It became possible several years ago to purify synaptic vesicles in reasonable yield and with high purity from the electric organ of fish. Because of a lack of suitable markers synaptic vesicles demonstrated to have similar purity could not be obtained from mammalian brain. We have discovered an antigen, SV2, that is present in synaptic vesicles in electric fish and also in the mammalian peripheral and central nervous system. Another antigen, SV4, is an intravesicular proteoglycan that carries pathway-specific antigens, also found in the synaptic cleft. in this funding period we will use the SV2 antigen as a marker to ask if a newly-synthesized synaptic vesicle membrane protein is targeted directly to the synaptic vesicle, and if so where the address information lies. We will also use the SV2 antigen to purify mammalian brain synaptic vesicles to look for other proteins common to all vesicles. With antibodies to the shared proteins of mammalian synaptic vesicles, it will become possible to explore the function of the proteins by generating mutants in exocytosis, by microinjection of antibodies, and by an in vitro reconstitution of fast axonal transport that we have recently developed. The synapse-specific antigen we have discovered (SV4) is not found in mammalian nerve terminals. To ask if in mammalian systems synaptic vesicles contribute unique proteoglycans to the synaptic junction, we will generate monoclonal antibodies to vesicle and synaptic junction proteoglycans from mammalian brain. We will be looking for a unique proteoglycan that travels by fast axonal transport, is found in synaptic vesicles and becomes a component of the synaptic junctional complex.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS015927-12
Application #
3396577
Study Section
Neurology C Study Section (NEUC)
Project Start
1979-12-01
Project End
1992-11-30
Budget Start
1990-12-01
Budget End
1991-11-30
Support Year
12
Fiscal Year
1991
Total Cost
Indirect Cost
Name
University of California San Francisco
Department
Type
Schools of Medicine
DUNS #
073133571
City
San Francisco
State
CA
Country
United States
Zip Code
94143
Marie, Bruno; Sweeney, Sean T; Poskanzer, Kira E et al. (2004) Dap160/intersectin scaffolds the periactive zone to achieve high-fidelity endocytosis and normal synaptic growth. Neuron 43:207-19
Verstreken, Patrik; Koh, Tong-Wey; Schulze, Karen L et al. (2003) Synaptojanin is recruited by endophilin to promote synaptic vesicle uncoating. Neuron 40:733-48
Jarousse, N; Kelly, R B (2001) Endocytotic mechanisms in synapses. Curr Opin Cell Biol 13:461-9
Faundez, V V; Kelly, R B (2000) The AP-3 complex required for endosomal synaptic vesicle biogenesis is associated with a casein kinase Ialpha-like isoform. Mol Biol Cell 11:2591-604
Qualmann, B; Kessels, M M; Kelly, R B (2000) Molecular links between endocytosis and the actin cytoskeleton. J Cell Biol 150:F111-6
Roos, J; Hummel, T; Ng, N et al. (2000) Drosophila Futsch regulates synaptic microtubule organization and is necessary for synaptic growth. Neuron 26:371-82
Qualmann, B; Kelly, R B (2000) Syndapin isoforms participate in receptor-mediated endocytosis and actin organization. J Cell Biol 148:1047-62
Marullo, S; Faundez, V; Kelly, R B (1999) Beta 2-adrenergic receptor endocytic pathway is controlled by a saturable mechanism distinct from that of transferrin receptor. Receptors Channels 6:255-69
Qualmann, B; Roos, J; DiGregorio, P J et al. (1999) Syndapin I, a synaptic dynamin-binding protein that associates with the neural Wiskott-Aldrich syndrome protein. Mol Biol Cell 10:501-13
Roos, J; Kelly, R B (1999) The endocytic machinery in nerve terminals surrounds sites of exocytosis. Curr Biol 9:1411-4

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