Effect of Oxygen on Temporary Stabilization of Photoreduced Quinone Acceptors in Rhodobacter sphaeroides Reaction Centers

The effect of molecular oxygen on the photochemical activity of the Rhodobacter sphaeroides reaction centers frozen to 160 K under actinic illumination was investigated by the ESR method. About 90% of initially photochemically active bacteriochlorophyll (P) were fixed at 160 K for a long time in aerobic samples in an inactive form. In anaerobic samples, not more than 65% were fixed in an inactive form under the same conditions. In aerobic preparations, a small portion of photochemically active bacteriochlorophyll (about 10%) that retains its photochemical activity at 160 K after freezing under illumination has dark reduction kinetics similar to that of samples at room temperature after several seconds of actinic illumination. In anaerobic samples frozen under illumination, the remaining photochemically active reaction centers (35%) have the same dark reduction kinetics as samples illuminated at 295 K for 1-2 min. The conclusion is that the irreversible stabilization of bacteriochlorophyll P in the oxidized inactive state formed in the reaction centers frozen under illumination is brought about by light-induced conformational changes fixed under low temperatures.     

Light-activated,-inhibited and-independent denitrification by a denitrifying phototrophic bacterium

Effects of illumination on denitrification by a freshly isolated denitrifying phototrophic bacterium were investigated. Denitrification activity was induced when cells were grown in either light or darkness in the presence of nitrate without oxygen. Denitrification of nitrate with malate as the electron donor by cells at a phase of exponential growth occurred independently of illumination while that by cells in a stationary phase was activated. Effects of illumination on denitrification varied with electron donors. Using malate or succinate, denitrification by cells in a stationary phase was accelerated by illumination, inhibited when glucose or lactate was used, and independent of illumination when pyruvate was used. Denitrification by cells in an exponential phase was independent of illumination when succinate, malate or pyruvate was used and inhibited by it when glucose or lactate was used. Effects of illumination on the denitrification of nitrite were similar to those involving nitrate. Effects of various inhibitors on denitrification were examined in light-succinate and dark-lactate systems. Differences between the two systems are discussed.Abbreviations KCN potassium cyanide - HQNO 2-n-heptyl-4-hydroxyquinoline-N-oxide - TTFA 2-thenoyltrifluoroacetone - CCCP carbonyl cyanide-m-chlorophenylhydrazone - DCCD dicyclohexylcarbodiimide     

Glu-69 of the D2 protein in photosystem II is a potential ligand to Mn involved in photosynthetic oxygen evolution

To probe the involvement of amino acid residues of the D2 protein in the water-splitting process in photosystem II, site-directed mutagenesis was applied to identify D2 residues that might contribute to binding the Mn cluster involved in oxygen evolution. Mutation of Glu-69 to Gln or Val in D2 of the cyanobacterium Synechocystis sp. PCC 6803 was found to lead to a loss of photoautotrophic growth. However, in cells of the Gln mutant (E69Q) a significant Hill reaction rate could be observed upon the start of illumination, but the oxygen evolution rate declined with a half-time of approximately 1 min. Addition of 1 mM Mn2+ stabilized oxygen evolution in E69Q thylakoids. Other divalent cations were ineffective in specific stabilization. When the water-splitting system was bypassed, the rate of electron transport remained stable during illumination, indicating that the inactivation of oxygen evolution is localized in the water-splitting complex. We interpret these observations to indicate that Glu-69 is a Mn ligand and that the loss of oxygen evolution in the E69Q mutant upon turnover of PS II is initiated by changes in the Mn cluster, possibly leading to Mn release from the water-splitting complex. The addition of exogenous Mn to E69Q thylakoids may help to keep the Mn cluster active for a longer time, perhaps by providing Mn to rebind in the cluster after release of one Mn and before the Mn cluster had disintegrated.(ABSTRACT TRUNCATED AT 250 WORDS)     

Oxidative damage to E. coli membranes caused by superoxide radicals]

The effects of bacterial membranes of active oxygen species photochemically generated by riboflavin-histidine systems were studied. According to SDS-PAAG data, the formation of high molecular weight protein aggregates and the appearance of fluorochromes whose fluorescence is seen in the longwave length region of the spectrum (lambda excit = 350 nm, lambda emis = 400-500 nm) and which are bound to the proteins, are suggestive of membrane oxidation consisting in the chemical modification of protein components. The presence in E. coli membranes of endogenous photosensitizers which upon illumination with visible light induce the oxidation of membrane proteins, was established.     

Isolation and characterization of a light-sensitive mutant of Escherichia coli K-12 with a mutation in a gene that is required for the biosynthesis of ubiquinone.

Cells with a novel mutation that is lethal when the cells are exposed to visible light were isolated from Escherichia coli K-12. The mutation was mapped at 63 min on the linkage map of the E. coli chromosome, and the gene, designated visB, was cloned and sequenced. From its map position and the evidence that the gene product VisB exhibits homology with flavin monooxygenase of Pseudomonas fluorescens, the visB gene was deduced to be identical to the ubiH gene, which is a gene required for the biosynthesis of ubiquinone and is thought to be similar to the gene for flavin monooxygenase. The photosensitive phenotype appears to be due to the accumulation of the substrate for the reaction catalyzed by the visB (ubiH) gene product because other mutations that block earlier steps in the biosynthesis of ubiquinone can reverse the photosensitivity. The accumulated intermediates may produce active species of oxygen in the mutant bacteria upon illumination by visible light, and these active oxygen species may cause the death of the cells by a mechanism similar to that associated with mutations in visA (hemH).     

Active oxygen produced during selective excitation of photosystem I is damaging not only to photosystem I, but also to photosystem II

With the aim to specifically study the molecular mechanisms behind photoinhibition of photosystem I, stacked spinach (Spinacia oleracea) thylakoids were irradiated at 4 degrees C with far-red light (>715 nm) exciting photosystem I, but not photosystem II. Selective excitation of photosystem I by far-red light for 130 min resulted in a 40% inactivation of photosystem I. It is surprising that this treatment also caused up to 90% damage to photosystem II. This suggests that active oxygen produced at the reducing side of photosystem I is highly damaging to photosystem II. Only a small pool of the D1-protein was degraded. However, most of the D1-protein was modified to a slightly higher molecular mass, indicative of a damage-induced conformational change. The far-red illumination was also performed using destacked and randomized thylakoids in which the distance between the photosystems is shorter. Upon 130 min of illumination, photosystem I showed an approximate 40% inactivation as in stacked thylakoids. In contrast, photosystem II only showed 40% inactivation in destacked and randomized thylakoids, less than one-half of the inactivation observed using stacked thylakoids. In accordance with this, photosystem II, but not photosystem I is more protected from photoinhibition in destacked thylakoids. Addition of active oxygen scavengers during the far-red photosystem I illumination demonstrated superoxide to be a major cause of damage to photosystem I, whereas photosystem II was damaged mainly by superoxide and hydrogen peroxide.     

Effect of membrane fluidity on photosynthetic oxygen production reactions

The effect of changes of membrane fluidity on the oxygen evolving capability of isolated thylakoids was investigated. Alteration of the lipid phase fluidity was achieved by incorporation of the plant sterol stigmasterol. Incorporation of stigmasterol in the lipid bilayer of thylakoid membranes results in rigidization of the hydrophobic phase of thylakoid membranes and decreases the degree of packing of the lipid head groups. These changes of lipid order are accompanied by a reduction of oxygen evolution, measured with 1,4-benzoquinone as an electron acceptor, and by a more pronounced inhibition of PSI-mediated electron transport. By analysis of the parameters of oxygen flash yields and oxygen burst under continuous illumination it was shown that after treatment with stigmasterol: 1.) the number of active oxygen-evolving centres decreased; 2.) the remaining active oxygen-evolving centres were not affected in respect to the oscillation pattern; 3.) the contribution of the slow oxygen-evolving centres in oxygen burst yield was increased. The effect of stigmasterol was compared with the well-studied effect of cholesterol. Results were discussed in terms of determining the role of lipid order for the organization and functioning of the photosynthetic machinery.     

A comparative analysis of phenothiazinium salts for the photosensitisation of murine fibrosarcoma (RIF-1) cells in vitro.

Photodynamic therapy (PDT) is a treatment combining a photosensitiser, molecular oxygen and visible light of characteristic wavelength to produce cytotoxic reactive oxygen species (ROS). Within our centre, a series of phenothiazinium salts were synthesised and initial characterisation studies performed to determine any potential use for PDT. All photosensitisers within the series were shown to have useful spectral properties for PDT, with absorbance lambdamax above 667 nm. The Log P values of the compounds were shown to range from -0.9 to > +2.0. Furthermore, Log P values were shown to be important in determining the site of subcellular localisation and as such the site of photooxidative damage. Derivatives with a Log P value of greater than +1.0 were shown to initially localise to the lysosomes then relocalise throughout the cytoplasm following illumination, whereas compounds with intermediate Log P values (-0.7 to +1.0) all remained lysosomal. Only methylene blue (Log P-0.9) was shown to redistribute to the nucleus upon illumination. Following treatment of RIF-1 cells with each phenothiazinium salt for 1 h and subsequent exposure to 665 nm laser light at a fluence rate of 10 mW cm(-2)(18 J cm(-2)), it was determined that the most potent photosensitiser was 260-fold more potent than methylene blue. Furthermore, the PDT efficacy of the photosensitisers was shown to be related to the level of mitochondrial damage induced directly following illumination.     

Singlet oxygen damages the function of Photosystem II in isolated thylakoids and in the green alga Chlorella sorokiniana

Photosynthesis Research - Singlet oxygen (1O2) is an important damaging agent, which is produced during illumination by the interaction of the triplet excited state pigment molecules with molecular...     

Changes in direct current input resistance in horizontal cells of fish retina during excitation

The input resistance of pike retinal horizontal cells was measured by means of coaxial electrodes under various conditions of illumination. With moderate intensities of illumination, the resistance (determined from a potential drop caused by the current passed through the microelectrode) increases, whereas at high saturating intensities it decreases, as compared with its value in darkness. Such changes in resistance of the horizontal cells explain the effects of input signals interaction in these cells, such as enhancement and complete saturation, observed earlier. Some properties of the horizontal cell response permit us to assume that the "active" cell response to polarization makes a substantial contribution to the measured resistance of these cells. Possible mechanisms of such changes in input resistance of horizontal cells are discussed.Institute of Problems in Information Transmission, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 3, No. 2, pp. 210–216, March–April, 1971.     

Generation of reactive oxygen species upon strong visible light irradiation of isolated phycobilisomes from Synechocystis PCC 6803

The mechanism of photodegradation of antenna system in cyanobacteria was investigated using spin trapping ESR spectroscopy, SDS-PAGE and HPLC-MS. Exposure of isolated intact phycobilisomes to illumination with strong white light (3500 micromol m(-2) s(-1) photosynthetically active radiation) gave rise to the formation of free radicals, which subsequently led to specific protein degradation as a consequence of reactive oxygen species-induced cleavage of the polypeptide backbone. The use of specific scavengers demonstrated an initial formation of both singlet oxygen (1O2) and superoxide (O2(-)), most likely after direct reaction of molecular oxygen with the triplet state of phycobiliproteins, generated from intersystem crossing of the excited singlet state. In a second phase carbon-based radicals, detected through the appearance of DMPO-R adducts, were produced either via O2(-) or by direct 1O2 attack on amino acid moieties. Thus photo-induced degradation of intact phycobilisomes in cyanobacteria occurs through a complex process with two independent routes leading to protein damage: one involving superoxide and the other singlet oxygen. This is in contrast to the mechanism found in plants, where damage to the light-harvesting complex proteins has been shown to be mediated entirely by 1O2 generation.     

Effects of oxygen and photosynthesis carbon cycle reactions on kinetics of P700 redox transients in cyanobacterium <Emphasis Type="Italic">Arthrospira platensis</Emphasis> cells

Effects of oxygen and photosynthesis and respiration inhibitors on the electron transport in photosystem I (PSI) of the cyanobacterium Arthrospira platensis cells were studied. Redox transients of P700 were induced by illumination at 730 nm and monitored as kinetics of the absorption changes at 810 nm; to block electron influx from PSII, the measurements were performed in the presence of 30 microM 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU). Inhibitors of terminal oxidases (potassium cyanide and pentachlorophenol) insignificantly influenced the fast oxidation of P700 under aerobic conditions, whereas removal of oxygen significantly decelerated the accumulation of P700(+). In the absence of oxygen the slow oxidation of P700 observed on the first illumination was accelerated on each subsequent illumination, suggesting an activation of the carbon cycle enzymes. Under the same conditions, pentachlorophenol (an uncoupler) markedly accelerated the P700 photooxidation. Under anaerobic conditions, potassium cyanide (an inhibitor of carbon dioxide assimilation) failed to influence the kinetics of redox transients of P700, whereas iodoacetamide (an inhibitor of NADP(H)-glyceraldehyde-3-phosphate dehydrogenase) completely prevented the photooxidation of P700. Thus, the fast photooxidation of P700 in the A. platensis cells under aerobic conditions in the presence of DCMU was caused by electron transport from PSI onto oxygen, and complicated transient changes in the P700 photooxidation kinetics under anaerobic conditions (in the presence of DCMU) were due to involvement of NADP+ generated during the reducing phase of the carbon cycle.     

Light-induced dynamic changes of NADPH fluorescence in Synechocystis PCC 6803 and its ndhB-defective mutant M55

Blue-green fluorescence emission of intact cells of Synechocystis PCC6803 and of its ndhB-defective mutant M55 was measured with a standard pulse-amplitude-modulation chlorophyll fluorometer equipped with a new type of emitter-detector unit featuring pulse-modulated UV-A measuring light and a photomultiplier detector. A special illumination program of repetitive saturating light pulses with intermittent dark periods (10 s light, 40 s dark) was applied to elicit dynamic fluorescence changes under conditions of quasi-stationary illumination. The observed effects of artificial electron acceptors and inhibitors on the responses of wild-type and mutant M55 cells lead to the conclusion that changes of NAD(P)H fluorescence are measured. In control samples, a rapid phase of light-driven NADP reduction is overlapped by a somewhat slower phase of NADPH oxidation which is suppressed by iodoacetic acid and, hence, appears to reflect NADPH oxidation by the Calvin cycle. Mercury chloride transforms the light-driven positive response into a negative one, suggesting that inhibition of NADP reduction at the acceptor side of PSI leads to reduction of molecular oxygen, with the hydrogen peroxide formed (via superoxide) causing rapid oxidation of NADPH. The new fluorescence approach opens the way for new insights into the complex interactions between photosynthetic and respiratory pathways in cyanobacteria.     

Influence of light on the apoplastic ph in microwounded cells of <Emphasis Type="Italic">Chara corallina</Emphasis>

Microscopic wounding of plant cell walls by pathogens or by feeding insects triggers the defense responses, including a sharp rise in pH at the cell surface (pH_o). Using internodal cells of Chara corallina Klein ex Willd., we show here that the elevated pH_o in the area of cell wall microincision decreases in darkness and increases on illumination. These pH_o changes occurred specifically in cell areas affected by microincision and were lacking in intact areas with active pHotosynthesis (acid zones). Localized illumination of a remote cell region located upstream the cytoplasmic flow at a 1.5-mm distance from the analyzed area also caused a transient increase in pH_o in the area of microwounding but had no such effect in unwounded cell regions having weakly acidic pH_o. Apparently, the increase in pH_o after wounding is mediated by a metabolite released from illuminated chloroplasts, which is transported with the cytoplasmic flow for long distances. The transient pH_o increase in the area of cell wall incision after illumination of a distant cell region coincided with a temporal increase in chlorophyll fluorescence F’. This implies the concurrent influence of the transported reductant (presumably NADH) on light emission of chloroplasts and on the H⁺ flow across the plasmalemma. We suppose that the alkalinization of cell surface in the area of microincision arises from H⁺ consumption in the apoplast in association with the transmembrane electron transport from cytoplasmic reducing equivalents to molecular oxygen.     

Effects of superoxide anions on red cell deformability and membrane proteins.

The effect of superoxide anions (O2-) on red blood cells (RBC) deformability and membrane proteins was investigated using hypoxanthine-xanthine oxidase system. Exposure of RBC to O2- caused a marked decrease in RBC deformability with a concomitant increase in cell volume and shape changes. The RBC exposed to O2- also displayed pronounced degradation of membrane proteins such as band 3 protein and spectrin; new bands of low molecular weight products appeared as the original membrane proteins tended to diminish, without the appearance of high molecular weight products. Since the membrane proteins are involved in processes regulating membrane properties such as permeability and viscoelasticity, the decreased deformability induced by O2- may be attributable to changes in membrane proteins. Interestingly, resealed ghosts exposed to O2- did not show any significant change in membrane proteins, which suggests the existence of further generation of O2- and subsequent production of other active oxygen species mediated by O2(-)-initiated autoxidation of hemoglobin in intact RBC. Furthermore, electrophoretic analysis suggested that active oxygens increased the endogenous proteolytic susceptibility of RBC. In conclusion, a close linkage was suggested between RBC deformability and the membrane proteins.     

Role of reactive oxygen species and Cr(VI) in Ras-mediated signal transduction

Previous studies have shown that a constitutively active isoform of Ras is able to produce superoxide radical (O2(-)). The present study investigate the mechanisms by which O2(-) radical mediates signals from Ras protein to the nucleus, leading to cellular responses such as apoptosis in Cr(VI)-stimulated cells. Two human prostate tumor cell lines, Ras(+), which overexpresses Ras, and Ras(-), which has a normal Ras level, were utilized. Compared to Ras(-) cells, Ras(+) cells exhibited higher susceptibility to apoptosis induced by Cr(VI). Catalase, sodium formate, and deferoxamine inhibited Cr(VI)-induced apoptosis. Similar differences were observed in both cellular DNA damage and the activation of p53 protein. The differences in Cr(VI)-induced cell responses in Ras(+) and Ras(-) cells were due to differences in the generation of free radicals between these two cells. ESR spin trapping measurements showed that Ras(+) cells generated more hydroxyl radical ((.)OH), O2(-) radical, and Cr(V) than Ras(-) cells following Cr(VI) stimulation. The generation of the reactive oxygen species (ROS) can be abolished by the addition of superoxide dismutase (SOD) or if the experiment were carried out in an argon atmosphere. Catalase inhibited spin adduct signals but was much less potent than SOD. The mechanism of ROS generation in Cr(VI)-stimulated Ras(+) cells involves the reduction of molecular oxygen to O2(-) radical by a flavoenzyme-containing NADPH oxidase complex as shown by oxygen consumption and diphenylene iodonium (DPI) inhibition. Results shown above support the following conclusions: (a) Ras protein mediates O2(-) radical generation through reduction of molecular oxygen by NADPH oxidase in Cr(VI)-stimulated cells. (b) The O2(-) radical and Cr(VI) produce other reactive species, including H2O2, OH radical, and Cr(V) through O2(-) dismutation and Haber-Weiss type of reactions. (c) Among these reactive species, (.)OH radical is responsible for the further transduction of signals from Ras to the nucleus, leading to various cell responses.     

Light-dependent pH changes in leaves of C4 plants Comparison of the pH response to carbon dioxide and oxygen with that of C3 plants

Cytosolic and vacuolar pH changes caused by illumination or a changed composition of the gas phase were monitored in leaves of the NAD malic-enzyme-type C₄ plant Amaranthus caudatus L. and the C₃ plant Vicia faba L. by recording changes in the fluorescence of pH-indicating dyes which had been fed to the leaves. Light-dependent cytosolic alkalization and vacuolar acidification were maximal in the mesophyll cells under high-fluence-rate illumination and in the absence of CO₂. Under the same conditions, measurements of light scattering and electrochromic absorption changes at 518 nm revealed maximum thylakoid energization. The results show an intimate relationship between the energization of the photosynthetic apparatus by light, an increase in cytosolic pH and a decrease in vacuolar pH. This was true for both the C₄ and the C₃ plant, although kinetics, extent and even direction of cytosolic pH changes differed considerably in these plants, reflecting the differences in photosynthetic carbon metabolism. Darkening produced rapid acidification in Vicia, but not in Amaranthus. Continued alkalization in Amaranthus is interpreted to be the result of the decarboxylation of a C₄ intermediate and the release of liberated CO₂. In the presence of CO₂, energy consumption by carbon reduction decreased thylakoid energization, cytosolic alkalization and vacuolar acidification. Under low-fluence-rate illumination, thylakoid energization and light-dependent cytosolic and vacuolar pH changes were decreased in CO₂-free air compared with thylakoid energization and pH changes in 1% oxygen/99% nitrogen not only in the C₃ plant, but also in Amaranthus. Since oxygenation of ribulose bisphosphate initiates energy-consuming photorespiratory reactions in 21% oxygen, but not in 1% oxygen, this shows that photorespiratory reactions are active not only in the C₃ but also in the C₄ plant in the absence of external CO₂. Photorespiratory conditions appeared to decrease energization not only in the chloroplasts, but also in the cytosol. This is indicated by decreased transfer of protons from the cytosol into the vacuole, a process which is energy-dependent.Abbreviations CDCF 5-(and 6-)carboxy-2,7-dichlorofluorescein - P₇₀₀ electron-donor pigment in the reaction center of photosystem I - RuBP ribulose-1,5-bisphosphate This work was supported, within the framework of the Sonderforschungsbereiche 176 and 251 of the University of Würzburg, by the Gottfried-Wilhelm-Leibniz Program of the Deutsche Forschungsgemeinschaft. A.S.R. was the recipient of a fellowship from the Alexander-von-Humboldt-Foundation. We are grateful to Mr. Carsten Werner and Mrs. Spidola Neimanis for cooperation.     

Light-induced changes of bioelectric potential in Chara

Experiments were performed on light-induced changes of the restingpotential in Chara under various conditions. In the dark-adaptedcells, a slow increase in resting potential, by about 60 mv,appeared in a solution containing 0.5 mM KCl, 0.2 mM NaCl and0.5 mM CaCl₂. On the contrary, a rapid decrease preceded bya small, sharp rise in potential was produced when the cellsbecame adapted to light. On the first illumination, the cellmembrane resistance decreased in dark-adapted cells, but a slightincrease was observed every time on subsequent illuminations.No parallel relation was found between the time course of thechanges of resistance and the potential difference. During severalilluminations, as well as during the short dark periods betweenthem, cells lost their sensitivity to change in a potassiumconcentration. The time courses of photosynthetic oxygen evolutionwere not in accordance with those of changes in the potential.However, 10µM 3-(3,4-dichlorophenyl)-l, l-dimethylureareversibly abolished both the oxygen evolution and the changesin potential. An enhancement of the photoelectric response wasobserved when bicarbonate ions were added in the external solution.On the other hand, the oxygen evolution was not affected bythe bicarbonate ions. On the basis of these observations itwas assumed that some assimilation products of photosynthesiswere responsible for the photoelectric response. (Received February 13, 1968; )     

Changes in Intensity and Spectral Distribution of Fluorescence: Effect of Light Treatment on Normal and DCMU*-Poisoned Anacystis nidulans‡

The intensity of the "steady-state" fluorescence of "aerobic" Anacystis nidulans is variable under prolonged illumination with orange (590 mmu) or blue (440 mmu) light for both normally photosynthesizing and DCMU-poisoned cells. In general, orange light illumination causes an increase of the fluorescence intensity followed by a decrease, while blue light causes an increase until a steady level is reached. Poisoned Anacystis cells show four to eight times larger changes in fluorescence intensity than the normal cells; the detailed time course of fluorescence changes is also different in poisoned and normal cells. When algae are cooled to -196 degrees C in light, the light-induced changes in the "steady-state" fluorescence disappear in both types of cells. Difference fluorescence spectra, constructed by subtracting the fluorescence spectra taken after 5-15 min of illumination from those after 60-90 min of illumination, show a doublet structure of the difference band with a major peak coinciding with the Anacystis emission maximum (685 mmu) and a minor peak located at about 693 mmu.     

Primary Events, Energy Transfer, and Reactions in Photosynthetic Units: 3-(3,4-Dichlorophenyl)-1,1-dimethylurea (DCMU) Inhibition of System II and Light-Induced Regulatory Changes in Energy Transfer Efficiency

Oxygen pulses produced in Chlorella by a xenon flash of 15 μsec half-width were measured by means of a rapid oxygen polarograph. Under appropriate conditions the height of the pulse caused by a saturating flash was a measure of the number of active reaction centers in system II. In pigment state II, caused by illumination during several minutes with light II, the number of active centers II was the same as in pigment state I. Oxygen pulses produced by about half-saturating flashes were diminished by about 7-10% in state II, showing that the fluorescence decrease in light II was at least partly caused by a decrease in energy transfer to reaction center II. After addition of 3(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU), only the first flash produced oxygen which gives additional support for the hypothesis that DCMU inhibits between Q and system I.