Actin-dependent,retrograde motility of surface-attached beads and aggregating pigment granules in dissociated teleost retinal pigment epithelial cells

Teleost retinal pigment epithelial (RPE) cells contain pigment granules within apical projections which undergo actin-dependent, bi-directional motility. Dissociated RPE cells in culture attach to the substrate and extend apical projections in a radial array from the central cell body. Pigment granules within projections can be triggered to aggregate or disperse by the presence or absence of 1 mM cAMP. Aminated, fluorescent latex beads attached to the dorsal surface of apical projections and moved in the retrograde direction, towards the cell body. Bead rates on RPE cells with aggregating or fully aggregated pigment granules were 2.2 +/- 0.5 and 2.6 +/- 0.2 microm/min (mean +/- SEM), respectively, similar to rates of aggregating (retrograde) pigment granule movement (2.0 +/- 0.4 microm/min). Bead rates were slightly slower on cells with fully dispersed or dispersing pigment granules (1.5 +/- 0.1 and 1.5 +/- 0.4 microm/min). Movements of surface-attached beads and aggregating pigment granules were closely correlated in the distal portions of apical projections, but were more independent of each other in proximal regions of the projections. The actin disrupting drug, cytochalasin D (CD), reversibly halted retrograde bead movements, suggesting that motility of surface-attached particles is actin-dependent. In contrast, the microtubule depolymerizing drug, nocodazole, had no effect on retrograde bead motility. The similar characteristics and actin-dependence of retrograde bead movements and aggregating pigment granules suggest a correlation between these two processes.     

Effects of the Actin‐Stabilizing Drug,Jasplakinolide, on Pigment Granule Motility in Isolated Retinal Pigment Epithelial (RPE) Cells of Green Sunfish,Lepomis cyanellus

The retinal pigment epithelium (RPE) of teleosts contains pigment granules that migrate in response to changes in light condition. Dissociated, cultured RPE cells in vitro can be triggered to aggregate or disperse pigment granules by the application of cAMP or dopamine, respectively. Previous research using the actin‐disrupting drug, cytochalasin D, suggested that pigment granule motility is actin dependent. To further examine the role of actin in pigment granule motility, we tested the effects of the actin‐stabilizing drug, jasplakinolide, on pigment granule motility. Pigment granules in previously dispersed RPE cells remained dispersed after jasplakinolide exposure (0.1–1 μM), but the drug halted movement of most pigment granules and stimulated rapid bi‐directional movements in a small subset of granules. Jasplakinolide also blocked net pigment granule aggregation and interfered with the maintenance of full aggregation. Although jasplakinolide did not block pigment granule dispersion, it did alter the motility of dispersing granules compared to control cells; rather than the normal saltatory, primarily centrifugal movements, granules of jasplakinolide‐treated cells demonstrated slow, creeping centrifugal movements and more rapid bi‐directional movements. Jasplakinolide also altered cell morphology; the length and thickness of apical projections increased, and enlarged, paddle‐like structures, which contained F‐actin appeared at the tips of projections. Actin antibody labeling of jasplakinolide‐treated cells revealed a more reticulated network of actin compared to antibody‐labeled control cells. These results indicate that jasplakinolide‐induced disruption of the actin network compromises normal pigment granule dispersion and aggregation in isolated RPE cells, thus providing further evidence that these movements are actin dependent.     

Actin-dependent motility of melanosomes from fish retinal pigment epithelial (RPE) cells investigated using in vitro motility assays

Melanosomes (pigment granules) within retinal pigment epithelial (RPE) cells of fish and amphibians undergo massive migrations in response to light conditions to control light flux to the retina. Previous research has shown that melanosome motility within apical projections of dissociated fish RPE cells requires an intact actin cytoskeleton, but the mechanisms and motors involved in melanosome transport in RPE have not been identified. Two in vitro motility assays, the Nitella assay and the sliding filament assay, were used to characterize actin-dependent motor activity of RPE melanosomes. Melanosomes applied to dissected filets of the Characean alga, Nitella, moved along actin cables at a mean rate of 2 microm/min, similar to the rate of melanosome motility in dissociated, cultured RPE cells. Path lengths of motile melanosomes ranged from 9 to 37 microm. Melanosome motility in the sliding filament assay was much more variable, ranging from 0.4-33 microm/min; 70% of velocities ranged from 1-15 microm/min. Latex beads coated with skeletal muscle myosin II and added to Nitella filets moved in the same direction as RPE melanosomes, indicating that the motility is barbed-end directed. Immunoblotting using antibodies against myosin VIIa and rab27a revealed that both proteins are enriched on melanosome membranes, suggesting that they could play a role in melanosome transport within apical projections of fish RPE.     

Effects of the actin-stabilizing drug, jasplakinolide, on pigment granule motility in isolated retinal pigment epithelial (RPE) cells of green sunfish, Lepomis cyanellus

The retinal pigment epithelium (RPE) of teleosts contains pigment granules that migrate in response to changes in light condition. Dissociated, cultured RPE cells in vitro can be triggered to aggregate or disperse pigment granules by the application of cAMP or dopamine, respectively. Previous research using the actin-disrupting drug, cytochalasin D, suggested that pigment granule motility is actin dependent. To further examine the role of actin in pigment granule motility, we tested the effects of the actin-stabilizing drug, jasplakinolide, on pigment granule motility. Pigment granules in previously dispersed RPE cells remained dispersed after jasplakinolide exposure (0.1-1 microM), but the drug halted movement of most pigment granules and stimulated rapid bi-directional movements in a small subset of granules. Jasplakinolide also blocked net pigment granule aggregation and interfered with the maintenance of full aggregation. Although jasplakinolide did not block pigment granule dispersion, it did alter the motility of dispersing granules compared to control cells; rather than the normal saltatory, primarily centrifugal movements, granules of jasplakinolide-treated cells demonstrated slow, creeping centrifugal movements and more rapid bi-directional movements. Jasplakinolide also altered cell morphology; the length and thickness of apical projections increased, and enlarged, paddle-like structures, which contained F-actin appeared at the tips of projections. Actin antibody labeling of jasplakinolide-treated cells revealed a more reticulated network of actin compared to antibody-labeled control cells. These results indicate that jasplakinolide-induced disruption of the actin network compromises normal pigment granule dispersion and aggregation in isolated RPE cells, thus providing further evidence that these movements are actin dependent.     

Light-Induced Dopamine Release from Teleost Retinas Acts as a Light-Adaptive Signal to the Retinal Pigment Epithelium

In the retinal pigment epithelium (RPE) of lower vertebrates, melanin pigment granules migrate in and out of the cells' long apical projections in response to changes in light condition. When the RPE is in its normal association with the retina, light onset induces pigment granules to disperse into the apical projections; dark onset induces pigment granules to aggregate into the cell bodies. However, when the RPE is separated from the retina, pigment granule movement in the isolated RPE is insensitive to light onset. It thus seems likely that a signal from the retina communicates light onset to the RPE to initiate pigment dispersion. We have examined the nature of this retina-to-RPE signal in green sunfish, Lepomis cyanellus. In isolated retinas with adherent RPE, light-induced pigment dispersion in the RPE is blocked by treatments known to block Ca2+-dependent transmitter release in the retina. In addition, the medium obtained from incubating previously dark-adapted retinas in the light induces light-adaptive pigment dispersion when added to isolated RPE. In contrast, the medium obtained from incubating dark-adapted retinas in constant darkness does not affect pigment distribution when added to isolated RPE. These results are consistent with the idea that RPE pigment dispersion is triggered by a substance that diffuses from the retina at light onset. The capacity of the conditioned medium from light-incubated retinas to induce pigment dispersion in isolated RPE is inhibited by a D2 dopamine antagonist, but not by D1 or alpha-adrenergic antagonists. Light-induced pigment dispersion in whole RPE-retinas is also blocked by a D2 dopamine antagonist.(ABSTRACT TRUNCATED AT 250 WORDS)     

Myosin II and Rho kinase activity are required for melanosome aggregation in fish retinal pigment epithelial cells

In the retinal pigment epithelium (RPE) of fish, melanosomes (pigment granules) migrate long distances through the cell body into apical projections in the light, and aggregate back into the cell body in the dark. RPE cells can be isolated from the eye, dissociated, and cultured as single cells in vitro. Treatment of isolated RPE cells with cAMP or the phosphatase inhibitor, okadaic acid (OA), stimulates melanosome aggregation, while cAMP or OA washout in the presence of dopamine triggers dispersion. Previous studies have shown that actin filaments are both necessary and sufficient for aggregation and dispersion of melanosomes within apical projections of isolated RPE. The role of myosin II in melanosome motility was investigated using the myosin II inhibitor, blebbistatin, and a specific rho kinase (ROCK) inhibitor, H-1152. Blebbistatin and H-1152 partially blocked melanosome aggregation triggered by cAMP in dissociated, isolated RPE cells and isolated sheets of RPE. In contrast, neither drug affected melanosome dispersion. In cells exposed to either blebbistatin or H-1152, then triggered to aggregate using OA, melanosome aggregation was completely inhibited. These results demonstrate that (1) melanosome aggregation and dispersion occur through different, actin-dependent mechanisms; (2) myosin II and ROCK activity are required for full melanosome aggregation, but not dispersion; (3) partial aggregation that occurred despite myosin II or ROCK inhibition suggests a second component of aggregation that is dependent on cAMP signaling, but independent of ROCK and myosin II.     

Stimulation of Distinct D2 Dopaminergic and α2-Adrenergic Receptors Induces Light-Adaptive Pigment Dispersion in Teleost Retinal Pigment Epithelium

In the retinal pigment epithelium (RPE) of lower vertebrates, melanin pigment granules aggregate and disperse in response to changes in light conditions. Pigment granules aggregate into the RPE cell body in the dark and disperse into the long apical projections in the light. Pigment granule movement retains its light sensitivity in vitro only if RPE is explanted together with neural retina. In the absence of retina, RPE pigment granules no longer move in response to light onset or offset. Using a preparation of mechanically isolated fragments of RPE from green sunfish, Lepomis cyanellus, we investigated the effects of catecholamines on pigment migration. We report here that 3,4-dihydoxyphenylethylamine (dopamine) and clonidine each mimic the effect of light in vivo by inducing pigment granule dispersion. Dopamine had a half-maximal effect at approximately 2 nM; clonidine, at 1 microM. Dopamine-induced dispersion was inhibited by the D2 dopaminergic antagonist sulpiride but not by D1 or alpha-adrenergic antagonists. Furthermore, a D2 dopaminergic agonist (LY 171555) but not a D1 dopaminergic agonist (SKF 38393) mimicked the effect of dopamine. Clonidine-induced dispersion was inhibited by the alpha 2-adrenergic antagonist yohimbine but not by sulpiride. These results suggest that teleost RPE cells possess distinct D2 dopaminergic and alpha 2-adrenergic receptors, and that stimulation of either receptor type is sufficient to induce pigment granule dispersion. In addition, forskolin, an activator of adenylate cyclase, induced pigment granule movement in the opposite direction, i.e., dark-adaptive pigment aggregation.(ABSTRACT TRUNCATED AT 250 WORDS)     

The unusual microtubule polarity in teleost retinal pigment epithelial cells

In cells of the teleost retinal pigment epithelium (RPE), melanin granules disperse into the RPE cell's long apical projections in response to light onset, and aggregate toward the base of the RPE cell in response to dark onset. The RPE cells possess numerous microtubules, which in the apical projections are aligned longitudinally. Nocodazole studies have shown that pigment granule aggregation is microtubule-dependent (Troutt, L. L., and B. Burnside, 1988b Exp. Eye Res. In press.). To investigate further the mechanism of microtubule participation in RPE pigment granule aggregation, we have used the tubulin hook method to assess the polarity of microtubules in the apical projections of teleost RPE cells. We report here that virtually all microtubules in the RPE apical projections are uniformly oriented with plus ends toward the cell body and minus ends toward the projection tips. This orientation is opposite that found for microtubules of dermal melanophores, neurons, and most other cell types.     

Selection of bead‐displayed,PNA‐encoded chemicals

The lack of efficient identification and isolation methods for specific molecular binders has fundamentally limited drug discovery. Here, we have developed a method to select peptide nucleic acid (PNA) encoded molecules with specific functional properties from combinatorially generated libraries. This method consists of three essential stages: (1) creation of a Lab‐on‐Bead? library, a one‐bead, one‐sequence library that, in turn, displays a library of candidate molecules, (2) fluorescence microscopy‐aided identification of single target‐bound beads and the extraction – wet or dry – of these beads and their attached candidate molecules by a micropipette manipulator, and (3) identification of the target‐binding candidate molecules via amplification and sequencing. This novel integration of techniques harnesses the sensitivity of DNA detection methods and the multiplexed and miniaturized nature of molecule screening to efficiently select and identify target‐binding molecules from large nucleic acid encoded chemical libraries. Beyond its potential to accelerate assays currently used for the discovery of new drug candidates, its simple bead‐based design allows for easy screening over a variety of prepared surfaces that can extend this technique's application to the discovery of diagnostic reagents and disease markers. Copyright © 2009 John Wiley & Sons, Ltd.     

Melanin Granules Prevent the Cytotoxic Effects of l‐DOPA on Retinal Pigment Epithelial Cells in Vitro by Regulation of NO and Superoxide Radicals

Inasmuch as the nitrogen cycle elicits the direct reduction of N₂ to NH₃ through enzymatic reactions, and inasmuch as l ‐DOPA ( l ‐dihydroxyphentlalamine), a catecholamine, can be a source of nitric oxide (NO), it is possible that melanin granules in the eye affect the generation of NO, which causes damage to the retinal pigment epithelial (RPE) cells during the oxidation of l ‐DOPA. In order to confirm this possibility, we analyzed the correlations of NO generation, cell growth, and superoxide dismutase (SOD) activities in two types (melanotic and amelanotic) of bovine RPE cells following exposure to l ‐DOPA. NO generation from l ‐DOPA was determined using an NO detector that is reliant on redox currents. The concentration of NO was measured in terms of diffusion currents run between a working electrode and a counter electrode, both being set in culture medium placed in a Petri dish. For the assays, l ‐DOPA was added to the medium at various concentrations (5, 29.9, 79.4, 152.7 or 249 μM), and 6 min after addition, an NO‐trapping agent 2,4‐carboxyphenyl‐4,4,5,5‐tetramethylimidazole‐1‐oxyl 3‐oxide (carboxy‐PTIO) was also added. The melanotic and amelanotic types of RPE cells were cultured separately in medium with l ‐DOPA under an atmosphere containing 20, 10 or 5% oxygen. Cell numbers were counted using a Coulter counter, and SOD activities were determined following incubation for 24, 48 or 72 hr using a modification of the luminol assay. The results obtained indicated that: (a) NO was produced from l ‐DOPA in a concentration‐dependent manner and was trapped quantitatively by carboxy‐PTIO; (b) the generation of NO was inhibited more markedly in the melanotic cell line than in the amelanotic one, suggesting an increased tolerance to l ‐DOPA‐derived cytotoxicity in the former; and (c) the SOD activities were more affected by oxygen concentration in the melanotic cells than in the amelanotic ones. From these results, it is concluded that melanin granules in RPE cells have a role in preventing the cytotoxicity derived from l ‐DOPA and in regulating the generation of NO and superoxide radicals.     

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.     

Apical Polarity of N-CAM and EMMPRIN in Retinal Pigment Epithelium Resulting from Suppression of Basolateral Signal Recognition

Retinal pigment epithelial (RPE) cells apically polarize proteins that are basolateral in other epithelia. This reversal may be generated by the association of RPE with photoreceptors and the interphotoreceptor matrix, postnatal expansion of the RPE apical surface, and/or changes in RPE sorting machinery. We compared two proteins exhibiting reversed, apical polarities in RPE cells, neural cell adhesion molecule (N-CAM; 140-kD isoform) and extracellular matrix metalloproteinase inducer (EMMPRIN), with the cognate apical marker, p75-neurotrophin receptor (p75-NTR). N-CAM and p75-NTR were apically localized from birth to adulthood, contrasting with a basolateral to apical switch of EMMPRIN in developing postnatal rat RPE. Morphometric analysis demonstrated that this switch cannot be attributed to expansion of the apical surface of maturing RPE because the basolateral membrane expanded proportionally, maintaining a 3:1 apical/basolateral ratio. Kinetic analysis of polarized surface delivery in MDCK and RPE-J cells showed that EMMPRIN has a basolateral signal in its cytoplasmic tail recognized by both cell lines. In contrast, the basolateral signal of N-CAM is recognized by MDCK cells but not RPE-J cells. Deletion of N-CAM''s basolateral signal did not prevent its apical localization in vivo. The data demonstrate that the apical polarity of EMMPRIN and N-CAM in mature RPE results from suppressed decoding of specific basolateral signals resulting in randomized delivery to the cell surface.     

Thrombin promotes actin stress fiber formation in RPE through Rho/ROCK‐mediated MLC phosphorylation

The retinal pigment epithelium (RPE) forms the outer blood–retina barrier (BRB). Most retinal diseases involve BRB breakdown, whereupon thrombin contained in serum directly contacts the RPE. Thrombin is known to promote actin stress fiber formation, an important determinant in eye diseases involving the epithelial–mesenchymal transition (EMT) and migration of RPE cells, such as proliferative vitreoretinopathy. We analyzed thrombin effect on signaling pathways leading to myosin light chain (MLC) phosphorylation and actin stress fiber formation in primary cultures of rat RPE cells, in order to support a role for thrombin in RPE transdifferentiation. MLC phosphorylation was measured by Western blot; actin cytoskeleton was visualized using immunofluorescent phalloidin, and Rho GTPase activation was assessed by ELISA. We showed that thrombin/PAR‐1 induces the time‐ and dose‐dependent phosphorylation of MLC through the activation of Rho/ROCK and myosin light chain kinase (MLCK). ROCK increased phospho‐MLC by phosphorylating MLC and by inhibiting MLC phosphatase. Thrombin effect was abolished by the ROCK inhibitor Y‐27632, whereas MLCK inhibitor ML‐7 and PLC‐β inhibitor U73122 attenuated MLC phosphorylation by ≈50%, suggesting the activation of MLCK by PLC‐β‐mediated calcium increase. Additionally, thrombin‐induced MLC phosphorylation was blocked by the inhibitory PKCζ pseudosubstrate, wortmannin, and LY294002, indicating IP₃/PKCζ involvement in the control of MLC phosphorylation. Moreover, we demonstrated that thrombin effect on MLC induces actin stress fiber formation, since this effect was prevented by inhibiting the pathways leading to MLC phosphorylation. We conclude that thrombin stimulation of MLC phosphorylation and actin stress fiber formation may be involved in thrombin‐induced RPE cell transformation subsequent to BRB dysfunction. J. Cell. Physiol. 226: 414–423, 2011. © 2010 Wiley‐Liss, Inc.     

X-Ray Microanalysis and Phagocytotic Activity of Cultured Retinal Pigment Epithelial Cells in Hypoxia

Purpose: To investigate the influence of the functional and morphological changes induced in retinal pigment epithelial (RPE) cells by retinal ischemia, we evaluated the phagocytotic activity, the concentration of various elements, and ultrastructure in cultured RPE cells in hypoxia. Methods: The concentrations of oxygen in incubators were adjusted to 20, 10, and 1% by the addition of nitrogen for 72 hr. To observe phagocytotic activity and its relationship to actin filaments, the filaments of RPE cells incubated with fluoresbrite carboxylate YG microspheres were stained with rhodamine phalloidin. Some of the specimens were subjected to X-ray microanalysis by scanning electron microscope after being fixed, freeze-dried, and coated with carbon to investigate the cytoplasmic concentration of elements. A part of the latter specimens was also observed by transmission electron microscope after being embedded in epon and cut into ultrathin sections to see the ultra-structural changes inside cell. Results: Lowering oxygen concentrations from 20% to 1% swelled RPE cells and decreased the number of fluoresbrite carboxylate YG microspheres phagocytized by RPE cells. Phagocytosis of a large amount of latex beads (30 μl) for 24 hr in 1% oxygen caused a disruption of RPE cells. Na, S, and P were detected in RPE cells cultured in 20% oxygen. Reducing the oxygen concentration from 20 to 10 or 1% significantly decreased Na and increased S. Mitochondria were observed in RPE cells in 20 and 10% oxygen, but many vacuoles were observed in the cytoplasm in 1% oxygen. Conclusion: Hypoxia as low as 1% oxygen induced malfunction of phagocytosis and the fragility of RPE cells. We could speculate the imbalance of the electrolytes such as Na or a decrease of antioxidants such as glutathione containing S as a reason of disturbance of cell viability.     

Functional analysis of alpha5beta1 integrin and lipid rafts in invasion of epithelial cells by Porphyromonas gingivalis using fluorescent beads coated with bacterial membrane vesicles

Porphyromonas gingivalis, a periodontal pathogen, was previously suggested to exploit alpha5beta1 integrin and lipid rafts to invade host cells. However, it is unknown if the functional roles of these host components are distinct from one another during bacterial invasion. In the present study, we analyzed the mechanisms underlying P. gingivalis invasion, using fluorescent beads coated with bacterial membrane vesicles (MV beads). Cholesterol depletion reagents including methyl-beta-cyclodextrin (MbetaCD) drastically inhibited the entry of MV beads into epithelial cells, while they were less effective on bead adhesion to the cells. Bead entry was also abolished in CHO cells deficient in sphingolipids, components of lipid rafts, whereas adhesion was negligibly influenced. Following MbetaCD treatment, downstream events leading to actin polymerization were abolished; however, alpha5beta1 integrin was recruited to beads attached to the cell surface. Dominant-negative Rho GTPase Rac1 abolished cellular engulfment of the beads, whereas dominant-negative Cdc42 did not. Following cellular interaction with the beads, Rac1 was found to be translocated to the lipid rafts fraction, which was inhibited by MbetaCD. These results suggest that alpha5beta1 integrin, independent of lipid rafts, promotes P. gingivalis adhesion to epithelial cells, while the subsequent uptake process requires lipid raft components for actin organization, with Rho GTPase Rac1.     

不同浓度A2E对离体猪视网膜色素上皮细胞的影响

目的评价体外合成的A2E对猪视网膜色素上皮（RPE）细胞的细胞活力和生物学特性影响,为进一步研究A2E在RPE细胞相关疾病中的作用提供细胞模型。方法利用全反式视黄醛和乙醇胺体外合成脂褐质荧光基团A2E。不同浓度的A2E（0,50,75,100μmol／L）作用第3代体外培养的猪RPE细胞30,45,60,90min,换10％FBS DMEM-F12培养液孵育24h后,倒置荧光显微镜观察荧光强度,IPP6．0软件灰度扫描定量荧光强度。采用MTT法检测A2E作用细胞各个时间段的吸光度值,应用SPSS11．0软件包对数据进行统计学分析,评价A2E的细胞毒性及RPE细胞活性。结果A2E被RPE细胞摄取后主要分布于细胞核周围,具有自发荧光。MTT实验及荧光灰度扫描结果显示,不同浓度的A2E被细胞摄取后细胞活力和荧光灰度扫描结果不同,以50μmol／L浓度A2E作用RPE细胞60min时,细胞内荧光强度高同时细胞活力强。结论体外培养的猪RPE细胞摄取体外合成的50μmol／L A2E 60min后细胞对A2E的摄取较多,A2E对细胞的毒性相对较低,该条件下进行A2E对离体猪RPE细胞的研究较好。     

Pigment epithelial ensheathment and phagocytosis of rod tips in the retina of Rana catesbeiana

Two modes of shedding of rod disc membranes were observed by electron microscopy in bullfrog retinas illuminated for various periods from 10 min to 2 hr. One mode is "autonomous shedding" whereby rods shed disc packets directly into the subretinal space. Most of the discarded disc packets are subsequently brought into contact with villous apical processes of pigment epithelial (PE) cells and are ultimately engulfed by these cells. When some of the shed disc membranes remain in the subretinal space, it appears that these remnants may be phagocytized by ameboid phagocytes. The other mode is "cooperative shedding" whereby rods shed disc packets with the participation of pigment epithelial ensheathment. Shedding of a disc packet from a rod tip, and enclosing of the rod tip by a broad, sleeve-like apical process of a PE cell, take place simultaneously. The separated disc packets may be immediately engulfed by the PE cells without risk of failure. Both villous and sleeve-like types of apical processes of PE cells in the bullfrog lack pigment granules, in contrast to the finger-like apical processes that do contain pigment granules. Villous and sleeve-like processes therefore probably belong to the same category as the leaf-like apical processes of PE cells in mammalian retinas.     

Controlled release of d-glucose from starch granules containing 29% free d-glucose and Eudragit L100-55 as a binding and coating agent

Waxy maize starch (100% amylopectin) granules were modified by reaction of the granules with glucoamylase in a minimum amount of water to give 29% (w/w) d-glucose inside the granules [Kim, Y.-K.; Robyt, J. F. Carbohydr. Res.1999, 318, 129−134]. These granules were made into beads by dropping an ethanol slurry of starch and different amounts of Eudragit L100-55 in a constant ratio of 100:1 from a pipette onto Whatman 3MM filter paper. The starch beads were air dried and then repeatedly sprayed 0-12 times with 2.0% (w/v) Eudragit L100-55 in ethanol, with drying between each spraying, to coat the surface of the starch beads, giving different amounts of Eudragit L100-55 coating. Seven different kinds of beads, with different amounts of Eudragit L100-55 binding and coating agent, were obtained. The rates of release of d-glucose into water from the seven kinds of beads were inversely proportional to the amount of binding and coating agent. Bead type I, which was without any binding and coating gave a fast 100% release of d-glucose in 30 min. Beads II and III also gave a fast 100% release in 60 min and 90 min, respectively. Bead IV gave a near linear release of 97% d-glucose in 150 min; Bead V gave a 50% release in 120 min followed by the remaining 50% in 60 min; and Beads VI and VII gave a slow release of 10% and 4%, respectively, from 0 to 120 min, followed by a rapid 100% release from 120 to 180 min.     

Pigment epithelium-derived factor protects retinal pigment epithelium from oxidant-mediated barrier dysfunction

Retinal pigment epithelium (RPE) cells form a monolayer at the blood-retina barrier between the retina and choriocapillaries. The barrier function may be damaged by multiple stresses to the cell, including the repeated exposure to oxidants that are generated by photoreceptor cell turnover. The purpose of our study was to document the protective effect of pigment epithelium-derived factor (PEDF), a tropic factor produced by the RPE, on H(2)O(2)-induced RPE barrier dysfunction. When assayed by a FITC-labeled dextran transepithelial flux, the increased permeability of the RPE barrier (induced by H(2)O(2)) was prevented by PEDF pretreatment. To further explore the mechanism leading to this permeability change, we investigated the distribution of cytoskeleton and junctional proteins. The redistribution of the two junctional proteins occludin, and N-cadherin and actin reorganization in RPE, induced by H(2)O(2), can be prevented by PEDF pretreatment. PEDF can also prevent H(2)O(2)-induced stress kinase p38/27-kDa heat shock protein signaling which is known to mediate actin rearrangement. These findings indicated that PEDF can stabilize actin, maintain normal membrane occludin and N-cadherin structure, and preserve the barrier function of RPE cells against oxidative stress.