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Modulation of Permeability and Adhesion Molecule Expression by Human Choroidal Endothelial Cells

¹ From the Save Sight Institute and the ² Departments of Clinical Ophthalmology, ³ Anatomy and Histology, and ⁴ Pathology, University of Sydney, New South Wales, Australia.

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

 
PURPOSE. The therapeutic potential of TA, an anti-inflammatory glucocorticoid, for the treatment of exudative retinopathy has been examined in several independent clinical studies. The modulation of permeability and adhesion molecule expression of an epithelial cell line has been described in vitro, with the use of cytokines and triamcinolone acetonide (TA). In the current study, the influence of proinflammatory cytokines and TA on permeability and adhesion molecule expression in human choroidal endothelial cells (CECs) was investigated.

METHODS. Human CEC isolates treated with IFN, TNF, and TA were evaluated by flow cytometry and immunocytochemistry for expression of intercellular adhesion molecule (ICAM)-1, vascular cell adhesion molecule (VCAM)-1, and major histocompatibility complex (MHC)-I and -II. The effects of IFN, TNF, and TA on paracellular permeability of CEC monolayers were assessed in transendothelial cell resistance (TER) assays.

RESULTS. Both IFN and TNF significantly upregulated expression of ICAM1 and MHC-I on CECs. Expression of VCAM1 was induced after stimulation with both IFN and TNF, whereas expression of MHC-II was induced only by stimulation with IFN. Cytokine-induced expression of ICAM1, MHC-I, and MHC-II antigen by CECs was significantly downregulated by TA. IFN stimulation also increased permeability of CEC monolayers, whereas subsequent TA treatment decreased permeability of CEC monolayers.

CONCLUSIONS. Human CEC isolates provide a useful in vitro model to study choroidal neovascular membrane characteristics and their potential response to pro- and anti-inflammatory agents. In addition, the results indicate that TA has the capacity to reduce adhesion molecule expression and permeability of choroidal vessels in vitro, confirming its potential as a therapeutic agent for treatment of exudative macular degeneration.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

 
Intravitreal administration of glucocorticoids has been shown to be effective in reducing the incidence of experimentally induced neovascularization in rabbits,^{1 2} monkeys,³ pigs,⁴ and rats.⁵ The therapeutic potential of triamcinolone acetonide (TA) for the treatment of exudative age-related macular degeneration (AMD)^{6 7} and cystoid macular edema in uveitis^{8 9} has been examined in several independent clinical pilot studies. Subretinal vessels are derived from the choroidal vasculature, and new vessels penetrate the retinal pigment epithelium (RPE), compromising the integrity of the blood–retinal barrier (BRB). Glucocorticoids are known to display differential capacities to mediate anti-angiogenic, anti-inflammatory, and permeability effects, although the mode of action of TA on human choroidal endothelial cells (CECs) has not been completely defined.

Immunoglobulin superfamily (IgSF) molecules, including intercellular adhesion molecule (ICAM)-1, vascular cell adhesion molecule (VCAM)-1, and major histocompatibility complex (MHC)-I and -II, are key indicators of vascular endothelial cell activation. ICAM1 is constitutively expressed on CEC and RPE cell surfaces and is a critical component of cell–cell interaction during inflammatory responses, mediating leukocyte adhesion and extravasation.^{10 11} Expression of adhesion molecules, including ICAM1, has been described in association with inflammatory cells in excised subretinal disciform lesions.¹² Furthermore, soluble factors released by reactive microglia may enhance expression of ICAM1 on vascular endothelial cells.¹³ It has also been shown that microglial activation is involved in the pathogenesis of AMD¹⁴ and that TA affects microglial morphology and quantitative expression of MHC-II in exudative AMD.¹⁵

Human CECs have been differentially isolated and purified by clonal elimination of contaminating cells.¹⁶ In addition, a method for the isolation of human fetal CECs using CD31-coated beads (Dynabeads; Dynal, Oslo, Norway) has been reported.¹⁷ In the current study, we used a novel method for the isolation of adult human CECs—Ulex europaeus I (UEAI) lectin–coated beads (Dynabeads). In an earlier study, we showed that TA has the capacity to modulate the expression of ICAM1 by and the permeability of a human epithelial cell line.¹⁸ In the present study, we used human CEC primary isolates to investigate the effects of TA on the permeability of vascular endothelial cells and the expression of a range of IgSF molecules after stimulation with cytokines.

	Materials and Methods

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Human Choroidal Endothelial Cell Isolates
Human eyes of five donors were obtained from the Lions New South Wales Eye Bank, consistent with the Declaration of Helsinki, and were used as the source of primary CECs. Specimen ages (in years) and postmortem delay (pm; in hours) were as follows: 20 (pm 12), 24 (pm 11), 50 (pm 18.5), 54 (pm 16), and 61 (pm 9). After the vitreous was removed, the choroidal segment was separated from the neural retina and retinal pigment epithelium (RPE), cut into small pieces, washed with cold Hanks’ balanced salt solution (HBSS) and 0.5 mg/mL penicillin-streptomycin (ThermoTrace Pty., Ltd., Noble Park, Australia) three times, and cut into 1- to 2-mm pieces. The pieces were incubated in an enzyme mixture containing 500 µg/mL collagenase 1A (Sigma, Australia Pty., Ltd., Sydney, Australia) and 1.2 U/mL Dispase II (Roche Diagnostics, Australia Pty., Ltd., Sydney, Australia) for 45 minutes at 37°C with constant agitation. Then, 400 µg/mL DNase I (Roche Diagnostics Pty., Ltd.) was added for a further 15 minutes. The choroidal digests were double filtered through 70- and 44-µm meshes, and the enzymes were neutralized by Iscoves modified Dulbecco’s medium (IMDM) and 10% fetal bovine serum (FBS; ThermoTrace Pty., Ltd.).

The cells from individual donors were centrifuged at 400g at 4°C, and resuspended in 80 µL HBSS and 5% FBS. The cell suspension was then incubated with 12 µL Ulex europaeus I (UEAI) lectin (Sigma, Australia Pty., Ltd.)–coated beads (Dynbeads; Dynal) for 15 minutes at room temperature (RT). After incubation, the bead–endothelial cell complexes were washed five times by resuspending in HBSS and 5%FBS, mixed by gentle agitation for 1 minute, and separated in a magnetic particle concentrator. The bead–endothelial cell complexes were resuspended in growth medium (IMDM supplemented with 20% pooled human heated inactivated serum, obtained from authors and their colleagues; 100 µg/mL endothelial cell growth supplement [Collaborative Research Inc., Bedford, MA]; 20 µL/mL bovine retinal extract, 7 U/mL heparin [ThermoTrace Pty., Ltd.], 0.2 µg/mL insulin, and 0.5 mg/mL penicillin-streptomycin). The resuspension was then placed in a 60-mm tissue culture dish that had been coated with 0.1% gelatin and 1 µg/mL fibronectin (ThermoTrace Pty., Ltd.). After overnight incubation in a humidified atmosphere of 5% CO₂ and air at 37°C, the debris and dead cells were washed off with IMDM, and fresh growth medium was added. The CECs were passaged with 0.05% trypsin and 0.02% EDTA in HBSS after 7 to 10 days of primary culture, when large confluent areas of cells were visible.

Cultures were routinely assessed by flow cytometry (FCM) or immunocytochemistry and confirmed to be endothelial cells by positive labeling with CD31 (Fig. 1) . Cells of passages 2 to 3 were used in all experiments.

View larger version (71K): [in this window] [in a new window]   Figure 1. Expression of CD31 was used to determine the purity of primary isolated CECs. (A) Flow cytometry (FCM) histogram showing CECs labeled with mouse IgG1 isotype control (a) and mouse anti-human CD31 antibody (b). (B) CEC monolayer immunolabeled with CD31 and visualized by streptavidin-fluorescein. Final magnification, x1250.

Reagents
IFN and TNF (Sigma, Australia Pty., Ltd.) were dissolved in medium according to the manufacturer’s instructions. TA (Sigma, Australia Pty., Ltd.) was dissolved in methanol (Selby-Biolab Scientific Pty., Ltd., Clayton, Australia) as a 10^-2-M stock solution. Optimal dose and time responses were established by FCM.

Flow Cytometry
CEC cells from five individual donors were seeded in 25-cm² flasks and cultured until confluent. The medium was removed, and the cells treated with medium alone (diluent control; methanol), 200 U/mL IFN for 48 hours, 200 U/mL TNF for 48 hours, or IFN (or TNF) for 4 hours with TA 5 x 10^-6 M added for a further 44 hours.

FCM Labeling.
After incubation, cultures were washed twice with HBSS and detached from the flasks with 0.05% trypsin and 0.02% EDTA for 2 minutes at 37°C. Cells (10⁵) were pelleted by centrifugation at 463g for 5 minutes at 4°C and resuspended in 50 µL of primary antibody at 4°C. After a 1-hour incubation, cells were washed through 100 µL FBS by centrifugation (463g, 5 minutes, 4°C) and resuspended in 100 µL FITC-conjugated antibody for 45 minutes at 4°C. Cells were finally centrifuged through FBS and resuspended in 250 µL IMDM-FBS for FCM.

FCM Analysis.
Fluorescence between 515 and 545 nm was measured by FCM (FACScan; BD Biosciences,) with an argon-ion laser set at an emission of 488 nm for excitation of FITC. Forward and side scatter measurements were within the same range for all populations, and 10⁴ events were collected from each sample. Data analysis was performed with the accompanying software (CellQuest; BD Biosciences) and results presented either as histograms or bar graphs. Histograms show results from individual experiments and express the number of events versus log₁₀ fluorescence intensity. Bar graphs show average normalized data (n = 5, from five donors) for peak channel fluorescence, which is a quantitative measure of the relative expression of the molecule on the cell surface.

Immunocytochemistry
In parallel with FCM experiments, CECs were seeded as described earlier, onto permeable membrane inserts (Transwell; Costar, Cambridge, MA), and immunolabeled using anti-ICAM1, anti-CD31, or the negative control (mouse IgG₁). After treatment, inserts were fixed in 2% paraformaldehyde at 4°C for 10 minutes, rinsed in PBS, and incubated at room temperature (RT) in 10% normal saline solution and 0.4% saponin and PBS for 20 minutes, before incubation with the primary antibody at 4°C overnight. Inserts were then rinsed in PBS and incubated in biotinylated secondary antibody for 45 minutes. Bound antibody was detected with streptavidin-fluorescein and Cy3 (1:100 dilution; Zymed, San Francisco, CA) labeling. Inserts were mounted on glass slides in anti-fade glycerol (Dako Pty., Ltd.) and examined by confocal microscopy.

Transendothelial Resistance
Permeable membrane inserts (3-µm pore size, 6-mm diameter, area 28.3 mm²; Transwell; Costar) were coated at RT with 35 µL of 0.1% gelatin overnight. The next day, wells were further coated with 70 µL laminin (Collaborative Research Inc.), collagen IV, and fibronectin for 2 hours (final concentrations: 1 µg laminin [50 µg/mL], 1 µg collagen IV [50 µg/mL], and 1.5 µg fibronectin [50 µg/mL]). After two washes in HBSS, the CECs (3.5 x 10⁴/well) were plated onto coated permeable membrane inserts in a 150-µL volume of medium; 700 µL of medium was added to each well. The medium used in the transendothelial resistance (TER) experiments contained CEC growth medium and medium conditioned with human retinal mixed glia (1:1). The medium was changed every second day for the duration of the experiment. Electrical resistance was measured from day 2 with a resistance meter (ERS; Millipore, North Ryde, Australia), and the monolayers were treated once resistance was higher than 15 /cm² (approximately 2–4 days). At that point, monolayers were either left untreated or were treated with TA (5 x 10^-6 M) or IFN (150 U/mL) for 4 hours or with TA (5 x 10^-6 M) after stimulation with IFN (150 U/mL).

The TERs of monolayers were calculated as the average resistance of the different groups minus the average resistance of the background control (medium and coated filter only) and then multiplied by the effective growing area (0.33 cm²). Each data point represents the mean ± SEM of electrical resistance in an individual experiment (n = 4 permeable membranes). The experiments were repeated with CECs from three individual donors.

Statistical Analysis
Results were expressed as the mean ± SEM. Analysis of variance, followed by a multiple-comparison Bonferroni t-test, was used to analyze results. P < 0.05 was considered significant.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
Phenotype of Unstimulated Human CECs
Constitutive expression of CD31 by human CECs was confirmed by FCM and immunocytochemistry (Fig. 1) . FCM showed that CECs constitutively expressed high levels of ICAM1 (496 ± 225 arbitrary units [AU]) and MHC-I (685 ± 160 AU; Fig. 2 ). However, significant levels of MHC-II (Fig. 2) , VCAM-1 (Fig. 3) , E-selectin, and P-selectin were not detected on resting, unstimulated CECs.

View larger version (56K): [in this window] [in a new window]   Figure 2. Representative FCM results showing expression on CECs of (A) ICAM1, (B) MHC-I, and (C) MHC-II. Stimulation with IFN for 48 hours significantly induced expression of ICAM1, MHC-I, and MHC-II, whereas addition of TA after 4 hours of stimulation with IFN significantly reduced expression of ICAM1, MHC-I, and MHC-II. The abscissa (FL 1-H) indicates log10 fluorescence intensity, and the ordinate indicates number of events. (a) Untreated CECs, (b) CECs stimulated with IFN (200 U/mL) for 48 hours, (c) CECs stimulated with IFN (200 U/mL) for 4 hours with TA (5 x 10-6 M) added for the remaining 44 hours, (d) CECs treated with isotype control mouse IgG1. (D) Unstimulated CECs constitutively expressed ICAM1 and high levels of MHC-I but did not express MHC-II compared with the isotype control antibody. Stimulation with IFN (200 U/mL) for 48 hours significantly induced expression of ICAM1 (3.5-fold), MHC-I (3-fold), and MHC-II on CECs. A subsequent 44 hours of TA treatment (5 x 10-6 M) after a 4-hour exposure to IFN significantly reduced expression of ICAM1, MHC-I, and MHC-II on CECs. Data are the mean ± SEM of normalized data from five donors in five separate FCM experiments.

View larger version (39K): [in this window] [in a new window]   Figure 3. Resting CECs expressed insignificant levels of VCAM1. Stimulation with IFN for 48 hours induced VCAM-1 expression. Subsequent treatment with TA for 44 hours after 4 hours of initial exposure to IFN reduced expression of VCAM1 on CECs, although not significantly. Data are the mean ± SEM of normalized data from five separate experiments.

We also examined CECs for expression of VCAM1, which was almost undetectable on unstimulated CECs (Fig. 3) . However, IFN induced low-level expression of VCAM1 (40 ± 3 AU), which was marginally but not significantly reduced by treatment with TA (Fig. 3) . TA also reduced TNF-induced expression of VCAM1 by approximately 35% (data not shown).

Stimulation with TNF also upregulated expression of ICAM1 on CECs (approximately twofold; data not shown), although the level of upregulation was much less than that induced by IFN (approximately 3.5-fold; Fig. 2A , histogram b). TA significantly downregulated both IFN- and TNF-induced expression of ICAM1 (IFN, Fig. 2A , histogram c; TNF, data not shown). A similar profile of modulation was observed for expression of MHC-I (Fig. 2B , histogram b). No induction of MHC-II was apparent after stimulation with TNF (data not shown). Stimulation with TNF for 4 hours markedly induced E-selectin (fourfold) and moderately induced P-selectin, whereas IFN did not. TA had no effect on the expression of these molecules (data not shown).

Immunocytochemistry
Immunolabeling for ICAM1 was consistent with the FCM results. CECs grown on permeable membrane inserts showed cell membrane localization of ICAM1 (Fig. 4A) , which was of greater intensity after 48 hours of stimulation with IFN (Fig. 4B) . In unstimulated cultures, ICAM1-positive labeling was generally uniform, with occasional individual cells being more intensely immunoreactive. In the IFN-stimulated cultures (Fig. 4B) , a patchy expression of ICAM1 occurred, perhaps due to clonal expansion of individual cells expressing high levels of ICAM1. A reduction in ICAM1 immunoreactivity was evident after treatment with TA (4 hours after stimulation, Fig. 4C ). Staining with isotype control mouse IgG₁ indicated insignificant levels of nonspecific binding to CECs (Fig. 4D) .

View larger version (160K): [in this window] [in a new window]   Figure 4. ICAM-1 immunostaining was consistent with FCM results. (A) Resting CEC monolayer showed cell membrane–localized ICAM1. (B) IFN-stimulated CEC monolayer displayed a greater intensity of ICAM1 staining on cell membranes. (C) Subsequent treatment of the IFN-stimulated CEC monolayer with TA reduced ICAM1 immunoreactivity. (D) Mouse IgG1 isotype control staining of the CEC monolayer showed low-level background staining. Final magnification, x950.

View larger version (16K): [in this window] [in a new window]   Figure 5. (A) Comparison of the TER of TA-treated CEC monolayers versus control CEC monolayers. TER was significantly higher in the TA-treated (5 x 10-6 M) monolayer from day 1 to the completion of the experiment, compared with the control monolayers. (B) IFN (150 U/mL) markedly decreased TER from day 1 after treatment to the conclusion of the experiment. Treatment with IFN followed by TA modulated the change, with a significant increase in TER at days 3, 5, and 6. Data are the mean TER ± SEM of four experiments (n = 4).

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

Chronic inflammatory cells have been reported in AMD lesions^{20 21 22} and surgically excised choroidal membranes,²³ and a variety of cell types are involved in subretinal neovascular lesions, including vascular endothelial cells and leukocytes.²⁴ It has been established that CECs are the primary source of exudation and neovascularization in exudative AMD¹⁶ ; however, it has been pointed out that in many cases of exudative AMD, there is a significant involvement of retinal vascular leakage.²⁵ Glucocorticoids, such as TA, influence the activity of various cell types (RPE, vascular endothelial cells, and leukocytes) involved in fibrovascular lesions and have shown anti-inflammatory, -exudative, and -angiogenic effects.^{6 7 8 9 26} Glucocorticoid receptors are widely distributed in mammalian tissues and have been detected in human RPE cells²⁷ and bovine endothelial cells.²⁸ The rationale for the use of anti-inflammatory glucocorticoids for the treatment of exudative macular degeneration has been derived from observations of animal models and pathologic specimens that implicate immune processes in AMD. Evidence relating leukocytes and cytokines to the formation of new vessels in the choroid and the role of microglia in AMD^{29 30} has been recently reviewed.²⁴

The proinflammatory cytokines TNF, IFN, and IL1ß are major inducers of expression of ICAM1 in most cell types.³¹ In a previous study, we demonstrated that TA ameliorates modulation of both permeability and expression of ICAM1 that is experimentally induced by treatment of the ECV304 epithelial cell line with phorbol myristate acetate (PMA), IFN, and/or TNF, representing a model of epithelial and RPE cell permeability.¹⁸ In the present study, using similar techniques, we investigated the influence of those cytokines and TA on human CEC primary isolates. Both IFN and TNF significantly upregulated expression of ICAM1 and MHC-I on human CECs. This contrasts with our previous findings in ECV304 cells that indicated that expression of MHC-I was not significantly modulated by either cytokines or TA.¹⁸

TNF is chemotactic for monocytes and fibroblasts, acting synergistically with IFN,³² which has been shown to induce expression of MHC-II in human RPE cells.³³ In the present study we found that IFN, but not TNF stimulation, induced expression of MHC-II on human CECs and that treatment with TA subsequently produced a small but consistent decrease in IFN-induced expression. It has been suggested that TNF secreted by macrophages promotes choroidal neovascularization.³⁴ Histopathologic analyses of AMD-affected eyes has revealed downregulation of expression of MHC-II antigen on vascular elements associated with intravitreal administration of TA.¹⁵ Collectively, the results of these studies reveal differential expression of IgSF in response to both pro- and anti-inflammatory agents by transformed epithelial and primary endothelial lineage cells.

Proinflammatory effects of TNF on the blood–retinal barrier have also been demonstrated to include permeability changes involving microglia and Müller cells.³⁵ We suggested previously that modulation of epithelial resistance by TA in vitro is consistent with clinical observations, indicating that reduction of the permeability of the outer blood–retinal barrier and downregulation of inflammatory stimuli are significant effects of intravitreal TA in vivo.¹⁸ Recent histopathologic analyses of human eyes showed diminished exudation associated with intravitreal administration of TA,¹⁵ and in the present study TA produced a decrease in the permeability of resting human CECs. It appears that the clinical effects of TA in exudative AMD, reported in abstracts and peer-reviewed publications,^{6 7} may involve downregulation of ICAM1, reduced choroidal leukostasis, and reduced paravascular permeability.¹⁸

	Acknowledgements

 
The authors thank Meidong Zhu for technical advice on isolation of adult choroidal vascular endothelial cells and Francis A. Billson and Diana van Driel for helpful discussion and review of the manuscript.

	Footnotes

 
Supported by the National Health and Medical Research Council of Australia and the Sydney Foundation for Medical Research.

Submitted for publication October 31, 2001; revised March 15, 2002; accepted April 17, 2002.

Commercial relationships policy: P (PLP); N (LW, MCM, NJCK, JMP).

The publication costs of this article were defrayed in part by page charge payment. This article must therefore be marked "advertisement" in accordance with 18 U.S.C. 1734 solely to indicate this fact.

Corresponding author: Philip L. Penfold, Department of Clinical Ophthalmology, University of Sydney, GPO Box 4337, Sydney NSW 2001, Australia; ppenfold{at}eye.usyd.edu.au.

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Top Abstract Introduction Materials and Methods Results Discussion References

 

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