Huafeng Xu scite author profile

Molecular dynamics simulations capture the behavior of biological macromolecules in full atomic detail, but their computational demands, combined with the challenge of appropriately modeling the relevant physics, have historically restricted their length and accuracy. Dramatic recent improvements in achievable simulation speed and the underlying physical models have enabled atomic-level simulations on timescales as long as milliseconds that capture key biochemical processes such as protein folding, drug binding, membrane transport, and the conformational changes critical to protein function. Such simulation may serve as a computational microscope, revealing biomolecular mechanisms at spatial and temporal scales that are difficult to observe experimentally. We describe the rapidly evolving state of the art for atomic-level biomolecular simulation, illustrate the types of biological discoveries that can now be made through simulation, and discuss challenges motivating continued innovation in this field.

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Pathway and mechanism of drug binding to G-protein-coupled receptors

Dror

Pan

Arlow

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

698

563

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How drugs bind to their receptors—from initial association, through drug entry into the binding pocket, to adoption of the final bound conformation, or “pose”—has remained unknown, even for G-protein-coupled receptor modulators, which constitute one-third of all marketed drugs. We captured this pharmaceutically critical process in atomic detail using the first unbiased molecular dynamics simulations in which drug molecules spontaneously associate with G-protein-coupled receptors to achieve final poses matching those determined crystallographically. We found that several beta blockers and a beta agonist all traverse the same well-defined, dominant pathway as they bind to the β 1 - and β 2 -adrenergic receptors, initially making contact with a vestibule on each receptor’s extracellular surface. Surprisingly, association with this vestibule, at a distance of 15 Å from the binding pocket, often presents the largest energetic barrier to binding, despite the fact that subsequent entry into the binding pocket requires the receptor to deform and the drug to squeeze through a narrow passage. The early barrier appears to reflect the substantial dehydration that takes place as the drug associates with the vestibule. Our atomic-level description of the binding process suggests opportunities for allosteric modulation and provides a structural foundation for future optimization of drug–receptor binding and unbinding rates.

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Molecular dynamics---Scalable algorithms for molecular dynamics simulations on commodity clusters

et al. 2006

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Activation mechanism of theβ₂-adrenergic receptor

Dror

Arlow

Maragakis

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

559

428

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A third of marketed drugs act by binding to a G-protein-coupled receptor (GPCR) and either triggering or preventing receptor activation. Although recent crystal structures have provided snapshots of both active and inactive functional states of GPCRs, these structures do not reveal the mechanism by which GPCRs transition between these states. Here we propose an activation mechanism for the β 2 -adrenergic receptor, a prototypical GPCR, based on atomic-level simulations in which an agonist-bound receptor transitions spontaneously from the active to the inactive crystallographically observed conformation. A loosely coupled allosteric network, comprising three regions that can each switch individually between multiple distinct conformations, links small perturbations at the extracellular drug-binding site to large conformational changes at the intracellular G-protein-binding site. Our simulations also exhibit an intermediate that may represent a receptor conformation to which a G protein binds during activation, and suggest that the first structural changes during receptor activation often take place on the intracellular side of the receptor, far from the drug-binding site. By capturing this fundamental signaling process in atomic detail, our results may provide a foundation for the design of drugs that control receptor signaling more precisely by stabilizing specific receptor conformations. molecular dynamics | ligand | biased signaling | functional selectivity | beta-adrenergic

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Pathway and Mechanism of Drug Binding to G-Protein-Coupled Receptors

Dror

Pan

Arlow

et al. 2012

Biophysical Journal

194

348

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Huafeng Xu

Biomolecular Simulation: A Computational Microscope for Molecular Biology

Pathway and mechanism of drug binding to G-protein-coupled receptors

Molecular dynamics---Scalable algorithms for molecular dynamics simulations on commodity clusters

Activation mechanism of theβ₂-adrenergic receptor

Pathway and Mechanism of Drug Binding to G-Protein-Coupled Receptors

Contact Info

Product

Resources

About

Huafeng Xu

Biomolecular Simulation: A Computational Microscope for Molecular Biology

Pathway and mechanism of drug binding to G-protein-coupled receptors

Molecular dynamics---Scalable algorithms for molecular dynamics simulations on commodity clusters

Activation mechanism of theβ2-adrenergic receptor

Pathway and Mechanism of Drug Binding to G-Protein-Coupled Receptors

Contact Info

Product

Resources

About

Activation mechanism of theβ₂-adrenergic receptor