Dysregulation of Autophagy Occurs During Congenital Cataract Development in ßA3ΔG91 Mice.

Purpose: To examine lens phenotypic characteristics in ßA3ΔG91 mice and determine if ßA3ΔG91 affects autophagy in the lens. Methods: We generated a ßA3ΔG91 mouse model using CRISPR/Cas9 methodology. Comparative phenotypic and biochemical characterizations of lenses from postnatal day 0 (P0), P15, and 1-month-old ßA3ΔG91 and wild-type (WT) mice were performed. The methodologies used included non-invasive slit-lamp examination, reverse transcription-quantitative polymerase chain reaction (RT-qPCR), western blot, and immunohistochemical (IHC) analyses to determine the levels of autophagy-related genes and proteins. Transmission electron microscopy (TEM) analysis of lenses was performed to assess organelle degradation and the presence of autophagic vesicles. TUNEL staining was used to determine apoptosis in the lens. Results: Relative to WT lenses, 1-month-old ßA3ΔG91 mice developed congenital nuclear cataract and microphthalmia and showed an early loss of endoplasmic reticulum (ER) in the cortex and attenuation of nuclei degradation. This observation was confirmed by TEM analysis, as was the presence of autophagic vesicles in ßA3ΔG91 lenses. Comparative IHC and RT-qPCR analyses showed relatively higher levels of autophagy markers (ubiquitinated proteins and p62, LC3, and LAMP2 proteins) in ßA3ΔG91 lenses compared to WT lenses. Additionally, ßA3ΔG91 lenses showed relatively greater numbers of apoptotic cells and higher levels of cleaved caspase-3 and caspase-9. Conclusions: The deletion of G91 in ßA3ΔG91 mice leads to higher levels of expression of autophagy-related proteins and their transcripts relative to WT lenses. Taken together, G91 deletion in ßA3/A1-crystallin is associated with autophagy disruption, attenuation of nuclei degradation, and cellular apoptosis in the lens, which might be congenital cataract causative factors.

Role of Fibroblast Growth Factor Receptor 2 (FGFR2) in Corneal Stromal Thinning.

Purpose: To determine the role of fibroblast growth factor receptor 2 (FGFR2)-mediated signaling in keratocytes during corneal development, a keratocyte-specific FGFR2-knockout (named FGFR2cKO) mouse model was generated, and its phenotypic characteristics were determined. Methods: A FGFR2cKO mouse model was generated by the following method: FGFR2 flox mice were crossed with the inducible keratocyte specific-Cre mice (Kera-rtTA/tet-O-Cre). Both male and female FGFR2cKO- and control mice (1 to 3-months-old) were analyzed for changes in corneal topography and pachymetry maps using the optical coherence tomography (OCT) method. The comparative TUNEL assay and immunohistochemical analyses were performed using corneas of FGFR2cKO and control mice to determine apoptotic cells, and expression of collagen-1 and fibronectin. Transmission electron microscopic analysis was conducted to determine collagen structures and their diameters in corneas of FGFR2cKO and control mice. Results: OCT-analyses of corneas of FGFR2cKO mice (n = 24) showed localized central thinning and an increased corneal steepness compared to control mice (n = 23). FGFR2cKO mice further showed a decreased expression in collagen-1, decreased collagen diameters, acute corneal hydrops, an increased fibronectin expression, and an increased number of TUNEL-positive cells suggesting altered collagen structures and keratocytes' apoptosis in the corneas of FGFR2cKO mice compared to control mice. Conclusions: The FGFR2cKO mice showed several corneal phenotypes (as described above in the results) that are also exhibited by the human keratoconus corneas. The results suggested that the FGFR2cKO mouse model serves to elucidate not only the yet unknown role of FGFR2-mediated signaling in corneal physiology but also serves as a model to determine molecular mechanism of human keratoconus development.

Lens-specific ßA3/A1-conditional knockout mice: Phenotypic characteristics and calpain activation causing protein degradation and insolubilization.

ßA3/A1-crystallin is a lens structural protein that plays an important role in maintaining lens transparency via interactions with other crystallins. While the function of ßA3/A1-crystallin in the retina is well studied, its functions in the lens, other than as a structural protein, remain unclear. In the current study, we generated the lens-specific ßA3/A1-crystallin conditional knockout mouse (named ßA3/A1ckO) and explored phenotypic changes and the function of the crystallin in the lens. The ßA3/A1ckO mice showed congenital cataract at birth and exhibited truncation of lens proteins. Several truncated protein fragments were recovered as a pellet during a low-speed centrifugation (800 rpm, 70 x g) followed by a relatively higher speed centrifugation (5000 rpm, 2744 x g). Mass spectrometric analysis of pellets recovered following the two centrifugations showed that among the fragments with Mr < 20 kDa, the majority of these were from ß-tubulin, and some from phakinin, αA-crystallin, and calpain-3. Further, we observed that in vitro activation of calpain-3 by calcium treatment of the wild-type-lens homogenate resulted in the degradation of calpain-3, αA-crystallin and ß-tubulin and insolubilization of these proteins. Based on these results, it was concluded that the activation of calpain 3 resulted in proteolysis of ß-tubulin, which disrupted cellular microtubular structure, and caused proteolysis of other lens proteins (αA-crystallin and phakinin). These proteolyzed protein fragments become insoluble, and together with the disruption of microtubular structure, and could be the causative factors in the development of congenital nuclear cataract in ßA3/A1cKO mice.

Modeling Keratoconus Using Induced Pluripotent Stem Cells.

PURPOSE: To model keratoconus (KC) using induced pluripotent stem cells (iPSC) generated from fibroblasts of both KC and normal human corneal stroma by a viral method. METHODS: Both normal and KC corneal fibroblasts from four human donors were reprogramed directly by delivering reprogramming factors in a single virus using 2A "self-cleaving" peptides, using a single polycistronic lentiviral vector coexpressing four transcription factors (Oct 4, Sox2, Klf4, and Myc) to yield iPSC. These iPS cells were characterized by immunofluorescence detection using of stem cell markers (SSEA4, Oct4, and Sox2). The mRNA sequencing was performed and the datasets were analyzed using ingenuity pathways analysis (IPA) software. RESULTS: The generated stem cell-like clones expressed the pluripotency markers, SSEA4, Oct4, Sox2, Tra-1-60, and also expressed pax6. Our transcriptome analysis showed 4300 genes, which had 2-fold change and 870 genes with a q-value of <0.05 in keratoconus iPSC compared to normal iPSC. One of the genes that showed difference in KC iPSC was FGFR2 (down-regulated by 2.4 fold), an upstream target of Pi3-Kinase pathway, was further validated in keratoconus corneal sections and also KC iPSC-derived keratocytes (down regulated by 2.0-fold). Both normal and KC-derived keratocytes expressed keratocan, signature marker for keratocytes. KC iPSC-derived keratocytes showed adverse growth and proliferation and was further confirmed by using Ly2924002, a PI3k inhibitor, which severely affected the growth and differentiation in normal iPSC. CONCLUSIONS: Based on our result, we propose a model for KC in which inhibition FGFR2-Pi3-Kinase pathway affects the AKT phosphorylation, and thus affecting the keratocytes survival signals. This inhibition of the survival signals could be a potential mechanism for the KC-specific decreased cell survival and apoptosis of keratocytes.

CRYßA3/A1-Crystallin Knockout Develops Nuclear Cataract and Causes Impaired Lysosomal Cargo Clearance and Calpain Activation.

ßA3/A1-crystallin is an abundant structural protein of the lens that is very critical for lens function. Many different genetic mutations have been shown to associate with different types of cataracts in humans and in animal models. ßA3/A1-crystallin has four Greek key-motifs that organize into two crystallin domains. It shown to bind calcium with moderate affinity and has putative calcium-binding site. Other than in the lens, ßA3/A1 is also expressed in retinal astrocytes, retinal pigment epithelial (RPE) cells, and retinal ganglion cells. The function of ßA3/A1-crystallin in the retinal cell types is well studied; however, a clear understanding of the function of this protein in the lens has not yet been established. In the current study, we generated the ßA3/A1-crystallin knockout (KO) mouse and explored the function of ßA3/A1-crystallin in lens development. Our results showed that ßA3-KO mice develop congenital nuclear cataract and exhibit persistent fetal vasculature condition. At the cellular level KO lenses show defective lysosomal clearance and accumulation of nuclei, mitochondria, and autophagic cargo in the outer cortical region of the lens. In addition, the calcium level and the expression and activity of calpain-3 were increased in KO lenses. Taken together, these results suggest the lack of ßA3-crystallin function in lenses, alters calcium homeostasis which in turn causes lysosomal defects and calpain activation. These defects are responsible for the development of nuclear cataract in KO lenses.

Molecular mechanism of formation of cortical opacity in CRYAAN101D transgenic mice.

PURPOSE: The CRYAAN101D transgenic mouse model expressing deamidated αA-crystallin (deamidation at N101 position to D) develops cortical cataract at the age of 7 to 9 months. The present study was carried out to explore the molecular mechanism that leads to the development of cortical opacity in CRYAAN101D lenses. METHODS: RNA sequence analysis was carried out on 2- and 4-month-old αA-N101D and wild type (WT) lenses. To understand the biologic relevance and function of significantly altered genes, Ingenuity Pathway Analysis (IPA) was done. To elucidate terminal differentiation defects, immunohistochemical, and Western blot analyses were carried out. RESULTS: RNA sequence and IPA data suggested that the genes belonging to gene expression, cellular assembly and organization, and cell cycle and apoptosis networks were altered in N101D lenses. In addition, the tight junction signaling and Rho A signaling were among the top three canonical pathways that were affected in N101D mutant. Immunohistochemical analysis identified a series of terminal differentiation defects in N101D lenses, specifically, increased proliferation and decreased differentiation of lens epithelial cells (LEC) and decreased denucleation of lens fiber cells (LFC). The expression of Rho A was reduced in different-aged N101D lenses, and, conversely, Cdc42 and Rac1 expressions were increased in the N101D mutants. Moreover, earlier in development, the expression of major membrane-bound molecular transporter Na,K-ATPase was drastically reduced in N101D lenses. CONCLUSIONS: The results suggest that the terminal differentiation defects, specifically, increased proliferation and decreased denucleation are responsible for the development of lens opacity in N101D lenses.

Downregulation of ß-actin gene and human antigen R in human keratoconus.

PURPOSE: The purpose of this study was to determine the expression levels and regulation of ß-actin in the stroma of keratoconus (KC) and normal corneas. METHODS: A total of 15 different human corneas from both KC and normal individuals were used for this study. Additionally, 3 Fuch's dystrophic corneas were also used. The ß-actin gene expression was analyzed at the transcriptional and translational levels in the epithelium and stroma of the KC and normal corneas. The human antigen R (HuR) gene expression was analyzed by real-time PCR in the stroma of five KC and five normal corneas. The keratocytes from three normal and three KC corneas were cultured in the presence of serum, and the expression levels of ß-actin and human antigen R (HuR) were analyzed by using confocal imaging in both normal and KC fibroblasts. RESULTS: The expression of the ß-actin gene was downregulated in the stroma of the six KC corneas but not in the stroma of six normal and Fuchs' dystrophic corneas. Immunofluorescence detection of ß-actin showed that it was absent in the KC fibroblast. The real-time PCR analysis of the HuR gene showed a relative 4.7-fold lower expression in KC corneas relative to the normal corneas, which was further confirmed by the immunofluorescence detection of HuR in fibroblasts of KC corneas. CONCLUSIONS: Although ubiquitous ß-actins are essential for cell survival during early embryogenesis, the effects on various stages of development are not well understood. Our results show that ß-actin is downregulated in the corneal stroma of patients with KC, which may be related to reduced levels of a stabilizing factor (HuR) for ß-actin mRNA. We propose that loss of ß-actin in the corneal stroma might be a triggering factor in the development of KC.

The common modification in alphaA-crystallin in the lens, N101D, is associated with increased opacity in a mouse model.

To elucidate the morphological and cellular changes due to introduction of a charge during development and the possible mechanism that underlies cataract development in humans as a consequence of an additional charge, we generated a transgenic mouse model mimicking deamidation of Asn at position 101. The mouse model expresses a human αA-crystallin gene in which Asn-101 was replaced with Asp, which is referred to as αAN101D-transgene and is considered to be "deamidated" in this study. Mice expressing αAN101D-transgene are referred to here CRYAA(N101D) mice. All of the lines showed the expression of αAN101D-transgene. Compared with the lenses of mice expressing wild-type (WT) αA-transgene (referred to as CRYAA(WT) mice), the lenses of CRYAA(N101D) mice showed (a) altered αA-crystallin membrane protein (aquaporin-0 (AQP0), a specific lens membrane protein) interaction, (b) extracellular spaces between outer cortical fiber cells, (c) attenuated denucleation during confocal microscopic examination, (d) disrupted normal fiber cell organization and structure during scanning electron microscopic examination, (e) distorted posterior suture lines by bright field microscopy, and (f) development of a mild anterior lens opacity in the superior cortical region during the optical coherence tomography scan analysis. Relative to lenses with WT αA-crystallin, the lenses containing the deamidated αA-crystallin also showed an aggregation of αA-crystallin and a higher level of water-insoluble proteins, suggesting that the morphological and cellular changes in these lenses are due to the N101D mutation. This study provides evidence for the first time that expression of deamidated αA-crystallin caused disruption of fiber cell structural integrity, protein aggregation, insolubilization, and mild cortical lens opacity.

Genistein and genistein-containing dietary supplements accelerate the early stages of cataractogenesis in the male ICR/f rat.

Cataract-related loss of vision affects large numbers of people in today's aging populations and presents a healthcare burden to many nations. The role of dietary supplements within the lens is largely unknown, although benefits from dietary anti-oxidants are expected. In this study, the effects of genistein as its aglycone, a genistein-containing dietary supplement (Novasoy(®)200), and a genistein-containing food (soy protein isolate, PRO-FAM 932) on the development of lens opacity were examined in the hereditary cataractous ICR/f rat. These studies were carried out in a background diet of semi-purified, isoflavone-free AIN-76A with casein as its protein source. The amount of genistein for the experimental diets was standardized to its concentration (as genistein aglycone as well as simple and complex ß-glucoside conjugates) in the soy protein isolate supplement. Also tested was a high-dose genistein diet containing an 11-fold higher amount of genistein aglycone. The composition of each diet was verified by reverse-phase HPLC and blood plasma isoflavone concentrations were determined by LC-tandem mass spectrometry. The development of opacity in each lens was monitored and digitally recorded using slit-lamp examination over the course of the study. Each of the genistein-containing diets caused a significantly more rapid development of fibrous opacification in the anterior cortical region and development of apparent water clefts or vacuoles in the posterior subcapsular region than the AIN-76A control diet; however, the establishment of dense lens opacification was not significantly different between each of the diets. There was also no significant difference observed between the low-dose and high-dose genistein aglycone groups. These data suggest that genistein-containing dietary supplements accelerate the early stages of cataractogenesis in the male ICR/f rat, with no dose-dependent effects.

Identification of interaction sites between human betaA3- and alphaA/alphaB-crystallins by mammalian two-hybrid and fluorescence resonance energy transfer acceptor photobleaching methods.

Our recent study has shown that betaA3-crystallin along with betaB1- and betaB2-crystallins were part of high molecular weight complex obtained from young, old, and cataractous lenses suggesting potential interactions between alpha- and beta-crystallins (Srivastava, O. P., Srivastava, K., and Chaves, J. M. (2008) Mol. Vis. 14, 1872-1885). To investigate this further, this study was carried out to determine the interaction sites of betaA3-crystallin with alphaA- and alphaB-crystallins. The study employed a mammalian two-hybrid method, an in vivo assay to determine the regions of betaA3-crystallin that interact with alphaA- and alphaB-crystallins. Five regional truncated mutants of betaA3-crystallin were generated using specific primers with deletions of N-terminal extension (NT) (named betaA3-NT), N-terminal extension plus motif I (named betaA3-NT + I), N-terminal extension plus motifs I and II (named betaA3-NT + I + II), motif III plus IV (named betaA3-III + IV), and motif IV (named betaA3-IV). The mammalian two-hybrid studies were complemented with fluorescence resonance energy transfer acceptor photobleaching studies using the above described mutant proteins, fused with DsRed (Red) and AcGFP fluorescent proteins. The results showed that the motifs III and IV of betaA3-crystallin were interactive with alphaA-crystallin, and motifs II and III of betaA3-crystallin primarily interacted with alphaB-crystallin.

High-resolution mass spectrometry analysis of protein oxidations and resultant loss of function.

MS, with or without pre-analysis peptide fractionation, can be used to decipher the residues on proteins where oxidative modifications caused by peroxynitrite, singlet oxygen or electrophilic lipids have occurred. Peroxynitrite nitrates tyrosine and tryptophan residues on the surface of actin. Singlet oxygen, formed by the interaction of UVA light with tryptophan, can oxidize neighbouring cysteine, histidine, methionine, tyrosine and tryptophan residues. Dose-response inactivation by 4HNE (4-hydroxynonenal) of hBAT (human bile acid CoA:amino acid N-acyltransferase) and CKBB (cytosolic brain isoform of creatine kinase) is associated with site-specific modifications. FT-ICR (Fourier-transform ion cyclotron resonance)-MS using nanoLC (nano-liquid chromatography)-ESI (electrospray ionization)-MS or direct-infusion ESI-MS with gas-phase fractionation identified 14 4HNE adducts on hBAT and 17 on CKBB respectively. At 4HNE concentrations in the physiological range, one member of the catalytic triad of hBAT (His362) was modified; for CKBB, although all four residues in the active site that were modifiable by 4HNE were ultimately modified, only one, Cys283, occurred at physiological concentrations of 4HNE. These results suggest that future in vivo studies should carefully assess the critical sites that are modified rather than using antibodies that do not distinguish between different modified sites.

Structural and functional roles of deamidation and/or truncation of N- or C-termini in human alpha A-crystallin.

The purpose of the study was to compare the effects of deamidation alone, truncation alone, or both truncation and deamidation on structural and functional properties of human lens alphaA-crystallin. Specifically, the study investigated whether deamidation of one or two sites in alphaA-crystallin (i.e., alphaA-N101D, alphaA-N123D, alphaA-N101/123D) and/or truncation of the N-terminal domain (residues 1-63) or C-terminal extension (residues 140-173) affected the structural and functional properties relative to wild-type (WT) alphaA. Human WT-alphaA and human deamidated alphaA (alphaA-N101D, alphaA-N123D, alphaA-N101/123D) were used as templates to generate the following eight N-terminal domain (residues 1-63) deleted or C-terminal extension (residues 140-173) deleted alphaA mutants and deamidated plus N-terminal domain or C-terminal extension deleted mutants: (i) alphaA-NT (NT, N-terminal domain deleted), (ii) alphaA-N101D-NT, (iii) alphaA-N123D-NT, (iv) alphaA-N101/123D-NT, (v) alphaA-CT (CT, C-terminal extension deleted), (vi) alphaA-N101D-CT, (vii) alphaA-N123D-CT, and (viii) alphaA-N101/123D-CT. All of the proteins were purified and their structural and functional (chaperone activity) properties determined. The desired deletions in the alphaA-crystallin mutants were confirmed by matrix-assisted laser desorption/ionization-time-of-flight (MALDI-TOF) mass spectrometric analysis. Relative to WT-alphaA homomers, the mutant proteins exhibited major structural and functional changes. The maximum decrease in chaperone activity in homomers occurred on deamidation of N123 residue, but it was substantially restored after N- or C-terminal truncations in this mutant protein. Far-UV circular dichroism (CD) spectral analyses generally showed an increase in the beta-contents in alphaA mutants with deletions of N-terminal domain or C-terminal extension and also with deamidation plus above N- or C-terminal deletions. Intrinsic tryptophan (Trp) and total fluorescence spectral studies suggested altered microenvironments in the alphaA mutant proteins. Similarly, the ANS (8-anilino-1-naphthalenesulfate) binding showed generally increased fluorescence with blue shift on deletion of the N-terminal domain in the deamidated mutant proteins, but opposite effects were observed on deletion of the C-terminal extension. Molecular mass, polydispersity of homomers, and the rate of subunit exchange with WT-alphaB-crystallin increased on deletion of the C-terminal extension in the deamidated alphaA mutants, but on N-terminal domain deletion these values showed variable results based on the deamidation site. In summary, the data suggested that the deamidation alone showed greater effect on chaperone activity than the deletion of N-terminal domain or C-terminal extension of alphaA-crystallin. The N123 residue of alphaA-crystallin plays a crucial role in maintaining its chaperone function. However, both the N-terminal domain and C-terminal extension are also important for the chaperone activity of alphaA-crystallin because the activity was partially or fully recovered following either deletion in the alphaA-N123D mutant. The results of subunit exchange rates among alphaA mutants and WT-alphaB suggested that such exchange is an important determinant in maintenance of chaperone activity following deamidation and/or deletion of the N-terminal domain or C-terminal extension in alphaA-crystallin.

Basis for N-acetyllactosamine-mediated inhibition of enteropathogenic Escherichia coli localized adherence.

In a previous article, the authors reported that exposing wild-type enteropathogenic Escherichia coli (EPEC) to chemically synthesized N-acetyllactosamine glycosides covalently coupled to BSA (LacNAc-BSA) inhibited localized adherence (LA) by these organisms and also caused them to lose their bundle-forming pili (BFP), the filamentous surface appendages responsible for their LA phenotype. This effect has now been further investigated by screening a panel of LacNAc-BSA-related glycosides for their ability to inhibit EPEC LA, which revealed that LacNAc-BSA retained its status as the most effective inhibitor of EPEC LA. It was also shown that LacNAc-BSA did not cause the loss of BFP in an EPEC strain containing a non-polar mutation in the bfpF gene and, as a consequence, unable to retract its BFP. LacNAc-BSA also effectively inhibited LA of the bfpF mutant EPEC. Taken together, these observations suggest that, as well as triggering BfpF-mediated BFP retraction, LacNAc-BSA likely functions as a competitive inhibitor of EPEC binding to LacNAc-related receptors on host cells. Moreover, transmission electron microscopy revealed that LacNAc conjugated to gold nanoparticles bound specifically to BFP. This observation indicated that either the major BFP structural subunit (BfpA) itself or, possibly, an accessory protein co-assembled with BfpA into the BFP filaments, contains a LacNAc-specific EPEC adhesin. The results suggest a mechanism whereby the initial binding of EPEC to LacNAc-like receptors on host cells triggers BfpF-mediated BFP retraction. This could then expedite the intimate adherence phase of the multi-step EPEC colonization process by drawing the organisms closer to the host-cell plasma membrane.

Molecular changes in selected epithelial proteins in human keratoconus corneas compared to normal corneas.

PURPOSE: The purpose of the study was to determine molecular changes in selected epithelial proteins in human keratoconus (KC) corneas compared to normal corneas. METHODS: Two-dimensional (2-D) gel electrophoretic profiles of epithelial cell proteins from normal and keratoconus corneas were compared, and the selected protein spots that showed either up- or downregulation were identified. The desired spots were identified after trypsin digestion and mass spectrometric analysis. Based on the results, two proteins, alpha-enolase and beta-actin, were further analyzed by immunohistochemical and western blot methods, using respective antibodies. To determine the presence of mRNA of the two proteins in the epithelial cells, RT-PCR studies were performed. RESULTS: On comparison of the 2-D gel electrophoretic protein profiles, two protein spots were identified in normal corneas that were either absent or present at lower levels in keratoconus corneas. The two spots were determined to be alpha-enolase (48 kDa) and beta-actin (42 kDa) by matrix-assisted laser desorption ionization-time of flight (MALDI-TOF), and ES-MS/MS mass spectrometric methods. Immunohistochemical analysis revealed that alpha-enolase and beta-actin were present at extremely low levels in the epithelial superficial and wing cells of the keratoconus corneas compared to these cells of normal corneas. 2-D gel electrophoresis followed by western blot analysis revealed relatively greater degradation of the two proteins in the keratoconus corneas compared to normal corneas. RT-PCR analysis showed the mRNA expression of the two proteins in the epithelial cells of both normal and keratoconus corneas. CONCLUSIONS: The results showed relatively low or negligible levels of alpha-enolase and beta-actin in the wing and superficial epithelial cells of keratoconus corneas compared to normal corneas. This was attributed to relatively greater degradation of the two proteins in keratoconus corneas compared to normal corneas.

Crystallins in water soluble-high molecular weight protein fractions and water insoluble protein fractions in aging and cataractous human lenses.

PURPOSE: The aim of the study was to comparatively analyze crystallin fragments in the water soluble high molecular weight (WS-HMW) and in the water insoluble (WI) protein fractions of human cataractous (with nuclear opacity) and age matched normal lenses to determine the identity of crystallin species that show cataract specific changes such as truncation and post-translational modifications. Because these changes were cataract specific and not aging specific, the results were expected to provide information regarding potential mechanisms of age related cataract development. METHODS: The WS-alpha-crystallin, WS-HMW protein, and WI protein fractions were isolated from normal lenses of different ages and from cataractous lenses. The three fractions were subjected to two dimensional (2D) gel electrophoresis (IEF in the first dimension and SDS-PAGE in the second dimension). Individual spots from 2D gels were trypsin digested and the tryptic fragments were analyzed by matrix-assisted laser desorption ionization-time of flight (MALDI-TOF) mass spectrometry. RESULTS: The 2D protein profiles of WS-alpha-crystallin fractions of normal human lenses showed an age related increase in the number of crystallin fragments. In young normal lenses, the WS-alpha-crystallin fragments were mostly C-terminally truncated, but in older lenses these were both N- and C-terminally truncated. The WS-HMW protein fraction from normal lenses contained mainly fragments of alphaA- and alphaB-crystallin, whereas additional fragments of betaB1- and betaA3-crystallin were present in this fraction from cataractous lenses. Similarly, the WI proteins in normal lenses contained fragments of alphaA- and alphaB-crystallin, but cataractous lenses contained additional fragments of betaA3- and betaB1-crystallin. The modifications identified in the WS-HMW and WI crystallin species of cataractous lenses were truncation, oxidation of Trp residues, and deamidation of Asn to Asp residues. CONCLUSIONS: The results show that the components of WS-HMW and WI protein fractions of cataractous lenses differed from normal lenses. Selective insolubilization of fragments of betaA3/A1- and betaB1-crystallin occurred during cataract development compared to normal lenses. Further, the crystallin species of cataractous lenses showed increased truncation, deamidation of Asn to Asp residues, and oxidation of Trp residue.

Deamidation affects structural and functional properties of human alphaA-crystallin and its oligomerization with alphaB-crystallin.

To determine the effects of deamidation on structural and functional properties of alphaA-crystallin, three mutants (N101D, N123D, and N101D/N123D) were generated. Deamidated alphaB-crystallin mutants (N78D, N146D, and N78D/N146D), characterized in a previous study (Gupta, R., and Srivastava, O. P. (2004) Invest. Ophthalmol. Vis. Sci. 45, 206-214) were also used. The biophysical and chaperone properties were determined in (a) homoaggregates of alphaA mutants (N101D, N123D, and N101D/N123D) and (b) reconstituted heteroaggregates of alpha-crystallin containing (i) wild type alphaA (WT-alphaA): WT-alphaB crystallins, (ii) individual alphaA-deamidated mutants:WT-alphaB crystallins, and (iii) WT-alphaA:individual alphaB-deamidated mutant crystallins. Compared with the WT-alphaA, the three alphaA-deamidated mutants showed reduced levels of chaperone activity, alterations in secondary and tertiary structures, and larger aggregates. These altered properties were relatively more pronounced in the mutant N101D compared with the mutant N123D. Further, compared with heteroaggregates of WT-alphaA and WT-alphaB, the heteroaggregates containing deamidated subunits of either alphaA- or alphaB-crystallins and their counterpart WT proteins showed higher molecular mass, altered tertiary structures, lower exposed hydrophobic surfaces, and reduced chaperone activity. However, the heteroaggregate containing WT-alphaA and deamidated alphaB subunit showed lower chaperone activity, smaller oligomers, and 3-fold lower subunit exchange rate than heteroaggregate containing deamidated alphaA- and WT-alphaB subunits. Together, the results suggested that (a) both Asn residues (Asn-101 and Asn-123) are required for the structural integrity and chaperone function of alphaA-crystallin and (b) the presence of WT-alphaB in the alpha-crystallin heteroaggregate leads to packing-induced structural changes which influences the oligomerization and modulate chaperone activity.

Characterization of covalent multimers of crystallins in aging human lenses.

The purpose of this study was to characterize covalent multimers with molecular mass of >90 kDa in the water-insoluble (WI) proteins of aging human lenses. The experimental approach was to first separate the multimers (molecular mass >90 kDa) as individual spots by two-dimensional gel electrophoresis and next analyze compositions of each multimers by matrix-assisted laser desorption ionization-time of flight and electrospray ionization-tandem mass spectrometric (ES-MS/MS) methods. The WI proteins from lenses of 25- and 41-year-old subjects showed distinct 5- and 16-multimer spots on two-dimensional gels, respectively, but the spots from 52- and 72-year-old lenses were non-descript and diffused. ES-MS/MS analyses showed two types of covalent multimers in 25- and 41-year-old lenses, i.e. the first type composed of fragments of eight different crystallins (i.e. alphaA, alphaB, betaA3, betaA4, betaB1, betaB2, gammaS, and gammaD), and the second type of alpha-, beta-, and gamma-crystallins (possibly fragments) and two beaded filament proteins (phakinin and filensin). The most commonly identified species in the complexes of 41-year-old lenses were: alphaA-fragment (C-terminally truncated, residues 1-157), alphaB-fragment (residues 83-90), betaB1-crystallin (residues 60-71), betaA3 (residues 33-44), betaA4 (residues 106-117), filensin (residues 78-90), and phakinin (residues 77-89). Three post-translational modifications (i.e. oxidation of Met and Trp, conversion of Ser to dehydroalanine, and formylation of His) were observed in alphaA-crystallin fragment, and the first two modifications could cross-link proteins. Together, the results suggested that covalent multimers appeared early in life (i.e. 25 years of age) and increased in number with aging, and the two beaded filament proteins form covalent complexes with crystallin fragments in vivo.

Effect of deamidation of asparagine 146 on functional and structural properties of human lens alphaB-crystallin.

PURPOSE: To elucidate the effect of deamidation on the structural and functional properties of human alphaB-crystallin. METHODS: Site-directed mutagenesis was used to generate three deamidated mutants of alphaB-crystallin: N78D, N146D, and N78D/N146D. The mutations were confirmed by DNA sequencing and matrix-assisted desorption ionization-time of flight (MALDI-TOF) mass spectrometry. Recombinant native alphaB-crystallin (wild type [WT]) and the three mutated alphaB species were expressed, and each species was purified to homogeneity by ion-exchange chromatography followed by hydrophobic interaction chromatography. The structural and functional properties compared with WT protein were investigated, respectively, by static light scattering (SLS), circular dichroism (CD), and fluorescence spectroscopy and by determining chaperone activity with the use of three substrates. RESULTS: Native WT and the N78D mutant showed relatively higher chaperone activity compared with the N146D and N78D/N146D mutants with all the substrates. Further, during binding experiments with 1-anilino-8-naphthalenesulfonate (ANS), the WT and N78D mutant showed relatively more solvent-exposed hydrophobic residues than the N146D and N78D/N146D mutants. On determining far-UV circular dichroism and tryptophan (Trp) fluorescence spectra, significant secondary and tertiary structural changes were observed in the N146D and N78D/N146D mutants compared with WT and the N78D mutant. The static light scattering data showed a high order of oligomerization in all the three mutants. N146D and N78D/N146D formed the largest oligomers of 750 and 770 kDa, respectively, compared with WT (580 kDa). CONCLUSIONS: The results show that the deamidation of N146 but not of N78 have profound effects on the structural and functional properties of alphaB-crystallin.

Crosslinking of human lens 9 kDa gammaD-crystallin fragment in vitro and in vivo.

PURPOSE: [corrected] The aims of this study were to determine in vitro crosslinking of a 9 kDa gammaD-crystallin fragment alone and with alpha-, beta-, or gamma-crystallins, the existence of covalent multimers of the polypeptide in vivo, and posttranslational modifications in the three isoforms of the polypeptide. METHODS: A mixture of crystallin fragments (3-14 kDa), a 9 kDa gammaD-crystallin polypeptide or the polypeptide and individual alpha-, beta-, or gamma-crystallins, were incubated at 37 degrees C for a desired length of time and the crosslinked species were analyzed by sodium dodecylsulfate-polyacrylamide gel electrophoresis (SDS-PAGE), size exclusion Agarose A 1.5 gel chromatography, and western blot analysis. In addition, the existence of covalent multimers of the 9 kDa polypeptide in human lens water soluble (WS) and water insoluble (WI) protein fractions of normal and cataractous human lenses was determined by western blot analyses. The posttranslationally modified amino acids of three isofroms of the polypeptide were identified by matrix assisted laser desorption ionization-time of flight (MALDI-TOF) and ES-MS/MS mass spectrometric analyses. RESULTS: Following incubation of a mixture of the crystallin fragments or the 9 kDa polypeptide, covalently crosslinked species held via non-disulfide bonding were seen on SDS-PAGE analysis. The polypeptide also exhibited crosslinking with individual alpha-, beta-, and gamma-crystallins. After western blot analysis with site specific anti-9 kDa antibodies, both WS and WI protein fractions from normal and cataractous lenses showed immunoreactive 27 and 45 kDa multimers. The mass spectrometric analysis of the three isoforms of the polypeptide (with identical molecular weight but different charges) showed oxidized methionine and tryptophan residues, with the latter residue containing two oxygens. CONCLUSIONS: The data suggest that a 9 kDa gammaD-crystallin fragment demonstrated crosslinking properties, which might be due to oxidation of its methionine and tryptophan residues.

Existence of deamidated alphaB-crystallin fragments in normal and cataractous human lenses.

PURPOSE: The aims of this study were to characterize lens crystallin fragments having a molecular mass of <10 kDa, isolated by solubilization in trichloroacetic acid, in order to identify cleavage sites in the parent crystallins for their origin and determine post-translational modifications in the fragments. METHODS: The water-soluble (WS) and water-insoluble (WI) protein fractions were isolated from normal human lenses of 60 to 80 year old donors and from age-matched cataractous lenses. Both WS and WI protein fractions were treated with TCA at 60 degrees C for 2 h and the TCA-soluble fractions were recovered following centrifugation. The preparations were dialyzed against H2O to remove TCA, concentrated by lyophilization and subjected to two dimensional gel electrophoresis (2D-GE). The spots from 2D-gels were analyzed by western blot analysis, partial N-terminal sequencing, or excised for mass spectrometric analysis. RESULTS: SDS-PAGE analysis showed that TCA solubilized polypeptides having a molecular mass of <10 kDa from both WS and WI protein fractions of normal and cataractous lenses. Following 2D-GE of TCA-solubilized species from normal lenses, 8 and 5 polypeptides from the WS and WI protein fractions, respectively, were observed. Using similar 2D-GE analysis of TCA solubilized species from cataractous lenses, 9 and 5 polypeptides from WS and WI protein fractions, respectively, were seen. Partial N-terminal sequence analysis showed that the majority of the polypeptides from both WS and WI protein fractions of normal and cataractous lenses were derived from alphaB-crystallin following cleavage at the D129-P130 bond. Western blot and partial N-terminal sequence analyses identified three additional 4-kDa alphaA-crystallin fragments with cleavage at the D136-G137 bond in the WS proteins from normal lenses. MALDI-TOF mass spectrometric analysis showed that all TCA soluble polypeptides from cataractous lenses, except one from normal lenses, contained residue number 130 to 175 from alphaB-crystallin. No further truncation occurred at the C-terminal region of the alphaB-crystallin polypeptides. Following comparison of the isotopic distribution in MALDI-TOF profiles of a tryptic fragment having a mass of 2,014 among the alphaB-crystallin polypeptides, a gain of one single Dalton was observed. This suggested deamidation of the N146 residue in alphaB-crystallin fragments. CONCLUSIONS: The results show that the N146 residue in human alphaB-crystallin undergoes in vivo deamidation and several fragments containing this modification exist in both WS and WI protein fractions of normal and cataractous human lenses.