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)

Cdc48p is an abundant and conserved member of the AAA ATPase family of molecular chaperones. Cdc48p performs ubiquitin-selective functions, which are mediated by numerous ubiquitin binding adaptors, including the Npl4p-Ufd1p complex. Previous studies suggest that Cdc48p-containing complexes carry out many biochemical activities, including ubiquitination, deubiquitination, protein complex segregation, and targeting of ubiquitinated substrates to the proteasome. The molecular mechanisms by which Cdc48p-containing complexes participate in these processes remain poorly defined. We show here by using physiologically relevant Cdc48p substrates (i.e., endoplasmic membrane-associated/tethered dimers of Mga2p and Spt23p) and in vitro systems with purified proteins that Cdc48p(Npl4p/Ufd1p) binds to and promotes segregation of the tethered proteins via a polyubiquitin signal present on the membrane-bound proteins. Mobilization does not involve retrotranslocation of the associated anchors. These results provide biochemical evidence that Cdc48p(Npl4p/Ufd1p) functions as a polyubiquitin-selective segregase and that a polyubiquitin-Cdc48p pathway modulates protein interactions at cell membranes.
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PMID:Cdc48p(Npl4p/Ufd1p) binds and segregates membrane-anchored/tethered complexes via a polyubiquitin signal present on the anchors. 1728 86

Prohibitins comprise a family of highly conserved ubiquitous eukaryotic proteins that mainly localize to the mitochondria. They have been implicated in important cellular processes such as cellular signaling and transcriptional control, apoptosis, cellular senescence, and mitochondrial biogenesis. Using molecular modeling techniques, we have generated structural models of human prohibitins BAP32 and BAP37, which have previously been shown to exist as large ringlike oligomers in the membrane-bound state. The middle domain of prohibitins is evolutionary conserved in the family of SPFH (PHB) domain proteins. On the basis of the known structure of flotillin-2, another member of the SPFH-domain family, we have generated homology models for BAP32 and BAP37, and elucidated the implications for formation of high molecular weight oligomers. A model for the dimeric-building block of BAP32: BAP37 for such assemblies was generated and its stability scrutinized by molecular dynamics simulations. The model of BAP32 was also analyzed as to potential ligand-binding sites and the previously identified ligand melanogenin was docked into a membrane-proximal cavity. The results are discussed in the context of prohibitin interactions with mitochondrial AAA-proteases and we suggest two possible interaction interfaces between the BAP32:BAP37 building block and the protease.
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PMID:Molecular modeling of prohibitin domains. 1742 53

To date, direct analysis of mitochondrial proteomes has largely been limited to animals, fungi and plants. To broaden our knowledge of mitochondrial structure and function, and to provide additional insight into the evolution of this key eukaryotic organelle, we have undertaken the first comprehensive analysis of the mitochondrial proteome of a protist. Highly purified mitochondria from Tetrahymena thermophila, a ciliated protozoon, were digested exhaustively with trypsin and the resulting peptides subjected to tandem liquid chromatography-tandem mass spectrometry (LC/LC-MS/MS). In this way, we directly identified a total of 573 mitochondrial proteins, 545 of which are encoded by the nuclear genome and 28 by the mitochondrial genome. The latter number includes a novel, 44 residue protein (which we designate Ymf78) that had not been recognized during annotation of the T. thermophila mtDNA sequence. The corresponding gene, ymf78, is highly conserved in genomic position, size and sequence within the genus Tetrahymena. Our analysis has provided broad coverage of both membrane-bound and soluble proteins from the various submitochondrial compartments, with prominent representatives including components of the tricarboxylic acid cycle, Complexes I-IV of the electron transport chain and Complex V (ATP synthase), the mitochondrial transcription and translation machinery, the TOM and TIM protein translocases, various mitochondrial transporters, chaperonins (Cpn60, Hsp70, Hsp90), at least four FtsH family ATP-dependent metalloproteases implicated in m-AAA and i-AAA protease function, and enzymes involved in lipid, amino acid and coenzyme metabolism, as well as iron-sulfur cluster formation. Unexpectedly, six of the ten enzymes of glycolysis were found by MS analysis of purified T. thermophila mitochondria, whereas no hits were seen to any cytosolic ribosomal proteins. At least one of the glycolytic proteins, enolase, has an evident N-terminal extension that exhibits characteristics of a typical mitochondrial targeting peptide. As in other organisms, phylogenetic analysis of functionally annotated mitochondrial proteins demonstrates that <20% can be traced confidently to the alpha-proteobacterial lineage of Bacteria, emphasizing the chimeric evolutionary nature of the mitochondrial proteome. Notably, about 45% of the proteins identified in our analysis have no known function, and most of these do not have obvious homologs outside of the ciliate lineage. About two-thirds of these ORFan proteins have putative homologs in another ciliate, Paramecium tetraurelia, whereas the remainder appear to be Tetrahymena-specific. These results emphasize the power and importance of direct MS-based analysis of mitochondria in revealing novel mitochondrial proteins in different eukaryotic lineages. Our observations reinforce an emerging view of the mitochondrion as an evolutionarily flexible organelle, with novel proteins (and presumably functions) being added in a lineage-specific fashion to an ancient, highly conserved functional core, much of which was contributed by the presumptive alpha-proteobacterial symbiont from which the mitochondrial genome was derived.
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PMID:Exploring the mitochondrial proteome of the ciliate protozoon Tetrahymena thermophila: direct analysis by tandem mass spectrometry. 1795 97

The AAA ATPase Vps4 disassembles the membrane-bound ESCRT-III lattice. Four recent publications show how Vps4 carries out this task in a partnership with another ESCRT-associated protein, Vta1. Vps4 and Vta1 both contain MIT domains, which bind to "MIT-interacting motifs" (MIMs) of ESCRT-III proteins. As new MIT domain proteins are rapidly being identified, these studies will likely have relevance well beyond Vps4.
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PMID:MIT domainia. 1819 47

The peroxisome is a single-membrane-bound organelle found in eukaryotes. The functional importance of peroxisomes in humans is highlighted by peroxisome-deficient PBDs (peroxisome biogenesis disorders), such as Zellweger syndrome. Two AAA (ATPase associated with various cellular activities) peroxins, Pex1p and Pex6p, are encoded by PEX1 and PEX6, the causal genes for CG (complementation group) 1 and CG4 PBDs respectively. PEX26, which is responsible for CG8 PBDs, codes for Pex26p, the recruiter of Pex1p-Pex6p complexes to peroxisomes. We recently assigned the binding regions between human Pex1p and Pex6p and elucidated the pivotal roles that the AAA cassettes, D1 and D2 domains, play in Pex1p-Pex6p interaction and in peroxisome biogenesis. ATP binding to both AAA cassettes of Pex1p and Pex6p was a prerequisite for the Pex1p-Pex6p interaction and peroxisomal localization, but ATP hydrolysis by the D2 domains was not required. Pex1p exists in two distinct oligomeric forms, a homo-oligomer in the cytosol and a hetero-oligomer on peroxisome membranes, with these possibly having distinct functions in peroxisome biogenesis. AAA peroxins are involved in the export from peroxisomes of Pex5p, the PTS1 (peroxisome-targeting signal type 1) receptor.
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PMID:Dynamic and functional assembly of the AAA peroxins, Pex1p and Pex6p, and their membrane receptor Pex26p involved in shuttling of the PTS1 receptor Pex5p in peroxisome biogenesis. 1820 96

The AAA ATPase complex known as p97 or VCP in mammals and Cdc48 in yeast is connected to a multitude of cellular pathways, including membrane fusion, protein folding, protein degradation and activation of membrane-bound transcription factors. The mechanism by which p97 participates in such a broad spectrum of cellular functions appears to be via recruiting certain specific co-factors. Here we isolate and characterize the human protein Ubxd1, a novel co-factor of p97. We show that Ubxd1 is a stable protein that localizes to the cytoplasm and nucleus and is highly enriched in centrosomes. In mice Ubxd1 is widely expressed, but especially abundant in brain. Curiously, Ubxd1 does not associate with p97 via its UBX domain, but via its PUB domain which binds the extreme C-terminus of p97. Phosphorylation of the penultimate tyrosine residue in p97 completely abolishes Ubxd1 interaction. Ternary complexes of Ubxd1, p47, and p97 were detected in vitro. Inhibition of Ubxd1 expression by siRNA did not affect the degradation of bulk protein or a model substrate of the ERAD pathway, indicating that Ubxd1 directs p97 activity to specialized functions in vivo.
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PMID:Ubxd1 is a novel co-factor of the human p97 ATPase. 1865 46

In Escherichia coli, FtsH (HflB) is a membrane-bound, ATP-dependent metalloendoprotease belonging to the AAA family (ATPases associated with diverse cellular activities). FtsH has a limited spectrum of known substrates, including the transcriptional activator sigma32. FtsH is the only known E. coli protease that is essential, as it regulates the concentration of LpxC, which carries out the first committed step in the synthesis of lipid A. Here we identify a new FtsH substrate--3-deoxy-D-manno-octulosonate (KDO) transferase--which carries out the attachment of two KDO residues to the lipid A precursor (lipid IVA) to form the minimal essential structure of the lipopolysaccharide (LPS) (KDO2-lipid A). Thus, FtsH regulates the concentration of the lipid moiety of LPS (lipid A) as well as the sugar moiety (KDO-based core oligosaccharides), ensuring a balanced synthesis of LPS.
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PMID:Dual role of FtsH in regulating lipopolysaccharide biosynthesis in Escherichia coli. 1877 15

Thermoacidophilic crenarchaea of the genus Sulfolobus contain six AAA (ATPase associated with various cellular activities) proteins, including a proteasome-associated ATPase, a Vps4 (vacuolar protein sorting 4) homologue, and two Cdc48 (cell-division cycle 48)-like proteins. The last two AAA proteins are deeply branching divergent members of this family without close relatives outside the Sulfolobales. Both proteins have two nucleotide-binding domains and, unlike other members of the family, they seem to lack folded N-terminal domains. Instead, they contain N-terminal extensions of approx. 50 residues, which are predicted to be unstructured, except for a single transmembrane helix. We have analysed the two proteins, MBA (membrane-bound AAA) 1 and MBA2, by computational and experimental means. They appear to be monophyletic and to share a common ancestor with the Cdc48 clade. Both are membrane-bound and active as nucleotidases upon heterologous expression in Escherichia coli. They form ring complexes, which are stable after solubilization in a mild detergent and whose formation is dependent on the presence of the N-terminal extensions.
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PMID:Two unique membrane-bound AAA proteins from Sulfolobus solfataricus. 1914 14

AtFtsH4 is one of four inner membrane-bound mitochondrial ATP-dependent metalloproteases in Arabidopsis thaliana, called AAA proteases, whose catalytic site is exposed to the intermembrane space. In the present study, we used a reverse-genetic approach to investigate the physiological role of the AtFtsH4 protease. We found that loss of AtFtsH4 did not significantly affect Arabidopsis growth under optimal conditions (long days); however, severe morphological and developmental abnormalities in late rosette development occurred under short-day conditions. The asymmetric shape and irregular serration of expanding leaf blades were the most striking features of the ftsh4 mutant phenotype. The severe abnormal morphology of the leaf blades was accompanied by ultrastructural changes in mitochondria and chloroplasts. These abnormalities correlated with elevated levels of reactive oxygen species and carbonylated mitochondrial proteins. We found that two classes of molecular chaperones, Hsp70 and prohibitins, were over-expressed in ftsh4 mutants during late vegetative growth under both short- and long-day conditions. Taken together, our data indicate that lack of AtFtsH4 results in impairment of organelle development and Arabidopsis leaf morphology under short-day conditions.
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PMID:The lack of mitochondrial AtFtsH4 protease alters Arabidopsis leaf morphology at the late stage of rosette development under short-day photoperiod. 2000 33

The conserved eukaryotic AAA-type ATPase complex, known as p97 or VCP in mammals and Cdc48 in yeast, is involved in a number of cellular pathways, including fusion of homotypic membranes, protein degradation, and activation of membrane-bound transcription factors. Most likely, p97 is directed to this broad spectrum of cellular functions through its binding to specific cofactors. More than 20 different p97 cofactors have been described to date and our understanding of their cellular functions is rapidly expanding. Common to these proteins is their intimate connection with the ubiquitin system. Recently, a small, conserved family of proteins, containing PUB domains, was found to function as p97 adaptors. Intriguingly, their association with p97 is regulated by tyrosine phosphorylation, suggesting that they act as a relay between signalling pathways and p97 functions. Here we give an overview of the currently known PUB-domain proteins and other p97-interacting proteins.
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PMID:New ATPase regulators--p97 goes to the PUB. 1949 84

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