2-Aminopyridinium salicylate.

C5H7N2+.C7H5O3-, Mr = 232.2, orthorhombic, Pbca, a = 15.928(5), b = 11.830(5), c = 11.768(6) A, V = 2217(2) A3, Z = 8, Dm = 1.40, Dx = 1.391 g cm3, graphite-monochromated CuK alpha, lambda = 1.54178 A, mu = 8.04 cm-1, F(000) = 976, T = 295 K, final R = 0.050 for 1116 reflections. Both six-membered rings are planar. The cations and anions are linked together in chains along the [001] direction by N-H...O hydrogen bonds.

Structural evidence for gene duplication in the evolution of the acid proteases.

X-ray studies of acid proteases indicate a bilobal structure with a well defined active site cleft. An intramolecular twofold symmetry axis relates two topologically similar domains and the active site residues. A possible mechanism for evolution by gene duplication, divergence and gene fusion is presented.

Mechanism of acid protease catalysis based on the crystal structure of penicillopepsin.

A proposed mechanism for the catalytic hydrolysis of peptide bonds by acid proteases is similar in many respects to the Zn-carbonyl mechanism previously derived for carboxypeptidase A. In the acid proteases the electrophilic component is the proton shared by Asp-32 and Asp-215; Tyr-75 donates its proton to the amide nitrogen of the scissile bond and an OH- ion from a water molecule bound between the carboxyl group of Asp-32 and the substrate attacks the carbonyl carbon atom.

Penicillopepsin from Penicillium janthinellum crystal structure at 2.8 A and sequence homology with porcine pepsin.

The polypeptide chain of the acid protease penicillo pepsin folds via an 18-stranded mixed beta-sheet into two distinct lobes separated by a 30-A long groove which is the extended substrate binding site. The catalytic residues Asp-32 and Asp-215 are located in this groove and their carboxyl groups are in intimate contact. Alignment of the amino acid sequence with that of pepsin shows regions of high homology.

Penicillopepsin: 2.8 A structure, active site conformation and mechanistic implications.

The crystal structure of penicillopepsin, an extracellular acid protease isolated from the mold Penicillium janthinellum, has been determined at 2.8 A resolution by the method of multiple isomorphous replacement. The resulting electron density map computed from the native structure factor amplitudes and MIR phases has an overall mean figure of merit of 0.90. The molecule is decidedly nonspherical, with the majority of residues in beta-structure. There is an 18-stranded mixed beta-sheet which forms the structural core in the region of the active site. This site, identified by the covalent binding of two EPNP molecules to Asp-32 and Asp-215, is located in a deep groove which divides the molecule into two approximately equal lobes. Both aspartic acid residues in the active site are in intimate contact with one another and the carboxyl group of Asp-32 makes two other important hydrogen-bonded contacts: one with Ser-35 and the other with the main chain peptide bond between Thr-216 and Gly-217. A proposed mechanism for acid protease catalysis is similar in many aspects to that proposed for carboxypeptidase A. The electrophilic component which polarizes the substrate carbonyl bond in the acid proteases is the proton shared between the beta-carboxyl groups of Asp-32 and Asp-215. The beta-carboxyl group of Asp-32 removes a proton from a water molecule bound between this side chain and the substrate; the resultant OH- attacks the carbonyl carbon atom of the substrate molecule. The phenolic -OH group of Tyr-75 donates its proton to the amide nitrogen of the scissile bond of the substrate.