Structure of the microbial carboxypeptidase T complexed with the transition state analog N-sulfamoyl-l-lysine

The carboxypeptidase T (CPT) from Thermoactinomyces vulgaris has an active site structure and 3D organization similar to pancreatic carboxypeptidases A and B (CPA and CPB), but differs in broader substrate specificity. The crystal structures of CPT complexes with the transition state analogs N-sulfamoyl-L-leucine and N-sulfamoyl-L-glutamate (SLeu and SGlu) were determined and compared with previously determined structures of CPT complexes with N-sulfamoyl-L-arginine and N-sulfamoyl-L-phenylalanine (SArg and SPhe). The conformations of residues Tyr255 and Glu270, the distances between these residues and the corresponding ligand groups, and the Zn-S gap between the zinc ion and the sulfur atom in the ligand’s sulfamoyl group that simulates a distance between the zinc ion and the tetrahedral sp3-hybridized carbon atom of the converted peptide bond, vary depending on the nature of the side chain in the substrate’s C-terminus. The increasing affinity of CPT with the transition state analogs in the order SGlu, SArg, SPhe, SLeu correlates well with a decreasing Zn-S gap in these complexes and the increasing efficiency of CPT-catalyzed hydrolysis of the corresponding tripeptide substrates (ZAAL > ZAAF > ZAAR > ZAAE). Thus, the side chain of the ligand that interacts with the primary specificity pocket of CPT, determines the geometry of the transition complex, the relative orientation of the bond to be cleaved by the catalytic groups of the active site and the catalytic properties of the enzyme. In the case of CPB, the relative orientation of the catalytic amino acid residues, as well as the distance between Glu270 and SArg/SPhe, is much less dependent on the nature of the corresponding side chain of the substrate. The influence of the nature of the substrate side chain on the structural organization of the transition state determines catalytic activity and broad substrate specificity of the carboxypeptidase T.

The crystal structures of carboxypeptidase T (CpT) complexes with phenylalanine and arginine substrate analogs - benzylsuccinic acid and (2-guanidinoethylmercapto)succinic acid - were determined by the molecular replacement method at resolutions of 1.57 Å and 1.62 Å to clarify the broad substrate specificity profile of the enzyme. The conservative Leu211 and Leu254 residues (also present in both carboxypeptidase A and carboxypeptidase B) were shown to be structural determinants for recognition of hydrophobic substrates, whereas Asp263 was for recognition of positively charged substrates. Mutations of these determinants modify the substrate profile: the CpT variant Leu211Gln acquires carboxypeptidase B-like properties, and the CpT variant Asp263Asn the carboxypeptidase A-like selectivity. The Pro248-Asp258 loop interacting with Leu254 and Tyr255 was shown to be responsible for recognition of the substrate's C-terminal residue. Substrate binding at the S1' subsite leads to the ligand-dependent shift of this loop, and Leu254 side chain movement induces the conformation rearrangement of the Glu277 residue crucial for catalysis. This is a novel insight into the substrate selectivity of metallocarboxypeptidases that demonstrates the importance of interactions between the S1' subsite and the catalytic center.

The 3D structure of recombinant bacterial carboxypeptidase T (CPT) in complex with N-BOC-L-leucine was determined at 1.38 Å resolution. Crystals for the X-ray study were grown in microgravity using the counter-diffusion technique. N-BOC-L-leucine and SO4(2-) ion bound in the enzyme active site were localized in the electron density map. Location of the leucine side chain in CPT-N-BOC-L-leucine complex allowed identification of the S1 subsite of the enzyme, and its structure was determined. Superposition of the structures of CPT-N-BOC-L-leucine complex and complexes of pancreatic carboxypeptidases A and B with substrate and inhibitors was carried out, and similarity of the S1 subsites in these three carboxypeptidases was revealed. It was found that SO4(2-) ion occupies the same position in the S1' subsite as the C-terminal carboxy group of the substrate.

Crystals of recombinant carboxypeptidase T (CPT) from Thermoactinomyces vulgaris were grown in a capillary by the counterdiffusion method in the absence of calcium ions. The three-dimensional structure of CPT was solved at 1.69-Å resolution using the X-ray diffraction data collected from the crystals of the enzyme on the SPring-8 synchrotron radiation facility and was then refined to Rfact = 16.903% and Rfree = 18.165%. The coordinates of the refined model were deposited in the Protein Data Bank (PDB ID: 3QNV). A comparison of this structure with the structure of wild-type CPT containing bound calcium ions, which was determined earlier, revealed a number of conformational changes both in the calcium-binding sites and the enzyme active site. Based on the results of this comparison, the possible factors responsible for the difference in the catalytic activity of the two forms of the enzyme are considered.

New determinants of Thermoactinomyces vulgaris carboxypeptidase T (CPT) substrate specificity--structural calcium ions and Leu254 residue--were found by means of steady-state kinetics and site-directed mutagenesis. The removal of calcium ions shifted the selectivity profile of hydrolysis of tripeptide substrates with C-terminal Leu, Glu, and Arg from 64/1.7/1 to 162/1.3/1. Substitution of the hydrophobic Leu254 in CPT for polar Asn did not change hydrolysis efficiency of substrates with C-terminal Leu and Arg, but resulted in more than 28-fold decrease in activity towards the substrate with C-terminal Glu. It is shown that the His68 residue is not a structural determinant of CPT specificity.

An influence of residues at positions 260 and 262 on a broad substrate specificity of Thermoactinomyces vulgaris carboxypeptidase T (CPT) has been studied by means of site-directed mutagenesis. The structure of the S1'-site of CPT is similar to those of pancreatic carboxypeptidases A (CPA) and B (CPB); however, the enzyme is capable of cleaving off C-terminal hydrophobic (like CPA), C-terminal positively charged (like CPB), and negatively charged residues. The spatial alteration of the S1' site hydrophobic area in CPT by an insertion of one residue in the active site loop with Tyr255 by analogy with CPA and CPB did not change the enzyme specificity. The introduction of Ile262 (CPT D260G/T262I) led to a statistically significant reduction in activity towards charged substrates. The removal of a negative (CPT D260G) and placement of a positive charge (CPT D260G/T262K and CPT D260G/T262R) in the S1' site shifted the specificity of the variants towards substrates with C-terminal Glu. The selectivity profile was 64:1.7:1 for wild-type CPT, 815:115:1 for CPT D260G, 3270:1060:1 for CPT D260G/T262K and 1:2.4:0 for CPT D260G/T262R for substrates with C-terminal Leu, Glu and Arg, respectively. The obtained results confirm the important role of the amino acid residues at positions 260 and 262 in determination of the CPT substrate specificity.

Site-directed mutagenesis in the active site of Thermoactinomyces vulgaris carboxypeptidase T (CpT), which is capable of hydrolyzing both hydrophobic and positively charged substrates, resulted in five mutants: CpT1 (A243G), CpT2 (D253G/T255D), CpT3 (A243G/D253G/T255D), CpT4 (G207S/A243G/D253G/T255D), and CpT5 (G207S/A243G/T250A/D253G/T255D). These mutants step-by-step reconstruct the primary specificity pocket of carboxypeptidase B (CpB), which is capable of cleaving only positively charged C-terminal residues. All of the mutants retained the substrate specificity of the wild-type CpT. Based on comparison of three-dimensional structures of CpB and the CpT5 model, it was suggested that the lower affinity of CpT5 for positively charged substrates than the affinity of CpB could be caused by differences in nature and spatial location of Leu247 and Ile247 and of His68 and Asp65 residues in CpT and CpB, respectively, and also in location of the water molecule bound with Ala250. An additional hydrophobic region was detected in the CpT active site formed by Tyr248, Leu247, Leu203, Ala243, CH3-group of Thr250, and CO-groups of Tyr248 and Ala243, which could be responsible for binding hydrophobic substrates. Thus, notwithstanding the considerable structural similarity of CpT and pancreatic carboxypeptidases, the mechanisms underlying their substrate specificities are different.

42] Carboxypeptidase T

Carboxypeptidase E (CPE), an enzyme that functions in the post-translational processing of bioactive peptides, is a member of the metallocarboxypeptidase gene family. A 12-residue region of CPE has 70% amino acid identity with the bacterial enzyme carboxypeptidase T (CPT); in CPT, this region has been identified previously as the Ca(2+)-binding region (Teplyakov, A., Polyakov, K., Obmolova, G., Strokopytov, B., Kuranova, I., Osterman, A., Grishin, N., Smulevitch, S., Zagnitko, O., Galperina, O., Matz, M., and Stepanov, V. (1992) Eur. J. Biochem. 208, 281-288). Using 45Ca2+ binding, we determined that CPE binds Ca2+. To investigate the potential function for the interaction of CPE with Ca2+, we investigated the effect of Ca2+ on aggregation, thermostability, and enzyme activity of CPE. CPE does not aggregate under a variety of Ca2+ concentrations at either pH 5.5 or 7.5, and with protein concentrations ranging from 10 to 100 micrograms/ml. Whereas Ca2+ generally stabilizes proteins to thermal denaturation, CPE was destabilized by Ca2+ and stabilized by low concentrations of EGTA. The Ca(2+)-induced destabilization of CPE was more pronounced at pH 8 than at lower pH values. At pH 8, CPE was unstable even at 37 degrees C, with approximately 40% loss of activity upon incubation for 30 min in the absence of added Ca2+ and 70% loss of activity upon incubation in the presence of 10 mM CaCl2. Enzyme activity was not influenced by added Ca2+, but was stimulated by micromolar concentrations of EGTA; kinetic analysis showed this stimulation to be due to a change in Vmax, and not Km. Taken together, these data suggest that Ca2+ plays a role in the regulation of CPE activity.