Covalent change of major intrinsic polypeptide (MIP26K) of lens membrane during human senile cataractogenesis

Polyclonal antisera have been made against synthetic peptides corresponding to the C-terminal octapeptide and N-terminal nonapeptide of bovine MIP26K. Western blot analysis demonstrated significant binding of the C-terminal antiserum to MIP26K of both normal and cataractous human lens. In contrast, the N-terminal antiserum bound to MIP26K of normal lenses, but failed to bind to MIP26K of 7 out of 10 cataractous lenses studied. These results demonstrate for the first time, a covalent change in MIP26K during human cataractogenesis, and strongly suggest that the location of this change is in the N-terminal region of the polypeptide.     

A study of a hereditary cataract in the mouse

This report presents a study of cataracts seen in a random-bred strain of Swiss mice with Balb/c mice used as a control group. The embryonic development, and histological and slit lamp observations of the lenses in the two groups of animals are contrasted. The cataract is dominant in its inheritance (Tissot, '62). It appears either unilaterally or bilaterally as a dense white opacity in the lens substance. The earliest sign of abnormal formation occurs at 14 days of embryonic development. This is associated with a defect in the primary lens fibers formation. Progressive degeneration of these fibers occurs until they are reduced to a mass of cellular debris seen at the last day of gestation. The secondary fibers are also laid down in an abnormal manner. The normal lamellar arrangement of the secondary fibers is not seen in cataractous lenses. The abnormal lens fiber development leads to progressive vacuolization. The mature cataract seen in the adult is filled with many vacuoles, the largest ones occurring at the equatorial region. The nuclear region consists of a clumpy eosinophilic mass with scattered calcified areas. The rate of growth of the secondary fibers is different from that of the normal group. Most of the mature cataracts in the adult contain a vascularized epithelium. There are three possible areas of primary involvement which may lead to the development of the cataract. This are: (1) A defect in the development of the primary lens fibers; (2) A defect in the development of the secondary lens fibers; (3) An abnormal lens epithelium which may interfere with nutrition of the lens and thus initiate cataract formation.     

Accumulation of the hydroxyl free radical markers meta-, ortho-tyrosine and DOPA in cataractous lenses is accompanied by a lower protein and phenylalanine content of the water-soluble phase

Post-translational modifications of lens proteins play a crucial role in the formation of cataract during ageing. The aim of our study was to analyze protein composition of the cataractous lenses by electrophoretic and high-performance liquid chromatographic (HPLC) methods. Samples were obtained after extracapsular cataract surgery performed by phacoemulsification technique from cataract patients with type 2 diabetes mellitus (DM CAT, n = 22) and cataract patients without diabetes (non-DM CAT, n = 20), while non-diabetic non-cataractous lenses obtained from cadaver eyes served as controls (CONTR, n = 17). Lens fragments were derived from the surgical medium by centrifugation. Samples were homogenized in a buffered medium containing protease inhibitor. Soluble and insoluble protein fractions were separated by centrifugation. The electrophoretic studies were performed according to Laemmli on equal amounts of proteins and were followed by silver intensification. Oxidized amino acid and Phe content of the samples were also analyzed by HPLC following acid hydrolysis of proteins. Our results showed that soluble proteins represented a significantly lower portion of the total protein content in cataractous lenses in comparison with the control group (CONTR, 71.25%; non-DM CAT, 32.00%; DM CAT, 33.15%; p < 0.05 vs CONTR for both). Among the proteins, the crystallin-like proteins with low-molecular weight can be found both in the soluble and insoluble fractions, and high-molecular weight aggregates were found mainly in the total homogenates. In our HPLC analysis, oxidatively modified derivatives of phenylalanine were detected in cataractous samples. We found higher levels of m-Tyr, o-Tyr and DOPA in the total homogenates of cataractous samples compared to the supernatants. In all three groups, the median Phe/protein ratio of the total homogenates was also higher than that of the supernatants (total homogenates vs supernatants, in the CONTR group 1102 vs 633 micromol/g, in the DM CAT group 1187 vs 382 micromol/g and in the non-DM CAT group 967 vs 252 micromol/g; p < 0.05 for all). In our study we found that oxidized amino acids accumulate in cataractous lenses, regardless of the origin of the cataract. The accumulation of the oxidized amino acids probably results from oxidation of Phe residues of the non-water soluble lens proteins. We found the presence of high-molecular weight protein aggregates in cataractous total homogenates, and a decrease of protein concentration in the water-soluble phase of cataractous lenses. The oxidation of lens proteins and the oxidative modification of Phe residues in key positions may lead to an altered interaction between protein and water molecules and thus contribute to lens opacification.     

Rescue of developmental lens abnormalities in chimaeras of noncataractous and congenital cataractous mice

In the study of the lens of a congenital cataractous mouse mutant (CAT), it has been shown that a loss of growth regulation at the cellular level causes gross lens abnormalities. The phenotypic characteristics of the cataractous mouse lens are similar to those seen in human congenital cataract and thus serves as a model system for medical research. In this present investigation, we have demonstrated that the abnormalities of the congenital cataractous lens can be rescued by forming chimaeras between DBA/2 (a noncataractous strain of mouse) and the CAT mutant. This report describes the histological, cellular and biochemical analysis of the resultant chimaeric eyes, and discusses possible mechanisms by which these results were achieved.     

Accumulation of the hydroxyl free radical markers meta-, ortho-tyrosine and DOPA in cataractous lenses is accompanied by a lower protein and phenylalanine content of the water-soluble phase

Post-translational modifications of lens proteins play a crucial role in the formation of cataract during ageing. The aim of our study was to analyze protein composition of the cataractous lenses by electrophoretic and high-performance liquid chromatographic (HPLC) methods.

Samples were obtained after extracapsular cataract surgery performed by phacoemulsification technique from cataract patients with type 2 diabetes mellitus (DM CAT, n = 22) and cataract patients without diabetes (non-DM CAT, n = 20), while non-diabetic non-cataractous lenses obtained from cadaver eyes served as controls (CONTR, n = 17). Lens fragments were derived from the surgical medium by centrifugation. Samples were homogenized in a buffered medium containing protease inhibitor. Soluble and insoluble protein fractions were separated by centrifugation. The electrophoretic studies were performed according to Laemmli on equal amounts of proteins and were followed by silver intensification. Oxidized amino acid and Phe content of the samples were also analyzed by HPLC following acid hydrolysis of proteins.

Our results showed that soluble proteins represented a significantly lower portion of the total protein content in cataractous lenses in comparison with the control group (CONTR, 71.25%; non-DM CAT, 32.00%; DM CAT, 33.15%; p < 0.05 vs CONTR for both). Among the proteins, the crystallin-like proteins with low-molecular weight can be found both in the soluble and insoluble fractions, and high-molecular weight aggregates were found mainly in the total homogenates. In our HPLC analysis, oxidatively modified derivatives of phenylalanine were detected in cataractous samples. We found higher levels of m-Tyr, o-Tyr and DOPA in the total homogenates of cataractous samples compared to the supernatants. In all three groups, the median Phe/protein ratio of the total homogenates was also higher than that of the supernatants (total homogenates vs supernatants, in the CONTR group 1102 vs 633 μmol/g, in the DM CAT group 1187 vs 382 μmol/g and in the non-DM CAT group 967 vs 252 μmol/g; p < 0.05 for all).

In our study we found that oxidized amino acids accumulate in cataractous lenses, regardless of the origin of the cataract. The accumulation of the oxidized amino acids probably results from oxidation of Phe residues of the non-water soluble lens proteins. We found the presence of high-molecular weight protein aggregates in cataractous total homogenates, and a decrease of protein concentration in the water-soluble phase of cataractous lenses. The oxidation of lens proteins and the oxidative modification of Phe residues in key positions may lead to an altered interaction between protein and water molecules and thus contribute to lens opacification.     

Localization of neutral and acidic glycosphingolipids in rat lens

Rat lens was found to contain several neutral and acidic glycosphingolipidsin lens epithelia, cortex and nucleus, and showed developmentalchanges in their content and localization. TLC-immunostainingof gangliosides revealed the enrichment of some ganglio-seriesgangliosides (GM3, GM1, GD3 and GD1b) in lens epithelia andthe presence of GM3 and GD3 in the lens nucleus. Immunohistochemicalstudies confirmed the distribution of GM3 and GM1 in anteriorlens epithelial cells and the cortex, with expression decreasingtoward the lens nucleus. Immunoreaction to GD3 was more intensein the lens nucleus than in epithelial cells. In contrast, theexpression of neolacto-series glycosphingolipids was restrictedto the lens nucleus. In order to investigate the pathologicalchanges of glycosphingolipids in cataract, galactose-inducedcataractous lenses were examined. However, no significant changeswere observed in the content and composition of glycosphingolipids.In addition, Lewis^x epitopes found in human cataractous lenseswere not detected in the cataractous lenses of galactosaemicrats and hereditary cataractous Emory mice. cataract gangliosides glcosphingolipids Lewis^x rat lens     

Immunocytochemical localization of the lens main intrinsic polypeptide (MIP26) in communicating junctions

Plasma membranes of vertebrate lens fiber cells contain a major intrinsic polypeptide with an apparent molecular weight of 26,000 (MIP26). These plasma membranes are extremely rich in communicating junctions, and it has been suggested that MIP26 is a component of them. MIP26 was purified from cow lenses using preparative SDS gel electrophoresis followed by hydroxylapatite column chromatography. From gel electrophoresis patterns and aggregational properties it was concluded that the MIP26 preparation was homogeneous. The purified MIP26 was used to produce monospecific antibodies in rabbits as assessed by double immunodiffusion and crossed immunoelectrophoresis of purified MIP26 and solubilized lens plasma membranes against the antiserum. Indirect immunocytochemical studies were performed on open and closed lens plasma membrane vesicles by incubation in anti-MIP antiserum followed by ferritin-conjugated goat antirabbit IgG. The conjugate bound unequivocally to lens communicating junctions, indicating that MIP26 is a component of these structures.     

Major intrinsic polypeptide (MIP26K) of the lens membrane: covalent change in an internal sequence during human senile cataractogenesis

Polyclonal antisera to three synthetic peptides of bovine MIP26K have been used in combination with Western blot analysis to probe for changes of the MIP26K molecule during human senile cataractogenesis. Anti-MIP26K229-237 binds well to the 26K component from cataractous lens membranes, but binds poorly to the same component from normal lens. In contrast, antisera to two other sequences of MIP26K (anti-MIP26K252-259 and anti-MIP26K256-263) bind approximately equally well to the 26K component from either cataractous or normal lens. Together, these results demonstrate that during cataract development there is a selective covalent change in a region of the MIP26K molecule that may have profound effects upon the ability of this molecule to facilitate intercellular communication between lens fiber cells.     

Comparing the content of lipids derived from the eye lenses of various species

The lipid content in the eye lens was analyzed and compared among various species in this study. The eye lens lipids of the following species were investigated: cow, horse, duck, and freshwater trout. Additionally, the lipids derived from cataractous bovine lens and from cataractous human eye lens lipoprotein complexes were analyzed. The following lipid classes were detected in clear lenses: cholesterol, sphingomyelin, phosphatidylcholine, phosphatidyletanolamine, and phosphatidylserine. In cataractous bovine lens and in lipoprotein complexes from human nuclear cataract, phosphatidyloinositol and phosphatidyloglycerol were detected. Cholesterol and sphingomyelin, essential for hypothetical formation of cholesterol-rich domains, were the most abundant lipids in the lenses of all investigated species. These two components of eye lens lipid fraction were analyzed quantitatively using thin layer chromatography and spectrophotometric assay; the other lipids were identified qualitatively using thin layer chromatography.     

Further studies on elastase and trypsin inhibitory activities in mammalian lenses

Elastase and trypsin inhibitory capacities increased significantly on heat treatment of the lens extract for 15 min at 60 degrees C in human infant (mean increase 290 and 335%), human adult (130 and 245%), ovine (90 and 140%), and bovine (70 and 90%) lenses. No increase was observed in human cataractous lenses. Preincubation with target enzymes in the absence of substrate abolished the antitryptic activity in lenses whereas antielastase activity was more resistant. No decrease in antielastase activity in human adult and cataractous lenses was observed on 15-min preincubation whereas about 50% of activity was abolished in human infant lenses. The differences were attributed to the changes in the levels of endogenous proteinases and proenzymes during cataractogenesis and aging.     

CRE-decoy oligonucleotide-inhibition of gene expression and tumor growth

The authors prepared water-soluble (WSF), urea-soluble (USF), alkali-soluble (ASF), sonicated (SF), sonicated insoluble (SIF) and membrane (MF) fractions of lens proteins from human senile and diabetic cataractous lenses and age-matched clear lenses. Levels of advanced glycation end products (AGEs) including carboxymethyl lysine (CML), a glycoxidation product, were determined by both non-competitive and competitive enzyme-linked immunosorbent assay (ELISA). Distribution of AGEs in the various protein fractions was ascertained by SDS-PAGE and Western blotting. An overall increase in the levels of AGEs in diabetic cataractous lenses as compared to senile cataractous lenses and clear lenses has been observed. ASF and SF , both of which originated from the urea-insoluble fraction, showed the highest levels of AGEs. However, no clear-cut differences in CML levels were seen among clear lenses and senile and diabetic cataractous lenses. AGEs were found to be distributed mostly in the high molecular aggregates in all the fractions. These data suggest that AGEs contribute to protein aggregation and subsequent insolubilization.     

Alpha-actinin expression during avian myogenesis in vivo. Evidence for the existence of an embryo-specific isoform of alpha-actinin

The isoforms of skeletal muscle alpha-actinin present during chick embryogenesis were analyzed by two-dimensional electrophoresis in combination with the immunoblot technique. Chicken embryonic muscles at 8-15 days contain an embryo-specific isoform of alpha-actinin. The embryonic alpha-actinin isoform has a molecular mass of 112 kDa and an isoelectric point of 5.8, whereas the values for the adult isoform of alpha-actinin were 100 kDa and 5.85, respectively. To characterize the two classes of alpha-actinin polypeptides we have compared the two proteins by 125I-labeled two-dimensional peptide mapping. The embryonic isoform is highly similar to, but exhibited extensive peptide differences to, the adult isoform of alpha-actinin. The developmental sequence of the expression of the alpha-actinins was also studied. In extracts of skeletal muscle from 8-10-day-old embryos, only the embryonic isoform was detected. In extracts from 15-day-old embryos, both the embryonic and the adult isoforms coexisted. However by 21 days, the embryonic isoform had disappeared and only the adult isoform was detected. These data suggested that the embryonic and the adult isoform of alpha-actinins are distinct proteins and that during skeletal myogenesis in ovo one class of alpha-actinin is replaced by a new class of alpha-actinin polypeptides, and that the latter is maintained into adulthood.     

Developmental regulation of the direct interaction between the intracellular loop of connexin 45.6 and the C terminus of major intrinsic protein (aquaporin-0)

The eye lens is dependent upon a network of gap junction-mediated intercellular communication to facilitate its homeostasis and development. Three gap junction-forming proteins are expressed in the lens of which two are in lens fibers, namely connexin (Cx) 45.6 and 56. Major intrinsic protein (MIP), also known as aquaporin-0 (AQP0), is the most abundant membrane protein in lens fibers. However, its role in the lens is not clear. Our previous studies show that MIP(AQP0) associates with gap junction plaques formed by Cx45.6 and Cx56 during the early stages of embryonic chick lens development but not in late embryonic and adult lenses. We report here that MIP(AQP0) directly interacts with Cx45.6 but not with Cx56. We further identified the intracellular loop of Cx45.6 as the interacting domain for the MIP(AQP0) C terminus. Surface plasmon resonance experiments indicated that the C-terminal domain of MIP(AQP0) interacts with two binding sites within the intracellular loop region of Cx45.6 with a K(D(app)) of 7.5 and 10.3 microm, respectively. The K(D(app)) for the full-length loop region is 7.7 microm. The cleavage at the intracellular loop of Cx45.6 was observed during lens development, and the C terminus of MIP(AQP0) did not interact with the loop-cleaved form of Cx45.6. Thus, the dissociation between these two proteins that occurs in the mature fibers of late lens development is likely caused by this cleavage. Finally this interaction had no impact on Cx45.6-mediated intercellular communication, suggesting that the Cx45.6-MIP(AQP0) interaction plays a novel unidentified role in lens fibers.     

Developmental changes in proteins of purified membranes of chicken lenses and evidence for contamination by cytoplasmic delta-crystallin.

Urea-washed membranes from embryonic chick lenses (15 days old) and from the cortical and nuclear regions of adult chicken lenses (1 year) have been prepared by repeated centrifugation through discontinuous density gradients. The protein components of the isolated membranes have been examined by electrophoresis in polyacrylamide gels containing sodium dodecyl sulfate and urea. Proteins with molecular weights of 75 000, 56 000, 54 000, 48 000, 34 000, 32 000, 25 000, and 22 000 were present in all the membrane preparations, although their proportions changed during development. One additional protein, molecular weight 70 000, was seen only in the embryonic lens membranes. The greatest developmental change was the increase in 25 000 molecular weight protein from 12% in the embryonic lens to about 45% in the adult lens. Since it has been suggested that this protein is associated with gap junctions, its increase during development may reflect a corresponding increase in the number of gap junctions in the lens. The 50 000 molecular weight protein of embryonic lens membranes and membranes of adult nuclear lens fibers consisted at least partly of delta-crystallin, since delta-crystallin peptides could be identified in tryptic peptide maps of the isolated protein after in vitro radioiodination. Peptide maps of the 50 000 molecular weight protein of cortical lens fiber membranes contained no identifiable delta-crystallin peptides, although it is possible that modified delta-crystallin peptides may be present. The level of cytoplasmic contamination of the membrane fraction was estimated by preparing lens membranes in the presence of added delta-[35S]crystallin. The results indicated that cytoplasmic contamination contributes significantly to the presence of delta-crystallin in lens membrane preparations.     

Peroxide-metabolizing systems of the crystalline lens

The ability of transparent and cataractous human, rabbit and mice lenses to metabolize hydrogen peroxide in the surrounding medium was evaluated. Using a chemiluminescence method in a system of luminol-horseradish peroxidase and a photometric technique, the temperature-dependent kinetics of H₂O₂ decomposition by lenses were measured. The ability of opaque human lenses to catalyze the decomposition of 10^?4 M H₂O₂ was significantly decreased. However, this was reserved by the addition of GSH to the incubation medium. Incubation of the mice lenses with the initial concentration H₂O₂ 10^?4 M led to partial depletion of GSH in normal and cataractous lenses. Human cataractous lenses showed decreased activities of glutathione reductase, glutathione peroxidase (catalyzing reduction of organic hydroperoxides including hydroperoxides of lipids), superoxide dismutase, but no signs of depletion in activities of catalase or glutathione peroxidase (utilizing H₂O₂). The findings indicated an impairment in peroxide metabolism of the mature cataractous lenses compared to normal lenses to be resulted from a deficiency of GSH. An oxidative stress induced by accumulation of lipid peroxidation products in the lens membranes during cataract progression could be considered as a primary cause of GSH deficiency and disturbance of the redox balance in the lens.     

Covalent change in alpha crystallin during human senile cataractogenesis

The high molecular weight aggregates (HMWA) obtained from normal and cataractous human lens nuclei have been resolved by SDS-polyacrylamide gel electrophoresis, and the alpha crystallin band has been probed with antisera made against the whole alpha crystallin molecule and with antisera made against synthetic peptides of alpha crystallin (alpha A2 147-161 and alpha A2 163-173). Quantitation of these antisera binding demonstrated that the anti-alpha A2 163-173 serum and the anti-alpha whole sera bound equally well to the alpha crystallin band from the HMWA fraction from normal and cataractous lenses. In contrast, the anti-alpha A2 147-161 serum bound little, if at all, to alpha crystallin from normal lenses, while it bound well to alpha crystallin from cataractous lenses. These results demonstrate a covalent alteration in the alpha crystallin molecule, and suggest a possible location of a covalent change that may occur during the cataractogenic process in the aged human lens.     

Estimation of structural changes in the cataractous rat lens using Raman spectroscopy.

For quantitative evaluation of cataract-related changes in lens proteins and lens water, the relative contents of water and SH residues and changes in the microenvironments of aromatic amino acid residues were quantitatively examined in cataract of the rat lens which had been induced by sodium selenite. Using Raman spectroscopy, results were compared with those of age-matched control lenses. The relative contents of water and SH residues decreased with increasing age in normal lenses from 3 to 8 weeks of age. In the cataractous lens, the relative water content increased constantly as compared with that of age-matched controls. The relative SH residue content continued to decline in the cataractous lenses of animals at every age. The microenvironments of tyrosine residues in cataractous lenses also changed progressively.     

Developmental changes in proteins of purified membranes of chicken lenses and evidence for contamination by cytoplasmic δ-crystallin

Urea-washed membranes from embryonic chick lenses (15 days old) and from the cortical and nuclear regions of adult chicken lenses (1 year) have been prepared by repeated centrifugation through discontinuous density gradients. The protein components of the isolated membranes have been examined by electrophoresis in polyacrylamide gels containing sodium dodecyl sulfate and urea. Proteins with molecular weights of 75 000, 56 000, 54 000, 48 000, 34 000, 32 000, 25 000, and 22 000 were present in all the membrane preparations, although their proportions changed during development. One additional protein, molecular weight 70 000, was seen only in the embryonic lens membranes. The greatest developmental change was the increase in 25 000 molecular weight protein from 12% in the embryonic lens to about 45% in the adult lens. Since it has been suggested that this protein is associated with gap junctions, its increase during development may reflect a corresponding increase in the number of gap junctions in the lens.The 50 000 molecular weight protein of embryonic lens membranes and membranes of adult nuclear lens fibers consisted at least partly of δ-crystallin, since δ-crystallin peptides could be identified in tryptic pepetide maps of the isolated protein after in vitro radioiodination. Peptide maps of the 50 000 molecular weight protein of cortical lens fiber membranes contained no identifiable δ-crystallin peptides, although it is possible that modified δ-crystallin peptides may be present. The level of cytoplasmic contamination of the membrane fraction was estimated by preparing lens membranes in the presence of added δ-[³⁵S]crystallin. The results indicated that cytoplasmic contamination contributes significantly to the presence of δ-crystallin in lens membrane preparations.     

Ethylnitrosourea-induced base pair substitution affects splicing of the mouse gammaE-crystallin encoding gene leading to the expression of a hybrid protein and to a cataract

A novel ENU-induced mutation in the mouse leading to a nuclear and cortical opacity of the eye lens (ENU418) was mapped to proximal chromosome 1 by a genome-wide mapping approach. It suggests that the cluster of gamma-crystallin encoding genes (Cryg) and the betaA2-crystallin encoding gene Cryba2 are excellent candidate genes. An A --> G exchange in the middle of intron 1 of the Cryge gene was found as the only alteration cosegregating with the cataractous phenotype. The mutation was confirmed by the presence of a novel restriction site for ApaI in the corresponding genomic DNA fragment. The mutation represses splicing of intron 1; the additional 92 bp in the corresponding cDNA leads to a frameshift and the expression of a novel hybrid protein containing 3 amino acids of the gammaE-crystallin at the N terminus, but 153 novel amino acids. The Cryge(ENU418) protein has a calculated molecular mass of approximately 15.6 kD and an alkaline isoelectric point (pH 10.1) and is predicted to have two hydrophobic domains. Western blot analysis using a polyclonal antibody against the hydrophilic C-terminal part of the Cryge(ENU418)-specific protein demonstrated its stable expression in the cataractous lenses; it was not found in the wild types. Histological analysis of the cataractous lenses indicated that the expression of the new protein disrupts the cellular structure of the eye lens.