Antidepressants are modifiers of lipid bilayer properties

Kapoor, Ruchi; Peyear, Thasin; Koeppe, Roger E.; Andersen, Olaf S.

doi:10.1085/jgp.201812263

Cited by 51 publications

(78 citation statements)

References 87 publications

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“…It is increasingly recognized that the biophysical properties of the membrane, whether in physiological or in vitro conditions, influence the structure and function of many membrane‐associated proteins . One reason is that the molecular mechanisms of membrane proteins often entail transient or persistent deformations in the surrounding membrane; thus, alteration of the elastic properties or natural curvature of these membranes, through variations in their lipid composition, is one way to regulate protein activity.…”

Section: Resultsmentioning

confidence: 99%

Direct Derivation of Free Energies of Membrane Deformation and Other Solvent Density Variations From Enhanced Sampling Molecular Dynamics

2019

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We report a methodology to calculate the free energy of a shape transformation in a lipid membrane directly from a molecular dynamics simulation. The bilayer need not be homogeneous or symmetric and can be atomically detailed or coarse grained. The method is based on a collective variable that quantifies the similarity between the membrane and a set of predefined density distributions. Enhanced sampling of this "Multi-Map" variable re-shapes the bilayer and permits the derivation of the corresponding potential of mean force. Calculated energies thus reflect the dynamic interplay of atoms and molecules, rather than postulated effects. Evaluation of deformations of different shape, amplitude, and range demonstrates that the macroscopic bending modulus assumed by the Helfrich-Canham model is increasingly unsuitable below the 100-Å scale. In this range of major biological significance, direct free-energy calculations reveal a much greater plasticity. We also quantify the stiffening effect of cholesterol on bilayers of different composition and compare with experiments. Lastly, we illustrate how this approach facilitates analysis of other solvent reorganization processes, such as hydrophobic hydration. Published 2019. This article is a U.S. Government work and is in the public domain in the USA.

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Section: Resultsmentioning

confidence: 99%

Direct Derivation of Free Energies of Membrane Deformation and Other Solvent Density Variations From Enhanced Sampling Molecular Dynamics

2019

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“…Therefore, both the vesicular and the plasma membranes (near the release sites) are exposed to a considerable amount of serotonin. Small amphipathic molecules, for example, specific anesthetics, are known to alter the physical properties of the membrane, such as membrane fluidity [26][27][28][29][30] . If serotonin also does so, then that in turn can affect cellular functions, including membrane protein function, membrane affinity of other molecules as a prerequisite for subsequent receptor binding, and key cellular processes such as exocytosis and endocytosis.…”

Section: Mainmentioning

confidence: 99%

Receptor-independent membrane mediated pathways of serotonin action

Dey

Surendran

Enberg

et al. 2020

Preprint

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AbstractSerotonin is a neurotransmitter as well as a somatic signaling molecule, and the serotonergic system is a major target for psychotropic drugs. Serotonin, together with a few related neurotransmitters, has recently been found to exhibit an unexpectedly high lipid membrane affinity1–3. It has been conjectured that extrasynaptic serotonin can diffuse in the lipid membrane to efficiently reach remote receptors (and receptors with buried ligand-binding sites)4, providing a mechanism for the diffuse ‘volume’ neurotransmission that serotonin is capable of5–10. Here we show that membrane binding by serotonin can directly modulate membrane properties and cellular function, independent of its receptor-mediated actions. Atomic force microscopy shows that serotonin binding makes artificial lipid bilayers softer. It induces nucleation of liquid disordered domains inside the raft-like liquid-ordered domains in a ternary bilayer displaying phase separation. Solid-state NMR spectroscopy corroborates this data, revealing a rather homogeneous decrease in the order parameter of the lipid chains in the presence of serotonin. In the RN46A immortalized serotonergic neuronal cell line, extracellular serotonin enhances transferrin receptor endocytosis, an action exerted even in the presence of both broad-spectrum serotonin receptor and transporter inhibitors. Similarly, it increases the binding and internalization of Islet Amyloid Polypeptide (IAPP) oligomers, suggesting a connection between serotonin, which is co-secreted with IAPP by pancreatic beta cells, and the cellular effects of IAPP. Our results uncover a hitherto unknown serotonin-bilayer interaction that can potentiate key cellular processes in a receptor-independent fashion. Therefore, some pathways of serotonergic action may escape potent pharmaceutical agents designed for serotonin transporters or receptors. Conversely, bio-orthogonal serotonin-mimetics may provide a new class of cell-membrane modulators.

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“…[20] Small amphipathic molecules, for example,s pecific anesthetics, are knownt oa lter the physical properties of the membrane, such as membrane fluidity. [21][22][23][24][25] It has also been shown that isothermal compressibility of lipid monolayers can be alteredb ys mall serotonin-related molecules (such as melatonin) at % 1mm concentration, and even by serotonin at higher concentrations. [26] Furthermore, serotonin binding to raft-like mixed model membranes was shown to alter domain size.…”

Section: Introductionmentioning

confidence: 99%

Altered Membrane Mechanics Provides a Receptor‐Independent Pathway for Serotonin Action

Dey

Surendran

Engberg

et al. 2021

Chemistry A European J

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Serotonin, an importants ignalingm olecule in humans, has an unexpectedly high lipid membrane affinity. The significance of this finding has evokedc onsiderable speculation. Here we show that membrane binding by serotonin can directly modulate membrane properties and cellular function, providing an activity pathway completelyi ndependent of serotonin receptors. Atomic force microscopy shows that serotonin makes artificial lipid bilayers softer,a nd inducesn ucleation of liquid disordered domains inside the raft-likel iquid-ordered domains. Solid-state NMR spectrosco-py corroborates this data at the atomic level,r evealing ah omogeneous decrease in the order parameter of the lipid chainsi nt he presence of serotonin. In the RN46A immortalized serotonergicn euronal cell line, extracellular serotonin enhances transferrin receptor endocytosis, even in the presence of broad-spectrum serotonin receptor and transporter inhibitors. Similarly,i ti ncreases the membrane binding and internalizationo fo ligomeric peptides. Our resultsu ncover a mode of serotonin-membrane interaction that can potentiate key cellular processes in ar eceptor-independent fashion.

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Antidepressants are modifiers of lipid bilayer properties

Cited by 51 publications

References 87 publications

Direct Derivation of Free Energies of Membrane Deformation and Other Solvent Density Variations From Enhanced Sampling Molecular Dynamics

Direct Derivation of Free Energies of Membrane Deformation and Other Solvent Density Variations From Enhanced Sampling Molecular Dynamics

Receptor-independent membrane mediated pathways of serotonin action

Altered Membrane Mechanics Provides a Receptor‐Independent Pathway for Serotonin Action

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