Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

---

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

The mechanism of selective protein degradation of membrane proteins in mitochondria has been studied employing a model protein that is subject to rapid proteolysis within the inner membrane. Protein degradation was mediated by two different proteases: (i) the m-AAA protease, a protease complex consisting of multiple copies of the ATP-dependent metallopeptidases Yta1Op (Afg3p) and Yta12p (Rcalp); and (ii) by Ymelp (Ytallp) that also is embedded in the inner membrane. Ymelp, highly homologous to Yta1Op and Yta12p, forms a complex of approximately 850 kDa in the inner membrane and exerts ATP-dependent metallopeptidase activity. While the m-AAA protease exposes catalytic sites to the mitochondrial matrix, Ymelp is active in the intermembrane space. The Ymelp complex was therefore termed 'i-AAA protease'. Analysis of the proteolytic fragments indicated cleavage of the model polypeptide at the inner and outer membrane surface and within the membrane-spanning domain. Thus, two AAA proteases with their catalytic sites on opposite membrane surfaces constitute a novel proteolytic system for the degradation of membrane proteins in mitochondria.
...
PMID:AAA proteases with catalytic sites on opposite membrane surfaces comprise a proteolytic system for the ATP-dependent degradation of inner membrane proteins in mitochondria. 886 50

Mitochondria harbor a conserved proteolytic system that mediates the complete degradation of organellar proteins. ATP-dependent proteases, like a Lon protease in the matrix space and m- and i-AAA proteases in the inner membrane, degrade malfolded proteins within mitochondria and thereby protect the cell against mitochondrial damage. Proteolytic breakdown products include peptides and free amino acids, which are constantly released from mitochondria. It remained unclear, however, whether the turnover of malfolded proteins involves only ATP-dependent proteases or also oligopeptidases within mitochondria. Here we describe the identification of Mop112, a novel metallopeptidase of the pitrilysin family M16 localized in the intermembrane space of yeast mitochondria. This peptidase exerts important functions for the maintenance of the respiratory competence of the cells that overlap with the i-AAA protease. Deletion of MOP112 did not affect the stability of misfolded proteins in mitochondria, but resulted in an increased release from the organelle of peptides, generated upon proteolysis of mitochondrial proteins. We find that the previously described metallopeptidase saccharolysin (or Prd1) exerts a similar function in the intermembrane space. The identification of peptides released from peptidase-deficient mitochondria by mass spectrometry indicates a dual function of Mop112 and saccharolysin: they degrade peptides generated upon proteolysis of proteins both in the intermembrane and matrix space and presequence peptides cleaved off by specific processing peptidases in both compartments. These results suggest that the turnover of mitochondrial proteins is mediated by the sequential action of ATP-dependent proteases and oligopeptidases, some of them localized in the intermembrane space.
...
PMID:Role of the novel metallopeptidase Mop112 and saccharolysin for the complete degradation of proteins residing in different subcompartments of mitochondria. 1577 85

Unlike many other organisms, the yeast Saccharomyces cerevisiae can tolerate the loss of mitochondrial DNA (mtDNA). Although a few proteins have been identified that are required for yeast cell viability without mtDNA, the mechanism of mtDNA-independent growth is not completely understood. To probe the relationship between the mitochondrial genome and cell viability, we conducted a microarray-based, genomewide screen for mitochondrial DNA-dependent yeast mutants. Among the several genes that we discovered is MGR1, which encodes a novel subunit of the i-AAA protease complex located in the mitochondrial inner membrane. mgr1Delta mutants retain some i-AAA protease activity, yet mitochondria lacking Mgr1p contain a misassembled i-AAA protease and are defective for turnover of mitochondrial inner membrane proteins. Our results highlight the importance of the i-AAA complex and proteolysis at the inner membrane in cells lacking mitochondrial DNA.
...
PMID:A genomewide screen for petite-negative yeast strains yields a new subunit of the i-AAA protease complex. 1626 74

Two membrane-bound ATP-dependent AAA proteases conduct protein quality surveillance in the inner membrane of mitochondria and control crucial steps during mitochondrial biogenesis. AAA domains of proteolytic subunits are critical for the recognition of non-native membrane proteins which are extracted from the membrane bilayer for proteolysis. Here, we have analysed the role of the conserved loop motif YVG, which has been localized to the central pore in other hexameric AAA(+) ring complexes, for the degradation of membrane proteins by the i-AAA protease Yme1. Proteolytic activity was found to depend on the presence of hydrophobic amino acid residues at position 354 within the pore loop of Yme1. Mutations affected proteolysis in a substrate-specific manner: whereas the degradation of misfolded membrane proteins was impaired at a post-binding step, folded substrate proteins did not interact with mutant Yme1. This reflects most likely deficiencies in the ATP-dependent unfolding of substrate proteins, since we observed similar effects for ATPase-deficient Yme1 mutants. Our findings therefore suggest an essential function of the central pore loop for the ATP-dependent translocation of membrane proteins into a proteolytic cavity formed by AAA proteases.
...
PMID:Substrate specific consequences of central pore mutations in the i-AAA protease Yme1 on substrate engagement. 1652 90

The energy-dependent proteolysis of cellular proteins is mediated by conserved proteolytic AAA(+) complexes. Two such machines, the m- and i-AAA proteases, are present in the mitochondrial inner membrane. They exert chaperone-like properties and specifically degrade nonnative membrane proteins. However, molecular mechanisms of substrate engagement by AAA proteases remained elusive. Here, we define initial steps of substrate recognition and identify two distinct substrate binding sites in the i-AAA protease subunit Yme1. Misfolded polypeptides are recognized by conserved helices in proteolytic and AAA domains. Structural modeling reveals a lattice-like arrangement of these helices at the surface of hexameric AAA protease ring complexes. While helices within the AAA domain apparently play a general role for substrate binding, the requirement for binding to surface-exposed helices within the proteolytic domain is determined by the folding and membrane association of substrates. Moreover, an assembly factor of cytochrome c oxidase, Cox20, serves as a substrate-specific cofactor during proteolysis and modulates the initial interaction of nonassembled Cox2 with the protease. Our findings therefore reveal the existence of alternative substrate recognition pathways within AAA proteases and shed new light on molecular mechanisms ensuring the specificity of proteolysis by energy-dependent proteases.
...
PMID:Substrate recognition by AAA+ ATPases: distinct substrate binding modes in ATP-dependent protease Yme1 of the mitochondrial intermembrane space. 1726 94

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.
...
PMID:Exploring the mitochondrial proteome of the ciliate protozoon Tetrahymena thermophila: direct analysis by tandem mass spectrometry. 1795 97

By screening yeast knockouts for their dependence upon the mitochondrial genome, we identified Mgr3p, a protein that associates with the i-AAA protease complex in the mitochondrial inner membrane. Mgr3p and Mgr1p, another i-AAA-interacting protein, form a subcomplex that bind to the i-AAA subunit Yme1p. We find that loss of Mgr3p, like the lack of Mgr1p, reduces proteolysis by Yme1p. Mgr3p and Mgr1p can bind substrate even in the absence of Yme1p, and both proteins are needed for maximal binding of an unfolded substrate by the i-AAA complex. We speculate that Mgr3p and Mgr1p function in an adaptor complex that targets substrates to the i-AAA protease for degradation.
...
PMID:Mgr3p and Mgr1p are adaptors for the mitochondrial i-AAA protease complex. 1884 51

Deficits in mitochondrial function result in many human diseases. The X-linked disease Barth syndrome (BTHS) is caused by mutations in the tafazzin gene TAZ1. Its product, Taz1p, participates in the metabolism of cardiolipin, the signature phospholipid of mitochondria. In this paper, a yeast BTHS mutant tafazzin panel is established, and 18 of the 21 tested BTHS missense mutations cannot functionally replace endogenous tafazzin. Four BTHS mutant tafazzins expressed at low levels are degraded by the intermembrane space AAA (i-AAA) protease, suggesting misfolding of the mutant polypeptides. Paradoxically, each of these mutant tafazzins assembles in normal protein complexes. Furthermore, in the absence of the i-AAA protease, increased expression and assembly of two of the BTHS mutants improve their function. However, the BTHS mutant complexes are extremely unstable and accumulate as insoluble aggregates when disassembled in the absence of the i-AAA protease. Thus, the loss of function for these BTHS mutants results from the inherent instability of the mutant tafazzin complexes.
...
PMID:Barth syndrome mutations that cause tafazzin complex lability. 2130 Aug 50

The mitochondrial proteome contains proteins from two different genetic systems. Proteins are either synthesized in the cytosol and imported into the different compartments of the organelle or directly produced in the mitochondrial matrix. To ensure proteostasis, proteins are monitored by the mitochondrial quality control system, which will degrade non-native polypeptides. Defective mitochondrial membrane proteins are degraded by membrane-bound AAA-proteases. These proteases are regulated by factors promoting protein turnover or preventing their degradation. Here we determined genetic interactions between the mitoribosome receptors Mrx15 and Mba1 with the quality control system. We show that simultaneous absence of Mrx15 and the regulators of the i-AAA protease Mgr1 and Mgr3 provokes respiratory deficiency. Surprisingly, mutants lacking Mrx15 were more tolerant against proteotoxic stress. Furthermore, yeast cells became hypersensitive against proteotoxic stress upon deletion of MBA1. Contrary to Mrx15, Mba1 cooperates with the regulators of the m-AAA and i-AAA proteases. Taken together, these results suggest that membrane protein insertion and mitochondrial AAA-proteases are functionally coupled, possibly reflecting an early quality control step during mitochondrial protein synthesis.
...
PMID:Insertion Defects of Mitochondrially Encoded Proteins Burden the Mitochondrial Quality Control System. 3033 42

---