Tyrosinase Protein Is Expressed Also in Some Neural Crest Derived Cells Which Are Not Melanocytes

Some neural crest cells give rise to pigment cells in early ontogenesis. We tested here whether tyrosinase-a key enzyme in melanogenesis—was present in some nonpigment neural crest derivatives in adult hamsters. Interestingly enough, inactive tyrosinase protein was detected, using indirect immunofluorescence, in the satellite cells of spinal ganglia and Schwann cells of sciatic and facial nerves in normal adult animals. The results of cell blotting from spinal ganglia were similar to the fluorescence findings. Thus, our results seem to support the hypothesis that Schwann cells, satellite cells of spinal ganglia, and melanocytes may be more intimately related developmentally than other neural-crest-derived cells. Moreover, since we detected tyrosinase protein in cells which normally do not produce melanosomes, it could be deduced that, during the melanocyte's differentiation from its cell precursor, the expression of tyrosinase protein might precede the point when melanosomes begin to differentiate from known cytoplasmic structures.     

Increased transgene expression by the mouse tyrosinase enhancer is restricted to neural crest-derived pigment cells

In this study, we have addressed the impact of the mouse tyrosinase enhancer on regulated expression from the mouse tyrosinase promoter during embryonic development. Stable and transient transgenic experiments using the reporter gene lacZ reveal that (1) expression is detected in neural crest-derived melanoblasts from E11.5 onward, (2) the enhancer does not increase transgenic expression in optic cup-derived pigment cells of the retinal pigment epithelium (RPE), and (3) expression in the telencephalon is not any longer detected. The importance of the enhancer for expression in pigment cells of the eye was further investigated in adult mice using an attenuated diphtheria toxin A gene. This demonstrated that in presence of the enhancer the transgene expression is specifically targeted to neural crest-derived melanocytes of the choroid and not, or slightly, to the RPE. This suggests that tyrosinase is differentially regulated in the two pigment cell lineages, and that this promoter can be used to target expression preferentially to the neural crest-derived melanocyte lineage.     

Isolation and developmental expression of tyrosinase family genes in Xenopus laevis

The tyrosinase family of genes in vertebrates consists of three related members encoding melanogenic enzymes, tyrosinase (Tyr), tyrosinase-related protein-1 (TRP-1, Tyrp1) and tyrosinase-related protein-2 (Dct, TRP-2, Tyrp2). These proteins catalyze melanin production in pigment cells and play important roles in determining vertebrate coloration. This is the first report examining melanogenic gene expression in pigment cells during embryonic development of amphibians. Xenopus provides a useful experimental system for analyzing molecular mechanisms of pigment cells. However, in this animal little information is available not only about the developmental expression but also about the isolation of pigmentation genes. In this study, we isolated homologues of Tyr, Tyrp1 and Dct in Xenopus laevis (XlTyr, XlTyrp1, and XlDct). We studied their expression during development using in situ hybridization and found that all of them are expressed in neural crest-derived melanophores, most of which migrate through the medial pathway, and in the developing diencephalon-derived retinal pigment epithelium (RPE). Further, XlDct was expressed earlier than XlTyr and XlTyrp1, which suggests that XlDct is the most suitable marker gene for melanin-producing cells among them. XlDct expression was detected in migratory melanoblasts and in the unpigmented RPE. In addition, the expression of XlDct was detected in the pineal organ. The sum of these studies suggests that expression of the tyrosinase family of genes is conserved in pigment cells of amphibians and that using XlDct as a marker gene for pigment cells will allow further study of the developmental mechanisms of pigment cell differentiation using Xenopus.     

Ascidian neural crest-like cells: phylogenetic distribution, relationship to larval complexity, and pigment cell fate

Migratory neural crest-like cells, which express the cell surface antigen HNK-1 and develop into pigment cells, have recently been identified in the ascidian Ecteinascidia turbinata. Here we use HNK-1 expression as a marker to determine whether neural crest-like cells are responsible for pigment development in diverse ascidian species. We surveyed HNK-1 expression and tyrosinase activity in 12 ascidian species, including those with different adult organizations, developmental modes, and larval sizes and complexities. We observed HNK-1 positive cells in every species, although the timing of HNK-1 expression varied according to the extent of larval complexity. HNK-1 expression was initiated during the late tailbud stage in species in which adult features are formed precociously in large complex larvae. In contrast, HNK-1 positive cells did not appear until the swimming tadpole or juvenile stage in species with small simple larvae in which most adult features appear after metamorphosis. Double labeling experiments indicated that HNK-1 and tyrosinase are expressed in the same subset of pigment-forming mesenchymal cells in species with complex or simple larvae. In addition, the absence of HNK-1 and tyrosinase expression in albino morphs of the colonial ascidian Botryllus schlosseri suggested that the major fate of neural crest-like cells is to become pigment cells. The results suggest that ascidian neural crest-like cells and vertebrate neural crest cells had a common origin during chordate evolution and that their primitive function was to generate body pigmentation.     

Pax-6 expression during retinal regeneration in the adult newt

The present study examined the expression of Pax-6 during retinal regeneration in adult newts using in situ hybridization. In a normal retina, Pax-6 is expressed in the ciliary marginal zone, the inner part of the inner nuclear layer, and the ganglion cell layer. After surgical removal of the neural retina, retinal pigment epithelial cells proliferate into retinal precursor cells and regenerate a fully functional retina. At the beginning of retinal regeneration, Pax-6 was expressed in all retinal precursor cells. As regeneration proceeded, differentiating cells appeared at the scleral and vitreal margins of the regenerating retina, which had no distinct plexiform layers. In this stage, the expression of Pax-6 was localized in a strip of cells along the vitreal margin of the regenerating retina. In the late stage of regeneration, when the layer structure was completed, the expression pattern of Pax-6 became similar to that of a normal retina. It was found that Pax-6 is expressed in the retinal precursor cells in the early regenerating retina and that the expression pattern of Pax-6 changed as cell differentiation proceeded during retinal regeneration.     

Tyrosinase in the presumptive pigment cells of ascidian embryos: Tyrosine accessibility may initiate melanin synthesis

Tyrosinase activity appears in the presumptive pigment cells of ascidian embryos (Ciona intestinalis) several hours before the cells begin to synthesize melanin. These presumptive pigment cells develop into the otolith and ocellus pigment cells of the larval brain. Tyrosinase was identified by histochemical tests for tyrosine oxidase and dopa oxidase; both reactions were sensitive to tyrosinase inhibitors. Studies with puromycin suggested that tyrosinase was synthesized at the time it was first detected histochemically and that it was stable during the time interval before melanin synthesis. Supernumerary tyrosinase-containing cells were found adjacent to the presumptive pigment cells in three ascidian species examined (C. intestinalis, Styela partita, and Molgula manhattensis). Tyrosinase disappeared from the supernumerary pigment cells during larval development and these cells did not synthesize melanin.Tyrosinase in the presumptive and supernumerary pigment cells is apparently a functional enzyme which does not interact with substrate. External substrates ( -tyrosine and -dopa) did not react with enzyme in the living cells before the normal time of pigment synthesis, but gentle disruption of the cells (by freezing-and-thawing or osmotic shock) released active tyrosinase. Progessive enlargement of nonpigmented vesicles in the otolith cells of embryos exposed to phenylthiourea, an inhibitor of tyrosinase activity, suggested that tyrosinase vesicles actively accumulate tyrosine at the beginning of melanin synthesis. This tyrosine accumulation probably initiates melanin synthesis.