Michelle Dong Wang | |
Alma Mater: | University of Michigan Nanjing University Chinese Academy of Sciences University of Southern Mississippi |
Thesis Title: | Reaction and aggregation dynamics of cell surface receptors. |
Thesis Url: | http://www.worldcat.org/oclc/713128957 |
Thesis Year: | 1993 |
Michelle Dong Wang is a Chinese-American physicist who is the James Gilbert White Distinguished Professor of the Physical Sciences at Cornell University. She is an Investigator of the Howard Hughes Medical Institute. Her research considers biomolecular motors and single molecule optical trapping techniques. She was appointed Fellow of the American Physical Society in 2009.
Wang earned her bachelor's degree in nuclear physics at Nanjing University.[1] She moved to the Chinese Academy of Sciences for her graduate studies, where she majored in physics and earned a doctorate in 1986. Wang moved to the United States in 1986, where she worked toward a master's degree at the University of Southern Mississippi. She completed a second doctorate at the University of Michigan.[2] Wang was a postdoctoral fellow at Princeton University.
In 1998, Wang was appointed Assistant Professor at Cornell University, where she was made Professor in 2009. Wang is interested in single-molecule biophysics. Her research considers biological molecular motors, including RNA polymerase molecules which move along the DNA template during cell division. During this process genetic information is transferred from DNA into new RNA.[3] DNA motor proteins often experience roadblocks, including binding proteins that can interfere with essential biological processes. Wang has looked to understand the interactions between histones and DNA in nucleosomes.[4]
Wang has pioneered several structural probes to better understand molecular motors, including angular optical trapping, DNA unzipping and nanophotonics.[5] Angular optical traps isolate birefringent particles within a polarized laser beam. The particles can be rotated by rotating the polarization of the laser, which allows for the precise control and identification of biological molecules which are attached to the birefringent particles. To perform these optical rotation measurements, Wang makes use of bio-functionalized quartz nano-cylinders.[6] Building on her experiences in photonics, Wang created an electro-optofluidic platform that can be used to trap single molecules. These traps use photonic interference to create three-dimensional on-chip optical traps at the antinodes of the standing waves of an evanescent field.[7]