E.S.R. of spin-trapped radicals in aqueous solutions of 5-halo derivatives of nucleic acid constituents: reactions of hydrated electrons, hydroxyl radicals and U.V. photolysis

In order to obtain information concerning the mechanism of radio- and photosensitization due to 5-halogen substituted nucleic acid constituents, the free radicals produced in iodo-, bromo-, chloro- and fluoro-derivatives of uracil, uridine and deoxyuridine by reaction with hydrated electrons and with hydroxyl radicals and by direct U.V. photolysis have been studied by e.s.r. and spin-trapping. t-Nitrosobutane was used as the spin-trap. From 5-halogenated bases (except 5-fluorouracil) U.V. photolysis and reactions with hydrated electrons produced the uracilyl radical which was subsequently spin-trapped. When hydroxyl radical reactions were studied, the free radical at the N(1) position of the base was identified. From 5-fluorouracil U.V. photolysis generated the alpha-halo radical at the C(5) position of the base. For 5-halogenated ribonucleosides and deoxyribonucleosides, free radicals located on the sugar moiety were observed for reactions with hydrated electrons, hydroxyl radicals and for U.V. photolysis. The implications of these results for understanding the mechanism of radio- and photosensitization by 5-halogenated nucleic acids are discussed.     

Photosensitization of consitutents of nucleic acids by proflavine. Mechanism of formation of hydrogen addition radicals in frozen aquenous solutions (author's transl)]

It is shown that the insertion of nucleotides between proflavine molecules is favourable to photosensitization. Furthermore (1) each molecule of proflavine gives at the most one free radical in the substrate, (2) the chromophore is largely restored when oxygen is not present, (3) superoxide radicals are observed in the presence of oxygen, and (4) formyl radicals are detected. The scheme elaborated for the mechanism gives an explanation for all these observations.     

Photosensibilisation des constituants des acides nucleiques par la proflavine. Mecanisme de formation de radicaux d''addition d''hydrogene en solutions aqueuses gelees

Photosensitization of constituents of nucleic acids by proflavine. Mechanism of formation of hydrogen addition radicals in frozen aqueous solutions

It is shown that the insertion of nucleotides between proflavine molecules is favourable to photosensitization. Furthermore, (1) each molecule of proflavine gives at the most one free radical in the substrate, (2) the chromophore is largely restored when oxygen is not present, (3) superoxide radicals are observed in the presence of oxygen, and (4) formyl radicals are detected. The scheme elaborated for the mechanism gives an explanation for all these observations.     

巴氏碳球C_（60）对红细胞膜的光敏作用研究

用人红细胞膜作实验材料,研究了巴氏碳球Ｃ_（６０）对红细胞膜的光敏作用。结果发现,Ｃ_（６０）光激发后对膜蛋白质几种重要氨基酸有明显破坏作用,并氧化膜蛋白巯基和膜不饱和脂肪酸,采用ＮａＮ３和ＳＯＤ作抑制剂探明了Ｃ_（６０）的光敏作用存在氧自由基的影响,并在Ｃ_（６０）光激发后的电子顺磁共振（ＥＳＲ）研究中得到进一步证实。     

Binding of hypocrellin B to human serum albumin and photo-induced interactions

Molecular binding of hypocrellins to human serum albumin (HSA) needs to be further clarified considering the phototherapeutic potentials of hypocrellins to vascular diseases. In the current work, it was estimated that the binding constant of hypocrellin B (HB) to HSA was 2.28 x 10(4) M(-1). Furthermore, based on the fluorescence responses for both HB and the tryptophan of HSA, it was suggested that the binding of HB to HSA should be more specific rather than distributed randomly on the surface of HSA, which was also confirmed by photobleaching of the tryptophan via photosensitization of HB. Besides, it was found that both of the photo-bleaching of the tryptophan and the photo-oxidation of HB were principally oxygen-dependent, suggesting reactive oxygen species generated via the photosensitization of HB, instead of the free radicals of the photosensitizer (HB*-), play the most important role in photodynamic processes.     

Activated radical species of oxygen

Oxygen free radicals are often formed during photosensitization processes. Kinetic and thermodynamical characteristics are briefly described for OH and O2-. radicals.     

Peptide repair of oxidative DNA damage

Guanyl radical species are produced in DNA by electron removal caused by ionizing radiation, photoionization, oxidation, or photosensitization. DNA guanyl radicals can be reduced by electron donation from mild reducing agents. Important biologically relevant examples are the redox active amino acids cysteine, cystine, methionine, tryptophan, and tyrosine. We have quantified the reactivity of derivatives of these amino acids with guanyl radicals located in plasmid DNA. The radicals were produced by electron removal using the single electron oxidizing agent (SCN)(2)(*)(-). Disulfides (cystine) are unreactive. Thioethers (methionine), thiols (cysteine), and phenols (tyrosine) react with rate constants in the range 10(4)-10(6), 10(5)-10(6), and 10(5)-10(6) dm(3) mol(-1) s(-1), respectively. Indoles (tryptophan) are the most reactive with rate constants of 10(7)-10(8) dm(3) mol(-1) s(-1). Selenium analogues of amino acids are over an order of magnitude more reactive than their sulfur equivalents. Increasing positive charge is associated with a ca. 10-fold increase in reactivity. The results suggest that amino acid residues located close to DNA (for example, in DNA binding proteins such as histones) might participate in the repair of oxidative DNA damage.     

Genotoxicity of singlet oxygen

Singlet oxygen, ¹O₂(¹Δ_g), fulfills essential prerequisites for a genotoxic substance, like hydroxyl radicals and other oxygen radicals: it can react efficiently with DNA and it can be generated inside cells, e.g. by photosensitization and enzymatic oxidation. As might be anticipated from the non-radical character of singlet oxygen, the pattern of DNA modifications it produces is very different from that caused by hydroxyl radicals. While hydroxyl radicals produce DNA strand breaks and sites of base loss (AP sites) in high yield and react with all four bases of DNA, singlet oxygen generates predominantly modified guanine residues and few strand breaks and AP sites. There is now convincing evidence that a major product of base modification caused by singlet oxygen is 8-hydroxyguanine (7,8-dihydro-8-oxoguanine). Indeed, the recently reported miscoding properties of 8-hydroxyguanine can explain the predominant type of mutations observed when DNA modified by singlet oxygen is replicated in cells. There are also strong indications that singlet oxygen generated by photosensitization can act as an ultimate DNA modifying species inside cells. However, indirect genotoxic mechanisms involving other reactive oxygen species produced from singlet oxygen are also possible and appear to predominate in some cases. The cellular defense system against oxidants consists of effective singlet oxygen scavengers such as carotenoids. The observation that carotenoids can inhibit neoplastic cell transformation when administered not only together with but also after the application of chemical or physical carcinogens might indicate a role of singlet oxygen in tumor promotion that could be independent of the direct or indirect DNA damaging properties.     

Activated oxygen species produced by photoexcited furocoumarin derivatives

Furocoumarin derivatives (FCD) are investigated in order to determine their ability to photosensitize the production of activated oxygen species. Using the method based on the specific singlet oxygen (1O2) oxydation of cholesterol, all FCD except bergaten appeared to be able to produce 1O2 with various efficiencies. EPR spin trapping experiments show that photoexcited FCD produce hydroxyl radicals as detected by the formation of a DMPO-OH signal which can be abolished when the photosensitization reaction is carried out in the presence of specific OH scavengers. Moreover, the photo-ejection of hydrated electron (e-) by FCD is demonstrated by the loss of paramagnetic absorption of nitroxide free radicals as e- trap.     

A wavelength dependent mechanism for rose bengal-sensitized photoinhibition of red cell acetylcholinesterase

A 2-fold enhancement in the efficiency of rose bengal-photosensitized inhibition of red cell acetylcholinesterase activity was observed upon excitation of the dye in the ultraviolet (UV) (313 nm) compared to irradiation in the visible (514 or 550 nm). The measurements of efficiency of photosensitized enzyme inhibition were based on the effect produced when the same number of photons are absorbed by rose bengal (RB) at each wavelength. The mechanism for this unexpected enhancement of RB photosensitization upon UV excitation was investigated. The yield of singlet oxygen (O2(1 delta g], detected by time-resolved luminescence at 1270 nm, was independent of excitation wavelength for RB. Radicals were produced upon irradiation of RB at 313 nm but not at 514 nm as detected by bleaching of N,N-dimethylnitrosoaniline (RNO). Irradiation of RB at 313 nm but not at 514 nm appeared to cause homolytic cleavage of carbon-iodine bonds in the dye because iodine radicals, I, detected as I2 were produced with a quantum yield of 0.0041 +/- 0.0005 upon excitation in the UV. Photolysis of I2 in the presence of RNO caused bleaching of the RNO absorption at 440 nm, apparently resulting from reaction of I with RNO. Thus, the enhanced photosensitization upon UV excitation of RB is attributed to formation of I and/or RB. These results indicate that radicals, produced with low relative yield but having high reactivity compared to O2(1 delta g), can contribute to photosensitized enzyme inhibition and may represent an alternative mechanism for photodynamic therapy.     

ESR and optical absorption evidence for free radical involvement in the photosensitizing action of furocoumarin derivatives and for their singlet oxygen production.

Frozen aqueous solutions of thymine and its derivatives were irradiated with visible light (lambda greater than 320 nm) in the presence of various furocoumarins. ESR analysis revealed the induction of hydrogen adduct free radicals at C-6 position of thymine, only with those furocoumarin derivatives which show a skin-photosensitizing ability. It has been shown, moreover, that the photocycloaddition of psoralen to thymine, which is responsible for the biological effects of this dye, is inhibited when the induction of free radicals in thymine moiety has been prevented by electron scavengers. It is suggested that the free radicals observed could be involved in the biological photosensitization. The mechanism of free radical generation and singlet oxygen production by furoccoumarins were also investigated.     

Photochemical synthesis of simple organic free radicals on simulated planetary surfaces—An ESR study

Electron spin resonance spectroscopy provided evidence for formation of hydroxyl radicals during ultraviolet photolysis (254 nm) at −170°C of H₂O adsorbed on silica gel or of silica gel alone. The carboxyl radical was observed when CO or CO₂ or a mixture of CO and CO₂ adsorbed on silica gel at −170°C was irradiated. The ESR signals of these radicals slowly disappeared when the irradiated samples were warmed to room temperature. However, re-irradiation of CO or CO₂, or the mixture CO and CO₂ on silica gel at room temperature then produced a new species, the carbon dioxide anion radical, which slowly decayed and which was identical with that produced by direct photolysis of formic acid adsorbed on silica gel. The primary photochemical process may involve formation of hydrogen and hydroxyl radicals by means of (1) photodissociation of H₂O physically adsorbed on the silica gel, or (2) absorption of the excitation energy by the silica gel surface with subsequent cleavage of the silanol bonds, or (3) dissociation of H₂O molecules through photosensitization by the surfaces or a combination of (1) to (3). Subsequent reactions of these radicals with adsorbed CO or CO₂ or both yield carboxyl radicals, CO₂H, the precursors of formic acid. Our results confirm the formation of formic acid under simulated. Martian conditions and provide a mechanistic basis for gauging the potential importance of gas-solid photochemistry for chemical evolution on other extraterrestrial bodies, on the primitive earth and on dust grains in the interstellar medium.     

OH radical formation by photolysis of aqueous porphyrin solutions. A spin trapping and e.s.r. study

Radical production during the photolysis of deaerated aqueous alkaline solutions (pH 11) of some water-soluble porphyrins was investigated. Metal-free and metallo complexes of tetrakis (4-N-methylpyridyl)porphyrin (TMPyP) and tetra (4-sulphonatophenyl)porphyrin (TPPS4) were studied. Evidence for the formation of OH radicals during photolysis at 615, 545, 435, 408 and 335 nm of Fe(III) TPPS4 is presented. Fe(III) TMPyP, Mn(III) TPPS4 and Mn(III) TMPyP also gave OH radicals but only during photolysis at 335 nm. The method of spin trapping with 5,5-dimethyl-1-pyrroline-1-oxide (DMPO) and 4-pyridyl-1-oxide-N-tert-butylnitrone (POBN) combined with e.s.r. was used for the detection of OH, H and hydrated electrons. With the spin trap DMPO, photolysis generated DMPO-OH adducts under certain conditions but no DMPO-H adducts could be observed. With POBN, no POBN-H adducts were found. The formation of OH was confirmed by studying competition reactions for OH between the spin traps and OH scavengers (formate, isopropanol) and the concomitant formation of the CO-2 adduct and the (CH3)2COH adduct with both DMPO and POBN. The photochemical generation of OH radicals was pH dependent; at pH 7.5 no OH radicals could be detected. Photolysis (615-335 nm) of dicyanocomplexes of the Fe(III) porphyrins did not produce OH radicals. When corresponding Cu(II), Ni(II), Zn(II) and metal-free porphyrins were photolysed at 615 and 335 nm, no OH radicals could be spin trapped. These results tend to associate the well-known phenomenon of photoreduction of Fe(III) and Mn(III) porphyrins with the formation of OH radicals. This process is described mainly as the photoreduction of the metal ion by the ligand-bound hydroxyl ion via an intramolecular process.     

Modelling the photosensitization-based inactivation of Bacillus cereus

Aims:  To study and to develop a model for the photo-destruction of the foodborne pathogen Bacillus cereus , initially treated with a precursor of endogenous photosensitizers (5-aminolevulinic acid, ALA).
Materials and methods:  The cells were incubated in the presence of ALA (3 or 7·5 mmol l⁻¹) for incubation times ranging from 2 to 60 min, inoculated onto the surface of LB Agar plates and submitted to light irradiation. The Weibull model was used to describe the survival curves of B. cereus . Quadratic equations were used to describe the effects of ALA concentration and incubation time on the Weibull model parameters.
Results:  ALA-based photosensitization proved to be an effective tool for inactivation of B. cereus . The decrease in viable counts observed after 20 min of irradiation, ranged from 4 to 6 log CFU g⁻¹.
Conclusions:  The developed model proved to be a parsimonious and robust solution to describe the observed data.
Significance and Impact of the Study:  The study demonstrates the effectiveness of photosensitization on B. cereus on agar plates. The model developed may be useful to optimize inactivation treatments by photosensitization.     

Production of singlet oxygen and superoxide radicals by psoralens and their biological significance

We have investigated a series of linear and angular furocoumarins, capable of forming either the monofunctional adducts (single strand) or bifunctional adducts (interstrand cross-links) with DNA with a view to examine the relationship of their skin photosensitizing potency, their ability to produce singlet oxygen (1O2) or superoxide radicals (O-.2 or HO.2), and their carcinogenic activity. The significance of photochemical interactions of psoralens and DNA is well known in skin photosensitization and skin carcinogenesis. Our data suggest that both monofunctional and bifunctional psoralens produce 1O2 and O-.2, and these reactive forms of oxygen may contribute to the development of skin cancer and membrane-damaging effects of these furocoumarins.     

Thiyl radicals abstract hydrogen atoms from carbohydrates: reactivity and selectivity.

Free radical damage of DNA is a well-known process affecting biological tissue under conditions of oxidative stress. Though carbohydrate-derived radicals are generally "repaired" by hydrogen transfer from thiols, the reverse possibility, namely hydrogen abstraction by thiyl radicals from carbohydrates, exists. The biological relevance of this process has been discussed controversially, especially because of the lack of rate constants. Therefore, we have measured rate constants for the hydrogen transfer reaction between thiyl radicals from cysteine and selected carbohydrates, 2-deoxy-D-ribose (dRib), 2-deoxy-D-glucose (dGls), alpha-D-glucose (Gls), and inositol (Ino). Rate constants are on the order of 10(4) M(-1)s(-1), with the highest average value for dRib, (2.7 +/- 1.0) x 10(4) M(-1)s(-1), and the lowest average value for dGls, (1.6 +/- 0.2) x 10(4) M(-1)s(-1), based on two ways of kinetic analysis, standard competition kinetics and stochastic simulation of the experimental results, respectively. In general, thiyl radicals attack preferentially the C(1)-H bond of the carbohydrates, to an extent of ca. 72% in dRib and 90% in dGls. Kinetic measurements were possible through a specifically designed competition system measuring the reaction of thiyl radicals with either the C-H bonds of the carbohydrates or the C(alpha)-H bond of cysteine under conditions where the extent of other competitive reactions of the thiyl radicals were minimized.     

Molecular mechanisms of photosensitization

The first part of this article is devoted to basic concepts of photosensitization and to the primary photophysical and photochemistry processes involved in the reaction. The electronic configuration of molecular oxygen in its ground or activated states, which intervene in numerous photosensitized reactions, is reviewed. Finally, the main photosensitized reactions are reviewed and classified into three different groups: reactions due to radicals (type I), reactions due to singlet oxygen (type II) and those which do not involve oxygen (type III).     

Effective inactivation of food pathogens Listeria monocytogenes and Salmonella enterica by combined treatment of hypericin-based photosensitization and high power pulsed light

Aims: The aim of this study was to evaluate the inactivation efficiency of Listeria monocytogenes ATC_L3C 7644 and Salmonella enterica serovar Typhimurium strain DS88 by combined treatment of hypericin (Hyp)‐based photosensitization and high power pulsed light (HPPL). Methods and Results: Cells were incubated with Hyp (1 × 10^?5 or 1 × 10^?7 mol l^?1) in PBS and illuminated with a light λ = 585 nm. For the combined treatment, bacteria were, after photosensitization, exposed to 350 pulses of HPPL (UV light dose = 0·023 J cm^?2). Fluorescence measurements were performed to evaluate optimal time for cell–Hyp interaction. Results indicate that Hyp tends to bind both Listeria and Salmonella. After photosensitization treatment, Listeria population was reduced 7 log, whereas Salmonella was inactivated just 1 log. Electron photomicrograps of Salmonella and Listeria confirmed that photosensitization induced total collapse of the Listeria cell wall, but not that of Salmonella. After combined photosensitization–HPPL treatment, the population of Listeria was diminished by 7 log and Salmonella by 6·7 log. Conclusions: Listeria can be effectively inactivated by Hyp‐based photosensitization (7 log), whereas Salmonella is more resistant to photosensitization and can be inactivated just by 1 log in vitro. Combined treatment of photosensitization and pulsed light inactivates effectively (6·7–7 log) both the Gram‐positive and the more resistant to photosensitization Gram‐negative bacteria. Significance and Impact of the Study: A new approach to combat Gram‐positive and Gram‐negative bacteria is proposed, combining photosensitization with high power pulsed light.     

Adenosine Diphosphate Ribosylation of Dinitrogenase Reductase and Adenylylation of Glutamine Synthetase Control Ammonia Excretion in Ethylenediamine-Resistant Mutants of Azospirillum brasilense Sp7

Three bacterial strains—Escherichia coli, Acinetobacter calcoaceticus, and the A. calcoaceticus RecA(−) mutant—underwent photosensitization by a low-concentration (0.73 μmol/L) tetramethyl pyridyl porphine (a cationic hydrophylic photosensitizer) and a 4-J/cm² dose of 407 to 420 nm blue light. The viability of the first two strains decreased by approximately 60%. and that of the RecA(−) strain decreased by 90%. Increasing the amount of photosensitizer to 14.6 μmol/L at the same dose of blue light resulted in a 95% to 98% decrease in viability of the three strains. Very little damage to the bacterial DNA was observed after this treatment. Increasing the concentration photosensitizer under the same illumination conditions also resulted in very little damage to the DNA. Western blotting demonstrated that the low photosensitization procedures enhance RecA production for mending the damaged chromosomal DNA. RecA production as a result of low-dose photosensitization was confirmed and demonstrated by immunofluorescent staining and gold immunolabeling. Although DNA is not the primary target for photosensitization, this process of RecA production may provide a certain degree of DNA mending and may also affect the survival of bacterial cells on low-intensity photosensitization.     

Photogeneration of free radicals (*OH and HB*-) and singlet oxygen (1O2) by hypocrellin B in TX-100 micelles microsurroundings

To solve the problems faced in clinical use of hypocrellins, a water-soluble preparation of Hypocrellin B (HB), HB-Triton X-100 (TX-100) micelles, was prepared. To evaluate the photodynamic activity, the free radicals (^•OH and HB^•¯) and singlet oxygen (

1

O

2

) generated via photosensitization of the preparation in aqueous solution were detected by using electron paramagnetic resonance (EPR) and spectrophotometric methods. It was observed that

1

O

2

was formed with a quantum yield of 0.72, similar to that for HB in organic solvents, further, hydroxyl radicals (

•

OH) could also be efficiently produced by the new preparation, which have never before been detected following HB photoactivities. In addition, the semiquinone anion radicals (HB^•-) could also be generated via the self-electron transfer between an excited triplet state and a ground state molecule. The accumulation of HB^•- would replace that of

•

OH or

1

O

2

with the depletion of oxygen in the system. All these findings suggested that the HB-TX-100 micelles could play the photodynamic action through not only the type I mechanism by free radicals (^•OH, O₂^•- and HB^•-) but also the type II mechanism by singlet oxygen (

1

O

2

). It can be concluded further that the new preparation basically maintains the inherent photodynamic activity of HB, or even higher.