Search results for "Dicarboxylic Acid"

showing 10 items of 75 documents

Identification of a third secondary carrier (DcuC) for anaerobic C4-dicarboxylate transport in Escherichia coli: roles of the three Dcu carriers in u…

1996

In Escherichia coli, two carriers (DcuA and DcuB) for the transport of C4 dicarboxylates in anaerobic growth were known. Here a novel gene dcuC was identified encoding a secondary carrier (DcuC) for C4 dicarboxylates which is functional in anaerobic growth. The dcuC gene is located at min 14.1 of the E. coli map in the counterclockwise orientation. The dcuC gene combines two open reading frames found in other strains of E. coli K-12. The gene product (DcuC) is responsible for the transport of C4 dicarboxylates in DcuA-DcuB-deficient cells. The triple mutant (dcuA dcuB dcuC) is completely devoid of C4-dicarboxylate transport (exchange and uptake) during anaerobic growth, and the bacteria are…

DNA BacterialMutantMolecular Sequence DataBiologymedicine.disease_causeMicrobiologyGene productBacterial ProteinsmedicineEscherichia coliDicarboxylic AcidsAmino Acid SequenceAnaerobiosisMolecular BiologyEscherichia coliPeptide sequenceGeneDicarboxylic Acid TransportersBase SequenceSequence Homology Amino AcidEscherichia coli ProteinsChromosome MappingBiological Transportbiology.organism_classificationIsoenzymesOpen reading frameMutagenesis InsertionalBiochemistryC4-dicarboxylate transportCarrier ProteinsBacteriaResearch ArticleJournal of bacteriology
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Preparation and structural studies on the tBu2Sn(IV) complexes with aromatic mono- and dicarboxylic acids containing hetero {N} donor atom

2004

Nine complexes of 'Bu2Sn(IV)(2+) were obtained in the solid state with ligands containing -COOH group(s) and aromatic (N) donor atom. The binding sites of the ligands were identified by FT-IR spectroscopic measurements. It was found that in most cases the -COO- groups are co-ordinated in monodentate manner. Nevertheless, in some of our complexes, the -COO- group forms bridges between two central {Sn} atoms resulting in the formation of an oligomeric structure, a motif that is characteristic only to the nicotinate compound. These pieces of information and the rationalisation of the experimental Sn-119 Mossbauer nuclear quadrupole splittings, Delta, - according to the point charge model forma…

DenticitygeometryX ray diffractionCrystal structureOrganotin(IV)nicotinic acid derivativeBiochemistryInorganic Chemistrycomplex formationMaterials ChemistryMoleculeorganotin compoundcontrolled studyPhysical and Theoretical Chemistryinfrared spectroscopychemical bindinghydrogen bondHydrogen bondChemistryMössbauer spectroscopybinding siteOrganic ChemistryarticleSquare pyramidal molecular geometryX-ray diffractionFT-IRtin derivativeTrigonal bipyramidal molecular geometryCrystallographyOctahedrondicarboxylic acidSettore CHIM/03 - Chimica Generale E Inorganicachemical structureMolecular modellingcarboxylic acidsynthesimolecular modelchemical analysiSingle crystal
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The sensor kinase DcuS of Escherichia coli: two stimulus input sites and a merged signal pathway in the DctA/DcuS sensor unit

2012

Abstract The membrane-integral sensor kinase DcuS of Escherichia coli consists of a periplasmically located sensory PASP domain, transmembrane helices TM1 and TM2, a cytoplasmic PASC domain and the kinase domain. Stimulus (C4-dicarboxylate) binding at PASP is required to stimulate phosphorylation of the kinase domain, resulting in phosphoryl transfer to the response regulator DcuR. PASC functions as a signaling device or a relay in signal transfer from TM2 to the kinase. Phosphorylated DcuR induces the expression of the target genes. Sensing by DcuS requires the presence of the C4-dicarboxylate transporter DctA during aerobic growth. DctA forms a sensor unit with DcuS, and a short C-termina…

Dicarboxylic Acid TransportersChemistryKinaseEscherichia coli ProteinsAntiporterClinical Biochemistrymedicine.disease_causeModels BiologicalBiochemistryCell biologyResponse regulatorTransmembrane domainBiochemistryProtein kinase domainPAS domainmedicinePhosphorylationProtein KinasesMolecular BiologyEscherichia coliSignal Transductionbchm
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DcuA of aerobically grownEscherichia coliserves as a nitrogen shuttle (L‐aspartate/fumarate) for nitrogen uptake

2018

DcuA of Escherichia coli is known as an alternative C4 -dicarboxylate transporter for the main anaerobic C4 -dicarboxylate transporter DcuB. Since dcuA is expressed constitutively under aerobic and anaerobic conditions, DcuA was suggested to serve aerobically as a backup for the aerobic (DctA) transporter, or for the anabolic uptake of C4 -dicarboxylates. In this work, it is shown that DcuA is required for aerobic growth with L-aspartate as a nitrogen source, whereas for growth with L-aspartate as a carbon source, DctA was needed. Strains with DcuA catalyzed L-aspartate and C4 -dicarboxylate uptake (like DctA), or an L-aspartate/C4 -dicarboxylate antiport (unlike DctA). DcuA preferred L-asp…

Glycerol0301 basic medicineendocrine system diseasesAntiporter030106 microbiologyMalateschemistry.chemical_elementBiologymedicine.disease_causeMicrobiology03 medical and health scienceschemistry.chemical_compoundBacterial ProteinsFumaratesAspartic acidEscherichia colimedicineGlycerolMolecular BiologyEscherichia coliDicarboxylic Acid TransportersAspartic AcidEscherichia coli Proteinsnutritional and metabolic diseasesBiological TransportTransporterbiology.organism_classificationNitrogen030104 developmental biologychemistryBiochemistryAnaerobic exercisehormones hormone substitutes and hormone antagonistsBacteriaMolecular Microbiology
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Fumarate regulation of gene expression in Escherichia coli by the DcuSR (dcuSR genes) two-component regulatory system.

1998

ABSTRACT In Escherichia coli the genes encoding the anaerobic fumarate respiratory system are transcriptionally regulated by C 4 -dicarboxylates. The regulation is effected by a two-component regulatory system, DcuSR, consisting of a sensory histidine kinase (DcuS) and a response regulator (DcuR). DcuS and DcuR are encoded by the dcuSR genes (previously yjdHG ) at 93.7 min on the calculated E. coli map. Inactivation of the dcuR and dcuS genes caused the loss of C 4 -dicarboxylate-stimulated synthesis of fumarate reductase ( frdABCD genes) and of the anaerobic fumarate-succinate antiporter DcuB ( dcuB gene). DcuS is predicted to contain a large periplasmic domain as the supposed site for C 4…

Histidine KinaseGenetics and Molecular Biologymedicine.disease_causeMicrobiologyAntiportersBacterial ProteinsFumaratesmedicineEscherichia coliDicarboxylic AcidsMolecular BiologyEscherichia coliRegulation of gene expressionDicarboxylic Acid TransportersbiologySuccinate dehydrogenaseEscherichia coli ProteinsHistidine kinaseMembrane ProteinsPeriplasmic spaceGene Expression Regulation BacterialFumarate reductaseTwo-component regulatory systemDNA-Binding ProteinsSuccinate DehydrogenaseResponse regulatorMutagenesis InsertionalBiochemistryGenes Bacterialbiology.proteinCarrier ProteinsProtein KinasesSignal TransductionTranscription FactorsJournal of bacteriology
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Sensing by the membrane-bound sensor kinase DcuS: exogenous versus endogenous sensing of C(4)-dicarboxylates in bacteria.

2010

Bacteria are able to grow at the expense of both common (succinate, L-malate, fumarate and aspartate) and uncommon (L-tartrate and D-malate) C4-dicarboxylates, which are components of central metabolism. Two types of sensors/regulators responding to the C4-dicarboxylates function in Escherichia coli, Bacillus, Lactobacillus and related bacteria. The first type represents membrane-integral two-component systems, while the second includes cytoplasmic LysR-type transcriptional regulators. The difference in location and substrate specificity allows the exogenous induction of metabolic genes by common C4-dicarboxylates, and endogenous induction by uncommon C4-dicarboxylates. The two-component s…

Microbiology (medical)Dicarboxylic Acid TransportersModels MolecularBacteriaEscherichia coli ProteinsCell MembraneRegulatory siteGene Expression Regulation BacterialBiologyLigand (biochemistry)MicrobiologyTransmembrane domainBiochemistryProtein kinase domainBacterial ProteinsPAS domainExtracellularEscherichia coliDicarboxylic AcidsBinding siteSignal transductionProtein KinasesSignal TransductionFuture microbiology
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The Nature of the Stimulus and of the Fumarate Binding Site of the Fumarate Sensor DcuS of Escherichia coli

2005

DcuS is a membrane-associated sensory histidine kinase of Escherichia coli specific for C(4) -dicarboxylates. The nature of the stimulus and its structural prerequisites were determined by measuring the induction of DcuS-dependent dcuB'-'lacZ gene expression. C(4)-dicarboxylates without or with substitutions at C2/C3 by hydrophilic (hydroxy, amino, or thiolate) groups stimulated gene expression in a similar way. When one carboxylate was replaced by sulfonate, methoxy, or nitro groups, only the latter (3-nitropropionate) was active. Thus, the ligand of DcuS has to carry two carboxylate or carboxylate/nitro groups 3.1-3.8 A apart from each other. The effector concentrations for half-maximal i…

Models MolecularMagnetic Resonance SpectroscopyHistidine KinaseRecombinant Fusion ProteinsMolecular Sequence Datamedicine.disease_causeBiochemistryCitric AcidStructure-Activity Relationshipchemistry.chemical_compoundFumaratesEscherichia colimedicineDicarboxylic AcidsAmino Acid SequenceCarboxylatePhosphorylationBinding siteKinase activityTartratesMolecular BiologyEscherichia coliPeptide sequenceDicarboxylic Acid TransportersBinding SitesChemistryEscherichia coli ProteinsAutophosphorylationHistidine kinaseGene Expression Regulation BacterialCell BiologyNitro CompoundsPeptide FragmentsEnzyme ActivationLac OperonBiochemistryMutagenesis Site-DirectedPropionatesProtein KinasesSequence AlignmentBinding domainJournal of Biological Chemistry
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Topology and accessibility of the transmembrane helices and the sensory site in the bifunctional transporter DcuB of Escherichia coli.

2011

C(4)-Dicarboxylate uptake transporter B (DcuB) of Escherichia coli is a bifunctional transporter that catalyzes fumarate/succinate antiport and serves as a cosensor of the sensor kinase DcuS. Sites and domains of DcuB were analyzed for their topology relative to the cytoplasmic or periplasmic side of the membrane and their accessibility to the water space. For the topology studies, DcuB was fused at 33 sites to the reporter enzymes PhoA and LacZ that are only active when located in the periplasm or the cytoplasm, respectively. The ratios of the PhoA and LacZ activities suggested the presence of 10 or 11 hydrophilic loops, and 11 or 12 α-helical transmembrane domains (TMDs). The central part…

Models MolecularRecombinant Fusion ProteinsMolecular Sequence Datalac operonTopologyBiochemistryProtein Structure SecondaryPolyethylene GlycolsProtein structureBacterial ProteinsCatalytic DomainStilbenesAmino Acid SequenceCysteineBinding sitePeptide sequenceDicarboxylic Acid TransportersEscherichia coli K12ChemistryEscherichia coli ProteinsCell MembranePeriplasmic spaceAlkaline PhosphataseTransmembrane domainMembrane proteinBiochemistryLac OperonEthylmaleimideSulfonic AcidsHydrophobic and Hydrophilic InteractionsCysteineBiochemistry
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Virtual Combinatorial Syntheses and Computational Screening of New Potential Anti-Herpes Compounds

1999

The activity of new anti-HSV-1 chemical structures, designed by virtual combinatorial chemical synthesis and selected by a computational screening, is determined by an in vitro assay. A virtual library of phenol esters and anilides was formed from two databases of building blocks: one with carbonyl fragments and the other containing both substituted phenoxy and phenylamino fragments. The library of virtually assembled compounds was computationally screened, and those compounds which were selected by our mathematical model as active ones were finally synthesized and tested. Our antiviral activity model is a "tandem" of four linear functions of topological graph-theoretical descriptors. A giv…

Models Molecularmedicine.drug_classStereochemistryChemical structureCarboxamideHerpesvirus 1 HumanViral Plaque AssayAntiviral AgentsChemical synthesisInhibitory Concentration 50Structure-Activity RelationshipPhenolsChlorocebus aethiopsDrug DiscoverymedicineIc50 valuesAnimalsStructure–activity relationshipAnilidesVero Cellschemistry.chemical_classificationBicyclic moleculeTandemChemistryEstersDicarboxylic acidMolecular MedicineJournal of Medicinal Chemistry
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A Na+-coupled C4-dicarboxylate transporter (Asuc_0304) and aerobic growth of Actinobacillus succinogenes on C4-dicarboxylates

2014

Actinobacillus succinogenes, which is known to produce large amounts of succinate during fermentation of hexoses, was able to grow on C4-dicarboxylates such as fumarate under aerobic and anaerobic conditions. Anaerobic growth on fumarate was stimulated by glycerol and the major product was succinate, indicating the involvement of fumarate respiration similar to succinate production from glucose. The aerobic growth on C4-dicarboxylates and the transport proteins involved were studied. Fumarate was oxidized to acetate. The genome of A. succinogenes encodes six proteins with similarity to secondary C4-dicarboxylate transporters, including transporters of the Dcu (C4-dicarboxylate uptake), Dcu…

Molecular Sequence Datamedicine.disease_causeModels BiologicalMicrobiologyDivalentBacterial ProteinsFumaratesmedicineDicarboxylic AcidsAmino Acid SequenceAnaerobiosisCarbon RadioisotopesEscherichia coliPhylogenyDicarboxylic Acid Transporterschemistry.chemical_classificationbiologySodiumBiological TransportSuccinatesActinobacillusGene Expression Regulation BacterialFumarate reductasebiology.organism_classificationAerobiosisTransport proteinActinobacillus succinogenesGlucoseBiochemistrychemistrySymporterFermentationCotransporterSequence AlignmentMicrobiology
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