Pheomelanin Effect on UVB Radiation-Induced Oxidation/Nitration of L-Tyrosine

Pheomelanin is a natural yellow-reddish sulfur-containing pigment derived from tyrosinase-catalyzed oxidation of tyrosine in presence of cysteine. Generally, the formation of melanin pigments is a protective response against the damaging effects of UV radiation in skin. However, pheomelanin, like other photosensitizing substances, can trigger, following exposure to UV radiation, photochemical reactions capable of modifying and damaging cellular components. The photoproperties of this natural pigment have been studied by analyzing pheomelanin effect on oxidation/nitration of tyrosine induced by UVB radiation at different pH values and in presence of iron ions. Photoproperties of pheomelanin can be modulated by various experimental conditions, ranging from the photoprotection to the triggering of potentially damaging photochemical reactions. The study of the photomodification of l-Tyrosine in the presence of the natural pigment pheomelanin has a special relevance, since this tyrosine oxidation/nitration pathway can potentially occur in vivo in tissues exposed to sunlight and play a role in the mechanisms of tissue damage induced by UV radiation.

Analysis of Proteins by Immunoblotting

In immunoblotting (western blotting), proteins are first separated by SDS-PAGE and then transferred electrophoretically from the gel onto a support membrane that binds proteins tightly. After the unreacted binding sites of the membrane are blocked to suppress nonspecific adsorption of antibodies, the immobilized proteins are reacted with a specific polyclonal or monoclonal antibody. Antigen–antibody complexes are visualized using chromogenic, fluorescent, or chemiluminescent reactions. Immunoblotting protocols are reagent specific and, owing to the wide assortment of equipment, reagents, and antibodies available, highly diverse. Presented here is an example of a workable protocol for developing a blot using horseradish peroxidase (HRP)–conjugated secondary antibody and enhanced chemiluminescence (ECL). ECL is based on the emission of light during the HRP-catalyzed oxidation of luminal or other substrates. Emitted light is captured on film or by a CCD camera, for qualitative or semiquantitative analysis. Because ECL is so sensitive, it has become a popular detection method. This protocol can be modified for different membranes, antibodies, and detection systems. Optimal dilutions of the primary and secondary antibodies need to be determined empirically, but recommendations provided by the manufacturer are usually a good starting point.