EC:3.6.1.3 - FACTA Search

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Query: EC:3.6.1.3 (ATPase)
65,361 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Translocational intermediates of precursor proteins of ATPase F1 beta subunit and cytochrome c1 across mitochondrial membranes were analyzed using two different approaches, transport at low temperature and transport after binding of precursor proteins to antibodies. Under both conditions precursors were partially transported into mitochondria in an energy-dependent manner. They were processed by the metalloprotease in the matrix but a major proportion of the polypeptide chains was still present at the outer face of the outer mitochondrial membrane. We conclude that transfer of precursors into the inner membrane or matrix space occurs through "translocation contact sites"; precursor polypeptides to F1 beta and cytochrome c1 enter the matrix space with the amino terminus first; and a membrane potential is required for the transmembrane movement on an amino-terminal "domain-like" structure but not for completing translocation of the major part of the polypeptides.
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PMID:Transport of proteins into mitochondria: translocational intermediates spanning contact sites between outer and inner membranes. 286 45

The Erwinia chrysanthemi metalloprotease C and the Serratia marcescens haem acquisition protein HasA are both secreted from Gram-negative bacteria by a signal peptide-independent pathway which requires a C-terminal secretion signal and a specific ABC-transporter made up of three proteins: a membrane ATPase (the ABC-protein), a second inner membrane component belonging to the membrane fusion protein family and an outer membrane polypeptide. HasA and protease C transporters are homologous although the secreted polypeptides share no sequence homology. Whereas protease C can use both translocators, HasA is secreted only by its specific transporter. Functional analysis of protease C and HasA secretion through hybrid transporters obtained by combining components from each system demonstrates that the ABC-protein is responsible for the substrate specificity and that inhibition of protease C secretion in the presence of HasA results from a defective interaction between HasA and the ABC-protein. We also show that the outer membrane protein, TolC, can combine with the membrane fusion protein HasE in the presence of either ABC-protein to form a functional transporter but not with the membrane fusion protein, PrtE. This indicates a specific interaction between the outer membrane component and the membrane fusion protein.
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PMID:Protein secretion by hybrid bacterial ABC-transporters: specific functions of the membrane ATPase and the membrane fusion protein. 777 88

Escherichia coli FtsH is an essential integral membrane protein that has an AAA-type ATPase domain at its C-terminal cytoplasmic part, which is homologous to at least three ATPase subunits of the eukaryotic 26S proteasome. We report here that FtsH is involved in degradation of the heat-shock transcription factor sigma 32, a key element in the regulation of the E. coli heat-shock response. In the temperature-sensitive ftsH1 mutant, the amount of sigma 32 at a non-permissive temperature was higher than in the wild-type under certain conditions due to a reduced rate of degradation. In an in vitro system with purified components, FtsH catalyzed ATP-dependent degradation of biologically active histidine-tagged sigma 32. FtsH has a zinc-binding motif similar to the active site of zinc-metalloproteases. Protease activity of FtsH for histidine-tagged sigma 32 was stimulated by Zn2+ and strongly inhibited by the heavy metal chelating agent o-phenanthroline. We conclude that FtsH is a novel membrane-bound, ATP-dependent metalloprotease with activity for sigma 32. These findings indicate a new mechanism of gene regulation in E. coli.
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PMID:Escherichia coli FtsH is a membrane-bound, ATP-dependent protease which degrades the heat-shock transcription factor sigma 32. 778 8

The ftsH gene encodes an ATP- and Zn(2+)-dependent metalloprotease with a molecular mass of about 70 kDa. It was first identified in Escherichia coli where it is also designated hflB, tolZ or mrsC, and seems to be present in most if not all bacteria. The FtsH protein is anchored to the cytoplasmic membrane via two transmembrane regions in such a way that the very short amino- and the long carboxy-termini are exposed into the cytoplasm. FtsH is member of the AAA family (ATPases associated with a variety of cellular activities) which are characterized by a module of about 200 amino acid residues in length containing an ATP-binding site. In Escherichia coli, FtsH forms a complex with a pair of periplasmically exposed membrane proteins, HflK and HflC. The E. coli enzyme is required for proteolytic degradation of some unstable proteins that include both soluble regulatory proteins such as sigma 32 (heat-shock sigma factor) and phage lambda CII (transcriptional activator), and membrane proteins including uncomplexed forms of SecY (forms the translocon together with SecE and SecG) and the a subunit of the F0 complex of the H(+)-ATPase. Its activity can be modulated by the HflKC proteins, by another membrane protein designated YccA which can transiently associate with both the FtsH and the HflKC proteins, or by small peptides such as CIII encoded by phage lambda (involved in lysogenization) or SpoVM (needed for sporulation) encoded by Bacillus subtilis. Besides being a protease, there is circumstantial evidence that FtsH also acts as a molecular chaperone. It influences protein assembly in and through the cytoplasmic membrane and associates with denatured alkaline phosphatase without degrading it. Therefore, FtsH may serve to maintain quality control of some cytoplasmic and membrane proteins. Such ATP-dependent proteases with intrinsic chaperone activity have been designated charonins.
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PMID:FtsH--a single-chain charonin? 1007 51

FtsH protease, the product of the essential ftsH gene, is a membrane-bound ATP-dependent metalloprotease of Escherichia coli that has been shown to be involved in the rapid turnover of key proteins, secretion of proteins into and through the membrane, and mRNA decay. The pleiotropic effects of ftsH mutants have led to the suggestion that FtsH possesses an ATP-dependent chaperone function that is independent of its protease function. When considering FtsH as a target for novel antibacterials, it is necessary to determine which of these functions is critical for the growth and survival of bacteria. To address this, we constructed the FtsH mutants E418Q, which retains significant ATPaseactivity but lacks protease activity, and K201N, which lacks both protease and ATPase activities. These mutants were introduced into an E. coli ftsH knockout strain which has wild-type FtsH supplied from a plasmid under control of the inducible araBAD promoter. Since neither mutant would complement the ftsH defect produced in the absence of arabinose, we conclude that the protease function of FtsH is required for bacterial growth.
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PMID:Escherichia coli requires the protease activity of FtsH for growth. 1090 Jan 38

TolAI--II--beta-lactamase, a fusion protein consisting of the inner membrane and transperiplasmic domains of TolA followed by TEM--beta-lactamase associated with the inner membrane but remained confined to the cytoplasm when expressed at high level in Escherichia coli. Although the fusion protein was resistant to proteolysis in vivo, it was hydrolyzed during preparative SDS-polyacrylamide electrophoresis and when insoluble cellular fractions unfolded with 5 M urea were subjected to microdialysis. Inhibitor profiling studies revealed that both a metallo- and serine protease were involved in TolAI--II--beta-lactamase degradation under denaturing conditions. The in vitro degradation rates of the fusion protein were not affected when insoluble fractions were harvested from a strain lacking protease IV, but were significantly reduced when microdialysis experiments were conducted with material isolated from an isogenic ftsH1 mutant. Adenine nucleotides were not required for degradation, and ATP supplementation did not accelerate the apparent rate of TolAI--II--beta-lactamase hydrolysis under denaturing conditions. Our results indicate that the metalloprotease active site of FtsH remains functional in the presence of 3--5 M urea and suggest that the ATPase and proteolytic activities of FtsH can be uncoupled if the substrate is sufficiently unstructured. Thus, a key role of the FtsH AAA module appears to be the net unfolding of bound substrates so that they can be efficiently engaged by the protease active site.
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PMID:Escherichia coli FtsH (HflB) degrades a membrane-associated TolAI-II-beta-lactamase fusion protein under highly denaturing conditions. 1123 95

Recently, paraplegin and spastin have been found to be mutated in two autosomal forms of hereditary spastic paraplegia. Both proteins harbour a common ATPase domain that expresses a chaperone function. Paraplegin is a nuclear-encoded mitochondrial metalloprotease, while the exact role and subcellular localisation of spastin are still unclear.
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PMID:Molecular basis of inherited spastic paraplegias. 1137 72

The identification of SPG7 as the gene defective in a recessive form of spastic paraplegia has drawn attention to the yeast protein family of ATP-dependent zinc metalloproteases. The protein encoded by SPG7, paraplegin, shows high homology to members of this protein family. Recently, many mammalian ATP-dependent zinc metalloproteases have been identified and considered as possible candidates for defects in other forms of hereditary spastic paraplegia and possibly other neurodegenerative disorders. So far only a partial sequence has been available for one of those genes, ATPase family gene-3, yeast-like-1 (AFG3L1). We have carried out detailed molecular analysis of this gene and identified and characterized its mouse orthologue, Afg3l1. Our data indicate that AFG3L1 is transcribed into four mRNA isoforms that are not translated in humans. Afg3l1 encodes a protein with high homology to paraplegin and the other members of the ATP-dependent zinc metalloprotease family. Like the other ATP-dependent zinc metalloproteases, Afg3l1 localizes to the mitochondria.
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PMID:Molecular and functional analyses of the human and mouse genes encoding AFG3L1, a mitochondrial metalloprotease homologous to the human spastic paraplegia protein. 1154 17

In mammalian cells, mitochondria provide energy from aerobic metabolism. They play an important regulatory role in apoptosis, produce and detoxify free radicals, and serve as a cellular calcium buffer. Neurodegenerative disorders involving mitochondria can be divided into those caused by oxidative phosphorylation (OXPHOS) abnormalities either due to mitochondrial DNA (mtDNA) abnormalities, e.g., chronic external ophthalmoplegia, or due to nuclear mutations of OXPHOS proteins, e.g., complex I and II associated with Leigh syndrome. There are diseases caused by nuclear genes encoding non-OXPHOS mitochondrial proteins, such as frataxin in Friedreich ataxia (which is likely to play an important role in mitochondrial-cytosolic iron cycling), paraplegin (possibly a mitochondrial ATP-dependent zinc metalloprotease of the AAA-ATPases in hereditary spastic paraparesis), and possibly Wilson disease protein (an abnormal copper transporting ATP-dependent P-type ATPase associated with Wilson disease). Huntingon disease is an example of diseases with OXPHOS defects associated with mutations of nuclear genes encoding non-mitochondrial proteins such as huntingtin. There are also disorders with evidence of mitochondrial involvement that cannot as yet be assigned. These include Parkinson disease (where a complex I defect is described and free radicals are generated from dopamine metabolism), amyotrophic lateral sclerosis, and Alzheimer disease, where there is evidence to suggest mitochondrial involvement perhaps secondary to other abnormalities.
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PMID:Mitochondria and degenerative disorders. 1157 22

Escherichia coli FtsH (HflB) is a membrane-bound and ATP-dependent metalloprotease. Its cytoplasmic domain contains a zinc-binding motif, H(417)EXXH, whose histidine residues have been shown to be functionally important. Although they are believed to be involved directly in zinc coordination, nothing is known about the third zinc ligand of this protease. Sequence alignment indicates that glutamic acid residues are conserved among the FtsH homologues at positions corresponding to Glu(479) and Glu(585) of E. coli FtsH. We replaced each of them by Gln, Asp, Lys, or Val. Mutations at position 479 compromised the proteolytic functions of FtsH in vivo. In vitro proteolytic activities of the E479Q, E479V, and E479D mutant enzymes were much lower than that of the wild-type protein and were significantly stimulated by a high concentration of zinc ion. These mutant proteins retained the wild-type levels of ATPase activities, and their trypsin susceptibilities as well as CD spectra were essentially indistinguishable from those of the wild-type protein, indicating that the mutations did not cause gross conformational changes in FtsH. They exhibited reduced zinc contents upon purification. From these results, we conclude that Glu(479) is a zinc-coordinating residue.
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PMID:Identification of glutamic acid 479 as the gluzincin coordinator of zinc in FtsH (HflB). 1182 31

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