Deciphering Single-Bacterium Adhesion Behavior Modulated by Extracellular Electron Transfer

For bacterial adhesion and biofilm formation, a thorough understanding of the mechanism and effective modulating is lacking due to the complex extracellular electron transfer (EET) at bacteria-surface interfaces. Here, we explore the adhesion behavior of a model electroactive bacteria under various metabolic conditions by an integrated electrochemical single-cell force microscopy system. A nonlinear model between bacterial adhesion force and electric field intensity is established, which provides a theoretical foundation for precise tuning of bacterial adhesion strength by the surface potential and the direction and flux of electron flow. In particular, based on quantitative analyses with equivalent charge distribution modeling and wormlike chain numerical simulations, it is demonstrated that the chain conformation and unfolding events of outer membrane appendages are dominantly impacted by the dynamic bacterial EET processes. This reveals how the anisotropy of bacterial conductive structure can translate into the desired adhesion behavior in different scenarios.

Automated summary

The study investigates the adhesion behavior of electroactive bacteria under various metabolic conditions using an integrated electrochemical single-cell force microscopy system. It establishes a nonlinear model between bacterial adhesion force and electric field intensity, and demonstrates how the EET processes impact the conformation and unfolding events of outer membrane appendages. The research reveals how the anisotropy of bacterial conductive structure translates into desired adhesion behavior in different scenarios.