, Fluorescence; Thylakoids; Xanthophylls; Zeaxanthins

The intrinsic chlorophyll protein CP 43, a component of photosystem II (PS II) in higher plants, green algae, and cyanobacteria, is encoded by the psbC gene. Oligonucleotide-directed mutagenesis was employed to introduce mutations into a segment of psbC that encodes the large extrinsic loop E of CP 43 in the cyanobacterium Synechocystis 6803. Two mutations, R305S and R342S, each produced a strain with impaired photosystem II activity. The R305S mutant strain grew photoautotrophically at rates comparable to the control strain. Immunological analyses of a number of PSII components indicated that this mutant accumulated normal quantities of PSII proteins. However, this mutant evolved oxygen to only 70% of control rates at saturating light intensities. Measurements of total variable fluorescence yield indicated that this mutant assembled approximately 70% of the PSII centers found in the control strain. The R342S mutant failed to grow photoautotrophically and exhibited no capacity for oxygen evolution. However, when grown photoheterotrophically in medium containing both glucose and 3-(3, 4-dichlorophenyl)-1,1-dimethylurea (DCMU), oxygen-evolving activity was observed in the R342S mutant, but at a low level of approximately 10% of the control rate. Immunological analysis of isolated thylakoid membranes from this mutant also indicated that this strain accumulated normal amounts of PSII core proteins. Total variable fluorescence yields for the R342S mutant indicated that it assembled a severely reduced number of fully functional PSII centers. R305S and R342S mutant strains exhibited, respectively, 2.7- and 4-fold increased sensitivity to photoinactivation. The fluorescence rise times for both mutants were comparable to the control when hydroxylamine was used as electron donor. However, both strains exhibited an increase (2.5- and 8-fold, respectively, for R305S and R342S) in fluorescence rise times with water as an electron donor. These results suggest that the mutations R305S and R342S each produce a defect associated with the oxygen-evolving complex of photosystem II. These are the first site-directed mutations in CP 43 to show such an effect.

Topics: Arginine; Benzoquinones; Chlorophyll; Cyanobacteria; Electron Transport; Genotype; Mutagenesis, Site-Directed; Oxygen; Photosynthetic Reaction Center Complex Proteins; Photosystem II Protein Complex; Water