The use of protein homologues in the rotation function

Modern developments in molecular replacement

Molecular replacement is a possible route to obtaining initial phasing for an unknown structure from a known, structurally related molecule. Recent years have seen an explosive growth in the number of protein structures solved using this technique. Automated packages can make the application quite straightforward. Progress has been made in the placing of fragments of complexes, and in the use of imprecise models from NMR or homology modelling. Such models have necessitated the development of new approaches to rebuilding and refinement.

The 1.6 A structure of Kunitz-type domain from the alpha 3 chain of human type VI collagen

The C-terminal Kunitz-type domain from the alpha 3 chain of human type VI collagen (C5), a single 58 amino acid residue chain with three disulfide bridges, was cloned, expressed and crystallized in a monoclonic form, space group P2(1), with a = 25.7 A, b = 38.2 A, c = 28.8 A and beta = 109 degrees. The structure was resolved by molecular replacement, using Alzheimer's protein precursor inhibitor and bovine pancreatic trypsin inhibitor three-dimensional structures as search models. The molecule with one sulfate ion and 43 associated water molecules was refined by XPLOR to an R-factor of 18.9% at 1.6 A. The molecule was not degraded by trypsin and did not inhibit trypsin or tested serine proteases. As opposed to the other Kunitz family members, C5 demonstrates left-handed chirality of the Cys14-Cys38 disulfide bond. Inversion of the Thr13 carbonyl and bulky side-chains at the interface with trypsin in a model of the C5-trypsin complex may explain the lack of inhibition of trypsin.