EC:3.6.1.3 - FACTA Search

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Query: EC:3.6.1.3 (ATPase)
65,361 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Exocytosis in neurons requires proteins known as SNAREs, membrane proteins that have now been implicated in many intracellular fusion events. SNAREs assemble into stable ternary complexes that are dissociated by the ATPase NSF (N-ethylmaleimide-sensitive factor), working together with SNAPs (soluble NSF attachment proteins). Recent results have shed new light on the mechanisms underlying SNARE (SNAP receptor) complex assembly and disassembly, and suggest changes in models that relate these reactions to vesicle docking and fusion.
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PMID:Neurotransmitter release - four years of SNARE complexes. 923 12

Using quick-freeze/deep-etch electron microscopy of recombinant proteins adsorbed to mica, we show that NSF, the oligomeric ATPase involved in membrane fusion, is a hollow 10 x 16 nm cylinder whose conformation depends upon nucleotide binding. Depleted of nucleotide, NSF converts to a "splayed" protease-sensitive conformation that reveals its subunit composition. NSF's synaptic membrane substrate, the ternary SNARE complex containing syntaxin, SNAP-25, and synaptobrevin, is a 4 x 14 nm rod with a "tail" at one end, corresponding to the N-terminus of syntaxin. Using epitope tags, antibodies, and maltose-binding protein markers, we find that syntaxin and synaptobrevin are aligned in parallel in the complex, with their membrane anchors located at the same end of the rod. This SNARE rod binds with alpha-SNAP to one end of the NSF cylinder to form an asymmetric "20S" complex. Together, these images suggest how NSF could dissociate the SNARE complex and how association and dissociation of the complex could be related to membrane fusion.
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PMID:Structure and conformational changes in NSF and its membrane receptor complexes visualized by quick-freeze/deep-etch electron microscopy. 926 32

The AAA proteins (ATPases Associated with a variety of cellular Activities) are found in eubacterial, archaebacterial, and eukaryotic species and participate in a large number of cellular processes, including protein degradation, vesicle fusion, cell cycle control, and cellular secretory processes. The AAA proteins are characterized by the presence of a 230 to 250-amino acid ATPase domain referred to as the Conserved ATPase Domain or CAD. Phylogenetic analysis of 133 CAD sequences from 38 species reveal that AAA CADs are organized into discrete groups that are related not only in structure but in cellular function. Evolutionary analyses also indicate that the CAD was present in the last common ancestor of eubacteria, archaebacteria, and eukaryotes. The eubacterial CADs are found in metalloproteases, while CAD-containing proteins in the archaebacterial and eukaryotic lineages appear to have diversified by a series of gene duplication events that lead to the establishment of different functional AAA proteins, including proteasomal regulatory, NSF/Sec, and Pas proteins. The phylogeny of the CADs provides the basis for establishing the patterns of evolutionary change that characterize the AAA proteins.
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PMID:The evolution of the conserved ATPase domain (CAD): reconstructing the history of an ancient protein module. 934 2

In the yeast Saccharomyces cerevisiae, autophagy, a bulk protein degradation in the vacuole, is induced in response to nutrient starvation. In a screen for mutations that result in induction of autophagy even in the presence of nutrients, we have isolated four mutants representing two csc complementation groups. These mutants induce autophagy of which activity is represented by activation of truncated alkaline phosphatase that is designed to be expressed in the cytosol. CSC1 was cloned by complementation of loss of viability phenotype of csc1-1 mutant and shown to be identical to END13/VPS4/GRD13. Though csc1-1 mutation is recessive, cells of delta csc1 do not induce autophagy in rich media, suggesting that csc1-1 allele is not a complete loss-of-function. Csc1p is a member of novel ATPase family named AAA protein including Sec18p/NSF, Cdc48p/p97, and Pas8p. Mutation site in csc1-1 is found in the SRH region that is highly conserved among AAA proteins. Cells of csc1-1 show sorting defect of CPY and the appearance of the class E compartment. These mutant phenotypes suggest the role of the protein that is involved in the traffic among the Golgi, endosome, and the vacuole in autophagy.
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PMID:Mutational analysis of Csc1/Vps4p: involvement of endosome in regulation of autophagy in yeast. 943 54

NSF (N-ethylmaleimide-sensitive factor) is an adenosine triphosphatase (ATPase) that contributes to a protein complex essential for membrane fusion. The synaptic function of this protein was investigated by injecting, into the giant presynaptic terminal of squid, peptides that inhibit the ATPase activity of NSF stimulated by the soluble NSF attachment protein (SNAP). These peptides reduced the amount and slowed the kinetics of neurotransmitter release as a result of actions that required vesicle turnover and occurred at a step subsequent to vesicle docking. These results define NSF as an essential participant in synaptic vesicle exocytosis that regulates the kinetics of neurotransmitter release and, thereby, the integrative properties of synapses.
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PMID:Regulation of neurotransmitter release kinetics by NSF. 946 10

The fusion of endoplasmic reticulum (ER) membranes in yeast does not require Sec18p/NSF and Sec17p, two proteins needed for docking of vesicles with their target membrane. Instead, ER membranes require a NSF-related ATPase, Cdc48p. Since both vesicular and organelle fusion events use related ATPases, we investigated whether both fusion events are also SNARE mediated. We present evidence that the fusion of ER membranes requires Ufe1p, a t-SNARE that localizes to the ER, but no known v-SNAREs. We propose that the Ufe1 protein acts in the dual capacity of an organelle membrane fusion-associated SNARE by undergoing direct t-t-SNARE and Cdc48p interactions during organelle membrane fusion as well as a t-SNARE for vesicular traffic.
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PMID:Organelle membrane fusion: a novel function for the syntaxin homolog Ufe1p in ER membrane fusion. 950 16

Vacuole fusion requires Sec18p (NSF), Sec17p (alpha-SNAP), Ypt7p (GTP binding protein), Vam3p (t-SNARE), Nyv1p (v-SNARE), and LMA1 (low Mr activity 1, a heterodimer of thioredoxin and I(B)2). LMA1 requires Sec18p for saturable, high-affinity binding to vacuoles, and Sec18p "priming" ATPase requires both Sec17p and LMA1. Either the sec18-1 mutation and deletion of I(B)2, or deletion of both I(B)2 and p13 (an I(B)2 homolog) causes a striking synthetic vacuole fragmentation phenotype. Upon Sec18p ATP hydrolysis, LMA1 transfers to (and stabilizes) a Vam3p complex. LMA1 is released from vacuoles in a phosphatase-regulated reaction. This LMA1 cycle explains how priming by Sec18p is coupled to t-SNARE stabilization and to fusion.
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PMID:LMA1 binds to vacuoles at Sec18p (NSF), transfers upon ATP hydrolysis to a t-SNARE (Vam3p) complex, and is released during fusion. 965 46

Soluble factors, NSF and SNAPs, are required at many membrane fusion events within the cell. They interact with a class of type II integral membrane proteins termed SNAP receptors, or SNAREs. Interaction between cognate SNAREs on opposing membranes is a prerequisite for NSF dependent membrane fusion. NSF is an ATPase which will disrupt complexes composed of different SNAREs. However, there is increasingly abundant evidence that the SNARE complex recognised by NSF does not bridge the two fusing membranes, but rather is composed of SNAREs in the same membrane. The essential role of NSF may be to prime SNAREs for a direct role during fusion. The best characterised SNAREs in the Golgi are Sed5p in yeast and its mammalian homologue syntaxin 5, both of which are predominantly localised to the cis Golgi. The SNARE-SNARE interactions in which these two proteins are involved are strikingly similar. Sed5p and syntaxin 5 may mediate three distinct pathways for membrane flow into the cis Golgi, one from the ER, one from later Golgi cisternae, and possibly a third from endosomes. Syntaxin 5 is itself likely to cycle through the ER, and thus may be involved in homotypic fusion of ER derived transport vesicles. In all well characterised SNARE dependent membrane fusion events one of the interacting SNAREs is a syntaxin homologue. There are only eight members of the syntaxin family in yeast. Besides Sed5p two others, Tlg1p and Tlg2p, are found in the Golgi complex. They are present in a late Golgi compartment, but neither is required for transit of secreted proteins through the Golgi. We suggest that these observations are most compatible with a model for transit through the Golgi in which anterograde cargo is carried in cisternae, the enzymatic composition of which changes with time as Golgi resident enzymes are delivered in retrograde transport vesicles.
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PMID:SNAREs and membrane fusion in the Golgi apparatus. 971 10

The neuronal SNARE complex is formed via the interaction of synaptobrevin with syntaxin and SNAP-25. Purified SNARE proteins assemble spontaneously, while disassembly requires the ATPase NSF. Cycles of assembly and disassembly have been proposed to drive lipid bilayer fusion. However, this hypothesis remains to be tested in vivo. We have isolated a Drosophila temperature-sensitive paralytic mutation in syntaxin that rapidly blocks synaptic transmission at nonpermissive temperatures. This paralytic mutation specifically and selectively decreases binding to synaptobrevin and abolishes assembly of the 7S SNARE complex. Temperature-sensitive paralytic mutations in NSF (comatose) also block synaptic transmission, but over a much slower time course and with the accumulation of syntaxin and SNARE complexes on synaptic vesicles. These results provide in vivo evidence that cycles of assembly and disassembly of SNARE complexes drive membrane trafficking at synapses.
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PMID:Temperature-sensitive paralytic mutations demonstrate that synaptic exocytosis requires SNARE complex assembly and disassembly. 972 21

Previous studies have demonstrated that beta-arrestin1 serves to target G protein-coupled receptors for internalization via clathrin-coated pits and that its endocytic function is regulated by dephosphorylation at the plasma membrane. Using the yeast two-hybrid system, we have identified a novel beta-arrestin1-binding protein, NSF (N-ethylmaleimide-sensitive fusion protein), an ATPase essential for many intracellular transport reactions. We demonstrate that purified recombinant beta-arrestin1 and NSF interact in vitro and that these proteins can be coimmunoprecipitated from cells. beta-Arrestin1-NSF complex formation exhibits a conformational dependence with beta-arrestin1 preferentially interacting with the ATP bound form of NSF. In contrast to the beta-arrestin1-clathrin interaction, however, the phosphorylation state of beta-arrestin1 does not affect NSF binding. Functionally, overexpression of NSF in HEK 293 cells significantly enhances agonist-mediated beta2-adrenergic receptor (beta2-AR) internalization. Furthermore, when coexpressed with a beta-arrestin1 mutant (betaarr1S412D) that mimics a constitutively phosphorylated form of beta-arrestin1 and that acts as a dominant negative with regards to beta2-AR internalization, NSF rescues the betaarr1S412D-mediated inhibition of beta2-AR internalization. The demonstration of beta-arrestin1-NSF complex formation and the functional consequences of NSF overexpression suggest a hitherto unappreciated role for NSF in facilitating clathrin coat-mediated G protein-coupled receptor internalization.
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PMID:Identification of NSF as a beta-arrestin1-binding protein. Implications for beta2-adrenergic receptor regulation. 1019 35

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