Localization of frog retinal pigment epithelium Na+-K+ ATPase

Retinal pigment epithelium in the pathogenesis of age-related macular degeneration and photobiomodulation as a potential therapy?

The retinal pigment epithelium (RPE) comprises a monolayer of cells located between the neuroretina and the choriocapillaries. The RPE serves several important functions in the eye: formation of the blood-retinal barrier, protection of the retina from oxidative stress, nutrient delivery and waste disposal, ionic homeostasis, phagocytosis of photoreceptor outer segments, synthesis and release of growth factors, reisomerization of all-trans-retinal during the visual cycle, and establishment of ocular immune privilege. Age-related macular degeneration (AMD) is the leading cause of blindness in developed countries. Dysfunction of the RPE has been associated with the pathogenesis of AMD in relation to increased oxidative stress, mitochondrial destabilization and complement dysregulation. Photobiomodulation or near infrared light therapy which refers to non-invasive irradiation of tissue with light in the far-red to near-infrared light spectrum (630-1000 nm), is an intervention that specifically targets key mechanisms of RPE dysfunction that are implicated in AMD pathogenesis. The current evidence for the efficacy of photobiomodulation in AMD is poor but its safety profile and proposed mechanisms of action motivate further research as a novel therapy for AMD.

Plasma membrane protein polarity and trafficking in RPE cells: past, present and future

The retinal pigment epithelium (RPE) comprises a monolayer of polarized pigmented epithelial cells that is strategically interposed between the neural retina and the fenestrated choroid capillaries. The RPE performs a variety of vectorial transport functions (water, ions, metabolites, nutrients and waste products) that regulate the composition of the subretinal space and support the functions of photoreceptors (PRs) and other cells in the neural retina. To this end, RPE cells display a polarized distribution of channels, transporters and receptors in their plasma membrane (PM) that is remarkably different from that found in conventional extra-ocular epithelia, e.g. intestine, kidney, and gall bladder. This characteristic PM protein polarity of RPE cells depends on the interplay of sorting signals in the RPE PM proteins and sorting mechanisms and biosynthetic/recycling trafficking routes in the RPE cell. Although considerable progress has been made in our understanding of the RPE trafficking machinery, most available data have been obtained from immortalized RPE cell lines that only partially maintain the RPE phenotype and by extrapolation of data obtained in the prototype Madin-Darby Canine Kidney (MDCK) cell line. The increasing availability of RPE cell cultures that more closely resemble the RPE in vivo together with the advent of advanced live imaging microscopy techniques provides a platform and an opportunity to rapidly expand our understanding of how polarized protein trafficking contributes to RPE PM polarity.

Internalization of Met requires the co-receptor CD44v6 and its link to ERM proteins

Receptor Tyrosine Kinases (RTKs) are involved in many cellular processes and play a major role in the control of cell fate. For these reasons, RTK activation is maintained under tight control. Met is an essential RTK that induces proliferation, differentiation, migration, survival and branching morphogenesis. Deregulation of Met by overexpression, amplification or lack of effective degradation leads to cancer and metastasis. We have shown that Met relies on CD44v6 for its activation and for signaling in several cancer cell lines and also in primary cells. In this paper, we show that internalization of Met is dependent on CD44v6 and the binding of Ezrin to the CD44v6 cytoplasmic domain. Both CD44v6 and Met are co-internalized upon Hepatocyte Growth Factor induction suggesting that Met-induced signaling from the endosomes relies on its collaboration with CD44v6 and the link to the cytoskeleton provided by ERM proteins.

Ouabain inhibition of Na/K-ATPase across the retina prevents signed refractive compensation to lens-induced defocus, but not default ocular growth in young chicks

Purpose: The relevance of retinal integrity and energy pathways to ocular growth and induction of refractive errors has seldom been investigated. Thus, we used ouabain to target the channels that are essential for the maintenance of membrane potentials in cells, sodium potassium ATPase (Na/K-ATPase), to examine refractive compensation and ocular growth in response to lens-induced defocus in the chick.

Methods:  A single intravitreal injection of 1 mM ouabain in dimethyl sulfoxide (DMSO) carrier or DMSO alone was followed by monocular defocus with positive or negative 10 D lens (or no lens) from post-hatching days 5-9 under 12/12 hr light/dark conditions. Biometry and dark-adapted flash and electroretinography (ERG) were conducted on day 9, followed by immunohistological analyses.

Results: Ouabain inhibited differential ocular growth and refractive compensation to signed defocus compared to DMSO. By 4-days post-ouabain injection all components of the typical ERG responses to light had been eliminated, and widespread histological damage was apparent, though some ‘default state’ ocular growth was measurable. Immunohistochemistry demonstrated reduction in the specialized water channel Aquaporin 4 (AQP4) expression and increased evidence of caspase 3 expression (a cell death associated protein) in ouabain-treated eyes compared with DMSO alone.

Conclusion: The current study demonstrates that blockade of photoreceptor and inner retinal responses to light onset and offset by ouabain inhibits differential refractive compensation to optical blur, but does not prevent ocular growth.

Integration of tight junctions and claudins with the barrier functions of the retinal pigment epithelium

The retinal pigment epithelium (RPE) forms the outer blood-retinal barrier by regulating the movement of solutes between the fenestrated capillaries of the choroid and the photoreceptor layer of the retina. Blood-tissue barriers use various mechanisms to accomplish their tasks including membrane pumps, transporters, and channels, transcytosis, metabolic alteration of solutes in transit, and passive but selective diffusion. The last category includes tight junctions, which regulate transepithelial diffusion through the spaces between neighboring cells of the monolayer. Tight junctions are extraordinarily complex structures that are dynamically regulated. Claudins are a family of tight junctional proteins that lend tissue specificity and selectivity to tight junctions. This review discusses how the claudins and tight junctions of the RPE differ from other epithelia and how its functions are modulated by the neural retina. Studies of RPE-retinal interactions during development lend insight into this modulation. Notably, the characteristics of RPE junctions, such as claudin composition, vary among species, which suggests the physiology of the outer retina may also vary. Comparative studies of barrier functions among species should deepen our understanding of how homeostasis is maintained in the outer retina. Stem cells provide a way to extend these studies of RPE-retinal interactions to human RPE.

The retinal pigment epithelium: something more than a constituent of the blood-retinal barrier--implications for the pathogenesis of diabetic retinopathy

The retinal pigment epithelium (RPE) is an specialized epithelium lying in the interface between the neural retina and the choriocapillaris where it forms the outer blood-retinal barrier (BRB). The main functions of the RPE are the following: (1) transport of nutrients, ions, and water, (2) absorption of light and protection against photooxidation, (3) reisomerization of all-trans-retinal into 11-cis-retinal, which is crucial for the visual cycle, (4) phagocytosis of shed photoreceptor membranes, and (5) secretion of essential factors for the structural integrity of the retina. An overview of these functions will be given. Most of the research on the physiopathology of diabetic retinopathy has been focused on the impairment of the neuroretina and the breakdown of the inner BRB. By contrast, the effects of diabetes on the RPE and in particular on its secretory activity have received less attention. In this regard, new therapeutic strategies addressed to modulating RPE impairment are warranted.

The retinal pigment epithelium in visual function

Located between vessels of the choriocapillaris and light-sensitive outer segments of the photoreceptors, the retinal pigment epithelium (RPE) closely interacts with photoreceptors in the maintenance of visual function. Increasing knowledge of the multiple functions performed by the RPE improved the understanding of many diseases leading to blindness. This review summarizes the current knowledge of RPE functions and describes how failure of these functions causes loss of visual function. Mutations in genes that are expressed in the RPE can lead to photoreceptor degeneration. On the other hand, mutations in genes expressed in photoreceptors can lead to degenerations of the RPE. Thus both tissues can be regarded as a functional unit where both interacting partners depend on each other.

A comparison of caveolae and caveolin-1 to folate receptor alpha in retina and retinal pigment epithelium

Caveolae are flask-shaped membrane invaginations present in most mammalian cells. They are distinguished by the presence of a striated coat composed of the protein, caveolin. Caveolae have been implicated in numerous cellular processes, including potocytosis in which caveolae are hypothesized to co-localize with folate receptor alpha and participate in folate uptake. Our laboratory has recently localized folate receptor alpha to the basolateral surface of the retinal pigment epithelium (RPE). It is present also in many other cells of the retina. In the present study, we asked whether caveolae were present in the RPE, and if so, whether their pattern of distribution was similar to folate receptor alpha. We also examined the distribution pattern of caveolin-1, which can be a marker of caveolae. Extensive electron microscopical analysis revealed caveolae associated with endothelial cells. However, none were detected in intact or cultured RPE. Laser scanning confocal microscopical analysis of intact RPE localized caveolin-1 to the apical and basal surfaces, a distribution unlike folate receptor alpha. Western analysis confirmed the presence of caveolin-1 in cultured RPE cells and laser scanning confocal microscopy localized the protein to the basal plasma membrane of the RPE, a distribution like that of folate receptor alpha. This distribution was confirmed by electron microscopic immunolocalization. The lack of caveolae in the RPE suggests that these structures may not be essential for folate internalization in the RPE.

Expression and differential polarization of the reduced-folate transporter-1 and the folate receptor alpha in mammalian retinal pigment epithelium

The differential polarized distribution of the reduced- folate transporter (RFT-1) and folate receptor alpha (FRalpha), the two proteins involved in the transport of folate, has been characterized in normal mouse retinal pigment epithelium (RPE) and in cultured human RPE cells. RPE cells mediate the vectorial transfer of nutrients from choroidal blood to neural retina. Whereas FRalpha is known to be present in many cell types of the neural retina, in situ hybridization analysis in the present study demonstrated that RFT-1 is present only in RPE. Laser-scanning confocal microscopy using antibodies specific for RFT-1 demonstrated an apical distribution of this protein in cultured human and intact mouse RPE, which contrasts with the basolateral distribution of FRalpha in these cells. The expression of RFT-1 in the RPE cell apical membrane was confirmed by functional studies with purified apical membrane vesicles from bovine RPE. These studies, done with N(5)-methyltetrahydrofolate (the predominant folate derivative in blood) and folate as substrates, have shown that RFT-1 functions in a Na(+)- and C1(-)-independent manner. The transporter is specific for folate and its analogs. A transmembrane H(+) gradient influences the transport function of this protein markedly; the transport mechanism is likely to be either folate/H(+) co-transport or folate/OH(-) exchange. Based on the differential polarization of FRalpha and RFT-1 in RPE, we suggest that these two proteins work in a concerted manner to bring about the vectorial transfer of folate across the RPE cell layer from the choroidal blood to the neural retina. This constitutes the first report of the differential polarization of the two folate transport proteins in any polarized epithelium.

A Na+/Ca2+ exchange mechanism in apical membrane vesicles of the retinal pigment epithelium

The retinal pigment epithelium (RPE) lying between the neural retina and the choroid, performs as a transport organ for solutes and water between the choriocapillaries and the subretinal space. It also has the function to maintain the microenvironment of photoreceptors including the regulation of calcium ions during light or dark adaptation. In order to further elucidate the transport functions of the RPE, apical membranes were isolated from RPE by differential precipitation with divalent ions. In this work bovine tissues were used as well as elasmobranch tissues. For the latter, we have already purified and characterized membrane vesicles in a previous paper. Na(+)-K(+)-ATPase, alkaline phosphatase, and 5'-nucleotidase, which are marker enzymes of the apical membrane, were highly enriched in the final membrane fraction. The majority of the fraction consists of right side out vesicles. The fluorescent indicator for sodium, SBFI, or the calcium specific indicator, Fura-2, were pre-loaded into the apical membrane vesicles of RPE of either dogfish eyes or bovine eyes. When an outwardly-directed Ca2+ gradient was formed across the vesicular membranes, the Ca2+ influx was also enhanced by 136% for dogfish RPE and 167% for bovine RPE. This Na+ gradient dependent Ca2+ influx was blocked by bepridil, an antiarrhythmic agent which is a Na+/Ca2+ exchanger inhibitor. These results indicate that a Na+/Ca2+ exchanger is present in the apical membrane of bovine and dogfish RPE.

Modulation of potassium transport in cultured retinal pigment epithelium and retinal glial cells by serum and epidermal growth factor

The ionic environment of retinal photoreceptors is partially controlled by potassium transporters on retinal glial and retinal pigment epithelial cells (RPE). In this study, serum and epidermal growth factor (EGF) were examined as modulators of potassium transport in confluent cultures of human RPE and rabbit retinal glia. EGF is a known mitogen for confluent RPE cultures and was shown here to also stimulate [3H]thymidine incorporation in cultures of retinal glia. For potassium transport studies 86Rb was used as a tracer during a 17-min incubation. For both retinal cell types the mean total 86Rb uptake in 10% serum was approximately 60% above basal, serum-free controls. For EGF, tested in several experiments in a concentration range from 1 to 100 ng/ml, maximal total uptake was 33 and 24% above controls for RPE and glia, respectively. Inhibitor studies suggested that basal and serum-stimulated uptake for both cell types occurred by the ouabain-sensitive Na-K ATPase pump and by the furosemide- or bumetanide-sensitive Na-K-Cl cotransporter. EGF-stimulated uptake appeared to be due predominantly to the cotransporter. The data suggest that serum components and EGF, which may be available to retina-derived cells under pathologic conditions, may not only stimulate proliferation but may also act as short-term modulators of potassium ion movement and thus affect physiologic processes that are sensitive to ion homeostasis.

The gamma-aminobutyric acid transporter and its interaction with taurine in the apical membrane of the bovine retinal pigment epithelium

The characteristics of gamma-aminobutyric acid (GABA) uptake were investigated in apical membrane vesicles prepared from the bovine retinal pigment epithelium. An inwardly directed NaCl gradient stimulated GABA uptake markedly, and the time course of uptake exhibited an overshoot phenomenon indicating the presence of an active transport mechanism for GABA in these membranes. Other monovalent cations were not capable of substituting for Na+. In addition to this obligatory requirement for Na+, the GABA uptake also exhibited a Cl(-)-dependence, evident from the observations that the uptake was negligible in the presence of NaF or sodium gluconate in place of NaCl. NO3- and SCN- could substitute for Cl- to some extent. The uptake process was electrogenic, with a Na+/Cl-/GABA stoichiometry of 2:1:1 or 3:1:1. Substrate-specificity studies showed that the beta-amino acids such as taurine, hypotaurine and beta-alanine interacted with the GABA uptake process. Uptake of GABA could be completely inhibited by an excess of taurine and, similarly, uptake of taurine could be completely inhibited by an excess of GABA, suggesting that common transport processes operate in the uptake of these two compounds. However, a number of compounds which are specific inhibitors of GABA uptake inhibited taurine uptake only to a maximum of 50%. Kinetic analysis of GABA uptake in the concentration range 0.1-10 microM revealed that the uptake occurred via a single system and that taurine was a competitive inhibitor of this system. The Michaelis-Menten constant (Kt) for GABA was 0.94 microM and the apparent inhibition constant (Ki) for taurine was 230 microM. On the contrary, even though the kinetic analysis of taurine uptake in the concentration range 25-150 microM revealed participation of a single system in the uptake process, the inhibition of taurine uptake by GABA was not competitive. The presence of GABA decreased the maximal velocity of the taurine uptake process and also decreased the Kt for taurine. Based on these data, it is proposed that: (i) there are two distinct transport systems, namely the GABA transporter and the taurine transporter, in these membranes which accept both GABA and taurine as substrates, (ii) the affinities of these systems for taurine are very similar and cannot be kinetically distinguished under the experimental conditions employed, and (iii) the difference between the affinities of these system for GABA is much greater than for taurine.

Apical and basal membrane ion transport mechanisms in bovine retinal pigment epithelium

1. Intracellular voltage recordings using conventional and double-barrelled chloride-selective microelectrodes have been used to identify several transport mechanisms at the apical and basolateral membranes of the isolated bovine retinal pigment epithelium (RPE)-choroid preparation. Intracellular recordings were obtained from two cell populations, melanotic (pigmented) and amelanotic (non-pigmented). The electrical properties of these two populations are practically identical. For melanotic cells the average apical resting membrane potential (VA) is -61 +/- 2 mV (mean +/- S.E.M., n = 49 cells, thirty-three eyes). For these cells the ratio of apical to basolateral membrane resistance (a) was 0.22 +/- 0.02. The mean transepithelial voltage and resistance were 6 +/- 1 mV and 138 +/- 7 omega cm2, respectively. 2. The apical membrane, which faces the distal retina, contains a Ba(2+)-inhibitable K+ conductance and a ouabain-inhibitable, electrogenic Na(+)-K+ pump. In addition it contains a bumetanide-sensitive mechanism, the putative Na(+)-K(+)-Cl- cotransporter. The basolateral membrane contains a DIDS (4,4'-diisothiocyanostilbene-2,2'-disulphonic acid)-inhibitable chloride channel. The relative conductances of the apical and basolateral membranes to K+ and Cl- are TK approximately 0.9 and TCl approximately 0.7, respectively. 3. The ouabain-induced fast phase of apical membrane depolarization (0-30 s) was used to calculate the equivalent resistances of the apical (RA) and basolateral (RB) cell membranes, as well as the paracellular or shunt resistance (RS). They are: 3190 +/- 400, 17920 +/- 2730 and 2550 +/- 200 omega (mean +/- S.E.M., n = 9 tissues), respectively. From these data the equivalent electromotive forces (EMF) at the apical (EA) and basolateral (EB) membranes were also calculated. They are: -69 +/- 5.0 and -24 +/- 5.0 mV, respectively. 4. Intracellular Cl- activity (aiCl) was measured using double-barreled ion-selective microelectrodes. In the steady state aiCl = 61 +/- 4.0 mM and the Nernst potential ECl = -13.5 +/- 1.5 mV (mean +/- S.E.M., n = 4). 5. In the intact eye or in retina, RPE-choroid preparations it has been shown that the transition between light and dark alters the K+ concentration in the extracellular (or subretinal) space between the photoreceptors and the apical membrane of the RPE. These light-induced changes in subretinal [K+]o were qualitatively simulated in vitro by altering apical K+ between 5 and 2 mM. This produced a sequence of voltage changes at the apical and basolateral membranes that had three operationally distinct phases. Phase 1 is generated by the combination of an apical membrane K+ diffusion potential and inhibition of the electrogenic Na(+)-K+ pump.(ABSTRACT TRUNCATED AT 400 WORDS)

Na+, K(+)-ATPase of the photoreceptor: selective expression of alpha 3 and beta 2 isoforms

In photoreceptors, Na+, K(+)-ATPase maintains the ion gradients which power the dark current that sustains the response to light. The enzyme is composed of at least two polypeptides: alpha (the catalytic subunit) and beta. Three different isoforms of the alpha subunit and two isoforms of the beta subunit have been identified in rat. In some tissues, the isoenzymes have been shown to be differentially expressed during development or in response to varying physiological conditions. RNAs prepared from isolated photoreceptors and from whole retina were analyzed on blots that were hybridized with cDNA probes for the alpha 1, alpha 2, alpha 3, beta 1 and beta 2 isoforms. The predominant alpha and beta subunit mRNAs present in the photoreceptor preparation were those encoding the alpha 3 and beta 2 isoforms, accounting for 85% of the total alpha signal and 79% of the total beta signal, respectively. Proportions of each mRNA were similar in retina, but very different from those observed in two control tissues, brain and kidney. To confirm that the alpha-subunit mRNA species detected were translated, membranes prepared from isolated photoreceptors and whole retina were examined by immunoblotting. The antibodies detected a pattern of alpha isoform distribution in these tissues and in kidney and brain controls that agreed remarkably well with the pattern of mRNA expression in the same tissues. Moreover, the alpha 3 isoform was detectable in the inner segment plasma membrane of the photoreceptor by electron microscopic immunocytochemistry. These results indicate that alpha 3, and beta 2 are the predominant isoforms of Na+, K(+)-ATPase expressed in photoreceptors and retina.

Regulation of MI transport in retinal pigment epithelium by sugars, amiloride, and pH gradients: potential impairment of pump-leak balance in diabetic maculopathy

Impairment of transport and metabolism of retinal pigment epithelium (RPE) has been recognized to play a role in the development of diabetic macular edema. To understand the mechanism(s) of action of high glucose levels in alteration of RPE metabolism, primary cultures of RPE cells were used as an in vitro model of diabetic retinopathy/maculopathy. RPE cells were grown with 5 mM (control) or 40 mM glucose (a monosaccharide that enters the cells), or 40 mM sucrose (a disaccharide that does not enter the cells), and the extent of Na(+)-dependent active transport of an osmolyte ([3H]-myo-inositol, MI, 10 microM) into cells was determined. While 40 mM glucose down-regulated 3H-MI transport, 40 mM sucrose stimulated it, compared to 5 mM glucose feeding. Addition of 1 mM amiloride, an inhibitor of Na+/H+ exchanger, in the incubation media, significantly inhibited MI transport. Cells treated with high sucrose or high glucose were more sensitive toward amiloride inhibition, compared to controls. Inhibition of either pump or leak pathway alone was not sufficient to completely inhibit MI transport, but simultaneous inhibition of both pathways, by amiloride and ouabain (1 mM each), strongly inhibited osmolyte accumulation. The strongest inhibition of uptake occurred when 150 mM NaCl in the incubation media was replaced by 150 mM choline-Cl, and the percent inhibition of uptake, with choline-Cl, was highest with sucrose-fed cells, compared to normal or high glucose-fed cells. Imposition of a pH gradient [pHi (6.1) less than pH0 (8.0)] across the cell membrane, a condition that stimulates Na+/H+ exchange activity, also reduced MI accumulation. Cellular water content, measured by the extent of [3H]-3-O-methyl glucose uptake, in the presence of balanced salt solution (BSS), BSS containing half the ionic strength (hypotonic solution), or BSS containing 20 mM K+, for induction of cell swelling, varied when cells were fed with various sugars. Cells fed with high glucose were less sensitive toward media tonicity compared to normal. These results suggested that in cultured RPE cells, changes in Na+/H+ exchanger activity (intracellularly or extracellularly), through its inhibition by amiloride, its activation via intracellular acidification, or perhaps by chronic feeding with high sucrose or high glucose, affected the Na(+)-dependent active accumulation of MI. A metabolic factor involved in the development of diabetic macular edema is perhaps associated with glucose-induced alterations in Na+ fluxes (e.g., changes in Na+/H+ exchanger activity), which can secondarily influence osmolyte accumulation, impairment of pump-leak balance, and/or intracellular pH.(ABSTRACT TRUNCATED AT 400 WORDS)

Active ion transport pathways in the bovine retinal pigment epithelium

1. Radioactive tracer flux measurements demonstrate that active ion transport across the isolated bovine retinal pigment epithelium (RPE)-choroid preparation can be maintained for hours after the eye is enucleated and the tissue removed from the eye. 2. It has been shown that 86Rb tracer fluxes can be used to monitor potassium (K+) transport across bull-frog RPE. In bovine RPE, net 86Rb (K+) absorption is zero. Apical barium (Ba2+) elevated active K+ absorption from zero to approximately 0.3 mu equiv cm-2 h-1. This Ba2(+)-induced increase in active K+ absorption was inhibited either by ouabain or bumetanide in the apical bath. 3. In control Ringer solution, buffered with bicarbonate and CO2, the RPE-choroid actively absorbs chloride (Cl-) at a rate of approximately 0.5 mu equiv cm-2 h-1. In contrast, sodium (Na+) is secreted at a rate of approximately 0.5 mu equiv cm-2 h-1. Chloride absorption was inhibited by apical bumetanide, and Na+ secretion was inhibited by apical ouabain. These drugs were only effective when placed in the solution bathing the apical or retinal side of the tissue. 4. Net Cl- absorption requires an exit mechanism at the basolateral membrane. DIDS (4,4'-diisothiocyanostilbene-2,2'-disulphonic acid) in the basal bath completely inhibited net Cl- absorption in bicarbonate-free Ringer solution. 5. These experiments show that the chloride transport pathway contains at least two components: (1) a bumetanide-sensitive uptake mechanism at the apical membrane; and (2) an efflux mechanism at the basolateral membrane that is blocked by DIDS. 6. Three apical membrane mechanisms were identified that could help modulate [K+]o in the subretinal or extracellular space that separates the distal retina and the RPE apical membrane. They are: (1) an ouabain-sensitive Na(+)-K+ pump; (2) a bumetanide-sensitive mechanism, the putative Na(+)-K(+)-Cl- co-transporter; (3) a barium-sensitive K+ channel that recycles, to the apical bath, most or all of the potassium that is actively taken up by the Na(+)-K+ pump and the co-transporter. 7. These data suggest that light-induced alterations in subretinal potassium that occur in vivo can activate the chloride transport pathway and help modulate RPE intracellular Cl- during transitions between the light and dark.

Partial characterization of a high affinity [Ca2+ + Mg2+]-dependent adenosinetriphosphatase from bovine retina

Examination of retinal tissue homogenates indicated the presence of a [Ca2+ + Mg2+]-dependent adenosinetriphosphatase activity that exhibited high affinity for Ca2+ (K0.5 = 0.17 microM) and moderately high affinity for Mg2+ and ATP (K0.5 = 12.5 microM and Km = 22.8 microM, respectively). Maximum ATP hydrolysis occurred at pH 7.4. Under conditions of optimal substrate, cation and hydrogen ion concentrations, specific activity ranged from 15 to 18 nmol phosphate released min-1 mg-1 protein. Although the retinal [Ca2+ + Mg2+] adenosinetriphosphatase hydrolyzes both ATP and dATP, other nucleotides (CTP, GTP, ITP and UTP) were not hydrolyzed to any great extent. The monovalent cations, Li+, K+ and Na+, had no effect upon hydrolysis of ATP; whereas Cs+ and NH4+ ions were moderately (approximately 30%) inhibitory. All divalent cations tested were stimulatory. With the exception of rotenone which inhibited ATP hydrolysis approximately 25%; retinal adenosinetriphosphatase activity was insensitive to mitochondrial inhibitors (NaN3, KCN, ruthenium red and oligomycin). Adenosinetriphosphatase activity was observed to be very sensitive to low concentrations (I50 approximately 2 microM) of vanadate; whereas, lanthanum administration resulted in no inhibition. Removal of calmodulin (80%) resulted in reducing adenosinetriphosphatase activity 60% but addition of exogenous calmodulin back to calmodulin deficient membranes did not restore activity to starting levels. Calmodulin antagonists trifluoperazine and calmidazolium reduced significantly Ca2+ stimulated, Mg2+ dependent ATP hydrolysis. We conclude that the [Ca2+ + Mg2+]-dependent adenosinetriphosphatase of bovine retina is a non-mitochondrial protein exhibiting very high affinity for Ca2+ and appears to require calmodulin for maximum activity. Because of its high affinity for Ca2+, this protein may play an important role in reducing intracellular Ca2+ to nanomolar levels.

Retinal pigment epithelial cell plasma membrane: a monoclonal antibody study

The plasma membranes of retinal pigment epithelial cells are highly specialized organelles with multiple functions including nutritional and metabolic support of the photoreceptor cells. Using purified bovine retinal epithelial cell plasma membranes as antigen, we produced two monoclonal antibodies, MAbD1-C6 and MAbD1-C8, that cross react with the plasma membranes from bovine, rat and human retinal pigment epithelial cells. In radioimmunoassay both MAbD1-C6 and MAbD1-C8 had similar affinities for bovine plasma membranes. Both monoclonal antibodies identified a protein of 72 Kd with an apparent subunit of 32-35 Kd. The protein was localized to the cell surface of human and bovine retinal pigment epithelium by immunocytohistochemistry. In the normal eye the antigen identified by the monoclonal antibodies was strongly associated with the retinal pigment epithelium and weakly associated with lens tissue. Using either monoclonal antibody, components of purified bovine or rat retinal pigment epithelial plasma membranes were precipitated from solution. Based on these results, we conclude that both monoclonal antibodies are closely related and that they may be useful for the isolation and study of retinal pigment epithelial cell structure.

Regulation of intracellular pH in cultured bovine retinal pigment epithelial cells

Regulation of intracellular pH (pHi) in bovine retinal pigment epithelium (RPE) was investigated in cell culture. pHi was measured using the pH-sensitive absorbance of intracellularly trapped 5 (and 6)-carboxy-dimethyl-fluorescein (CDMF). (1) Regulation of pHi after induction of an acid load by removal of NH4Cl could be blocked either totally by removal of extracellular sodium, or subtotally (about 90%) by application of amiloride (1 mmol/l). Additional flux measurements revealed a dose-dependent, amiloride-sensitive 22Na+-uptake into Na+-loaded cells. Both results suggest the presence of a Na+/H+ antiport. (2) When alkalinization of the cells was induced by preincubation with 50 mmol/l acetate in HCO3(-)-Ringer's and subsequent removal of the weak acid, the following regulation was dependent on the presence of extracellular chloride. This process could be blocked with DIDS (1 mmol/l), suggesting the presence of a Cl-/HCO3- exchange mechanism. (3) We found no evidence for a Na+/HCO3(-)-cotransport, which had been postulated to be present in RPE by others. We conclude that two processes are involved in regulation of pHi in RPE: A Na+/H+ antiport responsible for recovery of pHi from acid load, and a DIDS-sensitive Cl-/HCO3- exchange mechanism responsible for recovery of pHi after alkalinization.

cAMP stimulates the Na+-K+ pump in frog retinal pigment epithelium

Adenosine 3', 5'-cyclic monophosphate (cAMP) induced increases in active Na+ secretion and K+ absorption that were blocked by apical ouabain (10(-4) M), suggesting stimulation of the Na+-K+ pump. cAMP also produced rapid membrane voltage and resistance changes that could be divided chronologically into three phases. In phase 1, the basolateral membrane depolarized at a faster rate than the apical membrane, probably as a result of an increase in basolateral membrane conductance. In phase 2, the apical membrane repolarized toward control faster than the basal membrane, whereas in phase 3 the basolateral membrane repolarized faster than the apical membrane. Apical ouabain completely inhibited the cAMP-induced repolarization of the apical membrane during phase 2. Thus the stimulation of the Na+-K+ pump occurs within minutes of cAMP elevation. Na+ removal from the basal side did not block the cAMP-induced voltage changes, indicating that the initial conductance increase is not due to Na+. In contrast, Na+ removal from the apical bath inhibited all phases of the cAMP response. This suggests that apical membrane Na+-dependent transport mechanisms mediate the stimulation of the Na+-K+ pump. cAMP also caused a significant drop in intracellular K+ activity (approximately 5 mM) that preceded phase 2. This drop could stimulate the Na+-K+ pump, as suggested by previous experiments.

Lectin-affinity isolation of microvillous membranes from the pigmented epithelium of rat retina

The pigmented epithelium of the vertebrate retina phagocytizes the discarded tips of photoreceptors and it is likely that a specific cellular recognition process is involved in this phenomenon. The apical surface of retinal pigmented epithelium (RPE) contains microvilli which interdigitate with the outer segment regions of photoreceptor cells and it is this apical microvillous surface that is of particular interest with respect to phagocytosis. The present study is a report of a method to isolate a fraction that is enriched in microvilli from the apical surface of this highly polarized epithelial cell. Wheat germ agglutinin (WGA) conjugated sepharose beads are used to remove the microvillous membranes which are then observed with scanning and transmission electron microscopy. The proteins of this RPE-subfraction are separated through use of SDS-polyacrylamide gel electrophoresis. The relative molecular weights (Mr) and lectin binding properties of glycoproteins are examined in Western blots through the use of lectin-peroxidase conjugates as probes for carbohydrate residues. A preliminary comparison of membranes isolated from Long Evans (normal) and Royal College of Surgeons (dystrophic) rat retina RPE shows that the glycoproteins in these two preparations are different with respect to the binding of Concanavalin-A (Con-A) and WGA. In particular a glycoprotein in the normal RPE preparation with a Mr of 175K binds Con-A and WGA, but in the dystrophic RPE preparation binds little or no WGA. A glycoprotein present in the normal RPE preparation with a Mr of 86K binds Con-A and WGA, but both lectins have reduced binding sites in the dystrophic preparation. Limax flavus agglutinin (specific for sialic acid residues) binds to a high molecular weight glycoprotein with a Mr of 195K-196K which is present in both normal and dystrophic RPE membrane preparations and which also binds Con-A and WGA.

Examination of sialic acid binding on dystrophic and normal retinal pigment epithelium

In order to study differences in cell-surface sugars which may be involved in the phagocytic defect in Royal College of Surgeons (RCS) retinas, we have examined the presence or absence of lectin binding to carbohydrates on retinal pigment epithelial (RPE) plasma membranes of dystrophic (RCS-p+) and normal (Long-Evans) rats. A lectin which binds to both sialic acid and N-acetylglucosamine sugar residues, wheat germ agglutinin-ferritin (WGA-fe), was used. The specificity of WGA-fe binding to each sugar was studied by either pre-treating the tissue with neuraminidase enzyme which removes sialic acid residues, or by incubating the WGA-fe lectin with one of the haptens, N-acetylglucosamine. In non-enzyme-treated tissue, RPE cell-surface membranes from RCS retinas were densely labeled with WGA-fe as compared with the labeling on normal RPE, which appeared less dense and patchy in distribution. Wheat germ agglutinin-ferritin labeling in the presence of N-acetylglucosamine was blocked on both RCS and normal RPE surface membranes. After pre-treatment with neuraminidase, WGA-fe labeling on dystrophic RPE membranes was similar to non-enzyme-treated tissue but was enhanced on normal RPE. Labeling was blocked when N-acetylglucosamine was present with the lectin after enzyme pre-treatment. Other lectins which specifically bind to sialic acid, Limulus polyphemus agglutinin-ferritin (LPA-fe) and Limax flavus agglutinin (LFA) demonstrated sparse or no labeling on both RCS and normal RPE membranes. Our data suggests that N-acetylglucosamine residues predominate on RCS and normal RPE cell-surface membranes and that sialic acid binding sites are either not accessible to the lectins or may not be present.

Potassium transport of the frog retinal pigment epithelium: autoregulation of potassium activity in the subretinal space

The K+ transport of the isolated retinal pigment epithelium from the bull-frog was studied using micropuncture with double-barrelled ion-selective micro-electrodes. Transient changes of intracellular values of electrical potential and K+ activity were monitored in response to abrupt changes in the K+ concentration on the retinal side of the tissue. The data were interpreted in terms of a simple three-compartment model of the epithelium in which the retinal (or apical) and choroidal (or basal) membranes separate the cellular compartment from the retinal and choroidal compartments. K+ transport across the retinal membrane was described by an active ouabain-sensitive K+ influx in parallel with a passive electrodiffusive K+ efflux. In steady state under control conditions, the active K+ influx (pump rate) averaged 0.18 X 10(-9) mol cm-2 s-1. The electrodiffusive K+ efflux was described by a K+ permeability, which in steady state under control conditions averaged 1.7 X 10(-5) cm s-1. K+ transport across the choroidal membrane was described as purely electrodiffusive. In steady state under control conditions, the K+ permeability of the choroidal membrane averaged 0.6 X 10(-5) cm s-1. When the K+ concentration on the retinal side of the tissue was increased from its control value, the K+ permeability of the retinal membrane decreased and the K+ permeability of the choroidal membrane increased. This caused the epithelium to attain a new steady state in which the cells transported K+ away from the retinal compartment at a high rate. When the K+ concentration on the retinal side of the tissue was decreased from its control value, the K+ permeability of the retinal membrane increased and the pump rate decreased. This caused the epithelial cells to transport K+ from the cellular compartment into the retinal compartment. In effect, the K+ transport of the retinal pigment epithelium depends on the K+ concentration in the retinal compartment in such a way as to keep variations in this concentration at a minimum.

Interactions of pH and K+ conductance in cultured bovine retinal pigment epithelial cells

Passive ion transport properties were studied in confluent monolayers of cultured bovine retinal pigment epithelial cells using intracellular microelectrode technique. The mean stable intracellular (designated by subscript i) potential was -59.1 +/- 0.8 (SE) mV. Extracellular (designated by subscript o) acidification induced a depolarization, whereas alkalinization induced a hyperpolarization. These effects were observed both in bicarbonate-free as well as in HCO3- Ringer (pHo changed by varying [HCO3-]o at constant pCO2). Acidification of pHi (changed by addition and removal of butyrate, CO2 or NH3) also caused a depolarization. Complete removal of HCO3-/CO2 at constant pHo caused a hyperpolarization. K+ transference, checked by applying high K+o, increased with K+o. It decreased with both extra and intracellular acidification and increased with alkalinization. In the presence of Ba2+, voltage reactions to changes in either pHo or pHi were greatly reduced. Depolarization by 40 mM K+ caused a similar reduction. It is suggested that K+ conductance of bovine retinal pigment epithelial cells is reduced by either intra- or extracellular acidification at normal [K+]o. Depolarization by high K+ induces an increase in K+ transference and reduces pH sensitivity.

Isolation of plasma membranes from the bovine retinal pigment epithelium

Retinal pigment epithelium plasma membranes have been isolated by differential and density gradient centrifugation of glass-bead-bound, collagenase-treated cells. Electron microscopic evidence indicates that the glass-bead-bound cells were devoid of red blood cells, rod outer segments and other ocular cell contaminants. The plasma membranes were recovered in 4-6 micrograms/eye yields and purified 10-fold by 5'-nucleotidase and alkaline phosphodiesterase I, and 6.5-fold by (Na+ + K+)-ATPase. Plasma membrane purity as measured by covalent labeling of the epithelial cell plasma membrane proteins with p-(diazonium) benzene[32S]sulfonic acid was 8-19-fold. In purified plasma membranes contamination by mitochondria was undetectable and lysosomal contamination reduced 100-fold, while endoplasmic reticulum was 2-fold enriched. SDS-polyacrylamide gel electrophoresis of the plasma membrane proteins revealed 23-26 major bands by Coomassie blue staining and 12-16 major bands by radioactive labeling. The plasma membranes exhibited a 3-fold lower concentration of docosahexaenoic acid, a 3-fold higher cholesterol/phosphate ratio, and were 10-fold enriched in cholesterol per micrograms protein when compared to the whole cell fraction. Retinal epithelial plasma membranes contain an average of 1 mol cholesterol per mol of lipid phosphorus, a high palmitic acid concentration (39 mol%) and a low concentration of docosahexaenoic acid (2 mol%). The lipid profile of the retinal pigment epithelial plasma membranes indicates that they are typical of plasma membranes from many other cell types and that they appear to be less fluid than total rod outer segment membranes.

Localization of the Na-K pump in turtle retina

The kinetics of ouabain binding to Na-K pump and the distribution of pump sites were examined in the retina of Pseudemys scripta elegans. Binding to retinal slices followed bimolecular kinetics characterized by a KD of 1.5 X 10(-6) M and a maximum binding capacity of 11.2 X 10(-8) mol g-1 of protein. Quantitative autoradiography of slices revealed a high concentration of bound ouabain in the inner segment, outer plexiform, inner plexiform and optic nerve layers, and correspondingly, a low level of binding in layers containing cell bodies. In the few instances that outer segments remained attached to cones, little or no binding to outer segments was observed. The membrane density of inner segment binding sites was measured by combining autoradiographic measurements of pump site concentration with stereological measurements of membrane concentration. The densities were 6.3 and 3.7 X 10(3) sites micron-2 of cone-ellipsoid and cone-fin cell membrane, respectively. The density of Müller cell microvilli was measured similarly but in enzymatically isolated cells and found to be 600 sites micron-2 of membrane. Measurements of Measurements of cone-ellipsoid pump site density in enzymatically isolated cones were not different from measurements in slices. Calculation of Na-K pump site turnover number for the cone inner segment from pump site densities and published dark current measurements yielded a value of 30 Hz.

Redistribution of Na-K-ATPase in the dystrophic rat retinal pigment epithelium

Our previous studies have shown that a breakdown in tight junctions in the dystrophic retinal pigment epithelium (RPE) of Royal College of Surgeons' rats is accompanied by changes in intramembrane structure which suggest a redistribution of intramembrane particles. We have now investigated, using the p-nitrophenyl phosphate technique, the possibility that a specific membrane protein, Na-K-ATPase, is redistributed as tight junctions break down in the dystrophic RPE. In the normal RPE, Na-K-ATPase activity is restricted to the apical membrane. Junctional membranes and membranes around phagosomes are free of enzyme activity, suggesting a segregation of the transport enzyme from the junctional and phagocytic membrane. In the dystrophic RPE, prior to changes in tight junctions, enzyme activity is restricted to the apical membrane. During the initial stages of junctional breakdown, junctional membranes and membranes around cytoplasmic inclusions are also labelled. As the breakdown progresses, Na-K-ATPase activity is often present laterally and basolaterally and is sometimes absent apically. Enzyme activity is seen basally only where RPE cells have detached from Bruch's membrane and are superimposed over each other. These changes suggest that Na-K-ATPase redistributes during junctional breakdown, but that attachments between the RPE and Bruch's membrane may restrict the redistribution. The apparent reduction of enzyme activity apically suggests that active transport across the dystrophic RPE may be reduced as the tight junctions break down.

Identification of some plasma membrane proteins of cultured rat pigment epithelial cells by labeling with 125I

Cultured rat retinal pigment epithelial (PE) cells were labeled with 125I by lactoperoxidase (LPO)-catalyzed radioiodination. Examination of 125I-labeled cells by electron microscopic autoradiography suggested that 125I was incorporated into proteins at both the apical and basal surfaces of the PE cells, and into the extracellular matrix (ECM). Analysis of labeled cells by SDS-polyacrylamide gel electrophoresis and autoradiography showed that 125I was incorporated into at least 15 polypeptides. In order to determine which of these labeled proteins were derived from the plasma membrane. 125I-labeled cells were subjected to differential detergent extraction. Triton X-100 (2% v/v), which removed the cell plasma membrane, solubilized only three of the labeled proteins (152 000, 138 000, 123 000 daltons). SDS (0.25% w/v) completely removed cells from the tissue culture dish and solubilized all but four of the labeled proteins (225 000, 173 000, 87 000 and 72 100 daltons). When 125I-labeled PE cells were mechanically disrupted, and the resulting cell fractions separated by sucrose density gradient centrifugation, labeled proteins separated into two subcellular fractions. One fraction was especially enriched in the 152 000, 138 000 and 123 000 dalton labeled proteins, in addition to the plasma membrane marker enzymes Na+, K+-ATPase, and alkaline phosphodiesterase I. The second fraction was enriched in the 225 000, 196 000 and 173 000 dalton labeled proteins, the ECM proteins laminin and fibronectin, and the 43 000 actin band . It is proposed that 125I-labeled proteins in the former cell fraction are truly plasma membrane proteins, while those found in the latter cell fraction are a mixture of 125I-labeled ECM and basal plasma membrane proteins. The 152 000, 138 000 and 123 000 dalton labeled proteins of the plasma membrane fraction are glycoproteins and become firmly anchored to the Triton X-100 insoluble cytoskeleton when labeled cells are treated with concanavalin A.

Reaccumulation of [K+]o in the toad retina during maintained illumination

Using K+-selective microelectrodes, [K+]o was measured in the subretinal space of the isolated retina of the toad, Bufo marinus. During maintained illumination, [K+]o fell to a minimum and then recovered to a steady level that was approximately 0.1 mM below its dark level. Spatial buffering of [K+]o by Müller (glial) cells could contribute to this reaccumulation of K+. However, superfusion with substances that might be expected to block glial transport of K+ had no significant effect upon the reaccumulation of K+. These substances included blockers of gK (TEA+, Cs+, Rb+, 4-AP) and a gliotoxin (alpha AAA). Progressive slowing of the rods' Na+/K+ pump (perhaps caused by a light-evoked decrease in [Na+]i) also could contribute to this reaccumulation of K+ by reducing the uptake of K+ from the subretinal space. As evidence for a major contribution by this mechanism, treatments designed to prevent such slowing of the pump reversibly blocked reaccumulation. These treatments included superfusion with 2 microM ouabain, or lowering [K+]o, PO2, or temperature. It is likely that such treatments inhibit the pump, increase [Na+]i, and attenuate any light-evoked decrease in [Na+]i. The results are consistent with the following hypothesis. At light onset, the decrease in rod gNa will reduce the Na+ influx and the resulting rod hyperpolarization will reduce the K+ efflux. In combination with these reduced passive fluxes, the continuing active fluxes will lower both [K+]o and [Na+]i, which in turn will inhibit the pump. In support of this hypothesis, the solutions to a pair of coupled differential equations that model changes in both [K+]o and [Na+]i match quantitatively the time course of the observed changes in [K+]o during and after maintained illumination for all stimuli examined.

Cyclic AMP modulation of ion transport across frog retinal pigment epithelium. Measurements in the short-circuit state

In the frog retinal pigment epithelium (RPE), the cellular levels of cyclic AMP (cAMP) were measured in control conditions and after treatment with substances that are known to inhibit phosphodiesterase (PDE) activity (isobutyl-1-methylxanthine, SQ65442) or stimulate adenylate cyclase activity (forskolin). The cAMP levels were elevated by a factor of 5-7 compared with the controls in PDE-treated tissues and by a factor of 18 in forskolin-treated tissues. The exogenous application of cAMP (1 mM), PDE inhibitors (0.5 mM), or forskolin (0.1 mM) all produced similar changes in epithelial electrical parameters, such as transepithelial potential (TEP) and resistance (Rt), as well as changes in active ion transport. Adding 1 mM cAMP to the solution bathing the apical membrane transiently increased the short-circuit current (SCC) and the TEP (apical side positive) and decreased Rt. Microelectrode experiments showed that the elevation in TEP is due mainly to a depolarization of the basal membrane followed by, and perhaps also accompanied by, a smaller hyperpolarization of the apical membrane. The ratio of the apical to the basolateral membrane resistance increased in the presence of cAMP, and this increase, coupled with the decrease in Rt and the basolateral membrane depolarization, is consistent with a conductance increase at the basolateral membrane. Radioactive tracer experiments showed that cAMP increased the active secretion of Na (choroid to retina) and the active absorption of K (retina to choroid). Cyclic AMP also abolished the active absorption of Cl across the RPE. In sum, elevated cellular levels of cAMP affect active and passive transport mechanisms at the apical and basolateral membranes of the bullfrog RPE.

Effects of cyclic AMP on fluid absorption and ion transport across frog retinal pigment epithelium. Measurements in the open-circuit state

A modified version of a capacitance probe technique has been used to measure fluid transport across the isolated retinal pigment epithelium (RPE)-choroid of the bullfrog. The accuracy of this measurement is 0.5-1.0 nl/min. Experiments carried out in the absence of external osmotic or hydrostatic gradients show that the RPE-choroid transports fluid from the retinal to the choroid side of the tissue at a rate of approximately 10 nl/min (4-6 microliters/cm2 X h). Net fluid absorption (Jv) was abolished within 10 min by the mitochondrial uncoupler 2,4-dinitrophenol. It was also inhibited (70%) by the removal of bicarbonate from the bulk solutions bathing the tissue. Ouabain caused a slow decrease in Jv (no effect at 10 min, 70% at 3 h), which indicates that RPE fluid transport is not directly coupled to the activity of the Na-K pump located at the apical membrane of this epithelium. In contrast to ouabain, cyclic AMP (cAMP) produced a quick decrease in Jv (84% within 5 min). Radioisotope experiments in the open circuit show that cAMP stimulated secretory fluxes of Na and Cl, which accounted for the observed cAMP-induced decrease in Jv. The direction of net fluid absorption, the magnitudes of the net ionic fluxes in the open circuit, and the dependence of Jv on external bicarbonate concentration strongly suggest that fluid absorption is generated primarily by the active absorption of bicarbonate.

Acid phosphatase localization in normal and dystrophic retinal pigment epithelium

In this study acid phosphatase (ACPase) was localized in the retinal pigment epithelium (RPE) of normal and Royal College of Surgeons (RCS) rats pink-eyed and pigmented with inherited retinal dystrophy to determine differences in staining during the post-engulfment stages of phagocytosis using two substrates, Na-beta-glycerophosphate and cytidine-5'-monophosphate. Staining was similar using either substrate and in the normal RPE the Golgi system, lysosomes and phagosomes were ACPase-positive. In the dystrophic RPE, which has a diminished capacity to phagocytose photoreceptor rod outer segments, ACPase staining was localized on melanosomes in the pigmented dystrophic and on the apical microvillous membranes in the pink-eyed dystrophic, but was not localized on phagosomes in either the pink-eyed or pigmented dystrophic RPE. Since only a few phagosomes were seen at any given time in dystrophic RPE in vivo, a tissue explant system was used to examine the number of latex beads phagocytosed by normal and RCS RPE, as well as the number of phagosomes containing both beads and ACPase activity in the normal and mutant RPE. Our findings indicate that in the dystrophic, fewer phagosomes are ACPase-positive than in the normal, and that some enzyme may be inappropriately shunted to either the apical microvilli or to melanosomes instead of to phagolysosomes.

A model for transepithelial ion transport across the isolated retinal pigment epithelium of the frog

The contribution of chloride ion movement and sodium and bicarbonate concentrations to the net current across the isolated choroid-retinal pigment epithelium (RPE) of the bullfrog were studied. The presence of a ouabain-sensitive Na+/K+-pump on the retinal side was confirmed and complete inhibition of this pump with Na+ removal and ouabain treatment abolished nearly all the RPE transepithelial transport and SCC suggesting that all ionic transport was dependent on sodium. It was found that apical to basal (AB) chloride flux accounted for 26 +/- 2% (mean +/- S.E.M.) of the short circuit (SCC). Results suggest that AB bicarbonate and/or basal to apical (BA) hydrogen ion net transport accounts for 38 +/- 2% of the SCC while BA sodium is presumably responsible for the remaining 34% of the SCC. Transport was inhibited by apical administration of known chloride inhibitors. Trans-RPE 36Cl flux measurements indicate that furosemide (10(-4) M) and SITS (10(-3) ) decrease the retinal-choroid flux. Results suggest that net transport of chloride and bicarbonate are independent of each other and additive. It was found that a bicarbonate-free preparation was relatively unaffected by changes in pH (5.5-8.5) indicating that pH has little, if any, effect on sodium or chloride current in this range. A model is presented which is compatible with the various data. It is suggested that along with the apical Na+/K+-ATPase pump, there exists an apical Na+/Cl- -co-transport system which is driven by the established sodium gradient. Moreover, this pump established sodium gradient is postulated to drive a Na+/HCO3- -co-transport system tentatively placed on the retinal side of the RPE.

Permeability of retinal pigment epithelial cell junctions in the dystrophic rat retina

We have studied permeability of retinal pigment epithelial (RPE) cell junctions in Royal College of Surgeons rats with inherited retinal degeneration, and their genetic controls, using the horseradish peroxidase and lanthanum nitrate electron microscope tracer techniques. We find that early in the dystrophic process, at two postnatal weeks in the pink-eyed retina and three postnatal weeks in the black-eyed retina, RPE cell tight junctions form a barrier to extracellular tracer. However, at three postnatal weeks in the pink-eyed retina, at about the same time that degenerating photoreceptor nuclei begin to appear, RPE cell tight junctions become permeable. The permeability increase occurs later in the black-eyed strain, but by six postnatal weeks junctions are permeable in both strains. By 72 postnatal days, when most photoreceptor nuclei have disappeared, many RPE cells are abnormal in shape, with an elongated and flattened appearance, and some appear to have lost their junctions entirely. In the horseradish peroxidase experiments, many pinocytotic vesicles filled with reaction product were observed in the dystrophic RPE after the junctional breakdown. This suggests that an increase in transcellular transport may also occur in the dystrophic RPE.

Effects of maintained illumination upon [K+]0 in the subretinal space of the isolated retina of the toad

Illumination of the vertebrate retina evokes a transient decrease in extracellular potassium concentration, [K+]0, in the subretinal space. During maintained illumination, [K+]0 recovers toward its dark-adapted level. The mechanisms most likely to contribute to this recovery process were examined by using K+-selective microelectrodes to measure [K+]0 in the isolated retina of the toad. Bufo marinus. Although both diffusion of K+ and changes in the rod membrane voltage contribute to the recovery of [K+]0 during maintained illumination, other factors are likely to be involved as well. It is suggested that this recovery process could be due in part to inhibition of the Na+/K+ pump in the rod photo-receptors during maintained illumination.

Potassium transport across the frog retinal pigment epithelium

Previous experiments indicate that the apical membrane of the frog retinal pigment epithelium contains electrogenic Na:K pumps. In the present experiments net potassium and rubidium transport across the epithelium was measured as a function of extracellular potassium (rubidium) concentration, [K]0 ( [Rb]0). The net rate of retina-to-choroid 42K(86Rb) transport increased monotonically as [K]0 ( [Rb]0) increased from approximately 0.2 to 5 mM on both sides of the tissue or on the apical (neural retinal) side of the tissue. No further increase was observed when [K]0 ( [Rb]0) was elevated to 10 mM. Net sodium transport was also stimulated by elevating [K]0. The net K transport was completely inhibited by 10-4 M ouabain in the solution bathing the apical membrane. Ouabain inhibited the unidirectional K flux in the direction of net flux but had no effect on the back-flux in the choroid-to-retina direction. The magnitude of the ouabain-inhibitable 42K(86Rb) flux increased with [K]0 ( [Rb]0). These results show that the apical membrane Na:K pumps play an important role in the net active transport of potassium (rubidium) across the epithelium. The [K]0 changes that modulate potassium transport coincide with the light-induced [K]0 changes that occur in the extracellular space separating the photoreceptors and the apical membrane of the pigment epithelium.

Kinetics of the sodium pump in the frog choroid plexus

1. Active Na+ transport across the choroid plexus is mediated by Na-K pumps in the brush border membrane of the epithelium. We have studied the kinetics of Na+ pumping across the brush border membrane using a 22Na efflux procedure. 2. Frog choroid plexuses were loaded with 22Na in K+ -free, cold Ringer solution containing various Na+ concentrations. The efflux of 22Na from the tissues was monitored at 22 degrees C and the rate constant (k) was estimated for each flux interval. The pump component was obtained from the change in k(delta k) induced by the addition of KCl to the superfusate. 3. Ouabain blocked this K+ -sensitive Na+ efflux and other monovalent cations substituted for K+ in the sequence Tl+, Rb+, K+, greater than NH+4 greater than Cs+ much greater than Li+. Active sodium transport (delta k x Nac) increased in a sigmoidal and saturable way with intracellular Na+ and with extracellular K+ concentrations. 4. Kinetic parameters were estimated using the model of Garay & Garrahan (1973). The data indicate that there were two ligand binding sites for K+ on the outside face and three ligand binding sites for Na+ on the cytoplasmic face of the pump. The Kms for potassium and sodium were 1 . 1 and 7 mM. 5. The results also suggest that the Na-K pump has a coupling ratio of 1 . 5. We conclude that the Na-K pump in this epithelium is very similar to those in single cells such as erythrocytes, nerve and muscle.

Effects of maintained illumination upon [K+]0 in the subretinal space of the frog retina

Changes in extracellular potassium ion concentration, [K+]0, were measured in the subretinal space of an in vitro preparation of bullfrog retina, pigment epithelium and choroid. In response to maintained illumination [K+]0 fell to a minimum value in 30-40 sec, and then began to recover, reaching a steady-state approximately 10 min after light onset. At light offset, [K+]0 overshot the dark-adapted baseline before recovering. Pigment epithelial membrane potentials followed [K+]0 during this entire timeperiod, causing parallel changes in the d.c. level of the vitreal electroretinogram (ERG). These changes in [K+]0 are very similar to those observed in the cat retina in vivo, except that they are slower in time-course by nearly an order of magnitude. The vitreal ERG, however, is much different in frog than in cat, since in frog, but not in cat, it is an indirect measure of [K+]0 in the subretinal space.

Interaction of bovine pigment epithelium cells, photoreceptor outer segments, and interphotoreceptor matrix: a model for retinal adhesion

A model system for retinal adhesion, consisting of interacting bovine pigment, epithelium (PE) cells and photoreceptor outer segments, was utilized to examine any adhesive role of the interphotoreceptor matrix. PE cells were dissociated by trypsin treatment of the eyecup, and were allowed to replenish their surface proteins as single cells in spinner culture. They were then placed into short-term, slowly rotating suspension cultures, where their rapid aggregation as a function of time could be studied. Outer segments exhibited no tendency to interact with one another, or with PE cells, in suspension culture. Extracellular interphotoreceptor matrix from adult bovine eyes was isolated by rinsing the apposing surfaces of neural retina and PE. When this matrix material was added to the cell suspension cultures, adhesion between PE cells and outer segments in mixed cultures was not enhances. However, PE reaggregation itself appeared to be augmented. The principal matrix glycoprotein, obtained by concanavalin A affinity chromatography, displayed adhesive properties similar to those of the interphotoreceptor matrix. Thus, under the conditions of these in vitro experiments, no evidence could be obtained that either cell surface molecules or interphotoreceptor matrix plays a role in retinal adhesion.

Transmembrane components of taurine flux across frog retinal pigment epithelium

In previous work from this laboratory, a net transepithelial flux of the amino acid taurine was measured across the in vitro frog retinal pigment epithelium. This flux was from retina to choroid and could be modulated by small (0.5 mM) changes in K+ concentration, by changes in taurine concentration, and by ouabain. In the present experiments we measured the unidirectional transmembrane fluxes across each of the two cell membranes, the apical membrane (facing the neural retina) and the basal membrane (facing the choroid) of the retinal pigment epithelium. In modified Ringer's solution containing 2mM taurine + 2mM K+, we found that the apparent outward permeability of the basal membrane, corrected for its actual area, was 26 times that of the apical membrane. As expected from the direction of net flux, the inward apical and outward basal fluxes dominated the transmembrane fluxes. When the apical Na+:K+ pump was inhibited, the ratio of the apparent permeability of the basal membrane relative to the apical decreased from 26 to 4.4. The data are consistent with the previous suggestion of Na+:taurine co-transport into the retinal pigment epithelium across the apical membrane. The basal membrane response to ouabain and reduced K+ concentration suggests that a K+-dependent mechanism is responsible, at least in part, for the inward basal taurine flux.