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The Role of Rab GTPases in Regulating Plasma Membrane Receptor Recycling, Cell motility, and Cytokinesis
Eukaryotic cells compartmentalize biological functions in a series of membrane-bound organelles. The unique composition of each compartment is maintained despite the continuous movement of proteins and lipids within the cell. To achieve that proteins are specifically targeted to various subcellular compartments. Furthermore, regulated protein targeting also plays a key role in plasma membrane receptor recycling, cell motility and cytokinesis (cell division). Cells achieve protein targeting through the use of transport vesicles equipped with complex arrays of proteins that regulate vesicle formation, transport, and fusion. Small Rab GTPases are the key proteins involved in membrane traffic. Rabs function as "address" tags of transport vesicles by recruiting various effector proteins to the membranes (Figure 1). Critical questions in understanding the roles of Rab proteins are the identity and specificity of these effectors. Since most Rab GTPases have multiple effector proteins, the mechanisms and regulation of their binding are essential for understanding of Rab functions in membrane traffic. The identification of Rab binding proteins and understanding their function has been main focus of our laboratory in a last few years. The work in my laboratory led to identification of the novel family of Rab binding proteins, known as FIPs. Furthermore, we have shown that different Rab-FIP complexes play a key role in regulating many different cellular functions, including plasma membrane receptor recycling, cell motility, and cytokinesis . Three main projects are being currently investigated in the laboratory: (1) structure/function analysis of Rab-FIP protein complexes; (2) the role of Rab-FIP complexes in regulating recycling and targeting of plasma membrane receptors; and (3) the role of Rab-FIP complexes in epithelial-to-mesenchymal transition. To address these questions we use a variety of methods, including structural studies using circular dichroism, x-ray crystallography and NMR, immunoprecipitations, immunofluorescence and time-lapse microscopy, mutant analysis, permeabilized cell assays, proteomics, affinity chromatography, and yeast-two hybrid screens.
(1) Structure/function analysis of Rab-FIP protein complexes Structural information from above studies is then used to analyze the role of Rab and FIP interactions in vivo. Several microscopy assays are used for that purpose. That includes fluorescent energy transfer (FRET) as well as time-lapse microscopy analysis (for cool movie depicting the fusion of transport vesicle/tubule containing GFP-labeled FIP see Figure 2). (2) The role of Rab-FIP complexes in regulating recycling and targeting of plasma membrane receptors
(3) The role of Rab-FIP complexes in epithelial-to-mesenchymal transition Selected Publications
Simon, G.C., E. Schonteich, C.C. Wu, D. Ekiert, A. Piekny, X. Yu, G.W. Gould, M. Glotzer and R. Prekeris (2007) Sequential Cyk4/MgcRacGAP binding to ECT2 and Rab11-FIP3 regulates cleavage furrow ingression and abscission during cytokinesis. Submitted. Schonteich, E., G.M, Wilson, J. Burden, C.R. Hopkins, K. Anderson, J.R. Goldenring and R. Prekeris (2007) Rip11/FIP5 and Kinesin II complex regulates endocytic protein recycling. Submitted. Jing, J., Ma, L., Tarbutton, E., and R. Prekeris (2007) Rab11-FIP3 is a Rab11 and Arf6 binding proteins that regulates breast cancer motility by modulating actin cytoskeleton. Submitted. Schonteich, E., M. Pilli, G.C. Simon, H.T. Matern, J.R. Junutula, D. Sentz, R.K. Holmes and R. Prekeris (2007) Molecular characterization of Rab11-FIP3 binding to Arf GTPases. European Journal of Cell Biology. In Press. Yu, X., Prekeris, R., and G. W. Gould (2007) Role of endosomal Rab GTPases in cytokinesis. European Journal for Cell Biology. 86:25-35. Eathiraj, S., Mishra, A., Prekeris, R., and D.G. Lambright (2006) Structural basis for Rab11-mediated recruitment of FIP3 to recycling endosomes during cytokinesis. Journal of Molecular Biology. 364(2):121-135. Tarbutton, E., Peden, A.A., Junutula, J.R., and Prekeris, R. (2005) Class I FIPs, Rab11-binding proteins that regulate endocytic sorting and recycling. Methods in Enzymology, 403:512-525. Fielding, A.B., Schonteich, E., Yu, X., Matheson, J.,Wilson, G., Xinzi, Y., Hickson, G.R.X., Srivastava, S., Baldwin, S.A., Prekeris, R., and G.W. Gould (2005) Rab11-FIP3 and Rab11-FIP4 interact with Arf6 and Exocyst to control membrane traffic during cytokinesis. EMBO J. 24:3389-3399. Wilson, G.M., Fielding, A.B., Simon, G., Yu, X., Andrews, P.D., Hames, R.S., Frey, A.M., Peden, A.A., Gould, G.W., and R. Prekeris. (2005) The FIP3 protein complex regulates recycling endosome targeting to the cleavage furrow during late cytokinesis. Molecular Biology of the Cell. 16:849-860. Junutula, J.R., Schonteich, E., Wilson, G.M., Peden, A.A., Scheller, R.H., and R. Prekeris (2004) Molecular characterization of Rab11 interactions with the members of family of Rab11-interacting proteins (FIPs). The Journal of Biological Chemistry. 279:33430-33437. Peden, A.A., Schonteich, E., Chun, J., Jagath, J.R., Scheller, R.H., and R. Prekeris. (2004) The RCP-Rab11 complex regulates endocytic protein sorting. Molecular Biology of the Cell. 15:3530-3541. Prekeris, R. (2003) Rabs, Rips, FIPs, and Endocytic Membrane Traffic. The Scientific World Journal. 3:870-880. Meyers, J.M., and Prekeris, R. (2002) Formation of Mutually Exclusive Rab11 Complexes with Members of the FIP Family Regulate Rab11 Endocytic Targeting and Function. The Journal of Biological Chemistry. 277:49003-49010 Prekeris, R., Davies, J.M., and Scheller, R. (2001) Identification of a Novel Rab11/25 Binding Domain Present in Eferin and Rip Proteins. The Journal of Biological Chemistry. 276:38966-38970. |
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