Torsional Mechanics of Fundamental Processes

Michelle D Wang

Torsional Mechanics of Fundamental Processes

ORAL · Invited

Abstract

Because of the helical structure of DNA, motor proteins that translocate along DNA must also rotate around DNA. The resulting DNA supercoiling, in turn, regulates the activities of the motor proteins. Despite the importance of torsion on DNA, quantitative studies of torsion have been technically challenging. I will discuss our effort to develop single-molecule tools tailored for torsional mechanical studies. These approaches allow us to provide unique insights into how torsion is generated and relaxed during fundamental biological processes.

March 8, 2023, 11:00 AM – March 8, 2023, 11:36 AM

Publication: 1. T. T. Le, M. Wu, J.H. Lee, N. Bhatt, J.T. Inman, J.M. Berger, and M. D. Wang. "Etoposide Promotes DNA Loop Trapping and Barrier Formation by Topoisomerase II." Nat Chem. Bio., under revision.
2. X. Gao, Y. Hong, F. Ye, J.T. Inman, and M.D. Wang. "Torsional Stiffness of Extended and Plectonemic DNA." Phys. Rev. Lett. 127:028101 (2021).
3. T.T. Le, X. Gao, S. Park, J. Lee, J. T. Inman, J.H. Lee, J.L. Killian, R.P. Badman, J.M. Berger, and M.D. Wang. "Synergistic Coordination of Chromatin Torsional Mechanics and Topoisomerase Activity." Cell 179: 619–631 (2019).

Presenters

Michelle D Wang

Cornell University

Authors

Michelle D Wang

Cornell University