Study of the Interaction of Sorption and Catalytic Centers in Carboxypeptidase T by X-ray Analysis

Carboxypeptidase T (CPT; EC 3.4.17.18) from Thermoactinomyces vulgaris is a distant homolog of the highly specific pancreatic carboxypeptidase B; but has a broad substrate specificity; the source of which remains unclear. A previous study of the structural bases of the substrate specificity of CPT using stable sulfamoyl analogs of the transition state of the elimination of leucine; phenylalanine; arginine; and glutamic acid; showed that the binding of the C-terminal residue of the substrate to the primary selectivity pocket of CPT leads to a change in the distance between Zn2+ and the sulfur atom. This value is related to the efficiency of catalysis of the corresponding substrate or the inhibition constant of the corresponding stable analog of the transition state. In this work; we obtained crystallographic and kinetic data of the complex of CPT with N-sulfamoyl-L-valine; confirming the effect of the binding of the ligand’s side group by the primary specificity pocket of CPT on the structure of the catalytic center; which can explain the unusual substrate specificity of CPT.

Role of the I16-D194 ionic interaction in the trypsin fold

Activity in trypsin-like proteases is the result of proteolytic cleavage at R15 followed by an ionic interaction that ensues between the new N terminus of I16 and the side chain of the highly conserved D194. This mechanism of activation, first proposed by Huber and Bode, organizes the oxyanion hole and primary specificity pocket for substrate binding and catalysis. Using the clotting protease thrombin as a relevant model, we unravel contributions of the I16-D194 ionic interaction to Na+ binding, stability of the transition state and the allosteric E*-E equilibrium of the trypsin fold. The I16T mutation abolishes the I16-D194 interaction and compromises the architecture of the oxyanion hole. The D194A mutation also abrogates the I16-D194 interaction but, surprisingly, has no effect on the architecture of the oxyanion hole that remains intact through a new H-bond established between G43 and G193. In both mutants, loss of the I16-D194 ionic interaction compromises Na+ binding, reduces stability of the transition state, collapses the 215–217 segment into the primary specific pocket and abrogates the allosteric E*-E equilibrium in favor of a rigid conformation that binds ligand at the active site according to a simple lock-and-key mechanism. These findings refine the structural role of the I16-D194 ionic interaction in the Huber-Bode mechanism of activation and reveal a functional linkage with the allosteric properties of the trypsin fold like Na+ binding and the E*-E equilibrium.

Probing the S1 specificity pocket of the aminopeptidases that generate antigenic peptides

ERAP1 (endoplasmic reticulum aminopeptidase 1), ERAP2 and IRAP (insulin-regulated aminopeptidase) are three homologous enzymes that play critical roles in the generation of antigenic peptides. These aminopeptidases excise amino acids from N-terminally extended precursors of antigenic peptides in order to generate the correct length epitopes for binding on to MHC class I molecules. The specificity of these peptidases can affect antigenic peptide selection, but has not yet been investigated in detail. In the present study we utilized a collection of 82 fluorigenic substrates to define a detailed selectivity profile for each of the three enzymes and to probe structural and functional features of the S1 (primary specificity) pocket. Molecular modelling of the three S1 pockets reveals substrate–enzyme interactions that are critical determinants for specificity. The substrate selectivity profiles suggest that IRAP largely combines the S1 specificity of ERAP1 and ERAP2, consistent with its proposed biological function. IRAP, however, does not achieve this dual specificity by simply combining structural features of ERAP1 and ERAP2, but rather by an unique amino acid change at position 541. The results of the present study provide insights on antigenic peptide selection and may prove valuable in designing selective inhibitors or activity markers for this class of enzymes.

Substrate Specificity of a Cationic Peptidase from Bromelia Hemisphaerica L

A cationic peptidase, named hemisphaericin-C, has been purified from the juice of Bromelia hemisphaerica fruits by ammonium sulfate precipitation, gel filtration on Sephadex G-75 and cationic exchange chromatography on carboxymethyl cellulose (CMC), to yield a single 24 kDa band on SDS-polyacrylamide gel electrophoresis (SDS-PAGE), which showed esterase and proteolytic activities. The esterase activity was inhibited by E-64, leupeptin, and cystatin, but not by EDTA. Characterization of the primary specificity of hemisphaericin-C showed activity towards substrates specific for chymotrypsin: N-succinyl-L-Phe- p-nitroanilide (PHE pNA) and N-benzoyl-L-Tyr- p-nitroanilide (TYR pNA), and those for trypsin: N-benzoyl-L-arg- p-nitroanilide (BA pNA) to a lower degree. The higher selectivity, assessed by Vmax/Km, was obtained for PHE pNA, the substrate containing the aromatic lateral chain amino acid at the P1 position. The preference of hemisphaericin-C for PHE pNA gives a clue in the search for a chymotrypsin-like peptidase from a vegetal source.