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Expression and Regulation of Cornified Envelope Proteins in Human Corneal Epithelium

¹From the Ocular Surface Center, Cullen Eye Institute, Baylor College of Medicine, Houston, Texas; the ²Singapore National Eye Center, Singapore; and the ³Singapore Eye Research Institute, Singapore.

	Abstract

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PURPOSE. Stratified squamous epithelial cells assemble a specialized protective barrier structure on their periphery, termed the cornified envelope. The purpose of this study was to evaluate the presence and distribution of cornified envelope precursors in human corneal epithelium, their expression in human corneal epithelial cell cultures, and the effect of ultraviolet radiation (UVB) and transglutaminase (TG) inhibition on their expression.

METHODS. Tissue distribution of small proline-rich proteins (SPRRs) and filaggrin and involucrin was studied in human cornea sections by immunofluorescence staining. Primary human corneal epithelial cells (HCECs) from limbal explants were used in cell culture experiments. A single dose of UVB at 20 mJ/cm² was used to stimulate these cells, in the presence or absence of mono-dansyl cadaverine (MDC), a TG inhibitor. SPRR2 and involucrin protein levels were studied by immunofluorescence staining and Western blot analysis. Gene expression of 12 proteins was investigated by semiquantitative reverse transcription–polymerase chain reaction.

RESULTS. In human cornea tissue, SPRR1, SPRR2, filaggrin, and involucrin protein expression were detected in the central and peripheral corneal and limbal epithelium. In HCECs, SPRR2 and involucrin proteins were detected in the cytosolic fraction, and involucrin levels increased after UVB. Both SPRR2 and involucrin levels accumulated in the presence of MDC. Nine genes including involucrin, SPRR (types 1A, 1B, 2A, 2B, and 3), late envelope protein (LEP) 1 and 16, and filaggrin were expressed by HCECs. SPRR 4, loricrin, and LEP 6 transcripts were not detected. UVB downregulated SPRR (2A, 2B) and LEP 1 transcripts.

CONCLUSIONS. Various envelope precursors are expressed in human corneal epithelium and in HCECs, acute UVB stress differentially alters their expression in HCECs. The expression of envelope precursors and their rapid modulation by UVB supports the role of these proteins in the regulation of ocular surface stress. TG function may be relevant in the regulation of soluble precursors in UVB-stimulated corneal epithelium.

The corneal epithelium is stratified and bears similarities to the skin epidermis in its pattern of basal to superficial polarity,⁶ but it is different, in that the corneal epithelium does not have a water-impermeable apical layer that is equivalent to the cornified layer in the skin epithelium. Nevertheless, involucrin, a cornified envelope precursor, is expressed in normal corneal epithelium,⁷ and the precursors involucrin and filaggrin are elevated in the human conjunctiva in severe ocular surface diseases, such as Stevens-Johnson syndrome and alkali burns.⁸ Involucrin and loricrin have been detected in keratinized corneal epithelia in a rat model of dry eye.⁹ Because expression of such proteins can be found in nonsquamous tissues and cell lines,⁴ such molecules may have a function not associated with squamous differentiation. Indeed, these proteins may have a regulatory¹⁰ rather than structural role, as shown in the conjunctiva.¹¹

The first reason for the study of cornified envelope proteins in corneal epithelium is the involvement of these precursors in barrier function. For example, the LEPs have been linked to barrier formation in nonocular tissues.⁵ In the cornea, the stratified epithelium is avascular and has different barrier requirements than the skin, because oxygen and nutrients need to permeate the epithelial layers from the tear film. As such, envelope proteins may have evolved away from a simple mechanical role.

Second, cornified envelope precursors may be involved in inflammatory diseases. SPRR proteins are involved in inflammatory diseases of the skin.¹² Elafin, a naturally occurring precursor in skin epidermis, is a potent anti-inflammatory agent that serves as a proteinase inhibitor.¹⁰ Proinflammatory signaling may differentially regulate SPRR¹³ and involucrin genes.¹⁴ Third, these precursors are involved in wound healing. In murine skin, the migrating edge of epithelium after wounding expressed involucrin.¹⁵ The fourth reason for the study of such precursors is their possible role in mucosal defense against microbes. The role of SPRR in innate defense has been reported.^{16 17} Last, precursors may also play a role in less common diseases in the ocular surface. SPRRs are involved in neoplastic diseases of the skin,¹² and in ischemic stress in cardiomyocytes.¹⁸ Despite the possible significance of these proteins in the corneal epithelium, there have been no previous studies documenting the expression of SPRR and LEP in this tissue.

Ultraviolet irradiation^{19 20} is a useful method of studying the regulation of cornified envelope substrates. First, such stimulation alters the expression of these proteins in nonocular tissues and is the basis of a wound healing model.² Second, it causes corneal surface disease.²¹ Third, it plays a role in corneal barrier dysfunction²² in many ocular surface diseases. Last, it activates both cellular stress²³ and differentiation related pathways, such as calcium signaling, which have a prominent effect on cornified envelope protein expression.²⁴ The study of UVB-induced cornified envelope substrate regulation and the effect of TG inhibition may therefore have implications in the treatment of barrier-, inflammation- and wound-healing–related diseases in the ocular surface. Regulation of involucrin, SPRR1, SPRR3, SPRR4, loricrin, and filaggrin by UVB has been investigated in the skin,^{2 25} but not in the cornea. Although the anti-inflammatory effect of TG inhibition has been studied in allergic conjunctivitis,¹¹ the effects of TG inhibition on cornified envelope proteins have not been reported in corneal epithelial cells.

The purpose of this study was to investigate the expression of cornified envelope precursors in human corneal epithelium, to investigate the expression and UVB-induced regulation of a select panel of these precursors in cultured human corneal epithelial cells, and last, the effect of inhibiting TG function on the UVB-induced regulation.

	Methods

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Materials and Reagents
Cell culture dishes, plates, centrifuge tubes, and other plastic ware were purchased from BD Biosciences (Lincoln Park, NJ). Dulbecco’s modified Eagle’s medium (DMEM), Ham’s F-12, amphotericin B, gentamicin, and 0.25% trypsin/0.03% EDTA solution were from Invitrogen-Gibco (Grand Island, NY). Fetal bovine serum (FBS) was from Hyclone (Logan, UT). Bovine insulin, hydrocortisone, human EGF, cholera toxin A subunit, human transferrin, sodium selenite, dimethyl sulfoxide (DMSO) and Triton X-100 were from Sigma-Aldrich (St. Louis, MO). Mono-dansyl cadaverine (MDC) was from Invitrogen (Eugene, OR). OCT compound was obtained from Sakura Finetek USA. Inc. (Torrance, CA and the mounting medium (Immu-Mount) was from Thermo-Shandon (Pittsburgh, PA) Optisole-GS was purchased from Bausch and Lomb Inc. (Rochester, NY). Anti-fade medium (Gel/Mount M01) was from Biomeda Corp. (Foster City, CA).

The extraction reagent (TRIzol) was from Invitrogen-Gibco (Grand Island, NY). PCR buffer II (E12848) was obtained from Applied Biosystems (Foster City, CA). M-MuLV reverse transcriptase (Ready-To-Go You-Prime First-Strand Beads) were obtained from GE Healthcare, Inc. (Piscataway, NJ). PCR master mix (AmpErase UNG, Taqman MGB) probes for SPRR1A, SPRR1B, SPRR2A, and SPRR2B with assay IDs Hs00954595_s1, Hs00824893_m1, Hs01655189_sH, and Hs00863465_m1, respectively, were from Applied Biosystems.

The protein extraction kit (MPER) and BCA protein assay were from Pierce Biotechnology (Rockford, IL). Gel for protein electrophoresis (Ready Gel; 4%–15% Tris-HCl) was from Bio-Rad (Hercules, CA). Polyvinylidene difluoride (PVDF) membranes (Immobilon-P) were from Millipore (Billerica, MA). The electrophoretic transfer buffer was a Tris/glycine buffer from Bio-Rad. The TTBS wash buffer composed of 0.1% Tween 20 (Bio-Rad), 50 mM Tris and 0.15 M sodium chloride (pH 7.5). The chemiluminescent reagent (Luminol) was from Santa Cruz Biotechnology (Santa Cruz, CA).

Goat anti-rabbit AlexaFluor 488 antibodies (A11008) and goat anti-mouse AlexaFluor antibodies (A21151) were from Invitrogen-Molecular Probes (Carlsbad, CA). Goat anti-rabbit (no. 31460) and goat anti-mouse (no. 31430) horseradish peroxidase (HRP)–conjugated antibodies were from Pierce Biotechnology.

Human Corneal Tissue
Fresh human corneal tissues were obtained from the National Disease Research Interchange (NDRI, Philadelphia, PA). Details of tissue preparation have been described.⁷ Briefly, the specimens were cut and embedded in a mixture of 75% OCT and 25% mounting medium (by volume; ImmuMount; Thermo-Shandon) and frozen in liquid nitrogen. Frozen sections (6–10 µm thick) were used for immunostaining. Human corneoscleral tissues, which did not meet the criteria for clinical use, from donors aged 2 to 94 years were obtained from the Lions Eye Bank of Texas (Houston, TX) for the purpose of limbal explant culture. The details of the donors’ condition, tissue procurement, and length of preservation were supplied by the Eye Bank. These tissues were preserved (Optisol-GS; Chiron, Irvine, CA) at 4°C until they were processed for culture.

Cell Culture Procedure
Primary human corneal epithelial cells (HCECs) were grown from cadaveric limbal explants, as described previously.²⁶ Briefly, corneoscleral tissues were rinsed with Hanks’ balanced solution containing 50 µg/mL gentamicin and 1.25 µg/mL amphotericin B. After the central cornea, excess sclera, iris, corneal endothelium, conjunctiva and Tenon’s capsule were carefully removed, the remaining limbal rim was cut into 12 equal pieces (2 mm² each). Two pieces with the epithelium side up were directly placed in a well of a six-well culture plate or into a 35-mm dish, and they were covered with a drop of FBS overnight. The explants were then cultured in supplemented hormonal epithelial medium (SHEM), which was a 1:1 mixture of DMEM and Ham’s F12 medium containing 5 ng/mL epidermal growth factor (EGF), 5 µg/mL insulin, 5 µg/mL transferrin, 5 ng/mL sodium selenite, 0.5 µg/mL hydrocortisone, 30 ng/mL cholera toxin A, 0.5% dimethyl sulfoxide (DMSO), 50 µg/mL gentamicin, 1.25 µg/mL amphotericin B, and 5% FBS, at 37°C in 5% CO₂ and 95% humidity.

Cells grown for 7 to 12 days with 50% to 70% confluence were designated "young" cell cultures. Cells grown to 70% to 99% confluence, usually grown for 13 to 17 days, were designated "subconfluent." whereas cells grown for 18 to 21 days and noted to be 100% confluent were labeled "confluent cells." "Older" cells referred to cells that were overconfluent, grown for more than 21 days, and noted to have a relatively more opaque appearance. For experiments with UVB, cell cultures were observed daily under inverted light microscopy, and experiments commenced when cells became just confluent.

Corneal stroma were known to maintain a suitable microenvironment for human limbal epithelial stem cells and to control the plasticity of corneal epithelial differentiation.²⁷ For this reason, we speculate that human corneal epithelial cells cultured from human limbal explants may be able to differentiate and stratify on porcine corneal stroma.

Porcine eyes were ordered and obtained from VisionTech, Inc. (Mesquite, TX). After the eye’s corneal epithelium was completely removed with a surgical blade, a femtosecond YAG laser (IntraLase Corp., Irvine, CA) was used to create stromal discs. These stromal discs were cut to a diameter of 9 mm and thickness of 90 µm and were then placed on a culture plate containing 12 mm membrane insert supports (Corning Inc., Acton, MA). A piece of human cadaveric limbal tissue approximately 2 x 2 mm² in size was placed epithelium side up on each stromal disc and cultured in SHEM medium, as described earlier. After 3 weeks, the entire insert was trimmed with scissors, and frozen sections obtained as described previously.⁷ Hematoxylin and eosin staining was performed as described previously.⁷

Immunofluorescent Staining
Immunofluorescent staining was performed as described previously.⁷ Briefly, frozen human corneas were thawed and fixed with acetone at 4°C for 5 minutes. After blocking with 5% normal goat serum in phosphate-buffered saline (PBS) for 30 minutes, a primary antibody (Table 1) was applied at the specified dilution in 5% goat serum overnight at 4°C. These and subsequent steps were performed at room temperature. After washing with PBS, the appropriate AlexaFluor 488 secondary antibody (1:300 dilution or 6.7 µg/mL) was applied in 5% goat serum for 30 minutes in a dark incubation chamber. Counterstaining of cell nuclei was performed using 1 µg/mL propidium iodide in PBS for 2 minutes. After further washing, a coverslip was applied with gel. Staining patterns were examined and photographed with an epifluorescence microscope (Eclipse 400; Nikon, Melville, NY) with a digital camera (1200; DMX, Garden City, NY). Image acquisition was performed with the camera software (ACT-1, ver. 2.12 software; Nikon, Melville, NY). Appropriate negative controls were incubated as just described, in the absence of primary antibody, but with the various secondary antibodies.

UVB Procedure
UVB was administered with a UVB lamp (UVM57; UVP, Upland, CA) that principally emitted medium ultraviolet wavelengths. The power output of the lamp was monitored using a radiometer (UVX; UVP), and a 302-nm sensor probe was placed under the UVB source where the irradiated cell cultures would be placed. A single dose of UVB at 20 mJ/cm² was used to stimulate cells in a sterile culture hood, which generally corresponds to 24 seconds of continuous exposure after stabilization of power. Culture wells that did not receive any UVB exposure were used as the control. The media for all cell cultures (including nonirradiated controls) were aspirated before irradiation and replaced immediately after the irradiation. MDC was used as a cell-permeable competitive inhibitor of TG at concentrations of 40 and 60 µg/mL. This is an amine substrate²⁸ with a high affinity for transglutaminase, serving as a substrate as well as an inhibitor by projecting an alkyl side chain toward the active center of the enzyme. Incubation with the inhibitor, where appropriate, was for 1 hour before any UVB exposure, and continued after the UVB exposure until the end of the experiment.

Polymerase Chain Reaction
Reverse transcription–polymerase chain reaction (PCR) was performed as described previously.²⁹ Briefly, total cellular RNA was extracted 6 and 24 hours after UVB (TRIzol; Invitrogen-Gibco), after being washed with PBS. Reverse transcription was performed with magnesium chloride (5 mM), deoxynucleotides (1 mM each), RNAase inhibitor (1 U/µL), reverse transcriptase (2.5 U/µL), and random hexamers (2.5 uM) in PCR buffer II. PCR was performed with a custom-designed nucleotide primer against a unique part of the respective human mRNA or cDNA (Table 2) . cDNA amplification was performed with an individually optimized number of cycles and temperatures for each primer. Controls included the housekeeping gene GADPH, as well as nonirradiated samples incubated for the same duration as the irradiated samples. The relative amount of mRNA detected was indicated by the relative intensity of the ethidium bromide stained bands (which was an indicator of the amount of amplicon produced at the end of the PCR) on electrophoresis of PCR products in 2% agarose gel. Band intensities were analyzed using (1D ver. 3.6.2 software; Eastman-Kodak, New Haven, CT).

–Ct

Western Blot Analysis
Protein extraction was performed after incubation of cells for 24 hours after UVB irradiation. HCECs were lysed with MPER after aspiration of media and washing with PBS. Lysates were vortexed and centrifuged at 13,000g for 15 minutes. Pellets (the insoluble fraction) were solubilized by addition of 50 to 75 µL of 1% sodium dodecyl sulfate (SDS) followed by vigorous vortexing.

Western blot analysis was performed as previously described.³⁰ Briefly, protein concentration was determined using the BCA method according to the manufacturer’s instructions. The same mass of protein (40 µg) was loaded per gel lane for electrophoresis. The separated proteins were transferred to a PVDF membrane. Blots were washed in TTBS, and all subsequent steps performed at room temperature. Blocking for nonspecific proteins was performed for 1 hour in 5% skimmed milk.

Western blot analysis were performed using the primary antibodies specified in Table 1 . All dilutions were made in 5% skimmed milk in TTBS. Primary antibody incubation was for 1 hour. After further washing, the appropriate secondary HRP conjugated antibody was applied for a further hour in a rocker, at a dilution of 1:5000. Chemiluminescence was detected using Luminol and the imaging system (2000R; Eastman Kodak).

Statistical Analysis
All experiments were performed at least three times. Statistical analysis was performed on computer (Microsoft Excel, Redmond, WA, and Prism 4 for Windows, ver. 4.03; GraphPad Software Inc, San Diego, CA). Analysis of variance (ANOVA) with Tukey post hoc testing was used for statistical comparisons, and statistical significance was evaluated at the level of = 0.05.

	Results

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Expression of Cornified Envelope Proteins in Human Cornea Tissue and Epithelial Cultures
Expression of cornified envelope proteins was evaluated in fresh frozen human corneal tissue sections using immunofluorescent staining. SPRR1, SPRR2, filaggrin, and involucrin (Fig. 1) were present in the central, peripheral corneal epithelium, and limbal epithelium. SPRR1 and SPRR2 staining was noted in all layers but accentuated in the wing-cell layer and apical layer in the central cornea, staining was absent in some parts in the basal layer of the limbus. Involucrin was noted in the superficial layers of the central cornea and limbus. Filaggrin staining was weak in all layers with some accentuation in the superficial most layers.

View larger version (36K): [in this window] [in a new window]   FIGURE 1. Immunofluorescence images of human cornea tissue sections showing reactivity against SPRR1, and -2, filaggrin, and involucrin. Bottom: Negative control images merged with images of propidium iodide counterstaining.

View larger version (35K): [in this window] [in a new window]   FIGURE 2. Immunofluorescence images (A) and Western blot analysis (B) performed on confluent HCECs at 24 hours after UVB. Control, control cultures; UV, UVB-treated cultures; UV+MDC, UVB treatment + MDC; PI, propidium iodide. (C) H&E staining of human corneal epithelial cells (top arrow) grown on porcine corneal stroma (bottom arrow). (D) Immunofluorescent staining image for SPRR2 (top) and propidium iodide counterstaining (bottom). (E) Immunofluorescent staining for involucrin (top) and propidium iodide counterstaining (bottom).

mRNA Expression of Cornified Envelope Precursors
Cornified envelope mRNA expression was evaluated in confluent cultured cells. Among the 12 proteins studied, mRNA expression for nine genes were detected, whereas three genes were not. Involucrin, SPRR (1A, 1B, 2A, 2B and 3), LEP (1,16) and filaggrin were observed (Fig. 3) , whereas PCR of up to 60 cycles using the SPRR4, loricrin, or LEP6 primers shown in Table 2 did not produce any detectable amplicons.

View larger version (48K): [in this window] [in a new window]   FIGURE 3. Reverse transcription PCR for cornified envelope protein precursors in cultured human corneal epithelial cells. (A) Regulation of cornified envelope mRNA by UVB at 6 hours: SPRR2A, SPRR2B, and LEP-1, as well as GADPH. The effect of MDC on the UVB-induced change is also shown. The expected size of the amplicons is shown. Leftmost lane: The molecular size ladder in 100-bp increments. Bottom: densitometric intensities of bands relative to the control band. (B) Cornified envelope mRNA not up- or downregulated by UVB.

View larger version (52K): [in this window] [in a new window]   FIGURE 4. Effect of cell confluence on the mRNA expression of envelope proteins. (A) Semiquantitative PCR showing relative mRNA expression of cornified envelope precursors in the subconfluent and overconfluent cells. (B) Real-time PCR results for RNA expression of SPRR1A and -1B with different confluence and age of cells in culture. The change in expression (x-fold) was relative to the youngest cell category. Error bars, SEM. Probabilities refer to the results of ANOVA. The brackets indicate the statistically significant comparisons on post hoc testing.

Effect of MDC on Cornified Envelope Expression
UVB-induced mRNA expression of cornified envelope precursors was evaluated in the presence of the TG inhibitor MDC in confluent HCECs at 6 and 24 hours. This inhibitor suppressed the UVB-induced change in mRNA expression in SPRR2A, SPRR2B, and LEP1 (Fig. 3A) .

Immunofluorescent staining of confluent HCECs, 24 hours after UVB, showed that incubation with MDC increased the level of fluorescence when staining was performed for SPRR2 and involucrin (Fig. 2A , bottom panel). This finding was confirmed by Western blot on confluent HCECs 24 hours after UVB, where accumulation of SPRR2 and involucrin in the cytoplasmic fraction was observed in the presence of MDC (Fig. 2B) . This suggests that there was reduced incorporation of SPRR2 and involucrin into the insoluble envelope.

	Discussion

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Our results of a survey of various cornified envelope precursor proteins show their presence and distribution in human corneal epithelial tissue and the selective expression of some members in HCECs. For the first time, the gene expression of members of late envelope proteins (LEP) in an ocular cell type is reported. Culture confluence and UVB are observed to regulate the mRNA expression of some of these precursors. Furthermore, inhibition of transglutaminase (TG) appears to affect expression of certain members.

Expression of cornified envelope protein subtypes varies in different tissues: SPRR1 is restricted to appendageal areas, SPRR2 in sublingual and tongue epithelium and SPRR3 in esophageal epithelium.¹² LEP-1 to -5 are found in the skin, whereas LEP-14 and -15 are found in the esophagus and LEP-7 and -16, in the heart.⁵ Most (9/12) of the cornified envelope precursor mRNAs in corneal epithelial cells are detected in the control (non-irradiated) HCECs, especially in younger cells. In skin epidermis envelope assembly involves formation of a scaffold by ubiquitous proteins such as involucrin, and the "reinforcement" proteins which differ between epithelial cell types.³² In the corneal epithelium, SPRR may be the favored reinforcement protein, whereas in the skin, loricrin is preferred.³² SPRR members have a variable number of proline-rich peptide repeats in the central domains and span different lengths in their cross-bridging roles.³²

In our study, the human corneal epithelial cells grown on porcine stroma were able to stratify and differentiate. The pattern of SPRR2 and involucrin staining was similar to those we observed in central and peripheral human corneal sections. At the same time, we found that SPRR transcripts decrease with increasing confluence. Conditions unique to cell culture, such as crowding and competition for nutrients may affect the SPRR transcript level even in nonconfluent monolayer cells. This may be a function of proliferative rate or cellular turnover and may be unrelated to differential expression of the SPRR protein in stratified cultures. Expression of cornified envelope proteins has been noted to differ between cultured cells and tissue (e.g., cultured keratinocytes express loricrin poorly whereas skin keratinocytes express it abundantly).³

We have shown that mRNA levels of cornified envelope substrates are regulated by UVB. In previous studies involucrin, loricrin, and filaggrin were altered within 48 hours in ultraviolet irradiated human skin grafted to nude mice.³³ In the skin, UVB downregulates involucrin and SPRR3, but upregulates SPRR4 level and its incorporation into the envelope.²⁵ Loricrin and filaggrin are downregulated, whereas involucrin and SPRR1 are unaffected after UVB irradiation of in vitro reconstructed skin.² In corneal epithelial cells, the involucrin promoter may bind stress-induced transcription factors.^{34 35} Differences in dosage, wavelength, and regimen of ultraviolet irradiation make it difficult to compare results between studies. We observed discrepancies between protein and mRNA levels of involucrin and SPRR2A and -2B after UV treatment. The possible reasons for these "discrepancies" may relate to regulatory factors such as RNA stability, degradation, translational initiation and protein degradation (ubiquitylation, sumoylation).^{36 37 38 39} In addition, the SPRR2 antibody may react against some members of SPRR2 family other than SPRR2A and -2B.

The effects of MDC were: first, to suppress the UVB-induced reduction in mRNA levels of some precursors (SPRR2A and -2B and LEP1) and, second, to increase the soluble protein levels (SPRR2 and involucrin) after UVB exposure. How does the inhibitor oppose the UVB-induced decrease of mRNA levels? Proinflammatory cytokines and stress pathways interact at the SPRR1A promoter in nonocular cell types.¹⁸ Because TG inhibition reduces the TG-mediated increase in phospholipase¹¹ and NFB activation,⁴⁰ addition of inhibitor may alter the composition of the transcriptional complex in favor of transcription. Why does MDC increase the level of envelope protein after UVB? This is most likely due to the inhibition of cross-linking by TG. Covalent cross-linkage is expected to shift the soluble precursors to insoluble cornified envelope. Therefore, if UVB stimulates the cellular utilization of soluble precursors in this fashion, TG inhibitor is expected to block the shift and increase the detectable soluble precursor. The ability of TG to enzymatically cross-link substrates has been previously shown in the skin.^{41 42} Because soluble involucrin is located in the cytoplasm and not at the perimembranous cell envelope,¹ an additional regulatory step may involve TG-involucrin interaction⁴³ or targeting of involucrin to the cell periphery.

This study has identified the expression of LEP genes in HCECs. A limitation of the study is that we omitted protein studies for these members. We did not study such precursors as envoplakin, the S100⁴⁴ proteins, and the NICE proteins.⁴⁵ Because knocking out of major cornified envelope proteins has not produced marked phenotypes in animals,⁴⁶ it may be important to examine these less-well-studied members. We did not investigate in situ tissue distribution of cornified envelope mRNA, or the effect of UVA radiation, which may be more relevant than UVB in clinical scenarios.⁴⁷

According to the precursor-availability hypothesis for skin epidermis, the envelope structure incorporates whatever precursor is available under environmentally stressed conditions.^{44 48} The composition of the envelope may determine its biomechanical properties and barrier function.⁴² Application of the "precursor availability" hypothesis to the corneal epithelium underlies the importance of understanding the stress-induced regulation of envelope precursors in this specialized cell. Some newly discovered roles of the precursors in nonocular tissue have been found: SPRR2A may play a role in bacterial infection,^{16 17} and SPRR1A may protect cardiomyocytes against ischemic stress.¹⁸ It will not be surprising if these precursors have a protective role in the ocular surface.

In conclusion, SPRR1, SPRR2, filaggrin, and involucrin are expressed in human corneal epithelium. Many subtypes of cornified envelope protein precursors, including involucrin; SPRR1A, -1B, -2A, and -2B; LEP-1, -6, and -16; and filaggrin are expressed in primary cultured corneal epithelial cells. Some of these proteins are regulated by UVB exposure. SPRR in the corneal epithelial cells may be markers of an early stage of differentiation and may have additional roles in modulation of stress. Modulation of envelope precursors by inhibiting the activity of transglutaminase may have therapeutic implications in ocular surface disorders.

	Footnotes

 
Presented in part at the annual meeting of the Association for Research in Vision and Ophthalmology, Fort Lauderdale, Florida, May 2005.

Supported by National Eye Institute Grants EY11915 (SCP) and EY014553 (D-QL), a fellowship from the Agency for Science Technology and Research, Singapore, an unrestricted Grant from Research to Prevent Blindness, and by the Oshman Foundation, and The William Stamps Farish Fund.

Submitted for publication August 24, 2005; revised November 30, 2005, and January 9 and February 6, 2006; accepted March 22, 2006.

Disclosure: L. Tong, None; R.M. Corrales, None; Z. Chen, None; A.L. Villarreal, None; C.S. De Paiva, None; R. Beuerman, None; D.-Q. Li, None; S.C. Pflugfelder, None

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: Stephen C. Pflugfelder, Ocular Surface Center, Cullen Eye Institute, Baylor College of Medicine, 6565, Fannin Street NC205, Houston, TX 77030; stevenp{at}bcm.tmc.edu.

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