Crystallins are small heat shock proteins with chaperone function that prevent heat- and oxidative stress-induced aggregation of proteins. This is the first report describing modifications of alphaA crystallin in the sensory retina, including altered content and truncation with aging. Proteins from adult, middle age, and old Fischer 344 Brown Norway rats were compared. Western immunoblotting was used to evaluate alphaA crystallin content and identify protein spots on two-dimensional gels containing alphaA crystallin. The type and site of multiple post-translational modifications were identified by mass spectrometry. We found the content of alphaA crystallin was significantly decreased in the oldest rats. On two-dimensional gels, retinal crystallins resolved into multiple spots with altered migration, indicative of changes in intrinsic charge and/or truncation. Post-translational modifications that were identified included oxidation, phosphorylation, deamidation, acetylation, and truncation. In samples from rats of all ages, a highly modified N-terminus containing these modifications was found. We also observed an age-dependent difference in the extent of N- and C-terminal truncation. These results suggest that protection against stress-induced protein aggregation is compromised in the aged retina.
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