Electric-field-induced luminescence emission spectra of Photosystem I and Photosystem II from chloroplasts

The electroluminescence induced by external electric fields in blebs prepared from chloroplasts consists of two kinetically different phases, rapid (R) and slow (S), which were shown to be linked to Photosystem I (PS I) and Photosystem II (PS II) activities, respectively (Symons, M., Korenstein, R. and Malkin, S. (1985) Biochim. Biophys. Acta 806, 305–310). In this report we describe conditions involving heat treatment of broken chloroplasts, which make it possible to observe R phase electroluminescence essentially devoid of any contribution by the S phase. This allowed the precise measurement of the emission spectrum of PS I electroluminescence. The emission spectrum of PS II electroluminescence was obtained using regular broken chloroplasts, which show only S-type emission. The latter emission spectrum is identical to the one obtained for ordinary prompt fluorescence, peaking at 685 nm with a bandwidth of about 25 nm. The PS I emission spectrum is symmetric around 705 nm and is much broader, about 60 nm.     

Theoretical study of the binding site and mode of action for photosystem II herbicides

Several features of a proteinaceous binding site and a molecular mode of action are proposed for photosystem II (PS II) herbicides based upon a variety of experimental and theoretical evidence. Experimental studies have established that PS II herbicides bind non-covalently to a 32 kdalton protein in the PS II complex and inhibit electron transfer between the first quinone (Q) and the second quinone (B) on the reducing side of PS II. The herbicides each contain hydrophobic components as well as a flat polar component with a dipole moment in the range of 3–5 Debyes. The primary function of the hydrophobic components is to increase the lipid solubility of the entire herbicide molecule; the secondary function of the hydrophobic components is to fit the hydrophobic surface of the herbicide binding site. It is proposed that the flat polar component binds electrostatically at a highly polar protein site, probably a protein salt bridge or the terminus of a protein alpha helix. Further, it is proposed that the PS II herbicides shift the equilibrium Q^?Bz?QB^? to the left (i) by reducing the magnitude of an anion-stabilizing electric field across the B-binding site, or (ii) by inhibiting the conformational relaxation or protonation of the PS II protein in response to reduction of B to B^?, or (iii) by displacing the quinone head of B from its binding site. Ab initio molecular quantum mechanical calculations have been carried out to investigate the electrostatic interactions in specific herbicide-binding site models.     

Nanopore-facilitated, voltage-driven phosphatidylserine translocation in lipid bilayers--in cells and in silico

Nanosecond, megavolt-per-meter pulses--higher power but lower total energy than the electroporative pulses used to introduce normally excluded material into biological cells--produce large intracellular electric fields without destructively charging the plasma membrane. Nanoelectropulse perturbation of mammalian cells causes translocation of phosphatidylserine (PS) to the outer face of the cell, intracellular calcium release, and in some cell types a subsequent progression to apoptosis. Experimental observations and molecular dynamics (MD) simulations of membranes in pulsed electric fields presented here support the hypothesis that nanoelectropulse-induced PS externalization is driven by the electric potential that appears across the lipid bilayer during a pulse and is facilitated by the poration of the membrane that occurs even during pulses as brief as 3 ns. MD simulations of phospholipid bilayers in supraphysiological electric fields show a tight association between PS externalization and membrane pore formation on a nanosecond time scale that is consistent with experimental evidence for electropermeabilization and anode-directed PS translocation after nanosecond electric pulse exposure, suggesting a molecular mechanism for nanoelectroporation and nanosecond PS externalization: electrophoretic migration of the negatively charged PS head group along the surface of nanometer-diameter electropores initiated by field-driven alignment of water dipoles at the membrane interface.     

Self-deprivation of paradoxical sleep in cats

The phenomenon of paradoxical sleep (PS) self-deprivation has been detected and described. The self-deprivation is acquired just as a classical conditioned reflex during enforced PS deprivation both by water tank procedure and by the animal's awakenings in response to sensory stimuli or direct electric stimulation of activating structures of the midbrain and diencephalon, following the transition of slow-wave sleep to PS. In this situation the transition of the brain from one physiological state to another is a conditioned signal, and sensory stimulation or brain stimulation, resulting in arousal reaction, serves as an unconditioned stimulus. It is suggested that the detection and analysis of PS self-deprivation are of a great importance, on the one hand, for correct understanding of the functional significance of this physiological brain state, and, on the other hand, for accurate analysis and assessment of the dissociative processes, observed during PS deprivation and postdeprivation period.     

Electroporation of the photosynthetic membrane: structural changes in protein and lipid-protein domains.

A biological membrane undergoes a reversible permeability increase through structural changes in the lipid domain when exposed to high external electric fields. The present study shows the occurrence of electric field-induced changes in the conductance of the proton channel of the H(+)-ATPase as well as electric field-induced structural changes in the lipid-protein domain of photosystem (PS) II in the photosynthetic membrane. The study was carried out by analyzing the electric field-stimulated delayed luminescence (EPL), which originates from charge recombination in the protein complexes of PS I and II of photosynthetic vesicles. We established that a small fraction of the total electric field-induced conductance change was abolished by N,N'-dicyclohexylcarbodiimide (DCCD), an inhibitor of the H(+)-ATPase. This reversible electric field-induced conductance change has characteristics of a small channel and possesses a lifetime < or = 1 ms. To detect electric field-induced changes in the lipid-protein domains of PS II, we examined the effects of phospholipase A2 (PLA2) on EPL. Higher values of EPL were observed from vesicles that were exposed in the presence of PLA2 to an electroporating electric field than to a nonelectroporating electric field. The effect of the electroporating field was a long-lived one, lasting for a period > or = 2 min. This effect was attributed to long-lived electric field-induced structural changes in the lipid-protein domains of PS II.     

延髓面神经后核内侧区呼吸相关神经元的放电形式

实验用家兔和ＳＤ大鼠,氨基甲酸乙酯麻醉。记录膈神经或膈肌放电作为呼吸的指标。在延髓面神经后核内侧区细胞外记录呼吸相关神经元放电,在家兔所记录到的２４９个ＲＲＮｓ中,吸气神经元１１８个,呼气神经元９１个,呼吸跨时相神经元４０个。在大鼠所记录到的１５３个ＲＲＮｓ中,吸气神经元６８个,呼气神经元５５个,呼吸跨时相神经元３０个,在ｍＮＲＦ分布有较多的呼气－呼气跨时相神经元,这类神经元放电总是先天膈神经吸气     

Calcium ion binding between lipid bilayers: the four-component system of phosphatidylserine, phosphatidylcholine, calcium chloride, and water

Ca2+ binding between lamellae of phosphatidylserine (PS) and phosphatidylcholine (PC) gives rise to a rigid phase of Ca(PS)2. When aqueous Ca2+, hydrated PS/PC, and Ca(PS)2 coexist at equilibrium, the aqueous Ca2+ concentration is invariant and is characteristic of the PS/PC ratio. This characteristic Ca2+ concentration is 0.040 microM for palmitoyloleoylphosphatidylserine without PC and increases as the inverse square of the PS mole fraction at high PS concentration (Raoult's law) and as the inverse square of the PS mole fraction multiplied by a constant at low PS concentration (Henry's law). For example, for palmitoyloleoylphosphatidylserine/palmitoyloleoylphosphatidylcholi ne = 0.6/0.4 or 0.2/0.8, this characteristic Ca2+ concentration is about 0.1 or about 6 microM, respectively. These observations at constant temperature are summarized in a quaternary phase diagram for the four-component system CaCl2/PS/PC/water.     

Paradoxical sleep inhibition by central alpha-adrenoceptor stimulant clonidine antagonized by alpha-receptor blocker yohimbine.

In cats clonidine produces sedation and dose dependent inhibition of paradoxical sleep (PS). With 10 μg/kg PS is suppressed for ca. 8 hours. The α-adrenoceptor blocking drug yohimbine (2mg/kg) increases arousal and antagonizes the PS depressing effect of clonidine. This implies that the impact of clonidine on PS is due to its stimulating effect on central α-receptors. This interpretation, however, does not resolve the current controversy, whether noradrenaline (NA) is a positive or a negative factor in PS control. Stimulation of post-synaptic α-receptors may mimic the action of liberated NA, while stimulation of presynaptic receptors inhibits NA-liberation. Both clonidine and yohimbine are claimed to have a predominance of action on the presynaptic side. Definitive conclusions, however, would require more data about the central receptors, and the timing and balance of the agonist and antagonist actions envolved. Also central adrenaline receptors and interactions with the 5-HT system may complicate the situation.     

Conformational study of poly(L-lysine) interacting with acidic phospholipid vesicles

Circular dichroism measurements were carried out on poly(L-lysine) in the presence of vesicles of the negatively charged phospholipids, phosphatidylserine (PS; from bovine brain), phosphatidic acid (PA; prepared from egg yolk lecithin) and dimyristoylphosphatidylglycerol (DMPG). PS vesicles induced a conformational change in poly(L-lysine) from random coil to alpha-helix structure in 5 mM Tes (pH 7.0), whereas PA vesicles gave rise to beta-structure in the same buffer. The fraction of alpha-helix, F alpha (or beta-structure, F beta), increased with increasing PS (or PA) concentration, reaching a saturation value of about 0.7 (or about 1). Mixed vesicles comprising PS and dilauroylphosphatidylcholine (DLPC) also induced alpha-helix conformation, however, the saturation value of F alpha diminished with decreasing PS content in mixed vesicles. On the other hand, the spectral patterns for poly(L-lysine) in DMPG vesicle suspensions exhibited the coexistence of alpha-helix and beta-structure. Both F alpha and F beta increased with DMPG concentration and reached saturation values of about 0.5. Mixed vesicles composed of DMPG and dimyristoylphosphatidylcholine (DMPC) led to a reduction in F beta, while F alpha remained almost constant. The diversity in ordered structure induced by different phospholipid vesicles suggests the participation of lipid head groups in determining the secondary structure of poly(L-lysine) adsorbed on the vesicular surface.     

Carotenoid distribution and deepoxidation in thylakoid pigment-protein complexes from cotton leaves and bundle-sheath cells of maize

In response to excess light, the xanthophyll violaxanthin (V) is deepoxidized to zeaxanthin (Z) via antheraxanthin (A) and the degree of this deepoxidation is strongly correlated with dissipation of excess energy and photoprotection in PS II. However, little is known about the site of V deepoxidation and the localization of Z within the thylakoid membranes. To gain insight into this problem, thylakoids were isolated from cotton leaves and bundle-sheath strands of maize, the pigment protein-complexes separated on Deriphat gels, electroeluted, and the pigments analyzed by HPLC. In cotton thylakoids, 30% of the xanthophyll cycle pigments were associated with the PS I holocomplex, including the PS I light-harvesting complexes and PS I core complex proteins (CC I), and about 50% with the PS II light-harvesting complexes (LHC II). The Chl was evenly distributed between PS I and PS II. Less than 2% of the neoxanthin, about 18% of the lutein, and as much as 76% of the -carotene of the thylakoids were associated with PS I. Exposure of pre-darkened cotton leaves to a high photon flux density for 20 min prior to thylakoid isolation caused about one-half of the V to be converted to Z. The distribution of Z among the pigment-protein complexes was found to be similar to that of V. The distribution of the other carotenoids was unaffected by the light treatment. Similarly, in field-grown maize leaves and in the bundle-sheath strands isolated from them, about 40% of the V present at dawn had been converted to Z at solar noon. Light treatment of isolated bundle-sheath strands which initially contained little Z caused a similar degree of conversion of V to Z. As in cotton thylakoids, about 30% the V+A+Z pool in bundle-sheath thylakoids from maize was associated with the PS I holocomplex and the CC I bands and 46% with the LHC II bands, regardless of the extent of deepoxidation. These results demonstrate that Z is present in PS I as well as in PS II and that deepoxidation evidently takes place within the pigment-protein complexes of both photosystems.Abbreviations A antheraxanthin - CC I, CC II Core or reaction center complex of PS I, PS II - CP Chl protein - EPS epoxidation state - F_m Chl fluorescence at closed PS II reaction centers - IEF isoelectric focussing gels - LHC I, LHC II light-harvesting complex of PS I, PS II - OE oxygen evolving polypeptide - PFD photon flux density - PS I^* PS I holocomplex - V violaxanthin - Z zeaxanthin - antibody against C.I.W.-D.P.B. Publication No. 1127.     

Two purified fractions of alamethicin have different conductance properties

The properties of two purified alamethicin fractions, Fraction 4 and Fraction 6, have been studied in phosphatidylethanolamine (PE) membranes and phosphatidylserine (PS) membranes. Membranes doped with Fraction 4 show well-defined single channel conductance (mean lifetime about 20 ms). The autocorrelation function of the current fluctuations has one relaxation time of the same order as the mean lifetime of the single channels, and the current response to a voltage pulse follows an exponential with only one time constant. The conductance of a membrane doped with Fraction 6 has a voltage-independent part and a current-voltage curve with a slope that is half the slope of the Fraction 4 current-voltage curve. In the presence of Fraction 6, PS membranes and PE membranes both have symmetrical current-voltage curves even with Fraction 6 added to only one side. We did not detect any well-defined single channel levels in the presence of Fraction 6, and autocorrelation analysis of the current due to Fraction 6 gave two characteristic correlation times: a fast time (about 5 ms) and a slow time (about 50 ms). High current level kinetics of Fraction 6 also show two time constants. A possible explanation for the differences between the two fractions is that Fraction 6 monomers have a lower dipole moment than those of Fraction 4. The difference in channel stability can be explained by a lowered tendency of the monomers to line up parallel to the field. The negative branch and voltage-independent conductance can be explained by lowered energy of insertion of monomers into the membrane, and lowered energy of interaction between the monomers and the electric field.     

Familial Alzheimer disease presenilin-1 mutations alter the active site conformation of γ-secretase

Presenilin-1 (PS1) is the catalytic subunit of γ-secretase, and mutations in this protein cause familial Alzheimer Disease (FAD). However, little is known about how these mutations affect the active site of γ-secretase. Here, we show that PS1 mutations alter the S2 subsite within the active site of γ-secretase using a multiple photoaffinity probe approach called "photophore walking." Moreover, we developed a unique in vitro assay with a biotinylated recombinant Notch1 substrate and demonstrated that PS1 FAD mutations directly and significantly reduced γ-secretase activity for Notch1 cleavage. Substitution of the Notch Cys-1752 residue, which interacts with the S2 subsite, with Val, Met, or Ile has little effect on wild-type PS1 but leads to more efficient substrates for mutant PS1s. This study indicates that alteration of this S2 subsite plays an important role in determining the activity and specificity of γ-secretase for APP and Notch1 processing, which provides structural basis and insights on how certain PS1 FAD mutations lead to AD pathogenesis.     

In Vivo Muscle Electroporation Threshold Determination: Realistic Numerical Models and In Vivo Experiments

In vivo electroporation is used as an effective technique for delivery of therapeutic agents such as chemotherapeutic drugs or DNA into target tissue cells for different biomedical purposes. In order to successfully electroporate a target tissue, it is essential to know the local electric field distribution produced by an application of electroporation voltage pulses. In this study three-dimensional finite element models were built in order to analyze local electric field distribution and corresponding tissue conductivity changes in rat muscle electroporated either transcutaneously or directly (i.e., two-plate electrodes were placed either on the skin or directly on the skeletal muscle after removing the skin). Numerical calculations of electroporation thresholds and conductivity changes in skin and muscle were validated with in vivo measurements. Our model of muscle with skin also confirms the in vivo findings of previous studies that electroporation “breaks” the skin barrier when the applied voltage is above 50?V.     

Effects of a missense exonic mutation in cytochrome b gene, observed on isolated mitochondrial complex III of Saccharomyces cerevisiae: consequence for the antimycin binding site

The mitochondrial complex III was isolated from a wild type strain of Saccharomyces cerevisiae PS409 and from two mutants, PS490 and PS493, carrying a missense mutation in the structural gene of cytochrome b (in exons B1 and B4 respectively). These mutants synthesize cytochrome b in variable proportions, but they are unable to grow on a respirable substrate. Strain PS493 does not bind antimycin, whereas strain PS490 contains less cytochromes b and c1 but shows a strong binding to the inhibitor. The complex isolated from the wild type strain or mutant PS493 exhibited a specific cytochrome b and cytochrome c1 heme content of approximately 8 and 4 nmol/mg of protein respectively. This content was about 3 and 2 nmol/mg with PS490, which leads to a molar stoichiometry of 1.3 : 1 for cytochromes b and c1, instead of an 'ideal' ratio of 2 : 1 expected with b-c1 complex, and obtained with the two other strains. This implies that the association (or presence) of b and c1 cytochromes is not pre-requisite for complex III assembly. The wild type complex III isolated from PS409 was found to have a high level of CoQ2H2 activity, using a synthetic coenzyme Q analog as substrate (440 s-1 mol of cytochrome c reduced/mol of cytochrome c1). This activity is fully inhibited by antimycin. The complexes isolated from the two box mutants exhibited no such activity. Analysis of the subunit composition of the three isolated complexes on sodium dodecyl sulfate-gel electrophoresis showed that all the bands belonging to the b-c1 complex were synthesized in both mutants as well as in the wild type strain. Some of them appeared to have slightly diminished, but no specific decrease of a band has been observed in mutant PS493 that does not bind antimycin, with respect to mutant PS490 which binds strongly to the inhibitor. It should be noted that the subunit of about 12-13 kDa, qualified as the antimycin binding protein, is equally present in the three complexes. The results suggest that the loss of antimycin binding in mutant PS493 might be due to conformational perturbations in the modified complex rather than to the disappearance or significant modification of some protein support.     

Separation and characterization of stroma and grana membranes — evidence for heterogeneity in antenna size of both Photosystem I and Photosystem II

A rapid procedure to fractionate the thylakoid membrane into two well-separated vesicle populations, one originating from the grana and the other from the stroma-membrane region, has been developed. This was achieved by sonication of thylakoids present in an aqueous two-phase system followed by partitioning either by countercurrent distribution or by a batch procedure in three steps. The membrane populations were analysed according to their composition and photochemical activities. The grana membranes comprise, on chlorophyll basis, about 60% of the thylakoid material and are enriched in PS II, but also contain some PS I, while the stroma membranes comprise about 40% and are enriched in PS I, but also contain some PS II. Cytochrome f was slightly enriched in the grana-derived vesicle fraction. The properties of both PS I and PS II differ between the two populations. The PS I of the grana fraction (PS I) reached half-saturation at about half the light intensity of the PS I in the stroma-membrane fraction (PS I_β). The rate of P-700 photooxidation under low light illumination was higher for PS I than for PS I_β (30% larger rate constant), showing that PS I has a larger antenna. The PS II of the grana fraction (PS II) reached half-saturation at half the light intensity compared to the PS II of the stroma-membrane fraction (PS II_β). The results show that the grana-derived membranes contain PS I and PS II which have larger functional antenna sizes than the corresponding PS I_β and PS II_β of the stroma membranes. The results suggest that the photosystems of the grana are designed to allow effective electron transport both at low and high light intensities, while the stroma-membrane photosystems mainly work at high light intensities as a supplement to the grana systems.     

Phylogenetic signals in flea-host interaction networks from four biogeographic realms: differences between interactors and the effects of environmental factors

The structure of ecological interaction networks is associated with evolutionary histories of the interacting species. This is reflected by the phylogenetic signals (PS) in these networks when closely related species interact with similar partners because some traits inherited from the ancestors may determine ecological interactions. We investigated PS for small mammalian hosts and fleas in 80 regional interaction networks from four biogeographic realms (the Palearctic, the Nearctic, the Afrotropics, and the Neotropics). We asked (i) whether the relative strength of PS in host-flea networks is similar between hosts and fleas and/or between realms; (ii) how environmental variation affects the PS of hosts and fleas in their interaction networks; and (iii) whether the PS for hosts or fleas is affected by the phylogenetic diversity of either hosts or fleas, respectively. We found that the PS for hosts was stronger than that for fleas in all realms. An environmental effect on the PS for hosts, but not for fleas, was found in three of the four realms (except the Neotropics). In the Palearctic and the Nearctic, a stronger PS was characteristic for cooler and/or drier regions, whereas the opposite was the case for the Afrotropics in regard to precipitation. The phylogenetic diversity of regional host and flea assemblages was not associated with the values of the respective PS in any realm. We conclude that the pattern of the relative strength of the PS for hosts and fleas in their interaction networks is similar in different biogeographic realms with vastly different host and flea faunas. However, the environmental effects on the PS are geographically variable and might be associated with the history of host-flea associations, as well as the spatial pattern of environmental variation, within a realm.     

Evoking picomolar binding in RNA by a single phosphorodithioate linkage

RNA aptamers are synthetic oligonucleotide-based affinity molecules that utilize unique three-dimensional structures for their affinity and specificity to a target such as a protein. They hold the promise of numerous advantages over biologically produced antibodies; however, the binding affinity and specificity of RNA aptamers are often insufficient for successful implementation in diagnostic assays or as therapeutic agents. Strong binding affinity is important to improve the downstream applications. We report here the use of the phosphorodithioate (PS2) substitution on a single nucleotide of RNA aptamers to dramatically improve target binding affinity by ∼1000-fold (from nanomolar to picomolar). An X-ray co-crystal structure of the α-thrombin:PS2-aptamer complex reveals a localized induced-fit rearrangement of the PS2-containing nucleotide which leads to enhanced target interaction. High-level quantum mechanical calculations for model systems that mimic the PS2 moiety and phenylalanine demonstrate that an edge-on interaction between sulfur and the aromatic ring is quite favorable, and also confirm that the sulfur analogs are much more polarizable than the corresponding phosphates. This favorable interaction involving the sulfur atom is likely even more significant in the full aptamer-protein complexes than in the model systems.     

DAPT-induced intracellular accumulations of longer amyloid beta-proteins: further implications for the mechanism of intramembrane cleavage by gamma-secretase

Gamma-secretase cleaves the transmembrane domain of beta-amyloid precursor protein at multiple sites. These are referred to as gamma-, zeta-, and epsilon-cleavages. We showed previously that DAPT, a potent dipeptide gamma-secretase inhibitor, caused differential accumulations of longer amyloid beta-proteins (Abetas) (Abeta43 and Abeta46) in CHO cells that are induced to express the beta C-terminal fragment (CTF). To learn more about the cleavage mechanism by gamma-secretase, CHO cell lines coexpressing betaCTF and wild-type or mutant presenilin (PS) 1/2 were generated and treated with DAPT. In all cell lines treated with DAPT, as the levels of Abeta40 decreased, Abeta46 accumulated to varying extents. In wild-type PS1 or M146L mutant PS1 cells, substantial amounts of Abeta43 and Abeta46 accumulated. In contrast, this was not the case with wild-type PS2 cells. In M233T mutant PS1 cells, significant amounts of Abeta46 and Abeta48 accumulated differentially, whereas in N141I mutant PS2 cells, large amounts of Abeta45 accumulated concomitantly with a large decrease in Abeta42 levels. Most interestingly, in G384A mutant PS1 cells, there were no significant accumulations of longer Abetas except for Abeta46. Abeta40 was very susceptible to DAPT, but other Abetas were variably resistant. Complicated suppression and accumulation patterns by DAPT may be explained by stepwise processing of betaCTF from a zeta- or epsilon-cleavage site to a gamma-cleavage site and its preferential suppression of gamma-cleavage over zeta- or epsilon-cleavage.     

Thresholds for 60 Hz magnetic field stimulation of peripheral nerves in human subjects

The goal of the research reported here is to narrow the range of uncertainty about peripheral nerve stimulation (PNS) thresholds associated with whole body magnetic field exposures at 50/60 Hz. This involved combining PNS thresholds measured in human subjects exposed to pulsed magnetic gradient fields with calculations of electric fields induced in detailed anatomical models of the body by that same exposure system. PNS thresholds at power frequencies (50/60 Hz) can be predicted from these data due to the wide range of pulse durations (70 mus to 1 ms), the length of the pulse trains (several tens of ms), and the exposure of a large part of the body to the magnetic field. These data together with the calculations of the rheobase electric field exceeded in 1% (E(1%)) of two anatomical body models, lead to a median PNS detection threshold of 47.9 +/- 4.4 mT for a uniform 60 Hz magnetic field exposure coronal to the body. The threshold for the most sensitive 1% of the population is about 27.8 mT. These values are lower than PNS thresholds produced by magnetic fields with sagittal and vertical orientations or nonuniform exposures.     

Orientation of calcium in the Mn4Ca cluster of the oxygen-evolving complex determined using polarized strontium EXAFS of photosystem II membranes

The oxygen-evolving complex of photosystem II (PS II) in green plants and algae contains a cluster of four Mn atoms in the active site, which catalyzes the photoinduced oxidation of water to dioxygen. Along with Mn, calcium and chloride ions are necessary cofactors for proper functioning of the complex. The current study using polarized Sr EXAFS on oriented Sr-reactivated samples shows that Fourier peak II, which fits best to Mn at 3.5 A rather than lighter atoms (C, N, O, or Cl), is dichroic, with a larger magnitude at 10 degrees (angle between the PS II membrane normal and the X-ray electric field vector) and a smaller magnitude at 80 degrees . Analysis of the dichroism of the Sr EXAFS yields a lower and upper limit of 0 degrees and 23 degrees for the average angle between the Sr-Mn vectors and the membrane normal and an isotropic coordination number (number of Mn neighbors to Sr) of 1 or 2 for these layered PS II samples. The results confirm the contention that Ca (Sr) is proximal to the Mn cluster and lead to refined working models of the heteronuclear Mn(4)Ca cluster of the oxygen-evolving complex in PS II.