Multiple pilus motors cooperate for persistent bacterial movement in two dimensions.
Holz C, Opitz D, Greune L, Kurre R, Koomey M, Schmidt MA, Maier B
Research article (journal)Abstract
In various bacterial species surface motility is mediated by cycles of type IV pilus motor elongation, adhesion, and retraction, but it is unclear whether bacterial movement follows a random walk. Here we show that the correlation time of persistent movement in Neisseria gonorrhoeae increases with the number of pili. The unbinding force of individual pili from the surface F=10 pN was considerably lower than the stalling force F>100 pN, suggesting that density, force, and adhesive properties of the pilus motor enable a tug-of-war mechanism for bacterial movement.
Details about the publication
Journal: Physical Review Letters (Phys. Rev. Lett.)
Volume: 104
Issue: 17
Status: Published
Release year: 2010
Language in which the publication is written: English
Keywords: Neisseria gonorrhoeae; Fimbriae Bacterial; Phosphatidylcholines; Biomechanics; Serum Albumin Bovine; Bacterial Adhesion; Models Biological; Movement; Neisseria gonorrhoeae; Fimbriae Bacterial; Phosphatidylcholines; Biomechanics; Serum Albumin Bovine; Bacterial Adhesion; Models Biological; Movement
Authors from the University of Münster
| Greune, Lieselotte | Centre for Molecular Biology of Inflammation |
| Holz, Claudia | Institute for Molecular Cell Biology |
| Kurre, Rainer | Institute for Molecular Cell Biology |
| Maier, Berenike | Institute for Molecular Cell Biology |
| Opitz, Dirk | Institute for Molecular Cell Biology |
| Schmidt, M. Alexander | Institute of Infectiology |