EPR spectroelectrochemical investigation of guanine radical formation and environment effects.

Guanine radical detection was carried out by a new convenient and efficient method coupling electron paramagnetic resonance spectroscopy and indirect electrooxidation of guanine in different biological environments, from the free nucleotide to several types of DNA substrates. Compared to the widely used photoirradiation method, this method appeared more selective in the choice of the electrochemical mediator. Carried out in presence of a ruthenium mediator and PBN as spin trap, this method revealed two types of EPR spectra depending of the environment of the guanine radical. Both EPR spectra show the trapping of the neutral guanine radical G(-H)(•) obtained after fast deprotonation of the radical cation G(•+). However, they differ by the atom where the trapped radical is centered. This difference highlights the structural dependency of the environment on the nature of the radical formed. This work gave the evidence of an innovative method to detect in situ the guanine radical.

Correlations between electrochemical behaviors and DNA photooxidative properties of non-steroïdal anti-inflammatory drugs and their photoproducts.

Alkali-labile lesion to DNA photosensitized, via an electron transfer mechanism, by three non-steroidal anti-inflammatory drugs (NSAIDs), ketoprofen, tiaprofenic acid and naproxen and their photoproducts during drug photolysis, was investigated using (32)P-end labelled synthetic oligonucleotide. These photooxidative damages were correlated with the photophysical and electrochemical properties of drugs, appearing as the photosensitizer PS. Photophysical studies provided the excited state energies of the photosensitizer while their redox potentials and the relative stabilities of the PS(-) radical-anions were determined by cyclic voltammetry. On the basis of these data, we have calculated the Gibbs energy of photoinduced electron-transfer and evaluated the exergonicity of the oxidative photodamage. Moreover, kinetic control may be invoked according to the stabilities of PS(-). Applied to this NSAIDs family, the photoxidative damages through electron transfer mechanism were analyzed and a good correlation with photoredox and photobiological properties was established.

DNA photo-oxidative damage hazard in transfection complexes.

Complexes of DNA with various cationic vectors have been largely used for nonviral transfection, and yet the photochemical stability of DNA in such complexes has never been considered. We studied, for the first time, the influence of DNA complexation by a cationic lipid and polymers on the amount of damage induced by benzophenone photosensitization. The localization of benzophenone inside the hydrophobic domains formed by a cationic lipid, DOTAP (N-[1-(2,3-dioleoyloxy)propyl]-N,N,N-trimethylammonium chloride), and close to DNA, locally increases the photoinduced cleavage by the reactive oxygen species generated. The same effect was found in the case of DNA complexation with an amphiphilic polymer (polynorbornenemethyleneammonium chloride). However, a decrease in DNA damage was observed in the case of complexation with a hydrophilic polymer (polyethylenimine). The DNA protection in this case was because of the absence of benzophenone hydrophobic incorporation into the complex, and to DNA compaction which decreased the probability of radical attack. These results underline the importance of the chemical structure of the nonviral transfection vector in limiting the risks of photo-oxidative damage of the complexed DNA.

Modulation of photo-oxidative DNA damage by cationic surfactant complexation.

The natural packaging of DNA in the cell by histones provides a particular environment affecting its sensitivity to oxidative damage. In this work, we used the complexation of DNA by cationic surfactants to modulate the conformation, the dynamics, and the environment of the double helix. Photo-oxidative damage initiated by benzophenone as the photosensitizer on a plasmid DNA complexed by dodecyltrimethylammonium chloride (DTAC), tetradecyltrimethylammonium chloride (TTAC), cetyltrimethyammonium chloride (CTAC) and bromide (CTAB) was detected by agarose gel electrophoresis. By fluorescent titration in the presence of ethidium bromide (EB) and agarose gel electrophoresis, we experimentally confirmed the complexation diagrams with a critical aggregation concentration on DNA matrix (CAC DNA) delimiting two regions of complexation, according to the DNA-phosphate concentration. The study of the photo-oxidative damage shows, for the first time, a direct correlation between the DNA complexation by these surfactants and the efficiency of DNA cleavage, with a maximum corresponding to the CAC DNA for DTAC and CTAC, and to DNA neutralization for CTAC and CTAB. The localization of a photosensitizer having low water solubility, such as benzophenone, inside the hydrophobic domains formed by the surfactant aggregated on DNA, locally increases the photoinduced cleavage by the free radical oxygen species generated. The inefficiency of a water-soluble quencher of hydroxyl radicals, such as mannitol, confirmed this phenomenon. The detection of photo-oxidative damage constitutes a new tool for investigating DNA complexation by cationic surfactants. Moreover, highlighting the drastically increased sensitivity of a complexed DNA to photo-oxidative damage is of crucial importance for the biological use of surfactants as nonviral gene delivery systems.

Photodistribution of blue-gray hyperpigmentation after amiodarone treatment: molecular characterization of amiodarone in the skin.

BACKGROUND: For decades, the photodistributed blue-gray skin hyperpigmentation observed after amiodarone therapy was presumably attributed to dermal lipofuscinosis. Using electron microscopy and high-performance liquid chromatography, we identified amiodarone deposits in the hyperpigmented skin sample from a patient treated with this antiarrhythmic agent. Our findings therefore indicate that the hypothesis relating the blue-gray hyperpigmentation to lipofuscin should be challenged. OBSERVATIONS: A 64-year-old man, skin phototype III, presented with asymptomatic skin hyperpigmentation that had been slowly developing on sun-exposed areas since April 2004. He had been taking amiodarone for 4 years (cumulative dose, 277 g). Electron microscopy did not show lipofuscin pigments in his skin. Conversely, abundant electron-dense membrane-bound granule deposits were observed in most of the dermal cells (fibroblasts, macrophages, pericytes, Schwann cells, and endothelial cells), especially in photoexposed skin. High-performance liquid chromatography confirmed that the skin deposits were composed of amiodarone. These results demonstrate that amiodarone hyperpigmentation is related to drug deposition on photoexposed skin. CONCLUSION: Amiodarone-related hyperpigmentation should be considered a skin storage disease that is secondary to drug deposition.

Comparative study of the photophysical properties of indoprofen photoproducts in relation with their DNA photosensitizing properties.

The photophysical properties of indoprofen photoproducts have been examined in various solvents by absorbance and emission spectroscopies in relation with their photosensitizing properties. The photophysical properties of 2-[4-(1-hydroxy)ethylphenyl]isoindolin-1-one (HOINP) and 2-(4-ethylphenyl)isoindolin-1-one (ETINP) are typical of a singlet excited state when the ones of 2-(4-acetylphenyl)isoindolin-1-one (KINP) are based on its triplet excited state according to previous work. The effect of solvent polarity on the absorption and fluorescence properties of HOINP and ETINP has been investigated as a function of Delta f, the Lippert solvent polarity parameter. A solvatochromic effect, function of the polarity region, has been observed for both photoproducts due to a change in the dipole moment of the compound upon excitation. In low-polarity regions, the excited state dipole moment of HOINP undergoes only a moderate increase (11.5 D) as compared to the dipole moment of the ground state (4.5 D) suggesting that the fluorescence arises from the locally excited state while in high-polarity regions it is strongly increased (42.9 D), which can imply that the emission takes place from a charge transfer state. In the case of ETINP, it would seem that the emitting state is rather a charge transfer state whatever the region is (16.9 and 31.8 D for the calculated excited-state dipole moments in the low and high-polarity regions, respectively). HOINP and ETINP do not produce thymine dimers by photosensitization but induce photooxidative damage via an electron transfer mechanism.

DNA photosensitization by indoprofen - is DNA damage photoinduced by indoprofen or by its photoproducts?

The in vitro photosensitizing activity of indoprofen, a non-steroidal anti-inflammatory drug, toward DNA has been studied by gel sequencing experiments using (32)P-end labelled synthetic oligonucleotides in phosphate buffered solution. Upon irradiation at [small lambda] > 320 nm, piperidine-sensitive lesions were induced in single- and double-stranded DNA, exclusively at the position of guanine bases. In single-stranded DNA, all G sites were modified. This pattern of photooxidative damage without isotopic effect in deuterium oxide, is characteristic of a Type I mechanism involving electron transfer from the base to the excited drug. In duplex DNA, a Type I process was also observed since selective DNA breakage occurred with high selectivity at 5[prime or minute]-G of a 5[prime or minute]-GG-3[prime or minute]sequence. When the oligonucleotide displays TT sites, an energy transfer process becomes predominant, giving rise to the formation of thymine dimers as evidenced by using T4 endonuclease V. Moreover, the methyl ester of indoprofen has been synthesized in order to study the influence of the indoprofen photochemical properties in DNA photosensitization. The poor efficiency of this compound shows that the drug itself is not directly implicated in DNA photodamage and seems to imply the involvement of indoprofen photoproducts.