Stabilisation of PS-II-mediated electron transport in oxygen-evolving PS II core preparations by the addition of compatible co-solutes.

Addition of high concentrations of compatible co-solutes such as sugars, sugar alcohols and polyols has recently been shown to lead to marked increases in the thermal stability of oxygen-evolution in chloroplasts (Williams et al. (1992) Biochim. Biophys. Acta 1099, 137-144). In this paper, a similar stabilisation is demonstrated for oxygen-evolving PS II core preparations. The presence of such co-solutes appears, however, to have no ability to stabilise PS II reaction-centre preparations against heat-induced changes in their absorption spectrum. Nor do they protect electron transport from artificial electron donors in PS II core preparations lacking the extrinsic 33 kDa polypeptide of the oxygen-evolution system. Measurements performed on core preparations retaining the 33 kDa polypeptide but lacking the 17 kDa and 23 kDa polypeptides indicate that the co-solutes protect PS-II-mediated electron transport by stabilising the binding of the 33 kDa polypeptide to the core complexes. These findings are discussed in terms of an extension of the general principles underlying the Hofmeister effect observed for soluble proteins to the stabilisation of photosynthetic membrane preparations.     

Biosynthetic exchange of bromide for chloride and strontium for calcium in the photosystem II oxygen-evolving enzymes

The active site for water oxidation in photosystem II goes through five sequential oxidation states (S(0) to S(4)) before O(2) is evolved. It consists of a Mn(4)Ca cluster close to a redox-active tyrosine residue (Tyr(Z)). Cl(-) is also required for enzyme activity. To study the role of Ca(2+) and Cl(-) in PSII, these ions were biosynthetically substituted by Sr(2+) and Br(-), respectively, in the thermophilic cyanobacterium Thermosynechococcus elongatus. Irrespective of the combination of the non-native ions used (Ca/Br, Sr/Cl, Sr/Br), the enzyme could be isolated in a state that was fully intact but kinetically limited. The electron transfer steps affected by the exchanges were identified and then investigated by using time-resolved UV-visible absorption spectroscopy, time-resolved O(2) polarography, and thermoluminescence spectroscopy. The effect of the Ca(2+)/Sr(2+) and Cl(-)/Br(-) exchanges was additive, and the magnitude of the effect varied in the following order: Ca/Cl < Ca/Br < Sr/Cl < Sr/Br. In all cases, the rate of O(2) release was similar to that of the S(3)Tyr(Z)(.) to S(0)Tyr(Z) transition, with the slowest kinetics (i.e. the Sr/Br enzyme) being approximately 6-7 slower than in the native Ca/Cl enzyme. This slowdown in the kinetics was reflected in a decrease in the free energy level of the S(3) state as manifest by thermoluminescence. These observations indicate that Cl(-) is involved in the water oxidation mechanism. The possibility that Cl(-) is close to the active site is discussed in terms of recent structural models.     

Kinetics of the oxygen-evolving complex in salt-washed photosystem II preparations

The kinetics of flash-induced electron transport were investigated in oxygen-evolving Photosystem II preparations, depleted of the 23 and 17 kDa polypeptides by washing with 2 M NaCl. After dark-adaptation and addition of the electron acceptor 2,5-dichloro-p-benzoquinone, in such preparations approx. 75% of the reaction centers still exhibited a period 4 oscillation in the absorbance changes of the oxygen-evolving complex at 350 nm. In comparison to the control preparations, three main effects of NaCl-washing could be observed: the half-time of the oxygen-evolving reaction was slowed down to about 5 ms, the misses and double hits parameters of the period 4 oscillation had changed, and the two-electron gating mechanism of the acceptor side could not be detected anymore. EPR-measurements on the oxidized secondary donor Z⁺ confirmed the slower kinetics of the oxygen-releasing reaction. These phenomena could not be restored by readdition of the released polypeptides nor by the addition of CaCl₂, and are ascribed to deleterious action of the highly concentrated NaCl. Otherwise, the functional coupling of Photosystem II and the oxygen-evolving complex was intact in the majority of the reaction centers. Repetitive flash measurements, however, revealed P⁺Q⁻ recombination and a slow Z⁺ decay in a considerable fraction of the centers. The flash-number dependency of the recombination indicated that this reaction only appeared after prolonged illumination, and disappeared again after the addition of 20 mM CaCl₂. These results are interpreted as a light-induced release of strongly bound Ca²⁺ in the salt-washed preparations, resulting in uncoupling of the oxygen-evolving system and the Photosystem II reaction center, which can be reversed by the addition of a relatively high concentration of Ca²⁺.     

The release of polypeptides and manganese from oxygen-evolving photosystem II preparations following zinc-treatment

Inhibition of oxygen evolution in photosystem II membrane fragments from pea chloroplasts by washing with Zn₂₊ causes appearance of the EPR signal of Mn(H₂O)₆²⁺. This Mn²⁺ remains associated with the membrane fraction. Release of Mn²⁺ into the medium was correlated with the amount of the 23 kDa protein removed from the membrane. This suggests that this protein may function as a ‘gate’ to an aqueous compartment into which Mn²⁺ is released. Inhibition by Zn²⁺ correlated with the release of 1 Mn²⁺ per reaction centre, out of a total stoichiometry of 4 Mn atoms per reaction centre. By comparing the release of Mn following Zn-treatment of NaCI or CaC1₂ washed membranes, it is concluded that the 33 kDa protein is involved in binding of 2 Mn.     

Structural,biochemical and biophysical characterization of four oxygen-evolving Photosystem II preparations from spinach

Four procedures utilizing different detergent and salt conditions were used to isolate oxygen-evolving Photosystem II (PS II) preparations from spinach thylakoid membranes. These PS II preparations have been characterized by freeze-fracture electron microscopy, SDS-polyacrylamide gel electrophoresis, steady-state and pulsed oxygen evolution, 77 K fluorescence, and room-temperature electron paramagnetic resonance. All of the O₂-evolving PS II samples were found to be highly purified grana membrane fractions composed of paired, appressed membrane fragments. The lumenal surfaces of the membranes and thus the O₂-evolving enzyme complex, are directly exposed to the external environment. Biochemical and biophysical analyses indicated that all four preparations are enriched in the chlorophyll $\text{a}\text{b-}\text{light-harvesting}$ complex and Photosystem II, and depleted to varying degrees in the stroma-associated components, Photosystem I and the CF₁-ATPase. The four PS II samples also varied in their cytochrome f content. All preparations showed enhanced stability of oxygen production and oxygen-rate electrode activity compared to control thylakoids, apparently promoted by low concentrations of residual detergent in the PS II preparations. A model is presented which summarizes the effects of the salt and detergent treatments on thylakoid structure and, consequently, on the configuration and composition of the oxygen-evolving PS II samples.     

Pulsed EPR studies of doublet signal and singlet-like signal in oriented Ca2+-depleted PS II membranes: location of the doublet signal center in PS II

Doublet signal and singlet-like signal induced in Ca(2+)-depleted PS II were investigated by pulsed EPR in one-dimensionally oriented photosystem (PS) II membranes. The doublet signal showed marked angular dependent change in its spectrum in term of the applied magnetic field, indicating that the magnetic dipole-dipole interaction is mainly responsible for the doublet signal. The singlet-like signal also showed angular dependence, which was less pronounced than that of the doublet signal. The parameters of dipole and exchange interactions used to simulate the doublet signal indicate that the signal arises from a magnetically coupled organic radical pair. Angular dependence of the doublet signal indicates that the radius vector of the radical pair (r) and the normal of the thylakoid membrane is at an angle of 65 degrees. Pulsed ELDOR studies in the oriented membranes indicate that the vector (R) connecting the doublet-signal center with the Y(D)(*) radical and the plane of the thylakoid membrane are at an angle of 8 degrees. Furthermore, the angle between the projections of the R and r vectors on the plane of the thylakoid membrane was determined to be 64 degrees. The location of the doublet-signal species in PS II is discussed.     

Interaction of the high-spin Fe atom in the photosystem II reaction center with the quinones QA and QB in purified oxygen-evolving PS II reaction center complex and in PS II particles

EPR signals in the high-spin region were studied at 10 K in photosystem II (PS II) particles and in a purified oxygen-evolving PS II reaction center complex under oxidizing conditions. PS II particles showed EPR peaks at g = 8.0 and 5.6, confirming the recent report by Petrouleas and Diner [(1986) Biochim. Biophys. Acta 849, 264-275]. Addition of 3-(3',4'-dichlorophenyl)-1,1-dimethylurea (DCMU) or o-phenanthroline shifted the peaks to be closer to g = 6.0 depending on the medium pH. On the other hand, the PS II reaction center complex showed peaks at g = 6.1 and 7.8, and at g = 6.1 and 6.4, in the absence and presence of o-phenanthroline, respectively. All these peaks were found to be decreased by the illumination at 10 K. These results suggest that the high-spin signals are due to Q₄₀₀, Fe(III) atom interacting with the PS II primary electron acceptor quinone Q_A as reported and that the Fe atom also interacts with the secondary acceptor quinone Q_B. This interaction seems to induce the highly asymmetric ligand coordination of the Fe atom and to be affected by DCMU and o-phenanthroline in a somewhat different manner.     

Spectral characteristics of PS II reaction centres: as isolated preparations and when integral to PS II core complexes

The discovery that the native PS II enzyme undergoes charge separation via an absorption extending to 730 nm has led us to re-examine the low-temperature absorption spectra of Nanba-Satoh PS II reaction centre preparations with particular focus on the long wavelength region. It is shown that these preparations do not exhibit absorption in the 700-730 nm region at 1.7 K. Absorption in the Nanba-Satoh type preparations analogous to the 'red tail' as observed in functional PS II core complexes is likely shifted to higher energy by >20 nm. Spectral changes associated with the stable reduction of pheo(a) in chemically treated reaction centre preparations are also revisited. Dithionite treatment of PS II preparations in the dark leads to changes of pigment-pigment and/or pigment-protein interactions, as evidenced by changes in absorption and CD spectra. Absorption and CD changes associated with stable Pheo(D1) photo-reduction in PS II core complexes and Nanba-Satoh preparations are compared. For Nanba-Satoh preparations, Q(y) bleaches are approximately 3x broader than in PS II core complexes and are blue-shifted by approximately 4 nm. These data are discussed in terms of current models of PS II, and suggest a need to consider protein-induced changes of some electronic properties of reaction centre pigments.     

Binding and functions of the two chloride ions in the oxygen-evolving center of photosystem II

Photosynthesis Research - Light-driven water oxidation in photosynthesis occurs at the oxygen-evolving center (OEC) of photosystem II (PSII). Chloride ions (Cl?) are essential for oxygen...     

Studies on photosynthetic oxygen-evolving complex by means of Fourier transform infrared spectroscopy: calcium and chloride cofactors

Structural roles of functional Ca²⁺ and Cl⁻ ions in photosynthetic oxygen-evolving complexes (OEC) were studied using low- (640–350 cm⁻¹) and mid- (1800–1200 cm⁻¹) frequency S₂/S₁ Fourier transform infrared (FTIR) difference spectroscopy. Studies using highly active Photosystem (PS) II core particles from spinach enabled the detection of subtle spectral changes. Ca²⁺-depleted and Ca²⁺-reconstituted particles produced very similar mid- and low-frequency spectra. The mid-frequency spectrum was not affected by reconstitution with ⁴⁴Ca isotope. In contrast, Sr²⁺-substituted particles showed unique spectral changes in the low-frequency Mn–O–Mn mode at 606 cm⁻¹ as well as in the mid-frequency carboxylate stretching modes. The mid-frequency spectrum of Cl⁻-depleted OEC exhibited marked changes in the carboxylate stretching modes and the suppression of protein modes compared with that of Cl⁻-reconstituted OEC. However, Cl⁻-depletion did not exert significant effects on the low-frequency spectrum.     

CI-NMR measurement of chloride binding to the oxygen-evolving complex of spinach Photosystem II

The mechanism by which Cl⁻ activates the oxygen-evolving complex (OEC) of Photosystem II (PS II) in spinach was studied by ³⁵Cl-NMR spectroscopy and steady-state measurements of oxygen evolution. Measurements of the excess ³⁵Cl-NMR linewidth in dark-adapted, Cl⁻-depleted thylakoid and Photosystem II membranes show an overall hyperbolic decrease which is interrupted by sharp increases in linewidth (linewidth maxima) at approx. 0.3 mM, 0.75 mM, 3.25 mM (2.0 mM in PS II membranes), and 7.0 mM Cl⁻. The rate of the Hill reaction (H₂O → 2,6-dichlorophenolindophenol) at low light intensities (5% of saturation) as a function of [Cl⁻] in thylakoids shows three intermediary plateaus in the concentration range between 0.1 and 10 mM Cl⁻ indicating kinetic cooperativity with respect to Cl⁻. The presence of linewidth maxima in the ³⁵Cl-NMR binding curve indicates that Cl⁻ addition exposes four types of Cl⁻ binding site that were previously inaccessible to exchange with Cl⁻ in the bulk solution. These results are best explained by proposing that Cl⁻ binds to four sequestered (salt-bridged) domains within the oxygen-evolving complex. Binding of Cl⁻ is facilitated by the presence of H⁺ and vice versa. The pH dependence of the excess ³⁵Cl-NMR linewidth at 0.75 mM Cl⁻ shows that Cl⁻ binding has a maximum at pH 6.0 and two smaller maxima at pH 5.4 and 6.5 which may suggest that as many as three groups (perhaps histidine) with pK_a values in the region may control the binding.     

Purification of cytochrome b-559 from oxygen-evolving Photosystem II preparations of spinach and maize

A rapid and simple procedure is presented for the purification of chloroplast cytochrome b-559. The method is based on the protocol devised by Garewal and Wasserman (Garewal, H.S. and Wasserman, A.R. (1974) Biochemistry 13, 4063–4071), which we have modified to eliminate the requirement for a lengthy electrophoretic step. Novel features of our method include: the use of oxygen-evolving Photosystem II preparations (Kuwabara, T. and Murata, N. (1982) Plant Cell Physiol. 23, 533–539) as the starting material; isocratic elution of cytochrome b-559 from a DEAE-cellulose column (yielding the protein in a pure state); and a simple column procedure for removal of excess Triton X-100. The procedure has been applied to both spinach and maize (Zea mays L.). Purified cytochromes b-559 from these species have similar optical spectra and mobility during gel electrophoresis under native conditions. Lithium dodecyl sulfate polyacrylamide gel electrophoresis of cytochrome b-559 from both spinach and maize reveals a major polypeptide band (apparent molecular mass = 9 kDa), and two minor bands (apparent molecular masses = 10 kDa and 6 kDa).     

The location of the chloride binding sites in the oxygen-evolving complex of spinach Photosystem II

³⁵Cl-NMR studies are presented here for spinach Photosystem II membranes inhibited by hydroxylamine (to remove Mn), Tris (to remove Mn and 18, 24 and 33 kDa polypeptides), and salt-washing (to remove 18 and 24 kDa; and 33 kDa polypeptides). Removal of Mn affects the ³⁵Cl-NMR binding curve only slightly, indicating that not all of the bound Mn is directly required for Cl-binding. Removal of both Mn and extrinsic polypeptides eliminates almost all of the Cl⁻-specific binding observable by NMR. Removal of the extrinsic 18 and 24 kDa polypeptides drastically changes the ³⁵Cl-NMR binding pattern; this effect is partially restored by the addition of 2 mM CaSO₄, and, to a lesser extent, by the partial rebinding of the polypeptides. Existence of Cl⁻ binding to the intrinsic polypeptides (e.g., D₁/D₂), with a peak at 0.5 mM Cl⁻, is shown in samples lacking 18, 24 and 33 kDa polypeptides. Thus, both intrinsic (i.e., on the D₁/D₂ membrane protein) and extrinsic (i.e., on the 33 kDa protein) binding sites for Cl⁻ are suggested to exist.     

S-state dependence of the calcium requirement and binding characteristics in the oxygen-evolving complex of photosystem II

The functional role of the Ca (2+) ion in the oxygen-evolving complex of photosystem II is not yet clear. Current models explain why the redox cycle of the complex would be interrupted after the S 3 state without Ca (2+), but the literature shows that it is interrupted after the S 2 state. Reinterpretation of the literature on methods of Ca (2+) depletion [Miqyass, M., van Gorkom, H. J., and Yocum, C. F. (2007) Photosynth. Res. 92, 275-287] led us to propose that all S-state transitions require Ca (2+). Here we confirm that interpretation by measurements of flash-induced S-state transitions in UV absorbance. The results are explained by a cation exchange at the Ca (2+) binding site that, in the absence of the extrinsic PsbP and PsbQ polypeptides, can occur in minutes in low S-states and in seconds in high S-states, depending on the concentration of the substituting cation. In the S 2(K (+)) or S 2(Na (+)) state a slow conformational change occurs that prevents recovery of the slow-exchange situation on return to a lower S-state but does not inhibit the S-state cycle in the presence of Ca (2+). The ratio of binding affinities for monovalent vs divalent cations increases dramatically in the higher S-states. With the possible exception of S 0 to S 1, all S-state transitions specifically require Ca (2+), suggesting that Ca (2+)-bound H 2O plays an essential role in a H (+) transfer network required for H (+)-coupled electron transfer from the Mn cluster to tyrosine Z.     

Site-directed mutagenesis of glutamate residues in the large extrinsic loop of the photosystem II protein CP 43 affects oxygen-evolving activity and PS II assembly

The psbC gene encodes the intrinsic chlorophyll protein CP 43, a component of photosystem II in higher plants, green algae, and cyanobacteria. Oligonucleotide-directed mutagenesis was used to introduce mutations into the portion of psbC that encodes the large extrinsic loop E of CP 43 in the cyanobacterium Synechocystis 6803. Three mutations, E293Q, E339Q, and E352Q, each produced a strain with impaired photosystem II activity. The E293Q mutant strain grew photoautotrophically at rates comparable to the control strain. Immunological analyses of several PS II components indicated that this mutant accumulated normal quantities of PS II proteins. However, this mutant evolved oxygen to only 56% of control rates at saturating light intensities. Measurements of total variable fluorescence yield indicated that this mutant assembled approximately 60% of the fully functional PS II centers found in the control strain. The E339Q mutant grew photoautotrophically at a severely reduced rate. Both immunological analysis and variable fluorescence yield experiments indicated that E339Q assembled a normal complement of PS II centers. However, this mutant was capable of evolving oxygen to only 20% of control rates. Variable fluorescence yield experiments demonstrated that this mutant was inefficient at using water as an electron donor. Both E293Q and E339Q strains exhibited an increased (approximately 2-fold) sensitivity to photoinactivation. The E352Q mutant was the most severely affected. This mutant failed to grow photoautotrophically and exhibited essentially no capacity for oxygen evolution. Measurements of total variable fluorescence yield indicated that this mutant assembled no functional PS II centers. Immunological analysis of isolated thylakoid membranes from E352Q revealed a complete absence of CP 43 and reduced levels of both the D1 and manganese-stabilizing proteins. These results suggest that the mutations E293Q and E339Q each produce a defect associated with the oxygen-evolving complex of photosystem II. The E352Q mutation appears to affect the stability of the PS II complex. This is the first report showing that alteration of negatively charged residues in the CP 43 large extrinsic loop results in mutations affecting PS II assembly/function.     

Determination of the PS I content of PS II core preparations using selective emission: A new emission of PS II at 780 nm

Routinely prepared PS II core samples are often contaminated by a significant (~ 1–5%) fraction of PS I, as well as related proteins. This contamination is of little importance in many experiments, but masks the optical behaviour of the deep red state in PS II, which absorbs in the same spectral range (700–730 nm) as PS I (Hughes et al. 2006). When contamination levels are less than ~ 1%, it becomes difficult to quantify the PS I related components by gel-based, chromatographic, circular dichroism or EPR techniques. We have developed a fluorescence-based technique, taking advantage of the distinctively different low-temperature emission characteristics of PS II and PS I when excited near 700 nm. The approach has the advantage of providing the relative concentration of the two photosystems in a single spectral measurement. A sensitivity limit of 0.01% PS I (or better) can be achieved. The procedure is applied to PS II core preparations from spinach and Thermosynechococcus vulcanus. Measurements made of T. vulcanus PS II preparations prepared by re-dissolving crystallised material indicate a low but measurable PS I related content. The analysis provides strong evidence for a previously unreported fluorescence of PS II cores peaking near 780 nm. The excitation dependence of this emission as well as its appearance in both low PS I cyanobacterial and plant based PS II core preparations suggests its association with the deep red state of PS II.     

Effects of photoinhibition on the PS II acceptor side including the endogenous high spin Fe2+ in thylakoids,PS II-membrane fragments and PS II core complexes

Effects of photoinhibition at 0 °C on the PS II acceptor side have been analyzed by comparative studies in isolated thylakoids, PS II membrane fragments and PS II core complexes from spinach under conditions where degradation of polypeptide(s) D1(D2) is highly retarded. The following results were obtained by measurements of the transient fluorescence quantum and oxygen yield, respectively, induced by a train of short flashes in dark-adapted samples: (a) in the control the decay of the fluorescence quantum yield is very rapid after the first flash, if the dark incubation was performed in the presence of 300 M K₃[Fe(CN)₆]; whereas, a characteristic binary oscillation was observed in the presence of 100 M phenyl-p-benzoquinone with a very fast relaxation after the even flashes (2nd, 4th. . . ) of the sequence; (b) illumination of the samples in the presence of K₃[Fe(CN)₆] for only 5 min with white light (180 W m^-2) largely eliminates the very fast fluorescence decay after the first flash due to Q_A ^- reoxidation by preoxidized endogenous non-heme Fe³⁺, while a smaller effect arises on the relaxation kinetics of the fluorescence transients induced by the subsequent flashes; (c) the extent of the normalized variable fluorescence due to the second (and subsequent) flash(es) declines in all sample types with a biphasic time dependence at longer illumination. The decay times of the fast (6–9 min) and the slow degradation component (60–75 min) are practically independent of the absence or presence of K₃[Fe(CN)₆] and of anaerobic and aerobic conditions during the photo-inhibitory treatment, while the relative extent of the fast decay component is higher under anaerobic conditions. (d) The relaxation kinetics of the variable fluorescence induced by the second (and subsequent) flash(es) become retarded due to photoinhibition, and (e) the oscillation pattern of the oxygen yield caused by a flash train is not drastically changed due to photoinhibition.Based on these findings, it is concluded that photoinhibition modifies the reaction pattern of the PS II acceptor side prior to protein degradation. The endogenous high spin Fe²⁺ located between Q_A and Q_B is shown to become highly susceptible to modification by photoinhibition in the presence of K₃[Fe(CN)₆] (and other exogenous acceptors), while the rate constant of Q_A ^- reoxidation by Q_B(Q_B ^-) and other acceptors (except the special reaction via Fe³⁺) is markedly less affected by a short photoinhibition. The equilibrium constant between Q_A ^- and Q_B(Q_B ^-) is not drastically changed as reflected by the damping parameters of the oscillation pattern of oxygen evolution.     

Comparison of the effect of calcium(II) and manganese(II) ions on trypsin autolysis

The effect of Mn²⁺ and Ca²⁺ ions on the rate of trypsin autolysis was studied at pH 7.0 and at 34.4-60.2°C. For comparison, the kinetic constants of esterolytic activity of trypsin in the presence of the metal ion were determined at pH 7.4 and at 36° and 40°C. There was no significant difference in the rate of autolysis between Mn²⁺ and Ca²⁺ in the temperature range 34-47°C, but at 56.8° and 60.2° autolysis was slightly more rapid in the presence of Mn²⁺. The Mn²⁺ or Ca²⁺ ion bound to trypsin is supposed to control the conformation and thereby the stability and the activity of the enzyme. This indirect effect of Mn²⁺ and Ca²⁺ is discussed on a structural basis of the enzyme molecule.     

Effects of drought during grain filling on PS II activity in rice

The Rice varieties Araure 4 (A4) and Fonaiap 2000 (F2000) were grown in the glasshouse under natural sunlight and subjected to drought at heading. The drought induced changes in chlorophyll a fluorescence parameters, pigment composition, D1 contents and carbohydrate accumulation were investigated. Drought decreased phiPS II, FV'/FM' and qP, and increased qN in both varieties. F2000 had larger values of phiPS II and FV'/FM' at a lower RWC than A4. With the onset of drought only A4 increased the xanthophyll cycle pool, F2000 remaining constant throughout the drought cycle. Irrigated plants of A4 had a Larger de-epoxidation state (DEPS) of the xanthophyll cycle than F2000. A 40% increase in DEPS was induced by drought in both varieties but in A4 it was attained at a larger RWC than in F2000. Drought increased glucose and fructose contents of leaves 8-fold in A4 and 3-fold in F2000. Contrarily, sucrose contents decreased with drought but the effects were larger in A4 than in F2000. Sugars accumulation preceded and was proportional to the decrease in PS II activity elicited by drought in both varieties. In F2000 a decrease in D1 content smaller than 20% occurred at 70% of RWC, whereas droughted plants of A4 had lost 80% of D1 protein at 77% of RWC. Our data show that drought severely affected PS II activity and its main regulatory mechanisms in rice. There are genotypic differences in the response of PS II activity to drought that could be exploited as traits for selection to drought tolerance. There is a possible link between the drought-induced sugars accumulation in the flag leaf and the response of PS II to water deficit.