THREE LIGHT REACTIONS AND THE TWO PHOTOSYSTEMS OF PLANT PHOTOSYNTHESIS*

Abstract— Recent work in our laboratory yielded new evidence that noncyclic electron transport in chloroplasts from water to ferredoxin (Fd) and N ADP is carried out solely by System II which, unexpectedly, was found to include not one but two photoreactions (IIa and IIb). The evidence suggests that these operate in series, being joined together by a ‘dark’ chain of electron carriers that includes (but is not limited to) cytochrome b₅₅₉ and plastocyanin (PC): H₂O → IIb_hv→ C550 → Cyt b₅₅₉ rarr;PC→IIa_hv→ Fd → NADP. Photoreaction IIb involves an electron transfer from water to C550, a new chloroplast component distinct from cytochromes, whose photoreduction is observed as a decrease in absorb-ance with a maximum at 550 nm. The photoreduction of CSSO proceeds effectively only in short-wavelength System II light, is insensitive to low temperature (at least down to — 189°C). does not require plastocyanin, and is the first known System II photoreaction which is resistant to inhibition by DCMU or o-phenanthroline. Photoreaction IIa involves an electron transfer from cytochrome b₅₅₉ to ferredoxin-NADP and also proceeds effectively only in System II light. The photooxidation of cytochrome b₅₅₉ requires plastocyanin. Cytochrome b₅₅₉ is reduced by C550 in a reaction that is readily inhibited by DCMU or o-phenanthroline. Thus, the site of DCMU (and o-phenanthroline) inhibition of System II appears to lie between C550 and cytochrome b₅₅₉. System I, comprising a single long-wavelength light reaction and a cyclic electron transport chain that includes cytochromes b₆ and f, is viewed as operating in parallel to System II. The photoreduction of NADP by artificial electron donors via System I involves a portion of the cyclic electron transport chain and appears to be independent of plastocyanin. Chloroplast fragments have been prepared which either (a) exhibit System II activity (water → NADP) and lack functional cytochrome f and P700 or (b) exhibit System I activity and lack plastocyanin. The present concept is consistent with the following: (i) No enhancement effect was found for NADP reduction by water where only System II is thought to be involved, but a large enhancement effect was observed in chloroplasts engaged in complete photosynthesis where both cyclic (System I) and noncyclic photophosphorylation (System II) are needed for CO₂ assimilation. (ii) The transfer of one electron from water to ferredoxin via System II requires optimally two quanta, but the transfer of one electron from reduced dye to ferredoxin via System I requires optimally only one quantum of light.     

LIGHT-INDUCED ABSORBANCE CHANGES IN CHLOROPLASTS AT -196°C*

Abstract— Absorbance changes induced by irradiating chloroplasts at — 196°C were measured in the region of 525–575 nm with a single-beam spectrophotometer. Irradiation at low temperature caused a bleaching at 556 nm due to oxidation of cytochrome b₅₅₉ but little or no change of cytochrome f. There occurred in addition a loss of absorbance at 547 nm and an increase at 543 nm. The bleaching at 547 nrn (and possibly the increase at 543 nm) could be induced chemically with dithionite or borohydride but not ascorbate. Subchloroplast particles with only Photosystem I activity showed no light-induced absorbance changes, while particles containing combined Photosystem I and Photosystem II activities showed the same changes as whole chloroplasts. Scenedesmus mutant No. 11 cells showed no absorbance changes while mutant No. 8 and wild-type cells showed the normal changes. It is concluded that the photooxidation of cytochrome b₅₅₉ and the photoreduction causing the bleaching at 547 nm are both mediated by Photosystem II.     

BASF 13.338 INDUCED CHANGES IN STRUCTURE and FUNCTION OF THE PHOTOSYNTHETIC APPARATUS OF WHEAT SEEDLINGS

Abstract— Growing wheat seedlings in the presence of BASF 13.338 [4-chloro-5-dimethylamino-2-phenyl-3(2H)pyridazinone], a PS II inhibitor of the pyridazinone group, brought about notable changes in the structure and functioning of photosynthetic apparatus. In BASF 13.338 treated plants, there was a decrease in the ratio of Chi a/Chl b, an increase in xanthophyll/carotene ratio and an increase in the content of Cyt b 559 (HP + LP). Chl/p700 ratio increased when measured with the isolated chloroplasts but not with the isolated PS I particles of the treated plants. The SDS-PAGE pattern of chloroplast preparations showed an increase in the CPII/CP I ratio. The F685/F740 ratio in the emission spectrum of chloroplasts at -196°C increased. The difference absorption spectrum of chloroplasts between the control and the treated plants showed a relative increase of a chlorophyll component with a peak absorption at 676 nm and a relative decrease of a chlorophyll component with a peak absorption at 692 nm for the treated plants. The excitation spectra of these chloroplast preparations were similar. Chloroplasts from the treated plants exhibited a greater degree of grana stacking as measured by the chlorophyll content in the 10 K pellet. The rate of electron transfer through photosystem II at saturating light intensity in chloroplast thylakoids isolated from the treated plants increased (by 50%) optimally at treatment of 125 μM BASF 13.338 as compared to the control. This increase was accompanied by an increase in (a) I₅₀ value of DCMU inhibition of photosystem II electron transfer; (b) the relative quantum yield of photosystem II electron transfer; (c) the magnitude of C550 absorbance change; and (d) the rate of carotenoid photobleaching. These observations were interpreted in terms of preferential synthesis of photosystem II in the treated plants. The rate of electron transfer through photosystems I and through the whole chain (H₂O → methyl viologen) also increased, due to an additional effect of BASF 13.338, namely, an increase in the rate of electron transfer through the rate limiting step (between plastoquinol and cytochrome f). This was linked to an enhanced level of functional cytochrome f. The increase in the overall rate of electron transfer occurred in spite of a decrease in the content of photosystem I relative to photosystem II. Treatment with higher concentrations (> 125 μM) of BASF 13.338 caused a further increase in the level of cytochrome f, but the rate of electron transfer was no greater than in the control. This was due to an inhibition of electron transfer at several sites in the chain.     

ON THE INTERACTION OF PHOTOSYSTEMS I AND II IN ALGAL CELLS*,†

Abstract— Steady-state relaxation spectrophotometry was applied to intact algal cells. The results indicated System I operates in a cyclic manner, only indirectly affected by the presence or absence of oxygen evolution. This action in whole cells is distinct from that occurring in chloroplasts, where System I appears tightly coupled to System II. No evidence was found for the oxidation of cytochrome by P700. Fluorescence emission measurements on intact cells emphasized the role of membrane permeability agents in controlling the emission yield. Large changes in the yield caused by Systems I and II could be observed in the presence of these agents. In sum, the results proved complex and were difficult to resolve in any simple scheme but emphasized the possible role of protons (or membrane potential) in controlling fluorescence yield.     

CHARGE TRANSFER FROM PHOTOSYSTEM I TO THE CYTOCHROME b/f COMPLEX: DIFFUSION AND MEMBRANE LATERAL HETEROGENEITY

Abstract— We discuss here the minimum requirements for diffusion of a charge carrier between appressed and stroma-exposed membrane regions of chloroplasts based on recent models of the thylakoid membrane and flash-induced kinetic data. We have investigated the kinetics of the transfer of a positive charge from photosystem I to the cytochrome b/f complex in spinach chloroplasts by measuring the light-induced oxidation of cytochrome f. The rate and extent of cytochrome f oxidation were measured spectrophotometrically using either long actinic flashes that induced several turnovers of photosystem I or short actinic flashes that induced a single turnover of photosystem I. In the long actinic flashes, in the electron transfer reaction from water to methyl viologen, we observed the rapid oxidation of all of the cytochrome f present in the membrane. The half-time of the oxidation was 1.0 ± 0.1 ms. The total amount of the cytochrome was determined by chemical difference spectra to be one molecule of cytochrome f per 650 – 30 chlorophyll molecules. Using short actinic flashes we studied the photosystem I-driven electron transfer reaction from duroquinol to methyl viologen in the presence of the inhibitor 5-n-undecyl-6-hydroxy-4,7-dioxobenzothiazole. Under these conditions a single turnover flash induced the oxidation of 62 ± 5% of cytochrome f with a half-time of 240 ± 30 μs. An Arrhenius plot of the temperature dependence of the cytochrome f oxidation rate revealed an activation energy between 16 and 21 kJ/mol, a value consistent with a diffusion-controlled reaction. These kinetic data are considered in the context of two models of the thylakoid membrane.     

Type I and Type II Photosensitized Oxidation Reactions: Guidelines and Mechanistic Pathways

Here, 10 guidelines are presented for a standardized definition of type I and type II photosensitized oxidation reactions. Because of varied notions of reactions mediated by photosensitizers, a checklist of recommendations is provided for their definitions. Type I and type II photoreactions are oxygen‐dependent and involve unstable species such as the initial formation of radical cation or neutral radicals from the substrates and/or singlet oxygen (¹O₂ ¹?_g) by energy transfer to molecular oxygen. In addition, superoxide anion radical () can be generated by a charge‐transfer reaction involving O₂ or more likely indirectly as the result of O₂‐mediated oxidation of the radical anion of type I photosensitizers. In subsequent reactions, may add and/or reduce a few highly oxidizing radicals that arise from the deprotonation of the radical cations of key biological targets. can also undergo dismutation into H₂O₂, the precursor of the highly reactive hydroxyl radical () that may induce delayed oxidation reactions in cells. In the second part, several examples of type I and type II photosensitized oxidation reactions are provided to illustrate the complexity and the diversity of the degradation pathways of mostly relevant biomolecules upon one‐electron oxidation and singlet oxygen reactions.     

STRUCTURE OF PHOTOSYSTEM I AND PHOTOSYSTEM II OF PLANT CHLOROPLASTS*,†,§

Abstract— The action of Triton X-100 upon photosynthetic membranes which are devoid of carotenoids produces a small Photosystem I particle (HP700 particle) which is active in N ADP photoreduction and has a [Chl]/[P700] ratio of 30. The properties of the HP700 particle indicate that it is a reaction center complex which is served by an accessory complex containing the additional light-harvesting chlorophyll of Photosystem I as well as the cytochromes and plastoquinone. When Photosystem II particles obtained by the action of Triton X-100 are further washed with a solution 0.5 M in sucrose and 0.05 M in Tris buffer (pH 8.0), chlorophyll-containing material is released. After centrifugation, the supernatant contains about 1 per cent of the chlorophyll and contains three types of particles which can be separated by sucrose density gradient centrifugation. One of these particles, designated TSF-2b, has the same pigment composition as the original Photosystem II fragment, contains cytochrome 559, and shows Photosystem II activity (DCMU-sensitive diphenylcarbazide-supported photoreduction of 2,6-dichlorophenolindophenol). The other two particles (TSF-2a and TSF-2a′) have a [Chl a]/[Chl b] ratio of 8, have a low concentration of xanthophylls, and show a [Chl]/[Cyt 5591 ratio of about 20. Only the TSF-2a particle is active in the Photosystem II reaction described above. On the basis of these data, it is proposed that the Photosystem II unit consists of a reaction center complex which contains Chl a, Cyt 559, and an acceptor for the photochemical reaction. The reaction center complex would be served by an accessory complex which contains the light-harvesting pigments, Chl a. Chi b, and xanthophyils.     

THE PHOTO-OXIDATION OF N, N-DIETHYLHYDROXYLAMINE BY ROSE BENGAL IN ACETONITRILE AND WATER

The Rose Bengal photosensitized oxidation of N,N-diethylhydroxylamine has been investigated in water and acetonitrile using the techniques of oxygen uptake, singlet oxygen phosphorescence and electron spin resonance. In both solvents H₂O₂ is the major oxidation product and diethylnitroxide is an intermediate. In water, superoxide dismutase decreases oxygen uptake suggesting involvement of superoxide anions in the oxidation process. Results indicate that in water the photo-oxidation proceeds mainly by a Type I(electron transfer) mechanism, while in acetonitrile a Type II(energy transfer) mechanism has been confirmed (Encinas et al., 1987, J. Chem. Soc. Perkin Trans. II,1125–1127).     

CHEMILUMINESCENT DIPHENYLACETALDEHYDE OXIDATION BY MITOCHONDRIA IS PROMOTED BY CYTOCHROMES and LEADS TO OXIDATIVE INJURY OF THE ORGANELLE

Plant and animal mitochondria promote the aerobic oxidation of diphenylacetaldehyde (DPAA). This process is accompanied by chemiluminescence and rotenone-insensitive oxygen uptake. Tn rat liver and potato tubers, mitochondrial swelling is concurrently detected. Light emission and oxygen consumption decreased (about 50%) in cytochrome c-depleted mitochondria. A model system–cytochrome c or b5/dihexadecylphosphate liposomes–was also able to oxidize DPAA with parallel reduction of the cytochrome. Reduction of respiratory complex I or I plus II by addition of rotenone or antimycin A, respectively, did not prevent DPAA oxidation. However, when all cytochrome was reduced by addition of cyanide, aldehyde oxidation was completely suppressed. Altogether these data indicate that respiratory cytochromes are responsible for DPAA oxidation with production of excited species and consequent mitochondrial permeabilization.     

A microelectrode study of the mechanism of the reactions of silver(II) with manganese(II) and chromium(III) in sulphuric acid

The variation of the steady state limiting current for the Ag(I)/Ag(II) oxidation wave with the radius of the microdisc electrode, concentration and temperature has been used to probe the kinetics and mechanisms for the reactions of silver(II) with manganese(II) and chromium(III) in 10 mol dm⁻³ sulphuric acid. It is shown that the current density for the silver(I) mediated oxidation of manganese(II) is controlled by the diffusion of manganese(II) to the surface except for microelectrodes with radii below 5 μm. On the other hand, the current density for the mediated oxidation of chromium(III) is determined by the rate of the Ag(II)/Cr(III) reaction over a range of conditions. In contrast to the Ag(II)/water reaction, its kinetics can be fitted to a mechanism where the initial electron transfer from Cr(III) to the Ag(II) is the rate determining step.     

Photochromic liquid-crystalline polymers. Main chain and side chain polymers containing azobenzene mesogens

Abstract

Two classes of thermotropic polymers were synthesized containing the trans-azobenzene unit as both a mesogenic and a photochromic group. In the former class (I) the azobenzene unit is incorporated into the main chain of substituted polymalonates, while in the latter class (II) it is appended as a side chain substituent to a polyacrylate backbone. The liquid-crystalline properties of the polymers were studied as a function of the chemical structure. All of the prepared polymers I have smectic phases. Polymers II are nematic and/or smectic, or cholesteric when including a chiral residue R'. Polymers I and II when radiated at 348 nm in chloroform solution undergo trans-to-cis isomerization of the azobenzene moiety. The calculated rate constants are comparable with those of low molar mass model compounds, and indicate that the macromolecular structure does not significantly affect the photoisomerization rate.     

Cytochrome P450 119 Compounds I Formed by Chemical Oxidation and Photooxidation Are the Same Species

Compound I from cytochrome P450 119 prepared by the photooxidation method involving peroxynitrite oxidation of the resting enzyme to Compound II followed by photooxidation to Compound I was compared to Compound I generated by m-chloroperoxybenzoic acid (MCPBA) oxidation of the resting enzyme. The two methods gave the same UV/Visible spectra, the same products from oxidations of lauric acid and palmitic acid and their (ω-2,ω-2,ω-3,ω-3)-tetradeuterated analogues, and the same kinetics for oxidations of lauric acid and caprylic acid. The experimental identities between the transients produced by the two methods leave no doubt that the same Compound I species is formed by the two methods.     

ELECTRON TRANSFER REACTIONS OCCURRING UPON LASER FLASH PHOTOLYSIS OF PHOSPHOLIPID BILAYER SYSTEMS CONTAINING CHLOROPHYLL,BENZOQUINONE AND CYTOCHROME c-I. NEGATIVELY-CHARGED VESICLES*

Abstract— In negatively-charged lipid bilayer vesicles prepared in deionized water from egg phosphatidylcholine and 25 mol % of α-eleostearic acid, and containing chlorophyll a, benzoquinone, and cytochrome c, primary electron transfer after a laser flash occurred principally from chlorophyll triplet to benzoquinone, and to a smaller extent from chlorophyll triplet to oxidized cytochrome c. Several secondary electron transfer reactions occurred subsequent to this. The most rapid of these was electron transfer from reduced cytochrome c, which was bound to the outer surface of the negatively-charged vesicle, to chlorophyll cation radical (k= 3.9 times 10³ s^-1). Subsequent to this, the cation radical was reduced by benzoquinone anion radical (k= 1.6 times 10² s^-1>) and bound oxidized cytochrome c was reduced by the remaining anion radical which was expelled into the aqueous phase by the negative charge on the vesicle surface. This latter reaction occurred at the membrane-solution interface with an observed rate constant (k= 60 s^-1) two orders of magnitude smaller than cytochrome oxidation. Net reduced cytochrome c was produced in this process. The reduced cytochrome c was slowly reoxidized by benzoquinone (k= 17 s^-1) and the system was returned to its original state. When the vesicle system was made slightly basic by adding tris(hydroxymethyl)aminomethane, the rates of both the reverse electron transfer between chlorophyll cation radical and benzoquinone anion radical (k= 5 times 10² s^-1) and the oxidation of reduced cytochrome c by chlorophyll cation radical (k= 9.4 times 10³ s^-1) were accelerated. The rate of reduction of oxidized cytochrome c by benzoquinone anion radical remained approximately the same.     

Reactions of poly(phenylene oxide)s with quinones. I. The quinone-coupling reaction between low-molecular-weight poly(2,6-dimethyl-1,4-phenylene oxide) and 3,3′,5,5′-tetramethyl-4,4′-diphenoquinone

A bifunctional polymer is formed when low-molecular-weight poly(2,6-dimethyl-1,4-phenylene oxide) (I) reacts with 3,3′,5,5′-tetramethyl-4,4′-diphenoquinone (II). Infrared (IR), nuclear magnetic resonance (NMR), and gel permeation chromotography (GPC) measurements indicate that the quinone is bound covalently to the polymer chain as a biphenyl moiety which can be located at a terminal position (III, a = 0) or an internal position (III, a > 0): Acetylation of III produces a diacetate ester characterized by field desorption mass spectrometry to confirm the bifunctional nature of III. The reaction of I with II proceeds at 25°C but is faster at elevated temperatures or with amine catalysis. Oxidation of III with oxygen and a copper/amine catalyst of the type used initially to prepare I regenerates II from the biphenyl moiety in III in high yield and converts the remaining oxyphenylene units to high-molecular-weight polymer.     

Redox potentials of chlorophylls and beta-carotene in the antenna complexes of photosystem II

Electron transfer (ET) processes in reaction centers (RC) of photosystem II (PSII) are prerequisites of oxygen generation. They are promoted by energy transfer from antenna to RC. Here, we calculated the redox potentials of chlorophylla/beta-carotene (Chla/Car) in PSII CP43/CP47 antenna complexes, solving the linearized Poisson-Boltzmann (LPB) equation based on the PSII crystal structure. The majority of antenna Chla redox potentials for reduction/oxidation were lower than those of RC Chla. Hence, ET events with excess electrons remain localized in the RC. Simultaneously antenna Chla can serve as an efficient cation sink to rereduce RC Chla if normal PSII function is inhibited. Especially three antenna Chla (Chl-47, Chl-18, and Chl-12) and two Car bridging the space between Chl(Z(D1)) and cytochrome (cyt) b559 have the same level of oxidation redox potential. Together with Chl(Z(D2)) they form an electron hole transfer pathway and temporary storage device guiding from the oxidized P680(+.) Chla to the cyt b559. This path may play a photoprotective role as efficient electron hole quencher.     

Flavin-mediated photoreactions in artificial systems: a possible model for the blue-light photoreceptor pigment in living systems.

Abstract— The photoreduction of cytochrome c and the photostimulation of oxygen uptake were studied in solutions of flavin and cytochrome as a possible model system for similar photoreactions which have been observed in vivo. Light causes the photoreduction of the flavin. Under aerobic conditions the photoreduced flavin reacts with oxygen to form the superoxide anion which in turn can reduce cytochrome c. Dismutation of the superoxide anions forms hydrogen peroxide which mediates the dark oxidation of the photoreduced cytochrome. Superoxide formation and dismutation also account for the light-induced oxygen uptake. Action spectra confirm the role of flavin in the photoreduction of cytochrome c and the photostimulation of oxygen uptake. Under anaerobic conditions the photoreduced flavin reduces cytochrome c directly. In the presence of an electron donor only catalytic amounts of flavin are required. In the absence of an added electron donor flavin itself can act as the electron donor if substrate amounts are present. Azide inhibits all of these flavin-mediated photoresponses. Azide also inhibits the photoreduction of cytochrome b which occurs in the mycelium of Newospora.     

Polymer-Complex Mediated Enzyme Electrodes for Amperometric Determination of Glucose

The immobilized enzyme chemically modified solid-state electrodes based on bilayer-film coating for amperometric determination of glucose have been fabricated and their sensor characteristics have been examined. The electrode substrate was coated with two kinds of polymeric films in a bilayer state, that is, System I: first with the cobalt tetrakis(o-aminophenyl)porphyrin polymer (poly-CoTAPP) film and then with an enzyme film consisting of bovine serum albumin and glucose oxidase (GOx), and System II: first with the Ru(NH₃)³⁺ ₆-containing montmorillonite clay film and then with the GOx enzyme film. The glucose concentration could be monitored by measuring the currents corresponding to the O₂ reduction and the H₂O₂ reduction which are electrocatalyzed by the poly-CoTAPP film (System I) and the clay film (System II), respectively. The reproducible relationship between glucose concentration and sensor output was obtained for both systems with a dynamic range of ～ 1-100 mM (for System I as an electrochemical detector for a flow injection analysis) and ～0.4-4 mM (for System II). In addition, the sensors showed long-term stability (more than 1 and 2 months in System I and System II, respectively) and relatively rapid response (response times of System I and System II are ? 5-10 and 40-60 s, respectively).     

ELECTRON TRANSPORT IN RHODOPSEUDOMONAS VIRIDIS* AT LOW TEMPERATURES

Abstract— When chromatophores of Rhodopseudomonas viridis are briefly illuminated with very bright light at temperatures between —20°C and —196°C, reaction center chlorophyll (P985) is oxidized rapidly and becomes reduced in less than 0.1 sec upon cessation of illumination. In moderate exciting light one molecule of cytochrome 558 per molecule of P985 is oxidized rapidly and irreversibly while P985 oxidation is much slower and its oxidation rate is highly temperature-dependent. After a long illumination ends, P985 reduction occurs in two temperature-dependent phases, in 1 to 1 ratio. The data are interpreted as follows.

• 1 P985 and one mole of cytochrome 588 per mole of P985 can be photooxidized at low temperatures.
• 2 Electron transfer from the primary electron acceptor to the secondary acceptor or back to P985⁺ occurs in less than 0.1 sec at low temperatures.
• 3 There is one mole of secondary acceptor (a one-electron acceptor) per mole of P985. and electron transfer from the secondary acceptor to tertiary acceptors is highly temperature-dependent.

     

OXIDATION-REDUCTION REACTIONS OF P700 AND CYTOCHROME f IN FRACTION 1 PARTICLES PREPARED FROM SPINACH CHLOROPLASTS BY FRENCH PRESS TREATMENT

Abstract— –Fraction-1 particles were prepared by passing spinach chloroplasts three times through the French pressure cell and centrifuging in a sucrose gradient. With the electron donor DAD (diaminodurol or 2,3,5,6-tetramethyl-p-phenylenediamine) and ascorbate, a light-induced difference spectrum revealed the oxidation of both cytochrome f and P700 upon illumination of these particles. The oxidation of cytochrome f was completed in less than 0.5 msec. P700 and cytochrome f thus seem to be tightly bound to each other in these particles. Addition of Triton X-100 abolished the fast oxidation of cytochrome f but not that of P700. Artificial electron donors such as DAD, DCIP (2,6-dichlorophenol indophenol), and PMS (N-methylphenazonium methosulfate) were good electron donors for photoreaction 1 in these particles, while neither plastocyanin, Porphyra cytochrome 553, nor Euglena cytochrome-552 reduced P700 efficiently. However, after treatment of fraction 1 particles with Triton X-100 reduced DAD, DCIP and PMS were no longer efficient electron donors, while plastocyanin and the algal cytochromes were highly active in reducing P700. Mammalian cytochrome c was not a good electron donor either before or after Triton treatment. Measurements of the effectiveness of P700 reduction as a function of concentration in Triton-treated particles showed plastocyanin to be about four times more active than Porphyra or Euglena cytochromes which in turn were about fourteen times more active than mammalian cytochrome c. Recent studies by Murata and Brown have shown that plastocyanin is not required for the reduction of NADP in these particles with DCIP and isoascorbate as electron donors. The present investigation and that of Murata and Brown indicate that disintegration of chloroplasts with the French pressure cell and centrifugation in a sucrose gradient is the best method to separate system-1 particles having an electron-transport system in almost the native state as in chloroplasts.     

Kinetics of reversible recombination of aromatic C-centered radicals

The kinetics of the reversible recombination of the 2-phenyl- (I), 2-p-methoxyphenyl-(II), and 2-p-nitrophenyl-3-oxo-2,3-dihydrobenzothiophene-2-yl (III) radicals have been investigated. Recombination rate constants of R(I–III) have been determined in different solvents (2k₁ ～ 10⁹ M^?1 s^?1). The rate of reaction (I) with R(I–III) decreases with increasing solvent viscosity η. In the toluene-vaseline oil mixture (2 ? η ? 120 cP) the recombination of R(I–III) is molecular mobility limited. The thermodynamic parameters of reaction (I) have been determined: ΔH⁰ = 20–30 kcal/mol. Activation volumes ΔV for recombination of R(II) have been measured. In n-propanol ΔV is equal to the viscous flow activation volume of the solvent ΔV. In toluene and chloroform ΔV < ΔV. For the last two solvents the activation volumes of the cage reaction have been estimated ΔV = ?(2–3) cm³/mol. Visible-range absorption spectra and ESR spectra have been recorded for R(I–III). The role of cage effect in the reactivity anisotropy averaging of R(I–III) is discussed. The potential of the high-pressure tests for deriving information about the elementary act of a fast bimolecular reaction is considered.