Kingdom-specific Lipid Unsaturation Calibrates Sequence Evolution in Membrane Arm Subunits of Eukaryotic Respiratory Complexes

Overview

Journal Nat Commun

Specialty Biology

Date 2025 Feb 27

PMID 40016208

Authors

Pooja Gupta

Sristi Chakroborty

Arun K Rathod

K Ranjith Kumar

Shreya Bhat

Suparna Ghosh

Pallavi Rao T

Kameshwari Yele

Raman Bakthisaran

R Nagaraj

Moutusi Manna

Swasti Raychaudhuri

Affiliations

Soon will be listed here.

Abstract

Sequence evolution of protein complexes (PCs) is constrained by protein-protein interactions (PPIs). PPI-interfaces are predominantly conserved and hotspots for disease-related mutations. How do lipid-protein interactions (LPIs) constrain sequence evolution of membrane-PCs? We explore Respiratory Complexes (RCs) as a case study as these allow to compare sequence evolution in subunits exposed to both lipids in inner-mitochondrial membrane (IMM) and lipid-free aqueous matrix. We find that lipid-exposed surfaces of the IMM-subunits but not of the matrix subunits are populated with non-PPI disease-causing mutations signifying LPIs in stabilizing RCs. Further, IMM-subunits including their exposed surfaces show high intra-kingdom sequence conservation but remarkably diverge beyond. Molecular Dynamics simulation suggests contrasting LPIs of structurally superimposable but sequence-wise diverged IMM-exposed helices of Complex I (CI) subunit Ndufa1 from human and Arabidopsis depending on kingdom-specific unsaturation of cardiolipin fatty acyl chains. in cellulo assays consolidate inter-kingdom incompatibility of Ndufa1-helices due to the lipid-exposed amino acids. Plant-specific unsaturated fatty acids in human cells also trigger CI-instability. Taken together, we posit that altered LPIs calibrate sequence evolution at the IMM-arms of eukaryotic RCs.

Citing Articles

Kingdom-specific lipid unsaturation calibrates sequence evolution in membrane arm subunits of eukaryotic respiratory complexes.

Gupta P, Chakroborty S, Rathod A, Kumar K, Bhat S, Ghosh S Nat Commun. 2025; 16(1):2044.

PMID: 40016208 PMC: 11868549. DOI: 10.1038/s41467-025-57295-7.

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