Cargo Sorting and Intralumenal Vesicle Budding by the ESCRT Complexes Membrane budding and fission is a fundamental process of eukaryotic cell biology. Endocytosis, the formation of intracellular transport and secretory vesicles, and mitochondrial fission are examples of inward budding. In the classical example of clathrin-mediated endocytosis, the cytosolic protein dynamin forms arrays on the outside of the membrane neck, and membrane fission is driven thermodynamically by the hydrolysis of GTP. The formation of multivesicular bodies (MVBs) is the prototypical example of outward budding. MVBs are formed during the maturation of endosomes destined to fuse with lysosomes, and mediate the sorting of ubiquitinated membrane proteins to the lysosome. Portions of the limiting membrane of the endosome are internalized to form intralumenal vesicles (ILVs). When the MVB fuses with the lysosome, ILV contents are degraded by lysosomal hydrolases. When ILVs are released through fusion with the plasma membrane, they are referred to as exosomes. The budding of enveloped viruses from the plasma membrane and cell division (cytokinesis) are other examples of outward budding events. Outward budding events in MVB formation, viral budding, and cytokinesis are directed from the cytosol. Since cytosol is in contact with the inside, not the outside of the neck of the nascent bud, the mechanics of membrane fission differ fundamentally from inward budding, and utilize a completely distinct protein machinery. A major breakthrough in understanding outward budding came from the identification in yeast of the ESCRT machinery responsible for MVB formation. The ESCRT machinery is conserved throughout eukaryotes, and many enveloped viruses of mammals use the ESCRT pathway to bud, including HIV-1. The closure of the membrane neck in cytokinesis also uses the ESCRT pathway. The assembly of ESCRT complexes on endosomes is triggered by the presence of phosphatidylinositol 3-phosphate (PI(3)P) and ubiquitinated cargo proteins. ESCRT-I and II directly bind to cargo, and in turn recruit ESCRT-III. There are four ESCRT-III subunits in yeast, Vps2, Vps20, Vps24, and Snf7, together with two associated ESCRT-III-like proteins, Did2 and Vps60. ESCRT-III subunits exist in the cytosol as monomers, and assemble with each other on membranes in large multimeric arrays. ESCRT-II is a Y-shaped complex that contains two copies of the Vps25 subunit, which recruits ESCRT-III by directly binding to Vps20. Vps20 binds to Snf7, comprising a subcomplex of ESCRT-III. Snf7, in turn, directly binds to the Bro1 domain of the ESCRT-associated protein Alix (known as Bro1 in yeast). The Vps20:Snf7 complex recruits the Vps2:Vps24 subcomplex to form the complete ESCRT-III complex. A subset of ESCRT-III proteins directly bind to the N-terminal MIT domain of the AAA ATPase Vps4. Vps4 is a central player in the MVB pathway that is required for the disassembly of the ESCRT-III complex. ESCRT function can be conceptually separated into two phases: cargo recruitment and concentration, followed by membrane invagination and budding. The long term objectives of this project are to: 1) determine the structures of ESCRT complexes by x-ray crystallography, abetted where necessary by electron microscopy, hydrodynamics, molecular simulations, and small angle x-ray scattering;2) to determine how ESCRTs assemble on membranes containing PI(3)P and cargo using binding and spectroscopic techniques;and 3) to study the mechanism of ILV formation by a microscopic, spectroscopic, and structure/function approaches. ESCRT-I is a heterotetramer of Vps23, Vps28, Vps37, and Mvb12. The crystal structures of the core complex and the UEV and Vps28 C-terminal (CTD) domains have been determined, but internal flexibility has prevented crystallization of intact ESCRT-I. Over the past FY, we have characterized the structure of ESCRT-I in solution by simultaneous structural refinement against small angle x-ray scattering (SAXS) and double electron-electron resonance (DEER) spectroscopy of spin labeled complexes. An ensemble of at least six structures, comprising an equally populated mixture of closed and open conformations, was necessary to fit all of the data. This structural ensemble was cross-validated against single molecule Frster resonance energy transfer (FRET) spectroscopy, which suggested the presence of a continuum of open states. ESCRT-I in solution thus appears to consist of a 50 % population of one or a few related closed conformations, with the other 50 % populating a continuum of open conformations. These conformations provide references points for the structural pathway by which ESCRT-I induces membrane buds.

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Boura, Evzen; Różycki, Bartosz; Chung, Hoi Sung et al. (2012) Solution structure of the ESCRT-I and -II supercomplex: implications for membrane budding and scission. Structure 20:874-86
Roýýycki, Bartosz; Boura, Evzen; Hurley, James H et al. (2012) Membrane-elasticity model of Coatless vesicle budding induced by ESCRT complexes. PLoS Comput Biol 8:e1002736
Boura, Evzen; Ivanov, Vassili; Carlson, Lars-Anders et al. (2012) Endosomal sorting complex required for transport (ESCRT) complexes induce phase-separated microdomains in supported lipid bilayers. J Biol Chem 287:28144-51
Boura, Evzen; Hurley, James H (2012) Structural basis for membrane targeting by the MVB12-associated ýý-prism domain of the human ESCRT-I MVB12 subunit. Proc Natl Acad Sci U S A 109:1901-6
Boura, Evzen; Rózycki, Bartosz; Herrick, Dawn Z et al. (2011) Solution structure of the ESCRT-I complex by small-angle X-ray scattering, EPR, and FRET spectroscopy. Proc Natl Acad Sci U S A 108:9437-42
Hurley, James H; Hanson, Phyllis I (2010) Membrane budding and scission by the ESCRT machinery: it's all in the neck. Nat Rev Mol Cell Biol 11:556-66
Renvoisé, Benoît; Parker, Rell L; Yang, Dong et al. (2010) SPG20 protein spartin is recruited to midbodies by ESCRT-III protein Ist1 and participates in cytokinesis. Mol Biol Cell 21:3293-303
Wollert, Thomas; Hurley, James H (2010) Molecular mechanism of multivesicular body biogenesis by ESCRT complexes. Nature 464:864-9
Im, Young Jun; Wollert, Thomas; Boura, Evzen et al. (2009) Structure and function of the ESCRT-II-III interface in multivesicular body biogenesis. Dev Cell 17:234-43
Wollert, Thomas; Yang, Dong; Ren, Xuefeng et al. (2009) The ESCRT machinery at a glance. J Cell Sci 122:2163-6

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