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S U L P S A N Root-associated fungal microbiota of nonmycorrhizal P Arabis alpina and its contribution to plant phosphorus nutrition Y R A T N E M JulianaAlmarioa,b,1,GangaJeenaa,b,JörgWunderc,GregorLangena,b,AlgaZuccaroa,b,GeorgeCouplandb,c, M O andMarcelBuchera,b,2 C E E S aBotanicalInstitute,CologneBiocenter,UniversityofCologne,50674Cologne,Germany;bClusterofExcellenceonPlantSciences,UniversityofCologne, 50674Cologne,Germany;andcDepartmentofPlantDevelopmentalBiology,MaxPlanckInstituteforPlantBreedingResearch,50829Cologne,Germany EditedbyLuisHerrera-Estrella,CenterforResearchandAdvancedStudies,Irapuato,Guanajuato,Mexico,andapprovedSeptember1,2017(receivedfor reviewJune9,2017) Most land plants live in association with arbuscular mycorrhizal to account for these cross-kingdom interactions to be complete. (AM)fungiandrelyonthissymbiosistoscavengephosphorus(P) Here, we integrate these concepts and study the role of root- fromsoil.Theabilitytoestablishthispartnershiphasbeenlostin associatedfungiotherthanAMinplantPnutrition. someplantlineagesliketheBrassicaceae,whichraisesthequestion In some plant lineages, AM co-occurs with other mycorrhizal ofwhatalternativenutritionstrategiessuchplantshavetogrowin symbioseslikeectomycorrhiza (woodyplants),orchid mycorrhiza P-impoverishedsoils. To understandthecontribution ofplant–micro- (orchids), andericoid mycorrhiza (Ericaceae)(10).These associ- biotainteractions,westudiedtheroot-associatedfungalmicrobiome ations can also promote plant nutrition; however, they have not of Arabis alpina (Brassicaceae) with the hypothesis that some of its beendescribedinBrassicaceae.Endophyticmicrobescanpromote componentscanpromoteplantPacquisition.Usingampliconsequenc- plantPacquisitionbydifferentprocessesincludingPsolubilization ingofthefungalinternaltranscribedspacer2,westudiedtherootand and mineralization (11) or transfer of P in the form of soluble rhizosphere fungal communities of A. alpina growing under natural orthophosphate. P transfer to their hosts was considered a hall- andcontrolledconditionsincludinglow-Psoilsandidentifiedasetof mark of mycorrhizal fungi until recently. Two studies on binary 15fungaltaxaconsistentlydetectedinitsroots.Thiscohortincludeda root–fungusinteractionsshowedthattwoendophytes—theAsco- HelotialestaxonexhibitinghighabundanceinrootsofwildA.alpina mycete Colletotrichum tofieldiae (12) and the Basidiomycete growinginanextremelyP-limitedsoil.Consequently,weisolatedand Serendipita indica (syn. Piriformospora indica) (13)—are able subsequentlyreintroducedaspecimenfromthistaxonintoitsnative totransferPtotheirnonmycorrhizalhostArabidopsisthaliana, P-poorsoilinwhichitimprovedplantgrowthandPuptake.Thefun- promotingitsgrowthunderlow-Pconditions.S.indicawasalso gusexhibitedmycorrhiza-liketraitsincludingcolonizationoftheroot demonstratedtoparticipateinPuptakeofmaizeplantsdepending endosphereandPtransfertotheplant.Genomeanalysisrevealeda on the expression of a fungal high-affinity phosphate transporter linkbetweenitsendophyticlifestyleandtheexpansionofitsrepertoire (14).ThesestudiesprovidedproofofconceptforPtransferfrom ofcarbohydrate-activeenzymes.Wereportthediscoveryofaplant– fungi to nonmycorrhizal hosts; however, the ecological relevance fungus interaction facilitating the growth of a nonmycorrhizal of these interactions remains unclear as it is not known whether plantundernativeP-limited conditions, thus uncoveringa previ- theseendophytescanpromoteplantPuptakeundernativelow-P ouslyunderestimatedroleofrootfungalmicrobiotainPcycling. soil conditions, and only C. tofieldiae was shown to be a natural GY O Brassicaceae|microbiome|fungalendophyte|Helotiales|nutrient inhabitantofA.thalianaroots.Descriptiveandfunctionalstudies BIOL transfer NT Significance A L P Comparablewiththehumanmicrobiota,millionsofmicrobes Most terrestrial plants live in symbiosis with arbuscular my- colonizeplantsandformcomplexcommunitiesonplantsur- corrhizal (AM) fungi and rely on this association to scavenge facesandinplanttissues.Theinteractionsbetweentheplantand the macronutrient phosphorus (P) from soil. Arabis alpina itsmicrobiotarangefromparasitism (detrimentaltothehost) to thrivesinP-limitedalpinehabitats,although,likeallBrassica- mutualism(mutuallybeneficial),andtheiroutcomecanbepivotal ceaespecies,itlackstheabilitytoestablishanAMsymbiosis. for plant performance. Plant-associated microbes can influence By studying the fungal microbiota associated with A. alpina plant fitness by modulating plant growth, root architecture, nu- trient acquisition, or drought and disease resistance (1–3). Thus, rootsweuncovereditsassociationwithabeneficialHelotiales fungus capable of promoting plant growth and P uptake, the plant microbiota can be seen as an extension of the plant genome in the sense that it can increase the plant’s adaptation therebyfacilitatingplantadaptationtolow-Penvironments. capacity(4).Thisisillustratedbythearbuscularmycorrhizal(AM) Authorcontributions:J.A.,A.Z.,G.C.,andM.B.designedresearch;J.A.,G.J.,andJ.W. symbiosis established between land plants and Glomeromycota performedresearch;J.A.andG.J.contributednewreagents/analytictools;J.A.,G.J., fungi,whichisthoughttohavefacilitatedtheadaptationofplants andG.L.analyzeddata;andJ.A.andM.B.wrotethepaper. to a terrestrial life (5). It is estimated that 80% of the vascular Theauthorsdeclarenoconflictofinterest. plant species (6) receive phosphorus (P) and other nutritional ThisarticleisaPNASDirectSubmission. elementsfromthesefungiinexchangeforphotosynthates(7).The FreelyavailableonlinethroughthePNASopenaccessoption. ability to form an AM symbiosis has been lost independently in Datadeposition:ThesequencereportedinthispaperhasbeendepositedintheNational severalfloweringplantlineagesincludingtheBrassicaceaefamily CenterforBiotechnologyInformationunderBioprojectPRJNA386947andPRJNA378526. throughthelossofessentialsymbiosisgenesduringevolution(8). SeeCommentaryonpage11574. Given the beneficial effect of AM fungi on plant P uptake, the 1Presentaddress:DepartmentofPlantMicrobeInteractions,MaxPlanckInstitutefor question of whether nonmycorrhizal species thrive due to the PlantBreedingResearch,50829Cologne,Germany. exploitation of alternative P-mining strategies forms the basis of 2Towhomcorrespondenceshouldbeaddressed.Email:[email protected]. currentresearch(9).Inthecontextoftheplantholobiont,i.e.,the Thisarticlecontainssupportinginformationonlineatwww.pnas.org/lookup/suppl/doi:10. plantandallitsmicrobialpartners,modelsofplantnutritionneed 1073/pnas.1710455114/-/DCSupplemental. www.pnas.org/cgi/doi/10.1073/pnas.1710455114 PNAS | PublishedonlineOctober2,2017 | E9403–E9412 onthefungalmicrobiotaofnonmycorrhizalplantsareneededto four European A. alpina accessions (Fig. 1A and SI Appendix, improve our understanding of the ecological relevance of these Table S1) grown side by side at the Lautaret common garden interactionsforplantnutritionattheholobiontlevel. (GAR-Lau).Atharvesttime,theaccessionsdifferedinsizeand Although fungi represent a prominent part of the root micro- developmental stage (SI Appendix, Fig.S2D) but shared similar biotawheretheycanplayimportantrolesaspathogenicorbene- root and rhizosphere fungal communities with comparable di- ficialpartners,studiesofBrassicaceaespecieshavefocusedmainly versity(ANOVAP>0.05)(SIAppendix,Fig.S2B)andstructure, onbacterialcommunities(1,15–17).Thesestudieshaveincreased as observed in the principal coordinates analysis (PCoA) (SI our knowledge of how root bacterial communities are shaped by Appendix, Fig. S2A) and verified by permutational multivariate environmental,edaphic,andhost-relatedfactors.Expansionofthis analysis of variance (PERMANOVA) results (P > 0.05). This knowledgeto fungal communities iscrucialasstudieson themy- indicated that, under the assessed seminatural common garden corrhizalhostspeciespoplar(18),sugarcane(19),andAgave(20) conditions, host genetic variation fails to impact the root- suggest that fungal and bacterial root communities respond dif- associated fungal community in A. alpina. This contrasted with ferently to environmental cues. Microbiome studies focusing on studies in which a small but significant contribution of the host taxonomical description have shown that fungi detected in plant genotypetostructuringofbacterialrootmicrobiomeswasshown tissues are often phylogenetically related to described plant path- (1,15,26,27)inhostspeciesincludingA.alpina(16).Ourwork ogensorsaprotrophs(3,18).Comparativegenomicsanalyseshave suggests that, unlike bacterial communities, root-associated shownthatplantbeneficialendophyticlifestylescanemergefrom fungal communities are less or not at all affected by host geno- plant pathogenic or saprophytic fungal lineages through genome typic differences in A. alpina. However, we cannot exclude that modificationsofteninvolvingtheexpansionorcontractionofgene highwithin-genotypevariabilitymightbeshadingasmalleffect. families encoding carbohydrate active enzymes (CAZymes) in- volved in plant cell-wall degradation (21–23). Prediction of the Soil and Environmental Cues Shape A. alpina Root and Rhizosphere ecological role of fungal root endophytes is thus challenging and FungalCommunities.We next assessed how soil and environment- requiresmoresystematicstudiesassociatingendophyteisolation,in associated factors shape fungal communities inhabiting bulk soil, plantatesting,andgenomicinvestigation. theA.alpinarhizosphere,andtherootendosphere(Fig.1A).Un- Arabisalpina(Brassicaceae)isanonmycorrhizalperennialarctic- dercontrolledgreenhouseconditions(GrH)westudiedtheeffect alpine herb growing in harsh and rocky environments (24) in- of three soils (SI Appendix, Table S2) with different geographical cluding P-impoverished soils (this study). In recent years it has origins [Reckenholz (Rec) vs. Lautaret (Lau)] and P-fertilization emergedasamodelforecologicalanddevelopmentalstudies,and regimes [Reckenholz soils with amended nitrogen (N) and potas- its genome has recently been sequenced (25). The aim of the sium (K) (RecNK) vs. N, P, and K (RecNPK)]. on the fungal present study was to explore the root fungal microbiome of communitiesassociatedwithA.alpinaaccessionPajares(PM). A.alpinaanditscontributiontoplantPacquisition,followingthe Resultsshowedthatfungalalphadiversity(relatedtothenum- hypothesis that root-associated fungi other than AM fungi can ber of taxa per sample) estimated by the Shannon diversity in- promoteplantPuptakeundernaturalandcontrolledlow-Pcon- dexwashighlydeterminedbythecompartmenttype(P=2.10−10, ditions.WeusedIllumina-basedampliconsequencingofthefungal 70%ofvariance,SIAppendix,TableS3),withlowervaluesinroot taxonomical marker internal transcribed spacer 2 (ITS2) to de- relativetorhizosphereandbulksoilcompartments(ANOVAand scribethefungalmicrobiomeinA.alpinaroots(endosphere)and Tukey’s HSD, P < 0.05) (Fig. 1C), indicating the selection of a therhizosphere(soilzoneimmediatelysurroundingtheroot)under reducednumberoffungaltaxaenteringtheplantroots.Similarly, greenhouse,commongarden,andnaturalconditions.Microbiome comparingthestructureofthosefungalcommunities(taxapresent variabilityanalysisshowedthatrootfungalcommunitiesweremore and their relative abundances) by permutational multivariate robust in response to changing environments relative to the rhi- analysis of variance(PERMANOVA on Bray–Curtis dissimilar- zosphere assemblages, leading to the description of a set of ities) revealed that the major source of variation was the com- 15fungaltaxaconsistentlydetectedinA.alpinaroots.Withinthis partmenttype(P=10−4,29%ofvariance,SIAppendix,TableS3). cohort we identified a fungal taxon belonging to the Helotiales Althoughneitherthesoil’sgeographicalorigin(Reckenholzvs. order, exhibiting high abundance in the roots of wild A. alpina Lautaret)noritsP-fertilizationregime(ReckenholzsoilswithNK plantsgrowinginanextremelyP-limitedsoil.Successfulisolationof vs. NPK amendment) significantly impacted the overall fungal aspecimenfromthistaxonfromA.alpinaroots,followedbyits diversity (ANOVA, P > 0.05), they did affect the structure of reintroduction into the native P-limited soil after sterilization, fungal communities. The effect of the soil’s geographical origin promotedA.alpinagrowthandshootPaccumulation.Invitro (PERMANOVA,P=10−4,21%ofvariance)decreasedfromthe studiesfurtherdemonstratedthatthefungus’contributiontoplant bulksoil(67%ofvariance)overtherhizosphere(49%)totheroot growthinvolvestransferofinorganicphosphatetoitshost.Finally, compartment(30%),whereastheP-fertilizationeffectoverallwas fungalgenomesequencingrevealedanexpansionofitsrepertoire smaller(PERMANOVA P = 10−4, 6.3% ofvariance)and stable ofcarbohydrate-activeenzymes,whichmaybeassociatedwithits across the three compartments (14, 13, and 15% of variance in endophyticlifestyle. Cumulatively, these results provide evidence bulk soil, rhizosphere, and root communities, respectively) (SI for a beneficial role of a hitherto unknown member of the root Appendix,TableS3).ThiswasevidentinthePCoAonBray–Curtis microbiotainA.alpinagrowthperformanceinlow-Penvironments. dissimilarities where greenhouse samples from the Lautaret soil (GrH-Lau)weregroupedseparatelyfromsamplesobtainedfrom Results the two Reckenholz soils (GrH-RecNK and GrH-RecNPK), Root-Associated Fungal Communities in A. alpina Were Unaffected by which clustered more closely (Fig. 1B). This indicated that, under HostGeneticVariation.Our current understanding of the structure greenhouse conditions, the compartment type, the soil’s geo- of the root microbiome in nonmycorrhizal Brassicaceae species graphicalorigin,andtoalesserextentitsfertilizationregime,all rests primarily on bacterial communities, and information on the participatedintheshapingofroot-associatedfungalcommunities. factors shaping root-associated fungal consortia is scarce. We Collectively,theseresultssuggestedthatfungalcommunitiesthat studied fungal communities associated withA. alpina roots byse- wereaccommodatedintherootendospherewerelessdiverseand quencingthefungalITS2withprimersITS9/ITS4astheyshoweda lessaffectedbysoilchangesthanextraradicalconsortia. better recovery of low-abundance fungal diversity in comparison We then assessed whether these fungal communities were af- withotherprimersinapilotexperiment(SIAppendix,Fig.S1). fected by the plant growing environment and compared fungal We assessed the effect of plant intraspecific variation on the communities established under controlled greenhouse conditions structureoftheroot-associatedfungalcommunitybycomparing (GrH-Lau) with those established in the common garden under E9404 | www.pnas.org/cgi/doi/10.1073/pnas.1710455114 Almarioetal. S U L P S A N A B Condition: Compartment: Root P GrH-Lau Bulk soil GrH-RecNK Rhizosphere GrH-RecNPK Root Greenhouse (GrH). Botanical institute, Cologne,Germany. GAR-Lau WILD-Gal.2013 P WILD-Gal.2014 C o 2 (16 RY GrH n=6 n=6 n=6 P RPhCoi z1o (2s2p %h)er %)e ENTA C M Alpine garden (GAR). Jardin du Lautaret,western Alps, France. o 2 (14 PCo 2 (21 SEECOM % %) ) GAR n=5 n=5 n=6 n=6 PCo 1 (29 %) Bulk soil Alpine natural site (WILD). Col du galibier, western Alps, France. Sampling in 2013 and 2014. P C o WILD n=5 n=5 2 (27 PCo 1 (18 %) PCo 1 (37 %) %) C D x e e d c n n sity i abab a ab b a a unda er a b n's div c ab ative a anno ab b a a a Rel h ab S bc c CoGGnrrHdH-i-RtRieoeccnNNPKK GGrAHR-L-Laauu WWIILLDD--GGaall..22001134 GrH-RecNKGrH-RecNPKGrH-LauGAR-LauWILD-Gal.2013WILD-Gal.2014 GrH-RecNKGrH-RecNPKGrH-LauGAR-LauWILD-Gal.2013WILD-Gal.2014 GrH-RecNKGrH-RecNPKGrH-LauGAR-LauWILD-Gal.2013WILD-Gal.2014 OLOGY BI T N Fig.1. ComparisonofthefungalcommunitiescolonizingA.alpinarootsandrhizosphereundergreenhouse(GrH),commongarden(GAR),andnatural A L (WILD)conditionsindifferentsoils(RecNK,RecNPK,Lau,andGal).(A)Experimentalsetupshowingthedifferentplantgrowingconditions.Thegeographic P originofthedifferentA.alpinaaccessionsisindicatedinparentheses.MoreinformationaboutthesoilsandtheaccessionsisgiveninSIAppendix,Tables S1andS2,respectively.Thenumberofbiologicalreplicatespercondition(n)isindicated.(B)Principalcoordinatesanalysisonfungalcommunitydifferences (Bray–Curtisdissimilarities)inthedifferentcompartmentsandconditions.(C)FungalalphadiversityestimatedbyShannon’sdiversityindex.Lettersa–cin- dicatesignificantdifferencesbetweenconditionswithineachcompartment(ANOVAandTukey’sHSD,P<0.05).(D)Meanrelativeabundanceofthemajor fungalordersinthedifferentconditionsandcompartments:bulksoil,rhizosphere,androot.AsthefourA.alpinaaccessionsstudiedexhibitedsimilarfungal communitiesinthegardenexperiment(SIAppendix,Fig.S2),combinedresultsforthefouraccessionsareshownunderthe“GAR-Lau”condition. alpinesummerconditions(GAR-Lau)inthesamesoil(Lau)using diversity(Fig.1C)anddifferentcommunitystructure(PERMANOVA A.alpinaPMashostplant.Fungalcommunitiesestablishedinthe P=10−4,20%ofvariance)inrootandrhizospherefungalcommu- same soil but under the two contrasting environments, i.e., dif- nitiesfromwildA.alpina(WILD-Gal)(SIAppendix,TableS3).This feringinaltitudeandclimate,exhibitedsimilardiversity(ANOVA was observable in the PCoA with greenhouse and common garden P>0.05,Fig.1C)butdifferedinstructure(PERMANOVAP= samplesfromtheLautaretsoil(GrH-LauandGAR-Lau)clustering 0.002, 10% of variance). The effect of the environment type on close and separating from samples from wild growing A. alpina fungal community structure increased from bulk soil (PERMA- (WILD-Gal) (Fig. 1B). Collectively, these results showed that NOVAP=0.1)overrhizospheresoil(PERMANOVAP=0.002, underalpineconditionsroot-associatedfungalcommunitiesstill 21%ofvariance)totherootcompartment(PERMANOVAP= divergedaccording tothe soiltype. 0.003, 30% of variance) (SI Appendix, Table S3). This strongly suggested that root-associated communities were affected to a StabilityofRootandRhizosphereFungalCommunitiesAcrossVarying greater extent by environmental changes than bulk soil commu- Growth Conditions. We next performed a general analysis in- nities,whichremainedlargelyunaffected. cludingalloftheexperimentstoassesshowfungalcommunities Comparatively, common garden and wild A. alpina plants were affected by the plant growing condition. Six plant growing growingundersimilaralpinesummerconditionsbutindifferent conditions were considered based on the environment and the soils(GAR-Lauvs.WILD-Gal)alsoshoweddifferenceswithlower soil in which the plants grew and included the confounding Almarioetal. PNAS | PublishedonlineOctober2,2017 | E9405 effects of two different environments (greenhouse conditions: capturedonlyapartofthecommunities’differences.Interestingly, GrH and alpine summer conditions: GAR and WILD) and four therewasasignificantinteractionbetweenthecompartmenttype soils(Lau,RecNK,RecNPK,andGal).SinceA.alpinaaccessions andtheplantgrowingcondition(PERMANOVA,P=10−5,16%, harbored similar fungal communities (SI Appendix, Fig. S2), SIAppendix,TableS3),suggestingthatroot,rhizosphere,andbulk samples from the different accessions were grouped under the soil fungal communities responded differently to varying plant sameplantgrowingcondition,GAR-Lau. growing conditions. Indeed, PERMANOVA analysiswithin each In all plant growing conditions, A. alpina root-associated (i.e., compartment showed that the effect of the plant growing condi- root and rhizosphere) fungal communities were dominated by tiononthefungalcommunitysteadilydecreasedfromthebulksoil ascomycetes (58% of the fungal reads) belonging mostly to the (P=10−5,83%)overtherhizosphere(P=10−5,59%)totheroot orders Helotiales, Hypocreales, Pleosporales, and Sordariales. (P = 10−5, 49%) (SI Appendix, Table S3), suggesting that root Basidiomycetes (18%), unclassified fungi (14%), zygomycetes fungal communities were more robust relative to extraradical as- (4.4%), and chytridiomycetes (4.1%) were less abundant. As semblages. In sum, this analysis at a wide scale, including con- expectedforanonmycorrhizalplant,glomeromycetesthatinclude trasting environments and soils, showed that, although the theAMfungiwererarelydetected(0.04%).WhiletheHelotiales microhabitattype(bulksoil,rhizosphere,orrootcompartment)is (24% of the fungal reads in roots) and Cantharellales (16%) the main driver of fungal alpha diversity, the plant growing con- orders were enriched in root samples, Mortierellales (6% of dition is the main factor structuring root-associated fungal com- the fungal reads in the rhizosphere), Sordariales (4.2%), and munities,i.e.,determiningthetaxapresentandtheirabundances. anunclassifiedbasidiomycetetaxon(4.1%)wereenrichedinthe Moreover, itsuggestedthat,compared with rhizosphere commu- rhizosphere(pairedttestP< 0.05)(Fig.1D). nities, fungal communities living within A. alpina roots were less Comparisonoffungalcommunitiesattheoperationaltaxonomic affectedbychangesintheplantgrowingcondition. unit(OTU)levelshowedagainthatthecompartmenttypewasthe main driver of fungal alpha diversity (P = 2.10−16, 72% of vari- Fungal Taxa Consistently Found in A. alpina Roots. Following the ance) with a bigger effect than the plant growing condition postulatethatcommonlyoccurringorganismsplaycriticalrolesin (P=10−16,9.4%)(Fig.1C)(SIAppendix,TableS3).Comparisonof theirhabitat,weaimedatidentifyingfungaltaxathatconsistently fungalcommunitystructurebyPCoAshowedaseparationbetween colonized A. alpina roots, hypothesizing that they promote plant rootandsoil(rhizosphereandbulksoil)samplesmainlyalongthe growthand/orPuptake.Weidentified15highlyconservedfungal firstaxis(18%ofvariance)andaseparationbetweenplantgrowing OTUswithahighprevalenceinroots(i.e.,presentinatleast85% conditionsmainlyalongthesecondaxis(14%ofvariance)(Fig. of the root samples) (Fig. 2A). It comprised one zygomycete 1B).Withinthethreecompartments(root,rhizosphere,andbulk (Mortierella elongata, OTU00045), one basidiomycete (Ceratoba- soil) fungal communities clustered according to the geographic sidiaceae sp., OTU00008), and 13 ascomycetes belonging to the origin of the soil: samples from soil Gal (WILD-Gal) separated Helotiales(4OTUs),thePleosporales(4OTUs),theHypocreales from soil Lau (independently of the environment) and from (3 OTUs), the Sordariales (1 OTU), and one unclassified order ReckenholzsoilsRecNK andRecNPK,whichclustered together (OTU00015). On average, this cohort represented 43% of the (Fig.1B).PERMANOVAanalysisindicatedthatthemajorsource fungalreadsdetectedinA.alpinarootswithvaluesrangingfrom ofvariationincommunitystructurewastheplantgrowingcondi- 10 to 93% (Fig. 2B). Of these 15 highly conserved root OTUs, tion (P = 10−5, 32% of variance) and not the compartment type 7wereenrichedinplantrootsincomparisonwiththerhizosphere (P=10−5,16%)(SIAppendix,TableS3).Thiscontrastedwiththe (paired t test, P < 0.05). They included two unclassified species PCoA (Fig. 1B), which hinted to a stronger effect of the com- belongingtothePleosporales(OTU00007,92%prevalence,1.1% partment type. This can be explained by the fact that the PCoA relativeabundance)andtheCeratobasidiaceae(OTU00008,90%, A B GrHRecNK GrHRecNPK GrHLau GARLau WILDGal.2013 WILDGal.2014 Mortierellales Cantharellales s Helotiales t o o r n i Incertae sedis . u Pleosporales b a . el R Sordariales Hypocreales Fig.2. FungaltaxaconsistentlyfoundinA.alpinaroots(>85%prevalenceacrossallrootsamples).(A)Maximum-likelihoodphylogenetictreeofthehighly conservedrootOTUs.TherepresentativeITS2sequencesfromtheOTUswerealignedusingMuscle(28)andusedfortreeinferenceinPhyML(29)withaGTR+ I+γmodelwithoptimizedparameters.Fungalordersaredepictedwithdifferentcolors;whitecirclesindicatetheaveragerelativeabundance(Rel.abu.)of theOTUinrootsamples.Root(Ro)-orrhizosphere(Rz)-enrichedOTUsareindicated(comparisonrootvs.rhizosphererelativeabundance,pairedttest,P< 0.05).OTUswith100%prevalenceareshowninboldfacetype.(B)Relativeabundanceofthe15highlyconservedrootOTUsineachrootsample.Thedataare giveninDatasetS4. E9406 | www.pnas.org/cgi/doi/10.1073/pnas.1710455114 Almarioetal. S U L P S A N 6.5%);Alternariaembellisia(OTU00010,88%,2.8%);Dactylonectria A P torresensis (OTU00002, 100%, 11%); and three Helotiales in- cluding Tetracladium maxilliforme (OTU00004, 100%, 8.5%), a Cadophora OTU (OTU00033, 98%, 3%), and an unclassified OTU (OTU00005, 86%, 7%) (Fig. 2A). None of these highly conservedrootOTUswasrelatedto(i)AM,ectomycorrhizal,or Y R orchidmycorrhizalfungiknowntofacilitateplantnutrientuptake Water H.K. F229 NTA orto(ii)fungalendophytesS.indica(syn.P.indica)orC.tofiel- ME dFenioacueo,rmwophfaitcshhseewsereicrOeoiTddUemsscyrbcibeoelrodrnhtgiozeadtlraftuonnstfgheiresPuHctheoloantsoianOlmeidsyicooodrdrerenhrdizrkoannlopmwlananitutsos. B C eight (mg) ********* SEECOM w butalsoplantpathogenssuchasRhynchosporiumsecalis.Threeof h tahbeusnedfaonucreHeesploetciiaallelsyOunTdUerssnhaotuwreadlceonnridcihtimonesnt(Finigr.o2oBts).andhigh oot fres h S Helotiales Fungus F229 (OTU00005) Promotes A. alpina Growth and W) ****** Shoot P Accumulation. Helotiales OTU00005 exhibited a high D relativeabundanceintherootsofwildA.alpinaplantsfromCol Kg g/ du Galibier (45% in WILD-Gal.2013 and 23% in WILD- m Gal.2014samples,SIAppendix,Fig.S5B),wherethehostplants ot P ( grew on an extremely low-P soil (soil Gal, 3.7 mg/kg plant- ho S available P) while maintaining high shoot P concentration (SI Water H.K.F229 Appendix,Fig.S5A).WesubsequentlyidentifiedinourCologne Culture Collection of Root-Associated Fungi (CORFU) seven D isolates that were recovered from A. alpina collected at Col du GalibierandbelongedtothisOTU(DatasetS1).Thefull-length ITS sequences of the isolates shared 99–100% similarity, and their ITS2 regions showed 99–100% similarity to the represen- W tativeITS2sequenceofOTU00005.Blastanalysisrevealedthat D the ITS sequences of these isolates werehighly similar toother g Helotiales root endophytes isolated from the Brassicaceae spe- / q ciesMicrothlaspiperfoliatumgrowinginthesouthofSpain(30), B K thusreflecting arecurrent presence ofthese Helotialesfungi in P rootsofBrassicaceae(SIAppendix,Fig.S3). 3 3 Toaddressthesignificanceoffungalrootcolonizationforplant P uptake, the fungus with CORFU identifier F229 (hereafter namedF229),belongingtoOTU00005,wasselectedforfurtherin planta experiments in gnotobiotic Murashige and Skoog (MS) agar systems. F229 promoted growth of A. alpina F1gal and PM rootsunderlow-Pconditionsandleftplantsunaffectedinhigh-P GY O conditions (SI Appendix, Fig. S4). In contrast, another six fungal OL isolatesnotbelongingtoOTU00005(CORFUF226,F248,F247, Fig.3. FungusF229(OTU00005)increasesA.alpinagrowthandPcontent BI F91,F83, F222), screened indifferentexperiments, all exerted a undernativelow-PsoilconditionsandiscapableofhyphalPtransfertothe ANT rootinvitro.(A)A.alpinaF1galgrowthinsterilesoilmicrocosmuponwater L negativeeffectonplantrootand/orshootgrowthinatleastoneof P addition(Water),additionofheat-killedfungus(H.K.),andinoculationwith the P conditions (SI Appendix, Fig. S4). Fourteen days post- F229(F229)(1.32±0.8×104propagulespermicrocosm)at28dpi.(Scalebars, inoculation (dpi) on its natural host A. alpina F1gal, F229 1cm.)(B)Inter-andintracellularfungalrootcolonizationinsterilesoilmi- asymptomaticallycolonizedtheplantroots(SIAppendix,Fig.S6B crocosmsvisualizedbyconfocalmicroscopyafterstainingthefungalcellwall and C) with equal colonization at low-P (100 μM P MS agar, withWGA-Alexa(green,a–d),theplantcellwallwithpropidiumiodide(red, 89.6%ofcolonizedroots)and high-P(1,000 μM,88.6%ofcolo- a–c),andthecellularmembraneswithFM4-64(purple,d).(Scalebars,30μm.) nizedroots)conditions(χ2testP=0.87).However,underlow-P (C)EffectofF229inoculationonshootfreshweightandshootPconcentration conditions, fungal inoculation significantly increased root length insterilesoilmicrocosms.Theexperimentwasrepeatedfourtimesincluding (+12%, t test P = 0.02) and root surface area (+19%, t test P = the Water and F229 treatments and three times including also the H.K. 0.001) while leaving shoot biomass (t test P > 0.05) and shoot P treatment,withthreetofourmicrocosmspertreatment;similarresultswere concentration(ttestP>0.05)unchanged(SIAppendix,Fig.S6A oShbotaoitnewde,igahntdwcoasmmpieleadsurreesdulotsnfirnodmividthuealfopularnetsxp(ner≥im5e6n)twshareeresahsoawllnohfetrhee. andB).Aneutraleffectonrootgrowthwasapparentunderhigh-P shootsfromonemicrocosmwerepooledtomeasureshootPcontentbyICP- conditions (1,000 μM P, 14 dpi) (SI Appendix, Fig. S6A). Simi- MS(n≥9).Asterisksindicatesignificantdifferencesbetweenthetreatments larly, a second isolate (CORFU F240), also assigned to basedontheMann–Whitneytest(P<0.05).(D)Invitrotransferof33Por- OTU00005 and exhibiting 100% ITS sequence similarity with thophosphatetotheplantbyF229.TheF229andA.alpinaF1galplantswere F229, also promoted root growth of A. alpina F1gal under low-P grown onlow-P(100μM P)orhigh-P(1,000μM P)MS medium in a two- conditions(SIAppendix,Fig.S6D). compartmentsystem.33PwasaddedtothefungalHC,andafter7(experi- ment3),10(experiment2),or15(experiment1)days,33Pincorporationinto WenextassessedtheeffectofF229onthegrowthofitsnatural theplantshootgrowingintheRHCwasmeasuredbyscintillationcountingof host A. alpina F1gal under native P-limited soil conditions (Fig. individual plants.Nofunguswasaddedtothefungalcompartmentinthe 3A). At 28 dpi in gnotobiotic microcosms filled with autoclaved mockinoculatedtreatments.Barsrepresentindividualsamples. soilfromtheColduGalibier(soilGal),F229fullycolonizedplant roots(100%ofcolonizedroots)inter-andintracellularly(Fig.3B, a–d). Vital staining of plant and fungal membranes indicated vi- partners. While addition of heat-killed fungal suspension nega- abilityofhostandfungalcellsduringintracellularaccommodation tively affected plant growth, fungal inoculation translatedinto (Fig. 3B, d), indicating a biotrophic interaction between the 52%highershootbiomass(Mann–WhitneytestP=3.10−13)and Almarioetal. PNAS | PublishedonlineOctober2,2017 | E9407 61%highershootPconcentration(Mann–WhitneytestP=2.10−4) TheEndophyticLifestyleofF229isAssociatedwiththeExpansionof compared with the water control (Fig. 3C). The shoot P levels itsCAZymeRepertoire.We aimed at identifying genomic charac- were stilllower than observed intheir wild-growing counterparts teristicsassociatedwiththeF229endophyticbiotrophiclifestyle. (WILD-Galtreatments,SIAppendix,Fig.S5).Wecouldimagine A five-gene phylogenetic analysis on F229 and 50 other asco- two possible reasons explaining this discrepancy: (i) The young mycetes with available genome information confirmed the plantsinthemicrocosmsaccumulatedlessPintheirvacuoles,the placement of the fungus within the Leotiomycetes class and primaryintracellularcompartmentsforinorganicphosphate,than theHelotialesorder(SIAppendix,Fig.S10).Theclassificationof the fungus at the family or genus level was not possible as the themucholderwildplantsor(ii)differencesinpropertiesofsoil taxonomywithintheHelotialesorderisstillunclear.Theclosest inmicrocosmsrelativetosoilatColduGalibierlimitedPuptake, relatives(with sequencedgenome)ofF229areplantpathogens whichwaspartiallyalleviatedthroughrootcolonizationwithF229. Marssonina brunnea f. sp. multigermtubi and Rhynchosporium In sum, these results corroborate the hypothesis of a beneficial species R. secalis, R. commune, and R. agropyri, suggesting that effect of this endophyte on host growth and P acquisition under the endophytic lifestyle of F229 could have evolved from an nativelow-Psoilconditions. ancestralplantpathogeniclifestyle(Fig.4A).Similarly,theITS- based phylogenetic analysis including more fungal isolates sug- F229TranslocatesPtoItsHostinVitro.Fungi can promote plant P gests that F229 belongs to a lineage of root endophytic fungi acquisition by different mechanisms like P solubilization, P min- that diverged from related pathogenic Rhynchosporium and eralization, or hyphal P transfer. We wanted to know whether Pyrenopeziza species (SI Appendix, Fig. S3), but more Helotiales F229iscapableofhyphaltransportofradiolabeled33Ptoitshost. genomesareneededtoproperlyassessthishypothesisusingmore Usingatwo-compartmentagarosesystemlimitingradiotracerdif- robustphylogeneticanalyses. fusion, we observed that 33P added to the hyphal compartment The Helotiales order encompasses fungi with contrasting life- (HC) could be traced to the plant shoot in the root and hyphal styles including plant beneficial fungi, plant pathogens, and sap- compartment(RHC),withbothcompartmentsconnectedonlyby rotrophs(Fig.4A).Weusedacomparativegenomicsapproachon fungal hyphae crossing the physical barrier (Fig.3D). Fungal col- CAZymerepertoirestoidentifygenomicsignaturesassociatedwith onization was restricted to the root as the fungus was never de- abiotrophiclifestyleandplant-beneficialeffectswithinthisorder. tectedintheplantshoot(stemorleaves,SIAppendix,Fig.S7).33P Comparison of CAZyme class profiles of 11 Helotiales fungi translocationacrossthediffusionbarrierwasblockedbyBenomyl revealed large similarities between plant beneficial fungi that (SIAppendix,Fig.S8),acompoundthat inhibitsmicrotubulefor- clusteredtogether(Fig.4B).TheclusterincludingF229,thepoplar mation and intracellular transport in fungi (31), which indicated endophyte Phialocephala scopiformis, and the ericoid mycorrhiza thathyphalPtransportwasanactivefungalprocessratherthanme- O.maiuswascharacterizedbyahighernumber(ttestP<0.01)of diated by diffusion. Moreover, hyphal 33P translocation to the plant modulesofglycosidehydrolases(GH)(averagenumberof427in shoot was detectable as early as 7 d after 33P addition and was plant-beneficial fungi, 349 in F229, and 256 in the other fungi), independentfromlow-orhigh-Pconditions.Thissuggeststhatin carbohydrate-binding modules (CBM) (103, 109, and 77), carbo- F229 33P transfer to the host is not regulated by P availability, hydrate esterases (CE) (194, 160, and 105), glycosyltransferases whichstandsincontrasttowhatwasshownforC.tofieldiae(12). (GT)(128,122,and102),andauxiliaryactivities(AA)(137,135, These data suggest that plant growth promotion by F229 under and 83), indicating an overall larger CAZyme repertoire in the low-PsoilconditionsinvolveshyphaltransferofPintoitshost. genomes of plant beneficial Helotiales in comparison with plant pathogenicandsaprotrophicHelotiales(DatasetS3).Comparison TheF229GenomeEncodesTwoHigh-AffinityPhosphateTransporters. of CAZyme family profiles showed similar results (SI Appendix, Cellular uptake of nutrients, maintenance of cellular nutrient Fig. S11). Twenty-two CAZyme families were significantly more homeostasis,andiontransferacrosscellular(endo)membranesin abundant in plant beneficial fungi in comparison with the other fungus–plant symbioses involves high- and low-affinity ion trans- fungi (t test P < 0.01) (Fig. 4C). Notably, this concerned families porters. To obtain insight into the molecular mechanisms un- associatedwithplantcell-walldegradation,actingonhemicellulose derlyingtransportofinorganicphosphateinF229,weperformed (GH31, GH29, CE1, CE7, CE10), or in the transformation of genome-wide analysis to identify fungal phosphate transporters. lignocellulosic compounds (AA7). Three GHs associated with PacBiosequencingoftheF229genomeproducedafinalassembly fungalcell-walldegradation(GH20,GH72,GH76)werealsomore of39contigswithanestimatedgenomesizeof∼85Mb(Dataset abundantinplantbeneficialfungi.ComparisonofCAZymeclasses (SI Appendix, Fig. S12A) and selected CAZyme families (SI Ap- S2). The final genome version showed a high level of complete- pendix, Fig. S12B) across 51 ascomycetes genomes showed no ness with a high coverage of core fungal (98.7%, FUNYBASE clustering corresponding to fungal lifestyle differences, indicating geneset)andeukaryoticgenes(99.2%,ClusterofEssentialGenes that the observations made within the Helotiales are lineage- geneset).Weaimedtoidentifyhomologsofsixproteinsthatplay specific. Collectively, these data suggest that the endophytic be- aroleinphosphatetransportintheyeastSaccharomycescerevisiae. haviorofF229isassociatedwiththeenlargementofitsCAZyme One is the major proton-coupled high-affinity phosphate trans- repertoire and particularly with protein families associated with porterPho84,threetransportphosphatewithlowaffinityintocells plantcell-walldegradation. (Pho87, Pho90, Pho91), and the fifth and sixth proteins (Pho 88andPho89)areutilizedunderspecializedconditions(32).Two Discussion genes intheF229 genome(g8711.t1 and g16086.t1)encodepro- Lowavailabilityofphosphateisamajorfactorconstrainingplant teins sharing high similarity with S. cerevisiae Pho84 and with growth, performance, and metabolism in many natural and ag- fungal high-affinity phosphate transporters involved in P trans- riculturalsoilsworldwideduetothepoorsolubilityandmobility location from fungus to plant. One gene (g3490.t1) encodes a of soil P. The AM fungi have been shown to benefit plant pro- protein sharing similarity with Pho87, Pho90, and Pho91, and a ductivityduetotheircontributiontoplantnutrition,especiallyin last gene (g6261.t1) encodes a protein sharing similarity with nutrient-poorsoils(10).ThepredominantfunctionofAMfungi + Pho88. The gene encoding the Na -dependent high-affinity is attributed to increased host plant phosphate uptake as a Pho89 could not be identified (SI Appendix, Fig. S9). In sum, consequence of a phosphate transport mechanism (7). Brassi- these results show that the F229 genome encodes a set of phos- caceaespecieslacktheabilitytoestablishanAMsymbiosis,and, phate transporters potentially enabling phosphate uptake and to fully comprehend how these plants thrive in P-limited habi- translocationtoitshostplant. tats, it is required that we improve our understanding of their E9408 | www.pnas.org/cgi/doi/10.1073/pnas.1710455114 Almarioetal. S U L P S A N A P Sordariomycetes 0.2 Botrytis cinerea es Sclerotinia sclerotiorum Leotiomycet HRPROMARGshehhhliaadcilyyyraoriosnnnoeltscocccdaiooachhhenrellooonoeyipsssdnznshppporae oasoooy bnslprrreaiiira uuu.n mu rsmmmFsnccai2ons oisac2uiepdeog9saie*cmrfoosamrplmisyurinsie Helotiales EECOMMENTARY Blumeria graminis S Xyl. Xylona heveae Dot. CZylamdoosseppotroiurima tfruitlivcuim Pez. Tuber melanosporum B C * b FuPPPPSUnlalllngaaaapknnnnarnttttol o ppbbtlwriaaeeofnettnnphheeshoofftgiigccyeeiilaannell---NEEnreicdcorooipdtrh omyptyehcorrhiza CAZyme familiesabundanceMax.Min. R. commune.56. MbR. secalis.49. MbR. agropyri.52. MbA. sarcoides.34. MbS. sclerotiorum.38. MM. brunnea.52. MbB. cinerea.43. MbG. lozoyensis.40. MbHel. sp. F229.85. MbP. scopiformis.49. MbO. maius.46. Mb Lifestyle 48 50 50 42 42 36 54 54 71113123 CE10 24 21 21 11 13 14 14 26 33 37 34 CE1 * 14 12 14 7 22 21 26 40 39 41 47 AA7 CAZyme classesabundance Max.Min. S. sclerotiorum.38. MbM. brunnea.52. MbA. sarcoides.34. MbR. agropyri.52. MbR. secalis.49. MbR. commune.56. MbB. cinerea.43. MbG. lozoyensis.40. Mb O. maius.46. MbP. scopiformis.49. MbHel. sp. F229.85. Mb 111221001 111221001 011221001 111122001 100111001 000213001 010111101 220121001 332333101 323433112 356433212 CGGGCGCGCEEBBHHHTT71MM2212241329046736 Lifestyle 2 3 2 2 3 1 2 3 5 5 3 CBM13 2 3 2 4 5 1 5 3 5 8 9 GH92 229205261287269277250272 530404349 GH 13 14 14 10 12 12 10 13 16 17 15 GH76 80 74 73 82 78 75 67 84 10298109 CBM 7 7 7 4 6 4 5 5 13 11 13 GH31 90 99 97107108110101106 136126122 GT 7 7 7 9 8 6 10 6 10 11 13 GH47 75 79 44 89 79 86 86125 116160135 AA 7 6 7 7 4 5 7 6 7 15 15 GH78 93 85 83114111117107127 207214160 CE 6 6 7 4 5 5 5 6 8 7 8 GT90 Y G 5 20 2 9 9 9 12 13 19 3 23 PL 7 7 7 7 6 7 6 8 8 9 8 GH72 O L 6 6 6 11 6 7 5 8 10 14 23 GH109 O 8 9 8 11 5 8 6 7 9 15 19 GT32 BI T N A Fig.4. TheendophyticlifestyleofF229isassociatedwiththeexpansionofitsCAZymerepertoire.(A)Maximum-likelihoodphylogenetictreeinferredfromfive PL housekeepinggenes(28S,18S,Rpb1,Rpb2,EF1alpha).Bootstrapvalues>0.75areindicatedwithablackdot.Laccariabicolorsequenceswereusedfortree rooting.Helotialeswithplantbeneficial,plantpathogenic,orsaprophyticlifestylesareindicated;thekeyisgiveninB.ThefulltreeisshowninSIAppendix,Fig. S10.(B)ComparativeanalysisofCAZymerepertoiresinthegenomeofF229andrelatedHelotialeswithplantbeneficial,plantpathogenic,orsaprophyticlife- styles.HierarchicalclusteringontheabundanceofCAZymeclasseswithintheHelotiales.AA,auxiliaryactivities;CBM,carbohydrate-bindingmodule;CE,car- bohydrateesterase;GH,glycosidehydrolase;GT,glycosyltransferase;PL,polysaccharidelyase.(C)HierarchicalclusteringontheabundanceofselectedCAZyme familieswithintheHelotiales.Onlyfamiliesshowingasignificantlyhigherabundanceinplant-beneficialfungiareshown(ttests,P<0.01).InBandC,thecolor scaledepictsstandardizedvaluesforeachmodule.Fungalgenomesizesareindicatedaftertheirname.F229isshowninboldfacetypewithanasterisk. fungal microbiota. Here we close this gap by investigating havetheabilitytocrosstheselectionfiltersimposedbythehost. structural and functional properties of the fungal microbiota Thishypothesisissupportedbypreviousstudiesonrootmicrobial associated with the roots of the nonmycorrhizal Brassicaceae communities that have shown a similar diversity pattern in bac- speciesA.alpina.WehavechosenA.alpinabecauseitnaturally terialassemblagesinA.alpina,A.thaliana,andrice(1,15,16,26) grows in low-P habitats, and, in contrast to short-lived annuals and in fungal communities of Agave (20). Furthermore, the mi- likethemodelspeciesA.thaliana,itsperennialpatternofgrowth crohabitat type also affected the structure of these fungal com- and development gives longer time periods for microbial com- munities,i.e.,thetaxapresentandtheirrelativeabundances(Fig. munitiestoestablishinandaroundthe roots. 1B). Overall, the fungal microbiome associated with roots (root and rhizosphere) of nonmycorrhizal A. alpina was dominated by VariabilityandStabilityoftheA.alpinaRootFungalMicrobiome.Our ascomycetes,aswasshownformycorrhizalpoplarandAgave(18, study of the factors shaping root-associated fungal communities 20), and which is likely to be predetermined by the majoritarian showed that fungal alpha diversity is determined mainly by the presence ofascomycetes insoil(33). Still,root endosphere com- microhabitat type, i.e., bulk soil, rhizosphere, or root compart- munities systematically differed from rhizosphere communities ment, dropping dramatically in the root (Fig. 1C). This obser- locatedmillimetersapart(Fig.1B);theywereenrichedinHelot- vation further sustains the view that colonization of the root ialesandCantharellalesfungianddepletedinMortierellalesand endosphereisrestrictedtoareducednumberoffungaltaxathat Sordariales(Fig.1D).Surprisingly,therewasnoclearsimilarityin Almarioetal. PNAS | PublishedonlineOctober2,2017 | E9409 the pattern of enriched and depleted fungal orders in A. alpina indicating a plant growth-promoting effect of twoHelotiales iso- and mycorrhizal Agave, poplar, and sugarcane roots (18–20), lates(F229andF240,OTU00005)invitro(SIAppendix,Fig.S6) suggestinga low level of conservation offungal microbiome pat- in combination with the high relative abundance of the corre- ternsacrossdistantlyrelatedplanthostspecies. sponding OTU inA.alpina plants growing under P-poornatural Addingtothestrongmicrohabitateffect,thesoilgeographical conditions (SI Appendix, Fig. S5) suggests that this taxon could provenance was the second largest driver of fungal community facilitate plant P uptake in its natural environment. Further structure under controlled greenhouse conditions. Soil fungal studies are needed to investigate more A. alpina natural pop- communitiesshowstrongbiogeographicalpatternsshapedbylocal ulations at different locations to define the biogeographic distri- climatic and edaphic factors (33–35) and thus strongly diverge butionofthisbeneficialplant–fungusassociation. from the “everything is everywhere” postulate suggested for mi- crobial communities (36). The soil’s P-fertilization regime also EndophyticHelotialesFungusF229PromotesGrowthandPAcquisitionin impacted the structure of fungal communities, albeit to a lesser A. alpina. While most root-associated microbes compete with the extent than the soil geographical origin (Fig. 1B). This indicated plant and with each other for essential nutrients, some may have thatlong-termPfertilizationoftheRecNPKsoil(37)shiftedsoil the potential to positively affect plant nutrition and growth. Hel- fungalcommunities.Differencesinrootcommunitiescouldbethe otiales fungal isolate F229 belonging to OTU00005 was isolated consequence of these changes, but we cannot exclude that they from A. alpina roots growing at the Col du Galibier natural site could be linked to changes in the plant nutritional status associ- characterized by low-P availability in soil. The fungus exhibited ated with fertilization. Such changes could lead to differences in biotrophic endophytic growth as it asymptomatically colonized root-associatedcommunitiesbyalteringtherootexudationprofile plant roots inter- and intracellularly (Fig. 3B) rather than killing and/ormorphology,similarlytotheAMsymbiosisthatisconfined root cells during the infection process, coinciding with the root to conditions in which the plant is P-starved (7, 37). Even when enrichmentofthecorrespondingOTU(Fig.2A).F229wasableto growing in the same soil, fungal communities described under translocatePtotheplantunderhigh-andlow-PconditionsonMS controlledgreenhouseconditionsdifferedfromthoseestablished agar (Fig. 3D). However, no increase in shoot P content was ob- under alpine summer conditions (Fig. 1B). This environment ef- servedunderthoseconditions(SIAppendix,Fig.S6).Oneplausible fect increased from the bulk soil to the root compartment, sug- explanationisthatasobservedforAMsymbiosis,translocationofP gesting that root-associated communities were more responsive bythefungusdoesnotnecessarilytranslateintoincreasedPcontent to environmental change than bulk soil communities, which in the plant since the plant can tune-down the direct P uptake remainedroughlyalike.Lownighttemperatures(prevalentunder pathway and use the mycorrhizal pathway instead (41). When alpine summer conditions) affect plant defense mechanisms as reintroduced into its native low-P soil fungus, F229 successfully showninArabidospsis(38),whichcoulddirectlyimpactendophytic colonized plant roots and enhanced shoot growth and shoot P fungalcommunities. concentration (Fig. 3C) through an active process (Fig. 3C). Our Our analysis including all of the plant growing conditions results stay in accordance with a role of F229 in extending the studied showed that at this wide scale it was no longer the mi- potentialrangeofplantnutrientabsorptioninlow-Psoilsandpo- crohabitattype,i.e.,thecompartmenttype,buttheplantgrowing tentially also in P-rich habitats. In addition to increasing the ab- condition that was the main factor shaping fungal communities. sorptive surface area of the host plant root system, hyphal P ThisisconsistentwithwhathasbeendescribedinAgave(20)and translocation mediated through the activity of phosphate trans- poplar(18),wheretheplantbiogeographywasthemajorsourceof portersencodedinthefungalgenomewouldenableaccesstosoilP variation in fungal and bacterial communities. Interestingly, root sourcesotherwiseunavailabletotheplant(Fig.3DandSIAppen- communities were less affected by the plant growing condition dix,Fig.S9).Wecannotexclude,however,Pdeliveryfromfungus than soil communities (rhizosphere and bulk soil) (Fig. 1B) as tohostasaconsequenceoflysisoffungalcells,amechanismthat observed inAgave (20). This pointed to the existence of a set of was proposed for nutrient transfer in orchid mycorrhizae (42). fungal taxa consistently colonizing A. alpina roots in contrasting Overall, our work on F229 (P transfer) and studies on S. indica growthconditions.Ourstudyrevealedahighlyconservedsetof15 (P transfer) (13, 14), C. tofieldiae (P transfer) (12), Heteroconium OTUs that was dominated by ascomycetes (Fig. 2A) and repre- chaetospira(Ntransfer),(43)andMetarhiziumrobertsii(Ntransfer) sentedupto93%ofthefungalreadsinA.alpinaroots(Fig.2B). (44) provide accumulating evidence that fungus-to-plant nutrient SevenOTUsofthiscoremicrobiomeweresignificantlyenriched transfer,generallyassignedtoclassicalmycorrhizalsymbioses(10), inthe root endospherein comparisonwith the rhizosphere (Fig. ismorecommonthanpreviouslythought. 2B), suggesting not only that these taxa were able to cross the Plant-colonizing fungi rely on hydrolytic enzymes including selectionbarrierimposedbytheroot,butalsothattheyreacheda higher abundance within the root endosphere, implying some CAZymes for degradation of the plant cell wall and penetration degreeofadaptationtothisniche.Althoughmostoftheidentified into thehosttissue (45, 46),and changes inthe CAZymereper- OTUscouldnotbeclassifiedatthespecieslevel,wecouldidentify toires have been associated with lifestyle changes in plant- the A. embellisia and D. torresensis species. Both Alternaria and associated fungi (21, 22). The evolution from pathogenic ances- Dactylonectriageneraareknowntocontainahighnumberofplant tors toward the beneficial endophytic lifestyle of F229 was pathogenic species albeit with no evidence of pathogenicity in accompaniedbytheenlargementofitsCAZymearsenal(Fig.4). A. alpina. Interestingly, three closely related Helotiales OTUs This contrasts with observations of ectomycorrhizal fungi where were identified as highly conserved, root-enriched, and highly the transition from a saprophytic to an endophytic lifestyle was abundantinwild-growingplants(Fig.2A).WhileHelotialesfungi associatedwithareductionofthenumberofgenesencodingplant represented24%oftheA.alpinarootmicrobiome,theywerenot cell-wall–degrading enzymes (21, 22). This discrepancy has been commonly found in root microbiomes of the mycorrhizal hosts noted in other root endophytes including mycorrhizal fungi (21, Agave (20), poplar (18), or sugar cane (19). However, they were 45,47).Oneexplanationisthatthearsenalofenzymespotentially foundtodominatetherootmicrobiomeofmycorrhizalEricaceae involved in plant cell-wall degradation is a genomic indicator of speciesgrowingundersimilarcoldandnutrient-limitedconditions saprophyticgrowthinplantdebrisinsoil,makingthesefungiless as A. alpina (39), suggesting that this could be a specificity of dependentontheirhostforphotosyntheticallyderivedcarbon. plantsgrowinginsuchharshenvironments.TheHelotialesorder Inconclusion,bystudyingthefungalmicrobiotaassociatedwith is not well studied, and its phylogeny is still obscure. Although A.alpinaroots,wehaveuncoveredabeneficialHelotialesfungus Helotiales fungi have often been isolated from plant roots, their capable of promoting plant growth and P uptake and thereby ecological functions remain largely unknown (40). Our results potentiallyfacilitatingplantadaptationtolow-Penvironments. E9410 | www.pnas.org/cgi/doi/10.1073/pnas.1710455114 Almarioetal. S U L P S A N MaterialsandMethods experimentalconditions,amyceliumsuspensionwasusedforinoculation. P Aftergrowingthefungusfor4wkonmaltyeastpeptoneagar,thefungal Plant Growth and Sample Collection. We analyzed the fungal communities myceliumwasrecoveredfromthesurfaceoftheagar,weighted,anddiluted colonizingtherootsandrhizosphereof60A.alpinaplantsgrowing(i)under to250mg/mLwithsterilewater,and∼30glassbeadspermilliliter(Ø1.7– GrHinthreedifferentsoils(Lau,RecNK,andRecNPK;soilcharacteristicsare 2.1mm)(CarlRoth)wereaddedbeforegrindingtwiceat6,200×gfor10sin given in SI Appendix, Table S2); (ii) under alpine summer conditions in a aPrecellysinstrument(BertinTechnologies).Themyceliumwassubsequently commongardenintheFrenchAlps(GAR);and(iii)atanaturalsiteinthe Y washedtwicethroughadditionofninevolumesofwaterandcentrifugation R FrenchAlps(WILD)over2y(2013and2014)(Fig.1A).FourA.alpinaaccessions A (PM,E3, S2,and F1gal) originating fromdifferentEuropeanlocationswith at700×gfor2min.Thefinalpelletwasresuspendedinsterilewater,and ENT themycelialconcentrationwasadjustedto10mg/mL.Fungus-treatedmi- M different soil characteristics (SI Appendix, Table S1) were included in the M commongardenexperimenttoassessthecontributionoftheplantgenotype corfomcoyscmelsiuwmerpeeirnopcout)la,theedatw-kitilhle1d0cmonLtorofltshriescineoivceudla1t0iomnLsuosfpethnissiosuns(p1e0n0smiong CO tothestructuringoftheroot-associatedfungalcommunity.Rootandrhizo- afterautoclaving,andwatercontrolsreceived10mLofsterilewater.Plate SEE spherecompartmentsfromfivetosixreplicatesperconditionwerecollected. dilution series were made with the inoculum suspension, and colony Therhizospherewassampledasthesoiltightlyadheringtoroots,androot counting after 4 d indicated a level of inoculation of 1.32 ± 0.8 × 104 samples were enriched in endophytic fungi by detaching surface-adhering propagulesperpot.Soilhumiditywasadjustedto70%ofthewater-holding fungi through sonication (1). Three unplanted bulk-soil samples were in- capacity without further watering. A. alpina F1gal seeds were surface- cludedineachexperiment.ThedetailedprocedureisgiveninSIAppendix, sterilized as described in SI Appendix, Materials and Methods, and strati- MaterialsandMethods.Ineachtreatment,surface-sterilizedrootswereused fiedfor1wkat4°Conmoiststerilefilterpaper,and10seedsweresub- to recover fungal root endophytes deposited in CORFU (Dataset S1). The sequently placed on the soil surface in each microcosm 2 d after fungal methodisdescribedinSIAppendix,MaterialsandMethods. inoculation. The microcosms were closed and placed in a phytochamber (VersatileEnvironmentalTestChamber;Sanyo)with16-h/8-hday/nightcy- ShootPMeasurementsbyInductivelyCoupledPlasmaMassSpectrometry.For clesat22/18°Cand70%relativehumidity.Themicrocosmswererandom- determinationofshootPconcentrationbyinductivelycoupledplasmamass izedeveryotherday.After28d,plantswereharvestedindividually,shoot spectrometry (ICP-MS), shoot samples were dried for 2 d at 65 °C before weight was measured, and all of the shoots from one microcosm were digestion.Formatureplants(i.e.,∼3moold;GrH,GAR,andWILDexperi- pooledtomeasureshootPcontentbyICP-MSasdescribedabove.Oneroot ments),samplesweredigestedusingamicrowavesystem(Multiwave3000; systempermicrocosmwascollectedformicroscopyanalysisoffungalcolo- AntonPaar).Approximately0.3gofdryhomogenizedplantmaterialwas nization.MicroscopyanalyseswereconductedasdescribedinSIAppendix, digestedusing4mLofHNO3(66%vol/vol)and2mLofH2O2(30%vol/vol). Materials and Methods. The experiment was repeated four times; three The microwave program included a power ramp of 10 min followed by experiments included the “heat-killed”’ treatment, with three to five mi- 30minat1,400Wandafinal15minofcoolingdown.Finalsolutionswere crocosms per treatment. Due to a reduced germination rate, on average diluted1:5withdeionizedwaterbeforeanalysis.Foryoungplants(i.e.,1mo sevenplantspermicrocosmcouldbesampled(n=10–39pertreatmentper old; MS agar and sterilized soil experiments) plant material was digested experiment).Datanormalitywaschecked,andmeanswerecomparedwith using500μLofHNO3(66%)at100°Cfor20min.Finalsolutionswerediluted the Mann–Whitney test (P < 0.05). The impact of fungal inoculation on 1:10withdeionizedwaterbeforeanalysis.Solutionblankswereincluded. A.alpinagrowth was alsostudiedonMS agar; the detailed procedure is ThePconcentrationwasdeterminedusinganAgilent7700ICP-MS(Agilent giveninSIAppendix,MaterialsandMethods. Technologies)followingthemanufacturer’sinstructions. 33PTranslocationExperiments.Invitrohyphaltransferof33Porthophosphate Fungal Microbiome Analysis. For fungal community description, DNA was totheplantbyF229wasstudiedasdescribedinref.12.Abicompartment extractedfromeachcompartment,i.e.,root,rhizosphere,andbulksoil,and systemwasestablishedbyplacingtwosmallroundpetriplates(Ø3.8cm) usedforfungalITS2PCRamplificationwithprimersITS9/ITS4(SIAppendix, constituting the HC into a square petri plate that was filled with low-P TableS4).TaggedampliconsweresequencedusinganIlluminaMiseqplatform (100 μM P) or high-P (1,000 μM P) MS agar up to the rim of the small producing 2 × 300 paired-end reads, and data analysis was conducted in plate,whichservedastheRHC.Rootswereprecludedfromgrowingintothe Mothur(48).Thefinal3′388.918high-qualityfungalreadswereclusteredus- HCbyregularlymovingroottipsbeforerootingrowth,thusmaintainingthe ingdenovo OTU pickingat97% sequence similarity.Afterdiscarding low physicalbarrierbetweenbothcompartments(Fig.3D).Four-week-oldfun- GY abundance(<50reads)andnonfungalOTUs,2.966OTUswereobtained,and gal potato dextrose agar plates were used to inoculate the HC by trans- LO O eachOTUwastaxonomicallyclassifiedusingtheUNITEdatabaseinMothur. ferringa0.5-cm3agarplugcontainingfungalhyphae.A.alpinaF1galseeds BI Onaverage,38.405finalfungalreadsand567OTUswereobtainedpersample weresurface-sterilized, stratified, andallowedto germinateonlow-PMS NT (SIAppendix,TableS5).HighlyconservedrootOTUs(>85%prevalenceacross agar as described in SI Appendix, Materials and Methods. After 2 wk of LA P allrootsamples)aregiveninDatasetS4.ThedetailedprocedureisgiveninSI fungalgrowthinthebicompartmentsystem,two1-wk-oldA.alpinaF1gal Appendix,MaterialsandMethods.Therawsequencingdatahavebeende- seedlingsweretransferredtotheRHC.NofunguswasaddedtotheHCin posited at the National Centerfor Biotechnology Information (NCBI) Short themocktreatments.PlateswereclosedwithMicroporetape,placedver- ReadArchiveunderBioprojectPRJNA386947. ticallyinaphytochamber(Sanyo,16h/8hday/nightcyclesat22/18°Cand 70%relativehumidity),andincubatedforanother2wk.Whenfungalhy- StatisticalMethodsUsedforMicrobiomeStudies.Analyseswereconductedin phaehadcrossedthephysicalbarrierbetweenbothcompartments,350kBq R3.2.3.TheOTUrelativeabundanceswerecalculatedandtransformedusing ofcarrier-free33P-labeledH3PO4(∼3pmol;HartmannAnalytik)wasadded a log10 (x + 1) formula. Bray–Curtis dissimilarities between samples were to the HC. Plates were incubated horizontally in the phytochamber, and calculatedusingthe“vegdist”functionoftheveganpackage(49)andused after7(experiment1),10(experiment2),or15d(experiment3),plantshoots for principal coordinates analysis using the “dudi.pco” function of the weresampled,driedovernightat65°C,digestedwith500μL66%HNO3at ADE4 package (50). Fungal alpha diversity was estimated in each sample 100°Cfor20minwithadditionof250μLH2O2,andheatedat100°Cfor1min. using the Shannon diversity index (H) calculated in Mothur. Means were Thesolutionwasdiluted1:10,and500μLwasmixedwith4.5mLofscintilla- comparedwithANOVAfollowedbyTukey’sHSD(P<0.05).PERMANOVAon tionmixture(Rotiszintecoplus;Roth)andusedfordetectionof33Psignals Bray–Curtis dissimilarities was conducted to study the effect of different with a scintillation counter (Beckman Coulter LS 6500). Between 5 and factorsonthestructureoffungalcommunitiesusingthe“Adonis”function 36plantswereanalyzedpertreatmentperexperiment.TheeffectofBenomyl oftheveganpackage(atP<0.05).Aspreviouslyperformedinastudyon on fungal 33P translocation across the compartments was studied in low-P metalbioaccumulationinplants(51),wecalculatedaP-accumulationfactor (100μMP)MSagarintheabsenceoftheplantbysamplinga1-cm2agar (P concentration in the plant shoot divided by the plant-available P con- piecefromtheRHC7dafteradditionof33PtotheHC(SIAppendix,Fig.S8A). centrationinthesoil).Plant-availablePinthesoil(SIAppendix,TableS2) ForBenomyl-treatedsamples,theHCwascoveredwith1mLofaBenomyl was measured using the ammonium-acetate EDTA extraction method (InstituteofOrganicIndustrialChemistry,Warsaw)solutionof3μg/mL(wt/vol), (AAE10)bytheLaboratoryforSoilAnalysis(Thun,Switzerland),andshootP andplateswereleftopentodryfor1hbeforeadditionof33PtotheHC.The wasmeasuredbyICP-MSasindicatedabove. restoftheexperimentwasconductedasdescribedabove.Theexperimentwas repeatedthreetimeswith5–20replicates. EffectofF229InoculationonA.alpinaGrowthinSterile-SoilMicrocosms.For sterile-soilmicrocosms,250gofsoilGal(lowplant-availableP:3.7mg/kg,SI Phylogenetic Analysis of F229 and Related Ascomycetes. The F229 genome Appendix,TableS2)wasputinto500-mLglassjars(Weck)andautoclaved (NCBIBioProjectPRJNA378526)wassequencedandannotatedasdescribedin twicewitha48-hinterval.SincefungusF229didnotsporulateunderour SIAppendix,MaterialsandMethods.Amultigenephylogeneticanalysiswas Almarioetal. PNAS | PublishedonlineOctober2,2017 | E9411 conductedon51ascomycetegenomesincludingF229.Aphylogenetictree anddifferencesintheabundanceofparticularCAZymesbetweengroupswere wasinferredfromfivehousekeepinggenes:28S,18S,Rpb1,Rpb2,andEF1α. assessedwithttests(P<0.01). Foreachgene,thenucleotidesequencesretrievedfromthegenomeswere OtherexperimentalproceduresaredescribedinSIAppendix,Materials aligned with MUSCLE (28), and informative positions were selected using andMethods. Gblockswithrelaxedparameters(52).Alignmentswereconcatenatedand used to compute a maximum-likelihood tree using PhyML (29) with the ACKNOWLEDGMENTS.WethankJanineAltmüllerandChristianBeckeratthe GTR+I+γmodelandtheSH-aLRT method forbranch-support(1,000itera- Cologne Center for Genomics (https://portal.ccg.uni-koeln.de) for help with tions)calculationusingSeaview(53). ampliconsequencing;theMaxPlanckGenomeCenterCologne(mpgc.mpipz. mpg.de) for fungal genome sequencing; the Station Alpine Joseph Fourier ComparativeAnalysisoftheAbundanceofCAZymesinF229andRelated (Jardin Botanique Alpin du Lautaret, https://www.jardinalpindulautaret.fr); Stefan Wötzel for plant cultivation; René Flisch (Agroscope Reckenholz) for Ascomycetes.TheabundanceofCAZymesintheF229genomewascom- providingsoil;NinaGerlach,SabineMetzger,StefanieJunkerman,andtheCo- paredwiththatof51otherascomycetesgenomeswithplant-beneficial,plant- logneBiocenterMassSpectrometryPlatformforICP-MSanalysis;andE.Kemen pathogenic, saprophytic, and plant unrelated lifestyles. 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E9412 | www.pnas.org/cgi/doi/10.1073/pnas.1710455114 Almarioetal.

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Most land plants live in association with arbuscular mycorrhizal. (AM) fungi and rely on this symbiosis to scavenge phosphorus (P) from soil. The ability to establish this partnership has been lost in some plant lineages like the Brassicaceae, which raises the question of what alternative nutrition
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