Deamidation is a major age-related modification in the human lens that is highly prevalent in crystallins isolated from the insoluble fraction of cataractous lenses and also causes protein aggregation in vitro. However, the mechanism by which deamidation causes proteins to become insoluble is not known because only subtle structural changes were observed in vitro. We have identified Asn14 and Asn76 of γS-crystallin as highly deamidated in insoluble proteins isolated from aged lenses. These sites are on the surface of the N-terminal domain and were mimicked by replacing the Asn with Asp residues in order to generate recombinant human γS and deamidated mutants. Both N14D and N76D had increased light scattering compared to wild-type γS (WT) and increased aggregation during thermal-induced denaturation. Aggregation was enhanced by oxidized glutathione, suggesting deamidation may increase susceptibility to form disulfide bonds. These changes were correlated to changes in protein dynamics determined by NMR spectroscopy. Heteronuclear NMR spectroscopy was used to measure amide hydrogen exchange and 15N relaxation dynamics to identify regions with increased dynamics compared to γS WT. Residue-specific changes in solvent accessibility and dynamics were both near and distant from the sites of deamidation, suggesting that deamidation had both local and global effects on the protein structure at slow (ms to s) and fast (μs to ps) time scales. Thus, a potential mechanism for γS deamidation-induced insolubilization in cataractous lenses is altered dynamics due to local regions of unfolding and increased flexibility in both the N- and C-terminal domains particularly at surface helices. This conformational flexibility increases the likelihood of aggregation, which would be enhanced in the oxidizing cytoplasm of the aged and cataractous lens. The NMR data combined with the in vivo insolubility and in vitro aggregation findings support a model that deamidation drives changes in protein dynamics that facilitate protein aggregation associated with cataracts.
Age‐related lens cataract is the major cause of blindness worldwide. The mechanisms whereby crystallins, the predominant lens proteins, assemble into large aggregates that scatter light within the lens, and cause cataract, are poorly understood. Due to the lack of protein turnover in the lens, crystallins are long‐lived. A major crystallin, γS, is heavily modified by deamidation, in particular at surface‐exposed N14, N76, and N143 to introduce negative charges. In this present study, deamidated γS was mimicked by mutation with aspartate at these sites and the effect on biophysical properties of γS was assessed via dynamic light scattering, chemical and thermal denaturation, hydrogen‐deuterium exchange, and susceptibility to disulfide cross‐linking. Compared with wild type γS, a small population of each deamidated mutant aggregated rapidly into large, light‐scattering species that contributed significantly to the total scattering. Under partially denaturing conditions in guanidine hydrochloride or elevated temperature, deamidation led to more rapid unfolding and aggregation and increased susceptibility to oxidation. The triple mutant was further destabilized, suggesting that the effects of deamidation were cumulative. Molecular dynamics simulations predicted that deamidation augments the conformational dynamics of γS. We suggest that these perturbations disrupt the native disulfide arrangement of γS and promote the formation of disulfide‐linked aggregates. The lens‐specific chaperone αA‐crystallin was poor at preventing the aggregation of the triple mutant. It is concluded that surface deamidations cause minimal structural disruption individually, but cumulatively they progressively destabilize γS‐crystallin leading to unfolding and aggregation, as occurs in aged and cataractous lenses.
Age-related cataract is a major cause of blindness worldwide. Yet, the molecular mechanisms whereby large, light scattering aggregates form is poorly understood, because of the complexity of the aggregates isolated from human lenses. The predominant proteins in the lens are structural proteins called crystallins. The γS-crystallin is heavily modified in cataractous lenses by deamidation, which introduces a negative charge at labile asparagine residues. The effects of deamidation at asparagines, N14, N76, and N143, were mimicked by replacing the asparagine with aspartate using site-directed mutagenesis. The effects of these surface deamidations on the stability, unfolding, and aggregation properties of γS were determined using dynamic light scattering, chemical and thermal-denaturation, and hydrogen-deuterium exchange with mass spectrometry. We found that a small population of all the deamidation mimics aggregated directly into large light scattering bodies with a radius greater than 10 nm that contributed 14-60% of the total scattering intensity compared to 7% for WT under the same conditions. A possible mechanism was identified under partially denaturing conditions, where deamidation led to significantly more rapid unfolding and aggregation particularly for N76D compared to WT. The triple mutant was further destabilized, reflecting the enhanced aggregation properties of N14D and N143D. Thus, the effects of deamidation were both site-specific and cumulative. αA-crystallin was ineffective at acting as a chaperone to prevent the aggregation of destabilized, deamidated γS. It is concluded that surface deamidations, while causing minimal structural disruption individually, progressively destabilize crystallin proteins, leading to their unfolding and precipitation in aged and cataractous lenses. Abbreviations List:Tris(2-carboxyethyl)phosphine hydrochloride (TCEP), dithiothreitol (DTT), sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), guanidine hydrochloride (GuHCl), Dynamic, static, and multi-angle light scattering (DLS, SLS, and MALS), hydrogen deuterium exchange (H/D), mass spectrometry (MS), wild type (WT), triple mutant (TM), N-terminal domain (N-td), C-terminal domain (C-td). IntroductionIn mammals, the eye lens plays a crucial role in vision via transmitting, refracting and focusing light onto the retina. Lens functionality is maintained via a high concentration of crystallin proteins (up to 300-500 mg/mL in the center of the lens) that are arranged in a supramolecular array with short-range order (1). The lens is a unique organ in that it has no blood supply and there is no protein turnover in its fiber cells because they lack the organelles for protein synthesis and degradation. As a result, crystallins are long-lived proteins (2).Cataract arises from opacification and concomitant light scattering associated with the unfolding, aggregation and precipitation of crystallins. Cataract is the major cause of blindness in the world and is the leading cause of low vision in the United States (3)...
Deamidation is a major age-related modification in the human lens that is highly prevalent in crystallins isolated from cataractous lenses. However, the mechanism by which deamidation causes proteins to become insoluble is not known, because of only subtle structural changes observed in vitro. We have identified Asn14 and Asn76 of gS-crystallin as highly deamidated in insoluble proteins. These sites are on the surface of the N-terminal domain and were mimicked by replacing the Asn with Asp residues. We used heteronuclear NMR spectroscopy to measure their amide hydrogen exchange and 15 N relaxation dynamics to identify regions with significantly increased dynamics compared to wildtype-gS. Changes in dynamics were localized to the Cterminal domain, particularly to helix and surface loops distant from the mutation sites. Thus, a potential mechanism for gS deamidation-induced insolubilization in cataractous lenses is altered dynamics due to local regions of unfolding and increased flexibility.
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