David G. Drubin
Professor of Cell and Developmental Biology*
*And Affiliate, Division of Genetics, Genomics and Development
We use state-of-the-art real-time image analysis of live cells, genome-wide functional analyses, genetics, molecular genetics and biochemistry in mammalian stem cells and in budding yeast to elucidate the molecular mechanisms that underlie highly dynamic actin-mediated membrane trafficking events, which mediate formation of distinct cellular compartments. Cells are not bags of enzymes, but consist of many distinct micro-environments, each dedicated to a specific function. We are investigating the mechanisms that cells use to create these micro-environments, and how the micro-environments change in response to signals from a cell's surroundings.
Membrane Trafficking and the Cytoskeleton. Using real-time microscopy and sophisticated analytical tools, coupled with genetics and molecular genetics, we have identified a pathway in budding yeast in which proteins are recruited to endocytic sites in a highly regular, sequential manner. Near the end of this process, a burst of actin assembly facilitates vesicle formation. By studying mutants of over 60 proteins, we have identified several protein modules that provide distinct functions in this pathway. Since actin is among the most highly conserved proteins known, we long believed that the results we obtain from studies in yeast would be directly transferable to more complex eukaryotes including humans. Defects in trafficking events and cytoskeletal proteins are linked to human diseases such as cancer and neuronal degeneration. We are isolating and characterizing mammalian homologues of cytoskeletal proteins that we first identified and characterized in yeast. We are particularly interested in determining the roles of these proteins in endocytosis and cell polarity development. Using zinc finger nuclease-mediated genome-editing and stem cells, we are translating some of the experimental advantages of yeast to mammalian cells.
Actin Assembly. Elucidation of the molecular mechanisms used to regulate actin assembly will require a detailed knowledge of how actin subunits assemble into long polymers, and how proteins that bind to monomers and polymers affect assembly dynamics. We have performed a structure-function analysis of actin by mutating residues involved in nucleotide hydrolysis and assaying the effects of these mutations on actin assembly in vitro and in vivo. In complementary studies, genetic, biochemical and structural studies of the low molecular weight (16 kD) actin filament severing protein cofilin and its cofactor, Aip1p, and the actin nucleotide exchange factor, profilin, are being performed to determine how filament turnover is controlled in vivo. We have also identified and are studying several novel activators of the Arp2/3 complex, which regulates actin nucleation, and we are also studying the role of nucleotide in Arp2/3 function. Recently, we have succeeded in reconstituting a complex actin assembly system on the surface of microbeads incubated in yeast cell extracts, and next aspire to reconstitute complex actin-based trafficking events on membranes.
Determinants of endocytic membrane geometry, stability and scission. [Kishimoto T, Sun Y, Buser C, Liu J, Michelot A and Drubin, DG. (2011) Proc. Natl. Acad. Sci USA. 108(44):E979-88]
Rapid and efficient clathrin-mediated endocytosis revealed in genome-edited mammalian cells. [Doyon JB, Zeitler B, Cheng J, Cheng AT, Cherone JM, Santiago Y, Lee AH, Vo TD, Doyon Y, Miller JC, Paschon DE, Zhang L, Rebar EJ, Gregory PD, Urnov FD and Drubin DG (2011) Nat. Cell Biol. 13(3):331-7]
Reconstitution and Protein Composition Analysis of Endocytic Actin Patches. [Michelot A, CostanzoM, Sarkeshik A, Boone C, Yates III, JR, and Drubin DG (2010) Curr. Biol. 9;20(21):1890-9]
Loss of Aip1 reveals a role in maintaining the actin monomer pool and an in vivo oligomer assembly pathway. [Okreglak, V, and Drubin, DG (2010) J. Cell Biol. 188:769-77]
A yeast killer toxin screen provides insights into A/B toxin entry, trafficking and killing mechanisms. [Carroll, SY, Stirling, PC, Stimpson, HEM, Gießelmann, E., Schmitt, MJ and Drubin, DG. (2009) Dev. Cell. Oct 17(4):552-60.]
The mechanochemistry of endocytosis. [Liu, J, Sun, Y, Drubin, DG and Oster, GF. (2009) PLOS Biology. Sep;7(9):e1000204. Epub 2009 Sep 29.]
Cofilin recruitment and function during actin-mediated endocytosis dictated by actin nucleotide state. [Okreglak, V and Drubin, DG (2007) J. Cell Biol. 178(7):1251-64.]
Endocytic internalization in budding yeast requires coordinated actin nucleation and myosin motor activity. [Sun, y, Martin, AC and Drubin, DG (2006) Dev. Cell 11:33-46]
Spatial dynamics of receptor-mediated endocytic trafficking in budding yeast. [Toshima, JY, Toshima, J, Kaksonen, M, Martin, AC, King, DS and Drubin, DG (2006) Proc. Natl. Acad. Sci. USA 103:5793-8.
A modular design for the clathrin- and actin-mediated endocytosis machinery [Kaksonen, M, Toret, CP and Drubin, DG (2005) Cell 123:305-320]
A pathway for association of receptors, adaptors and actin during endocytic internalization. [Kaksonen, M, Sun, Y and Drubin, DG (2003) Cell 115:475-487]
Last Updated 2012-08-08