Fine Structure of Melanogenesis in the Ink Sac of Sepia offidnalis

The ink sac epithelium of the cuttlefish Sepia officinalis was investigated by electron microscopy. Melanogenesis in a simplified view seems to follow the general scheme of melanin formation in vertebrates. First, a membrane-bound protein matrix is formed, which is called an early stage melanosome. The early stage melanosomes are more or less irregular in shape with a size up to 1.5 μm and contain membranous, granular, or vesicular material. They seem to originate from Golgi bodies and/or endoplasmic reticulum. Membranes that frequently are present in the early stage melanosomes may originate from fusion of vesicles or from incorporation of Golgi membranes into early stage melanosomes. Free cytoplasmic material or mitochondria probably are also incorporated into the early stage melanosomes or melanosomes. Therefore, the origin of the early stage melanosomes seems to be similar to that of autophagosomes. The early stage melanosomes mature to melanosomes in which several dozen melanin granules are formed. These melanosomes, at last, release the melanin granules together with other cellular material, including early stage melanosomes, into the lumen of the ink gland. This finding confirms the earlier postulated holocrine character of the release. Active tyrosinase was localized in the lumen of the ink sac as already shown by biochemical methods. There was also additional evidence that most of the material of broken down cells inside the lumen of the ink sac seems to be converted into melanin granules.     

ELECTRON MICROSCOPIC DEMONSTRATION OF TYROSINASE IN PTERINOSOMES OF THE FROG XANTHOPHORE,AND THE ORIGIN OF PTERINOSOMES*

In the frog, Rana japonica, the successive appearance of types I, II and III pterinosomes, which were defined according to the degree of lamellar structure, is in keeping with the xanthophore differentiation at the larval stage, but these three types coexist in a single xanthophore in the adult. An intense tyrosinase reaction was found in type I–II intermediate form in the larval and adult xanthophores, but it was rarely observed in types I and III. A tyrosinase reaction was always found in the GERL (Golgi-associated Endoplasmic Reticulum) of larval and adult xanthophores, and it was similarly evident in small Golgi vesicles which were separated from the GERL and dispersed in the cytoplasm. The above findings suggest that tyrosinase and pterinosome originate from different parts of the cytoplasm. The hypothesis that small Golgi vesicles are transported to the tyrosinase-negative premelanosomes involved in the origin of the melanosome is also applicable to the origin of pterinosomes.     

Assembly, target-signaling and intracellular transport of tyrosinase gene family proteins in the initial stage of melanosome biogenesis

Assembly, target-signaling and transport of tyrosinase gene family proteins at the initial stage of melanosome biogenesis are reviewed based on our own discoveries. Melanosome biogenesis involves four stages of maturation with distinct morphological and biochemical characteristics that reflect distinct processes of the biosynthesis of structural and enzymatic proteins, subsequent structural organization and melanin deposition occurring in these particular cellular compartments. The melanosomes share many common biological properties with the lysosomes. The stage I melanosomes appear to be linked to the late endosomes. Most of melanosomal proteins are glycoproteins that should be folded or assembled correctly in the ER through interaction with calnexin, a chaperone associated with melanogenesis. These melanosomal glycoproteins are then accumulated in the trans Golgi network (TGN) and transported to the melanosomal compartment. During the formation of transport vesicles, coat proteins assemble on the cytoplasmic face of TGN to select their cargos by interacting directly or indirectly with melanosomal glycoproteins to be transported. Adapter protein-3 (AP-3) is important for intracellular transport of tyrosinase gene family proteins from TGN to melanosomes. Tyrosinase gene family proteins possess a di-leucine motif in their cytoplasmic tail, to which AP-3 appears to bind. Thus, the initial cascade of melanosome biogenesis is regulated by several factors including: 1) glycosylation of tyrosinase gene family proteins and their correct folding and assembly within ER and Golgi, and 2) supply of specific signals necessary for intracellular transport of these glycoproteins by vesicles from Golgi to melanosomes.     

Assembly,Target‐Signaling and Intracellular Transport of Tyrosinase Gene Family Proteins in the Initial Stage of Melanosome Biogenesis

Assembly, target‐signaling and transport of tyrosinase gene family proteins at the initial stage of melanosome biogenesis are reviewed based on our own discoveries. Melanosome biogenesis involves four stages of maturation with distinct morphological and biochemical characteristics that reflect distinct processes of the biosynthesis of structural and enzymatic proteins, subsequent structural organization and melanin deposition occurring in these particular cellular compartments. The melanosomes share many common biological properties with the lysosomes. The stage I melanosomes appear to be linked to the late endosomes. Most of melanosomal proteins are glycoproteins that should be folded or assembled correctly in the ER through interaction with calnexin, a chaperone associated with melanogenesis. These melanosomal glycoproteins are then accumulated in the trans Golgi network (TGN) and transported to the melanosomal compartment. During the formation of transport vesicles, coat proteins assemble on the cytoplasmic face of TGN to select their cargos by interacting directly or indirectly with melanosomal glycoproteins to be transported. Adapter protein‐3 (AP‐3) is important for intracellular transport of tyrosinase gene family proteins from TGN to melanosomes. Tyrosinase gene family proteins possess a di‐leucine motif in their cytoplasmic tail, to which AP‐3 appears to bind. Thus, the initial cascade of melanosome biogenesis is regulated by several factors including: 1) glycosylation of tyrosinase gene family proteins and their correct folding and assembly within ER and Golgi, and 2) supply of specific signals necessary for intracellular transport of these glycoproteins by vesicles from Golgi to melanosomes.     

The melanocytic protein Melan-A/MART-1 has a subcellular localization distinct from typical melanosomal proteins

To delineate the role of the melanocyte lineage-specific protein Melan-A/MART-1 in melanogenic functions, a set of biochemical and microscopical studies was performed. Biochemical analysis revealed that Melan-A/MART-1 is post-translationally acylated and undergoes a rapid turnover in a pigmented melanoma cell line. Immunofluorescence and immunoelectron microscopy analyses indicated that Melan-A/MART-1 is mainly located in the Golgi area and only partially colocalizes with melanosomal proteins. Quantitative immunoelectron microscopy showed that the highest proportion of the cellular content of Melan-A/MART-1 was found in small vesicles and tubules throughout the cell, whereas the concentration was maximal in the Golgi region, particularly the trans-Golgi network. Substantial labeling was also present on melanosomes, endosomes, ER, nuclear envelope, and plasma membrane. In early endosomes, Melan-A was enriched in areas of the limiting membrane covered by a bi-layered coat, a structural characteristic of melanosomal precursor compartments. Upon melanosome maturation, Melan-A concentration decreased and its predominant localization shifted from the limiting membrane to internal vesicle membranes. In conjunction with its acylation, the high expression levels of Melan-A in the trans-Golgi network, in dispersed vesicles, and on the limiting membrane of premelanosomes indicate that the protein may play a role during the early stage of melanosome biogenesis.     

ON THE POSSIBLE FUNCTION OF COATED VESICLES IN MELANOGENESIS OF THE REGENERATING FOWL FEATHER

How tyrosinase becomes associated with the premelanosomes was investigated by histochemical demonstration of tyrosinase activity by the use of dihydroxyphenylalanine (DOPA) in melanocytes of regenerating fowl feathers. The reaction product of DOPA was localized in the anastomosing membrane tubules associated with the concave side of some dictyosomes of the Golgi apparatus and in coated vesicles most of which were in connection with the dictyosomes. No reaction product was found in early premelanosomes. In premelanosomes, the reaction product of DOPA appears first in vesicles approximately 400 A in diameter which are surrounded by a matrix with a characteristic periodicity. These observations seem to allow the speculation that the coated vesicles function in the transport of tyrosinase, and that the premelanosomes are formed in a process which is not necessarily dependent on the Golgi apparatus as was assumed earlier.     

Tyrosinase positive oculocutaneous albinism in the goldfish,Carassius auratus L., an ultrastructural and biochemical study of the eye

Summary Ultrastructural studies, and cytochemical and biochemical determinations of tyrosinase activity were conducted on the pigment epithelium of albino and xanthic goldfish eyes. In eyes of xanthic goldfish, two types of melanosomes are present, spherical and elongated. Melanized melanosomes are absent in the eyes of the albino goldfish, but elongated lamellar premelanosomes are observed. Internal vesicles are present in both melanosome types in the pigment epithelium of the xanthic goldfish but are absent in premelanosomes of the albino. There are also differences in the distribution of lipid droplets, smooth endoplasmic reticulum and Golgi complexes with the latter two being more abundant in the albino. Tyrosinase was not identified cytochemically; however, the enzyme was demonstrated biochemically in the pigment epithelia of both albino and xanthic goldfish. The enzyme is associated with the particulate and soluble fractions of both types of eyes. Particulate albino tyrosinase may be solubilized by triton X-100 treatment. Tyrosinase inhibitors are present in the particulate fractions of both albino and xanthic goldfish eyes. Thus, in the goldfish, ocular albinism appears to be a multiple defect at the molecular and ultrastructural levels.Contribution Number 362, Department of Biology     

Oogenesis in Xenopus laevis (Daudin). II. The induction and subcellular localization of tyrosinase activity in developing oocytes

Tyrosinase activity is increased at specific stages of development in Xenopus laevis oocytes in mature females by an injection of 1000 units of human chorionic gonadtropin (HCG). Enzyme activity is stimulated slightly in stage II oocytes, greatly (5- to 6-fold) in stage III and early stage IV oocytes, slightly in late stage IV, and not at all in stage V oocytes. Tyrosinase activity has been localized cytochemically in oocytes by the DOPA-reaction. The DOPA-reaction product is found in the distal cisterna of the Golgi complex and in an anastomosing network of smooth-surfaced tubules associated with the Golgi complex. No reaction product is found in the clustered elements of smooth endoplasmic reticulum which gives rise to the premelanosomes. Substantial melanization of the premelanosomes does not occur until the DOPA-positive Golgi complexes move into proximity with the premelanosomes at the oocyte periphery. Biochemical assay of the isolated melanin granules shows that premelanosomes isolated from stage III and IV oocytes contain significant tyrosinase activity. This activity appears to decrease in the later stages of melanization. It is concluded that the metabolic activities leading to the formation of oocyte pigmentation are stimulated by gonadotropins and the degree of response to the stimulation is quantitatively regulated according to parameters typical of the specific stage of oocyte development.     

Melanophore differentiation in leaf frogs

In melanosomes of Pachymedusa (Agalychnis) dacnicolor and other leaf frogs, the pteridine dimer, pterorhodin, is found in fibers concentric to a kernel of eumelanin. The kernel is a remnant mature larval melanosome that is renovated at metamorphic climax and on which pterorhodin is deposited at the completion of metamorphosis. When pterorhodin is initially detected by chemical means in the skin of stage 25 individuals, flocculations of fibers are first seen in melanosomes. At stage 25+ a more intense chemical demonstration is accompanied by larger flocculations. These larval melanosomes are smaller than those of other vertebrates, but are formed from classical premelanosomes. At metamorphosis, the melanosome's limiting membrane is elevated from the surface of the eumelanin, and small spheroids are seen in the space and on the pigment surface. The Golgi complex is extremely active, numerous small vesicles are seen in the cytoplasm, and blebbing of the outer membrane of the nuclear envelope occurs. At stage 25 small thick-walled vesicles appear in the cytoplasm in contact with or within the melanosome; they may represent the transport of pterorhodin or elements necessary for its formation.     

The classical pathway of melanogenesis is not essential for melanin synthesis in the adult retinal pigment epithelium

Premelanosomes are presumed to be essential for melanogenesis in melanocytes and pre-natal retinal pigment epithelium (RPE) cells. We analysed melanin synthesis in adenoviral-transduced tyrosinase-gene-expressing amelanotic RPE (ARPE) 19 cells to determine whether premelanosome formation is needed for post-natal melanogenesis. The synthesis of melanogenic proteins and melanin granules was investigated by immunocytochemistry and light and electron microscopy. The occurrence of tyrosinase was analysed ultrastructurally by dihydroxyphenylalanine histochemistry. The viability of transduced cell cultures was examined via MTT assay. We found active tyrosinase in small granule-like vesicles throughout the cytoplasm and in the endoplasmic reticulum and nuclear membrane. Tyrosinase was also associated with multi-vesicular and multi-lamellar organelles. Typical premelanosomes, structural protein PMEL17, tyrosinase-related protein 1 and classic melanosomal stages I–IV were not detected. Instead, melanogenesis took place inside multi-vesicular and multi-lamellar bodies of unknown origin. Viability was not affected up to 10 days after transduction. We thus demonstrate a pathway of melanin formation lacking typical hallmarks of melanogenesis.     

Immunoelectron microscopic localization of tyrosinase in the mouse melanocyte

In the melanocyte, tyrosinase is known as the dey enzyme for melanin formation. Purified tyrosinase protein was prepared that was capable of oxidizing tyrosine. The localization of tyrosinase antigen in the melanocyte was studied using antiserum against tyrosinase. DOPA (L-3,4-dihydroxyphenylalanine)-reaction product and tyrosinase antigen were found on the same organelles i.e., premelanosomes, melanosomes, GERL, and Golgi vesicles. This result seems to suggest that it is cytochemically appropriate to use DOPA as the substrate of tyrosinase. It appeared that tyrosinase antigen was present as granule-like structures inside GERL cisterna and associated with its membrane.     

A melanosome-associated monoclonal antibody J1 recognizes luminal membrane of prelysosomes common to biogenesis of melanosomes and lysosomes

Melanogenesis cascade may be directly or indirectly linked to the dynamics of endosome-lysosome biogenesis. This study aims to identify how and to what extent the endosome-lysosome system is involved in melanosome biogenesis, by utilizing a novel melanogenesis marker, J1, which we identified in the process of developing monoclonal antibodies (MoAbs) against human melanosomes. The antigenic epitope of MoAb J1 was expressed by all of the melanotic and nonmelanotic cells examined. It was expressed primarily by granular structures located in regions proximal to the Golgi complex. Most of MoAb J1 positive granules were co-stained with melanogenic markers, tyrosinase or tyrosinase-related protein (TRP-1). The epitope of MoAb J1 was also coexpressed by most, but not all, of LGP85 (a lysosomal marker) positive granules in both melanoma and non-melanoma cells, indicating that MoAb J1 recognizes a subset of lysosomal vesicles. MoAb J1 did not, however, react with vesicles with late/early (syntaxin 8/ EEA1) endosomal markers. Further examination using fluorophore-labeled pepstatin, a marker of lysosomal luminal content, confirmed that MoAb J1 specifically recognizes the luminal surface of lysosomes. These results indicate that MoAb J1 possesses an antigen epitope that is expressed in the luminal component of prelysosomal granules which are involved in the biogenesis cascade common to both melanosomes and lysosomes. We suggest that tyrosinase family protein, tyrosinase and TRP-1 are transported to melanosomes from TGN via these prelysosomal granules after being transiently transported to late endosomes.     

AP-3 Mediates Tyrosinase but Not TRP-1 Trafficking in Human Melanocytes

Patients with Hermansky-Pudlak syndrome type 2 (HPS-2) have mutations in the beta 3A subunit of adaptor complex-3 (AP-3) and functional deficiency of this complex. AP-3 serves as a coat protein in the formation of new vesicles, including, apparently, the platelet's dense body and the melanocyte's melanosome. We used HPS-2 melanocytes in culture to determine the role of AP-3 in the trafficking of the melanogenic proteins tyrosinase and tyrosinase-related protein-1 (TRP-1). TRP-1 displayed a typical melanosomal pattern in both normal and HPS-2 melanocytes. In contrast, tyrosinase exhibited a melanosomal (i.e., perinuclear and dendritic) pattern in normal cells but only a perinuclear pattern in the HPS-2 melanocytes. In addition, tyrosinase exhibited a normal pattern of expression in HPS-2 melanocytes transfected with a cDNA encoding the beta 3A subunit of the AP-3 complex. This suggests a role for AP-3 in the normal trafficking of tyrosinase to premelanosomes, consistent with the presence of a dileucine recognition signal in the C-terminal portion of the tyrosinase molecule. In the AP-3-deficient cells, tyrosinase was also present in structures resembling late endosomes or multivesicular bodies; these vesicles contained exvaginations devoid of tyrosinase. This suggests that, under normal circumstances, AP-3 may act on multivesicular bodies to form tyrosinase-containing vesicles destined to fuse with premelanosomes. Finally, our studies demonstrate that tyrosinase and TRP-1 use different mechanisms to reach their premelanosomal destination.     

Conformation-dependent post-translational glycosylation of tyrosinase. Requirement of a specific interaction involving the CuB metal binding site

Tyrosinase, the rate-limiting enzyme in mammalian melanogenesis, is a copper-containing transmembrane glycoprotein. Tyrosinase undergoes a complex post-translational processing before reaching the melanosomal membrane. This processing involves N-glycosylation in several sites, including one located in the CuB copper binding site, movement from the endoplasmic reticulum (ER) to the Golgi, copper binding, and sorting to the melanosome. Aberrant processing is causally related to the depigmented phenotype of human melanomas. Moreover, some forms of albinism and several other pigmentary syndromes are considered ER retention diseases or trafficking defects. A critical step in tyrosinase maturation is the acquisition of an ER export-competent conformation recognized positively by the ER quality control system. However, the minimal structural requirements allowing exit from the ER to the Golgi have not yet been identified for tyrosinase or other melanosomal proteins. We addressed this question by analyzing the enzymatic activity and glycosylation pattern of mouse tyrosinase point mutants and chimeric constructs, where selected portions of tyrosinase were replaced by the homologous fragments of the highly similar tyrosinase-related protein 1. We show that a completely inactive tyrosinase point mutant lacking a critical histidine residue involved in copper binding is nevertheless able to exit from the ER and undergo further processing. Moreover, we demonstrate that tyrosinase displays at least two sites whose glycosylation is post-translational and most likely conformation-dependent and that a highly specific interaction involving the CuB site is essential not only for correct glycosylation but also for exit from the ER and enzymatic activity.     

Electron microscopic and cytochemical studies of the mouse subcommissural organ

Summary In mice most of the ependymal cells of the subcommissural organ (SCO cells) are densely packed with dilated cisternae of the endoplasmic reticulum (ER) containing either finely granular or flocculent materials. The well developed supra-nuclear Golgi apparatus consists of stacks of flattened saccules and small vesicles; the two or three outer Golgi saccules are moderately dilated and exhibit numerous fenestrations; occasional profiles suggesting the budding of coated vesicles and formation of membrane-bound dense bodies from the ends of the innermost Golgi saccules are seen. A few coated vesicles and membrane-bound dense bodies of various sizes and shapes are also found in the Golgi region.The contents of the dilated ER cisternae are stained with periodic acid-silver methenamine techniques. In the Golgi complex the two or three inner saccules are stained as deeply as the dense bodies, and the outer saccules are only slightly stained. The stained contents of ER cisternae are more electron opaque than those of the outer but less opaque than those of the inner Golgi saccules and the dense bodies.Acid phosphatase activities are localized in the dense bodies, some of the coated vesicles in the Golgi region, and in the one or two inner Golgi saccules.On the basis of these results the following conclusions have been reached: (1) In mouse SCO cells the finely granular and the flocculent materials in the lumen of ER cisternae contain a complex carbohydrate(s) which is secreted into the ventricle to form Reissner's fiber; (2) the secretory substance is assumed to be synthesized by the ER and stored in its cisternae, and the Golgi apparatus might play only a minor role, if any, in the elaboration of the secretory material; (3) most of the dense bodies in the mouse SCO cells are lysosomal in nature instead of being so-called dark secretory granules.Sponsored by the National Science Council, Republic of China.     

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.     

Clathrin-coated vesicular transport of secretory proteins during the formation of ACTH-containing secretory granules in AtT20 cells

We have studied by electron microscopy and immunocytochemistry the formation of secretory granules containing adrenocorticotropic hormone (ACTH) in murine pituitary cells of the AtT20 line. The first compartment in which condensed secretory protein appears is a complex reticular network at the extreme trans side of the Golgi stacks beyond the TPPase-positive cisternae. Condensed secretory protein accumulates in dilated regions of this trans Golgi network. Examination of en face and serial sections revealed that "condensing vacuoles" are in fact dilations of the trans Golgi network and not detached vacuoles. Only after presumptive secretory granules have reached an advanced stage of morphological maturation do they detach from the trans Golgi network. Frequently both the dilations of the trans Golgi network containing condensing secretory protein and the detached immature granules in the peri-Golgi region have surface coats which were identified as clathrin by immunocytochemistry. Moreover both are the site of budding (or fusion) of coated vesicles, some of which contain condensed secretory protein. The mature granules below the plasma membrane do not, however, have surface coats. Immunoperoxidase labeling with an antiserum specific for ACTH and its precursor polypeptide confirmed that many of the coated vesicles associated with the trans Golgi network contain ACTH. The involvement of the trans Golgi network and coated vesicles in the formation of secretory granules is discussed.     

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.     

DIFFERENTIATION OF MONOCYTES : Origin, Nature, and Fate of Their Azurophil Granules

The origin, content, and fate of azurophil granules of blood monocytes were investigated in several species (rabbit, guinea pig, human) by electron microscopy and cytochemistry. The life cycle of monocytes consists of maturation in bone marrow, transit in blood, and migration into tissues where they function as macrophages. Cells were examined from all three phases. It was found that: azurophil granules originate in the Golgi complex of the developing monocyte of bone marrow and blood, and ultimately fuse with phagosomes during phagocytosis upon arrival of monocytes in the tissues. They contain lysosomal enzymes in all species studied and peroxidase in the guinea pig and human. These enzymes are produced by the same pathway as other secretory products (i.e., they are segregated in the rough ER and packaged into granules in the Golgi complex). The findings demonstrate that the azurophil granules of monocytes are primary lysosomes or storage granules comparable to the azurophils of polymorphonuclear leukocytes and the specific granules of eosinophils. Macrophages from peritoneal exudates (72–96 hr after endotoxin injection) contain large quantities of lysosomal enzymes throughout the secretory apparatus (rough ER and Golgi complex), in digestive vacuoles, and in numerous coated vesicles; however, they lack forming or mature azurophil granules. Hence it appears that the monocyte produces two types of primary lysosomes during different phases of its life cycle—azurophil granules made by developing monocytes in bone marrow or blood, and coated vesicles made by macrophages in tissues and body cavities.     

Evidence of membrane transformation during melanogenesis. Electron microscopic study on the retinal pigment epithelium of chick embryos

Summary Some characteristics of early premelanosomes (PM) suggest that primarily a continuous cisternal complex of the endoplasmic reticulum (ER) is transformed simultaneously to PM. These characteristics are: (i) the form and size, which are similar to ER cisternae; (ii) the localization in groups in the ER; (iii) the same stage of maturation within a group; (iv) the continuities between early PM, and (v) the lack of continuities between ER and PM. Comparative measurements reveal that the limiting membrane of PM, with a total thickness of 7.6±0.19 nm and a center-to-center distance of 5.2±0.06 nm, is significantly thicker than the ER membrane (6.3±0.15 nm and 4.3±0.04 nm, respectively) and the melanosome limiting membrane (6.5±0.22nm and 4.4±0.05 nm, respectively). Therefore, during the formation of melanosomes, the limiting membrane must be transformed from a thin (ER) to a thick (PM) and again to a thin (melanosome) state.