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)

We characterized a family consisting of four mammalian proteins of unknown function (NKAIN1, 2, 3 and 4) and a single Drosophila ortholog dNKAIN. Aside from highly conserved transmembrane domains, NKAIN proteins contain no characterized functional domains. Striking amino acid conservation in the first two transmembrane domains suggests that these proteins are likely to function within the membrane bilayer. NKAIN family members are neuronally expressed in multiple regions of the mouse brain, although their expression is not ubiquitous. We demonstrate that mouse NKAIN1 interacts with the beta1 subunit of the Na,K-ATPase, whereas Drosophila ortholog dNKAIN interacts with Nrv2.2, a Drosophila homolog of the Na,K-ATPase beta subunits. We also show that NKAIN1 can form a complex with another beta subunit-binding protein, MONaKA, when binding to the beta1 subunit of the Na,K-ATPase. Our results suggest that a complex between mammalian NKAIN1 and MONaKA is required for NKAIN function, which is carried out by a single protein, dNKAIN, in Drosophila. This hypothesis is supported by the fact that dNKAIN, but not NKAIN1, induces voltage-independent amiloride-insensitive Na(+)-specific conductance that can be blocked by lanthanum. Drosophila mutants with decreased dNKAIN expression due to a P-element insertion in the dNKAIN gene exhibit temperature-sensitive paralysis, a phenotype also caused by mutations in the Na,K-ATPase alpha subunit and several ion channels. The neuronal expression of NKAIN proteins, their membrane localization and the temperature-sensitive paralysis of NKAIN Drosophila mutants strongly suggest that this novel protein family may be critical for neuronal function.
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PMID:A novel family of transmembrane proteins interacting with beta subunits of the Na,K-ATPase. 1760 67

The archaeal flagellum is a unique motility apparatus in the prokaryotic domain, distinct from the bacterial flagellum. Most of the currently recognized archaeal flagella-associated genes fall into a single fla operon that contains the genes for the flagellin proteins (two or more genes designated as flaA or flaB), some variation of a set of conserved proteins of unknown function (flaC, flaD, flaE, flaF, flaG and flaH), an ATPase (flaI) and a membrane protein (flaJ). In addition, the flaD gene has been demonstrated to encode two proteins: a full-length gene product and a truncated product derived from an alternate, internal start site. A systematic deletion approach was taken using the methanogen Methanococcus maripaludis to investigate the requirement and a possible role for these proposed flagella-associated genes. Markerless in-frame deletion strains were created for most of the genes in the M. maripaludis fla operon. In addition, a strain lacking the truncated FlaD protein [FlaD M(191)I] was also created. DNA sequencing and Southern blot analysis confirmed each mutant strain, and the integrity of the remaining operon was confirmed by immunoblot. With the exception of the DeltaFlaB3 and FlaD M(191)I strains, all mutants were non-motile by light microscopy and non-flagellated by electron microscopy. A detailed examination of the DeltaFlaB3 mutant flagella revealed that these structures had no hook region, while the FlaD M(191)I strain appeared identical to wild type. Each deletion strain was complemented, and motility and flagellation was restored. Collectively, these results demonstrate for first time that these fla operon genes are directly involved and critically required for proper archaeal flagella assembly and function.
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PMID:Systematic deletion analyses of the fla genes in the flagella operon identify several genes essential for proper assembly and function of flagella in the archaeon, Methanococcus maripaludis. 1788 63

The AAA+ ATPases are essential for various activities such as membrane trafficking, organelle biogenesis, DNA replication, intracellular locomotion, cytoskeletal remodelling, protein folding and proteolysis. The AAA ATPase Vps4, which is central to endosomal traffic to lysosomes, retroviral budding and cytokinesis, dissociates ESCRT complexes (the endosomal sorting complexes required for transport) from membranes. Here we show that, of the six ESCRT--related subunits in yeast, only Vps2 and Did2 bind the MIT (microtubule interacting and transport) domain of Vps4, and that the carboxy-terminal 30 residues of the subunits are both necessary and sufficient for interaction. We determined the crystal structure of the Vps2 C terminus in a complex with the Vps4 MIT domain, explaining the basis for selective ESCRT-III recognition. MIT helices alpha2 and alpha3 recognize a (D/E)xxLxxRLxxL(K/R) motif, and mutations within this motif cause sorting defects in yeast. Our crystal structure of the amino-terminal domain of an archaeal AAA ATPase of unknown function shows that it is closely related to the MIT domain of Vps4. The archaeal ATPase interacts with an archaeal ESCRT-III-like protein even though these organisms have no endomembrane system, suggesting that the Vps4/ESCRT-III partnership is a relic of a function that pre-dates the divergence of eukaryotes and Archaea.
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PMID:Structural basis for selective recognition of ESCRT-III by the AAA ATPase Vps4. 1792 61

Helicobacter pylori is one of the world's most successful human pathogens causing gastric ulcers and cancers. A key virulence factor of H. pylori is the Cag pathogenicity island, which encodes a type IV secretion system. HP0525 is an essential component of the Cag system and acts as an inner membrane associated ATPase. HP0525 forms double hexameric ring structures, with the C-terminal domains (CTDs) forming a closed ring and the N-terminal domains (NTDs) forming a dynamic, open ring. Here, the crystal structure of HP0525 in complex with a fragment of HP1451, a protein of previously unknown function, is reported. The HP1451 construct consists of two domains similar to nucleic acid-binding domains. Two HP1451 molecules bind to the HP0525 NTDs on opposite sides of the hexamer, locking it in the closed form and forming a partial lid over the HP0525 chamber. From the structure, it is suggested that HP1451 acts as an inhibitory factor of HP0525 to regulate Cag-mediated secretion, a suggestion confirmed by results of in vitro ATPase assay and in vivo pull-down experiments.
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PMID:Identification, structure and mode of action of a new regulator of the Helicobacter pylori HP0525 ATPase. 1797 18

The coat protein complex II (COPII) is essential for vesicle formation from the endoplasmic reticulum (ER) and is composed of two heterodimeric subcomplexes, Sec23p/Sec24p and Sec13p/Sec31p, and the small guanosine triphosphatase Sar1p. In an effort to identify novel factors that may participate in COPII vesicle formation, we isolated SMY2, a yeast gene encoding a protein of unknown function, as a multicopy suppressor of the temperature-sensitive sec24-20 mutant. We found that even a low-copy expression of SMY2 was sufficient for the suppression of the sec24-20 phenotypes, and the chromosomal deletion of SMY2 led to a severe growth defect in the sec24-20 background. In addition, SMY2 exhibited genetic interactions with several other genes involved in the ER-to-Golgi transport. Subcellular fractionation analysis showed that Smy2p was a peripheral membrane protein fractionating together with COPII components. However, Smy2p was not loaded onto COPII vesicles generated in vitro. Interestingly, coimmunoprecipitation between Smy2p and the Sec23p/Sec24p subcomplex was specifically observed in sec23-1 and sec24-20 backgrounds, suggesting that this interaction was a prerequisite for the suppression of the sec24-20 phenotypes by overexpression of SMY2. We propose that Smy2p is located on the surface of the ER and facilitates COPII vesicle formation through the interaction with Sec23p/Sec24p subcomplex.
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PMID:Smy2p participates in COPII vesicle formation through the interaction with Sec23p/Sec24p subcomplex. 1797 54

DNA duplication is one of the main forces acting on the evolution of organisms because it creates the raw genetic material that natural selection can subsequently modify. Duplicated regions are mainly due to "errors" in different phases of meiosis, but DNA transposable elements and reverse transcription also contribute to amplify and move the genomic material to different genomic locations. As a result, redundancy affects genomes to variable degrees: from the single gene to the whole genome (WGD). Gene families are clusters of genes created by duplication and their size reflects the number of duplicated genes, called paralogs, in each species. The aim of this review is to describe the state of the art in the identification and analysis of gene families in eukaryotes, with specific attention to those generated by ancient large scale events in vertebrates (WGD or large segmental duplications). As a case study, we report our work on the evolution of gene families encoding subunits of the five OXPHOS (oxidative phosphorylation) complexes, fundamental and highly conserved in all respiring cells. Although OXPHOS gene families are smaller than the general trend in nuclear gene families, some exceptions are observed, such as three gene families with at least two paralogs in vertebrates. These gene families encode cytochrome c (Cyt c, the electron shuttle protein between complex III and IV), Lipid Binding Protein (LBP, the channel protein of complex V which transfers protons through the inner mitochondrial membrane) and the MLRQ subunit (MLRQ, a supernumerary subunit of the large complex I, with unknown function). We provide a two-step approach, based on structural genomic data, to demonstrate that these gene families should have arisen through WGD (or large segmental duplication) events at the origin of vertebrates and, only afterwards, underwent species-specific events of further gene duplications and loss. In summary, this review reflects the need to apply genome comparative approaches, deriving from both "classical" molecular phylogenetic analysis and "new" genome map analysis, to successfully define the complex evolutionary relations between gene family members which, in turn, are essential to obtain any other comparative phylogenetic or functional results.
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PMID:Genome duplication and gene-family evolution: the case of three OXPHOS gene families. 1857 16

The NifA protein is the central regulator of the nitrogen fixation genes. It activates transcription of nif genes by an alternative holoenzyme form of RNA polymerase containing the sigma(54) factor. The NifA protein from Klebsiella pneumoniae consists of the N-terminal domain of unknown function, the central catalytic domain with ATPase activity and the C-terminal DNA-binding domain. The Kp NifA protein is sensitive to temperature, while the Enterobacter cloacae NifA protein is less sensitive to temperature than Kp NifA. Our results show that the N-terminal domain of NifA plays the decisive role in the temperature sensitivity of the protein.
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PMID:The N-terminal domain of NifA determines the temperature sensitivity of NifA in Klebsiella pneumoniae and Enterobacter cloacae. 1876 10

The hyperthermophilic archaeon Sulfolobus solfataricus has been shown to exhibit a complex transcriptional response to UV irradiation involving 55 genes. Among the strongest UV-induced genes was a putative pili biogenesis operon encoding a potential secretion ATPase, two pre-pilins, a putative transmembrane protein and a protein of unknown function. Electron microscopy and image reconstruction of UV-treated cells showed straight pili with 10 nm in diameter, variable in length, not bundled or polarized and composed of three evenly spaced helices, thereby clearly being distinguishable from archaeal flagella. A deletion mutant of SSO0120, the central type II/IV secretion ATPase, did not produce pili. It could be complemented by reintroducing the gene on a plasmid vector. We have named the operon ups operon for UV-inducible pili operon of Sulfolobus. Overexpression of the pre-pilins, Ups-A/B (SSO0117/0118) in Sulfolobus resulted in production of extremely long filaments. Pronounced cellular aggregation was observed and quantified upon UV treatment. This aggregation was a UV-dose-dependent, dynamic process, not inducible by other physical stressors (such as pH or temperature shift) but stimulated by chemically induced double-strand breaks in DNA. We hypothesize that pili formation and subsequent cellular aggregation enhance DNA transfer among Sulfolobus cells to provide increased repair of damaged DNA via homologous recombination.
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PMID:UV-inducible cellular aggregation of the hyperthermophilic archaeon Sulfolobus solfataricus is mediated by pili formation. 1899 Jan 82

Escherichia coli YjeE is a broadly conserved bacterial ATPase of unknown function that has been widely characterized as essential. Here, the transcriptional regulation of the promoter of yjeE (P(yjeE)) was probed using a luciferase reporter and 172 antibiotics of diverse mechanisms. Norfloxacin and other fluorquinolones were found to be the most potent activator of P(yjeE) through binding to DNA gyrase. The stimulation of P(yjeE) by norfloxacin was most impacted by lesions in two-component signal transduction systems with roles in respiration, central metabolism, and oxidative stress responses. This suggested that YjeE may have a critical role in aerobic metabolism. Remarkably, YjeE was found to be dispensable when cells were grown in the absence of oxygen. To the best of our knowledge, these findings represent the first definitive phenotypes for this enigmatic protein.
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PMID:Known bioactive small molecules probe the function of a widely conserved but enigmatic bacterial ATPase, YjeE. 1910 73

Substrates of the proteasome are recognized and unfolded by the regulatory particle, and then translocated into the core particle (CP) to be degraded. A hetero-hexameric ATPase ring, containing subunits Rpt1-6, is situated within the base subassembly of the regulatory particle. The ATPase ring sits atop the CP, with the Rpt carboxy termini inserted into pockets in the CP. Here we identify a previously unknown function of the Rpt proteins in proteasome biogenesis through deleting the C-terminal residue from each Rpt in the yeast Saccharomyces cerevisiae. Our results indicate that assembly of the hexameric ATPase ring is templated on the CP. We have also identified an apparent intermediate in base assembly, BP1, which contains Rpn1, three Rpts and Hsm3, a chaperone for base assembly. The Rpt proteins with the strongest assembly phenotypes, Rpt4 and Rpt6, were absent from BP1. We propose that Rpt4 and Rpt6 form a nucleating complex to initiate base assembly, and that this complex is subsequently joined by BP1 to complete the Rpt ring. Our studies show that assembly of the proteasome base is a rapid yet highly orchestrated process.
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PMID:Hexameric assembly of the proteasomal ATPases is templated through their C termini. 1951 31

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