Inhibition of photosynthetic electron transfer by amphotericin B

The polyene antibiotic amphotericin B inhibits photosynthetic electron transfer by Class II maize mesophyll chloroplasts, from water to FeCN, DCIP and diquat but not to plastocyanin. Photosystem 1 activity is also inhibited by amphotericin B, but ferredoxin-NADP reductase activity is not affected. The activity of all the photosynthetic electron transfer systems inhibited by amphotericin B can be restored by the addition of carrier amounts of plastocyanin. The results suggest that amphotericin B inhibits photosynthetic electron transfer by acting only at the plastocyanin site in the chain, and that the primary site of reduction of FeCN and DCIP from water by Class II chloroplasts lies on the reducing side of photosystem 1.     

The Effect of Polyene Antibiotics on Photosynthetic Electron Transfer

The effect of four polyene antibiotics and digitonin on photosyntheticelectron transfer by maize mesophyll chloroplasts has been investigated.All five compounds, at concentrations between 0.1 mM and 20mM, inhibited photosystem 2 activity as measured by the photo-reductionof ferricyanide and 2,6-dichlorophenolindophenol from water.Etruscomycin, amphotericin B, and digitonin were more inhibitorythan filipin and nystatin. Photosystem 1 activity was inhibitedby 1 mM concentrations of etruscomycin, amphotericin B, anddigitonin but not by filipin and nystatin. In all cases whereinhibition occurred, it was temperature dependent. The inhibition of photosystem 1 activity could be relieved byplastocyanin. Etruscomycin and digitonin, at concentrationsof 0.5 mM and above, caused disintegration of the chloroplasts,and this disintegration was accompanied by a two- to three-foldincrease in photosystem 1 activity in the presence of plastocyanin.It is concluded that the action of polyene antibiotics resultsin the release of plastocyanin from its site in the photosyntheticelectron transfer chain. The results are discussed in termsof the abilities of polyene antibiotics and digitonin to formcomplexes with sterols.     

Inhibition by dibromothymoquinone of photosynthetic electron transfer in chloroplasts of differing ultrastructure

The effect of the plastoquinone antagonist, dibromothymoquinone, on the photoreduction of ferricyanide and plastocyanin by maize mesophyll, maize bundle-sheath and Euglena gracilis chloroplasts has been investigated. Maximum inhibition of FeCN and plastocyanin reduction by mesophyll chloroplasts was obtained at dibromothymoquinone concentrations of 5 × 10^?7m. At higher concentrations dibromothymoquinone acted as an electron shuttle, increasing the rate of reduction of both substrates. In contrast, little inhibition of FeCN and plastocyanin reduction by bundle-sheath chloroplasts occurred at 5 × 10?7 m dibromothymoquinone, and above this concentration of inhibitor, the extent of inhibition increased, with no shuttle effect being observed. Euglena chloroplasts showed a response intermediate between that of mesophyll and bundle-sheath chloroplasts.The presence of a shuttle effect caused by dibromothymoquinone appears to be directly related to the presence of a proton pump in the chloroplast preparations. Plastocyanin is reduced by photosystem 2 alone and shows some of the properties of a class III electron acceptor, although the rates of reduction observed were much lower than those observed with lipophilic class III acceptors.     

Sedimentation equilibrium in reacting systems. VII. The temperature-dependent self-association of beta-lactoglobulin A at pH 2.46

The polyene antibiotic filipin inhibits the activities of both photosystem I and photosystem II in maize mesophyll chloroplasts and pea chloroplasts. Maximum inhibition of photosystem II activity was observed at a filipin concentration of about 0.4 mm in maize mesophyll chloroplasts and 1.0 mm in pea chloroplasts. Inhibition of photosystem II activity was temperature dependent, being much less if the antibiotic and chloroplasts were incubated at 0 °C compared to 25 °C. The inhibition of photosystem I activity of both maize mesophyll and pea chloroplasts caused by filipin, could be overcome by the addition of the soluble electron transfer protein, plastocyanin. It is concluded that the inhibition of photochemical activity caused by filipin is a secondary effect resulting from a change in membrane conformation induced by the antibiotic.     

Effect of metalloproteins on the photochemical activity of chloroplasts treated with polyene antibiotics]

The effects of various metall-containing proteins (plastocyanin, plantacyanin, azurine and cytochromes of the f type) on the activity of photosystem I of chloroplasts, treated with polyene antibiotics, were studied. The inhibiting effect of the polyenes, surgumycin and philipin, was completely removed by an addition of copper-containing protein plastocyanin. No similar effect was exerted by other Cu-containing proteins--azurine and plantacyanin. The cytochromes of the f type isolated from the green algae chlorella, blue-green algae spiruline and aphanezomenone, having different electrophoretic properties, restored the activity of photosystem I of chloroplasts incubated with antibiotics in a different degree. Acid cytochrome f of chlorella restored the activity by 80--100%; less acid cytochrome f from spiruline-only by 50%. The least restoring effect was exerted by aphanezomenone cytochrome, which possesses some basic properties. The chloroplasts treatment with surgumycin did not affect the isolation of the terminal enzyme of the chloroplast electron-transporting chain of ferredoxin--NADP--reductase. Possible environment of plastocyanin in the chloroplast membrane and the mechanism of photosystem I restoration are discussed.     

pH Dependence and Cofactor Requirements of Photochemical Reactions in Maize Chloroplasts

The pH dependence of the photoreduction of ferricyanide and the photoreduction of NADP from water and photosystem I activity have been compared in isolated chloroplasts from mesophyll and bundle sheath cells of Zea mays. The maximum activity of photoreduction of ferricyanide occurs at pH 8.5 in isolated mesophyll chloroplasts. The addition of methylamine does not cause a marked shift in the pH maximum, but brief sonication lowers the pH maximum to 7.0. In contrast, isolated bundle sheath chloroplasts have a pH maximum at 7.0 and the shape of the pH versus activity curve is similar to that of sonicated mesophyll chloroplasts. When photoreduction of ferricyanide by the isolated chloroplasts is measured at their pH maxima, the values for bundle sheath chloroplasts are about half those of methylamine-treated mesophyll chloroplasts on a chlorophyll basis.     

Evidence for multiple sites of ferricyanide reduction in chloroplasts

Various sites of ferricyanide reduction were studied in spinach chloroplasts. It was found that in the presence of dibromothymoquinone a fraction of ferricyanide reduction was dibromothymoquinone sensitive, implying that ferricyanide can be reduced by photosystem I as well as photosystem II. To separate ferricyanide reduction sites in photosystem II, orthophenanthroline and dichlorophenyl dimethylurea inhibitions were compared at various pH's. It was noted that at low pH ferricyanide reduction was not completely inhibited by orthophenanthroline. At high pH's, however, inhibition of ferricyanide reduction by orthophenanthroline was complete. It was found that varying concentration of orthophenanthroline at a constant pH showed different degrees of inhibition. In the study of ferricyanide reduction by photosystem II various treatments affecting plastocyanin were performed. It was found that Tween-20 or KCN treatments which inactivated plastocyanin did not completely inactivate ferricyanide reduction. These data support the conclusion that ferricyanide accepts electrons both before and after plastoquinone in photosystem II.Abbreviations DCMU 3-(3,4-dichlorophenyl)-1,1-dimethyurea - MV methyl viologen - DBMIB 2,5-dibromothymoquinone - DMBQ 2,6-dimethyl benzoquinone - OP 1,10-orthophenanthroline - TMPD tetramethyl-p-phenylenediamine - PS 1 photosystem I - PS II photosystem II - SN sucrose-sodium chloride chloroplasts Supported by NSF Grant BMS 74-19689.     

Evidence for multiple sites of ferricyanide reduction in chloroplasts.

Various sites of ferricyanide reduction were studied in spinach chloroplasts. It was found that in the presence of dibromothymoquinone a fraction of ferricyanide reduction was dibromothymoquinone sensitive, implying that ferricyanide can be reduced by photosystem I as well as photosystem II. To separate ferricyanide reduction sites in photosystem II, orthophenanthroline and dichlorophenyl dimethylurea inhibitions were compared at various pHs. It was noted that at low pH ferricyanide reduction was not completely inhibited by orothophenanthroline. At high pH's, however, inhibition of ferricyanide reduction by orthophenanthroline was complete. It was found that varying concentration of orthophenanthroline at a constant pH showed different degrees of inhibition. In the study of ferricyanide reduction by photosystem II various treatments affecting plastocyanin were performed. It was found that Tween-20 or KCN treatments which inactivated plastocyanin did not completely inactivate ferricyanide reduction. These data support the conclusion that ferricyanide accepts electrons both before and after plastoquinone in photosystem II.     

Mechanism of KCN inhibition of photosystem I.

Experiments with chloroplasts and purified spinach plastocyanin suggest a mechanism for KCN inhibition of Photosystem I. KCN inhibition can be bypassed by a detergent or reversed by replacement of the inactive plastocyanin. KCN bleaches and inactivates purified plastocyanin. KCN releases copper from chloroplast membranes and from purified plastocyanin. Cyanide does not bind to the apoprotein produced when plastocyanin is treated with KCN, and KCN-produced apoplastocyanin has a N-ethylmaleimide-reactive sulfhydryl group not found in holoplastocyanin. Apoplastocyanin is not active in restoring Photosystem I activity to plastocyanin-depleted membranes. Holoplastocyanin restores Photosystem I activities to plastocyanin-depleted membranes prepared from either control or KCN-treated chloroplasts to about the same extent. KCN-treated chloroplast membranes are found to have higher amounts of apoplastocyanin than do control chloroplast membranes. These results offer evidence that KCN removes the copper from plastocyanin in the chloroplast membrane, leaving the inactive apoplastocyanin which is unable to transfer electrons to Photosystem I.     

Plastocyanin participation in chloroplast Photosystem I

French pressure cell disruption of spinach chloroplasts releases much of the plastocyanin from chloroplast membranes. Heavy particles obtained from French pressure cell disrupted chloroplasts lose most of their plastocyanin while light particles retain a high plastocyanin to chlorophyll ratio. Photosystem I activity is dependent on the presence of plastocyanin in our preparations.     

Inhibition of photosynthetic electron transport by amphotericin B

By assaying partial reactions of the photosynthetic electron transport system using thylakoids from spinach as well as from the algae Bumilleriopsis, Dunaliella , and Anabaena , it was demonstrated that the polyene antibiotic amphotericin B has no specific effect on plastocyanin. Pretreating spinach and algal thylakoids with this antibiotic decreased photosystem-II as well as photosystem-I activity regardless of whether the membranes contained plastocyanin or cytochrome c-553. Different sensitivity of cell-free electron transport activity against this antibiotic was observed due to the species used. With Dunaliella , the photosystem-II region was inhibited more strongly than photosystem-I, while Bumilleriopsis chloroplasts – although not containing plastocyanin – exhibited a stronger inhibition of the photosystem-I region. Apparently, amphotericin B mainly solubilizes redox compounds that form connecting pools in the photosynthetic electron transport chain.     

Localization of the reaction side of plastocyanin from immunological and kinetic studies with inside-out thylakoid vesicles

(1) The effect of four active antisera against plastocyanin on Photosystem I-driven electron transport and phosphorylation was investigated in spinach chloroplasts. Partial inhibition of electron transport and stimulation of plastocyanin-dependent phosphorylation were sometimes observed after adding amounts of antibodies which were in large excess and not related to the plastocyanin content of the chloroplasts. This indicates effects of the antibodies on the membrane. (2) The antibodies against plastocyanin neither directly nor indirectly agglutinated unbroken chloroplast membranes. (3) The plastocyanin content of right-side-out and inside-out thylakoid vesicles isolated by aqueous polymer two-phase partition from chloroplasts disrupted by Yeda press treatment was determined by quantitative rocket electroimmunodiffusion. Right-side-out vesicles retained about 25%, inside-out vesicles none of the original amount of plastocyanin. (4) The effect of externally added plastocyanin on the reduction of P-700 was studied by monitoring the absorbance changes at 703 nm after a long flash. In inside-out vesicles P-700 was reduced by the added plastocyanin but not in right-side-out vesicles and class II chloroplasts. These results provide strong evidence for a function of plastocyanin at the internal side of the thylakoid membrane.     

Photoreduction of 2,6-dichlorophenolindophenol by diphenylcarbazide: a photosystem 2 reaction catalyzed by tris-washed chloroplasts and subchloroplast fragments

The use of diphenylcarbazide as an electron donor coupled to the photoreduction of 2,6-dichlorophenolindophenol by tris-washed chloroplasts or subchloroplast fragments provides a simple and sensitive assay for photosystem 2 of chloroplasts. By varying the concentration of tris buffer at pH 8.0 during an incubation period it is shown that the destruction of oxygen evolution activity is accompanied by a corresponding emergence of an ability to photooxidize diphenylcarbazide, as evidenced by absorbance changes due to diphenylcarbazide at 300 nm. The temperature-sensitive oxidation of diphenylcarbazide is inhibited by DCMU and by high ionic strengths. This activity appears to measure the primary photochemical reaction of photosystem 2.     

A new, light-induced absorbance change related to the reaction-center of photosystem II

A new, light-induced absorbance change centered at 591 nm wasfound during analysis of the effect of preliminary illuminationon ferricyanide photoreduction in spinach chloroplasts. Thisabsorbance change is believed to come from a chloroplast componentfunctionally related to the reaction-center of photosystem IIfor the following reasons: (1) It occurred rapidly upon illumination.(2) It was driven by only PS-II light. (3) It was observed evenat 77 K. (4) It was observed with subchloroplast preparationsenriched in the reaction-center of PS-II. (Received October 23, 1978; )     

Effect of light quality on the organization of photosynthetic electron transport chain of pea seedlings

The activity of NADP and O₂ photoreduction by water is essentially higher in chloroplasts isolated from pea seedlings (Pisum sativum L.) grown under blue light as compared with that from plants grown under red light. In contrast, the photoreduction of NADP and O₂ with photosystem I only is practically the same or even lower in chloroplasts isolated from plants grown under blue light. The addition of plastocyanin does not affect the rate or the extent of NADP photoreduction by water in the chloroplasts isolated from plants grown under blue light, whereas it sharply activates NADP reduction in the chloroplasts isolated from plants grown under red light. The extent of the light-induced oxidation of cytochrome f is appreciably higher in chloroplasts isolated from plants grown under blue light. Cytochrome b₅₅₉ plays the predominant role in the oxidoreductive reactions of these chloroplasts. Furthermore, the fluorescence measurements indicate more effective transfer of excitation energy from chlorophyll to the photosystem II reaction center in chloroplasts isolated from plants grown under blue light.     

Kinetic analysis of P-700 photoconversion: Effect of secondary electron donation and plastocyanin inhibition

The kinetics of P-700 photoconversion under weak continuous actinic illumination were quantitatively analyzed to provide information on the relative absorption cross-section σ_PSI of the light-harvesting pigments associated with photosystem I and on the number of electrons stored between the two photosystems in dark-adapted chloroplasts. The theory of chemical kinetics for a system of monomolecular consecutive first-order reactions is reviewed briefly to provide support for the experimental approach taken. A complete inhibition of plastocyanin by cyanide eliminated all secondary electron donation to P-700⁺ and allowed the registration of the exponential (monomolecular) P-700 photoconversion at room temperature. The rate constant K_p-700 of the exponential kinetics was independent of the ionic (± Mg²⁺) and osmotic (± sucrose) strength of the chloroplast suspension medium, and of the oxidation-reduction state of photosystem II. The extent of plastocyanin inhibition in partially inhibited samples was greater under low ionic and low osmotic conditions. In dark-adapted chloroplast samples that were not cyanide treated, the number of electrons stored between the two photosystems was 3.9 ± 0.2 and independent of divalent cations. It is concluded that plastocyanin inhibition by cyanide is favored under low ionic and low osmotic conditions. The Mg²⁺ ion and redox state of photosystem II-independent photoconversion of P-700 does not support significant changes in the spillover of excitation from photosystem II to photosystem I in isolated chloroplasts.     

Electron paramagnetic resonance saturation studies of P-700+ reaction center chlorophyll in plant photosynthesis

Electron paramagnetic resonance (EPR) power saturation and saturation recovery methods have been used to determine the spin lattice, T1, and spin-spin, T2, relaxation times of P-700+ reaction-center chlorophyll in Photosystem I of plant chloroplasts for 10 K less than or equal to T less than or equal to 100 K. T1 was 200 mus at 100 K and increased to 900 mus at 10 K. T2 was 40 ns at 40 K and increased to 100 ns at 10 K. T1 for 40 K less than or equal to T less than or equal to 100 K is inversely proportional to temperature, which is evidence of a direct-lattice relaxation process. At T = 20 K, T1 deviates from the 1/T dependence, indicating a cross relaxation process with an unidentified paramagnetic species. The individual effects of ascorbate and ferricyanide on T1 of P-700+ were examined: T1 of P-700+ was not affected by adding 10 mM ascorbate to digitonin-treated chloroplast fragments (D144 fragments). The P-700+ relaxation time in broken chloroplasts treated with 10 mM ferricyanide was 4-times shorter than in the untreated control at 40 K. Ferricyanide appears to be relaxing the P-700+ indirectly to the lattice by a cross-relaxation process. The possibility of dipolar-spin broadening of P-700+ due to either the iron sulfur center A or plastocyanin was examined by determining the spin-packet linewidth for P-700+ when center A and plastocyanin were in either the reduced or oxidized states. Neither reduced center A nor oxidized plastocyanin was capable of broadening the spin-packet linewidth of P-700+ signal. The absence of dipolar broadening indicates that both center A and plastocyanin are located at a distance at least 3.0 nm from the P-700+ reaction center chlorophyll. This evidence supports previous hypotheses that the electron donor and acceptor to P-700 are situated on opposite sides of the chloroplast membrane. It is also shown that the ratio of photo-oxidized P-700 to photoreduced centers A and B at low temperature is 2 : 1 if P-700 is monitored at a nonsaturating microwave power.     

Absorption and Transfer of Light and Photoreduction Activities of Spinach Chloroplasts under Calcium Deficiency: Promotion by Cerium

Chloroplasts were isolated from spinach cultured in calcium-deficient, cerium-chloride-administered calcium-present Hoagland’s media or that of calcium-deficient Hoagland’s media and demonstrated the effects of cerium on distribution of light energy between photosystems II and I and photochemical activities of spinach chloroplast grown in calcium-deficient media. It was observed that calcium deprivation significantly inhibited light absorption, energy transfer from LHCII to photosystemII, excitation energy distribution from PSI to PSII, and transformation from light energy to electron energy and oxygen evolution of chloroplasts. However, cerium treatment to calcium-deficient chloroplasts could obviously improve light absorption and excitation energy distribution from photosystem I to photosystem II and increase activity of whole chain electron transport, photosystems II and I DCPIP photoreduction, and oxygen evolution of chloroplasts. The results suggested that cerium under calcium deficiency condition could substitute for calcium in chloroplasts, maintain the stability of chloroplast membrane, and improve photosynthesis of spinach chloroplast, but the mechanisms still need further study.     

A Lipid Requirement for Photosystem I Activity in Heptane-extracted Spinach Chloroplasts

A lipid requirement for photosystem I activity in Spinacia oleracea chloroplasts has been characterized. The transfer of electrons from tetramethyl-p-phenylenediamine through the chloroplast photosystem to viologen dye was used as an assay of photosystem I activity. Activity is diminished by prolonged heptane extraction and is partially restored by readdition of the extracted lipid. Extracted chloroplasts require plastocyanin for maximal restoration of activity. The effect of lipid extract in restoration is partially replaced by triglycerides containing unsaturated, C₁₈ fatty acids. Various potential redox carriers which occur naturally in chloroplasts do not substitute for extracted lipid. Galacto-lipids, sulfolipids, and phospholipids are not involved in the restoration of activity.     

The Effect of Antibiotics on the Ultrastructure and Photochemical Activity of a Developing Chloroplast

The effects of the antibiotics chloramphenicol and cycloheximideon the ultrastructure of the chloroplast in greening cells ofEuglena gracilis strain Z have been investigated. The rate ofchloroplaat development in the presence of either antibioticwas closely related to that of chlorophyll production. Chloramphenicol,which at 10 mg/ml inhibits chlorophyll synthesis but not celldivision, caused a marked inhibition of the development of chloroplaststructure. The chloroplasts were smaller than those of untreatedcells and contained a smaller number of internal lamellae. Mostof these lamellae were not appressed and the results supportthe suggestion that chloramphenicol inhibits the synthesis ofa protein responsible for the fusion of individual lamellaein the chloroplast. Measurement of the photochemical activityof chloroplasts isolated from chloramphenicol-treated cellsshowed that the photoreduction of NADP from water (photosystemI+II), photosystem II activity, and photosystem I activity weregreatly inhibited when compared with chloroplasts from untreatedcells. In contrast, cycloheximide at 2.5 to 5.0 µg/mlinhibited cell division but allowed the chloroplasts to developafter a lag phase, the length of which was related to the concentrationof antibiotic employed. The number of lamellae per chloroplastand the degree of appression of the lamellae in chloroplastsof cycloheximide-treated cells and untreated cells were comparable.After 48-h illumination the photochemical activities of chloroplastsisolated from cycloheximide-treated cells were about 50 percent of those of the untreated cells.