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 97-kDa molecular chaperone valosin-containing protein (VCP) belongs to a highly conserved AAA family and forms a hexameric structure that is essential for its biological functions. The AAA domain contains highly conserved motifs, the Walker A, Walker B, and the second region of homology (SRH). Although Walker A and B motifs mediate ATP binding and hydrolysis, respectively, the function of the SRH in VCP is not clear. We examined the significance of the SRH in VCP, especially the conserved Arg(359) and Arg(362) in the first AAA domain, D1 and Arg(635) and Arg(638) in the second AAA domain, D2. We show that Arg(359) and Arg(362) in D1 are critical for maintaining the hexameric structure and the ability to bind the polyubiquitin chains. Although the rest of the tested SRH mutants retain the hexameric structure, all of them exhibit severely reduced ATPase activity. Tryptophan fluorescence analysis showed that all of the tested mutants can bind to ATP or ADP. Thus, the reduced ATPase activity likely results from the hampered communications among protomers during hydrolysis. Moreover, when the ATPase-defective mutant R635A or R638A is mixed with the Walker A mutant of D2, the ATPase activity is partially restored, suggesting that Arg(635) and Arg(638) can stimulate the ATPase activity of the neighboring protomer. Interestingly, mutation of Arg(359) and Arg(362) uncouples the inhibitory effect of p47, a VCP co-factor, on the ATPase activity of VCP. Therefore, the Arg residues allow D1 to take on a specific conformation that is required for substrate binding and co-factor communications. Taken together, these results demonstrate that the conserved Arg residues in the SRH of both D1 and D2 play critical roles in communicating the conformational changes required for ATP hydrolysis, and SRH in D1 also contributes to substrate binding and co-factor communications.
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PMID:Multifunctional roles of the conserved Arg residues in the second region of homology of p97/valosin-containing protein. 1621 72

The current status of research on the structure, regulation, mechanism and importance of Rubisco activase is reviewed. The activase is now recognized to be a member of the AAA(+) family, whose members participate in macromolecular complexes that perform diverse chaperone-like functions. The conserved nucleotide-binding domain of AAA(+) family members appears to have a common fold that when applied to the activase is generally consistent with previous site-directed mutagenesis studies of the activase. Regulation of the activase in species containing both isoforms can occur via redox changes in the carboxy-terminus of the larger isoform, mediated by thioredoxin-f, which alters the response of activase to the ratio of ADP to ATP in the stroma. Studies of Rubisco activation in transgenic Arabidopsis plants demonstrated that light modulation is dependent on redox regulation of the larger isoform, providing a model for the regulation in other species. Further insights into the mechanism of the activase have emerged from an analysis of the crystal structures of Rubisco conformational variants and the identification of Rubisco residues that confer specificity in its interaction with the activase. The physiological importance of the activase is reinforced by recent studies indicating that it plays a vital role in the response of photosynthesis to temperature. Rubisco activase is one of a new type of chaperone, which in this case functions to promote and maintain the catalytic activity of Rubisco.
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PMID:Rubisco activase - Rubisco's catalytic chaperone. 1624 90

Bacterial enhancer-binding proteins (EBP) activate transcription by hydrolyzing ATP to restructure the sigma(54)-RNA polymerase-promoter complex. We compare six high resolution structures (<2.1 A) of the AAA(+) domain of EBP phage shock protein F (PspF) including apo, AMPPNP, Mg(2+)-ATP, and ADP forms. These structures permit a description of the atomic details underpinning the origins of the conformational changes occurring during ATP hydrolysis. Conserved regions of PspF's AAA(+) domain respond distinctively to nucleotide binding and hydrolysis, suggesting functional roles during the hydrolysis cycle, which completely agree with those derived from activities of PspF mutated at these positions. We propose a putative atomic switch that is responsible for coupling structural changes in the nucleotide-binding site to the repositioning of the sigma(54)-interacting loops. Striking similarities in nucleotide-specific conformational changes and atomic switch exist between PspF and the large T antigen helicase, suggesting conservation in the origin of those events amongst AAA(+) proteins.
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PMID:Structural basis of the nucleotide driven conformational changes in the AAA+ domain of transcription activator PspF. 1643 Sep 18

Dihydroxyacetone (Dha) kinases are a family of sequence-conserved enzymes which utilize either ATP (in animals, plants and eubacteria) or phosphoenolpyruvate (PEP, in eubacteria) as their source of high-energy phosphate. The kinases consist of two domains/subunits: DhaK, which binds Dha covalently in hemiaminal linkage to the Nepsilon2 of a histidine, and DhaL, an eight-helix barrel that contains the nucleotide-binding site. The PEP-dependent kinases comprise a third subunit, DhaM, which rephosphorylates in situ the firmly bound ADP cofactor. DhaM serves as the shuttle for the transfer of phosphate from the bacterial PEP: carbohydrate phosphotransferase system (PTS) to the Dha kinase. The DhaL and DhaK subunits of the PEP-dependent Escherichia coli kinase act as coactivator and corepressor of DhaR, a transcription factor from the AAA(+) family of enhancerbinding proteins. In Gram-positive bacteria genes for homologs of DhaK and DhaL occur in operons for putative transcription factors of the TetR and DeoR families. Proteins with the Dha kinase fold can be classified into three families according to phylogeny and function: Dha kinases, DhaK and DhaL homologs (paralogs) associated with putative transcription regulators of the TetR and DeoR families, and proteins with a circularly permuted domain order that belong to the DegV family.
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PMID:Small substrate, big surprise: fold, function and phylogeny of dihydroxyacetone kinases. 1650 71

N-acetylcysteine (NAC) may offer renal and hepatic protection during surgery, but in experimental studies it has been shown to impair coagulation. Since very little is known about the effects of NAC on blood coagulation in surgical patients, we studied its effects during abdominal aortic reconstruction. NAC (a bolus of 150 mg/kg followed by a continuous 24-h infusion of 150 mg/kg) or the same volume of placebo was given intravenously, in a randomized double-blinded fashion, to 20 patients undergoing abdominal aortic aneurysm repair. The haematocrit, platelet count, prothrombin time, thromboelastometry, and platelet aggregation were studied during and after surgery. Total blood loss was also measured. The median (25th-75th percentiles) decrease of the prothrombin time value was 33.0% (30-37%) after NAC treatment and 6.5% (4-8%) after placebo (P<0.001). Postoperative prothrombin time values remained lower in the patients receiving NAC. In thromboelastometry tracings the coagulation time was more prolonged after the bolus of NAC (P=0.02). Platelet aggregation induced with adenosine diphosphate decreased after NAC but not after placebo. Low prothrombin time values before and after bolus infusions were associated with increased blood loss (P=0.008 and P=0.015, respectively). NAC has anticoagulant and platelet-inhibiting properties in patients undergoing major vascular surgery. This abnormal haemostatic activity should be considered when NAC is administered to patients with increased bleeding risk.
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PMID:The effect of N-acetylcysteine on blood coagulation and platelet function in patients undergoing open repair of abdominal aortic aneurysm. 1660 76

Rubisco activase is a member of the AAA(+) family in which arginines located in the Box VII and Sensor 2 domains are a recurrent feature and typically contribute to ATP-binding/hydrolysis or an inter-subunit interface. Replacement of R241 or R244 in Box VII or R294 or R296 in Sensor 2 with alanine in tobacco activase did not greatly alter the binding of ATP or ADP. However, ATP hydrolysis was minimal (R241A and R244A) or greatly diminished (R296A) and none of these mutants were able to activate Rubisco. R241, R244 and R296 were also required for nucleotide-dependent conformational changes detected by intrinsic fluorescence and limited proteolysis. ATP-induced oligomerization, monitored by gel filtration, was not observed with the wild type and mutant tobacco activases in contrast to spinach activase and a R239A mutant (corresponding to R244A in tobacco). Thus, there is not a strict correlation of oligomerization with ATP hydrolysis and intrinsic fluorescence.
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PMID:Identification of critical arginine residues in the functioning of Rubisco activase. 1671 73

The E1 protein of papillomavirus is a hexameric ring helicase belonging to the AAA + family. The mechanism that couples the ATP cycle to DNA translocation has been unclear. Here we present the crystal structure of the E1 hexamer with single-stranded DNA discretely bound within the hexamer channel and nucleotides at the subunit interfaces. This structure demonstrates that only one strand of DNA passes through the hexamer channel and that the DNA-binding hairpins of each subunit form a spiral 'staircase' that sequentially tracks the oligonucleotide backbone. Consecutively grouped ATP, ADP and apo configurations correlate with the height of the hairpin, suggesting a straightforward DNA translocation mechanism. Each subunit sequentially progresses through ATP, ADP and apo states while the associated DNA-binding hairpin travels from the top staircase position to the bottom, escorting one nucleotide of single-stranded DNA through the channel. These events permute sequentially around the ring from one subunit to the next.
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PMID:Mechanism of DNA translocation in a replicative hexameric helicase. 1685 83

Astrocytes can act as intermediaries between neurons and cerebral arterioles to regulate vascular tone in response to neuronal activity. Release of glutamate from presynaptic neurons increases blood flow to match metabolic demands. CO is a gasotransmitter that can be related to neural function and blood flow regulation in the brain. The present study addresses the hypothesis that glutamatergic stimulation promotes perivascular astrocyte CO production and pial arteriolar dilation in the newborn brain. Experiments used anesthetized newborn pigs with closed cranial windows, piglet astrocytes, and cerebrovascular endothelial cells in primary culture and immunocytochemical visualization of astrocytic markers. Pial arterioles and arteries of newborn pigs are ensheathed by astrocytes visualized by glial fibrillary acidic protein staining. Treatment (2 h) of astrocytes in culture with L-2-alpha-aminoadipic acid (L-AAA), followed by 14 h in toxin free medium, dose-dependently increased cell detachment, suggesting injury. Conversely, 16 h of continuous exposure to L-AAA caused no decrease in endothelial cell attachment. In vivo, topical L-AAA (2 mM, 5 h) disrupted the cortical glia limitans histologically. Such treatment also eliminated pial arteriolar dilation to the astrocyte-dependent dilator ADP and to glutamate but not to isoproterenol or CO. Glutamate stimulated CO production by the brain surface that also was abolished following L-AAA. In contrast, tetrodotoxin blocked dilation to N-methyl-D-aspartate but not to glutamate, isoproterenol, or CO or the glutamate-induced increase in CO. The concurrent loss of CO production and pial arteriolar dilation to glutamate following astrocyte injury suggests astrocytes may employ CO as a gasotransmitter for glutamatergic cerebrovascular dilation.
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PMID:Contributions of astrocytes and CO to pial arteriolar dilation to glutamate in newborn pigs. 1689 4

RuvBL1 is an evolutionarily highly conserved eukaryotic protein belonging to the AAA(+)-family of ATPases (ATPase associated with diverse cellular activities). It plays important roles in essential signaling pathways such as the c-Myc and Wnt pathways in chromatin remodeling, transcriptional and developmental regulation, and DNA repair and apoptosis. Herein we present the three-dimensional structure of the selenomethionine variant of human RuvBL1 refined using diffraction data to 2.2A of resolution. The crystal structure of the hexamer is formed of ADP-bound RuvBL1 monomers. The monomers contain three domains, of which the first and the third are involved in ATP binding and hydrolysis. Although it has been shown that ATPase activity of RuvBL1 is needed for several in vivo functions, we could only detect a marginal activity with the purified protein. Structural homology and DNA binding studies demonstrate that the second domain, which is unique among AAA(+) proteins and not present in the bacterial homolog RuvB, is a novel DNA/RNA-binding domain. We were able to demonstrate that RuvBL1 interacted with single-stranded DNA/RNA and double-stranded DNA. The structure of the RuvBL1.ADP complex, combined with our biochemical results, suggest that although RuvBL1 has all the structural characteristics of a molecular motor, even of an ATP-driven helicase, one or more as yet undetermined cofactors are needed for its enzymatic activity.
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PMID:Crystal structure of the human AAA+ protein RuvBL1. 1706 Mar 27

The mechanisms of hypoxia-mediated aneurysm wall weakening and rupture are unknown. During hypoxia, strategies to maintain cellular ATP levels include increasing glycolysis (glycolytic strategy) or decreasing ATP consumption (metabolic depression). This study demonstrated that compared to anterior aneurysm sac, rupture edge overexpressed hypoxia-inducible factor-1-alpha (marker of hypoxia) and showed no significant difference in levels of combined ADP and ATP or lactate (glycolytic end product). Further studies are needed to confirm whether hypoxic AAA cells adapt through metabolic depression rather than glycolysis. The downregulation of protein synthesis during such metabolic depression may be a factor in hypoxia-mediated wall weakening.
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PMID:Hypoxia at the site of abdominal aortic aneurysm rupture is not associated with increased lactate. 1718 47

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