High-resolution X-ray Crystal Structures of Human γD Crystallin (1.25 Å) and the R58H Mutant (1.15 Å) Associated with Aculeiform Cataract

Several human cataracts have been linked to mutations in the γ crystallin gene. One of these is the aculeiform cataract, which is caused by an R58H mutation in γD crystallin. We have shown previously that this cataract is caused by crystallization of the mutant protein, which is an order of magnitud...

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Bibliographic Details
Published in:Journal of molecular biology 2003-05, Vol.328 (5), p.1137-1147
Main Authors: Basak, Ajit, Bateman, Orval, Slingsby, Christine, Pande, Ajay, Asherie, Neer, Ogun, Olutayo, Benedek, George B., Pande, Jayanti
Format: Article
Language:English
Subjects:
crystal cataract
crystallin
eye lens
ion-pairs
protein solubility
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Summary:Several human cataracts have been linked to mutations in the γ crystallin gene. One of these is the aculeiform cataract, which is caused by an R58H mutation in γD crystallin. We have shown previously that this cataract is caused by crystallization of the mutant protein, which is an order of magnitude less soluble than the wild-type. Here, we report the very high-resolution crystal structures of the mutant and wild-type proteins. Both proteins crystallize in the same space group and lattice. Thus, a strict comparison of the protein–protein and protein–water intermolecular interactions in the two crystal lattices is possible. Overall, the differences between the mutant and wild-type structures are small. At position 58, the mutant protein loses the direct ion-pair intermolecular interaction present in the wild-type, due to the differences between histidine and arginine at the atomic level; the interaction in the mutant is mediated by water molecules. Away from the mutation site, the mutant and wild-type lattice structures differ in the identity of side-chains that occupy alternate conformations. Since the interactions in the crystal phase are very similar for the two proteins, we conclude that the reduction in the solubility of the mutant is mainly due to the effect of the R58H mutation in the solution phase. The results presented here are also important as they are the first high-resolution X-ray structures of human γ crystallins.
ISSN:0022-2836
1089-8638
DOI:10.1016/S0022-2836(03)00375-9