Introduction

Cataracts are the main cause of reversible blindness globally.¹ They manifest as a progressive decrease of visual acuity, and the only available treatment is surgical extraction.² The main risk factor for cataract formation is aging, but other factors can induce cataract development, such as trauma, Down syndrome, and myotonic dystrophy, to name a few. After aging, diabetes is one of the most significant risk factors for cataract formation.³

Type 2 diabetes mellitus (T2DM) is a chronic systemic disease that can affect all ocular structures, including the lens. Cataract formation in diabetic patients correlates with disease duration.^4,5 There are several mechanisms responsible for cataract formation in T2DM; one of the most studied is overproduction of sorbitol that plays an important role in increasing the osmotic pressure of the lens, causing loss of transparency.⁶ However, there is increasing evidence indicating that lens capsule alterations are also responsible for cataract development.

The lens capsule is a basal membrane (BM) secreted by lens epithelial cells (LECs). The BM and LECs form a continuous barrier that surrounds the entire lens. The primary functions of this barrier are physical protection, promotion of lens differentiation, and regulation of selective permeability to various growth factors, inflammatory mediators, and nutrients, among other molecules. During aging and in certain metabolic disorders like T2DM, chemical and biomechanical properties of the capsule are affected, disrupting selective permeability and allowing the entry of different molecules to the lens.^7,8 Specifically, the formation of advanced glycation end products (AGEs) potentially leads to lens fiber damage⁹ due to alterations in lens capsule permeability. Glycosylation also seems to be an important modulator of the inflammatory response in various disorders such as diabetes, cancer, and neurodegenerative diseases.¹⁰ In the eye, glycosylation has been associated with diseases with an inflammatory component, such as dry eye.¹¹ Regarding cataracts, recent studies showed an increase of proinflammatory cytokines in the aqueous humor of cataract patients, suggesting that intraocular inflammation plays a role in the pathogenesis of cataracts.^12–14

Based on the above, since glycosylation is related to several mechanisms that induce cataract formation,^15–17 we aimed to evaluate glycosylation patterns in human lens capsules from T2DM and ND patients.

Methods Design and Setting

This experimental study used anterior capsules from T2DM and ND patients undergoing routine cataract surgery at the Anterior Segment Department of the Asociación para Evitar la Ceguera en Mexico I.A.P., Hospital "Dr. Luis Sánchez Bulnes", in Mexico City, Mexico. The Institutional Internal Review Board approved this study, which was conducted following the tenets of the Declaration of Helsinki. Informed consent was obtained from all patients before any study procedure.

Samples

Anterior lens capsules were obtained by continuous circular capsulorhexis during routine phacoemulsification. All patients were free from other ocular diseases and were graded for cataract severity (NO1NC1 to NO5NC5) using the Lens Opacities Classification System III (LOCS III).¹⁸ We obtained a total of 24 anterior capsules from 24 patients; 12 were used for protein expression (6 from T2DM patients and 6 from ND patients), and 12 for microscopic examination (6 from T2DM patients and 6 from ND patients).

Hematoxylin–Eosin Staining

Lens capsules were immersed in Zamboni fixative for 24 hours at 4°C. Tissues were mounted on silane-coated slides, then rehydration was performed, and finally they were stained with hematoxylin and eosin using conventional histological techniques and coverslipped using a synthetic mounting media.¹⁹

Tricine-SDS-PAGE Electrophoresis

After pulverizing the capsules in a mortar with liquid nitrogen and adding 20 μL of buffer with 2 μL of a protease inhibitor, samples were centrifuged at 13,000 rpm and 4°C for 30 min. After this time, the pellet was discarded and the supernatant was recovered. Then, tricine-sodium dodecyl sulphate-polyacrylamide gel electrophoresis ([tricine-SDS-PAGE) was performed using the method described by Ref. ²⁰ A constant voltage of 70 V, 100 mA was applied for 15 min followed by 120 V, 100 mA for 75 min. After electrophoresis, the gel and nitrocellulose paper were incubated in a transfer buffer (25 mM Tris base, 192 mM glycine, and 20% methanol, pH 8.3) for 90 min. Transfer was carried out in a semi-dry system (Bio-Rad, Richmond, CA, USA) at 25 V for 1 hour.

Immunohistochemistry

Lens capsules were immersed in Zamboni fixative and mounted on silane-coated slides. The slides were rehydrated using conventional histological techniques. Nonspecific binding sites were blocked by incubation with 2% IgG-free bovine serum albumin (BSA, Sigma-Aldrich), followed by permeabilization with 0.2% Triton X-100 (Sigma). Lectins were diluted at 1:100 with 1% BSA in PBS. Incubations were made at 4°C overnight. DAPI was used as nuclear counterstain. Biotinylated lectins used were concanavalin A (Con A, Mannose specific) (Sigma-Aldrich), jacalin (Galactose/N-acetyl-galactosamine specific, Vector Labs, CA, USA), and PNA (Galactose-specific, peanut agglutinin, Vector Labs). Anti-pan cytokeratin antibody (Abcam, Cambridge UK) was diluted 1:200. Immunostained cells were counted with a Leica DM/LS fluorescent microscope at 40x (Leica Microsystems, Wetzlar, GmBH, Germany).

Two-Dimensional Electrophoresis

For first dimension analysis, 50 μg of protein from the capsule lysates were treated with a mixture of 8 M urea, 0.5% CHAPS, 0.2% dithiothreitol, IPG buffer pH 3–10 and 0.002% bromophenol blue, for a final volume of 130 μL. Samples were loaded into the immobilized pH gradient strips, for room temperature incubation during 12 h. Subsequently, the strips were placed in the Amersham Biosciences Multiphor II chamber. An isoelectric focusing was carried out in three phases: the first one at 200 V for 1 min, at 0.001 kilovolts per hour (kVh) and the second at 3500 V for 90 min, at 2.8 kVh, and finally at 3500 V for 35 min at 2.2 kVh. For second dimension separation, the strips were soaked in 10 mL of an equilibration buffer (50 mM Tris-HCl pH 8.8, 6 M urea, 30% glycerol, 2% SDS, and 0.002% bromophenol blue and 65 mM DTT) for 15 min at room temperature, followed by incubation during 15 min with 10 mL of a buffer with 135 mM iodoacetamide. The strips were then placed in 10% SDS-polyacrylamide gels and run at 200 V for 40 min. Gels were fixed in a solution of 10% methanol and 7% acetic acid. Photographs were taken with an Olympus E-500 camera (Japan) and processed with ImageJ.

Liquid Chromatography with Tandem Mass Spectrometry (LC-MS/MS)

After visualization, target protein spots were excised from the Coomassie stained 2D-SDS PAGE, and they were distained, washed, digested with modified porcine trypsin (Promega, Madison, WI), and extracted as previously described.²¹ The volume of the extracts was reduced by evaporation in a vacuum centrifuge at room temperature and then adjusted to 20 µL with 1% formic acid. Mass spectrometric analysis was carried out in a 3200 QTRAP hybrid tandem mass spectrometer (Applied Biosystems/MDS Sciex, Concord, ON, Canada), equipped with a nanoelectrospray ion source (NanoSpray II) and a MicroIonSpray II head. The instrument was coupled on line to a nanoAcquity Ultra Performance LC (Waters Corporations, Milford, MA, USA). Samples were desalted by injection onto a Symmetry C18 UPLC trapping column (5 µm, 180 µm x 20 mm, Waters Corporations) and washed with 0.1% formic acid in Milli Q water. Spectra were acquired in automated mode using Information Dependent Acquisition (IDA). The scan range for EMS was set at m/z 300–1500 and 4000 amu/s, with an ion spray voltage of +2.2 kV applied to a Picotip emitter FS150-20-10-N (New Objective, Woburn, MA). Data interpretation and protein identification were performed from the MS/MS spectra datasets using the MASCOT search algorithm (Version 1.6b9, Matrix Science, London, UK, available at http://www.matrixscience.com). Searches were conducted using the National Center for Biotechnology Information non-redundant database (NCBIprot, http://www.ncbi.nih.gov).

Results

Hematoxylin and eosin staining of the anterior capsule showed LECs alterations in T2DM samples, namely loss of intercellular junctions, evidenced by cell retraction and epithelial discontinuity, as well as cytoplasmic vacuolization (Figure 1). To explore the relationship of glycosylated proteins with these histologic changes, we performed immunohistochemistry with the lectin Con A, observing differences in staining intensity between groups. For ND, Con A staining was homogenous both in the cytoplasm and in the membrane but for T2DM, in addition to membrane and cytoplasmic staining, we observed perinuclear vesicles with high reactivity to Con A (Figure 2A). We explored other lectins like jacalin (specific only for O-glycosidically linked oligosaccharides containing galactose/N-acetyl-galactosamine) and PNA (specific for terminal galactose residues), observing no differences between groups (data not shown). When capsules were treated with trypsin for more than 6 hours, Con A labeling decreased considerably; however, ConA positive vesicles in T2DM samples showed a slight decrease, suggesting resistance to trypsin treatment (Figure 2B).

These observations led us to examine the electrophoretic profile between both groups. As depicted in Figure 3, we observed differences between protein extracts from T2DM and ND lysates with Coomassie blue staining, observing a density increase of the 147, 64, and 23 KDa bands in T2DM capsules. After these findings, we performed a 2D-PAGE that evidenced protein spots from 250 to 15 kDa with areas of higher concentration in the isoelectric points from 4 to 8. In T2DM samples, we observed a spot with a higher density compared to ND samples of ~70 KDa, with an isoelectric point of 5.5 (Figure 4A). LC-MS/MS analysis using the MASCOT algorithm and the National Center for Biotechnology Information non-redundant (NCBInr) database of the proteolytic fragments showed a 62% homology with human cytokeratin (CK) types1 and 2 (Figure 4B).

To further explore if CK-1/2 had a relationship with the previously described glycosylation-induced alterations, we performed double labeling with ConA-FITC and an anti-pan-cytokeratin antibody conjugated to rhodamine in samples from both groups. We observed co-localization of ConA with anti-pan-CK in both samples; however, T2DM samples showed a stronger co-localization, specifically with the same vesicular pattern observed by immunohistochemistry (Figure 5A). Finally, we performed a lectin blot with biotinylated Con A using capsule homogenates from both groups that confirmed the presence of a ~65 kDa band in T2DM samples, not detected in ND samples (Figure 5B), suggesting the presence of glycosylated CK-1/2 in T2DM lysates. To confirm whether CK-1/2 has glycosylation sites, we conducted a NetNGlyc 1.0 server analysis to identify potential N-glycosylation sites, indicating that type-1 cytokeratin may be glycosylated at the Asp 410 site (Figure 5C).

Discussion

Senile and metabolic cataracts show different demographics and progression patterns. T2DM patients show a relatively faster progression and are diagnosed at an earlier age compared to ND patients with senile cataracts.^22,23 These differences are believed to be secondary, among other factors, to lens capsule alterations that facilitate cataract development.^7,24–28 It has been shown that alterations in capsule proteins induce loss of transparency of lens fibers and cataract formation, as in the case of patients with Marfan syndrome who have a mutation the glycoprotein fibrillin-1,²⁹ as well as mutations in laminin-β2³⁰ and collagen IVa5, that result on fragile and thinner capsules and cataract formation.³¹ Another analysis revealed that mice deficient for the glycoprotein SPARC also develops cataracts; these mice show an abnormal capsule morphology with protrusions and increased capsule permeability to macromolecules.^32,33 As demonstrated in this work, capsules from T2DM patients show changes like lens epithelial cell disruption and cytoplasmic vacuolization indicative of intercellular junctions loss and epithelial discontinuity that suggest adaptive responses for damage limitation.³⁴

In the eye, glycosylation has also been associated with dry eye disease due to a deficiency in MUC5AC mucin glycosylation.¹¹ Also, in pterygium, there was an abnormal sialylation of the MUC1 glycoprotein that contributes to neoplastic growth.^35,36 Therefore, we considered it interesting exploring the relationship between lens epithelial cells alterations and glycosylation using lectins since they are widely studied proteins that recognize specific carbohydrates and glycoproteins; jacalin and PNA are specific for O-glycosylation and ß-galactose-containing structures, while Con A shows high specificity for α-mannose and α-mannose-containing structures such as N-glycosidically linked proteins.^37,38 As previously described, Con A immunohistochemistry suggested that where there seems to be LEC damage in T2DM patients, there is a potential synthesis of de novo N-glycosylated proteins, in contrast to ND patients. This is consistent with other studies that have observed a relationship between N-glycosylation alterations and diabetes, where metabolic stress induces deregulation of glycan transferases.³⁹

From the relevant N-glycosylated proteins detected, we chose to characterize the ~65-kDa protein since it showed the greatest statistically significant difference between groups. 2D-PAGE confirmed the presence of this protein in T2DM samples, and LC-MS/MS confirmed a 62% homology with CK types 1 and 2. When exploring the role of CK-1/2 with the presumptive glycosylation-induced alterations, we found co-localization of ConA with the anti-pan cytokeratin antibody, and further testing through a lectin blot revealed that Con A recognizes a band of ~65 kDa that potentially corresponds to CK-1/2. Finally, we confirmed by the NetNGlyc 1.0 server that CK-1 has a potential glycosylation site.

The cytoskeleton is a key factor for the proper functioning of the lens, maintaining both cell organization and optical properties.⁴⁰ Indeed, cataracts show cytoskeleton alterations, especially related to intermediate filaments, causing loss of cell morphology that contributes to cataract progression.⁴¹ Therefore, certain post-translational modifications of cytoskeletal proteins could affect their correct functioning; specifically, glycosylation affects cytoskeleton structure, necessary to maintain lens transparency. An interesting finding of this study was the vesicular localization of Con A observed by IHQ, in contrast to the homogeneous membrane localization observed in ND patients. It has been reported that glycosyltransferases can interact with cytoskeletal proteins, such as the case of core 1 β3-galactosyltransferase (C1GalT1) that interacts with giantin, and core 2 N-acetyl-glucosaminyltransferase (C2GnT-M) that interacts with CK-1,⁴² forming complexes on RER vesicles and the Golgi apparatus, which are important for protein transit and recycling. It is unknown if such glycosyltransferase-cytoskeletal interactions exist or are altered under pathological conditions, but our results suggest that in T2DM, N-glycosylation of cytoskeletal proteins is potentially affecting intermediate filaments, and thus contributing to cataract progression.

Currently, many studies are focused on glycosylation as a therapeutic target, using glycosylated markers for diagnostics, and glycan characterization for drug screening. Also, glycosylation seems to be an important modulator of the inflammatory response in various disorders such as diabetes, cancer, or neurodegenerative diseases.^10,43 At present, it is unknown how diabetes alters glycosylation, but it has been hypothesized that it could be a direct result of metabolic stress and/or alteration of the hexosamine pathway or secondary to the inflammatory process that affects the expression of glycosyltransferases.

The main limitation of our study is the sparse number of samples, due to the fact that most patients in our tertiary care setting have ocular comorbidities, and we decided to exclude patients with ocular disorders different from cataracts in both groups. Nevertheless, we believe that our results strongly suggest that cytoskeleton-associated glycosylation is a relevant mechanism for cataract development in T2DM patients, but further studies are required to identify the specific role of N-glycosylation in cataract occurrence and progression.

Acknowledgments

Special thanks to Dr. Roberto González Salinas for fruitful discussions and donation of Anterior Lens Capsules to carry out this work. Ivan Emmanuel Ramos Martínez thanks CONACYT for the postdoctoral fellowship (442504).

Funding

This work was supported in part by the PAPIIT Program from Universidad Nacional Autónoma de Mexico (IN213818) and of the Asociación para Evitar la Ceguera en Mexico I.A.P., Hospital "Dr. Luis Sánchez Bulnes", in Mexico City, Mexico.

Disclosure

Rosario Gulias-Cañizo is currently an employee of Alcon Laboratories outside of this work. The authors report no other conflicts of interest in this work.