Three-dimensional models corresponding to the C-terminal domain of human alphaA- and alphaB-crystallins based on the crystal structure of the small heat-shock protein HSP16.9 from wheat.

We propose three-dimensional models corresponding to the C-terminal domain of human alphaA- and alphaB-crystallins by using the comparative modeling program Modeler and the more closely related crystal structure of the small heat-shock protein (sHSP) belonging to the eukaryotic species from wheat HSP16.9 as template structure. The sequence alignments differ slightly from alignments that were used previously to construct alpha-crystallin models based on homology and the crystal structure of the more distantly related small heat-shock protein from archaeal species; Methanococcus jannaschii Mj HSP16.5, the only related structure then available as a template. The alpha-crystallin models based on HSP16.9 show better 3-D profile scores and reflect the relative shifts in the beta-strands corresponding to the beta-sandwich associated with the core C-terminal domain that is common to small heat-shock proteins and the alpha-crystallins. The loop between the equivalent beta5-beta7 strands corresponds to a region of seven amino acid residues deletion in alpha-crystallins and defines the new set of amino acid residues likely to be associated with a dimer interface. The models may be useful to examine sites of mutations that are known to affect chaperone-like activity and provide the structural basis for dimerization in alpha-crystallins.