Search results for "Apoplast"

showing 6 items of 6 documents

Two ectomycorrhizal truffles, Tuber melanosporum and T. aestivum , endophytically colonise roots of non‐ectomycorrhizal plants in natural environments

2020

International audience; Serendipitous findings and studies on Tuber species suggest that some ectomycorrhizal fungi, beyond their complex interaction with ectomycorrhizal hosts, also colonise roots of nonectomycorrhizal plants in a loose way called endophytism. Here, we investigate endophytism of T. melanosporum and T. aestivum . We visualised endophytic T. melanosporum hyphae by fluorescent in situ hybridisation on nonectomycorrhizal plants. For the two Tuber species, microsatellite genotyping investigated the endophytic presence of the individuals whose mating produced nearby ascocarps. We quantified the expression of four T. aestivum genes in roots of endophyted, non‐ectomycorrhizal plan…

0106 biological sciences0301 basic medicineHyphaPlant rootsPhysiology[SDV]Life Sciences [q-bio]fungifood and beveragesPlant ScienceEnvironmentBiology01 natural sciencesApoplastSpore03 medical and health sciences030104 developmental biologyAscomycotaMeiosisTuber melanosporumMycorrhizaeBotany[SDE]Environmental SciencesLIVING STATUSMating010606 plant biology & botany
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Water recycling in leaves of Lithops (Aizoaceae)

2016

Lithops plants consist of a pair of succulent leaves inserted on a short stem; each growing season young leaves develop in a cavity formed between the older pair. Young leaves can take up water from the older pair allowing the plant to maintain growth and leaf expansion even without external supply of water. Recycling water between vegetative organs is one of the possible adaptation strategies of plants under drought stress, but it had never been demonstrated experimentally in Lithops. The methodology used to verify the existence of water redistribution from old leaves to young leaves was fluorescence microscopy, using two dyes to follow the water pathway inside the plant: Sulforhodamine G …

0106 biological sciencesDrought stressGrowing seasonPlant Science010603 evolutionary biology01 natural sciencesfluorescent tracerBotanyapoplastic pathwaysymplastic pathwaySettore BIO/04 - Fisiologia Vegetalesucculent plantEcology Evolution Behavior and SystematicsLeaf expansionShort stembiologyfungidrought strefood and beveragesLithopsbiology.organism_classificationAdaptation strategiesApoplastAizoaceaeSettore BIO/03 - Botanica Ambientale E Applicata010606 plant biology & botany
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Dynamic changes in the subcellular distribution of the tobacco ROS-producing enzyme RBOHD in response to the oomycete elicitor cryptogein.

2014

Highlight text The oomycete elicitor cryptogein triggers the relocation of RBOHD from intracellular compartments to the plasma membrane in tobacco cells. This suggests that intracellular trafficking is a potential determinant of RBOHD activity.

DETERGENT-RESISTANT MEMBRANESPhysiologyNicotiana tabacum[SDV]Life Sciences [q-bio]BY-2 cellsPlant SciencecryptogeinCell membranechemistry.chemical_compoundAPOPLASTIC OXIDATIVE BURSTCELL-SURFACEDISEASE RESISTANCE[MATH]Mathematics [math]Plant Proteinsreactive oxygen speciesFungal proteinNADPH oxidaseMicroscopy Confocalbiologyfood and beveragesElicitorCell biologymedicine.anatomical_structureBiochemistryprotein trafficking.[SDE]Environmental SciencessymbolsNADPH OXIDASE RBOHDprotein traffickingResearch PaperPhytophthoraCycloheximiderespiratory burst oxidase homolog D (RBOHD)Real-Time Polymerase Chain ReactionFungal Proteinssymbols.namesakeNICOTIANA-BENTHAMIANAMicroscopy Electron TransmissionTobaccomedicine[SDV.BV]Life Sciences [q-bio]/Vegetal Biology[INFO]Computer Science [cs]NITRIC-OXIDENicotiana tabacumCell MembraneNADPH OxidasesGolgi apparatusbiology.organism_classificationSubcellular localizationLIPID RAFTSchemistryPLASMA-MEMBRANEbiology.proteinPLANT DEFENSE
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The Synapse-Like Interaction between Chloroplast, dictyosome, and Other Cell Compartments during Increased Ethylene Production in Leaves of Rye (Seca…

2000

Rye (Secale cereale L.) plants were treated with an ethylene releaser ethephon (2-chloroethylphosphonic acid) in concentration of 4×10−2 M. We studied electron microscopically, if and how chloroplasts interact with well-documented sites of ethylene production/binding, i.e., with endoplasmic reticulum, dictyosomes, mitochondria, plasma membrane, and tonoplast. During the sharp increase of ethylene synthesis in mesophyll cells of rye leaves, the direct local continguity of chloroplast envelope or envelope protrusions with the above mentioned cell compartments was typical. Moreover, a large number and diversity of versatile chloroplast-dictyosome associations were conspicuous, in which both th…

SecalePhysiologyEndoplasmic reticulumfood and beveragesPlant ScienceVacuoleGolgi apparatusBiologybiology.organism_classificationChloroplast membraneApoplastChloroplastVesicular transport proteinsymbols.namesakeBiochemistryBiophysicssymbolsPhotosynthetica
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Impact of Plasmopara viticola on starch metabolism and stomachal functions in grapevine leaves

2011

The grapevine downy mildew affects leaves and young berries and can affect the harvest quality and quantity. The causal agent is the obligate biotroph oomycete Plasmopara viticola that induces severe physiological alterations in infected leaves. One is the abnormal accumulation of starch in oil spots, the characteristic symptoms of the disease. Another is a deregulation of stomatal movements. Stomata, natural openings on the leaf surface allowing gas exchanges between the plant and the atmosphere, stay abnormally open during the night and do no longer close upon water stress or ABA treatment in infected leaves. This thesis is divided into two chapters that aim to i) explain the origin and m…

SucresPlasmopara viticola[SDV.SA] Life Sciences [q-bio]/Agricultural sciencesStomatesVitis viniferaStarchInvertaseApoplastic fluidsSugarsAmidonStomataFluides apoplastiques
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Toward the Identification of Two Glycoproteins Involved in the Stomatal Deregulation of Downy Mildew–Infected Grapevine Leaves

2015

SPE Pôle IPM UB; International audience; Stomata remain abnormally opened and unresponsive to abscisic acid in grapevine leaves infected by downy mildew. This deregulation occurs from 3 days post inoculation and increases concomitantly with leaf colonization by the pathogen. Using epidermal peels, we demonstrated that the active compound involved in this deregulation is located in the apoplast. Biochemical assays showed that the active compound present in the apoplastic fluids isolated from Plasmopara viticola infected grapevine leaves (IAF) is a CysCys bridge-independent, thermostable and glycosylated protein. Fractionation guided assays based on chromatography / stomatal response and prot…

[SDE] Environmental SciencesProteomicsPhysiology[SDV]Life Sciences [q-bio]stomataMolecular Sequence DataPlant EpidermisFungal ProteinsCell wallPlasmoparaPlasmopara viticolachemistry.chemical_compoundCell WallBotany[SDV.BV]Life Sciences [q-bio]/Vegetal Biology[SDV.BV] Life Sciences [q-bio]/Vegetal BiologyComputer SimulationVitisAmino Acid SequencePathogenAbscisic acidPhylogenyproteomicGlycoproteinsPlant DiseasesPlant Proteinsplant-microbe interactionFungal proteinSequence Homology Amino AcidbiologyfungiPlant Stomatafood and beveragesGeneral MedicineChromatography Ion Exchangebiology.organism_classificationApoplast[SDV] Life Sciences [q-bio]Plant LeavesOomycetesBiochemistrychemistryVitis viniferaHost-Pathogen InteractionsPlant Stomata[SDE]Environmental SciencesDowny mildewguard cellAgronomy and Crop ScienceMolecular Plant-Microbe Interactions®
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