Human dipeptidyl peptidase III (DPP III) is a two domain metallo-peptidase from the M49 family. The wide interdomain cleft and broad substrate specificity suggest that this enzyme could experience significant conformational change. Long (>100 ns) molecular dynamics (MD) simulations of DPP III revealed large range conformational changes of the protein, suggesting the pre-existing equilibrium model for a substrate binding. The binding free energy calculations revealed tighter binding of the preferred synthetic substrate Arg-Arg-2-naphtylamide to the "closed" than to the "open" DPP III conformation. Our assumption that Asp372 plays a crucial role in the large scale interdomain closure was proved by the MD simulations of the Asp372Ala variant. During the same simulation time, the variant remained more "open" than the wild type protein. Apparently, Ala was not as efficient as Asp in establishing the interdomain interactions. According to the MM-PBSA calculations, the electrostatic component of the free energy of solvation turned out to be higher for the "closed" protein than for its less compact form. However, the gain in entropy due to water released from the interdomain cleft nicely balanced this negative effect.
Human dipeptidyl-peptidase III (h.DPP III) is a zinc-exopeptidase that hydrolyses dipeptides from the N-terminus of its substrates. Its mechanism of action was assumed to be similar to that of thermolysin, but was never thoroughly investigated. This study presents the first insight into the reaction mechanism of h.DPP III, determined on the model and real (hydrated enzyme with Leu-enkephalin bound in the active site) systems. The Glu451-assisted water addition on amide carbon atoms and nitrogen inversion (i.e. change of pyramidalization on the leaving nitrogen) are shown to be the rate-determining steps with the activation energies in a good agreement with the experimental results for the Leu-enkephalin hydrolysis. The energy barrier for nucleophilic attack is about 28 kJ mol, while barriers for the N-inversion differ as a consequence of the number of hydrogen bonds that have to be changed, which is smaller in the model active site than in the solvated enzyme. Although precisely defined geometry of the enzyme binding site puts an additional restraint on the hydrogen bonding interactions, at the same time it stimulates the forward reaction towards the final hydrolytic product. Namely, different from the model, the N-inversion is in a concerted fashion followed by favourable hydrogen bonding with Glu451 that immediately "locks" the system into the configuration where reversion to the enzyme-substrate complex is hardly achievable. Therefore we propose that the functional significance of DPP III is dual: to lower the energy barrier of the peptide hydrolysis and to suppress the reverse reaction.
Human dipeptidyl peptidase III (DPP III) is a zinc-exopeptidase with implied roles in protein catabolism, pain modulation, and defense against oxidative stress. To understand the mode of ligand binding into its active site, we performed molecular modeling, site-directed mutagenesis, and biochemical analyses. Using the recently determined crystal structure of the human DPP III we built complexes between both, the wild-type (WT) protein and its mutant H568N with the preferred substrate Arg-Arg-2-naphthylamide (RRNA) and a competitive inhibitor Tyr-Phe-hydroxamate (Tyr-Phe-NHOH). The mutation of the conserved His568, structurally equivalent to catalytically important His231 in thermolysin, to Asn, resulted in a 1300-fold decrease of k(cat) for RRNA hydrolysis and in significantly lowered affinity for the inhibitor. Molecular dynamics simulations revealed the key protein-ligand interactions as well as the ligand-induced reorganization of the binding site and its partial closure. Simultaneously, the non-catalytic domain was observed to stretch and the opening at the wide side of the inter-domain cleft became enhanced. The driving force for these changes was the formation of the hydrogen bond between Asp372 and the bound ligand. The structural and dynamical differences, found for the ligand binding to the WT enzyme and the H568N mutant, and the calculated binding free energies, agree well with the measured affinities. On the basis of the obtained results we suggest a possible reaction mechanism. In addition, this work provides a foundation for further site-directed mutagenesis experiments, as well as for modeling the reaction itself.
Multiple choices of the protein active conformations in flexible metalloenzymes complicate study of their catalytic mechanism. We used three different conformations of human dipeptidyl-peptidase III (DPP III) to investigate the influence of the protein environment on ligand binding and the Zn(2+) coordination. MD simulations followed by calculations of binding free energy components accomplished for a series of DPP III substrates, both synthetic and natural, revealed that binding of the β-strand shaped substrate to the five-stranded β-core of the compact DPP III form (in antiparallel fashion) is the preferred binding mode, in agreement with the experimentally determined structure of the DPP III inactive mutant-tynorphin complex (Bezerra et al., Proc. Natl. Acad. Sci. U. S. A., 2012, 109, 6525). Previously it was proposed that the catalytic mechanism of DPP III is similar to that of thermolysin, which assumes exchange of five and four coordinated Zn(2+), and activation of Zn-bound water by a nearby Glu. Our QM/MM calculations, performed for a total of 18 protein structures with different zinc ion environments, revealed that the 5-coordinated metal ion is more favourable than the 6-coordinated one in only the most compact DPP III form. Besides, in this structure E451 is H-bonded to the metal ion coordinating water. Also, our study revealed two constraints for the broad substrate specificity of DPP III. One is the possibility of the substrate adopting the β-strand shape and the other is its charged N-terminus. Altogether, we assume that the human DPP III active conformation would be the most compact form, similar to the "closed X-ray" DPP III structure.
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