Arginine 54 and Tyrosine 118 residues of {alpha}A-crystallin are crucial for lens formation and transparency

Abstract

Purpose: To identify new mouse models for studying roles of alphaAlpha-crystallin in vivo and to investigate why and how different mutations of the alphaAlpha-crystallin gene lead to dominant or recessive cataracts.

Methods: Using mouse genetic approaches and slit lamp screening, we identified two mouse cataractous mutant lines. Causative genes were mapped by a genome-wide linkage analysis. DNA sequencing verified missense mutations of alphaA-crystallin gene in both mutant lines. Histology, imaging of green fluorescent protein (GFP)-positive lenses, and protein 2-DE gel were used to determine the morphologic and biochemical properties of mutant lenses.

Results: Two new alphaA-crystallin gene mutations were identified, alphaA-R54C (alphaA-Cys) and alphaA-Y118D, which cause recessive whole cataracts and dominant nuclear cataracts, respectively. In homozygous alphaA-Cys mutant mice, lens epithelial and fiber cells lost their characteristic cellular features and developed disrupted subcellular structures, such as actin filaments and mitochondria. The nuclear cataract caused by alphaA-Y118D mutation was associated with increased water-insoluble crystallins (alpha, beta, and gamma classes). These results suggest that the Arg54 residue in the N-terminal region is crucial for alphaA-crystallin to perform its roles in lens epithelial and fiber cells during development, whereas the Y118D mutation in the central alpha-crystallin domain impairs alphaA-crystallin's ability to maintain the solubility of crystallin proteins in the lens.

Conclusions: This work demonstrates that different regions of alphaA-crystallin mediate distinct functions in vivo. These two mutant mouse lines provide useful animal models for further investigating the multiple roles of alphaA-crystallin in the lens.