Synthesis and Assembly of the Polypeptides of Photosystem I and II in Isolated Etiochloroplasts of Wheat

Synthesis and assembly of photosystems (PS) I and II polypeptides in etiochloroplasts isolated from greening wheat (Triticum aestivum L. cv Norin 61) seedlings were studied. The isolated etiochloroplasts synthesized PSI polypeptides of 66 and 15 kilodaltons, PSII polypeptides of 46 and 42 kilodaltons, and atrazine-binding 34 to 32 kilodalton polypeptide. Their assembly processes in the thylakoid membrane were studied by pulse-chase labeling with [³⁵S]methionine, mild solubilization of the thylakoid membrane with Triton X-100, sucrose density gradient centrifugation, and polyacrylamide gel electrophoresis. The newly synthesized polypeptides of 66, 46, 42, 34, and 32 kilodaltons were first integrated into the complexes of 7.5, 5.9, 7.5, 6.3, and 7.5 Svedberg units, respectively, in 20 minutes. After the chase with excess amount of methionine for 100 min, they were found in complexes of 9.5, 9.1, 9.1, 9.1, and 9.1 Svedberg units, respectively. In this condition, stained polypeptides of PSI and PSII were found in the complexes of 11.1 and 10.3 Svedberg units, respectively. These results indicated that newly synthesized PSI or PSII polypeptides are integrated into intermediate complexes, but not complete complexes in the isolated etiochloroplasts. The relationship between the processing of the atrazine-binding 32 kilodalton polypeptide and its assembly into the PSII complex is also discussed.     

Spectral Properties and Composition of Reaction Center and Ancillary Polypeptide Complexes of Photosystem II Deficient Mutants of Synechocystis 6803

The polypeptide composition and spectral properties of three photosystem II (PSII) deficient mutants of the cyanobacterium Synechocystis 6803 have been determined. The levels of the 43 and 47 kilodalton chlorophyll-binding proteins and the reaction center component D2 are affected differently in each mutant; the 33 kD polypeptide of the oxygen-evolving complex is found at wild-type levels in all three. The 43 and 47 kilodalton proteins are implicated as important elements in the assembly and/or stability of the PSII reaction center, although the loss of one of these polypeptides does not lead to the loss of all PSII proteins. Low temperature fluorescence emission spectra of wild-type cells reveal chlorophyll-attributable peaks at 687 (PSII), 696 (PSII), and 725 (photosystem I) nanometers. All three mutants retain the 725 nanometer fluorescence but lack the 696 nanometer peak. This suggests that the latter fluorescence arises from PSII reaction center chlorophyll or results from interactions among functional PSII components in vivo. Cells that contain the 43 kilodalton and lack the 47 kilodalton protein, retain the 687 fluorescence; furthermore, in as much as this fluorescence is absent from cells without the 43 kilodalton protein, the 687 nanometer peak is judged to emanate from the 43 kilodalton chlorophyll-protein. A new peak, probably previously obscured, is revealed at 691 nanometers in cells that retain the 47 kilodalton protein but lack the 43 kilodalton polypeptide, suggesting that emission near 691 nanometers can be attributed to the 47 kilodalton polypeptide. Membrane-bound phycobilisomes are retained in these cells as is coupled-energy transfer between phycocyanin and allophycocyanin. Energy transfer to photosystem I by way of phycocyanin excitation proceeds as in wild-type cells despite the absence of certain PSII components.     

The highly abundant chlorophyll-protein complex of iron-deficient Synechococcus sp. PCC7942 (CP43') is encoded by the isiA gene.

A chlorophyll (Chl)-protein complex designated CPVI-4 becomes the major pigment-protein complex in Synechococcus sp. PCC7942 cells grown under conditions of iron limitation. Work by Laudenbach et al. (J Bacteriol [1988] 170: 5018-5026) has identified an iron-repressible operon, designated isiAB, containing the flavodoxin gene and a gene predicted to encode a Chl-binding protein resembling CP43 of photosystem II. To test the hypothesis that the CP43-like protein is a component of the CPVI-4 complex, we have inactivated the isiAB operon in Synechococcus sp. PCC7942 using directed insertional mutagenesis. Mutant cells grown under conditions of iron limitation exhibit pronounced changes in their spectroscopic and photosynthetic properties relative to similarly grown wild-type cells. Notably, the strong 77 K fluorescence emission at 685 nm, which dominates the spectrum of iron-deficient wild-type cells, is dramatically reduced in the mutant. The loss of this emission appears to unmask the otherwise obscured photosystem II emissions at 685 and 695 nm. Most importantly, mildly denaturing gel electrophoresis shows that mutant cells no longer express the CPVI-4 complex, indicating that the isiA gene encodes a component of this abundant Chl-protein complex.     

Apparent processing of a soybean oil body protein accompanies the onset of oil mobilization

The membrane surrounding the oil body contains several different specific polypeptides. To study the biosynthesis and posttranslational modification of these polypeptides we have prepared monoclonal antibodies against purified oil bodies of soybean (Glycine max). Three of the five monoclonals selected recognize a molecular mass 34 kilodalton protein (P34). Epitope mapping of CNBr and proteolytic fragments of P34 indicates that two of the anti-P34 monoclonal antibodies are directed at different epitopes. P34 is accumulated during seed maturation at the same time as the reserve proteins and oil. SDS/PAGE-immunoblots of germinating soybean seed cotyledons indicate that the protein is initially present as a molecular mass 34 kilodalton polypeptide and is processed to molecular mass 32 kilodalton on the fourth through sixth days of seedling growth simultaneously with the onset of oil mobilization. A comparison of reduced and carboxymethylated oil body proteins with nonreduced proteins by SDS/PAGE indicates that P34 exists in vivo as a dimer of molecular mass 58 kilodalton. Comparing the amino terminal sequences of P34 and P32 indicates that their difference is at least in part due to the removal of the amino terminus of P34. The amino terminal sequences of P34 and P32 were aligned to show that the transition of P34 to P32 was accompanied by the removal of a hydrophilic decapeptide (KKMKKEQYSC) at the amino terminus of P34. Hopp-Woods hydrophilicity analysis of the deleted amino terminus of P34 shows that it is more hydrophilic and charged than the sequence of the protein which immediately follows.     

Dynamics of Photosystem II and Its Light Harvesting System in Response to Light Changes in the Halotolerant Alga Dunaliella salina

A photosystem two (PSII) core complex consisting of five major polypeptides (47, 40, 32, 30, and 10 kilodaltons) and a light harvesting chlorophyll a/b complex (LHC-2) have been isolated from the halotolerant alga Dunaliella salina. The chlorophyll and polypeptide composition of both complexes were compared in illuminated and dark-adapted cultures. Dark adaptation is accompanied by a decrease in the chlorophyll a to chlorophyll b (Chl a/Chl b) ratio of intact thylakoids without any change in total chlorophyll. These changes occur with a half-time of 3 hours and are reversed upon reillumination. Analyses of PSII enriched membrane fragments suggest that the decrease in the Chl a/Chl b is due partly to an increase in the Chl b content of LHC-2 and partly to changes in the relative levels of the two complexes. Apparently during dark adaptation there is: (a) a net synthesis of chlorophyll b, (b) removal of PSII core complexes resulting in a 2-fold drop in the PSII cores to LHC-2 chlorophyll ratio. These changes should dramatically increase the light harvesting capacity of the remaining PSII reaction centers. Presumably this adjustment of antenna size and composition is a physiological mechanism necessary for responding to shade conditions. Also detected, using ³²P, are light-induced phosphorylation of the LHC-2 (consistent with the ability to undergo State transitions) and of the 40 and 30 kilodalton subunits of the PSII core complex. These observations indicate that additional mechanisms may also exist to help optimize the interception of quanta during rapid changes in illumination conditions.     

Dephosphorylation of photosystem II proteins and phosphorylation of CP29 in barley photosynthetic membranes as a response to water stress

Kinetic studies of protein dephosphorylation in barley thylakoid membranes revealed accelerated dephosphorylation of photosystem II (PSII) proteins, and meanwhile rapidly induced phosphorylation of a light-harvesting complex (LHCII) b4, CP29 under water stress. Inhibition of dephosphorylation aggravates stress damages and hampers photosystem recovery after rewatering. This increased dephosphorylation is catalyzed by both intrinsic and extrinsic membrane protein phosphatase. Water stress did not cause any thylakoid destacking, and the lateral migration from granum membranes to stroma-exposed lamellae was only found to CP29, but not other PSII proteins. Activation of plastid proteases and release of TLP40, an inhibitor of the membrane phosphatases, were also enhanced during water stress. Phosphorylation of CP29 may facilitate disassociation of LHCII from PSII complex, disassembly of the LHCII trimer and its subsequent degradation, while general dephosphorylation of PSII proteins may be involved in repair cycle of PSII proteins and stress-response-signaling.     

Phosphorylation of Photosystem II Components, CP43 Apoprotein, D1, D2, and 10 to 11 Kilodalton Protein in Chloroplast Thylakoids of Higher Plants

Phosphorylated thylakoid proteins of spinach (Spinacia oleracea L.) and pea (Pisum sativum L.) were solubilized, fractionated by sucrose density gradient centrifugation, and analyzed by gel electrophoresis and crossed immunoelectrophoresis to identify the phosphoproteins. It was found that in addition to intense phosphorylation of light-harvesting chlorophyll complex II, four photosystem II components, CP43 apoprotein, D1, D2, and a 10 to 11 kilodalton protein, are substantially phosphorylated in the light. Furthermore, the CP43 apoprotein, D1 and D2 can be resolved into two electrophoretic subspecies, only one of which is phosphorylated. This indicates that only a fraction of the PSII polypeptides is phosphorylated. Finally, analysis of detergent procedures suggests that the 10 to 11 kilodalton phosphoprotein is a peripheral component of the O₂-evolving PSII reaction center complex.     

Identification of a chloroplast membrane polypeptide associated with the oxidizing side of photosystem II by the use of select low-fluorescent mutants of Scenedesmus

Comparison of photochemical activities and variable fluorescence yield characteristics of whole cells and isolated chloroplast particles of low-fluorescent, photosystem II mutants of $\text{Scenedesmus}$$\text{obliquus}$ to those of the wild-type showed that several strains were affected primarily on the oxidizing side of photosystem II. In strains LF-1, LF-3, and LF-5 analysis of the manganese content of isolated chloroplast membranes showed a predominant shift in the $\text{Mn}\text{400}$ Chl from the wild-type value (4.3) to values near 1.5; this difference was also associated with a near total loss of cytochrome b-559 (high potential). Examination of chloroplast membrane polypeptides by gel electrophoresis revealed a decrease only in the mobility of one band in all three mutants; the apparent molecular weight was shifted from 34 kilodalton in the wild-type to 36 kilodalton in the mutants. Evidence is presented suggesting that the 34 kilodalton polypeptide of the wild-type is probably associated with the manganese requiring portion of the water-splitting apparatus of photosystem II.     

Light quality effects on corn chloroplast development

Corn was grown under greenhouse and controlled light quality conditions incluing full spectrum, red (R), and far-red (FR) sources. Young leaf samples were analyzed for pigments, pigment-proteins, membrane polypeptides, and ultrastructure. Chloroplast development in full spectrum white light was similar to that found in R but different from that found in FR plus low R. Compared to greenhouse and R, FR plus low R (670-760) repressed the formation of photosystem I reaction center protein (CP1 + CP1a) and enhanced those of photosystem II (CPa) in both bundle sheath and mesophyll cells. Photosystem II polypeptides were present in both cell types, with the 46 and 34 kilodalton proteins predominant in mesophyll cells. Bundle sheath cells contained relatively more of the 51 kilodalton and less of the 46 kilodalton proteins. However, they also contained measurable amounts of ribulose bisphosphate carboxylase which may interfere with estimates of the 51 kilodalton protein.     

Photosystem II in Guard Cells of Vicia faba: Immunological Detection

Antibodies were raised against individual polypeptides of the oxygen-evolving photosystem II (PSII) complex from mesophyll chloroplasts of Vicia faba (Long Pod). These antibodies were used to probe immunologically for the presence of the main structural components of the PSII complex in guard cell chloroplasts, using both immunofluorescence microscopy and Western blotting. Immunofluorescence of epidermal peels with antibodies raised against the extrinsic 33 kilodalton polypeptide, as well as the 47 and the 44 kilodalton subunits and the light-harvesting chlorophyll a/b protein, resulted in intense fluorescence indicating the presence of these polypeptide components in guard cell chloroplasts. Results obtained with Western blot analysis showed that the relative amounts of the 33 kilodalton and light-harvesting complex protein polypeptides are between 60 and 80% of that found in mesophyll cells (on chlorophyll basis). These results provide evidence for the existence of structural components associated with PSII activity in guard cell similar to those of mesophyll chloroplasts.     

Changes in Protein Composition and Mn Abundance in Photosystem II Particles on Photoactivation of the Latent O(2)-Evolving System in Flash-Grown Wheat Leaves

Protein composition and Mn abundance were compared between the two photosystem II (PSII) particle preparations obtained before and after photoactivation of the latent O₂-evolving system in intermittently flashed wheat leaves. The following results have been obtained: (a) nonphotoactivated PSII particles were devoid of two extrinsic proteins which corresponded to the 24 and 16 kilodalton proteins in spinach particles, although the particles contained all the intrinsic proteins and the 33 kilodalton extrinsic protein. (b) The two extrinsic proteins absent in nonphotoactivated PSII particles were present in nonphotoactivated thylakoids, but were easily removed by a hypotonic shock followed by brief sonication. Such removal of the proteins did not occur in photoactivated thylakoids. (c) Nonphotoactivated PSII particles contained 1.5 Mn/400 chlorophyll, while photoactivated particles contained 8 Mn/400 chlorophyll. (d) Nonphotoactivated thylakoids contained 6 Mn/400 chlorophyll, but most of them were removed from thylakoids by a hypotonic shock in the presence of ethylenediaminetetraacetate. Such removal of Mn did not occur in photoactivated thylakoids.     

Role of the Colorless Polypeptides in Phycobilisome Assembly in Nostoc sp

We have identified the function of the `extra' polypeptides involved in phycobilisome assembly in Nostoc sp. These phycobilisomes, as those of other cyanobacteria, are composed of an allophycocyanin core, phycoerythrin- and phycocyanin-containing rods, and five additional polypeptides of 95, 34.5, 34, 32, and 29 kilodaltons. The 95 kilodalton polypeptide anchors the phycobilisome to the thylakoid membrane (Rusckowski, Zilinskas 1982 Plant Physiol 70: 1055-1059); the 29 kilodalton polypeptide attaches the phycoerythrin- and phycocyanin-containing rods to the allophycocyanin core (Glick, Zilinskas 1982 Plant Physiol 69: 991-997). Two populations of rods can exist simultaneously or separately in phycobilisomes, depending upon illumination conditions. In white light, only one type of rod with phycoerythrin and phycocyanin in a 2:1 molar ratio is synthesized. Associated with this rod are the 29, 32, and 34 kilodalton colorless polypeptides; the 32 kilodalton polypeptide links the two phycoerythrin hexamers, and the 34 kilodalton polypeptide attaches a phycoerythrin hexamer to a phycocyanin hexamer. The second rod, containing predominantly phycocyanin, and the 34.5 and 29 kilodalton polypeptides, is synthesized by redlight-adapted cells; the 34.5 kilodalton polypeptide links two phycocyanin hexamers. These assignments are based on isolation of rods, dissociation of these rods into their component biliproteins, and analysis of colorless polypeptide composition, followed by investigation of complexes formed or not formed upon their recombination.     

Chlorophyll-protein composition of the thylakoid membrane from Prochlorothrix hollandica, a prokaryote containing chlorophyll b

The chlorophyll-protein complexes of the thylakoid membrane from Prochlorothrix hollandica were identified following electrophoresis under nondenaturing conditions. Five complexes, CP1-CP5, were resolved and these green bands were analyzed by spectroscopic and immunological methods. CP1 contains the photosystem I (PSI) reaction center, as this complex quenched fluorescence at room temperature, and had a 77 K fluorescence emission peak at 717 nm. CP4 contains the major chlorophyll-a-binding proteins of the photosystem II (PSII) core, because this complex contained polypeptides which cross-reacted to antibodies raised against Chlamydomonas PSII proteins 5 and 6. Furthermore, fluorescence excitation studies at 77 K indicated that only a Chl a is bound to CP4. Complexes CP2, CP3 and CP5 contained functionally bound Chl a and b as judged by absorption spectroscopy at 20 degrees C and fluorescence excitation spectra at 77 K. CP2, CP3 and CP5 all contain polypeptides of 30-33 kDa which are immunologically distinct from the LHC-II complex of higher plant thylakoids.     

Different response of photosystem II to short and long‐term drought stress in Arabidopsis thaliana

Short‐ and long‐term drought stress on photosystem II (PSII) and oxidative stress were studied in Arabidopsis thaliana. Under drought stress, chlorophyll (Chl) content, Chl fluorescence, relative water content and oxygen evolution capacity gradually decreased, and the thylakoid structure was gradually damaged. Short‐term drought stress caused a rapid disassembly of the light‐harvesting complex II (LHCII). However, PSII dimers kept stable under the short‐term drought stress and significantly decreased only after 15 days of drought stress. Immunoblotting analysis of the thylakoid membrane proteins showed that most of the photosystem proteins decreased after the stress, especially for Lhcb5, Lhcb6 and PsbQ proteins. However, surprisingly, PsbS significantly increased after the long‐term drought stress, which is consistent with the substantially increased non‐photochemical quenching (NPQ) after the stress. Our results suggest that the PSII–LHCII supercomplexes and LHCII assemblies play an important role in preventing photo‐damages to PSII under drought stress.     

Small CAB-like proteins prevent formation of singlet oxygen in the damaged photosystem II complex of the cyanobacterium Synechocystis sp. PCC 6803

The cyanobacterial small CAB-like proteins (SCPs) are single-helix membrane proteins mostly associated with the photosystem II (PSII) complex that accumulate under stress conditions. Their function is still ambiguous although they are assumed to regulate chlorophyll (Chl) biosynthesis and/or to protect PSII against oxidative damage. In this study, the effect of SCPs on the PSII-specific light-induced damage and generation of singlet oxygen ((1)O(2)) was assessed in the strains of the cyanobacterium Synechocystis sp. PCC 6803 lacking PSI (PSI-less strain) or lacking PSI together with all SCPs (PSI-less/scpABCDE(-) strain). The light-induced oxidative modifications of the PSII D1 protein reflected by a mobility shift of the D1 protein and by generation of a D1-cytochrome b-559 adduct were more pronounced in the PSI-less/scpABCDE(-) strain. This increased protein oxidation correlated with a faster formation of (1)O(2) as detected by the green fluorescence of Singlet Oxygen Sensor Green assessed by a laser confocal scanning microscopy and by electron paramagnetic resonance spin-trapping technique using 2, 2, 6, 6-tetramethyl-4-piperidone (TEMPD) as a spin trap. In contrast, the formation of hydroxyl radicals was similar in both strains. Our results show that SCPs prevent (1)O(2) formation during PSII damage, most probably by the binding of free Chl released from the damaged PSII complexes.     

Reversible changes in structure and function of photosynthetic apparatus of pea (Pisum sativum) leaves under drought stress

The effects of drought on photosynthesis have been extensively studied, whereas those on thylakoid organization are limited. We observed a significant decline in gas exchange parameters of pea (Pisum sativum) leaves under progressive drought stress. Chl a fluorescence kinetics revealed the reduction of photochemical efficiency of photosystem (PS)II and PSI. The non-photochemical quenching (NPQ) and the levels of PSII subunit PSBS increased. Furthermore, the light-harvesting complexes (LHCs) and some of the PSI and PSII core proteins were disassembled in drought conditions, whereas these complexes were reassociated during recovery. By contrast, the abundance of supercomplexes of PSII-LHCII and PSII dimer were reduced, whereas LHCII monomers increased following the change in the macro-organization of thylakoids. The stacks of thylakoids were loosely arranged in drought-affected plants, which could be attributed to changes in the supercomplexes of thylakoids. Severe drought stress caused a reduction of both LHCI and LHCII and a few reaction center proteins of PSI and PSII, indicating significant disorganization of the photosynthetic machinery. After 7 days of rewatering, plants recovered well, with restored chloroplast thylakoid structure and photosynthetic efficiency. The correlation of structural changes with leaf reactive oxygen species levels indicated that these changes were associated with the production of reactive oxygen species.     

Photoinhibition of photosystem II in vitro: Spectral and kinetic analyses

Two different preparations of photosystem II (PSII) (BBY-type membrane fragments and PSII core complexes) were isolated from 14-day-old pea seedlings (Pisum sativum L.) and used for spectral and kinetic study of photobleaching of chlorophyll (Chl) and amino acids under photoinhibitory conditions. A short-term (2–4 min) illumination of PSII preparations with high-intensity red light (λ > 610 nm, 800 W/m²) resulted in irreversible photobleaching of Chl at 672 and 682 nm under conditions of both acceptor- and donor-side photoinhibition. At longer illumination exposures (> 10 min) the photobleaching maximum at 682 nm was predominant. The calculated kinetic constants for Chl photobleaching in both absorption bands at temperatures of 20 and 4°C had similar values under different photoinhibitory conditions. The shape of action spectrum for Chl photooxidation indicates that photoinhibition of PSII was sensitized by two spectral forms of Chl with absorption maxima at 670 and 680 nm. The photobleaching of amino acids in PSII membrane fragments was only observed during acceptor-side photoinhibition and displayed the photobleaching peaks at 220 and 274 nm. The photogeneration of superoxide anion radical during donor-side photoinhibition was 4–6 times larger than during acceptor-side photoinhibition. Nevertheless, the kinetics of Chl and amino acid photobleaching in PSII preparations showed no appreciable differences. The activation energies for Chl photooxidation were estimated around 3.5 and 9 kcal/mol during acceptor- and donor-side photoinhibition, respectively, providing evidence for the involvement of biochemical stages in PSII photoinhibition. Based on the data obtained, it is proposed that the antenna Chl, rather than Chl of the reaction center, is the sensitizer for both acceptor- and donor-side photoinhibition of PSII in vitro.     

Drought-induced changes in chlorophyll fluorescence,photosynthetic pigments,and thylakoid membrane proteins of Vigna radiata

The effects of drought on chlorophyll fluorescence characteristics of PSII, photosynthetic pigments, thylakoid membrane protein (D1), and proline content in different varieties of mung bean plants were studied. Drought stress inhibits PSII activity and induces alterations in D1 protein. We observed a greater decline in the effective quantum yield of PSII, electron transport rate, and saturating photosynthetically active photon flux density (PPFD_sat) under drought stress in var. Anand than var. K-851 and var. RMG 268. This may possibly be due to either downregulation of photosynthesis or photoinhibition process. Withholding irrigation resulted in gradual diminution in total Chl content at Day 4 of stress. HPLC analysis revealed that the quantity of β-carotene in stressed plants was always higher reaching maxima at Day 4. Photoinactivation of PSII in var. Anand includes the loss of the D1 protein, probably from greater photosynthetic damage caused by drought stress than the other two varieties.     

Chlorophyll limitation in plants remodels and balances the photosynthetic apparatus by changing the accumulation of photosystems I and II through two different approaches

Arabidopsis plants with a reduced expression of CHL27 ( chl27 ), an enzyme (EC 1.14.13.81) required for the synthesis of Pchlide, are chlorotic and have a Chl a / b ratio two times higher than wild-type (WT). Knockdown plants transformed with a construct constitutively expressing CHL27 recovered regarding Chl level, a / b ratio and 77K fluorescence. A negative correlation was found between total Chl and Chl a / b ratio in the examined plants. The chl27 plants fail to assemble WT amounts of complete PSI and PSII, leading to an elevated PSII/PSI ratio. The PSI remaining in chl27 is fully functional with a quantum yield higher than for WT. Despite a severe reduction of photosystem II antennae protein (LHCII) and an increased proportion of stroma lammella, the chl27 plants are able to perform state transitions. No major differences were found regarding PSII quantum yield, qN and 1 − qp whereas non-photochemical quenching was decreased by a factor two in chl27 plants. The PSII quantum yield for dark-adapted plants and plants given 10 min recovery after high light treatment were similar for both WT and chl27 showing that chl27 plants are not more susceptible to photoinhibition than WT. Taken together the plant manage to acclimate and to balance the two photosystems well even when it is severely limited in Chl. The way to achieve this differs for the two photosystems: regarding PSI a general reduction of core and antenna subunits occurs with no apparent change in the antenna composition; whereas for PSII there is a preferential loss of antenna proteins.     

Studies on 17,24 kD Depleted Photosystem II Membranes : I. Evidences for High and Low Affinity Calcium Sites in 17,24 kD Depleted PSII Membranes from Wheat versus Spinach

Analyses were made of the effects of extraction of the 17,24 kilodalton extrinsic proteins from spinach versus wheat photosystem II (PSII) membranes on Ca abundance and O(2) evolution capacity determined in the absence and presence of either Cl(-) or Ca(2+). Extraction of these proteins from spinach PSII routinely diminished steady state O(2) evolution by about 70% when assayed in the presence of sufficient Cl(-). Additionally, O(2) evolution of 17,24 kilodalton-less spinach PSII membranes showed about 2-fold more enhancement by Ca(2+) than by Cl(-) during assay. When the same extraction and assay procedures were applied to wheat PSII membranes, we observed, in contrast to 17,24 kilodalton-less spinach PSII, only about 50% inhibition of O(2) evolution and about 2-fold greater enhancement by Cl(-) than by Ca(2+). Irrespective of differences in the magnitude of enhancement of O(2) evolution by Ca(2+)versus Cl(-) in spinach versus wheat, the K(m) values for Cl(-) (about 1.7 millimolar) and Ca(2+) (about 1.5 millimolar) were similar for both type preparations. The abundance of Ca specifically associated with fully functional PSII (about 2 and about 3 Ca/200 chlorophyll for spinach and wheat, respectively) was diminished to about 1 per 200 chlorophyll upon 17.24 kilodalton protein depletion. Further treatment of wheat 17,24 kilodalton-less PSII in darkness with 2 molar NaCl/1 millimolar ethyleneglycol-bis(beta-aminoethyl ether)-N,N'-tetraacetic acid/20 micromolar A23187(2) made O(2) evolution highly dependent on Ca(2+) addition, much like the 17,24 kilodalton-less spinach PSII. Analyses of this Ca(2+) effect on O(2) evolution revealed both high (K(m) about 65 micromolar) and low (K(m) about 1.5 millimolar) affinity Ca(2+) sites in wheat 17,24 kilodalton-less PSII. The results suggest that during 17,24 kilodalton extraction by NaCl, spinach PSII is more susceptible than wheat PSII to loss of high affinity Ca and irreversible inhibition of O(2) evolution.