Fatty acid synthesis by spinach chloroplasts III. Relationship between fatty acid synthesis and photophosphorylation

The modes of actions of photosynthetic inhibitors on photosynthesisand fatty acid synthesis were examined. DCMU, an electron transport inhibitor, inhibited fatty acidsynthesis and photophosphorylation to the same extent, suggestingdependence of fatty acid synthesis on photosynthesis. The samewas also the case with FCCP, a photophosphorylation uncoupler.In contrast, NH₄Cl and phlorizin at concentrations completelysuppressing ATP formation, only partially inhibited the fattyacid synthesis. These facts suggest that a certain level ofhigh-energy intermediate (state) is responsible for the lightenhancement of fatty acid synthesis. This idea is further supportedby the fact that the partial inhibition of fatty acid synthesisby NH₄Cl was relieved by addition of DCCD at low concentrationssuppressing the ATP formation but not completely destroyingthe high energy intermediate. The lag period in the initial period of fatty acid synthesiswas shortened by preillumination of chloroplasts, even in theabsence of ADP. This indicates that the light dependent fattyacid synthesis is closely associated with the high-energy intermediate(state), but not directly with ATP formation by photophosphorylation. ¹ Present address: Radioisotope Centre, University of Tokyo,Yayoi, Bunkyo, Tokyo 113, Japan. (Received August 26, 1974; )     

Inhibition of photophosphorylation by ATP and the role of magnesium in photophosphorylation.

ATP and pyrophosphate at high concentration (greater than 1 mM) inhibited photophosphorylation of isolated spinach chloroplasts in the normal salt medium and did not cause stimulation of electron transport. The inhibition of photophosphorylation by ATP or pyrophosphate was shown to be abolished by the addition of excess MgCl2, ADP and phosphate. It has been demonstrated that the rates of photophosphorylation in the absence and presence of ATP or pyrophosphate are determined similarly by the concentrations of magnesium-ADP (Mg - ADP-) and magnesiumphosphate (Mg - Pi) complexes. It is highly probable that Mg - ADP- and Mg - Pi, but not free ADP and free phosphate, are the active form of the substrates of photophosphorylation. This is in support of the view that ATP inhibits photophosphorylation by decreasing the concentration of Mg2+ which is available for the formation of the complex with ADP and phosphate.     

Effects of Water Stress on Energy Transduction in Chloroplasts

Water stress inhibited the photosynthetic O2 evolution rate of wheat leaves. It was shown that water stress decreased the electron transport rate, the activities of photophosphorylation and, coupling factor, and, the synthesis of ATP in chloroplasts. PS Ⅱ electron transport was more senstitive to water stress than PS Ⅰ. The reduction in photophosphorylation activity might be the results of reduction in electron transport rate and coupling factor activity, as well as the uncoupling effect of water stress on chloroplasts. The uncoupling effect could be due to the inhibition of light induced proton translocation in chloroplasts.     

Photophosphorylation Associated with Photosystem II: I. Photosystem II Cyclic Photophosphorylation Catalyzed by p-Phenylenediamine

Incubation of spinach chloroplast membranes for 90 minutes in the presence of 50 mm KCN and 100 mum HgCl(2) produces an inhibition of photosystem I activity which is stable to washing and to storage of the chloroplasts at -70 C. Subsequent exposure of these preparations to NH(2)OH and ethylenediaminetetraacetic acid destroys O(2) evolution and flow of electrons from water to oxidized p-phenylenediamine, but two types of phosphorylating cyclic electron flow can still be observed. In the presence of 3-(3,4-dichlorophenyl)-1,1'-dimethylurea, phenazinemethosulfate catalyzes ATP synthesis at a rate 60% that observed in uninhibited chloroplasts. C-Substituted p-phenylenediamines will also support low rates of photosystem I-catalyzed cyclic photophosphorylation, but p-phenylenediamine is completely inactive. When photosystem II is not inhibited, p-phenylenediamine will catalyze ATP synthesis at rates up to 90 mumol/hr.mg chlorophyll. This reaction is unaffected by anaerobiosis, and an action spectrum for ATP synthesis shows a peak at 640 nm. These results are interpreted as evidence for the existence of photosystem II-dependent cyclic photophosphorylation in these chloroplast preparations.     

Inhibition and uncoupling of photophosphorylation in isolated chloroplasts by organotin, organomercury and diphenyleneiodonium compounds

1. Trialkyltin, triphenyltin and diphenyleneiodonium compounds inhibited ADP-stimulated O(2) evolution by isolated pea chloroplasts in the presence of phosphate or arsenate. Tributyltin and triphenyltin were the most effective inhibitors, which suggests a highly hydrophobic site of action. Phenylmercuric acetate was a poor inhibitor of photophosphorylation, which suggests that thiol groups are not involved. 2. Triethyltin was a potent uncoupler of photophosphorylation by isolated chloroplasts in media containing Cl(-), but had little uncoupling activity when Cl(-) was replaced by NO(3) (-) or SO(4) (2-), which are inactive in the anion-hydroxide exchange. It is suggested that uncoupling by triethyltin is a result of the Cl(-)-OH(-) exchange together with a natural uniport of Cl(-). Tributyltin, triphenyltin and phenylmercuric acetate had low uncoupling activity, probably because in these compounds the uncoupling activity is partially masked by inhibitory effects. 3. At high concentrations the organotin compounds caused inhibition of electron transport uncoupled by carbonyl cyanide m-chlorophenylhydrazone or NH(4)Cl. At these high concentrations the organotin compounds may be producing a detergent-like disorganization of the membrane structure. In contrast, diphenyleneiodonium sulphate inhibited uncoupled electron transport at low concentrations; however, this inhibition is less than the inhibition of photophosphorylation, which suggests that the compound also inhibits the phosphorylation reactions as well as electron transport. 4. The effects of these compounds on basal electron transport were complex and depended on the pH of the reaction media. However, they can be explained on the basis of three actions: inhibition of the phosphorylation reactions, uncoupling and direct inhibition of electron transport. 5. The inhibition of cyclic photophosphorylation in the presence of phenazine methosulphate by diphenyleneiodonium sulphate shows that it inhibits in the region of photosystem 1.     

Inhibition of energy conservation reactions in chromatophores of Rhodospirillum rubrum by antibiotics

The antibiotics efrapeptin and leucinostatin inhibited photosynthetic and oxidative phosphorylation and related reactions such as the dark and light ATP-P_i exchange reactions and the Mg-ATPase in Rhodospirillum rubrum chromatophores. Higher concentrations of leucinostatin were required for inhibition of the phenazine methosulfate-catalyzed photophosphorylation and light ATP-P_i exchange reaction than for the endogenous or succinate-induced photophosphorylation and dark ATP-P_i exchange reaction. Efrapeptin and leucinostatin inhibited the ATP-driven transhydrogenase while only the latter inhibited the light-driven transhydrogenase, proton gradient formation, and NAD⁺ reduction by succinate in chromatophores. Efrapeptin, but not leucinostatin, inhibited the soluble Ca-ATPase activity of the coupling factor obtained from chromatophores. The inhibition was competitive with ATP. It is concluded that efrapeptin is an effective energy transfer inhibitor whose site of action may be localized in the soluble coupling factor, while the effects of leucinostatin are more complex and cannot be explained as a simple uncoupling.     

Inhibition of photophosphorylation by ATP and the role of magnesium in photophosphorylation

ATP and pyrophosphate at high concentration (> 1 mM) inhibited photophosphorylation of isolated spinach chloroplasts in the normal salt medium and did not cause stimulation of electron transport. The inhibition of photophosphorylation by ATP or pyrophosphate was shown to be abolished by the addition of excess MgCl₂, ADP and phosphate. It has been demonstrated that the rates of photophosphorylation in the absence and presence of ATP or pyrophosphate are determined similarly by the concentrations of magnesium-ADP (Mg · ADP^?) and magnesium-phosphate (Mg · P_i) complexes.It is highly probable that Mg · ADP^? and Mg · P_i, but not free ADP and free phosphate, are the active form of the substrates of photophosphorylation. This is in support of the view that ATP inhibits photophosphorylation by decreasing the concentration of Mg²⁺ which is available for the formation of the complex with ADP and phosphate.     

Effects of Light and 3-(3,4-Dichlorophenyl)-1,1-Dimethylurea on Levels of ATP in Lemna paucicostata 6746 and a Photosynthetic Mutant with Abnormal Flowering Responses

The effects of light, 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU), and ammonium ion on pool sizes of ATP were studied in Lemna paucicostata 6746 (wild type) and a photosynthetic mutant (strain 1073) with abnormal flowering responses. Wild type fronds were capable of endogenous and phenazine methosulfate-catalyzed cyclic photophosphorylation. The endogenous cyclic photophosphorylation was inhibited by DCMU. The mutant fronds showed little endogenous but appreciable rates of phenazine methosulfate-catalyzed cyclic photophosphorylation. Treatment with DCMU during prolonged exposure to light did not result in elevated levels of ATP. Ammonium ion in the medium did not inhibit light-induced increases in pool sizes of ATP. It is concluded that the previously reported effects on flowering of DCMU, the photosynthetic mutation or ammonium ion, were not due to altered pool sizes of ATP.     

Inhibition of photophosphorylation by kaempferol

Kaempferol, a naturally occurring flavonol, inhibited coupled electron transport and both cyclic and noncyclic photophosphorylation in isolated pea (Pisum sativum) chloroplasts. Over a concentration range which gave marked inhibition of ATP synthesis, there was no effect on basal or uncoupled electron flow or light-induced proton accumulation by isolated thylakoids. It is suggested that kaempferol acts as an energy transfer inhibitor.     

Photophosphorylation in cell envelope vesicles from Halobacteriumhalobium

We have prepared vesicles from cell envelope membranes of $\text{Halobacterium}\text{halobium}$ strains R₁ and ET-15 which are able to synthesize ATP in response to illumination. This photophosphorylation is inhibited by dicyclohexylcarbodiimide (DCCD) and by phloretin. ATP synthesis in L vesicles from the R₁ strain (which contain bacteriorhodopsin) is inhibited by the protonophore 1799 but not by valinomycin. In M vesicles from the R₁ strain and in ET-15 vesicles (both contain halorhodopsin) photophosphorylation is inhibited by both 1799 and valinomycin. These data are consistent with the idea that light-driven ATP synthesis can be coupled to the electrochemical H⁺ gradient generated by bacteriorhodopsin or by halorhodopsin through the membrane potential component of protonmotive force.     

N-Ethylmaleimide inhibition of the catalytic activities of the Dunaliella salina coupling factor 1 (CF1) and the restoration of the inhibition of the CF1 ATPase activity by N-ethylmaleimide

The sensitivity of the catalytic activities of the D. salina chloroplast coupling factor 1 (CF1) to chemical modification by N-ethylmaleimide has been investigated. When D. salina thylakoid membranes are treated with N-ethylmaleimide, both photophosphorylation and the inducible CF1 ATPase activity are partially (approx. 60%) inhibited. The inhibition of both activities does not require the presence of a proton-motive force, and the inhibition of photophosphorylation is directly related to the N-ethylmaleimide-covalent modification of CF1 as shown by the time-course for the inhibition and the maximal extent of inhibition. Treatment of the purified, latent, D. salina CF1 with low concentrations of N-ethylmaleimide also results in the partial (approx. 60%) inhibition of the inducible ATPase activity (I50 approximately 50 microM). The inhibition does not require the presence of the chemical modifier during the activation of the enzyme. N-ethylmaleimide-induced inhibition of the ATPase activity of either membrane-bound or solubilized CF1 is partially reversed by either prolonged incubation at low concentrations of N-ethylmaleimide or short incubation times at high concentrations of N-ethylmaleimide. The results are interpreted as indicating multiple binding sites on the D. salina CF1 that have different rates of reactivity with N-ethylmaleimide. Those sites (or site) that react rapidly with N-ethylmaleimide cause(s) an inhibition of both ATP synthase and ATPase activities, whereas those sites (or site) that react more slowly partially restore(s) the original ATPase activity. The effects of N-ethylmaleimide on the catalytic activity of D. salina CF1 are probably mediated by N-ethylmaleimide-induced conformational changes of the enzyme.     

The Role of Cyclic and Pseudocyclic Photophosphorylation in Photosynthetic 14CO2 Fixation in Hydrodictyon africanum

Experiments are reported in which the effects on photosynthesisof various inhibitors of cyclic photophosphorylation were investigated.These inhibitors, generally had only a small inhibitory effecton photosynthesis, and the inhibition was not increased by conditionswhich inhibit pseudocyclic photophosphorylation. These inhibitorsdo not inhibit the Emerson enhancement effect. From these resultsit was concluded that photosynthesis does not need any ATP otherthan that produced in non-cyclic photophosphorylation. The effectsof these inhibitors on active K influx in light-anaerobic conditionsin the presence or absence of CO₂ suggest that some of the ATPproduced by non-cyclic photophosphorylation can be used to supportactive K influx. The results are discussed in relation to themechanism of the Emerson effect, the stoichiometry of non-cyclicphotophosphorylation, and the ATP requirements for autotrophicgrowth.     

Sulphydryl groups in photosynthetic energy conservation. I. Light-dependent inhibition of photophosphorylation by the sulphydryl reagent 2-2'dithio bis-(5-nitropyridine).

1. The sulphydryl reagent 2-2'dithio bis-(5-nitropyridine) (DTNP) inhibited photophosphorylation when the chloroplasts were preincubated with the reagent in the light. A maximum inhibition of about 50% was obtained in the presence of pyocyanine and MgCl 2 at 0.3 mumol DTNP per mg chlorophyll and was completed in about 40 s of preillumination. 2. Dithioerythritol, ADP plus Pi (or arsenate) and uncouplers prevented the inhibition when present during the preillumination while phloridzin, Dio-9 and discarine B were ineffective. Low concentrations of ADP or ATP afforded partial protection but other nucleotides had no effect. 3. DTNP inhibited the coupled electron transport rate to the basal level and had no effect on the uncoupled electron transport. The stimulation of proton uptake and inhibition of electron transport by ATP was prevented by DTNP. 4. The trypsin-activated but not the light- and dithioerythritol-triggered ATPase was inhibited by light preincubation of chloroplasts with DTNP. 5. Reversal of DTNP inhibition of photophosphorylation was obtained by a second preillumination in the presence of thiol groups. 6. More DTNP reacted with chloroplasts in the light than in the dark. Two mol of thione were formed in the light per mol of DTNP disappeared. 7. The results suggested that DTNP inhibition is related to the oxidation by DTNP of chloroplast vicinal dithiols probably exposed by a light-induced conformational change.     

Tentoxin Inhibits Both Photophosphorylation in Thylakoids and the ATPase Activity of Isolated Coupling Factor F1 from the Cyanobacterium Anacystis nidulans

Tentoxin strongly inhibited the ATPase activity of isolatedcoupling factor 1 (AF₁) from the cyanobacterium Anacystis nidulans,with 50% inhibition occurring at 0.3 µM. When thylakoidsfrom A. nidulans were preincubated with 0.3 µM tentoxinfor 30 min, photophosphorylation was inhibited by 50%. Measurementsof fluorescence from 9-aminoacridine indicated that tentoxininhibited the utilization of the proton gradient by ATP formationin thylakoids. These results indicate that tentoxin is a strongenergy-transfer inhibitor of photophosphorylation in A. nidulans.Tentoxin decreased the level of ATP in intact cells both inthe light and in darkness, its effects being much stronger inthe dark. Tentoxin at 50 µM strongly inhibited the growthof the cells. ³Present address: Corporate Research and Development Laboratory,Tonen Co. 1-3-1 Nishi-tsurugaoka, Ohi-machi, Saitama, 354 Japan ⁴Present address: Technology and Engineering Laboratories, AjinomotoCo., Inc. Suzuki-cho 1, Kawasaki, 210 Japan     

Inhibition of energy-transducing functions of chloroplasts by spegazzinine.

The effects of spegazzinine, a dihydroindole alkaloid, on various energy-transducing functions of chloroplasts were studied. The following observations were made, (i) Spegazzinine inhibited both cyclic and noncyclic photophosphorylation in isolated spinach chloroplast. The I₅₀ value was about 80 μm. Over a concentration range which gave marked inhibition of ÀTP synthesis, there was no effect on basal or uncoupled electron flow or light-induced proton accumulation by isolated thylakoids, while the fraction of electron transport stimulated by coupled phosphorylation was reduced to the basal level by spegazzinine. (ii) The regulatory effect of low concentrations of ATP on proton movements and electron transport was diminished by the alkaloid, (iii) Spegazzinine also inhibited with similar efficiency the ATPase activities of membrane-bound coupling factor 1 (CF₁) and of purified CF₁. One mole of spegazzinine per mole of CF₁ seemed to be required to inhibit the ATPase activity, (iv) The allosteric effect of ADP on ATPase activity was not affected by spegazzinine. (v) On the basis of these results it is concluded that spegazzinine acts as an energy transfer inhibitor of hotophosphorylation and that its site of action may be at or near the catalytic site of ATPase.     

Glycolate synthesis by intact chloroplasts: Studies with inhibitors of photophosphorylation

Intact spinach chloroplasts, capable of evolving O₂ in response to CO₂ at rates greater than 70 μmol/h · mg of chlorophyll, synthesize glycolate from added dihydroxyacetone phosphate, ribose 5-phosphate, or xylulose 5-phosphate, when illuminated in the presence of O₂. The synthesis of glycolate from these compounds is dependent upon photophosphorylation and is inhibited by each of the three classes of photophosphorylation inhibitors [Izawa, S., and Good, N. E. (1972) in Methods in Enzymology, Vol. 24, Part B, pp. 355–377)]: an uncoupler, carbonylcyanide-4-trifluoromethoxyphenylhydrazone (FCCP), an energy transfer inhibitor, Dio-9, and a phosphate analog, arsenate. Neither arsenate nor Dio-9 causes the collapse of the light-generated proton gradient between thylakoid and stroma compartments of the chloroplasts, so that the inhibition of glycolate synthesis by these compounds cannot be ascribed to an inactivation of Calvin cycle enzymes thought to be associated with the collapse of such a proton gradient. The dependency of glycolate synthesis upon photophosphorylation indicates that an ATP-consuming reaction(s) is involved in the conversion of the substrates (triose and pentose monophosphates) to glycolate. The formation of dihydroxyethylthiamine pyrophosphate, the “active glycolaldehyde” intermediate of the transketolase reaction, from triose and pentose monophosphates has no known requirements for ATP. On the other hand, the conversion of both triose and pentose monophosphates to ribulose 1,5-bisphosphate, the substrate for the ribulose 1,5-bisphosphate oxygenase reaction, requires ATP. It is concluded that glycolate synthesis by intact isolated chloroplasts is primarily the result of ribulose 1,5-bisphosphate oxygenase activity. No substantial role in glycolate synthesis can be attributed to the oxidation of dihydroxyethylthiamine pyrophosphate, the intermediate of the transketolase reaction.     

Cyclic and Non-cyclic Photophosphorylation as Energy Sources for Active K Influx in Hydrodictyon africanum

Under anaerobic conditions in the light, active K influx inHydrodictyon africanum is supported by cyclic photophosphorylation.The use of selective inhibitors shows that, in the presenceof CO₂, a considerable portion of the ATP used by the K pumpis supplied by noncyclic photophosphorylation. The rest of theATP in these conditions comes from cyclic photophosphorylation.This is true under light-limiting as well as light-saturatedconditions. If non-cyclic photophosphorylation is inhibited (by removalof carbon dioxide, by the addition of cyanide which interfereswith the carboxylation reaction, or by inhibition of photosystemtwo with DCMU or supplying only far-red light), the K influxat low light intensities is stimulated, and its characteristicsbecome those of a process powered by cyclic photophosphorylationalone. These results are interpreted in terms of a competitionfor ATP between K influx and CO₂ fixation. Implicit in thisexplanation is a requirement for a switch of excitation energyabsorbed by photosystem one from cyclic photophosphorylationto non-cyclic photophosphorylation whenever conditions (presenceof CO₂and photosystem two activity) allow CO₂ fixation to occur. Further evidence for such a switch of excitation energy absorbedby photosystem one was obtained in experiments in which redand far-red light were applied separately and together. It wasfound that CO₂ fixation showed the Emerson enhancement effect,while K influx (in the presence of CO₂) shows a ‘de-enhancement’.This suggests that far-red light alone powers cyclic photophosphorylation;if red light is also present, some of the far-red quanta arediverted to non-cyclic photophosphorylation. The nature of the interaction between cyclic and non-cyclicphotophosphorylation is discussed in relation to these and otherpublished results.     

Uptake of ATP analogs by isolated pea chloroplasts and their effect on CO2 fixation and electron transport.

1. The ATP analog, adenylyl-imidodiphosphate rapidly inhibited CO2-dependent oxygen evolution by isolated pea chloroplasts. Both alpha, beta- and beta, gamma-methylene adenosine triphosphate also inhibited oxygen evolution. The inhibition was relieved by ATP but only partially relieved by 3-phosphoglycerate. Oxygen evolution with 3-phosphoglycerate as substrate was inhibited by adenylyl-imidodiphosphate to a lesser extent than CO2-dependent oxygen evolution. The concentration of adenylylimidodiphosphate required for 50% inhibition of CO2-dependent oxygen evolution was 50 micronM. 2. Although non-cyclic photophosphorylation by broken chloroplasts was not significantly affected by adenylyl-imidodiphosphate, electron transport in the absence of ADP was inhibited by adenylyl-imidodiphosphate to the same extent as by ATP, suggesting binding of the ATP analog to the coupling factor of phosphorylation. 3. The endogenous adenine nucleotides of a chloroplast suspension were labelled by incubation with [14C]ATP and subsequent washing. Addition of adenylyl-imidodiphosphate to the labelled chloroplasts resulted in a rapid efflux of adenine nucleotides suggesting that the ATP analog was transported into the chloroplasts via the adenine nucleotide translocator. 4. It was concluded that uptake of ATP analogs in exchange for endogenous adenine nucleotides decreased the internal ATP concentration and thus inhibited CO2 fixation. Oxygen evolution was inhibited to a lesser extent in spinach chloroplasts which apparently have lower rates of adenine nucleotide transport than pea chloroplasts.     

Mechanisms by which reactions catalyzed by chloroplast coupling factor 1 are inhibited: ATP synthesis and ATP-H2O oxygen exchange

The ATP-H2O back-exchange reaction catalyzed by membrane-bound chloroplast coupling factor 1 (CF1) in the light is known to be extensive; each reacting ATP molecule nearly equilibrates its gamma-PO3 oxygens with H2O before it dissociates from the enzyme. Pi, ASi, ADP, and GDP, alternate substrates of photophosphorylation, each inhibit the exchange reaction. At all concentrations of these substrate/inhibitor molecules tested, the high extent of exchange per molecule of ATP that reacts remains the same, while the number of ATP molecules experiencing exchange decreases. Thus, these inhibitors appear to act in a competitive-type manner, decreasing ATP turnover, as opposed to modulating the rate constants responsible for the partitioning of E X ATP during the exchange reaction. This is consistent with the identity of CF1 catalytic sites for ATP-H2O back-exchange and ATP synthesis. Carbonyl cyanide m-chlorophenylhydrazone and NH4Cl (uncouplers of photophosphorylation) and phloridzin (an energy-transfer inhibitor) also lower the rate of ATP-H2O back-exchange; they too are found to act by decreasing the turnover of the ATP pool, not the extent of exchange per reacting ATP molecule. The extent of ATP-H2O forward oxygen exchange, which occurs during net ATP synthesis prior to product dissociation, is unaffected by uncouplers, whether catalyzed by native CF1 (ATPase latent) or the dithiothreitol/light-activated ATPase form. The mode of NH4Cl inhibition of the ATP synthesis reaction, therefore, is not through a change in the partitioning of the E X ATP complex.(ABSTRACT TRUNCATED AT 250 WORDS)     

Photophosphorylation Associated with Photosystem II: II. Effects of Electron Donors, Catalyst Oxidation, and Electron Transport Inhibitors on Photosystem II Cyclic Photophosphorylation

Incubation of KCN-Hg-NH₂OH-inhibited spinach (Spinacia oleracea L.) chloroplasts with p-phenylenediamine for 10 minutes in the dark prior to illumination produced rates of photosystem II cyclic photophosphorylation up to 2-fold greater than the rates obtained without incubation. Partial oxidation of p-phenylenediaine with ferricyanide produced a similar stimulation of ATP synthesis; addition of dithiothreitol suppressed the stimulation observed with incubation. Addition of ferricyanide in amounts sufficient to oxidize completely p-phenylenediamine failed to inhibit completely photosystem II cyclic activity. This is due at least in part to the fact that the ferrocyanide produced by oxidation of p-phenylenediamine is itself a catalyst of photosystem II cyclic photophosphorylation. N,N,N′N′-Tetramethyl-p-phenylenediamine catalyzes photosystem II cyclic photophosphorylation at rates approaching those observed with p-phenylenediamine. The activities of both proton/electron and electron donor catalysts of the photosystem II cycle are inhibited by dibromothyoquinone and antimycin A. These findings are interpreted to indicate that photosystem II cyclic photophosphorylation requires the operation of endogenous membrane-bound electron carriers for optimal coupling of ATP synthesis to electron transport.