Addressing the Glycine‐Rich Loop of Protein Kinases by a Multi‐Facetted Interaction Network: Inhibition of PKA and a PKB Mimic

Lauber, Birgit S.; Hardegger, Leo A.; Alam, Kazi Asraful; Lund, Bjarte Aarmo; Dumele, Oliver; Harder, Michael; Kuhn, Bernd; Engh, Richard A.; Diederich, François

doi:10.1002/chem.201503552

Cited by 24 publications

(27 citation statements)

References 58 publications

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“…Optimizing amide stacking has also been used to improve inhibition of an umber of targets, includingt he aspartic protease endothiapepsin, [14] protein kinase A( PKA), [15] and the cysteine proteasea utophagin-1. [16] Most recently,D iederich et al [17] tried to design an inhibitor for the cysteine protease cathepsin Lb ym aximizing amide stackingi nteractions.…”

Section: Introductionmentioning

confidence: 99%

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Stacking Interactions of Heterocyclic Drug Fragments with Protein Amide Backbones

Bootsma

Wheeler

2018

ChemMedChem

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Stacking interactions can be important enthalpic contributors to drug binding. Among the less well-studied stacking interactions are those occurring between an arene and the π-face of an amide group. Given the ubiquity of heterocycles in drugs, combined with the abundance of amides in the protein backbone, optimizing these noncovalent interactions can provide a potential route to enhanced drug binding. Previously, Diederich et al. (ChemMedChem 2013, 8, 397-404) studied stacked dimers of a model amide with a set of 18 heterocycles, showing that computed interaction energies correlate with the dipole moments of the heterocycles and providing guidelines for the optimization of these interactions. We considered stacked dimers of the same model amide with a larger set of 28 heterocycles common in pharmaceuticals, by using more robust ab initio methods. While the overall trends in these new data corroborate many of the results of Diederich et al., these data provide a more refined view of the nature of amide stacking interactions. We present a robust scoring function for amide stacking interaction energies based on the molecular dipole moment and strength of the electric field above the arene.

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Section: Introductionmentioning

confidence: 99%

“…Optimizing amide stacking has also been used to improve inhibition of a number of targets, including the aspartic protease endothiapepsin, protein kinase A (PKA), and the cysteine protease autophagin‐1 . Most recently, Diederich et al .…”

Section: Introductionmentioning

confidence: 99%

Stacking Interactions of Heterocyclic Drug Fragments with Protein Amide Backbones

Bootsma

Wheeler

2018

ChemMedChem

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“…The off-target interactions have been shown to be involving the residues Gly 50, Thr 51, Gly 52, Ser 53, which are part of the Glycine rich loop (spanning from residue 50–55), an integral part of ATP binding site, and the residue Glu 170, part of ribose pocket, which carries the phosphate binding cassette 145 . Interestingly, the Glycine rich loop is one of the targeted sites for the development of PKA inhibitors 77 . Moreover, off-target interactions have also been observed in the activation loop hooking residues Phe 187, Thr 201, Pro 202 and Glu 203.…”

Section: Discussionmentioning

confidence: 99%

“…In case of PKA, the inhibitor 4L7 had been bound to glycine rich loop and β2–3 loop (ribose pocket). The 5 Å area around the residues involved in interactions with 4L7 was used as active site for docking studies 77 . In ERK2, the co-crystallize ligand had been 82 A that bound to protein kinase and glycine rich loop.…”

Section: Methodsmentioning

confidence: 99%

The Route to ‘Chemobrain’ - Computational probing of neuronal LTP pathway

Fahim

Rehman

Bhatti

et al. 2019

Sci Rep

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Chemotherapy causes deleterious side effects during the course of cancer management. The toxic effects may be extended to CNS chronically resulting in altered cognitive function like learning and memory. The present study follows a computational assessment of 64 chemotherapeutic drugs for their off-target interactions against the major proteins involved in neuronal long term potentiation pathway. The cancer chemo-drugs were subjected to induced fit docking followed by scoring alignment and drug-targets interaction analysis. The results were further probed by electrostatic potential computation and ligand binding affinity prediction of the top complexes. The study identified novel off-target interactions by Dactinomycin, Temsirolimus, and Everolimus against NMDA, AMPA, PKA and ERK2, while Irinotecan, Bromocriptine and Dasatinib were top interacting drugs for CaMKII. This study presents with basic foundational knowledge regarding potential chemotherapeutic interference in LTP pathway which may modulate neurotransmission and synaptic plasticity in patient receiving these chemotherapies.

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“…The binding of staurosporine to PKA was seen to displace a residue characteristic of the AGC group of kinases 20 The inhibitor H89, one of a series of Rho kinase inhibitors, was seen to possess hydrophobic interactions between its bromine moiety and the glycine‐rich loop, with both exhibiting flexibility 21,22 . Of great interest for this manuscript are a set of quinazoline‐based compounds (Figure 2) designed specifically to optimize interactions by varying substituents and geometries of interactions with the glycine‐rich loop, 23 keeping the hinge anchoring quinazoline group unchanged.…”

Section: Introductionmentioning

confidence: 99%

Inhibitor binding to mutants of protein kinase A with GGGxxG and GxGxxA glycine‐rich loop motifs

Alam

Gani

Engh

2020

J of Molecular Recognition

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The conserved GxGxxG motif of protein kinases forms a beta turn at the tip of the flexible glycine‐rich loop and creates much of the ATP pocket binding surface. Notable exceptions to this sequence include GGGxxG in ABL kinase and GxGxxA in protein kinase C isoforms. We constructed the corresponding mutants of PKA, T51G, and G55A, and tested quinazoline inhibitors that were designed to bind via glycine‐rich loop interactions, testing also staurosporine for comparison. The quinazoline inhibitors have significantly reduced binding strengths in both mutants. In striking contrast to these results, the binding of the “pan‐kinome” inhibitor staurosporine is strengthened in the mutants. Surface plasmon resonance (SPR) shows that the tightened binding of staurosporine arises from increased kon rates, changes not offset by more moderately increased koff rates. The SPR results fit best to a two step binding process for staurosporine in wild type PKA, but not the mutants.

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Addressing the Glycine‐Rich Loop of Protein Kinases by a Multi‐Facetted Interaction Network: Inhibition of PKA and a PKB Mimic

Cited by 24 publications

References 58 publications

Stacking Interactions of Heterocyclic Drug Fragments with Protein Amide Backbones

Stacking Interactions of Heterocyclic Drug Fragments with Protein Amide Backbones

The Route to ‘Chemobrain’ - Computational probing of neuronal LTP pathway

Inhibitor binding to mutants of protein kinase A with GGGxxG and GxGxxA glycine‐rich loop motifs

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