Search results for "dicarboxylic acid"

showing 10 items of 75 documents

CCDC 241330: Experimental Crystal Structure Determination

2005

Related Article: M.Brunner, M.Nissinen, T.Straub, K.Rissanen, A.M.P.Koskinen|2005|J.Mol.Struct.|734|177|doi:10.1016/j.molstruc.2004.09.020

Space GroupCrystallographyCrystal SystemCrystal StructureCell Parametersanti-(1'R2R4R)-2-t-butyl-4-(1-hydroxy-3-phenylpropyl)oxazolidine-34-dicarboxylic acid 3-t-butyl ester 4-methyl esterExperimental 3D Coordinates

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CCDC 1025299: Experimental Crystal Structure Determination

2015

Related Article: Carolina Pejo, Guilherme P. Guedes, Miguel A. Novak, Nivaldo L. Speziali, Raúl Chiozzone, Miguel Julve, Francesc Lloret, Maria G. F. Vaz, Ricardo González|2015|Chem.-Eur.J.|21|8696|doi:10.1002/chem.201500168

Space GroupCrystallographyCrystal SystemCrystal StructureCell Parameterscatena-[nonakis(tetraethylammonium) tris(mu-pyridine-35-dicarboxylato)-tetrakis(mu-5-carboxypyridine-3-carboxylato)-(mu-pyridine-35-dicarboxylic acid)-tetracontabromo-diaqua-octa-rhenium-tri-dysprosium heptahydrate]Experimental 3D Coordinates

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CCDC 1025298: Experimental Crystal Structure Determination

2015

Space GroupCrystallographyCrystal SystemCrystal StructureCell Parameterstetra-n-butylammonium penta-bromo-(pyridine-35-dicarboxylic acid)-rhenium(iv) propan-2-ol solvateExperimental 3D Coordinates

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CCDC 173785: Experimental Crystal Structure Determination

2004

Related Article: A.M.Costero, J.P.Villarroya, S.Gil, P.Gavina, M.C.R.De Arellano|2003|Supramol.Chem.|15|403|doi:10.1080/1061027031000116001

Space GroupCrystallographyCrystal SystemCrystal StructureCell Parameterstrans-258111417-Hexaoxabicyclo(16.4.0)docosa-2021-dicarboxylic acid chloroform solvate monohydrateExperimental 3D Coordinates

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CCDC 171929: Experimental Crystal Structure Determination

2001

Related Article: M.J.Plater, M.R.St.J.Foreman, R.A.Howie, J.M.S.Skakle, E.Coronado, C.J.Gomez-Garcia, T.Gelbrich, M.B.Hursthouse|2001|Inorg.Chim.Acta|319|159|doi:10.1016/S0020-1693(01)00449-2

Space GroupCrystallographyCrystal SystemCrystal Structurebis(Benzene-1-carboxylato-35-dicarboxylic acid)-(pyridine-2-(1-methyl-1H-pyrazol-3-yl))-zinc(ii)Cell ParametersExperimental 3D Coordinates

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CCDC 801665: Experimental Crystal Structure Determination

2011

Related Article: M.Tuikka, P.Hirva, K.Rissanen, J.Korppi-Tommola, M.Haukka|2011|Chem.Commun.|47|4499|doi:10.1039/c1cc10491h

Space GroupCrystallographybis(22'-Bipyridyl-44'-dicarboxylic acid)-bis(isothiocyanato)-ruthenium(ii) bis(diiodine) methanol solvateCrystal SystemCrystal StructureCell ParametersExperimental 3D Coordinates

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The Sensor Kinase DctS Forms a Tripartite Sensor Unit with DctB and DctA for Sensing C4-Dicarboxylates in Bacillus subtilis

2013

The DctSR two-component system of Bacillus subtilis controls the expression of the aerobic C4-dicarboxylate transporter DctA. Deletion of DctA leads to an increased dctA expression. The inactivation of DctB, an extracellular binding protein, is known to inhibit the expression of dctA. Here, interaction between the sensor kinase DctS and the transporter DctA as well as the binding protein DctB was demonstrated in vivo using streptavidin (Strep) or His protein interaction experiments (mSPINE or mHPINE), and the data suggest that DctA and DctB act as cosensors for DctS. The interaction between DctS and DctB was also confirmed by the bacterial two-hybrid system (BACTH). In contrast, no indicati…

StreptavidinRegulation of gene expressionKinaseBinding proteinMembrane ProteinsTransporterGene Expression Regulation BacterialArticlesPlasma protein bindingBacillus subtilisBiologybiology.organism_classificationMicrobiologyGene Expression Regulation Enzymologicchemistry.chemical_compoundPlasmidBacterial ProteinsBiochemistrychemistryDicarboxylic AcidsCarrier ProteinsMolecular BiologyBacillus subtilisPlasmidsProtein BindingJournal of Bacteriology

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Polar Localization of a Tripartite Complex of the Two-Component System DcuS/DcuR and the Transporter DctA in Escherichia coli Depends on the Sensor K…

2014

The C4-dicarboxylate responsive sensor kinase DcuS of the DcuS/DcuR two-component system of E. coli is membrane-bound and reveals a polar localization. DcuS uses the C4-dicarboxylate transporter DctA as a co-regulator forming DctA/DcuS sensor units. Here it is shown by fluorescence microscopy with fusion proteins that DcuS has a dynamic and preferential polar localization, even at very low expression levels. Single assemblies of DcuS had high mobility in fast time lapse acquisitions, and fast recovery in FRAP experiments, excluding polar accumulation due to aggregation. DctA and DcuR fused to derivatives of the YFP protein are dispersed in the membrane or in the cytosol, respectively, when …

Yellow fluorescent proteinCardiolipinslcsh:MedicineMicrobiologyMreBMicrobial PhysiologyBacterial Physiologylcsh:ScienceCytoskeletonMicrobial MetabolismDicarboxylic Acid TransportersMultidisciplinaryEscherichia coli K12biologyBacterial GrowthEscherichia coli Proteinslcsh:RMicrobial Growth and DevelopmentBiology and Life SciencesFluorescence recovery after photobleachingBacteriologyFusion proteinTwo-component regulatory systemBacterial BiochemistryTransport proteinDNA-Binding ProteinsProtein TransportBiochemistryCytoplasmMultiprotein ComplexesBiophysicsbiology.proteinlcsh:QProtein KinasesResearch ArticleDevelopmental BiologyTranscription FactorsPLoS ONE

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Bempedoic acid as adjunct for traditional lipid-lowering therapy in patients with hyperlipidaemia

2020

Statin therapy has been the cornerstone for the reduction of cholesterol and circulating low-density lipoprotein (LDL) in patients with cardiovascular diseases. However, statin monotherapy has disadvantages attributable to myopathies and to the insufficient cholesterol reduction observed in some patients. There is a need for new well-tolerated therapies for lowering LDL. This review will focus on bempedoic acid in combination with traditional statin therapy or other lipid-lowering agents and its emerging role in LDL-C lowering. Bempedoic acid is also a viable alternative for reducing LDL cholesterol in the treatment of some patients suffering from heterozygous familial hypercholesterolemia.

bempedoic acidmedicine.medical_specialtyStatinmedicine.drug_classHyperlipidemiasFamilial hypercholesterolemia030204 cardiovascular system & hematologyLipid-lowering therapystatins03 medical and health scienceschemistry.chemical_compound0302 clinical medicineInternal medicinemedicineHumansDicarboxylic AcidsIn patient030212 general & internal medicineHypolipidemic AgentsClinical Trials as Topiclipid-lowering therapyCholesterolbusiness.industryFatty Acidsnutritional and metabolic diseasesCholesterol LDLGeneral Medicinemedicine.diseaselow-density lipoproteinchemistryDrug Therapy Combinationlipids (amino acids peptides and proteins)Statin therapyHydroxymethylglutaryl-CoA Reductase InhibitorsatherosclerosisCardiology and Cardiovascular MedicinebusinessBempedoic acidLipoproteinCoronary Artery Disease

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C2-Symmetric Ferrocene-Bis(ureido)peptides : Synthesis, Conformation and Solid-State Structure

2009

The extension of peptide derivatives of ferrocene-1,1'-dicarboxylic acid by formal insertion of NH units between ferrocene and peptide strands results in ferrocene-bis(ureido)-peptides. Experimentally, alanine and dialanine methyl esters were attached to the 1- and 1'-position of 1,1'-diiso-cyanoferrocene to give the corresponding bis(ureido)peptide derivatives 3 and 4. The conformation of 3 has been determined in the solid state by X-ray crystallography. In solution the preferred conformation of 3 and 4 has been elucidated by NMR, IR and CD spectroscopy in concert with DFT calculations. The secondary structure of ferrocene―bis(ureido)peptides 3 and 4 is determined by double bifurcated intr…

chemistry.chemical_classificationAlanineCircular dichroismStereochemistryHydrogen bondPeptideInorganic Chemistrychemistry.chemical_compoundDicarboxylic acidFerrocenechemistryIntramolecular forceconformation analysis; density functional calculations; hydrogen bonds; metallocenes; peptidesProtein secondary structure

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