Impact of Hydrodynamic Interactions on the Kinetic Pathway of Protein Folding.

Protein folding is a fundamental process critical to cellular function and human health, but it remains a grand challenge in biophysics. Hydrodynamic interaction (HI) plays a vital role in the self-organization of soft and biological materials, yet its role in protein folding is not fully understood despite folding occurring in a fluid environment. Here, we use the fluid particle dynamics method to investigate many-body hydrodynamic couplings between amino acid residues and fluid motion in the folding kinetics of a coarse-grained four-α-helices bundle protein. Our results reveal that HI helps select fast folding pathways to the native state without being kinetically trapped, significantly speeding up the folding kinetics compared to its absence. First, the directional flow along the protein backbone expedites protein collapse. Then, the incompressibility-induced squeezing flow effects retard the accumulation of non-native hydrophobic contacts, thus preventing the protein from being trapped in local energy minima during the conformational search of the native structure. We also find that the significance of HI in folding kinetics depends on temperature, with a pronounced effect under biologically relevant conditions. Our findings suggest that HI, particularly the short-range squeezing effect, may be crucial in avoiding protein misfolding.

• Publication year

  2024

• Venue

  Physical Review Letters

• Publication date

  2024-03-27

• Fields of study

  Biology, Medicine, Physics

• Identifiers
  DOI 10.1103/physrevlett.132.138402PMID 38613272
• External record

  Open on Semantic Scholar

• Source metadata

  Semantic Scholar, PubMed

• No claims are published for this paper.

• No concepts are published for this paper.

• Hydrodynamic Effects on the Collapse Kinetics of Flexible Polyelectrolytes.

  2024cited by this paper
• Enhanced statistical sampling reveals microscopic complexity in the talin mechanosensor folding energy landscape

  2022cited by this paper
• State-of-the-Art Estimation of Protein Model Accuracy Using AlphaFold

  2022cited by this paper
• Impact of Inverse Squeezing Flow on the Self-Assembly of Oppositely Charged Colloidal Particles under Electric Field.

  2022cited by this paper
• Power-law coarsening in network-forming phase separation governed by mechanical relaxation

  2021cited by this paper
• Highly accurate protein structure prediction with AlphaFold

  2021cited by this paper
• Fluids at the Nanoscale: From Continuum to Subcontinuum Transport

  2020cited by this paper
• Numerical prediction of colloidal phase separation by direct computation of Navier–Stokes equation

  2019cited by this paper
• The singular hydrodynamic interactions between two spheres in Stokes flow

  2018cited by this paper
• Simulations of sheared dense noncolloidal suspensions: Evaluation of the role of long-range hydrodynamics

  2018cited by this paper
• Physical foundation of the fluid particle dynamics method for colloid dynamics simulation.

  2018influential reference
• Editorial overview: Protein Folding and Binding, Complexity Comes of Age.

  2017cited by this paper
• Impact of hydrodynamic interactions on protein folding rates depends on temperature.

  2017influential reference
• The nature of protein folding pathways

  2014cited by this paper
• Capturing the essence of folding and functions of biomolecules using coarse-grained models.

  2011cited by this paper
• Hydrodynamic effects in proteins

  2011influential reference
• Protein folding in the cell: challenges and progress.

  2011cited by this paper
• Theoretical perspectives on protein folding.

  2010cited by this paper
• Key role of hydrodynamic interactions in colloidal gelation.

  2010influential reference
• Challenges in protein folding simulations: Timescale, representation, and analysis.

  2010cited by this paper
• Collapse Dynamics of Copolymers in a Poor Solvent: Influence of Hydrodynamic Interactions and Chain Sequence

  2010cited by this paper
• Generic coarse-grained model for protein folding and aggregation.

  2009cited by this paper
• Striking Effects of Hydrodynamic Interactions on the Simulated Diffusion and Folding of Proteins.

  2009cited by this paper
• Hydrodynamic selection of the kinetic pathway of a polymer coil-globule transition.

  2009influential reference
• Hydrodynamic interactions in protein folding.

  2008cited by this paper
• Brownian dynamics simulation of polymer collapse in a poor solvent: influence of implicit hydrodynamic interactions.

  2008cited by this paper
• Hydrodynamic Fluctuations in Fluids and Fluid Mixtures

  2006cited by this paper
• STOKESIAN DYNAMICS

  2006cited by this paper
• Viscoelastic phase separation in soft matter: Numerical-simulation study on its physical mechanism

  2006cited by this paper
• Kinetics of the polymer collapse transition: the role of hydrodynamics.

  2005influential reference
• Roles of hydrodynamic interactions in structure formation of soft matter: protein folding as an example

  2005cited by this paper
• The competition between protein folding and aggregation: off-lattice minimalist model studies.

  2005cited by this paper
• Protein folding and misfolding

  2003cited by this paper
• Coarse-grained sequences for protein folding and design

  2003cited by this paper
• Lubrication corrections for lattice-Boltzmann simulations of particle suspensions.

  2002cited by this paper
• Polymer collapse in the presence of hydrodynamic interactions

  2002cited by this paper
• Influence of the Hydrodynamic Interaction on Kinetics and Thermodynamics of Minimal Protein Models

  2002influential reference
• Solvent effects on the collapse dynamics of polymers

  2001cited by this paper
• Introduction to Protein Science: Architecture, Function, and Genomics

  2001cited by this paper
• Simulation method of colloidal suspensions with hydrodynamic interactions: fluid particle dynamics

  2000influential reference
• Mechanisms and kinetics of beta-hairpin formation.

  2000cited by this paper
• Lubrication corrections for three-particle contribution to short-time self-diffusion coefficients in colloidal dispersions

  1999cited by this paper
• Molecular dynamics simulations of unfolding and refolding of a beta-hairpin fragment of protein G.

  1999cited by this paper
• The nucleation-collapse mechanism in protein folding: evidence for the non-uniqueness of the folding nucleus.

  1997cited by this paper
• Kinetics and thermodynamics of folding of a de novo designed four-helix bundle protein.

  1996cited by this paper
• The quickhull algorithm for convex hulls

  1996cited by this paper
• DIFFUSIVE DYNAMICS OF THE REACTION COORDINATE FOR PROTEIN FOLDING FUNNELS

  1996cited by this paper
• Kinetic and thermodynamic analysis of proteinlike heteropolymers: Monte Carlo histogram technique

  1995cited by this paper
• Kinetics of protein folding: Nucleation mechanism, time scales, and pathways

  1995cited by this paper
• The nature of folded states of globular proteins

  1992cited by this paper
• Microhydrodynamics: Principles and Selected Applications

  1991cited by this paper
• Metastability of the folded states of globular proteins.

  1990cited by this paper
• Dynamic simulation of hydrodynamically interacting particles

  1987influential reference
• Brownian dynamics with hydrodynamic interactions

  1978cited by this paper
• Variational Treatment of Hydrodynamic Interaction in Polymers

  1969cited by this paper
• Numerical Calculation of Time‐Dependent Viscous Incompressible Flow of Fluid with Free Surface

  1965cited by this paper

• Cross-linking driven collapse dynamics of polyelectrolyte single-chain in good solvents.

  2026cites this paper
• Preserving enzyme conformation and catalytic efficiency in crowded and active environments

  2025cites this paper
• Collapse and expansion kinetics of a single polyelectrolyte chain with hydrodynamic interactions.

  2024cites this paper
• Irreversibility of mesoscopic processes with hydrodynamic interactions.

  2024cites this paper
• Impact of Hydrodynamic Interactions on the Collapse-Expansion Kinetics of Nanogels

  2024cites this paper