Search results for "Mycorrhiza"

showing 10 items of 284 documents

A mycorrhiza helper bacterium enhances ectomycorrhizal and endomycorrhizal symbiosis of Australian Acacia species.

2003

The aims of this study were to test the effects of a mycorrhiza helper bacterium (MHB), Pseudomonas monteilii strain HR13 on the mycorrhization of (1) an Australian Acacia, A. holosericea, by several ectomycorrhizal fungi or one endomycorrhizal fungus Glomus intraradices, and (2) several Australian Acacia species by Pisolithus alba strain IR100 under glasshouse conditions. Bacterial inoculant HR13 significantly promoted ectomycorrhizal colonization for all the Acacia species, from 45.8% ( A. mangium) to 70.3% ( A. auriculiformis). A stimulating effect of HR13 on the ectomycorrhizal establishment was recorded with all the fungal isolates (strains of Pisolithus and Scleroderma). The same effe…

0106 biological sciencesHyphaAcaciaPlant Science01 natural sciencesPisolithusSymbiosisMycorrhizaePseudomonasBotanyGeneticsMycorrhizaPhycomycetesSymbiosisMolecular BiologyEcology Evolution Behavior and SystematicsScleroderma (fungus)ComputingMilieux_MISCELLANEOUS[SDV.MP.MYC]Life Sciences [q-bio]/Microbiology and Parasitology/MycologybiologyAcacia04 agricultural and veterinary sciencesGeneral Medicine15. Life on landbiology.organism_classification[SDV.MP.MYC] Life Sciences [q-bio]/Microbiology and Parasitology/MycologyEctomycorrhiza040103 agronomy & agriculture0401 agriculture forestry and fisheries010606 plant biology & botanyMycorrhiza
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Priming: getting ready for battle

2006

International audience; Infection of plants by necrotizing pathogens or colonization of plant roots with certain beneficial microbes causes the induction of a unique physiological state called “priming.” The primed state can also be induced by treatment of plants with various natural and synthetic compounds. Primed plants display either faster, stronger, or both activation of the various cellular defense responses that are induced following attack by either pathogens or insects or in response to abiotic stress. Although the phenomenon has been known for decades, most progress in our understanding of priming has been made over the past few years. Here, we summarize the current knowledge of p…

0106 biological sciencesInsectaPhysiology[SDV]Life Sciences [q-bio]beta-Aminobutyric acidPriming (agriculture)01 natural sciencesPlant Physiological Phenomenachemistry.chemical_compoundsalicylic acid.ethylenePlant biology (Botany)0303 health sciencesAminobutyratesJasmonic acidfood and beveragesGeneral MedicinePlantsLife sciencesmycorrhizal fungimycorhizeBiologieSignal Transductionacide jasmoniquesalicylic acidBiologyMicrobiology03 medical and health sciencesβ-aminobutyric acidMycorrhizal fungiAnimalsβ-aminobutyric acid;bacterial lipopolysaccharides;ethylene;jasmonic acid;mycorrhizal fungi;salicylic acid.Plant Physiological Phenomena030304 developmental biologyacide aminobutyriquePlant rootsAbiotic stressjasmonic acidfungiEthylenesCellular defenseImmunity Innateß-aminobutyric acidbacterial lipopolysaccharideschemistryéthylènefungiAgronomy and Crop Science010606 plant biology & botanyMolecular Plant-Microbe Interactions
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Protein actors sustaining arbuscular mycorrhizal symbiosis: underground artists break the silence

2013

'Summary' 26 I. 'Casting for a scenario' 26 II. 'Nominees for a preliminary role' 27 III. 'Nominees for a leading role' 32 IV. 'Future artists' 37   'Acknowledgements' 38   References 38 Summary The roots of most land plants can enter a relationship with soil-borne fungi belonging to the phylum Glomeromycota. This symbiosis with arbuscular mycorrhizal (AM) fungi belongs to the so-called biotrophic interactions, involving the intracellular accommodation of a microorganism by a living plant cell without causing the death of the host. Although profiling technologies have generated an increasing depository of plant and fungal proteins eligible for sustaining AM accommodation and functioning, a …

0106 biological sciencesLASER MICRODISSECTIONPhysiologycarbon (C)phosphorus (P)[SDV]Life Sciences [q-bio]Plant Science01 natural sciencesPlant RootsGlomeromycotaMEDICAGO-TRUNCATULA ROOTSRNA interferenceMycorrhizaeLOTUS-JAPONICUSPlastidsMycorrhizaFUNGUS GLOMUS-INTRARADICESPlant ProteinsGENE-EXPRESSIONGenetics0303 health sciencesGene knockdownFungal proteinPHOSPHATE TRANSPORTERarbuscular mycorrhizaCADMIUM STRESS ALLEVIATIONfood and beveragesSTRIGOLACTONE BIOSYNTHESISArbuscular mycorrhizaEPIDERMAL-CELLSProtein Transportmembranes[SDE]Environmental SciencesSignal TransductionINTRACELLULAR ACCOMMODATIONHyphaeBiologybiotrophyPhosphatesFungal Proteins03 medical and health sciencesSymbiosisBotanyGene silencing[SDV.BV]Life Sciences [q-bio]/Vegetal BiologyGlomeromycotaSymbiosis030304 developmental biologyfungi15. Life on landbiology.organism_classificationCarbonsilencing010606 plant biology & botany
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Temporal turnover of the soil microbiome composition is guild-specific.

2021

Although spatial and temporal variation are both important components structuring microbial communities, the exact quantification of temporal turnover rates of fungi and bacteria has not been performed to date. In this study, we utilised repeated resampling of bacterial and fungal communities at specific locations across multiple years to describe their patterns and rates of temporal turnover. Our results show that microbial communities undergo temporal change at a rate of 0.010-0.025 per year (in units of Sorensen similarity), and the change in soil is slightly faster in fungi than in bacteria, with bacterial communities changing more rapidly in litter than soil. Importantly, temporal deve…

0106 biological sciencesLITTERBACTERIALSPATIAL VARIABILITYDIVERSITYBiologyFUNGAL COMMUNITIES010603 evolutionary biology01 natural sciences03 medical and health sciencesforestSoilTemporal changeMicrobiomeBacterial phylabacteriaEcology Evolution Behavior and SystematicsSCALESoil Microbiology030304 developmental biology0303 health sciencesNITROGEN DEPOSITIONECTOMYCORRHIZAL FUNGIEcologyMicrobiotaFungi15. Life on landMicrobial population biologyOAKGuild1181 Ecology evolutionary biologyLittertemporal turnovercommunity assemblyRESPONSESMycobiomeEcology lettersREFERENCES
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Nitrogen Type and Availability Drive Mycorrhizal Effects on Wheat Performance, Nitrogen Uptake and Recovery, and Production Sustainability

2020

Plant performance is strongly dependent on nitrogen (N), and thus increasing N nutrition is of great relevance for the productivity of agroecosystems. The effects of arbuscular mycorrhizal (AM) fungi on plant N acquisition are debated because contradictory results have been reported. Using 15N-labeled fertilizers as a tracer, we evaluated the effects of AM fungi on N uptake and recovery from mineral or organic sources in durum wheat. Under sufficient N availability, AM fungi had no effects on plant biomass but increased N concentrations in plant tissue, plant N uptake, and total N recovered from the fertilizer. In N-deficient soil, AM fungi led to decreased aboveground biomass, which sugges…

0106 biological sciencesLimiting factorAgroecosystemorganic nitrogenchemistry.chemical_elementBiomassarbuscular mycorrhizal fungiPlant Scienceengineering.materiallcsh:Plant culture01 natural sciencesarbuscular mycorrhizal (AM) symbiosislcsh:SB1-1110Original Researchsoil nitrogen (N) sourcefungifood and beverages04 agricultural and veterinary sciencessoil nitrogen (N) availabilityNitrogenPlant tissuemineral nitrogennitrogen uptakeSettore AGR/02 - Agronomia E Coltivazioni ErbaceechemistryProductivity (ecology)Agronomy040103 agronomy & agricultureengineering0401 agriculture forestry and fisheriesFertilizerArbuscular mycorrhizal fungi AM symbiosis Soil N Source Soil N availability Organic nitrogen Mineral nitrogen nitrogen uptake 15 N Fertilizer Recovery15N fertilizer recoveryArbuscular mycorrhizal010606 plant biology & botanyFrontiers in Plant Science
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AM fungal exudates activate MAP kinases in plant cells in dependence from cytosolic Ca2+ increase

2011

International audience; The molecular dialogue occurring prior to direct contact between the fungal and plant partners of arbuscular-mycorrhizal (AM) symbioses begins with the release of fungal elicitors, so far only partially identified chemically, which can activate specific signaling pathways in the host plant. We show here that the activation of MAPK is also induced by exudates of germinating spores of Gigaspora margarita in cultured cells of the non-leguminous species tobacco (Nicotiana tabacum), as well as in those of the model legume Lotus japonicus. MAPK activity peaked about 15 min after the exposure of the host cells to the fungal exudates (FE). FE were also responsible for a rapi…

0106 biological sciencesMAPK/ERK pathwayTime FactorsMAP Kinase Signaling SystemPhysiologyNicotiana tabacumLotus japonicusPlant ScienceComplex MixturesBiology01 natural sciences03 medical and health sciencesPlant CellsTobaccoBotanyGenetics[SDV.BV]Life Sciences [q-bio]/Vegetal BiologyGlomeromycotaSymbiosisNicotiana plumbaginifoliaPlant Proteins030304 developmental biologyMitogen-Activated Protein Kinase Kinasesarbuscular-mycorrhizal fungi0303 health sciencesdiffusible factorcalciumKinasefungiArbuscular-mycorrhizal fungi; Signaling; Diffusible factor; MAPK; Calciumfood and beveragesSpores FungalPlant cellbiology.organism_classificationMAPKsym pathwayCell biologyCytosolCell cultureLotus[SDE.BE]Environmental Sciences/Biodiversity and Ecologysignaling010606 plant biology & botanyPlant Physiology and Biochemistry
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Spatial monitoring of gene activity in extraradical and intraradical developmental stages of arbuscular mycorrhizal fungi by direct fluorescent in si…

2008

International audience; Gene expression profiling based on tissue extracts gives only limited information about genes associated with complex developmental processes such as those implicated in fungal interactions with plant roots during arbuscular mycorrhiza development and function. To overcome this drawback, a direct fluorescent in situ RT-PCR methodology was developed for spatial mapping of gene expression in different presymbiotic and symbiotic structures of an arbuscular mycorrhizal fungus. Transcript detection was optimized by targeting the LSU rRNA gene of Glomus intraradices and monitoring expression of a stearoyl-CoA-desaturase gene that is consistently expressed at high levels in…

0106 biological sciencesMYCORHIZES A ARBUSCULESGENE EXPRESSIONHyphaGLOMUS INTRARADICESDIRECT FLUORESCENT IN SITU RT-PCR01 natural sciencesMicrobiologyPlant RootsARBUSCULAR MYCORRHIZAL FUNGIFungal ProteinsSUPEROXIDE DISMUTASE03 medical and health sciencesFungal StructuresGene Expression Regulation FungalMycorrhizaeBotanyGene expressionGeneticsMedicagoCONFOCAL MICROSCOPYGene030304 developmental biologyDNA PrimersFluorescent DyesPeptidylprolyl isomerase0303 health sciences[SDV.GEN]Life Sciences [q-bio]/GeneticsMicroscopy ConfocalbiologyPEPTIDYLPROPYL ISOMERASEReverse Transcriptase Polymerase Chain ReactionGene Expression ProfilingfungiSYMBIOSISGene Expression Regulation DevelopmentalPeptidylprolyl Isomerasebiology.organism_classificationMedicago truncatulaCell biologyArbuscular mycorrhizaGene expression profilingSTEAROYL-CoA-DESATURASEXanthenesMEDICAGO TRUNCATULAStearoyl-CoA Desaturase010606 plant biology & botany
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Fungal Diversity in the Mediterranean Area

2020

The Special Issue entitled “Fungal Diversity in the Mediterranean Area” aimed at highlighting the role of various organisms in the Mediterranean habitat. The role of fungi at the root and phyllosphere level; the biodiversity in small island territories and the sea; rare forms of fungi never previously found; the commercial, food, and therapeutic value of some ascomycetes and basidiomycetes; the diversity related to fungi associated with galls on plants; and the important role of culture collection for the ex situ conservation of fungal biodiversity are the topics dealt with in this Special Issue.

0106 biological sciencesMediterranean climateBiodiversitybioprospectingmycorrhizaBiology010603 evolutionary biology01 natural sciencesMediterranean forestlcsh:QH301-705.5Marine fungiNature and Landscape ConservationBioprospectingGenetic diversityEcologyEcology010604 marine biology & hydrobiologyEcological Modelingmarine fungifungiEx situ conservationAgricultural and Biological Sciences (miscellaneous)medicinal mushroomfungal diversityHabitatlcsh:Biology (General)PhyllosphereDiversity
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Molecular evidence supports simultaneous association of the achlorophyllous orchid Chamaegastrodia inverta with ectomycorrhizal Ceratobasidiaceae and…

2020

Abstract Background Achlorophyllous orchids are mycoheterotrophic plants, which lack photosynthetic ability and associate with fungi to acquire carbon from different environmental sources. In tropical latitudes, achlorophyllous forest orchids show a preference to establish mycorrhizal relationships with saprotrophic fungi. However, a few of them have been recently found to associate with ectomycorrhizal fungi and there is still much to be learned about the identity of fungi associated with tropical orchids. The present study focused on mycorrhizal diversity in the achlorophyllous orchid C. inverta, an endangered species, which is endemic to southern China. The aim of this work was to identi…

0106 biological sciencesMicrobiology (medical)ChinaAchlorophyllous orchidslcsh:QR1-502HyphaeCeratobasidiaceaePlant-fungus interactions01 natural sciencesMicrobiologyPlant Rootslcsh:Microbiology03 medical and health sciencesOrchid mycorrhizaSymbiosisAscomycotaMycologyOrchid mycorrhizaMycorrhizaeBotanyEctomycorrhizal fungiRussulaDNA FungalOrchidaceaeSymbiosisMyceliumPhylogeny030304 developmental biology0303 health sciencesbiologySettore BIO/02 - Botanica SistematicaBasidiomycotaEndangered SpeciesCeratobasidiaceaeChaetomiumbiology.organism_classificationRussulaMycoheterotrophySeedlingsAchlorophyllous orchids Ceratobasidiaceae Ectomycorrhizal fungi Endangered species Orchid mycorrhiza Plant-fungus interactions Mycoheterotrophy RussulaSettore BIO/03 - Botanica Ambientale E ApplicataRussulaceae010606 plant biology & botanyResearch ArticleBMC Microbiology
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Local and systemic mycorrhiza-induced protection against the ectoparasitic nematode Xiphinema index involves priming of defence gene responses in gra…

2012

International audience; The ectoparasitic dagger nematode (Xiphinema index), vector of Grapevine fanleaf virus (GFLV), provokes gall formation and can cause severe damage to the root system of grapevines. Mycorrhiza formation by Glomus (syn. Rhizophagus) intraradices BEG141 reduced both gall formation on roots of the grapevine rootstock SO4 (Vitis berlandierixV. riparia) and nematode number in the surrounding soil. Suppressive effects increased with time and were greater when the nematode was post-inoculated rather than co-inoculated with the arbuscular mycorrhizal (AM) fungus. Using a split-root system, decreased X. index development was shown in mycorrhizal and non-mycorrhizal parts of my…

0106 biological sciencesNematodaPhysiology[SDV]Life Sciences [q-bio]NepovirusPlant Science01 natural sciencesXiphinema indexPlant RootsGlomeromycota03 medical and health sciencesGene Expression Regulation PlantMycorrhizaeBotanyGallAnimalsVitisMycorrhizaGlomeromycotaGlomus030304 developmental biologyPlant DiseasesPlant Proteins2. Zero hunger0303 health sciencesbiologyarbuscular mycorrhizaGrapevine fanleaf virussplit-root systembiology.organism_classificationgrapevineNematode[SDE]Environmental Sciencesbioprotectionxiphinema indexdefence gene expressionRootstock010606 plant biology & botanyResearch Paper
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