Relationships among the three light-induced absorbance changes related to the reaction-center of photosystem II

The relationships among X₅₉₁, Cyt-b₅₅₉ and C-550 in the primaryphotoact of PS-II were analysed by examining the effects ofvarious inhibitory substances and treatments on the light-inducedabsorbance changes of these components. The results were fully explainable by the scheme previouslypresented by Huzisige, in which two photoreactions are involvedin PS-II. Our conclusion is that X₅₉₁ acts as the electron acceptorfor one of the photoreactions in PS-II. (Received October 23, 1978; )     

Analysis of photosystem II using particle II preparation. I. Experimental evidence supporting the idea of the involvement of two light reactions in photosystem II of green plant photosynthesis

(1) To analyze the photoelectron flow related to photosystemII, particle II preparation, i.e., the chloroplast fragmenthaving only photosystem II activity, proved to be far betterthan the generally used chloroplast preparations having activitiesof both PS-I and PS-II. (2) By simultaneous measurements ofthe activities of O₂ evolution and DPIP- and ferricyanide photoreductionusing variously-treated particle II preparations, it was foundthat a noticeable activity of ferricyanide photoreduction wasstill observed, though the former two activities were completelylost in the course of treatments such as Tris-treatment, pre-illuminationand aging. (3) Besides this, differences were found betweenferricyanide- and DPIP-photoreduction in respect to susceptibilityto CCCP, availability of artificial electron donor, and theeffect of chloride addition. However, both photo-reductionswere equally inactivated by heat-treatment and addition of DCMU.(4) To explain the observed distinctions between DPIP and ferricyanidein their mode of action as electron acceptor for PS-II, a schemesuggesting the involvement of two light reactions in PS-II isproposed and the electron flow near PS-II is discussed. ¹ This work has been supported by Grants from the Ministry ofEducation (Nos. 8425- 70-'71; 4970l4-'69-'71), which are gratefullyacknowledged here. (Received January 12, 1972; )     

Studies on cytochromes in photosynthetic electron transport system I. photoreduction and photo-oxidation of cytochrome b559 by photosystem II in spinach chloroplasts

Light-induced redox-reactions of cytochrome b₅₅₉ in spinachchloroplasts were investigated. Illumination of chloroplastsinduced photoreduction of cytochrorne b₅₅₉ Red light (650 nm)was more effective than far-red light (725 nm), indicating thatthe photoreduction is a photosystem II-mediated reaction. Onaddition of DCMU, the photoreduction was eliminated and a photooxidationof cytochrome b₅₅₉ was observed. The rate of this photooxidationwas faster with photosystem II light than with photo-systemI light. On addition of Mn⁺⁺ the photooxidation was partly suppressed;far-red light became as effective as red light in inducing photooxidationof cytochrome b₅₉₉, in the presence of DCMU and Mn⁺⁺. Ascorbate completely suppressed photooxidation of cytochromeb⁵⁵⁹ In the presence of ascorbate, however, photooxidation wasobserved in the presence of inhibitors or after inhibitory treatmentsof chloroplasts which affected the oxidizing side of systemII. These inhibitors and inhibitory treatments, but not DCMU,decreased the redoxpotential of cytochrome b₅₅₉. Reactivationof Hill reaction in Tris-washed chloroplasts by indophenol-ascorbatetreatment was not accompanied by an abolishment of photooxidationof cytochrome b₅₅₉. A possible mechanism is proposed to account for these reactionsof cytochrome b₅₅₉ in the photosynthetic electron transportin chloroplasts. (Received April 4, 1972; )     

Nature of light-induced absorbance changes at 682 m{micro} and 702 m{micro} in photosynthesis of Anacystis nidulans

Light-induced absorbance changes in the region around the redabsorption band of chlorophyll a were measured in cells andlamella fragments of Anacystis nidulans. In both materials,absorbance decreases were observed at 702 mµ and 682 mµ.(The pigments are designated as P₇₀₀ and P₆₈₀.) The nature ofP₆₈₀ was investigated with special reference to its relationshipto P₇₀₀. In the cells, light absorbed by chlorophyll a causedan absorbance decrease at 682 mµ; Simultaneous illuminationwith light absorbed by phycocyanin caused a partial recoveryof the absorbance decrease. Similar results were observed withthe light-induced absorbance change at 702 mµ. This indicatesthat P₆₈₀ is also an electron carrier in the electron transportchain and occupies a place between the two photoreactions. Inlamella fragments, both the light-induced reversible absorbancechanges of P₆₈₀ and P₇₀₀ appeared in the presence of an electrondonor system; i.e., ascorbate and 2,6-dichlorophenolindophenolor N,N,N',N'-tetramethyl-l,4-phenylenediamine. The experimentsin which the oxidation-reduction potential of the reaction mediumwas changed showed that both P₆₈₀ and P₇₀₀ are one-electroncarriers, having a normal oxidation-reduction potential of 0.44v (assuming that the normal oxidation-reduction potential ofthe ferricyanide-ferrocyanide system is 0.409 v). A possibilitywas suggested that the absorbance change observed at 682 mµis another expression of the oxidation-reduction reaction ofP₇₀₀). (Received October 30, 1968; )     

Flavine nucleotide nitrate reductase from broad bean leaves

Hydrosulfite-reduced FMN served as an electron donor for nitratereductase purified from broad bean leaves. FMN was successfullyreplaced with BV. The flavine nucleotide nitrate reductase hadits pH optima at about 7.8 with phosphate buffer and at about7.4 with Tris-HCl buffer. The Km's for nitrate and FMN were3.7 ? 10^–4 M and 3.7 ? 10^–5 M, respectively. NADH₂: nitrate reductase activity was completely inhibited by0.1 mM p-CMB, whereas FMNH₂: nitrate reductase activity wasnot. Inhibited activity was restored by the addition of cysteine.A sulfhydryl enzyme is involved in the NADH₂: nitrate reductasesystem but not in the FMNH₂ : nitrate reductase system. NADH₂and FMNH₂ probably feed electrons into the electron transportchain at different sites. The nitrate reductase preparationhad an NADH₂-specific diaphorase activity which was almost completelyinhibited by 0.1 mM p-CMB. The NADH₂-specific diaphorase mayform the sulfhydryl enzyme which mediates electron transferbetween NADH₂ and nitrate. (Received May 6, 1969; )     

Effects of CaCl2-washing on EPR Signals of Cytochrome b559 in Photosystem II Preparation from Spinach Chloroplasts

Washing of PS II preparation by 1 M CaCl₂ inactivates oxygenevolution without loss of bound manganese [Ono and Inoue (1983)FEBS Lett. 164: 255]. Most of the high-potential Cyt b₅₅₀, whichamounts to about a half of the total Cyt b₅₅₉ in untreated preparation,was converted to its low-potential form by CaCl₂-washing. Theeffect was similar to that of Tris-washing. The peak positionof the g_s band of the EPR spectrum of the CaCl₂-washed preparation(g=2.95) was the same as that of the low potential form of untreatedpreparation but was slightly different from that of the Tris-washedor heat-treated preparation (g=2.98). ¹ Present address: Department of Biology, Faculty of Science,Tokyo Metropolitan University, Fukazawa 2-1-1, Setagaya, Tokyo158, Japan. (Received November 14, 1984; Accepted January 30, 1985)     

The light-induced oxidation-reduction reaction of cytochrome b-559 in membrane fragments of the blue-green alga Anabaena variabilis

Light-induced oxidation-reduction reactions of cytochrome b-559were investigated with membrane fragments of Anabaena variabilisand supplementarily with Plectonema boryanum. The oxidation-reduction reactions of cytochrome b-559 observedwith membrane fragments were similar in their kinetics to thoseof the cytochrome in aged chloroplasts. The reactions were annihilatedby the addition of Ferro, indicating that the cytochrome ofhigh redox potential (E'_o=+373 mV, pH 6.5) was photoreducedand oxidized. Titration with reducing agents indicated that cytochrome b-559is contained in Anabaena membrane fragments in an amount 1.5times as much as the content of P700 on a molar basis; the contentof the species of high redox potential was estimated to be around70%. Kinetic treatment of the photoreduction indicated that the cytochromewas reduced at some site of the electron transport system betweenthe two photosystems. The photo-oxidation depended on the actionof either photosystem II or I even in the presence of DCMU,indicating that the photooxidation was induced by both photosystems.The oxidation by photosystem I action was inhibited by HgCl₂-treatment,indicating that this reaction is mediated by plastocyanin. EDTA (5?10^-3 M) suppressed the cytochrome photoreduction andenhanced the rapid phase of the photooxidation. The latter effectappeared only when an appropriate dark time (3 min) was insertedafter the cytochrome photoreduction. The phenomenon was interpretedas showing that EDTA modifies the reactivity of the electroncarrier which directly donates electrons to cytochrome b-559.The oxidation, and probably also the reduction of cytochromeb-559, was assumed to be regulated by the oxidation-reductionstate of this carrier. (Received April 26, 1974; )     

On two photoreactions in System II of plant photosynthesis

Light-induced absorbance changes of cytochrome b₅₅₉ and C₅₅₀ in chloroplasts indicate that noncyclic electron transport from water to ferredoxin (Fd)-NADP⁺ is carried out solely by System II and includes not one but two photoreactions (IIa and IIb) that proceed effectively only in short-wavelength light. (C₅₅₀ is a new chloroplast component identified by spectral evidence and distinct from cytochromes.) The evidence suggests that the two short-wavelength light reactions operate in series, being joined by a System II chain of electron carriers that includes (but is not limited to) C₅₅₀, cytochrome b₅₅₉, and plastocyanin (PC).

H₂O → IIb_hv → C₅₅₀ → cyt. b₅₅₉ → PC → IIa_hv → Fd → NADP⁺

Photoreaction IIb involves an electron transfer from water to C₅₅₀ that does not require plastocyanin and is the first known System II photoreaction resistant to inhibition by 3-(3,4-dichlorophenyl)-1,1-dimethyl urea (DCMU) and o-phenanthroline. Cytochrome b₅₅₉ is reduced by C₅₅₀ in a reaction that is readily inhibited by DCMU or o-phenanthroline. Thus, the site of DCMU (and o-phenanthroline) inhibition of System II appears to lie between C₅₅₀ and cytochrome b₅₅₉. Photoreaction IIa involves an electron transfer from cytochrome b₅₅₉ and plastocyanin to ferredoxin-NADP⁺.     

Correlated behavior of the EPR signal of cytochrome b-559 heme Fe(III) ligated by OH− and the multiline signal of the Mn cluster in PS-II membrane fragments

EPR signals of Cyt b-559 heme Fe(III) ligated by OH⁻ and the multiline signal of the Mn cluster in PS-II membrane fragments have been investigated. In 2,3-dicyano-5,6-dichloro-p-benzoquinone-oxidized PS-II membrane fragments the light-induced decrease of the EPR signal of the heme Fe(III)-OH⁻ is accompanied by the appearance of the EPR multiline signal of the Mn cluster. Addition of F⁻ ions, which act as a stronger ligand for heme Fe(III) than OH⁻, decreases to the same extent the dark- and light-induced signal of the heme Fe(III)-OH⁻ and the light-induced multiline signal of the Mn cluster. These results are discussed in terms of the light-induced formation of a bound OH′ radical shared between the Cyt b-559 heme Fe and the Mn cluster as a first step of water oxidation.     

Artificial Quinones Replace the Function of Quinone Electron Acceptor (QA) in the Isolated D1-D2-Cytochrome b559 Photosystem II Reaction Center Complex

Various benzo- and naphthoquinone derivatives were introducedinto the purified photosystem II Dl-D2-cytochrome b₅₅₉ reactioncenter complex, which lacks the intrinsic plasto-quinone electronacceptors. Effects of these quinones on the electron transferreactions in nanoseconds to milliseconds time range were studiedat room and cryogenic temperatures. 1) The addition of quinonesto the purified photosystem II reaction center complex suppressedthe nanosecond charge recombination between oxidized reactioncenter chlorophyll a (P680⁺) and reduced pheophytin a (Ph^–),and stabilized P680⁺ up to millisecond time range at 280 K andat 77 K. 2) In the reaction center complex supplemented withdibromothymoquinone (DBMIB), P68O was almost fully oxidizedand cytochrome b₅₅₉ was partially reduced by flash excitation.A semi-quinone-like signal with a peak around 320 nm was alsoinduced but the shift of pheophytin absorption band (C55O) wasnot observed. 3) Halogenated quinones, especially DBMIB, werebetter electron acceptors than unsubstituted or methylated quinones.4) The affinities of quinones to the reaction center complexwere weakly dependent on their molecular structure. (Received July 9, 1991; Accepted August 15, 1991)     

Effects of Light Stress on Redox Potential Forms of Cyt b-559 in Photosystem II Membranes Depleted of Water-Oxidizing Complex

Effects of photoinhibition on the redox properties of Cyt b-559were studied with NH₂OH treated PSII membranes, which are depletedof the water-oxidizing complex. The membranes contained threeredox forms (HP-, IP- and LP-forms) of Cyt b-559, with E_m valuesof +435, +237 and +45 mV, respectively. A novel intermediate-potentialform of Cyt b-559 was generated during photoinhibition on thedonor side of PSII: photoinhibitory illumination (7,000 µEm^–2 s^–1) for 1 min induced a 30% decrease in thelevel of the HP-form, with concomitant generation of the intermediate-potential(IP-) form whose E_m value was about +350mV. Prolonged illumination(10 min) resulted in complete loss of the HP-form and an apparentincrease in the level of the IPform. After further photoinhibitorytreatment (60 min), complete loss of the IP'-form was observedand levels of the IP- and LP-forms each increased to about 50%of the total amount of Cyt b-559. Kinetic analysis of thesedata led to the conclusion that the HP-form is converted tothe LP-form via two intermediate-potential forms (IP' and IP),and that IP'-form appears only at the early phase of photoinhibition. (Received March 30, 1994; Accepted February 27, 1995)     

Anion-dependent changes of energy transfer in chloroplasts II. Relationships of the coupling factor to light-induced proton transport and absorbance change at 515 nm

Roles of the coupling factor in light-induced proton transportand 515-nm absorption change were investigated in chloroplastswashed with high concentrations of Tris salts (pH 7.2). Washingthe chloroplasts with Tris-HCl and Tris-HNO₃ buffers diminishedboth the light-induced pH rise and absorbance change at 515-nm,while Tris-H₂SO₄ buffer was much less effective. Inhibited activitiescould be restored by replacement of the coupling factor afterextraction with EDTA. N,N'-dicyclohexylcarbodiimide also restoredboth activities. Effects of various anions on the proton pumpand 515-nm shift were also investigated. The order of effectivenesswas NO₃^–>Cl^–>SO₄^2–. The role of thecoupling factor and its mode of action; the action mechanismsof Tris and anionsn energy transducing processes in chloroplasts,photophosphorylation, proton transport and absorbance changeat 515 nm, are discussed. ¹Present address: Biology Department, College of Science andEngineering, Ryukyu University, Naha, Okinawa, Japan. (Received June 27, 1972; )     

Photosynthetic Electron Transport under Phosphorylating Conditions as Influenced by Different Concentrations of Various Salts

Osman, M. E-A. H. and El-Shentenawy, F. 1988. Photosyntheticelectron transport under phosphorylating conditions as influencedby different concentrations of various salts.—J. exp.Bot. 39: 859–863. The rate of light-induced electron transport by isolated spinachthylakoids under phosphorylating conditions, as affected bydifferent concentrations of Br^–, Cl^–, NO₃^–,HCO₃^–, SO₄^2– and CO₃^2– has been investigated.The results show that both low and high concentrations of HCO₃^2–stimulated the oxygen evolution capacity under phosphorylatingconditions, whereas only low concentrations of CO₃^2–,SO₄^2– and Cl^– stimulated the oxygen evolution capacity.However, irrespective of concentration, both Br^– and NO₃^–reduced this capacity. The rate of photosynthetic electron transportwas generally stimulated by addition of ADP, even in cases whereelectron transport was inhibited by addition of bromide andnitrate. The different concentrations of these anions also causedreduction of the power generated by proton pumping and usedfor phosphorylation. The greatest level of reduction was observedin the presence of high concentrations of Cl^– and HCO₃^–. Key words: Spinach thylakoids, photosynthetic electron transport, phosphorylation     

Light-Induced H+ Accumulation in the Vacuole of Nitellopsis obtusa

The effects of light on the pH in the vacuole and the electricpotential difference across the plasmalemma and the tonoplastof Nitellopsis obtusa were investigated by means of conventionaland H⁺-specific glass or antimony microelectrodes. Illuminationis found to bring about a decrease in the pH of the vacuolarsap by 0.1–0.5 units concomitant with a depolarizationof the cell. The light-induced changes of the potential differenceand the vacuolar pH depend in different ways on the pH of theexternal medium (pH_o). At pH_o 9.0 cells exhibit great light-inducedpotential changes (up to 100 mV), but only small pH changesof the vacuolar sap. At neutral or slightly acidic pH_o valuesthe amplitude of the light-induced pH changes in the vacuoleincreases up to 0.3–0.5 pH units, but the amplitudes ofthe potential changes at the plasmalemma are relatively small.At pH_o 9.0 a transient acidification of the medium is observedupon illumination whereas at lower pH values light-induced alkalinizationwas only seen. Transfer of the cells from pH_o 9.0 to pH_o 7.5results in a cell hyperpolarization by 60–80 mV and adecrease of the vacuolar pH by 0.4–0.5 units under lightconditions but has no significant effect on the potential andthe vacuolar pH in the darkness. It is proposed that mechanismsof active H⁺ extrusion from the cytoplasm are located both inthe plasmalemma and the tonoplast. The observed acidificationin the vacuole appears to be determined by a light-induced increaseof the concentration of H⁺ in the cytoplasm. The H⁺ conductionof the plasmalemma seems to increase on illumination. The patternof the light-induced H⁺ fluxes across the tonoplast and theplasmalemma depends crucially on the extent of the light-inducedchanges in the H⁺ conductance and on the electrochemical gradientfor H⁺ at the plasmalemma.     

Energy conversion and changes in physical parameters in chloroplasts and subchloroplast particles II. Energy conversion in chloroplasts and different types of subchloroplast particles

The light-induced absorbance change at 515 nm, light-inducedhydrogen ion uptake and ATP formation were compared in chloroplastsand different types of sonicated subchloroplast particles. Noparallel relationship among the activities for ATP formation,hydrogen ion uptake and the 515-nm change was observed in differenttypes of preparations. NH₄Cl inhibited ATP formation in chloroplastsbut had little effect on subchloroplast particles. In contrast,the light-induced hydrogen ion uptake was inhibited by NH₄Clin a similar manner. Tetraphenylboron (TPB), at 1 µM, inhibited ATP formationby about 30% in both chloroplasts and subchloroplast particles.In the presence of TPB, ATP formation in chloroplasts was stronglyinhibited by NHC₄Cl, but in subchloroplast particles the additionalinhibitory effect of NH₄Cl was small. A synergistic inhibitionof photophosphorylation by valinomycin plus NH₄Cl was much clearer.Although acceleration of the recovery of the 515-nm change byNH₄Cl or valinomycin was moderate, the 515-nm change virtuallydisappeared when NH₄Cl and valinomycin were added simultaneously. Although the membrane potential has a major role as the principaldriving force for ATP formation in subchloroplast particles,the simultaneous abolishment of the pH gradient and membranepotential may be required to uncouple ATP formation. ¹Present address: Fukuoka Women's University, Kasumigaoka, Fukuoka813, Japan. ²Present address: Ryukyu University, Naha, Okinawa 903, Japan. (Received February 5, 1974; )     

Contents of Cytochromes, Quinones and Reaction Centers of Photosystems I and II in a Cyanobacterium Synechococcus sp.

The contents of photosystem I and photosystem II reaction centers,cytochrome c-553, cytochrome c-550, cytochrome f, cytochromeb-559, cytochrome b-563, plastoquinone and vitamin K₁ in thecyanobacterium Synechococcus sp. were determined. About threephotosystem I reaction centers were present for each photosystemII reaction center. The amounts of cytochromes functioning betweenthe two photosystems were approximately half those of the photosystemI reaction center. Plastocyanin was not detected, while plastoquinoneand vitamin K₁ were present in excess of other electron carriersand reaction centers. The results indicate the importance ofplastoquinone and cytochrome c-553 for cooperation of the tworeaction centers through electron transport. ¹Present address: Toray Basic Research Laboratory, 1111 Tebiro,Kamakura, Kanagawa 248, Japan. (Received June 17, 1982; Accepted January 17, 1983)     

Electron Transport Reactions in Grana Preparations from Spinach Chloroplasts

Fraction 2 (grana-stack) particles prepared with the French press showed absorbance changes, at room temperature and with sodium ascorbate and methyl-viologen, that were produced by the oxidation of cytochrome b-559. This oxidation was inhibited by 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) and sensitized by system II of photosynthesis. The oxidation is too slow to account for the rates of the Hill reaction that have been observed with nicotinamide-adenine dinucleotide phosphate (NADP⁺). It appears that this cytochrome is not functioning in the main pathway of electron transport. In the presence of 2,3,5,6-tetramethyl-p-phenylene-diamine (DAD) and ascorbate, light-induced oxidation of cytochrome f took place within 3 msec (or faster) in the grana-stack particles. Treatment with the detergent Triton X-100 disrupted this rapid cytochrome f oxidation as well as the oxidation of cytochrome b-559. Subsequent plastocyanin addition did not restore the rapid oxidation of cytochrome f (nor of cytochrome b-559) but only slow changes of cytochrome f. In view of the fact that these particles contain almost no plastocyanin, it is unlikely that plastocyanin functions in electron transport between cytochrome f and P-700 in the particles derived from the grana-stack regions of the chloroplast.     

Dibromothymoquinone (DBMIB) Replaces the Function of QA at 77 K in the Isolated Photosystem II Reaction Center (D1-D2-Cytochrome b559) Complex: Difference Spectrum of the P680+(DBMIB-) State

Transient absorbance changes of the primary electron donor chlorophylla (P680) and acceptor pheophytin a (H) were measured at 77 Kby nanosecond laser spectroscopy in the D1-D2-cytochrome b₅₅₉photosystem II reaction center complex containing dibromomethylisopropylbenzoquinone (DBMIB). After the laser excitation of the reactioncenter in the presence of DBMIB, only the P680⁺-(DBMIB^-) statewas detected. P680⁺ mainly decayed with a t_1/e of 11 ms. Inthe absence of DBMIB, the excitation produced the P680⁺H^- radicalpair. The radical pair produced the triplet state (P680^T) witha t_1/e of 50 ns, and P680^T then decayed with a t_1/e of 2.1 ms.It was concluded that H_- was oxidized by DBMIB in a time rangefaster than the detecting time resolution (3.5 ns) even at 77K. The rapid oxidation of H^- by DBMIB was also confirmed bythe suppression of delayed fluorescence with a decay t_1/e of50 ns. The P680⁺(DBMIB^-)/P680(DBMIB) difference spectrum exhibiteda Q_y, band with a peak at 682 nm with a shoulder at 673 nm.The spectral shape was almost temperature insensitive between77 and 265 K. The feature of this spectrum in the wavelengthrange between 330 and 720 nm was compared with that of P680_T/P680or H^-/H at 77 K. (Received May 8, 1996; Accepted June 24, 1996)     

Properties of Chlamydomonas Photosystem II Core Complex with a His-Tag at the C-Terminus of the D2 Protein

A His-tagged PSII core complex was purified from recombinantChlamydomonas reinhardtii D2-H thylakoids by single-step Ni²⁺-affinitycolumn chromatography and its properties were partially characterizedin terms of their PSII functions and chemical compositions.The PSII core complex that has a His-tag extension at the C-terminusof the D2 protein evolved oxygen at a high rate of 2,400 µmol(mg Chl)^–1h^–1 at the optimum pH of 6.5 with ferricyanideand 2,6-dichlorobenzoquinone as electron acceptors in the presenceof Ca²⁺ as an essential cofactor, and approximately 90% of theactivity was blocked by 10 µM DCMU. The core complex exhibitedthe thermoluminescence Q-band but not the B-band regardlessof the presence or absence of DCMU, although both bands wereobserved in the His-tagged thylakoids. The core complex wasfree from PSI and contained one Y_D, Tyr 160 of the D2 protein,four Mn atoms, two cytochrome b-559, about 46 Chl a molecules,and probably one Q_A, the primary acceptor quinone of PSII. Itwas inferred from these results that His-tagging at the C-terminusof the D2 protein does not affect the functional and structuralintegrity of the PSII core complex, and that the ‘His-tagstrategy’ is highly useful for biochemical, physicochemical,and structural studies of Chlamydomonas PSII. (Received October 22, 1998; Accepted December 25, 1998)     

Specific inhibition of photosystem II activity in chloroplasts by fumigation of spinach leaves with SO2

The phytotoxic effects of sulfur dioxide (SO₂) were investigatedby fumigating spinach plants with SO₂. Inhibition of 2,6-dichloroindophenol(DCIP) photoreduction was observed in spinach chloroplasts isolatedfrom fumigated leaves. NADP and DCIP photoreductions were inhibitedto a similar extent by fumigation with 2.0 ppm SO₂ but electronflow from reduced DCIP to NADP was not affected. When electronflow from H₂O to NADP was inhibited by 36%, a 39% inhibitionof non-cyclic photophosphorylation was observed. However, phenazinemethosulfate(PMS)-catalyzed cyclic photophosphorylation wasas active as in the control chloroplasts. Moreover, in the presenceof PMS, no significant suppression was observed in the extentof light-induced H⁺ uptake or in the rate of H⁺ efflux in chloroplasts.From these results, it can be concluded that SO₂ inhibits theelectron flow driven by photosystem II when plants have beenfumigated with SO₂. In spinach leaves fumigated with SO₂, the rate of photosyntheticO₂ evolution was reduced under light-limited conditions, whilethe rate of respiratory O₂ uptake changed slightly. (Received February 8, 1979; )