Showing papers by "Pietro De Camilli published in 1996"

Phosphoinositides as Regulators in Membrane Traffic

Abstract: Phosphorylated products of phosphatidylinositol play critical roles in the regulation of membrane traffic, in addition to their classical roles as second messengers in signal transduction at the cell surface. Growing evidence suggests that phosphorylation-dephosphorylation of the polar heads of phosphoinositides (polyphosphorylated inositol lipids) in specific intracellular locations signals either the recruitment or the activation of proteins essential for vesicular transport. Cross talk between phosphatidylinositol metabolites and guanosine triphosphatases is an important feature of these regulatory mechanisms.

A presynaptic inositol-5-phosphatase

Abstract: SYNAPTOJANIN is a nerve terminal protein of relative molecular mass 145,000 which appears to participate with dynamin in synaptic vesicle recycling1,2. The central region of synaptojanin defines it as a member of the inositol-5-phosphatase family, which includes the product of the gene that is defective in the oculocerebrorenal syndrome of Lowe3–7. Synaptojanin has 5-phosphatase activity and its amino-terminal domain is homologous with the yeast protein Sacl (Rsdl), which is genetically implicated in phospholipid metabolism and in the function of the actin cytoskeleton8–10. The carboxy terminus, which is of different lengths in adult and developing neurons owing to the alternative use of two termination sites, is proline-rich, consistent with the reported interaction of synaptojanin with the SH3 domains of Grb2 (refs 1, 2). Synaptojanin is the only other major brain protein besides dynamin that binds the SH3 domain of amphi-physin, a presynaptic protein with a putative function in endo-cytosis11–14. Our results suggest a link between phosphoinositide metabolism and synaptic vesicle recycling.

Mobility of Synaptic Vesicles in Nerve Endings Monitored by Recovery from Photobleaching of Synaptic Vesicle-Associated Fluorescence

Abstract: In nerve terminals, synaptic vesicles form large clusters anchored to the presynaptic plasmalemma. Recently, FM1-43 photobleaching experiments carried out at frog motor endplates demonstrated lack of lateral intermixing of synaptic vesicles within clusters, even during sustained nerve terminal stimulation (Henkel and Betz, 1995; Henkel et al., 1996b). We now have investigated the mobility of synaptic vesicle membranes during the endocytic limb of their exo-endocytic cycle. To this aim, we have carried out photobleaching experiments on nerve terminals of hippocampal neurons prelabeled with CY3-conjugated antibodies directed against lumenal epitopes of synaptotagmin I. This conjugate is taken up specifically by synaptic vesicle membranes during endocytosis and then is recovered in newly formed synaptic vesicles. Using this method, we show that synaptic vesicle membranes intermix after endocytosis. Staurosporine, which at hippocampal synapses partially inhibits unloading of FM1-43, but does not block uptake of antibody probes, prevents this intermixing. Our results indicate that synaptic vesicle docking and/or fusion with the plasmalemma correlate with the release of their membranes from a restraining matrix that hinders their lateral mobility. They suggest that membrane intermediates involved in synaptic vesicle reformation interact with a distinct, highly dynamic cytoskeleton and that newly formed synaptic vesicles are recaptured at random within vesicle clusters. Staurosporine, by inhibiting mobility within the terminal, may favor recapture of new vesicles near sites of endocytosis.

Yeast protein translocation complex: Isolation of two genes SEB1 and SEB2 encoding proteins homologous to the Sec61β subunit

Abstract: A yeast gene (cDNA clone) was isolated in a screen for suppressors of secretion-defective sec15-1 mutation. This gene encodes a protein homologous to the beta subunit of the mammalian Sec61 protein complex functioning in protein translocation into the endoplasmic reticulum (ER). The predicted protein, Seb1p, consists of 82 amino acids and contains one potential membrane-spanning region at the C-terminus but no N-terminal signal sequence. Seb1p shows 30% identity to the mammalian Sec61 beta subunit and 34% identity to the Arabidopsis thaliana Sec61 beta subunit. Overexpression of SEB1 from a multicopy plasmid suppressed the temperature sensitivity of sec61-2 and sec61-3 mutants. Immunofluorescence and immunoelectron microscopy indicated that Seb1p resides in the ER membranes with the hydrophilic N-terminus exposed to the cytoplasm. The in vitro translated Seb1p was post-translationally inserted into microsomal membranes. As the chromosomal disruption of the SEB1 gene was not lethal, potential homologous genes were screened by heterologous hybridization. The SEB1 homologue thus isolated, SEB2, encodes a protein 53% identical to Seb1p. Disruption of the chromosomal SEB2 was not lethal whereas the double disruption of SEB1 and SEB2 resulted in a temperature-sensitive phenotype. This study further emphasizes the evolutionary conservation of the ER protein translocation apparatus and provides novel genetic tools for its functional analysis.

From Th1 to Th2: diabetes immunotherapy shifts gears.

Abstract: Autoantigen administration in an animal model of diabetes prevents development of the disease even after insulitis is established (pages 1348−1353).