Perturbation of the vesicle cycle in reticulospinal synapses of lamprey after presynaptic microinjections of GTPγS

The synaptic vesicle cycle sustains neurotransmission and keeps exo- and endocytosis in synapses in dynamic equilibrium. GTP-binding proteins function as key regulators of this cycle. The large GTPase dynamin is implicated in the fission of clathrin-coated vesicles from presynaptic membrane during endocytosis. The present study addresses the effect of the nonhydrolysable GTP analog GTPγS on assembly of the dynamin fission complex in situ. Intraaxonal microinjections of GTPγS induced the following distinct ultrastructural changes in the synapses: the number of synaptic vesicles in a cluster decreased while the number of the docked vesicles at the active zone increased; at the same time, the clathrin-coated intermediates also increased in number, indicating the inhibition of synaptic vesicle recycling. Unusual clathrin-coated intermediates were found. At low concentrations of GTPγS, they were presented by long tubules wreathed with a dynamin helix (spiral) and topped with a clathrin-coated vesicle. At high concentrations of GTPγS the tubular structures were much shorter and branched, with each branch topped with a clathrin-coated vesicle. The spiral pitch and the tubule diameter were significantly reduced as the concentration of GTPγS built up (23.1 ± 0.4 and 26.6 ± 0.4 nm, respectively, at low and 19.0 ± 0.5 and 23.3 ± 0.4 nm at high concentration of GTPγS, p < 0.001). We suggest that these ultrastructural changes reflect different steps in dynamin-mediated fission of clathrin-coated vesicles and propose a model for this process. The model implies that at first, GTP hydrolysis leads to a fast elongation of the helix due to a straightening of its dynamin dimmers. This entails an increase both in a pitch and a diameter of the dynamin helix. The shift in diameter disrupts local hydrophobic interactions between the inner and the outer lipid layers of the membrane at the sites of dynamin binding. Concurrent stretching of the helix and the clathrin-coated vesicle’s neck disintegrates the neck membrane and results finally in a release of the clathrincoated vesicle.     

Dynamin: possible mechanism of "Pinchase" action.

Dynamin is a GTPase playing an essential role in ubiquitous intra cellular processes involving separation of vesicles from plasma membranes and membranes of cellular compartments. Recent experimental progress (. Cell. 93:1021-1029;. Cell. 94:131-141) has made it possible to attempt to understand the action of dynamin in physical terms. Dynamin molecules are shown to bind to a lipid membrane, to self-assemble into a helicoidal structure constricting the membrane into a tubule, and, as a result of GTP hydrolysis, to mediate fission of this tubule (). In a similar way, dynamin is supposed to mediate fission of a neck connecting an endocytic bud and the plasma membrane, i.e., to complete endocytosis. We suggest a mechanism of this "pinchase" action of dynamin. We propose that, as a result of GTP hydrolysis, dynamin undergoes a conformational change manifested in growth of the pitch of the dynamin helix. We show that this gives rise to a dramatic change of shape of the tubular membrane constricted inside the helix, resulting in a local tightening of the tubule, which is supposed to promote its fission. We treat this model in terms of competing elasticities of the dynamin helix and the tubular membrane and discuss the predictions of the model in relation to the previous views on the mechanism of dynamin action.     

Dynamin at the Neck of Caveolae Mediates Their Budding to Form Transport Vesicles by GTP-driven Fission from the Plasma Membrane of Endothelium

The molecular mechanisms mediating cell surface trafficking of caveolae are unknown. Caveolae bud from plasma membranes to form free carrier vesicles through a “pinching off” or fission process requiring cytosol and driven by GTP hydrolysis (Schnitzer, J.E., P. Oh, and D.P. McIntosh. 1996. Science. 274:239–242). Here, we use several independent techniques and functional assays ranging from cell-free to intact cell systems to establish a function for dynamin in the formation of transport vesicles from the endothelial cell plasma membrane by mediating fission at the neck of caveolae. This caveolar fission requires interaction with cytosolic dynamin as well as its hydrolysis of GTP. Expression of dynamin in cytosol as well as purified recombinant dynamin alone supports GTP-induced caveolar fission in a cell-free assay whereas its removal from cytosol or the addition to the cytosol of specific antibodies for dynamin inhibits this fission. Overexpression of mutant dynamin lacking normal GTPase activity not only inhibits GTP-induced fission and budding of caveolae but also prevents caveolae-mediated internalization of cholera toxin B chain in intact and permeabilized endothelial cells. Analysis of endothelium in vivo by subcellular fractionation and immunomicroscopy shows that dynamin is concentrated on caveolae, primarily at the expected site of action, their necks. Thus, through its ability to oligomerize, dynamin appears to form a structural collar around the neck of caveolae that hydrolyzes GTP to mediate internalization via the fission of caveolae from the plasma membrane to form free transport vesicles.     

Dynamin-Catalyzed Membrane Fission Requires Coordinated GTP Hydrolysis

Dynamin is the most-studied membrane fission machinery and has served as a paradigm for studies of other fission GTPases; however, several critical questions regarding its function remain unresolved. In particular, because most dynamin GTPase domain mutants studied to date equally impair both basal and assembly-stimulated GTPase activities, it has been difficult to distinguish their respective roles in clathrin-mediated endocytosis (CME) or in dynamin catalyzed membrane fission. Here we compared a new dynamin mutant, Q40E, which is selectively impaired in assembly-stimulated GTPase activity with S45N, a GTP-binding mutant equally defective in both basal and assembly-stimulated GTPase activities. Both mutants potently inhibit CME and effectively recruit other endocytic accessory proteins to stalled coated pits. However, the Q40E mutant blocks at a later step than S45N, providing additional evidence that GTP binding and/or basal GTPase activities of dynamin are required throughout clathrin coated pit maturation. Importantly, using in vitro assays for assembly-stimulated GTPase activity and membrane fission, we find that the latter is much more potently inhibited by both dominant-negative mutants than the former. These studies establish that efficient fission from supported bilayers with excess membrane reservoir (SUPER) templates requires coordinated GTP hydrolysis across two rungs of an assembled dynamin collar.     

Three-dimensional reconstruction of dynamin in the constricted state

Members of the dynamin family of GTPases have unique structural properties that might reveal a general mechanochemical basis for membrane constriction. Receptor-mediated endocytosis, caveolae internalization and certain trafficking events in the Golgi all require dynamin for vesiculation. The dynamin-related protein Drp1 (Dlp1) has been implicated in mitochondria fission and a plant dynamin-like protein phragmoplastin is involved in the vesicular events leading to cell wall formation. A common theme among these proteins is their ability to self-assemble into spirals and their localization to areas of membrane fission. Here we present the first three-dimensional structure of dynamin at a resolution of approximately 20 A, determined from cryo-electron micrographs of tubular crystals in the constricted state. The map reveals a T-shaped dimer consisting of three prominent densities: leg, stalk and head. The structure suggests that the dense stalk and head regions rearrange when GTP is added, a rearrangement that generates a force on the underlying lipid bilayer and thereby leads to membrane constriction. These results indicate that dynamin is a force-generating 'contrictase'.     

Real-time detection reveals that effectors couple dynamin's GTP-dependent conformational changes to the membrane

The GTPase dynamin is a mechanochemical enzyme involved in membrane fission, but the molecular nature of its membrane interactions and their regulation by guanine nucleotides and protein effectors remain poorly characterized. Using site-directed fluorescence labeling and several independent fluorescence spectroscopic techniques, we have developed robust assays for the detection and real-time monitoring of dynamin-membrane and dynamin-dynamin interactions. We show that dynamin interacts preferentially with highly curved, PIP2-dense membranes and inserts partially into the lipid bilayer. Our kinetic measurements further reveal that cycles of GTP binding and hydrolysis elicit major conformational rearrangements in self-assembled dynamin that favor dynamin-membrane association and dissociation, respectively. Sorting nexin 9, an abundant dynamin partner, transiently stabilizes dynamin on the membrane at the onset of stimulated GTP hydrolysis and may function to couple dynamin's mechanochemical conformational changes to membrane destabilization. Amphiphysin I has the opposite effect. Thus, dynamin's mechanochemical properties on a membrane surface are dynamically regulated by its GTPase cycle and major binding partners.     

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 Mechanoenzymatic Core of Dynamin-related Protein 1 Comprises the Minimal Machinery Required for Membrane Constriction

Mitochondria are dynamic organelles that continually undergo cycles of fission and fusion. Dynamin-related protein 1 (Drp1), a large GTPase of the dynamin superfamily, is the main mediator of mitochondrial fission. Like prototypical dynamin, Drp1 is composed of a mechanochemical core consisting of the GTPase, middle, and GTPase effector domain regions. In place of the pleckstrin homology domain in dynamin, however, Drp1 contains an unstructured variable domain, whose function is not yet fully resolved. Here, using time-resolved EM and rigorous statistical analyses, we establish the ability of full-length Drp1 to constrict lipid bilayers through a GTP hydrolysis-dependent mechanism. We also show the variable domain limits premature Drp1 assembly in solution and promotes membrane curvature. Furthermore, the mechanochemical core of Drp1, absent of the variable domain, is sufficient to mediate GTP hydrolysis-dependent membrane constriction.     

A Highlights from MBoC Selection: Dynamin recruitment and membrane scission at the neck of a clathrin-coated pit

Dynamin, the GTPase required for clathrin-mediated endocytosis, is recruited to clathrin-coated pits in two sequential phases. The first is associated with coated pit maturation; the second, with fission of the membrane neck of a coated pit. Using gene-edited cells that express dynamin2-EGFP instead of dynamin2 and live-cell TIRF imaging with single-molecule EGFP sensitivity and high temporal resolution, we detected the arrival of dynamin at coated pits and defined dynamin dimers as the preferred assembly unit. We also used live-cell spinning-disk confocal microscopy calibrated by single-molecule EGFP detection to determine the number of dynamins recruited to the coated pits. A large fraction of budding coated pits recruit between 26 and 40 dynamins (between 1 and 1.5 helical turns of a dynamin collar) during the recruitment phase associated with neck fission; 26 are enough for coated vesicle release in cells partially depleted of dynamin by RNA interference. We discuss how these results restrict models for the mechanism of dynamin-mediated membrane scission.     

Fission of biological membranes: interplay between dynamin and lipids

Membrane budding and fission are the key stages of ubiquitous processes of formation of intracellular transport vesicles. We present a theoretical consideration of one of the most important types of fission machinery, which is mediated by GTPase dynamin and controlled by lipid composition of the membrane. We suggest a mechanism for collapse of a membrane neck driven by interplay between the dynamin collar and the bending elastic energy of the neck membrane. The collar plays a role of a rigid external skeleton, which imposes mechanical constraints on the neck. We show that in certain conditions the membrane of the neck loses its stability and collapses. Collapse can result from: (i) shifting of the spontaneous curvature of the neck membrane towards negative values, (ii) stretching of the dynamin collar, (iii) tightening of the dynamin collar. The three factors can act separately or concertedly. The suggested model accounts for the major experimental knowledge on membrane fission mediated by dynamin. It includes the elements of all previous models of dynamin action based on different sets of experimental results [Sever et al., Traffic 2000; 1: 385-392]. It reconciles, at least partially, the apparent contradictions between the existing alternative views on biomembrane fission machinery.     

Alternate pleckstrin homology domain orientations regulate dynamin-catalyzed membrane fission

The self-assembling GTPase dynamin catalyzes endocytic vesicle scission via membrane insertion of its pleckstrin homology (PH) domain. However, the molecular mechanisms underlying PH domain–dependent membrane fission remain obscure. Membrane-curvature–sensing and membrane-curvature–generating properties have been attributed, but it remains to be seen whether the PH domain is involved in either process independent of dynamin self-assembly. Here, using multiple fluorescence spectroscopic and microscopic techniques, we demonstrate that the isolated PH domain does not act to bend membranes but instead senses high membrane curvature through hydrophobic insertion into the membrane bilayer. Furthermore, we use a complementary set of short- and long-distance Förster resonance energy transfer approaches to distinguish PH-domain orientation from proximity at the membrane surface in full-length dynamin. We reveal, in addition to the GTP-sensitive “hydrophobic mode,” the presence of an alternate, GTP-insensitive “electrostatic mode” of PH domain–membrane interactions that retains dynamin on the membrane surface during the GTP hydrolysis cycle. Stabilization of this alternate orientation produces dramatic variations in the morphology of membrane-bound dynamin spirals, indicating that the PH domain regulates membrane fission through the control of dynamin polymer dynamics.     

Regulation of dynamin family proteins by post-translational modifications

Dynamin superfamily proteins comprising classical dynamins and related proteins are membrane remodelling agents involved in several biological processes such as endocytosis, maintenance of organelle morphology and viral resistance. These large GTPases couple GTP hydrolysis with membrane alterations such as fission, fusion or tubulation by undergoing repeated cycles of self-assembly/disassembly. The functions of these proteins are regulated by various post-translational modifications that affect their GTPase activity, multimerization or membrane association. Recently, several reports have demonstrated variety of such modifications providing a better understanding of the mechanisms by which dynamin proteins influence cellular responses to physiological and environmental cues. In this review, we discuss major post-translational modifications along with their roles in the mechanism of dynamin functions and implications in various cellular processes.     

Perturbations of the vesicle cycle in reticulospinal synapses of axons in lamprey after presynaptic microinjections of GTPgammaS

The synaptic vesicle cycle sustains neurotransmission and keeps pace between exo- and endocytosis in synapses. GTP-binding proteins function as key regulators of this cycle. The large GTPase dynamin is implicated in fission of clathrin-coated vesicles from the presynaptic membrane during endocytosis. The present study addresses the effect of the non-hydrolysable GTP analog, GTPgammaS, on the assembly of the dynamin fission complex in situ. Intraaxonal microinjections of GTPgammaS induced distinct ultrastructural changes in synapses: the number of synaptic vesicles at active zones was reduces, and the number of docked vesicles was increased; at the same time the number of clathrin-coated intermediates at the synaptic endocytic zone was increased, indicating that synaptic vesicle recycling was inhibited. Clathrin-coated intermediates with unusual shape were found. At low concentrations of GTPgammaS they were represented by long tubules decorated by spirals containing dynamin and clathrin-coated vesicles on the top. At high concentrations of GTPgammaS the tubulular structures were shorted and branched. The pitch of the spiral and tubule's diameter were significantly reduced (23.1 +/- 0.4 and 19.0 +/- 0.5 nm, respectively, as compared to those at low concentration of GTPgammaS, 26.6 +/- 0.4 and 23.3 +/- 0.4 nm; P < 0.001). We suggest that these structural changes correspond to distinct steps in the fission reaction. A model is proposed. It implies that the fast GTP hydrolysis leads to an increase in length of the spiral due to the straightening of the dynamin dimmers, composing the spiral. This leads to a fast increase both in the pitch and the diameter of the helix. The shift in diameter breaks the local hydrophobic interactions between the inner and the outer leaflets of the lipid membrane at the sites of dynamin binding. Stretching of the spiral leads to an expansion of the neck in the longitudinal direction and promotes severing of the membrane that subsequently results in the release of the clathrin-coated vesicle.     

Membrane Tethering and Nucleotide-dependent Conformational Changes Drive Mitochondrial Genome Maintenance (Mgm1) Protein-mediated Membrane Fusion

Cellular membrane remodeling events such as mitochondrial dynamics, vesicle budding, and cell division rely on the large GTPases of the dynamin superfamily. Dynamins have long been characterized as fission molecules; however, how they mediate membrane fusion is largely unknown. Here we have characterized by cryo-electron microscopy and in vitro liposome fusion assays how the mitochondrial dynamin Mgm1 may mediate membrane fusion. Using cryo-EM, we first demonstrate that the Mgm1 complex is able to tether opposing membranes to a gap of ∼15 nm, the size of mitochondrial cristae folds. We further show that the Mgm1 oligomer undergoes a dramatic GTP-dependent conformational change suggesting that s-Mgm1 interactions could overcome repelling forces at fusion sites and that ultrastructural changes could promote the fusion of opposing membranes. Together our findings provide mechanistic details of the two known in vivo functions of Mgm1, membrane fusion and cristae maintenance, and more generally shed light onto how dynamins may function as fusion proteins.     

An Intramolecular Signaling Element that Modulates Dynamin Function In Vitro and In Vivo

Dynamin exhibits a high basal rate of GTP hydrolysis that is enhanced by self-assembly on a lipid template. Dynamin''s GTPase effector domain (GED) is required for this stimulation, though its mechanism of action is poorly understood. Recent structural work has suggested that GED may physically dock with the GTPase domain to exert its stimulatory effects. To examine how these interactions activate dynamin, we engineered a minimal GTPase-GED fusion protein (GG) that reconstitutes dynamin''s basal GTPase activity and utilized it to define the structural framework that mediates GED''s association with the GTPase domain. Chemical cross-linking of GG and mutagenesis of full-length dynamin establishes that the GTPase-GED interface is comprised of the N- and C-terminal helices of the GTPase domain and the C-terminus of GED. We further show that this interface is essential for structural stability in full-length dynamin. Finally, we identify mutations in this interface that disrupt assembly-stimulated GTP hydrolysis and dynamin-catalyzed membrane fission in vitro and impair the late stages of clathrin-mediated endocytosis in vivo. These data suggest that the components of the GTPase-GED interface act as an intramolecular signaling module, which we term the bundle signaling element, that can modulate dynamin function in vitro and in vivo.     

Rapid constriction of lipid bilayers by the mechanochemical enzyme dynamin

Dynamin, a large GTPase, is located at the necks of clathrin-coated pits where it facilitates the release of coated vesicles from the plasma membrane upon GTP binding, and hydrolysis. Previously, we have shown by negative stain electron microscopy that wild-type dynamin and a dynamin mutant lacking the C-terminal proline-rich domain, DeltaPRD, form protein-lipid tubes that constrict and vesiculate upon addition of GTP. Here, we show by time-resolved cryo-electron microscopy (cryo-EM) that DeltaPRD dynamin in the presence of GTP rapidly constricts the underlying lipid bilayer, and then gradually disassembles from the lipid. In agreement with the negative stain results, the dynamin tubes constrict from 50 to 40 nm, and their helical pitch decreases from approximately 13 to 9.4 nm. However, in contrast to the previous results, examination by cryo-EM shows that the lipid bilayer remains intact and small vesicles or fragments do not form upon GTP binding and hydrolysis. Therefore, the vesicle formation seen by negative stain may be due to the lack of mobility of the dynamin tubes on the grid during the GTP-induced conformational changes. Our results confirm that dynamin is a mechanochemical enzyme and suggest that during endocytosis dynamin is directly responsible for membrane constriction. In the cell, other proteins may enhance the activity of dynamin or the constraints induced by the surrounding coated pit and plasma membrane during constriction may cause the final membrane fission event.     

Live-Cell Imaging in Caenorhabditis elegans Reveals the Distinct Roles of Dynamin Self-Assembly and Guanosine Triphosphate Hydrolysis in the Removal of Apoptotic Cells

Dynamins are large GTPases that oligomerize along membranes. Dynamin''s membrane fission activity is believed to underlie many of its physiological functions in membrane trafficking. Previously, we reported that DYN-1 (Caenorhabditis elegans dynamin) drove the engulfment and degradation of apoptotic cells through promoting the recruitment and fusion of intracellular vesicles to phagocytic cups and phagosomes, an activity distinct from dynamin''s well-known membrane fission activity. Here, we have detected the oligomerization of DYN-1 in living C. elegans embryos and identified DYN-1 mutations that abolish DYN-1''s oligomerization or GTPase activities. Specifically, abolishing self-assembly destroys DYN-1''s association with the surfaces of extending pseudopods and maturing phagosomes, whereas inactivating guanosine triphosphate (GTP) binding blocks the dissociation of DYN-1 from these membranes. Abolishing the self-assembly or GTPase activities of DYN-1 leads to common as well as differential phagosomal maturation defects. Whereas both types of mutations cause delays in the transient enrichment of the RAB-5 GTPase to phagosomal surfaces, only the self-assembly mutation but not GTP binding mutation causes failure in recruiting the RAB-7 GTPase to phagosomal surfaces. We propose that during cell corpse removal, dynamin''s self-assembly and GTP hydrolysis activities establish a precise dynamic control of DYN-1''s transient association to its target membranes and that this control mechanism underlies the dynamic recruitment of downstream effectors to target membranes.     

Specific Interaction with Cardiolipin Triggers Functional Activation of Dynamin-Related Protein 1

Dynamin-Related Protein 1 (Drp1), a large GTPase of the dynamin superfamily, is required for mitochondrial fission in healthy and apoptotic cells. Drp1 activation is a complex process that involves translocation from the cytosol to the mitochondrial outer membrane (MOM) and assembly into rings/spirals at the MOM, leading to membrane constriction/division. Similar to dynamins, Drp1 contains GTPase (G), bundle signaling element (BSE) and stalk domains. However, instead of the lipid–interacting Pleckstrin Homology (PH) domain present in the dynamins, Drp1 contains the so-called B insert or variable domain that has been suggested to play an important role in Drp1 regulation. Different proteins have been implicated in Drp1 recruitment to the MOM, although how MOM-localized Drp1 acquires its fully functional status remains poorly understood. We found that Drp1 can interact with pure lipid bilayers enriched in the mitochondrion-specific phospholipid cardiolipin (CL). Building on our previous study, we now explore the specificity and functional consequences of this interaction. We show that a four lysine module located within the B insert of Drp1 interacts preferentially with CL over other anionic lipids. This interaction dramatically enhances Drp1 oligomerization and assembly-stimulated GTP hydrolysis. Our results add significantly to a growing body of evidence indicating that CL is an important regulator of many essential mitochondrial functions.     

Mechanical requirements for membrane fission: Common facts from various examples

Membrane fission is the last step of membrane carrier formation. As fusion, it is a very common process in eukaryotic cells, and participates in the integrity and specificity of organelles. Although many proteins have been isolated to participate in the various membrane fission reactions, we are far from understanding how membrane fission is mechanically triggered. Here we aim at reviewing the well-described examples of dynamin and lipid phase separation, and try to extract the essential requirements for fission. Then, we survey the recent knowledge obtained on other fission reactions, analyzing the similarities and differences with previous examples.     

The Drosophila circadian clock: what we know and what we don't know.

Circadian rhythms are regulated by endogenous body clocks, which are formed by rhythmic cycles of clock gene expression. Almost all reviews of the Drosophila circadian clock state that the intracellular oscillator is based on a simple negative feedback loop. However, not many 'simple' feedback loops in biology last for 24 h. Instead, the Drosophila clock is a series of precisely timed steps that are deliberately slow. In this paper, I will discuss the current model for how the Drosophila clock is regulated, and ask what questions remain to be answered.