THE FINE STRUCTURE OF NORMAL AND NEOPLASTIC MELANOCYTES IN THE SYRIAN HAMSTER, WITH PARTICULAR REFERENCE TO CARCINOGEN-INDUCED MELANOTIC TUMORS

The dermal melanocyte system of the Syrian hamster is particularly responsive to the melanogenetic and tumor-inducing effects of 7,12-dimethylbenz(a)anthracene (DMBA). The melanocytes of the hair follicles appear to be susceptible to the melanogenetic effect of DMBA but not to its tumor-inducing effect. The epidermal melanocytes are non-pigmented and are unresponsive to both melanogenetic and carcinogenic effects of DMBA. The pigmented granules of the dermal melanocytes of both the golden and the white hamster have an identical substructure and pattern of melanization which occurs in an orderly fashion on a delicate fibrillar component. The hair melanocytes have larger pigment granules with a more complicated fibrillar substructure. The epidermal melanocytes do not possess pigment granules but are recognized by their dendritic shape, the absence of desmosomes and tonofilaments, and the presence of racket-shaped or rod-shaped organelles. The melanin granules in neoplastic melanocytes of the golden hamster differ from corresponding normal melanocytes only in their larger size. In the white hamster, however, the melanin granules in tumors produced under identical experimental conditions are so bizarre and atypical that consideration was given to the possibility that a genetic difference in the melanization pattern between the two varieties becomes apparent in carcinogen-induced melanotic tumors. No definite conclusions could be reached as to the precise origin of the melanin granules in either normal or neoplastic melanocytes.     

ELECTRON MICROSCOPE STUDIES OF EPIDERMAL MELANOCYTES, AND THE FINE STRUCTURE OF MELANIN GRANULES

Melanocytes and melanin granules have been studied by electron microscopy in normal human and cat skin, and in hyperplastic human skin lesions. The melanocytes have always been found as free cells within the epidermis,i.e., on the epidermal side of the dermal membrane. Melanocytes frequently rest on the dermal membrane or bulge towards the dermis. In such cases the uninterrupted dermal membrane is uniformly thin and smooth in appearance, in contrast with the regions alongside Malpighian cells, where it appears appreciably thicker and seemingly anchored to the basal cell layer. Two types of melanin granules have been distinguished according to their location in the melanocytes and to morphological characteristics which may only express different stages in the maturation of the granules: (a) light melanin granules in which a structure resembling a fine network is apparent; (b) dense melanin granules which, in osmium-fixed preparations, appear as uniformly dense masses surrounded by a coarsely granular, intensely osmiophilic shell. Treatment of sections of osmium-fixed tissues with potassium permanganate has revealed within the dense granules the existence of an organized framework in the form of a regular, crystalline-like lattice. It is suggested that this basic structure is protein in nature and may include the enzymatic system capable of producing melanin. The existence is reported of fine filaments located in the cytoplasm of melanocytes and morphologically distinct from the tonofilaments found in Malpighian cells.     

Identification of two types of melanocyte within the stria vascularis of the mouse inner ear

We have distinguished two types of melanocyte within the intermediate layer of the stria vascularis in the cochlea of normally pigmented mice: light and dark intermediate cells. The light intermediate cells are present in the stria from birth and have the typical appearance of a melanocyte. They are large and dendritic with electron-lucent cytoplasm containing numerous vesicles that show tyrosinase activity, and pigment granules in various stages of development. These granules have the ultrastructural and histochemical characteristics of premelanosomes and melanosomes. The light intermediate cells persist throughout life, but less frequently contain pigment in older animals. The dark intermediate cells, present only in adult mice, vary considerably in number and distribution between animals. Pigment granules, bound within an electron-dense acid phosphatase-rich matrix, form the main component of the dark intermediate cells. The intermediate cells may comprise either two distinct cell populations or different developmental stages of the same cell type; ultrastructural observations suggest the latter. In young mice, light intermediate cells contain the electron-dense matrices, which at later stages of development are found almost exclusively in dark cells. The dark intermediate cells contain few cell organelles other than pigment granules accumulated within lysosomal bodies and they often have pycnotic nuclei. These observations suggest that the dark intermediate cells are a degenerate form of the light intermediate cells. Clusters of melanosomes also occur in the basal cells, and to a much lesser extent in the marginal cells. These cells do not stain after incubation in DOPA, suggesting that they are not capable of melanin synthesis, and therefore probably acquire melanin by donation from adjacent melanocytes. Pigment clusters are also found within the spiral ligament at all stages of development.     

Transport of Endocytosed Material Into Melanin Granules in Cultured Choroidal Melanocytes of Cattle—New Insights Into the Relationship of Melanosomes With Lysosomes

Cultured choroidal melanocytes from cattle were incubated with gold labeled albumin. After phagocytosis of the labeled protein, the label appeared inside the melanin granules, as was observed under the electron microscope. Melanin granules associated with gold particles were also exocytosed into the culture medium by the melanocytes. The results of this study show that endosomes or phagosomes are transported from the cell surface of a melanocyte to the melanin granules. Therefore, melanin granules are part of the lysosomal degradation pathway. The possibility that albumin is degraded by proteases present in lysosomes and melanosomes and that the tyrosine released during degradation is used as substrate by tyrosinase and thereby converted to melanin is discussed. The present study additionally shows that the choroidea of cattle can be used as a source for cell culture of melanocytes.     

Quantitative control of end products in the melanocyte lineage of the ascidian embryo.

Terminal amounts of tyrosinase (EC 1.10.3.1) activity and melanin pigment in the giant melanocytes of cleavage-arrestedCiona intestinalis (L.) embryos are regulated independently of cell size and number of nuclei in the cells. Embryos were cleavage-arrested in cytochalasin B at a time before the last two divisions of the melanocyte lineage took place. The resulting two giant melanocytes, one from each of the two bilateral melanocyte lineages, developed tyrosinase and melanin. The cells were about three times larger in volume than the normal larval melanocytes and each contained four nuclei instead of just one. Quantitative measurements of melanin synthesized and tyrosinase activity in embryos with the giant melanocytes revealed amounts identical to those found in normal embryos. This specification of exact quantities differs markedly from the situation in mammalian melanocytes where cell volume and gene dosage influence the extent of melanotic differentiation. Quantitative control of differentiation in ascidian melanocytes appears to be mediated by a cytoplasmic determinant segregated through the melanocyte lineage and inherited by one daughter at each division of the lineages.     

Effect of keratinocytes on regulation of melanogenesis in culture of melanocytes

Melanocytes are the melanin-producing cells by melanogenesis, and the pigment melanin is primarily responsible for the color of skin. These cells contain dendrites that are in close contact with neighboring keratinocytes. Keratinocytes produce and secrete factors that regulate the proliferation and melanogenesis of melanocytes in vitro. Therefore, adopting only melanocyte pure culture may not clearly reflect the skin physiology in vivo. In this study, we applied a two-culture model using melanocytes and keratinocytes from human skin, such as melanocyte pure culture and melanocyte co-culture with keratinocyte. And then, there was compared the responses of melanocytes under different culture conditions (treatment with arbutin, MSH-α and UV-B irradiation). The results show that there was no significant difference in melanocyte proliferation and melanogenesis between arbutin and MSH-α treatment. However, the co-culture model was more stable than the pure culture model in terms of melanocyte proliferation and melanogenesis upon UV-B irradiation. Therefore, the co-culture model was superior to the pure culture as a useful method for the study of melanocytes and epidermal melanin unit.     

The cell biology of human hair follicle pigmentation

Although we have made significant progress in understanding the regulation of the UVR‐exposed epidermal‐melanin unit, we know relatively little about how human hair follicle pigmentation is regulated. Progress has been hampered by gaps in our knowledge of the hair growth cycle’s controls, to which hair pigmentation appears tightly coupled. However, pigment cell researchers may have overly focused on the follicular melanocytes of the nocturnal and UVR‐shy mouse as a proxy for human epidermal melanocytes. Here, I emphasize the epidermis‐follicular melanocyte pluralism of human skin, as research models for vitiligo, alopecia areata and melanoma, personal care/cosmetics innovation. Further motivation could be in finding answers to why hair follicle and epidermal pigmentary units remain broadly distinct? Why melanomas tend to originate from epidermal rather than follicular melanocytes? Why multiple follicular melanocyte sub‐populations exist? Why follicular melanocytes are more sensitive to aging influences? In this perspective, I attempt to raise the status of the human hair follicle melanocyte and highlight some species‐specific issues involved which the general reader of the pigmentation literature (with its substantial mouse‐based data) may not fully appreciate.     

Role of light in human skin color viariation.

The major source of color in human skin derives from the presence within the epidermis of specialized melanin-bearing organelles, the melanosomes. Tanning of human skin on exposure to ultraviolet light results from increased amounts of melanin within the epidermis. Melanosomes synthesized by melanocytes are acquired by keratinocytes and transported within them to the epidermal surface. In some cases, the melanosomes are catobolized en route. New information indicates that the multicellular epidermal melanin unit (melanocyte and associated pool of keratinocytes) rather than the melanocyte alone is the focal point for the control of melanin metabolism within mammalian epidermis. Gross human skin color derives from the visual impact of the summed melanin pigmentation of the many epidermal melanin units. In theory, constitutive skin color in man designates the genetically-determined levels of melanin pigmentation developed in the absence of exposure to solar radiation or other environmental influences; facultative skin color or "tan" characterizes the increases in melanin pigmentation above the constitutive level induced by ultraviolet light. The details of genetic regulation of pigment metabolism within the epidermal melanin units are being clarified. In some mammals at least, the function of epidermal melanin units is significantly influenced by hormones which may be regulated by radiations received through the eyes. Based on an evolutionary history of the human family which exceeds ten million years, it is proposed that melanin pigmentation may have played a number of roles in human adaptions to changing biologic and physical environments.     

The effects of single gene substitution on the mammalian melanocyte system—a qualitative and quantitative histological study in the C57BL and DBL mice

About 160 skin samples from the tail, sole, palm, ear and scrotum of DBL and C57BL/St mice were “split” with NaBr and treated with DOPA. A quantitative and qualitative microscopic analysis showed that: (a) the two strains did not differ consistently in the frequency of epidermal or dermal melanocytes; nor did the sexes differ from each other in this respect; (b) the melanocytes of the two strains differed morphologically. The DBL melanocytes were generally larger, with melanin-congested perikarya. They had fewer dendrites than the C57BL melanocytes and their dendrites were shorter; and (c) the melanocytes of the DBL and C57BL strains differed in activity, the DBL melanocytes donating less melanin to Malpighian cells than did the C57BL melanocytes. It was concluded that the morphology of DBL and C57BL melanocytes is largely autonomously determined, although regional differences in melanocyte morphology suggest that the cellular environment also plays some part in influencing melanoblast differentiation.     

Melanosomal pH controls rate of melanogenesis, eumelanin/phaeomelanin ratio and melanosome maturation in melanocytes and melanoma cells.

The skin pigment melanin is produced in melanocytes in highly specialized organelles known as melanosomes. Melanosomes are related to the organelles of the endosomal/lysosomal pathway and can have a low internal pH. In the present study we have shown that melanin synthesis in human pigment cell lysates is maximal at pH 6.8. We therefore investigated the role of intramelanosomal pH as a possible control mechanism for melanogenesis. To do this we examined the effect of neutralizing melanosomal pH on tyrosinase activity and melanogenesis in 11 human melanocyte cultures and in 3 melanoma lines. All melanocyte cultures (9 of 9) from Caucasian skin as well as two melanoma cell lines with comparable melanogenic activity showed rapid (within 24 h) increases in melanogenesis in response to neutralization of melanosomal pH. Chemical analysis of total melanin indicated a preferential increase in eumelanin production. Electron microscopy revealed an accumulation of melanin and increased maturation of melanosomes in response to pH neutralization. In summary, our findings show that: (i) near neutral melanosomal pH is optimal for human tyrosinase activity and melanogenesis; (ii) melanin production in Caucasian melanocytes is suppressed by low melanosomal pH; (iii) the ratio of eumelanin/phaeomelanin production and maturation rate of melanosomes can be regulated by melanosomal pH. We conclude that melanosomal pH is an essential factor which regulates multiple stages of melanin production. Furthermore, since we have recently identified that pink locus product (P protein) mediates neutralization of melanosomal pH, we propose that P protein is a key control point for skin pigmentation. We would further propose that the wide variations in both constitutive and facultative skin pigmentation seen in the human population could be associated with the high degree of P-locus polymorphism.     

The Interaction of Agouti Signal Protein and Melanocyte Stimulating Hormone to Regulate Melanin Formation in Mammals

Important regulatory controls of melanogenesis that operate at the subcellular level to modulate the structural and/or the functional nature of the melanins and melanin granules produced in melanocytes are reviewed. Melanocyte stimulating hormone and agouti signal protein have antagonistic roles and possibly opposing mechanisms of action in the melanocyte. In the mouse, melanocyte stimulating hormone promotes melanogenic enzyme function and elicits increases in the amount of eumelanins produced, while agouti signal protein reduces total melanin production and elicits the synthesis of pheomelanin rather than eumelanin. We are now beginning to understand the complex controls involved in regulating this switch at the molecular and biochemical levels. The quality and quantity of melanins produced by melanocytes have important physiological consequences for melanocyte function and undoubtedly play important roles in the various functions of the melanins per se, including hair and skin coloration and photoprotection.     

Presence of melanin in the cat pineal gland.

Light- and electron-microscopic features of pigmented cells in the cat pineal gland are described. These cells were observed throughout postnatal life from the second postnatal day to the oldest cats studied (up to 13 years old). No apparent relationship was observed among the amount of pigment and the animal age or sex. Pigmented cells showed a preferential localization at the ventral surface of the pineal gland near its distal end. The pineal pigment was histochemically identified as melanin. Pineal pigment granules showed ultrastructural features similar to melanocyte melanin granules.     

Skeletal muscle–melanocyte association during tadpole tail resorption in a tropical frog,Clinotarsus curtipes Jerdon (Anura,Ranoidea)

We tested the hypothesis that melanin has a role as a molecule within the thyroid-mediated cascade. Light microscopic and ultrastructural changes in the skeletal muscle during tail resorption in tadpoles of the tropical frog Clinotarsus curtipes Jerdon (Anura: Ranoidea) were observed. Light microscopic analysis at metamorphic stage XVIII showed a melanized epidermis. A gradual migration of melanocytes from the epidermis to the dermis and filopodia of melanocytes pervading the skeletal muscle preceded tail resorption. The invasion of melanocytes into the muscle bundles coincided with the breakdown of the muscle bundles into sarcolytes and the arrival of macrophages at this site. This would suggest that the melanocyte–sarcolyte association signals the arrival of macrophages at these sites as metamorphosis progressed. Melanophages, macrophages with melanin granules, were observed at the climax stage of XXIII. The sarcolytes and the melanin granules were phagocytosed by macrophages so as to completely cleanse the exocytic muscle debris and the melanin granules. The presence of large melanomacrophage centers in the tadpole liver at metamorphic climax suggests that these phagocytic macrophages were further processed in the liver and, likely, in the spleen. It is proposed that melanin, a byzantine molecule, has a role in the cascade of events leading to tail resorption in anuran tadpoles.     

Regulation of eumelanin/pheomelanin synthesis and visible pigmentation in melanocytes by ligands of the melanocortin 1 receptor

The production of melanin in the hair and skin is tightly regulated by the melanocortin 1 receptor (MC1R) whose activation is controlled by two secreted ligands, alpha-melanocyte stimulating hormone (alphaMSH) and agouti signal protein (ASP). As melanin is extremely stable, lasting years in biological tissues, the mechanism underlying the relatively rapid decrease in visible pigmentation elicited by ASP is of obvious interest. In this study, the effects of ASP and alphaMSH on the regulation of melanin synthesis and on visible pigmentation were assessed in normal murine melanocytes and were compared with the quick depigmenting effect of the tyrosinase inhibitor, phenylthiourea (PTU). alphaMSH increased pheomelanin levels prior to increasing eumelanin content over 4 days of treatment. Conversely, ASP switched off the pigment synthesis pathway, reducing eu- and pheo-melanin synthesis within 1 day of treatment that was proportional to the decrease in tyrosinase protein level and activity. These results demonstrate that the visible depigmentation of melanocytes induced by ASP does not require the degradation of existing melanin but rather is due to the dilution of existing melanin by melanocyte turnover, which emphasizes the importance of pigment distribution to visible color.     

Cell Division: Pressure-induced reversal of the antimeiotic effects of heavy water in the oocytes of the starfish,Asterias forbesi

In dermal melanocytes of Rana pipiens, colchicine is known to produce a gradual, dosage-dependent dispersion of melanin granules, irreversible over several hours. This effect is potentiated by a number of chemical agents that normally produce a reversible dispersion of granules. In the present study we examined the effect of high hydrostatic pressure on changes induced in melanocytes by colchicine. In Ringer's solution, samples of skin from a single frog were incubated for 30 minutes at room temperature with or without colchicine, 9 × 10^?5 M. Then two samples, one of which had been pretreated with colchicine, were successively subjected to 12,000 psi for one hour at 25 to 26°C. The degree of dispersion of melanin granules in melanocytes was observed before, during and after the period of pressure. In frog skin pretreated with colchicine, the usually gradual, irreversible dispersion of melanin granules in melanocytes was potentiated. Since high pressure is known to produce solational changes in protoplasm, such changes may accompany dispersion of melanin granules in melanocytes. If this be so, then sol-gel equilibria may be important in the action of dispersing and aggregating agents, many of which are hormones and other physiologically active agents. Finally, the present study supports the hypothesis that colchicine shifts protoplasmic sol-gel equilibria toward a less gelated condition.     

Efficacy of hydroquinone in the treatment of cutaneous hyperpigmentation in hairless descendants of Mexican hairless dogs (Xoloitzcuintli)

The skin of adult hairless dogs is clinically nonpigmented, clinically lightly pigmented, or clinically hyperpigmented (spotty pigmented). The pigment noted clinically is attributable to melanin granules in the epidermis. Spotty pigmentation in the skin of adult hairless dogs was treated by administration of the depigmenting agent (3% hydroquinone, HQ) for 1 month. Depigmenting effects were examined by use of three methods: skin color, dihydroxyphenylalanine (DOPA)-positive melanocyte count, and histologic evaluation. The treated skin of hairless dogs began to become depigmented after application of HQ for 1 week. After 1 month of treatment with HQ, depigmentation spread over a quarter of the body. The number of DOPA-positive melanocytes in the HQ-treated sites decreased to less than approximately a fifth of that before treatment. In HQ-treated skin, histologic staining by use of Fontana-Masson's (FM) method revealed complete absence of melanin pigment. These results suggested that hairless dogs should be a useful animal model for investigating the effects and cutaneous toxicity of depigmenting agents.     

Melanosomes, melanocytes and keratinocytes in the human epidermis in incontinentia pigmenti

A functioning epidermal melanin unit implies a melanocyte capable of transferring melanosomes to keratinocytes; this requires not only melanocytes with adequate dendrites but also "receptive" keratinocytes. Skin with incontinentia pigmenti was examined by electron microscopy. Premelanosomes were occasionally found within keratinocytes and deposits of extracellular granular material that came from vacuolar degeneration of keratinocytes adjacent to melanocytes.     

Skin as a living coloring book: how epithelial cells create patterns of pigmentation

The pigmentation of mammalian skin and hair develops through the interaction of two basic cell types — pigment donors and recipients. The pigment donors are melanocytes, which produce and distribute melanin through specialized structures. The pigment recipients are epithelial cells, which acquire melanin and put it to use, collectively yielding the pigmentation visible to the eye. This review will focus on the pigment recipients, the historically less understood cell type. These end‐users of pigment are now known to exert a specialized control over the patterning of pigmentation, as they identify themselves as melanocyte targets, recruit pigment donors, and stimulate the transfer of melanin. As such, this review will discuss the evidence that the skin is like a coloring book: the pigment recipients create a ‘picture,’ a blueprint for pigmentation, which is colorless initially but outlines where pigment should be placed. Melanocytes then melanize the recipients and ‘color in’ the picture.     

Mammalian tyrosinase—The critical regulatory control point in melanocyte pigmentation

• 1.1. Tyrosinase is a copper-containing enzyme responsible for the production of melanin pigment throughout the phylogenetic spectrum.
• 2.2. In mammals, tyrosinase is glycosylated enzyme found specifically in melanocytes—cells functional in the production and secretion of pigment granules.
• 3.3. Although many factors determine the type, quantity and quality of the melanin produced, tyrosinase activity is the critical factor that ultimately regulates melanogenesis.

     

Melanosome capping of keratinocytes in pigmented reconstructed epidermis--effect of ultraviolet radiation and 3-isobutyl-1-methyl-xanthine on melanogenesis

Reconstructed pigmented epidermis was established by co-seeding autologous melanocytes and keratinocytes onto a dermal substrate and culturing for up to 6 weeks at the air-liquid interface. Inspection of the tissue architecture revealed that melanocytes are regularly interspersed only in the basal layer and transfer melanosomes to the keratinocytes. We report for the first time, the in vitro formation of supranuclear melanin caps above the keratinocyte nuclei. The formation and abundance of these melanin caps could be enhanced by pigment modifiers such as ultraviolet light and 3-isobutyl-1-methyl-xanthine (IBMX). In untreated cultures, the capping was observed in the spinous layers after 6 weeks of culture, whereas after irradiation or supplementation of the culture medium with IBMX, the capping occurred already in the basal layer 2 weeks after initiation of the stimulus. In this study, we show that IBMX and ultraviolet irradiation stimulate pigmentation via different mechanisms. After supplementation of the culture medium with IBMX the increase in pigmentation was entirely due to the increase in melanocyte activity as observed by increased dendrite formation, melanin production and transport to the keratinocytes and was not due to an increase in melanocyte proliferation. In contrast, after UV irradiation, the increase in pigmentation was also accompanied with an increase in melanocyte proliferation as well as an increase in melanocyte activity. In conclusion, we describe the establishment of pigmented reconstructed epidermis with autologous keratinocytes and melanocytes that can be kept in culture for a period of at least 6 weeks. The complete program of melanogenesis occurs: melanosome synthesis, melanosome transport to keratinocytes, supranuclear capping of keratinocyte nuclei and tanning of the epidermis. This enables sustained application of pigment stimulators over a prolonged period of time and also repeated application of pigment stimulators to be studied.