Search results for "Article Addendum"

showing 5 items of 15 documents

Arbuscular mycorrhiza - studies on the geosiphon symbiosis lead to the characterization of the first glomeromycotan sugar transporter

2007

Article Addendum ; International audience; The intimate arbuscular mycorrhiza (AM) association between roots and obligate symbiotic Glomeromycota (‘AM fungi’) ‘feeds’ about 80% of land plants. AM forming fungi supply land plants with inorganic nutrients and have an enormous impact on terrestrial ecosystems. In return, AM fungi obtain up to 20% of the plant‑fixed CO2, putatively as monosaccharides. In a recent work we have reported the characterization of the first glomeromycotan monosaccharide transporter, GpMST1, and its gene sequence. We discuss that AM fungi might take up sugars deriving from plant cell‑wall material. The GpMST1 sequence delivers valuable data for the isolation of orthol…

ObligatebiologyEcologyGEOSIPHON SYMBIOSISfungiARBUSCULAR MYCORRHIZAPlant ScienceHEXOSESbiology.organism_classificationMONOSACCHARIDE TRANSPORTERArticle AddendumGlomeromycotaArbuscular mycorrhiza[SDV.GEN.GPL]Life Sciences [q-bio]/Genetics/Plants geneticsNutrientSymbiosis[SDV.GEN.GPL] Life Sciences [q-bio]/Genetics/Plants geneticsGeosiphonBotanySugar transporterGene sequence
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A critical role of plastidial glycolytic Glyceraldehyde-3-Phosphate Dehydrogenase in the control of plant metabolism and development

2009

3 páginas.

PlastidArabidopsisDehydrogenasePlant ScienceSerine biosynthesisGenes PlantPlant RootsGene Expression Regulation EnzymologicSerinechemistry.chemical_compoundBiosynthesisGene Expression Regulation PlantSerineGlycolysisRNA MessengerPlastidsAmino AcidsPhosphorylationPhylogenyGlyceraldehyde 3-phosphate dehydrogenasebiologyArabidopsis ProteinsGAPDHGenetic Complementation TestGlyceraldehyde-3-Phosphate DehydrogenasesMetabolismLipid MetabolismArticle AddendumPlant LeavesProtein TransportCytosolMetabolic pathwayPhenotypeBiochemistrychemistryMutationbiology.proteinCarbohydrate MetabolismGlyceraldehyde-3-Phosphate Dehydrogenase (Phosphorylating)GlycolysisResearch Article
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Interactions between abscisic acid and plastidial glycolysis in Arabidopsis

2011

[EN] The phytohormone abscisic acid (ABA) controls the development of plants and plays a crucial role in their response to adverse environmental conditions like salt and water stress.1-3 Complex interactions between ABA and sugar signal transduction pathways have been shown. However, the role played by glycolysis in these interactions is not known. In the associated study,4 we investigated the interactions between plastidial glycolytic glyceraldehyde-3-phosphate dehydrogenase (GAPCp) and ABA signal transduction in Arabidopsis. We followed physiological, genetic and genomic approaches to understand the processes and mechanisms underlying the ABAglycolysis interactions. Our results indicated …

PlastidArabidopsisPlant Sciencechemistry.chemical_compoundAmino acid homeostasisArabidopsisTranscriptional regulationBIOQUIMICA Y BIOLOGIA MOLECULARHomeostasisPlastidsAmino AcidsTranscription factorAbscisic acidGlyceraldehyde 3-phosphate dehydrogenasebiologyArabidopsis Proteinsorganic chemicalsfungiGlyceraldehyde-3-Phosphate Dehydrogenasesfood and beveragesbiology.organism_classificationArticle AddendumGAPCpSugar-ABA interactionschemistryBiochemistryMutationABA signal transductionbiology.proteinCarbohydrate MetabolismGlyceraldehyde- 3-phosphate dehydrogenaseSignal transductionSugar signal transductionGlycolysisAbscisic AcidSignal Transduction
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Ni2+ toxicity in rice: effect on membrane functionality and plant water content.

2007

The heavy metal nickel is an essential mineral trace nutrient found at low concentrations in most natural soils. However, it may reach toxic levels in certain areas and affect a number of biochemical and physiological processes in plants. Wilting and leaf necrosis have been described as typical visible symptoms of Ni(2+) toxicity. The plasma membrane (PM) of root cells constitutes the first barrier for the entry of heavy metals but also a target of their toxic action. This work studies the relationship between disturbances of membrane functionality and the development of the typical symptoms of Ni(2+) toxicity. Rice plants (Oryza sativa L. cv. Bahia) grown in nutrient medium containing 0.5m…

Stomatal conductanceCell Membrane PermeabilityMembrane permeabilityPhysiologyChemistryWiltingfood and beveragesWaterOryzaPlant ScienceMembrane PotentialsArticle AddendumHorticultureNutrientNickelShootToxicityBotanyGeneticsWater contentTranspirationPlant physiology and biochemistry : PPB
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Organization into higher-ordered ring structures counteracts membrane binding of IM30, a protein associated with inner membranes in chloroplasts and …

2017

ABSTRACT PspA, IM30 (Vipp1) and LiaH, which all belong to the PspA/IM30 protein family, form high molecular weight oligomeric structures. For all proteins membrane binding and protection of the membrane structure and integrity has been shown or postulated. Here we discuss the possible membrane chaperoning activity of PspA, IM30 and LiaH and propose that larger oligomeric structures bind to stressed membrane regions, followed by oligomer disassembly and membrane stabilization by protein monomers or smaller/different oligomeric scaffolds.

YjfJPspAmembrane stressLiaHIM30oligomerVipp1Article Addendummembrane chaperonePspA/IM30 familyCommunicative & Integrative Biology
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