Physical Chemistry Seminar: Professor Andreas Gahlmann, University of Virginia

Physical Chemistry Seminar: Professor Andreas Gahlmann, University of Virginia (Host: W.E. Moerner)

**This seminar is available for in-person attendance.**

"Visualizing Bacterial Physiology at High Resolution using Single-Molecule Tracking and Lattice-Light Sheet Microscopy"

About the Seminar

Our lab develops new imaging approaches for visualizing bacterial physiology in relevant contexts: We use live-cell single-molecule localization microscopy and lattice-light sheet microscopy to access 3D spatial and temporal information with high resolution. At molecular and cellular length scales, our research focuses on understanding how Gram-negative bacterial pathogens assemble and regulate the Type 3 Secretion System (T3SS) – a 7 MDa multi-protein complex that spans two, and sometimes three cellular membranes. The T3SS is used by prominent bacterial pathogens to inject effector proteins into the cytosol of eukaryotic host cells and, in aggregate, this virulence mechanism results in more than 1 million human deaths each year. At cellular and super-cellular length scales, our research focuses on visualizing the behaviors of individual bacteria inside tissue-like microbial communities. As a major component of bacterial biomass on earth, microbial communities have substantial impacts on the biogeochemistry of our planet and on the biochemistry of higher living organisms.

In the first part of my talk, I will describe how single-molecule localization and tracking microscopy in different genetic backgrounds provides a path towards understanding the molecular assembly mechanism(s) that contribute to type 3 secretion in living cells. Through computational aberration correction and numerical modeling, we determine the 3D subcellular localization and diffusive states of individual, fluorescently labeled T3SS proteins. Our results indicate that T3SS proteins pre-assemble into freely diffusing cytosolic complexes prior to binding to the membrane-spanning multi-protein complex. Determining to what extent cytosolic proteins assemble with each other in living cells provides key insights into the dynamic regulatory network that controls type 3 secretion.

In the second part of my talk, I will describe how lattice light-sheet microscopy enables non-invasive 3D imaging of microbial communities at single-cell resolution. Analyzing the resulting 3D images using a combination of computer vision and machine learning approaches enables multi-cell tracking of cell motions, cell morphologies, and cellular gene expression over time. Our goal is to apply these new imaging and image analysis approaches to understand the emerging functional capabilities of microbial communities in terms of the behavioral phenotypes of individual cells. Such knowledge can help inform new strategies for controlling microbial community growth and harness the metabolic potential of the microbial world in biotechnological applications.  

About the Speaker

Andreas Gahlmann received his B.S degree in Chemistry from the University of Portland and his Ph.D. degree in Physical Chemistry from the California Institute of Technology under the supervision of Prof. Ahmed H. Zewail. Thereafter, he joined the laboratory of W.E. Moerner at Stanford University as a Swiss National Science Foundation postdoctoral fellow.  

Prof. Gahlmann is an Assistant Professor of Chemistry and of Molecular Physiology & Biological Physics at the University of Virginia. The overarching goal of research in the Gahlmann laboratory is to develop and apply nanoscale microscopy methods for 3D single-molecule localization and super-resolution imaging in live bacterial cells and microbial communities. At molecular and cellular length scales, research focuses on understanding how Gram-negative bacterial pathogens assemble and regulate Type 3 Secretion Systems (T3SSs) that inject bacterial proteins into the cytosol of eukaryotic host cells. At cellular and super-cellular length scales, research focuses on visualizing the behaviors of individual bacteria in 3-dimensional cellular communities at living microbe-human host interfaces.

In his free time, Prof. Gahlmann enjoys playing tennis, skiing, and working on home improvement projects.