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Plasminogen Activator Inhibitor-1 mRNA Is Localized in the Ciliary Epithelium of the Rodent Eye

From the Department of Biological Chemistry, the Weizmann Institute of Science, Rehovot, Israel.

	Abstract

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PURPOSE. To identify in the adult and developing rodent eye cells expressing the gene encoding plasminogen activator inhibitor-1 (PAI-1), an important component of the fibrinolytic system.

METHODS. PAI-1 mRNA was localized in cryostat thin eye sections via in situ hybridization analysis using specific ³⁵S-labeled riboprobes. PAI-1 activity was tested in the aqueous humor using one-phase reverse zymography.

RESULTS. In the adult eye, PAI-1 mRNA was detected exclusively in epithelial cells of the ciliary processes, primarily in the apexes. In addition, PAI-1 activity was detected in the aqueous humor. PAI-1 mRNA was first found in the ciliary epithelium in embryonic day 18.5, when the ciliary body has reached an advanced developmental stage. PAI-1 mRNA was also detected in the ganglion cell layer of the retina at postnatal days 1 to 4, when angiogenesis takes place.

CONCLUSIONS. During development, PAI-1 is likely to be involved in retina vascularization, in agreement with other cases of angiogenesis. Results for the adult eye indicate that the ciliary epithelium is the source for PAI-1 activity found in the aqueous humor. The results suggest that PAI-1 plays a role in balancing fibrinolysis and proteolysis specifically in the anterior segment of the eye, implying that PAI-1 overproduction in the ciliary epithelium could shift the balance against proteolysis and thus may interfere with aqueous outflow.

	Introduction

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Plasminogen activator inhibitor-1 (PAI-1) is a secreted ~50 kDa glycoprotein belonging to the serpin superfamily of serine protease inhibitors. PAI-1 is the principal physiological inhibitor of tissue-type (tPA) and urokinase-type (uPA) plasminogen activators (PAs). These are serine proteases that specifically convert the inactive proenzyme plasminogen into plasmin, the ultimate blood clot–dissolving enzyme.^{1 2} Plasmin is a nonspecific trypsin-like protease that can also directly degrade diverse extracellular components and can activate proenzymes of matrix-degrading metalloproteases, thereby mediating extracellular proteolysis and cell adhesion. Plasmin can also extracellularly activate transforming growth factor-ß (TGF-ß) from its large latent form and can release growth factors bound to extracellular matrices. Apart from fibrinolysis, the PA/plasmin system has been implicated in various normal and pathologic events, including wound healing, angiogenesis, inflammation, restenosis, tumor metastases, and the maintenance of patency of tubular structures, such as the urinary tubules and vas deferens.^{3 4 5 6}

In humans, PAI-1 deficiency correlates with abnormal bleeding tendency, whereas elevated plasma PAI-1 has been associated with thrombotic diseases, with the acute phase response, and with non–insulin-dependent diabetes.^{1 7} Increased PAI-1 synthesis has also been demonstrated in atherosclerotic plaques, suggesting that PAI-1 may play a role in atherogenesis as well, perhaps by promoting matrix deposition.^{6 8} PAI-1 has also been implicated in PA-mediated non-fibrinolytic events, including angiogenesis,⁹ cell migration,⁵ inhibition of neointima formation,⁶ and mediating uPA and tPA internalization/degradation through the multiligand surface receptor LRP/₂MR.⁵

PAI-1 is normally produced in several species in vivo in various tissues and cell types.^{2 10 11} The PAI-1 gene can respond to multiple biological modulators in vivo in mice or in cultured cells, usually at the transcriptional level. Inducers of PAI-1 gene expression include glucocorticoids, TGF-ß, tumor necrosis factor- (TNF-), interleukin-1, the tumor promoter phorbal-myristate acetate (PMA), bacterial endotoxins,^{2 12} and kainic acid, an analogue of the neurotransmitter glutamate.¹¹ Conversely, PAI-1 gene expression has been shown to be reduced by interferons¹³ and cAMP-elevating agents.² Insulin is thought to be a major physiological regulator of PAI-1 in plasma.⁷ However, the regulation of PAI-1 concentration in plasma is complex and not well understood.

In the eye, tPA and uPA activities have previously been detected in different structures and fluids in several species, including human trabecular cells and meshwork^{14 15} and aqueous humor.^{16 17 18 19} In addition, tPA administration into the eye accelerates clot lysis,¹⁶ introducing plasmin accelerated aqueous outflow,²⁰ and reduced fibrinolytic activity was reported in the aqueous humor of patients with chronic simple glaucoma²¹ and in chronic uveitis in the cat.²² Accordingly, PAs were suggested to be involved in intraocular clot lysis, extracellular matrix dissolution, or aqueous outflow.^{14 15 16 17 18 19 20 21 22}

Less attention has been given to PAI-1 in the eye. So far, antigenic PAI-1 has been detected in the human aqueous humor; however, PAI-1 activity could not be detected.^{17 18} To evaluate whether PAI-1 could play a role in the eye, we localized in this study PAI-1 gene expression in adult and developing murine eyes through in situ hybridization experiments and also tested PAI-1 activity in the aqueous humor. Most of our PAI-1 analysis has been conducted in the FVB/N mouse strain, because we previously used this strain to generate transgenic mice overproducing uPA in the ocular lens, carrying uPA cDNA linked to the A-crystallin promoter.²³ However, FVB/N mice exhibit retinal degeneration, resulting from an rd nonsense mutation in the gene encoding the ß subunit of the rod photoreceptor cGMP phosphodiesterase.²⁴ Therefore, to exclude effects of the rd mutation on PAI-1 expression, we also localized PAI-1 mRNA in the adult eye of nonmutated rodents.

	Methods

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Animals
FVB/N mice (originally obtained from Dr. H. Westphal, the NIH), CD-1 mice (originally purchased from Charles River Labs, Wilmington, MA), and Wistar-derived rats were propagated and maintained at the Weizmann Institute Animal House. Experiments were conducted in accordance with the ARVO Statement for the Use of Animals in Ophthalmic and Vision Research.

In Situ Hybridization
Adult female mice (3-months-old) were killed by deep anesthesia with ether, and eyes were immediately enucleated and frozen over dry ice. Newborn mice (day 4) were similarly killed, and their heads were excised and immediately frozen. Frozen samples were kept at -70°C for up to 2 weeks until sectioned. Thin cryostat sections (10- to 12-µm) were tested through in situ hybridization using ³⁵S-labeled riboprobes at the antisense and sense orientations, specific for mouse PAI-1 (derived from the 3.2 kb murine PAI-1 cDNA), as we described previously in detail.^{11 25} Sections were kept under photographic emulsion for 12 to 14 days and lightly counterstained with cresyl violet or hematoxylin and eosin.

One-Phase Reverse Zymography
Mice (3 months old) were killed as noted above, and the aqueous humor was extracted from both eyes (7–10 µl per eye) with a 29-gauge needle attached to a 1 ml syringe. PAI-1 activity was tested in one-phase reverse zymography as previously described.^{11 26} Briefly, the indicated samples were electrophoresed in a sodium dodecyl sulfate (SDS)–polyacrylamide gel containing human plasminogen (purified from human plasma) and casein. The gel was then washed with 2.5% Triton X-100 to remove SDS, incubated for 4 hours at 37°C in a buffer containing standard human uPA (0.5 IU/ml; WHO International Laboratory, Holly Hill, Hampstead, London), and then stained with Coomassie brilliant blue. A parallel control gel was conducted without plasminogen and casein. This gel was incubated without any enzyme to distinguish between dark bands generated from inhibition of casein degradation and those resulting from just staining of sample proteins.

	Results

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PAI-1 mRNA Localization in the Adult Rodent Eye
To identify cells producing PAI-1 in the adult eye, we tested cryostat thin eye sections from adult mice through in situ hybridization experiments using PAI-1–specific ³⁵S-labeled riboprobes at the antisense and sense orientations. Specific PAI-1 hybridization signals were detected exclusively in the ciliary body (Fig. 1A ). These signals were confined to the ciliary epithelium, but specifically to cells in the apexes of the ciliary processes (Figs. 1D 1E 1F) . PAI-1 hybridization signals appeared to be associated with both layers of the ciliary epithelium. The signals were seen with the antisense but not with the sense riboprobe (Fig. 1G) , thus indicating that they represented PAI-1 mRNA. These results were obtained with FVB/N, an inbred mouse strain often used to generate transgenic mice. Previously we derived from this strain transgenic mice overproducing uPA in the ocular lens²³ ; therefore, we have also extensively studied PAI-1 in the parental mouse strain. However, FVB/N mice carry the rd mutation that leads to photoreceptor degeneration that can be detected by postnatal day 8.²⁴ We therefore tested the FVB/N eye at younger postnatal ages and also localized PAI-1 mRNA in the ciliary body (Figs. 1B 1C 1K) . In addition, we confirmed the specific ciliary body localization of PAI-1 mRNA also for the nonmutated eyes of the CD-1 mouse (Figs. 1H 1I) and the Wistar rat (results not shown).

View larger version (151K): [in this window] [in a new window]   Figure 1. Localization of PAI-1 mRNA hybridization signals in adult and developing murine eyes. (A) A coronal section through the eye (excluding the lens) of a 3-month-old FVB/N mouse was hybridized with PAI-1 35S-labeled riboprobe at the antisense orientation. The photograph was taken in dark field illumination. (B, C) A section through the eye of a 4-day-old FVB/N mouse was hybridized as in (A), and photographed in bright field (B) or dark field (C) illumination. (D, E) The ciliary body of a section as in (A), but from a different eye, was photographed in bright field (D) or dark field (E) illumination. Note the association of hybridization signals specifically with the process apexes. (F) A higher magnification photograph of a ciliary process from a section analyzed as in (A). (G) The ciliary body in a section close to (F), but hybridized with PAI-1 35S-labeled sense riboprobe. (H, I) Ciliary body processes of 3-month-old CD-1 mice analyzed as in (A). (J) FVB/N ciliary body at embryonic day 18.5. (K) A higher magnification view of the left side ciliary body seen in (B). (L) A higher magnification view of the left side retina seen in (B). The cell indicated by the rod is magnified in the inset. Note hybridization signals in the ciliary body of the adult and developing eyes. No PAI-1–specific hybridization signals were seen in the lens or retinal pigment epithelium at any age in sections noted above and similar sections. C, cornea; R, retina; CB, ciliary body; CP, ciliary body processes; L, lens; GCL, ganglion cell layer. Arrows point to the ciliary body; arrowhead points to the ganglion cell layer of the retina. Scale bars, (A) 0.6 mm; (B, C) 0.7 mm; (D, E) 0.1 mm; (F, I, K) 11 to 13 µm; (G) 140 µm; (H, J, L) 30 µm.

PAI-1 Activity in the Aqueous Humor
To test whether PAI-1 mRNA in the ciliary body is translated into a biochemically active protein, we analyzed the aqueous humor of the adult eye for protease inhibitor activity by one-phase reverse zymography.²⁶ This assay can visualize in crude biological samples activities of PA inhibitors (i.e., PAI-1 and plasminogen activator inhibitor-2 [PAI-2], a second specific albeit less potent PA inhibitor³ ) and plasmin inhibitors. Thus, aqueous samples were electrophoresed in a SDS–polyacrylamide gel containing plasminogen and casein. To detect PAI-1, we coelectrophoresed conditioned media collected from murine and human hepatoma cell lines (Hepa lc17 and HepG2, respectively) previously shown to produce PAI-1 activity via this assay.²⁶ After electrophoretic separation, the denaturing SDS was washed out to restore inhibitor activity, and the gel was incubated in the presence of uPA, which converted plasminogen throughout the gel to plasmin, which in turn degraded the casein. Subsequently the gel was stained with Coomassie brilliant blue. In this assay, activities inhibiting uPA or plasmin are seen as darkly stained bands on the lightly stained background of semidegraded casein. The results (Fig. 2A ) show that the aqueous samples contained a dark band corresponding to an ~50 kDa protein comigrating with the Hepa PAI-1 when tested separately (lanes 3 and 5), or when mixed with the Hepa sample (lanes 4 and 6). We also conducted a control gel without plasminogen and casein to test whether the dark inhibitory band could represent just staining of sample proteins. No band corresponding to an ~50 kDa protein could be seen in this control gel (Fig. 2B) . Notably, in the aqueous humor we did not detect activity of PAI-2 or of ₂-antiplasmin, the major plasmin inhibitor in blood. These two inhibitors have previously been detected in other biological samples via the one-phase reverse zymography, where they were clearly distinguished from PAI-1 by their sizes.²⁶

View larger version (48K): [in this window] [in a new window]   Figure 2. PAI-1 and PA activities in the aqueous humor. Samples were tested in one-phase reverse zymography as described in the text and the Methods section. Gel (A) included plasminogen and casein, and gel (B) did not include any protein substrate. The samples applied to the gels were as follows: lanes 1 and 2, samples (10 µl) of conditioned medium collected without serum from Hepa or HepG2 cells, respectively; lanes 3 and 5, undiluted aqueous humor samples from two different FVB/N mice (aq-1 and aq-2, 10 µl each in gel [A]; 5 µl aq-1 in gel [B], lane 3); lanes 4 and 6, mixtures of aq-1 or aq-2 (5 µl each) with Hepa (5 µl). MW, Molecular weight; m., murine; h., human.

Based on these results, we concluded that the murine aqueous humor contains activities of PAI-1, uPA, and tPA, with PAI-1 being the major inhibitor capable of balancing the PA/plasmin-mediated proteolysis. Notably, we also conducted in the aqueous humor the one-phase reverse zymography under conditions to detect trypsin inhibitors (i.e., plasminogen was omitted, and the gel was incubated with trypsin²⁶ ). The results revealed several trypsin inhibitory bands that have not been further investigated (results not shown).

	Discussion

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This study has shown that the PAI-1 gene is expressed in the ciliary epithelium and that PAI-1 activity is found in the aqueous humor of the murine eye (see Fig. 3 for a schematic represention). These findings, together with previous reports on uPA and tPA in the aqueous humor,^{16 17 18 19} link the PA/plasmin system specifically to the anterior segment of the adult eye. Our results suggest that PAI-1 is involved in balancing fibrinolysis and proteolysis in the aqueous humor and imply that overproduction of PAI-1 in the ciliary epithelium will suppress proteolysis. Normal PAI-1 levels may be required to maintain a homeostatic state in the anterior segment with respect to the fibrinolytic capacity and the extracellular matrix composition. Increased PAI-1 levels in the aqueous humor could potentially interfere with clot lysis and with PA-mediated extracellular proteolysis in the aqueous channels. Such proteolysis could also involve activation of metalloprotease proenzymes previously detected in the aqueous humor and reported to be released from cultured ciliary smooth muscle cells.^{28 29} Decreased extracellular proteolysis may result in the accumulation of excessive extracellular matrix, which if occurring in the trabecular meshwork could obstruct aqueous drainage and thus contribute to increasing the intraocular pressure (IOP).

View larger version (93K): [in this window] [in a new window]   Figure 3. Sites of PAI-1 synthesis and activity in the adult eye. Schematic representation of the anterior segment of the eye and aqueous inflow and outflow (according to Ref. 32 ). Arrows indicate the sites of PAI-1 synthesis and secretion.

Our finding that in the ciliary epithelium PAI-1 mRNA is confined to cells in the process apexes indicates for the first time that these cells are somewhat distinct from the rest of the epithelium. The nature and mechanism of this difference are not known. Interestingly, the ciliary body has recently been demonstrated to express a large group of genes, including genes encoding protease inhibitors.³³ Collectively, these published data and the results presented here indicate the need to carefully balance proteolytic activities in the aqueous humor and the anterior segment of the eye. Notably, we did not detect PAI-1 mRNA in retinal pigment epithelial cells, which have been found previously to secrete PAI-1 when derived from the human eye and grown in culture.¹² This discrepancy could reflect differences between the species and/or the states in vivo and in culture.

In the present study, we also found that among developing eye tissues PAI-1 mRNA could be detected only in the ganglion cell layer of the retina at postnatal days 1 to 4 (we did not test later postnatal ages). This PAI-1 expression coincides with retinal angiogenesis³⁴ and is in accordance with PAI-1 involvement in neovascularization in other physiological cases.⁹ It is as yet unknown whether PAI-1 is involved in pathologic cases of ocular neovascularization such as after hypoxia, reperfusion, or diabetic retinopathy. It is of interest, however, that retinal microvessels from diabetic patients contain increased levels of PAI-1 mRNA as determined by solution hybridization.³⁵

In conclusion, our results indicate that PAI-1 is produced in the ciliary epithelium and found in the aqueous humor, suggesting that PAI-1 plays a role in balancing proteolysis specifically in the anterior segment of the eye. Our data raise the possibility that PAI-1 overproduction in the ciliary epithelium may inhibit proteolysis and thus could causally contribute to outflow obstruction, implying that suppression of PAI-1 synthesis could be a novel therapeutic approach to reduce the IOP.

	Acknowledgements

 
The authors thank Rene Abramovitz for conducting the one-phase reverse zymography.

	Footnotes

 
Supported by the Dorot Science Fellowship Foundation administered by the Israeli Academy of Sciences and Humanities, by the Israel Ministry of Health, and by the Leo and Julia Forchheimer Center for Molecular Genetics at the Weizmann Institute of Science.

Submitted for publication January 22, 1999; revised June 10 and November 1, 1999; accepted November 30, 1999.

Commercial relationships policy: N.

Corresponding author: Ruth Miskin, Department of Biological Chemistry, Weizmann Institute of Science, Rehovot 76100, Israel. ruth.miskin{at}weizmann.ac.il

	References

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1. Wiman, B. (1995) Plasminogen activator inhibitor 1 (PAI-1) in plasma: its role in thrombotic disease Thromb Haemost 74,71-76[Medline][Order article via Infotrieve]
2. Loskutoff, DJ (1991) Regulation of PAI-1 gene expression Fibrinolysis 5,197-206
3. Vassalli, J–D, Sappino, A–P, Belin, D (1991) The plasminogen activator/plasmin system J Clin Invest 88,1067-1072
4. Rifkin, DB (1997) Cross-talk among proteases and matrix in the control of growth factor action Fibrinolysis & Proteolysis 11,3-9
5. Chapman, HA (1997) Plasminogen activators, integrins, and the coordinated regulation of cell adhesion and migration Curr Opin Cell Biol 9,714-724[Medline][Order article via Infotrieve]
6. Carmeliet, P. (1997) Insights from gene-inactivation studies of the coagulation and plasminogen Fibrinolysis & Proteolysis 11(suppl 2),181-191
7. Juhan–Vague, I, Alessi, MC, Vague, P. (1991) Increased plasma plasminogen activator inhibitor 1 levels: a possible link between insulin resistance and atherothrombosis Diabetologia 34,457-462[Medline][Order article via Infotrieve]
8. Schneiderman, J, Sawdey, MS, Keeton, MR, et al (1992) Increased type 1 plasminogen activator inhibitor gene expression in atherosclerotic human arteries Proc Natl Acad Sci USA 89,6998-7002[Abstract/Free Full Text]
9. Bacharach, E, Itin, A, Keshet, E. (1992) In vivo patterns of expression of urokinase and its inhibitor PAI-1 suggest a concerted role in regulating physiological angiogenesis Proc Natl Acad Sci USA 89,10686-10690[Abstract/Free Full Text]
10. Simpson, AJ, Booth, NA, Moore, NR, Bennett, B. (1991) Distribution of plasminogen activator inhibitor (PAI-1) in tissues J Clin Pathol 44,139-143[Abstract/Free Full Text]
11. Masos, T, Miskin, R. (1997) mRNAs encoding urokinase-type plasminogen activator and plasminogen activator inhibitor-1 are elevated in the mouse brain following kainate-mediated excitation Mol Brain Res 47,157-169[Medline][Order article via Infotrieve]
12. Hackett, SF, Campochiaro, PA (1993) Modulation of plasminogen activator inhibitor-1 and urokinase in retinal pigmented epithelial cells Invest Ophthalmol Vis Sci 34,2055-2061[Abstract/Free Full Text]
13. Siren, V, Immonen, I, Cantell, K, Vaheri, A. (1994) Alpha- and gamma-interferon inhibit plasminogen activator inhibitor-1 gene expression in human retinal pigment epithelial cells Ophthalmic Res 26,1-7[Medline][Order article via Infotrieve]
14. Shuman, MA, Polansky, JR, Merkel, C, Alvarado, JA (1988) Tissue plasminogen activator in cultured human trabecular meshwork cells: predominance of enzyme over plasminogen activator inhibitor Invest Ophthalmol Vis Sci 29,401-405[Abstract/Free Full Text]
15. Tripathi, RC, Tripathi, BJ, Park, JK (1990) Localization of urokinase-type plasminogen activator in human eyes: an immunocytochemical study Exp Eye Res 51,545-552[Medline][Order article via Infotrieve]
16. Tripathi, RC, Park, JK, Tripathi, BJ, Millard, C. (1988) Tissue plasminogen activator in human aqueous humor and its possible therapeutic significance Am J Ophthalmol 106,719-722[Medline][Order article via Infotrieve]
17. Bernatchez, SF, Tabatabay, C, Belin, D. (1992) Urokinase-type plasminogen activator in human aqueous humor Invest Ophthalmol Vis Sci 33,2687-2692[Abstract/Free Full Text]
18. Wang, Y, Taylor, DM, Smalley, DM, Cone, RE, O’Rourke, J. (1994) Increased basal levels of free plasminogen activator activity found in human aqueous humor Invest Ophthalmol Vis Sci 35,3561-3566[Abstract/Free Full Text]
19. Smalley, DM, Fitzgerald, JE, Taylor, DM, Cone, RE, O’Rourke, J. (1994) Tissue plasminogen activator activity in human aqueous humor Invest Ophthalmol Vis Sci 35,48-53[Abstract/Free Full Text]
20. Pandolfi, M, Astrup, T. (1966) Effect of plasmin on outflow resistance in the primate eye Proc Soc Exp Biol Med 121,139-141[Medline][Order article via Infotrieve]
21. Mehra, KS, Dube, B, Mikuni, I, Dube, RK (1984) Reduced fibrinolytic activity in aqueous humor of chronic simple glaucoma Tokai J Exp Clin Med 9,33-34[Medline][Order article via Infotrieve]
22. O’Rourke, J, Lindsay, M, Kreutzer, D, et al (1982) Evidence of impaired anterior segment fibrinolytic activity in chronic uveitis Ophthalmic Res 14,256-264[Medline][Order article via Infotrieve]
23. Miskin, R, Axelrod, JH, Griep, AE, et al (1990) Human and murine urokinase cDNAs linked to the murine A-crystallin promoter exhibit lens and non-lens expression in transgenic mice Eur J Biochem 190,31-38[Medline][Order article via Infotrieve]
24. Pittler, SJ, Baehr, W. (1991) Identification of a nonsense mutation in the rod photoreceptor cGMP phosphodiesterase ß-subunit gene of the rd mouse Proc Natl Acad Sci USA 88,8322-8326[Abstract/Free Full Text]
25. Masos, T, Miskin, R. (1996) Localization of urokinase-type plasminogen activator mRNA in the adult mouse brain Mol Brain Res 35,139-148[Medline][Order article via Infotrieve]
26. Miskin, R, Abramovitz, R. (1995) One-phase reverse zymography after denaturing gel electrophoresis: high sensitivity detection of activity of plasminogen activator inhibitor-2 and other protease inhibitors Fibrinolysis 9,331-342
27. Kaufman, MH. (1992) The Atlas of Mouse Development ,294 Academic Press San Diego, CA.
28. Vodillo–Ortega, F, Gonzalez–Avila, G, Chevez, P, Abraham, CR, Montano, M, Selman–Lamoa, M. (1989) A latent collagenase in human aqueous humor Invest Ophthalmol Vis Sci 30,332-335[Abstract/Free Full Text]
29. Weinreb, RN, Kashiwagi, K, Kashiwagi, F, Tsukahara, S, Lindsey, JD (1997) Prostaglandins increase matrix metalloproteinase release from human ciliary smooth muscle cells Invest Ophthalmol Vis Sci 38,2772-2780[Abstract/Free Full Text]
30. Pasquale, LR, Dorman–Pease, ME, Lutty, GA, Quigley, HA, Jampel, HD (1993) Immunolocalization of TGF-ß1, TGF-ß2, and TGF-ß3 in the anterior segment of the human eye Invest Ophthalmol Vis Sci 34,23-30[Abstract/Free Full Text]
31. Jampel, HD, Roche, N, Stark, WJ, Roberts, AB. (1990) Transforming growth factor-ß in human aqueous humor Curr Eye Res 9,963-969[Medline][Order article via Infotrieve]
32. Kolker, AE, Hetherington, J, Jr. (1983) Kolker, AE Hetherington, J, Jr eds. Becker-Shaffer’s Diagnosis and Therapy of the Glaucomas CV Mosby St. Louis, MO.
33. Ortego, J, Escribano, J, Coca–Prados, M. (1997) Gene expression of proteases and protease inhibitors in the human ciliary epithelium and ODM-2 cells Exp Eye Res 65,289-299[Medline][Order article via Infotrieve]
34. Stone, J, Itin, A, Alon, T, et al (1995) Development of retinal vasculature is mediated by hypoxia-induced vascular endothelial growth factor (VEGF) expression by neuroglia J Neurosci 15,4738-4747[Abstract]
35. Cagliero, E, Grant, MB, Lorenzi, M. (1991) Measurement of gene expression in human retinal microvessels by solution hybridization Invest Ophthalmol Vis Sci 32,1439-1445[Abstract/Free Full Text]

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