Comparative Modeling of Substrate Binding in the S1‘ Subsite of Serine Carboxypeptidases from Yeast, Wheat, and Human

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Abstract
Human cathepsin A (“lysosomal protective protein”; E.C.3.4.16.5) is a multifunctional lysosomal protein which forms a high-molecular-weight complex with β-galactosidase and α-neuraminidase, protecting them against intralysosomal proteolysis. In addition to this protective function, cathepsin A is a serine carboxypeptidase and the understanding of its catalytic function requires a definition of its substrate specificity. For this purpose, we used a combined experimental [Pshezhetsky, A. V., Vinogradova, M. V., Elsliger, M.-A., El-Zein, F., Svedas, V. K., & Potier, M. (1995) Anal. Biochem. 230, 303−307] and theoretical approach comparing cathepsin A to two different homologous carboxypeptidases of the same family: yeast carboxypeptidase Y and wheat carboxypeptidase II. We computed the energies involved in substrate binding to the S1‘ subsite (C-terminal) of cathepsin A using a structural model based on the X-ray structure of the homologous wheat carboxypeptidase II. The binding energies of N-blocked Phe-Xaa dipeptide substrates to the active sites of cathepsin A, wheat carboxypeptidase II, and yeast carboxypeptidase Y were estimated using a molecular mechanics force field supplemented with a solvation energy term. This theoretical analysis showed a good correlation with the experimentally determined free energies of substrate binding. This result validates the use of this approach to analyze the energetics of substrate binding to the S1‘ subsite and provides a rational interpretation of serine carboxypeptidase−substrate interactions in molecular terms. We conclude that the three serine carboxypeptidases have similar affinities for substrates with hydrophobic P1‘ amino acid residues but that the wheat enzyme has an additional capacity for binding positively charged P1‘ residues. Finally, the substrate specificity of human cathepsin A is very similar to that of carboxypeptidase Y, with a high binding affinity for substrates with hydrophobic P1‘ residues, but the affinity of cathepsin A for P1‘ Phe residue is higher than for the Leu residue.