Role of albumin as a fatty acid carrier for biosynthesis of lens lipids.

Although serum albumin is the major protein component of the aqueous humor and vitreous humor, its possible physiological role(s) in lens metabolism has not yet been determined. BODIPY fatty acid, a fluorescent analogue of a C(12) long chain fatty acid, was bound to serum albumin, then incubated with lenses in culture. After various times of incubation, the lenses were homogenized, lipids extracted, and the extracted lipids resolved by thin layer chromatography. Fluorescence analyses demonstrated that the BODIPY fatty acid--albumin complex was translocated into the lens, where the BODIPY fatty acid was incorporated in a time dependent manner into numerous lipids, including phosphatidylcholine, phosphatidylethanolamine, and sphingomyelin. Together, the results strongly suggest that serum albumin in the aqueous humor and/or vitreous humor facilitates the translocation of long chain fatty acids into the lens, where they are used for the biosynthesis of lens lipids.

Glutathione peroxidase-1 deficiency leads to increased nuclear light scattering, membrane damage, and cataract formation in gene-knockout mice.

PURPOSE: Previous in vitro studies with transgenic and gene-knockout mice have shown that lenses with elevated levels of glutathione peroxidase (GPX)-1 activity are able to resist the cytotoxic effect of H(2)O(2), compared with normal lenses and lenses from GPX-1-deficient animals. The purpose of this study was to investigate the functional role of this enzyme in antioxidant mechanisms of lens in vivo by comparing lens changes of gene-knockout mice with age-matched control animals. METHODS: In vivo lens changes were monitored by slit lamp biomicroscopy, and enucleated lenses were examined under a stereomicroscope in gene-knockout animals and age-matched control animals ranging in age from 3 weeks to 18 months. Transmission (TEM) and confocal microscopy were performed on different regions of lenses after the mice were killed at various times. RESULTS: Slit lamp images showed an increase in nuclear light scattering (NLS) in gene-knockout mice compared with control animals. TEM revealed changes in the nucleus as early as 3 weeks of age by the appearance of waviness of fiber membranes. With increasing age, there was greater distortion of fiber membranes and distension of interfiber space at the apex of fiber cells compared with control mice. The changes in nuclear fiber membranes were even more dramatic, as observed by confocal microscopy, which was performed on thicker sections. In contrast to the changes in the lens nucleus, the morphology of the epithelium and superficial cortex remained unchanged in knockout animals during the same experimental period, consistent with slit lamp observations. Stereomicroscopy of ex vivo lenses demonstrated a significant increase in opacification in gene-knockout mice relative to control animals of the same age. This effect became evident in mice aged 5 to 9.9 months and persisted thereafter in older animals, resulting in mature cataracts after 15 months. CONCLUSIONS: The results demonstrate the critical role of GPX-1 in antioxidant defense mechanisms of the lens nucleus. The increased NLS appears to be associated with damage to fiber membranes in the nucleus, which is particularly susceptible to oxidative challenge because of the deficiency of GPX-1. It is suggested that the lens membrane changes in the knockout animals may be due to the formation of lipid peroxides, which serve as substrates for GPX-1. Cataract development in gene-knockout mice appeared to progress from focal opacities, apparent at an earlier age, to lamellar cataracts between 6 and 10 months, and finally to complete opacification in animals older than 15 months. This is the first reported phenotype in GPX-1-knockout mice.

PKC-gamma phosphorylation of connexin 46 in the lens cortex.

PURPOSE: To identify the role of PKC-gamma in control of and phosphorylation of connexin 46 (Cx46) in the lens cortex. METHODS: The association between PKC-gamma and Cx46 was determined by co-immunoprecipitation from whole lens. Phosphorylation of Cx46 and activity of PKC-gamma were determined using Western blots, PKC activity assays, and inhibition of PKC activity by addition of isoform-specific PKC pseudosubstrate inhibitors. RESULTS: Co-localization of PKC-gamma and Cx46 was observed in the bow regions and cortical regions of rat lens. PKC-gamma was not observed in the nuclear region and Cx46 was not observed in the epithelial layer. PKC-alpha was not found in lens cortex or nuclear regions. PKC-gamma could be co-immunoprecipitated with Cx46 from lens cortical regions. Cx46 was phosphorylated on both serine and threonine. No tyrosine phosphorylation was observed. The PKC-gamma specific pseudosubstrate inhibitor caused a 73% inhibition of serine phosphorylation on Cx46 at 1 microM, and, 36% inhibition of threonine phosphorylation at the same concentration. Inhibition of phosphorylation of Cx46 with PKC-alpha pseudosubstrate inhibitor was not observed. CONCLUSIONS: PKC-gamma may phosphorylate Cx46, primarily on serine in whole lens. A role for PKC-gamma in control of lens cortical gap junctions is suggested.

Inversion and isomerization of Asp-58 residue in human alphaA-crystallin from normal aged lenses and cataractous lenses.

We have previously shown that L-Asp-151 in alphaA-crystallin from the human lens is converted to the biologically uncommon D-isomer. This process was not simple racemization, but stereoinversion, accompanied by isomerization to form the beta-Asp residue, such that L-beta-Asp, D-alpha-Asp and D-beta-Asp were formed. The present study shows that Asp-58 of human alphaA-crystallin is also converted to the D-isomer to a high degree to form the same isomers with age. The D/L ratio of beta-Asp-58 in aged normal lens increased to more than 3.0, showing stereoinversion by the 60 year range, then decreased to 1.0 in the 80 year range, while the isomerization of Asp-58 increased in the 80 year range. We also measured inversion and isomerization of the same residue from cataractous and normal human lenses of the 60 year range. The D/L ratio of Asp-58 from cataractous lenses was significantly lower than that from normal lenses, while the isomerization at Asp-58 in cataractous alphaA-crystallin was significantly higher than that of normal alphaA-crystallin. These results indicate that isomerization to the beta isomer of Asp-58 in cataractous alphaA-crystallin increased more than inversion to the D-isomer, suggesting that there are changes in the native structure of alphaA-crystallin in the human cataractous lens.

Deamidation of Asn-143 of gamma S crystallin from protein aggregates of the human lens.

PURPOSE: Determine if gamma S crystallin is preferentially deamidated in the high molecular weight aggregate fraction of old human lenses. METHODS: The high molecular weight aggregate and lower molecular weight fractions were prepared from water soluble proteins of old human lenses. Synthetic peptides corresponding to expected amidated and deamidated tryptic fragments of gamma S crystallin, together with reverse phase chromatography, were used to resolve and quantitate possible deamidation of glutamine-92, glutamine-96 and asparagine-143 from this protein. RESULTS: Analyses of the high molecular weight aggregate from lenses of different ages consistently demonstrated deamidation of asparagine-143, with no deamidation of glutamine-92 or glutamine-96, while analyses of the lower molecular weight fraction from the same lenses showed no detectable deamidation of any of these three residues. CONCLUSIONS: Preferential deamidation of asparagine-143 of gamma S crystallin is present in the high molecular weight fraction of human lenses, consistent with the possibility that modification of this residue may play a role in the aggregation process occurring in vivo.

Mechanism of asparagine deamidation during human senile cataractogenesis.

Previous studies have demonstrated that asparagine-143 of gammaS crystallin is preferentially deamidated in human cataractous lenses. A possible mechanism of nonenzymatic deamidation involves the initial formation of L -succinimidyl and D -succinimidyl intermediates, followed by ring cleavage and production of the respective L - and D - forms of beta-aspartate and alpha-aspartate. To determine if this mechanism occurs during cataractogenesis of the human lens, synthetic peptide standards together with reverse phase HPLC were used to purify and quantitate tryptic peptides from cataractous lenses that contained the beta-aspartate and alpha-aspartate forms of residue 143. For all lenses analysed, the ratios of beta-aspartate/alpha-aspartate produced were consistent with a mechanism of deamidation involving succinimide intermediates. Surprisingly, the D / L ratios for all beta- and alpha-aspartates produced were very low, suggesting that the mechanism of deamidation preferentially involves the L -succinimidyl intermediate, with formation of the D -succinimidyl intermediate almost completely blocked by steric hindrance. Together, the results demonstrate that deamidation of asparagine-143 from gammaS crystallin of different human cataracts undergoes the same mechanism, which due to higher ordered structure of the native protein, results in the preferential production of one of two possible succinimidyl intermediates.

Comparison of d-aspartic acid contents in alpha A-crystallin from normal and age-matched cataractous human lenses.

We have previously shown that biologically uncommon d-beta-aspartic acids (Asp) were localized with very high contents at Asp-151 and Asp-58 of alpha A-crystallin from aged human lenses. The amounts increased with age, and we have proposed the mechanism of this reaction. In the present study, in order to elucidate the possible relationship between the formation of d-beta-aspartic acids in alpha A-crystallin and cataract formation, we measured the d/l ratio of beta-Asp-151 of alpha A-crystallin from both cataractous and age-matched normal human lenses. alpha A-crystallin from total proteins of cataractous and age-matched normal lenses was prepared, followed by tryptic digestion and quantification of d/l ratios for tryptic fragments containing the alpha- and beta-aspartate forms of Asp-151 residues. The results demonstrate that the d/l ratio of beta-Asp-151 of alpha A-crystallin from normal lenses is not statistically significant from that of alpha A-crystallin from cataractous lenses, suggesting that formation of this biologically uncommon amino acid may not play a role in human cataractogenesis.

Increased deamidation of asparagine during human senile cataractogenesis.

PURPOSE: To identify and quantitate deamidation of a specific asparagine residue of gammaS-crystallin that preferentially undergoes deamidation during the process of human senile cataractogenesis. METHODS: Reverse phase chromatography, together with synthetic peptide standards, was used to resolve the amidated and deamidated forms of asparagine-143 in the gammaS-crystallin sequence 131-145 from total tryptic digests of the central, nuclear region of human cataractous and normal lenses. Identities of the resolved peptides co-eluting with synthetic peptide standards were confirmed by mass spectral analysis. The synthetic peptide standards were also used to quantitate the amount of deamidation occurring in individual cataractous and normal lenses. RESULTS: In all lenses analyzed, there was greater deamidation of asparagine-143 in cataractous lenses, as compared with age-matched normal lenses. CONCLUSIONS: The results demonstrate, for the first time, that increased deamidation of a specific asparagine residue is present in proteins from the human cataractous lens.

Specific glutamine and asparagine residues of gamma-S crystallin are resistant to in vivo deamidation.

It has been hypothesized that resistance to nonenzymatic deamidation of asparagine and glutamine residues may be an important determinant of protein stability in vivo. As a test of this hypothesis, we analyzed the central region of old human lenses, which contain proteins such as gamma-S crystallin that were synthesized during the fetal-embryonic periods of development. Total protein from the fetal-embryonic region of old human lenses was digested with trypsin, followed by resolution of tryptic fragments containing amidated and deamidated forms using high pressure liquid chromatography-reverse phase chromatography together with synthetic peptide standards and mass spectral analysis. The results demonstrate no detectable deamidation of glutamine 92, glutamine 96, asparagine 143, and glutamine 170 from gamma-S crystallin from old human lenses, consistent with the hypothesis that very long-lived proteins can contain asparagine and glutamine residues that are extremely resistant to in vivo deamidation.

A possible role for alpha-crystallins in lens epithelial cell differentiation.

PURPOSE: To test the hypothesis that crystallin proteins may actively participate in the differentiation of lens epithelial cells into fiber cells. METHODS: Primary epithelial cells from adult bovine lenses were cultured at 37 degrees C until reaching 95-100% confluency in approximately 4-7 days. Using osmotic lysis of pinocytic vesicles, cells were then loaded with proteins labeled or unlabeled with the fluorescent marker Texas Red (TR). Fetal bovine proteins loaded into cells were lens water soluble fractions, HPLC-purified alpha-, beta-, and gamma-crystallin fractions, or bovine serum albumin (BSA). Cultures were then monitored for morphological changes over a 7 day period. RESULTS: Both TR-labeled and unlabeled water-soluble and a-crystallin fractions from bovine lenses resulted in morphological changes to epithelial cells during the first two h postloading. These changes included aggregation of epithelial cells into raised multilayered cell masses, as well as several cells losing attachment to the dish. The initial changes were subsequently followed by elongation of cells within the mass and an increase in size of the mass, so that by 4 days postloading the multilayered, multicellular structures could be visualized with the unaided eye. Differentiation was confirmed within these structures by expression of MIP 26, beta- and gamma-crystallin. These changes did not occur in cultures containing cells originally loaded with beta- or gamma-crystallin fractions, or with cells loaded with BSA. CONCLUSIONS: The results support the hypothesis that alpha-crystallins may actively participate in the differentiation of lens epithelial cells into fiber cells.

Inhibition of selenite cataract by S-diethylsuccinyl glutathione isopropyl ester.

PURPOSE: Previous studies have demonstrated that glutathione derivatives can partially prevent loss of hepatic glutathione levels, in vivo, during periods of oxidative stress. Since cataracts in animal model systems and in humans are thought to be the direct result of oxidative insult, the following study tested the possibility that treatment with these glutathione analogues may affect the progression of lens opacification. METHODS: Glutathione esters were tested for their ability to inhibit the selenite-induced cataract in rats. RESULTS: The S-alkyl glutathione ester Et(2)Sc-GS-iPr, but not a similar glutathione derivative S-succinyl glutathione (Sc-GS), at 0.5 mmoles/kg body weight, had anti-cataract activity in the selenite-induced cataract of rats. Analysis of lenses from treated and untreated animals demonstrated that Et(2)Sc-GS-iPr partially prevented the loss of reduced glutathione levels. CONCLUSIONS: The results demonstrate for the first time that an S-alkylated glutathione ester has anti-cataractogenic potential in the selenite-treated rat, and suggest possible mechanisms involving glutathione in the prevention of this lens opacification.

Formation of four isomers at the asp-151 residue of aged human alphaA-crystallin by natural aging.

Although proteins are generally composed entirely of l-amino acids, we have previously shown that Asp-151 in alphaA-crystallin from aged human lens is converted to the biologically uncommon d-isomer to a high degree. The formation of d-isomer was not simple racemization, but stereoinvertion. The reaction was also accompanied with isomerization to form beta-Asp (isoaspartate) residue simultaneously; therefore, four isomers of Asp-151, normal l-alpha-Asp and biologically uncommon l-beta-Asp, d-alpha-Asp, and d-beta-Asp, are formed in alphaA-crystallins. In the present study, we measured the ratio of the four isomers of Asp-151 in alphaA-crystallins obtained from total lens proteins of human lenses of newborn and 30-, 60-, and 80-year-olds. The isomers increased with age, and the total amount of three isomers was more than that of normal l-alpha-Asp in the alphaA-crystallin of the human lenses of the 80-year-olds. These drastic changes started at birth, with about 45% of normal l-alpha-Asp lost by 30 years. These modifications of the Asp residue likely affect the three-dimensional packing array of the lens proteins.

Increased cleavage of the c-terminal serine from alpha-A crystallin present in the high molecular weight aggregate fraction from human and bovine lenses.

PURPOSE: To determine the relative amount of serine-173 cleavage from the C-terminus of alpha-A crystallin from the high molecular weight aggregate fraction and lower molecular weight alpha crystallin fraction from water soluble proteins of human and bovine lenses. METHODS: Using gel permeation chromatography, the high molecular weight aggregate fraction and lower molecular weight alpha crystallin fractions were purified from soluble proteins of human lenses and mature bovine lenses. Alpha-A crystallin present in these fractions was digested with trypsin, followed by the use of reverse phase chromatography and synthetic peptide standards to identify and quantitate the relative amount of in vivo cleavage of C-terminal serine -173. RESULTS: For all human and bovine lenses studied, alpha-A crystallin in the high molecular weight aggregate fraction had undergone more truncation at the C-terminus, than the alpha-A crystallin present in the lower molecular weight alpha crystallin fraction from the same lens. CONCLUSIONS: Relative to the alpha-A crystallin present in the lower molecular weight alpha fraction, the alpha-A crystallin present in the high molecular weight aggregate fraction from the same human and bovine lenses has undergone increased cleavage of the C-terminal serine residue, suggesting a common mechanism that may contribute towards formation of protein aggregation in vivo.

Deamidation of alpha-A crystallin from nuclei of cataractous and normal human lenses.

PURPOSE: To quantitate the extent of deamidation of asparagine-101, glutamine-50, and glutamine-6 of alpha-A crystallin in the nucleus from human cataractous and normal lenses. METHODS: Reverse phase chromatography was used to prepare alpha-A crystallin from total proteins of the nucleus from cataractous and age-matched normal human lenses. Synthetic peptides were made corresponding to the expected amidated and deamidated tryptic fragments containing asparagine-101, glutamine-50, and glutamine-6. The peptides were used to identify and quantitate amidated and deamidated forms of tryptic fragments from alpha-A crystallin eluting from a reverse phase column. RESULTS: Significant amounts of deamidation of asparagine-101 and glutamine-50, but not glutamine-6, were present in alpha-A crystallin from nuclear sections of both cataractous and age-matched normal lenses. Quantitative analysis of tryptic peptides containing these residues indicated no statistical difference in deamidation in cataractous versus normal lenses. CONCLUSIONS: There was no significant difference in the extent of deamidation of asparagine-101, glutamine-50, and glutamine-6 for alpha-A crystallin, purified from the nucleus of cataractous versus age-matched normal lenses. These results strongly suggest that deamidation of these residues does not play a role in the biogenesis of human nuclear cataract.

Localization of MIP 26 in nuclear fiber cells from aged normal and age-related nuclear cataractous human lenses.

The purpose of the current study was to localize the lens membrane protein, MIP 26, in nuclear fiber cells from different regions of aged normal and age-related cataractous human lenses. Adult, juvenile, fetal and embryonic nuclear regions in aged normal and age-related nuclear cataractous lenses were morphologically and biochemically characterized using the technologies of immuno-gold (5 nm) labeling, semi-thin sections (200-500 nm), serial sections, DiI staining following by photobleaching, transmission electron microscopy and spot-blot analysis. Numbers of gold particles per micron length of plasma membrane and numbers of gold particles per square micron of cytosol in the embryonic-fetal and juvenile-adult nuclear regions were quantified. Results showed that the labeling pattern of MIP 26 localized to the cytosol was unique to senescent fiber cells from age-related cataractous lenses. Numbers of gold particles per square micron of cytosol in the embryonic-fetal nucleus of age-related cataractous lenses were significantly elevated (P<0.001) above numbers from fiber cells located within the adult or juvenile nuclei of the same lens or senescent fiber cells from aged normal lenses. Some of the cytosolic labeling in cataracts was localized to lipid vesicles, while the remaining labeling was negative for the lipid specific stain DiI. Spot blot analysis demonstrated that binding of the ant-MIP 26 serum was exclusive to large molecular weight components greater than 10 kDa, and not to small molecular weight fragments of the protein. The results of the current study supply further evidence that damage to membranes occurs in senescent fiber cells during age-related nuclear cataracts, resulting in the internalization of structures containing the membrane protein MIP 26.

Deamidation of specific glutamine residues from alpha-A crystallin during aging of the human lens.

Although it has been hypothesized that age-dependent deamidation of glutamine and/or asparagine residues may play an important role in the turnover of proteins in vivo, surprisingly little is known concerning the extents of deamidation of biologically important proteins with very long half-lives. Alpha-A crystallin is the most abundant protein of the adult human lens, which contains long-lived proteins in the central fetal-embryonic region that were synthesized before birth of the individual. Peptides, corresponding to tryptic fragments of alpha-A crystallin, were synthesized with either the expected glutamine-6, glutamine-50, and glutamine-147 residues, or deamidated glutamic acid residues at the same positions. These synthetic peptides were used to identify and quantitate the amidated versus deamidated forms of each tryptic fragment of alpha-A crystallin from the fetal-embryonic region of lenses from donors of increasing age up to 64 years old. The results demonstrate that all three glutamine residues are very stable, with glutamine-50 undergoing a maximum of approximately 30% deamidation after 64 years postsynthesis, while glutamine-6 and glutamine-147 undergo no detectable deamidation during the same period of time. Together, these results are consistent with the hypothesis that resistance to age-dependent, nonenzymatic deamidation may be an important prerequisite for the stability of proteins in vivo.

The possible role of alpha-crystallins in human senile cataractogenesis.

alpha-Crystallins possess molecular chaperone properties and are one of the most abundant of the lenticular proteins. Posttranslational modifications of these proteins have been implicated as a possible etiology of human cataracts. This article will review current knowledge concerning the effects of known posttranslational modifications upon the molecular chaperone properties and aggregation behavior of alpha-A and alpha-B crystallin. Based upon these effects, experimental approaches will be discussed that may be useful in the development of reagents that may selectively inhibit the cataractogenic process in the aging human lens.