The traffic patterns established by transport vesicles are of fundamental importance for protein localization, modification, and function within eukaryotic cells. Cargo transported by these vesicles is delivered through the fusion of the vesicle with the membrane of a target organelle or, in the case of exocytosis, the plasma membrane. Membrane fusion is executed by SNARE complexes that bridge the vesicle and target membranes. The formation of these complexes requires that four different SNARE proteins, anchored in two different membranes, undergo a coupled folding and assembly reaction during which the SNARE motifs zipper up into a parallel four-helix bundle. This complicated process is inefficient in vitro, and is certain to be even more challenging in vivo, where it must compete with the formation of various non-cognate and off-pathway SNARE complexes. We hypothesize that SNARE complex assembly reactions in the cell are orchestrated by `topologically aware' chaperones called multisubunit tethering complexes (MTCs). We furthermore propose that the key task of catalyzing four-helix bundle formation falls to the Sec1/Munc18 (SM) proteins, working together with?and sometimes as integral subunits of?the MTCs. Therefore, the overarching goal of this proposal is to achieve an improved structural and mechanistic understanding of MTC and SM function, especially as they relate to one another, in the assembly of membrane fusogenic SNARE complexes.
Aim 1 is focused on SM proteins with the goal of characterizing their precise catalytic role in SNARE complex assembly. Principally through the use of X-ray crystallography and complementary single-molecule optical tweezers experiments, we will determine the structures and thermodynamic stabilities of SM-bound SNARE assembly intermediates.
In Aims 2 and 3, we broaden our focus to include MTCs.
In Aim 2, we will investigate the simplest known MTC, the yeast Dsl1 complex, and its interactions with SNAREs and the SM protein Sly1. Cryo-EM studies of arrested SNARE assembly intermediates in complex with both the Dsl1 complex and Sly1 are designed to reveal how the Dsl1 complex and Sly1 collaborate.
In Aim 3, we will turn our attention to the homotypic fusion and vacuole protein sorting (HOPS) complex, a well-studied MTC that is required for fusion at late endosomes and lysosomes/vacuoles. Importantly, HOPS contains an SM protein as an integral subunit, making it an ideal system for studying MTC?SM collaboration. In order to elucidate how HOPS organizes SNAREs for assembly, we will expand our ongoing cryo-EM studies of HOPS to include bound SNAREs and SNARE assembly intermediates. Overall, this research program has the potential to revolutionize our mechanistic understanding of chaperoned SNARE complex assembly, with potentially profound implications for elucidating diverse biological processes and their subversion during infection and disease. While the proposed work is more fundamental than applied, it will lay a foundation for efforts to manipulate trafficking and other processes entailing membrane fusion, with potential future applications to therapeutic intervention.

Public Health Relevance

The proposed work takes a structural approach to investigate the machinery responsible for sorting and transporting proteins and lipids among the compartments of eukaryotic cells. Mutations in many components of this machinery have been shown to perturb cellular architecture and function, resulting in human disease.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
2R01GM071574-17
Application #
10210474
Study Section
Membrane Biology and Protein Processing Study Section (MBPP)
Program Officer
Flicker, Paula F
Project Start
2005-03-01
Project End
2025-02-28
Budget Start
2021-03-15
Budget End
2022-02-28
Support Year
17
Fiscal Year
2021
Total Cost
Indirect Cost
Name
Princeton University
Department
Biochemistry
Type
Schools of Arts and Sciences
DUNS #
002484665
City
Princeton
State
NJ
Country
United States
Zip Code
08543
Baker, Richard W; Hughson, Frederick M (2016) Chaperoning SNARE assembly and disassembly. Nat Rev Mol Cell Biol 17:465-79
Ha, Jun Yong; Chou, Hui-Ting; Ungar, Daniel et al. (2016) Molecular architecture of the complete COG tethering complex. Nat Struct Mol Biol 23:758-60
Suckling, Richard J; Poon, Pak Phi; Travis, Sophie M et al. (2015) Structural basis for the binding of tryptophan-based motifs by ?-COP. Proc Natl Acad Sci U S A 112:14242-7
Baker, Richard W; Jeffrey, Philip D; Zick, Michael et al. (2015) A direct role for the Sec1/Munc18-family protein Vps33 as a template for SNARE assembly. Science 349:1111-4
Ha, Jun Yong; Pokrovskaya, Irina D; Climer, Leslie K et al. (2014) Cog5-Cog7 crystal structure reveals interactions essential for the function of a multisubunit tethering complex. Proc Natl Acad Sci U S A 111:15762-7
Rogers, Jason V; McMahon, Conor; Baryshnikova, Anastasia et al. (2014) ER-associated retrograde SNAREs and the Dsl1 complex mediate an alternative, Sey1p-independent homotypic ER fusion pathway. Mol Biol Cell 25:3401-12
Baker, Richard W; Jeffrey, Philip D; Hughson, Frederick M (2013) Crystal Structures of the Sec1/Munc18 (SM) Protein Vps33, Alone and Bound to the Homotypic Fusion and Vacuolar Protein Sorting (HOPS) Subunit Vps16*. PLoS One 8:e67409
Bharucha, Nike; Liu, Yang; Papanikou, Effrosyni et al. (2013) Sec16 influences transitional ER sites by regulating rather than organizing COPII. Mol Biol Cell 24:3406-19
McMahon, Conor; Studer, Sean M; Clendinen, Chaevia et al. (2012) The structure of Sec12 implicates potassium ion coordination in Sar1 activation. J Biol Chem 287:43599-606
Ren, Qiansheng; Wimmer, Christian; Chicka, Michael C et al. (2010) Munc13-4 is a limiting factor in the pathway required for platelet granule release and hemostasis. Blood 116:869-77

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