UMLS:C0162871 - FACTA Search

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Query: UMLS:C0162871 (abdominal aortic aneurysm)
8,664 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The AAA(+) ATPase component of magnesium chelatase (ChlI) drives the insertion of Mg(2+) into protoporphyrin IX; this is the first step in chlorophyll biosynthesis. We describe the ATPase activity, nucleotide binding kinetics, and structural organization of the ChlI protein. A consistent reaction scheme arises from our detailed steady state description of the ATPase activity of the ChlI subunit and from transient kinetic analysis of nucleotide binding. We provide the first demonstration of metal ion binding to a specific subunit of any of the multimeric chelatases and characterize binding of Mg(2+) to the free and MgATP(2)(-) bound forms of ChlI. Transient kinetic studies with the fluorescent substrate analogue TNP-ATP show that there are two forms of monomeric enzyme, which have distinct magnesium binding properties. Additionally, we describe the self-association properties of the subunit and provide a structural analysis of the multimeric ring formed by this enzyme in the presence of nucleotide. This single particle analysis demonstrates that this species has a 7-fold rotational symmetry, which is in marked contrast to most members of the AAA(+) family that tend to form hexamers.
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PMID:The ATPase activity of the ChlI subunit of magnesium chelatase and formation of a heptameric AAA+ ring. 1277 46

The AAA+ protein ClpB mediates the solubilization of protein aggregates in cooperation with the DnaK chaperone system (KJE). The order of action of ClpB and KJE on aggregated proteins is unknown. We describe a ClpB variant with mutational alterations in the Walker B motif of both AAA domains (E279A/E678A), which binds but does not hydrolyze ATP. This variant associates in vitro and in vivo in a stable manner with protein substrates, demonstrating direct interaction of ClpB with protein aggregates for the first time. Substrate interaction is strictly dependent on ATP binding to both AAA domains of ClpB. The unique substrate binding properties of the double Walker B variant allowed to dissect the order of ClpB and DnaK action during disaggregation reactions. ClpB-E279A/E678A outcompetes the DnaK system for binding to the model substrate TrfA and inhibits the dissociation of small protein aggregates by DnaK only, indicating that ClpB acts prior to DnaK on protein substrates.
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PMID:Characterization of a trap mutant of the AAA+ chaperone ClpB. 1280 57

The 97-kDa valosin-containing protein (p97-VCP) belongs to the AAA (ATPases associated with various cellular activities) family and acts as a molecular chaperone in diverse cellular events, including ubiquitinproteasome-mediated degradation. We previously showed that VCP contains a substrate-binding domain, N, and two conserved ATPase domains, D1 and D2, of which D2 is responsible for the major enzyme activity. VCP has a barrel-like structure containing two stacked homo-hexameric rings made of the D1 and D2 domains, and this structure is essential for its biological functions. During ATPase cycles, VCP undergoes conformational changes that presumably apply tensions to the bound substrate, leading to the disassembly of protein complexes or unfolding of the substrate. How ATPase activity is coupled with the conformational changes in VCP complex and the D1 and D2 rings is not clear. In this report, we took biochemical approaches to study the structure of VCP in different nucleotide conditions to depict the conformational changes in the ATPase cycles. In contrast to many AAA chaperones that require ATP/ADP to form oligomers, both wild type VCP and ATP-binding site mutants can form hexamers without the addition of nucleotide. This nucleotide-independent hexamerization requires an intact D1 and the down-stream linker sequence of VCP. Tryptophan fluorescence and trypsin digestion analyses showed that ATP/ADP binding induces dramatic conformational changes in VCP. These changes do not require the presence of an intact ATP-binding site in D1 and is thus mainly attributed to the D2 domain. We propose a model whereby D1, although undergoing minor conformational changes, remains as a relatively trypsin-resistant hexameric ring throughout the ATPase cycle, whereas D2 only does so when it binds to ATP or ADP. After ADP is released at the end of the ATP hydrolysis, D2 ring is destabilized and adopts a relatively flexible and open structure.
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PMID:D1 ring is stable and nucleotide-independent, whereas D2 ring undergoes major conformational changes during the ATPase cycle of p97-VCP. 1280 84

The gene products (peroxins) of at least 29 PEX genes are known to be necessary for peroxisome biogenesis but for most of them their precise function remains to be established. Here we show that Pex15p, an integral peroxisomal membrane protein, in vivo and in vitro binds the AAA peroxin Pex6p. This interaction functionally interconnects these two hitherto unrelated peroxins. Pex15p provides the mechanistic basis for the reversible targeting of Pex6p to peroxisomal membranes. We could demonstrate that the N-terminal part of Pex6p contains the binding site for Pex15p and that the two AAA cassettes D1 and D2 of Pex6p have opposite effects on this interaction. A point mutation in the Walker A motif of D1 (K489A) decreased the binding of Pex6p to Pex15p indicating that the interaction of Pex6p with Pex15p required binding of ATP. Mutations in Walker A (K778A) and B (D831Q) motifs of D2 abolished growth on oleate and led to a considerable larger fraction of peroxisome bound Pex6p. The nature of these mutations suggested that ATP-hydrolysis is required to disconnect Pex6p from Pex15p. On the basis of these results, we propose that Pex6p exerts at least part of its function by an ATP-dependent cycle of recruitment and release to and from Pex15p.
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PMID:Pex15p of Saccharomyces cerevisiae provides a molecular basis for recruitment of the AAA peroxin Pex6p to peroxisomal membranes. 1280 25

We report here the crystal structure of an SF3 DNA helicase, Rep40, from adeno-associated virus 2 (AAV2). We show that AAV2 Rep40 is structurally more similar to the AAA(+) class of cellular proteins than to DNA helicases from other superfamilies. The structure delineates the expected Walker A and B motifs, but also reveals an unexpected "arginine finger" that directly implies the requirement of Rep40 oligomerization for ATP hydrolysis and helicase activity. Further, the Rep40 AAA(+) domain is novel in that it is unimodular as opposed to bimodular. Altogether, the structural connection to AAA(+) proteins defines the general architecture of SF3 DNA helicases, a family that includes simian virus 40 (SV40) T antigen, as well as provides a conceptual framework for understanding the role of Rep proteins during AAV DNA replication, packaging, and site-specific integration.
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PMID:Crystal structure of the SF3 helicase from adeno-associated virus type 2. 1290 33

Intracellular membrane fusion is conserved from yeast to man as well as among different intracellular trafficking pathways. This process can be generally divided into several well-defined biochemical reactions. First, an early recognition (or tethering) takes place between donor and acceptor membranes, mediated by ypt/rab GTPases and complexes of tethering factors. Subsequently, a closer association between the two membranes is achieved by a docking process, which involves tight association between membrane proteins termed SNAREs. The formation of such a trans-SNARE complex leads to the final membrane fusion, resulting in an accumulation of cis-SNARE complexes on the acceptor membrane. Thus, multiple rounds of transport and delivery of the donor SNARE back to its original membrane require dissociation of the SNARE complexes. SNARE dissociation, termed priming, is mediated by the AAA ATPase, N-ethylmaleimide-sensitive factor (NSF) and its partner, soluble NSF attachment protein (SNAP), in a reaction that requires ATP hydrolysis. In the present review we focus on LMA1 and GATE-16, two low-molecular-weight proteins, which assist in priming SNARE molecules in the vacuole in yeast and the Golgi complex in mammals, respectively. LMA1 and GATE-16 are suggested to keep the dissociated cis-SNAREs apart from each other, allowing multiple fusion processes to take place. GATE-16 belongs to a novel family of ubiquitin-like proteins conserved from yeast to man. We discuss here the involvement of this family in multiple intracellular trafficking pathways.
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PMID:Involvement of LMA1 and GATE-16 family members in intracellular membrane dynamics. 1291 55

N-ethyl maleimide sensitive factor (NSF) belongs to the AAA family of ATPases and is involved in a number of cellular functions, including vesicle fusion and trafficking of membrane proteins. We present the three-dimensional structure of the hydrolysis mutant E329Q of NSF complexed with an ATP-ADP mixture at 11 A resolution by electron cryomicroscopy and single-particle averaging of NSF.alpha-SNAP.SNARE complexes. The NSF domains D1 and D2 form hexameric rings that are arranged in a double-layered barrel. Our structure is more consistent with an antiparallel orientation of the two rings rather than a parallel one. The crystal structure of the D2 domain of NSF was docked into the EM density map and shows good agreement, including details at the secondary structural level. Six protrusions corresponding to the N domain of NSF (NSF-N) emerge from the sides of the D1 domain ring. The density corresponding to alpha-SNAP and SNAREs is located on the 6-fold axis of the structure, near the NSF-N domains. The density of the N domain is weak, suggesting conformational variability in this part of NSF.
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PMID:Electron cryomicroscopy structure of N-ethyl maleimide sensitive factor at 11 A resolution. 1294 89

Archaea are a valuable source of enzymes for industrial and scientific applications because of their ability to survive extreme conditions including high salt and temperature. Thanks to advances in molecular biology and genetics, archaea are also attractive hosts for metabolic engineering. Understanding how energy-dependent proteases and chaperones function to maintain protein quality control is key to high-level synthesis of recombinant products. In archaea, proteasomes are central players in energy-dependent proteolysis and form elaborate nanocompartments that degrade proteins into oligopeptides by processive hydrolysis. The catalytic core responsible for this proteolytic activity is the 20S proteasome, a barrel-shaped particle with a central channel and axial gates on each end that limit substrate access to a central proteolytic chamber. AAA proteins (ATPases associated with various cellular activities) are likely to play several roles in mediating energy-dependent proteolysis by the proteasome. These include ATP binding/hydrolysis, substrate binding/unfolding, opening of the axial gates, and translocation of substrate into the proteolytic chamber.
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PMID:Archaeal proteasomes: potential in metabolic engineering. 1294 49

Vps4p (End13p) is an AAA-family ATPase that functions in membrane transport through endosomes, sorting of soluble vacuolar proteins to the vacuole, and multivesicular body (MVB) sorting of membrane proteins to the vacuole lumen. In a yeast two-hybrid screen with Vps4p as bait we isolated VPS20 (YMR077c) and the novel open reading frame YLR181c, for which the name VTA1 has recently been assigned (Saccharomyces Genome Database). Vps4p directly binds Vps20p and Vta1p in vitro and binding is not dependent on ATP - conversely, Vps4p binding to Vps20p is partially sensitive to ATP hydrolysis. Both ATP binding [Vps4p-(K179A)] and ATP hydrolysis [Vps4p-(E233Q)] mutant proteins exhibit enhanced binding to Vps20p and Vta1p in vitro. The Vps4p-Vps20p interaction involves the coiled-coil domain of each protein, whereas the Vps4p-Vta1p interaction involves the (non-coiled-coil) C-terminus of each protein. Deletion of either VPS20 (vps20Delta) or VTA1 (vta1Delta) leads to similar class E Vps- phenotypes resembling those of vps4Delta, including carboxypeptidase Y (CPY) secretion, a block in ubiquitin-dependent MVB sorting, and a delay in both post-internalisation endocytic transport and biosynthetic transport to the vacuole. The vacuole resident membrane protein Sna3p (whose MVB sorting is ubiquitin-independent) does not appear to exit the class E compartment or reach the vacuole in cells lacking Vps20p, Vta1p or Vps4p, in contrast to other proteins whose delivery to the vacuole is only delayed. We propose that Vps20p and Vta1p regulate Vps4p function in vivo.
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PMID:Vps20p and Vta1p interact with Vps4p and function in multivesicular body sorting and endosomal transport in Saccharomyces cerevisiae. 1295 57

The integrity of the inner membrane of mitochondria is maintained by a membrane-embedded quality control system that ensures the removal of misfolded membrane proteins. Two ATP-dependent AAA proteases with catalytic sites at opposite membrane surfaces are key components of this proteolytic system. Here we describe the identification of a novel conserved metallopeptidase that exerts activities overlapping with the m-AAA protease and was therefore termed Oma1. Both peptidases are integral parts of the inner membrane and mediate the proteolytic breakdown of a misfolded derivative of the polytopic inner membrane protein Oxa1. The m-AAA protease cleaves off the matrix-exposed C-terminal domain of Oxa1 and processively degrades its transmembrane domain. In the absence of the m-AAA protease, proteolysis of Oxa1 is mediated in an ATP-independent manner by Oma1 and a yet unknown peptidase resulting in the accumulation of N- and C-terminal proteolytic fragments. Oma1 exposes its proteolytic center to the matrix side; however, mapping of Oma1 cleavage sites reveals clipping of Oxa1 in loop regions at both membrane surfaces. These results identify Oma1 as a novel component of the quality control system in the inner membrane of mitochondria. Proteins homologous to Oma1 are present in higher eukaryotic cells, eubacteria and archaebacteria, suggesting that Oma1 is the founding member of a conserved family of membrane-embedded metallopeptidases.
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PMID:Oma1, a novel membrane-bound metallopeptidase in mitochondria with activities overlapping with the m-AAA protease. 1296 38

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