FLASH PHOTOLYSIS-ELECTRON SPIN RESONANCE: A KINETIC STUDY OF ENDOGENOUS LIGHT-INDUCED FREE RADICALS IN REACTION CENTER PREPARATIONS FROM RHODOPSEUDOMONAS SPHEROIDES*

Abstract— Using the technique of flash photolysis-electron spin resonance, we have detected, by means of a kinetic analysis, a rapidly decaying signal in reaction center preparations from the R26 blue-green mutant of Rhodopseudomonas spheroides. This signal, which we designate Signal B3, is essentially the same as that seen previously in iron-free preparations. Signal B3 decays at 20°C with a 1/ e time of ˜ 3 ms and exhibits an activation energy of 5 ± 1 kcal mol^-1 over the temperature range 0–30°C. Extraction with isooctane completely eliminates Signal B3, whereas readdition of exogenous ubiquinone-30 completely restores the signal. o -Phenanthroline has no effect on Signal B3. We discuss these results in terms of a model in which the primary acceptor is an iron-ubiquinone complex with excess ubiquinone serving as a secondary electron acceptor pool.     

COMPARISON OF PHOTOTRAP COMPLEXES FROM CHROMATOPHORES OF RHODOSPIRILLUM RUBRUM, RHODOPSEUDOMONAS SPHEROIDES, AND THE R-26 MUTANT OF RHODOPSEUDOMONAS SPHEROIDES*

Abstract— After dissolution of the membrane structure of chromatophores from Rhodospirillum rubrum, Rhodopseudomonas spheroides , and the R-26 mutant of Rhodopseudomonas spheroides , active phototrap complexes from each have been purified by a column electrophoresis procedure. Phospholipids and transition metals were well separated from the phototrap complex in all three systems. The purified R. rubrum phototrap complex retained a full complement of antenna bacteriochlorophyll and carotenoid pigments which had nearly the same absorbance spectra as in the intact cell, and which delivered absorbed light energy to the phototrap with just as high efficiency as in the intact cell. Sodium dodecyl sulfate (SDS) disc gel electrophoresis using Tris buffer showed that these preparations often contained only two prominent polypeptides of 30,000 ± 2000 and 12,000 ± 4000 mol. wt., and a lesser amount of a third polypeptide of 21,000 ± 2000 mol. wt.
The phototrap complexes prepared from the wild type and the R-26 mutant of R. spheroides were similar, in that a partial separation from antenna pigments occurred during column electrophoresis. Both complexes had prominent polypeptides of 24,000 ± 2000 and 21,000 ± 2000 mol. wt., but no polypeptide of 30,000 mol. wt remained after electrophoresis. A third major polypeptide occurred with a mol. wt. of about 12,000 but seemed identifiable with an incompletely separated antenna pigment fraction. The phototrap complex prepared from the R-26 mutant had a typical reaction center spectrum.
In the case of wild type R. spheroides purification, two distinct protein-pigment complexes separated. Although the absorbance of the bacteriochlorophyll and carotenoid pigments were little changed from those of the in vivo system, different polypeptides in the two fractions were observed by SDS disc gel electrophoresis; only one fraction seemed to be intimately related with the phototrap complex.     

INTERACTION OF VIOLOGEN DYES WITH CHROMATOPHORES AND REACTION-CENTER PREPARATIONS FROM RHODOSPIRILLUM RUBRUM

Abstract —Various low-potential viologen dyes enhance light-induced absorption changes in the near-infrared region (ΔA870) in chromatophore preparations from Rhodospirillum rubrum in the presence of dichlorophenol indophenol and a high concentration of ascorbate (DCPIP + asc). An increase in ΔA870 was also observed in large reaction-center preparations from R. rubrum with viologens in the presence of ascorbate. Our results indicate that E'₀, of the primary electron acceptor X may be as low as -0.37 V, as suggested recently by P. A. Loach (1973, personal communication).     

FLASH PHOTOLYSIS-ELECTRON SPIN RESONANCE STUDIES OF THE DYNAMICS OF PHOTOSYSTEM I IN GREEN-PLANT PHOTOSYNTHESIS-I. EFFECTS OF ACCEPTORS AND DONORS IN SUBCHLOROPLAST PARTICLES*

Abstract —Transient decay kinetics of Signal I in spinach subchloroplast particles have been studied in the presence of artificial donors [5-methyl phenazonium methyl sulfate (PMS), 2, 6-dichlorophenolindophenol (DPIP), N, N, N', N'-tetramethyl-p-phenylenediamine (TMPD) and ascorbate], artificial acceptors [benzyl viologen (BV) and methyl viologen (MV)] and various natural donor and acceptor moieties, using the technique of flash photolysis-electron spin resonance spectroscopy. The results are discussed in the framework of three mechanisms for reduction of P700⁺: (1) direct electron return from the primary acceptor to P700⁺, (2) cyclic electron flow via an electron carrier, and (3) noncvclic electron flow.     

FLASH PHOTOLYSIS-ELECTRON SPIN RESONANCE STUDIES OF THE DYNAMICS OF PHOTOSYSTEM I IN GREEN-PLANT PHOTOSYNTHESIS—II. INTACT AND BROKEN SPINACH CHLOROPLASTS*

Abstract —The transient oxidation and subsequent reduction of P700⁺ in spinach chloroplasts has been monitored by flash photolysis-electron spin resonance spectroscopy in the presence of various donors and acceptors. In general, the results obtained correlate well with results on Photosystem I subchloroplast particles, with two major differences. For Type A and B intact chloroplasts in the presence of 3-(3, 4-dichlorophenyl)-1, 1-dimethylurea (DCMU), the electron acceptor methyl viologen has no effect on the decay kinetics. This phenomenon is interpreted in terms of a functioning cyclic electron flow path around Photosystem I. Also, the photoresponse of Signal I depends on the length of the photolyzing flash. This is interpreted in terms of the existence of a primary electron donor to P700⁺ with a transfer time of ? 10 μs.     

EFFECTS OF HIGH PRESSURE ON PHOTOCHEMICAL REACTION CENTERS FROM RHODOPSEUDOMONAS SPHEROIDES*

Abstract— Photochemical reaction centers from Rhodopseudomonas spheroides were subjected to pressures ranging from 1 to 6000 atm. Optical absorption, fluorescence and photochemical activities were studied under these conditions. Absorption spectra showed bathychromic shifts of the long-wave bands attributed to bacteriopheophytin and bacteriochlorophyll (the latter as P800 and P870). The quantum efficiency of photochemical oxidation of P870 was diminished at high pressure. The quantum yield of P870 fluorescence showed a parallel decline, as if high pressure introduced a quenching process that competed with both photochemistry and fluorescence. The original efficiencies were largely restored when the pressure was returned to 1 atm. The efficiency of oxidation of mammalian cytochrome c, coupled to the photochemical oxidation of P870 in reaction centers, was lowered by high pressure. This effect was more pronounced than the effect on P870 oxidation, and was irreversible. The kinetics of recovery of P870 following its photochemical oxidation showed effects of high pressure. The main effect was the appearance, at high pressure, of slow recovery suggesting the trapping of electrons. This effect was partly irreversible.     

ELECTRON SPIN RESONANCE STUDIES OF THE TRIPLET STATES OF MONOANIONIC THYMINE*

Abstract— Ultraviolet irradiation of the thymine anion tautomers 1-HT- and 3-HT^- at -196°C generates excited triplet states having δm=±2 resonances at 1067 and 1260 G respectively (with v= 9.0 GHz). Excitation at 270nm gave predominantly the low field signal while excitation at 300 nm produced only the high field resonance. These results when compared with the absorbance properties of the monoanions are consistent with the low field resonance being due to 1-HT^- and the high field resonance being due to 3-HT^-.     

STUDIES ON THE INTERACTION OF EPOXY POLYMERS WITH HOMOPOLYUREAS

INTRODUCTION Epoxy resins are reactive polymers which when cured with a variety of chemicals lead to a host of useful thermosets. Since the epoxide is a strained ring, it readily undergoes addition and homopolymerization. The homopolymerization is a process catalysed by acids, bases, Lewis acids, t-amines as well as by inorganic salts.     

ELECTRON SPIN RESONANCE STUDIES OF ULTRAVIOLET IRRADIATED KERATIN AND RELATED PROTEINS

Abstract— The formation of free radicals in keratin and related proteins by exposure to u.v. light has been examined by electron spin resonance spectroscopy. From a comparison of the spectra obtained and the effects of different wavelengths and the stabilities of the radicals produced, it has been shown that several species of free radicals are produced by the u.v. irradiation of keratin. However it has been possible to identify only those free radicals associated with the cystine residues. The free radicals produced in keratin by exposure to shorter wavelength irradiation (below 3250 Å) were found to be quite different to those produced at longer wavelengths.     

希土与L-甲状腺素(T4)相互作用的研究

在二甲亚砜-水混合溶剂中用pH电位法测定了T4的质子化常数以及与五种希土离子(Pr³⁺、Eu³⁺、Gd³⁺、Tb³⁺、Yb³⁺)生成配合物的稳定常数。体系中主要生成110型配合物，紫外吸收光谱，HNMR表明，在较低pH值，T4通过羧基与希土配位，pH较高时，氨基也相继配位。配位键以离子性为主，荧光光谱表明，T4对中心希土离子的荧光有猝灭作用。     

ABC三自旋质子磁共振谱的标划归属

本文对ABC三自旋质子磁共振谱的标划归属提出了一个新的方法.     

INTERACTION OF DIHYDROOROTATE DEHYDROGENASE WITH LIGHT*

Abstract— Several flavoproteins are known to undergo photoactivated reduction by EDTA. However, the effects of visible light on the non-heme iron containing flavoproteins have not been characterized previously. Dihydroorotate dehydrogenase was studied as an example of this class of enzymes. Interaction with visible light was found to be complex. Under low intensity photoirradiation of long duration the anaerobic enzyme was partially reduced to a form having increased absorbance at 630 nm. Similar absorbance changes have been correlated with semiquinone species. However, the irradiated enzyme exhibited irreversible changes in catalytic function. Activity with NADH was greatly reduced and a portion of the flavin coenzyme content was labilized. Fluorescence intensity of the enzyme was markedly increased by exposure to light, confirming partial degradation of a catalytic site. Isothermal irradiation with light of high intensity in the range 330–600 nm caused the enzyme to be reduced rapidly. Spectroscopic changes were observed which persisted after reoxidation of flavins. Intense new absorbance maxima between 310 and 330 nm together with a large decrase in absorbance at 450 nm were noted. Under controlled conditions approximately half of the total flavin and practically all of the bound FAD were labilized. NADH oxidase activity and NADH linked reduction of orotate were selectively lost. The correlation between FAD labilization and loss of activity strengthens the hypothesis that FAD represents the site of activity with NADH. Activity with NADH was partially restored by incubation of the irradiated enzyme with FAD or FMN.     

INTERACTION OF HYDROXYLAMINE WITH THE WATER-OXIDIZING ENZYME INVESTIGATED VIA PROTON RELEASE*

Abstract— Photosynthetic water oxidation is a four-step redox process which is driven by a one-quantum-one-electron reaction center. Stepwise electron Abstract—ion from the water-oxidizing enzyme is accompanied by stepwise proton release with the following stoichiometric pattern at given half-rise times: 1 H⁺ (250 μs, S₀→ S₁):0 H⁺(S₁→ S₂): 1 H⁺ (200 μs, S₂→ S₃): 2 H⁺ (1.2 ms, S₃→ S₄→ S₀). (Förster and Junge, 1985, preceding article in this issue). Hydroxylamine at low concentrations (?100 μ M) appears to compete with water at the active site of the water- oxidizing enzyme. Its interference shifts the dark state of the water-oxidizing enzyme by two steps backwards (Bouges, 1971). We found that the hydroxylamine-induced shift was also reflected in the stoichiometric pattern and in the kinetics of proton-release. In the presence of hydroxylamine, two protons per reaction center were released with a half-rise time of ? 2 ms upon the first exciting flash given to dark adapted thylakoids. This was slower than observed for each of the protons released during unperturbed water oxidation. One proton was released upon the second flash. The half-rise time of the main component observed upon the second flash in hydroxylamine-treated samples agreed with the one observed upon the fourth flash in the absence of hydroxylamine, which had been attributed to the S₀→ S₁ transition. The two protons which were observed upon the first flash in hydroxylamine-treated thylakoids may be due to hydroxylamine oxidation or to the association of water to the catalytic manganese center after detachment of oxidized hydroxylamine from its binding site.     

ROLE OF CAROTENOIDS IN PROTECTING CHLOROPHYLL FROM PHOTODESTRUCTION—II. STUDIES ON THE EFFECT OF FOUR MODIFIERS OF THE ALBINO cl1 MUTANT OF MAIZE*

Abstract— By combining independent, dominant, niodifier genes of the albino cl₁ mutant it is possible to produce a spectrum of phenotypes ranging from normal green to albino. Analysis of plastid pigments reveals that the albino possesses the ability to produce as much or more chlorophyll than normal siblings and that this ability is not impaired by the presence of the modifier genes. The modifiers do influence, however, the amount of carotene and xanthophyll the plants produced. The level of the three plastid pigments (chlorophyll, carotene and xanthophyll) vary simultaneously and, in most modified phenotypes, occur in approximately the same concentrations relative to their normal siblings. Since chlorophyll production appears to be normal in these mutants, it is suggested that the modifier genes do not directly influence the concentration of this pigment. Rather, the ultimate amount of chlorophyll will not rise above that which can be protected from photodestruction by the carotenoid levels determined by the various modifier genotypes.     

THE PHOTOPHYSICAL AND PHOTOCHEMICAL PROCESSES OF TRYPTOPHAN IN INTERACTION WITH POLYNUCLEOTIDES: LASER FLASH PHOTOLYSIS STUDY

Abstract— The influence of nucleotides or polynucleotides on the photophysics and the photochemistry of tryptophan (Trp) derivatives has been investigated in aqueous solutions using the 265 nm laser flash photolysis technique. In solutions containing mixtures of N -acetyltryptophanamide and uridine monophosphate (UMP) or mercurated dUMP, the Trp triplet and the hydrated electron (e_aq) are quenched at almost diffusion controlled rates by the nucleotides leading to uracil reduction. Lysyl-tryptophyl-α-lysine (Lys-Trp-Lys) forms stable complexes in solution with normal or mercurated poly(uridylic acid) [poly(U)]. In the Poly(rU)-Lys-Trp-Lys complex the Trp triplet state is completely quenched, whereas the Trp triplet formation quantum yield is enhanced in complexes with mercurated poly(U). In this last case, the 'heavy atom effect' is characterized by a shortening of the Trp triplet lifetime in agreement with low temperature experiments. Our results also show that photoionization of Trp does occur in the complexed state with both polymers. The e_aq lifetime is however longer with the complexed than with the free peptide.     

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.     

ELECTRON SPIN RESONANCE OF MELANIN FROM HAIR. EFFECTS OF TEMPERATURE, pH AND LIGHT IRRADIATION

Abstract— The variation with temperature, pH and light of the ESR signal of hydrated melanin powders from Japanese black hair has been studied. An explanation of the results is proposed on the basis of quinhydrone type complexes and of acid-base equilibria of melanin and its semiquinone radicals. During exposure to light of wavelengths 254–600 nm, both stable and unstable radicals have been observed. The action spectrum for the formation of stable melanin radicals has been determined.     

达旦黄与氨基糖苷类抗生素相互作用的共振瑞利散射光谱研究及其应用

在弱酸性介质中,达旦黄(TY)和氨基糖苷类抗生素(AGs)本身的共振瑞利散射(RRS)均很微弱。但两者相互作用形成离子缔合物时,溶液的RRS显著增强,并产生了新的RRS光谱。不同AGs的反应产物具有相似的光谱特征,其RRS峰位于278和469 nm;与此同时,它的倍频散射(FDS)也明显增强,并且最大FDS峰位于392 nm处,但二级散射(SOS)变化不明显。RRS较FDS具有较高的灵敏度,而且在一定范围内,AGs的浓度与散射强度(ΔIRRS)成正比。对于不同抗生素的检出限在17.2~23.3μg.L-1之间,用于氨基糖苷类注射液和血清样品中AGs的测定,测得结果的RSD(n=5)值均小于3.5%,回收率在96.3%~97.2%之间。     

植物血凝素与金属离子锰(Ⅱ)的配位作用

植物血凝素简称PHA是从菜豆中提取的一种凝集素,能激活T淋巴细胞使其增殖,含有红血球凝集素(H-PHA)和白血球凝集素(L-PHA),某些凝集素分子中含有金属离子,如Mn~(2+)、Ca~(2+)等,这些凝集素与糖结合的活力和生物活性均依赖于金属离子的存在,这表明金属离子对凝集素的活性有影响.PHA与金属离子的作用研究还未见报道,本     

SPECTROSCOPIC STUDIES OF CUTANEOUS PHOTOSENSITIZING AGENTS—X. A SPIN-TRAPPING AND DIRECT ELECTRON SPIN RESONANCE STUDY OF THE PHOTOCHEMICAL PATHWAYS OF DAUNOMYCIN AND ADRIAMYCIN

Abstract— Irradiation of daunomycin (or adriamycin) and the spin trap 5,5-dimethyl-l-pyrroline-1-oxide (DMPO) at 490 nm in the presence or in the absence of air generated the hydroxyl radical adduct (DMPO-OH). The observed DMPO-OH signal was not affected by the addition of hydroxyl radical scavengers (ethanol, formate), suggesting that direct trapping of the hydroxyl radical was not involved. The DMPO-OH signal was insensitive to superoxide dismutase and catalase, which ruled out the possibility of superoxide or H₂O₂ involvement. These findings demonstrate that daunomycin (or adriamycin) does not generate hydroxyl radicals or superoxide radical anions when subjected to 490-nm excitation. However, when daunomycin (or adriamycin) was irradiated at 310 nm DMPO adducts derived from two carbon-centered radicals, superoxide and the hydroxyl radical were detected. The superoxide adduct of DMPO was abolished by the addition of SOD, providing unequivocal evidence for the generation of the superoxide anion radical. The daunomycin semiquinone radical, observed upon 310-nm irradiation of daunomycin in the absence of DMPO, appears to be the precursor of the superoxide radical anion. One of the carbon-centered radicals trapped by DMPO exhibited a unique set of hyperfine parameters and was identified as an acyl radical. This suggests that the known photochemical deacylation of daunomycin occurs via a homolytic cleavage mechanism. The free radicals generated photolytically from adriamycin and daunomycin may be involved in the etiology of the skin ulceration and inflammation caused by these drugs. A knowledge of the dependence of these photogenerated radicals on the wavelength of excitation may be important in the development of adriamycin and daunomycin for photodynamic therapy.