Carothers Uses Cellular Design to Advance SocietyJanuary 26, 2016 |
by B. Denise Hawkins
The shiny new steel and glass laboratory that sits on the corner of campus at the University of Washington (UW) “looks like a high-tech company,” but it’s where James M. Carothers makes his research home. Microbes grow there, and he and his research team move about in the brightly lit, modular laboratory.
This is the place that Carothers, an assistant professor of chemical engineering and an adjunct assistant professor as well as a member of the Molecular Engineering & Sciences Institute and Center for Synthetic Biology at UW, investigates solutions to real-world problems. It is complex, grueling work, but what excites Carothers more than the process are what his efforts over the years are poised to yield — “new approaches to produce renewable chemicals” and one day reduce the need to use petroleum for some applications.
Even as a high school student who enjoyed and excelled at math, biology and technology, Carothers recalls the need he had even then to see the practical applications of all that he was learning and how it could ultimately benefit society. Using cells, Carothers later found a way forward.
As a graduate student at Harvard, Carothers began to develop “cellular design-driven approaches to re-engineer living systems for biotech applications.” And as a postdoctoral fellow and research scientist at the University of California, Berkeley, Carothers continued that work alongside pioneering synthetic biologist Jay D. Keasling. Carothers’ co-authored publications have been cited more than 1,200 times, and his scholarship was recognized by the UW Innovation Award and the Alfred P. Sloan Foundation Research Fellowship in 2013.
But when this award-winning scholar goes in search of a few high school students to join him and his research team—the Carothers Research Group—in the lab, Carothers knows how to translate the work that he does in a way that makes even complicated science sound familiar and doable to teens.
“We’re trying to convert leftover agricultural material into fuel to power your car. That’s how I usually start out,” says Carothers of his palatable pitch to students for whom the inside of a science lab and a university campus are unfamiliar places. But even among first-generation students, Carothers says he doesn’t worry about finding recruits: “The lab is exciting and new and the science sells itself.”
In 2008, as a postdoctoral fellow, Carothers co-founded the Introduction to College Level Experience in Microbiology (iCLEM) program for low-income high school students in the San Francisco Bay area. It was a success—100 percent of iCLEM participants have enrolled in college and 70 percent have majored in science or engineering.
When Carothers came to UW in 2012, the successful iCLEM program followed.
“Drawing on successful lessons from iCLEM, James created research modules that combine concepts in molecular design with wet-lab experiments and quantitative analyses to engage and motivate students from groups typically underrepresented in quantitative science and engineering,” says Dr. François Baneyx, chair of the department of chemical engineering at UW and the Charles W.H. Matthaei Professor of Chemical Engineering.
While Carothers’ days are packed with teaching and research, he is committed to training and mentoring through iCLEM. “If we want the U.S. to be an exciting place to do science and enjoy all of the benefits that come with it and new technology, we need to be concerned about casting a wide net for the next generation of scientists,” adds Carothers, whose own college going was “expected” and his path to a STEM career straight and sure.
“We know that for a whole group of students that’s not the case,” adds Carothers. “For those in iCLEM, we want to give them even a little taste of college and normalize the college experience. This work for them could be a bridge to opportunity, careers and to the middle class. We want to be that kind of bridge for our students.”