Pietro De Camilli

Phosphoinositides in cell regulation and membrane dynamics

Inositol phospholipids have long been known to have an important regulatory role in cell physiology. The repertoire of cellular processes known to be directly or indirectly controlled by this class of lipids has now dramatically expanded. Through interactions mediated by their headgroups, which can be reversibly phosphorylated to generate seven species, phosphoinositides play a fundamental part in controlling membrane–cytosol interfaces. These lipids mediate acute responses, but also act as constitutive signals that help define organelle identity. Their functions, besides classical signal transduction at the cell surface, include regulation of membrane traffic, the cytoskeleton, nuclear events and the permeability and transport functions of membranes.Inositol phospholipids have long been known to have an important regulatory role in cell physiology. The repertoire of cellular processes known to be directly or indirectly controlled by this class of lipids has now dramatically expanded. Through interactions mediated by their headgroups, which can be reversibly phosphorylated to generate seven species, phosphoinositides play a fundamental part in controlling membrane–cytosol interfaces. These lipids mediate acute responses, but also act as constitutive signals that help define organelle identity. Their functions, besides classical signal transduction at the cell surface, include regulation of membrane traffic, the cytoskeleton, nuclear events and the permeability and transport functions of membranes.

Tubular membrane invaginations coated by dynamin rings are induced by GTP-γS in nerve terminals

THE mechanisms through which synaptic vesicle membranes are reinternalized after exocytosis remain a matter of debate1–5. Because several vesicular transport steps require GTP hydrolysis6–9, GTP-γS may help identify intermediates in synaptic vesicle recycling. In GTP-γS-treated nerve terminals, we observed tubular invaginations of the plasmalemma that were often, but not always, capped by a clathrin-coated bud. Strikingly, the walls of these tubules were decorated by transverse electron-dense rings that were morphologically similar to structures formed by dynamin around tubular templates10,11. Dynamin is a GTPase implicated in synaptic vesicle endocytosis12–14 and here we show that the walls of these membranous tubules, but not their distal ends, were positive for dynamin immunoreactivity. These findings demonstrate that dynamin and clathrin act at different sites in the formation of endocytic vesicles. They strongly support a role for dynamin in the fission reaction and suggest that stabilization of the GTP-bound conformation of dynamin leads to tubule formation by progressive elongation of the vesicle stalk.

Phosphoinositides as Regulators in Membrane Traffic

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.

Essential Role of Phosphoinositide Metabolism in Synaptic Vesicle Recycling

Growing evidence suggests that phosphoinositides play an important role in membrane traffic. A polyphosphoinositide phosphatase, synaptojanin 1, was identified as a major presynaptic protein associated with endocytic coated intermediates. We report here that synaptojanin 1-deficient mice exhibit neurological defects and die shortly after birth. In neurons of mutant animals, PI(4,5)P2 levels are increased, and clathrin-coated vesicles accumulate in the cytomatrix-rich area that surrounds the synaptic vesicle cluster in nerve endings. In cell-free assays, reduced phosphoinositide phosphatase activity correlated with increased association of clathrin coats with liposomes. Intracellular recording in hippocampal slices revealed enhanced synaptic depression during prolonged high-frequency stimulation followed by delayed recovery. These results provide genetic evidence for a crucial role of phosphoinositide metabolism in synaptic vesicle recycling.

Functional partnership between amphiphysin and dynamin in clathrin-mediatedendocytosis

Amphiphysin, a protein that is highly concentrated in nerve terminals, has been proposed to function as a linker between the clathrin coat and dynamin in the endocytosis of synaptic vesicles. Here, using a cell-free system, we provide direct morphological evidence in support of this hypothesis. Unexpectedly, we also find that amphiphysin-1, like dynamin-1, can transform spherical liposomes into narrow tubules. Moreover, amphiphysin-1 assembles with dynamin-1 into ring-like structures around the tubules and enhances the liposome-fragmenting activity of dynamin-1 in the presence of GTP. These results show that amphiphysin binds lipid bilayers, indicate a potential function for amphiphysin in the changes in bilayer curvature that accompany vesicle budding, and imply a close functional partnership between amphiphysin and dynamin in endocytosis.

Generation of high curvature membranes mediated by direct endophilin bilayer interactions

Endophilin 1 is a presynaptically enriched protein which binds the GTPase dynamin and the polyphosphoinositide phosphatase synptojanin. Perturbation of endophilin function in cell-free systems and in a living synapse has implicated endophilin in endocytic vesicle budding (Ringstad, N., H. Gad, P. Low, G. Di Paolo, L. Brodin, O. Shupliakov, and P. De Camilli. 1999. Neuron. 24:143–154; Schmidt, A., M. Wolde, C. Thiele, W. Fest, H. Kratzin, A.V. Podtelejnikov, W. Witke, W.B. Huttner, and H.D. Soling. 1999. Nature. 401:133–141; Gad, H., N. Ringstad, P. Low, O. Kjaerulff, J. Gustafsson, M. Wenk, G. Di Paolo, Y. Nemoto, J. Crun, M.H. Ellisman, et al. 2000. Neuron. 27:301–312). Here, we show that purified endophilin can directly bind and evaginate lipid bilayers into narrow tubules similar in diameter to the neck of a clathrin-coated bud, providing new insight into the mechanisms through which endophilin may participate in membrane deformation and vesicle budding. This property of endophilin is independent of its putative lysophosphatydic acid acyl transferase activity, is mediated by its NH2-terminal region, and requires an amino acid stretch homologous to a corresponding region in amphiphysin, a protein previously shown to have similar effects on lipid bilayers (Takei, K., V.I. Slepnev, V. Haucke, and P. De Camilli. 1999. Nat. Cell Biol. 1:33–39). Endophilin cooligomerizes with dynamin rings on lipid tubules and inhibits dynamins GTP-dependent vesiculating activity. Endophilin B, a protein with homology to endophilin 1, partially localizes to the Golgi complex and also deforms lipid bilayers into tubules, underscoring a potential role of endophilin family members in diverse tubulovesicular membrane-trafficking events in the cell.

Epsin is an EH-domain-binding protein implicated in clathrin-mediated endocytosis

During endocytosis, clathrin and the clathrin adaptor protein AP-2 (ref. 1), assisted by a variety of accessory factors, help to generate an invaginated bud at the cell membrane,. One of these factors is Eps15, a clathrin-coat-associated protein that binds the α-adaptin subunit of AP-2 (refs 4–8). Here we investigate the function of Eps15 by characterizing an important binding partner for its region containing EH domains; this protein, epsin, is closely related to the Xenopus mitotic phosphoprotein MP90 (ref. 10) and has a ubiquitous tissue distribution. It is concentrated together with Eps15 in presynaptic nerve terminals, which are sites specialized for the clathrin-mediated endocytosis of synaptic vesicles. The central region of epsin binds AP-2 and its carboxy-terminal region binds Eps15. Epsin is associated with clathrin coats in situ, can be co-precipitated with AP-2 and Eps15 from brain extracts, but does not co-purify with clathrin coat components in a clathrin-coated vesicle fraction. When epsin function is disrupted, clathrin-mediated endocytosis is blocked. We propose that epsin may participate, together with Eps15, in the molecular rearrangement of the clathrin coats that are required for coated-pit invagination and vesicle fission.

Autoantibodies to GABA-ergic Neurons and Pancreatic Beta Cells in Stiff-Man Syndrome

Stiff-man syndrome is a rare disorder of the central nervous system of unknown pathogenesis. We have previously reported the presence of autoantibodies against glutamic acid decarboxylase (GAD) in a patient with stiff-man syndrome, epilepsy, and insulin-dependent diabetes mellitus. GAD is an enzyme selectively concentrated in neurons secreting the neurotransmitter gamma-aminobutyric acid (GABA) and in pancreatic beta cells. We subsequently observed autoantibodies to GABA-ergic neurons in 20 of 33 patients with stiff-man syndrome. GAD was the principal autoantigen. In the group of patients positive for autoantibodies against GABA-ergic neurons, there was a striking association with organ-specific autoimmune diseases, primarily insulin-dependent diabetes mellitus. These findings support the hypothesis that stiff-man syndrome is an autoimmune disease and suggest that GAD is the primary autoantigen involved in stiff-man syndrome and the associated insulin-dependent diabetes mellitus. Our findings also indicate that autoantibodies directed against GABA-ergic neurons are a useful marker in the diagnosis of the disease.

Accessory factors in clathrin-dependent synaptic vesicle endocytosis

Clathrin-mediated endocytosis is a special form of vesicle budding important for the internalization of receptors and extracellular ligands, for the recycling of plasma membrane components, and for the retrieval of surface proteins destined for degradation. In nerve terminals, clathrin-mediated endocytosis is crucial for synaptic vesicle recycling. Recent structural studies have provided molecular details of coat assembly. In addition, biochemical and genetic studies have identified numerous accessory proteins that assist the clathrin coat in its function at synapses and in other systems. This review summarizes these advances with a special focus on accessory factors and highlights new aspects of clathrin-mediated endocytosis revealed by the study of these factors.Key PointsClathrin-mediated endocytosis is a special form of vesicle budding that has a key function in synaptic vesicle recycling at nerve terminals. The fundamental features of this form of endocytosis in nerve terminals are similar to clathrin-mediated endocytosis in other cell types. However, it has some unique characteristics such as its fast kinetics and the existence of several neuron-specific molecules involved in the endocytic process.The main building blocks of the clathrin coats are clathrin and the adaptor protein AP-2. Coat assembly starts with the oligomerization of AP-2 and the subsequent recruitment of clathrin. As the coat expands, the curvature of the membrane becomes more pronounced until it undergoes fission. The newly formed vesicle rapidly sheds its coat.There are many accessory factors that assist the formation of clathrin-coated vesicles. Some of them, such as AP-180, amphiphysin, Eps15, epsin or dynamin are involved in coat assembly and in the regulation of coat dynamics. The protein AP-180, for instance, seems to be important for determining the size of the coat. Similarly, amphiphysin seems to function as a multifunctional adaptor that contributes to the recruitment of coat protein, and dynamin seems to be crucial for the fission event.Other accessory factors coordinate growth of the coat with changes of the lipid bilayer and with modifications of the actin cytoskeleton. For instance, dynamin and some of its binding partners (for example, amphiphysin and syndapin) seem to interact functionally with actin. Similarly, endophilin seems to have lysophosphatidic acid acyl transferase activity that may be important for membrane invagination. Other factors, such as synaptojanin, amphiphysin, intersectin or auxilin, participate in the crosstalk between endocytic mechanisms and intracellular signalling pathways. For instance, synaptojanin is a phosphoinositide phosphatase that regulates a PtdIns(4,5)P2 pool important both for endocytosis and for signalling.One important aspect about the different accessory factors involved in clathrin-mediated endocytosis is that each of them may act at several stages during the endocytic process. This is probably related to the existence in each factor of binding sites for many of the other molecules involved in endocytosis. A current challenge for the field is to establish the hierarchy, the sequence of action, and the precise site of assembly of all of these factors into the clathrin coat.A recurring theme in the study of clathrin-accessory factors is their link to actin. Indeed, the evidence for a role of actin in clathrin-mediated endocytosis is strong in some systems. Its actual involvement is not understood yet but it has been proposed that actin could be involved in the fission step and in the subsequent translocation of vesicles away from the membrane.The fact that clathrin coats form in the synaptic membrane only after exocytosis indicates that the regulation of endocytosis in nerve terminals might be related to the exocytotic process, although the exact mechanism remains to be elucidated. In addition, protein phosphorylation is another mechanism involved in the regulation of the endocytic machinery.

Dynamin, a membrane-remodelling GTPase.

Dynamin, the founding member of a family of dynamin-like proteins (DLPs) implicated in membrane remodelling, has a critical role in endocytic membrane fission events. The use of complementary approaches, including live-cell imaging, cell-free studies, X-ray crystallography and genetic studies in mice, has greatly advanced our understanding of the mechanisms by which dynamin acts, its essential roles in cell physiology and the specific function of different dynamin isoforms. In addition, several connections between dynamin and human disease have also emerged, highlighting specific contributions of this GTPase to the physiology of different tissues.