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Rewiring Receptor Activation: Mechanistic Insights into Toggle Switch Modulation by 25CN-NBx Compounds

Vito F. Palmisano, Micaela Vidal−sánchez, Juan J. Nogueira

ACS Chemical Neuroscience February 18, 2026 Peer reviewed DOI: 10.1021/acschemneuro.6c00023 via OpenAlex

Summary

Molecular dynamics simulations of 25CN-NBx compounds bound to the 5-HT 2A receptor reveal that bulky substitutions on the N-benzyl ring significantly shift the position of W336, a key residue influencing receptor activation. This shift enhances van der Waals interactions with F332 and I163, crucial for receptor signaling. The compounds 25CN-NB-2-OH-3-Me and 25CN-NB-2-OH-5-MeO exhibit the highest and lowest affinities for the receptor, respectively, aligning with experimental data.

Study at a glance

Key finding Bulky substitutions on the N-benzyl ring of 25CN-NBx compounds significantly shift W336's position, enhancing van der Waals interactions critical for receptor activation.

Abstract

High Resolution Image Download MS PowerPoint Slide The development of new treatments for neuropsychiatric disorders relies on a deeper understanding of the molecular mechanisms behind psychedelic compounds, particularly how they differentiate between hallucinogenic and antidepressant effects. In this study, we explore by molecular dynamics simulations a series of 25CN-NBx compounds bound to the 5-HT 2A receptor. The simulations uncover that bulky substitutions on the N -benzyl ring cause a significant shift in the position of W336, a key toggle switch residue known to influence receptor activation and thought to play a crucial role in mediating psychedelic signaling. This result is confirmed through potential of mean force calculations along the toggle switch’s dihedral angle. End-state free energy calculations align closely with experimental data, showing that 25CN-NB-2-OH-3-Me and 25CN-NB-2-OH-5-MeO have the highest and lowest affinities, respectively, for the 5-HT 2A receptor. Further analysis indicates that when W336 adopts its negative dihedral state, it establishes stronger van der Waals interactions, stabilizing its contacts with residues F332 and I163─key players previously linked to receptor activation. Our findings provide a framework for understanding receptor activation and can be extended to other G protein-coupled receptors where the toggle switch is central to signal activation.

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