Membrane lipids drive formation of KRAS4b-RAF1 RBDCRD nanoclusters on the membrane.
Rebika ShresthaTimothy S CarpenterQue N VanConstance AgamasuMarco TonelliFikret AydinDe ChenGulcin GultenJames N GlosliCésar A LópezTomas OppelstrupChris NealeSandrasegaram GnanakaranWilliam K GilletteHelgi I IngólfssonFelice C LightstoneAndrew G StephenFrederick H StreitzDwight V NissleyThomas J TurbyvillePublished in: Communications biology (2024)
The oncogene RAS, extensively studied for decades, presents persistent gaps in understanding, hindering the development of effective therapeutic strategies due to a lack of precise details on how RAS initiates MAPK signaling with RAF effector proteins at the plasma membrane. Recent advances in X-ray crystallography, cryo-EM, and super-resolution fluorescence microscopy offer structural and spatial insights, yet the molecular mechanisms involving protein-protein and protein-lipid interactions in RAS-mediated signaling require further characterization. This study utilizes single-molecule experimental techniques, nuclear magnetic resonance spectroscopy, and the computational Machine-Learned Modeling Infrastructure (MuMMI) to examine KRAS4b and RAF1 on a biologically relevant lipid bilayer. MuMMI captures long-timescale events while preserving detailed atomic descriptions, providing testable models for experimental validation. Both in vitro and computational studies reveal that RBDCRD binding alters KRAS lateral diffusion on the lipid bilayer, increasing cluster size and decreasing diffusion. RAS and membrane binding cause hydrophobic residues in the CRD region to penetrate the bilayer, stabilizing complexes through β-strand elongation. These cooperative interactions among lipids, KRAS4b, and RAF1 are proposed as essential for forming nanoclusters, potentially a critical step in MAP kinase signal activation.
Keyphrases
- wild type
- single molecule
- protein protein
- fatty acid
- small molecule
- atomic force microscopy
- living cells
- high resolution
- binding protein
- sensitive detection
- fluorescent probe
- energy transfer
- deep learning
- oxidative stress
- signaling pathway
- genome wide
- minimally invasive
- immune response
- amino acid
- ionic liquid
- quantum dots
- single cell
- high throughput
- dendritic cells
- optical coherence tomography
- case control
- dna methylation
- transcription factor
- high density