Reconstruction of symmetry deviations: a procedure to analyze partially decorated F-actin and other incomplete structures.

The absolute value of individual differences (AVID) procedure is a method to map variations within images arising from deviations in symmetry. We devised this procedure to analyze images of actin filaments decorated with actin-binding proteins (ABPs). In three-dimensional maps of such actin complexes, ABPs often appear weak (i.e. they have low density) relative to actin. Because the 3D map represents an average taken over equivalent positions in the helix, the final density at the position of the ABP represents an average of the densities at all ABP sites. If there is either incomplete binding or a conformational variability of the bound ABP, the average density will be lowered. By the same argument, the variation of density at these sites will be increased. The aim of the AVID procedure is to calculate the density variations within partially decorated filaments and thereby attempt to locate the bound protein. We tested the AVID procedure with model data and then applied it to electron micrographs of F-actin decorated with an actin-binding domain of fimbrin known as N375 [Hanein et al., J. Cell Biol. 139 (1997) 387-396]. The AVID maps have peaks at the site where N375 binds. Because it excludes the layer line data, the AVID procedure uses data that are independent of the data used for 3D reconstruction and difference mapping. It therefore provides an independent way to localize the bound subunit without the need for a map of undecorated actin. Moreover, the difficulties of scaling maps are minimized. This procedure could also be applied to structures with non-helical symmetry.

Crystal structure of the mutant yeast triosephosphate isomerase in which the catalytic base glutamic acid 165 is changed to aspartic acid.

The three-dimensional structure of the E165D mutant of the glycolytic enzyme yeast triosephosphate isomerase has been determined by X-ray diffraction at a nominal resolution of 2 A. For crystallization, the mutant enzyme was complexed with the tight-binding intermediate analog, phosphoglycolohydroxamate. Comparison with the structure of the wild-type enzyme reveals that, as originally intended, replacement of the catalytic base Glu-165 with the shorter side chain of aspartic acid has increased the distance between the base and the intermediate analog by 1 A. In addition, the catalytic base is oriented in the E165D structure so as to use the anti orbital of the carboxylate for proton abstraction; in the structure of the wild-type enzyme, the syn orbital is oriented for this purpose. It has been hypothesized that the 1000-fold loss in catalytic activity for this mutant triosephosphate isomerase is due either to the use of the less basic anti orbital for proton transfer or to the greater distance between the base and the substrate. The structure of yeast E165D triosephosphate isomerase suggests that both distance and orientation factors contribute to the loss of activity in the mutant enzyme and, therefore, that both factors contribute to the catalytic efficiency of the wild-type enzyme.