Distribution and quantitation of skin iron in primary haemochromatosis: correlation with total body iron stores in patients undergoing phlebotomy.

Measurement of the concentration of iron in the skin, if correlated with total body iron stores, may enable better informed decisions on when to initiate, change or stop therapy in hereditary heamochromatosis. Naïve haemochromatosis patients with iron overload and with C282Y and/or H63D HFE mutations were evaluated at the following time-points: disease diagnosis, end of the therapy programme, and 6 months after the end of therapy. The distribution and concentration of iron in the skin were assessed by quantitative nuclear microscopy methods, in parallel with serum and plasma iron concentration. Iron content in the liver was determined by nuclear magnetic resonance. Iron accumulated in the epidermis; its concentration increased from outer to inner layers, being maximal in the basal layer (7.33 ± 0.98 µmol/g). At all 3 time-points, most of the iron was associated with the extracellular space. During the phlebotomy programme the iron content of the skin and the liver decreased by a factor of 2. These data suggest that measurements of iron concentration in the epidermis, which is a readily accessible tissue, reflect iron overload in the liver.

Photosensitization of human skin fibroblasts by vemurafenib promotes pleiotropic effects on membrane-enclosed organelles and apoptosis.

Vemurafenib (VB), a BRAF inhibitor and a first-line treatment for unresectable or metastatic melanoma, is strongly phototoxic towards normal skin cells. Herein, we show that in cultured HS 68 human diploid dermal fibroblasts, low concentrations of VB suffice to promote photosensitization to low doses of UVA (∼ 5 J/cm2), as evidenced by a significant decrease in cell viability. In contrast to data obtained in chemico our results support a role for ROS (reactive oxygen species). Indeed, peroxidation of cellular lipids was observed which could be alleviated by the lipophilic antioxidant BHT (2,6-di-tert-butyl-4-methylphenol). Using in vivo confocal laser scanning microscopy and vital fluorescent probes it was shown at the single cell level that the plasma membrane and lipid-rich organelles, namely mitochondria, endoplasmic reticulum, and lysosomes, as well as actin filaments, were severely damaged by the UVA-induced VB-photosensitization. Finally, we showed that mitochondrial impairment was concurrent with caspase 3/7 activation and cell death by apoptosis.

Evidence for a slow and oxygen-insensitive intra-molecular long range electron transfer from tyrosine residues to the semi-oxidized tryptophan 214 in human serum albumin: its inhibition by bound copper (II).

A slow, long range electron transfer (SLRET) in human serum albumin (HSA) is observed from an intact tyrosine (Tyr) residue to the neutral tryptophan (Trp) radical (Trp·) generated in pulse radiolysis. This radical is formed, at neutral pH, through oxidation with Br (2) (·-) radical anions of the single Trp 214 present. The SLRET rate constant of ~0.2 s(-1) determined is independent of HSA concentration and radiation dose, consistent with an intra-molecular process. This is the slowest rate constant so far reported for an intra-molecular LRET. In sharp contrast with the LRET reported for other proteins, the SLRET observed here is insensitive to oxygen, suggesting that the oxidized Trp is inaccessible to-or do not react with radiolytically generated O (2) (·-) . In N(2)O-saturated solutions, the SLRET is inhibited by Cu(2+) ions bound to the His 3 residue of the N-terminal group of HSA but it is partially restored in O(2)-saturated solutions.

The dependence of α-tocopheroxyl radical reduction by hydroxy-2,3-diarylxanthones on structure and micro-environment.

The flavonoid quercetin is known to reduce the α-tocopheroxyl radical (˙TocO) and reconstitute α-tocopherol (TocOH). Structurally related polyphenolic compounds, hydroxy-2,3-diarylxanthones (XH), exhibit antioxidant activity which exceeds that of quercetin in biological systems. In the present study repair of ˙TocO by a series of these XH has been evaluated using pulse radiolysis. It has been shown that, among the studied XH, only 2,3-bis(3,4-dihydroxyphenyl)-9H-xanthen-9-one (XH9) reduces ˙TocO, though repair depends strongly on the micro-environment. In cationic cetyltrimethylammonium bromide (CTAB) micelles, 30% of ˙TocO radicals are repaired at a rate constant of ~7.4 × 10(6) M(-1) s(-1) by XH9 compared to 1.7 × 10(7) M(-1) s(-1) by ascorbate. Water-soluble Trolox (TrOH) radicals (˙TrO) are restored by XH9 in CTAB (rate constant ~3 × 10(4) M(-1) s(-1)) but not in neutral TX100 micelles where only 15% of ˙TocO are repaired (rate constant ~4.5 × 10(5) M(-1) s(-1)). In basic aqueous solutions ˙TrO is readily reduced by deprotonated XH9 species leading to ionized XH9 radical species (radical pK(a) ~10). An equilibrium is observed (K = 130) yielding an estimate of 130 mV for the reduction potential of the [˙X9,H(+)/XH9] couple at pH 11, lower than the 250 mV for the [˙TrO,H(+)/TrOH] couple. A comparable value (100 mV) has been determined by cyclic voltammetry measurements.

Structure-activity relationships in hydroxy-2,3-diarylxanthone antioxidants. Fast kinetics spectroscopy as a tool to evaluate the potential for antioxidant activity in biological systems.

A structure-activity relationship has been established for eight hydroxy-2,3-diarylxanthones (XH) bearing hydroxy groups on the two aryl rings. One-electron oxidation by superoxide radical-anions (˙O(2)(-)) and ˙Trp radicals as well as reaction with ˙CCl(3)O(2) and ˙CHCl(2)O(2) radicals demonstrates that two OH groups are required for efficient antioxidant reactivity in cetyltrimethylammonium bromide micelles. Hydroxy groups at the meta and para positions on either of the two phenyl rings confer enhanced reactivity, but XH bearing an OH at the para position of either phenyl ring is unreactive. While oxidation is favoured by OH in both meta and para positions of 2-aryl xanthone substituents, addition of a third and/or fourth OH enhances electron-donating capacity. In Cu(2+)-induced lipid peroxidation of human LDL, the lag period preceding the commencement of lipid peroxidation in the presence of XH bearing OH at meta and para positions on the 3-phenyl ring is extended to twice that observed with a comparable concentration of quercetin, a reference antioxidant. These antioxidants are also superior to quercetin in protecting human skin keratinocytes against tert-butylhydroperoxide-induced oxidative stress. While XH antioxidant activity in model biological systems is consistent with the structure-activity relationship, their response is also modulated by the localization of XH and by structural factors.

EDU (5-Ethynyl-2'-Deoxyuridine)-Coupled Fluorescence-Intensity Analysis: Determining Absolute Parameters of the Cell Cycle.

The principles and practice of a methodology of cell cycle analysis that allows the estimation of the absolute length (in units of time) of all cell cycle stages (G1, S, and G2) are detailed herein. This methodology utilizes flow cytometry to take full advantage of the excellent stoichiometric properties of click chemistry. This allows detection, via azide-fluorochrome coupling, of the modified deoxynucleoside 5-ethynyl-2'-deoxyuridine (EDU) incorporated into replicated DNA through incremental pulsing times. This methodology, which we designated as EdU-Coupled Fluorescence Intensity (E-CFI) analysis, can be applied to cell types with very distinct cell cycle features, and has shown excellent agreement with established techniques of cell cycle analysis. Useful modifications to the original protocol (Pereira et al., Oncotarget, 8:40514-40,532, 2017) have been introduced to increase flexibility in data collection and facilitate data analysis.

One-electron reduction of superoxide radical-anions by 3-alkylpolyhydroxyflavones in micelles. Effect of antioxidant alkyl chain length on micellar structure and reactivity.

In micellar solutions, one-electron reduction of *O2(-) radical-anions by 3-alkylpolyhydroxyflavones (FnH) with alkyl chains of n = 1, 4, 6, 10 carbons produces phenoxyl radicals ( (*Fn) identical to those obtained by one-electron oxidation by *Br2(-) radical-anions or by repair of tryptophan radicals. In cetyltrimethylammonium bromide (CTAB), F1H localizes in the Stern layer, and alkyl chains of other FnH solubilize in the hydrophobic interior, interacting with cetyl tails. This interaction produces more compact micelles with lower intramicellar fluidity, as suggested by the increase in the pseudo-first-order rate constant of *Fn formation ( k 1) from approximately 390 s (-1) for n = 1 to 610 s (-1) for n = 10, leading to an intramicellar bimolecular rate constant of 1 x 10 (5) M (-1) s (-1). Additionally, *F1 and *F4 decay by intermicellar bimolecular reaction (2 k = 20 and 2 x 10 (5) M (-1) s (-1), respectively) whereas other *Fn radicals are stable over seconds due to increased localization with regards to the Stern layer. In contrast, the thick uncharged hydrophilic palisade layer and the compact hydrophobic core of Triton X100 micelles are responsible for a much higher microviscosity resulting in a decrease in k 1 from approximately 15.6 s (-1) for n = 1 to 9.6 s (-1) for n = 10.

Photodynamic therapy: Dermatology and ophthalmology as main fields of current applications in clinic.

Photodynamic therapy (PDT) of skin tumors or pre-cancerous lesions and of age-related macular degeneration combines the administration of porphyrins or porphyrin precursors and illumination with red light at the diseased sites. Photosensitizers absorbing light beyond 630 nm where tissues have the highest transmittance produce singlet oxygen, a highly reactive activated oxygen species and a major cytotoxin. The PDT of age-related macular degeneration is performed with red laser light after i.v. injection of verteporfin (Visudyne) a hydrophobic porphyrin carried by serum lipoproteins whose endocytosis leads to accumulation of the porphyrin in endothelial cells of choroidal neo-vessels. In the PDT of skin cancers, local synthesis of the photosensitizer occurs after topical application of the natural protoporphyrin IX precursor delta-aminolevulinic acid (or its ester forms) on the lesions. In all the cases, the photosensitizers should be rapidly excreted to avoid a long lasting skin photosensitivity.

Targeting TNFα in severe psoriasis-mass spectrometry reveals a time-dependent specific inhibition of Factor H in responding patients.

Drugs targeting TNFα (eg, Etanercept®) provide effective control of severe psoriasis. In absence of validated biological parameters of inflammation in psoriasis most decisions on therapeutics have relied mostly on clinical criteria, namely the "Psoriasis Area and Severity Index" (PASI). The purpose of this study was to assess by mass spectrometry alterations in concentrations of serum proteins that specifically correlated with effectiveness of Etanercept treatment. This prospective study enrolled 10 patients suffering from moderate to severe psoriasis (PASI score > 10 and < 17) and treated with Etanercept over a period of 24 weeks; 10 healthy, age-matched volunteers provided controls. Serum proteins sensitive to Etanercept treatment were identified using SELDI-TOF (surface-enhanced laser desorption and ionization - time of flight) coupled to nano LC-ESI/MS (nano liquid chromatography-electrospray ionization/tandem mass spectrometry) technologies. For comparisons between groups of individuals p-values (considered significant when < 0.01) were estimated with non-parametric tests, namely Mann-Whitney (for unpaired data) and Wilcoxon signed-rank (for paired data). In responding patients it could be shown using SELDI-TOF spectrometry that two proteins (134 kDa and 4.3 kDa) return to control levels by 24 weeks of treatment. Using nano LC-ESI/MS the 134 kDa species was identified as complement Factor H. These observations deserve further analyses utilizing larger cohorts of patients. Determination of Factor H levels may become a complementary tool to follow remission or predict the onset of relapse in the follow-up of patients under treatment with Etanercept.

Quantification of cell cycle kinetics by EdU (5-ethynyl-2'-deoxyuridine)-coupled-fluorescence-intensity analysis.

We propose a novel single-deoxynucleoside-based assay that is easy to perform and provides accurate values for the absolute length (in units of time) of each of the cell cycle stages (G1, S and G2/M). This flow-cytometric assay takes advantage of the excellent stoichiometric properties of azide-fluorochrome detection of DNA substituted with 5-ethynyl-2'-deoxyuridine (EdU). We show that by pulsing cells with EdU for incremental periods of time maximal EdU-coupled fluorescence is reached when pulsing times match the length of S phase. These pulsing times, allowing labelling for a full S phase of a fraction of cells in asynchronous populations, provide accurate values for the absolute length of S phase. We characterized additional, lower intensity signals that allowed quantification of the absolute durations of G1 and G2 phases.Importantly, using this novel assay data on the lengths of G1, S and G2/M phases are obtained in parallel. Therefore, these parameters can be estimated within a time frame that is shorter than a full cell cycle. This method, which we designate as EdU-Coupled Fluorescence Intensity (E-CFI) analysis, was successfully applied to cell types with distinctive cell cycle features and shows excellent agreement with established methodologies for analysis of cell cycle kinetics.

Photodynamic therapies: principles and present medical applications.

Photodynamic therapy (PDT) by porphyrins and related tetrapyrrole derivatives is an emerging new treatment modality of tumors of lung, eosophagus and skin and of age-related macular degeneration. Phase III clinical trials for other applications such as re-stenosis after angioplasty are also underway. Under systemic conditions, the transport of porphyrin photosensitizers by serum low density lipoproteins and their specific delivery to tumor cells and vasculature is a determinant of treatment effectiveness. However, this effectiveness can be improved by increasing the selectivity of the photosensitizer uptake by tumors and by using photosensitizers absorbing light in the 660-800 nm range where tissues have the highest transmittance. Another treatment showing great promise is the PDT of skin cancers after topical application of the protoporphyrin IX precursor delta-aminolevulinic acid (or its ester forms). In all the cases, the photosensitizers should be rapidly excreted to avoid a long lasting skin photosensitivity.

Interplay Between Membrane Lipid Peroxidation and Photoproduct Formation in the Ultraviolet A-Induced Phototoxicity of Vemurafenib in Skin Keratinocytes.

According to some authors, the phototoxic response to ultraviolet A (UVA) of patients treated with vemurafenib (VB) may involve VB metabolites. However, the production of singlet oxygen and free radicals and photoproduct formation upon UVA light absorption by the lipophilic VB have been demonstrated. This work is aimed at determining the contribution of reactive oxygen species (ROS), lipid photoperoxidation, and VB photochemistry in the UVA-induced photocytotoxicity in NCTC 2544 keratinocytes. The potent membrane lipid peroxidation effectiveness of VB-photosensitization has been proved by the observation of an effective photohemolysis accompanied by thiobarbituric reactive substances (TBARS) formation in 2% red blood cell (RBC) suspensions. Photohemolysis is inhibited by human serum albumin (HSA) that binds VB and by the antioxidants 2,6-di-tert-butyl-4-methylphenol and Trolox. These data on RBC suggest that VB is readily incorporated in cell membranes and provide clues for understanding the UVA-induced VB-photosensitization of keratinocytes. In keratinocytes, ROS and TBARS formation with 10 µM VB is inhibited by approximately 40% and 50% by 30 µM Trolox and 50 µM vitamin E, respectively, but the light dose-dependent cell survival is unaffected. Whereas cell photokilling depends on the VB concentration, much smaller changes in the lethal doses (LD) than theoretically expected are observed for 25% or 50% cell photokilling when changing absorbed UVA doses and irradiation wavelengths. The lack of antioxidant effect on cell survival and the unexpectedly small LD dependence on absorbed UVA light doses and on irradiation wavelengths strongly suggest that, instead of metabolites, membrane photosensitization and photoproduct formation contribute to the cell photocytotoxicity.

Mechanisms of flavonoid repair reactions with amino acid radicals in models of biological systems: a pulse radiolysis study in micelles and human serum albumin.

Neutral tryptophan (*Trp) and tyrosine (TyrO(*)) radicals are repaired by certain flavonoids in buffer, in micelles and in human serum albumin (HSA) with corresponding formation of semioxidized flavonoid radicals. In deaerated buffer, *Trp but not TyrO(*) radicals react with catechin. In micelles, quercetin and rutin repair both *Trp and TyrO(*) radicals. In addition to amino acid reactivity, microenvironmental factors and nature of the flavonoids govern this repair. Electron transfer efficiencies from quercetin to negatively charged *Trp radicals are 100% in the micellar pseudophases of positively charged cetyltrimethylammonium bromide, (CTAB), and neutral Triton X100 (TX100), but 55% in negatively charged sodium dodecyl sulfate (SDS). In oxygen-saturated CTAB micelles, quercetin also reacts with the superoxide radical anion. When bound to domain IIA of HSA, quercetin repairs, by intra- or intermolecular encounter, less than 20% of oxidative damage to HSA. Quercetin can also repair freely circulating oxidized molecules with repair efficiencies falling to 7% for oxidized *Trp, Tyr and alpha-MSH and to less than 2% for urate radical. This limited effectiveness is attributed both to the inaccessibility of bound quercetin and rutin toward radicals of circulating molecules and to the diffusion-controlled recombination of these radicals.

Mechanisms of flavonoid repair reactions with amino acid radicals in models of biological systems: a pulse radiolysis study in micelles and human serum albumin.

Neutral tryptophan (*Trp) and tyrosine (TyrO(*)) radicals are repaired by certain flavonoids in buffer, in micelles and in human serum albumin (HSA) with corresponding formation of semioxidized flavonoid radicals. In deaerated buffer, *Trp but not TyrO(*) radicals react with catechin. In micelles, quercetin and rutin repair both *Trp and TyrO(*) radicals. In addition to amino acid reactivity, microenvironmental factors and nature of the flavonoids govern this repair. Electron transfer efficiencies from quercetin to negatively charged *Trp radicals are 100% in the micellar pseudophases of positively charged cetyltrimethylammonium bromide, (CTAB), and neutral Triton X100 (TX100), but 55% in negatively charged sodium dodecyl sulfate (SDS). In oxygen-saturated CTAB micelles, quercetin also reacts with the superoxide radical anion. When bound to domain IIA of HSA, quercetin repairs, by intra- or intermolecular encounter, less than 20% of oxidative damage to HSA. Quercetin can also repair freely circulating oxidized molecules with repair efficiencies falling to 7% for oxidized Trp, Tyr and alpha-MSH and to less than 2% for urate radical. This limited effectiveness is attributed both to the inaccessibility of bound quercetin and rutin toward radicals of circulating molecules and to the diffusion-controlled recombination of these radicals.

Low UVA doses activate the transcription factor NFAT in human fibroblasts by a calcium-calcineurin pathway.

UVA radiation induces an inflammatory response as observed in erythema, and the cytokine genes involved in this response are under the control of the transcription factor NFAT (nuclear factor of activated T lymphocytes). The effects of UVA on NFAT DNA binding activity were investigated in cultured human fibroblasts. A dose-dependent increase was observed within the range of 0.6-4.5 J/cm2 UVA. Beyond this value, the activity decreased and a value of 60% of control was found at 13.5 J/cm2. The enhancement of NFAT activity was transient and peaked 45 min after irradiation. Furthermore, immunoblot analysis demonstrated a nuclear translocation of NFAT under low UVA doses. Concomitantly, as assessed by the fluorescent probe Fluo3, UVA induced an increase in intracellular free calcium, with a maximum increase found at 9 J/cm2. The UVA-induced activation of NFAT was prevented by the intracellular calcium trapping drug BAPTA, whereas the extracellular calcium chelator EGTA had no significant effect. In addition, the calcineurin inhibitors cyclosporin A and FK506 both prevented the UVA-induced NFAT activation. Furthermore, the antioxidant vitamin E prevented the UVA-induced increase in both intracellular free calcium and NFAT binding activity. Finally, the cytotoxicity of UVA was enhanced in the presence of the inhibitors cyclosporin and FK506, suggesting that the activation of NFAT might play a protective role after the UVA-induced oxidative stress. These results demonstrate that UVA activates the calcium-calcineurin signaling pathway of NFAT activation, that the calcium ions are mainly released from intracellular stores, and that the increase in calcium is, at least partially, due to the oxidative stress generated under UVA. Because NFAT regulates several genes implicated in the inflammatory response, the enhancement of NFAT activity by low UVA doses might be interpreted in view of the proinflammatory action of solar radiation.

Assessment of laboratory and field assays of sunlight-induced killing of mosquito larvae by photosensitizers.

The effectiveness of light-induced killing of mosquito larvae in the presence of photosensitizers was studied with larvae of Aedes aegypti (L.), Anopheles stephensi (Liston), and Culex quinquefasciatus Say grown in the laboratory and of Cx. quinquefasciatus grown under field conditions. Tested photosensitizers included xanthene, chlorin, and porphyrin derivatives. All the larvae were treated at the fourth instar. Preliminary laboratory experiments showed a light-induced lethal effect of Rose Bengal (RB) on three species of mosquito larvae. Compared with other photosensitizers, RB seemed to be more efficient at even lower concentration than chlorin (e6) and chlorophyllin on Ae. aegypti larvae. Among the four porphyrin derivatives, i.e., chloroquinoline tetraphenyl propioamidoporphine, tetraphenyl porphine tetrasulfonate, hematoporphyrin (HP), and tetraphenylporphinepropionic acid porphine, HP was the only effective photosensitizer on Ae. aegypti larvae. The best conditions for field tests using RB were conducted on Cx. quinquefasciatus in Bobo-Dioulasso, Burkina Faso. The mortality induced by RB varied from 80 to 96% obtained with unfiltered cesspit water to 0.4 to 6.7% in cesspits with a heavy load of organic materials, thus providing the basis for further developments of this technique under field conditions.

Impairment of the EGF signaling pathway by the oxidative stress generated with UVA.

Ultraviolet A (UVA) is a component of sunlight reaching the surface of the earth and involved in photodegenerescence and photocarcinogenesis. The effect of UVA was investigated on the EGF-induced activation of the signaling kinase ERK and the transcription factors AP1, NFkappaB, and STAT1. UVA prevented the Epidermal Growth Factor (EGF)-induced stimulation of ERK in a dose-dependent manner within the range of 1.5-9 J/cm(2). Concomitantly, the DNA binding activity of AP1, NFkappaB, and STAT1 under EGF were markedly inhibited by UVA within the same dose range. UVA by itself induced an activation of ERK activity, and a stimulation of AP1, NFkappaB, and STAT1 binding activity. UVA decreased EGF binding in a dose-dependent manner. Furthermore, the highest dose of UVA (9 J/cm(2)) prevented the EGF-induced Tyr-phosphorylation of the EGF-receptor (EGF-R). The generation of reactive oxygen species (ROS), as assessed by the fluorescent probe dichloro-fluorescein, showed an additive effect of EGF and UVA, within the studied range of UVA doses. Finally, the antioxidant Vitamin E prevented the inhibitory effect of UVA on ERK, AP1, NFkappaB, and STAT1. These results demonstrate that an overproduction of ROS, initiated by two different and successive triggering agents such as UVA and EGF, leads to inactivation of the EGF signaling pathway. This inhibition of gene expression control by EGF might play a role in the photodegenerative processes observed after exposition of skin cells to solar radiation.

Inhibition of insulin signaling by oxidized low density lipoprotein. Protective effect of the antioxidant Vitamin E.

Oxidative stress is involved in several pathological conditions, including diabetes. Reactive oxygen species (ROS) have been demonstrated to act as second messengers for several hormones and cytokines, including insulin (INS). The effect of Cu(2+)-oxidized LDL (CuLDL) on INS-induced generation of ROS and on INS signaling was investigated on cultured human fibroblasts. Intracellular ROS generation was observed either in CuLDL- or in INS-treated cells. Moreover, CuLDL and INS had an additive effect on ROS formation in human fibroblasts. CuLDL by itself increased the phosphorylation of ERK without affecting the PKB/Akt phosphorylation. CuLDL also stimulated the DNA binding activities of the transcription factors AP1 and NFkappaB. However, CuLDL dose-dependently prevented the INS-signaling pathway, by inhibiting the INS-induced phosphorylation of the signaling kinases ERK and PKB/Akt and the INS-induced activation of the transcription factors AP1 and NFkappaB. Finally, the lipophilic antioxidant Vitamin E (Vit E) partially restored all the studied signaling events initiated by INS and impaired after pretreatment with CuLDL. These studies demonstrate that the oxidative stress generated by CuLDL has a negative effect on the INS-signaling pathway, independently of the INS-induced generation of ROS. Thus, oxidized LDL might be involved not only in atherosclerosis, as it is commonly admitted, but also in the INS-resistance observed in type 2 diabetes mellitus.

Polyhydroxylated 2-styrylchromones as potent antioxidants.

Four polyhydroxylated 2-styrylchromones, structurally related to flavones and cinnamic acid, have been studied. An SC derivative with OH groups only at positions 3' and 4' on the styryl moiety and another SC bearing an additional OH group at position 5 on the benzopyrone ring were more potent inhibitors of the Cu2+-induced peroxidation of LDL than the flavonoid quercetin. Fluorescence and absorption spectroscopies suggested that one LDL particle may bind 40 SC molecules. A pulse radiolysis study in pH 7 buffered micellar solutions of neutral TX100 and positively charged CTAB demonstrated that one-electron oxidation by *Br2-, *O2- and tryptophan radicals (8Trp) depends strongly on the micellar microenvironment. All SCs were readily oxidized by *O2- in CTAB micelles (rate constants: 6-18 x 10(6) M(-1) s(-1)). In TX100 micelles only the SC derivative with OH groups in position 3' and 4' reacted with *O2- (rate constant: 1.1 x 10(6) M(-1)s(-1)). In CTAB, electron transfer to *Trp radicals was observed for all SCs with rate constants > or =3.2 x 10(7) M(-1) s(-1). In TX100 micelles, this reaction occurred solely with the derivative bearing OH groups only at positions 3' and 4'.

Oxygen-copper (II) interplay in the repair of semi-oxidized urate by quercetin bound to human serum albumin.

The 1:1 complex of copper (II) and human serum albumin (HSA) slowly reacts with radiolytically generated *O2- radical-anion at a rate constant of 6.1 x 10(6) M(-1) s(-1). Absorbance and fluorescence spectroscopies demonstrate that addition of an equimolar portion of quercetin (QH2) to the solution of the copper (II)-HSA complex induces a relocalization of the copper resulting in a ternary copper (II)-QH2-HSA complex. This form of quercetin slowly oxidizes in air-saturated solutions. A 10-fold excess urate, a plasma antioxidant, cannot displace copper (II) bound to HSA. In N2O-saturated solutions the ternary complex form of QH2 can repair the urate radical with a rate constant of 2.7 x 10(6) M(-1) s(-1) by an electron transfer reaction similar to that observed in the absence of copper (II). In O2-saturated solutions and in the absence of copper, HSA-bound QH2 fails to repair the urate radical because of the fast competitive reaction of *O2- with urate radicals. However, addition of equimolar copper (II) restores the electron transfer from QH2 to the urate radical. These contrasting results are tentatively explained either by an enhanced reactivity of copper (II) with *O2- in the ternary complex or by direct production of quercetin radicals via a copper-catalyzed reduction of the *O2- radicals by QH2.