David Taylor - US grants

With NSF support through the Historically Black Colleges and Universities Undergraduate Program (HBCU-UP), Morehouse College will enhance the quality of their science, technology, engineering, and mathematics instructional and outreach programs as a means to increase participation in the Nation's STEM workforce. Project objectives include (1) increasing the number of STEM graduates; (2) increasing the number of STEM graduates who enter graduate school in pursuit of research careers; and, (3) increasing the success of STEM majors in graduate school and the STEM workforce.

Project components include comprehensive curriculum reform and laboratory enhancement, expansion of undergraduate research experience and enhancement of students' preparation for and success in graduate school. Curriculum enhancements include a summer program for High School students; reform of the gatekeeper courses in biology, chemistry, computer science, mathematics, physics and psychology; and, the infusion of technology and new pedagogy into STEM courses and laboratories. Undergraduate research opportunities will be enhanced through the Atlanta Undergraduate Research Alliance.

The intellectual merit of this project includes research in curriculum reform and laboratory enhancement designed to provide students with the skills and knowledge needed to pursue STEM research careers. Research efforts will yield valuable information regarding key questions concerning the critical skills a mentoring program should address and the role of diversity in furthering student success.

Broader impacts of this project include the dissemination of effective undergraduate research and educational enhancement practices among institutional members of the Atlanta Undergraduate Research Alliance.

My laboratory is interested in understanding the regulation of gene expression at the molecular level. Our primary tool is cryo-electron microscopy (cryo-EM). We use cryo-EM to study the atomic details of snapshots of our macromolecular machines of interest in action. We have revealed exciting insights into the structure and function of macromolecular machines and assemblies involved in (1) protein production and (2) genome editing. We will continue to apply cryo-EM as well as other tools in our repertoire, including site-specific labeling and conformational analysis using negative stain EM, to produce mechanistic insights into the structure and function of macromolecular machines involved in gene regulation, broadly-defined. In the next five years, my lab plans on elucidating the molecular architectures that set the foundation for accurate gene expression and production of proteins, the workforce of the cell. Combined with the work on CRISPR genome-engineering complexes, these results will have major implications for researchers performing translational research to combat a myriad of diseases.