PURPOSE: To investigate the influence of diabetes on the cleavage of C-terminal amino acid residues of alphaA- and alphaB-crystallins in human and rat lenses. METHODS: The human lenses were diabetic or age-matched control lenses from donors 57, 59, 69, and 72 years of age. Lenses were also obtained from streptozotocin-induced diabetic rats. Individual lens crystallins in water-soluble fractions were separated by gel-permeation chromatography. The high (alphaH)- and low (alphaL)-molecular-weight fractions were analyzed by electrospray ionization mass spectrometry. RESULTS: A typical mass spectrum of alphaA-crystallin from human lenses showed intact unmodified alphaA-crystallin, truncated alphaA(1-172), and monophosphorylated alphaA-crystallin. Diabetic lenses showed nearly twofold higher levels of alphaA(1-172) than did the control lenses. Also, the alphaH fraction consistently showed significantly higher levels of alphaA(1-172) than the alphaL fraction. Human alphaB-crystallin showed no evidence of C-terminal truncation. Rat alphaA-crystallin had five C-terminal-truncated components, most of which showed substantial increases in diabetes. Truncated alphaA(1-162) appeared only in the diabetic rat lenses, suggesting specific activation of m-calpain in diabetes. alphaB-crystallin had only one C-terminal-truncated component, alphaB(1-170), which also showed increased levels in diabetes. CONCLUSIONS: These data suggest that diabetic stress causes either enzymatic or nonenzymatic cleavage of peptide bonds between specific C-terminal amino acid residues. Such truncated alpha-crystallins appear to contribute to an increased level of the alphaH fraction generally present in diabetic lenses. Loss of alphaA-crystallin chaperone activity seems to be related to truncation of the C-terminal amino acid residues.
PURPOSE: To investigate the influence of diabetes on the cleavage of C-terminal amino acid residues of alphaA- and alphaB-crystallins in human and rat lenses. METHODS: The human lenses were diabetic or age-matched control lenses from donors 57, 59, 69, and 72 years of age. Lenses were also obtained from streptozotocin-induced diabeticrats. Individual lens crystallins in water-soluble fractions were separated by gel-permeation chromatography. The high (alphaH)- and low (alphaL)-molecular-weight fractions were analyzed by electrospray ionization mass spectrometry. RESULTS: A typical mass spectrum of alphaA-crystallin from human lenses showed intact unmodified alphaA-crystallin, truncated alphaA(1-172), and monophosphorylated alphaA-crystallin. Diabetic lenses showed nearly twofold higher levels of alphaA(1-172) than did the control lenses. Also, the alphaH fraction consistently showed significantly higher levels of alphaA(1-172) than the alphaL fraction. HumanalphaB-crystallin showed no evidence of C-terminal truncation. Rat alphaA-crystallin had five C-terminal-truncated components, most of which showed substantial increases in diabetes. Truncated alphaA(1-162) appeared only in the diabeticrat lenses, suggesting specific activation of m-calpain in diabetes. alphaB-crystallin had only one C-terminal-truncated component, alphaB(1-170), which also showed increased levels in diabetes. CONCLUSIONS: These data suggest that diabetic stress causes either enzymatic or nonenzymatic cleavage of peptide bonds between specific C-terminal amino acid residues. Such truncated alpha-crystallins appear to contribute to an increased level of the alphaH fraction generally present in diabetic lenses. Loss of alphaA-crystallin chaperone activity seems to be related to truncation of the C-terminal amino acid residues.
Authors: Ram H Nagaraj; Rooban B Nahomi; Niklaus H Mueller; Cibin T Raghavan; David A Ammar; J Mark Petrash Journal: Biochim Biophys Acta Date: 2015-04-01
Authors: Mahesha H Gangadhariah; Benlian Wang; Mikhail Linetsky; Christian Henning; Robert Spanneberg; Marcus A Glomb; Ram H Nagaraj Journal: Biochim Biophys Acta Date: 2010-01-18