Nucleotide-dependent conformational changes in dynamin: evidence for a mechanochemical molecular spring.

The GTPase dynamin plays an essential part in endocytosis by catalysing the fission of nascent clathrin-coated vesicles from the plasma membrane. Using preformed phosphatidylinositol-4,5-bisphosphate-containing lipid nanotubes as a membrane template for dynamin self-assembly, we investigate the conformational changes that arise during GTP hydrolysis by dynamin. Electron microscopy reveals that, in the GTP-bound state, dynamin rings appear to be tightly packed together. After GTP hydrolysis, the spacing between rings increases nearly twofold. When bound to the nanotubes, dynamin's GTPase activity is cooperative and is increased by three orders of magnitude compared with the activity of unbound dynamin. An increase in the Kcat (but not the K(m) of GTP hydrolysis accounts for the pronounced cooperativity. These data indicate that a novel, lengthwise ('spring-like') conformational change in a dynamin helix may participate in vesicle fission.

The structural era of endocytosis.

Endocytosis is crucial for an array of cellular functions and can occur through several distinct mechanisms with the capacity to internalize anything from small molecules to entire cells. The clathrin-mediated endocytic pathway has recently received considerable attention because of (i) the identification of an array of molecules that orchestrate the assembly of clathrin-coated vesicles and the selection of the vesicle cargo and (ii) the resolution of structures for a number of these proteins. Together, these data provide an initial three-dimensional framework for understanding the clathrin endocytic machinery.

Simultaneous binding of PtdIns(4,5)P2 and clathrin by AP180 in the nucleation of clathrin lattices on membranes.

Adaptor protein 180 (AP180) and its homolog, clathrin assembly lymphoid myeloid leukemia protein (CALM), are closely related proteins that play important roles in clathrin-mediated endocytosis. Here, we present the structure of the NH2-terminal domain of CALM bound to phosphatidylinositol-4,5- bisphosphate [PtdIns(4,5)P2] via a lysine-rich motif. This motif is found in other proteins predicted to have domains of similar structure (for example, Huntingtin interacting protein 1). The structure is in part similar to the epsin NH2-terminal (ENTH) domain, but epsin lacks the PtdIns(4,5)P2-binding site. Because AP180 could bind to PtdIns(4,5)P2 and clathrin simultaneously, it may serve to tether clathrin to the membrane. This was shown by using purified components and a budding assay on preformed lipid monolayers. In the presence of AP180, clathrin lattices formed on the monolayer. When AP2 was also present, coated pits were formed.

Differential release of amino acids, neuropeptides, and catecholamines from isolated nerve terminals.

We have investigated transmitter release from small and large dense-core vesicles in nerve terminals isolated from guinea pig hippocampus. Small vesicles are found in clusters near the active zone, and large dense-core vesicles are located at ectopic sites. The abilities of Ca2+ channel activation and uniform elevation of Ca2+ concentration (with ionophores) to evoke secretion of representative amino acids, catecholamines, and neuropeptides were compared. For a given increase in Ca2+ concentration, ionophore was less effective than Ca2+ channel activation in releasing amino acids, but not in releasing cholecystokinin-8. Titration of the average Ca2+ concentration showed that the Ca2+ affinity for cholecystokinin-8 secretion was higher than that for amino acids. Catecholamine release showed intermediate behavior. It is concluded that neuropeptide release is triggered by small elevations in the Ca2+ concentration in the bulk cytoplasm, whereas secretion of amino acids requires higher elevations, as produced in the vicinity of Ca2+ channels.

The Peripheral Inflammatory Response to Alpha-Synuclein and Endotoxin in Parkinson's Disease.

The immune system is activated in Parkinson's Disease (PD), as evidenced by neuroinflammatory changes within the brain as well as elevated immune markers in peripheral blood. Furthermore, inflammatory cytokine levels in the blood are associated with disease severity and rate of progression. However, the factors driving this immune response in PD are not well established. We investigated cell-extrinsic factors in systemic immune activation by using α-synuclein monomers and fibrils, as well as bacterial toxins, to stimulate peripheral blood mononuclear cells (PBMCs) derived from 31 patients and age/gender-matched controls. α-synuclein monomers or fibrils resulted in a robust cytokine response (as measured by supernatant cytokine concentrations and mRNA expression in cultured cells) in both PD and control PBMCs, similar to that induced by bacterial LPS. We found no PD vs. control differences in cytokine production, nor in mRNA expression. Levels of endotoxin within the recombinant α-synuclein used in these experiments were very low (0.2-1.3EU/mL), but nonetheless we found that comparable levels were sufficient to potentially confound our cytokine concentration measurements for a number of cytokines. However, α-synuclein monomers increased production of IL-1ß and IL-18 to levels significantly in excess of those induced by low-level endotoxin. In conclusion, this study: (i) highlights the importance of accounting for low-level endotoxin in antigen-PBMC stimulation experiments; (ii) indicates that cell-extrinsic factors may be a major contributor to immune activation in PD; and (iii) suggests that α-synuclein may play a role in inflammasome-related cytokine production in the periphery.

Endocytosis: an assembly protein for clathrin cages.

The protein AP180 is known to have clathrin-assembly activity in vitro. AP180 has now been found to be crucial for synaptic vesicle endocytosis and the maintenance of a uniform-size vesicle population in vivo. These results significantly advance our understanding of clathrin-mediated endocytosis in the synapse and elsewhere.

Inhibition of receptor-mediated endocytosis by the amphiphysin SH3 domain.

BACKGROUND: Receptor-mediated endocytosis appears to require the GTP-binding protein dynamin, but the process by which dynamin is recruited to clathrin-coated pits remains unclear. Dynamin contains several proline-rich clusters that bind to Src homology 3 (SH3) domains, which are short modules found in many signalling proteins and which mediate protein-protein interactions. Amphiphysin, a protein that is highly expressed in the brain, interacts with dynamin in vitro, as do Grb2 and many other SH3 domain-containing proteins. In this study, we examined the role of amphiphysin in receptor-mediated endocytosis in vivo. RESULTS: To address the importance of the amphiphysin SH3 domain in dynamin recruitment, we used a transferrin and epidermal growth factor (EGF) uptake assay in COS-7 fibroblasts. Amphiphysin is present in these cells at a low level and indeed in other peripheral tissues. Confocal immunofluorescence revealed that cells transfected with the amphiphysin SH3 domain showed a potent blockade in receptor-mediated endocytosis. To test whether the cellular target of amphiphysin is dynamin, COS-7 cells were contransfected with both dynamin and the amphiphysin SH3 domain; here, transferrin uptake was efficiently rescued. Importantly, the SH3 domains of Grb2, phospholipase C gamma and spectrin all failed to exert any effect on endocytosis. The mechanism of amphiphysin action in recruiting dynamin was additionally tested in vitro: amphiphysin could associate with both dynamin and alpha-adaptin simultaneously, further supporting a role for amphiphysin in endocytosis. CONCLUSIONS: Our results suggest that the SH3 domain of amphiphysin recruits dynamin to coated pits in vivo, probably via plasma membrane adaptor complexes. We propose that amphiphysin is not only required for synaptic-vesicle endocytosis, but might also be a key player in dynamin recruitment in all cells undergoing receptor-mediated endocytosis.

Calcium triggers calcineurin-dependent synaptic vesicle recycling in mammalian nerve terminals.

BACKGROUND: Following exocytosis at the synapse, synaptic vesicle components are recovered by endocytosis. Morphological analysis has suggested that this occurs by a clathrin-mediated pathway, and the GTPase dynamin is thought to be involved in 'pinching off' endocytosing vesicles. The finding that the calcium-dependent phosphatase calcineurin can dephosphorylate dynamin and two other proteins implicated in endocytosis (amphiphysin and synaptojanin) has suggested a potential role for calcium and dephosphorylation in regulating synaptic vesicle endocytosis. RESULTS: We tested this hypothesis with an endocytosis assay in isolated nerve terminals (synaptosomes) that relies on the use of the fluorescent dye FM2-10. In synaptosomes, vesicle recycling occurs predominantly via a pathway dependent on both dynamin and amphiphysin. We found that endocytosis could be stimulated maximally at calcium concentrations that yielded only low levels of exocytosis, suggesting that the two processes had different calcium sensitivities cyclosporin A and Fk506, we identified calcineurin as a calcium sensor for endocytosis and showed that its activity is essential for synaptic vesicle endocytosis in synaptosomes. CONCLUSIONS: Our results suggest that dynamin-dependent synaptic vesicle endocytosis is triggered by calcium influx occurring upon nerve-terminal depolarisation. An essential mediator of calcium's effect is calcineurin, the activation of which leads to dephosphorylation of at least four proteins implicated in endocytosis-dynamin, amphiphysin 1, amphiphysin 2 and synaptojanin. Our findings also imply that endocytosis and exocytosis may occur in tandem in vivo simply because they share a responsiveness to calcium influx, rather than because they are mechanistically coupled.

Importance of the pleckstrin homology domain of dynamin in clathrin-mediated endocytosis.

The GTPase dynamin plays an essential role in clathrin-mediated endocytosis [1] [2] [3]. Substantial evidence suggests that dynamin oligomerisation around the necks of endocytosing vesicles and subsequent dynamin-catalysed GTP hydrolysis is responsible for membrane fission [4] [5]. The pleckstrin homology (PH) domain of dynamin has previously been shown to interact with phosphoinositides, but it has not been determined whether this interaction is essential for dynamin's function in endocytosis [6] [7] [8] [9]. In this study, we address the in vivo function of the PH domain of dynamin by assaying the effects of deletions and point mutations in this region on transferrin uptake in COS-7 fibroblasts. Overexpression of a dynamin construct lacking its entire PH domain potently blocked transferrin uptake, as did overexpression of a dynamin construct containing a mutation in the first variable loop of the PH domain. Structural modelling of this latter mutant suggested that the lysine residue at position 535 (Lys535) may be critical in the coordination of phosphoinositides, and indeed, the purified mutant no longer interacted with lipid nanotubes. Interestingly, the inhibitory phenotype of cells expressing this dynamin mutant was partially relieved by a second mutation in the carboxy-terminal proline-rich domain (PRD), one that prevents dynamin from binding to the Src homology 3 (SH3) domain of amphiphysin. These data demonstrate that dynamin's interaction with phosphoinositides through its PH domain is essential for endocytosis. These findings also support our hypothesis that PRD-SH3 domain interactions are important in the recruitment of dynamin to sites of endocytosis.

Amphiphysin heterodimers: potential role in clathrin-mediated endocytosis.

Amphiphysin (Amph) is a src homology 3 domain-containing protein that has been implicated in synaptic vesicle endocytosis as a result of its interaction with dynamin. In a screen for novel members of the amphiphysin family, we identified Amph2, an isoform 49% identical to the previously characterized Amph1 protein. The subcellular distribution of this isoform parallels Amph1, both being enriched in nerve terminals. Like Amph1, a role in endocytosis at the nerve terminal is supported by the rapid dephosphorylation of Amph2 on depolarization. Importantly, the two isoforms can be coimmunoprecipitated from the brain as an equimolar complex, suggesting that the two isoforms act in concert. As determined by cross-linking of brain extracts, the Amph1-Amph2 complex is a 220- to 250-kDa heterodimer. COS cells transfected with either Amph1 or Amph2 show greatly reduced transferrin uptake, but coexpression of the two proteins rescues this defect, supporting a role for the heterodimer in clathrin-mediated endocytosis. Although the src homology 3 domains of both isoforms interact with dynamin, the heterodimer can associate with multiple dynamin molecules in vitro and activates dynamin's GTPase activity. We propose that it is an amphiphysin heterodimer that drives the recruitment of dynamin to clathrin-coated pits in endocytosing nerve terminals.

The amphiphysin family of proteins and their role in endocytosis at the synapse.

Clathrin-mediated endocytosis at the plasma membrane is a major pathway of synaptic vesicle recycling in neurones, but little is known about the molecular machinery that orchestrates the process. The amphiphysin protein has recently emerged into the limelight since its discovery in 1992 as a synaptic vesicle-associated protein. It was subsequently found to interact in vitro with the GTPase dynamin through its SH3 domain. However, only in the past year has its role in endocytosis been confirmed, with the demonstration that the introduction of dominant-negative-acting SH3 domains into living cells causes a potent blockade of clathrin-mediated endocytosis. This, together with the discovery by several groups of a second nerve terminal-enriched amphiphysin isoform, and the finding that the two proteins heterodimerize, further suggests that the amphiphysins are closely connected with dynamin-mediated vesicle budding. This review summarizes current views in the field, and draws on data that suggest intriguing alternative roles--including possible involvement in the cytoskeleton and in tumour suppression--for certain members of the amphiphysin family.

Clathrin interacts specifically with amphiphysin and is displaced by dynamin.

Amphiphysin is an SH3 domain protein that has been implicated in synaptic vesicle endocytosis. We have recently cloned a second amphiphysin isoform, Amph2 (sequence submitted to GenBank, Y13380). Proteins capable of forming a complex with amphiphysin were isolated from rat brain by using recombinant GST-Amph2 for binding experiments. As well as interacting with dynamin I, the full-length protein bound to a weaker 180-kDa band. Immunoblotting demonstrated this protein to be clathrin. To address whether this is a direct interaction, the clathrin binding to amphiphysin was reconstituted in vitro with purified proteins. The N-terminal domain of Amph2 is sufficient for clathrin binding. Dynamin, which interacts with the SH3 domain of Amph2, displaces clathrin from the N-terminus. We propose a model that may explain how clathrin and dynamin are recruited to non-overlapping sites of the coated pit.

Ca2+-dependent and Ca2+-independent glutamate release, energy status and cytosolic free Ca2+ concentration in isolated nerve terminals following metabolic inhibition: possible relevance to hypoglycaemia and anoxia.

Hypoglycaemia and anoxia both cause massive release of glutamate from the brain in vivo, and the nature of this release was investigated using guinea-pig cerebral-cortical synaptosomes and iodoacetate and rotenone to simulate the energetic consequences of these conditions. Glutamate release (by continuous fluorimetry), cytoplasmic free Ca2+ (by fura-2), membrane potentials, ATP, ADP and creatine phosphate were determined in parallel, following the addition of iodoacetate or rotenone, alone or in combination. Ca2+-dependent glutamate release had a high energy requirement which could only be satisfied by aerobic glycolysis. Respiration using endogenous substrates, or anaerobic glycolysis following rotenone, caused a progressive inhibition of Ca2+-dependent release, correlating with a decline in the total ATP/ADP ratio and creatine phosphate. With rotenone, an increase in Ca2+-independent glutamate release was observed, correlating with a decline in plasma membrane potential. Only a slight increase in free Ca2+ was seen. Rotenone plus iodoacetate caused an almost immediate collapse of ATP/ADP ratio and a parallel loss of Ca2+-dependent glutamate release before free Ca2+ had risen to a level sufficient for exocytosis. In contrast, Ca2+-independent glutamate release increased. The Ca2+-dependent release of L-glutamate had the characteristics of an exocytotic transmitter release mechanism, being energy-dependent and triggered by elevated cytoplasmic free Ca2+ concentration. A distinct Ca2+-independent release of cytoplasmic glutamate occurred by reversal of the Na+-coupled uptake carrier, which was accelerated by a decline in the Na+ gradient. It is concluded that the Ca2+-independent release of cytoplasmic glutamate may make the major contribution to the excitotoxic release of glutamate in hypoglycaemic and anoxic conditions.

Synaptic core complex of synaptobrevin, syntaxin, and SNAP25 forms high affinity alpha-SNAP binding site.

SNAPs (soluble NSF attachment proteins) are cytoplasmic proteins that bind to specific membrane receptors and mediate the membrane binding of NSF (N-ethylmaleimide-sensitive factor), a protein that is required for membrane fusion reactions. Three synaptic proteins in brain (SNAP25 (synaptosomal-associated protein of 25 kDa; no relation to the SNAPs for NSF), synaptobrevin/VAMP, and syntaxin) were identified as SNAP receptors by affinity chromatography on immobilized alpha-SNAP complexed to NSF (Söllner, T., Whiteheart, S. W., Brunner, M., Erdjument-Bromage, H., Geromanos, S., Tempst, P. and Rothman, J. E. (1993) Nature 362, 318-324). However, the nature of the alpha-SNAP binding site is unclear. We now show that alpha-SNAP binds tightly to the complex of syntaxin with synaptobrevin. SNAP25 is not required for tight binding of alpha-SNAP to this complex but stabilizes the syntaxin-synaptobrevin complex by forming a trimeric core complex with it. alpha-SNAP does not bind to synaptobrevin individually and binds only weakly to syntaxin and SNAP25 in the absence of synaptobrevin. These data suggest that the complex of the vesicular protein synaptobrevin with the plasma membrane protein syntaxin is required for physiological alpha-SNAP binding. Thus, alpha-SNAP probably functions in a late step of the membrane fusion reaction after the formation of the synaptobrevin-syntaxin-SNAP25 core complex.

Barium-evoked glutamate release from guinea-pig cerebrocortical synaptosomes.

Ba2+ has multiple effects on presynaptic terminals. The ion inhibits the K+ channels responsible for stabilizing the plasma membrane potential in the same way as previously reported for dendrotoxin and 4-aminopyridine. Secondly, the ion can substitute fully for Ca2+ in supporting KCl-evoked release of glutamate from guinea-pig cerebrocortical synaptosomes. In the latter case, the kinetics of glutamate release in the presence of saturating Ca2+ or Ba2+ are essentially identical. Substantially lower external concentrations of Ba2+ are required to achieve the same release kinetics as with Ca2+. The average internal free Ba2+ concentration attained during KCl depolarization is some 10-fold higher than that for Ca2+. However, because the fura-2 signal reflects predominantly the overflow of divalent cation after dissociation from the release trigger, it is not the valid parameter to compare effectiveness of the cations in triggering glutamate exocytosis. In view of the established inability of Ba2+ to interact with calmodulin, these results are discussed in relation to theories in which Ca2+/calmodulin-dependent protein kinase-mediated phosphorylation is a prerequisite for synaptic vesicle exocytosis.

Transmitter glutamate release from isolated nerve terminals: evidence for biphasic release and triggering by localized Ca2+.

The kinetics of Ca2(+)-dependent release of glutamate from guinea-pig cerebrocortical synaptosomes evoked by KCl or 4-aminopyridine are investigated using a continuous fluorimetric assay. Release by both agents is biphasic, with a rapid phase complete within 2 s followed by a more extensive slow phase with a half-maximal release in 52 s for KCl-evoked release and greater than 120 s for 4-aminopyridine-evoked release. The two phases of glutamate release may reflect a dual localization of releasable vesicles at the active zone and in the bulk cytoplasm. Decreasing depolarization depresses the extent rather than increasing the time for half-maximal Ca2(+)-dependent release. Both the fast and the slow phases of glutamate release require external Ca2+ and cytoplasmic ATP. KCl depolarization produces a transient "spike" of cytoplasmic free Ca2+ [( Ca2+]c), which recovers to a plateau; the major component of glutamate release occurs during this plateau. Predepolarization in the absence of added external Ca2+, to inhibit transient Ca2+ channels, does not affect the subsequent glutamate release evoked by Ca2+ readdition. Thus, release involves primarily noninactivating Ca2+ channels. For a given increase in [Ca2+]c, KCl and 4-aminopyridine cause equal release of glutamate, while ionomycin releases much less glutamate. This lowered efficiency is not due to ATP depletion. It is concluded that glutamate exocytosis is evoked by localized Ca2+ entering through noninactivating voltage-dependent Ca2+ channels and that nonlocalized Ca2+ entry with ionomycin is inefficient.

Glutamine and aspartate loading of synaptosomes: a reevaluation of effects on calcium-dependent excitatory amino acid release.

Guinea-pig cerebral cortical synaptosomes were preincubated for 60 min with 100 microM D-aspartate, L-aspartate, or L-glutamate. The total D- plus L-aspartate content of the synaptosomal fraction increased to 235%, 195%, or 164%, respectively, of the control. Despite this no increase was seen in the very low KCl evoked, Ca2+-dependent release of aspartate. Preincubation with the three amino acids changed the synaptosomal glutamate content to 78% (D-aspartate), 149% (L-aspartate), or 168% (L-glutamate) of control. However there was no statistically significant effect of these preincubations on the extent of Ca2+-dependent glutamate release. Thus the Ca2+-dependent release of aspartate and glutamate is not determined by the total synaptosomal content of these amino acids. The addition of 0.1-0.5 mM glutamine to the incubation caused a massive appearance of glutamate in the extrasynaptosomal medium. Analysis of specific activities showed that glutamine was hydrolysed directly by an extrasynaptosomal glutaminase, and that intrasynaptosomal glutamate was predominantly labelled by uptake of this glutaminase-derived glutamate. No increase was seen in the extent of Ca2+-dependent release of glutamate (by fluorimetry) either after preincubation with glutamine or in the continued presence of glutamine. Thus we are unable to confirm reports that glutamine expands the transmitter pool of glutamate. The extrasynaptosomal glutaminase activity in the synaptosomal preparation was inhibited by Ca2+ and activated by phosphate. Identical kinetics were obtained with "free" brain mitochondria, confirming the origin of the glutamine-derived glutamate.

Complexins: cytosolic proteins that regulate SNAP receptor function.

A family of proteins called complexins was discovered that compete with alpha-SNAP, but not synaptotagmin, for SNAP receptor binding. Complexins I and II are highly homologous hydrophilic proteins that are tightly conserved, with 100% identity among mouse, rat, and human complexin II. They are enriched in neurons where they colocalize with syntaxin and SNAP-25; in addition, complexin II is expressed ubiquitously at low levels. Complexins bind weakly to syntaxin alone and not at all to synaptobrevin and SNAP-25, but strongly to the SNAP receptor-core complex composed of these three molecules. They compete with alpha-SNAP for binding to the core complex but not with other interacting molecules, including synaptotagmin I, suggesting that the complexins regulate the sequential interactions of alpha-SNAP and synaptotagmins with the SNAP receptor during exocytosis.

Glutamate release from guinea-pig synaptosomes: stimulation by reuptake-induced depolarization.

Glutamate (10-100 microM) reversibly depolarizes guinea-pig cerebral cortical synaptosomes. This does not appear to be because of a conventional autoreceptor. Neither kainate at 1 mM, 100 microM N-methyl-D-aspartate (NMDA), 100 microM L-2-amino-4-phosphonobutanoate (APB), nor 100 microM quisqualate affects the Ca2+-dependent release of glutamate from suboptimally depolarized synaptosomes. However, kainate, quisqualate, and the quisqualate agonists beta-N-oxalylamino-L-alanine and alpha-amino-3-hydroxy-5-methylisoxazole propionate cause a slow Ca2+-independent release of glutamate from polarized synaptosomes. However, unlike kainate, quisqualate does not inhibit the acidic amino acid carrier. APB, NMDA, and the NMDA receptor-mediated neurotoxin beta-N-methylamino-L-alanine do not influence Ca2+-independent release at 100 microM. The depolarization of the plasma membrane by glutamate can be mimicked by D-aspartate, can be blocked by the transport inhibitor dihydrokainate, and is accompanied by the net uptake of acidic amino acids. L-Glutamate or D-aspartate at 100 microM increases the cytoplasmic free Ca2+ concentration. D-aspartate at 100 microM causes a Ca2+-dependent release of endogenous glutamate, superimposed on the Ca2+-independent heteroexchange with glutamate through the acidic amino acid carrier. The results suggest that the glutamatergic subpopulation of synaptosomes can be depolarized by exogenous glutamate.