Clathrin-mediated vesicle recycling in synapses is maintained by a unique set of endocytic proteins and interactions. We show that endophilin localizes in the vesicle pool at rest and in spirals at the necks of clathrin-coated pits (CCPs) during activity in lamprey synapses. Endophilin and dynamin colocalize at the base of the clathrin coat. Protein spirals composed of these proteins on lipid tubes in vitro have a pitch similar to the one observed at necks of CCPs in living synapses, and lipid tubules are thinner than those formed by dynamin alone. Tubulation efficiency and the amount of dynamin recruited to lipid tubes are dramatically increased in the presence of endophilin. Blocking the interactions of the endophilin SH3 domain in situ reduces dynamin accumulation at the neck and prevents the formation of elongated necks observed in the presence of GTPγS. Therefore, endophilin recruits dynamin to a restricted part of the CCP neck, forming a complex, which promotes budding of new synaptic vesicles.
Clathrin-mediated synaptic vesicle (SV) recycling involves the spatiotemporally controlled assembly of clathrin coat components at phosphatidylinositiol (4, 5)-bisphosphate [PI(4,5)P 2 ]-enriched membrane sites within the periactive zone. Such spatiotemporal control is needed to coordinate SV cargo sorting with clathrin/AP2 recruitment and to restrain membrane fission and synaptojanin-mediated uncoating until membrane deformation and clathrin coat assembly are completed. The molecular events underlying these control mechanisms are unknown. Here we show that the endocytic SH3 domaincontaining accessory protein intersectin 1 scaffolds the endocytic process by directly associating with the clathrin adaptor AP2. Acute perturbation of the intersectin 1-AP2 interaction in lamprey synapses in situ inhibits the onset of SV recycling. Structurally, complex formation can be attributed to the direct association of hydrophobic peptides within the intersectin 1 SH3A-B linker region with the "side sites" of the AP2 α-and β-appendage domains. AP2 appendage association of the SH3A-B linker region inhibits binding of the inositol phosphatase synaptojanin 1 to intersectin 1. These data identify the intersectin-AP2 complex as an important regulator of clathrinmediated SV recycling in synapses.endocytosis | synapse | scaffolding proteins | appendage | synaptojanin S ynaptic vesicles (SVs), following their activity-dependent exocytic fusion with the presynaptic plasma membrane, are recycled by compensatory endocytosis at the periactive zone (1-3), largely via clathrin-mediated reinternalization of fully fused SV membrane (4). Clathrin-coated pit (CCP) formation (5) proceeds through the assembly of endocytic proteins at phosphatidylinositiol (4, 5)-bisphosphate [PI(4,5)P 2 ]-enriched membrane sites (6, 7). A key factor in the assembly pathway is the heterotetrameric adaptor complex AP2, whose α-and β2-appendage domains act as major recruitment platforms for accessory proteins (6, 7), regulating distinct steps within the pathway. Despite our extensive knowledge regarding the endocytic interactome, we know comparably little about the structural components within the periactive zone that scaffold the endocytic process, thereby allowing the high fidelity of SV recycling. Such spatiotemporal control is needed to coordinate SV cargo protein sorting with coat recruitment (8) and to restrain membrane fission and uncoating until membrane deformation and CCP assembly are completed. Moreover, stabilizing scaffolds may aid coupling of SV exo-and endocytosis (1, 3). The Drosophila multidomain protein Dap160, an ortholog of mammalian intersectin, has been postulated to act as an endocytic scaffold of the periactive zone (9-11), although its precise role in SV recycling in mammalian nerve terminals remains largely unclear (12).Here we show that intersectin 1 scaffolds the endocytic process by directly associating with AP2. Acute perturbation of intersectin-AP2 complex formation blocks the onset of SV recycling. Moreover, association of the SH3A-B l...
The monomer/dimer equilibrium of adhesion molecule CEACAM1-L is regulated by binding between opposing membranes, which in turn controls cytoplasmic enzyme binding and signaling (see also in this issue the accompanying paper by Klaile et al.).
Structural analyses reveal that oligomerization between cell adhesion molecules in the same membrane is influenced by their interactions across opposing membranes (see also in this issue the accompanying paper by Müller et al.).
Electrostatic interactions between DNA and DNA-packaging proteins, the histones, contribute substantially to stability of eukaryotic chromatin on all levels of its organization and are particularly important in formation of its elementary structural unit, the nucleosome. The release of DNA from the histones is an unavoidable stage in reading the DNA code. In the present review, we discuss the disassembly/assembly process of the nucleosome from a thermodynamic standpoint by considering it as a competition between an excess of polyanions (DNA and acidic/phosphorylated domains of the nuclear proteins) for binding to a limited pool of polycations (the histones). Results obtained in model systems are used to discuss conditions for the electrostatic component of DNA-protein interactions contributing to chromatin statics and dynamics. We propose a simple set of "electrostatic conditions" for the disassembly/assembly of nucleosome/chromatin and apply these to put forward a number of new interpretations for the observations reported in literature on chromatin. The approach sheds light on the functions of acidic domains in the nuclear proteins (nucleoplasmin and other histone chaperones, HMG proteins, the activation domains in transcriptional activators). It results in a putative explanation for the molecular mechanisms behind epigenetic regulation through histone acetylation, phosphorylation, and other alterations ("the language of covalent histone modification"). We also propose a new explanation for the role of phosphorylation of C-terminal domain of RNA polymerase II for regulation of the DNA transcription. Several other examples from literature on chromatin are discussed to support applicability of electrostatic rules for description of chromatin structure and dynamics.
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