Journal of Histochemistry and Cytochemistry, Vol. 46, 1033-1042, September 1998, Copyright © 1998, The Histochemical Society, Inc.


ARTICLE

Human Corneal Epithelial Basement Membrane and Integrin Alterations in Diabetes and Diabetic Retinopathy1

Alexander V. Ljubimova, Zhi-shen Huanga, Gang H. Huanga, Robert E. Burgesonb, Donald Gullbergc, Jeffrey H. Minerd, Yoshifumi Ninomiyae, Yoshikazu Sadof, and M. Cristina Kenneya
a Ophthalmology Research Laboratories, Burns & Allen Research Institute, Cedars-Sinai Medical Center, UCLA Medical School Affiliate, Los Angeles, California
b MGH/Harvard Cutaneous Biology Research Center, Massachusetts General Hospital East, Charlestown, Massachusetts
c Department of Animal Physiology, Uppsala University, Uppsala, Sweden
d Renal Division, Washington University School of Medicine, St Louis, Missouri
e Okayama University Medical School, Okayama, Japan
f Shigei Medical Research Institute, Okayama, Japan

Correspondence to: Alexander V. Ljubimov, Cedars-Sinai Medical Center, Davis-5069, 8700 Beverly Boulevard, Los Angeles, CA 90048..


  Summary
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Summary
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Materials and Methods
Results
Discussion
Literature Cited

Corneas of diabetic patients have abnormal healing and epithelial adhesion, which may be due to alterations of the corneal extracellular matrix (ECM) and basement membrane (BM). To identify such alterations, various ECM and BM components and integrin receptors were studied by immunofluorescence on sections of normal and diabetic human corneas. Age-matched corneas from 15 normal subjects, 10 diabetics without diabetic retinopathy (DR), and 12 diabetics with DR were used. In DR corneas, the composition of the central epithelial BM was markedly altered, compared to normal or non-DR diabetic corneas. In most cases the staining for entactin/nidogen and for chains of laminin-1 ({alpha}1ß1{gamma}1) and laminin-10 ({alpha}5ß1{gamma}1) was very weak, discontinuous, or absent over large areas. Other BM components displayed less frequent changes. The staining for {alpha}3ß1 (VLA-3) laminin binding integrin was also weak and discontinuous in DR corneal epithelium. Components of stromal ECM remained unchanged even in DR corneas. Therefore, distinct changes were identified in the composition of the epithelial BM in DR corneas. They may be due to increased degradation or decreased synthesis of BM components and related integrins. These alterations may directly contribute to the epithelial adhesion and wound healing abnormalities found in diabetic corneas. (J Histochem Cytochem 46:1033–1041, 1998)

Key Words: diabetic retinopathy, corneal epithelium, basement membrane, integrins, VLA-3, laminin chains, entactin/nidogen, type IV collagen isoforms, extracellular matrix, immunofluorescence


  Introduction
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

Diabetes mellitus, both insulin-dependent (IDDM, or Type I) and non-insulin-dependent (NIDDM, or Type II), causes loss of vision not only from major abnormalities of the retina and lens but also from the alterations in the cornea, tear film, eyelids, iris, ciliary body, and cranial nerves (Herse 1988 ). Patients with diabetes and diabetic retinopathy (DR) are at increased risk for developing corneal disorders, such as epithelial defects, recurrent epithelial erosions, decreased sensitivity, delayed re-epithelialization, abnormal wound repair, increased susceptibility to injury, ulcers, and edema (Hatchell et al. 1983 ; Herse 1988 ). Other diabetic corneal alterations include increased basement membrane (BM) thickness (Herse 1988 ; Azar et al. 1989 ), decreased hemidesmosome numbers (Azar et al. 1992 ; Meller et al. 1996 ), impaired endothelial cell function (Saini and Mittal 1996 ), altered collagen (Sady et al. 1995 ), and abnormal deposition of complement proteins (Weiss et al. 1990 ).

These and other defects are likely to result from alterations in epithelial adhesion, migration, differentiation, and renewal. Extracellular matrix (ECM) and BM components acting through cell surface adhesive receptors, integrins (Giancotti 1997 ), play an important role in the adhesion, migration, and differentiation of various cells (Azar et al. 1992 ; Kurpakus et al. 1992 ; Zieske et al. 1994 ). We therefore hypothesized that corneal epithelial abnormalities in diabetes may be due to altered BM structure and/or epithelial integrin expression. However, despite abundant information on normal corneal integrin patterns and BM structure (Lauweryns et al. 1991 ; Tervo et al. 1991 ; Virtanen et al. 1992 ; Masur et al. 1993 ; Stepp et al. 1993 ; Trinkaus-Randall et al. 1993 ; Ljubimov et al. 1995 , Ljubimov et al. 1996a ; Tuori et al. 1996 ), their changes in diabetes remained unknown.

Consequently, the purpose of this investigation was to identify the specific changes in individual BM and ECM components and in integrins that occur in the diabetic human cornea, with special reference to DR. Such a study was a necessary first step in understanding of the molecular mechanisms of corneal epithelial abnormalities in diabetes. Because of lack of pertinent data, we needed to study many BM components and integrins to single out those that were specifically altered in diabetes and DR. We conclude that corneas from patients with DR have specific alterations in the distribution of major epithelial BM components, entactin/nidogen, laminin-1 and laminin-10, and of an integrin receptor, {alpha}3ß1 (VLA-3), reported to bind to these components. In contrast, corneas from diabetic patients without DR showed such alterations much less frequently. This suggests that, as retinal diabetic disease worsens, concomitant alterations of the corneal epithelial BM occur in parallel. Our study therefore provides the necessary background information for future investigations of the role of changes in specific BM components and integrins in DR-associated corneal dysfunction.


  Materials and Methods
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

Tissue
Human autopsy corneas were obtained within 30 hr after death from the National Disease Research Interchange (Philadelphia, PA). They included age-matched corneas from 15 non-diabetic individuals (normal group), 10 diabetics without DR, referred to as non-DR diabetics (four IDDM and six NIDDM), and 12 diabetics with DR (nine IDDM and three NIDDM). All corneas were bisected, embedded in OCT (Miles; Elkhart, IN), and cryostat sections were studied.

Immunohistological Analysis
Indirect immunofluorescent staining of cryostat sections, their treatment with urea to reveal type IV collagen epitopes, and photography were performed as described (Ljubimov et al. 1995 ). Routine specificity controls (without primary or secondary antibodies) were negative. Monoclonal antibodies were used as straight hybridoma supernatants or at 10–20 µg/ml when purified, and polyclonal antibodies were used at 20–30 µg/ml. At least two independent experiments were performed for each marker, with identical results. Abnormalities in the immunofluorescent distribution of a specific protein, such as appearance of staining (Figure 5, {alpha}1(IV) chain, tenascin-C, fibrillin-1), markedly decreased staining (Figure 6, {alpha}3ß1, ß1 integrins), discontinuity (Figure 2, laminin {gamma}1, entactin/nidogen; Figure 4, {alpha}3(IV) chain) and absence of staining (Figure 2, laminin {alpha}5, ß1) were taken into account only if they were reproducible on serial sections and/or with different antibodies (e.g., to different chains of laminin).



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Figure 1. Distribution of {alpha}1, {alpha}4 and {alpha}5 laminin chains in the normal adult human corneal epithelial BM (upper row) and DM (lower row). {alpha}1 and {alpha}5 chains (double labeling) co-distribute in both BMs, whereas {alpha}4 chain is absent. Note keratocyte staining for {alpha}1 and {alpha}5 chains. Only central corneas are shown. Bar = 40 µm.



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Figure 2. Representative distribution of laminin-10 chains ({alpha}5, ß1, {gamma}1) and entactin/nidogen in normal (N, upper row) and DR (lower row) human corneas. Note disappearance of staining in DR corneas for laminin {alpha}5 and ß1 chains and discontinuity of staining for laminin {gamma}1 chain and entactin/nidogen. Laminin-1 ({alpha}1ß1{gamma}1) was altered in a very similar way to laminin-10 (not shown here). E, epithelium; S, stroma; LN, laminin; ENT, entactin/nidogen. Bar = 40 µm.



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Figure 3. Alterations in Type IV collagen chains in DR corneas. Strong BM staining is seen in normal corneas (N, upper row). Note discontinuous staining for {alpha}3(IV) chain and absence of staining for {alpha}4(IV) chain in DR corneas (lower row). E, epithelium; S, stroma. Bar = 40 µm.



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Figure 4. Normal distribution patterns of {alpha}5 and {alpha}6 chains of type IV collagen, laminin-5, and Type VII collagen in DR corneas. Sections of two DR corneas were double labeled for {alpha}5(IV) and {alpha}6(IV) chains or for laminin-5 and Type VII collagen. All proteins are continuous in the epithelial BM. E, epithelium; S, stroma; LN-5, laminin-5; C VII, Type VII collagen. Bar = 40 µm.



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Figure 5. Frequent ECM abnormalities in DR corneas. Fibronectin (FN) is absent from Descemet's membrane (DM). {alpha}1(IV) chain appears in the central epithelial BM. Tenascin-C (TN-C) and fibrillin-1 (FIB-1), normally present only in the limbus, are expressed in the stroma (TN-C) and epithelial BM (FIB-1). E, epithelium; S, stroma. Bar = 40 µm.



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Figure 6. Integrins in normal and DR corneas. The staining for {alpha}3ß1 integrin (left column) and ß1 integrin subunit (middle column) is very weak and discontinuous in DR corneas compared to normal (N) corneas. At the same time, in DR corneas, patterns of {alpha}6 and ß4 integrin subunits are typically normal (double labeling, right column). In view of reduced ß1 subunit, but abundant ß4 subunit, {alpha}6 may mostly complex with ß4 to form {alpha}6ß4 integrin. E, epithelium; S, stroma. Bar = 40 µm.

Antibodies
Well-characterized antibodies were used to {alpha}1{alpha}6 chains of Type IV collagen, to {alpha}1, {alpha}2, {alpha}4, ß1, ß2, and {gamma}1 chains of laminin, to laminin-5 ({alpha}3ß3{gamma}2), to entactin/nidogen, to fibronectin eighth Type III repeat, to Types VI, VII, XII, and XIV collagen, and to perlecan and bamacan core proteins (Ljubimov et al. 1995 ; Ljubimov et al. 1996a , Ljubimov et al. 1996b ; Miner et al. 1997 ; Tiger et al. 1997 ). Antibodies to Types I, III, and V collagen were from Southern Biotechnology (Birmingham, AL), antibodies to fibrillin-1 (clone 11C1), tenascin-C (clone TN-2), and decorin core protein were from Chemicon International (Temecula, CA). An antibody to cellular fibronectin (clone IST-9) was from Sera-Lab (Crawley Down, UK), and an antibody to Type VIII collagen (clone 9H3) was from Seikagaku America (Rockville, MD). The monoclonal antibody 4C7 to {alpha}5 chain of laminin was from Chemicon International. This antibody was previously believed to react with laminin {alpha}1 chain and was only recently shown to recognize the {alpha}5 chain instead (Tiger et al. 1997 ). Antibodies to {alpha}5ß1 integrin heterodimer, {alpha}3ß1 integrin heterodimer (clone M-KID 2), to {alpha}6 (clone NKI-GoH3), {alpha}3 (clone P1B5), {alpha}2, {alpha}1 (clone FB12 to I domain), ß1 (clone HB1.1), and ß4 (clone 3E1) integrin subunits, and cross-species-absorbed fluorescein- and rhodamine-conjugated secondary antibodies were from Chemicon International.

Statistical Analysis
This was performed using a double-sided Fisher's exact test (InStat software program; GraphPad Software, San Diego, CA).


  Results
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Materials and Methods
Results
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Literature Cited

Laminin Chain Distribution in Normal Human Corneas
Human cornea can be topographically divided into the central part, which has the collagenous Bowman's layer under the epithelial BM, and the peripheral corneoscleral limbus, which harbors epithelial stem cells but does not have Bowman's layer (Ljubimov et al. 1995 ). Previously, the corneal distribution of laminin and Type IV collagen isoforms has been described in detail (Ljubimov et al. 1995 , Ljubimov et al. 1996a ; Tuori et al. 1996 ). However, the antibody 4C7 commonly used to recognize laminin {alpha}1 chain was recently shown to react with a ubiquitous {alpha}5 chain instead (Tiger et al. 1997 ). To reveal corneal expression of laminin {alpha}1 chain, we have previously used an 11D5 antibody (see Ljubimov et al. 1995 ) that gave identical staining patterns to 4C7 and also may have recognized the {alpha}5 chain. Therefore, the distribution of laminin chains in the normal human cornea first had to be revisited using other antibodies with a properly defined {alpha}-chain specificity. Such antibodies became available only very recently (Miner et al. 1997 ; Tiger et al. 1997 ).

In normal adult corneas, the laminin {alpha}5 chain-specific antibody 4C7 yielded the same staining pattern as 11D5: the epithelial central and limbal BM, limbal blood vessels, and the endothelial face of Descemet's membrane (DM) were strongly positive (Figure 1). Laminin {alpha}1 chain was present in the epithelial BM throughout the cornea, and on the endothelial face of DM (Figure 1). Limbal blood vessels exhibited weak to no staining (not shown). Some keratocyte staining was observed for both the {alpha}1 and {alpha}5 chains (Figure 1). The {alpha}4 chain could not be detected with the antibody used (Figure 1). These and previous data (Ljubimov et al. 1995 ; Tuori et al. 1996 ) suggest that multiple laminins may be present in the corneal epithelial BM, including laminin-1 ({alpha}1ß1{gamma}1), laminin-5 ({alpha}3ß3{gamma}2), laminin-6 (ß1{gamma}1), and laminin-10 ({alpha}5ß1{gamma}1), with more isoforms in the limbus (see Miner 1998 for nomenclature). In DM, chains of laminin-1 and laminin-10 have been detected (Figure 1; Ljubimov et al. 1995 ).

Basement Membrane Abnormalities in Diabetic Retinopathy Corneas
In the corneoscleral limbus, all ECM and BM components studied had a normal distribution in all non-DR diabetic or DR corneas. In addition, the corneal stromal components decorin, bamacan, and Types I, III, V, VI, and XII collagen were unchanged compared to normal corneas (not shown). However, profound alterations were revealed at the level of the epithelial BM in the central part of DR corneas.

In most DR cases, staining for chains of laminin-1 and laminin-10, {alpha}1 (nine of 12 cases), {alpha}5 (10 of 12 cases), ß1 (10 of 12 cases) and {gamma}1 (eight of 10 cases), and for entactin/nidogen (seven of 11 cases) was very weak, discontinuous, or absent from parts or whole central epithelial BM (Figure 2; Table 1). In contrast, these components displayed strong and continuous staining in normal corneas (Figure 1 and Figure 2). The incidence of the abnormal distribution of laminin-1, laminin-10, or entactin/nidogen in the DR group was significantly higher (p<0.03) than in either non-DR diabetic or normal group. Laminin chains {alpha}2 and ß2 did not appear in the central epithelial BM or DM of non-DR diabetic or DR corneas and were seen only in the limbal BM, similar to normal corneas (not shown). In about half of the DR cases, alterations similar to laminin-1 and entactin/nidogen were observed in the central epithelial BM for {alpha}3 and {alpha}4 Type IV collagen chains (Figure 3; Table 1), although differences from the non-DR diabetic group were not significant. Laminin-5, Type VII collagen, {alpha}5 and {alpha}6 chains of Type IV collagen (Figure 4; Table 1), and perlecan (not shown) were rarely altered even in DR corneas. In the epithelial BM, fibronectin was also normal in most cases.


 
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Table 1. Alterations of BM, ECM, and integrins in diabetic corneasa

In DM, the only consistent change in DR group was the absence of fibronectin (both total and cellular, six of nine cases, Figure 5), which was found at the stromal aspect of DM in normal corneas (Ljubimov et al. 1995 ). This change was also detected in some non-DR diabetic corneas. In addition, in some non-DR diabetic corneas and especially in DR corneas, several ECM components appeared that were not present in normal central corneas. These were {alpha}1{alpha}2 Type IV collagen abnormally deposited in the epithelial BM, fibrillin-1 deposited in BM and stroma, and tenascin-C mainly deposited in stroma (Figure 5). The deposition of these components may be related to diabetes-associated corneal edema, because they also appeared in human corneas with bullous keratopathy, an edematous blistering disease (Ljubimov et al. 1996a ).

Epithelial Integrin Alterations in Diabetic Retinopathy Corneas
The next question was to determine whether the observed alterations of laminin-1, laminin-10, and entactin/nidogen in DR corneal epithelial BM were accompanied by changes in the expression of specific integrin receptors on corneal cells that bind to these components. To this end, we studied the distribution of chains of most of the known laminin-binding inte-grins, including {alpha}6, {alpha}3 (also reported to bind entactin/nidogen), {alpha}2, {alpha}1, ß4, and ß1. One of these integrin chains, {alpha}1, was not found in any of the central corneas studied (not shown). In addition, corneas were stained for the fibronectin receptor {alpha}5ß1, which served as a negative control because its ligand did not change in the epithelial BM of diabetic corneas. Because diabetic changes mainly concerned the epithelial BM, we will discuss below primarily the epithelial patterns of studied integrins. The endothelium and keratocytes of non-DR diabetic and DR corneas were positive for {alpha}5ß1, {alpha}6, {alpha}3, {alpha}2, and ß1 integrins, similar to normal corneas (not shown).

In normal corneas, the epithelial patterns of studied integrins and their subunits were identical to previously described patterns (Lauweryns et al. 1991 ; Tervo et al. 1991 ; Virtanen et al. 1992 ; Stepp et al. 1993 ; Trinkaus-Randall et al. 1993 ). In the epithelium of DR corneas (8/10 cases), the staining for {alpha}3ß1 integrin was markedly weaker or discontinuous compared to non-DR diabetic or normal corneas (Figure 6; Table 1). Changes were more pronounced in suprabasal layers and on the basal surface of basal epithelial cells. In some DR corneas these alterations were local, whereas in other corneas they were seen in the majority of the epithelial cells. Identical results were obtained with antibodies recognizing the whole integrin heterodimer (Figure 6) or its {alpha}3 chain (not shown). The staining for ß1 integrin was also weaker than normal or discontinuous in more than half of DR corneas (Figure 6; Table 1), unlike non-DR diabetic corneas. In contrast, the distribution of {alpha}6, ß4 (Figure 6) and {alpha}5ß1 (not shown) integrins did not change in either non-DR diabetic or DR corneas compared to normal corneas. Because the ß1 integrin subunit, unlike {alpha}6 and ß4, appeared to be reduced in DR corneas, the epithelial {alpha}6 subunit may mostly be part of {alpha}6ß4 rather than of {alpha}6ß1 integrin.


  Discussion
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Materials and Methods
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Diabetic retinopathy is a severe ocular diabetic complication and a major cause of legal blindness. Although diabetes affects mostly the retina and iris (Lim and Murphy 1991 ), it also causes a corneal disorder, diabetic keratopathy, which involves epitheliopathy (altered epithelial barrier function, increased epithelial fragility, decreased basal cell adhesion and impaired healing), corneal edema resulting from endothelial alteration, and tear film dysfunction (Rao 1987 ; Meller et al. 1996 ; Ohashi 1997 ).

Diabetic nephropathy and retinopathy bring about profound changes in the ECM and BM in kidney and retina, respectively. Glomerular, retinal, and vascular BMs are thickened in diabetics and exhibit alterations in the expression of laminins, collagens, fibronectin, tenascin-C, proteoglycans, and some integrins (Osterby 1990 ; Nerlich and Schleicher 1991 ; Jin et al. 1996 ; Ljubimov et al. 1996b ; Yokoyama and Deckert 1996 ; Regoli and Bendayan 1997 ). In diabetic corneas, only general BM changes have been described. They include BM thickening, decreased stromal penetration of anchoring fibrils, and greater susceptibility of epithelial BM to damage (Hatchell et al. 1983 ; Azar et al. 1989 ). The influence of diabetes on corneal BM/ECM components and integrins was not studied, which prompted us to analyze in detail their distribution patterns in non-DR diabetic and DR corneas.

We show here that the epithelial BM composition in DR corneas is significantly altered. Major epithelial BM components, entactin/nidogen, laminin-1, and laminin-10, were markedly diminished in DR corneas as revealed by specific immunofluorescence. Alterations in other BM components, laminin-5, Type IV collagen isoforms, Type VII collagen, and fibronectin, were less pronounced and less common.

The next step was to analyze in DR corneas the fate of integrins that bind laminin and entactin/nidogen. Only one integrin studied, {alpha}3ß1 (VLA-3), was significantly altered in the epithelium of DR corneas compared to both normal and non-DR diabetics (Table 1). This integrin has been reported to bind both isolated entactin/nidogen and laminins (Dedhar et al. 1992 ; Gresham et al. 1996 ; de Melker et al. 1997 ). Possibly its ubiquitous splice variant, {alpha}31, is expressed in cornea, because the other variant, {alpha}31, has a restricted tissue distribution (de Melker et al. 1997 ).

Laminin-binding integrin {alpha}1ß1 (not shown) was not found in the corneal epithelium. Laminin-binding integrins {alpha}2ß1 and {alpha}6ß4 were generally not altered in DR corneas (Table 1). This might be due to preferential binding of {alpha}2ß1 integrin to collagen and of {alpha}6ß4, to laminin-5 (Niessen et al. 1994 ; Giancotti 1997 ), both of which were not significantly changed in DR corneas. {alpha}7ß1 laminin binding integrin (Velling et al. 1996 ) was not analyzed here owing to lack of available antibodies.

The observed alterations in major human corneal epithelial BM components and in their binding {alpha}3ß1 integrin appear to be DR-specific. In fact, in corneas from patients with bullous keratopathy, laminin and entactin/nidogen abnormalities were less severe and less common (similar to non-DR diabetics), and both {alpha}3ß1 and ß1 integrins retained a normal distribution (not shown). In addition, BM and integrin alterations were significantly more pronounced and more common in DR corneas than in non-DR diabetic corneas (Table 1). It should be noted that no similar alterations have been reported in retinas of DR patients or in kidneys of diabetic nephropathy patients. In contrast, there was an increased expression of BM proteins and integrins (Nerlich and Schleicher 1991 ; Jin et al. 1996 ; Ljubimov et al. 1996b ).

What could be the mechanisms of such alterations and why would they develop late in the course of the disease, with the advent of DR and proliferative DR? One possibility is that BM and/or integrin synthesis is decreased because of the action of growth factors abnormally expressed in the diabetic eye. Growth factor modulation of laminin-1, entactin/nidogen, and {alpha}3ß1 integrin expression was shown in other systems (Schreiber et al. 1995 ; Narita et al. 1996 ; Nissinen et al. 1997 ). Elevated levels of fibroblast growth factor-2, insulin-like growth factor-I, and vascular endothelial growth factor have been found in the vitreous of DR patients compared to non-DR diabetics (Aiello 1997 ; Boulton et al. 1997 ). Some of these growth factors may also become elevated in DR corneas or may diffuse from the vitreous to the aqueous, this affecting corneal cell BM and integrin production.

Another possibility is that, in DR corneas, BM components and/or integrins may be altered because of their increased degradation by proteinases elevated in these corneas. Several lines of evidence support this hypothesis. Cultured diabetic human retinal endothelial cells have abnormal expression of matrix metalloproteinase-2 (MMP-2), which can cleave laminin (Grant et al. in press ). In mouse mammary gland epithelium, entactin/nidogen is a specific target of MMP-3/stromelysin-1 (Alexander et al. 1996 ), and we have found increased expression of MMP-3 in DR corneas compared to normal and non-DR diabetic corneas (unpublished data). Additional experiments are needed to determine the actual mechanism(s) of laminin and entactin/nidogen decrease in the DR corneal epithelial BM.

The laminin {gamma}1 chain is involved in the formation of stable complexes with entactin/nidogen (Mishima et al. 1996 ; Kadoya et al. 1997 ) that serves as a linker between laminin and Type IV collagen networks. This interaction is important for BM assembly, embryonic development, and tissue morphogenesis (Dziadek 1995 ; Kadoya et al. 1997 ). It is possible that reduced expression of {gamma}1 chain-containing laminin-1 and laminin-10 in the epithelial BM of DR corneas could trigger coordinate alterations in entactin/nidogen. If proteolysis is involved in the DR corneal alterations, it may first affect entactin/nidogen, which is easily proteolysed (Dziadek 1995 ; Alexander et al. 1996 ; Kadoya et al. 1997 ). This, in turn, may lead to changes of laminins that complex with entactin/nidogen.

Interaction of corneal epithelial cells with BM components is known to modulate integrin expression patterns (Grushkin-Lerner et al. 1997 ). Therefore, BM changes in DR corneas may trigger respective changes in the integrin expression. Alternatively, the inhibition of {alpha}3ß1 integrin expression by gene knockout has been recently shown to disrupt epidermal BM assembly (DiPersio et al. 1997 ). It can be suggested that downregulation of {alpha}3ß1 integrin by some DR-activated factors may cause BM alterations observed in DR corneas. One such mechanism may be an increase in the expression of matrix metalloproteinases that degrade {alpha}3ß1 BM ligands (Chintala et al. 1996 ).

The concerted reduction of expression of entactin/nidogen, laminin-1, laminin-10, and of their binding {alpha}3ß1 integrin in DR corneas may severely impair the adhesive and migratory properties of corneal epithelial cells. Such alterations in corneal cell–BM adhesion may be the mechanism underlying clinically observed diabetic abnormalities in epithelial barrier function, adhesion, epithelial integrity and wound healing. Finding ways to inhibit or retard corneal BM and integrin downregulation may prove useful in the development of novel therapeutics aimed at alleviating the symptoms of diabetic keratopathy.


  Footnotes

1 Presented in part at the Annual Meeting of the Association for Research in Vision and Ophthalmology (ARVO), Fort Lauderdale, FL, May 1997.


  Acknowledgments

Supported by the Iris and B. Gerald Cantor Foundation, the Discovery Fund for Eye Research, and the Skirball Program for Molecular Ophthalmology.

We thank Profs J.R. Couchman (University of Alabama, Birmingham, AL), E. Engvall (The Burnham Institute, La Jolla, CA), and A.F. Michael (University of Minnesota, Minneapolis, MN) for providing antibodies. Antibodies to laminin ß2 chain produced by Dr J. Sanes and to Type IV collagen {alpha}1{alpha}2 chains produced by Dr H. Furthmayr were obtained from the Developmental Studies Hybridoma Bank, Department of Biology, University of Iowa (Iowa City, IA), under contract N01-HD-2-3144 from the NICHD.

Received for publication December 18, 1997; accepted May 12, 1998.


  Literature Cited
Top
Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

Aiello LP (1997) Vascular endothelial growth factor and the eye: biochemical mechanisms of action and implications for novel therapies. Ophthalmi Res 29:354-362

Alexander CM, Howard EW, Bissell MJ, Werb Z (1996) Rescue of mammary epithelial cell apoptosis and entactin degradation by a tissue inhibitor of metalloproteinase-1 transgene. J Cell Biol 135:1669-1677[Abstract]

Azar DT, Spurr–Michaud SJ, Tisdale AS, Gipson IK (1989) Decreased penetration of anchoring fibrils into the diabetic stroma. A morphometric analysis. Arch Ophthalmol 107:1520-1523[Abstract]

Azar DT, Spurr–Michaud SJ, Tisdale AS, Gipson IK (1992) Altered epithelial-basement membrane interactions in diabetic corneas. Arch Ophthalmol 110:537-540[Abstract]

Boulton M, Gregor Z, McLeod D, Charteris D, Jarvis–Evans J, Moriarty P, Khaliq A, Foreman D, Allamby D, Bardsley B (1997) Intravitreal growth factors in proliferative diabetic retinopathy: correlation with neovascular activity and glycaemic management. Br J Ophthalmol 81:228-233[Abstract/Free Full Text]

Chintala SK, Sawaya R, Gokaslan ZL, Rao JS (1996) Modulation of matrix metalloproteinase-2 and invasion in human glioma cells by {alpha}3ß1 integrin. Cancer Lett 103:201-208[Medline]

Dedhar S, Jewell K, Rojiani M, Gray V (1992) The receptor for the basement membrane glycoprotein entactin is the integrin {alpha}31. J Biol Chem 267:18908-18914[Abstract/Free Full Text]

de Melker AA, Sterk LM, Delwel GO, Fles DL, Daams H, Weening JJ, Sonnenberg A (1997) The A and B variants of the {alpha}3 integrin subunit: tissue distribution and functional characterization. Lab Invest 76:547-563[Medline]

DiPersio CM, Hodivala-Dilke KM, Jaenisch R, Kreidberg JA, Hynes RO (1997) {alpha}3ß1 Integrin is required for normal development of the epidermal basement membrane. J Cell Biol 137:729-742[Abstract/Free Full Text]

Dziadek M (1995) Role of laminin-nidogen complexes in basement membrane formation during embryonic development. Experientia 51:901-913[Medline]

Giancotti FG (1997) Integrin signaling: specificity and control of cell survival and cell cycle progression. Curr Opin Cell Biol 9:691-700[Medline]

Grant MB, Caballero S, Tarnuzzer RW, Bush DM, Bass KE, Ljubimov AV, Spoerri PE, Galardy RE (in press) Matrix metalloproteinases in human retinal microvascular cells. Diabetes

Gresham HD, Graham IL, Griffin GL, Hsieh J-C, Dong L-J, Chung AE, Senior RM (1996) Domain-specific interactions between entactin and neutrophil integrins. G2 domain ligation of integrin {alpha}3ß1 and E domain ligation of the leukocyte response integrin signal for different responses. J Biol Chem 271:30587-30594[Abstract/Free Full Text]

Grushkin–Lerner LS, Kewalramani R, Trinkaus–Randall V (1997) Expression of integrin receptors on plasma membranes of primary corneal epithelial cells is matrix specific. Exp Eye Res 64:323-334[Medline]

Hatchell DL, Magolan JJ, Jr, Besson MJ, Goldman AI, Pederson HJ, Schultz KJ (1983) Damage to the epithelial basement membrane in the corneas of diabetic rabbits. Arch Ophthalmol 101:469-471[Abstract]

Herse PR (1988) A review of manifestations of diabetes mellitus in the anterior eye and cornea. Am J Optom Physiol Opt 65:224-230[Medline]

Jin DK, Fish AJ, Wayner EA, Mauer M, Setty S, Tsilibary E, Kim Y (1996) Distribution of integrin subunits in human diabetic kidneys. J Am Soc Nephrol 7:2636-2645[Abstract]

Kadoya Y, Salmivirta K, Talts JF, Kadoya K, Mayer U, Timpl R, Ekblom P (1997) Importance of nidogen binding to laminin {gamma}1 for branching epithelial morphogenesis of the submandibular gland. Development 124:683-691[Abstract/Free Full Text]

Kurpakus MA, Stock EL, Jones JC (1992) The role of basement membrane in differential expression of keratin proteins in epithelial cells. Dev Biol 150:243-255[Medline]

Lauweryns B, van den Oord JJ, Volpes R, Foets B, Missotten L (1991) Distribution of very late activation integrins in the human cornea. An immunohistochemical study using monoclonal antibodies. Invest Ophthalmol Vis Sci 32:2079-2085[Abstract]

Lim JI, Murphy RP (1991) Review of diabetic retinopathy. Curr Opin Ophthalmol 2:315-323

Ljubimov AV, Burgeson RE, Butkowski RJ, Couchman JR, Wu R-R, Ninomiya Y, Sado Y, Maguen E, Nesburn AB, Kenney MC (1996a) Extracellular matrix alterations in human corneas with bullous keratopathy. Invest Ophthalmol Vis Sci 37:997-1007[Abstract]

Ljubimov AV, Burgeson RE, Butkowski RJ, Couchman JR, Zardi L, Ninomiya Y, Sado Y, Huang Z, Nesburn AB, Kenney MC (1996b) Basement membrane abnormalities in human eyes with diabetic retinopathy. J Histochem Cytochem 44:1469-1479[Abstract]

Ljubimov AV, Burgeson RE, Butkowski RJ, Michael AF, Sun T-T, Kenney MC (1995) Human corneal basement membrane heterogeneity: topographical differences in the expression of type IV collagen and laminin isoforms. Lab Invest 72:461-473[Medline]

Masur SK, Cheung JK, Antohi S (1993) Identification of integrins in cultured corneal fibroblasts and in isolated keratocytes. Invest Ophthalmol Vis Sci 34:2690-2698[Abstract]

Meller D, Augustin AJ, Koch FH (1996) A modified technique of impression cytology to study the fine structure of corneal epithelium. Ophthalm Res 28:71-79

Miner JH (1998) Developmental biology of glomerular basement membrane components. Curr Opin Nephrol Hypertens 7:13-19[Medline]

Miner JH, Patton BL, Lentz SI, Gilbert DJ, Snider WD, Jenkins NA, Copeland NG, Sanes JR (1997) The laminin {alpha} chains: expression, developmental transitions, and chromosomal locations of {alpha}1-5, identification of heterotrimeric laminins 8-11, and cloning of a novel {alpha}3 isoform. J Cell Biol 137:685-701[Abstract/Free Full Text]

Mishima H, Hibino T, Hara H, Otori T (1996) Entactin modulates the attachment of rabbit corneal epithelial cells. Curr Eye Res 15:733-738[Medline]

Narita T, Kawakami–Kimura N, Sato M, Matsuura N, Higashiyama S, Taniguchi N, Kannagi R (1996) Alteration of integrins by heparin-binding EGF-like growth factor in human breast cancer cells. Oncology 53:374-381[Medline]

Nerlich A, Schleicher E (1991) Immunohistochemical localization of extracellular matrix components in human diabetic glomerular lesions. Am J Pathol 139:889-899[Abstract]

Niessen CM, Hogervorst F, Jaspars LH, de Melker AA, Delwel GO, Hulsman EH, Kuikman I, Sonnenberg A (1994) The {alpha}6ß4 integrin is a receptor for both laminin and kalinin. Exp Cell Res 211:360-367[Medline]

Nissinen L, Pirila L, Heino J (1997) Bone morphogenetic protein-2 is a regulator of cell adhesion. Exp Cell Res 230:377-385[Medline]

Ohashi Y (1997) Diabetic keratopathy. Nippon Ganka Gakkai Zasshi 101:105-110[Medline]

Østerby R (1990) Basement membrane morphology in diabetes mellitus. In Rifkin H, Porte D, Jr, eds. Diabetes Mellitus. Theory and Practice. 4th Ed. New York, Elsevier, 220-233

Rao GN (1987) Dr. P. Siva Reddy oration. Diabetic keratopathy. Indian J Ophthalmol 35:16-36[Medline]

Regoli M, Bendayan M (1997) Alterations in the expression of the {alpha}3ß1 integrin in certain membrane domains of the glomerular epithelial cells (podocytes) in diabetes mellitus. Diabetologia 40:15-22[Medline]

Sady C, Khosrof S, Nagaraj R (1995) Advanced Maillard reaction and crosslinking of corneal collagen in diabetes. Biochem Biophys Res Commun 214:793-797[Medline]

Saini JS, Mittal S (1996) In vivo assessment of corneal endothelial function in diabetes mellitus. Arch Ophthalmol 114:649-653[Abstract]

Schreiber BD, Hughes ML, Groggel GC (1995) Insulin-like growth factor-I stimulates production of mesangial cell matrix components. Clin Nephrol 43:368-374[Medline]

Stepp MA, Spurr–Michaud S, Gipson IK (1993) Integrins in the wounded and unwounded stratified squamous epithelium of the cornea. Invest Ophthalmol Vis Sci 34:1829-1844[Abstract]

Tervo K, Tervo T, van Setten G-B, Virtanen I (1991) Integrins in human corneal epithelium. Cornea 10:461-465[Medline]

Tiger C-F, Champliaud M-F, Pedrosa–Donello F, Thornell L-E, Ekblom P, Gullberg D (1997) Presence of laminin {alpha}5 chain and lack of laminin {alpha}1 chain during human muscle development and in muscular dystrophies. J Biol Chem 272:28590-28595[Abstract/Free Full Text]

Trinkaus–Randall V, Tong M, Thomas P, Cornell-Bell A (1993) Confocal imaging of the {alpha}6 and ß4 integrin subunits in the human cornea with aging. Invest Ophthalmol Vis Sci 34:3103-3109[Abstract]

Tuori A, Uusitalo H, Burgeson RE, Terttunen J, Virtanen I (1996) The immunohistochemical composition of the human corneal basement membrane. Cornea 15:286-294[Medline]

Velling T, Collo G, Sorokin L, Durbeej M, Zhang H, Gullberg D (1996) Distinct {alpha}7Aß1 and {alpha}7Bß1 integrin expression patterns during mouse development: {alpha}7A is restricted to skeletal muscle but {alpha}7B is expressed in striated muscle, vasculature, and nervous system. Dev Dyn 207:355-371[Medline]

Virtanen I, Tervo K, Korhonen M, Päällysaho T, Tervo T (1992) Integrins as receptors for extracellular matrix proteins in human cornea. Acta Ophthalmol 70:18-21

Weiss JS, Sang DN, Albert DM (1990) Immunofluorescent characteristics of the diabetic cornea. Cornea 9:131-138[Medline]

Yokoyama H, Deckert T (1996) Central role of TGF-ß in the pathogenesis of diabetic nephropathy and macrovascular complications: a hypothesis. Diabet Med 13:313-320[Medline]

Zieske JD, Mason VS, Wasson ME, Meunier SF, Nolte CJ, Fukai N, Olsen BR, Parenteau NL (1994) Basement membrane assembly and differentiation of cultured corneal cells: importance of culture environment and endothelial cell interaction. Exp Cell Res 214:621-633[Medline]