Our research interests encompass questions on cell cycle control, the control of cell polarity, and the specification of distinct cortical domains within cells. We are also trying to understand how cells can monitor their shape and react to environmental influences that affect cytoskeletal behavior.
One focus is the study of how the Cyclin Dependent Kinases (CDKs) that control cell cycle progression act to promote specific changes in cell polarity. A ras-related G protein, Cdc42p, is key for enacting changes in cell polarity involving reorganization of both actin and septins (a poorly understood filamentous system that specializes specific cortical domains) in response to CDK activity. We are tracing the links between the CDK and Cdc42p to understand how polarity is established, and the links between Cdc42p and the cytoskeleton to determine how polarized behavior is executed.
A second focus involves investigation of a cell cycle checkpoint control that monitors cell shape. When environmental insults disrupt cytoskeletal organization, this checkpoint delays entry into mitosis through inhibition of CDK/cyclin kinases. A tyrosine kinase, Swe1p, is responsible for the cell cycle block, and we have found that the degradation of Swe1p is regulated both by cell shape and by perturbation of the actin cytoskeleton. Recently, we discovered that the septin cytoskeleton is directly affected by local cell shape, and that proteins controlling Swe1p degradation can monitor this septin change.
The biological problems we address are universal, and the proteins that we study are widely conserved. We have chosen the experimentally tractable budding yeast as our experimental system and are using genetic, cell biological, and biochemical approaches to study these pathways.
Education and Training
- Rockefeller University, Ph.D. 1990
Selected Grants and Awards
- Studies of cell polarity, chemotropism, and cell-cycle control
- Bioinformatics and Computational Biology Training Program
- Program to Support Student Development and Diversity in Duke Biosciences
- Mechanisms of cell fusion during mating in Saccharomyces cerevisiae
- Spatiotemporal modeling of signal transduction in yeast
- Gradient Tracking and Chemotropism
- Polarity Establishment in Yeast
- Cell Cycle Checkpoint that Monitors Morphogenesis