PHOTOCHEMICAL-LIKE BEHAVIOUR OF RIBOFLAVIN IN THE DARK PROMOTED BY ENZYME-GENERATED TRIPLET ACETONE

Abstract— Triplet acetone obtained enzymically by the isobutyraldehyde/peroxidase/O₂ system transfers its energy to the riboflavin, which changes into a decomposition product of lumichrome type and produces aggregates. When riboflavin and tryptophan are added to this system, further products—formylkynurenine and an adduct between the riboflavin and the tryptophan—are formed. The adduct can be separated by gel filtration and ion exchange chromatography and is similar to that prepared by irradiating riboflavin in the presence of tryptophan.     

LONG-RANGE TRIPLET-SINGLET ENERGY TRANSFER FROM ENZYME GENERATED TRIPLET ACETONE TO XANTHENE DYES

Enzyme-generated and protected acetone transfers its energy to xanthene dyes by a nontrivial process. The relative populations of the S₁ state are indicative of the operation of a heavy atom effect, being 1:15:100 for fluorescein, eosine and Rose Bengal. On the other hand Stern-Volmer constants and k _ET⁰ values are similar for the three dyes and are remarkably higher than for collisional processes.
It is tentatively suggested that at least for eosine and Rose Bengal, a triplet-triplet cxciton transfer may occur to populate an upper triplet state of the dye followed by heavy-atom enhanced intersystem crossing to the S₁ state.     

RED EMISSION FROM CHLOROPLASTS ELICITED BY ENZYME-GENERATED TRIPLET ACETONE AND TRIPLET INDOLE-3-ALDEHYDE

—Enzyme-generated triplet acetone and triplet indole-3-aldehyde transfer energy very efficiently to chloroplasts, as indicated by the intensity of the sensitized red emission that is observed. The intermediacy of excited species of oxygen (¹O₂, O₂⁻, HO) has been excluded. Our results open the way for investigating energy transfer in architecturally organized systems in the absence of light.     

ENERGY TRANSFER FROM ENZYME-GENERATED TRIPLET CARBONYLS TO THYLAKOID MEMBRANE FRACTIONS ENRICHED IN PHOTOSYSTEMS I and II

Abstract— Enzyme-generated triplet species transfer energy very efficiently to thylakoid membrane fractions enriched in either photosystem-I or photosystem-II. Independent of the nature of the triplet donor, the emission is always more intense with photosystem-I. Since the fluorescence quantum yield of chlorophyll in PS-I is lower and the rate of energy transfer usually smaller than to chlorophyll in PS-II, the yield of ¹S chlorophylls in PS-I is substantially higher. This is tentatively attributed to more favorable reverse intersystem crossing from an upper triplet state in PS-I.     

TRIPLET ENERGY TRANSFER TO CHLOROPLASTS FROM PEROXIDASE-GENERATED EXCITED ALIPHATIC ALDEHYDES

Abstract Linear aldehydes trigger red emission from chloroplasts. If horseradish peroxidase is present, the aldehyde is oxidized to the next lower homologue in the triplet state, which in turn sensitizes chlorophyll fluorescence. Only certain chlorophylls are activated.     

ENERGY TRANSFER FROM ENZYMICALLY-GENERATED TRIPLET SPECIES TO ACCEPTORS IN MICELLES

Abstract— Electronically excited triplet species generated during the peroxidase catalyzed aerobic oxidation of appropriate substrates efficiently elicit fluorescence from acceptors in micelles, as shown with 9, 10-dibromoanthracene and chlorophyll solubilized by various surfactants. In the case of 9, 10-dibromoanthracene excited by triplet acetone, phosphorescence also can be detected near O₂ depletion.
The significant implications of this study are that micelle-solubilized chlorophyll is an excellent detector of enzyme-generated triplet carbonyl species, as confirmed with several systems, and that the use of micelles make it possible to extend 'photobiochemistry without light' to other photobiologically important, yet water insoluble acceptors.     

HEAVY ATOM PERTURBATION IN MOLECULES RELATED TO THYROXINE

En conección con la perturbación producida en las hormonas tiroideas y moléculas asociadas, por el átomo pesado iodo; se ha investigado el espectro de absorción singulete-triplete de la p—benzoquinona (max = 539 nm) cuando se la sustituye en la posicién 2–6 con el dihalógeno. En oposición a los resultados reportados por Kuboyama, no se observaun cambio en la intensidad cuando se sustituyen dos átomos de cloro. La ausencia de acomplamiento spin-órbita se ve confirmada por la pequen?a intensificación de la absorción cuando los átomos sustituidos son bromo o iodo, y probablemente está conectada con el caracter n→π* de la transición. Algo sorpresivamente. la sustitución de dos átomos de iodo produce un marcado efecto batocromico cerca de donde esta localizada la transición singulete- triplete, aproximadamente encima de los 600 nm.     

ENERGY TRANSFER FROM CHEMIEXCITED ACETONE TO SUBSTANCES THAT DISPLAY ANOMALOUS FLUORESCENCE

Abstract— Excited acetone generated in the thermolysis of tetramethyldioxetane elicits the anomalous S₂→ S₀ fluorescence from azulene and from xanthione. In the case of azulene it could be demonstrated that (i) only the acetone singlets transfer energy to the S ₂ state and (ii) the acetone triplets are quenched. These energy transfer processes are diffusion-controlled.     

AFFINITY-CONTROLLED TRIPLET ENERGY TRANSFER FROM p-BENZOYLBENZYL-BOVINE SERUM ALBUMIN TO LOW MOLECULAR WEIGHT QUENCHERS

Abstract— Methods for the controlled synthesis of modified protein photosensitizers which maximize affinity-controlled energy transfer are discussed. Modified proteins containing covalently linked benzophenone groups were prepared by the reaction of bovine serum albumin with p -benzoylbenzyl bromide under conditions limiting the number and locations of the introduced benzophenone chromophores. The mechanism of energy transfer responsible for quenching of triplet photochemical reactions of the modified proteins was explored using water soluble quenchers. In addition, methods were employed to determine the magnitude of the contribution of the affinity-controlled mechanism for energy transfer in these systems. The utility of sodium- cis -8-methylene-4,9-decadienoate as a triplet energy transfer indicator for macromolecular systems was demonstrated using the modified proteins as sensitizers. The trienoic acid was prepared starting with the known 4-methylene-5-hexenal by the Wittig reaction with 3-ethoxycarbonylpropylidene triphenylphosphorane followed by saponification. Triplet sensitized irradiation of this trienoic acid using p -benzoylbenzyltriethylammonium chloride as sensitizer led to production of endo- and exo-1-vinyl-5-(3-carboxyethyl)bicyclo[2.1.1]hexane along with the trans acid. Characterization of the bicyclohexane products was made on the basis of spectroscopic evidence. Results demonstrate that quenching of the intramolecular photoreactions of the modified proteins by trienoic acid must be a result of triplet energy transfer, since irradiation of these modified proteins in the presence of the trienoic acid salt led to the characteristic triplet photoproduct mixture.     

DEACTIVATION OF EXCITED AZO DYE MOLECULES BY ENERGY TRANSFER

Abstract— Förster energy transfer from an excited azo dye monolayer to a luminescent cyanine dye monolayer was investigated. It is concluded that higher vibronic levels of the excited singlet state are efficiently deactivated by processes other than thermal equilibration.     

EXTERNAL HEAVY ATOM EFFECT IN THE ENERGY TRANSFER FROM TETRAMETHYL-1,2-DIOXETANE CHEMI-EXCITED ACETONE TO ANTHRACENE

Generation of the fluorescent state of anthracene by energy transfer from chemi-excited acetone is remarkably more efficient in bromobenzene than in benzene. Triplet-triplet energy transfer populates the second triplet of the acceptor and is followed by intersystem crossing (ISC) to the fluorescent state. It is only on the latter ISC step that the external heavy atom perturbation operates. However, with 9,10-dibromoanthracene as acceptor, spin-orbital coupling also increases the transfer step and more in bromobenzene than in benzene. A possible inference from this work is that 9,10-diphenyl-anthracene, which is commonly used to count singlets, may to some extent also count triplets.     

双色双共振-多光子电离光谱研究小分子的碰撞诱导转动能量转移

用双色双共振多光子电离光谱方法测量了NO分子A~(2∑+)(v=0)态的转动能量转移,得到了由R-F能量转移导致的转动可分辨的弛豫光谱,计算了转动态-态转移速率常数。用以转移能量为基础的指数和幂指数能隙模型,对碰撞弛豫态分布进行计算机模拟,并从计算值与实验值的比较讨论了能隙模型存在的不足。用同法对I_2分子B∏(O_u~+)态的测量,得到由转动能量转移导致的谱线展宽及交叠并作了分析。     

PHOTOCHEMICAL-LIKE DESTRUCTION OF TRYPTOPHAN IN SERUM ALBUMINS INDUCED BY ENZYME-GENERATED TRIPLET SPECIES

Abstract —Human and bovine serum albumin quench enzyme-generated acetone phosphorescence ( K _sv= ca . 10⁴ M ¹). Concomitantly, these proteins are altered as shown by diminished tryptophan absorption at 280 nm, appearance of products of the formylkynurenine type (_max= ca . 320 nm) and disappearance of tryptophan fluorescence. These alterations—which are similar to those induced photochemically—were also observed with serum albumins exposed to enzyme-generated triplet acetaldehyde. On the other hand, triplet acetone generated by the thermolysis of tetramethyldioxetane failed to induce alterations. Presumably energy transfer occurs from the enzyme-generated triplet species to tryptophan group(s) in the serum albumin associated with the acting enzyme. The detailed mechanism is, however, not yet understood.     

萘酰亚胺及其含二茂铁二元化合物的分子间(内)三重态能量传递

近年来萘酰亚胺类化合物作为超分子体系中的功能单元逐渐引起了人们的重视,如快速响应的光开关体系[1]、生物荧光探针体系[2]、激光染料天线分子[3]等.     

ENERGY TRANSFER FROM MICELLAR SODIUM PHENYLUNDECANOATE TO SOLUBILIZED NAPHTHALENE

Abstract— Excitation energy transfer from the phenyl groups of surface active phenylundecanoate ions to naphthalene molecules has been studied under conditions such that the naphthalene molecules have been solubilized by micelles of phenylundecanoate. From measurements of the naphthalene fluorescence intensity in solutions of varying surfactant concentration the critical micelle concentration has been determined as 0·0091 M. The product of the micellar aggregation number and the efficiency of energy transfer has been obtained as 75 from measurements of both the sensitized naphthalene fluorescence and the quenching of the phenylgroup fluorescence. In the evaluation of the experimental data it has been assumed that the partition of naphthalene between the micelles and the aqueous phase may be treated as a distribution equilibrium, and that the solubilized naphthalene molecules are partitioned among the micelles according to a Poisson distribution. With this model, the naphthalene fluorescence intensities may be accounted for over the whole range of surfactant concentrations.
At high naphthalene concentrations, emission from naphthalene excimers has been observed. The possibility of self-quenching via excimer formation is considered.
The experimental results point to a quantum efficiency near unity for the transfer of excitation energy from the phenyl groups of the surfactant ions that form a micelle to a single solubilized naphthalene molecule. The high efficiency suggests that the naphthalene molecule and the phenyl groups are present inside the micelles.     

EXCITATION ENERGY TRANSFER IN SYSTEMS OF MANY MOLECULES

Abstract— Förster's theory of energy transfer in condensed systems is re-examined in the light of recent criticisms. It is concluded that his approach is correct and holds for a wide range of donor and quencher concentrations as long as there is no transfer among donor molecules. In contrast, the modified result of Tweet, Bellamy and Gaines, holds only for complete delocalization of the excitation among the donor molecules.     

CONJUGATED DIENE FORMATION PROMOTED BY TRIPLET ACETONE ACTING UPON ARACHIDONIC ACID

Abstract— Post UV-B(280–320 nm) exposure to UV-A(320–400 nm) reverses pyrimidine dimers in the epidermal DNA of the South American opossum Monodelphis domestica [Ley, R. D. (1984) photorepair of pyrimidine dimers in the epidermis of the marsupial Monodelphis domestica. Photochem. Photobiol . 40 ,141–143.] To demonstrate that the observed photorepair is mediated by an enzyme, we have isolated a DNA photolyase from the opossum. DNA photolyase from liver was purified 3000-fold by ammonium sulfate fractionation and phenylsepharose, hydroxylapatite, DEAE-cellulose and DNA-cellulose column chromatography. Heat denaturation (60°C for 4 min) completely eliminated the photoreactivating activity. The enzyme was active in the pH range of 5.5 to 8.5 with a pH optimum of 7.5. The enzyme has an apparent molecular weight of 32 000 under nondenaturing conditions. The activity of the enzyme was not affected by sodium chloride up to 250 m M . The action spectrum for the purified DNA photolyase showed activity in the range of325–475 nm with peak actvity at 375 nm.     

QUENCHING OF ENZYME GENERATED TRIPLET ACETONE BY 2-METHYL-1,4-NAPHTOQUINONE

Abstract 2-Methyl-1,4-naphtoquinone (vitamin K₃) quenches the phosphorescence from enzyme-generated triplet acetone. Concomitantly the vitamin undergoes a photochemical-like alteration as the result of transfer of the electronic energy ( k _ET– 1 ± 10⁵ M^-1). This transfer appears to be of the long-range type.     

ELECTRON TRANSFER FROM PHOTOEXCITED SINGLET AND TRIPLET BACTERIOPHEOPHYTIN

Abstract— Nanosecond and picosecond. kinetic techniques have been used to study electron transfer from the first excited singlet state (Bph*) and the first excited triplet state (Bph ^T ) of bacteriopheophytin to p -benzoquinone. Quenching of the first excited singlet state by 40 m M p -benzoquinone results in a decrease in the lifetime of Bph* but does not lead directly to the formation of the π-cation radical (Bph†). In the presence of 8 M methyl iodide and 40 m M p -benzoquinone together, the singlet lifetime is reduced further; however, the quantum yield of Bph ^T is enhanced due to the increased rate of intersystem crossing between Bph* and Bph ^T . Electron transfer from Bph ^T to p -benzoquinone leads to the formation and detection of Bph†. The results are discussed in terms of the spin-selectivity of the reverse electron transfer process within the intermediate charge transfer complexes.     

QUENCHING OF CHEMICALLY and ENZYMICALLY-GENERATED TRIPLET ACETONE BY TYROSINE and 3,5-DIHALOGENODERIVATIVES

Tyrosine and especially its 3,5-dihalogenoderivatives quench acetone triplets. When the excited acetone is generated free in solution, the Stern-Volmer plots for the quenching by these species, monitored via the sensitized emission of the 9,10-dibromoanthracene-2-sulfonate ion, are linear. When triplet acetone is generated enzymically by the peroxidase-catalyzed aerobic oxidation of isobutyral-dehyde, the Stern-Volmer plots for the quenching of the acetone phosphorescence curve upwards in the case of 3,5-dibromotyrosine and even more markedly with 3,5-diiodotyrosine. Quenching appears likely to occur by triplet-triplet energy transfer and especially in the case of the phenoxide form, also by electron transfer. The curvature denotes a static contribution to quenching favoured by the enzyme.