Degradation of gamma D- and gamma s-crystallins in human lenses

Protection of human γD-crystallin protein from ultraviolet C-induced aggregation by ortho-vanillin

Cataract is known as one of the leading causes of vision impairment worldwide. While the detailed mechanism of cataratogenesis remains unclear, cataract is believed to be correlated with the aggregation and/or misfolding of human ocular lens proteins called crystallins. A 173-residue structural protein human γD-crystallin is a major γ-crystallin protein in the human eye lens and associated with the development of juvenile and mature-onset cataracts. This work is aimed at investigating the effect of a small molecule, e.g., ortho-vanillin, on human γD-crystallin aggregation upon exposure to ultraviolet-C irradiation. According to the findings of right-angle light scattering, transmission electron microscopy, and gel electrophoresis, ortho-vanillin was demonstrated to dose-dependently suppress ultraviolet-C-triggered aggregation of human γD-crystallin. Results from the synchronous fluorescence spectroscopy, tryptophan fluorescence quenching, and molecular docking studies revealed the structural change of γD-crystallin induced by the interaction/binding between ortho-vanillin and protein. We believe the outcome from this work may contribute to the development of potential therapeutics for cataract.

Increased Association of Deamidated αA-N101D with Lens membrane of transgenic αAN101D vs. wild type αA mice: potential effects on intracellular ionic imbalance and membrane disorganization

We have generated two mouse models, in one by inserting the human lens αAN101D transgene in CRYαAN101D mice, and in the other by inserting human wild-type αA-transgene in CRYαAWT mice. The CRYαAN101D mice developed cortical cataract at about 7-months of age relative to CRYαAWT mice. The objective of the study was to determine the following relative changes in the lenses of CRYαAN101D- vs. CRYαAWT mice: age-related changes with specific emphasis on protein insolubilization, relative membrane-association of αAN101D vs. WTαA proteins, and changes in intracellular ionic imbalance and membrane organization.

METHODS

Lenses of varying ages from CRYαAWT and CRYαAN101D mice were compared for an age-related protein insolubilization. The relative lens membrane-association of the αAN101D- and WTαA proteins in the two types of mice was determined by immunohistochemical-, immunogold-labeling-, and western blot analyses. The relative levels of membrane-binding of recombinant αAN101D- and WTαA proteins was determined by an in vitro assay, and the levels of intracellular Ca2+ uptake and Na, K-ATPase mRNA were determined in the cultured epithelial cells from lenses of the two types of mice.

RESULTS

Compared to the lenses of CRYαAWT, the lenses of CRYαAN101D mice exhibited: (A) An increase in age-related protein insolubilization beginning at about 4-months of age. (B) A greater lens membrane-association of αAN101D- relative to WTαA protein during immunogold-labeling- and western blot analyses, including relatively a greater membrane swelling in the CRYαAN101D lenses. (C) During in vitro assay, the greater levels of binding αAN101D- relative to WTαA protein to membranes was observed. (D) The 75% lower level of Na, K-ATPase mRNA but 1.5X greater Ca2+ uptake were observed in cultured lens epithelial cells of CRYαAN101D- than those of CRYαAWT mice.

CONCLUSIONS

The results show that an increased lens membrane association of αAN101D--relative WTαA protein in CRYαAN101D mice than CRYαAWT mice occurs, which causes intracellular ionic imbalance, and in turn, membrane swelling that potentially leads to cortical opacity.

Kinetic Stability of Long-Lived Human Lens γ-Crystallins and Their Isolated Double Greek Key Domains

The γ-crystallins of the eye lens nucleus are among the longest-lived proteins in the human body. Synthesized in utero, they must remain folded and soluble throughout adulthood to maintain lens transparency and avoid cataracts. γD- and γS-crystallin are two major monomeric crystallins of the human lens. γD-crystallin is concentrated in the oldest lens fiber cells, the lens nucleus, whereas γS-crystallin is concentrated in the younger cells of the lens cortex. The kinetic stability parameters of these two-domain proteins and their isolated domains were determined and compared. Kinetic unfolding experiments monitored by fluorescence spectroscopy in varying concentrations of guanidinium chloride were used to extrapolate unfolding rate constants and half-lives of the crystallins in the absence of the denaturant. Consistent with their long lifespans in the lens, extrapolated half-lives for the initial unfolding step were on the timescale of years. Both proteins' isolated N-terminal domains were less kinetically stable than their respective C-terminal domains at denaturant concentrations predicted to disrupt the domain interface, but at low denaturant concentrations, the relative kinetic stabilities were reversed. Cataract-associated aggregation has been shown to proceed from partially unfolded intermediates in these proteins; their extreme kinetic stability likely evolved to protect the lens from the initiation of aggregation reactions. Our findings indicate that the domain interface is the source of significant kinetic stability. The gene duplication and fusion event that produced the modern two-domain architecture of vertebrate lens crystallins may be the origin of their high kinetic as well as thermodynamic stability.

New functions of an old kinase MPK4 in guard cells

Mitogen-activated protein kinase (MPK) cascades play important roles in plant development, immune signaling and stress responses. MPK4 was initially identified as a negative regulator in systemic acquired resistance (SAR) because the levels of salicylic acid (SA) and reactive oxygen species (ROS) were higher in the Arabidopsis mpk4 mutant. MPK4 is highly expressed in guard cells, specialized epidermal cells forming stomatal pores on leaf surface that function at the frontline of bacterial pathogen invasion. In addition to biotic stresses, stomatal guard cells also mediate cellular responses to abiotic stimuli such as drought and CO₂ changes. MPK4 appears to play different roles in different plant systems. In this review, we briefly discuss the protein kinase MPK4 functions and focus on its signaling roles in different plant systems, especially in stomatal guard cells.

Degradation of an old human protein: age-dependent cleavage of γS-crystallin generates a peptide that binds to cell membranes

Long-lived proteins exist in a number of tissues in the human body; however, little is known about the reactions involved in their degradation over time. Lens proteins, which do not turn over, provide a useful system to examine such processes. Using a combination of Western blotting and proteomic methodology, age-related changes to a major protein, γS-crystallin, were studied. By teenage years, insoluble intact γS-crystallin was detected, indicative of protein denaturation. This was not the only change, however, because blots revealed evidence of significant cross-linking as well as cleavage of γS-crystallin in all adult lenses. Cleavage at a serine residue near the C terminus was a major reaction that caused the release of a 12-residue peptide, SPAVQSFRRIVE, which bound tightly to lens cell membranes. Several other crystallin-derived peptides with double basic residues also lodged in the cell membrane fraction. Model studies showed that once cleaved from γS-crystallin, SPAVQSFRRIVE adopts a markedly different shape from that in the intact protein. Further, the acquired helical conformation may explain why the peptide seems to affect water permeability. This observation may help explain the changes to cell membranes known to be associated with aging in human lenses. Age-related cleavage of long-lived proteins may therefore yield peptides with untoward biological activity.

Racemization of two proteins over our lifespan: deamidation of asparagine 76 in γS crystallin is greater in cataract than in normal lenses across the age range

PURPOSE

Long-lived proteins are widespread in man, yet little is known about the processes that affect their function over time, or their role in age-related diseases.

METHODS

Racemization of two proteins from normal and cataract human lenses were compared with age using tryptic digestion and LC/mass spectrometry. Asp 151 in αA crystallin and Asn 76 in γS crystallin were studied.

RESULTS

Age-dependent profiles for the two proteins from normal lenses were different. In neither protein did the modifications increase linearly with age. For αA crystallin, racemization occurred most rapidly during the first 15 years of life, with approximately half of L-Asp 151 converted to D-isoAsp, L-isoAsp, and D-Asp in a ratio of 3:1:0.5. Values then changed little. By contrast, racemization of Asn 76 in γS crystallin was slow until age 15, with isoAsp accounting for only 5%. Values remained relatively constant until age 40 when a linear increase (1%/year) took place. When cataract lenses were compared with age-matched normal lenses, there were marked differences in the time courses of the two crystallins. For αA crystallin, there was no significant difference in Asp 151 racemization between cataract and normal lenses. By contrast, in γS crystallin the degree of conversion of Asn 76 to isoAsp in cataract lenses was approximately double that of normals at every age.

CONCLUSIONS

Modification of Asn and Asp over time may contribute to denaturation of proteins in the human lens. An accelerated rate of deamidation/racemization at selected sites in proteins, such as γS crystallin, may contribute to cataract formation.

Age-dependent deamidation of glutamine residues in human γS crystallin: deamidation and unstructured regions

Human aging is associated with the deterioration of long-lived proteins. Gradual cumulative modifications to the life-long proteins of the lens may ultimately be responsible for the pronounced alterations to the optical and physical properties that characterize lenses from older people. γS crystallin, a major human lens protein, is known to undergo several age-dependent changes. Using proteomic techniques, a site of deamidation involving glutamine 92 has been characterized and its time course established. The proportion of deamidation increased from birth to teen-age years and then plateaud. Deamidation at this site increased again in the eighth decade of life. There was no significant difference in the extent of deamidation between cataract and age-matched normal lenses. Gln92 is located in the linker region between the two domains, and the introduction of a negative charge at this site may alter the interaction between the two regions of the protein. Gln170, which is located in another unstructured part of γS crystallin, showed a similar deamidation profile to that of Gln92. As the other Gln residues in β-sheet regions of γS crystallin appear to remain as amides, modification of Gln92 and Gln170 thus conforms to a pattern whereby deamidation is localized to the unstructured regions of long-lived proteins.

Age-related cataracts in alpha3Cx46-knockout mice are dependent on a calpain 3 isoform

PURPOSE

Previous studies have demonstrated that in 129alpha3Cx46-/- mice, age-related nuclear cataract is formed. In the present study, a more in vivo-relevant model was generated to test the hypothesis that the calpain 3 gene is involved in age-related nuclear cataractogenesis in alpha3Cx46 knockout mice.

METHODS

To test the hypothesis that the calpain 3 gene is involved in age-related nuclear cataractogenesis in alpha3Cx46 knockout mice, 129alpha3Cx46-/- and CAPN3-/- mice were mated to generate homozygous double-knockout (dKO) mice. Lenses from the mice were examined by visual observation, laser scan analysis, and histologic and biochemical methods.

RESULTS

In the absence of the CAPN3 gene, the formation of a cataract was delayed, and its appearance was changed to a more diffuse, pulverulent type. Unlike in the 129alpha3Cx46-/- mouse, cleavage of gamma-crystallin was not detected in the dKO mouse. In both 129alpha3Cx46-/- and dKO mice, total Ca2+ increased.

CONCLUSIONS

The present study shows for the first time that calpain 3 is necessary for the formation of age-dependent nuclear cataracts in alpha3Cx46-/- mice. Evidence that the calpain 3 gene is directly involved in, or part of the pathway that leads to, gamma-crystallin cleavage is presented. These results are consistent with the hypothesis that the loss of alpha3Cx46 leads to increased levels of Ca2+ ions, and this increase activates the CAPN3 isoform, Lp82/85, which results in the formation of a nuclear cataract.

Eye lens proteomics

The eye lens is a fascinating organ as it is in essence living transparent matter. Lenticular transparency is achieved through the peculiarities of lens morphology, a semi-apoptotic process where cells elongate and loose their organelles and the precise molecular arrangement of the bulk of soluble lenticular proteins, the crystallins. The 16 crystallins ubiquitous in mammals and their modifications have been extensively characterized by 2-DE, liquid chromatography, mass spectrometry and other protein analysis techniques. The various solubility dependant fractions as well as subproteomes of lenticular morphological sections have also been explored in detail. Extensive post translational modification of the crystallins is encountered throughout the lens as a result of ageing and disease resulting in a vast number of protein species. Proteomics methodology is therefore ideal to further comprehensive understanding of this organ and the factors involved in cataractogenesis.

BetaB2-crystallin undergoes extensive truncation during aging in human lenses

Based on the present literature, it is unclear whether betaB2-crystallin undergoes age-related truncation in human lenses. To answer this question, the purpose of this study was to determine in vivo truncation of betaB2-crystallin in human lenses during aging by examining its fragments in the beta(H)-crystallin fraction. The WS-protein fraction was isolated from lenses of desired ages and separated by a size-exclusion Agarose A 1.5m column to recover alpha-, beta(H)-, beta(L)-, and gamma-crystallin fractions. The beta(H)-crystallin fractions, isolated from lenses of 24- and 70-year-old donors, were utilized for two-dimensional (2D) gel electrophoresis (isoelectric focusing in the first dimension followed by SDS-PAGE in the second dimension). The partial N-terminal sequences of the desired fragments (Molecular weights [M(r)]<18-19kDa) from a 2D-gel of WS-proteins from lenses of a 70-year-old donor were determined. More than 37 crystallin fragments with M(r) between 4 and 19kDa were observed on a 2D-gel. Nine fragments in beta(H)-crystallin fraction were from betaB2-crystallin but additional single fragments of alphaA-, gammas-, betaA4, and of either gammaB-, gammaC- or gammaD-crystallins were also observed. Seven cleavage sites in the betaB2-crystallin were identified, which included two sites at Q(7)-A(8) and A(8)-G(9) bonds in the N-terminal extension, two sites at E(46)-K(47) and G(49)-S(50) bonds in the motif 1, one site at S(94) -S(95) in the motif 2, and two sites at N(115)-F(116) and Q(135)-Y(136) in motif 3. No fragments with cleavage in the motif 4 and C-terminal extension of betaB2-crystallin were seen. Apparently, three betaB2-crystallin fragments with only N-terminal cleavage and five with both N- and C-terminal cleavages were observed. Additional fragments with cleavage sites at Q(54)-Y(55) in alphaA-crystallin, at E(112)-N(113) in betaA4-crystallin, at G(4)-T(5) in gammas-crystallin, at M(69)-G(70) in either gammaB-, gammaC- or gammaD-crystallins (three have identical sequences at the cleaved bond), and at G(1)-K(2) in gammaB or gammaC (both have identical sequences at the cleavage site) were observed.Conclusions. The results showed that betaB2-crystallin undergoes age-related truncation producing fragments with M(r) between 4 and 19kDa that existed in the beta(H)-crystallin oligomer. The beta(H)-crystallin fraction also contained single fragments of alpha-, betaA4-, gammas-, and other gamma-crystallins.

Proteomics in experimental gerontology

The first gerontological studies using two-dimensional gel electrophoresis (2DGE) were frustrating since it was very difficult, when not impossible, to identify the proteins for which an age-related change in expression level was suspected. Reproducibility was also a main pitfall. Accumulated progress in 2DGE and especially the development of mass spectrometry of proteins and peptides gave accessibility to the routine identification of differentially expressed proteins. A new paradigm was born: proteomics. In addition to expression changes, post-translational modifications are included in proteomics, and will be more and more studied using mass spectrometry. After a review of the current developments of 2DGE and mass spectrometry, we shall discuss how the technologies currently available in proteomics could give fresh impetus to experimental gerontology, complementary to more recent approaches based on wide expression analysis tools such as DNA and protein arrays.

Defining a link between gap junction communication, proteolysis, and cataract formation

Disruption of the connexin alpha 3 (Cx46) gene (alpha 3 (-/-)) in mice results in severe cataracts within the nuclear portion of the lens. These cataracts are associated with proteolytic processing of the abundant lens protein gamma-crystallin, leading to its aggregation and subsequent opacification of the lens. The general cysteine protease inhibitor, E-64, blocked cataract formation and gamma-crystallin cleavage in alpha 3 (-/-) lenses. Using a new class of activity-based cysteine protease affinity probes, we identified the calcium-dependent proteases, m-calpain and Lp82, as the primary targets of E-64 in the lens. Profiling changes in protease activities throughout cataractogenesis indicated that Lp82 activity was dramatically increased in alpha 3 (-/-) lenses and correlated both spatially and temporally with cataract formation. Increased Lp82 activity was due to calcium accumulation as a result of increased influx and decreased outflux of calcium ions in alpha 3 (-/-) lenses. These data establish a role for alpha 3 gap junctions in maintaining calcium homeostasis that in turn is required to control activity of the calcium-dependent cysteine protease Lp82, shown here to be a key initiator of the process of cataractogenesis.

Resistance of human betaB2-crystallin to in vivo modification

Post-translational modifications and/or structural changes induced by modifications are likely causes of the decrease in crystallin solubility associated with aging and the development of cataract. Characterization of human lens crystallins by mass spectrometry has demonstrated that betaB2-crystallin undergoes less modification than any of the other crystallins. As the lens ages, betaB2-crystallin retains its hydrophilic N-terminus while the hydrophilic C-termini of alpha-crystallins and large portions of the N-termini of betaA3/A1 and betaB1 are truncated. The hydrophilic terminal regions of crystallins contribute to their solubility. Furthermore, deamidation and disulfide bond formation, other modifications that may affect solubility by altering conformation, are less extensive in betaB2 than in the other crystallins. This resistance to modification results in higher levels of betaB2 compared with the other crystallins in the water-soluble fraction of older lenses. The solubility of betaB2 and its propensity to form non-covalent associations with less soluble beta-crystallins may contribute to the solubility of the other beta-crystallins. A current hypothesis is that the chaperone-like properties of alpha-crystallins contribute to lens crystallin solubility, particularly in younger lenses. In older lenses, where most of the alpha-crystallins have become water-insoluble, betaB2-crystallins may play a dominant role in lens crystallin solubility.

Lop12, a mutation in mouse Crygd causing lens opacity similar to human Coppock cataract

A new cataract mutation was discovered in an ongoing program to identify new mouse models of hereditary eye disease. Lens opacity 12 (Lop12) is a semidominant mutation that results in an irregular nuclear lens opacity similar to the human Coppock cataract. Lop12 is associated with a small nonrecombining segment that maps to mouse Chromosome 1 close to the eye lens obsolescence mutation (Cryge(Cat2-Elo)), a member of the gamma-crystallin gene cluster (Cryg). Using a systemic candidate gene approach to analyze the entire Cryg cluster, a G to A transition was found in exon 3 of Crygd associated with the Lop12 mutation and has been designated Crygd(Lop12). The mutation Crygd(Lop12) leads to the formation of an in-frame stop codon that produces a truncated protein of 156 amino acids. It is predicted that the defective gene product alters protein folding of the gamma-crystallin(s) and results in lens opacity.

Age-related degradation of betaA3/A1-crystallin in human lenses

The aim of this study was to determine age-related degradation of betaA3/A1-crystallin in human lenses. The betaA3/A1-crystallin fragments were identified by Western blot analysis using two site-specific anti-betaA3/A1-crystallin antibodies. The first antibody was raised against a N-terminal region (residues 35-66), and the second to the C-terminal (residues 203-214) region of the crystallin. During the analyses, either preparative SDS-PAGE-separated fragments from betaH-crystallin fraction or water-soluble (WS) protein fractions from lenses of different aged donors were used. In lenses from 27- to 30-year-old donors, four major crystallin fragments of about 5, 16, 17, and 18 kDa immunoreacted with the anti-betaA3/A1-N-terminal antibody, suggesting their intact N-terminus but cleaved C-terminus. A similar analysis with the anti-betaA3/A1-C-terminal antibody identified 15-, 18-, 19-, and 20-kDa species and also five species between 4 and 11 kDa that had intact C-terminus but cleaved N-terminus. In lenses from a 5-year-old donor only two crystallin species, a major 15-kDa and a minor 18-kDa species, showed an intact N-terminus and cleaved C-terminus, whereas, eight species with Mr's between 4 and 19 kDa exhibited intact C-terminus but cleaved N-terminus. Upon two-dimensional gel electrophoresis of a betaH-crystallin fraction from the lenses of a 70-year-old donor, a degradation profile almost similar to the crystallin mentioned above was observed. However, the existence of multiple spots with identical Mr's of truncated betaA3/A1-crystallin species on the 2D-gel suggests their existence as isoforms (identical size species with different charges) because of post-translational modifications. Five species of 4, 6, 11, 15, and 18 kDa showed an identical partial N-terminal sequence of N-F-Q-G, suggesting cleavage at the E39-N40 bond during their production. Together, the data suggest that the majority of age-related cleavages in betaA3/A1-crystallin occur at the N-terminal region, with a major cleavage site at the E39-N40 bond generating some of these fragments.