Mislocalization of melanosomal proteins in melanocytes from mice with oculocutaneous albinism type 2.

More than 10% of admissions worldwide to institutions for the visually impaired are due to some form of albinism. The most common form, oculocutaneous albinism type 2, results from mutations at the p locus. The function of the p gene is yet to be determined. It has been shown that melanocytes from p -null mice exhibit an abnormal melanosomal ultrastructure in addition to alterations in activity and localization of tyrosinase, a critical melanogenic enzyme. In light of these observations, we examined tyrosinase trafficking in p -null vs wildtype mouse melanocytes in order to explore p function. Electron microscopy of wildtype melan-a and p -null melan-p1 cells demonstrated accumulation of tyrosinase in 50 nm vesicles throughout the cell in the absence of p, an observation corroborated by an increase in tyrosinase activity in vesicle-enriched fractions from melan-p1 compared to melan-a cells. Misrouting in the absence of p was not limited to tyrosinase; a second melanosomal protein, tyrosinase-related protein 1, also trafficked incorrectly. In melan-p1, mislocalization led to secretion of tyrosinase into the medium. Adding tyrosine to the medium was found to partially correct tyrosinase trafficking and to reduce secretion; the cysteine protease inhibitor E64 also reduced secretion. We propose that p is required by melanocytes for transport of melanosomal proteins. In its absence, tyrosinase accumulates in vesicles and, in cultured melanocytes, is proteolysed and secreted.

Expression of tyrosinase and the tyrosinase related proteins in the Mitfvit (vitiligo) mouse eye: implications for the function of the microphthalmia transcription factor.

Mitf (Microphthalmia transcription factor), a basic-helix-loop-helix zipper protein, encoded at the microphthalmia (Mitf) locus, regulates the transcription of the gene encoding tyrosinase, the rate-limiting enzyme in melanin biosynthesis, by binding the DNA sequence CATGTG. This binding site is present also in the genes encoding two tyrosinase related proteins, TRP-1 and TRP-2. To gain insight into the function of Mitf in vivo, we determined whether there was a difference in the levels of these proteins in the RPE/choroid of the vitiligo (Mitfvit) mouse, in which there is a mutation of the Mitf gene. This mouse has alteration of RPE pigmentation and function that presumably leads to slow progressive loss of photoreceptor cells. The RPE/choroid was dissected from eyes of vitiligo and C57BL/6 wild-type mice at postnatal ages 2, 4, 7, 10, 14, 21 and 42 days. Extracts of pooled tissues were subjected to electrophoresis and immunoblotting. The levels of tyrosinase, TRP-1 and TRP-2 were determined densitometrically following immunodetection with rabbit antipeptide antisera. In addition, the tyrosine hydroxylase activity of tyrosinase as assayed radiometrically. Levels of TRP-1 were 3-7 fold greater in control RPE/choroid compared with mutants. This marked difference in protein level was observed at the earliest age examined (P2) and persisted throughout the first two weeks. Tyrosinase levels in mutants were similar to controls at P2 and P4, but were reduced at P10 and beyond. Tyrosinase activity was diminished also in mutants by P10. Levels of TRP-2 were similar between mutants and controls, although the typical decrease seen in controls after P14 was attenuated in the mutant mice. There is a significant reduction in the level of TRP-1 in the RPE/choroid of the Mitfvit mouse. The data suggests that transcription of the gene encoding TRP-1 is extremely dependent upon functional Mitf. It provides in vivo evidence that Mitf regulates the transcription of the gene encoding TRP-1 as well as tyrosinase.

Comparative decreases in tyrosinase, TRP-1, TRP-2, and Pmel 17/silver antigenic proteins from melanotic to amelanotic stages of syngeneic mouse cutaneous melanomas and metastases.

Malignant cutaneous melanomas and metastases were taken directly from in situ lesions of genetically identical (C57BL/6 strain) Tyr-SV40E transgenic mice, and samples were analyzed by Western immunoblotting with antisera specific for the COOH terminus of each of four melanocytic proteins. These were tyrosinase, TRP-1, TRP-2, and Pmel 17/silver. Of the 13 melanomas examined, there were 5 melanotic primary tumors, 5 amelanotic primary tumors, and 3 amelanotic metastases. The melanotic tumors expressed all of the markers to some extent. In contrast, the amelanotic tumors lacked detectable levels of one, two, or three of the proteins, except for an apparently amelanotic tumor sample in which all were expressed, but in which some melanotic cells were likely to have been present. Thus, despite some variability, there is clearly a downward trend in the presence of these proteins as the tumors become amelanotic, a pigmentary change associated with ongoing malignant progression. In the amelanotic tumors, tyrosinase was most often deficient, whereas TRP-2 was most often persistently expressed. These results, obtained from melanomas of syngeneic origin, indicate that tumors in the relatively early stages of malignancy might be more responsive than later-stage tumors to immunotherapy involving an ensemble of antigenic peptides of the tested gene products. Moreover, TRP-2 peptides may be especially useful for therapeutic intervention at the later stages.

The pinkeyed-dilution protein and the eumelanin/pheomelanin switch: in support of a unifying hypothesis.

The two major types of mammalian melanin are pheomelanin (yellow or red pigment) and eumelanin (black or brown). The agouti (A) and extension (E) loci determine whether follicular melanocytes will deposit pheomelanin or eumelanin within their melanosomes. Mutations at the murine pinkeyed-dilution (P) locus cause a striking reduction in deposition of eumelanic, but not pheomelanic, pigment. The mRNA encoded at the P locus is not expressed in skin that exclusively produces pheomelanic pigment as a result of mutation at the agouti locus. We have suggested, based upon both genetic and biochemical evidence, that three key melanogenic proteins--tyrosinase, tyrosinase-related-protein-1 (TRP-1), and TRP-2, encoded at the albino (C), brown (B), and slaty (Slt) loci, respectively--form a high-molecular-weight "melanogenic complex" within the melanosome. High-molecular-weight forms of tyrosinase, TRP-1 and TRP-2, are absent from eumelanic ocular tissues of p(un)/p(un) mice that fail to produce normal P-locus transcript, even though these mice are genetically normal at the loci that regulate production of the three melanogenic proteins. We have hypothesized that the presence of the p-locus protein is important for the integrity of the melanogenic complex and for the levels of members of the TRP family. We show here that the yellow skins of mice mutant at the agouti or extension loci, as well as the nonyellow skins of pinkeyed-unstable (p(un)/p(un)) mice, demonstrate greatly diminished levels of tyrosinase, TRP-1 and TRP-2, and an absence or markedly decreased proportion of high-molecular-weight forms of melanogenic proteins. We conclude that normal levels of wild-type P-locus protein are necessary for eumelanogenesis and that the absence of this protein may be necessary, but is not sufficient to cause the melanosome to switch to the production of pheomelanin. We discuss the implications of our results in relation to the interacting genetic controls regulating melanogenesis.

Changes in expression of putative antigens encoded by pigment genes in mouse melanomas at different stages of malignant progression.

Cutaneous melanomas of Tyr-SV40E transgenic mice (mice whose transgene consists of the tyrosinase promoter fused to the coding regions of simian virus 40 early genes) strikingly resemble human melanomas in their development and progression. Unlike human melanomas, the mouse tumors all arise in genetically identical individuals, thereby better enabling expression of specific genes to be characterized in relation to advancing malignancy. The products of pigment genes are of particular interest because peptides derived from these proteins have been reported to function as autoantigens with immunotherapeutic potential in some melanoma patients. However, the diminished pigmentation characteristic of many advanced melanomas raises the possibility that some of the relevant products may no longer be expressed in the most malignant cells. We have therefore investigated the contributions of several pigment genes in melanotic vs. relatively amelanotic components of primary and metastatic mouse melanomas. The analyses reveal marked differences within and among tumors in levels of mRNAs and proteins encoded by the wild-type alleles at the albino, brown, slaty, and silver loci. Tyrosinase (the protein encoded by the albino locus) was most often either absent or undetectable as melanization declined. The protein encoded by the slaty locus (tyrosinase-related protein 2) was the only one of those tested that was clearly present in all the tumor samples. These results suggest that sole reliance on targeting tyrosinase-based antigens might selectively favor survival of more malignant cells, whereas targeting the ensemble of the antigens tested might contribute toward a more inclusive and effective antimelanoma strategy.

High-molecular-weight forms of tyrosinase and the tyrosinase-related proteins: evidence for a melanogenic complex.

Tyrosinase, tyrosinase-related protein-1 (TRP-1), and tyrosinase-related protein-2, (TRP-2, dopachrome tautomerase) were shown by immunoblotting and enzyme assays to copurify from extracts of Cloudman S91 melanoma cells. Antibodies to TRP-1 and TRP-2 immunoprecipitated tyrosinase activity, suggesting a stable interaction (complex) among these proteins. The tyrosine hydroxylase activity of tyrosinase was reduced in the complexed form; treatment with Triton X-100 dissociated the complex and activated the tyrosinase present within it. To further study this complex, we employed sucrose gradient density centrifugation of extracts from cultured murine melanocytes. Tyrosinase, TRP-1, and TRP-2 all existed in high molecular weight "multimers" of approximately 200 to > 700 kilodaltons. Extraction of cells with buffers containing the detergent CHAPS preserved the high molecular weight multimers; Triton X-100 caused their dissociation into monomers. Low pH, low ionic strength, and millimolar concentrations of calcium ions favored the maintenance of multimers. The results of this study demonstrate that the participation of tyrosinase, TRP-1, and TRP-2 in a multimeric complex could have important physiologic consequences, and raise the possibility that some of the well-known interactions between coat color genes may be explained by intermolecular interactions between the gene products.

Identification of a melanosomal matrix protein encoded by the murine si (silver) locus using "organelle scanning".

To identify a broad spectrum of melanosomal proteins, antisera were raised in rabbits against melanosomal protein fractions separated on the basis of their solubility in the nonionic detergent Triton X-114. Antisera against the different fractions each recognized a distinct set of bands when used for immunoblotting analysis with extracts of melanocytes cultured from wild-type black mice. Immunoblotting with antisera to whole melanosomes or to Triton X-114-soluble melanosomal proteins that segregated with the detergent phase gave identical patterns with protein extracts from melanocytes from wild-type mice and from mice homozygous for the si (silver) coat color mutation. By contrast, an antiserum against Triton X-114 soluble melanosomal proteins that segregated in the aqueous phase recognized an 85-kDa protein that was present in extracts from wild-type melanocytes but was absent from si melanocytes. This suggested that the protein was encoded at the si (silver) locus. This was confirmed by employing an antiserum directed against the carboxyl terminus of the predicted murine silver protein sequence. The detergent solubility, biochemical characteristics, and immunologic properties of the 85-kDa protein and of the authentic si gene product were identical. Further analysis demonstrated that this protein corresponds to a melanosomal matrix glycoprotein that we recently described. Our results suggest that employing polyclonal antisera to fractionated organelles such as melanosomes, to screen tissues from mutant mice, a technique that we call "organelle scanning", can serve as a powerful means of identifying new organellar proteins and their respective genes.

Pathogenesis of the platinum (cp) mutation, a model for oculocutaneous albinism.

The platinum mutation at the C (albino) locus in the mouse is a potential model for oculocutaneous albinism in humans other than type IA (tyrosinase-negative) albinism. Although tissues from mice homozygous for the mutation display substantial tyrosinase activity, cutaneous and ocular pigmentation is severely restricted in affected animals. Using specific antipeptide antisera, we demonstrate that ocular extracts from wild-type mice contain two isoforms of tyrosinase bearing either the amino-terminal PEP5 epitope or the carboxy-terminal PEP7 epitope. The latter isoform participates in a high-molecular-weight complex detectable on sucrose density gradients. In platinum mice, antiserum to the PEP7 epitope fails to recognize any protein species, and the high-molecular-weight form of tyrosinase is not detectable. Our results support a key role for this high-molecular-weight complex in melanogenesis, and suggest that mutations that interfere with the ability of tyrosinase to participate in a multimeric complex may be a cause of oculocutaneous albinism in people.

Identification of a mammalian melanosomal matrix glycoprotein.

Antiserum raised in rabbits against the Triton X-100 insoluble fraction of melanosomes from mouse melanoma cells specifically decorates the internal matrix of melanosomes in immunoelectron microscopy. In metabolic labeling studies, the antiserum recognizes a protein of 94 kDa, which is processed to a band of 53 kDa. Whereas the precursor is relatively soluble in buffers containing Triton X-100, the processed protein requires the addition of sodium dodecyl sulfate for effective solubilization, as would be expected for a melanosomal matrix constituent. Tunicamycin reduces the Mr of the nascent protein to 75 kDa, but deoxymannojirimycin and swainsonine have no effect, suggesting that following initial glycosylation in the endoplasmic reticulum, the protein is not subject to processing by glycosidases in the Golgi apparatus or may bypass it entirely. Subcellular fractionation followed by immunoblotting confirms that the protein is present in the melanosome-rich, large granule fraction. Expression of the protein is regulated differently from that of the tyrosinase-related protein family. Conditions that greatly stimulate expression of tyrosinase-related proteins do not affect matrix protein expression, nor is the protein immunologically related to the tyrosinase-related protein family. Our results suggest that we have identified an authentic component of the mammalian melanosomal matrix, and that its characteristics lend support to a bipartite pathway for melanosomal biogenesis.

Lysosome-associated membrane protein-1 (LAMP-1) is the melanocyte vesicular membrane glycoprotein band II.

Coated vesicles play a critical role in the process of melanogenesis. Antisera raised against a coated vesicle fraction from mouse melanoma cells recognize two major glycoprotein antigens, band I (47-55 kd) and band II (90-120 kd). We demonstrate that band II is lysosome-associated membrane protein 1 (LAMP-1) by the following criteria: 1) the molecular weight and abundance of LAMP-1 varies among tissues but is always identical to that of band II; 2) band II and LAMP-1 co-migrate in sucrose gradient sedimentation studies; 3) immunodepletion of cell extracts with antivesicle serum removes all LAMP-1; and 4) intact organelles immunoisolated with antivesicle serum contain band II and LAMP-1. Our results further confirm the long-suspected relationship between melanosomes and the lysosomal lineage of organelles.