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 hexameric ATPase, N-ethylmaleimide sensitive factor (NSF), is essential to vesicular transport and membrane fusion because it affects the conformations and associations of the soluble NSF attachment protein receptor (SNARE) proteins. NSF binds SNAREs through adaptors called soluble NSF attachment proteins (alpha- or beta-SNAP) and disassembles SNARE complexes to recycle the monomers. NSF contains three domains, two nucleotide-binding domains (NSF-D1 and -D2) and an amino terminal domain (NSF-N) that is required for SNAP-SNARE complex binding. Mutagenesis studies indicate that a cleft between the two sub-domains of NSF-N is critical for binding. The structural conservation of N domains in NSF, p97/VCP, and VAT suggests that a similar type of binding site could mediate substrate recognition by other AAA proteins. In addition to SNAP-SNARE complexes, NSF also binds other proteins and protein complexes such as AMPA receptor subunits (GluR2), beta2-adrenergic receptor, beta-Arrestin1, GATE-16, LMA1, rabs, and rab-containing complexes. The potential for these interactions indicates a broader role for NSF in the assembly/disassembly cycles of several cellular complexes and suggests that NSF may have specific regulatory effects on the functions of the proteins involved in these complexes. The structural requirements for these interactions and their physiological significance will be discussed.
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PMID:Multiple binding proteins suggest diverse functions for the N-ethylmaleimide sensitive factor. 1503 35

The 97-kDa valosin-containing protein (p97 or VCP) is a type-II AAA ( ATPases associated with a variety of activities) ATPases, which are characterized by possessing two conserved ATPase domains. VCP forms a stable homo-hexameric structure, and this two-tier ring-shaped complex acts as a molecular chaperone that mediates many seemingly unrelated cellular activities. The involvement of VCP in the ubiquitin-proteasome degradation pathway and the identification of VCP cofactors provided us important clues to the understanding of how this molecular chaperone works. In this review, we summarize the reported biological functions of VCP and explore the molecular mechanisms underlying the diverse cellular functions. We discuss the structural and biochemical studies, and elucidate how this sophisticated enzymatic machine converts chemical energy into the mechanical forces required for the chaperone activity.
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PMID:Molecular perspectives on p97-VCP: progress in understanding its structure and diverse biological functions. 1503 36

A class of inherited neurodegenerative diseases including Huntington's disease is caused by polyglutamine (polyQ) expansion in the responsible proteins. Pathology is typically associated with polyQ expansions of greater than 40 residues, and the longer the length of the expansion, the earlier the onset of disease. It has been reported that p97/VCP/Cdc48p, a member of AAA family of proteins, can bind to longer polyQ tracts. In Caenorhabditis elegans, two p97/VCP/Cdc48p homologues, C41C4.8 and C06A1.1, have been identified. Our results indicate that these p97/VCP/Cdc48p homologues have essential but redundant functions in C. elegans. To provide a model system for investigating the molecular basis of pathogenesis, we have expressed polyQ expansions fused to green fluorescent protein in the body wall muscle cells of C. elegans. When the repeats are longer than 40, discrete cytoplasmic aggregates are formed and these appear at an early stage of embryogenesis. The formation of aggregates was partially suppressed by co-expression of either C41C4.8 or C06A1.1. These results suggest that these p97/VCP/Cdc48p homologues, AAA chaperones, may play a protective role in polyQ aggregation.
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PMID:Analysis of the two p97/VCP/Cdc48p proteins of Caenorhabditis elegans and their suppression of polyglutamine-induced protein aggregation. 1503 55

Machado-Joseph disease (MJD)/Spinocerebellar ataxia type 3 (SCA3) is neurodegenerative disease which is caused by polyglutamine expansion in a responsible gene product, MJD1/Ataxin3. MJD1 has now been shown to undergo ubiquitylation and degradation by proteasome-dependent pathway. MJD1 with expanded polyglutamine tract was more resistant to degradation than normal MJD1. We established an in vitro system of ubiquitylation of MJD1, thereby biochemically purified activity to mediate polyubiquitylation of MJD1 from rabbit reticulocyte lysate. An AAA-family ATPase VCP was isolated from the active fraction, and found to binds to MJD1. Furthermore, UFD2a, a mammalian ubiquitin-chain assembly factor (E4), associated with VCP and induced polyubiquitylation of MJD1. UFD2a markedly promoted ubiquitylation and degradation of MJD1 with expanded polyglutamine tract, resulting in the clearance of MJD1 protein. In contrast, dominant-negative mutant UFD2a reduced the degradation rate of MJD1, leading to the formation of intracellular aggregation. In Drosophila model, overexpression of UFD2a significantly suppressed the neurodegeneration induced by expression of MJD1 with expanded polyglutamine tract. These findings suggest that E4 is a rate-limiting factor of degradation of pathologic polyglutamine-containing proteins, and may give a potential tool for gene therapy to control the clinical conditions of MJD.
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PMID:[Mechanisms to control degradation of polyglutamine-containing protein]. 1515

Peroxisomes are responsible for several pathways in primary metabolism, including beta-oxidation and lipid biosynthesis. PEX1 and PEX6 are hexameric AAA-type ATPases, both of which are indispensable in targeting over 50 peroxisomal resident proteins from the cytosol to the peroxisomes. Although the tandem AAA-ATPase domains in the central region of PEX1 and PEX6 are highly similar, the N-terminal sequences are unique. To better understand the distinct molecular function of these two proteins, we analyzed the unique N-terminal domain (NTD) of PEX1. Extensive computational analysis revealed weak similarity (<10% identity) of PEX1 NTD to the N-terminal domains of other membrane-related type II AAA-ATPases, such as VCP (p97) and NSF. We have determined the crystal structure of mouse PEX1 NTD at 2.05-A resolution, which clearly demonstrated that the domain belongs to the double-psi-barrel fold family found in the other AAA-ATPases. The N-domains of both VCP and NSF are structural neighbors of PEX1 NTD with a 2.7- and 2.1-A root mean square deviation of backbone atoms, respectively. Our findings suggest that the supradomain architecture, which is composed of a single N-terminal domain followed by tandem AAA domains, is a common feature of organellar membrane-associating AAA-ATPases. We propose that PEX1 functions as a protein unfoldase in peroxisomal biogenesis, using its N-terminal putative adaptor-binding domain.
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PMID:Structure of the N-terminal domain of PEX1 AAA-ATPase. Characterization of a putative adaptor-binding domain. 1532 46

Endoplasmic reticulum-associated degradation (ERAD) is a protein quality control mechanism that eliminates unwanted proteins from the endoplasmic reticulum (ER) through a ubiquitin-dependent proteasomal degradation pathway. gp78 is a previously described ER membrane-anchored ubiquitin ligase (E3) involved in ubiquitination of ER proteins. AAA ATPase (ATPase associated with various cellular activities) p97/valosin-containing protein (VCP) subsequently dislodges the ubiquitinated proteins from the ER and chaperones them to the cytosol, where they undergo proteasomal degradation. We now report that gp78 physically interacts with p97/VCP and enhances p97/VCP-polyubiquitin association. The enhanced association correlates with decreases in ER stress-induced accumulation of polyubiquitinated proteins. This effect is abolished when the p97/VCP-interacting domain of gp78 is removed. Further, using ERAD substrate CD3delta, gp78 consistently enhances p97/VCP-CD3delta binding and facilitates CD3delta degradation. Moreover, inhibition of endogenous gp78 expression by RNA interference markedly increases the levels of total polyubiquitinated proteins, including CD3delta, and abrogates VCP-CD3delta interactions. The gp78 mutant with deletion of its p97/VCP-interacting domain fails to increase CD3delta degradation and leads to accumulation of polyubiquitinated CD3delta, suggesting a failure in delivering ubiquitinated CD3delta for degradation. These data suggest that gp78-p97/VCP interaction may represent one way of coupling ubiquitination with retrotranslocation and degradation of ERAD substrates.
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PMID:AAA ATPase p97/valosin-containing protein interacts with gp78, a ubiquitin ligase for endoplasmic reticulum-associated degradation. 1533 98

The AAA ATPase p97/VCP forms complexes with different adapters to fulfill distinct cellular functions. We analyzed the structural organization of the Ufd1-Npl4 adapter complex and its interaction with p97 and compared it with another adapter, p47. We found that the binary Ufd1-Npl4 complex forms a heterodimer that cooperatively interacts with p97 via a bipartite binding mechanism. Binding site 1 (BS1) is a short hydrophobic stretch in the C-terminal domain of Ufd1. The second binding site is located at the N terminus of Npl4 and is activated upon binding of Ufd1 to Npl4. It consists of about 80 amino acids that are predicted to form a ubiquitin fold domain (UBD). Despite the lack of overall homology between Ufd1-Npl4 and p47, both adapters use identical binding mechanisms. Like the ubiquitin fold ubiquitin regulatory X (UBX) domain in p47, the Npl4-UBD interacts with p97 via the loop between its strands 3 and 4 and a conserved arginine in strand 1. Furthermore, we identified a region in p47 homologous to Ufd1-BS1. The UBD/UBX and the BS1 of both adapters interact with p97 independently, whereas homologous binding sites in both adapters compete for binding to p97. In contrast to p47, however, Ufd1-Npl4 does not regulate the ATPase activity of p97; nor does a variant of p47 that contains both binding sites but lacks the N-terminal domains. Therefore, the binding sites alone do not regulate p97 directly but rather serve as anchor points to position adapter-specific domains at critical locations to modulate p97-mediated reactions.
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PMID:The AAA ATPase p97/VCP interacts with its alternative co-factors, Ufd1-Npl4 and p47, through a common bipartite binding mechanism. 1537 28

Certain protein toxins, including cholera toxin, ricin, and Pseudomonas aeruginosa exotoxin A, are transported to the lumen of the endoplasmic reticulum where they retro-translocate across the endoplasmic reticulum membrane to enter the cytoplasm. The mechanism of retrotranslocation is poorly understood but may involve the endoplasmic reticulum-associated degradation pathway. The AAA ATPase p97 (also called valosin-containing protein) participates in the retro-translocation of cellular endoplasmic reticulum-associated degradation substrates and is therefore a candidate to participate in the retrotranslocation of protein toxins. To investigate whether p97 functions in toxin delivery to the cytoplasm, we measured the sensitivity to toxins of cells expressing either wild-type p97 or a dominant ATPase-defective p97 mutant under control of a tetracycline-inducible promoter. The rate at which cholera toxin and related toxins entered the cytoplasm was reduced in cells expressing the ATPase-defective p97, suggesting that the toxins might interact with p97. To detect interaction, the cholera toxin A chain was immunoprecipitated from cholera toxin-treated Vero cells, and co-immunoprecipitation of p97 was assessed by immunoblotting. The immunoprecipitates contained both cholera toxin A chain and p97, evidence that the two proteins are in a complex. Altogether, these results provide functional and structural evidence that p97 participates in the transport of cholera toxin to the cytoplasm.
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PMID:p97 Is in a complex with cholera toxin and influences the transport of cholera toxin and related toxins to the cytoplasm. 1569 47

Misfolded or unassembled polypeptides in the endoplasmic reticulum (ER) are retro-translocated into the cytosol and degraded by the ubiquitin-proteasome system. We reported previously that the SCF(Fbs1,2) ubiquitin-ligase complexes that contribute to ubiquitination of glycoproteins are involved in the ER-associated degradation pathway. Here we investigated how the SCF(Fbs1,2) complexes interact with unfolded glycoproteins. The SCF(Fbs1) complex was associated with p97/VCP AAA ATPase and bound to integrin-beta1, one of the SCF(Fbs1) substrates, in the cytosol in a manner dependent on p97 ATPase activity. Both Fbs1 and Fbs2 proteins interacted with denatured glycoproteins, which were modified with not only high-mannose but also complex-type oligosaccharides, more efficiently than native proteins. Given that Fbs proteins interact with innermost chitobiose in N-glycans, we propose that Fbs proteins distinguish native from unfolded glycoproteins by sensing the exposed chitobiose structure.
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PMID:Glycoprotein-specific ubiquitin ligases recognize N-glycans in unfolded substrates. 1572 43

The AAA (ATPases associated with a variety of cellular activities) family of proteins bind, hydrolyze, and release ATP to effect conformational changes, assembly, or disassembly upon their binding partners and substrate molecules. One of the members of this family, the hexameric p97/valosin-containing protein p97/VCP, is essential for the dislocation of misfolded membrane proteins from the endoplasmic reticulum. Here, we observe large motions and dynamic changes of p97/VCP as it proceeds through the ATP hydrolysis cycle. The analysis is based on crystal structures of four representative ATP hydrolysis states: APO, AMP-PNP, hydrolysis transition state ADP x AlF3, and ADP bound. Two of the structures presented herein, ADP and AMP-PNP bound, are new structures, and the ADP x AlF3 structure was re-refined to higher resolution. The largest motions occur at two stages during the hydrolysis cycle: after, but not upon, nucleotide binding and then following nucleotide release. The motions occur primarily in the D2 domain, the D1 alpha-helical domain, and the N-terminal domain, relative to the relatively stationary and invariant D1alpha/beta domain. In addition to the motions, we observed a transition from a rigid state to a flexible state upon loss of the gamma-phosphate group, and a further increase in flexibility within the D2 domains upon nucleotide release. The domains within each protomer of the hexameric p97/VCP deviate from strict 6-fold symmetry, with the more flexible ADP state exhibiting greater asymmetry compared to the relatively rigid ADP x AlF3 state, suggesting a mechanism of action in which hydrolysis and conformational changes move about the hexamer in a processive fashion.
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PMID:Nucleotide dependent motion and mechanism of action of p97/VCP. 1574 Jul 51

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