Conserved internal hydration motifs in protein kinases

Setny, Piotr

doi:10.1002/prot.25977

Cited by 6 publications

(4 citation statements)

References 82 publications

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“…For a review of the first experimental observations and quantum-mechanical analysis of the “flip-flop” hydrogen bonds see ( Saenger et al, 1985 ; Jeffrey and Saenger, 1991 ). Below are some representative publications analyzing the mechanisms of delocalized hydrogen bonds and “water wires” ( Cui and Karplus, 2003 ; Cukierman, 2003; Marx, 2006 ; Yan et al, 2007 ; Sakti et al, 2019 ; Setny, 2020 ). The analysis of structural conformational changes coupled with proton transfer processes shows that the covalent docking reactions described in this study are highly cooperative processes, and future studies should probably also take into account the quantum-dynamical effects associated with cooperative proton transfer mechanisms.…”

Section: Discussionmentioning

confidence: 99%

Exploring Covalent Docking Mechanisms of Boron-Based Inhibitors to Class A, C and D β-Lactamases Using Time-dependent Hybrid QM/MM Simulations

Charzewski

Krzyśko

Lesyng

2021

Front. Mol. Biosci.

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Recently, molecular covalent docking has been extensively developed to design new classes of inhibitors that form chemical bonds with their biological targets. This strategy for the design of such inhibitors, in particular boron-based inhibitors, holds great promise for the vast family of β-lactamases produced, inter alia, by Gram-negative antibiotic-resistant bacteria. However, the description of covalent docking processes requires a quantum-mechanical approach, and so far, only a few studies of this type have been presented. This study accurately describes the covalent docking process between two model inhibitors - representing two large families of inhibitors based on boronic-acid and bicyclic boronate scaffolds, and three β-lactamases which belong to the A, C, and D classes. Molecular fragments containing boron can be converted from a neutral, trigonal, planar state with sp2 hybridization to the anionic, tetrahedral sp3 state in a process sometimes referred to as morphing. This study applies multi-scale modeling methods, in particular, the hybrid QM/MM approach which has predictive power reaching well beyond conventional molecular modeling. Time-dependent QM/MM simulations indicated several structural changes and geometric preferences, ultimately leading to covalent docking processes. With current computing technologies, this approach is not computationally expensive, can be used in standard molecular modeling and molecular design works, and can effectively support experimental research which should allow for a detailed understanding of complex processes important to molecular medicine. In particular, it can support the rational design of covalent boron-based inhibitors for β-lactamases as well as for many other enzyme systems of clinical relevance, including SARS-CoV-2 proteins.

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Section: Discussionmentioning

confidence: 99%

Exploring Covalent Docking Mechanisms of Boron-Based Inhibitors to Class A, C and D β-Lactamases Using Time-dependent Hybrid QM/MM Simulations

Charzewski

Krzyśko

Lesyng

2021

Front. Mol. Biosci.

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“…This residue reaches across the active site cleft and in the active conformation shields the γphosphate from water. 26 The activation loop (A-loop; residues 184−197) is part of the activation segment in PKA (residues 184−208). The A-loop includes several highly conserved features (Figure 2A).…”

Section: Pocket and The Active Conformationmentioning

confidence: 99%

“…Another key feature of the G-loop is a conserved aromatic amino acid in the β-hairpin turn, usually phenylalanine. This residue reaches across the active site cleft and in the active conformation shields the γ-phosphate from water …”

Section: The First Pka Structures the Atp Binding Pocket And The Acti...mentioning

confidence: 99%

Drugging the Undruggable: How Isoquinolines and PKA Initiated the Era of Designed Protein Kinase Inhibitor Therapeutics

Lorenz

Herberg

et al. 2021

Biochemistry

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In 1984, Japanese researchers led by the biochemist Hiroyoshi Hidaka described the first synthetic protein kinase inhibitors based on an isoquinoline sulfonamide structure (Hidaka et al. Biochemistry, 1984 Oct 9; 23(21): 5036–41. doi: 10.1021/bi00316a032). These led to the first protein kinase inhibitor approved for medical use (fasudil), an inhibitor of the AGC subfamily Rho kinase. With potencies strong enough to compete against endogenous ATP, the isoquinoline compounds established the druggability of the ATP binding site. Crystal structures of their protein kinase complexes, including with cAMP-dependent protein kinase (PKA), showed interactions that, on the one hand, could mimic ATP but, on the other hand, could be optimized for high potency binding, kinase selectivity, and diversification away from adenosine. They also showed the flexibility of the glycine-rich loop, and PKA became a major prototype for crystallographic and nuclear magnetic resonance (NMR) studies of protein kinase mechanism and dynamic activity control. Since fasudil, more than 70 kinase inhibitors have been approved for clinical use, involving efforts that progressively have introduced new paradigms of data-driven drug discovery. Publicly available data alone comprise over 5000 protein kinase crystal structures and hundreds of thousands of binding data. Now, new methods, including artificial intelligence techniques and expansion of protein kinase targeting approaches, together with the expiration of patent protection for optimized inhibitor scaffolds, promise even greater advances in drug discovery. Looking back to the time of the first isoquinoline hinge binders brings the current state-of-the-art into stark contrast. Appropriately for this Perspective article, many of the milestone papers during this time were published in Biochemistry (now ACS Biochemistry).

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“…The C-terminal region of the kinase domain consists of seven α-helices and a two-stranded β-sheet, and contains the catalytic aspartic acid of the HRD motif (sequence histidine, arginine, and aspartate at positions 254-256) and the mobile activation loop, whose position and conformation determine whether a kinase is active or inactive. 22,23 The Aurora A activation loop (the most crucial part required for functional activation of the protein) spans 274-299 amino acid residues, beginning with an aspartate, phenylalanine, and glycine sequence motif and ending with an alanine, proline, and glutamate motif (sequence proline, proline, and glutamate in Aurora A). Aurora A becomes active by its autophosphorylation (discussed in detail later) and trans-phosphorylation at threonine 287 and threonine 288 residues by targeting protein for Xenopus kinesin-like protein 2, 24 p21 activated kinase, 25 protein kinase A, 26 or atypical protein kinase C. 27…”

Section: Aurora a Salient Structural Featuresmentioning

confidence: 99%

Emerging Role of Aurora A in Radioresistance: A Comprehensive Review

et al. 2021

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Radiotherapy is one of the most conventional modes of treatment in several cancers. Failure of radiotherapy followed by acquisition of radioresistance is one of the emerging challenges faced by clinical experts. Unusual expression and functional implications of several molecules are observed to facilitate radioresistance. Aurora A, a member of the Aurora kinase (serine/threonine kinase) family, is one such molecule that shows significantly altered expression as well as non-canonical functional crosstalk with other associated factors (cell cycle regulators, signaling molecules, stemness markers, etc.) to favour the adaptations for the acquirement of radioresistance. These mechanisms include progression of cell cycle, stimulatory activation of factors by phosphorylation for enhancing the chance of cellular survivability, and prevention of apoptosis. This review article summarises how Aurora A is responsible for radioresistance in cancer and why this kinase should be considered a negative biomarker of radiosensitivity. This review discloses a wider opportunity in the field of research to find the mechanistic key regulatory pathway of Aurora A, which can be a potential target for enhancing the efficiency of treatment. Further investigations are required to explore the potential of Aurora A inhibitors as reliable radiosensitisers.

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Conserved internal hydration motifs in protein kinases

Cited by 6 publications

References 82 publications

Exploring Covalent Docking Mechanisms of Boron-Based Inhibitors to Class A, C and D β-Lactamases Using Time-dependent Hybrid QM/MM Simulations

Exploring Covalent Docking Mechanisms of Boron-Based Inhibitors to Class A, C and D β-Lactamases Using Time-dependent Hybrid QM/MM Simulations

Drugging the Undruggable: How Isoquinolines and PKA Initiated the Era of Designed Protein Kinase Inhibitor Therapeutics

Emerging Role of Aurora A in Radioresistance: A Comprehensive Review

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