I. Marvels of Bacterial Behavior - History & Physics
II. Marvels of Bacterial Behavior - Molecular Machinery
Part I: Marvels of Bacterial Behavior - History & Physics
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Berg begins his lecture with a brief history of observations of bacterial motion. He then uses physics to describe the many hurdles that E. coli must overcome as it tries to swim up or down a chemical gradient. For instance, an entity as tiny as E. coli is constantly buffeted by Brownian motion and can neither stay still nor swim in a straight line. Then there is the question of how E. coli senses a gradient and translates that information into a change in its direction of movement. And finally, how does E. coli use its flagella to generate thrust at all?
In Part 2, Berg explains that E. coli travels using a series of runs, when it moves in a straight line, and tumbles, when it changes direction. During a run, all of the flagella are moving counterclockwise in a tight bundle. During a tumble, one or more flagella switch to a clockwise movement and disengage from the bundle causing a change in the swimming direction. The motor that drives the rotation of the flagella is an amazing structure made of about 20 different protein parts. Berg tells us that chemosensory receptors on the cell surface detect a chemical gradient and transfer this information, via protein phosphorylation, to the motor. This chemical modification determines the direction of motor rotation and, hence, the direction the E. coli swims. An amazing system that E. coli has been perfecting for millions of years!
Howard Berg is the Herchel Smith Professor of Physics and a Professor of Molecular and Cellular Biology at Harvard University and a member of the Rowland Institute for Science at Harvard. He received his B.S. in Chemistry from the California Institute of Technology and his Ph.D. in Chemical Physics from Harvard University. Berg was on the faculty of the University of Colorado and Cal Tech before joining Harvard in 1986.
Berg’s lab applies methods from physics to biological problems. They strive to understand how a bacterium, such as E. coli, can sense changes in its environment and respond by swimming towards, or away from, a stimulus. To this end, the lab studies the mechanics of the bacterial flagellar motor and how it is regulated by signals from cell surface receptors.
Berg has received numerous awards and honors for his work including election to the National Academy of Sciences and the American Academy of Arts and Sciences.
- Stanley Falkow iBioSeminar: Host-Pathogen Interaction and Human Disease
- Lucy Shapiro iBioSeminar: The Dynamic Bacterial Cell
- Stanley Falkow Short Clip: Bacterial Flagella