Melanophores in the isolated tail from the amphibian larvae Xenopus laevis, Hyla japonicus, Rana pirica, and Hynobius retardatus aggregated melanin granules in response to light and dispersed them when placed in darkness. The spectral characteristics for the melanin-aggregation response were examined by irradiating the Xenopus tail-fin locally (diameter, 2.1 mm) with monochromatic light (380-1,020 nm). The spectral region of wave length which induced melanosome aggregation depended on the light intensity but was limited to the visible spectrum. At low light intensity (1.59 microW/cm2, delta lambda = 5 nm), the aggregation response occurred in the spectral region between 400 and 600 nm and the maximum response was observed at 500 nm. This range is very close to the absorption spectrum of rhodopsin in the visual rod cell. Hypodermic injection of cGMP into isolated tail-fin induced a marked melanin-dispersion in spite of light-stimuli. When the tail-fin was treated with isobutylmethylxanthine (IBMX; phosophodiesterase inhibitor) in darkness and then was re-exposed to light, the aggregation response was inhibited. The photo-sensitive melanin aggregation was independent of a requirement for Ca2+ ions but melanosome dispersion in darkness was Ca(2+)-dependent. K(+)-rich Hanks' solution, ouabain (inhibitor of Na(+)-K(+)-ATPase) or nonactin (cation ionophore), which induced a change of the membrane potential of melanophores, inhibited the aggregation response when the melanophores were re-exposed to light after a period in darkness. These results suggest that the molecular mechanism of photoreception in melanophores of amphibian tadpoles is similar to that in visual cells.
Recently, we demonstrated the expression of rhodopsin in the tail fin of the Xenopus tadpole, in which photosensitive melanophores exist (Miyashita et al, The photoreceptor molecules in Xenopus tadpole tail fin, in which melanophores exist. Zool Sci 18:671-674, 2001). The presence of opsin molecules in pigment cells of lower vertebrates raises the possibility that pigment cells in animal skin function as photosensors generally. To explore this possibility in higher vertebrates, we tried to detect photoreception molecules in mammalian melanocytes. We extracted total RNA from Melan a2, a cell line of immortal murine melanocyte, which is derived from C57BL mice. The DNA sequence obtained by reverse transcriptase-polymerase chain reaction (RT-PCR) amplification was homologous to the corresponding portion of the sequence of ocular rhodopsin of mice. Western blotting and fluorescent immunocytochemistry showed the existence of the opsin protein in the melanocytes. Another cell line, EL4, which is derived from lymphoma of C57BL/6N, scarcely expresses opsin mRNA, as judged by RT-PCR. Thus expression of the opsin gene is not ubiquitous among immortal cell lines. Detection of rhodopsin mRNA in murine tissues of C57BL/6N by RT-PCR showed its presence in the eye and skin but not in the liver. The role of the opsin molecule in melanocyte is not known at present, but this will provide additional insight into photoreception systems in animal skin.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.