Two electron donation sites for exogenous reductants in chloroplast Photosystem II

Two sites are distinguished for the oxidation of exogenous donors by Photosystem II in non-oxygen evolving chloroplasts. In the presence of lipophilic donors (e.g. phenylenediamine, benzidine, diphenylcarbazide), the rate for Signal IIf rereduction following a flash increases as the concentration of exogenous reductant increases. There is a decrease (20–40%) in Signal IIf magnitude accompanying donor addition at low (< 10^?5M) concentrations, but the extent of the decrease does not change further with increasing donor concentration. Complementary polarographic experiments monitoring donor (phenylenediamine) oxidation show an increase in oxidation rate with increasing donor concentration.In the presence of the hydrophilic donor, Mn²⁺, the Signal IIf decay halftime remains constant with increasing Mn²⁺ concentration. However, the flash-induced Signal IIf magnitude progressively decreases with increasing Mn²⁺ concentration.These results are interpreted in terms of two competing paths for the reduction of P680⁺. In one path P680⁺ reduction is accompanied by the appearance of Signal IIf, and lipophilic donors subsequently rereduce the Signal IIf species in a series reaction. This reduction follows pseudo-first order kinetics as a function of donor concentration. In the second path Mn²⁺ reduces P680⁺ in a parallel reaction that competes with the formation of the Signal IIf species. This results in a decrease in the magnitude of Signal IIf, but no change in its decay time.     

The rapid component of electron paramagnetic resonance signal II: A candidate for the physiological donor to Photosystem II in spinach chloroplasts

Rapid light-induced transients in EPR Signal IIf (F^?+) are observed in 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU)-treated, Tris-washed chloroplasts until the state F P680 Q^? is reached. In the absence of exogenous redox mediators several flashes are required to saturate this photoinactive state. However, the Signal IIf transient is observed on only the first flash following DCMU addition if an efficient donor to Signal IIf, phenylenediamine or hydroquinone, is present. Complementary polarographic measurements show that under these conditions oxidized phenylenediamine is produced only on the first flash of a series. The DCMU inhibition of Signal IIf can be completely relieved by oxidative titration of a one-electron reductant with E′_08.0 = +480 mV. At high reduction potentials the decay time of Signal IIf is constant at about 300 ms, whereas in the absence of DCMU the decay time is longer and increases with increasing reduction potential.A model is proposed in which Q^?, the reduced Photosystem II primary acceptor, and D, a one-electron 480 mV donor endogenous to the chloroplast suspension, compete in the reduction of Signal IIf (F^?+). At high potentials D is oxidized in the dark, and the (Q^? + F^?+) back reaction regenerates the photoactive F P680 Q state. The electrochemical and kinetic evidence is consistent with the hypothesis that the Signal IIf species, F, is identical with Z, the physiological donor to P680.     

Rise time of EPR signal IIvf in chloroplast Photosystem II

The rise time of the photoinduced, reversible EPR Signal II_vf in spinach chloroplasts is found using flash excitation to be 20 ± 10 μs. The results are interpreted as evidence that the Signal II_vf radical is an electron carrier on the donor side of Photosystem II, but probably does not result from the first donor to P680⁺.     

EPR studies on the photosystem II donor side in salt-washed and reconstituted inside-out thylakoids

EPR measurements on inside-out thylakoids revealed that salt-washing, known to inhibit oxygen evolution and release a 23 and a 16 kDa protein, induced a Signal II_f and decreased the EPR signal from state S₂. Readdition of the released 23 kDa protein restored the oxygen evolution and decreased the Signal II_f, but did not relieve the decrease in the state S₂ signal. It is suggested that salt-washing inhibits the electron transfer from the oxygen-evolving site to Z, the physiological donor to P680. In inhibited photosystem II units lacking Signal II_f, Z⁺ is rapidly reduced, possibly by a modified S-cycle unable to evolve oxygen.     

Tadpole begging reveals high quality

Parents can benefit from allocating limited resources nonrandomly among offspring, and offspring solicitation (i.e. begging) is often hypothesized to evolve because it contains information valuable to choosy parents. We tested the predictions of three ‘honest begging’ hypotheses – Signal of Need, Signal of Quality and Signal of Hunger – in the tadpoles of a terrestrial frog (Oophaga pumilio). In this frog, mothers provision tadpoles with trophic eggs, and when mothers visit, tadpoles perform a putative begging signal by stiffening their bodies and vibrating rapidly. We assessed the information content of intense tadpole begging with an experimental manipulation of tadpole condition (need/quality) and food deprivation (hunger). This experiment revealed patterns consistent with the Signal of Quality hypothesis and directly counter to predictions of Signal of Need and Signal of Hunger. Begging effort and performance were higher in more developed and higher condition tadpoles and declined with food deprivation. Free‐living mothers were unlikely to feed tadpoles of a nonbegging species experimentally cross‐fostered with their own, and allocated larger meals to more developed tadpoles and those that vibrated at higher speed. Mother O. pumilio favour their high‐quality young, and because their concurrent offspring are reared in separate nurseries, must do so by making active allocation decisions. Our results suggest that these maternal choices are based at least in part on offspring signals, indicating that offspring solicitation can evolve to signal high quality.     

Supposition of the origin of Signal II from random and oriented chloroplasts

From previous studies of biological semiquinones in different solvents, the origin of Signal II in chloroplasts is hypothesized to be a plastosemiquinone anion radical perturbed by a metal cation. Assuming this model, theoretical principal g factors and hyperfine splitting constants were calculated and used to simulate the random spectrum of spinach Signal II. Oriented chloroplasts were used to determine the principal angles of this model. Oriented chloroplasts from collard greens showed a different angular dependency of Signal II from those of spinach as well as the presence of added fine structure.     

Similarity of EPR Signal IIf rise and P-680+ decay kinetics in Tris-washed chloroplast Photosystem II preparations as a function of pH

The rise time, of Signal II_f and the decay time of P-680⁺ have been measured kinetically as a function of pH by using EPR. The Photosystem II-enriched preparations which were used as samples were derived from spinach chloroplasts, and they evolved oxygen before Tris washing. The onset kinetics of Signal II_f are in agreement, within experimental error, with the fast component of the decay of an EPR signal attributable to P-680⁺. The signal II_f rise kinetics also show good agreement with published values of the pH dependence of the decay of P-680⁺ measured optically (Conjeaud, H. and Mathis, P. (1980) Biochim. Biophys. Acta 590, 353–359). These results are consistent with a model where the species Z (or D₁) responsible for Signal II_f is the immediate electron donor to P-680⁺ in tris-washed Photosystem II fragments.     

Batesian mimicry and signal detection theory

Signal Detection Theory can be used to provide a mathematical model describing the choice of a predator trying to distinguish between a model and a Batesian mimic. The mathematical model yields a number of a deductions, in particular that it may or may not assist the mimic population if mimics more closely resemble their models. The assumptions underlying the analysis are discussed in some detail.     

Characteristics of the Photosystem II reaction centre. II. Electron donors

The properties of Photosystem II electron donation were investigated by EPR spectrometry at cryogenic temperatures. Using preparations from mutants which lacked Photosystem I, the main electron donor through the Photosystem II reaction centre to the quinone-iron acceptor was shown to be the component termed Signal II. A radical of 10 G line width observed as an electron donor at cryogenic temperatures under some conditions probably arises through modification of the normal pathway of electron donation. High-potential cytochrome b-559 was not observed on the main pathway of electron donation. Two types of PS II centres with identical EPR components but different electron-transport kinetics were identified, together with anomalies between preparations in the amount of Signal II compared to the quinone-iron acceptor. Results of experiments using cells from mutants of Scenedesmus obliquus confirm the involvement of the Signal II component, manganese and high-potential cytochrome b-559 in the physiological process leading to oxygen evolution.     

The cationic plastoquinone radical of the chloroplast water splitting complex: Hyperfine splitting from a single methyl group determines the EPR spectral shape of Signal II

The proposal that EPR Signal II in spinach chloroplasts is due to a plastoquinone cation radical (O'Malley, P.J. and Babcock, G.T. (1983) Biophys. J. 41, 315a) has been investigated in further detail. The similarity in spectral shape between Signal II and the 2-methyl-5-isopropylhydroquinone cation radical is shown to arise from hyperfine coupling to one methyl group for both radicals. A well-resolved four line EPR spectrum of approximate relative intensity 1:3:3:1 for membrane orientation parallel and perpendicular to the applied magnetic field direction also indicates that the partially resolved structure of Signal II is due to hyperfine interaction with one methyl group, i.e., the 2-CH₃ group of the plastoquinone cation radical. The ENDOR band observed for this coupling is similar to that observed for methyl group bands of model quinone radicals. The principal hyperfine tensor values obtained for the methyl group interactions are A_⊥ = 27.2 MHz and $\text{A}{}_{\mathrm{}}\text{= 31.4}\text{MHz}$. The large isotropic coupling value (28.6 MHz) of the plastoquinone cation radical's 2-methyl group in vivo indicates that the antisymmetric orbital is the sole contributor to the spin-density distribution of Signal II. The orientation data also suggest that the plastoquinone cation radical is oriented such that the C-CH₃ bond direction, and hence the aromatic ring plane, lies perpendicular to the membrane plane.     

Charge Distribution on the Membrane Surface of the Donor Side of Photosystem II. Effect of the Free Radical Relaxing Agent Dysprosium on the Power Saturation of EPR Signal IIS in PS-II Particles

The effect of the paramagnetic rare earth dysprosium (Dy) onthe power saturation of EPR Signal II, was studied with thePS-II particles to obtain information on the charge distributionand structure of the donor side of PS II, which contains thethree peripheral polypeptides of 33, 24 and 18 kDa. DyCl₃ andDy-EDTA complex were used as relaxing agents for Signal II,in the untreated, NaCl-washed and CaCl₂-washed PS-II particles.In the untreated PS-II particles, DyCl₃ significantly relievedthe power saturation of Signal II_S, whereas Dy-EDTA was lesseffective. After the NaCl washing of the PS-II particles, whichremoved the 24- and 18-kDa polypeptides, the effectiveness ofDyCl₃ increased while that of Dy-EDTA did not change. In theCaCl₂- washed particles, from which all the three polypeptideshad been removed, DyCl₃ was slightly more effective and Dy-EDTAwas more effective than in the NaCl-washed particles. Theseresults suggest that the binding site of the 24- and /or 18-kDapolypeptides on the inner surface of PS II is negatively charged,while the binding site of the 33-kDa polypeptide is positivelycharged. (Received September 24, 1986; Accepted September 7, 1987)     

Electron paramagnetic resonance Signal II in spinach chloroplasts. I. Kinetic analysis for untreated chloroplasts

An analysis of electron paramagnetic resonance Signal II in spinach chloroplasts has been made using both continuous and flashing light techniques. In order to perform the experiments we developed a method which allows us to obtain fresh, untreated chloroplasts with low dark levels of Signal II. Under these conditions a single 10-μs flash is sufficient to generate greater than 80% of the possible light-induced increase in Signal II spin concentration. The risetime for this flash-induced increase in Signal II is approx. 1 s. The close association of Signal II with Photo-system II is confirmed by the observations that red light is more effective than is far red light in generating Signal II, and that 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) does not inhibit the formation of the radical. Single flash saturation curves for the flash-induced increase in Signal I and Signal II indicate that the quantum efficiency for Signal II formation is close to that for Signal I. While one or two flashes (spaced 10 ms apart) are quite efficient in generating Signal II, three or four flashes are much less effective. However, if this spacing is decreased to 100 μs, three or four flashes become as efficient as one or two flashes. From observations of a deficiency of O₂ evolved during the initial flashes of dark-adapted chloroplasts, we conclude that the species which gives rise to Signal II is able to compete with water for oxidizing equivalents generated by Photosystem II. On the basis of these results we postulate a model in which Signal II arises from an oxidized radical which is produced by a slow electron transfer to the specific states S₂ and S₃ on the water side of Photo-system II.     

Site of salicylaldoxime interaction with photosystem II

The reversible inhibition of Photosystem II by salicylaldoxime was studied in spinach D-10 particles by fluorescence, optical absorption, and electron spin resonance spectroscopy. In the presence of 15 mM salicylaldoxime, the initial fluorescence yield was raised to the level of the maximum fluorescence, indicating efficient charge recombination between reduced pheophytin (Ph) and P680⁺. In agreement with the rapid (ns) backreaction expected between Ph^– and P680⁺, the optical absorption transient at 820 mm was not observed. When the particles were washed free of salicylaldoxime, the optical absorption transient resulting from the rereduction of P680⁺ was restored to the µs timescale. These results, along with the previously observed inhibition of electron transport reactions and diminution of the 515-nm absorption change in chloroplasts [Golbeck, J.H. (1980) Arch Biochem Biophys 202, 458–466], are consistent with a site of inhibition between Ph and QA in Photosystem II. ESR Signal IIf and Signal Its were abolished in the presence of 25 mM salicylaldoxime, but both signals could be recovered by washing the D-10 particles free of the inhibitor. The loss of Signal Ilf is most likely a consequence of the inhibition between Ph and Q_A; the rapid charge recombination between Ph^– and P680⁺ would preclude electron transfer from an electron donor on the oxidizing side of Photosystem II. The loss of Signal Its may be due to a change in the environment of the donor complex such that the semiquinone radical giving rise to Signal Its interacts with a nearby reductant.Abbreviations D₁ electron donor to P680⁺ in oxygen-inhibited chloroplasts - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - F₀ prompt chlorophyll a fluorescence yield - F_i initial chlorophyll a fluorescence yield - F_max maximum chlorophyll a fluorescence yield - F_var variable chlorophyll a fluorescence yield - FWHM full width at half maximum - Mes 2-(N-morpholino) ethanesulfonic acid - P680 reaction center chlorophyll a of photosystem II - Ph pheophytin intermediate electron acceptor - Q_A primary quinone electron acceptor - Q_B secondary quinone electron acceptor - Tris tris(hydroxymethyl)aminomethane - Z electron donor to P680⁺     

Electron donation to Photosystem II in reaction center preparations

The room-temperature EPR characteristics of Photosystem II reaction center preparations from spinach, pokeweed and Chlamydomonas reinhardii have been investigated. In all preparations a light-induced increase in EPR Signal II, which arises from the oxidized form of a donor to P-680⁺, is observed. Spin quantitation, with potassium nitrosodisulfonate as a spin standard, demonstrates that the Signal II species, Z^?, is present in approx. 60% of the reaction centers. In response to a flash, the increase in Signal II spin concentration is complete within the 98 μs response time of our instrument. The decay of Z^? is dependent on the composition of the particle suspension medium and is accelerated by addition of either reducing agents or lipophilic anions in a process which is first order in these reagents. Comparison of these results with optical data reported previously (Diner, B.A. and Bowes, J.M. (1981) in Proceedings of the 5th International Congress on Photosynthesis (Akoyunoglou, G., ed.), Vol. 3, pp. 875–883, Balaban, Philadelphia), supports the identification of Z with the P-680⁺ donor, D₁. From the polypeptide composition of the particles used in this study, we conclude that Z is an integral component of the reaction center and use this conclusion to construct a model for the organization of Photosystem II.     

Involvement of the donor tyrosine-D1 (Yd) in Photosystem II electron transport in the green alga, Chlamydobotrys stellata

The light-induced oxidation of the accessory donor tyrosine-D (Y_D) has been studied by measurements of the EPR Signal II_slow at room temperature in the autotrophically and photoheterotrophically cultivated alga Chlamydobotrys stellata. After illumination and dark adaptation, Y_D Signal II_slow was observed only in autotrophic algae, i.e. under conditions of a linear photosynthetic electron transfer from water to NADP⁺. The addition of artificial electron acceptors phenyl-p-benzoquinone (PPQ) or dichloro-p-benzoquinone (DCQ) to the autotrophic cells caused an almost negligible increase of this signal. When photosynthetic electron flow and oxygen evolution were diminished by removal of the carbon source CO₂ and addition of acetate (photoheterotrophy), a pronounced Y_D Signal II_slow was seen only in presence of DCQ or PPQ. Several possibilities are discussed to explain the absence of Y_D Signal II_slow in photoheterotrophic Chl. stellata such as the existence of a cyclic PS II electron flow very effectively reducing P₆₈₀ and thereby preventing the possibility of Y_D oxidation. Artificial electron acceptors withdraw electrons from this cycle thus keeping the primary quinone acceptor, Q_A, oxidized and thereby diminishing the reduction of P₆₈₀ ⁺ by cyclic PSII. This leads to the appearance of the Y_D Signal II_slow also in the photoheterotrophically grown algae.Abbreviations A-band- thermoluminescence band associated with S₂Q_A ^- charge recombination - DCQ- 2,5-dichlorobenzoquinone - D₂- structure protein of Photosystem II - EPR- electron paramagnetic resonance - OEC- oxygen evolving complex - PPQ- phenyl-p-benzoquinone - PS II- Photosystem II - P₆₈₀- reaction center of Photosystem II - Q-band- thermoluminescence band associated with S₂Q_A ^- charge recombination - S_i- oxidation levels of the OEC - Y_D- tyrosine-D accessory donor to P₆₈₀ - Y_Z- tyrosine-Z electron donor to P₆₈₀ Dedicated to Prof. Dr E. Schnepf/Heidelberg.     

Characterization of commercial MOSFET detectors and their feasibility for in-vivo HDR brachytherapy

AimThe present study was to investigate the use of MOSFET as an vivo dosimeter for the application of Ir-192 HDR brachytherapy treatments.Material and methodsMOSFET was characterized for dose linearity in the range of 50–1000 cGy, depth dose dependence from 2 to 7 cm, angular dependence. Signal fading was checked for two weeks.Result and discussionDose linearity was found to be within 2% in the dose range (50–1000 cGy). The response varied within 8.07% for detector-source distance of 2–7 cm. The response of MOSFET with the epoxy side facing the source (0 degree) is the highest and the lowest response was observed at 90 and 270 degrees. Signal was stable during the study period.ConclusionThe detector showed high dose linearity and insignificant fading. But due to angular and depth dependence, care should be taken and corrections must be applied for clinical dosimetry.     

An EPR study of Signal II in oriented photosystem II membranes

Signal II of plant photosynthesis, which is thought to be due to a plastosemiquinone cation radical, has been studied by EPR at 9 and 35 GHz in non-oriented and partly oriented PS II particles. The spectra measured of the oriented particles at 35 GHz show that the molecular Z-axis, which is the axis perpendicular to the plane of the radical, makes an angle of 60° with the membrane normal. All spectra could be computer-simulated with one set of parameters. This set is essentially the same as that given earlier on the basis of EPR spectroscopy on non-oriented membranes [(1985) Biochim. Biophys. Acta 809, 421-428], except that the bond bending of the hydroxyl group on ring position 1 is found to be 60°, resulting in a somewhat smaller isotropie hyperfine splitting of the hydroxyl proton.Signal IIEPROrientationHyperfine coupling     

Oxido-reduction kinetics of Signal II slow in tris-washed chloroplasts

In this report, we characterize the relationship between species “Z” (giving rise to EPR Signal II fast) and “D” (EPR Signal II slow) in triswashed chloroplasts.At pH 8.5 an externally added donor phenylenediamine competes with D for Z⁺ reduction after its oxidation by a flash. The reduction of Z⁺ by D occurs within some milliseconds. In a subsequent dark period, D⁺ is reduced by PD, the reaction rate being independant of phenylenediamine concentration. These results are consistent with the hypothesis of an equilibrium between Z⁺D and ZD⁺, the reduction of D by phenylenediamine occuring via Z. At lower pH's, the connection between Z and D is looser: a high concentration of phenylenediamine which reduces rapidly Z⁺, is very slow in reducing D⁺ and the subsequent photooxidation of D is less efficient.     

Comparison of Signal and Bactec NR-660 blood culture systems

M. STEVENS, M.B. PRENTICE, R.A. SWANN, C.J. MITCHELL AND A. DONKIN. 1993. The Signal blood culture system was compared with the Bactec NR-660. A total of 1617 blood culture sets yielded 143 (8.8%) significant isolates; 113 (79.0%) were from positive bottles in both the Bactec and Signal systems. Twelve organisms (8.4%) were detected and isolated from the Signal system only and another 18 (12.6%) from the Bactec system only. Of these 18, five were Signal-positive but the organism was not recovered and four organisms were isolated from negative Signal bottles on terminal subculture. The time taken to detection for each system was similar; the Signal system detected 68% and the Bactec 63% of significant positives within 24 h. At 48 h Bactec detected 91% and the Signal 85%. A significantly-reduced number of bottles which gave a positive signal but were negative by microscopical and cultural methods was found, compared with previous reports. The 1 h incubation period prior to the insertion of the Signal growth indicator device was considered to be the cause of this reduction in the proportion of false positives.
Fifty-five percent (42/77) of the Bactec false positives were due to delta growth value. This is when there is an increase in the growth index of ≥ 15 without the positive threshold level of 30 being attained. This occurred in the anaerobic bottle on day 2 with 42 bottles. Another 40% (31/77) of the false positives had a growth value between the positive threshold of 30 and a value of 35.
Eighty (4.9%) of Bactec and 65 (4.0%) of Signal sets yielded clinically non-significant isolates. Although the yield of significant isolates for the two systems was similar, Signal failed to detect a small number of medically important organisms without subculture.     

On the Molecular Identity of ESR Signal II Observed in Photosynthetic Systems: The Effect of Heptane Extraction and Reconstitution With Plastoquinone and Deuterated Plastoquinone

Speculation as to the identity of Signal II, the light-induced, broad, slow decaying electron spin resonance signal with hyperfine structure observed in photosynthetic materials, has tended to center on the semiquinone of plastoquinone. Experiments reported here were designed to give direct evidence bearing on that speculation. Heptane extraction of lipids from lyophilized spinach and tobacco chloroplast fragments reduced the amplitude of Signal II and increased the ratio of Signal I:Signal II. Reconstitution of the system by the addition of plastoquinone partially restored Signal II as well as the ratio of Signal I:Signal II to its pre-extraction condition. Addition of totally deuterated plastoquinone to extracted chloroplasts in which considerable Signal II had survived heptane extraction resulted in a spectrum which showed the characteristic hallmarks of Signal II observed in totally deuterated organisms. These results establish that a free radical immediately derived from plastoquinone contributes to Signal II. The data taken by themselves are consistent with plastochromanoxyl as well as plastosemiquinone free radicals giving rise to Signal II. Other contributors to Signal II are not ruled out.