Anthroyl stearate as a fluorescent probe of chloroplast membranes

1. A reversible light-induced enhancement of the fluorescence of a “hydrophobic fluorophore”, 12-(9-anthroyl)-stearic acid (anthroyl stearate), is observed with chloroplasts supporting phenazine methosulfate, cyclic or 1,1′-ethylene-2,2′-dipyridylium dibromide (Diquat) pseudo-cyclic electron flow; no fluorescence change is observed when methyl viologen or ferricyanide are used as electron acceptors. The stearic acid moiety of anthroyl stearate is important for its localization and fluorescence response in the thylakoid membrane, since structural analogs of anthroyl stearate lacking this group do not show the same response.

2. This effect is decreased under phosphorylating conditions (presence of ADP, P_i, Mg²⁺), and completely inhibited by the uncoupler of phosphorylation NH₄Cl (5–10 mM), as well as the ionophores nigericin and gramicidin-D (both at 5 · 10⁻⁸ M). The MgCl₂ concentration dependence of the anthroyl stearate enhancement effect is identical to that previously observed for cyclic photophosphorylation, as well as for the formation of a “high energy intermediate”. The anthroyl stearate fluorescence enhancement is inhibited by increasing concentrations of ionophores in parallel with the decrease in ATP synthesis, but is essentially unaffected by specific inhibitors (Dio-9 and phlorizin) of photophosphorylation; thus, it appears that anthroyl stearate monitors a component of the “high energy state” of the thylakoid membrane rather than a terminal phosphorylation step.

3. The light-induced anthroyl stearate fluorescence enhancement is suggested to monitor a proton gradient in the energized chloroplast because (a) similar enhancement can be produced by sudden injection of hydrogen ions in a solution of anthroyl stearate; (b) when the proton gradient is dissipated by gramicidin or nigericin light-induced anthroyl stearate fluorescence is eliminated; (c) when the proton gradient is dissipated by tetraphenylboron, light-induced anthroyl stearate fluorescence decreases, and (d) light-induced anthroyl stearate fluorescence change as a function of pH is qualitatively similar to that observed with other probes for a proton gradient (e.g. 9-aminoacridine). Furthermore, anthroyl stearate does not monitor H⁺ uptake per se because (a) the pH dependence of H⁺ transport is different from that of the anthroyl stearate fluorescence change, and (b) tetraphenylboron, which does not inhibit H⁺ uptake, reduces anthroyl stearate fluorescence.

Thus, anthroyl stearate appears to be a useful probe of a proton gradient supported by phenazine methosulfate or Diquat catalyzed electron flow and is the first “non-amine” fluorescence probe utilized for this purpose in chloroplasts.     

The relation of millisecond delayed light emission to light-induced ion accumulations in chloroplasts

Delayed fluorescence (delayed light emission) from chloroplasts is increased by ATP, ADP and, to a lesser extent, by ITP. However, neither phosphorylation nor ATP utilization seems to play any part in the phenomenon since the energy transfer inhibitor deoxyphlorizin, which is also an ATPase inhibitor, has no effect on the enhancement of delayed fluorescence. The enhancement of delayed fluorescence by these nucleotides is accompanied by an increase in the extent of proton uptake and n decrease in the nonphosphorylating (basal) electron transport.Uncouplers and ionophores such as imidazole, glycineamide, morpholine, methyl-amine, cyclohexylamine, atebrin, and gramicidin nearly abolish delayed fluorescence. However, ammonium salts are exceptional; they considerably enhance the emission although they also abolish phosphorylation and proton gradient formation. This enhancement of delayed fluorescence occurs only near or above pH 8 and seems to be specific for ammonia when relatively intact lamellae are employed. When particles prepared therefrom with digitonin are used, methylamine also enhances the delayed fluorescence. The enhancement by ammonium salts is correlated with the uptake of ammonium ions. Valinomycin, which is known to increase the permeability of membranes to ammonium ions, abolishes delayed fluorescence in the presence of ammonium salts. It is suggested that (a) ammonia uncoupling abolishes the pH component of the light-induced transmembrane electrochemical potential gradient, but that (b) at higher pH's the electrical component of the gradient (the membrane potential) is not abolished and may even increase while (c) this increased membrane potential is responsible for enhancement of the delayed fluorescence.Gradients which contribute to delayed fluorescence are not necessarily capable of supporting phosphorylation. The requirements for phosphorylation seem more stringent than the requirements for delayed fluorescence and it may be that phosphorylation, unlike the delayed light emission, has an obligatory requirement for a pH gradient.     

Energy-dependent changes in the ATP/ADP ratio at the tight nucleotide binding site of chloroplast ATP synthase

Using DTT-modulated thylakoid membranes we studied tight nucleotide binding and ATP content in bound nucleotides and in the reaction mixture during [¹⁴C] ADP photophosphorylation. The increasing light intensity caused an increase in the rate of [¹⁴C] ADP incorporation and a decrease in the steady-state level of tightly bound nucleotides. Within the light intensity range from 11 to 710 w m^–2, ATP content in bound nucleotides was larger than that in nucleotides of the reaction mixture; the most prominent difference was observed at low degrees of ADP phosphorylation. The increasing light intensity was accompanied by a significant increase of the relative ATP content in tightly bound nucleotides. The ratio between substrates and products formed at the tight nucleotide binding site during photophosphorylation was suggested to depend on the light-induced proton gradient across the thylakoid membrane.Abbreviations AdN adenine nucleotide - Chl chlorophyll - DTT dithiothreitol - FCCP carbonylcianide p-trifluoromethoxyphenilhydrazone - P_i inorganic orthophosphate - PMS phenazine methosulfate - TLC thin-layer chromatography - Tricine N-[tris(hydroxymethyl)methyl] glycine     

Nigericin-induced stimulation of photophosphorylation in chloroplasts

Amines have been shown recently to stimulate at low concentrations the steady-state rate of photophosphorylation by unbroken chloroplasts (Giersch, C. (1982) Z. Naturforsch. 37c, 242–250). In the present contribution it is demonstrated that not only amines but also the carboxylic ionophores nigericin and monensin at concentrations of 10 and 150 nM, respectively, stimulate the phosphorylation rate. The $\text{ATP}\text{2}\text{e}$ ratio is not decreased upon the addition of nigericin at concentrations that stimulate phosphorylation. Nigericin-induced stimulation is observed only in the presence of sufficient external potassium, indicating that the observed stimulation is unlikely to be a side-effect of the uncoupler but is related to H⁺-K⁺ exchange. The proton permeability of the thylakoid membrane is increased and the proton gradient decreased by amounts of nigericin that stimulate phosphorylation. The membrane potential is not affected in the steady state, indicating that the proton-motive force is slightly reduced upon addition of the ionophore. Data on the proton-motive force were related to maximum values of the phosphorylation potential, which was 45 000–50 000 M^?1 in the absence and 30 000–35 000 M^?1 in the presence of 10 nM nigericin. The observation that the $\text{ATP}\text{2}\text{e}$ ratio is not decreased in the presence of uncoupler-induced proton leakage is suggested to indicate that the thylakoid lumen does not represent a homogeneous phase of constant proton electrochemical potential. The results presented here are in agreement with the chemiosmotic concept as far as energetic aspects are concerned but seem to be at variance with the postulated free mobility of protons inside the thylakoids. A tentative model of uncoupler-induced stimulation of phosphorylation is presented.     

Respiration-coupled calcium transport by membrane vesicles from Azotobacter vinelandii.

Membrane vesicles, isolated from osmotic lysates of Azotobacter vinelandii spheroplasts in Tris-acetate buffer, rapidly accumulate calcium in the presence of an oxidizable substrate. The addition of D-lactate to vesicles increases the rate of calcium uptake by 34-fold; L-malate, NADH, NADPH, and reduced phenazine methosulfate are nearly as effective as lactate. The intravesicular calcium pool which accumulates under these conditions is rapidly discharged by isotopic exchange or in the presence of respiratory inhibitors, uncouplers, or EGTA. The uptake rates for calcium follow Michaelis-Menten kinetics yielding a Km of 48 microM and a V max of 45 nmoles/min/mg membrane protein. Initial rates of EGTA-induced calcium efflux also follow saturation kinetics, giving a V max identical to that for calcium entry; but the Km for exodus is 14 mM, assuming that free calcium accumulates in vesicles. The difference in the affinity of calcium for the entry and exit processes observed during respiration is sufficient to account for the estimated 150-fold calcium concentration gradient achieved under steady-state conditions. The uptake system is specific for calcium as opposed to other cations, but zinc and lanthanum are effective competitors. Calcium uptake is blocked when electron is inhibited by exposure of vesicles to p-chlormercuriphenylsulfonate, hydroxyquinoline-N-oxide, or cyanide, or under anoxic conditions. Divalent cation ionophores (A23187 and X537A) and proton ionophores (CCP and gramicidin D) also block calcium transport effectively. The electrogenic potassium ionophore valinomycin has no effect on lactate-dependent calcium uptake in the presence of potassium; but ionophores which induce electroneutral exchange of protons for sodium or potassium (monensin and nigericin, respectively) did block calcium transport in the presence of the appropriate cation. The fluorescence intensity of quinacrine (an amine probe) in the presence of A. vinelandii membrane vesicles is reduced by 25% on addition of lactate; the quenching is blocked by CCP. This indicates that a pH gradient (inside acid) is developed across the vesicle membrane during lactate oxidation. These results indicate that these membrane preparations contain vesicles of inverted topology (with respect to the intact cell) and suggest that calcium transport occurs by means of electroneutral calcium/proton antiport.     

Photochemical and Nonphotochemical Fluorescence Quenching Processes in the Diatom Phaeodactylum tricornutum

Nonphotochemical fluorescence quenching was found to exist in the dark-adapted state in the diatom Phaeodactylum tricornutum. Pretreatment of cells with the uncoupler carbonylcyanide m-chlorophenylhydrazone (CCCP) or with nigericin resulted in increases in dark-adapted minimum and maximum fluorescence yields. This suggests that a pH gradient exists across the thylakoid membrane in the dark, which serves to quench fluorescence levels nonphotochemically. The physiological processes involved in establishing this proton gradient were sensitive to anaerobiosis and antimycin A. Based on these results, it is likely that this energization of the thylakoid membrane is due in part to chlororespiration, which involves oxygen-dependent electron flow through the plastoquinone pool. Chlororespiration has been shown previously to occur in diatoms. In addition, we observed that cells treated with 3-(3,4-dichlorophenyl)-1,1-dimethylurea exhibited very strong nonphotochemical quenching when illuminated with actinic light. The rate and extent of this quenching were light-intensity dependent. This quenching was reversed upon addition of CCCP or nigericin and was thus due primarily to the establishment of a pH gradient across the thylakoid membrane. Preincubation of cells with CCCP or nigericin or antimycin A completely abolished this quenching. Cyclic electron transport processes around photosystem I may be involved in establishing this proton gradient across the thylakoid membrane under conditions where linear electron transport is inhibited. At steady state under normal physiological conditions, the qualitative changes in photochemical and nonphotochemical fluorescence quenching at increasing photon flux densities were similar to those in higher plants. However, important quantitative differences existed at limiting and saturating intensities. Dissimilarities in the factors that regulate fluorescence quenching mechanisms in these organisms may account for these differences.     

The influence of energy-transfer inhibitors on proton permeability and photophosphorylation in normal and preilluminated Rhodospirillum rubrum chromatophores.

(1) Chromatophores were preilluminated in the presence of phenazine methosulphate or diaminodurene, and without phosphorylation substrates; next they were transferred to fresh medium and assayed for light-induced proton uptake, light-induced 9-aminoacridin fluorescence quenching, and photophosphorylation. (2) Preillumination in the presence of phenazine methosulphate or diaminodurene causes an inhibition of the photophosphorylation rate. The presence of ADP + MgCl2 + phosphate, or ADP + MgCl2 + arsenate during preillumination provides full protection against this effect. (3) Preilluminated chromatophores are leaky for protons. The leak is expressed as an accelerated dark decay, and a diminished extent of succinate-supported, light-induced proton uptake. The extent of light-induced 9-aminoacridin fluorescence quenching is also diminished. (4) The proton leak can be closed by oligomycin and by dicyclohexyl carbodiimide (at concentrations similar to those used to inhibit photophosphorylation), but not by aurovertin. Closure of the proton leak results in partial restoration of the photophosphorylation rate. (5) The inhibition of phosphorylation by oligomycin or dicyclohexyl carbodiimide is time-dependent. In untreated chromatophores, the time-dependence is determined by the extent of membrane energization. In preilluminated chromatophores, the time-dependence is determined in addition by the extent to which the proton leaks have been closed. The reasons for this are briefly discussed.     

The influence of energy-transfer inhibitors on proton permeability and photophosphorylation in normal and preilluminated Rhodospirillum rubrum chromatophores

(1) Chromatophores were preilluminated in the presence of phenazine methosulphate or diaminodurene, and without phosphorylation substrates; next they were transferred to fresh medium and assayed for light-induced proton uptake, light-induced 9-aminoacridin fluorescence quenching, and photophosphorylation.(2) Preillumination in the presence of phenazine methosulphate or diaminodurene causes an inhibition of the photophosphorylation rate. The presence of ADP + MgCl₂ + phosphate, or ADP + MgCl₂ + arsenate during preillumination provides full protection against this effect.(3) Preilluminated chromatophores are leaky for protons. The leak is expressed as an accelerated dark decay, and a diminished extent of succinate-supported, light-induced proton uptake. The extent of light-induced 9-aminoacridin fluorescence quenching is also diminished.(4) The proton leak can be closed by oligomycin and by dicyclohexyl carbodiimide (at concentrations similar to those used to inhibit photophosphorylation), but not by aurovertin. Closure of the proton leak results in partial restoration of the photophosphorylation rate.(5) The inhibition of phosphorylation by oligomycin or dicyclohexyl carbodiimide is time-dependent. In untreated chromatophores, the time-dependence is determined by the extent of membrane energization. In preilluminated chromatophores, the time-dependence is determined in addition by the extent to which the proton leaks have been closed. The reasons for this are briefly discussed.     

The electrochemical proton gradient in Escherichia coli membrane vesicles.

Membrane vesicles isolated from Escherichia coli grown under various conditions generate a transmembrane pH gradient (delta pH) of about 2 pH units (interior alkaline) under appropriate conditions when assayed by flow dialysis. Using the distribution of weak acids to measure delta pH and the distribution of the lipophilic cation triphenylmethylphosphonium to measure the electrical potential (delta psi) across the membrane, the vesicles are demonstrated to develop an electrochemical proton gradient (delta-muH+) of almost - 200 mV (interior negative and alkaline) at pH 5.5 in the presence of reduced phenazine methosulfate or D-lactate, the major component of which is a deltapH of about - 120 mV. As external pH is increased, deltapH decreases, reaching 0 at about pH 7.5 and above, while delta psi remains at about - 75 mV and internal pH remains at pH 7.5-7.8. The variations in deltapH correlate with changes in the oxidation of reduced phenazine methosulfate or D-lactate, both of which vary with external pH in a manner similar to that described for deltapH. Finally, deltapH and delta psi can be varied reciprocally in the presence of valinomycin and nigericin with little change in delta-muH+ and no change in respiratory activity. These data and those presented in the following paper (Ramos and Kaback 1976) provide strong support for the role of chemiosmotic phenomena in active transport and extend certain aspects of the chemiosmotic hypothesis.     

Evidence against proton gradient formation being the cause of chlorophyll fluorescence quenching by N-methylphenazonium methosulfate.

In strong illumination, 3-(3, 4-dichlorophenyl)-1,1-dimethylurea (DCMU)-poisoned chloroplasts exhibit a high yield of chlorophyll fluorescence while P-700 turnover, proton uptake, and phosphorylation are inhibited and a pH gradient is undectectable. When 10muM N-methylphenazonium methosulfate (PMS) is included, the fluorescence yield in light is substantially reduced, and when 100 muM ascorbate is also included, the yield is diminished approximately to the level in darkness. Only very slight increases in P-700 turnover and proton uptake (but no detectable pH gradient) accompany the fluorescence yield decline. When 10muM PMS and 15 mM ascorbate are added to poisoned chloroplasts (the oxygen concentration being greatly reduced), P-700 turnover, proton uptake, the pH gradient and phosphorylation all reach high levels. In this case, the yield of chlorophyll fluorescence is low and is the same in both light and dark. Further addition of an uncoupler eliminates proton uptake, the pH gradient and phosphorylation but does not significantly elevate the fluorescence yield. From these observations we suggest that, in DCMU-poisoned chloroplasts, the fluorescence quenching with PMS occurrs by a mechanism unrelated to the generation of a phosphyorylation potential. With chloroplasts unpoisoned by DCMU, PMS quenches fluorescence and considerably stimulates proton uptake, the pH gradient and phosphorylation. However, in this case, PMS serves to restore net electron transport.     

Suppression of flash-induced PSII-dependent electrogenesis caused by proton pumping in chloroplasts

Pre-illumination of the thylakoid membrane of Peperomia metallica chloroplasts leads to a reversible suppression of the flash-induced electrical potential as measured either with the electrochromic bandshift (P515), microelectrode impalement or patch-clamp technique. The energization-dependent potential suppression was not observed in the presence of 1 μ M nigericin suggesting the involvement of proton and/or cation gradients. Energization in the presence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) and N,N,N',N'-tetramethylphenylenediamine (TMPD), i.e. cyclic electron flow around photosystem (PS) I, results in the accumulation of TMPD⁺ in the thylakoid lumen. The reversible suppression of the flash-induced membrane potential was not observed in these conditions indicating that it is not a general cation-induced increase of membrane capacitance. Cyclic electron flow around PSI in the presence of DCMU and phenazine methosulfate (PMS) results in the accumulation of PMS⁺ and H⁺ in the thylakoid lumen. The absence of reversible suppression of the flash-induced membrane potential for this condition shows that accumulation of protons does not lead to (1) a reversible increase of membrane capacitance and (2) a reversible suppression of PSI-dependent electrogenesis. Reversible inactivation of PSII by a low pH in the thylakoid lumen is therefore proposed to be the cause for the temporary suppression of the flash-induced electrical potential. The flash-induced PSII-dependent membrane potential, as measured after major oxidation of P700 in far-red background light, was indeed found to be suppressed at low assay pH (pH 5) in isolated spinach ( Spinacia oleracea ) chloroplasts.     

Photoinactivation of photophosphorylation and dark ATPase in Rhodospirillum rubrum chromatophores

Preillumination of Rhodospirillum rubrum chromatophores with strong, far-red light in the presence of phenazine methosulfate under non-phosphorylation conditions results in a selective, irreversible inactivation (typically about 70%) of photophosphorylation and of uncoupler-stimulated dark ATPase. The time course of the photoinactivation is similar to the light-on kinetics of the light-induced proton uptake in the absence of ADP. Only little photoinactivation occurs when the uncoupler carbonyl cyanide m-chlorophenyl hydrazone is present or when phenazine methosulfate is absent during the preillumination, indicating that the reaction occurs only when the membrane is energized.

Phosphorylation conditions offer a practically complete protection against the photoinactivation. Inorganic phosphate, Mg²⁺ or ADP do not provide a significant protection against the photoinactivation, nor does ATP. The pH-dependence of the reaction(s) leading to photoinactivation may indicate that a partial reaction of the photophosphorylation process (perhaps only a conformational change of the coupling factor) precedes the photoinactivation.     

Photoinactivation of photophosphorylation and dark ATPase in Rhodospirillum rubrum chromatophores.

Preillumination of Rhodospirillum rubrum chromatophores with strong, far-red light in the presence of phenazine methosulfate under non-phosphorylation conditions results in a selective, irreversible inactivation (typically about 70%) of photophosphorylation and of uncoupler-stimulated dark ATPase. The time course of the photoinactivation is similar to the light-on kinetics of the light-induced proton uptake in the absence of ADP. Only little photoinactivation occurs when the uncoupler carbonyl cyanide m-chlorophenyl hydrazone is present or when phenazine methosulfate is absent during the preillumination, indicating that the reaction occurs only when the membrane is energized. Phosphorylation conditions offer a practically complete protection against the photoinactivation. Inorganic phosphate, Mg2+ or ADP do not provide a significant protection against the photoinactivation, nor does ATP. The pH-dependence of the reaction(s) leading to photoinactivation may indicate that a partial reaction of the photophosphorylation process (perhaps only a conformational change of the coupling factor) precedes the photoinactivation.     

The effects of tetraphenylboron on energy-linked reactions in spinach chloroplasts

1. The inhibitory action of tetraphenylboron, a lipid-soluble anion, on the proton uptake, the photophosphorylation and the light-induced quenching of the fluorescence of 9-aminoacridine by spinach chloroplasts was studied.2. The inhibition of the three processes by tetraphenylboron was transient; the proton uptake was affected to a much smaller extent than either the photophosphorylation or the fluorescence quenching.3. The inhibitory effects of tetraphenylboron on the proton uptake and the fluorescence quenching of 9-aminoacridine were qualitatively the same in CF₁-depleted chloroplasts, that were recoupled with N,N′-dicyclohexylcarbodiimide (DCCD).4. The reversal of the fluorescence quenching of 9-aminoacridine upon addition of tetraphenylboron in the light was found to be very fast, being completed within the response time of the apparatus.5. The presence of tetraalkylammonium salts in the incubation medium prevented the inhibitory effect of tetraphenylboron.6. Tetraphenylboron disappeared from the chloroplast suspension in a light-dependent irreversible way; in the dark no ‘ptake’ of tetraphenylboron could be detected.7. The effects of tetraphenylboron may be explained by the presence of groups with a high affinity for tetraphenylboron in the membrane; these groups become protonated upon illumination of the chloroplasts.     

Photosynthetic control, “energy-dependent” quenching of chlorophyll fluorescence and photophosphorylation under influence of tertiary amines

The effects of the tertiary amines tetracaine, brucine and dibucaine on photophosphorylation and control of photosynthetic electron transport in isolated chloroplasts of Spinacia oleracea were investigated. Tertiary amines inhibited photophosphorylation while the related electron transport decreased to the rates, observed under non-phosphorylating conditions. Light induced quenching of 9-aminoacridine fluorescence and uptake of ¹⁴C-labelled methylamine in the thylakoid lumen declined in parallel with photophosphorylation, indicating a decline of the transthylakoid proton gradient. In the presence of ionophoric uncouplers such as nigericin, no effect of tertiary amines on electron transport was seen in a range of concentration where photophosphorylation was inhibited. Under the influence of the tertiary amines tested, pH-dependent feed-back control of photosystem II, as indicated by energy-dependent quenching of chlorophyll fluorescence, was unaffected or even increased in a range of concentration where 9-aminoacridine fluorescence quenching and photophosphorylation were inhibited. The data are discussed with respect to a possible involvement of localized proton flow pathways in energy coupling and feed-back control of electron transport.Abbreviations 9-AA 9-aminoacridine - J _e flux of photosynthetic electron transport - PC photosynthetic control - pH₁ H⁺ concentration in the thylakoid lumen - pmf proton motive force - _P potential quantum yield of photochemistry of photosystem II (with open reaction centers) - Q _A primary quinone-type electron acceptor of photosystem II - q _Q photochemical quenching of chlorophyll fluorescence - q _E energy-dependent quenching of chlorophyll fluorescence - q _AA light-induced quenching of 9-amino-acridine fluorescence     

Localization of photophosphorylation and proton transport activities in various regions of the chloroplast lamellae

Membrane fragments released by French pressure cell treatment of whole chloroplasts and isolated by differential centrifugation have been characterized structurally and with respect to phosophorylating and proton transport activities. In agreement with results of other workers, the heavy fraction released by pressure treatment was found by electron microscopy studies to be made up of mostly intact grana stacks while the light fraction was comprised of vesicles derived from the stromal lamellae. Both fractions were found to carry out rapid rates of cyclic photophosphorylation catalyzed by phenazine methosulfate (PMS). However, only the grana membranes demonstrated active proton accumulation in the presence of PMS. No light induced H⁺ uptake could be detected in the stromal lamellae fraction; and as expected, proton gradient dissipating agents such as NH₄Cl, nigericin in the presence of K⁺, and gramicidin were only slightly inhibitory to phosphorylation at concentrations which were very inhibitory in the grana membrane fraction.

Further evidence that stromal lamellae do not have active proton transport in the intact chloroplast was obtained by comparing various chloroplasts having different amounts of stromal and grana membranes. Comparative studies on young and old chloroplasts from lettuce, mesophyll and bundle sheath cell plastids from sorghum, and greening plastids from etiolated corn seedlings revealed a direct correlation between the extent of grana formation and the amount of proton transport activity. Samples which had larger amounts of stromal lamellae had high rates of ATP formation but a reduced capacity for H⁺ accumulation.     

Evidence against proton gradient formation being the cause of chlorophyll fluorescence quenching by N-methylphenazonium methosulfate

In strong illumination, 3-(3,4-dichlorophenyl)-1, 1-dimethylurea (DCMU)-poisoned chloroplasts exhibit a high yield of chlorophyll fluorescence while $\text{P-700}$ turnover, proton uptake, and phosphorylation are inhibited and a pH gradient is undetectable. When 10 μM $\text{N-}\text{methylphenazonium}$ methosulfate (PMS) is included, the fluorescence yield in light is substantially reduced, and when 100 μM ascorbate is also included, the yield is diminished approximately to the level in darkness. Only very slight increases in $\text{P-700}$ turnover and proton uptake (but no detectable pH gradient) accompany the fluorescence yield decline.When 10 μM PMS and 15 mM ascorbate are added to poisoned chloroplasts (the oxygen concentration being greatly reduced), $\text{P-700}$ turnover, proton uptake, the pH gradient and phosphorylation all reach high levels. In this case, the yield of chlorophyll fluorescence is low and is the same in both light and dark. Further addition of an uncoupler eliminates proton uptake, the pH gradient and phosphorylation but does not significantly elevate the fluorescence yield. From these observations we suggest that, in DCMU-poisoned chloroplasts, the fluorescence quenching with PMS occurs by a mechanism unrelated to the generation of a phosphorylation potential.With chloroplasts unpoisoned by DCMU, PMS quenches fluorescence and considerably stimulates proton uptake, the pH gradient and phosphorylation. However, in this case, PMS serves to restore net electron transport.     

On the mechanism of the PMS-effected quenching of chloroplast fluorescence

Evidence is presented which suggests that N-methylphenazonium methosulfate suppresses the fluorescence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea-poisoned chloroplasts by two mechanisms: (i) indirectly, by catalyzing the buildup of the phosphorylating potential X_E across the thylaknid membrane; (ii) directly, by interacting with excited chlorophyll molecules.Arguments in support of direct quenching are as follows: (i) N-methylphenazonium methosulfate is an efficient quencher of the fluorescence of chlorophyll a in methanol; (ii) the dark-irreversible portion of the light-induced fluorescence lowering in the presence of N-methylphenazonium-methosulfate increases with the concentration of the cofactor, (iii) N-methylphenazonium methosulfate lowers the fluorescence of chloroplasts at an excitation that is too weak to allow formation of X_E.Ascorbate-reduced N-methylphenazonium methosulfate (PMS-SQ) is a more efficient direct quencher of chloroplast fluorescence than oxidized PMS because the thylakoid membrane is more permeable to the reduced species. The permeability to these quenchers is enhanced by the light-induced protonation of the membrane, and suppressed by added Mg²⁺. Different permeability barriers appear to exist for the direct and for the X_E-mediated quenching by N-methylphenazonium methosulfate, since the latter is known to be insensitive to the presence of Mg²⁺.     

Studies on 9-amino-6-chloro-2-methoxy acridine fluorescence quenching and enhancement in relation to energy transduction in spheroplasts and intact cells of the cyanobacterium Plectonema boryanum

The fluorescent probe 9-amino-6-chloro-2-methoxy acridine was used to study the energy transduction in the thylakoid and cell membranes of the cyanobacterium Plectonema boryanum. Apart from light-driven electron transfer, the dark endogenous respiration also leads to energization resulting in an ACMA fluorescence response, that is sensitive to the electron flow inhibitor 2, 5-dibromo-3-methyl-6-isopropyl-p-benzoquinone, to the energy transfer inhibitors dicyclohexylcarbodiimide and venturicidine and to the uncoupler 5-chloro-3-t-butyl-2-chloro-4-nitrosalicylanilide.In spheroplasts, in which the cell membranes have lost their capacity to maintain a proton gradient, the respiration-and light-induced ACMA fluorescence changes (quenching) are similar to those in chloroplasts. In intact cells a combination of reversible quenching and enhancement of ACMA fluorescence was found. This dualistic behaviour is supposedly caused by an opposite orientation of the thylakoid and cell membranes. ACMA quenching at the level of the thylakoids was obtained either by respiratory or photosynthetic electron transfer and gave similar responses to those obtained in the spheroplasts. The slower ACMA fluorescence enhancement, only observed in cells with intact cell membranes, also evoked by both respiration and light-induced energization is sensitive to the compounds mentioned above and in addition to KCN.Our results support the view [8] that dark oxidation of substrates by O₂ proceeds via the thylakoid membrane and terminates at a CN^- sensitive oxidase located in the cell membrane which requires the involvement of a mobile cytoplasmic redox mediator.Abbreviations ACMA 9-amino-6-chloro-2-methoxy acridine - chl a chlorophyll a - DBMIB 2, 5-dibromo-3-methyl-6-isopropyl-p-benzoquinone - DCCD dicyclohexylcarbodiimide - DNP dinitrophenol - DNP-INT dinitrophenyl ether of 2-iodo-4-nitrothymol - FCCP carbonylcyanide-p-trifluoro-methoxy phenylhydrazone - S-13 5-chloro-3-t-butyl-2-chloro-4-nitrosalicylanilide - tricine N-2 (2-Hydroxy-1, 1-bis (hydroxymethyl) ethyl)-glycine - Tris Tris (hydroxymethyl) amino methane     

Uptake of inorganic pyrophosphate by Bacillus megaterium

Cells of Bacillus megaterium take up inorganic pyrophosphate, employing a saturable carrier which is sensitive to sulfhydryl reagents, orthophosphate, and arsenate. Uptake is stimulated by proton ionophores, including CCCP and nigericin, indicating that proton cotransport can lead to an opposing gradient. Inhibitor sensitivity, as well a relatively high Km for inorganic pyrophosphate render it likely that uptake is mediated by an orthophosphate transport system.