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)

Resistance to toxic oxyanions of arsenic and antimony in Escherichia coli results from active efflux of these anions out of the cell. Extrusion is an active process mediated by an ATP-dependent pump composed of two types of subunits, the integral membrane ArsB protein and the catalytic ArsA subunit. An in vitro assay for transport in everted membrane vesicles of E. coli was developed. Uptake of 73AsO2- by everted vesicles was time- and temperature-dependent and required both pump subunits. Transport required ATP; no other nucleotide, including GTP, CTP, UTP, or the nonhydrolyzable analog adenosine 5'-O-(thiotriphosphate), could substitute for ATP. Protonophores, ionophores, or inhibitors of other types of ion-motive ATPases did not inhibit arsenite uptake. The sulfhydryl reagent N-ethylmaleimide was a potent inhibitor of ATP-dependent arsenite accumulation in vesicles. The apparent Km values for ATP and arsenite were approximately 2 and 0.1 mM, respectively. Antimonite, the most potent activator of the ArsA ATPase, inhibited arsenite uptake with an apparent Ki of 10 microM.
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PMID:ATP-dependent arsenite transport in everted membrane vesicles of Escherichia coli. 792 43

Resistance to arsenical and antimonial compounds in Escherichia coli is due to active extrusion of these compounds from cells expressing the ars operon. The arsenical pump is an ion-translocating ATPase which consists of two polypeptide components, the ArsA and ArsB proteins. The ArsB protein, the inner membrane component of the pump, has been shown to function as the membrane anchor for the catalytic subunit, the ArsA protein. The properties and nature of interaction between these two components of the pump were investigated using an in vitro binding assay. Purified ArsA protein bound to the membrane in a saturable manner. In the absence of arsenite or antimonite an apparent positive cooperativity in the binding of the ArsA protein to membrane vesicles containing the ArsB protein was observed. In the presence of arsenite or antimonite binding became hyperbolic, with a 10-fold decrease in the concentration of ArsA protein required for half-maximal binding, without any change in the stoichiometry of the complex. Addition of ATP had little affect on membrane binding of the ArsA ATPase subunit. In the presence or absence of the anionic substrates binding was maximal in a pH range 7.5-8.5.
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PMID:Interaction of the catalytic and the membrane subunits of an oxyanion-translocating ATPase. 820 5

Arsenic compounds, often present as environmental pollutants, are highly toxic for most microorganisms. Some microbial strains possess genetic determinants conferring resistance to arsenic derivatives. In bacteria, these determinants are usually located on plasmids, which has facilitated their analysis with molecular detail. Bacterial plasmids conferring arsenic resistance encode specific pumps that extrude arsenite (AsIII). In Gram-negative bacteria, the efflux pump consists of a complex formed by an ATPase (ArsA) associated with a membrane anion channel (ArsB). Arsenate (AsV) is converted to arsenite by a soluble reductase (ArsC). Proteins ArsB and ArsC, but not the ATPase, are also found in Gram-positive bacteria. Besides the widely spread plasmid arsenic resistance determinants, some bacteria possess the ability to enzimatically oxidize arsenite to less toxic arsenate.
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PMID:[Bacterial resistance to arsenic compounds]. 890 May 73

Bacterial plasmids encode resistance systems for toxic metal ions including Ag+, AsO2-, AsO4(3-), Cd2+, CO2+, CrO4(2-), Cu2+, Hg2+, Ni2+, Pb2+, Sb3+, TeO3(2-), Tl+, and Zn2+. In addition to understanding of the molecular genetics and environmental roles of these resistances, studies during the last few years have provided surprises and new biochemical mechanisms. Chromosomal determinants of toxic metal resistances are known, and the distinction between plasmid resistances and those from chromosomal genes has blurred, because for some metals (notably mercury and arsenic), the plasmid and chromosomal determinants are basically the same. Other systems, such as copper transport ATPases and metallothionein cation-binding proteins, are only known from chromosomal genes. The largest group of metal resistance systems function by energy-dependent efflux of toxic ions. Some of the efflux systems are ATPases and others are chemiosmotic cation/proton antiporters. The CadA cadmium resistance ATPase of gram-positive bacteria and the CopB copper efflux system of Enterococcus hirae are homologous to P-type ATPases of animals and plants. The CadA ATPase protein has been labeled with 32P from gamma-32P-ATP and drives ATP-dependent Cd2+ uptake by inside-out membrane vesicles. Recently isolated genes defective in the human hereditary diseases of copper metabolism, Menkes syndrome and Wilson's disease, encode P-type ATPases that are more similar to the bacterial CadA and CopB ATPases than to eukaryote ATPases that pump different cations. The arsenic resistance efflux system transports arsenite, using alternatively either a two-component (ArsA and ArsB) ATPase or a single polypeptide (ArsB) functioning as a chemiosmotic transporter. The third gene in the arsenic resistance system, arsC, encodes an enzyme that converts intracellular arsenate [As (V)] to arsenite [As (III)], the substrate of the efflux system. The three-component Czc (Cd2+, Zn2+, and CO2+) chemiosmotic efflux pump of soil microbes consists of inner membrane (CzcA), outer membrane (CzcC), and membrane-spanning (CzcB) proteins that together transport cations from the cytoplasm across the periplasmic space to the outside of the cell. Finally, the first bacterial metallothionein (which by definition is a small protein that binds metal cations by means of numerous cysteine thiolates) has been characterized in cyanobacteria.
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PMID:Bacterial heavy metal resistance: new surprises. 890 98

Bacterial plasmids encode resistance systems for toxic metal ions, including Ag+, AsO2-, AsO4(3-), Cd2+, Co2+, CrO4(2-), Cu2+, Hg2+, Ni2+, Pb2+, Sb3+, TeO3(2-), Tl+ and Zn2+. The function of most resistance systems is based on the energy-dependent efflux of toxic ions. Some of the efflux systems are ATPases and others are chemiosmotic cation/proton antiporters. The Cd(2+)-resistance ATPase of Gram-positive bacteria (CadA) is membrane cation pump homologous with other bacterial, animal and plant P-type ATPases. CadA has been labeled with 32P from [alpha-32P] ATP and drives ATP-dependent Cd2+ (and Zn2+) uptake by inside-out membrane vesicles (equivalent to efflux from whole cells). Recently, isolated genes defective in the human hereditary diseases of copper metabolism, namely Menkes syndrome and Wilson's disease, encode P-type ATPases that are more similar to bacterial CadA than to other ATPases from eukaryotes. The arsenic resistance efflux system transports arsenite [As(III)], alternatively using either a double-polypeptide (ArsA and ArsB) ATPase or a single-polypeptide (ArsB) functioning as a chemiosmotic transporter. The third gene in the arsenic resistance system, arsC, encodes an enzyme that converts intracellular arsenate [As(V)] to arsenite [As(III)], the substrate of the efflux system. The triple-polypeptide Czc (Cd2+, Zn2+ and Co2+) chemiosmotic efflux pump consists of inner membrane (CzcA), outer membrane (CzcC) and membrane-spanning (CzcB) proteins that together transport cations from the cytoplasm across the periplasmic space to the outside of the cell.
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PMID:Bacterial resistances to toxic metal ions--a review. 899 52

Bacterial chromosomes have genes for transport proteins for inorganic nutrient cations and oxyanions, such as NH4+, K+, Mg2+, Co2+, Fe3+, Mn2+, Zn2+ and other trace cations, and PO4(3-), SO4(2-) and less abundant oxyanions. Together these account for perhaps a few hundred genes in many bacteria. Bacterial plasmids encode resistance systems for toxic metal and metalloid ions including Ag+, AsO2-, AsO4(3-), Cd2+, Co2+, CrO4(2-), Cu2+, Hg2+, Ni2+, Pb2+, TeO3(2-), Tl+ and Zn2+. Most resistance systems function by energy-dependent efflux of toxic ions. A few involve enzymatic (mostly redox) transformations. Some of the efflux resistance systems are ATPases and others are chemiosmotic ion/proton exchangers. The Cd(2+)-resistance cation pump of Gram-positive bacteria is membrane P-type ATPase, which has been labeled with 32P from [gamma-32P]ATP and drives ATP-dependent Cd2+ (and Zn2+) transport by membrane vesicles. The genes defective in the human hereditary diseases of copper metabolism, Menkes syndrome and Wilson's disease, encode P-type ATPases that are similar to bacterial cadmium ATPases. The arsenic resistance system transports arsenite [As(III)], alternatively with the ArsB polypeptide functioning as a chemiosmotic efflux transporter or with two polypeptides, ArsB and ArsA, functioning as an ATPase. The third protein of the arsenic resistance system is an enzyme that reduces intracellular arsenate [As(V)] to arsenite [As(III)], the substrate of the efflux system. In Gram-negative cells, a three polypeptide complex functions as a chemiosmotic cation/protein exchanger to efflux Cd2+, Zn2+ and Co2+. This pump consists of an inner membrane (CzcA), an outer membrane (CzcC) and a membrane-spanning (CzcB) protein that function together.
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PMID:Genes for all metals--a bacterial view of the periodic table. The 1996 Thom Award Lecture. 952 53

ArsA protein is the soluble subunit of the Ars anion pump in the Escherichia coli membrane which extrudes arsenite or antimonite from the cytoplasm. The molecular weight of the subunit is 63 kDa. In the cell it hydrolyzes ATP, and the energy released is used by the membrane-bound subunit ArsB to transport the substrates across the membrane. We have obtained two-dimensional crystals of ArsA in the presence of arsenite on negatively-charged lipid monolayer composed of DMPS and DOPC. These crystals have been studied using electron microscopy of negatively-stained specimens followed by image processing. The projection map obtained at 2.4 nm resolution reveals a ring-like structure with threefold symmetry. Many molecular assemblies with the same ring-shape and dimensions were also seen dispersed on electron microscopy grids, prepared directly from purified ArsA protein solution. Size-exclusion chromatography of the protein sample with arsenite present revealed that the majority of the protein particles in solution have a molecular weight of about 180 kDa. Based on these experiments, we conclude that in solution the ArsA ATPase with substrate bound is mainly in a trimeric form.
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PMID:Trimeric ring-like structure of ArsA ATPase. 1070 66

The ArsAB ATPase is an efflux pump located in the inner membrane of Escherichia coli. This transport ATPase confers resistance to arsenite and antimonite by their extrusion from the cells. The pump is composed of two subunits, the catalytic ArsA subunit and the membrane subunit ArsB. The complex is similar in many ways to ATP-binding cassette ('ABC') transporters, which typically have two groups of six transmembrane-spanning helical segments and two nucleotide-binding domains (NBDs). The 45 kDa ArsB protein has 12 transmembrane-spanning segments. ArsB contains the substrate translocation pathway and is capable of functioning as an anion uniporter. The 63 kDa ArsA protein is a substrate-activated ATPase. It has two homologous halves, A1 and A2, which are clearly the result of an ancestral gene duplication and fusion. Each half has a consensus NBD. The mechanism of allosteric activation of the ArsA ATPase has been elucidated by a combination of molecular genetics and biochemical, structural and kinetic analyses. Conformational changes produced by binding of substrates, activator and/or products could be revealed by stopped-flow fluorescence measurements with single-tryptophan derivatives of ArsA. The results demonstrate that the rate-limiting step in the overall reaction is a slow isomerization between two conformations of the enzyme. Allosteric activation increases the rate of this isomerization such that product release becomes rate-limiting, thus accelerating catalysis. ABC transporters, which exhibit similar substrate activation of ATPase activity, can undergo similar conformational changes to overcome a rate-limiting step. Thus the ArsAB pump is a useful model for elucidating mechanistic aspects of the ABC superfamily of transport ATPases.
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PMID:Structure-function relationships in an anion-translocating ATPase. 1096 52

Active extrusion is a common mechanism underlying detoxification of heavy metals, drugs and antibiotics in bacteria, protozoa and mammals. In Escherichia coli, the ArsAB pump provides resistance to arsenite and antimonite. This pump consists of a soluble ATPase (ArsA) and a membrane channel (ArsB). ArsA contains two nucleotide-binding sites (NBSs) and a binding site for arsenic or antimony. Binding of metalloids stimulates ATPase activity. The crystal structure of ArsA reveals that both NBSs and the metal-binding site are located at the interface between two homologous domains. A short stretch of residues connecting the metal-binding site to the NBSs provides a signal transduction pathway that conveys information on metal occupancy to the ATP hydrolysis sites. Based on these structural features, we propose that the metal-binding site is involved directly in the process of vectorial translocation of arsenite or antimonite across the membrane. The relative positions of the NBS and the inferred mechanism of allosteric activation of ArsA provide a useful model for the interaction of the catalytic domains in other transport ATPases.
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PMID:Structure of the ArsA ATPase: the catalytic subunit of a heavy metal resistance pump. 1097 Aug 74

The ArsA ATPase is the catalytic subunit of the pump protein, coupling the hydrolysis of ATP to the movement of arsenicals and antimonials through the membrane-spanning ArsB protein. Previously, we have shown the binding and hydrolysis of MgATP to ArsA to be a multi-step process in which the rate-limiting step is an isomerization between different conformational forms of ArsA. This isomerization occurs after product release, at the end of the ATPase reaction, and involves the return of the ArsA to its original conformation, which can then bind MgATP. ArsA possesses an allosteric site for antimonite [Sb(III)], the binding of which elevates the steady-state ATPase activity. We have used a transient kinetics approach to investigate the kinetics of ternary complex formation that lead to an enhancement in the ATPase activity. These studies revealed that ArsA exists in at least two conformational forms that differ in their ligand binding affinities, and that ATP favours one form and Sb(III) the other. Ternary complex formation is rate-limited by a slow transition between these conformational forms, leading to a lag in attaining maximal steady-state activity. Sb(III) enhances the steady-state ATPase activity by inducing rapid product release, allowing ArsA to adopt a conformation that can bind MgATP for the next catalytic cycle. In the presence of Sb(III), ArsA avoids the rate-limiting isomerization at the end of the ATPase reaction and ATP hydrolysis becomes rate-limiting for the reaction. The binding of Sb(III) probably results in more effective pumping of the substrates from the cell by enhancing the rate of efflux.
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PMID:Antimonite regulation of the ATPase activity of ArsA, the catalytic subunit of the arsenical pump. 1173 48

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