Crystallographic Proof for an Extended Hydrogen-Bonding Network in Small Prolyl Isomerases

Mueller, Jonathan Wolf; Link, Nina M.; Matena, Anja; Hoppstock, Lukas; Rüppel, Alma; Bayer, Peter; Blankenfeldt, Wulf

doi:10.1021/ja2086195

Cited by 32 publications

(75 citation statements)

References 20 publications

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“…17 The results are consistent with the tautomers of the corresponding histidines identified in the high-resolution crystal structure of Par14, a PPIase homologous to Pin1. 16 Our NMR results showed that the hydrogen bond network exists as in the Par14 crystal structure; however, NMR could not directly observe the sample if C113 was in the thiolate or thiol form. 17 As described in the Results, the unusual 1 H− 15 N and 1 H− 13 C HSQC spectra for the imidazole rings in the mutants could represent chemical exchange between the different protonation states of the H59 imidazole ring ( Figure 9B,C).…”

Section: Biochemistrymentioning

confidence: 63%

“…The histidines in the dual-histidine motif engage in the hydrogen bond network, in which H59 and H157 are in ε-and δ-tautomers, respectively. 16,17 In our previous work, we showed that impairing the hydrogen bond between H59 and H157 destabilized the structure. 17 The change in the protonation states of the histidines, which is theoretically predicted to occur according to the state of C113, 20 should have a significant impact on the structure and dynamics of these residues.…”

Section: Biochemistrymentioning

confidence: 94%

“…Both mutants showed similar Δδ profiles, demonstrating the obvious spectral changes for residues in the β1 strand, β3−β4 loop, and β4 strand, which includes residues engaged in the C113−H59−H157−T152 hydrogen bond network (Figure 2, right). 16 This observation shows that structural perturbation by the C113 mutation, as evidenced by the spectral changes, propagates through the hydrogen bond network. Thus, the C113 mutation disturbs all residues in the network, irrespective of their spatial distance from the mutation site in the α2−α3 loop.…”

mentioning

confidence: 85%

“…16 The residues in the hydrogen bond network are structurally superpositioned to C113, H59, H157, and T152 (listed in the connecting order in the hydrogen bonding network) in Pin1 (in Scheme 1, the residue numbers in Pin1 are in parentheses). 16 Par14 has aspartate instead of cysteine at position 113. 16 A C113D mutant Pin1 PPIase, mimicking the Par14 active site, was shown to have a reduced rate of isomerization relative to that of the wild type.…”

mentioning

confidence: 99%

“…16 Par14 has aspartate instead of cysteine at position 113. 16 A C113D mutant Pin1 PPIase, mimicking the Par14 active site, was shown to have a reduced rate of isomerization relative to that of the wild type. 17 Nuclear magnetic resonance (NMR) analysis showed that D113 formed a tighter hydrogen bond with H59 via the carboxylate oxygen in D113 while the hydrogen bond between H59 and H157 was destabilized.…”

mentioning

confidence: 99%

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Allosteric Breakage of the Hydrogen Bond within the Dual-Histidine Motif in the Active Site of Human Pin1 PPIase

et al. 2015

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Intimate cooperativity among active site residues in enzymes is a key factor for regulating elaborate reactions that would otherwise not occur readily. Peptidyl-prolyl cis-trans isomerase NIMA-interacting 1 (Pin1) is the phosphorylation-dependent cis-trans peptidyl-prolyl isomerase (PPIase) that specifically targets phosphorylated Ser/Thr-Pro motifs. Residues C113, H59, H157, and T152 form a hydrogen bond network in the active site, as in the noted connection. Theoretical studies have shown that protonation to thiolate C113 leads to rearrangement of this hydrogen bond network, with switching of the tautomeric states of adjacent histidines (H59 and H157) [Barman, A., and Hamelberg, D. (2014) Biochemistry 53, 3839-3850]. This is called the "dual-histidine motif". Here, C113A and C113S Pin1 mutants were found to alter the protonation states of H59 according to the respective residue type replaced at C113, and the mutations resulted in disruption of the hydrogen bond within the dual-histidine motif. In the C113A mutant, H59 was observed to be in exchange between ε- and δ-tautomers, which widened the entrance of the active site cavity, as seen by an increase in the distance between residues A113 and S154. The C113S mutant caused H59 to exchange between the ε-tautomer and imidazolium while not changing the active site structure. Moreover, the imidazole ring orientations of H59 and H157 were changed in the C113S mutant. These results demonstrated that a mutation at C113 modulates the hydrogen bond network dynamics. Thus, C113 acts as a pivot to drive the concerted function among the residues in the hydrogen bond network, as theoretically predicted.

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Section: Biochemistrymentioning

confidence: 63%

Section: Biochemistrymentioning

confidence: 94%

mentioning

confidence: 85%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Allosteric Breakage of the Hydrogen Bond within the Dual-Histidine Motif in the Active Site of Human Pin1 PPIase

et al. 2015

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Design and Synthesis of Oligopeptidic Parvulin Inhibitors

et al. 2022

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Pin1 catalyzes the cis‐trans isomerization of pThr‐Pro or pSer‐Pro amide bonds of various proteins involved in several physio/pathological processes. In this framework, recent research activity is directed toward the identification of new selective Pin1 inhibitors. Here, we developed a set of peptide‐based Pin1 inhibitors. Direct‐binding experiments allowed the identification of the peptide‐based inhibitor 5 k (methylacetyl‐l‐alanyl‐l‐histidyl‐l‐prolyl‐l‐phenylalaninate) as a potent ligand of Pin1. Notably, 5 k binds Pin1 with higher affinity than Pin4. The comparative analysis of molecular models of Pin1 and Pin4 with the selected compound gave a rational explanation of the biochemical activity and pinpointed the chemical elements that, if opportunely modified, may further improve inhibitory potency, pharmacological properties, and selectivity of future peptide‐based parvulin inhibitors. Since 5 k showed limited cell penetration and no antiproliferative activity, it was conjugated to a polyarginine stretch (R8), known to promote cell penetration of peptides, to obtain the R8–5 k derivative, which displayed antiproliferative effects on cancer cell lines over non‐tumor cells. The effect of R8 on cell proliferation was also investigated. This work warrants caution about applying the R8 strategy in the development of cell‐penetrating antiproliferative peptides, as it is not inert.

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Mechanistic insights into Pin1 peptidyl-prolylcis-transisomerization from umbrella sampling simulations

et al. 2014

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The peptidyl-proyl isomerase Pin1 plays a key role in the regulation of phospho(p)-Ser/Thr-Pro proteins, acting as a molecular timer of the cell cycle. After recognition of these motifs, Pin1 catalyzes the rapid cis-trans isomerization of proline amide bonds of substrates, contributing to maintain the equilibrium between the two conformations. Although a great interest has arisen on this enzyme, its catalytic mechanism has long been debated. Here, the cis-trans isomerization of a model peptide system was investigated by means of umbrella sampling simulations in the Pin1-bound and unbound states. We obtained free energy barriers consistent with experimental data, and identified several enzymatic features directly linked to the acceleration of the prolyl bond isomerization. In particular, an enhanced autocatalysis, the stabilization of perturbed ground state conformations, and the substrate binding in a procatalytic conformation were found as main contributions to explain the lowering of the isomerization free energy barrier.

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Crystallographic Proof for an Extended Hydrogen-Bonding Network in Small Prolyl Isomerases

Cited by 32 publications

References 20 publications

Allosteric Breakage of the Hydrogen Bond within the Dual-Histidine Motif in the Active Site of Human Pin1 PPIase

Allosteric Breakage of the Hydrogen Bond within the Dual-Histidine Motif in the Active Site of Human Pin1 PPIase

Design and Synthesis of Oligopeptidic Parvulin Inhibitors

Mechanistic insights into Pin1 peptidyl-prolylcis-transisomerization from umbrella sampling simulations

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