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AFM Unravels the Unique Adhesion Properties of the <i>Caulobacter</i> Type IVc Pilus Nanomachine

Johann Mignolet, Albertus Viljoen, Marion Mathelié‐Guinlet, Felipe Viela, Claire Valotteau, Yves F. Dufrêne

2021Nano Letters19 citationsDOIOpen Access PDF

Abstract

Bacterial pili are proteinaceous motorized nanomachines that play various functional roles including surface adherence, bacterial motion, and virulence. The surface-contact sensor type IVc (or Tad) pilus is widely distributed in both Gram-positive and Gram-negative bacteria. In Caulobacter crescentus, this nanofilament, though crucial for surface colonization, has never been thoroughly investigated at the molecular level. As Caulobacter assembles several surface appendages at specific stages of the cell cycle, we designed a fluorescence-based screen to selectively study single piliated cells and combined it with atomic force microscopy and genetic manipulation to quantify the nanoscale adhesion of the type IVc pilus to hydrophobic substrates. We demonstrate that this nanofilament exhibits high stickiness compared to the canonical type IVa/b pili, resulting mostly from multiple hydrophobic interactions along the fiber length, and that it features nanospring mechanical properties. Our findings may be helpful to better understand the structure–function relationship of bacterial pilus nanomachines.

Topics & Concepts

PilusCaulobacter crescentusAdhesionBiophysicsAtomic force microscopyNanotechnologyChemistryFluorescence microscopeBacteriaCell biologyVirulenceBiologyMaterials scienceFluorescenceOpticsBacterial proteinPhysicsBiochemistryGeneticsOrganic chemistryGeneBacterial biofilms and quorum sensingBiochemical and Structural CharacterizationBacteriophages and microbial interactions
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