Ultrastructural investigation of autophagocytosis of melanosomes and programmed death of melanocytes in White Leghorn feathers: a study of morphogenetic events leading to hypomelanosis

White Leghorn chickens have decreased feather melanin, not because pigment cells are absent, but because of a genetically determined programmed cell death that causes pigment cells to degenerate prematurely before the melanin can be deposited in the feathers. In this paper, we studied the feather germs of this breed and of control Black Minorca chickens by light and electron microscopy to elucidate further the mechanism of cell death.White Leghorn feature-germ melanocytes produced a large number of unmelanized melanosomes which, however, did not become melanized, nor were they transferred into the keratinocytes of the follicles. From day 10 of incubation onward, large autophagosomes appeared in the melanocytes of White Leghorn feather follicles. These autophagosomes were acid phosphatase positive and engulfed incompletely melanized melanosomes. They also contained melanosome degradation products. Finally, degeneration of the whole melanocyte followed. These necrotic melanocytes were engulfed by normal-looking keratinocytes of the same follicle. In Black Minorcas, on the other hand, there was a normal sequence of synthesis, melanization, and transfer of melanosomes. The melanocytes degenerated only at the time of hatching, without the formation of large autophagosomes.     

A method for quantifying melanosome transfer efficacy from melanocytes to keratinocytes in vitro

Several different in vivo and in vitro bioassays are used to evaluate melanosome transfer efficacy from melanocytes to keratinocytes. However, these methods are complicated and time consuming. Here, we report on a simple, rapid, direct, and reliable in vitro method for observing the process of melanosome transfer from melanocytes to keratinocytes. First, we selected and tested a melanoma cell line RPMI-7951 that can normally synthesize melanin and transfer from mature melanosomes to keratinocytes in vitro. We cocultured these cells with a human ovarian teratoma transformed epidermal carcinoma cell line, which is also capable of accepting melanosomes transferred from melanocytes, as in normal keratinocytes. The cells were cocultured for 24-72 h and double labeled with FITC-conjugated antibody against the melanosome-associated protein TRP-1, and with Cy5-conjugated antibody against the keratinocyte-specific marker keratin 14. The cells were examined by fluorescence microscope and flow cytometry. Melanosome transfer from melanocytes to keratinocytes increased in a time-dependent manner. To verify the accessibility of this method, the melanosome transfer inhibitor, a serine protease inhibitor, 4-(2-aminoethyl) benzenesulfonyl fluoride hydrochloride, and a melanosome transfer stimulator, alpha-melanocyte-stimulating hormone, were added. The serine protease inhibitor decreased melanosome transfer, and alpha-melanocyte-stimulating hormone increased melanosome transfer, in a dose-dependent manner. In conclusion, this is a simple, rapid, and effective model system to quantify the melanosome transfer efficacy from melanocytes to keratinocytes in vitro.     

Manassantin B inhibits melanosome transport in melanocytes by disrupting the melanophilin–myosin Va interaction

Human skin hyperpigmentation disorders occur when the synthesis and/or distribution of melanin increases. The distribution of melanin in the skin is achieved by melanosome transport and transfer. The transport of melanosomes, the organelles where melanin is made, in a melanocyte precedes the transfer of the melanosomes to a keratinocyte. Therefore, hyperpigmentation can be regulated by decreasing melanosome transport. In this study, we found that an extract of Saururus chinensis Baill (ESCB) and one of its components, manassantin B, inhibited melanosome transport in Melan‐a melanocytes and normal human melanocytes (NHMs). Manassantin B disturbed melanosome transport by disrupting the interaction between melanophilin and myosin Va. Manassantin B is neither a direct nor an indirect inhibitor of tyrosinase. The total melanin content was not reduced when melanosome transport was inhibited in a Melan‐a melanocyte monoculture by manassantin B. Manassantin B decreased melanin content only when Melan‐a melanocytes were co‐cultured with SP‐1 keratinocytes or stimulated by α‐MSH. Therefore, we propose that specific inhibitors of melanosome transport, such as manassantin B, are potential candidate or lead compounds for the development of agents to treat undesirable hyperpigmentation of the skin.     

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.     

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.     

Essential Role of RAB27A in Determining Constitutive Human Skin Color

Human skin color is predominantly determined by melanin produced in melanosomes within melanocytes and subsequently distributed to keratinocytes. There are many studies that have proposed mechanisms underlying ethnic skin color variations, whereas the processes involved from melanin synthesis in melanocytes to the transfer of melanosomes to keratinocytes are common among humans. Apart from the activities in the melanogenic rate-limiting enzyme, tyrosinase, in melanocytes and the amounts and distribution patterns of melanosomes in keratinocytes, the abilities of the actin-associated factors in charge of melanosome transport within melanocytes also regulate pigmentation. Mutations in genes encoding melanosome transport-related molecules, such as MYO5A, RAB27A and SLAC-2A, have been reported to cause a human pigmentary disease known as Griscelli syndrome, which is associated with diluted skin and hair color. Thus we hypothesized that process might play a role in modulating skin color variations. To address that hypothesis, the correlations of expression of RAB27A and its specific effector, SLAC2-A, to melanogenic ability were evaluated in comparison with tyrosinase, using human melanocytes derived from 19 individuals of varying skin types. Following the finding of the highest correlation in RAB27A expression to the melanogenic ability, darkly-pigmented melanocytes with significantly higher RAB27A expression were found to transfer significantly more melanosomes to keratinocytes than lightly-pigmented melanocytes in co-culture and in human skin substitutes (HSSs) in vivo, resulting in darker skin color in concert with the difference observed in African-descent and Caucasian skins. Additionally, RAB27A knockdown by a lentivirus-derived shRNA in melanocytes concomitantly demonstrated a significantly reduced number of transferred melanosomes to keratinocytes in co-culture and a significantly diminished epidermal melanin content skin color intensity (ΔL* = 4.4) in the HSSs. These data reveal the intrinsically essential role of RAB27A in human ethnic skin color determination and provide new insights for the fundamental understanding of regulatory mechanisms underlying skin pigmentation.     

Inhibition of melanosome transfer from melanocytes to keratinocytes by lectins and neoglycoproteins in an in vitro model system.

We propose that some of the critical molecules involved in the transfer of melanosomes from melanocytes to keratinocytes include plasma membrane lectins and their glycoconjugates. To investigate this mechanism, co-cultures of human melanocytes and keratinocytes derived from neonatal foreskins were established. The process of melanosome transfer was assessed by two experimental procedures. The first involved labeling melanocyte cultures with the fluorochrome CFDA. Labeled melanocytes were subsequently co-cultured with keratinocytes, and the transfer of fluorochrome assessed visually by confocal microscopy and quantitatively by flow cytometry. The second investigative approach involved co-culturing melanocytes with keratinocytes, and processing the co-cultures after 3 days for electron microscopy to quantitate the numbers of melanosomes in keratinocytes. Results from these experimental approaches indicate significant transfer of dye or melanosomes from melanocytes to keratinocytes that increased with time of co-culturing. Using these model systems, we subsequently tested a battery of lectins and neoglycoproteins for their effect in melanosome transfer. Addition of these selected molecules to co-cultures inhibited transfer of fluorochrome by approximately 15-44% as assessed by flow cytometry, and of melanosomes by 67-93% as assessed by electron microscopy. Therefore, our results suggest the roles of selected lectins and glycoproteins in melanosome transfer to keratinocytes in the skin.     

Excess tyrosine restores the morphology and maturation of melanosomes affected by the murine slaty mutation

The slaty (Dct(slt)) mutation is known to reduce the activity of dopachrome tautomerase in melanocytes and to reduce the melanin content in the skin, hairs, and eyes. The slaty gene is known to be important for maximizing melanin deposition in melanosomes. However, it was not known whether the slaty mutation affects the morphology of melanosomes. Moreover, it was unknown whether melanosome development is modulated by melanogenic factors. In this study, the characteristics of melanosomes of slaty melanocytes in serum-free primary culture were investigated in detail under the electron microscope. In slaty melanocytes, melanosome maturation was blocked at stage III, and numerous spherical melanosomes with globular depositions of pigment in addition to elliptical melanosomes were observed. L-tyrosine (Tyr), the starting material of melanin synthesis, is known to stimulate melanin synthesis. To clarify whether L-Tyr restores the reduced production of melanin, L-Tyr was added to the culture medium and tested for its melanogenic effect. L-Tyr greatly increased the number and percentage of mature stage IV melanosomes. Moreover, L-Tyr increased elliptical melanosomes, but decreased spherical melanosomes. These results suggest that the slaty mutation inhibits the development of elliptical stage IV melanosomes, and that L-Tyr restores the development of elliptical stage IV melanosomes. L-Tyr seems to restore both the morphology and maturation of melanosomes affected by the slaty mutation.     

Inhibition of Melanosome Transfer from Melanocytes to Keratinocytes by Lectins and Neoglycoproteins in an In Vitro Model System

We propose that some of the critical molecules involved in the transfer of melanosomes from melanocytes to keratinocytes include plasma membrane lectins and their glycoconjugates. To investigate this mechanism, co‐cultures of human melanocytes and keratinocytes derived from neonatal foreskins were established. The process of melanosome transfer was assessed by two experimental procedures. The first involved labeling melanocyte cultures with the fluorochrome CFDA. Labeled melanocytes were subsequently co‐cultured with keratinocytes, and the transfer of fluorochrome assessed visually by confocal microscopy and quantitatively by flow cytometry. The second investigative approach involved co‐culturing melanocytes with keratinocytes, and processing the co‐cultures after 3 days for electron microscopy to quantitate the numbers of melanosomes in keratinocytes. Results from these experimental approaches indicate significant transfer of dye or melanosomes from melanocytes to keratinocytes that increased with time of co‐culturing. Using these model systems, we subsequently tested a battery of lectins and neoglycoproteins for their effect in melanosome transfer. Addition of these selected molecules to co‐cultures inhibited transfer of fluorochrome by approximately 15–44% as assessed by flow cytometry, and of melanosomes by 67–93% as assessed by electron microscopy. Therefore, our results suggest the roles of selected lectins and glycoproteins in melanosome transfer to keratinocytes in the skin.     

Pyridinyl imidazole compounds interfere with melanosomes sorting through the inhibition of Cyclin G-associated Kinase,a regulator of cathepsins maturation

Transfer of melanin-containing melanosomes from melanocytes to neighboring keratinocytes results in skin pigmentation. Pharmacological modulation of melanosomal transfer has recently gained much attention as a strategy for modifying normal or abnormal pigmentation. In this study, while investigating the impact of pyridinyl imidazole (PI) compounds, a class of p38 MAPK inhibitors, on melanocyte differentiation we observed that some, but not all PIs interfere with the physiological melanosome sorting producing a strong retention of melanin in the intracellular compartment associated with a general reduction of melanin synthesis. Electron microscopy studies illustrated an accumulation of melanosomes inside melanocytes with enrichment in immature melanosome at stages II and III at the end of dendrites. We identified cyclin G-associated kinase GAK, a protein expressed ubiquitously in various tissues, as the off-target responsible of intracellular melanin accumulation and we report evidence that reduced GAK-dependent cathepsin maturation is implicated in melanosome sorting deficiency. The co-regulation of GAK and cathepsin B and L expression with the melanogenic biosynthetic pathway in normal human melanocytes as well as in B16-F0 melanoma cells strengthen the idea that these proteins represent new possible targets for prevention and treatment of irregular pigmentation.     

Melanosome maturation defect in Rab38-deficient retinal pigment epithelium results in instability of immature melanosomes during transient melanogenesis

Pathways of melanosome biogenesis in retinal pigment epithelial (RPE) cells have received less attention than those of skin melanocytes. Although the bulk of melanin synthesis in RPE cells occurs embryonically, it is not clear whether adult RPE cells continue to produce melanosomes. Here, we show that progression from pmel17-positive premelanosomes to tyrosinase-positive mature melanosomes in the RPE is largely complete before birth. Loss of functional Rab38 in the "chocolate" (cht) mouse causes dramatically reduced numbers of melanosomes in adult RPE, in contrast to the mild phenotype previously shown in skin melanocytes. Choroidal melanocytes in cht mice also have reduced melanosome numbers, but a continuing low level of melanosome biogenesis gradually overcomes the defect, unlike in the RPE. Partial compensation by Rab32 that occurs in skin melanocytes is less effective in the RPE, presumably because of the short time window for melanosome biogenesis. In cht RPE, premelanosomes form but delivery of tyrosinase is impaired. Premelanosomes that fail to deposit melanin are unstable in both cht and tyrosinase-deficient RPE. Together with the high levels of cathepsin D in immature melanosomes of the RPE, our results suggest that melanin deposition may protect the maturing melanosome from the activity of lumenal acid hydrolases.     

The exocyst is required for melanin exocytosis from melanocytes and transfer to keratinocytes

Skin pigmentation involves the production of the pigment melanin by melanocytes, in melanosomes and subsequent transfer to keratinocytes. Within keratinocytes, melanin polarizes to the apical perinuclear region to form a protective cap, shielding the DNA from ultraviolet radiation‐induced damage. Previously, we found evidence to support the exocytosis by melanocytes of the melanin core, termed melanocore, followed by endo/phagocytosis by keratinocytes as a main form of transfer, with Rab11b playing a key role in the process. Here, we report the requirement for the exocyst tethering complex in melanocore exocytosis and transfer to keratinocytes. We observed that the silencing of the exocyst subunits Sec8 or Exo70 impairs melanocore exocytosis from melanocytes, without affecting melanin synthesis. Moreover, we confirmed by immunoprecipitation that Rab11b interacts with Sec8 in melanocytes. Furthermore, we found that the silencing of Sec8 or Exo70 in melanocytes impairs melanin transfer to keratinocytes. These results support our model as melanocore exocytosis from melanocytes is essential for melanin transfer to keratinocytes and skin pigmentation and suggest that the role of Rab11b in melanocore exocytosis is mediated by the exocyst.     

Melanocyte-keratinocyte interaction induces calcium signalling and melanin transfer to keratinocytes

Physical contact between melanocytes and keratinocytes is a prerequisite for melanosome transfer to occur, but cellular signals induced during or after contact are not fully understood. Herein, it is shown that interactions between melanocyte and keratinocyte plasma membranes induced a transient intracellular calcium signal in keratinocytes that was required for pigment transfer. This intracellular calcium signal occurred due to release of calcium from intracellular stores. Pigment transfer observed in melanocyte-keratinocyte co-cultures was inhibited when intracellular calcium in keratinocytes was chelated. We propose that a 'ligand-receptor' type interaction exists between melanocytes and keratinocytes that triggers intracellular calcium signalling in keratinocytes and mediates melanin transfer.     

Melanosomal dynamics assessed with a live-cell fluorescent melanosomal marker

Melanocytes present in skin and other organs synthesize and store melanin pigment within membrane-delimited organelles called melanosomes. Exposure of human skin to ultraviolet radiation (UV) stimulates melanin production in melanosomes, followed by transfer of melanosomes from melanocytes to neighboring keratinocytes. Melanosomal function is critical for protecting skin against UV radiation, but the mechanisms underlying melanosomal movement and transfer are not well understood. Here we report a novel fluorescent melanosomal marker, which we used to measure real-time melanosomal dynamics in live human epidermal melanocytes (HEMs) and transfer in melanocyte-keratinocyte co-cultures. A fluorescent fusion protein of Ocular Albinism 1 (OA1) localized to melanosomes in both B16-F1 cells and HEMs, and its expression did not significantly alter melanosomal distribution. Live-cell tracking of OA1-GFP-tagged melanosomes revealed a bimodal kinetic profile, with melanosomes exhibiting combinations of slow and fast movement. We also found that exposure to UV radiation increased the fraction of melanosomes exhibiting fast versus slow movement. In addition, using OA1-GFP in live co-cultures, we monitored melanosomal transfer using time-lapse microscopy. These results highlight OA1-GFP as a specific and effective melanosomal marker for live-cell studies, reveal new aspects of melanosomal dynamics and transfer, and are relevant to understanding the skin's physiological response to UV radiation.     

Functional analysis of Slac2-c/MyRIP as a linker protein between melanosomes and myosin VIIa

Slac2-c/MyRIP, an in vitro Rab27A- and myosin Va/VIIa-binding protein, has recently been proposed to regulate retinal melanosome transport in retinal pigment epithelium cells by directly linking melanosome-bound Rab27A and myosin VIIa; however, the exact function of Slac2-c in melanosome transport has never been clarified. In this study, we used melanosome transport in skin melanocytes as a model for retinal melanosome transport and analyzed the in vivo function of Slac2-c in melanosome transport by the ectopic expression of Slac2-c, together with myosin VIIa, in Slac2-a-depleted melanocytes. In vitro binding experiments revealed that myosin VIIa had a greater affinity for Slac2-c, compared with the binding affinity of myosin Va, and that the myosin VIIa-binding domain of Slac2-c is different from the previously characterized myosin Va-binding domain that is conserved between Slac2-a/melanophilin and Slac2-c. Consistent with this result, cyan fluorescent protein-tagged Slac2-c expressed in melanocytes was localized on melanosomes via the specific interaction with Rab27A and recruited co-expressed yellow fluorescent protein-tagged myosin VIIa to the melanosomes without interfering with the normal peripheral melanosome distribution, whereas when myosin VIIa alone was expressed in melanocytes, it was not localized on the melanosomes. Moreover, Slac2-c ectopically expressed in melanocytes did not rescue the perinuclear aggregation phenotype induced by the knockdown of endogenous Slac2-a with a specific small interfering RNA, whereas the expression of the Slac2-c x myosin VIIa complex supported the normal melanosome distribution in Slac2-a-depleted melanocytes, indicating that Slac2-c functions as a myosin VIIa receptor rather than a myosin Va receptor in melanosome transport. Based on these findings, we propose that Slac2-c acts as a functional myosin VIIa receptor and that the Rab27A.Slac2-c x myosin VIIa tripartite protein complex regulates the transport of retinal melanosomes in pigment epithelium cells.     

Melanocyte–keratinocyte interaction induces calcium signalling and melanin transfer to keratinocytes

Physical contact between melanocytes and keratinocytes is a prerequisite for melanosome transfer to occur, but cellular signals induced during or after contact are not fully understood. Herein, it is shown that interactions between melanocyte and keratinocyte plasma membranes induced a transient intracellular calcium signal in keratinocytes that was required for pigment transfer. This intracellular calcium signal occurred due to release of calcium from intracellular stores. Pigment transfer observed in melanocyte–keratinocyte co‐cultures was inhibited when intracellular calcium in keratinocytes was chelated. We propose that a ‘ligand‐receptor’ type interaction exists between melanocytes and keratinocytes that triggers intracellular calcium signalling in keratinocytes and mediates melanin transfer.     

How are proliferation and differentiation of melanocytes regulated?

Coat colors are determined by melanin (eumelanin and pheomelanin). Melanin is synthesized in melanocytes and accumulates in special organelles, melanosomes, which upon maturation are transferred to keratinocytes. Melanocytes differentiate from undifferentiated precursors, called melanoblasts, which are derived from neural crest cells. Melanoblast/melanocyte proliferation and differentiation are regulated by the tissue environment, especially by keratinocytes, which synthesize endothelins, steel factor, hepatocyte growth factor, leukemia inhibitory factor and granulocyte-macrophage colony-stimulating factor. Melanocyte differentiation is also stimulated by alpha-melanocyte stimulating hormone; in the mouse, however, this hormone is likely carried through the bloodstream and not produced locally in the skin. Melanoblast migration, proliferation and differentiation are also regulated by many coat color genes otherwise known for their ability to regulate melanosome formation and maturation, pigment type switching and melanosome distribution and transfer. Thus, melanocyte proliferation and differentiation are not only regulated by genes encoding typical growth factors and their receptors but also by genes classically known for their role in pigment formation.     

Regulation of Melanogenesis in Melanocytes

Melanogenesis refers to the biosynthesis of melanin pigment in pigment cells called melanocytes. Melanins are mixed biopolymers formed during a series of oxidation/reduction reactions that are initiated by the enzymatic hydroxylation of L-tyrosine to L-dopa. In living cells, melanogenesis is limited to melanosomes, the membrane bounded microscopic secretory granules of melanocytes. Melanosomes may be secreted into the environment as, for example, from the squid's ink gland; or be transferred to neighboring cells, such as the keratinocytes in human skin and hair; or they may remain within the pigment cell and change only their subcellular localization, as in the rapidly color-changing dermis of lower vertebrates. Regulation of the melanocytic phenotype involves synthesis of the biosynthetically active subcellular apparatus of melanogenesis, premelanosomes and tyrosinase, and the utilization of the final product, melanized melanosomes, in the translocation and secretory processes mentioned above. Genetic information for this regulation is stored in the nuclear genome whose expression is controlled by the intra- and extracellular environment. As premelanosomes become biosynthetically active, they mature into melanosomes by fusing with vesicles derived from the trans-Golgi network and the plasmalemma, thereby internalizing and incorporating contents and membrane components from inside the cell and the cell surface. In the process, melanosomes become acidified. The thesis pursued in this review explores the importance of the melanosome as the final common pathway of regulation of melanin biosynthesis.     

C32 human melanoma cell endogenous lectins: characterization and implication in vesicle-mediated melanin transfer to keratinocytes.

To optimize skin pigmentation in order to help body prevention against UV radiation, the mechanism of melanin pigment transfer from melanocytes to keratinocytes must be elucidated. Melanin transfer to keratinocytes requires specific recognition between keratinocytes and melanocytes or melanosomes. Cell surface sugar-specific receptor (membrane lectin) expression was studied in human C32 melanoma cells, an amelanotic melanoma, by flow cytometry analysis of neoglycoprotein binding as an approach to the molecular specificity. Sugar receptors on melanocytes are mainly specific for alpha-L-fucose. Their expression is enhanced upon treatment by the diacylglycerol analogue 1-oleoyl-2-acetylglycerol, which can induce melanin synthesis in amelanotic human melanoma cells in a dose-dependent manner. Flow cytometry analyses showed a small-sized population of vesicles distinguishable from large cells by their fluorescence properties upon neoglycoprotein binding. Sorting indicated that the small-sized subpopulation is composed of vesicles produced by melanocytic cells. Upon vesicle formation, a selective concentration of sugar receptors specific for 6-phospho-beta-D-galactosides appears in the resulting melanocytic vesicles. Vesicles are recognized and taken up by cultured keratinocytes and a partial inhibitory effect was obtained upon cell incubation in the presence of neoglycoproteins, indicating a possible participation of sugar receptors in this recognition. The validity for such a model to help in understanding the natural melanin transfer by melanosomes is confirmed by electron microscopy, which demonstrates the presence of melanin inside keratinocytic cells upon incubation with melanocytic vesicles.