Litcius/Paper detail

Motor-independent retraction of type IV pili is governed by an inherent property of the pilus filament

Jennifer L. Chlebek, Rémi Denise, Lisa Craig, Ankur B. Dalia

2021Proceedings of the National Academy of Sciences32 citationsDOIOpen Access PDF

Abstract

toxin-coregulated T4P stabilizes the filament and diminishes pilus retraction. Furthermore, alignment of pilins from the broader type IV filament (T4F) family indicated that retraction motor-independent T4P, gram-positive Com pili, and type II secretion systems generally encode larger residues within α1C oriented toward the pilus core compared to retraction motor-dependent T4P. Together, our data demonstrate that motor-independent retraction relies, in part, on the inherent instability of the pilus filament, which may be a conserved feature of diverse T4Fs. This provides evidence for a long-standing yet previously untested model in which pili retract in the absence of a motor by spontaneous depolymerization.

Topics & Concepts

PilusPilinProtein filamentFimbriae ProteinsBiologyVibrio choleraeBiophysicsMicrobiologyGeneticsEscherichia coliGeneBacteriaVibrio bacteria research studiesBacterial biofilms and quorum sensingBacterial Genetics and Biotechnology