Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P10721 (c-kit)
 6,575 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

In this article we describe the rapid advances made in the molecular genetics of three inherited pigmentation disorders: albinism, piebaldism, and vitiligo, all of which throw light on normal pigment cell function. The focus is on studies in mice, with comparison of data in humans. The critical role of tyrosinase (c-locus or human tyrosinase protein) in normal pigmentation and albinism has been reinforced by the cloning and identification of mutations in tyrosinase and two other melanocyte-specific oxidoreductases structurally related to but functionally different from tyrosinase: the (b) brown-locus protein/gp75/catalase B and dopachrome tautomerase. Each possesses a distinct enzyme activity and yet the three share homology in strategic regions. Most of the point mutations that reduce or abrogate the respective enzyme activities are located in those regions. Tyrosinase-negative albinism is caused only by defects in tyrosinase. A locus for human tyrosinase-positive albinism has been recently mapped to chromosome 15q11.2-->q12, at a gene identified in mice as pink-eyed dilution. On the other hand, several genes encoding proteins critical for the proliferation of melanocytes are known to control the piebald phenotype. So far identified are two membrane-receptor tyrosine kinases, c-Kit and PDGF-R/alpha, and the ligand for c-kit, MGF (mast-cell growth factor, also known as stem-cell factor, c-Kit-ligand, or steel factor). Mutations in W/c-kit (white spotting), Ph/Pdgfr/a (patch), and Sl/MGF (steel), lead to a reduction in receptor kinase activity and failure of melanocytes to thrive and reach the skin during embryogenesis. Finally, mouse mutant models suggest at least two possible causes for vitiligo, a progressive loss of pigmentation that occurs after birth. In one mutant, the Blt (light) mouse, the cyclic death of hair melanocytes may be due to the toxicity of intermediates and byproducts of melanogenesis in the presence of a dysfunctional b-locus protein. In the other model, the "vitiligo mouse," in which the allele vit has been assigned to the microphthalmia (mi) locus, the loss of melanocytes may be caused by defective signal transduction, because in addition to vitiligo mivit/mivit mice have extensive piebaldism.
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PMID:White mutants in mice shedding light on humans. 843 6

An outstanding problem in the study of vertebrate development is the identification of the genes that direct neural crest precursor cells to adopt and maintain specific differentiated cell fates. In an effort to identify such genes, we have carried out a mutagenesis screen in zebrafish and isolated mutants that lack neural crest-derived melanophores. In this manuscript we describe the phenotype of one such mutant, touchtone(b722) (tct), and the map position of the gene it defines. Analysis of expression of dopachrome tautomerase (dct) and microphthalmia (mitfa) suggests that melanophore precursors are specified normally in homozygous tct mutants. However, differentiated melanophores are pale, small, and about half of them have disappeared by 48 h of development, apparently by cell death. We show that melanophores require Tct function cell autonomously. Signals from the receptor tyrosine kinase receptor C-kit are essential for survival of melanophores in zebrafish and mammals. However, differences in the phenotypes of tct and c-kit homozygous mutants, and an absence of interaction between c-kit and tct heterozygotes, suggest that Tct functions independently of the C-kit pathway. Other neural crest derivatives, including other pigment cell types, appear normal in tct mutants. Interestingly, tct mutant embryos undergo a temporary period of near complete paralyzis during the second day of development, although markers of axons of motor and sensory neurons look normal in this period. A fraction of tct(b722) mutants survive to adulthood, but mutant adults are small, indicating a role for Tct in post-larval growth. The tct gene maps to a small interval near a telomere of chromosome 18. Thus, we have identified a zebrafish gene that when mutated produces semi-viable offspring and that may serve as a model of human diseases that have both pigmentation and neurological symptoms.
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PMID:Touchtone promotes survival of embryonic melanophores in zebrafish. 1545 66

Hermansky-Pudlak Syndrome-type 3 (HPS-3) is a relatively mild subtype of HPS with minimal cutaneous and ocular depigmentation. The HPS-3 gene encodes a novel protein of unknown function with a predicted molecular weight of 114 kd. To assess the role of the HPS3 protein in melanization, cultured melanocytes developed from HPS-3 patients were evaluated biochemically and histologically for activity and localization of melanocyte-specific proteins. Endogenous tyrosinase activity of HPS-3 melanocytes was substantial, but tyrosinase activity and melanin synthesis was suppressed in intact melanocytes. However, the level of suppression, as well as extent to which up-regulation by isobutylmethylxanthine and cholera toxin was muted, was less that in HPS-1 melanocytes. Ultrastructurally, HPS-3 melanocytes contained morphologically normal melanosomes, predominantly of stage I and II with minimal stage III and few stage IV melanosomes. Dihydroxyphenylalanine (DOPA) histochemistry demonstrated an increase in melanization of melanosomes. Unique to HPS-3 melanocytes were numerous DOPA-positive 50-nm vesicles and tubular elements present throughout the cell body and dendrites. Tyrosinase, tyrosinase-related protein-1 (Tyrp1), dopachrome tautomerase (Dct), and LAMP1 and 3 localization in HPS-3 melanocytes, as evaluated by immunocytochemistry and confocal microscopy, demonstrated a fine, floccular distribution in contrast to the coarse, granular distribution characteristic of control melanocytes. The localization profile of other proteins expressed by melanocytes (ie, Silver/Pmel17, Melan-A/MART-1, LAMP2, Rab 27, transferrin, c-kit, adaptin-3, and the HPS1 protein) appeared normal. These results suggest that a specific subset of melanocyte proteins are aberrantly trafficked throughout the HPS-3 melanocyte and may be responsible for the reduction in melanin synthesis.
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PMID:Melanocyte-specific proteins are aberrantly trafficked in melanocytes of Hermansky-Pudlak syndrome-type 3. 1563 15