Catalytic conformation of carboxypeptidase A. The structure of a true reaction intermediate stabilized at subzero temperatures

The structure of the mixed anhydride, acyl-enzyme intermediate of the esterolytic reaction of carboxypeptidase A is characterized by application of cryoenzymologic, magnetic resonance, and molecular graphics methods with use of the Co²⁺-substituted enzyme and the specific spin-label ester substrate O-3-(2,2,5,5-tetra-methylpyrrolinyl-1-oxyl)-propen-2-oyl-l-β-phenyllactate. A radial separation of 7·7 Å between the active site Co²⁺ and the nitroxide group in the low temperature-stabilized acyl-enzyme intermediate is determined on the basis of their spin-spin (dipole-dipole) interactions. Application of molecular graphics techniques shows that the only configuration of the substrate that is sterically accommodated by the active site yields a calculated metal ion-to-nitroxide distance of 7·8 Å. Steric accommodation of the spin-label in the active site requires severe torsional distortion around the aliphatic double bond of the propenoyl side-chain. Examination of the structure of the enzyme: spin-label intermediate reveals that the distortion arises from steric interactions of the pyrrolinyl group with the protein at a position that corresponds to the site occupied by the penultimate amide residue of an oligopeptide substrate from the site of cleavage. Together with kinetic data showing that hydrolysis of the spin-label is governed by rate-limiting deacylation, the results indicate that geometric distortion of substrates by secondary interactions with the enzyme, in general, is an obligatory part of the catalytic action of carboxypeptidase A. When viewed with respect to requirements for stereoelectronic control of bond cleavage in tetrahedral adducts of esters and amides (Deslongchamps, 1975) the results suggest that torsional distortion during catalysis results in rotation around the scissile bond of the substrate, and that this rotation is required to form the mixed anhydride reaction intermediate. These findings further support the interpretation that the hydrolysis of esters and amides catalyzed by carboxypeptidase A proceeds according to similar mechanisms except that formation of the mixed anhydride is rate-determining in peptide hydrolysis while deacylation of the mixed anhydride is rate-limiting in ester hydrolysis.Additionally, in this study application of the extension of the theory of the Solomon-Bloembergen-Morgan equations derived by Lindner (1965) for paramagnetic metal ions with S ≥ 1 demonstrates that the zero-field splitting of the high-spin Co²⁺ in the metal-substituted enzyme has no significant influence in determination of the relaxation enhancement of solvent protons by the active site metal ion.