Major Research Areas
Researchers in the College of Graduate Studies focus their efforts where it truly matters—on the diseases and illnesses that affect many people. Much of our research activity is grouped into four areas of concentration: cancer; infectious diseases; disorders of the nervous system; and diabetes, metabolic disorders and cardiovascular diseases.
David W Pruyne, PhD
- Assistant Professor of Cell and Developmental Biology
- Assistant Professor of Biochemistry and Molecular Biology
Research Programs and Affiliations
- Biomedical Sciences Program
- Cancer Research Institute
- Cell and Developmental Biology
Education & Fellowships
- PhD: Cornell University, 1999, Biochemistry, Molecular and Cell Biology
- BS: Cornell University, 1993, Biochemistry
- Biochemistry and cell biology of formins as actin cytoskeleton organizers, using Caenorhabditis elegans as a model system.
- American Society for Cell Biology (ASCB)
Link to PubMed (Opens new window. Close the PubMed window to return to this page.)
The actin cytoskeleton is a network of filaments composed of the protein actin that populate the cell's cytoplasm. In a given cell, this network can be organized into a large number of distinct substructures that may range form from simple cable-like bundles through complex, repetitive arrays. These cytoskeletal structures give cells their proper shape, control the distribution of organelles, and allow cells to move. Our primary goal is to understand at the molecular level how distinct actin filament structures assemble, and how they perform their functions. Our focus is on the family of actin-organizing proteins called Formins. Formins are conserved proteins with homologs in nearly every type of eukaryotic organism, including animals, plants, and fungi. Among animals, seven distinct subclasses of Formins exist, but their precise functions are not clear. We are probing the functions of these Formin subclasses through a combination of biochemical assays using purified proteins, and genetic and microscopic studies using the model organism Caenorhabditis elegans. Our current work focuses on the relationship between one Formin subclass and muscle development.