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Atomistic modeling of lysophospholipids from the Campylobacter jejuni lipidome

Atomistic modeling of lysophospholipids from the Campylobacter jejuni lipidome
Atomistic modeling of lysophospholipids from the Campylobacter jejuni lipidome
Lysophospholipids are an important class of lipids in both prokaryotic and eukaryotic organisms. These lipids typically constitute a very small proportion (<1%) of the bacterial lipidome but can constitute 20%–45% of the Campylobacter jejuni lipidome under stress conditions. It is thus of importance to include these lipids in model C. jejuni membrane simulations for an accurate representation of the lipidic complexity of these systems. Here, we present atomistic models for four lysophospholipids from the C. jejuni lipidome, each derived from existing phospholipid models. Herein, we use molecular dynamics simulations to evaluate the ability of these models to reproduce the expected micellar, hexagonal, and lamellar phases at varying levels of hydration. Mixtures of phospholipids and lysophospholipids emulating the C. jejuni lipidome under ideal growth conditions were found to self-assemble into bilayers in solution. The properties of these mixed bilayers were compared with those containing only phospholipids: the presence of the selected lysophospholipids causes a subtle thinning of the bilayer and a reduction in area per lipid, but no significant change in lipid diffusion. We further test the mixed bilayer model running simulations in which a native inner membrane protein is embedded within the bilayer. Finally, we show that lysophospholipids facilitate the formation of pores in the membrane, with lysophospholipid-containing bilayers more susceptible to electroporation than those containing only phospholipids.
0006-3495
3227 - 3243
Brandner, Astrid F.
e15d5c1c-2e5c-4697-9363-99f8732c7d9f
Newman, Kahlan
7fccd66d-2aa1-4dd6-b477-2ad528389f83
Essex, Jonathan W.
1f409cfe-6ba4-42e2-a0ab-a931826314b5
Khalid, Syma
90fbd954-7248-4f47-9525-4d6af9636394
Brandner, Astrid F.
e15d5c1c-2e5c-4697-9363-99f8732c7d9f
Newman, Kahlan
7fccd66d-2aa1-4dd6-b477-2ad528389f83
Essex, Jonathan W.
1f409cfe-6ba4-42e2-a0ab-a931826314b5
Khalid, Syma
90fbd954-7248-4f47-9525-4d6af9636394

Brandner, Astrid F., Newman, Kahlan, Essex, Jonathan W. and Khalid, Syma (2025) Atomistic modeling of lysophospholipids from the Campylobacter jejuni lipidome. Biophysical Journal, 124 (19), 3227 - 3243. (doi:10.1016/j.bpj.2025.08.024).

Record type: Article

Abstract

Lysophospholipids are an important class of lipids in both prokaryotic and eukaryotic organisms. These lipids typically constitute a very small proportion (<1%) of the bacterial lipidome but can constitute 20%–45% of the Campylobacter jejuni lipidome under stress conditions. It is thus of importance to include these lipids in model C. jejuni membrane simulations for an accurate representation of the lipidic complexity of these systems. Here, we present atomistic models for four lysophospholipids from the C. jejuni lipidome, each derived from existing phospholipid models. Herein, we use molecular dynamics simulations to evaluate the ability of these models to reproduce the expected micellar, hexagonal, and lamellar phases at varying levels of hydration. Mixtures of phospholipids and lysophospholipids emulating the C. jejuni lipidome under ideal growth conditions were found to self-assemble into bilayers in solution. The properties of these mixed bilayers were compared with those containing only phospholipids: the presence of the selected lysophospholipids causes a subtle thinning of the bilayer and a reduction in area per lipid, but no significant change in lipid diffusion. We further test the mixed bilayer model running simulations in which a native inner membrane protein is embedded within the bilayer. Finally, we show that lysophospholipids facilitate the formation of pores in the membrane, with lysophospholipid-containing bilayers more susceptible to electroporation than those containing only phospholipids.

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Accepted/In Press date: 25 August 2025
e-pub ahead of print date: 27 August 2025
Additional Information: Publisher Copyright: © 2025 The Authors
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Identifiers

Local EPrints ID: 505946
URI: http://eprints.soton.ac.uk/id/eprint/505946
DOI: doi:10.1016/j.bpj.2025.08.024
ISSN: 0006-3495
PURE UUID: 1a4f4327-cf8b-42af-a222-049503ff18f1
ORCID for Jonathan W. Essex: ORCID iD orcid.org/0000-0003-2639-2746
ORCID for Syma Khalid: ORCID iD orcid.org/0000-0002-3694-5044

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Date deposited: 23 Oct 2025 17:06
Last modified: 24 Oct 2025 01:34

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Contributors

Author: Astrid F. Brandner
Author: Kahlan Newman
Author: Jonathan W. Essex ORCID iD
Author: Syma Khalid ORCID iD

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