Spectroscopic characterisation of the reaction centre of photosystem II using polarised light: Evidence for β-carotene excitons in PS II reaction centres

1991 ◽  
Vol 1057 (2) ◽  
pp. 232-238 ◽  
Author(s):  
W.R. Newell ◽  
H. van Amerongen ◽  
J. Barber ◽  
R. van Grondelle
Keyword(s):  
Photosystem Ii ◽  
Reaction Centre ◽  
Ps Ii ◽  
Reaction Centres ◽  
Polarised Light ◽  
Spectroscopic Characterisation ◽  
Β Carotene

Blue Light-Enhanced Photosynthetic Oxygen Evolution from Liposome-Bound Photosystem II Particles; Possible Role of the Xanthophyll Cycle in the Regulation of Cyclic Electron Flow Around Photosystem II?

1995 ◽  
Vol 50 (1-2) ◽  
pp. 61-68 ◽  
Author(s):  
W. I. Gruszecki ◽  
K. Strzałka ◽  
A. Radunz ◽  
J. Kruk ◽  
G. H. Schmid
Keyword(s):  
Electron Transport ◽  
Photosystem Ii ◽  
Oxygen Evolution ◽  
Xanthophyll Cycle ◽  
Red Light ◽  
Photosynthetic Oxygen Evolution ◽  
Reaction Centre ◽  
Ps Ii ◽  
Photosynthetic Oxygen ◽  
Β Carotene

Abstract Light-driven electron transport in liposome-bound photosystem II (PS-II) particles be­tween water and ferricyanide was monitored by bare platinum electrode oxymetry. The modi­fication of the experimental system with the exogenous quinones α-tocopherol quinone ( α-TQ) or plastoquinone (PQ) resulted in a pronounced effect on photosynthetic oxygen evolution. The presence of α-tocopherolquinone ( α-TQ) in PS-II samples decreased the rate of red light-induced oxygen evolution but increased the rate of green light-induced oxygen evolution. Blue light applied to the assay system in which oxygen evolution was saturated by red light resulted in a further increase of the oxygen signal. These findings are interpreted in terms of a cyclic electron transport around PS-II, regulated by an excitation state of β-carotene in the reaction centre of PS-II. A mechanism is postulated according to which energetic coupling of β-carotene in the reaction centre of PS-II and that of other antenna carotenoid pigments is regulated by the portion of the xanthophyll violaxanthin, which is under control of the xanthophyll cycle.

Kinetic response of photosystem II photochemistry in the cyanobacterium Spirulina platensis to high salinity is characterized by two distinct phases

1999 ◽  
Vol 26 (3) ◽  
pp. 283 ◽  
Author(s):  
Congming Lu ◽  
Giuseppe Torzillo ◽  
Avigad Vonshak
Keyword(s):  
Electron Transport ◽  
Quantum Yield ◽  
Photosystem Ii ◽  
Spirulina Platensis ◽  
High Salinity ◽  
Photochemical Quenching ◽  
Second Phase ◽  
Ps Ii ◽  
Reaction Centres ◽  
Two Phases

The kinetic response of photosystem II (PS II) photochemistry in Spirulina platensis(Norstedt M2 ) to high salinity (0.75 M NaCl) was found to consist of two phases. The first phase, which was independent of light, was characterized by a rapid decrease (15–50%) in the maximal efficiency of PS II photochemistry (Fv /Fm), the efficiency of excitation energy capture by open PS II reaction centres (Fv′/Fm′), photochemical quenching (qp) and the quantum yield of PS II electron transport (Φ PS II) in the first 15 min, followed by a recovery up to about 80–92% of their initial levels within the next 2 h. The second phase took place after 4 h, in which further decline in above parameters occurred. Such a decline occurred only when the cells were incubated in the light, reaching levels as low as 45–70% of their initial levels after 12 h. At the same time, non-photochemical quenching (qN) and Q B -non-reducing PS II reaction centres increased significantly in the first 15 min and then recovered to the initial level during the first phase but increased again in the light in the second phase. The changes in the probability of electron transfer beyond QA (ψo) and the yield of electron transport beyond QA (φ Eo), the absorption flux (ABS/RC) and the trapping flux (TRo /RC) per PS II reaction centre also displayed two different phases. The causes responsible for the decreased quantum yield of PS II electron transport during the two phases are discussed.

scholarly journals New Perspectives on Photosystem II Reaction Centres

2020 ◽  
Vol 73 (8) ◽  
pp. 669 ◽  
Author(s):  
Jeremy Hall ◽  
Rafael Picorel ◽  
Nicholas Cox ◽  
Robin Purchase ◽  
Elmars Krausz
Keyword(s):  
Photosystem Ii ◽  
Charge Separation ◽  
Cd Spectra ◽  
Negative Component ◽  
Ps Ii ◽  
Pheophytin A ◽  
Chl A ◽  
Special Pair ◽  
Reaction Centres ◽  
Weak Luminescence

We apply the differential optical spectroscopy techniques of circular polarisation of luminescence (CPL) and magnetic CPL (MCPL) to the study of isolated reaction centres (RCs) of photosystem II (PS II). The data and subsequent analysis provide insights into aspects of the RC chromophore site energies, exciton couplings, and heterogeneities. CPL measurements are able to identify weak luminescence associated with the unbound chlorophyll-a (Chl-a) present in the sample. The overall sign and magnitude of the CPL observed relates well to the circular dichroism (CD) of the sample. Both CD and CPL are reasonably consistent with modelling of the RC exciton structure. The MCPL observed for the free Chl-a luminescence component in the RC samples is also easily understandable, but the MCPL seen near 680nm at 1.8K is anomalous, appearing to have a narrow, strongly negative component. A negative sign is inconsistent with MCPL of (exciton coupled) Qy states of either Chl-a or pheophytin-a (Pheo-a). We propose that this anomaly may arise as a result of the luminescence from a transient excited state species created following photo-induced charge separation within the RC. A comparison of CD spectra and modelling of RC preparations having a different number of pigments suggests that the non-conservative nature of the CD spectra observed is associated with the ‘special pair’ pigments PD1 and PD2.

scholarly journals What is β–carotene doing in the photosystem II reaction centre?

2002 ◽  
Vol 357 (1426) ◽  
pp. 1431-1440 ◽  
Author(s):  
Alison Telfer
Keyword(s):  
Electron Transfer ◽  
Photosystem Ii ◽  
Excitation Energy ◽  
Triplet State ◽  
Singlet Oxygen ◽  
Spin Exchange ◽  
Primary Electron ◽  
Triplet States ◽  
Reaction Centre ◽  
Β Carotene

During photosynthesis carotenoids normally serve as antenna pigments, transferring singlet excitation energy to chlorophyll, and preventing singlet oxygen production from chlorophyll triplet states, by rapid spin exchange and decay of the carotenoid triplet to the ground state. The presence of two β–carotene molecules in the photosystem II reaction centre (RC) now seems well established, but they do not quench the triplet state of the primary electron–donor chlorophylls, which are known as P 680 . The β–carotenes cannot be close enough to P 680 for triplet quenching because that would also allow extremely fast electron transfer from β–carotene to P + 680 , preventing the oxidation of water. Their transfer of excitation energy to chlorophyll, though not very efficient, indicates close proximity to the chlorophylls ligated by histidine 118 towards the periphery of the two main RC polypeptides. The primary function of the β–carotenes is probably the quenching of singlet oxygen produced after charge recombination to the triplet state of P 680 . Only when electron donation from water is disturbed does β–carotene become oxidized. One β–carotene can mediate cyclic electron transfer via cytochrome b 559. The other is probably destroyed upon oxidation, which might trigger a breakdown of the polypeptide that binds the cofactors that carry out charge separation.

Understanding the Topography of the Photosystem II Herbicide Binding Niche: Does QSAR Help?

1993 ◽  
Vol 48 (3-4) ◽  
pp. 140-145 ◽  
Author(s):  
John L. Huppatz ◽  
Helen G. McFadden
Keyword(s):  
Photosystem Ii ◽  
Binding Site ◽  
Photosynthetic Electron Transport ◽  
Reaction Centre ◽  
Ps Ii ◽  
Qsar Analysis ◽  
Qsar Studies ◽  
Chemical Structures ◽  
Herbicide Binding ◽  
Inhibition Potency

Abstract For thirty years the study of Quantitative Structure Activity Relationships (QSAR) has been an active area of research aimed at developing an understanding of the interactions be­ tween inhibitors of photosynthetic electron transport and the herbicide binding site in the Photosystem II (PS II) reaction centre. Many QSAR studies of PS II inhibitors with diverse chemical structures have emphasized the hydrophobic nature of the binding domain, with lipophilicity being the dominant determinant of Hill inhibition activity. The cyanoacrylate classes of PS II inhibitors also show a diversity of active structures and considerable variation in inhibition potency with minor alterations to structure. QSAR analysis and examination of chirality in cyanoacrylate inhibitors has also shown the importance of steric factors in determining activity. Different modes of binding for different classes of cyanoacrylates have been identified; a classical urea-type relationship between activity and hydrophobicity and another type of interaction in which the lipophilicity or electronic nature of phenyl substituents plays little part and the size of the substituents is of primary importance. Because size and shape are parameters of great importance in determining the topography of a binding site, QSAR studies of flexible PS II inhibitors such as cyanoacrylates will continue to be important in elucidating the intricacies of inhibitor/PS II interactions.

Molecular Modelling Studies on the Binding of Phenylurea Inhibitors to the D 1 Protein of Photosystem II

1990 ◽  
Vol 45 (5) ◽  
pp. 379-387 ◽  
Author(s):  
John Bowyer ◽  
Mark Hilton ◽  
Julian Whitelegge ◽  
Philip Jewess ◽  
Patrick Camilleri ◽  
...  
Keyword(s):  
Photosystem Ii ◽  
Molecular Model ◽  
Binding Domain ◽  
Side Chain ◽  
Head Group ◽  
Reaction Centre ◽  
Binding Interactions ◽  
Reaction Centres ◽  
Molecular Modelling Studies ◽  
Modelling Studies

Abstract A hypothetical molecular model of part of the D 1 protein of photosystem II, based on the analogous portion of the L subunit of the Rhodopseudomonas viridis reaction centre, has been used to study the binding of an extended hydrophobic phenylurea inhibitor (N,N-dimethyl-carbamoyl)4 -amino-4 ′-chloro-trans-stilbene) (I) to the QB site. The inhibitor was fitted by eye into a cleft in the site, and a limited part of the inhibitor/D 1 complex was energy minimized. The gross orientation of the inhibitor placed the dimethylurea moiety towards the predicted binding domain of the plastoquinone head group, and the stilbene moiety directed along the quinone isoprenoid side chain binding domain, suggesting a similar pathway of approach of the two molecules from the membrane into the binding site. Binding interactions of the inhibitor included hydrogen bonds to the side chain hydroxyl of ser 264 and the peptide carbonyl group of ala 251, with the side chain hydroxyl of ser 268 as an alternative ligand. Numerous hydrophobic contacts were also possible. Although phenylureas do not bind to reaction centres of Rp. viridis, many of the binding interactions to D1 could also be detected in Rp. viridis. However, the β-CH2 and δ-CO2-groups of glu 212 in Rp. viridis are located in the corresponding region of D1 occupied by the dimethylurea moiety of the inhibitor in our model of its binding to D 1. This may explain why diuron (DCMU) does not bind to Rp. viridis reaction centres.

Photosynthetic Responses of Pisum sativum to an Increase in Irradiance During Growth. II. Thylakoid Membrane Components

1987 ◽  
Vol 14 (1) ◽  
pp. 9 ◽  
Author(s):  
WS Chow ◽  
JM Anderson
Keyword(s):  
Thylakoid Membrane ◽  
High Light ◽  
Cytochrome F ◽  
Reaction Centre ◽  
Leaf Photosynthesis ◽  
Low Light ◽  
Ps Ii ◽  
Reaction Centres ◽  
Ps I ◽  
Membrane Components

Following the transfer of pea plants grown at low irradiance (60 �mol photons m-2 s-1, 16 h light/8 h dark cycles) to high irradiance (390 �mol photons m-2 s-1), the extents and time courses of the increase in the concentrations of thylakoid membrane components on a chlorophyll basis have been determined. The increase in cytochrome f (~ 70%) and plastoquinone (~ 50%) contents occurred with no noticeable lag phase. The increase in photosystem Il reaction centres (PS II, ~ 35%) and ATP synthetase (~ 90%) occurred possibly with a lag period of 1-2 days. In contrast, there was no significant increase in the concentration of P700 (reaction centre) of PS I complex. The concentration of PS II reaction centres measured by atrazine-binding exceeded that from the O2 yield per single-turnover flash by a factor of 1.17 (compared with the expected value of 1.14); this contrasts with the factor of 1.8 obtained by P. A. Jursinic and R. Dennenberg [Arch. Biochem. Biophys. (1985) 241, 540-9]. It is suggested that both methods are equivalent for the determination of PS II reaction centres in active chloroplasts. The stoichiometry of PS II : cyt f: PS I was highly flexible, and not fixed at 1 : 1 : 1. We obtained the stoichiometries of 1.25 : 0.7 : 1.0 for low-light pea chloroplasts and 1.7 : 1.25 : 1.0 for chloroplasts in pea plants that had been transferred to high light for about 10 days, demonstrating the dynamic nature of thylakoid composition and function. In the first 2 days after transferring low light pea plants to high light, the time course of the increase in CO2- and light-saturated rate of leaf photosynthesis corresponded better with that of cyt f and plastoquinone than that of other chloroplast components examined. This suggests that, during the transition period, the relatively prompt increase of cyt b/f and plastoquinone plays a part in enhancing the CO2- and light-saturated rate of leaf photosynthesis.

The origin of chlorophyll fluorescence In vivo and its quenching by the photosystem II reaction centre

1989 ◽  
Vol 323 (1216) ◽  
pp. 227-239 ◽  
Keyword(s):  
Chlorophyll Fluorescence ◽  
Photosystem Ii ◽  
Electron Acceptor ◽  
Charge Separation ◽  
Bright Light ◽  
Sodium Dithionite ◽  
Reaction Centre ◽  
Primary Charge Separation ◽  
Ps Ii ◽  
Variable Yield

Isolated chlorophyll a , in contrast to when it is dissolved in organic solvents, shows a lower and variable yield of fluorescence when bound to protein and embedded in the thylakoid membrane of photosynthetic organisms. There are two current theories that attempt to explain the origin of this variable yield of fluorescence, (i) It may be emitted directly from the photosystem II (PSII) antenna system and therefore in competition with photochemical trapping (prompt fluorescence), (ii) It may be derived from a recombination reaction between oxidized P 680 and reduced pheophytin within the PS II reaction centre (delayed fluorescence). We have isolated a PS II reaction centre complex that binds only four chlorophyll a molecules and can carry out primary charge separation. The complex contains no plastoquinone and therefore is devoid of the secondary electron acceptor Q A . It does, however, contain two pheophytin a molecules, and one of these acts as a primary electron acceptor. The electron donor is P 680 , which is either a monomeric or dimeric form of chlorophyll a . The isolated PS II reaction centre fluoresces at room temperature with a maximum at 683 nm, and the intensity of this emission is almost totally quenched when reduced pheophytin (bright light plus sodium dithionite) or oxidized P 680 (bright light plus silicomolybdate) is photoaccumulated. The photo-induced quenching of chlorophyll fluorescence when sodium dithionite is present is also observed in intact PS II preparations containing plastoquinone Q A . In the latter case Q A is chemically reduced in the dark by dithionite. Bearing in mind the above two postulates for the origin of variable chlorophyll fluorescence it has been possible to investigate the relative quantum yields for the photoproduction of the P 680 Pheo - state either in the absence (with isolated PS II reaction centres) or presence (with PSII-enriched membranes) of reduced Q A . It has been shown that in the absence of Q - A the quantum efficiency for production of the P 680 Pheo - is several orders of magnitude greater than when Q - A is present. This difference probably partly reflects the coulombic restraints on primary charge separation when Q A is reduced and would suggest that under these conditions the PS II reaction centre is a less efficient trap. Such a conclusion is therefore consistent with postulate (i) that the increase inyield of chlorophyll fluorescence as Q A becomes reduced is not due to a back reaction between P + 680 and Pheo - but rather to a decrease in competition between emission and trapping. The results do emphasize however, that the P 680 Pheo - and P + 680 Pheo states are quenchers of chlorophyll fluorescence. In addition to the above, it has been noted that at 77 K fluorescence from the isolated PS II reaction centre reaches a maximum at 685 nm and does not have a peak at 695 nm. This observation appears to invalidate the postulate that the 695 nm emission is from the pheophytin of the PS II reaction centre.

Sign in / Sign up

Export Citation Format

Share Document