Oxidatively Generated Damage to Cellular DNA by UVB and UVA Radiation,

This review article focuses on a critical survey of the main available information on the UVB and UVA oxidative reactions to cellular DNA as the result of direct interactions of UV photons, photosensitized pathways and biochemical responses including inflammation and bystander effects. UVA radiation appears to be much more efficient than UVB in inducing oxidatively generated damage to the bases and 2‐deoxyribose moieties of DNA in isolated cells and skin. The UVA‐induced generation of 8‐oxo‐7,8‐dihydroguanine is mostly rationalized in terms of selective guanine oxidation by singlet oxygen generated through type II photosensitization mechanism. In addition, hydroxyl radical whose formation may be accounted for by metal‐catalyzed Haber–Weiss reactions subsequent to the initial generation of superoxide anion radical contributes in a minor way to the DNA degradation. This leads to the formation of both oxidized purine and pyrimidine bases together with DNA single‐strand breaks at the exclusion, however, of direct double‐strand breaks. No evidence has been provided so far for the implication of delayed oxidative degradation pathways of cellular DNA. In that respect putative characteristic UVA‐induced DNA damage could include single and more complex lesions arising from one‐electron oxidation of the guanine base together with aldehyde adducts to amino‐substituted nucleobases.     

Guanine-specific DNA damage photosensitized by the dihydroxo(tetraphenylporphyrinato)antimony(V) complex

The dihydroxo(tetraphenylporphyrinato)antimony(V) complex (SbTPP) demonstrates bactericidal activity under visible-light irradiation. This phototoxic effect could be caused by photodamage to biomolecules, but the mechanism has not been well understood. In this study, to clarify the mechanism of phototoxicity by SbTPP, DNA damage photosensitized by SbTPP was examined using [(32)P]-5'-end-labeled DNA fragments. SbTPP induced markedly severe photodamage to single-stranded rather than to double-stranded DNA. Photo-irradiated SbTPP frequently caused DNA cleavage at the guanine residue of single-stranded DNA after Escherichia coli formamidopyrimidine-DNA glycosylase or piperidine treatment. HPLC measurement confirmed the formation of 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxodG), an oxidation product of 2'-deoxyguanosine, and showed that the content of 8-oxodG in single-stranded DNA is larger than that in double-stranded DNA. The effects of scavengers of reactive oxygen species on DNA damage suggested the involvement of singlet oxygen. These results have shown that the mechanism via singlet oxygen formation mainly contributes to the phototoxicity of SbTPP. On the other hand, SbTPP induced DNA damage specifically at the underlined G of 5'-GG, 5'-GGG, and 5'-GGGG in double-stranded DNA. The sequence-specificity of DNA damage is quite similar to that induced by the type I photosensitizers, suggesting that photo-induced electron transfer slightly participates in the phototoxicity of SbTPP. In conclusion, SbTPP induces DNA photodamage via singlet oxygen formation and photo-induced electron transfer. A similar mechanism can damage other biomacromolecules, such as protein and the phospholipid membrane. The damage to biomacromolecules via these mechanisms may participate in the phototoxicity of SbTPP.     

PHOTOSENSITIZED FORMATION OF 8-HYDROXY-2'-DEOXYGUANOSINE AND DNA STRAND BREAKAGE BY A CATIONIC meso-SUBSTITUTED PORPHYRIN

Abstract Cationic porphyrins, known to have a high affinity for DNA, are useful tools with which to probe a variety of interactions with DNA. In this study we have examined both DNA strand scission and oxidative DNA base damage, measured by 8-hydroxy-2'-deoxyguanosine (8-OHdG) formation, using a photoactivated cis-dicationic por-phyrin. The data demonstrated a dose-dependent formation for each type of DNA damage. Inhibition of strand scission and 8-OHdG formation with the singlet oxygen scavenger 1,3-diphenylisobenzofuran and with MgCl₂ and no apparent effect by D₂O suggests that a singlet oxygen mechanism generated in close proximity to the DNA may be responsible for the damage. However, a nearly complete inhibition of 8-hydroxy-2'-deoxyguanosine formation in 75% D₂O and the substantial enhancement of 8-hydroxy-2'-deoxyguanosine formation in a helium atmosphere by photoactivated porphyrin rules out singlet oxygen as a primary mechanism for this process. These data indicate that distinct mechanisms lead to 8-OHdG formation and strand scission activity.     

THE PHOTOOXIDATION OF DIETHYLHYDROXYLAMINE BY ROSE BENGAL IN MICELLAR AND NONMICELLAR AQUEOUS SOLUTIONS

The photooxidation of N,N -diethylhydroxylamine (DEHA) by Rose Bengal (RB) has been investigated in micellar and nonmicellar aqueous solutions. We measured the quantum yield of oxygen consumption forming H₂O₂ and monitored two intermediates, the superoxide and diethylnitroxide radicals. When the pH was vaned, the quantum yield of oxidation remained constant for 6 < pH < 10.5, decreased in acidic pH, and increased considerably in NaOH solution; these changes could be attributed to the protonation and dissociation processes of the >N-OH moiety of DEHA. The formation of diethylnitroxide radical was enhanced by superoxide dismutase or strong alkaline solution. Around neutral pH, the oxidation proceeded mainly via electron transfer from DEHA to the RB triplet ( k _q = 10⁷ M ^-1 s^-1) with little ¹O₂ participation ( k_q < 10⁵ M ^-1 s^-1). However, when RB was incorporated into micelles in alkaline solution, the contribution of the singlet oxygen pathway increased at the expense of electron transfer, which was inhibited by the less polar micellar environment. Dark autoxidation of DEHA was accelerated by heavy metal impurities and increased very strongly in NaOH solution.     

SINGLET OXYGEN INDUCES FRANK STRAND BREAKS AS WELL AS ALKALI- AND PIPERIDINE-LABILE SITES IN SUPERCOILED PLASMID DNA

A covalently closed, circular, supercoiled plasmid was exposed to singlet oxygen by a separated-surface sensitizer. For each exposure, the quantity of single oxygen entering the DNA target solution was estimated by its oxidation of histidine. After singlet oxygen exposure, some DNA samples were treated to disclose occult lesions. Agarose gel electrophoresis was then used to resolve the unrelaxed supercoils from the relaxed circular and linear species, and all bands were quantitated fluorometrically. Exposure of supercoiled plasmid DNA to singlet oxygen induced frank DNA strand breaks, alkali-labile sites (pH 12.5, 90 degrees C, 30 min), and piperidine-labile sites (0.4 M, 60 degrees C, 30 min), all in a dose-dependent manner. Yields of alkali-labile and piperidine-labile sites ranged from one to four times the frank strand break yield. Replacement of buffered H2O by buffered D2O as the DNA solvent for singlet oxygen exposures increased DNA lesion yields by a factor of 2.6 (averaged over lesion classes). Our data for the detection of frank strand breaks is at variance with published results from studies in which singlet oxygen was derived from a thermolabile endoperoxide dissolved in the DNA solution.     

PHOTOSENSITIZATION OF SUPERCOILED DNA DAMAGE BY 5,6-DIHYDROXYINDOLE-2-CARBOXYLIC ACID, A PRECURSOR OF EUMELANIN

The photosensitizing or photoprotecting action of 5,6-dihydroxyindole-2-carboxylic acid (DICA), an intermediate in the biosynthesis of eumelanins, was investigated. Under irradiation at 313 nm, aqueous buffered solutions of DICA (22.5 μW) photosensitized the cleavage of phage φX174 DNA. The number of single strand breaks (SSB) depended on the dose of irradiation and was more important in the absence than in the presence of oxygen. In the presence of oxygen, the quantum yield of SSB was around 6′10 ⁷ (Φ_SSB) The influence of specific scavengers, such as mannitol, sodium azide or superoxide dismutase, indicated that hydroxyl radicals, superoxide anions and perhaps singlet oxygen were involved in these processes. The increase in SSB in D₂O was also indicative of the participation of singlet oxygen. Comparative experiments performed with indole-2-carboxylic acid (IC), a dehydrox-ylated analog of DICA, showed that this compound, although lacking a phenol group, also photosensitized DNA cleavage via a mechanism involving hydroxyl radicals. Various sources of these radicals were envisioned. Furthermore, under our conditions, DICA was not found to photoinduce the formation of DNA dimers: No increase in SSB was observed in DNA irradiated in the presence of DICA, after treatment by phage T4 endonuclease V (an enzyme that selectively cuts DNA at dimer sites), whereas, in contrast, a significant increase in SSB was detected after treatment of DNA irradiated alone. So it appears that DICA may both photosensitize DNA cleavage and reduce UV-induced DNA dimer formation.     

Photochemical reactions of aromatic ketones with nucleic acids and their components. 3. Chain breakage and thymine dimerization in benzophenone photosensitized DNA

Abstract— Excitation of benzophenone in the presence of calf thymus and E. coli DNA leads to photosensitized damages to the macromolecule. Two main reactions are observed: thymine dimerization and chain break formation. Benzophenone photosensitized chain breaks are also observed in polyadenylic acid. The melting temperature of DNA decreases with the duration of irradiation. Under our experimental conditions, the ratio of the yields of dimers and single-chain breaks produced in DNA is about 1. Photosensitized damage to deoxyribose residues leading to chain breakage is shown to be similar to that produced by X or γ ray irradiation. The oxygen effect upon chain break production is studied and discussed in relation with its effect upon intermediate species. Thymine dimers are formed following energy transfer from benzophenone in its triplet state. In previous flash-photolysis studies we showed that benzophenone in its triplet state reacts with water molecules to give ketyl and OH radicals. Ketyl radicals are not involved in reactions with DNA. It is proposed that OH radicals produced in the above reaction are responsible for the production of single-chain breaks by attack on the deoxyribose residues.     

MOLECULAR MECHANISM OF DRUG PHOTOSENSITIZATION 7. PHOTOCLEAVAGE OF DNA SENSITIZED BY SUPROFEN

Abstract— Ultraviolet-A irradiation of a suprofen (2-[4-(2-thenoyl)phenyl]propionic acid) (SPF) buffered solution (pH 7.4) in the presence of supercoiled pBR322 DNA leads to single strand breaks with the formation of an open circular form and subsequent linearization of the plasmid. On the basis of agarose gel electrophoresis data of samples irradiated in an air-saturated solution or in an oxygen-modified atmosphere, and the effects of sodium azide, D₂O, mannitol, copper(II), superoxide dismutase, 2-H-propanol, deferoxamine and surfactants, we suggest a photosensitization mechanism involving singlet oxygen and free radicals. The higher rate of photocleavage in nitrogen compared to that in an air-saturated solution and the results obtained from oxygen consumption measurements support the hypothesis that both the type I and type II photosensitization mechanisms are operative and that oxygen quenches the excited state of the irradiated drug. The photosensitization model applied was in agreement with that previously applied to cell membrane SPF photoinduced damage. Interaction of the drug with DNA, studied through circular dichroism and fluorescence anisotropy, probably occurs through a surface binding mode. The experimental techniques used for assessing the photodamaging activity of this drug may be useful for screening of phototoxic compounds in the environment and for determining the active species involved.     

Near-UV induced interstrand cross-links in anthraquinone-DNA duplexes

Anthraquinone (AQ) has been extensively used as a photosensitizer to study charge transfer in DNA. Near-UV photolysis of AQ induces electron abstraction in oligonucleotides leading to AQ radical anions and base radical cations. In general, this reaction is followed by the transport of base radical cations to sites of low oxidation potential, that is, GG, and conversion of G radical cations to DNA breaks. Here, we show that AQ also produces interstrand cross-links in DNA duplexes. About half of the cross-links collapse to single strands in hot piperidine treatment. The structure of stable interstrand cross-links was deduced by MS, NMR, and sequence substitution. The cross-links consist of a covalent link between the methyl group of T on one strand with either C6 or C7 of AQ on the other strand. The formation of interstrand cross-links decreased in O2 compared to deoxygenated solutions. In the presence of O2, the yield of breaks at GG doublets was 10-fold greater than that of cross-links for end tethered AQ, while cross-links exceeded breaks for centrally located AQ. The formation of stable cross-links can be explained by initial charge transfer from T to excited AQ, deprotonation of T radical cations, and condensation of the latter species with AQ radicals. These studies reveal a novel pathway of damage in the photolysis of AQ-DNA duplexes.     

Molecular Mechanism of Drug Photosensitization. IX. Effect of Inorganic Ions on DNA Cleavage Photosensitized by Naproxen

Abstract— Photocleavage of DNA induced by naproxen and the correlated protective effect by some inorganic ions have been considered. The presence of a DNA complex is suggested and only associated naproxen seems to be responsible for the cleavage, for which the quantum yield of single strand breaks was calculated. The inorganic ions I^-, Mn²⁺, Co²⁺ and Cu²⁺ decrease naproxen-photoin-duced DNA cleavage. Iodide acts by a heavy atom mechanism, thus inhibiting naproxen photolysis and decreasing the amount of free radicals responsible for the photocleavage both in aerobic and anaerobic conditions. Metallic ions protect only within a range of concentrations, as for higher amounts damaging processes are observed. The protective efficiency of cations decreases with the increase of free drug concentration in the bulk of the solution, due to their involvement in the scavenging of naproxen radicals generated by photolysis of the free drug. In the presence of EDTA the cations show a better protective action. The most likely hypothesis is an inhibiting effect on the damaging processes via a redox cycle. The different behaviors of copper and of the two other cations can be justified by the influence of redox potentials of free and complexed metals and by the superoxide dis-mutase-like activity of copper.     

Effects of direct radiation on deoxyribonucleic acid

It is argued that effects of ionizing radiation on DNA in cell nuclei may frequently be direct in the sense that many electron-gain and electron-loss centres become localised within the DNA molecules. The water of solvation that would also be present in the cell is presumed to pass on holes and electrons prior to the formation of OH· radicals and solvated electrons since these are not detected by ESR of in vitro model systems. Furthermore, a case is made that this direct damage may be particularly significant in that the cationic and anionic centres (G⁺ and T^- according to ESR results) are thought to be formed close enough together to lead, ultimately, to double strand breaks. Evidence that both G⁺ and T^- can lead to strand breaks is discussed. The presence of histone proteins modifies the yields of G⁺ and T^- to a significant extent. The effects of various additives are discussed. Oxygen has been shown by ESR spectroscopy to scavenge electrons in competition with DNA and also to react to form RO₂· radicals that are located on the DNA. It has been shown that this is accompanied by a significant enhancement of strand breaks. Nitroimidazoles act as efficient electron scavengers, their anions being clearly detected by ESR studies. The yield of T^- is consequently reduced and that of the protonated form, TH·, falls to zero. However, the initial yields of G⁺ are not greatly affected. This results in a reduction in the yield of single strand breaks and a proportionately greater decrease in the yield of double-strand breaks due to scavenging of only one of the radical centres. The origin of this is discussed in terms of a proposal for the mechanism of double-strand-break formation. Thus, at the molecular level these drugs protect the DNA against strand sission, in marked contrast with their radiosensitisation in vivo, particularly of hypoxic cells. Other additives studied include hydrogen peroxide and iodoacetamide. The studies on hydrogen peroxide have allowed us to assess the role of OH· radicals under the conditions used for ESR studies. Iodoacetamide gives ·CH₂CONH₂ radicals which are detected by ESR and, on annealing, these apparently attack the DNA to give species thought to be sugar radicals. This is associated with a significant increase in the yields of strand breaks. The ESR features assigned to sugar radicals have been shown to decay at temperatures below which the DNA radicals G⁺ and T^- are normally lost. This provides a good explanation of our failure to detect sugar radical intermediates by ESR spectroscopy on annealing samples in the absence of additives.     

Sequence specificity of alkali-labile DNA damage photosensitized by suprofen

On irradiation at UVB wavelengths, in aerated neutral aqueous solution, the anti-inflammatory drug suprofen (SP) photosensitizes the production of alkali-labile cleavage sites in DNA much more efficiently than direct strand breaks. It is active at submillimolar concentrations despite having no significant binding affinity for DNA. Gel sequencing studies utilizing 32P-end-labeled oligonucleotides have revealed that piperidine-sensitive lesions are formed predominantly at the positions of guanine (G) bases, with the extent of modification being UV dose- and SP concentration-dependent. Quite distinct patterns of G-specific damage are observed in single-stranded and duplex DNA molecules. The uniform attack at all G residues in single-stranded DNA, which is enhanced in D2O, is compatible with a Type-II mechanism. SP is a known generator of singlet oxygen whose participation in the reaction is supported by the effects of quenchers and scavengers. In duplex DNA, piperidine-induced cleavage occurs with high selectivity at the 5'-G of GG and (less prominently) GA doublets. This behavior is characteristic of a Type-I process involving electron transfer from DNA to photoexcited SP molecules. The ability of SP to sensitize the formation of Type-I and Type-II photo-oxidation products from 2'-deoxyguanosine attests to the feasibility of competing mechanisms in DNA.     

Electron attachment-induced DNA single strand breaks: C3'-O3' sigma-bond breaking of pyrimidine nucleotides predominates

A detailed understanding of DNA strand breaks induced by low energy electrons (LEE) is of crucial importance for the advancement of many areas of molecular biology and medicine. To elucidate the mechanism of DNA strand breaks by LEEs, theoretical investigations of the electron attachment-induced C3'-O3' sigma-bond breaking of the pyrimidine nucleotides have been performed. Calculations of 2'-deoxycytidine-3'-monophosphate and 2'-deoxythymidine-3'-monophosphate in their protonated form (denoted as 3'-dCMPH and 3'-dTMPH) have been carried out with the reliably calibrated B3LYP/DZP++ theoretical approach. Our results demonstrate that the transfer of the negative charge from the pi*-orbital of the radical anion of pyrimidines to the DNA backbone does not pass through the N1-glycosidic bond. Instead, the migration of the excessive negative charge through the atomic orbital overlap between the C6 of pyrimidine and the C3' of ribose most likely represents a pathway that subsequently leads to the strand breaks. The proposed mechanism of the LEE-induced single strand breaks in DNA assumes that the formation of the base-centered radical anions is the first step in this process. Subsequently, these electronically stable radical anions may undergo either C-O bond breaking or N-glycosidic bond rupture. The present investigation of 3'-dCMPH and 3'-dTMPH yields an energy barrier of 6.2-7.1 kcal/mol for the C3'-O3' sigma-bond cleavage. This is much lower than the energy barriers required for the C5'-O5' sigma-bond and the N1-glycosidic bond break. Therefore, we conclude that the C3'-O3' sigma-bond rupture dominates the LEE-induced single strand breaks of DNA.     

Electric magnetic resonance and spectrophotometry evidence on the photodynamic activity of a new perylenequinonoid pigment

Di-cysteine substituted hypocrellin B (DCHB) is a new water-soluble photosensitizer with significantly enhanced red absorption at wavelengths longer than 600 nm over the parent compound hypocrellin B (HB). The photosensitizing properties (Type I and/or Type II mechanisms) of DCHB have been investigated in dimethylsulfoxide (DMSO) and aqueous solution (pH 7.4) using electron paramagnetic resonance (EPR) and spectrophotometric methods. In anaerobic DMSO solution, the semiquinone anion radical of DCHB (DCHB^•−) is predominantly photoproduced via self-electron transfer between excited- and ground-state DCHB species. The presence of an electron donor significantly promotes the formation of the reduced form of DCHB. When a deoxygenated aqueous solution of DCHB and an electron donor are irradiated with 532 nm light, the hydroquinone of DCHB (DCHBH₂) is formed via the disproportionation of the first-formed DCHB^•− and second electron transfer to DCHB^•− from the electron donor. When oxygen is present, singlet oxygen (¹O₂), superoxide anion radical (O₂^•−) and hydroxyl radical (^•OH) are produced. The quantum yield of ¹O₂ generation by DCHB photosensitization is estimated to be 0.54 using Rose Bengal as a reference, a little lower than that of HB (0.76). The superoxide anion radical is also significantly enhanced by the presence of electron donors. Moreover, (O₂^•−) upon disproportionation generated H₂O₂ and ultimately the highly reactive ^•OH via the Haber-Weiss reaction pathway. The efficiency of (O₂^•−) generation by DCHB is obviously enhanced over that of HB. These findings suggest that the photodynamic actions of DCHB may proceed via Type I and Type II mechanisms and that this new photosensitizer retains photosensitizing activity after photodynamic therapy-oriented chemical modification.     

Structure reactivity relationship in the reaction of DNA guanyl radicals with hydroxybenzoates

In DNA, guanine bases are the sites from which electrons are most easily removed. As a result of hole migration to this stable location on guanine, guanyl radicals are major intermediates in DNA damage produced by the direct effect of ionizing radiation (ionization of the DNA itself and not through the intermediacy of water radicals). We have modeled this process by employing gamma irradiation in the presence of thiocyanate ions, a method which also produces single electron oxidized guanyl radicals in plasmid DNA in aqueous solution. The stable products formed in DNA from these radicals are detected as strand breaks after incubation with the FPG protein. When a phenolic compound is present in the solution during gamma irradiation, the formation of guanyl radical species is decreased by electron donation from the phenol to the guanyl radical. We have quantified the rate of this reaction for four different phenolic compounds bearing carboxylate substituents as proton acceptors. A comparison of the rates of these reactions with the redox strengths of the phenolic compounds reveals that salicylate reacts ca. 10-fold faster than its structural analogs. This observation is consistent with a reaction mechanism involving a proton coupled electron transfer, because intra-molecular transfer of a proton from the phenolic hydroxyl group to the carboxylate group is possible only in salicylate, and is favored by the strong 6-membered ring intra-molecular hydrogen bond in this compound.     

Photosensitization of 2'-deoxyadenosine-5'-monophosphate by pterin

UV-A radiation (320-400 nm) induces damages to the DNA molecule and its components through photosensitized reactions. Pterins, heterocyclic compounds widespread in biological systems, participate in relevant biological processes and are able to act as photosensitizers. We have investigated the photosensitization of 2'-deoxyadenosine-5'-monophosphate (dAMP) by pterin (PT) in aqueous solution under UV-A radiation. The effect of pH was evaluated, the participation of oxygen was investigated and the products analyzed. Kinetic studies revealed that the reactivity of dAMP towards singlet oxygen (1O2) is very low and that this reactive oxygen species does not participate in the mechanism of photosensitization, although it is produced by PT upon UV-A excitation. In contrast, analysis of irradiated solutions by means of electrospray ionization mass spectrometry strongly suggested that 8-oxo-7,8-dihydro-2'-deoxyadenosine-5'-monophosphate (8-oxo-dAMP) was produced, indicating that the photosensitized oxidation takes place via a type I mechanism (electron transfer).     

COMPARATIVE STUDY OF OXIDATION OF NUCLEIC ACID COMPONENTS BY HYDROXYL RADICALS, SINGLET OXYGEN AND SUPEROXIDE ANION RADICALS

Abstract— Superoxide radicals, singlet oxygen and hydroxyl radicals are individually or in combination involved in radiation or photochemical processes and in various enzymatic reactions. The reactivity and the mechanism of reaction of these oxygen species with some biologically significant DNA components were investigated through the characterization of the final oxidation products.
Superoxide radicals appear to be unreactive with purine and pyrimidine 2'-deoxyribonucleosides. However, the autoxidation reaction of 6-hydroxydopamine leads to extensive degradation of thymine through the intermediary of hydroxyl radicals. Chemically and microwave-discharge generated singlet oxygen oxidation is specific to 2'-deoxyguanosine. The main oxidized products of these reactions were also characterized as well as an as yet unidentified nucleoside in the methylene-blue photooxydation of 2-deoxyguanosine. These results, in addition to specific deuterium effect experiments, lend support to the involvment of singlet oxygen (type II mechanism) in the methylene-blue photosentization. No singlet oxygen effect was observed in aqueous irradiated system.     

SINGLET MOLECULAR OXYGEN INDUCED MUTAGENICITY IN A MAMMALIAN SV40-BASED SHUTTLE VECTOR

We have determined the deleterious effects of singlet oxygen (1O2), generated by thermal decomposition of the water-soluble endoperoxide 3,3'-(1,4-naphthylidene)dipropionate (NDPO2), on plasmid DNA. By following the electrophoretic mobility of DNA on agarose gels, we detected single and double strand breaks induced by treatment with NDPO2. The vector employed was a mammalian shuttle vector and the mutagenic consequences of these damages were investigated, using as mutation target the supF suppressor tRNA gene. A high increase of the mutation frequency, over the background, was observed in plasmids transfected in bacteria or after passage through mammalian cells. Trapping agents and quencher effects and other controls confirm the involvement of 1O2 in DNA damage and mutagenicity. These findings indicate that 1O2 can induce DNA lesions which are repaired by an error-prone process in prokaryotic and eukaryotic cells.     

ON THE REACTION OF SINGLET MOLECULAR OXYGEN WITH N-ALLYLTHIOUREA IN AQUEOUS SOLUTION

Abstract— Experiments on the photooxidation of N -allylthiourea, thiourea, and N-allylurea sensitized by the dye phenosafranine show that in N -allylthiourea the thiourea group is the site of singlet oxygen attack, while the allyl moiety neither reacts with nor quenches this metastable form of O₂ (in neutral aqueous solutions). Low concentrations of N^-₃ (a known quencher of singlet oxygen) strongly reduce the photooxidation of allylthiourea by a mechanism which apparently obeys simple competition kinetics. From these results the rate constant of the reaction between allylthiourea and singlet oxygen is obtained ( k = 4 × 10⁶ M ^-1 s^-1; pH = 7.1).     

Die photosensibilisierte Oxydation einwertiger Phenole zu Chinonen

The photosensitized oxidation of methyl substituted phenols with free para-positions starts with an electrophilic attack of position 4 by singlet oxygen. This follows from the course of the reaction using phenols with methyl groups in different positions. The influence of the solvent shows that the hydroperoxide formation from the primary oxygen adduct proceeds via an inter-molecular hydrogen shift. The solvent is the hydrogen donator, whereas the phenoxy radicals resulting from the oxidation of the phenol by the excited sensitizer are the hydrogen acceptors. Finally, the quinones are formed from the hydroperoxides by elimination of water.