Search results for "thione"

showing 10 items of 865 documents

CCDC 921191: Experimental Crystal Structure Determination

2013

Related Article: Pilar Amo-Ochoa, Simone S. Alexandre, Samira Hribesh, Miguel A. Galindo, Oscar Castillo, Carlos J. Gómez-García, Andrew R. Pike, José M. Soler, Andrew Houlton, Ross W. Harrington, William Clegg, Félix Zamora|2013|Inorg.Chem.|52|5290|doi:10.1021/ic400237h

(2-amino-9-pentofuranosyl-9H-purine-6-thiolato)-bis(2-amino-9-pentofuranosyl-19-dihydro-6H-purine-6-thione)-cobalt(iii) sulfate trihydrateSpace GroupCrystallographyCrystal SystemCrystal StructureCell ParametersExperimental 3D Coordinates

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CCDC 262732: Experimental Crystal Structure Determination

2005

Related Article: C.Faulmann, S.Dorbes, B.G.de Bonneval, G.Molnar, A.Bousseksou, C.J.Gomez-Garcia, E.Coronado, L.Valade|2005|Eur.J.Inorg.Chem.||3261|doi:10.1002/ejic.200500125

(4-azaheptamethylene-17-bis(salicylideneiminate))-(1-(pyridine-4-yl)-2-(N-methylpyrrol-2-yl)ethene)-iron(iii) bis(13-dithiole-2-thione-45-dithiolato)-nickelSpace GroupCrystallographyCrystal SystemCrystal StructureCell ParametersExperimental 3D Coordinates

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CCDC 262731: Experimental Crystal Structure Determination

2005

Related Article: C.Faulmann, S.Dorbes, B.G.de Bonneval, G.Molnar, A.Bousseksou, C.J.Gomez-Garcia, E.Coronado, L.Valade|2005|Eur.J.Inorg.Chem.||3261|doi:10.1002/ejic.200500125

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CCDC 262734: Experimental Crystal Structure Determination

2005

Related Article: C.Faulmann, S.Dorbes, B.G.de Bonneval, G.Molnar, A.Bousseksou, C.J.Gomez-Garcia, E.Coronado, L.Valade|2005|Eur.J.Inorg.Chem.||3261|doi:10.1002/ejic.200500125

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CCDC 262730: Experimental Crystal Structure Determination

2005

Related Article: C.Faulmann, S.Dorbes, B.G.de Bonneval, G.Molnar, A.Bousseksou, C.J.Gomez-Garcia, E.Coronado, L.Valade|2005|Eur.J.Inorg.Chem.||3261|doi:10.1002/ejic.200500125

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Anhydrobiosis in yeasts: Glutathione synthesis by yeast Ogataea (Hansenula) polymorpha cells after their dehydration-rehydration.

2019

The possibility of using active dry microbial preparations in biotechnological processes is essential for the development of new modern industrial technologies. In this study, we show the possibility of obtaining such preparations of the genetically engineered yeast strain Ogataea (Hansenula) polymorpha with glutathione overproduction. Special pre-treatment involving the gradual rehydration of dry cells in water vapour led to the restoration/reactivation of almost 100% of dehydrated cells. Furthermore, dry cells do not lose their viability during storage at room temperatures. Application of dry cells as the inoculum provides the same levels of glutathione synthesis as that of a native yeast…

0106 biological sciences0301 basic medicineBioengineeringGlutathione synthesis01 natural sciencesApplied Microbiology and BiotechnologyGlutathione Synthase03 medical and health scienceschemistry.chemical_compound010608 biotechnologymedicineDehydrationDesiccationOverproductionCryptobiosisMicrobial ViabilityChemistryGeneral MedicineGlutathionemedicine.diseaseGlutathioneYeast030104 developmental biologyDehydration rehydrationBasic-Leucine Zipper Transcription FactorsBiochemistrySaccharomycetalesFluid TherapyGenetic EngineeringHansenula polymorphaBiotechnologyJournal of biotechnology

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Responsiveness of metallothionein and hemocyanin genes to cadmium and copper exposure in the garden snail Cornu aspersum.

2020

Abstract Terrestrial gastropods express metal‐selective metallothioneins (MTs) by which they handle metal ions such as Zn2+, Cd2+, and Cu+/Cu2+ through separate metabolic pathways. At the same time, they depend on the availability of sufficient amounts of Cu as an essential constituent of their respiratory protein, hemocyanin (Hc). It was, therefore, suggested that in snails Cu‐dependent MT and Hc pathways might be metabolically connected. In fact, the Cu‐specific snail MT (CuMT) is exclusively expressed in rhogocytes, a particular molluscan cell type present in the hemocoel and connective tissues. Snail rhogocytes are also the sites of Hc synthesis. In the present study, possible interacti…

0106 biological sciences0301 basic medicineDNA ComplementaryPhysiologymedicine.medical_treatmentSnailsGastropodaSnailBiology010603 evolutionary biology01 natural sciences03 medical and health sciencesstressbiology.animalGastropodaparasitic diseasesGeneticsmedicineMetallothioneinAnimalsMolecular BiologyEcology Evolution Behavior and SystematicsMetal metabolismBase Sequencefungimetal metabolismMidgutHemocyaninbiology.organism_classificationResearch PapersRespiratory protein030104 developmental biologybioaccumulationBiochemistryGene Expression RegulationMetalsHemocyaninsAnimal Science and ZoologyMetallothioneinCornu aspersumCopperrespirationCadmiumResearch PaperJournal of experimental zoology. Part A, Ecological and integrative physiology

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Thioredoxin (Trxo1) interacts with proliferating cell nuclear antigen (PCNA) and its overexpression affects the growth of tobacco cell culture.

2017

Thioredoxins (Trxs), key components of cellular redox regulation, act by controlling the redox status of many target proteins, and have been shown to play an essential role in cell survival and growth. The presence of a Trx system in the nucleus has received little attention in plants, and the nuclear targets of plant Trxs have not been conclusively identified. Thus, very little is known about the function of Trxs in this cellular compartment. Previously, we studied the intracellular localization of PsTrxo1 and confirmed its presence in mitochondria and, interestingly, in the nucleus under standard growth conditions. In investigating the nuclear function of PsTrxo1 we identified proliferati…

0106 biological sciences0301 basic medicineTFs transcription factorsOverexpressionBiologíaBiFC bimolecular fluorescence complementationClinical BiochemistryCell Culture TechniquesTobacco BY-2 cells01 natural sciencesBiochemistryTBY-2 tobacco bright yellow-2DTT 14-dithiothreitolBimolecular fluorescence complementationThioredoxinsGene Expression Regulation PlantTrx thioredoxinlcsh:QH301-705.5GFP green fluorescent proteinlcsh:R5-920biologyProliferating cell nuclear antigen (PCNA)Cell cycleGlutathione3. Good healthCell biologyMitochondriaNTR NADPH thioredoxin reductaseProtein TransportDEM diethyl maleateRT-qPCR Reverse transcription quantitative polymerase chain reactionThioredoxinlcsh:Medicine (General)Oxidation-ReductionAMS 4-acetamido-4-maleimidylstilbene-22-disulfonic acidResearch PaperPCNA proliferating cell nuclear antigenOex overexpressingCell cycleNucleusThioredoxin o103 medical and health sciencesROS reactive oxygen speciesDownregulation and upregulationProliferating Cell Nuclear AntigenTobaccoDAPI 46-diamidine-2-phenylindolmCBM monochlorobimaneCellular compartmentCell NucleusCell growthOrganic ChemistryBotánicaPeasMolecular biologyYFP yellow fluorescent proteinProliferating cell nuclear antigenTBS Tris-buffered salineOD optical density030104 developmental biologylcsh:Biology (General)Cell cultureRNA reactive nitrogen speciesbiology.proteinPrx peroxiredoxinBSA bovine serum albumin010606 plant biology & botanyRedox biology

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The In Vitro Interaction of 12-Oxophytodienoic Acid and Related Conjugated Carbonyl Compounds with Thiol Antioxidants

2021

α,β-unsaturated carbonyls interfere with numerous plant physiological processes. One mechanism of action is their reactivity toward thiols of metabolites like cysteine and glutathione (GSH). This work aimed at better understanding these interactions. Both 12-oxophytodienoic acid (12-OPDA) and abscisic acid (ABA) conjugated with cysteine. It was found that the reactivity of α,β-unsaturated carbonyls with GSH followed the sequence trans-2-hexenal &lt

0106 biological sciences0301 basic medicinecysteine covalent modification570Isomerase activityArabidopsis thalianaArabidopsislcsh:QR1-50201 natural sciencesBiochemistryArticleAntioxidantslcsh:Microbiology03 medical and health scienceschemistry.chemical_compoundThioredoxinsPlant Growth RegulatorsmedicineCysteineSulfhydryl CompoundsMolecular BiologyCyclophilinchemistry.chemical_classificationChemistry<i>Arabidopsis thaliana</i>peroxiredoxinGlutathionethioredoxinphytohormones030104 developmental biologyMechanism of actionBiochemistryprotein–ligand interactioncyclophilinThiolFatty Acids Unsaturatedmedicine.symptomThioredoxinPeroxiredoxinthiol antioxidants010606 plant biology & botanyCysteineBiomolecules

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Deficiency in the Phosphorylated Pathway of Serine Biosynthesis Perturbs Sulfur Assimilation.

2018

Although the plant Phosphorylated Pathway of l-Ser Biosynthesis (PPSB) is essential for embryo and pollen development, and for root growth, its metabolic implications have not been fully investigated. A transcriptomics analysis of Arabidopsis (Arabidopsis thaliana) PPSB-deficient mutants at night, when PPSB activity is thought to be more important, suggested interaction with the sulfate assimilation process. Because sulfate assimilation occurs mainly in the light, we also investigated it in PPSB-deficient lines in the day. Key genes in the sulfate starvation response, such as the adenosine 5′phosphosulfate reductase genes, along with sulfate transporters, especially those involved in sulfat…

0106 biological sciences570PhysiologyArabidopsisPlant Science01 natural sciencesSerinechemistry.chemical_compoundSulfur assimilationBiosynthesisArabidopsisGeneticsSerineSulfate assimilationPhosphorylationbiologyWild typeAssimilation (biology)GlutathioneArticlesbiology.organism_classificationchemistryBiochemistryTranscriptomeOxidation-ReductionSulfur010606 plant biology & botanySignal TransductionPlant physiology

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