23 July 2026, 15:00
Intermittent active motion of bacteria in complex environments
Description AbstractThe study of bacterial swimming is one of the most classical and fundamental approaches to understanding motility at the cellular level It helps us solve not only the biological puzzles of how microorganisms spread infections or communicate with each other but also pave the way to un blackboxing physical phenomenon far from equilibrium like anomalous diffusion and pattern formation While bacterial motility has been well characterized in liquid environments only little is known about how bacteria navigate complex environments mimicking their natural habitats like soil mucus or tissues where they generally face strong confinements and heterogenities In this talk I will discuss how we can combine experimental analysis using the soil bacterium Pseudomonas putida and active particle modeling to examine migration patterns of bacteria in disordered environments agar gel which leads to remarkable motility characteristics like transient subdiffusion and ergodicity breaking Next I will address another paradoxical question in this direction how can bacteria perform chemotaxis in a confined environment providing insights about the role of signaling in active transport Finally I will introduce a coarse grained model that we are working on recently where the non reciprocal interplay of two chemicals coupled with a Keller Segel like motility of microorganisms leads to a prolific variety of patterns ranging from different types of novel phase separation to travelling waves breathing spots and spiral waves About the speakerAgniva Datta is a doctoral researcher and physicist at the University of Potsdam in Germany He works within the Institute of Physics and Astronomy and specializes in the fields of biological physics statistical physics nonlinear dynamics and active matter... AbstractThe study of bacterial swimming is one of the most classical and fundamental approaches to understanding motility at the cellular level. It helps us solve not only the biological puzzles of how microorganisms spread infections or communicate with each other, but also pave the way to "un-blackboxing" physical phenomenon far from equilibrium like anomalous diffusion and pattern formation. While bacterial motility has been well characterized in liquid environments, only little is known about how bacteria navigate complex environments mimicking their natural habitats like soil, mucus or tissues, where they generally face strong confinements and heterogenities. In this talk, I will discuss how we can combine experimental analysis using the soil bacterium Pseudomonas putida and active particle modeling to examine migration patterns of bacteria in disordered environments (agar...
Speaker(s): Germany, University of Potsdam, Agniva Datta
Host: Anna Erzberger
Place: Room 13-518 a + b
EMBL Heidelberg
Additional information
Abstract
The study of bacterial swimming is one of the most classical and fundamental approaches to understanding motility at the cellular level. It helps us solve not only the biological puzzles of how microorganisms spread infections or communicate with each other, but also pave the way to "un-blackboxing" physical phenomenon far from equilibrium like anomalous diffusion and pattern formation. While bacterial motility has been well characterized in liquid environments, only little is known about how bacteria navigate complex environments mimicking their natural habitats like soil, mucus or tissues, where they generally face strong confinements and heterogenities. In this talk, I will discuss how we can combine experimental analysis using the soil bacterium Pseudomonas putida and active particle modeling to examine migration patterns of bacteria in disordered environments (agar gel), which leads to remarkable motility characteristics like transient subdiffusion and ergodicity breaking. Next, I will address another paradoxical question in this direction: how can bacteria perform chemotaxis in a confined environment, providing insights about the role of signaling in active transport. Finally, I will introduce a coarse-grained model that we are working on recently, where the non-reciprocal interplay of two chemicals, coupled with a Keller–Segel-like motility of microorganisms, leads to a prolific variety of patterns, ranging from different types of novel phase separation to travelling waves, breathing spots and spiral waves. ].
About the speaker
Agniva Datta is a doctoral researcher and physicist at the University of Potsdam in Germany. He works within the Institute of Physics and Astronomy and specializes in the fields of biological physics, statistical physics, nonlinear dynamics, and active matter.].