The structure of the pyruvoyl-dependent histidine decarboxylase has been refined to 2.5 A resolution by the methods of x-ray crystallography from crystals grown at pH 4.8, where the enzyme is optimally active. Models of the active site with and without the bound substrate analog, histidine methyl ester (HisOMe), or the product, histamine, have been produced. Comparison of native and ligand-bound structures reveals no widespread differences in conformation but does reveal motion of a few key residues (Tyr-62', Ile-59', Ser-81) upon binding of HisOMe in the active site. The HisOMe binds with the appropriate alpha-carbon-carbon bond oriented as required to facilitate the formation of the transition state. The binding site contains two pockets, one for the imidazole group, and another for the -COOMe group. In the imidazole pocket, the imidazolium group forms hydrogen bonds with two neighboring carboxylates, Asp-63' and the carboxyl terminus of the beta chain, Ser-81. Hydrophobic contacts are also observed. The carboxylate pocket is predominantly hydrophobic as predicted by Alston and Abeles (Alston, T. A., and Abeles, R. H. (1987) Biochemistry 26,4082-4085), but includes one carboxyl group, that of Glu-197, about 3.5 A from the substrate carboxylate. If Glu-197 is protonated under these conditions, it could serve as the proton donor following decarboxylation; if it is ionized under these conditions, its carboxylate group is appropriately placed to enhance the lability of the substrate carboxylate ion by providing a "push" in promoting the flow of electrons that results in decarboxylation. These and other structural features of the binding complex are discussed as they relate to a proposed mechanism of decarboxylation.