PHOTO ACTIVATION OF ISOFLAVONOID PHYTOALEXINS: INVOLVEMENT OF FREE RADICALS

Abstract— Upon irradiation with ultraviolet light the isoflavonoid phytoalexins phaseollin, 3,6a, 9-trihydroxypterocarpan, glyceollin, tuberosin and pisatin, but not medicarpin, brought about inactivation ofglucose–6-phosphate dehydrogenase in an in vitro assay system. Photoinactivation of the enzyme by photoactivated pisatin in air-saturated solutions was hardly affected by singlet oxygen quenchers such as NaN₃, bovine serum albumin, histidine or methionine. Neither addition of the hydroxyl radical scavengers mannitol, Na-benzoate and ethanol nor the presence of catalase or supcroxide dismutase protected the enzyme against photoinactivation, suggesting that OH, H₂O₂ and O₂ are not the reactive oxygen species involved. However, the free radical scavenger S-(2-amino-ethyl)isothiouronium bromide hydrobromide (AET) protected the enzyme against inactivation by photoactivated pisatin. Direct evidence for the generation of free radicals was obtained by ESR measurements of solutions of phaseollin, pisatin and medicarpin in hexane irradiated with ultraviolet light in the presence or absence of O₂. Phaseollin produced the most stable free radicals, whereas medicarpin hardly gave rise to free radical formation; pisatin took a somewhat intermediate position by producing a strong ESR signal which, however, decayed rather quickly. Photodegradation of all phytoalexins, except for medicarpin, was accompanied with loss of fungitoxicity, as shown in thin-layer chromatographic bioassays, and formation of new products.
These results indicate free radical formation as the causative process for photoinactivation of enzymes by photoactivated isoflavonoid phytoalexins.     

SINGLET OXYGEN FORMATION BY SENSITIZATION OF FUROCOUMARINS COMPLEXED WITH, OR BOUND COVALENTLY TO DNA

Abstract— The formation of singlet molecular oxygen (¹O₂) by sensitization of the furocoumarins 5-methoxypsoralen (5-MOP), 8-methoxypsoralen (8-MOP) and psoralen complexed with DNA was investigated. From the results it is concluded that 5-MOP complexed with native DNA is able to generate ¹O₂, even in a larger extent than 5-MOP free in solution. Also, with 8-MOP and especially with psoralen, ¹O₂ formation by the complexed compound could be observed. The ¹O₂ formation sensitized by covalently bound furocoumarin was demonstrated with psoralen as a model compound. 4',5'-Dihydropsoralen, a model compound for the UVA light absorbing 4',5'monoadducts of furocoumarins to DNA, is also able to generate ¹O₂.     

INACTIVATION OF THE ACCEPTOR SIDE AND DEGRADATION OF THE D1 PROTEIN OF PHOTOSYSTEM II BY SINGLET OXYGEN PHOTOGENERATED FROM THE OUTSIDE

Abstract— The possible association of photodynamic sensitization with photoinhibition damage to the photosystem II complex (PS II) has been investigated using isolated intact thylakoids from pea leaves. For this study singlet oxygen (¹O₂), photoproduced by endogenous chromophores that are independent of the function of PS II, was assumed to be the major reactive intermediate involved in the photoinhibition process. When thylakoid samples preincubated with rose bengal were subjected to exposure to relatively weak green light (500–600 nm) under aerobic conditions, PS II was severely damaged. The pattern of the rose bengal-sensitized inhibition of PS II was similar to that of high light-induced damage to PS II: (1) the secondary quinone (Q_B)-dependent electron transfer through PS II is inactivated much faster than the Q_B-independent electron flow, (2) PS II activity is lost prior to degradation of the D1 protein, (3) diuron, an herbicide that binds to the Q_B domain on the D1 protein, prevents D1 degradation, and (4) PS II is damaged to a greater extent by the deuteration of thylakoid suspensions but to a lesser extent by the presence of histidine. Furthermore, it was observed that destroying thylakoid Fe-S centers resulted in a marked reduction of high light-induced PS II damage. These results may suggest that the primary processes of photoinhibition are mediated by ¹O₂ and that Fe-S centers, which are located in some membrane components, but not in PS II, play an important role in photogenerating the activated oxygen immediately responsible for the initiation of photodamage to PS II.     

SPECTROSCOPIC STUDIES OF CUTANEOUS PHOTOSENSITIZING AGENTS—II. SPIN TRAPPING OF PHOTOLYSIS PRODUCTS FROM SULFANILAMIDE AND 4-AMINOBENZOIC ACID USING 5,5-DIMETHYL-1-PYRROLINE-1-OXIDE

Abstract— The photodecomposition of sulfanilamide, 4-aminobenzoic acid and related analogs in aqueous solution has been studied with the aid of spin traps 5,5-dimethyl-1-pyrroline-1-oxide (DMPO) and CH₃NO₂ as well as by direct electron spin resonance techniques. The NH₂ radical was trapped by DMPO during the photolysis of aqueous solutions of sulfanilamide with a Xe arc lamp. Studies with [¹⁵N¹]-sulfanilamide indicated that the NH₂ radical was generated by homolytic fission of the sulfur-nitrogen bond. Under the same conditions DMPO trapped the H and SO⁻₃ radicals during photolysis of sulfanic acid. Direct photolysis of sulfanilamide, sulfanilic acid and Na₂SO₃ in the absence of any spin trap yielded the SO⁻³ radical. Photolysis of 4-aminobenzoic acid at pH 7 gave the H radical which was trapped by DMPO. At low pH values OH and C₆H₄COOH radicals were generated during the photolysis of 4-aminobenzoic acid. No e⁻_aq were trapped by CH₃NO₂ when acid (pH 4) and neutral aqueous solutions of sulfanilamide or 4-aminobenzoic acid were photoirradiated. The mechanism of formation of known photoproducts from the free radicals generated by sulfanilamide and 4-aminobenzoic acid during irradiation are discussed. The free radicals generated by these agents may play an important role in their phototoxic and photoallergic effects.     

Denaturation of a Recombinant Cutinase from Fusarium solani in AOT-iso-Octane Reverse Micelles: a Steady-State Fluorescence Study

Abstract— Near UV absorbance and fluorescence spectroscopy show conformational changes of a recombinant cutinase from Fusarium solani incorporated in sodium-di-2-ethylhexyl sulfosuccinate (AOT)-iso-octane reversed micelles with W₀= [H₂O]/[AOT] = 20. Excitation spectra were used to decompose cutinase absorbance in its Trp and Tyr components, showing that the latter absorb red-shifted in the native cutinase in aqueous solution as compared to free Tyr, whereas in reverse micelles and denatured cutinase no shift is detected. Emission maxima variations (λ_max 303, 311 and 335 nm, respectively in aqueous, reverse micelles and thermally denatured cutinase) reflect progressive changes in the micropolarity of the environment and exposure of Trp residues at the protein surface. The encapsulation of cutinase in AOT-iso-octane reversed micelles induces a time-dependent denaturation measured by fluorescence intensity changes at 330 nm, which match the profile of enzyme activity loss in this media.     

PHOTOSENSITIZING EFFECTS OF HEMATOPORPHYRIN DERIVATIVE IMMOBILIZED ON SEPHAROSE

Abstract— The cytotoxicity that ensues following photosensitization by hematoporphyrin derivative (Hpd) is attributed to production of singlet oxygen. Many of the cellular end points reported to be affected are localized to membranes, hydrophobic environments conducive to partitioning of hydrophobic porphyrins in Hpd. In order to test the hypothesis that efficacy of Hpd-induced photosensitization is enhanced by its ability to freely enter cells or subcellular organelles, we immobilized Hpd on a sepharose support. This immobilized reagent was found to produce ¹O₂ when photoradiated, in yields similar to those observed for Hpd in solution, as evidenced by the bleaching of p -nitrosodimethylaniline in the presence of imidazole. The immobilized Hpd was capable of photosensitizing, i.e. inhibit, cytochrome c oxidase activity in intact mitochondrial membranes and in aqueous solution. However, enzymes located on the interior of mitochondrial membranes (F₀F₁ ATP synthase and succinate dehydrogenase), in the mitochondrial matrix (malate dehydrogenase), or on the inside of the plasma membrane, (Na++ K+)- ATPase, were unaffected by immobilized Hpd plus photoradiation compared to free Hpd. The results suggest that photosensitization by Hpd most likely arises from entry of the photosensitizer into the biological membrane, although proteins on the exterior membrane surface may be susceptible to damage by ¹O₂ produced in proximity to their location.     

BACTERIORHODOPSIN AND THE SENSORY PIGMENT OF THE PHOTOSYSTEM 565 IN HALOBACTERIUM HALOBIUM

Abstract Blocking in vivo synthesis of retinal by addition of nicotine to the culture medium leads to the loss of photobehavior in Halobacterium halobium. Addition of rrans -retinol or frans-retinol₂ (3,4-dehy-droretinol) restores the responses to light decreases in the green-yellow spectral range. Action spectra of the reconstituted retinal- and retinal₂-photosystem show maximal sensitivity at 565 and 580 nm, respectively. Addition of retinol or retinol₂ also restores the formation of bacteriorhodopsin (BR) or bacteriorhodopsin₂ (BR₂= 3,4-dehydroretinal-bacterio-opsin complex). The absorption spectra of BR and BR₂, measured in isolated membranes, as well as in living bacteria, show maxima at 568 nm (BR) and at about 600 nm (BR₂), respectively. Comparison of the action spectrum of the retinal2-containing sensory photosystem with the absorption spectrum of BR₂ suggests that a retinal pigment different from BR is responsible for the photosensory behavior to green-yellow light.     

PHOTOKINETIC AND PHOTOPHYSICAL MEASUREMENTS OF THE SENSITIZED PHOTOOXIDATION OF THE TRYPTOPHYL RESIDUE IN N-ACETYL TRYPTOPHANAMIDE AND IN HUMAN SERUM ALBUMIN

Abstract— The photosensitized oxidation of 10–100 μ M N -acetyl-L-tryptophanamide (NATA) in neutral aqueous solution and in the presence of various dyes proceeds by a pure O₂(¹Δ_g)-involving mechanism. Incorporation of the tryptophyl (Trp) residue into the polypeptide chain of human serum albumin (HSA) has no influence on the mechanism and efficiency of Trp photooxidation when sensitized either by methylene blue, a non-binding dye, or by rose bengal, a dye that gives non-covalent 1: 1 complexes with HSA. This is due to the location of the Trp residue in close proximity of the protein surface and, in the case of rose bengal, to the coincidence of the photophysical properties (including the quantum yield of O₂(¹Δ_g) generation) for the free and HSA-bound dye. Hematoporphyrin also binds to HSA with 1: 1 stoichiometry, although at a different site from rose bengal. Bound Hp again displays photophysical properties very similar with those of free Hp; however, the efficiency of Trp photo-oxidation in HSA is about 5-fold higher than in NATA owing to a limited rearrangement of the protein structure, induced by Hp binding, which enhances the probability of chemical quenching of O₂(¹Δ_g) by the indole ring.     

EFFECT OF INTENSITY AND WAVELENGTH OF FLUORESCENT LIGHT ON CHROMOSOME DAMAGE IN CULTURED MOUSE CELLS

Abstract—A single 3- to 20-hr exposure of line NCTC 9266 mouse cells to cool-white fluorescent light (4.6 W/m²) produces chromatid breaks and exchanges. The effective wavelength is in the visible range and coincides with the mercury emission peak at 405 nm. Increasing light intensity from 4.6 W to 15.3 W/m² for 20 h causes a concomitant increase both in production of chromosome damage and formation of hydrogen peroxide (H₂O₂) in the serum-free medium. Cells washed free of medium and illuminated in saline for 3 h show chromosome damage to the same extent as cells illuminated in culture medium. Addition of catalase during the exposure period of 3 h eliminates the light-induced damage. We conclude that the light-induced chromatid breaks and exchanges result from H₂O₂ production within the cell and that exogenous catalase can enter the cell and prevent the damage.     

ULTRAVIOLET IRRADIATION OF POTATO VIRUS X, ITS RNA, AND A HYBRID VIRUS PARTICLE: PHOTOREACTIVATION, KINETIC ISOTOPE EFFECTS, AND QUANTUM YIELD OF INACTIVATION*

Abstract— Studies have been made of the inactivation of potato virus X (PVX), free PVX-RNA, and a phenotypically mixed virus particle composed of PVX-RNA and tobacco mosiac virus (U-1 strain) protein (PVX_RNA: TMV_PRO) by ultraviolet radiation of 254, 280 and 302 nm wavelengths. Rate constants and quantum yields of inactivation have been determined under conditions of photoreactivation and non-photoreactivation in H₂O and D₂O. The ratios of the rate constants in H₂O to those in D₂O obtained for PVX-RNA were greater than unity at the above three wavelengths, as was the case for PVX at 254 and 302 nm. The ratios of the rate constants were, within experimental error, equal to unity for PVX_RNA:TMV_PRO at all three wavelengths and for PVX at 280 nm. It is concluded that, in contrast to the situation observed with TMV and PVX_RNA:TMV_PRO, the behavior of the intact PVX viron upon irradiation closely approximates the behavior of free RNA in solution, on the basis of quantum yields of inactivation, photoreactivated sector, and the ratio of kinetic isotope effects in H₂O and D₂O.     

HYDROGEN PEROXIDE INDUCED RESISTANCE TO BROAD-SPECTRUM NEAR-ULTRAVIOLET LIGHT(300–400 nm) INACTIVATION IN Escherichia coli

Abstract— Strains of Escherichia coli carrying the four possible combinations of the alleles nur, nur⁺, uvrAb, and uvrA ⁺ were either untreated or pretreated with a sublethal dose of H₂0₂ prior to inactivation with NUV radiation. Pretreated cells exhibited a greater resistance to NUV than did untreated cells. Pretreatment with H₂O₂ did not induce resistance to FUV radiation. The induction of resistance to NUV inactivation by H₂O₂ pretreatment apparently leads to protection against the damage caused by NUV radiation. Although pretreatment of cells with H₂0₂ leads to resistance of such cells to inactivation by H₂O₂ and NUV, survival of H₂O₂ treated bacteriophage PI cml clr100 is not enhanced when assayed on H₂O₂ pretreated E. coli host cells.     

THE EFFECT OF IRRADIANCE ON VIRUS STERILIZATION AND PHOTODYNAMIC DAMAGE IN RED BLOOD CELLS SENSITIZED BY PHTHALOCYANINES

Abstract— Phthalocyanines are being studied as photosensitizers for virus sterilization of red blood cells (RBC). During optimization of the reaction conditions, we observed a marked effect of the irradiance on production of RBC damage. Using a broad-band light source (600–700 nm) between 5 and 80 mW/ cm², there was an inverse relationship between irradiance and rate of photohemolysis. This effect was observed with aluminum sulfonated phthalocyanine (AlPcS_n) and cationic silicon (HOSiPc-OSi[CH₃]₂ [CH₂]₃N⁺[CH₃]₃I^- phthalocyanine (Pc5) photosensitizers. The same effect occurred when the reduction of RBC negative surface charges was used as an endpoint. Under the same treatment conditions, vesicular stomatitis virus inactivation rate was unaffected by changes in the irradiance. Reduction in oxygen availability for the photochemical reaction at high irradiance could explain the effect. However, theoretical estimates suggest that oxygen depletion is minimal under our conditions. In addition, because the rate of photohemolysis at 80 mW/cm² was not increased when irradiations were carried out under an oxygen atmosphere this seems unlikely. Likewise, formation of singlet oxygen dimoles at high irradiances does not appear to be involved because the effect was unchanged when light exposure was in D₂O. While there is no ready explanation for this irradiance effect, it could be used to increase the safety margin of RBC virucidal treatment by employing exposure at high irradiance, thus minimizing the damage to RBC.     

INDUCTION OF FREE RADICALS IN DNA BY PROFLAVINE AND VISIBLE LIGHT: INFLUENCE OF OXYGEN AND IONIC STRENGTH

Abstract —The photosensitization of native DNA is observed as an induction of free radicals in the DNA moiety of proflavine-DNA complexes. The intensity of the electron paramagnetic resonance spectra (at 77 K) is a measure of the number of free radicals present in frozen solutions of DNA-proflavine complexes after irradiation with visible light (Λ > 320 nm). In the absence of O₂, the photosensitization is significant but very low; it increases slightly with increasing NaCl ionic strength; it appears to be due to intercalated dye molecules and the qualitative analysis of the spectra obtained shows that mainly thymidine is involved. The reaction measured after saturation with O₂ is the same as the reaction in air but is quantitatively higher; the free radicals observed are peroxides. This induction of free radicals appears to be due to the intercalated dye molecules, each molecule acting independently. The important observation is a very sharp and large (around a hundred-fold) increase in the photosensitizing efficiency of the bound dye molecules occurring in NaCl between μ, # 0–25 and μ= 0–5 and in MgCl₂ between μ# 0–01 and μ=0–1.     

HEMATOPORPHYRIN PHOTOSENSITIZATION OF SERUM ALBUMIN and SUBTILISIN BPN'

—The photosensitized inactivation of subtilisin BPN' by free hematoporphyrin (HP) followed exponential kinetics with positive mechanistic tests for the involvement of singlet oxygen (¹O₂) as the principal intermediate. The photoinactivation quantum yield was 0.029 at 390 nm in oxygen-saturated, D₂O buffer at pH 7.0. The effects of HP binding were investigated for tryptophan oxidation in bovine serum albumin (BSA) and human serum albumin (HSA) at high protein:HP concentration ratios where the HP was > 97% complexed. The reaction kinetics were non-exponential and mimick a second-order process in the initial stages. The rate of HP photobleaching was 30-fold faster for complexed HP compared with free HP, which was shown to account for the observed kinetics. Mechanistic tests showed that ¹O₂ was the dominant photooxidizing intermediate of tryptophan residues and that it was not involved in the accompanying photobleaching of HP. The quantum yield for tryptophan oxidation in BSA was 0.11 at 390 nm in oxygen-saturated, D₂O buffer at pH 8.0. The reactivity of HSA was approximately 2-fold lower than BSA for equivalent conditions. Estimates of the reaction cross sections led to 3 Ų for the inactivation of subtilisin BPN' by ¹O₂ and 20 Ų for the oxidation of tryptophan in BSA.     

A Photophysical Study of Purines and Theophylline by Using Laser-Induced Optoacoustic Spectroscopy

Abstract— The photophysics of purinic compounds (purine, 6-meth-ylpurine, 6-aminopurine [adenine], 6-chloropurine, 6-methoxypurine) and theophylline in acetonitrile solution were studied by pulsed laser-induced optoacoustic spectroscopy (LIOAS) exciting at 266 nm. The effect of O₂, Xe and MnCl₂ on the photophysical behavior of these compounds was studied; as well, the formation quantum yield of purine and 6-methylpurine triplet states were determined, with φ_T= 0.88 ± 0.03 for both compounds. Multiphotonic and depletion processes were observed at high laser fluences. In order to explain this behavior, theoretical UV-visible absorption electronic spectra from both the S₀ and S₁ state have been calculated for purines and theophylline by using the semiempirical PM3 and ZINDO/S methods.     

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).     

PHOTOCHEMICAL HYDROXYLATION OF 7,8-DIMETHYLALLOXAZINE (LUMICHROME)-A FLASH PHOTOLYSIS STUDY

Abstract— Flash photolysis experiments on the hydroxylation of lumichrome (L) in aqueous 0.5 M H₂SO₄ solution in the presence of O₂ or Ni²⁺ as triplet quenchers and quantum yield measurements confirm the assignment of the photoreactive species to the protonated form of the excited singlet state. A mechamism concerning the photochemical step is proposed, accounting for the formation of protonated 9-hydroxy-5,10-dihydrolumichrome (LOH₃⁺). This primary stable photoproduct was characterized by spectral and kinetic data. The dark reactions originating from LOH₃⁺ were investigated, and data regarding the successive steps are presented. The reaction LOH₃⁺ L→ LO + LH₃⁺ is demonstrated to be a two-electron reduction. The rate constant for the reaction of LH₂⁺ with O₂ is much larger than that for the oxidation of LH₃⁺ by oxygen.     

AN EPR STUDY ON THE TRIPLET STATE OF PURINE FREE BASE IN AQUEOUS GLASSES AT 77 K

Abstract— Since purine free base in aqueous solution exists in different ionic forms at different pHs and most of its photoreactions are likely to involve the triplet excited states of these different ionic forms, electron paramagnetic resonance studies (EPR) have been performed in order to determine intersystem crossing quantum yields and other characteristic parameters of the excited triplet state of these forms. Intersystem crossing yields decrease with a decrease in pH, being 0.62, 0.37 and 0.10 in 8 M NaOH, 8 M NaCIO₄ and 6M H₃P0₄ glasses, respectively. Differences in triplet decay lifetimes 3.4, 2.5 and 3.1 s, as well as in root mean-square zero-field splitting (ZFS) parameter, D_*, (0,1304, 0.1512 and 0.1353 cm_-1) are also observed for the anionic, neutral and cationic species of purine free base. The EPR signals of the triplet state of the neutral and anionic forms have been observed simultaneously in the pH range of7–10.     

EFFECT OF AGGREGATION ON THE HEMATOPORPHYRIN-SENSITIZED PRODUCTION OF SINGLET MOLECULAR OXYGEN

Abstract— The hematoporphyrin-sensitized production of singlet molecular oxygen, O₂(¹Δ_g), has been investigated in methanol and in aqueous solution. The quantum yield for formation of O₂(¹Δ_g) (Φ_Δ) has been measured by both steady-state (oxygen consumption) and time-resolved (near-infrared luminescence) methods. In methanol, both techniques indicate that Φ_Δ= 0.76 and the value remains independent of sensitizer concentration over a wide range. This finding is consistent with the dye persisting in a monomelic form in methanol solution. In contrast, Φ_Δ decreases markedly with increasing sensitizer concentration in water due to dimerization of the dye. Analysis of the steady-state data indicates Φ_Δ values of 0.74 and 0.12, respectively, for monomer and dimer. It is further shown that the efficiency whereby quenching of the triplet state by O₂ results in generation of O₂(¹Δ_g) is substantially lower for the dimer than for the corresponding monomer. Because monomer and dimer possess quite different absorption spectral profiles, the efficacy for photodynamic action with hematoporphyrin exhibits a pronounced wavelength dependence.     

A Comparative Kinetic and Mechanistic Study Between Tetrahydrozoline and Naphazoline Toward Photogenerated Reactive Oxygen Species

Kinetic and mechanistic aspects of the vitamin B2 (riboflavin [Rf])-sensitized photo-oxidation of the imidazoline derivates (IDs) naphazoline (NPZ) and tetrahydrozoline (THZ) were investigated in aqueous solution. The process appears as important on biomedical grounds, considering that the vitamin is endogenously present in humans, and IDs are active components of ocular medicaments of topical application. Under aerobic visible light irradiation, a complex picture of competitive interactions between sensitizer, substrates and dissolved oxygen takes place: the singlet and triplet (³Rf*) excited states of Rf are quenched by the IDs: with IDs concentrations ca.  5.0 m m and 0.02 m m Rf, ³Rf* is quenched by IDs, in a competitive fashion with dissolved ground state oxygen. Additionally, the reactive oxygen species: O₂(¹Δ_g), O₂^•−, HO^• and H₂O₂, generated from ³Rf* and Rf ^•−, were detected with the employment of time-resolved methods or specific scavengers. Oxygen uptake experiments indicate that, for NPZ, only H₂O₂ was involved in the photo-oxidation. In the case of THZ, O₂^•−, HO^• and H₂O₂ were detected, whereas only HO^• was unambiguously identified as THZ oxidative agents. Upon direct UV light irradiation NPZ and THZ generate O₂(¹Δ_g.), with quantum yields of 0.2 (literature value, employed as a reference) and 0.08, respectively, in acetonitrile.