Detection of a Fine Lamellar Gridwork After Degradation of Ocular Melanin Granules by Cultured Peritoneal Macrophages

In the present study we investigated by electron microscopy whether melanin granules derived from choroidal melanocytes and retinal pigment epithelium of cattle could be degraded in the phagolysosomes of cultured murine macrophages. It was found that degradation of ocular melanin is possible by the lysosomes of these macrophages. During degradation of the melanin granules an internal gridwork of fine concentric, highly ordered membranes, 3-4 nm thick, became visible. These membranes may represent remnants of the melanin polymer in the original melanosome or may result from self-assembly of degradation products. Early-stage melanosome-like structures also appeared during digestion of these melanin granules. Melanin granules that seemed to break down into smaller fragments without any visible internal structure were also observed.     

Evidence for melanogenesis in the retinal pigment epithelium of adult cattle and golden hamster.

1. The ultrastructure of the retinal pigment epithelium (RPE) of adult Syrian golden hamsters and cattle was examined with respect to pigment granules and phagosomes involved in degradation of disk membranes from rod outer segments. 2. In the RPE of cattle, phagosomes were found that contained an electron-dense melanin-like material that was not autofluorescent and therefore not lipofuscin. 3. Disk membranes of rods are about 4 nm thick and become enlarged (7-20 nm) and electron-dense during degradation in the RPE. 4. Additionally electron-dense vesiculo-globular bodies (10-100 nm) were found in phagosomes during disk membrane degradation and in mature melanin granules. 5. In the RPE of adult hamsters that had been exposed to intense light, premelanosomes containing unmelanised filaments with a striated periodicity were found in the cytoplasm or in association with mature melanin granules. Early and late stage melanosomes were also present. Phagosomes in the RPE contained degraded disk membranes, melanin-like material and melanofilaments. 6. Dopa oxidase was detected ultrastructurally within shed disk membranes that were in close contact with the microvilli of the RPE. 7. The possibility of melanogenesis within phagosomes during disk membrane degradation is discussed.     

Ultrastructural study of the retinal pigment epithelium during metamorphosis in the sea lamprey (Petromyzon marinus L.)

Summary The sequence of morphological changes in the retinal pigment epithelium during the metamorphic period of the sea lamprey Petromyzon marinus L. has been investigated using electron microscopy. At early metamorphic stages (stages I and II), photoreceptors are present in a small zone of the retina. During these stages, the lateral surface of the epithelial cells shows zonulae occludentes and adhaerentes. The degree of cell differentiation varies throughout the retinal pigment epithelium. Cells covering the differentiated photoreceptors in the central retina have phagosomes, whereas pigment granules appear only in the retinal pigment epithelium dorsal to the optic nerve head. Most epithelial cells have myeloid bodies; their morphology is more complex around the optic nerve head. At stage III, when photoreceptors develop over the whole retina, the distribution of cytoplasmic organelles is almost homogeneous in the retinal pigment epithelium. Subsequently, the basal plasma membrane of the epithelial cells becomes progressively folded and their apical processes enlarged. In addition, extensive gap junctions develop between retinal pigment cells. In late metamorphic stages, noticeable growth of myeloid bodies occurs and consequently the retinal pigment epithelium resembles that of the adult. This study also describes, for the first time, the presence of wandering phagocytes in the retinal pigment epithelium of lampreys; their role in melanosome degradation is discussed.     

Loss of melanin by eye retinal pigment epithelium cells is associated with its oxidative destruction in melanolipofuscin granules

The effect of superoxide radicals on melanin destruction and degradation of melanosomes isolated from cells of retinal pigment epithelium (RPE) of the human eye was studied. We found that potassium superoxide causes destruction of melanin in melanosomes of human and bovine RPE, as well as destruction of melanin from the ink bag of squid, with the formation of fluorescent decay products having an emission maximum at 520-525 nm. The initial kinetics of the accumulation of the fluorescent decay products is linear. Superoxide radicals lead simultaneously to a decrease in the number of melanosomes and to a decrease in concentration of paramagnetic centers in them. Complete degradation of melanosomes leads to the formation of a transparent solution containing dissolved proteins and melanin degradation products that do not exhibit paramagnetic properties. To completely degrade one melanosome of human RPE, 650 ± 100 fmol of superoxide are sufficient. The concentration of paramagnetic centers in a melanolipofuscin granule of human RPE is on average 32.5 ± 10.4% (p < 0.05, 150 eyes) lower than in a melanosome, which indicates melanin undergoing a destruction process in these granules. RPE cells also contain intermediate granules that have an EPR signal with a lower intensity than that of melanolipofuscin granules, but higher than that of lipofuscin granules. This signal is due to the presence of residual melanin in these granules. Irradiation of a mixture of melanosomes with lipofuscin granules with blue light (450 nm), in contrast to irradiation of only melanosomes, results in the appearance of fluorescent melanin degradation products. We suggest that one of the main mechanisms of age-related decrease in melanin concentration in human RPE cells is its destruction in melanolipofuscin granules under the action of superoxide radicals formed during photoinduced oxygen reduction by lipofuscin fluorophores.     

The postnatal reaction of the albino rat pigment epithelium after administration of chloroquindiphosphate]

The development of pigment granules has been studied in 0...5 day old normal albino-rats and after a single injection of chloroquinediphosphat. During the postnatal time the pigment epithelial cell changes structurally. The basal region of the epithelium containes lipoidvacuoles and later on glycogen. The apical region form long skin projections that enclose the developing inner segments of photoreceptor cells. The pigment granules develop normally until the stage of melanin deposition. The lamellated premelanosomes are equipped by helical structures. The development of premelanosomes are not disturbed, by chloroquinediphosphate blocking the protein synthesis in the cell. The drug produce lamellated vacuoles inside the cell arising from the ergastoplasm. Also the extracellular space is enlarged. A significant increase or decrease in the number of phagosomes in the pigment epithelial cells after administration of the drug does not occur as compared to the cells of untreated animals.     

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.     

Melanosome–iron interactions within retinal pigment epithelium‐derived cells

Melanosomes were recently shown to protect ARPE‐19 cells, a human retinal pigment epithelium (RPE) cell line, against oxidative stress induced by hydrogen peroxide. One postulated mechanism of antioxidant action of melanin is its ability to bind metal ions. The aim here was to determine whether melanosomes are competent to bind iron within living cells, exhibiting a property previously shown only in model systems. The outcomes indicate retention of prebound iron and accumulation of iron by granules after iron delivery to cells via the culture medium, as determined by both colorimetric and electron spin resonance analyses for bound‐to‐melanosome iron. Manipulation of iron content did not affect the pigment's ability to protect cells against H₂O₂, but the function of pigment granules within RPE cells should be extended beyond a role in light irradiation to include participation in iron homeostasis.     

Does Melanin Turnover Occur in the Eyes of Adult Vertebrates?

This paper is a review of what is known about the turnover of melanin in iris, choroid, and retinal pigment epithelium (RPE) of the adult vertebrate eye. Differences in size and structure of choroideal and retinal pigment epithelial melanin granules are shown by electron micrographs. The classical stages of melanin synthesis, including the premelanosome, are shown in the RPE of adult hamsters that had been exposed to intense light. Degradation or synthesis of melanin also seem to occur in the melanocytes of the choroid in these animals. It is postulated that all three pigmented eye tissues (iris, RPE, and choroid) of adult vertebrates form melanin granules in vivo. However, nothing is known about the amount of this turnover.     

The molecular regulation of organelle transport in mammalian retinal pigment epithelial cells

Retinal pigment epithelial cells contain large numbers of melanosomes that can enter the apical processes extending between the outer segments of the overlying photoreceptors. Every day the distal portion of the photoreceptor outer segment is shed and phagocytosed by the retinal pigment epithelial cell. The phagosome is then transported into the cell body and the contents degraded by lysosomal enzymes. This review focuses on recent progress made in the identification of molecules that regulate the transport of melanosomes into the apical processes and the transport of phagosomes into the cell body. Myosin VIIa is a key player in both processes and, at least in the case of melanosome movement, myosin VIIa is recruited to the melanosome via the GTPase, Rab27a. The possible role played by defects in the transport of melanosomes and phagosomes in the development of retinal degenerative diseases is discussed.     

The Effect of Sodium Iodate and Melanin on the Formation of Glyoxylate

Sodium iodate damages retinal pigment epithelium specifically, but the reason for this specificity is not well understood. The work reported here describes an effect of sodium iodate on melanin, a major component of the retinal pigment epithelium. Sodium iodate increases the ability of melanin to convert glycine to glyoxylate. Almost ten times as much glyoxylate is formed when sodium iodate is present compared to the amount formed with melanin alone, although iodate alone does not convert glycine to glyoxylate. A chemical reaction between sodium iodate and melanin is suggested as a partial explanation of the specificity of iodate toxicity towards retinal pigment epithelium.     

The effect of sodium iodate and melanin on the formation of glyoxylate.

Sodium iodate damages retinal pigment epithelium specifically, but the reason for this specificity is not well understood. The work reported here describes an effect of sodium iodate on melanin, a major component of the retinal pigment epithelium. Sodium iodate increases the ability of melanin to convert glycine to glyoxylate. Almost ten times as much glyoxylate is formed when sodium iodate is present compared to the amount formed with melanin alone, although iodate alone does not convert glycine to glyoxylate. A chemical reaction between sodium iodate and melanin is suggested as a partial explanation of the specificity of iodate toxicity towards retinal pigment epithelium.     

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.     

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.     

Melanin granule metabolism in the iris and retinal pigment epithelium in adult tritions after completion of eye regeneration

It was concluded that the newly synthesized melanin granules were replaced in the pigmented tissues of the newt eye on the basis of redistribution of the cells of pigment epithelium of retina and iris labelled by 3H-DOPA 2.5 and 6.5 months after the isotope injection. The replacement of melanin granules and, correspondingly, melanin synthesis proceed more actively in the peripheral zones of the pigment epithelium of retina. The depigmentation of cells preceding the melanin synthesis appears to be realized with the participation of macrophages.     

The fine structure of the retina in the Japanese Quail (Coturnix Coturnix Japonica). I. Pigment Epithelium and its Vascular Barrier

The uItrastructure oft he pigment epithelium and its vascular barrier was examined in the Japanese quail by electron microscopy. Most endothelial pores in the choriocapillaris appear bridged by double diaphragms. The pigment epithelium is characterized by numerous slender basal infoldings, myeloid bodies and phagosomes. Myeloid bodies communicate with the nuclear envelope and profiles of both the rough and smooth endoplasmic reticulum.Phagosome formation appears to be accomplished by concomitant activity of the rod itself (curling of apical lamellae) and the apical villi of the pigment epithelium. Within the pigment epithelium cytoplasm the phagosomes undergo degeneration and are associated with increased numbers of lysosomal-like granules.     

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

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

Ultimate Fate of Rod Outer Segments in the Retinal Pigment Epithelium

To investigate the degradation pathway of rod outer segments (ROS) in vivo, we injected gold-labeled ROS into the subretinal space of rabbits using a pars plana approach. Histology and electron microscopy performed on the specimens 72 hr after ROS injection revealed that the retina over the injection site was reattached, the retinal pigment epithelial (RPE) cells were intact, and gold granules were localized inside melanin granules and melanosomes. These results indicate that, in RPE, in vivo degradation of ROS is associated with melanosomes.     

Ultimate fate of rod outer segments in the retinal pigment epithelium.

To investigate the degradation pathway of rod outer segments (ROS) in vivo, we injected gold-labeled ROS into the subretinal space of rabbits using a pars plana approach. Histology and electron microscopy performed on the specimens 72 hr after ROS injection revealed that the retina over the injection site was reattached, the retinal pigment epithelial (RPE) cells were intact, and gold granules were localized inside melanin granules and melanosomes. These results indicate that, in RPE, in vivo degradation of ROS is associated with melanosomes.     

The retinal pigment epithelium and photoreceptor cells light-and electron microscopic studies on monkey eyes

Summary In the perifoveal retina of the monkey, Cercopithecus aethiops, the melanin granules are accumulated in apical cytoplasmatic protrusions of the pigment epithelial cells, facing the end of the cones. The rods are inserted deeper into the pigment epithelium than the cones; they reach the bottom of the infoldings of the apical surface membrane of the pigment epithelial cells. No melanin granules or other inclusions are situated at the end of the rods. The outer extremity of the rods is considerably inclined and in sections often appears as groups of rod discs which are incompletely or completely separated from the main part of the outer segments. This separation is regarded as an artifact caused by the inclination of the rods, and it is therefore not considered to represent phagocytosis of the outer segments by the pigment epithelium.The inclusions of the pigment epithelial cells are classified in five categories which seem to be related to each other owing to their shared structural characteristics. It is suggested that melanin granules are produced, modified and destroyed by the pigment epithelial cells of the adult.Because of the relations between the photoreceptors and the melanin granules it is suggested that light scattered by the melanin granules may pass backwards through the outer segments of the cones, but not of the rods.This investigation was supported in part by the Danish Foundation for the Advancement of Science and by the Danish Medical Research Council.     

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.