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)

SecA is the precursor protein binding subunit of the bacterial precursor protein translocase, which consists of the SecY/E protein as integral membrane domain. SecA is an ATPase, and couples the hydrolysis of ATP to the release of bound precursor proteins to allow their proton-motive-force-driven translocation across the cytoplasmic membrane. A putative ATP-binding motif can be predicted from the amino acid sequence of SecA with homology to the consensus Walker A-type motif. The role of this domain is not known. A lysine residue at position 106 at the end of the glycine-rich loop in the A motif of the Bacillus subtilis SecA was replaced by an asparagine through site-directed mutagenesis (K106N SecA). A similar replacement was introduced at an adjacent lysine residue at position 101 (K101N SecA). Wild-type and mutant SecA proteins were expressed to a high level and purified to homogeneity. The catalytic efficacy (kcat/km) of the K106N SecA for lipid-stimulated ATP hydrolysis was only 1% of that of the wild-type and K101N SecA. K106N SecA retained the ability to bind ATP, but its ATPase activity was not stimulated by precursor proteins. Mutant and wild-type SecA bind with similar affinity to Escherichia coli inner membrane vesicles and insert into a phospholipid monolayer. In contrast to the wild type, membrane insertion of the K106N SecA was not prevented by ATP. K106N SecA blocks the ATP and proton-motive-force-dependent chase of a translocation intermediate to fully translocated proOmpA. It is concluded that the GKT motif in the amino-terminal domain of SecA is part of the catalytic ATP-binding site. This site may be involved in the ATP-driven protein recycling function of SecA which allows the release of SecA from its association with precursor proteins, and the phospholipid bilayer.
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PMID:Characterization of a Bacillus subtilis SecA mutant protein deficient in translocation ATPase and release from the membrane. 849 95

Protein splicing is a chemical reaction in which a spliced intervening polypeptide is excised from a precursor protein and the flanking N- and C-terminal regions are ligated with the peptide bond to produce two mature proteins. This unique autocatalytic reaction was first discovered in the yeast VMA1 protein, a 120kDa spliced polypeptide encoded by the VMA1 gene of Saccharomyces cerevisiae. The VMA1 protein catalyses a self protein splicing post-translationally to yield the 70 kDa catalytic subunit of the vacuolar H+-ATPase and the 50 kDa DNA endonuclease. Accumulating evidence has indicated that splicing precursors distribute widely in many organisms covering eukarya, bacteria and archaea. This article argues and summarizes current chemical and biological views on protein splicing.
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PMID:Protein splicing: its chemistry and biology. 928 54

The homodimeric SecA protein is the ATP-dependent force generator in the Escherichia coli precursor protein translocation cascade. SecA contains two essential nucleotide binding sites (NBSs), i.e., NBS1 and NBS2 that bind ATP with high and low affinity, respectively. The photoactivatable bifunctional cross-linking agent 3'-arylazido-8-azidoadenosine 5'-triphosphate (diN3ATP) was used to investigate the spatial arrangement of the nucleotide binding sites of SecA. DiN3ATP is an authentic ATP analogue as it supports SecA-dependent precursor protein translocation and translocation ATPase. UV-induced photo-cross-linking of the diN3ATP-bound SecA results in the formation of stable dimeric species of SecA. D209N SecA, a mutant unable to bind nucleotides at NBS1, was also photo-cross-linked by diN3ATP, whereas no cross-linking occurred with the NBS2 mutant R509K SecA. We concluded that the low-affinity NBS2, which is located in the carboxyl-terminal half of SecA, is the site of crosslinking and that NBS2 binds nucleotides at or near the subunit interface of the SecA dimer.
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PMID:The low-affinity ATP binding site of the Escherichia coli SecA dimer is localized at the subunit interface. 939 16

SecA is the ATP-dependent force generator in the Escherichia coli precursor protein translocation cascade, and is bound at the membrane surface to the integral membrane domain of the preprotein translocase. Preproteins are thought to be translocated in a stepwise manner by nucleotide-dependent cycles of SecA membrane insertion and de-insertion, or as large polypeptide segments by the protonmotive force (Deltap) in the absence of SecA. To determine the step size of a complete ATP- and SecA-dependent catalytic cycle, translocation intermediates of the preprotein proOmpA were generated at limiting SecA translocation ATPase activity. Distinct intermediates were formed, spaced by intervals of approximately 5 kDa. Inhibition of the SecA ATPase by azide trapped SecA in a membrane-inserted state and shifted the step size to 2-2.5 kDa. The latter corresponds to the translocation elicited by binding of non-hydrolysable ATP analogues to SecA, or by the re-binding of partially translocated polypeptide chains by SecA. Therefore, a complete catalytic cycle of the preprotein translocase permits the stepwise translocation of 5 kDa polypeptide segments by two consecutive events, i.e. approximately 2.5 kDa upon binding of the polypeptide by SecA, and another 2.5 kDa upon binding of ATP to SecA.
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PMID:The catalytic cycle of the escherichia coli SecA ATPase comprises two distinct preprotein translocation events. 940 59

Secretogranin II (SgII) is a sulphated secretory protein found in a broad variety of neuroendocrine cells. We have raised an antiserum against SgII to monitor its fate in Xenopus intermediate pituitary. Pulse-chase incubations in combination with immunoprecipitation analysis showed that SgII was synthesised as an 84-kDa precursor protein which was processed to fragments of 69, 54, 34, 21 and 15 kDa. Secretion of these cleavage products was sensitive to the dopamine D2 receptor agonist apomorphine, and thus occurred via the regulated secretory pathway. When cells were treated with the fungal metabolite brefeldin A or with the specific vacuolar H+-ATPase inhibitor bafilomycin A1, the processing of SgII and the release of its cleavage products were strongly inhibited, indicating that its processing commenced in the later compartments of the secretory pathway. Pulse-chase and immunoblot analysis showed that the 21-kDa fragment was the major SgII-derived cleavage and release product, and carried secretoneurin, a highly conserved peptide flanked by potential dibasic processing sites. Hence, SgII is cleaved to a variety of products that are released via the regulated secretory pathway, while secretoneurin does not seem to represent a major end-product of SgII processing in Xenopus intermediate pituitary.
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PMID:Biosynthesis of secretogranin II in Xenopus intermediate pituitary. 1019 92

The interaction between SStp, the transit peptide of the precursor protein to the small subunit of Rubisco (prSSU) and two Hsp70 molecular chaperones, Escherichia coli DnaK and pea (Pisum sativum) CSS1, was investigated in detail. Two statistical analyses were developed and used to investigate and predict regions of SStp recognized by DnaK. Both algorithms suggested that DnaK would have high affinity for the N terminus of SStp, moderate affinity for the central region, and low affinity for the C terminus. Furthermore, both algorithms predicted this affinity pattern for >75% of the transit peptides analyzed in the chloroplast transit peptide (CHLPEP) database. In vitro association between SStp and these Hsp70s was confirmed by three independent assays: limited trypsin resistance, ATPase stimulation, and native gel shift. Finally, synthetic peptides scanning the length of SStp and C-terminal deletion mutants of SStp were used to experimentally map the region of greatest DnaK affinity to the N terminus. CSS1 displayed a similar affinity for the N terminus of SStp. The major stromal Hsp70s affinity for the N terminus of SStp and other transit peptides supports a molecular motor model in which the chaperone functions as an ATP-dependent translocase, committing chloroplast precursor proteins to unidirectional movement across the envelope.
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PMID:Identification of a Hsp70 recognition domain within the rubisco small subunit transit peptide. 1075 26

Lymphoma proprotein convertase (LPC) is a subtilisin-like serine protease of the mammalian proprotein convertase family. It is synthesized as an inactive precursor protein, and propeptide cleavage occurs via intramolecular cleavage in the endoplasmic reticulum. In contrast to other convertases like furin and proprotein convertase-1, propeptide cleavage occurs slowly. Also, both a glycosylated and an unglycosylated precursor are detected. Here we demonstrate that the unglycosylated precursor form of LPC is localized in the cytosol due to the absence of a signal peptide. Using a reducible cross-linker, we found that glycosylated pro-LPC is associated with the molecular chaperone BiP. In addition, we show that pro-LPC is prone to aggregation and forms large complexes linked via interchain disulfide bonds. BiP is associated mainly with non-aggregated pro-LPC and pro-LPC dimers and trimers, suggesting that BiP prevents aggregation. Overexpression of wild-type BiP or a dominant-negative BiP ATPase mutant resulted in reduced processing of pro-LPC. Taken together, these results suggest that binding of BiP to pro-LPC prevents aggregation, but results in slower maturation.
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PMID:Binding of BiP to the processing enzyme lymphoma proprotein convertase prevents aggregation, but slows down maturation. 1096 28

Arabidopsis cDNAs encoding ATJ11, the smallest known J-domain protein, have been isolated and characterized. The precursor protein of 161 amino acid residues was synthesized in vitro and imported by isolated pea chloroplasts where it was localized to the stroma and cleaved to a mature protein of 125 amino acid residues. The mature protein consists of an 80 amino acid J-domain, and N- and C-terminal extensions of 24 and 21 amino acid residues, respectively, which show no similarity to regions in other DnaJ-related proteins. ATJ11 produced in Escherichia coli stimulated the weak ATPase activity of E. coli DnaK, but was unable to stimulate refolding of firefly luciferase by DnaK, and inhibited refolding by DnaK, DnaJ and GrpE. ATJ11 is encoded by a single-copy gene on chromosome 4, and is expressed in all plant organs examined. A paralogue of ATJ11, showing 72% identity, is encoded in a 4.5 Mb duplication of chromosome 4 on chromosome 2. These proteins represent a novel class of J-domain proteins.
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PMID:A novel plastid-targeted J-domain protein in Arabidopsis thaliana. 1151 54

In the accompany paper (Mukhopadhyay, A., Avramova, L. V. and Weiner, H., Arch. Biochem. Biophys.), it was shown that Tom34, a previously proposed putative translocase of the mitochondrial outer membrane, binds to the mature region of a precursor protein and appears to be a cytosol protein. Here Tom34 was used as bait in a yeast two-hybrid screening to search for its potential binding partners. Two of the identified proteins were the ATPase-related valosin-containing protein (VCP) and the lysosomal H(+)-transporting ATPase member M (ATP6M). Tom34 was found primarily in the cytosol while VCP and ATP6M were found in the cytosol as well as in nonmitochondrial organelles. Tom34 formed a approximately 400-kDa complex with them in the cytosol. Tom34 was found to possess a weak ATPase activity that did not change when associated with VCP. The tetratricopeptide repeat (TPR) motif region of Tom34 (residue 201-256) was responsible for binding to the other proteins. Tom34 appears not to be a member of the mitochondrial outer membrane translocase family but might function as a chaperone-like protein during protein translocation.
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PMID:Yeast two-hybrid screening identifies binding partners of human Tom34 that have ATPase activity and form a complex with Tom34 in the cytosol. 1191 76

SecA, a 202 kDa dimeric protein, is the ATPase for the Sec-dependent translocase of precursor proteins in vivo. SecA must undergo conformational changes, which may involve dissociation into a monomer, as it translocates the precursor protein across the inner membrane. To better understand the dynamics of SecA in vivo, protein folding studies to probe the native, intermediate, and unfolded species of SecA in vitro have been done. SecA folds through a stable dimeric intermediate and dimerizes in the dead-time of a manual-mixing kinetic experiment ( approximately 5-7 seconds). Here, stopped-flow fluorescence and CD, as well as ultra-rapid continuous flow fluorescence techniques, were used to further probe the rapid folding kinetics of SecA. In the absence of urea, rapid, near diffusion-limited ( approximately 10(9)M(-1)s(-1)) SecA dimerization occurs following a rate-limiting unimolecular rearrangement of a rapidly formed intermediate. Multiple kinetic folding and unfolding phases were observed and SecA was shown to have multiple native and unfolded states. Using sequential-mixing stopped-flow experiments, SecA was determined to fold via parallel channels with sequential intermediates. These results confirm that SecA is a highly dynamic protein, consistent with the rapid, major conformational changes it must undergo in vivo.
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PMID:SecA folding kinetics: a large dimeric protein rapidly forms multiple native states. 1531 73

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