Molecular Mechanism of P53 Peptide Permeation through Lipid Membranes from Solid-State NMR Spectroscopy and Molecular Dynamics Simulations.
Mingyue LiJianguo LiXingyu LuRyan SchroderArun ChandramohanW Peter WuelfingAllen C TempletonWei XuMarian GindyFilippos KesisoglouJing LingTomi SawyerChandra Shekhar VermaAnthony W PartridgeYongchao SuPublished in: Journal of the American Chemical Society (2024)
Macrocyclic peptides show promise in targeting high-value therapeutically relevant binding sites due to their high affinity and specificity. However, their clinical application is often hindered by low membrane permeability, which limits their effectiveness against intracellular targets. Previous studies focused on peptide conformations in various solvents, leaving a gap in understanding their interactions with and translocation through lipid bilayers. Addressing this, our study explores the membrane interactions of stapled peptides, a subclass of macrocyclic peptides, using solid-state nuclear magnetic resonance (ssNMR) spectroscopy and molecular dynamics (MD) simulations. We conducted ssNMR measurements on ATSP-7041M, a prototypical stapled peptide, to understand its interaction with lipid membranes, leading to an MD-informed model for peptide membrane permeation. Our findings reveal that ATSP-7041M adopts a stable α-helical structure upon membrane binding, facilitated by a cation-π interaction between its phenylalanine side chain and the lipid headgroup. This interaction makes the membrane-bound state energetically favorable, facilitating membrane affinity and insertion. The bound peptide displayed asymmetric insertion depths, with the C-terminus penetrating deeper (approximately 9 Å) than the N-terminus (approximately 4.3 Å) relative to the lipid headgroups. Contrary to expectations, peptide dynamics was not hindered by membrane binding and exhibited rapid motions similar to cell-penetrating peptides. These dynamic interactions and peptide-lipid affinity appear to be crucial for membrane permeation. MD simulations indicated a thermodynamically stable transmembrane conformation of ATSP-7041M, reducing the energy barrier for translocation. Our study offers an in silico view of ATSP-7041M's translocation from the extracellular to the intracellular region, highlighting the significance of peptide-lipid interactions and dynamics in enabling peptide transit through membranes.
Keyphrases
- molecular dynamics
- solid state
- molecular dynamics simulations
- magnetic resonance
- fatty acid
- systematic review
- molecular docking
- randomized controlled trial
- computed tomography
- density functional theory
- mesenchymal stem cells
- cell therapy
- reactive oxygen species
- amino acid
- magnetic resonance imaging
- gene expression
- endothelial cells
- bone marrow
- transcription factor
- big data
- high resolution
- drug delivery
- ionic liquid
- cancer therapy
- deep learning