TIME RESOLVED STUDIES OF 1.27 μm LUMINESCENCE FROM SINGLET OXYGEN GENERATED IN HOMOGENEOUS and MICROHETEROGENEOUS FLUIDS

-The luminescence at 1.27 μm from the ³→→¹δ_g transition of the oxygen molecule has been detected from a variety of liquid systems. A Q-switched laser delivering pulses of 532 nm light was the excitation source, a germanium photodiode was the detector and substituted porphyrins were used as photosensitizers. Protio- and deutero- forms of several solvents were studied and the singlet oxygen lifetimes determined directly agreed well with published values. T_δ in D₂O was found to be 55 μs and, by extrapolation from a series of H₂O - D₂O mixtures, a value of 3.3 μs was obtained for T_δ in H₂O. The technique was shown to be useful in measuring T_δ values in several microheterogeneous systems such as surfactant micelles, vesicles and human serum albumin.     

BIOLOGISCHE WIRKUNGEN PHOTOCHEMISCHER WASSERSTOFFPEROXYDBILDUNG:

Abstract— As previously demonstrated, there is a considerable increase in the photodynamic activity of anthraquinone-sulphonic acid on the addition of ethylene glycol, glycerol and sugars in concentrations of the order of 0.4 M . This system exhibits cytostatic activity. With H₂O₂ at higher concentrations there is also formation of aldehydes in approximately equivalent yields as follows:
R.CH₂OH+Q → QH₂+R.CHO
QH₂+O₂→ Q+H₂O₂
In accordance with the recent results of Warburg this accounts for the fundamental importance of glyceraldehyde in cancer research.
Our results on the irradiation of Proteus vulgaris SG2 in buffered medium with the addition of glycerin to anthraquinone-sulphonic acid show the existence of a similar cytostatic effect. One hour's irradiation with visible light reduces the cell count by about 50 per cent.     

THE QUANTUM EFFICIENCY OF DYE-INDUCED PHOTOELECTRIC EFFECTS IN BILAYER MEMBRANES

Abstract— Voltage transients are generated across lipid bilayer membranes by light flashes as a result of photophysical processes in sorbed dyes which displace electrical charges. A theory is presented which indicates that: (i) the fraction of sorbed dye which displaces charge from one flash can be determined by the fractional reduction in the photovoltage amplitude resulting from a second and identical flash, providing the second flash occurs before dye excited by the first flash returns to its equilibrium condition. (ii) The photoeffect quantum efficiency can be determined from the fraction of dye displacing charge, the light intensity and the dyes' optical absorption cross section. Apparatus constraints required different experimental procedures for dyes with different excited state life times, which are discussed. Experimental results are presented for an azo dye, 3,3'-bis(α-(trimethyiammonium)methyl)azobenzenebromide (Bis-Q), three carbocyanine dyes in the series 3,3'-dimethyl-2,2'-oxacarbocyanine-iodide (diO-C₁-3), an amino-pyridinium dye, 4-( p -(dimethyl-amino)styryl)-1-rnethyl-pyridinium-iodide (di-1-ASP), and a xanthene dye, 2',4',5',7'-tetraiodofluorescein (erythrosin), the sodium salt of which is known as F, D and C red number 3. The dyes' optical absorption cross section values are uncertain owing to solvent and orientational effects in membranes. Photoeffect quantum efficiency values obtained by calculating optical absorption cross sections from the dyes' molar extinction coefficients in aqueous solutions are: Bis-Q (0.08), diO-C₁-3 (0.31), diO-C₂-3 (0.22), diO-C₅-3 (0.08), di-l-ASP (0.3) and erythrosin (0.39).     

STOICHIOMETRY and KINETICS OF PROTON RELEASE UPON PHOTOSYNTHETIC WATER OXIDATION

Abstract— We studied the magnitude and the rise kinetics of proton release into the interior of thylakoids by flash spectrophotometty with neutral red as pH indicator. Excitation of dark-adapted thylakoids by a series of between 4 and 11 flashes produced a complex pattern of proton release into the thylakoid lumen. Proton release upon each flash was time resolved.
A slow component of proton release oscillated weakly in magnitude with period of two as function of flash number. It exhibited a half-rise time of approximately 20 ms from the very first flash on, and it was abolished by inhibitors of plastohydroquinone oxidation. This component was attributed to the oxidation of plastohydroquinone by PS I via the Cytb₆/f complex.
Additionally, rapid and multiphasic proton release was observed with half-rise times of less than 2 ms which exhibited a pronounced and damped oscillation with period of four as function of flash number. This rapid proton release was attributed to water oxidation. A detailed kinetic analysis suggested that proton release occurred with the following stoichiometry and with the following half-rise times during the transitions S₁ S_i+1 of water oxidation: 1 H⁺(250 μs, S₀→₁): 0 H⁺(S₁→ S₂):1 H⁺(200 μs, S₂→S₃):2 H⁺(1.2 ms, S₃→ S₄→ S₀) . Proton release and proton rebinding upon oxidation and reduction of the intermediate electron carrier Z, respectively, may have influenced the kinetics of the respective proton yields but not the stoichiometric pattern.     

PORPHYRIN-SENSITIZED PHOTOREACTIONS IN THE PRESENCE OF ASCORBATE: OXIDATION OF CELL MEMBRANE LIPIDS AND HYDROXYL RADICAL TRAPS

Abstract— Photooxidation reactions in ascorbate (AH)-containing erythrocyte membrane suspensions have been studied in broad perspective by simultaneously monitoring lipid peroxidation in the membrane compartment and formation of hydrogen peroxide (H₂O₂) and hydroxyl radical (OH) in the aqueous compartment. Non-bound uroporphyrin (UP) and membrane-bound protoporphyrin (PP) were used as sensitizers. Photoreduction of UP to the radical anion (UP^-) was detected by electron spin resonance when UP/AH/membrane mixtures were irradiated anaerobically. Aerobic irradiation resulted in a strong AH^--stimulation of lipid peroxidation, H₂O₂ formation, and OH^- generation (detected with 2-deoxyribose (DOR) and the spin trap 5,5-dimethyl-l-pyrroline-N-oxide). Use of diagnostic agents (e.g. catalase, desferrioxamine, mannitol) revealed that OH^- is involved in light-stimulated DOR oxidation, but not in lipid peroxidation. Similar irradiation in the presence of PP resulted in far greater lipid peroxidation than observed with UP, but less DOR oxidation, and insignificant accumulation of H₂O₂. This suggests that photoreduction of membrane-bound PP is less efficient, possibly due to hindered access of AH^-.     

THE REACTION OF METHYLENE WITH HYDROGEN

Abstract— An investigation has been made of the reaction between methylene, formed by the photolysis of ketene, and hydrogen. Ethane, ethylene and methane are the major hydrocarbon products, and it has been shown that the formation of these products may be adequately described by the sequence of processes
CH₂CO + hv → CH₂+ CO (1)
CH₂+ H₂→ CH₃+H (2)
2CH₃→ C₂H₆ (3)
CH₃+ H₂+ CH₄+ H (4)
CH₂+ CH₂CO → C₂H₄+ CO (7)
In particular, the relative rates of ethane and methane formation are consistent with the known rate constants for reactions (3) and (4), and it is not therefore necessary to postulate the participation of an 'insertion' process
CH₂+ H₂→ CH₄ (6) to account for the formation of methane.
Decrease of the energy possessed by the methylene, either by increase of the wavelength of ketene photolysis, or by increase of gas pressure, is shown to result in an increase in the reactivity of the methylene towards ketene relative to its reactivity towards hydrogen (i.e. the ratio k₂/k₂ increases).     

CHEMILUMINESCENCE AND THE FORMATION OF SINGLET OXYGEN IN THE OXIDATION OF CERTAIN POLYPHENOLS AND QUINONES

Abstract— The possibility of ¹O₂ (¹Δ_g) participation in the oxidation of polyphenols and quinones has been investigated in two systems: (1) the system involving autooxidation leading to oxidative polymerization and destruction, and (2) the modified Trautz-Schorigin reaction, i.e. oxidation of polyphenols and HCHO with H₂O₂ in concentrated alkaline solutions. The red band with maximum at 635 nm observed in chemiluminescence of pyrocatechol, adrenaline, pyrogallol, gallic acid, adrenochrome and p -benzoquinone corresponds to the transition 2O₂(¹Δ_g) → 2O₂(³Σ^-_g). Emission bands in the range 475–540 nm arise from the superposition of the 2O₂(¹Δ_g) → 2O₂(³Σ^-_g) transition and radiative deactivation of excited oxidation products. In system (2) chemiluminescence has a broad band from 580 nm beyond 800 nm and much higher intensity than in system (1). Formaldehyde was found to enhance light emission in system (1) by a factor of about 30. The influence of solvents, including D₂O in which ¹O₂ has varying lifetimes, on kinetics of chemiluminescence as well as quenching effect of β-carotene, hydroquinone, cysteine, bilirubin and biliverdin strongly support the involvement of ¹O₂ in the chemiluminescence of both systems.     

A MICROSECOND KINETIC STUDY OF THE PHOTOGENERATED MEMBRANE POTENTIAL OF BACTERIORHODOPSIN WITH A FAST RESPONDING DYE

Abstract— Bacteriorhodopsin is a light activated proton pump which generates proton and electric gradients across the cytoplasmic membrane of Halobacterium halobium. In this study, a dye whose fluorescence intensity responds rapidly to membrane potential was used to follow the evolution of the potential on liposomes reconstituted with bacteriorhodopsin, in the microseconds time domain. By comparing the formation kinetics of the potential to those of the long-lived intermediate species in the bacteriorhodopsin photocycle, M₄₁₂, both in H₂O and ₂H₂O suspensions, we can draw the following conclusion: the electric potential onset time is 20 μs after initiation of the illumination. The triggering of the potential is not the formation of the M₄₁₂ intermediate, which was hitherto considered to be the first species in the bacteriorhodopsin cycle which has an unprotonated Schiff base linkage at the retinal chromophore. Rather, the potential forms at the transition of the L₅₅₀ intermediate to the species X which precedes M₄₁₂ or even at the preceding conversion of K₅₉₀ to L₅₅₀.     

CHLOROPHYLL PHOTOSENSITIZED ELECTRON TRANSFER REACTIONS IN LIPID VESICLES:ENHANCEMENT IN YIELD OF VECTORIAL ELECTRON TRANSFER ACROSS THE BILAYER FROM REDUCED CYTOCHROME c TO OXIDIZED FERREDOXIN BY ADDITION OF VALINOMYCIN PLUS POTASSIUM ION

Chlorophyll photosensitized electron transfer across a vesicle bilayer from reduced cytochrome c in the inner compartment to oxidized ferredoxin in the outer compartment, using propylene diquat as a mediator, has been investigated using both steady-state and laser flash photolysis methods. One of the factors limiting the quantum yield is the transmembrane potential, which is formed during sample preparation and is increased by the electron transfer process across the membrane bilayer. This limitation can be diminished by the incorporation of valinomycin into the bilayer in the presence of potassium ion. The overall quantum yield can be approximately doubled (up to a total of 22% based on the chlorophyll triplet which is quenched, and 2.8% based on the absorbed quanta) by valinomycin addition. Another quantum yield limitation arises from the accumulation of oxidized cytochrome c in the inner aqueous compartment, which is formed as a consequence of the transbilayer electron transport process and can quench triplet chlorophyll on the inner side of the vesicle. The chlorophyll cation radical generated in this way can participate in the electron exchange equilibrium between chlorophyll molecules located within the bilayer, and thus inhibit electron flow from inside to outside. This acts to limit the extent of cytochrome c oxidation to less than or equal to 50% of the original amount.     

HYDROGEN AND OXYGEN PHOTOPRODUCTION BY TITANATE POWDERS

Abstract— Uncoated powders of TiO₂ or SrTiO₃ did not produce H₂ or O₂ on UV irradiation of aqueous suspensions of the powders. TiO₂ powders coated with platinum or rhodium photoproduced H₂ on irradiation (effective wavelengths 334 and 366 nm) and the reaction was stimulated by catalytic quantities of methyl viologen. The turnover numbers for H₂ production relative to TiO₂ were very low suggesting that the powders were not acting catalytically. Hydrogen production was never stoichiometric with respect to TiO₂ and the kinetics of H₂ production were first order, not zero order as would be expected for catalytic photolysis of water. Oxygen was never detected and it appears that H₂ did not arise from water photolysis but rather from oxidation of reduced sites in TiO₂. A rhodium-coated SrTiO₃ powder prepared photochemically produced both H₂ and O₂ on irradiation but the turnover numbers were very low. A Rh-SrTiO₃ powder prepared thermally showed higher turnover numbers for H₂ photoproduction and may be acting catalytically. However, little O₂ was detected with this powder. When the turnover numbers for the different titanate powders were expressed with respect to the number of surface monolayer hydroxyl groups calculated from the surface area of the powders, some turnover numbers greater than one were obtained.     

A Role for Hydrogen Peroxide in the Pro-apoptotic Effects of Photodynamic Therapy

Although the first reactive oxygen species (ROS) formed during irradiation of photosensitized cells is almost invariably singlet molecular oxygen (¹O₂), other ROS have been implicated in the phototoxic effects of photodynamic therapy (PDT). Among these are superoxide anion radical (^•O₂⁻), hydrogen peroxide (H₂O₂) and hydroxyl radical (^•OH). In this study, we investigated the role of H₂O₂ in the pro-apoptotic response to PDT in murine leukemia P388 cells. A primary route for detoxification of cellular H₂O₂ involves the peroxisomal enzyme catalase. Inhibition of catalase activity by 3-amino-1,2,4-triazole led to an increased apoptotic response. PDT-induced apoptosis was impaired by addition of an exogenous recombinant catalase analog (CAT- skl) that was specifically designed to enter cells and more efficiently localize in peroxisomes. A similar effect was observed upon addition of 2,2'-bipyridine, a reagent that can chelate Fe⁺², a co-factor in the Fenton reaction that results in the conversion of H₂O₂ to ^•OH. These results provide evidence that formation of H₂O₂ during irradiation of photosensitized cells contributes to PDT efficacy.     

VECTORIAL ELECTRON TRANSPORT ACROSS LIPID VESICLE MEMBRANES DRIVEN BY TWO PHOTOREACTIONS. I. ETHYLENEDIAMINETETRAACETIC ACID AS AN ELECTRON DONOR via FLAVIN TRIPLET STATE IN THE INNER COMPARTMENT AND CYTOCHROME c AS AN ELECTRON ACCEPTOR FROM CHLOROPHYLL TRIPLET STATE IN THE OUTER COMPARTMENT

Negatively charged vesicle suspensions containing chlorophyll a (chl) dissolved in the lipid bilayer, flavin mononucleotide (FMN) and/or ethylenediaminetetraacetic acid (EDTA) enclosed in the inner compartment as electron sources and oxidized cytochrome c (cyt c[ox]) in the outer compartment as an electron acceptor have been studied using laser flash photolysis and steady-state irradiation methods. Cytochrome c initially quenches the chl triplet state (³chl) generating the chlorophyll cation radical (chi⁺′) in the membrane. Reverse electron transfer from cyt c(red) to chl^+. subsequently occurs in a kinetically biphasic reaction, with rate constants of 430 pT 30 and 21.9 pT 1.7 s^?1 for the fast and slow phases, respectively. In the absence of FMN, reduction of chl⁺′ by EDTA in the inner compartment can be observed during steady-state irradiation but not in a laser flash photolysis experiment. This is due to a low reaction yield, which is probably limited by the repulsive electrostatic interaction between EDTA and the negatively charged membrane. When FMN was enclosed together with EDTA in the inner Compartment, the reaction yield of vectorial electron transfer across the bilayer from EDTA to cyt c(oX) was increased by a factor of six during steadystate white light irradiation. Laser flash photolysis and steady-state irradiation experiments using red and blue light excitation have demonstrated that the enhancement mechanism involves the formation of fully reduced FMN by blue light-sensitized photooxidation of EDTA via the flavin triplet state, occumng simultaneously with red lightsensitized electron transfer to cyt c via the chlorophyll triplet state.     

The Photoyellowing of Stilbene-derived Fluorescent Whitening Agents—Mass Spectrometric Characterization of Yellow Photoproducts

The application of fluorescent whitening agents (FWAs) significantly accelerates the photoyellowing of wool and silk under exposure to the ultraviolet and visible components of sunlight <500 nm. The photochemistry involved in this process is poorly understood, particularly the role of photoproducts derived directly from the FWA itself. Hydroxylation was identified as the key initial mechanism of photodegradation leading to coloration of the solution in the irradiation of the stilbene-derived FWA 4,4'-bis(2-sulfostyryl)biphenyl (DSBP) in the presence of hydrogen peroxide (H₂O₂). Polyhydroxylated DSBP derivatives were implicated as critical intermediates in the formation of yellow photoproducts under these conditions. The formation of trace quantities of DSBP quinone derivatives subsequent to hydroxylation was identified as the key cause of DSBP photoyellowing. These results are the first successful characterization of yellow photoproducts resulting directly from irradiation of a stilbene-based FWA. Formation of these yellow stilbene-based FWA-derived photoproducts may occur on the surface of FWA-treated wool exposed to simulated sunlight, as previous work has shown that H₂O₂ is photogenerated when wet FWA-treated wool is exposed to light. These results therefore suggest that yellow FWA-derived photoproducts contribute to the accelerated photoyellowing of FWA-treated wool.     

OBSERVATIONS ON THE PHOTOSENSITIZED BREAKAGE OF DNA BY 2-THIOURACIL AND 334-nm ULTRAVIOLET RADIATION

Abstract— Breaks induced in purified DNA by 334-nm ultraviolet (UV) radiation are enhanced 30 times when 2-thiouracil (s²Ura) is present during aerobic irradiation. This enhancement by s²Ura is maximally effective at a concentration of about 1 m M. Anoxic irradiation reduces the s²Ura-enhanced breakage by 90%, indicating a Type II photosensitization. Benzoate, glycerol, diazabicyclo[2.2.2.]octane (DABCO) and histidine all inhibit formation of s²Ura photosensitized breaks, unlike diethylenetriaminepenta-acetic acid (DETAPAC) and catalase, which do not. The relationships between the concentration of DABCO. benzoate and histidine and their protection against induction of single strand breaks (SSBs) were similar, with little inhibition below 10 m M and maximal inhibition near 0.1 M for all compounds. Irradiation of the DNA-s²Ura mixture dissolved in D₂O instead of H₂O enhanced the rate of induction of SSBs in DNA by 334-nm light almost five times. Addition of superoxide dismutase (40, 80 and 200 μg/ml) decreased the rate of induction of breaks in DNA by 334-nm radiation plus s²Ura (in H₂O) by about 40%. Boiled superoxide dismutase had no effect.     

Near-infrared Light Emission from Nanomolar-level Singlet Molecular Oxygen Generated with an Ultra low Concentration Mixture of Hypochlorite and Hydrogen Peroxide

Abstract— We report the detection of a weak near-infrared light emission originating from 8 nM singlet molecular oxygen (¹O₂) produced in a mixture of 1 m M hypochlorite (OC1^-) and 8 n M hydrogen peroxide (H₂O₂). The measurements were made with a highly sensitive detection system for ultraweak light emission in the 1.0-1.5 μm wavelength region. The emission intensity exhibited linear dependence for H₂O₂ concentrations in the range of 8-670 n M . The mixture containing a lower concentration (33 μ M ) of OCl^- pseudocontinuously emitted near-infrared light for 5 s. The rate constant for ¹O₂ production obtained from the kinetic analysis agrees with that previously reported. Our results demonstrate the possibility of measuring very low concentrations of ¹O₂ in a OCi-/H₂O² mixture as well as ¹O₂ production in intact living systems.     

NEAR-UV-INDUCED BREAKS IN PHAGE DNA: SENSITIZATION BY HYDROGEN PEROXIDE (A TRYPTOPHAN PHOTOPRODUCT)

Abstract— Near-UV irradiation of l -tryptophan yields a large number of photoproducts. When this mixture is added to recombinationless ( rec ) mutants of bacteria, the cells are killed. The most toxic component of tryptophan photoproducts has been identified as hydrogen peroxide (H₂O₂). We now report that both tryptophan photoproducts and H₂O₂ sensitize phage DNA to near-UV radiation resulting in enhanced killing as well as enhanced DNA breakages. We conclude that the in situ production of H₂O₂ via tryptophan photolysis may be an important biological event.     

EFFECT OF TEMPERATURE AND pH ON THE QUENCHING OF TRIPLET LUMIFLAVIN IN THE PRESENCE AND ABSENCE OF FERRI- AND FERROCYANIDE

Abstract— –Flash photolysis at 450 nm over the temperature range 0.8–60°C was used to determine Arrhenius parameters for the first and second order disappearance of triplet lumiflavin (1.66 µ .M ) at a flash energy of 2 kj in deaerated phosphate buffer at varying pH:
³Lf → Lf₀
³Lf +³Lf → Lf₀+ Lf₀
Arrhenius parameters were also determined for the pseudo first-order quenching of triplet lumiflavin by 10 µ M ferri- and ferrocyanide ions,
³Lf + Fe³⁺→ Fe³⁺→ Lf₀+ Fe³⁺ (energy transfer)
³Lf + Fe²⁺→ Lf^-+ Fe³⁺ (electron transfer)
and for disappearance of the semireduced lumiflavin in the presence of ferrocyanide at pH 6.8, by the second-order reaction
Lf^-+Lf ^-→ Lf₀+ Lf⁼.     

PROTECTION OF Ustilago violacea FROM TOLUIDINE BLUE PHOTOSENSITIZATION and HYDROGEN PEROXIDE INDUCED KILLING and MITOTIC RECOMBINATION BY CAROTENES

Abstract— The accumulation of (J-carotene in the ph/ph ⁺ y diploid strain of the smut fungus Ustilago violacea was associated with reduced killing and lower levels of induced mitotic recombination compared to the β-carotene lacking ph/ph⁺ w strain in response to both incandescent photosensitization and treatment with H₂0₂. The ph/ph⁺ y strain was only slightly more resistant to killing by exogenous toluidine blue (TB) photosensitization. The ph/ph⁺ y strain exhibited significantly greater levels of survival when exposed to incandescent radiation and 1.5 μ.M TB for 15 min, as well as 3.0. 0.3, 0.03, 0.003% H₂0₂ in the dark. The ph/ph⁺ y strain also exhibited lower levels of mitotic recombination after endogenous TB photosensitization and the latter two H₂0₂ treatments. Similar survival results were obtained for the carotene accumulating haploid strain l.C2y and the carotene lacking haploid strain l.C2iv in response to H₂0₂ exposure.     

ACTION OF HYDROGEN PEROXIDE ON HUMAN FIBROBLAST IN CULTURE

Abstract— Human fibroblasts in culture lose the capacity of proliferating when exposed to hydrogen peroxide in the concentration range of 1 to 10 μ M . The toxicity of H₂O₂ to xeroderma pigmentosum cells (XP12RO). defective in excision repair of lesions produced by UV-irradiation, was about twice as high as to cells proficient in excision repair (VA13). This compound produces single-strand breaks in intracellular DNA but not in purified DNA. These breaks are in situ physical discontinuities rather than alkali-labile bonds, and their generation occurs at the same extent at 4°C and 37° indicating that they are not produced by an endonuclease. The results favor the hypothesis that H₂O₂ reacts in the cell producing a radical species which brings about the formation of DNA single-strand breaks. These breaks are effectively repaired by both XP12RO and VA13 fibroblasts. The possible reason for the lethality of H₂O₂ is discussed.     

Role of Enterobactin and Intracellular Iron in Cell Lethality During Near-UV Irradiation in Escherichia coli

Abstract— In Escherichia coli, fur mutants that constitutively express their native iron chelating agent, enterobactin, are significantly more sensitive to near-UV radiation (NUV) than wild type. An entA mutant, which is incapable of synthesizing enterobactin, is equal to wild type in resistance to NUV irradiation. However, the addition of Fe⁺³ enterobactin but not Al⁺¹ enterobactin to entA cell suspensions just prior to irradiation results in an increased sensitivity to NUV irradiation. A fes mutant, which is unable to reduce and release iron from enterobactin, is significantly more sensitive to NUV irradiation than wild type. The addition of nontoxic levels of H₂O₂ (5 μ M ) just prior to irradiation significantly increases sensitivity of both fur and fes mutants. These results suggest that one mechanism by which NUV irradiation leads to cell lethality is by creating a transient iron overload, producing very favorable conditions for the production of highly deleterious free radicals through a variety of mechanisms that lead to oxidative stress and DNA damage including lethal and mutagenic lesions. These results are consistent with the hypothesis that enterobactin is an endogenous chromophore for NUV and contributes to cell lethality via the destruction of its ligand, releasing Fe⁺² into the cytoplasm to catalyze the production of highly reactive hydroxyl radicals and other toxic oxygen species via the Haber-Weiss reaction.