Sequencing a protein by x-ray crystallography. II. Refinement of yeast hexokinase B co-ordinates and sequence at 2.1 A resolution.

Although the amino acid sequence of yeast hexokinase B has not been determined by chemical means, crystallographic refinement of the hexokinase monomer was carried out at 2.1 A resolution to improve both the atomic co-ordinates and the amino acid sequence, which had been obtained from a 2.5 A electron density map. The atomic co-ordinates were adjusted by real-space refinement into a multiple isomorphous replacement map, followed by automated difference Fourier refinement, and restrained parameter structure factor least-squares refinement. The amino acid sequence was altered periodically after visual inspection of (Fo − Fc) difference electron density maps. Evidence of the improvement in the amino acid sequence was provided by the better agreement between the X-ray and chemically derived amino acid compositions, and most importantly by the ability to locate two short peptides which had been chemically sequenced. While only 6 out of the 18 residues in these two peptides agree with the sequence of the original model, 12 residues agree with the sequence of the refined model and the others differ by only an atom or two. The refined model contains 3293 of of the 3596 non-hydrogen atoms expected from the amino acid composition and 152 bound water molecules. The crystallographic R factor at 2.1 A is 0.25. We show that there are several advantages to refining the structure of even a protein of unknown sequence. (1) Improved phases can be obtained to the resolution limit of the diffraction pattern starting with a model derived from a 2.5 A map. (2) The accuracy of the amino acid sequence derived by X-ray methods alone can be substantially improved. (3) Functionally important residues can be identified before chemical sequence information is available. (4) The improved X-ray sequence should greatly reduce the effort required to obtain a chemical sequence; since peptides as short as eight or nine residues can be located in the refined X-ray sequence, peptides do not need to be overlapped by chemical means.

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