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Upcoming Event

Capillary Attraction Underlies Bacterial Collective Dynamics.

“Water Is The Driving Force Of All Nature.” — Leonardo da Vinci


Event Details

Type
Center for Studies in Physics and Biology Seminars
Speaker(s)
Ned Wingreen, Ph.D., Howard A. Prior Professor in the Life Sciences. Professor of Molecular Biology and the Lewis-Sigler Institute for Integrative Genomics., Princeton University
Speaker bio(s)

Collective motion of active matter occurs in many living systems, such as bacterial communities, epithelial cell populations, bird flocks, and fish schools. A remarkable example can be found in the soil-dwelling bacterium Myxococcus xanthus. Key to the life cycle of M. xanthus cells is the formation of collective groups: they feed on prey in swarms and aggregate upon starvation. However, the physical mechanisms that keep M. xanthus cells together remains unclear. I’ll present a computational model to explore the role that capillary forces play in bacterial collective dynamics. The modeling results, combined with experiments, show that water menisci forming around bacteria mediate strong capillary attraction between cells. The model accounts for a variety of previously observed phases of collective dynamics as the result of a competition between cell-cell capillary attraction and cell motility. Finally, I’ll discuss the large-scale self-organization of bacterial populations and highlight the importance of capillary force in this process. Together, these results suggest that cell-cell capillary attraction provides a generic mechanism underpinning bacterial collective dynamics.

Open to
Public
Contact
Melanie Lee
Phone
(212) 327-8636
Sponsor
Melanie Lee
(212) 327-8636
leem@rockefeller.edu



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