A wavelength effect on urocanic acid E/Z photoisomerization

Endogenous Photosensitizers in Human Skin

Endogenous photosensitizers play a critical role in both beneficial and harmful light-induced transformations in biological systems. Understanding their mode of action is essential for advancing fields such as photomedicine, photoredox catalysis, environmental science, and the development of sun care products. This review offers a comprehensive analysis of endogenous photosensitizers in human skin, investigating the connections between their electronic excitation and the subsequent activation or damage of organic biomolecules. We gather the physicochemical and photochemical properties of key endogenous photosensitizers and examine the relationships between their chemical reactivity, location within the skin, and the primary biochemical events following solar radiation exposure, along with their influence on skin physiology and pathology. An important take-home message of this review is that photosensitization allows visible light and UV-A radiation to have large effects on skin. The analysis presented here unveils potential causes for the continuous increase in global skin cancer cases and emphasizes the limitations of current sun protection approaches.

Final Report on the Safety Assessment of Urocanic Acid

Urocanic Acid is a naturally occurring metabolite of histidine. The trans-Urocanic Acid isomer is found as a normal constituent of the epidermis, where it accumulates because there are only very low levels of the enzyme urocanase available to break it down; the accumulation causes trans-Urocanic Acid excretion in sweat. On exposure to UV radiation present in sunlight, the trans-Urocanic Acid isomer converts to the cis-Urocanic Acid isomer. In cosmetic formulations, Urocanic Acid is used as a skin-conditioning agent and as a sunscreen. Several questions were specifically considered in this safety assessment, including the extent to which applied Urocanic Acid is absorbed by the skin and, if absorbed, what the effect is on endogenous levels. Recognizing that photoisomerization is likely to occur in the skin, what is the resultant ability of cis-Urocanic Acid to act as an immunosuppressant? If the ingredient does cause immunosuppression, is there concomitant enhancement of photo-carcinogenesis? The available data indicate that Urocanic Acid is absorbed in mouse and human skin, although at a faster rate in mouse skin. Limited human data suggest that there is no increase in the total level (endogenous + applied) of Urocanic Acid in the skin over a 16-week period. Extensive animal data indicate that cis-Urocanic Acid is an immunosuppressant, but the clinical data are inconclusive as to the immunosuppressant effect of Urocanic Acid in humans (it may be problematic that Urocanic Acid was not exposed to UV radiation in the clinical tests). To directly assess the question of enhanced photocarcinogenesis, the results of two studies were considered. In one study of hairless mice, no neoplasms were found in the group exposed only to trans-Urocanic Acid, carcinomas were found in the group that received UV exposure and no trans-Urocanic Acid, and a significantly greater number of carcinomas was found in the group exposed to trans-Urocanic Acid followed by UV exposure. In a second study, using three similar groups of hairless mice (Urocanic Acid alone, UV alone, and UV plus varying concentrations of Urocanic Acid), all groups showed comparable numbers of carcinomas, papillomas, and other tumors. While there was concern about the influence of the methodologies on the interpretation of results in these two studies, the results from neither study could be discounted. Only further study, therefore, can resolve the questions of the immunosuppressive effect of Urocanic Acid in humans and whether the immunosuppressive effect in animals is linked to the incidence of cancer in those animals. The additional information needed includes human photoimmunosuppression data, data on the modulation of photocarcinogenicity using specified procedures, and a DNA adduct study in vivo and in vitro. Until these data are available, it cannot be concluded that Urocanic Acid is safe for use in cosmetic formulations.

Microwave discharge electrodeless lamps (MDEL). Part VII. Photo-isomerization of trans-urocanic acid in aqueous media driven by UV light from a novel Hg-free Dewar-like microwave discharge thermally-insulated electrodeless lamp (MDTIEL). Performance evaluation

A novel mercury-free Dewar-like (double-walled structure) microwave discharge thermally-insulated electrodeless lamp (MDTIEL) was fabricated and its performance evaluated using the photo-isomerization of trans-urocanic acid (trans-UA) in aqueous media as a test process driven by the emitted UV light when ignited with microwave radiation. The photo-isomerization processes trans-UA → cis-UA and cis-UA → trans-UA were re-visited using light emitted from a conventional high-pressure Hg light source and examined for the influence of UV light irradiance and solution temperature; the temperature dependence of the trans → cis process displayed a negative activation energy, E(a) = -1.3 cal mol(-1). To control the photo-isomerization of urocanic acid from the heat usually dissipated by a microwave discharge electrodeless lamp (single-walled MDEL), it was necessary to suppress the microwave-initiated heat. For comparison, the gas-fill in the MDEL lamp, which typically consists of a mixture of Hg and Ar, was changed to the more eco-friendly N(2) gas in the novel MDTIEL device. The dynamics of the photo-isomerization of urocanic acid driven by the UV wavelengths of the N(2)-MDTIEL light source were compared to those from the more conventional single-walled N(2)-MDEL and Hg/Ar-MDEL light sources, and with those from the Hg lamp used to irradiate, via a fiber optic, the photoreactor located in the wave-guide of the microwave apparatus. The heating efficiency of a solution with the double-walled N(2)-MDTIEL was compared to the efficiency from the single-walled N(2)-MDEL device. Advantages of N(2)-MDTIEL are described from a comparison of the dynamics of the trans-UA → cis-UA process on the basis of unit surface area of the lamp and unit power consumption. The considerably lower temperature on the external surface of the N(2)-MDTIEL light source should make it attractive in carrying out photochemical reactions that may be heat-sensitive such as the photothermochromic urocanic acid system.

Recent advances in urocanic acid photochemistry, photobiology and photoimmunology

Urocanic acid (UCA), produced in the upper layers of mammalian skin, is a major absorber of ultraviolet radiation (UVR). Originally thought to be a 'natural sunscreen', studies conducted a quarter of a century ago proposed that UCA may be a chromophore for the immunosuppression that follows exposure to UVR. With its intriguing photochemistry, its role in immunosuppression and skin cancer development, and skin barrier function, UCA continues to be the subject of intense research effort. This review summarises the photochemical, photobiological and photoimmunological findings regarding UCA, published since 1998.

Effect of Ring Methylation on the Photophysical, Photochemical and Photobiological Properties of cis-Dichlorobis(1,10-Phenanthroline)Rhodium(III)Chloride†

Methylated analogues of cis-dichlorobis(1,10-phenanthroline)rhodium(III)chloride (BISPHEN) have been prepared in order to increase the hydrophobicity of the parent compound, and thus create octahedral rhodium (III) complexes suitable for use as anticancer and antiviral agents that can be photoactivated. The parent complex has been shown in earlier work to be unable to cross through cell membranes. Octamethylation, as in the case of cis-dichlorobis(3,4,7,8-tetramethyl-1,10-phenanthroline)rhodium(III)chloride (OCTBP), provides enough hydrophobicity to be taken up by KB tumor cells. It also provides a higher level of ground-state association with double-stranded DNA and increases the quantum efficiency of photoaquation by greater than 10-fold, relative to BISPHEN. OCTBP forms covalent bonds to deoxyguanosine when irradiated with the nucleoside, as has been seen with the parent complex. Irradiation of OCTBP in the presence of the KB or M109 tumor cell lines using narrow-band UVB (lambda = 311 nm) irradiation initiates a considerable amount of phototoxicity. There is evidence that OCTBP acts as a prodrug (i.e. after passing through the cell membrane the metal complex is photolyzed to cis-chloro aquo OCTBP, which may be the active phototoxic agent). OCTBP and the tetramethyl analogue cis-dichlorobis(4,7-dimethyl-1,10-phenanthroline)rhodium(III)chloride (47TMBP) also show photoaquation upon excitation with visible light (lambda > 500 nm), and indeed, some phototoxicity of KB cells is observed at these wavelengths as well. This is attributed to direct population of photoactive triplet-excited states. These results, together with our earlier studies of cis-dichloro[dipyrido(3,2-a: 2',3'-c)phenazine (1,10-phenanthroline)rhodium(III)chloride (DPPZPHEN) demonstrate that such octahedral rhodium complexes are viable "photo-cisplatin" reagents.

An Action Spectrum for the Production of cis-Urocanic Acid in Human Skin In Vivo

Urocanic acid (UCA) is present at millimolar concentrations in mammalian epidermis and undergoes photoisomerization from the naturally occurring trans-isomer to the cis-isomer on exposure to ultraviolet radiation (UVR). Cis-UCA causes downregulation of various immune responses in mouse and human experimental models and has been proposed as both a chromophore and a mediator of UV-induced immune suppression. In this study, the wavelength dependence from 260-340 nm for trans to cis-UCA photoisomerization in human skin was analyzed in five healthy volunteers. The resulting action spectrum demonstrated maximal cis-UCA production in the UVB spectral region of 280-310 nm. This spectral peak is red-shifted to longer wavelengths compared with the erythemal action spectrum. The cis-UCA action spectrum can be used to predict the ability of sunscreens to protect against UVR-induced cis-UCA formation and may assist in explaining discrepancies between sunscreens' abilities to protect against erythema and photoimmunosuppression.

Structure and action of urocanase

Urocanase (EC 4.2.1.49) from Pseudomonas putida was crystallized after removing one of the seven free thiol groups. The crystal structure was solved by multiwavelength anomalous diffraction (MAD) using a seleno-methionine derivative and then refined at 1.14 A resolution. The enzyme is a symmetric homodimer of 2 x 557 amino acid residues with tightly bound NAD+ cofactors. Each subunit consists of a typical NAD-binding domain inserted into a larger core domain that forms the dimer interface. The core domain has a novel chain fold and accommodates the substrate urocanate in a surface depression. The NAD domain sits like a lid on the core domain depression and points with the nicotinamide group to the substrate. Substrate, nicotinamide and five water molecules are completely sequestered in a cavity. Most likely, one of these water molecules hydrates the substrate during catalysis. This cavity has to open for substrate passage, which probably means lifting the NAD domain. The observed atomic arrangement at the active center gives rise to a detailed proposal for the catalytic mechanism that is consistent with published chemical data. As expected, the variability of the residues involved is low, as derived from a family of 58 proteins annotated as urocanases in the data banks. However, one well-embedded member of this family showed a significant deviation at the active center indicating an incorrect annotation.

Formation of singlet oxygen by urocanic acid by UVA irradiation and some consequences thereof

Singlet oxygen-initiated decomposition of urocanic acid (UCA) (3-(1H-imidazol-4(5)-yl)-2-propenoic acid) was used to successfully confirm the report that UCA generates singlet oxygen when irradiated with ultraviolet A light (UVA). The UCA-generated singlet oxygen converts UCA to one or more products that then catalyze the further destruction of the UCA with UVA light by singlet oxygen formation. Some nicking of the phiX-174 supercoiled plasmid DNA was observed when UCA was irradiated with UVA to complete destruction of the starting material, and the product mixture was then mixed with the plasmid in the dark. More extensive nicking was seen when the photoproduct mixture and the plasmid were irradiated with UVA light. An "aged" (4 days) solution of UCA photoproduct no longer caused nicking in the dark but retained the capability to nick the plasmid when irradiated. There is evidence for the presence of hydroperoxides in the UCA photolysis product mixture, and the quenching studies with 2-propanol indicate that free radicals are involved in the plasmid-nicking photochemistry. Singlet oxygen does not appear to play a role in the nicking of the plasmid.

Photogeneration and quenching of reactive oxygen species by urocanic acid

Urocanic acid, UCA, is characterized by two electronic transitions in the UV-B (280-320 nm) which comprise its broad absorption spectrum and give rise to wavelength-dependent isomerization quantum yields. The absorption spectrum of UCA extends into the UV-A (320-400 nm). Given the UV-A component of sunlight is significantly greater than the UV-B component it is hypothesized even weak UV-A photochemistry of UCA could be important for in vivo responses to UV radiation. Degenerate pump-probe experiments performed on t-UCA at several wavelengths in the UV-A reveal an excited-state absorption that undergoes a rapid, approximately 1 ps decay. Photoacoustic experiments performed on both the cis and trans isomers reveal the formation of a long-lived intermediate following UV-A excitation. The efficiency and action spectra for this latter photoactive process are presented and are similar for both isomers of UCA. Cholesterol hydroperoxide assays designed to investigate the nature of the UV-A photoreactivity of t-UCA confirm the production of reactive oxygen species. The bimolecular rate constant for the quenching of singlet oxygen by t-UCA is determined to be 3.5 x 10(6) M(-1) s(-1). Taking into consideration recent theoretical calculations and jet expansion studies of the electronic structure of gas-phase t-UCA, a model is proposed to explain the isomerization and photoreactivity of t-UCA in solution over the UV-A region.

A TD-DFT study of the photochemistry of urocanic acid in biologically relevant ionic, rotameric, and protomeric forms

The photochemistry of Urocanic acid, a chromophore present in human skin and linked to photoimmunosuppression and skin cancer, is investigated theoretically by means of time-dependent density functional theory. Extensive calculations are carried out for different ionic, rotameric, and protomeric forms of both the trans and cis form. Inclusion of solvation effects, here accounted for by means of a continuum solvent model, are found to be crucial for the correct description of the biologically relevant zwitterionic forms of the molecule. For the trans zwitterionic form, it is found that the planar form usually assumed in the literature is not stable, and that a realistic charge separation cannot be achieved in the gas phase. Calculated vertical excitation energies are in excellent agreement with available experimental data, with a weakly absorbing n --> pi transition around 4.0 eV, and strongly absorbing pi --> pi transitions at 4.5-4.9 eV. The debated intramolecular hydrogen bond is predicted to have a modest impact on the vertical spectra in solution, but improves agreement with experiment when included. In general, we also predict that different rotameric forms have very similar absorption spectra. In addition, we find a candidate absorbing state to link trans-urocanic acid to singlet oxygen production and subsequent photoaging of the skin.

Computational analysis of the autocatalytic posttranslational cyclization observed in histidine ammonia-lyase. A comparison with green fluorescent protein

Density functional calculations using hybrid functionals (B3LYP) have been performed to study the mechanism of the autocatalytic posttranslational cyclization observed in histidine ammonia-lyase. Two mechanisms were analyzed, the commonly accepted mechanism in which cyclization precedes dehydrogenation (reduced mechanism) and a mechanism in which dehydrogenation precedes cyclization (oxidized mechanism). The reduced pathway is not supported by the calculations, while the alternative oxidized mechanism where a dehydration occurs prior to the formation of the ring yields reasonable energetics for the system. Database searches showed that the oxidative mechanism in which the formation of the dehydro amino acids in residue i + 1 precedes the cyclization is also structurally advantageous as it results in shorter distances between the carbonyl carbon of residue i and the amide nitrogen of residue i + 2 and, therefore, preorganizes the protein for cyclization. Conformational searches showed that these distances were also unusually short and exhibited very little variation in the Delta-Ala143 HAL tetramer, indicating that like GFP the tetrameric form of HAL is rigidly preorganized for cyclization. The monomeric form of HAL is less preorganized than the tetrameric form of HAL. Dehydro amino acids aid in the preorganization, but the main driving force in the rigid tight turn formation is the influence of the surrounding protein.

Spectroscopic and dynamic studies of the epidermal chromophores trans-urocanic acid and eumelanin

Photoaging and skin cancer can result from the exposure of skin to ultraviolet A (UV-A, 320-400 nm) radiation. The detailed chemical mechanisms by which these processes occur are not known, but they must begin with the absorption of a UV-A photon by one or more photoreceptor(s) within the skin. The situation is complicated by the lack of understanding of the photoreactions of many of the UV-A-absorbing molecules in skin. In this Account, we describe recent research efforts directed at elucidating the UV-A-induced photoreactivity of two light-absorbing epidermal photoreceptors: trans-urocanic acid and eumelanin.

Epidermal trans-urocanic acid and the UV-A-induced photoaging of the skin

The premature photoaging of the skin is mediated by the sensitization of reactive oxygen species after absorption of ultraviolet radiation by endogenous chromophores. Yet identification of UV-A-absorbing chromophores in the skin that quantitatively account for the action spectra of the physiological responses of photoaging has remained elusive. This paper reports that the in vitro action spectrum for singlet oxygen generation after excitation of trans-urocanic acid mimics the in vivo UV-A action spectrum for the photosagging of mouse skin. The data presented provide evidence suggesting that the UV-A excitation of trans-urocanic acid initiates chemical processes that result in the photoaging of skin.

Estimation of the effect of increasing UVB exposure on the human immune system and related resistance to infectious diseases and tumours

Exposure to UV light has, besides some beneficial effects (vitamin D production), many harmful effects on human health. UVB irradiation has been shown to suppress both systemic and local immune responses to a variety of antigens, including some microorganisms. However, it is still not known whether such immunomodulating effects may lead to an increase in the number and severity of certain tumours and/or infections in humans. We report herein the data provided by a project that was funded by the European Union (Programme Environment), and that was aimed at the estimation of the risk associated with increased UVB exposure due to ozone depletion regarding the deleterious effects on the immune system and related resistance to tumours and infections in humans. The data, obtained by the different research groups involved, were assembled and used to calculate for the first time a risk assessment for increased environmental exposure to UVB in human subjects.

Investigating the red shift between in vitro and in vivo urocanic acid photoisomerization action spectra

Trans-urocanic acid (UCA) is found in the upper layer of the skin and UV irradiation induces its photoisomerization to cis-UCA. Cis-UCA mimics some of the immunosuppressive properties of UV exposure. The wavelength dependence for in vitro photoisomerization of trans-UCA (15 microM) over the spectral range 250 nm-340 nm (10 nm intervals) was determined. The action spectrum revealed that maximal cis-UCA production occurred at 280 nm, which is red-shifted by 10-12 nm from its absorption peak at 268 nm and differs markedly from the reported action spectra for cis-UCA production in mouse skin in vivo, which peaks at 300-310 nm. The reasons for the red shift between the in vitro and in vivo action spectra are not clear. There is limited evidence suggesting that the UV absorption maximum of trans-UCA red shifts from 268 nm in vitro to 310 nm on interaction with stratum corneum proteins in vivo. This phenomenon was investigated by applying trans-UCA (2.5 mg/cm2) in an oil emulsion to isolated human stratum corneum. After incubation at 37 degrees C for 1 h, the absorption spectra of stratum corneum with UCA and with oil only were compared using a Xe arc source and a spectroradiometer. A moderate red shift in trans-UCA absorption from approximately 268 nm to 280 nm was observed. In summary, we suggest that the 10-12 nm red shift between the UCA absorption spectrum peak and the action spectrum peak in vitro may be accounted for by the wavelength dependence of quantum yields reported over the 254-313 nm range. The red shift between the in vitro and in vivo photoisomerization action spectra may result from the 10 to 12 nm red shift in the absorption of UCA in association with stratum corneum proteins, combined with increasing quantum yields over the 254-313 nm range.

Photoisomerization spectrum of urocanic acid in human skin and in vitro: effects of simulated solar and artificial ultraviolet radiation

Ultraviolet (UV) irradiation of trans-urocanic acid (UCA), a major UV absorbing component of the epidermis, leads to the formation of cis-UCA, which mediates immunosuppressive effects. In this study, the net yield of cis-UCA was measured after the photoisomerization of urocanic acid by narrow UV wavebands (spectral range 295-405 nm), with the irradiation doses related to solar irradiance at sea level. The formation of cis-UCA in Caucasian skin (in vivo), as well as in aqueous solution (in vitro), was determined by HPLC analysis. The same irradiation conditions were met in both components of the study. The in vivo experiments showed high efficiency of cis-UCA formation in the spectral region of 305-341 nm, whereas high efficiency in vitro was found at 305 and 326 nm. At 350 and 363 nm, cis-UCA was formed in vivo, but not in vitro. At longer test wavelengths up to 405 nm, no significant formation of cis-UCA was detectable. The established partition between UVB and UVA at 320 nm is not relevant for the isomerization pattern of UCA. Additional studies revealed substantial cis-UCA formation in human skin by UVA phototherapy lamps. Furthermore, raised levels of 295 nm irradiation doses, a possible effect of stratospheric ozone depletion, were found to increase the cis-UCA yield. Our results demonstrate that the formation of cis-UCA in the skin with common exposures takes place over a broad spectrum range of UVB and UVA, up to at least 363 nm. These findings emphasize the potency of UVA to isomerize UCA, and they may contribute to further elucidation of the effects of phototherapy and sunbathing.

Comparative potency of different UV sources in reducing the density and antigen-presenting capacity of Langerhans cells in C3H mice

Although broadband UV-B irradiation has been shown to induce selective immunosuppression in a variety of experimental systems, the wavelength dependence of the immunomodulation and the initial events in the skin remain unclear. In the present study three UV lamps were used at suberythermal doses on C3H mice: a conventional broadband UV-B source (270-350 nm), a narrowband UV-B source (311-312 nm) and a UV-A source (320-400 nm). Their effects on the photoisomerization of the naturally occurring trans-isomer of urocanic acid (UCA) to cis-UCA, on the density of Langerhans cells and on the ability of epidermal cells to stimulate allogeneic lymphocytes in the mixed skin lymphocyte reaction (MSLR) were ascertained. Broadband UV-B irradiation was more efficient than narrowband UV-B at reducing the density and function of Langerhans cells, while UV-A irradiation was least effective. These changes were most pronounced immediately following irradiation, were dose dependent and were only detected in UV-exposed areas of skin. There was a close correlation between the UV-induced reduction in Langerhans cell density and the formation of cis-UCA in the epidermis. This correlation was not detected between the reduction in the MSLR response following UV irradiation in vivo and cis-UCA formation.

Lack of correlation between suppression of contact hypersensitivity by UV radiation and photoisomerization of epidermal urocanic acid in the hairless mouse

The immunological consequences of exposure to UVA (320-400 nm) radiation are unclear. This study describes the relationship between the generation of epidermal cis-urocanic acid and the ability to respond to a contact-sensitizing agent, in hairless mice exposed to different UV radiation sources, which incorporate successively greater short-wavelength cutoff by filtration of the radiation from fluorescent UV tubes. Mice were exposed to these radiation sources at doses systematically varying in UVB radiation content but supplying increasing proportions of UVA radiation. All radiation sources were found to generate approximately 35% cis-urocanic acid in the epidermis, thus normalizing the sources for cis-urocanic acid production. However, only those sources richest in short-wavelength UVB resulted in suppression of the systemic contact hypersensitivity response. These sources also induced the greatest erythema reaction, measured as its edema component, in the exposed skin. A strong correlation was thus demonstrated between the induction of edema and the suppression of contact hypersensitivity, but there appeared to be no correlation between the generation of epidermal cis-urocanic acid and suppression of contact hypersensitivity. The sources richest in UVA content did not result in suppression of contact hypersensitivity; furthermore mice previously irradiated with such UVA-rich sources were refractory to the immunosuppressive action of exogenous cis-urocanic acid. A protective effect of the increased UVA content thus appeared to be inhibiting immunosuppression by the available endogenously generated or exogenously applied cis-urocanic acid.

Adventitious interconversion of cis- and trans-urocanic acid by laboratory light

Urocanic acid (UCA) is a chromophore in the stratum corneum. Ultraviolet radiation (ultraviolet B) has been shown to suppress mammalian cell-mediated immunity. The photoisomerization of trans-UCA to cis-UCA was proposed as the initiator of the suppression process. Cis-urocanic acid has been demonstrated to suppress immunity by a variety of experiments. Investigators should be aware that laboratory illumination may be capable of interconverting trans-UCA and cis-UCA during experimental manipulations. This possible inadvertent contamination of one isomer by the other may influence results. We demonstrated that fluorescent lamps, daylight, sunlight and incandescent lamps were able to bring about isomerization. Window glass and container materials of plastic and clear glass did not filter out effective wavelengths, but three commercial plastic diffusers on fluorescent fixtures prevented the isomerization. Because the molar extinction coefficient (epsilon) for cis-UCA is less than that of trans-UCA, we have exposed 0.1 mM trans-UCA to ambient light and monitored the change in absorbance. A method is given to calculate the percentage of trans and cis isomers from the absorbance at 277 nm when the initial purity and absorbance are known. Using this procedure, we validated the molar extinction coefficient of cis-UCA.

Photosensitized inactivation of infectious DNA by urocanic acid, indoleacrylic acid and rhodium complexes

Naked, infectious single-stranded (ss) and double-stranded (ds) DNA from phages S13 and G4 were irradiated with 308 nm UV radiation in the absence and presence of several photobiologically active compounds: E- and Z-urocanic acid (E- and Z-UA), their methyl esters (E- and Z-MU), E- and Z-indoleacrylic acid (E- and Z-IA), cis-dichloro-bis(1,10-phenanthroline)rhodium(III) chloride (cDCBPR) and tris(1,10-phenanthroline)rhodium (III) perchlorate (TPR). E-urocanic acid protects against cyclobutane pyrimidine dimer formation in ssDNA but concomitantly photosensitizes the formation of other lesions that inactivate ssDNA. Z-urocanic acid also protects ssDNA against such dimerization but without the associated sensitized damage. The methyl ester isomers behave similarly. There is no such differential activity observed for the IA isomers, both of which sensitize the inactivation of ssDNA. Photostationary state mixtures of both UA and IA efficiently sensitize the inactivation of dsDNA, and cDCBPR strongly protects ssDNA from UV damage, while TPR is a significant sensitizer. Both of these metal complexes sensitize the inactivation of dsDNA slightly. For all compounds, cyclobutane pyrimidine dimers were the predominant lethal lesions produced by sensitization of the dsDNA, but they were not the major lethal lesions created by sensitization of the ssDNA. In the case of dsDNA, both UA and IA created pyrimidine dimers with a high degree of potential for mutagenesis, as determined by an assay that monitors the frequency of mutations following the spontaneous deamination of cytosine in photodimers.

Action spectra for the trans to cis photoisomerisation of urocanic acid in vitro and in mouse skin

Urocanic acid (UCA) is a major UV chromophore in the upper layers of the skin where it is found predominantly as the trans isomer. UV irradiation induces photoisomerisation of trans-UCA to cis-UCA which has been shown to mimic some of the immunosuppressive properties of UV exposure. We examined the wavelength dependence for trans-UCA to cis-UCA photoisomerisation in vitro and in mouse skin in vivo over the spectral range 270-340 nm. The resulting action spectra were very similar with maximal effectiveness at 300-315 nm and equal activity at 270 nm and 325-330 nm, demonstrating that UVA-II radiation (320-340 nm) is efficient at UCA photoisomerisation. These action spectra differed markedly from the trans-UCA absorption spectrum in vitro and also the reported action spectrum for UV suppression of contact hypersensitivity in mice. These findings suggest that the relationship between cis-UCA formation in skin and UV-induced immunosuppression may be complex.