Melanogenesis in visceral tissues of Salmo salar. A link between immunity and pigment production?

Melanogenesis is mostly studied in melanocytes and melanoma cells, but much less is known about other pigment cell systems. Liver, spleen, kidney, and other organs of lower vertebrates harbour a visceral pigment cell system with an embryonic origin that differs from that of melanocytes. In teleosts, melanin-containing cells occur in the reticulo-endothelial system and are mainly in the kidney and spleen. The Atlantic salmon (Salmo salar L.) is an ichthyic breeding species of considerable economic importance. The accumulation of pigments in salmon visceral organs and musculature adversely affects the quality of fish products and is a problem for the aquaculture industry. With the aim to reveal novel functions and behaviour of the salmonid extracutaneous pigment system, we investigated aspects of the melanogenic systems in the tissues of Atlantic salmon, as well as in SHK-1 cells, which is a long-term cell line derived from macrophages of the Atlantic salmon head-kidney. We demonstrate that a melanogenic system is present in SHK-1 cells, head-kidney, and spleen tissues. As teleosts lack lymph nodes and Peyer's patches, the head-kidney and spleen are regarded as the most important secondary lymphoid organs. The detection of tyrosinase activity in lymphoid organs indicates that a link exists between the extracutaneous pigmentary system and the immune system in salmon.

Mechanism of dimerization of the human melanocortin 1 receptor.

The melanocortin 1 receptor (MC1R) is a dimeric G protein-coupled receptor expressed in melanocytes, where it regulates the amount and type of melanins produced and determines the tanning response to ultraviolet radiation. We have studied the mechanisms of MC1R dimerization. Normal dimerization of a deleted mutant lacking the seventh transmembrane fragment and the C-terminal cytosolic extension excluded coiled-coil interactions as the basis of dimerization. Conversely, the electrophoretic pattern of wild type receptor and several Cys-->Ala mutants showed that four disulfide bonds are established between the monomers. Disruption of any of these bonds abolished MC1R function, but only the one involving Cys35 was essential for traffic to the plasma membrane. A quadruple Cys35-267-273-275Ala mutant migrating as a monomer in SDS-PAGE in the absence of reducing agents was able to dimerize with WT, suggesting that in addition to disulfide bond formation, dimerization involves non-covalent interactions, likely of domain swap type.

Molecular cloning and biochemical characterization of the skin tyrosinase from Rana esculenta L.

Amphibian tyrosinases display unique and poorly understood properties such as seasonal activity variations, different activities in dorsal and ventral skin and the occurrence as inactive forms requiring proteolytic activation. For the first time we have sequenced and characterized Rana esculenta L. tyrosinase by functional expression of the cloned cDNA, and compared it with frog skin extracts. R. esculenta tyrosinase ORF is well conserved compared with tyrosinases of various sources. The amino acid similarities between the tyrosinases from R. esculenta and other amphibia range from 85% to 98%. Homology remains high with mammalian tyrosinases (65% identity with Homo sapiens, and 63% with Mus musculus) and with bird orthologues (66% identity with Gallus gallus). Tyrosinase was expressed in HEK293T cells as an active enzyme. Activity staining on non reducing SDS-PAGE revealed two bands around 63 and 68 kDa. R. esculenta skin extracts were mildly active and reached maximal activity upon protease treatment, revealing a high molecular weight dopa-positive band in the 200 kDa range and one of higher MW, after nagarse treatment, in activity stainings. The different behaviour of recombinant tyrosinase compared to skin extracts suggests formation in vivo of a multimeric complex.