Tyrosinase positive oculocutaneous albinism among the Zuni and the Brandywine triracial isolate: biochemical and clinical characteristics and fertility

Zuni albinos develop increased pigmentation in hair and eyes, and decreased nystagmus and photophobia with age. Hair bulbs cultured in l-tyrosine produced pigment. Ultrastructure of melanocytes demonstrated a predominance of Stage II and early Stage III premelanosomes that readily converted to mature Stage IV melanosomes after incubation in 1-tyrosine. Eleven obligate heterozygotes failed to demonstrate diaphanous irides. Data on the fertility of Zuni and Brandywine male albinos did not indicate that they had more offspring than pigmented males. As the physical features of this form of albinism overlap those of many normal Caucasians, it is probably not a particularly deleterious trait with high selective value under the recent conditions of Zuni life.     

Ultrastructural change of melanosomes associated with agouti pattern formation in mouse hair.

We have studied the structural alteration of melanosomes in the melanocytes of agouti mice whose genetic characteristic is to produce eumelanin and phaeomelanin alternately in a single hair bulb. Melanocytes of hair bulbs from 1 to 2 day old mice of the black phase were observed to contain rod-shaped melanosomes of the eumelanin type (eumelanosome). In the melanocytes of the hair bulbs from 4 to 6-day old skin, which exclusively contain phaeomelanin, spherical melanosomes (phaeomelanosomes) were seen. On the other hand, the mice of the transitional phase from black to yellow possessed melanocytes that contained both eumelanosomes and phaeomelanosomes within a single cell. This result indicates that the shift from the eumelanin formation to the phaeomelanin formation or vice versa in agouti hair occurs within a single melanocyte.We observed multivesicular bodies in both the agouti melanocytes of the yellow phase and the genotypically yellow melanocytes. These bodies are considered to be the precursor of the phaeomelanin-containing melanosome. They are sometimes observed to have continuity with E. R. suggesting that the melanosomes are derived from E. R. in the phaeomelanin-forming melanocytes.     

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.     

Growth and maturation of melanosomes in the melanophores of a teleost,Oryzias latipes

Summary Formation of melanosomes in melanophores of a teleost, Oryzias latipes, was studied by means of electron microscopy. Two distinct types of premelanosomes are observed in the same cell: (i) multivesicular premelanosomes, which later develop into melanosomes with electron-lucent hollows in the center, appear at early embryonic stages; (ii) premelanosomes with highly organized, fibrous internal structure are formed at later stages of development and give rise to melanosomes with a filamentous center. Melanosomes are generally ellipsoid in shape, and the difference in the dimensions of fibrillar premelanosomes, melanosomes in the cells at younger developmental stages and those developed fully in melanophores of adults indicates that these organelles grow during development. The growth is achieved by fusion of small unmelanized vesicles or fibrillar premelanosomes to preformed melanosome and by fusion of two or more premelanosomes to form a larger organelle. The addition of the matrix of fibrillar premelanosomes around preformed melanosomes, which are derived from either multivesicular or fibrillar premelanosomes, forms a concentric outer deposit, and the fusion of small vesicles produces electron-lucent pits which are scattered irregularly in mature melanosomes.     

Development of amelanotic retinal pigment epithelium in eyes with a tapetum lacidum: melanosome autophagy and termination of melanogenesis

Bovine eyes of embryos and fetuses were examined to determine the developmental processes involved in establishment of the amelanotic retinal pigment epithelium (RPE) which overlies the tapetum lucidum. Melanogenesis was detectable at the optic vesicle stage (Day 28); premelanosomes were visible by electron microscopy in neuroepithelium temporal to the lens placode. Pigmentation of the eye was visible by light microscopy at the optic cup stage (about Day 30) and spread from the lip of the optic cup throughout the entire fundus by the 40th day. Thereafter, pigmentation of the superior temporal fundus diminished and by the 65th day the adult pattern of amelanotic and melanotic RPE was established. Calculations showed that after the 40th day, growth of the eyeball brought about a 16-fold dilution of those melanosomes which had been synthesized by RPE cells of the presumptive amelanotic zone during the initial wave of pigmentation. Enzyme cytochemical studies showed that the remaining melanosomes became sequestered in autophagic vacuoles. Also, individual premelanosomes of these RPE cells became positive for acid phosphatase and aryl sulfatase. The contents of these autophagosomes were later consolidated into a single macromelanosome which was present in adult eyes and was generally positive for acid hydrolases. In contrast, melanosomes of melanotic areas of RPE were negative for acid hydrolases. Thus, the RPE overlying the tapetum lucidum becomes amelanotic by at least three processes: (1) premature termination of melanogenesis, (2) dilution of preexisting melanosomes, and (3) autophagic digestion (melanolysis) and centralization of the residua of preexisting premelanosomes and melanosomes into a macromelanosome.     

Stereological Studies of the Effects of α-MSH and cAMP on Melanosomes in Melanoma Cells

The effects of α-MSH and cAMP on melanosomes in Cloudman S91 melanoma cells were investigated by modern stereological techniques. Cells were cultured for 4 days in medium containing α-MSH or cAMP harvested at 24 hour intervals; some were frozen for melanin assay and the reminder embedded in Epon for light and electron microscopy. Cellular and melanosomal parameters were estimated by new stereological probes. We found that both stimulators induced increases in nuclear volume, cell volume, and the volume fractions and volumes of premelanosomes (V_Vpm,cell’V_pm) and mature melanosomes (V_Vmm,cell’V_mm) and the number of mature melanosomes (N_mm). Both stimulators also caused declines in the volume of individual mature melanosomes (_Vimm) the melanin content per mature melanosome unit volume and the melanin content per individual mature melanosome. The increases in the volume of individual premelanosomes and the number of premelanosomes were only induced by cAME The effect cAMP on some parameters occurred 24 hours prior to α-MSH and was more marked. The response of premelanosomes to the stimulators was more sensitive than mature melanosomes. These results suggest that both stimulators enchanced melanogenesis by increasing the V_Vpm,cell’V_Vmm,cell’V_pm, V_mm and N_mm. The melanogenic level did not depend on the _Vimm and melanin concentration in melanosomes. The maturation of premelanosomes was involved in melanogenesis induced by both stimulators, but, de novo synthesis and enlargement of premelanosomes were only stimulated by cAME It imply that exogenous cAMP may affect melanosomes, and hence melanogenesis in quantitatively or qualitatively different ways to α-MSH.     

Melanosomal Proteins – Role in Melanin Polymerization

Melanin, the major determinant of skin colour, is a tyrosine‐based heteropolymer of indeterminate molecular weight. In vivo, melanin synthesis occurs within highly specialized organelles called melanosomes. Coated vesicles encapsulating the enzyme tyrosinase and tyrosinase related proteins, fuse with premelanosomes that contain structural proteins to form mature melanosomes. Coated vesicles and premelanosomes have been shown to have only melanin monomers but not the polymer. Our earlier results have clearly shown that the presence of proteins other than tyrosinase are critical for the post‐tyrosinase steps of melanin polymerization at acidic pH. Proteins in melanosomes are difficult to purify because of their firm association with melanin. Thus, with progressive melanization, melanoproteins become progressively insoluble. In this paper, we discuss the isolation and purification of melanosomal proteins and their role in melanin polymerization. We have hypothesized that the initiation of polymerization and the binding of melanin to proteins are two discrete events and we have developed assays to quantify these events. Purified melanosomal proteins differ in their ability to polymerize melanin monomers. Further, we have also shown that two polypeptides (28 and 45 kDa) purified from melanosomes inhibit melanin polymerization but can bind preformed melanin. In conclusion, melanosomal proteins regulate melanin polymerization and differ in their ability to bind melanin. Polymerization and binding abilities of melanosomal proteins are specific to each protein and melanin–protein interaction is not nonspecific.     

Inhibition of melanosome transformation in embryonic chick pigment retina cultured in vitro.

When the retinal pigment epithelial cells of the chick embryo are transferred to monolayer cultures, they lose their phenotypic trait-- melanin granules-- after a few days. Within the first 24 hours almost all of the melanosomes and premelanosomes are transformed into the degradative structures of the dense bodies or the melanosome complexes. Then, within a few days, these structures disappear completely from the cytoplasm. Actinomycin D, added to the culture medium during the first four hours, almost completely prevents the transformation of melanosomes and premelanosomes. The inhibition of cell proliferation, caused by the addition of colcemid, does not prevent the transformation, though the time of initiation of transformation is delayed considerably. The mechanisms of the transformation of pigment granules are discussed.     

Melanosomal proteins--role in melanin polymerization

Melanin, the major determinant of skin colour, is a tyrosine-based heteropolymer of indeterminate molecular weight. In vivo, melanin synthesis occurs within highly specialized organelles called melanosomes. Coated vesicles encapsulating the enzyme tyrosinase and tyrosinase related proteins, fuse with premelanosomes that contain structural proteins to form mature melanosomes. Coated vesicles and premelanosomes have been shown to have only melanin monomers but not the polymer. Our earlier results have clearly shown that the presence of proteins other than tyrosinase are critical for the post-tyrosinase steps of melanin polymerization at acidic pH. Proteins in melanosomes are difficult to purify because of their firm association with melanin. Thus, with progressive melanization, melanoproteins become progressively insoluble. In this paper, we discuss the isolation and purification of melanosomal proteins and their role in melanin polymerization. We have hypothesized that the initiation of polymerization and the binding of melanin to proteins are two discrete events and we have developed assays to quantify these events. Purified melanosomal proteins differ in their ability to polymerize melanin monomers. Further, we have also shown that two polypeptides (28 and 45 kDa) purified from melanosomes inhibit melanin polymerization but can bind preformed melanin. In conclusion, melanosomal proteins regulate melanin polymerization and differ in their ability to bind melanin. Polymerization and binding abilities of melanosomal proteins are specific to each protein and melanin-protein interaction is not nonspecific.     

Melanogenesis in amphibians

Summary The pigmented epithelium of Rana pipiens tadpole eyes normally develops at least two types of melanosomes: (1) an elongated melanin granule of relatively homogeneous electron density, and (2) a complex melanosome which has an outer electrondense area and one or more less dense cores. Evidence indicates that complex melanosomes are formed by new melanin enclosing preexisting melanosomes. An organized fibrillar premelanosome is demonstrated with the aid of the antimelanogenic compound phenylthiourea (PTU). These premelanosomes are the developing forms of the elongated melanosomes. There is evidence that the premelanosomes originate in the smooth endoplasmic reticulum. Phenylthiourea blocks melanin synthesis in the premelanosomes; however, removal of the PTU allows pigment deposition. This finding of an organized, fibrillar premelanosome in an amphibian marks the lowest phylogenetic group in which these organelles have been described.An Oak Ridge Graduate Fellow from Catholic University of America, Washington, D.C., under appointment from Oak Ridge Associated Universities.The MAN Program is supported by the National Cancer Institute, the National Institute of General Medical Sciences, the National Institute of Allergy and Infectious Diseases, and the U.S. Atomic Energy Commission.Oak Ridge National Laboratory is operated by Union Carbide Corporation Nuclear Division for the U.S. Atomic Energy Commission.     

Melanosome metabolism in the retinal pigmented epithelium of the opossum

Summary Melanosomal metabolism, including both formation and degradation of melanosomes, was studied in the retinal pigmented epithelium (RPE) of the adult opossum. The majority of the observations were made on a transitional zone between the tapetal and non-tapetal RPE, the region where melanosome metabolism was at its highest level. Formation of melanosomes, demonstrated ultrastructurally by the presence of stage-II and -III premelanosomes, was also examined autoradiographically following the incorporation of the melanin precursor, dihydroxyphenylalanine. The autoradiographic evidence indicated that many newly formed melanosomes were rapidly incorporated into complexes. Ultrastructural observations suggested that melanosome complexes were formed by at least two methods, via the fusion of melanosomes with phagosomes derived from outer segments of photoreceptors, or by the sequestration of melanosomes by cisternae. A central finding of this study, supported by both ultrastructural and histochemical data, is that there are specialized cellular regions that vary in melanosomal formation and lysosomal activity. Stage-II premelanosomes were observed only in the basal parts of the RPE cells, whereas stage-III and -IV melanosomes were found primarily in the apical RPE. Both ultrastructural and cytochemical observations indicated that degradation of melanosomes occurs only in the basal RPE. These findings are interpreted in terms of the expression of both tapetal and nontapetal characteristics in transitional cells. Finally, this study illustrates the role of lysosomal enzymes in shaping the pattern of pigmentation, and shows that the association of lysosomal activity with melanosomes depends on the functional state of the melanosome.This investigation was supported by National Institutes of Health research grant EY 01429 and, in part, by a Bob Hope award from Fight for Sight, Inc., New York City (to R.H. Steinberg), and a Fight for Sight, Inc. Summer Fellowship to K.G. Herman     

On the formation and degradation of melanosomes in smooth muscle cells: electron microscopic investigation on the m. sphincter pupillae of the rat

The electron microscopic investigation of the m. sphincter pupillae of adult black hooded rats showed the presence of melanosomes in the smooth muscle cells. In shape and size the melanosomes were like those of the iridial epithelium. In addition, premelanosomes and tyrosinase activity were observed as well as melanosomes with disintegrated content and acid phosphatase activity. The data suggest that the smooth muscle cells of the m. sphincter pupillae are capable of the formation and degradation of melanosomes.     

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.     

Distinct protein sorting and localization to premelanosomes, melanosomes, and lysosomes in pigmented melanocytic cells

Melanosomes and premelanosomes are lysosome-related organelles with a unique structure and cohort of resident proteins. We have positioned these organelles relative to endosomes and lysosomes in pigmented melanoma cells and melanocytes. Melanosome resident proteins Pmel17 and TRP1 localized to separate vesicular structures that were distinct from those enriched in lysosomal proteins. In immunogold-labeled ultrathin cryosections, Pmel17 was most enriched along the intralumenal striations of premelanosomes. Increased pigmentation was accompanied by a decrease in Pmel17 and by an increase in TRP1 in the limiting membrane. Both proteins were largely excluded from lysosomal compartments enriched in LAMP1 and cathepsin D. By kinetic analysis of fluid phase uptake and immunogold labeling, premelanosomal proteins segregated from endocytic markers within an unusual endosomal compartment. This compartment contained Pmel17, was accessed by BSA-gold after 15 min, was acidic, and displayed a cytoplasmic planar coat that contained clathrin. Our results indicate that premelanosomes and melanosomes represent a distinct lineage of organelles, separable from conventional endosomes and lysosomes within pigmented cells. Furthermore, they implicate an unusual clathrin-coated endosomal compartment as a site from which proteins destined for premelanosomes and lysosomes are sorted.     

The hair melanosome: another tissue reservoir of zinc.

Melanosomes were isolated from human and dog hairs and their Zn content was determined. The mean Zn concentrations, in mug Zn/g dry weight, were 687 (men's melanosomes), 641 (women's melanosomes) and 691 (dog melanosomes). These values rank melanosomes from pigmented keratinous structures among the structural elements with the highest Zn content. An interpretation of the possible causes of this accumulation was submitted. By means of the conversion factor between hair length and weight (determined at 0.004), it was estimated that daily Zn lossess via hair vary in the region of 19 mug. In detailed studies of Zn metabolism, excretion via pigmented keratinous structures ought not to be neglected.     

Ultrastructure of the integumental melanophores of the Australian lungfish,Neoceratodus forsteri

The integumental melanophores of Australina lungfish, Neoceratodus forsteri, were examined by light and electron microscopy and found to possess essentially the same structural characteristics observed in other vertebrates. The epidermal melanophores are located in the intermediate epidermis and possess round perikarya and slender dendrites extending into nearby intercellular spaces. The dermal melanophores are found immediately below the basement membrane as well as in the deeper dermis. These cells possess flattened nuclei and dendrites running parallel to the basement membrane. Each melanophore contains numerous oval or elliptical, intensely electron-dense melanosomes, relatively large mitochondria, systems of vacuolar endoplasmic reticulum, groups of free RNP particles, and some microfilaments. Only a few, short microtubules could be demonstrated in the perinuclear cytoplasm of the dermal melanophore, while a relatively large number of late premelanosomes are found both in perikarya and dendritic processes of epidermal melanophores. These premelanosomes exhibit a particulate internal structure in cross section. Both melanosomes and premelanosomes occur singly in the cytoplasm of epidermal cells, thereby confirming the existence of the epidermal melanin unit in the lowest vertebrates thus far examined electron microscopically.     

Biogenesis of melanosomes in Kupffer cells of Proteus anguinus (Urodela,Amphibia)

The ultrastructural characteristics of melanosomes and premelanosomes observed during the biogenesis of melanosomes in liver pigment cells of the neotenic cave salamander Proteus anguinus (Proteidae) are described. It is well known that amphibian liver pigment cells, also known as Kupffer cells (KC), contain melanosomes and are able to synthesize melanin. Liver pigment cells of P. anguinus contain numerous siderosomes and melanosomes. The melanosomes are grouped together within single-membrane-bounded bodies, named as 'clusters of melanosomes' or 'melanosomogenesis centers'. Inside such clusters, different structures are present: (1) filament-like structures, characteristic of the initial stage of melanosome biogenesis, (2) medium electron-dense melanosomes in different stages of melanization, (3) melanosomes with an electron-dense cortical area and a less electron-dense medullar area, and (4) uniformly highly electron-dense mature melanosomes or melanin granules. Histochemical and cytochemical dihydroxyphenylalanine (DOPA) oxidase reactions in pigment cells were positive. Our results confirm the ability of amphibian KC to synthesize melanin and contribute to this little known subject.     

The Amphibian Kupffer Cells Build and Demolish Melanosomes: An Ultrastructural Point of View

This ultrastructural research was carried out to investigate the nature of the liver pigment cells of anuran and caudate amphibians, the pattern of melanosome ontogenesis, and the demolition processes of old melanosomes. We demonstrate that these liver pigment cells are able to internalize zymosan particles and latex beads; therefore, being professional phagocytes, they, as liver resident macrophages, can be classified as Kupffer cells (KCs). They show “melanosomogenesis centers” in which several maturation stages of premelanosomes are visible; the premelanosomes are formed by two principal components: a filamentous structure that will constitute the “inner” area of the melanosome and a vesicular component, budding from the Trans Golgi Network and that carries enzymes, which will constitute the “cortical area” of the melanosome. Thus the KCs, thanks to the presence of the “melanosomogenesis centers,” are also melanosome producing cells. They are also able to demolish melanosomes by heterophagocytosis and, probably, also by autophagocytosis. In conclusion, we propose a classification of vertebrate pigment cells.     

Morphological changes in hair melanosomes by aging

Various changes appear in hair by aging, and graying is the most remarkable one. Changes in melanocytes have been well studied as the cause; however, little is known about the change in melanosomes which have a role of carrying melanin pigments into hair shafts. Using pigmented hairs of Japanese females from their age of 4–75, I isolated melanosomes and observed them. As a result, I found a significant change in the morphology of hair melanosomes with age. They were ellipsoidal on the whole and there was no age dependence in the major axis, while the minor axis significantly increased and its frequency distribution broadened with age. The anticipated volume of the melanosome of the oldest person hairs was about twice larger than that of child hairs. This enlargement of melanosome seems to be a cause of the age‐related color change in pigmented hairs from brown to black.     

The human vocal cord surface

Summary The effect of phenylthiourea (PTU) on the pigment epithelium and the photoreceptor cells in the developing retina of Haplochromis burtoni was studied by electron microscopy. In the retinal pigment epithelium of 6-day old embryos, both types of melanin granule (spindle-shaped and rod-shaped) are already found. PTU inhibits the biosynthesis of melanin but does not influence the formation of premelanosomes so that in PTU-treated embryos there are no melanosomes, but an abundance of premelanosomes. The structure of the premelanosomes is described. It differs completely from that of all other vertebrates. Other changes: an increase in polysomes, retarded development of the inner segment of the photoreceptor cells and enlargement of the intercellular space between the inner and outer leaflet of the retina, may be due to a toxic effect of PTU.This investigation was supported by grants of the Deutsche Forschungsgemeinschaft