Indira Nederpelt scite author profile

A considerable number of approved drugs show non-equilibrium binding characteristics, emphasizing the potential role of drug residence times for in vivo efficacy. Therefore, a detailed understanding of the kinetics of association and dissociation of a target-ligand complex might provide crucial insight into the molecular mechanism-of-action of a compound. This deeper understanding will help to improve decision making in drug discovery, thus leading to a better selection of interesting compounds to be profiled further. In this review, we highlight the contributions of the Kinetics for Drug Discovery (K4DD) Consortium, which targets major open questions related to binding kinetics in an industry-driven public-private partnership.

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Multiple Binding Sites for Small-Molecule Antagonists at the CC Chemokine Receptor 2

Zweemer

et al. 2013

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The chemokine receptor CCR2 is a G protein-coupled receptor that is activated primarily by the endogenous CC chemokine ligand 2 (CCL2). Many different small-molecule antagonists have been developed to inhibit this receptor, as it is involved in a variety of diseases characterized by chronic inflammation. Unfortunately, all these antagonists lack clinical efficacy, and therefore a better understanding of their mechanism of action is warranted. In this study, we examined the pharmacological properties of smallmolecule CCR2 antagonists in radioligand binding and functional assays. Six structurally different antagonists were selected for this study, all of which displaced the endogenous agonist 125

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Characterization of 12 GnRH peptide agonists – a kinetic perspective

Nederpelt

Georgi

Schiele

et al. 2015

British J Pharmacology

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BACKGROUND AND PURPOSEDrug-target residence time is an important, yet often overlooked, parameter in drug discovery. Multiple studies have proposed an increased residence time to be beneficial for improved drug efficacy and/or longer duration of action. Currently, there are many drugs on the market targeting the gonadotropin-releasing hormone (GnRH) receptor for the treatment of hormone-dependent diseases. Surprisingly, the kinetic receptor-binding parameters of these analogues have not yet been reported. Therefore, this project focused on determining the receptor-binding kinetics of 12 GnRH peptide agonists, including many marketed drugs. EXPERIMENTAL APPROACHA novel radioligand-binding competition association assay was developed and optimized for the human GnRH receptor with the use of a radiolabelled peptide agonist, [ 125 I]-triptorelin. In addition to radioligand-binding studies, a homogeneous time-resolved FRET Tag-lite ™ method was developed as an alternative assay for the same purpose. KEY RESULTSTwo novel competition association assays were successfully developed and applied to determine the kinetic receptor-binding characteristics of 12 high-affinity GnRH peptide agonists. Results obtained from both methods were highly correlated. Interestingly, the binding kinetics of the peptide agonists were more divergent than their affinities with residence times ranging from 5.6 min (goserelin) to 125 min (deslorelin). CONCLUSIONS AND IMPLICATIONSOur research provides new insights by incorporating kinetic, next to equilibrium, binding parameters in current research and development that can potentially improve future drug discovery targeting the GnRH receptor. AbbreviationsCHOhGnRH, CHO cells stably expressing the human GnRH receptor; GnRH, gonadotropin-releasing hormone; k 1 , the association rate constant of the radioligand; k 2 , the dissociation rate constant of the radioligand; k 3 , the association rate constant of the unlabelled ligand; k 4 , the dissociation rate constant of the unlabelled ligand; RT, residence time; TR-FRET, time-resolved FRET

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Mechanistic models enable the rational use of in vitro drug-target binding kinetics for better drug effects in patients

Witte

Wong

Nederpelt

et al. 2015

Expert Opinion on Drug Discovery

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More scientific evidence is required for the rational selection and development of drug-candidates on the basis of in vitro estimates of drug-target binding kinetics. To elucidate the value of in vitro binding kinetics measurements, it is necessary to obtain information on system-specific properties which influence the kinetics of target occupancy and drug effect. Mathematical integration of this information enables the identification of drug-specific properties which lead to optimal target occupancy and drug effect in patients.

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Kinetic binding and activation profiles of endogenous tachykinins targeting the NK1 receptor

Nederpelt

Bleeker

Tuijt

et al. 2016

Biochemical Pharmacology

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Persistent GnRH receptor activation in pituitary αT3-1 cells analyzed with a label-free technology

Nederpelt

Vergroesen

IJzerman

et al. 2016

Biosensors and Bioelectronics

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Kinetic Profile of Neuropeptide–Receptor Interactions

Nederpelt

Bunnik

IJzerman

et al. 2016

Trends in Neurosciences

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From receptor binding kinetics to signal transduction; a missing link in predicting in vivo drug-action

Nederpelt

Kuzikov

Witte

et al. 2017

Sci Rep

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An important question in drug discovery is how to overcome the significant challenge of high drug attrition rates due to lack of efficacy and safety. A missing link in the understanding of determinants for drug efficacy is the relation between drug-target binding kinetics and signal transduction, particularly in the physiological context of (multiple) endogenous ligands. We hypothesized that the kinetic binding parameters of both drug and endogenous ligand play a crucial role in determining cellular responses, using the NK1 receptor as a model system. We demonstrated that the binding kinetics of both antagonists (DFA and aprepitant) and endogenous agonists (NKA and SP) have significantly different effects on signal transduction profiles, i.e. potency values, in vitro efficacy values and onset rate of signal transduction. The antagonistic effects were most efficacious with slowly dissociating aprepitant and slowly associating NKA while the combination of rapidly dissociating DFA and rapidly associating SP had less significant effects on the signal transduction profiles. These results were consistent throughout different kinetic assays and cellular backgrounds. We conclude that knowledge of the relationship between in vitro drug-target binding kinetics and cellular responses is important to ultimately improve the understanding of drug efficacy in vivo.

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