Engineering cardiolipin binding to an artificial membrane protein reveals determinants for lipid-mediated stabilization

Mia L Abramsson; Robin A Corey; Jan L Skerle; Louise J Persson; Olivia Anden; Abraham O Oluwole; Rebecca J Howard; Erik Lindahl; Carol V Robinson; Kvido Strisovsky; Erik G Marklund; David Drew; Phillip J Stansfeld; Michael Landreh; Heedeok Hong

doi:10.7554/elife.104237

Engineering cardiolipin binding to an artificial membrane protein reveals determinants for lipid-mediated stabilization

Mia L Abramsson, Robin A Corey^*, Jan L Skerle, Louise J Persson, Olivia Anden, Abraham O Oluwole, Rebecca J Howard, Erik Lindahl, Carol V Robinson, Kvido Strisovsky, Erik G Marklund, David Drew, Phillip J Stansfeld^*, Michael Landreh^*, Heedeok Hong (Editor)

^*Corresponding author for this work

School of Physiology, Pharmacology & Neuroscience

Research output: Contribution to journal › Article (Academic Journal) › peer-review

Abstract

Integral membrane proteins carry out essential functions in the cell, and their activities are often modulated by specific protein-lipid interactions in the membrane. Here, we elucidate the intricate role of cardiolipin (CDL), a regulatory lipid, as a stabilizer of membrane proteins and their complexes. Using the in silico-designed model protein TMHC4_R (ROCKET) as a scaffold, we employ a combination of molecular dynamics simulations and native mass spectrometry to explore the protein features that facilitate preferential lipid interactions and mediate stabilization. We find that the spatial arrangement of positively charged residues as well as local conformational flexibility are factors that distinguish stabilizing from non-stabilizing CDL interactions. However, we also find that even in this controlled, artificial system, a clear-cut distinction between binding and stabilization is difficult to attain, revealing that overlapping lipid contacts can partially compensate for the effects of binding site mutations. Extending our insights to naturally occurring proteins, we identify a stabilizing CDL site within the E. coli rhomboid intramembrane protease GlpG and uncover its regulatory influence on enzyme substrate preference. In this work, we establish a framework for engineering functional lipid interactions, paving the way for the design of proteins with membrane-specific properties or functions.

Original language	English
Article number	RP104237
Number of pages	21
Journal	eLife
Volume	14
DOIs	https://doi.org/10.7554/elife.104237
Publication status	Published - 30 Apr 2025

Keywords

membrane protein
lipid binding
E. coli
mass spectrometry

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Abramsson, M. L., Corey, R. A., Skerle, J. L., Persson, L. J., Anden, O., Oluwole, A. O., Howard, R. J., Lindahl, E., Robinson, C. V., Strisovsky, K., Marklund, E. G., Drew, D., Stansfeld, P. J., Landreh, M., & Hong, H. (Ed.) (2025). Engineering cardiolipin binding to an artificial membrane protein reveals determinants for lipid-mediated stabilization. eLife, 14, Article RP104237. https://doi.org/10.7554/elife.104237

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title = "Engineering cardiolipin binding to an artificial membrane protein reveals determinants for lipid-mediated stabilization",

abstract = "Integral membrane proteins carry out essential functions in the cell, and their activities are often modulated by specific protein-lipid interactions in the membrane. Here, we elucidate the intricate role of cardiolipin (CDL), a regulatory lipid, as a stabilizer of membrane proteins and their complexes. Using the in silico-designed model protein TMHC4\_R (ROCKET) as a scaffold, we employ a combination of molecular dynamics simulations and native mass spectrometry to explore the protein features that facilitate preferential lipid interactions and mediate stabilization. We find that the spatial arrangement of positively charged residues as well as local conformational flexibility are factors that distinguish stabilizing from non-stabilizing CDL interactions. However, we also find that even in this controlled, artificial system, a clear-cut distinction between binding and stabilization is difficult to attain, revealing that overlapping lipid contacts can partially compensate for the effects of binding site mutations. Extending our insights to naturally occurring proteins, we identify a stabilizing CDL site within the E. coli rhomboid intramembrane protease GlpG and uncover its regulatory influence on enzyme substrate preference. In this work, we establish a framework for engineering functional lipid interactions, paving the way for the design of proteins with membrane-specific properties or functions.",

keywords = "membrane protein, lipid binding, E. coli, mass spectrometry",

author = "Abramsson, \{Mia L\} and Corey, \{Robin A\} and Skerle, \{Jan L\} and Persson, \{Louise J\} and Olivia Anden and Oluwole, \{Abraham O\} and Howard, \{Rebecca J\} and Erik Lindahl and Robinson, \{Carol V\} and Kvido Strisovsky and Marklund, \{Erik G\} and David Drew and Stansfeld, \{Phillip J\} and Michael Landreh and Heedeok Hong",

year = "2025",

month = apr,

day = "30",

doi = "10.7554/elife.104237",

language = "English",

volume = "14",

journal = "eLife",

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Abramsson, ML, Corey, RA, Skerle, JL, Persson, LJ, Anden, O, Oluwole, AO, Howard, RJ, Lindahl, E, Robinson, CV, Strisovsky, K, Marklund, EG, Drew, D, Stansfeld, PJ, Landreh, M & Hong, H (ed.) 2025, 'Engineering cardiolipin binding to an artificial membrane protein reveals determinants for lipid-mediated stabilization', eLife, vol. 14, RP104237. https://doi.org/10.7554/elife.104237

TY - JOUR

T1 - Engineering cardiolipin binding to an artificial membrane protein reveals determinants for lipid-mediated stabilization

AU - Abramsson, Mia L

AU - Corey, Robin A

AU - Skerle, Jan L

AU - Persson, Louise J

AU - Anden, Olivia

AU - Oluwole, Abraham O

AU - Howard, Rebecca J

AU - Lindahl, Erik

AU - Robinson, Carol V

AU - Strisovsky, Kvido

AU - Marklund, Erik G

AU - Drew, David

AU - Stansfeld, Phillip J

AU - Landreh, Michael

A2 - Hong, Heedeok

PY - 2025/4/30

Y1 - 2025/4/30

N2 - Integral membrane proteins carry out essential functions in the cell, and their activities are often modulated by specific protein-lipid interactions in the membrane. Here, we elucidate the intricate role of cardiolipin (CDL), a regulatory lipid, as a stabilizer of membrane proteins and their complexes. Using the in silico-designed model protein TMHC4_R (ROCKET) as a scaffold, we employ a combination of molecular dynamics simulations and native mass spectrometry to explore the protein features that facilitate preferential lipid interactions and mediate stabilization. We find that the spatial arrangement of positively charged residues as well as local conformational flexibility are factors that distinguish stabilizing from non-stabilizing CDL interactions. However, we also find that even in this controlled, artificial system, a clear-cut distinction between binding and stabilization is difficult to attain, revealing that overlapping lipid contacts can partially compensate for the effects of binding site mutations. Extending our insights to naturally occurring proteins, we identify a stabilizing CDL site within the E. coli rhomboid intramembrane protease GlpG and uncover its regulatory influence on enzyme substrate preference. In this work, we establish a framework for engineering functional lipid interactions, paving the way for the design of proteins with membrane-specific properties or functions.

AB - Integral membrane proteins carry out essential functions in the cell, and their activities are often modulated by specific protein-lipid interactions in the membrane. Here, we elucidate the intricate role of cardiolipin (CDL), a regulatory lipid, as a stabilizer of membrane proteins and their complexes. Using the in silico-designed model protein TMHC4_R (ROCKET) as a scaffold, we employ a combination of molecular dynamics simulations and native mass spectrometry to explore the protein features that facilitate preferential lipid interactions and mediate stabilization. We find that the spatial arrangement of positively charged residues as well as local conformational flexibility are factors that distinguish stabilizing from non-stabilizing CDL interactions. However, we also find that even in this controlled, artificial system, a clear-cut distinction between binding and stabilization is difficult to attain, revealing that overlapping lipid contacts can partially compensate for the effects of binding site mutations. Extending our insights to naturally occurring proteins, we identify a stabilizing CDL site within the E. coli rhomboid intramembrane protease GlpG and uncover its regulatory influence on enzyme substrate preference. In this work, we establish a framework for engineering functional lipid interactions, paving the way for the design of proteins with membrane-specific properties or functions.

KW - membrane protein

KW - lipid binding

KW - E. coli

KW - mass spectrometry

U2 - 10.7554/elife.104237

DO - 10.7554/elife.104237

M3 - Article (Academic Journal)

SN - 2050-084X

VL - 14

JO - eLife

JF - eLife

M1 - RP104237

ER -

Engineering cardiolipin binding to an artificial membrane protein reveals determinants for lipid-mediated stabilization

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Keywords

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