PHOTOINDUCED ONE-ELECTRON TRANSFER BETWEEN BACTERIOCHLOROPHYLL AND QUINONE IN ACETONE*

Abstract— Illumination with red light of a degassed solution of bacteriochlorophyll and benzoquinone or ubiquinone in dry acetone at low temperatures (< - 105°C) leads to the formation of the bacteriochlorophyll cation radical and the quinone anion radical, as detected by ESR spectroscopy. At temperatures around - 110°C, the quinone radical signal corresponds to an emission of microwave radiation. These results are interpreted in terms of a one-electron transfer from a spin-polarized bacteriochlorophyll triplet state to the quinone, producing an anion radical which is predominantly in the upper spin state.     

A REACTION BETWEEN PHEOPHYTIN and CHLOROPHYLL ADSORBED TO POLYETHYLENE-TETRADECANE PARTICLES*

Abstract— When chlorophyll is adsorbed to polyethylene-tetradecane particles along with ligating amphiphiles, and pheophytin is present also, a slow but irreversible photobleaching of the chlorophyll is observed in suspensions of the particles in aqueous media. It is suggested that the reaction starts by transfer of an electron from singlet excited chlorophyll to pheophytin and concludes by hydration and reduction of the chlorophyll radical cation.     

CHLOROPHYLL ONE-ELECTRON PHOTOCHEMISTRY-I. PHOTOPRODUCTION OF THE CATION RADICALS OF CHLOROPHYLL AND BACTERIOCHLOROPHYLL IN SOLUTIONS AT LOW TEMPERATURES*

Abstract— Electron spin resonance studies have shown that chlorophyll and bacteriochlorophyll can be photo-oxidized in a variety of solvents via their lowest excited singlet states to produce cation radicals. Pheophytin does not undergo this reaction. The mechanism of this photoprocess and its implications for photosynthesis are discussed.     

THE CHLOROPHYLL-SENSITIZED REACTION BETWEEN BENZOQUINONE AND ETHANOL*

The electron-transfer reaction between triplet excited chlorophyll and quinones has been extensively studied as a model of the primary reaction in photosystem II. There has also been reported a minor reaction in which the chlorophyll cation radical ostensibly oxidizes the alcohol solvent or even water, leading to a gradual net reduction of quinone, but the exact mechanism and even the existence of this reaction has been uncertain. We have examined the consequences of prolonged irradation of ethyl chlorophyllide and benzoquinone in acidulated ethanol, and find a chlorophyllide-sensitized reaction which is not analogous to the better-known autosensitized reduction of quinones in blue or UV light. In the chlorophyllide-sensitized reaction, benzoquinone is apparently converted to ethoxy-substituted quinones and quinols, and polymeric material. Ethyl chlorophyllide (or chlorophyll) is simultaneously oxidized to more polar products which themselves continue to photosensitize the reaction of quinones. The production of acetaldehyde could not be demonstrated in the sensitized reaction. Chlorophyllide-sensitized reaction of (l-hydroxyethyl)benzoquinone, ethoxybenzoquinone and 2.5-diethoxybenzo-quinone were examined for additional information. A reaction sequence, tentatively proposed to accommodate the known facts, starts with oxidative attack by quinone on an oxidized chlorophyllide radical formed by loss of a hydroxyl proton from alcohol bound as a ligand to Mg²⁺. It is not likely that this reaction is closely related to events at the oxidizing side of photosystem II.     

LIGHT-INDUCED ELECTRON TRANSFER REACTIONS BETWEEN CHLOROPHYLL AND QUINONE IN LIPOSOMES: RADICAL FORMATION AND DECAY IN NEGATIVELY AND POSITIVELY CHARGED VESICLES*

Abstract— The incorporation of relatively small amounts (≤ 20 mol%) of a negatively charged surfactant into otherwise electrically neutral phosphatidylcholine vesicles containing chlorophyll in the presence of benzoquinone has been shown to produce large effects on radical formation and decay as measured by laser flash photolysis. When salt ions are present in the aqueous phase, increasing the level of negative surfactant leads to a small increase in radical yield, followed by a larger decrease in radical yield. When the salt concentration is low, increasing the negative surfactant concentration leads to a suppression of the fast radical recombination process, an increase in slow radical decay and, at the highest surfactant concentration, an approximately 35% increase in total radical yield. An analysis of these effects is given in terms of the influence of a negative electrostatic field on radical pair stabilization and recombination, radical pair separation and expulsion of the acceptor radical anion from the vesicle. The incorporation of relatively small amounts (≤ 20 mol%) of a positively charged surfactant into egg phosphatidylcholine (EPC) vesicles containing chlorophyll and benzoquinone also produces large effects on radical formation and decay. When the electrolyte concentration in the suspending aqueous medium is high, radical yields are decreased as the surfactant concentration is increased, without any appreciable effect on decay kinetics. When deionized water is used, the slow recombination component of the decay is specifically suppressed by the presence of the positive surfactant, whereas the fast decay component decreased and then increased in amount as the surfactant concentration is increased. In all cases, however, the total radical yield is less than in pure EPC vesicles. These results can be understood in terms of the influence of a positive electrostatic field on radical pair separation and acceptor radical anion mobility. When equimolar amounts of both positively and negatively charged surfactants are incorporated into EPC vesicles, the radical yields and decay kinetics are relatively unaffected, but a large effect is observed on the radical difference spectrum. This may be a consequence of clustering of oppositely charged molecules within the bilayer surface.     

SPECTRAL PROPERTIES OF CHLOROPHYLL a MONOLAYERS: MONOLAYERS OF CHLOROPHYLL a AND PHEOPHYTIN AT A GAS-WATER INTERFACE*

Abstract— Surface and spectral properties of chlorophyll a monolayers were studied at a nitrogen-water interface. Direct spectral analysis of Chl monolayers indicated that compression results in a heterogenous mixture of Chl species. Fourth derivative and difference spectra showed the presence of minor bands at 692, 726 and 748 nm. The state of compression determines the quantity and type of spectral species formed. A Chl monolayer on an acid subphase results in the formation of a long wavelength absorbing species (705 nm) similar to that of pheophytin. The half-band width, optical density/monolayer, and extinction coefficients of Chl monolayers are given. It is concluded that in the monolayer the formation of various aggregated species of Chl can be induced.     

CHLOROPHYLL ONE-ELECTRON PHOTOCHEMISTRY: FLASH PHOTOLYSIS STUDIES OF THE CHLOROPHYLL-QUINONE REACTION IN ALCOHOL SOLVENTS*

Abstract— Flash photolysis of chlorophyll a alone in CBE (cyclohexanol-t-butanol-ethanol) yields a difference spectrum similar to those obtained upon steady illumination of chlorophyll a-quinone mixtures in this solvent. Decay kinetics in CBE and dimethylsulfoxide are faster at the Soret band than at 460–580 nm and red band regions. This difference is not obtained in other solvents (CHCI₃, CCI₄, t-butanol, ethanol), implying that two or more species are obtained in CBE and DMSO. β-Carotene in CBE increases the rate of decay of the flash-induced chlorophyll transients at 430 and 660 nm but only decreases the magnitude of the signal at 470 nm. This implies that the 470 nm absorbance is due to a product formed from the triplet state. This effect is not observed in ethanol. Adding quinone to chlorophyll solutions results in slowly decaying species being generated by flash excitation in CBE. Three components can be distinguished: the first (t_1/2? 0.2 msec) corresponds to the triplet state; the second (t_1/2= 5–10 msec) is quinone concentration and species independent; the third (t_1/2= several seconds) is dependent upon quinone concentration and species (rate is faster for higher concentrations and lower potential quinones). The ESR signal decay rate is approximately equal to the third component flash decay rate when the chlorophyll and quinone concentrations are equal. With excess quinone, the flash decay rate becomes faster, and the ESR decay rate decreases slightly. These slowly-decaying species are not produced when quinone is added to chlorophyll a in ethanol or t-butanol, or to pheophytin in CBE. One observes merely a decrease in signal height with no accompanying increase in decay rate. Mechanisms to account for all of these phenomena are presented which involve an initial chlorophyll triplet-solvent reaction with the subsequent formation of several species of chloro-phyll-quinone radical complexes.     

TRANSFER OF ENERGY FROM REACTION CENTER TO LIGHT HARVESTING CHLOROPHYLL IN A PHOTOSYNTHETIC BACTERIUM*

Abstract— Previous evidence indicates that energy transfer in photosynthetic bacteria can occur from reaction center to light harvesting chlorophyll (the reverse of the usually considered flow) and that the amount of this flow depends on the strain of bacteria. The present report demonstrates that the action spectrum for fluorescence of Rhodopseudomonas spheroides, strain R26, is changed by adding the strong reductant dithionite. This change indicates that the amount of reverse flow can be altered chemically. The amount of reverse flow inferred from these measurements is consistent with the amount predicted from the absorption and fluorescence spectra of chromatophores and isolated reaction centers, and from the relative fluorescence yields of these two. The measurements permit an estimate of the transfer rates describing the energy flow from light harvesting to reaction center chlorophyll as well as the reverse flow. The spectrum for delayed fluorescence of Rps. spheroides, strain Ga, was found to be similar to that of the variable part of the fluorescence. This is a necessary, but not sufficient, condition that the energy for delayed fluorescence originates in the reaction centers.     

CHLOROPHYLL PHOTOCHEMISTRY IN CONDENSED MEDIA—II. TRIPLET STATE QUENCHING AND ELECTRON TRANSFER TO QUINONE IN LIPOSOMES*

The fate of excitation energy and electron transfer to quinones within Chl-a-containing phosphatidyl choline liposomes has been investigated. The bilayer membrane of the liposome stabilizes the Chl triplet state, as evidenced by a three-fold increase in the lifetime over that observed in ethanol solution. The relative triplet yield follows the relative fluorescence yield, indicative of quenching at the singlet level. Triplet state lifetimes are markedly shortened as the Chl concentration is increased, demonstrating that quenching occurs at the triplet level as well. This process is shown to be due to a collisional de-excitation. In the presence of quinones, the Chl triplet reduces the quinone resulting in production of long-lived electron transfer products. The percent conversion of Chl triplet to cation radical when benzoquinone is employed as acceptor is approximately 60 ± 10%, which is slightly less than in ethanol solution (70 ± 10%). The lifetime of the radical, however, can be as much as 1900 times longer. With respect to potentially useful photochemical energy conversion, the magnitude of this increased lifetime is far more significant than is the decreased radical yield.     

REVERSIBLE LIGHT-TNDUCED SINGLE ELECTRON TRANSFER REACTIONS BETWEEN CHLOROPHYLL AND HYDROQUINONE IN SOLUTION*

Abstract— EPR and optical studies demonstrate the occurrence of reversible temperature-independent light-induced single electron transfer reactions between chlorophyll (and pheophytin) and hydroquinone in degassed ethanol solutions. Oxygen is shown to quench this process, presumably by interacting with chlorophyll excited states. Pyridine and isoquino-line increase the effectiveness of the hydroquinone as an electron donor to chlorophyll, probably by acting as bases to form hydroquinone anions (or perhaps ion-pairs) which are more easily oxidized. Hydroquinone is found to be more effective in electron transfer than is benzoquinone, suggesting that the chlorophyll excited state is a better oxidizing agent than it is a reducing agent.     

LIGHT-INDUCED ELECTRON TRANSFER REACTIONS BETWEEN CHLOROPHYLL AND QUINONE IN ELECTRICALLY-CHARGED VESICLES: EFFECTS OF COUNTERIONS LOCATED IN EITHER THE INNER OR OUTER AQUEOUS PHASES ON RADICAL FORMATION AND DECAY*

Abstract— The presence of relatively low concentrations of counterions (millimolar in the case of univalent ions and micromolar in the case of polyvalent ions) in either the inner or outer aqueous compartments of electrically charged lipid bilayer vesicles containing chlorophyll in the presence of benzoquinone has been shown to produce large effects on radical formation and decay as measured by laser flash photolysis. With negatively charged vesicles having no added salt inside, salt ions added to the external phase caused radical yields to markedly decrease, with no change in decay kinetics. When salt was present only in the interior phase, radical decay became biphasic and the ability of externally added salt to affect radical yields was greatly diminished. With positively charged vesicles having no added salt inside, salt addition to the external medium caused both the radical decay rate and yield to decrease. The presence of interior salt, however, caused radical decay to become faster and, as was the case with negative vesicles, greatly reduced the effects of salt added externally. These results have been interpreted in terms of electrostatic and structural effects of charge neutralization by counterions on the dynamics of radical-ion separation and recombination.     

REACTION OF EXCITED CHLOROPHYLL MOLECULES AT ELECTRODES AND IN PHOTOSYNTHESIS*

Abstract— Excited molecules can exchange electrons with suitable electrodes in an electrochemical cell. Excitation energy of molecules can therefore be converted into electrochemical energy. Electrochemical reactions of excited chlorophyll molecules have been investigated with the help of semiconductor electrodes. It is suggested that this type of reaction also occurs during the primary steps of photosynthesis. Consequently, concepts of electrochemical kinetics would have to be applied in order to elucidate chlorophyll-sensitized reactions in photosynthetic membranes. In order to provide evidence for this conclusion, electrochemical kinetics is applied to the calculation of decay of delayed light from photosynthetic membranes, and the result is compared with experimental data from Chlorella pyrenoidosa. The conversion of light into electrochemical energy via photoelectrochemical reactions of organic dyes in an electrochemical cell is demonstrated, and the postulated analogous electrochemical mechanism for photosynthesis is discussed.     

ESR STUDIES OF CHLOROPHYLL ONE-ELECTRON PHOTOCHEMISTRY: KINETICS AND MECHANISM OF REVERSIBLE HYDROQUINONE OXIDATION IN SOLUTION*

Abstract— ESR studies have been made of the kinetics of semiquinone radical formation and disappearance resulting from the reversible photosensitization by chlorophyll of hydroquinone oxidation in a pyridine-water solvent. The rate of radical decay was found to be second order with respect to the radical concentration, with a rate constant of 6.7 × 10⁵ l./mole sec at -30°C and an activation energy of 6900 cal/mole. The rate of radical formation was recombination-limited and, through the use of β-carotene as a quencher, the rate constant was determined to be 8.81 × 10⁵ l./mole sec at -30°C. The effect of light intensity and hydroquinone concentration on the rate of semiquinone radical formation and on the steady state radical concentration was also investigated and possible mechanisms to explain the results are discussed.     

PHOTOCHEMISTRY AND SPECTROSCOPY OF CHLOROPHYLL, BACTERIOCHLOROPHYLL AND BACTERIOVIRIDIN IN MODEL SYSTEMS AND PHOTOSYNTHETIZING ORGANISMS

Abstract— In the system (electron donor—pigment—electron acceptor), the photosensitising pigment transfers an electron (hydrogen) from the donor to the acceptor by converting light energy, absorbed by the pigment, into the potential chemical energy of the products. The dependence of the reaction of excited pigments with electron donors or acceptors on the magnitude of the electron affinity of the reacting molecules, the nature of the medium, and the experimental conditions was observed. The initial photo-process was seen to involve the formation of free radicals, with the subsequent formation of compounds with saturated valencies. The reverse reaction of the photoproducts was accompanied by chemiluminescence. The study of systems containing pyridinenucleotides showed the possibility of photosensitised oxidation—reduction of these compounds by a pigment, and of direct photooxidation of reduced pyridinenucleotides by an electron acceptor of a different kind. In order to understand the specific photo-transfer of an electron in organisms, the spectral properties of pigments in organisms were compared with the properties of model pigments in monomeric and aggregated forms. It was established that the main role in the spectroscopic properties shown by bacteriochlorophyll, bacterioviridin and chloropyll in organisms is played by various types of intermolecular interactions (aggregations). Different forms of pigment may be involved in different stages of the phototransfer of an electron.     

CHLOROPHYLL PHOTOCHEMISTRY IN CONDENSED MEDIA—I. TRIPLET STATE QUENCHING AND ELECTRON TRANSFER TO QUINONE IN CELLULOSE ACETATE FILMS*

Chlorophyll-a was incorporated into cellulose acetate films and the triplet state decay kinetics and electron transfer from triplet to p-benzoquinone in aqueous solution was studied using laser flash photolysis and EPR. The triplet was found to decay by first order kinetics with a rate constant which was independent of Chl concentration. The triplet yield, however, was concentration dependent. These properties are due to quenching which occurs only at the singlet state level. In the presence of quinone, the triplet is quenched and, when the quinone is in an aqueous solution in contact with the film, Chl cation radical (C^±) as well as the semiquinone anion radical (Q^±) can be observed. The C decays by second order kinetics with a rate constant of 1.5 × 10⁶M^-1 s^-1. Although triplet conversion to radicals is slightly lower in the films as compared to fluid solutions (? 3 times), the lifetimes of the radicals are greatly increased (? 10³ times).     

PHOTOOXIDATION OF CHLOROPHYLL AND PHEOPHYTIN. QUENCHING OF SINGLET OXYGEN AND INFLUENCE OF THE MICELLAR STRUCTURE

Abstract— When chlorophyll(Chl) and pheophytin(Phn) are irradiated in Triton X-100 water binary solvents, singlet oxygen is formed in the medium in a higher yield for Phn than for Chi. Chlorophyll shows an irreversible photooxidation reaction and a chemical oxidation reaction when 1,3-diphenyliso-benzofuran (DPBF) is added to the solution. During the chemical oxidation, Chi is destroyed by an oxidizing agent that is a reaction product of the endoperoxide formed in the medium by the addition of singlet oxygen to DPBF. This reaction depends on the structure of the medium and has some characteristics of an oxidation by hydroxyl radicals. The highest yield is obtained with the micellar structure. Chlorophyll and Phn are readily oxidized by hydroxyl radicals generated using the Fenton reagent. This suggests that in the presence of Triton X-100, the Mg²⁺ ion of a Chi molecule plays a key role in the irreversible oxidation of the pigment.     

FAR-INFRARED SPECTRA OF LANGMUIR-BLODGETT FILMS OF CHLOROPHYLL a,CHLOROPHYLL b,PHEOPHYTIN a and THEIR ADDUCTS WITH WATER and DIOXANE*

Fourier transform infrared spectra in the low frequency region (500–150cm^?1) of Langmuir-Blodgett films of chlorophyll a (Chi a), chlorophyll b (Chi b) and pheophytin a have been studied. Correlations between spectral changes in monolayer and multilayers of Chi a and Chi b and their adducts with water and dioxane have been established. Spectroscopic evidence has indicated that, although there are no individual absorption bands that can be assigned to pure Mg-nitrogen and/or Mg-oxygen stretching or bending modes, there are several bands in the400–200 cm^?1 region of the spectra containing considerable contributions from metal-nitrogen and metal-oxygen vibrational modes. These specific vibrations exhibit marked intensity changes and shifts upon water and dioxane interaction. The different states of chlorophyll aggregation in Langmuir-Blodgett mono- and multilayers films resulted in noticeable changes in their far-IR spectra.     

EXCITATION TRANSFER BY CHLOROPHYLL a IN MONOLAYERS AND THE INTERACTION WITH CHLOROPLAST GLYCOLIPIDS*

In mixed monolayers with purified chloroplast glycolipids and other colorless lipids, chlorophyll a fluorescence exhibits a decrease in quantum efficiency with increasing chlorophyll concentration. The fluorescence, which is strongly polarized in dilute films, becomes progressively depolarized as the area fraction of chlorophyll increases, and it is completely depolarized in a pure chlorophyll a monolayer. The observed behavior is consistent with an inductive resonance mechanism of energy transfer among the chlorophyll molecules with a critical transfer distance of 20–90 Å, depending on the model chosen for the energy transfer mechanism. The purified glycolipids–mono-and digalactosyl diglycerides and sulfoquinovodiglyceride–separately form stable, compressible monolayers of the liquid-expanded type on an aqueous subphase and in an atompshere of nitrogen. At maximum compression the three glycolipids occupy areas of 55, 80 and 47 A²-molecule^-1, respectively, in the monolayer. Mixed monolayers of chlorophyll a with, separately, the monogalactolipid and the sulfolipid behave upon compression as two-dimensional solutions. The fluorescence polarization at high chlorophyll concentrations in mixed monolayers indicates that several of the lipid diluents facilitate local ordering of the pigment molecules.     

PHOTOELECTRON TRANSFER BETWEEN A CHARGED DERIVATIVE OF CHLOROPHYLL AND FERRICYANIDE AT THE LIPID BILAYER-WATER INTERFACE

Abstract— Flash illumination of a lipid bilayer containing a positively charge pigment: chlorophyll b cholyl hydrazone and separating two salt solutions, one of which contained ferricyanide, resulted in a photovoltage of ∼20mV, acceptor side negative. The positive charge on the pigment resulted in several novel effects. (1) The photo-emf is twice that of chlorophyll a and five times that of chlorophyll b at a given concentration. A higher surface concentration of the charged derivative is the likely cause of this effect. (2) The pheophytin of chlorophyll b cholyl hydrazone produces about one-half the photo emf of the magnesium derivative whereas pheophytin a or b produced only one-tenth the signal. This may be a reflection of the changed redox potential of the cation chlorophyll b cholyl hydrazone. (3) A voltage drop of 100 mV across the membrane, the acceptor side negatively biased, causes a 3–4-fold increase in the charge recombination rate. Biasing the acceptor side 100 mV positive has no effect. Chlorophyll a or b do not show this field effect. This asymmetric effect is explained as a movement of the more polar chlorophyll dication towards the water interface, leading to more rapid reaction with donor. Thus the kinetics of the charge reversal are a sensitive and specific probe of the polar interfacial region of the lipid bilayer-water interface.     

PHOTOSENSITIZATION OF ANTICANCER AGENTS-8. ONE-ELECTRON REDUCTION OF MITOXANTRONE: AN EPR AND SPECTROPHOTOMETRIC STUDY

An efficient method of one-electron reduction of the anticancer agent mitoxantrone is described. The method depends on illumination of a suitable photosensitizer absorbing blue light [acriflavine, anthrapyrazole, or Ru(bpy)2+(3)] in the presence of the drug and an electron donor, such as NAD(P)H, in deaerated solutions. An EPR spectrum, assigned to a semiquinone of mitoxantrone, is generated under these conditions and identified by spectral simulation. Decay of this species, attributed to a radical-radical reaction, gives a second order rate constant of 1.7 x 10(2) M-1 s-1 in organic media [dimethylsulfoxide (DMSO)/pH 8 buffer, 1:1 vol/vol] but is more rapid (approximately 10(4) M-1 s-1) in aqueous media under comparable conditions. The considerably decreased lifetime of the mitoxantrone radical at pH 5 is attributed to an additional electron transfer, promoted by protonation of the radical, and/or to an accelerated recombination of neutral radicals, leading to an EPR-silent species. Parallel spectrophotometric studies on the generation of the mitoxantrone reduced species by photosensitized reduction are described. The method offers convenient access to a key radical species involved in the metabolism and possible mode of action of this clinical anticancer agent.