# Living at the border: biophysical gateways into membrane protein insertion and folding

**Authors:** Brayan Grau, Ismael Mingarro

PMC · DOI: 10.1007/s12551-026-01408-z · 2026-02-04

## TL;DR

This paper reviews how membrane proteins fold and insert into cell membranes, focusing on the physical and energetic factors that guide these processes.

## Contribution

The paper provides a unified view of membrane protein biogenesis by integrating sequence-encoded information, molecular machinery, and membrane physics.

## Key findings

- The membrane-water interface acts as a critical energetic gateway for α-helical membrane protein folding.
- Co-translational folding within the ribosome exit tunnel influences secondary structure formation and final polypeptide behavior.
- Lipid-protein coupling and bilayer adaptability stabilize transmembrane helices and promote higher-order assembly.

## Abstract

Membrane proteins inhabit a uniquely heterogeneous environment in which folding, insertion, and assembly are inseparably coupled to the physical properties of lipid bilayers. Despite their central biological relevance, the principles governing membrane protein folding are less well defined than those for soluble proteins due to the energetic complexity of transferring polypeptide chains across, into, or along membranes. This review examines the biophysical determinants that shape the early stages of α-helical membrane protein folding, emphasizing the membrane-water interface as a critical energetic gateway. We trace the historical development of hydrophobic scales, from early solvent-based peptide measurements to membrane-translocon-derived scales, highlighting how successive refinement has revealed distinct energetic preferences for aqueous, interfacial, and fully inserted states. Building on this framework, we discuss how co-translational folding within the ribosome exit tunnel and the ribosome-translocon complex constrains secondary structure formation and modulates the final behavior of the polypeptide segment. We further analyze the contributions of intrahelical and interhelical interactions, lipid-protein coupling, and bilayer adaptability in stabilizing transmembrane helices and promoting higher-order assembly. Finally, we integrate these concepts into a unified view in which membrane protein biogenesis emerges as a continuous energy-driven process where sequence-encoded information, molecular machinery, and membrane physics converge to ensure faithful folding, topogenesis, and quality control.

## Full-text entities

- **Chemicals:** water (MESH:D014867), lipid (MESH:D008055)

## Figures

3 figures with captions in the complete paper: https://tomesphere.com/paper/PMC13031457/full.md

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Source: https://tomesphere.com/paper/PMC13031457