Galectin-3 enhances epithelial cell adhesion and wound healing in rat cornea.

BACKGROUND/AIMS: To investigate if galectin-3: (1) enhances adhesion of rat corneal epithelial cells onto a collagen IV substrate and (2) promotes wound healing in rat corneal explants. METHODS: Primary cultures of rat corneal epithelial cells were fixed and immunostained with galectin-3 antibody. To test cellular adherence onto plates coated with collagen type IV, isolated corneal epithelial cells from rats were cultured for 24 h with or without recombinant galectin-3. The attached cells were counted after fixing and staining with 0.1% crystal violet. Direct binding of galectin-3 to collagen IV was tested using a biotin label transfer method. To evaluate wound healing, explants with a 3.5-mm diameter wound in the central corneal epithelium from rats were incubated for 16 h with or without recombinant galectin-3. Changes in the size of the wound were measured with a digital microscope after staining with 5% fluorescein sodium. RESULTS: In rat corneal epithelial cells, galectin-3 was stained throughout the cytoplasm, with increasing density adjacent to the plasma membrane. Exogenous galectin-3, but not epidermal growth factor (EGF), significantly promoted adhesion of corneal epithelial cells onto the collagen IV substrate. Galectin-3 directly bound to collagen IV in vitro. Exogenous galectin-3 significantly enhances wound healing in the corneal explants, which was partially inhibited by ß-lactose. CONCLUSION: Galectin-3 promotes adhesion of corneal epithelial cells onto collagen IV and enhances wound healing in corneal explants. Since galectin-3 functions in promoting wound healing by a different mechanism than that used by EGF, exogenous galectin-3 may be a candidate drug for enhancing epithelial cell wound healing in disorders of the cornea.

The role of calcium-activated protease calpain in experimental retinal pathology.

The purpose of this review is to present the recent evidence linking the family of ubiquitous proteases called calpains (EC 3.4.22.17) to neuropathologies of the retina. The hypothesis being tested in such studies is that over-activation of calpains by elevated intracellular calcium contributes to retinal cell death produced by conditions such as elevated intraocular pressure and hypoxia. Recent x-ray diffraction studies have provided insight into the molecular events causing calpain activation. Further, x-ray diffraction data has provided details on how side chains on calpain inhibitors affect docking into the active site of calpain 1. This opens the possibility of testing calpain-specific inhibitors, such as SJA6017 and SNJ1945, for human safety and as a site-directed form of treatment for retinal pathologies.

Amelioration of retinal degeneration and proteolysis in acute ocular hypertensive rats by calpain inhibitor ((1S)-1-((((1S)-1-benzyl-3-cyclopropylamino-2,3-di-oxopropyl)amino)carbonyl)-3-methylbutyl)carbamic acid 5-methoxy-3-oxapentyl ester.

BACKGROUND: Our recent study suggested involvement of calpain-induced proteolysis in retinal degeneration and dysfunction in acute ocular hypertensive rats. The purpose of the present study was to determine if an orally available form of calpain inhibitor, ((1S)-1-((((1S)-1-benzyl-3-cyclopropylamino-2,3-di-oxopropyl)amino)carbonyl)-3-methylbutyl)carbamic acid 5-methoxy-3-oxapentyl ester (SNJ-1945), ameliorated retinal degeneration induced by acute hypertension in rats. To help extrapolate the effect of SNJ-1945 from the rat model to the human glaucomatous patient, in vitro inhibition of calpain-induced proteolysis by SNJ-1945 in monkey and human retinal proteins was compared with proteolysis in rat proteins. METHODS: Intraocular pressure (IOP) in rats was elevated to 110 mm Hg for 50 min. SNJ-1945 was administrated i.p. or orally before ocular hypertension. Retinal degeneration was evaluated by hematoxylin and eosin (H&E) staining and cell counting. Transcripts for calpains and calpastatin in rat, monkey, and human retinas were measured by quantitative RT-PCR. Calpain activities were determined by casein zymography. Soluble retinal proteins from rat, monkey, and humans were incubated with calcium to activate calpains, with or without SNJ-1945. Proteolysis of calpain substrate alpha-spectrin was analyzed by immunoblotting. RESULTS: Elevated IOP caused retinal degeneration and proteolysis of alpha-spectrin. Both i.p. and oral administration of SNJ-1945 inhibited proteolysis of alpha-spectrin and ameliorated retinal degeneration. Transcript levels for calpain 1 and calpastatin were similar in rat, monkey, and human retinas. Calpain 2 transcript levels were higher in rats compared with monkey and human. Appreciable caseinolytic activities due to calpains were observed in monkey and human retinas. Incubation of retinal soluble proteins with calcium led to proteolysis of alpha-spectrin due to calpains in rat, monkey, and human samples. SNJ-1945 similarly inhibited proteolysis in all species. CONCLUSION: Our results suggested that orally available calpain inhibitor SNJ-1945 might be a possible candidate drug for testing in preventing progression of glaucomatous retinal degeneration.

Superior prevention of calcium ionophore cataract by E64d.

The purposes of this experiment were: (1), to compare effect of three E64 derivatives, E64, E64c and E64d in preventing nuclear opacity and proteolysis in calcium ionophore-induced cataract and (2), to measure the accumulation of E64 derivatives in the cultured lenses. In vitro E64 and E64c strongly inhibited purified calpain II from porcine heart, while E64d showed weaker inhibition than E64 and E64c. In cultured lenses, all three E64 derivatives reduced nuclear opacity by calcium ionophore A23187 in a concentration-dependent manner, and E64d, the ethyl-ester of E64c, was the most effective. When lenses were cultured in E64d for 2 h, the resulting concentration of E64 derivative in the lens was markedly higher than during culture in E64 or E64c. All three E64 derivatives prevented proteolysis of crystallins seen in A23187 cataract. The stronger effect of E64d against A23187 cataract was likely due to an earlier penetration into the lens, conversion to E64c and inhibition of activated calpain.

Expression changes in mRNAs and mitochondrial damage in lens epithelial cells with selenite.

An overdose of sodium selenite induces cataracts in young rats. The mid-stage events producing the cataract include calpain-induced hydrolysis and precipitation of lens proteins. Apoptosis in lens epithelial cells has been suggested as an initial event in selenite cataracts. Expression levels of two genes associated with apoptosis were altered in lens epithelial cells from selenite-injected rats. The purpose of the present experiment was to perform a more comprehensive search for changes in expression of mRNAs in lens epithelial cells in order to more fully delineate the early events in selenite-induced cataracts. Lens epithelial cells were harvested at 1 and 2 days after a single subcutaneous injection of sodium selenite (30 mumol/kg body weight) into 12-day-old rats. Gene expression was analyzed using a commercial DNA array (Rat Genome U34A GeneChip array, Affymetrix). Of approximately 8000 genes assayed by hybridization, 13 genes were decreased and 27 genes were increased in the rat lens epithelial cells after injection of selenite. Some of the up-regulated genes included apoptosis-related genes, and a majority of the down-regulated genes were mitochondrial genes. Previously observed changes in expression of EGR-1 mRNA were also confirmed. Changes in the expression patterns of mRNAs were also confirmed by RT-PCR. To determine the mechanism for damage of lens epithelial cells (alpha TN4 cell) by culture in selenite, leakage of cytochrome c from mitochondria was measured. Selenite caused significant leakage of cytochrome c into the cytosol of alpha TN4 cells. Our data suggested that the loss of integrity of lens epithelial cells by selenite might be caused by preferential down-regulation of mitochondrial RNAs, release of cytochrome c, and impaired mitochondrial function. Up-regulation of mRNAs involved in maintenance of DNA, regulation of metabolism, and induction of apoptosis may also play roles.

Different expression patterns for ubiquitous calpains and Capn3 splice variants in monkey ocular tissues.

The purpose of the present investigation was to compare the expression of ubiquitous and tissue-specific calpains in ocular tissues from the Macaca fascicularis monkey. Calpain isoforms in retina and corneal epithelium from adult M. fascicularis monkeys were characterized by RT-PCR, cDNA cloning and sequencing. Calpain isoform activities in ocular tissues were investigated by fractionation on DEAE-HPLC, immunoblotting, and casein zymography. Capn3 splice variants in the ocular tissues from rat, rabbit and monkey were compared after RT-PCR. RT-PCR analysis revealed that numerous splice variants of Capn3 were expressed in the epithelium from monkey cornea. The variants contained deletions or insertions in or around the IS1, IS2, and NS regions. The cDNAs for Capn3 variants were highly conserved, yet the expression patterns of the Capn3 isoforms were widely different among the mammalian species. In contrast, the expression patterns of ubiquitous calpains in ocular tissues were conserved among the mammalian species, and similarities between monkey and human cDNAs for Capn1 (mu-calpain) and Capn2 (m-calpain) were 98 and 99%, respectively. These results suggested that differences in expression patterns of Capn3 variants might be related to the function of each variant in a particular tissue or species.

Calpain II induced insolubilization of lens beta-crystallin polypeptides may induce cataract.

Addition of calpain II (EC 3.4.22.17) to soluble proteins from 10-day-old rat lens caused an increase in turbidity and production of water-insoluble protein. The insolubilization increased with higher concentrations of both lens protein and calpain II, it could be prevented by the cysteine protease inhibitor E-64; it required at least 0.5 mM Ca2+, it was limited to 6% of the soluble protein present and resulted from precipitation of proteolyzed beta-crystallin polypeptides. When compared by two-dimensional electrophoresis, the insoluble beta-crystallin polypeptides produced by calpain II were similar to insoluble beta-crystallin polypeptides found in cataractous lenses. Trypsin also caused insolubilization of beta-crystallin polypeptides, but these polypeptides were unlike polypeptides produced during cataract formation. These data suggested that the loss of solubility was due to a specific removal of N/or C-terminal extensions from beta-crystallin polypeptides by calpain II, and that a similar process may occur in vivo during cataract formation. It is hypothesized that the insoluble protein produced by calpain II causes cataract by increasing light scatter in the lens.

SJA6017, a newly synthesized peptide aldehyde inhibitor of calpain: amelioration of cataract in cultured rat lenses.

The purposes of this experiment were to: (1), characterize the peptide aldehyde SJA6017, N-(4-fluorophenylsulfonyl)-L-valyl-L-leucinal, a newly synthesized inhibitor of calpain, and (2) test the effect of SJA6017 in preventing calcium ionophore-induced cataract in cultured rat lenses. In vitro, SJA6017 strongly inhibited purified m-calpain from porcine kidney. Casein zymography confirmed that SJA6017 reversibly bound to the active site of m-calpain. SJA6017 was also confirmed to be a cell-permeable inhibitor in Molt-4 cells. In cultured lenses, SJA6017 reduced nuclear opacity and proteolysis of crystallins and alpha-spectrin caused by calcium ionophore A23187. These results suggested that SJA6017 is a reversible and cell-permeable calpain inhibitor which may possess great efficacy against calcium-induced models of cataract.

Degradation of human aquaporin 0 by m-calpain.

Opacities (cataracts) in the lens of the eye are a leading cause of preventable blindness. Aquaporins function as water channels, and the C-terminus is postulated as a regulatory domain. The C-terminal domain of aquaporin 0 (AQP0) develops numerous truncation sites during lens aging. The purpose of the present experiment was to determine if the calcium-activated protease m-calpain (EC 3.4.22.17) was responsible for truncation of human AQP0. AQP0 was isolated from young human donors, incubated with recombinant m-calpain, and the cleavage sites on the released peptides were determined by on-line electrospray ionization mass spectrometry. We found that four cleavage sites on human AQP0 could be tentatively assigned to m-calpain. This is the first evidence for possible calpain activity in human lens. Because the cause(s) of 17 other cleavage sites was unknown, the data also suggested that other, as yet unknown, proteases or non-enzymatic mechanisms are more active than calpain in human lens.

Beta-crystallins insolubilized by calpain II in vitro contain cleavage sites similar to beta-crystallins insolubilized during cataract.

Incubation of soluble proteins from rat lens with the protease calpain II caused the precipitation of beta-crystallin polypeptides. Two-dimensional electrophoresis and sequence analysis identified beta-crystallin polypeptides both before and after their precipitation by calpain II. beta-crystallin polypeptides precipitated by calpain were cleaved at their NH2-terminal extensions. These cleavage sites were similar to cleavage sites occurring in beta-crystallin polypeptides precipitated during formation of experimental cataract induced by an overdose of selenite. These data suggested that calpain II caused beta-crystallin insolubilization during cataract formation, and indicated that the process can be mimicked in vitro.

Involvement of calpain in diamide-induced cataract in cultured lenses.

Lenses cultured in diamide first developed outer cortical opacities followed by nuclear cataract. Lens hydration and total calcium were markedly increased by diamide. Proteolysis of crystallins were observed in nuclear cataract lenses. Calpain in the soluble fraction of lenses cultured with diamide was decreased, while calpain in the insoluble fraction was increased. Co-culture with E64d, an inhibitor of cysteine protease such as calpain, especially prevented nuclear opacities and proteolysis of crystallins, indicating that calpain was involved in cataract formation by diamide.

Induction of elongation in cultured rat lens epithelial cells by FGF and inhibition by selenite.

The purposes of this experiment were to: (1) test if fibroblast growth factor (FGF) induced elongation of cultured rat lens epithelial cells (LEC) and (2) determine if selenite affected elongation of LEC. FGF (125-500 ng/ml) reduced the number of colonies of LEC, but it did not induce elongation when cells were cultured on plastic dishes. One hundred micromolar and, to a lesser extent, 10 mumol/l selenite also reduced the number of colonies of LEC. Coculture of FGF and selenite on plastic caused a synergistic reduction in the number of colonies. FGF (125-1000 ng/ml) induced a dramatic morphologic change in LEC. Elongated processes radiated from stellate-like cell aggregates when cells were cultured on reconstituted basement membrane matrix (Matrigel). Again, 100 mumol/l selenite and, to a lesser extent, 10 mumol/l selenite reduced the number of cell aggregates with processes on Matrigel. These results indicated that an inhibitory effect of selenite on the elongation of LEC may be a factor in the development of selenite cortical cataract.

Calcium-activated proteolysis in the lens nucleus during selenite cataractogenesis.

A single injection of 20 mumol sodium selenite/kg body weight in 10-day-old rats caused severe nuclear cataract within 4 days. By 4 days postselenite injection, nuclear calcium levels increased from 0.4 to 6.8 mmol/kg lens dry weight. The purpose of these experiments was to determine if this calcium increase was associated with proteolysis specifically in the lens nuclear region. Sodium dodecyl sulfate polyacrylamide electrophoresis of lens nuclear proteins following selenite injection showed: loss of 30, 27, and 26 K molecular weight polypeptides in the soluble fraction, loss of 83, 52, 30, 27, and 26 K polypeptides in the insoluble fraction, and loss of the major 26 K membrane protein. Gel chromatography of nuclear soluble proteins indicated a decrease in beta H and beta L crystallins following selenite injection. Two-hour in vitro incubation of nuclear lens homogenates with calcium duplicated many of the proteolytic changes occurring in lenses in vivo following selenite injection. Calcium induced proteolysis in vitro was inhibited by EGTA, leupeptin, and iodoacetate but was not inhibited by phenylmethylsulfonyl fluoride. These properties are similar to calcium activated protease (CAP) from other tissues. Activation of CAP, and subsequent degradation of nuclear proteins, may be causes of selenite cataract.

Cataract and the acceleration of calpain-induced beta-crystallin insolubilization occurring during normal maturation of rat lens.

PURPOSE: To determine if limited proteolysis of beta-crystallins is associated with insolubilization of proteins in rats lens during maturation and to test if the protease, calpain II, is involved. METHODS: Soluble and insoluble lens proteins from 4-day-old to 4-month-old rat lens cortexes and nuclei were separated by two-dimensional electrophoresis. The insoluble proteins from 4-month-old nuclei were electroblotted and the NH2 termini of proteins sequenced. Cleavage sites appearing at 4 months of age were compared to cleavage sites produced by purified calpain II and to cleavage sites appearing in cataracts induced by selenite in vivo or in lenses cultured with calcium ionophore A23187 or diamide. RESULTS: In solubilization of more than 50% of proteins occurred in the nucleus of the transparent rat lens by 4 months of age. The insoluble protein that formed contained an abundance of partially degraded beta-crystallin polypeptides missing portions of their NH2 terminal extensions. In contrast, these truncated beta-crystallins were largely absent from both the cortex and soluble fraction of the nucleus. The cleavage sites in the insoluble beta-crystallins appearing during maturation in the lens nucleus were similar to cleavage sites produced by purified calpain II and also similar to cleavage sites appearing in the insoluble protein of cataractous lenses. CONCLUSIONS: These results suggest that proteolysis of beta-crystallins by the protease calpain II contributes to protein insolubilization during lens maturation and that acceleration of this insolubilization process is associated with cataract formation in rodent lenses.

Crystallin degradation and insolubilization in regions of young rat lens with calcium ionophore cataract.

PURPOSE: To determine if the susceptibility of rat lenses to cataract formation in culture changes with increasing age and to investigate the regional differences in crystallin degradation and insolubilization during the formation of cataracts in cultured lenses. METHODS: Lenses from 4-week-old (young group) and 12-week-old (adult group) rats were divided into four subgroups: noncultured control, cultured control, cultured in calcium ionophore A23187, and cultured in ionophore plus calpain inhibitor E64. Lenses were cultured for 7 days, and the cortex and nucleus were homogenized and separated into water-soluble and water-insoluble fractions. Two-dimensional electrophoresis and N-terminal sequencing were then performed. RESULTS: Young lenses treated with ionophore produced thin cortical and dense nuclear opacities. Adult lenses treated with ionophore also developed thin cortical opacity, but no nuclear opacity was observed, even though a large increase in the concentration of insoluble protein occurred. Two-dimensional electrophoresis and sequencing suggested that calpain caused protein degradation in the cortex region. However, unlike nuclear opacity, the formation of opacity in the cortex was not inhibited by E64 in young or adult lenses. CONCLUSIONS: Calpain was activated, and crystallins were proteolyzed in the cortex of ionophore-treated lenses. However, cortical opacity was not the result of proteolysis by calpain. Maturation also decreased the susceptibility of rat lens nucleus to calcium ionophore cataract.

Amelioration of cataracts and proteolysis in cultured lenses by cysteine protease inhibitor E64.

Cataracts were produced in cultured rat lenses by either 10 microM calcium ionophore A23187, 25 microM sodium selenite, or 30 mM xylose. E64, an inhibitor of cysteine proteases, such as calpain (EC, 3.4.22.17), reduced severity of cataract and proteolysis of crystallins when included at a 500 microM concentration in the culture medium along with cataractogenic agents. Calpain II enzyme activity and the amount of calpain antigen were decreased in the cytosol of cataractous lens. However, E64 caused an increase in the amount of an 80-kD calpain subunit associated with the ethyleneglycol-bis-(beta-aminoethylether) tetraacetic acid/ethylenediaminetetraacetic acid-washed insoluble proteins when lenses were incubated with cataractous agents. These data indicate that E64 was at least partially effective in inhibiting lens calpain, and that activation of lens calpain may involve binding to the insoluble fraction. These results provide strong evidence for the activation of calpain in rodent cataracts and suggest testing inhibitors of calpain as anticataract drugs.

Modifications to rat lens major intrinsic protein in selenite-induced cataract.

PURPOSE: To identify modifications to rat lens major intrinsic protein (MIP) isolated from selenite-induced cataract and to determine whether m-calpain (EC 3.4.22.17) is responsible for cleavage of MIP during cataractogenesis. METHODS: Cataracts were induced in rats by a single injection of sodium selenite. Control and cataract lenses were harvested on day 16 and dissected into cortical and nuclear regions. Membranes were washed with urea buffer followed by NaOH. The protein was reduced/alkylated, delipidated, and cleaved with cyanogen bromide (CNBr). Cleavage products were fractionated by high-performance liquid chromatography (HPLC), and peptides were characterized by mass spectrometry and tandem mass spectrometry. MIP cleavage by m-calpain was carried out by incubation with purified enzyme, and peptides released from the membrane were analyzed by Edman sequencing. RESULTS: The intact C terminus, observed in the control nuclear and cataractous cortical membranes, was not observed in the cataractous nuclear membranes. Mass spectrometric analysis revealed heterogeneous cleavage of the C terminus of MIP in control and cataract nuclear regions. The major site of cleavage was between residues 238 and 239, corresponding to the major site of in vitro cleavage by m-calpain. However, sodium dodecyl sulfate-polyacrylamide gel electrophoresis and mass spectrometric analysis indicated that in vivo proteolysis during cataract formation also included sites closer to the C terminus not produced by m-calpain in vitro. Evidence for heterogeneous N-terminal cleavage was also observed at low levels with no differences between control and cataractous lenses. The major site of phosphorylation was determined to be at serine 235. CONCLUSIONS: Specific sites of MIP N- and C-terminal cleavage in selenite-induced cataractous lenses were identified. The heterogeneous cleavage pattern observed suggests that m-calpain is not the sole enzyme involved in MIP C-terminal processing in rat lens nuclei.

Cloning and expression of mRNA for calpain Lp82 from rat lens: splice variant of p94.

PURPOSE: To describe mRNA for Lp82, a lens-specific form of calcium-activated protease (EC 34.22.17, calpain) in rat. METHODS: Total RNA was extracted from lenses of 12-day-old rats, reverse transcribed, and amplified using polymerase chain reaction (PCR) with degenerate primers for the active site of calpains. Tissue specificity and relative amounts of mRNA for Lp82 in rat lens and other tissues were demonstrated by reverse transcription-PCR using gene-specific primers. PCR products were subcloned and sequenced using standard techniques. RESULTS: Abundant amounts of mRNA for Lp82, a variant of muscle-type calpain p94, were discovered only in lens and not in seven other tissues assayed. When translated, the Lp82 mRNA would code for protein containing the usual cysteine active site residues and calcium-binding domains. Remarkably, the Lp82 cDNA product was identical to that of muscle-type calpain p94, except for deletions of most of the nucleotides coding for three unique insert regions termed NS, IS1, and IS2 found in p94. Compared with p94, a different exon 1 was present, and the nucleotides for all exons 6, 15, and 16 were deleted in Lp82. CONCLUSIONS: Lp82 is a lens-specific calpain. It is a splice variant of muscle-type calpain p94, resulting from deletions of IS1 and IS2 regions and a different exon 1, possibly from an alternative, lens-specific promoter in the p94 gene. Lp82 is important because it may have lens-specific functions suited to the unique properties of the lens. Lp82 may also give insight into the functions of NS, IS1, and IS2 regions in p94, which is important in normal muscle physiology and in the study of limb-girdle muscular dystrophy type 2A in humans.

Origin of urea-soluble protein in the selenite cataract. Role of beta-crystallin proteolysis and calpain II.

Nuclear cataract resulting from an overdose of selenite was characterized by a five-fold increase in nuclear urea-soluble protein. The origin of this urea-soluble protein was examined by two-dimensional electrophoresis, immunoblotting with monospecific antisera against rat lens crystallins, and tryptic mapping. Cataractous urea-soluble protein was primarily composed of insolubilized beta- and gamma-crystallin polypeptides. Polypeptides from cataractous urea-soluble protein, and normal beta L-crystallin aggregates were compared by tryptic mapping. Approximately 19% of the urea-soluble protein from opaque nuclei was composed of 24.7 and 24.0 K polypeptides derived by limited proteolysis of 26.5 K beta L-crystallin polypeptide. Incubation of 26.5 K beta-crystallin polypeptide with purified rat lens calpain II in vitro caused production of fragments with similar molecular weights to polypeptides found in cataractous lenses. These results support the hypothesis that proteolysis may contribute to formation of urea-soluble protein in selenite cataract.

Regional distribution of free calcium in selenite cataract: relation to calpain II.

The purpose of this experiment was to assess the roles of free, intracellular calcium and calcium-dependent neutral protease (calpain II, EC.34.22.17) in selenite nuclear cataract. Free calcium ion concentrations within lens nuclear fibers during selenite cataractogenesis increased to 3 microM on day 2 post-injection (clear lens) and to 108 microM at day 4 (nuclear cataract). Calpain II is known to be activated in vitro by calcium levels above 50 microM. Calpain II activity was present in the lens nucleus at time periods preceding formation of selenite cataract. These data suggested that after selenite injection, calpain II was activated by elevated free calcium in the nucleus, and that calpain II-induced proteolysis of nuclear proteins was an important mechanism in selenite cataract. Calpain II levels were also observed to decrease in the nucleus during selenite cataractogenesis, probably due to autolysis. This was supported by the finding that incubation of purified lens calpain II with 100 microM calcium caused partial inactivation of the protease.