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

Carboxypeptidase T (CPT) from Thermoactinomyces vulgaris (EC 3.4.17.18) has a broad substrate specificity, the mechanism of which remains unclear. It cleaves off arginine residues by 10, and lysine residues by 100 times worse than hydrophobic leucine residues despite the presence of negatively charged Asp260 at the bottom of the primary specificity pocket. To study the relationship between the structure and specificity the 3D structure of CPT in complex with the stable transition state analog N-sulfamoyl-l-lysine (SLys) was determined in which the S-atom imitates the sp3-hybridized carbon in the scissile-bond. Crystals grown in microgravity has the symmetry of space group P6322. The present complex structure was compared with the previously reported complex structure of CPT and N-sulfamoyl-L-arginine (SArg). The location/binding of SLys in the active site of CPT very closely resembled that of SArg, and the positively charged N-atom of SLys was at the same position as the corresponding positively charged N-atom of SArg. The SLys complex is stabilized by the hydrogen bond between the nitrogen atom and OH-group of Thr257. The contact areas of the residues Tyr255, Leu211, and Thr262 with SLys were reduced in comparison with the same of SArg. This difference in bonding of SArg and SLys side chains in the primary specificity pocket induces shifts differences within the catalytic center (especially Tyr255-O20 and S18-Arg129 N1 gap) that may influence the enzyme's catalytic reaction. Therefore, this information may be useful for the design of carboxypeptidases with improved selectivity towards Arg/Lys for biotechnological applications.

Kinetics of the thermal inactivation and the refolding of bacterial luciferases in Bacillus subtilis and in Escherichia coli differ.

Here we present a study of the thermal inactivation and the refolding of the proteins in Gram positive Bacillus subtilis. To enable use of bacterial luciferases as the models for protein thermal inactivation and refolding in B. subtilis cells, we developed a variety of bright luminescent B. subtilis strains which express luxAB genes encoding luciferases of differing thermolability. The kinetics of the thermal inactivation and the refolding of luciferases from Photorhabdus luminescens and Photobacterium leiognathi were compared in Gram negative and Gram positive bacteria. In B. subtilis cells, these luciferases are substantially more thermostable than in Escherichia coli. Thermal inactivation of the thermostable luciferase P. luminescens in B. subtilis at 48.5°Ð¡ behaves as a first-order reaction. In E.coli, the first order rate constant (Kt) of the thermal inactivation of luciferase in E. coli exceeds that observed in B. subtilis cells 2.9 times. Incubation time dependence curves for the thermal inactivation of the thermolabile luciferase of P. leiognathi luciferase in the cells of E. coli and B. subtilis may be described by first and third order kinetics, respectively. Here we shown that the levels and the rates of refolding of thermally inactivated luciferases in B. subtilis cells are substantially lower that that observed in E. coli. In dnaK-negative strains of B. subtilis, both the rates of thermal inactivation and the efficiency of refolding are similar to that observed in wild-type strains. These experiments point that the role that DnaKJE plays in thermostability of luciferases may be limited to bacterial species resembling E. coli.

The nature of the ligand's side chain interacting with the S1'-subsite of metallocarboxypeptidase T (from Thermoactinomyces vulgaris) determines the geometry of the tetrahedral transition complex.

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.

Structure of the carboxypeptidase B complex with N-sulfamoyl-L-phenylalanine - a transition state analog of non-specific substrate.

Carboxypeptidase B (EC 3.4.17.2) (CPB) is commonly used in the industrial insulin production and as a template for drug design. However, its ability to discriminate substrates with hydrophobic, hydrophilic, and charged side chains is not well understood. We report structure of CPB complex with a transition state analog N-sulfamoyl-L-phenylalanine solved at 1.74Å. The study provided an insight into structural basis of CPB substrate specificity. Ligand binding is affected by structure-depended conformational changes of Asp255 in S1'-subsite, interactions with Asn144 and Arg145 in C-terminal binding subsite, and Glu270 in the catalytic center. Side chain of the non-specific substrate analog SPhe in comparison with that of specific substrate analog SArg (reported earlier) not only loses favorable electrostatic interactions and two hydrogen bonds with Asp255 and three fixed water molecules, but is forced to be in the unfavorable hydrophilic environment. Thus, Ser207, Gly253, Tyr248, and Asp255 residues play major role in the substrate recognition by S1'-subsite.

Structural insights into the broad substrate specificity of carboxypeptidase T from Thermoactinomyces vulgaris.

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.

Molecular modeling of different substrate-binding modes and their role in penicillin acylase catalysis.

Molecular modeling was addressed to understand different substrate-binding modes and clarify the role of two positively charged residues of the penicillin G acylase active site - ßR263 and αR145 - in binding of negatively charged substrates. Although the electrostatic contribution to productive substrate binding was dominated by ßR263 rather than αR145, it was found that productive binding was not the only possible mode of substrate placement in the active site. Two extra binding modes - nonproductive and preproductive - were located by means of molecular docking and dynamics with binding affinities comparable with the productive one. A unique feature of nonproductive and preproductive complexes was that the substrate's acyl group did not penetrate the hydrophobic pocket, but occupied a patch on the protein interface spanning from ßR263 to αR145. Nonproductive and preproductive complexes competed with each other and productive binding mode, giving rise to increased apparent substrate binding. Preproductive complex revealed an ability to switch to a productive one during molecular dynamics simulations, and conformational plasticity of the penicillin G acylase active site was shown to be crucial for that. Nonproductive binding observed at molecular modeling corresponded well with experimentally observed substrate inhibition in penicillin acylase catalysis. By combining estimated free energies of substrate binding in each mode, and accounting for two possible conformations of the penicillin G acylase active site (closed and open) quantitative agreement with experimentally measured K(M) values was achieved. Calculated near-attack conformation frequencies from corresponding molecular dynamics simulations were in a quantitative correlation with experimental k(cat) values and demonstrated adequate application of molecular modeling methods.