Investigation of the regulation of pigmentation in alpha-melanocyte-stimulating hormone responsive and unresponsive cultured B16 melanoma cells

In vitro melanocyte-stimulating hormone (MSH) stimulates melanogenesis in some, but not all, melanocytes and melanoma cells. In an attempt to explain this variation in response to alpha MSH, we examined cyclic adenosine monophosphate (cAMP) accumulation, tyrosinase activity, and melanin production in primary (1 degree) murine B16 melanoma cells and in two B16 cell lines (B16 F1 and B16 F10) that are known to respond to alpha MSH. In vivo all three B16 melanoma cell types produced pigmented tumours. In vitro alpha MSH increased tyrosinase activity and melanin content in the F1 and F10 cells but not in the B16 1 degree cells. alpha MSH, however, increased cAMP production in all three cell types, confirming that the inability of B16 1 degree cells to produce melanin in response to alpha MSH is not due to a lack of alpha MSH receptors or cAMP response to alpha MSH. Further, we present evidence for a separate pathway of melanogenesis that is independent of cAMP as calmodulin antagonists, which do not elevate cAMP, increased tyrosinase activity, and melanin production in both 1 degree and F1 cells.     

The Amphibian Melanization Inhibiting Factor (MIF) Blocks the α-MSH Effect on Mouse Malignant Melanocytes

We have found that a melanization inhibitory factor (MIF) extracted from the ventral skin of Rana forreri has a slight inhibitory effect on the activity levels of tyrosinase and dopachrome tautomerase in B16/F10 and Cloudman S-91 murine melanoma cell lines. Furthermore, this factor appears to block the effects of α-MSH on these enzymatic activities. However, MIF treatment does not affect the melanogenic action of theophylline on the same cells, suggesting that MIF acts proximal to MSH-mediated cAMP formation, possibly by interaction with the MSH receptor. In this way, we show that this amphibian factor has biological activity on mammalian melanocytes. This suggests the existence of mammalian counterparts of amphibian MIF in the mouse integument that might regulate epidermal melanocytes. These peptides might be related to the agouti protein, as they share similar mechanisms of action. The interaction of different peptides with the MSH receptor would be a complex but general mechanism responsible for many mammalian coat color variants.     

Regulation of mammalian melanogenesis by tyrosinase inhibition

Melanocyte stimulating hormone (MSH) specifically induces differentiation of mammalian melanocytes. To further define the biochemical events elicited by this stimulus, we have cloned murine melanoma cells which are either highly responsive or nonresponsive to MSH, and have examined their ultrastructural appearance, their melanogenic activities, and also their expression of tyrosinase. We have found that the basal levels of melanogenic activity in pigmented and nonpigmented cells correlate with expression of surface MSH receptors rather than with production of tyrosinase. Nonpigmented cells produce a potent, highly stable inhibitor of melanogenesis; this inhibitor acts directly on tyrosinase to dramatically and abruptly suppress melanin production. This posttranslational control of tyrosinase activity may represent a critical regulatory point in mammalian pigmentation.     

Modulation of murine melanocyte function in vitro by agouti signal protein.

Molecular and biochemical mechanisms that switch melanocytes between the production of eumelanin or pheomelanin involve the opposing action of two intercellular signaling molecules, alpha-melanocyte-stimulating hormone (MSH) and agouti signal protein (ASP). In this study, we have characterized the physiological effects of ASP on eumelanogenic melanocytes in culture. Following exposure of black melan-a murine melanocytes to purified recombinant ASP in vitro, pigmentation was markedly inhibited and the production of eumelanosomes was decreased significantly. Melanosomes that were produced became pheomelanosome-like in structure, and chemical analysis showed that eumelanin production was significantly decreased. Melanocytes treated with ASP also exhibited time- and dose-dependent decreases in melanogenic gene expression, including those encoding tyrosinase and tyrosinase-related proteins 1 and 2. Conversely, melanocytes exposed to MSH exhibited an increase in tyrosinase gene expression and function. Simultaneous addition of ASP and MSH at approximately equimolar concentrations produced responses similar to those elicited by the hormone alone. These results demonstrate that eumelanogenic melanocytes can be induced in culture by ASP to exhibit features characteristic of pheomelanogenesis in vivo. Our data are consistent with the hypothesis that the effects of ASP on melanocytes are not mediated solely by inhibition of MSH binding to its receptor, and provide a cell culture model to identify novel factors whose presence is required for pheomelanogenesis.     

Investigation of the Regulation of Pigmentation in α-Melanocyte-Stimulating Hormone Responsive and Unresponsive Cultured B16 Melanoma Cells

In vitro melanocyte-stimulating hormone (MSH) stimulates melanogenesis in some, but not all, melanocytes and melanoma cells. In an attempt to explain this variation in response to αMSH, we examined cyclic adenosine monophosphate (cAMP) accumulation, tyrosinase activity, and melanin production in primary (1°) murine B16 melanoma cells and in two B16 cell lines (B16 F1 and B16 F10) that are known to respond to αMSH. In vivo all three B16 melanoma cell types produced pigmented tumours. In vitro αMSH increased tyrosinase activity and melanin content in the F1 and F10 cells but not in the B16 1° cells. αMSH, however, increased cAMP production in all three cell types, confirming that the inability of B16 1° cells to produce melanin in response to αMSH is not due to a lack of αMSH receptors or cAMP response to αMSH. Further, we present evidence for a separate pathway of melanogenesis that is independent of cAMP as calmodulin antagonists, which do not elevate cAMP, increased tyrosinase activity, and melanin production in both 1° and F1 cells.     

Decay of hormone responsiveness in mouse melanoma cells in culture as a function of cell density

Cloudman S91 mouse melanoma cells lose their ability to demonstrate an MSH-induced increase in tyrosinase activity as cell density increases. This loss in hormone responsiveness occurs before confluency is reached and cannot be reversed by exposure of cells to increasing concentrations of MSH. The failure of high-density cultures to respond to MSH is apparently not the result of an inability of MSH to stimulate cAMP production, since either low- or high-density cultures exposed to MSH demonstrate equivalent increases in intracellular levels of cAMP. Further, neither theophylline (1mM), dibutyryl cyclic AMP (10(-4)M), or prostaglandin E1 (10(-6)M) is effective in stimulating tyrosinase activity in melanoma cells cultured at densities exceeding 6 X 10(4) cells/cm2. This finding suggests that the decay of hormone responsiveness occurs at a cellular site distal to cAMP production. The decrease in tyrosinase stimulation by MSH as cell density increases is also apparently not the result of an increase in activity of any soluble inhibitor of the enzyme, for cytosol preparations from high-density cultures (10(5) cells/cm2) fail to inhibit tyrosinase activity in cell homogenates from low-density cultures treated with MSH.     

Cultured Human Melanocytes Respond to MSH Peptides and ACTH

Although the administration of melanocyte-stimulating hormone (MSH) peptides results in skin darkening in man, cultured human melanocytes have been reported to be unresponsive to these peptides. This may be a consequence of the conditions under which the cells were maintained in vitro, particularly the use of phorbol esters and cholera toxin as melanocyte mitogens. By culturing the cells in the absence of these additives, we demonstrate that α-MSH and its synthetic analogue Nle⁴DPhe⁷α-MSH (NDP-MSH) induce dose-related increases in melanin content and tyrosinase activity and affect cell morphology in the majority of human melanocyte cultures. In addition, NDP-MSH induces increases in tyrosinase mRNA and tyrosinase-related protein-1 (TRP-1) mRNA. The dose-response curves for the MSH peptides are sigmoidal and the two peptides are equipotent in their effects on human melanocytes. Adrenocorticotropic hormone (ACTH) also affects morphology and stimulates melanogenesis and tyrosinase activity in human melanocytes. However, the dose-response curves for ACTH are biphasic, and the melanocytes respond to lower concentrations of ACTH than MSH peptides, similar to those normally present in human plasma. These findings may be important in understanding the role of these pro-opiomelanocortin peptides in human skin pigmentation.     

The role of RNA and protein synthesis in mediating the action of MSH on mouse melanoma cells.

Exposure of mouse melanoma cells in culture to MSH (melanocyte stimulating hormone) results in a marked increase in tyrosinase (O-diphenyl: O₂ oxidoreductase) activity following a lag period of 6–9 hours. Within 20 minutes after exposure of cells to MSH, the intracellular levels of cyclic AMP rise to levels which are ten times those of controls but fall to concentrations twice control values by 60 minutes. Transient increases in both protein and RNA synthetic rates also occur following MSH administration correlating in time with the dramatic but rapidly decaying increase in cellular cyclic AMP. The increase in tyrosinase activity observed in response to either MSH, dibutyryl cAMP, or theophylline, is completely suppressed by the addition of either cycloheximide (0.28 μg/ml) or actinomycin D (0.05 μg/ml) as is the basal activity of the enzyme. Results from ¹⁴C/³H leucine studies suggest that MSH may cause increased $\text{de}$$\text{novo}$ synthesis of tyrosinase.     

Interactions between ultraviolet light and interleukin-1 on MSH binding in both mouse melanoma and human squamous carcinoma cells

Interactions between beta-melanotropin (MSH), interleukin 1-a (IL-1), and ultraviolet light (UV) were examined in Cloudman S91 mouse melanoma and RHEK human squamous carcinoma cell lines. The following points were established: 1) both cell lines produced IL-1 and their production was stimulated by exposure of the cells to UV; 2) both cell lines possessed high affinity binding sites for MSH, and their ability to bind MSH was modulated by IL-1; 3) IL-1 exhibited both stimulatory and inhibitory effects on MSH binding to Cloudman cells; and 4) the stimulatory effect of IL-1 on MSH binding to melanoma cells was reflected in enhanced cellular responsiveness to MSH regarding tyrosinase activity (E.C. 1.14.18.1) and melanin content. The findings raise the possibility that interactions between keratinocytes and melanocytes may be regulated by IL-1 and MSH, and suggest a possible mechanism for stimulation of cutaneous melanogenesis by solar radiation: enhancement of MSH receptor activity by induction of IL-1.     

Decreased dopachrome oxidoreductase activity in yellow mice

Dopachrome oxidoreductase (DCOR) is a newly characterized enzyme in the melanin synthetic pathway, active in the conversion of dopachrome to 5,6-dihydroxyindole. DCOR and tyrosinase activity were measured in skin anagen hairbulbs from lethal yellow (Ay/a), sienna yellow (Asy/a) and recessive yellow (e/e) mice with and without treatment with melanocyte-stimulating hormone (MSH). DCOR activity was low (Asy/a) or absent (Ay/a, e/e) in yellow mice without MSH treatment, and increased dramatically in the lethal and sienna yellow mice with MSH. There was no increase in DCOR activity in recessive yellow mice with MSH. Corresponding tyrosinase activity was reduced in lethal yellow and sienna yellow mice without MSH, and increased with MSH. Tyrosinase activity was normal in recessive yellow mice without MSH and did not change with MSH. We conclude that DCOR is an MSH-sensitive enzyme and that DCOR activity is absent in recessive yellow melanocytes. The latter finding suggests that the extension locus may be the DCOR locus.     

Interleukin-1alpha stimulates the differentiation of melanocytes but inhibits the proliferation of melanoblasts from neonatal mouse epidermis

Interleukin (IL)-1alpha is one of the important cytokines involved in regulating immunological reactions in the mouse skin. However, it is not known whether IL-1alpha regulates the proliferation and differentiation of mouse epidermal melanocytes. In this study, to investigate the role of IL-1alpha in the regulation of the proliferation and differentiation of mouse epidermal melanocytes, IL-1alpha was supplemented to serum-free primary cultures of epidermal cell suspensions from the initiation of the primary culture (keratinocytes and melanoblasts-melanocytes) as well as to pure cultures of melanoblasts-melanocytes (keratinocyte-depleted cultures, after 14 days), and its effect was tested. IL-1alpha inhibited the proliferation of undifferentiated melanoblasts irrespective of the presence or absence of keratinocytes, whereas the cytokine inhibited the proliferation of differentiated melanocytes only in the presence of keratinocytes. Moreover, IL-1alpha induced the differentiation of melanocytes and, in addition, stimulated tyrosinase activity, melanin synthesis, and dendritogenesis of melanocytes irrespective of the presence or absence of keratinocytes. These results suggest that IL-1alpha is involved in inhibiting the proliferation of neonatal murine epidermal melanoblasts and in stimulating the differentiation, melanogenesis, and dendritogenesis of melanocytes. The results also suggest that IL-1alpha inhibits the proliferation of differentiated melanocytes in cooperation with keratinocyte-derived factors.     

Evaluation of the inhibition of mushroom tyrosinase and cellular tyrosinase activities of oxyresveratrol: comparison with mulberroside A

The inhibitory effects of oxyresveratrol, the aglycone of mulberroside A, on mushroom and cellular tyrosinase activities and melanin synthesis were evaluated. Mulberroside A and oxyresveratrol showed inhibitory activity against mushroom tyrosinase, with oxyresveratrol demonstrating a greater inhibitory effect than that of mulberroside A. Oxyresveratrol and mulberroside A strongly inhibited melanin production in Streptomyces bikiniensis and exhibited dose-dependent inhibition of tyrosinase activity and inhibition of melanin synthesis in B16F10 melanoma cells. However, the compounds exhibited nearly similar inhibitory effects on the activity of cellular tyrosinase and melanin synthesis in murine melanocytes. The inhibition of melanin synthesis by mulberroside A and oxyresveratrol was involved in suppressing the expression level of melanogenic enzymes, tyrosinase, tyrosinase-related protein-1 (TRP-1), and tyrosinase-related protein-2 (TRP-2). These results indicate that the inhibition rate of mushroom tyrosinase might not provide an accurate estimate of the inhibition rate of melanin synthesis in melanocytes.     

α‐MSH activates immediate defense responses to UV‐induced oxidative stress in human melanocytes

Exposure of cultured human melanocytes to ultraviolet radiation (UV) results in DNA damage. In melanoma, UV‐signature mutations resulting from unrepaired photoproducts are rare, suggesting the possible involvement of oxidative DNA damage in melanocyte malignant transformation. Here we present data demonstrating immediate dose‐dependent generation of hydrogen peroxide in UV‐irradiated melanocytes, which correlated directly with a decrease in catalase activity. Pretreatment of melanocytes with α‐melanocortin (α‐MSH) reduced the UV‐induced generation of 7,8‐dihydro‐8‐oxyguanine (8‐oxodG), a major form of oxidative DNA damage. Pretreatment with α‐MSH also increased the protein levels of catalase and ferritin. The effect of α‐MSH on 8‐oxodG induction was mediated by activation of the melanocortin 1 receptor (MC1R), as it was absent in melanocytes expressing loss‐of‐function MC1R, and blocked by concomitant treatment with an analog of agouti signaling protein (ASIP), ASIP‐YY. This study provides unequivocal evidence for induction of oxidative DNA damage by UV in human melanocytes and reduction of this damage by α‐MSH. Our data unravel some mechanisms by which α‐MSH protects melanocytes from oxidative DNA damage, which partially explain the strong association of loss‐of‐function MC1R with melanoma.     

Bioactive motifs of agouti signal protein

The switch between the synthesis of eu- and pheomelanins is modulated by the interaction of two paracrine signaling molecules, alpha-melanocyte stimulating hormone (MSH) and agouti signal protein (ASP), which interact with melanocytes via the MSH receptor (MC1R). Comparison of the primary sequence of ASP with the known MSH pharmacophore provides no suggestion about the putative bioactive domain(s) of ASP. To identify such bioactive motif(s), we synthesized 15-mer peptides that spanned the primary sequence of ASP and determined their effects on the melanogenic activities of murine melanocytes. Northern and Western blotting were used, together with chemical analysis of melanins and enzymatic assays, to identify three distinct bioactive regions of ASP that down-regulate eumelanogenesis. The decrease in eumelanin production was mediated by down-regulation of mRNA levels for tyrosinase and other melanogenic enzymes, as occurs in vivo, and these effects were comparable to those elicited by intact recombinant ASP. Shorter peptides in those motifs were synthesized and their effects on melanogenesis were further investigated. The amino acid arginine, which is present in the MSH peptide pharmacophore (HFRW), is also in the most active domain of ASP (KVARP). Our data suggest that lysines and an arginine (in motifs such as KxxxxKxxR or KxxRxxxxK) are important for the bioactivity of ASP. Identification of the specific ASP epitope that interacts with the MC1R has potential pharmacological applications in treating dysfunctions of skin pigmentation.     

Inhibition of tyrosinase activity and protein synthesis in melanoma cells by calcium ionophore A23187

Calcium ionophore A23187 lowers basal levels of tyrosinase and inhibits the MSH-induced increase in tyrosinase in Cloudman S-91 mouse melanoma cell cultures. Ionophore at a concentration of 10(-6) g/ml causes a 50% reduction in basal levels of tyrosinase and inhibits the MSH stimulated level of enzyme. Ionophore A23187 also inhibits the PGE1 mediated stimulation of tyrosinase, as well as the rise in enzyme activity observed in cells exposed to either theophylline (1 mM) or dbcAMP (10(-4)M). Ionophore does not affect basal levels of cyclic AMP nor the elevated levels produced by either MSH or PGE1, suggesting then, that the antagonistic activity of A23187 is localized to a point in the pathway of tyrosinase activation distal to the formation of cAMP. Ionophore causes a rapid and marked (greater than 50%) inhibition of cellular protein synthesis and it is possible that this calcium mobilizing compound may exert its inhibitory effects on tyrosinase activity by causing a general reduction in cellular translation. Since the inhibition of protein synthesis occurs in cells exposed to ionophore in either the presence or absence of calcium in the medium, it seems, likely that the ionophore may exert its effects by causing the release of calcium from intracellular sites.     

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.     

Effects of Ultraviolet Light on Melanocyte Differentiation: Studies with Mouse Neural Crest Cells and Neural Crest‐derived Cell Lines

To evaluate the etiologic role of ultraviolet (UV) radiation in acquired dermal melanocytosis (ADM), we investigated the effects of UVA and UVB irradiation on the development and differentiation of melanocytes in primary cultures of mouse neural crest cells (NCC) by counting the numbers of cells positive for KIT (the receptor for stem cell factor) and for the L ‐3,4‐dihydroxyphenylalanine (DOPA) oxidase reaction. No significant differences were found in the number of KIT‐ or DOPA‐positive cells between the UV‐irradiated cultures and the non‐irradiated cultures. We then examined the effects of UV light on KIT‐positive cell lines derived from mouse NCC cultures. Irradiation with UVA but not with UVB inhibited the tyrosinase activity in a tyrosinase‐positive cell line (NCCmelan5). Tyrosinase activity in the cells was markedly enhanced by treatment with α‐melanocyte‐stimulating hormone (α‐MSH), but that stimulation was inhibited by UVA or by UVB irradiation. Irradiation with UVA or UVB did not induce tyrosinase activity in a tyrosinase‐negative cell line (NCCmelb4). Levels of KIT expression in NCCmelan5 cells and in NCCmelb4 cells were significantly decreased after UV irradiation. Phosphorylation levels of extracellular signal‐regulated kinase 1/2 in cells stimulated with stem cell factor were also diminished after UV irradiation. These results suggest that UV irradiation does not stimulate but rather suppresses mouse NCC. Thus if UV irradiation is a causative factor for ADM lesions, it would not act directly on dermal melanocytes but may act in indirect manners, for instance, via the overproduction of melanogenic cytokines such as α‐MSH and/or endothelin‐1.