Formation of the Photosynthetic Electron Transport System during the Early Phase of Greening in Barley Leaves

The development of photochemical activity in isolated plastids during the early phase of greening of 5-day-old etiolated barley seedlings was studied and related to the appearance of chlorophyll-protein complexes. Photochemical activities of PSI (DCIPH₂ → MV) and PSII (H₂O → DCIP, DPC → DCIP) appeared at 1 and 1.5 hours after the onset of illumination, respectively. However, PSI + PSII activity (H₂O → MV, H₂O → NADP) appeared at 4 hours. The functional plastoquinone pool was noticed, at the latest, from 4 hours. Chloroplast preparations from seedlings of 1 h of greening showed O₂ uptake upon illumination in the absence of MV (−MV activity). This activity peaked at 2 hours of greening, then fell to zero by 6 hours. In contrast to the −MV activity, MV-Hill activity began to increase at 2 hours. Although PSI activity appeared at 1 hour, it failed to reduce ferredoxin until 2 hours. NADP began to be photoreduced at 4 hours in accordance with the appearance of the ferredoxin:NADP reductase activity. After formation of PSI and PSII, electron transport systems between them and between PSI and NADP developed in coordination with each other. Thus, the whole electron transport from water to NADP began to operate at 4 hours.     

Respiration-driven proton translocation in rat liver mitochondria

1. Pulses of acidity of the outer aqueous phase of rat liver mitochondrial suspensions induced by pulses of respiration are due to the translocation of H⁺ (or OH⁻) ions across the osmotic barrier (M phase) of the cristae membrane and cannot be attributed to the formation (with acid production) of a chemical intermediate that subsequently decomposes. 2. The effective quantity of protons translocated per bivalent reducing equivalent passing through the succinate-oxidizing and β-hydroxybutyrate-oxidizing spans of the respiratory chain are very close to 4 and 6 respectively. These quotients are constant between pH5·5 and 8·5 and are independent of changes in the ionic composition of the mitochondrial suspension medium provided that the conditions permit the accurate experimental measurement of the proton translocation. 3. Apparent changes in the →H⁺/O quotients may be induced by conditions preventing the occurrence of the usual backlash; these apparent changes of →H⁺/O are attributable to a very fast electrically driven component of the decay of the acid pulses that is not included in the experimental extrapolations. 4. Apparent changes in the →H⁺/O quotients may also be induced by the presence of anions, such as succinate, malonate and phosphate, or by cations such as Na⁺. These apparent changes of →H⁺/O are due to an increase in the rate of the pH-driven decay of the acid pulses. 5. The uncoupling agents, 2,4-dinitrophenol, carbonyl cyanide p-trifluoromethoxyphenylhydrazone and gramicidin increase the effective proton conductance of the M phase and thus increase the rate of decay of the respiration-driven acid pulses, but do not change the initial →H⁺/O quotients. The increase in effective proton conductance of the M phase caused by these uncouplers accounts quantitatively for their uncoupling action; and the fact that the initial →H⁺/O quotients are unchanged shows that uncoupler-sensitive chemical intermediates do not exist between the respiratory-chain system and the effective proton-translocating mechanism. 6. Stoicheiometric acid–base changes associated with the activity of the regions of the respiratory chain on the oxygen side of the rotenone- and antimycin A-sensitive sites gives experimental support for a suggested configuration of loop 3.     

K+-independent effects of valinomycin in photosynthetic systems

With chromatophores ofRhodospirillum rubrum, valinomycin inhibited electron transport in the presence or absence of K⁺. NH₄Cl had no effect on photophosphorylation but uncoupled with valinomycin present. ATPase activity was stimulated by NH₄Cl plus valinomycin but not by either alone. K⁺ partially reversed the inhibition of phosphorylation and the stimulation of ATPase by valinomycin plus NH₄Cl.With chloroplasts, valinomycin inhibited coupled but not basal electron transport. The inhibition was only partially reversed by uncouplers. Valinomycin stimulated the light-activated Mg²⁺-dependent ATPase similar to several uncouplers such as quinacrine, methylamine, and S-13. In addition, valinomycin inhibited delayed light emission and stimulated the H⁺/e^– ratio. These contrasting activities in chloroplasts are not easily explained.Contribution number 389 of the Charles F. Kettering Research Laboratory.     

Human SLC4A11 Is a Novel NH3/H+ Co-transporter

SLC4A11 has been proposed to be an electrogenic membrane transporter, permeable to Na⁺, H⁺ (OH⁻), bicarbonate, borate, and NH₄⁺. Recent studies indicate, however, that neither bicarbonate or borate is a substrate. Here, we examined potential NH₄⁺, Na⁺, and H⁺ contributions to electrogenic ion transport through SLC4A11 stably expressed in Na⁺/H⁺ exchanger-deficient PS120 fibroblasts. Inward currents observed during exposure to NH₄Cl were determined by the [NH₃]_o, not [NH₄⁺]_o, and current amplitudes varied with the [H⁺] gradient. These currents were relatively unaffected by removal of Na⁺, K⁺, or Cl⁻ from the bath but could be reduced by inclusion of NH₄Cl in the pipette solution. Bath pH changes alone did not generate significant currents through SLC4A11, except immediately following exposure to NH₄Cl. Reversal potential shifts in response to changing [NH₃]_o and pH_o suggested an NH₃/H⁺-coupled transport mode for SLC4A11. Proton flux through SLC4A11 in the absence of ammonia was relatively small, suggesting that ammonia transport is of more physiological relevance. Methylammonia produced currents similar to NH₃ but with reduced amplitude. Estimated stoichiometry of SLC4A11 transport was 1:2 (NH₃/H⁺). NH₃-dependent currents were insensitive to 10 μm ethyl-isopropyl amiloride or 100 μm 4,4′- diisothiocyanatostilbene-2,2′-disulfonic acid. We propose that SLC4A11 is an NH₃/2H⁺ co-transporter exhibiting unique characteristics.     

Solubilization and reconstitution of the oat root vacuolar h/ca exchanger

Calcium is sequestered into vacuoles of oat (Avena sativa L.) root cells via a H⁺/Ca²⁺ antiporter, and vesicles derived from the vacuolar membrane (tonoplast) catalyze an uptake of calcium which is dependent on protons (pH gradient [ΔpH] dependent). The first step toward purification and identification of the H⁺/Ca²⁺ antiporter is to solubilize and reconstitute the transport activity in liposomes. The vacuolar H⁺/Ca²⁺ antiporter was solubilized with octylglucoside in the presence of soybean phospholipids and glycerol. After centrifugation, the soluble proteins were reconstituted into liposomes by detergent dilution. A ΔpH (acid inside) was generated in the proteoliposomes with an NH₄Cl gradient (NH₄⁺_in » NH₄⁺_out) as determined by methylamine uptake. Fundamental properties of ΔpH dependent calcium uptake such as the K_m for calcium (~15 micromolar) and the sensitivity to inhibitors such as N,N′-dicyclohexylcarbodiimide, ruthenium red, and lanthanum, were similar to those found in membrane vesicles, indicating that the H⁺/Ca²⁺ antiporter has been reconstituted in active form.     

Key-word system of indexing

The effects of uncouplers of photophosphorylation on the P-S₁ transient of the fluorescence induction in darkadapted intact chloroplasts of Bryopsis maxima were studied to examine the mechanism of light-dependent regulatory changes in electron transport. (1) Carbonyl cyanide m-chlorophenylhydrazone (CCCP) and nigericin slowed down the fluorescence quenching from P to S₁, whereas the transient was significantly accelerated by the addition of NH₄Cl and methylamine. (2) The P-S₁ decline was slowed down at low pH of the suspending medium, suggesting sensitivity of the transient to the stroma pH. The inhibitory effect of nigericin was markedly enhanced at low pH and at low KCl concentrations, whereas the ionophore stimulated the transient at high pH and at high KCl concentrations. Similar results were obtained on the combined addition of CCCP and valinomycin. (3) Nigericin and the CCCP-valinomycin couple altered the internal pH of intact chloroplast through the H⁺-K⁺ exchange across the outer limiting membrane. The fluorescence decline was rapid at alkaline internal pH but was suppressed with lowering internal pH below 8.0 (4) A similar internal pH dependence of the transient was obtained when the internal pH was changed by the addition of NH₄Cl and acetate. (5) It is proposed that the photoactivation of electron transport is regulated by the stroma pH. The progress of the photoactivation is slow at acidic or neutral pH but is significantly accelerated by light-induced alkalinization near the light-regulation site of electron transport located on the outer surface of the thylakoid membrane.     

Hydrogen peroxide synthesis in isolated spinach chloroplast lamellae : an analysis of the mehler reaction in the presence of NADP reduction and ATP formation

Light-dependent O₂ reduction concomitant with O₂ evolution, ATP formation, and NADP reduction were determined in isolated spinach (Spinacia oleracea L. var. America) chloroplast lamellae fortified with NADP and ferredoxin. These reactions were investigated in the presence or absence of catalase, providing a tool to estimate the reduction of O₂ to H₂O₂ (Mehler reaction) concomitant with NADP reduction. In the presence of 250 micromolar O₂, O₂ photoreduction, simultaneous with NADP photoreduction, was dependent upon light intensity, ferredoxin, Mn²⁺, NADP, and the extent of coupling of phosphorylation to electron flow.

In the presence of an uncoupling concentration of NH₄⁺, saturating light intensity (>500 watts/square meter), saturating ferredoxin (10 micromolarity) rate-limiting to saturating NADP (0.2-0.9 millimolarity), and Mn²⁺ (50-1000 micromolarity), the maxium rates of O₂ reduction were 13-25 micromoles/milligram chlorophyll per hour, while concomitant rates of O₂ evolution and NADP reduction were 69 to 96 and 134 to 192 micromoles/milligram chlorophyll per hour, respectively. Catalase did not affect the rate of NADPH or ATP formation but decreased the NADPH:O₂ ratios from 2.3-2.8 to 1.9-2.1 in the presence of rate-limiting as well as saturating concentrations of NADP.

Photosynthetic electron flow at a rate of 31 micromoles O₂ evolved/milligram chlorophyll per hour was coupled to the synthesis of 91 micromoles ATP/milligram chlorophyll per hour, while the concomitant rate of O₂ reduction was 0.6 micromoles/milligram chlorophyll per hour and was calculated to be associated with an apparent ATP formation of only 2 micromoles/milligram chlorophyll per hour. Thus, electron flow from H₂O to O₂ did not result in ATP formation significantly above that produced during NADP reduction.

     

Temperature Dependence of Photosynthesis in Agropyron smithii Rydb. : II. CONTRIBUTION FROM ELECTRON TRANSPORT AND PHOTOPHOSPHORYLATION

As part of an analysis of the factors regulating photosynthesis in Agropyron smithii Rydb., a C₃ grass, the response of electron transport and photophosphorylation to temperature in isolated chloroplast thylakoids has been examined. The response of the light reactions to temperature was found to depend strongly on the preincubation time especially at temperatures above 35°C. Using methyl viologen as a noncyclic electron acceptor, coupled electron transport was found to be stable to 38°C; however, uncoupled electron transport was inhibited above 38°C. Photophosphorylation became unstable at lower temperatures, becoming progressively inhibited from 35 to 42°C. The coupling ratio, ATP/2e⁻, decreased continuously with temperature above 35°C. Likewise, photosystem I electron transport was stable up to 48°C, while cyclic photophosphorylation became inhibited above 35°C. Net proton uptake was found to decrease with temperatures above 35°C supporting the hypothesis that high temperature produces thermal uncoupling in these chloroplast thylakoids. Previously determined limitations of net photosynthesis in whole leaves in the temperature region from 35 to 40°C may be due to thermal uncoupling that limits ATP and/or changes the stromal environment required for photosynthetic carbon reduction. Previously determined limitations to photosynthesis in whole leaves above 40°C correlate with inhibition of photosynthetic electron transport at photosystem II along with the cessation of photophosphorylation.     

Inhibition of the photosynthetic capacity of isolated chloroplasts by ozone

Isolated spinach chloroplasts have been used as a model system for studying the interaction of ozone, a component of photochemical smog, with plant membranes. Ozone bubbled into a suspension of isolated chloroplasts inhibits electron transport in both photosystems without uncoupling ATP production. Photosystem I (reduced 2,6-dichlorophenolindolphenol → NADP⁺) is a little more sensitive than photosystem II (H₂O → 2,6-dichlophenolindolphenol). Ozone does not act as an energy transfer inhibitor, since the drop in ATP production and high energy intermediate (measured by amine-induced swelling) is nearly parallel to the decline in electron transport. A reasonable hypothesis is that ozone disrupts the normal pathway of energy flow from light-excited chlorophyll into the photoacts by a disruption of the components of the membrane but not a general disintegration of the membrane. In addition, ozone does not seem to penetrate into the grana region through the outer membrane of intact plastids, since ozone lowers the bicarbonate-supported O₂ evolution but does not affect the rate of ferricyanide reduction in the same plastids after osmotic disruption. This would indicate that the effect of ozone on green plants, at low concentrations, may be due to the interaction of ozone with the first membrane it contacts and not directly with internal metabolic processes.     

Temperature Dependence of Photosynthetic Activities in Wheat Seedlings Grown in the Presence of BASF 13.338 (4-Chloro-5-Dimethylamino-2-Phenyl-3(2H)Pyridazinone)

When Triticum vulgare cv HD 2189 seedlings were grown in the presence of 125 micromolar BASF 13.338 (4-chloro-5-dimethylamino-2-phenyl-3(2H)pyridazinone), the rate of electron transport (H₂O → methyl viologen) in chloroplast thylakoids isolated from the treated seedlings was higher (by 50%) as compared to the control at assay temperatures above 30°C. Below 30°C, however, the rate with the treated seedlings was lower than the control rate. The temperature dependence of the rate of photosystem I electron transport (2-6-dichlorophenol indophenol-reduced → methyl viologen) in the treated system was similar to that in the control. At high temperatures (>30°C), with diphenyl carabazide as electron donor, the rates of electron transfer (diphenyl carbazide → methyl viologen) were similar in the treated and in the control thylakoids. Direct addition of BASF 13.338 to the assay mixture for the measurement of rate of electron transport (H₂O → methyl viologen) in the thylakoids isolated from the control plants did not cause any change in the temperature dependence of photosynthetic electron transport. These results suggested that the donor side of photosystem II became tolerant to heat in the treated plants. Chlorophyll a fluorescence emission was monitored continuously in the leaves of control and BASF 13.338 treated wheat seedlings during continuous increase in temperature (1°C per minute). The fluorescence-temperature profile showed a decrease in the fluorescence yield above 55°C; this decrease was biphasic in the control and monophasic in the treated plants.     

The stoichiometry (ATP/2e− ratio) of non-cyclic photophosphorylation in isolated spinach chloroplasts

1. The stoichiometry of non-cyclic photophosphorylation and electron transport in isolated chloroplasts has been re-investigated. Variations in the isolation and assay techniques were studied in detail in order to obtain optimum conditions necessary for reproducibly higher ADP/O (equivalent to ATP/2e^?) and photosynthetic control ratios.2. Studies which we carried out on the possible contribution of cyclic phosphorylation to non-cyclic phosphorylation suggested that not more than 10% of the total phosphorylation found could be due to cyclic phosphorylation.3. Photosynthetic control, and the uncoupling of electron transport in the presence of NH₄Cl, were demonstrated using oxidised diaminodurene as the electron acceptor. A halving of the ADP/O ratio was found, suggesting that electrons were being accepted between two sites of energy conservation, one of which is associated with Photosystem I and the other associated with Photosystem II.4. ATP was shown to inhibit State 2 and State 3 of electron transport, but not State 4 electron transport or the overall ADP/O ratio, thus confirming its activity as an energy transfer inhibitor. It is suggested that part of the non-phosphorylating electron transport rate (State 2) which is not inhibited by ATP is incapable of being coupled to subsequent phosphorylation triggered by the addition of ADP (State 3). If the ATP-insensitive State 2 electron transport is deducted from the State 3 electron transport when calculating the ADP/O ratio, a value of 2.0 is obtained.5. The experiments reported demonstrate that there are two sites of energy conservation in the non-cyclic electron transfer pathway: one associated with Photosystem II and the other with Photosystem I. Thus, non-cyclic photophosphorylation can probably produce sufficient ATP and NADPH “in vivo” to allow CO₂ fixation to proceed.     

Energetic factors affecting carbon dioxide fixation in isolated chloroplasts

Light- and HCO₃⁻-saturated (10 millimolar) rates of O₂ evolution (120 to 220 micromoles O₂ per milligram chlorophyll per hour), obtained with intact spinach chloroplasts, are decreased up to 3-fold by changes in assay conditions such as omission of catalase from the medium, the use of high (≥1 millimolar) inorganic phosphate, inclusion of NO₂⁻ as an electron acceptor, or bright illumination at low partial pressures of O₂. These inhibitions may be reversed by addition of uncoupling levels of NH₄Cl or of antimycin concentrations that partially block cyclic electron transfer between cytochrome b₆ and cytochrome f. Measurements of the pH gradient across the thylakoid membrane with the fluorescent probe, 9-aminoacridine, indicate that changes in ΔpH are sufficient to account for both the inhibited and restored rates of electron transport. It follows that the rate of HCO₃⁻-saturated photosynthesis may be restricted by a proton gradient back pressure under these conditions.     

Relationships between Root Temperature and the Transport of Ammonium and Nitrate Ions by Italian and Perennial Ryegrass (Lolium multiflorum and Lolium perenne)

At root temperature below 14 C the absorption of ¹⁵N from NH₄⁺ greatly exceeded that from NO₂⁻ by tillers of Lolium multiflorum and Lolium perenne under conditions where pH, external concentration, plant N status, and pretreatment temperature were varied. There was a marked increase in the temperature sensitivity of NO₃⁻ transport below 14 C, irrespective of the temperature at which plants were grown previously. A marked increase in the temperature sensitivity was also seen for NH₄⁺ transport, but this occurred at the lower temperature of 10 C. Pretreatment of roots at 8 C lowered this still further to 5 C. Above and below these transition temperatures the Q₁₀ values for NO₃⁻ and NH₄⁺ transport were similar. Thus, the increased absorption of NH₄⁺ relative to NO₃⁻ at low temperatures seems to be related primarily to the difference in transition temperatures.     

ADP Is a Competitive Inhibitor of ATP-Dependent H Transport in Microsomal Membranes from Zea mays L. Coleoptiles

An anion-sensitive ATP-dependent H⁺ transport in microsomal membranes from Zea mays L. coleoptiles was partially characterized using the pH gradient-dependent decrease of unprotonated neutral red. The following criteria strongly suggest a tonoplast origin of the H⁺ transport observed: strict dependence on Cl⁻; inhibition by SO₄²⁻ and NO₃⁻; insensitivity against vanadate, molybdate, and azide; reversible inhibition by CaCl₂ (H⁺/Ca²⁺ antiport); inhibition by diethylstilbestrol. The substrate kinetics revealed simple Michaelis Menten kinetics for ATP in the presence of 1 millimolar MgCl₂ with a K_m value of 0.56 millimolar (0.38 millimolar for MgATP). AMP and c-AMP did not influence H⁺ transport significantly. However, ADP was a potent competitive inhibitor with a K_i value of 0.18 millimolar. The same inhibition type was found for membranes prepared from primary roots by the same procedure.     

Active extrusion of protons into deionized water by roots of intact maize plants

The investigations were focussed on the question as to whether roots of intact maize plants (Zea mays L. cv Blizzard) release protons into deionized H₂O. Plants in the six to seven leaf stage depressed the pH of deionized H₂O from 6 to about 4.8 during an experimental period of 4 hours. Only one-third of the protons released could be ascribed to the solvation of CO₂ in H₂O. The main counter anions released were Cl⁻, NO₃⁻, and SO₄²⁻. At low temperature (2°C), the H⁺ release was virtually blocked while a relatively high amount of K⁺ was released. The presence of K⁺, Na⁺, Ca²⁺, and Mg²⁺ in the external solution increased the H⁺ secretion significantly. Addition of vanadate to the outer medium inhibited the H⁺ release while fusicoccin had a stimulating effect. Substituting the nutrient solution of deionized H₂O resulted in a substantial increase of the membrane potential difference from −120 to −190 millivolts. The experimental results support the conclusion that the H⁺ release by roots of intact maize plants is an active process driven by a plasmalemmalocated ATPase. Since the net H⁺ release was not associated with a net uptake of K⁺, it is unlikely to originate from a K⁺/H⁺ antiport.     

Life by a new decarboxylation-dependent energy conservation mechanism with Na as coupling ion

We report here a new mode of ATP synthesis in living cells. The anaerobic bacterium Propionigenium modestum gains its total energy for growth from the conversion of succinate to propionate according to: succinate + H₂O → propionate + HCO₃^- (G^o' = -20.6 kJ/mol). The small free energy change of this reaction does not allow a substrate-linked phosphorylation mechanism, and no electron transport phosphorylation takes place. Succinate was degraded by cell-free extracts to propionate and CO₂ via succinyl-CoA, methyl-malonyl-CoA and propionyl-CoA. This pathway involves a membrane-bound methylmalonyl-CoA decarboxylase which couples the exergonic decarboxylation with a Na⁺ ion transport across the membrane. The organism also contained a membrane-bound ATPase which was specifically activated by Na⁺ ions and catalyzed and transport of Na⁺ ions into inverted bacterial vesicles upon ATP hydrolysis. The transport was abolished by monensin but not by the uncoupler carbonylcyanide-p-trifluoromethoxy phenylhydrazone. Isolated membrane vesicles catalyzed the synthesis of ATP from ADP and inorganic phosphate when malonyl-CoA was decarboxylated and malonyl-CoA synthesis from acetyl-CoA when ATP was hydrolyzed. These syntheses were sensitive to monensin which indicates that Na⁺ functions as the coupling ion. We conclude from these results that ATP synthesis in P. modestum is driven by a Na⁺ ion gradient which is generated upon decarboxylation of methylmalonyl-CoA.     

Effects of Light Intensity and Oxidized Nitrogen Sources on Hydrogen Production by Chlamydomonas reinhardii

Chlamydomonas reinhardii cells, after a period of dark anaerobic adaptation, evolve H₂ not only in the dark but also in the light. Our results show that high irradiances impair prolonged H₂ evolution, while under low irradiances or darkness H₂ evolution proceeds for more than 50 hours. NO₃⁻ and NO₂⁻ suppress H₂ evolution both in the dark or under low irradiance. Apparently the cells prefer these oxidized nitrogen sources to protons as electron acceptors, since both NO₃⁻ and NO₂⁻ become reduced to NH₄⁺, which is excreted to the culture medium in high amounts. H₂ evolution started once these oxidized anions were largely depleted from the medium. Moreover, H₂ evolution was consistently associated with NH₄⁺ excretion even if NH₄⁺ was already present in high amounts in the medium. This observation indicates that the cells utilize not only their carbohydrate but also their protein reserves as sources of reducing power for H₂ evolution. This conclusion was supported by the observation that when nitrogen-starved cells were made anaerobic in a nitrogen-free medium, they not only evolved H₂ at very high rates but excreted concomitantly NH₄⁺ up to concentrations in the millimolar range.     

Dissimilatory Reduction of NO2− to NH4+ and N2O by a Soil Citrobacter sp.

Dissimilatory reduction of NO₂⁻ to N₂O and NH₄⁺ by a soil Citrobacter sp. was studied in an attempt to elucidate the physiological and ecological significance of N₂O production by this mechanism. In batch cultures with defined media, NO₂⁻ reduction to NH₄⁺ was favored by high glucose and low NO₃⁻ concentrations. Nitrous oxide production was greatest at high glucose and intermediate NO₃⁻ concentrations. With succinate as the energy source, little or no NO₂⁻ was reduced to NH₄⁺ but N₂O was produced. Resting cell suspensions reduced NO₂⁻ simultaneously to N₂O and free extracellular NH₄⁺. Chloramphenicol prevented the induction of N₂O-producing activity. The K_m for NO₂⁻ reduction to N₂O was estimated to be 0.9 mM NO₂⁻, yet the apparent K_m for overall NO₂⁻ reduction was considerably lower, no greater than 0.04 mM NO₂⁻. Activities for N₂O and NH₄⁺ production increased markedly after depletion of NO₃⁻ from the media. Amendment with NO₃⁻ inhibited N₂O and NH₄⁺ production by molybdate-grown cells but not by tungstate-grown cells. Sulfite inhibited production of NH₄⁺ but not of N₂O. In a related experiment, three Escherichia coli mutants lacking NADH-dependent nitrite reductase produced N₂O at rates equal to the wild type. These observations suggest that N₂O is produced enzymatically but not by the same enzyme system responsible for dissimilatory reduction of NO₂⁻ to NH₄⁺.     

The phosphorylation site associated with the oxidation of exogenous donors of electrons to Photosystem I

1. The Photosystem I-mediated transfer of electrons from diaminodurene, diaminotoluene and reduced 2,6-dichlorophenolindophenol to methylviologen is optimal at pH 8–8.5, where phosphorylation is also maximal. In the presence of superoxide dismutase, the efficiency of phosphorylation rises from ? 0.1 at pH 6.5 to 0.6–0.7 at pH 8–8.5, regardless of the exogenous electron donor used.2. The apparent K_m (at pH 8.1) for diaminodurene is 6·10^?4 M and for diaminotoluene is 1.2·10^?3 M. The concentrations of diaminodurene and diaminotoluene required to saturate the electron transport processes are > 2 mM and > 5 mM, respectively. At these higher electron donor concentrations the rates of electron transport are markedly increased by phosphorylation (1.5-fold) or by uncoupling conditions (2-fold).3. Kinetic analysis of the transfer of electrons from reduced 2,6-dichlorophenolindophenol (DCIPH₂) to methylviologen indicates that two reactions with very different apparent K_m values for DCIPH₂ are involved. The rates of electron flux through both pathways are increased by phosphorylation or uncoupling conditions although only one of the pathways is coupled to ATP formation. No similar complications are observed when diaminodurene or diaminotoluene serves as the electron donor.4. In the diaminodurene → methylviologen reaction, ATP formation and that part of the electron transport dependent upon ATP formation are partially inhibited by the energy transfer inhibitor HgCl₂. This partial inhibition of ATP formation rises to about 50% at less than 1 atom of mercury per 20 molecules of chlorophyll, then does not further increase until very much higher levels of mercury are added.5. It is suggested that exogenous electron donors such as diaminodurene, diaminotoluene and DCIPH₂ can substitute for an endogenous electron carrier in donating electrons to cytochrome f via the mercury-sensitive coupling site (Site I) located on the main electron-transporting chain. If this is so, there would seem to be no reason for postulating yet another coupling site on a side branch of the electron transport chain in order to account for cyclic photophosphorylation.