BACKGROUND: Lens cataract is associated with protein oxidation and aggregation. Two proteins that cause cataract when deleted from the lens are methionine sulfoxide reductase A (MsrA) that repairs protein methionine sulfoxide (PMSO) oxidized proteins and alpha-crystallin which is a two-subunit (alphaA and alphaB) chaperone. Here, we tested whether PMSO formation damages alpha-crystallin chaperone function and whether MsrA could repair PMSO-alpha-crystallin. METHODS: Total alpha-crystallin was oxidized to PMSO and evaluated by CNBr-cleavage and mass spectrometry. Chaperone activity was measured by light scattering using lysozyme as target. PMSO-alpha-crystallin was treated with MsrA, and repair was assessed by CNBr cleavage, mass spectrometry and recovery of chaperone function. The levels of alpha-crystallin-PMSO in the lenses of MsrA-knockout relative to wild-type mice were determined. RESULTS: PMSO oxidation of total alpha-crystallin (met 138 of alphaA and met 68 of alphaB) resulted in loss of alpha-crystallin chaperone activity. MsrA treatment of PMSO-alpha-crystallin repaired its chaperone activity through reduction of PMSO. Deletion of MsrA in mice resulted in increased levels of PMSO-alpha-crystallin. CONCLUSIONS: Methionine oxidation damages alpha-crystallin chaperone function and MsrA can repair PMSO-alpha-crystallin restoring its chaperone function. MsrA is required for maintaining the reduced state of alpha-crystallin methionines in the lens. SIGNIFICANCE: Methionine oxidation of alpha-crystallin in combination with loss of MsrA repair causes loss of alpha-crystallin chaperone function. Since increased PMSO levels and loss of alpha-crystallin function are hallmarks of cataract, these results provide insight into the mechanisms of cataract development and likely those of other age-related diseases.
BACKGROUND:Lens cataract is associated with protein oxidation and aggregation. Two proteins that cause cataract when deleted from the lens are methionine sulfoxide reductase A (MsrA) that repairs protein methionine sulfoxide (PMSO) oxidized proteins and alpha-crystallin which is a two-subunit (alphaA and alphaB) chaperone. Here, we tested whether PMSO formation damages alpha-crystallin chaperone function and whether MsrA could repair PMSO-alpha-crystallin. METHODS: Total alpha-crystallin was oxidized to PMSO and evaluated by CNBr-cleavage and mass spectrometry. Chaperone activity was measured by light scattering using lysozyme as target. PMSO-alpha-crystallin was treated with MsrA, and repair was assessed by CNBr cleavage, mass spectrometry and recovery of chaperone function. The levels of alpha-crystallin-PMSO in the lenses of MsrA-knockout relative to wild-type mice were determined. RESULTS:PMSO oxidation of total alpha-crystallin (met 138 of alphaA and met 68 of alphaB) resulted in loss of alpha-crystallin chaperone activity. MsrA treatment of PMSO-alpha-crystallin repaired its chaperone activity through reduction of PMSO. Deletion of MsrA in mice resulted in increased levels of PMSO-alpha-crystallin. CONCLUSIONS:Methionine oxidation damages alpha-crystallin chaperone function and MsrA can repair PMSO-alpha-crystallin restoring its chaperone function. MsrA is required for maintaining the reduced state of alpha-crystallinmethionines in the lens. SIGNIFICANCE: Methionine oxidation of alpha-crystallin in combination with loss of MsrA repair causes loss of alpha-crystallin chaperone function. Since increased PMSO levels and loss of alpha-crystallin function are hallmarks of cataract, these results provide insight into the mechanisms of cataract development and likely those of other age-related diseases.
Authors: Marc Kantorow; John R Hawse; Tracy L Cowell; Sonia Benhamed; Gresin O Pizarro; Venkat N Reddy; J F Hejtmancik Journal: Proc Natl Acad Sci U S A Date: 2004-06-15 Impact factor: 11.205
Authors: Rebecca S McGreal; Lisa A Brennan; Wanda Lee Kantorow; Jeffrey D Wilcox; Jianning Wei; Daniel Chauss; Marc Kantorow Journal: Exp Eye Res Date: 2013-03-04 Impact factor: 3.467