Grapevine(Vitis vinifera L.)is an economically important fruit crop in the world,and China ranks first in the production of grapes with approximately 15%of the world’s total yield.However,diseases that cause the deat...Grapevine(Vitis vinifera L.)is an economically important fruit crop in the world,and China ranks first in the production of grapes with approximately 15%of the world’s total yield.However,diseases that cause the death of grapevine shoots pose a severe threat to the production of grapes.In this study,the fungus Neopestalotiopsis eucalypti was identified as a causal pathogen of grapevine shoot rot based on the morphology of conidia and a phylogenetic analysis.The phylogenetic analysis was performed with three isolates based on the combined sequence of internal transcribed spacer(ITS)region of ribosomal DNA,part of the translation elongation factor 1-alpha(Tef)and theβ-tubulin(Tub2)genes.The three isolates were all identified as N.eucalypti.Pathogenicity tests of the three fungal isolates were conducted on grapevines shoots in vitro and in vivo.The results showed that all three fungal isolates caused severe rot lesions on the inoculated grapevine shoots,and N.eucalypti was re-isolated from the inoculated grapevine shoots.Therefore,N.eucalypti was confirmed as a causal agent of the grapevine shoot rot.This is the first report of N.eucalypti causing grapevine shoot disease in China.展开更多
Grapevines(Vitis vinifera)are colonized by ubiquitous microorganisms known as endophytes,which may have advantageous or neutral effects without causing disease symptoms.Certain endophytes are uncultivable,so culture-...Grapevines(Vitis vinifera)are colonized by ubiquitous microorganisms known as endophytes,which may have advantageous or neutral effects without causing disease symptoms.Certain endophytes are uncultivable,so culture-independent approaches such as next generation sequencing(NGS)can help for a better understanding of their ecology and distribution.To date,there are no studies which directly link NGS results with taxa derived from a culturing approach,integrating morphological and multi-gene phylogenetic analysis of endophytes.In this study,a culture-dependent and high-resolution culture-independent approach(next generation sequencing)were used to identify endophytes in grapevine stems.In the culture-dependent approach,a total of 94 isolates were recovered from 84 of 144 healthy grapevine stem fragments(colonization rate=58.3%).The study is unique as we used subsets of combined multi-gene regions to identify the endophytes to species level.Based on each multi-gene phylogenetic analysis,28 species belong to 19 genera(Acremonium,Alternaria,Arthrinium,Ascorhizoctonia,Aspergillus,Aureobasidium,Bipolaris,Botryosphaeria,Botrytis,Chaetomium,Cladosporium,Curvularia,Hypoxylon,Lasiodiplodia,Mycosphaerella,Nigrospora,Penicillium,Phoma,Scopulariopsis)were identified.A higher number of culturable fungi were obtained from 13 year-old vines,followed by eight and three yearold vines.In the culture-independent approach,a fungal richness of 59 operational taxonomic units(OTU)was detected,being highest in 13 year-old grapevines,followed by eight and three years.Even though the cultivation approach detected lower fungal richness,the results related to stem are consistent for fungal community composition and richness.Comparison of the fungal taxa identified by the two approaches resulted in an overlap of 53%of the fungal genera.Due to interspecific variability of the sequences from NGS,in many cases the OTUs(even with the highly abundant ones)were only assignable to order,family or genus level.Incorporating multi-gene phylogenies we successfully identified many of the NGS derived OTUs with poor taxonomic information in reference databases to the genus or species levels.Hence,this study signifies the importance of applying both culture-dependent and culture-independent approaches to study the fungal endophytic community composition in Vitis vinifera.This principle could also be applied to other host species and ecosystem level studies.展开更多
This study is unique as it compares traditional and high-resolution culture-independent approaches using the same set of samples to study the saprotrophic fungi on Vitis vinifera.We identified the saprotrophic communi...This study is unique as it compares traditional and high-resolution culture-independent approaches using the same set of samples to study the saprotrophic fungi on Vitis vinifera.We identified the saprotrophic communities of table grape(Red Globe)and wine grape(Carbanate Gernischet)in China using both traditional and culture-independent techniques.The traditional approach used direct observations based on morphology,single spore isolation and phylogenetic analysis yielding 45 taxa which 19 were commonly detected in both cultivars.The same set of samples were then used for Illumina sequencing which analyzed ITS1 sequence data and detected 226 fungal OTUs,of which 176 and 189 belong to the cultivars Carbanate Gernischet and Red Globe,respectively.There were 139 OTUs shared between the two V.vinifera cultivars and 37 and 50 OTUs were specific to Carbanate Gernischet and Red Globe cultivars respectively.In the Carbanate Gernischet cultivar,Ascomycota accounted for 77%of the OTUs and in Red Globe,almost all sequenced were Ascomycota.The fungal taxa overlap at the genus and species level between the traditional and culture-independent approach was relatively low.In the traditional approach we were able to identify the taxa to species level,while in the culture-independent method we were frequently able to identify the taxa to family or genus level.This is remarkable as we used the same set of samples collected in China for both approaches.We recommend the use of traditional techniques to accurately identify taxa.Culture-independent method can be used to get a better understanding about the organisms that are present in a host in its natural environment.We identified primary and secondary plant pathogens and endophytes in the saprotrophic fungal communities,which support previous observations,that dead plant material in grape vineyards can be the primary sources of disease.Finally,based on present and previous findings,we provide a worldwide checklist of 905 fungal taxa on Vitis species,which includes their mode of life and distribution.展开更多
Numerous new taxa and classifications of Dothideomycetes have been published following the last monograph of families of Dothideomycetes in 2013.A recent publication by Honsanan et al.in 2020 expanded information of f...Numerous new taxa and classifications of Dothideomycetes have been published following the last monograph of families of Dothideomycetes in 2013.A recent publication by Honsanan et al.in 2020 expanded information of families in Dothideo-mycetidae and Pleosporomycetidae with modern classifications.In this paper,we provide a refined updated document on orders and families incertae sedis of Dothideomycetes.Each family is provided with an updated description,notes,including figures to represent the morphology,a list of accepted genera,and economic and ecological significances.We also provide phylogenetic trees for each order.In this study,31 orders which consist 50 families are assigned as orders incertae sedis in Dothideomycetes,and 41 families are treated as families incertae sedis due to lack of molecular or morphological evidence.The new order,Catinellales,and four new families,Catinellaceae,Morenoinaceae Neobuelliellaceae and Thyrinulaceae are introduced.Seven genera(Neobuelliella,Pseudomicrothyrium,Flagellostrigula,Swinscowia,Macroconstrictolumina,Pseudobogoriella,and Schummia)are introduced.Seven new species(Acrospermum urticae,Bogoriella complexoluminata,Dothiorella ostryae,Dyfrolomyces distoseptatus,Macroconstrictolumina megalateralis,Patellaria microspora,and Pseu-domicrothyrium thailandicum)are introduced base on morphology and phylogeny,together with two new records/reports and five new collections from different families.Ninety new combinations are also provided in this paper.展开更多
Light signaling precisely controls photomorphogenic development in plants.PHYTOCHROME INTERACTING FACTOR 4 and 5(PIF4 and PIF5)play critical roles in the regulation of this developmental process.In this study,we repor...Light signaling precisely controls photomorphogenic development in plants.PHYTOCHROME INTERACTING FACTOR 4 and 5(PIF4 and PIF5)play critical roles in the regulation of this developmental process.In this study,we report CONSTITUTIVELY PHOTOMORPHOGENIC 1 SUPPRESSOR 6(CSU6)functions as a key regulator of light signaling.Loss of CSU6 function largely rescues the cop1-6 constitutively photomorphogenic phenotype.CSU6 promotes hypocotyl growth in the dark,but inhibits hypocotyl elongation in the light.CSU6 not only associates with the promoter regions of PIF4 and PIF5 to inhibit their expression in the morning,but also directly interacts with both PIF4 and PIF5 to repress their transcriptional activation activity.CSU6 negatively controls a group of PIF4-and PIF5-regulated gene expressions.Mutations in PIF4 and/or PIF5 are epistatic to the loss of CSU6,suggesting that CSU6 acts upstream of PIF4 and PIF5.Taken together,CSU6 promotes light-inhibited hypocotyl elongation by negatively regulating PIF4 and PIF5 transcription and biochemical activity.展开更多
When attacked by pathogens,plants need to reallocate energy from growth to defense to fend off the invaders,frequently incurring growth penalties.This phenomenon is known as the growth–defense tradeoff and is orchest...When attacked by pathogens,plants need to reallocate energy from growth to defense to fend off the invaders,frequently incurring growth penalties.This phenomenon is known as the growth–defense tradeoff and is orchestrated by a hardwired transcriptional network.Altering key factors involved in this network has the potential to increase disease resistance without growth or yield loss,but the mechanisms underlying such changes require further investigation.By conducting a genome-wide association study(GWAS)of leaves infected by the hemi-biotrophic bacterial pathogen Pseudomonas syringae pv.tomato(Pst)DC3000,we discovered that the Arabidopsis transcription factor REPLUMLESS(RPL)is necessary for bacterial resistance.More importantly,RPL functions in promoting both disease resistance and growth.Transcriptome analysis revealed a cluster of genes in the GRETCHEN HAGEN 3(GH3)family that were significantly upregulated in rpl mutants,leading to the accumulation of indole-3-acetic acid-aspartic acid(IAA-Asp).Consistent with this observation,transcripts of virulence effector genes were activated by IAA-Asp accumulated in the rpl mutants.We found that RPL protein could directly bind to GH3 promoters and repress their expression.RPL also repressed flavonol synthesis by directly repressing CHI expression and thus activated the auxin transport pathway,which promotes plant growth.Therefore,RPL plays an important role in plant immunity and functions in the auxin pathway to optimize Arabidopsis growth and defense.展开更多
This article is the 13th contribution in the Fungal Diversity Notes series,wherein 125 taxa from four phyla,ten classes,31 orders,69 families,92 genera and three genera incertae sedis are treated,demonstrating worldwi...This article is the 13th contribution in the Fungal Diversity Notes series,wherein 125 taxa from four phyla,ten classes,31 orders,69 families,92 genera and three genera incertae sedis are treated,demonstrating worldwide and geographic distri-bution.Fungal taxa described and illustrated in the present study include three new genera,69 new species,one new com-bination,one reference specimen and 51 new records on new hosts and new geographical distributions.Three new genera,Cylindrotorula(Torulaceae),Scolecoleotia(Leotiales genus incertae sedis)and Xenovaginatispora(Lindomycetaceae)are introduced based on distinct phylogenetic lineages and unique morphologies.Newly described species are Aspergillus lan-naensis,Cercophora dulciaquae,Cladophialophora aquatica,Coprinellus punjabensis,Cortinarius alutarius,C.mammil-latus,C.quercoflocculosus,Coryneum fagi,Cruentomycena uttarakhandina,Cryptocoryneum rosae,Cyathus uniperidiolus,Cylindrotorula indica,Diaporthe chamaeropicola,Didymella azollae,Diplodia alanphillipsii,Dothiora coronicola,Efibula rodriguezarmasiae,Erysiphe salicicola,Fusarium queenslandicum,Geastrum gorgonicum,G.hansagiense,Helicosporium sexualis,Helminthosporium chiangraiensis,Hongkongmyces kokensis,Hydrophilomyces hydraenae,Hygrocybe boertmannii,Hyphoderma australosetigerum,Hyphodontia yunnanensis,Khaleijomyces umikazeana,Laboulbenia divisa,Laboulbenia triarthronis,Laccaria populina,Lactarius pallidozonarius,Lepidosphaeria strobelii,Longipedicellata megafusiformis,Lophiotrema lincangensis,Marasmius benghalensis,M.jinfoshanensis,M.subtropicus,Mariannaea camelliae,Mel-anographium smilaxii,Microbotryum polycnemoides,Mimeomyces digitatus,Minutisphaera thailandensis,Mortierella solitaria,Mucor harpali,Nigrograna jinghongensis,Odontia huanrenensis,O.parvispina,Paraconiothyrium ajrekarii,Par-afuscosporella niloticus,Phaeocytostroma yomensis,Phaeoisaria synnematicus,Phanerochaete hainanensis,Pleopunctum thailandicum,Pleurotheciella dimorphospora,Pseudochaetosphaeronema chiangraiense,Pseudodactylaria albicolonia,Rhexoacrodictys nigrospora,Russula paravioleipes,Scolecoleotia eriocamporesi,Seriascoma honghense,Synandromyces makranczyi,Thyridaria aureobrunnea,Torula lancangjiangensis,Tubeufia longihelicospora,Wicklowia fusiformispora,Xenovaginatispora phichaiensis and Xylaria apiospora.One new combination,Pseudobactrodesmium stilboideus is pro-posed.A reference specimen of Comoclathris permunda is designated.New host or distribution records are provided for Acrocalymma fici,Aliquandostipite khaoyaiensis,Camarosporidiella laburni,Canalisporium caribense,Chaetoscutula juniperi,Chlorophyllum demangei,C.globosum,C.hortense,Cladophialophora abundans,Dendryphion hydei,Diaporthe foeniculina,D.pseudophoenicicola,D.pyracanthae,Dictyosporium pandanicola,Dyfrolomyces distoseptatus,Ernakula-mia tanakae,Eutypa flavovirens,E.lata,Favolus septatus,Fusarium atrovinosum,F.clavum,Helicosporium luteosporum,Hermatomyces nabanheensis,Hermatomyces sphaericoides,Longipedicellata aquatica,Lophiostoma caudata,L.clematidis-vitalbae,Lophiotrema hydei,L.neoarundinaria,Marasmiellus palmivorus,Megacapitula villosa,Micropsalliota globocys-tis,M.gracilis,Montagnula thailandica,Neohelicosporium irregulare,N.parisporum,Paradictyoarthrinium diffractum,Phaeoisaria aquatica,Poaceascoma taiwanense,Saproamanita manicata,Spegazzinia camelliae,Submersispora variabi-lis,Thyronectria caudata,T.mackenziei,Tubeufia chiangmaiensis,T.roseohelicospora,Vaginatispora nypae,Wicklowia submersa,Xanthagaricus necopinatus and Xylaria haemorrhoidalis.The data presented herein are based on morphological examination of fresh specimens,coupled with analysis of phylogenetic sequence data to better integrate taxa into appropriate taxonomic ranks and infer their evolutionary relationships.展开更多
This article is the tenth series of the Fungal Diversity Notes,where 114 taxa distributed in three phyla,ten classes,30 orders and 53 families are described and illustrated.Taxa described in the present study include ...This article is the tenth series of the Fungal Diversity Notes,where 114 taxa distributed in three phyla,ten classes,30 orders and 53 families are described and illustrated.Taxa described in the present study include one new family(viz.Pseudoberkleasmiaceae in Dothideomycetes),five new genera(Caatingomyces,Cryptoschizotrema,Neoacladium,Paramassaria and Trochilispora)and 71 new species,(viz.Acrogenospora thailandica,Amniculicola aquatica,A.guttulata,Angustimassarina sylvatica,Blackwellomyces lateris,Boubovia gelatinosa,Buellia viridula,Caatingomyces brasiliensis,Calophoma humuli,Camarosporidiella mori,Canalisporium dehongense,Cantharellus brunneopallidus,C.griseotinctus,Castanediella meliponae,Coprinopsis psammophila,Cordyceps succavus,Cortinarius minusculus,C.subscotoides,Diaporthe italiana,D.rumicicola,Diatrypella delonicis,Dictyocheirospora aquadulcis,D.taiwanense,Digitodesmium chiangmaiense,Distoseptispora dehongensis,D.palmarum,Dothiorella styphnolobii,Ellisembia aurea,Falciformispora aquatic,Fomitiporia carpinea,F.lagerstroemiae,Grammothele aurantiaca,G.micropora,Hermatomyces bauhiniae,Jahnula queenslandica,Kamalomyces mangrovei,Lecidella yunnanensis,Micarea squamulosa,Muriphaeosphaeria angustifoliae,Neoacladium indicum,Neodidymelliopsis sambuci,Neosetophoma miscanthi,N.salicis,Nodulosphaeria aquilegiae,N.thalictri,Paramassaria samaneae,Penicillium circulare,P.geumsanense,P.mali-pumilae,P.psychrotrophicum,P.wandoense,Phaeoisaria siamensis,Phaeopoacea asparagicola,Phaeosphaeria penniseti,Plectocarpon galapagoense,Porina sorediata,Pseudoberkleasmium chiangmaiense,Pyrenochaetopsis sinensis,Rhizophydium koreanum,Russula prasina,Sporoschisma chiangraiense,Stigmatomyces chamaemyiae,S.cocksii,S.papei,S.tschirnhausii,S.vikhrevii,Thysanorea uniseptata,Torula breviconidiophora,T.polyseptata,Trochilispora schefflerae and Vaginatispora palmae).Further,twelve new combinations(viz.Cryptoschizotrema cryptotrema,Prolixandromyces australi,P.elongatus,P.falcatus,P.longispinae,P.microveliae,P.neoalardi,P.polhemorum,P.protuberans,P.pseudoveliae,P.tenuistipitis and P.umbonatus),an epitype is chosen for Cantharellus goossensiae,a reference specimen for Acrogenospora sphaerocephala and new synonym Prolixandromyces are designated.Twenty-four new records on new hosts and new geographical distributions are also reported(i.e.Acrostalagmus annulatus,Cantharellus goossensiae,Coprinopsis villosa,Dothiorella plurivora,Dothiorella rhamni,Dothiorella symphoricarposicola,Dictyocheirospora rotunda,Fasciatispora arengae,Grammothele brasiliensis,Lasiodiplodia iraniensis,Lembosia xyliae,Morenoina palmicola,Murispora cicognanii,Neodidymelliopsis farokhinejadii,Neolinocarpon rachidis,Nothophoma quercina,Peroneutypa scoparia,Pestalotiopsis aggestorum,Pilidium concavum,Plagiostoma salicellum,Protofenestella ulmi,Sarocladium kiliense,Tetraploa nagasakiensis and Vaginatispora armatispora).展开更多
Fungi are an understudied,biotechnologically valuable group of organisms.Due to the immense range of habitats that fungi inhabit,and the consequent need to compete against a diverse array of other fungi,bacteria,and a...Fungi are an understudied,biotechnologically valuable group of organisms.Due to the immense range of habitats that fungi inhabit,and the consequent need to compete against a diverse array of other fungi,bacteria,and animals,fungi have developed numerous survival mechanisms.The unique attributes of fungi thus herald great promise for their application in biotechnology and industry.Moreover,fungi can be grown with relative ease,making production at scale viable.The search for fungal biodiversity,and the construction of a living fungi collection,both have incredible economic potential in locating organisms with novel industrial uses that will lead to novel products.This manuscript reviews fifty ways in which fungi can potentially be utilized as biotechnology.We provide notes and examples for each potential exploitation and give examples from our own work and the work of other notable researchers.We also provide a flow chart that can be used to convince funding bodies of the importance of fungi for biotechnological research and as potential products.Fungi have provided the world with penicillin,lovastatin,and other globally significant medicines,and they remain an untapped resource with enormous industrial potential.展开更多
Sexual reproduction is the basic way to form high genetic diversity and it is beneficial in evolution and speciation of fungi.The global diversity of teleomorphic species in Ascomycota has not been estimated.This pape...Sexual reproduction is the basic way to form high genetic diversity and it is beneficial in evolution and speciation of fungi.The global diversity of teleomorphic species in Ascomycota has not been estimated.This paper estimates the species number for sexual ascomycetes based on five different estimation approaches,viz.by numbers of described fungi,by fungus:substrate ratio,by ecological distribution,by meta-DNA barcoding or culture-independent studies and by previous estimates of species in Ascomycota.The assumptions were made with the currently most accepted,“2.2–3.8 million”species estimate and results of previous studies concluding that 90%of the described ascomycetes reproduce sexually.The Catalogue of Life,Species Fungorum and published research were used for data procurement.The average value of teleomorphic species in Ascomycota from all methods is 1.86 million,ranging from 1.37 to 2.56 million.However,only around 83,000 teleomorphic species have been described in Ascomycota and deposited in data repositories.The ratio between described teleomorphic ascomycetes to predicted teleomorphic ascomycetes is 1:22.Therefore,where are the undiscovered teleomorphic ascomycetes?The undescribed species are no doubt to be found in biodiversity hot spots,poorly-studied areas and species complexes.Other poorly studied niches include extremophiles,lichenicolous fungi,human pathogens,marine fungi,and fungicolous fungi.Undescribed species are present in unexamined collections in specimen repositories or incompletely described earlier spe-cies.Nomenclatural issues,such as the use of separate names for teleomorph and anamorphs,synonyms,conspecific names,illegitimate and invalid names also affect the number of described species.Interspecies introgression results in new species,while species numbers are reduced by extinctions.展开更多
Fungi are an understudied resource possessing huge potential for developing products that can greatly improve human well-being.In the current paper,we highlight some important discoveries and developments in applied m...Fungi are an understudied resource possessing huge potential for developing products that can greatly improve human well-being.In the current paper,we highlight some important discoveries and developments in applied mycology and interdisciplinary Life Science research.These examples concern recently introduced drugs for the treatment of infections and neurological diseases;application of–OMICS techniques and genetic tools in medical mycology and the regulation of mycotoxin production;as well as some highlights of mushroom cultivaton in Asia.Examples for new diagnostic tools in medical mycology and the exploitation of new candidates for therapeutic drugs,are also given.In addition,two entries illustrating the latest developments in the use of fungi for biodegradation and fungal biomaterial production are provided.Some other areas where there have been and/or will be significant developments are also included.It is our hope that this paper will help realise the importance of fungi as a potential industrial resource and see the next two decades bring forward many new fungal and fungus-derived products.展开更多
基金the financial support from the earmarked fund for China Agriculture Research System(CARS-27)
文摘Grapevine(Vitis vinifera L.)is an economically important fruit crop in the world,and China ranks first in the production of grapes with approximately 15%of the world’s total yield.However,diseases that cause the death of grapevine shoots pose a severe threat to the production of grapes.In this study,the fungus Neopestalotiopsis eucalypti was identified as a causal pathogen of grapevine shoot rot based on the morphology of conidia and a phylogenetic analysis.The phylogenetic analysis was performed with three isolates based on the combined sequence of internal transcribed spacer(ITS)region of ribosomal DNA,part of the translation elongation factor 1-alpha(Tef)and theβ-tubulin(Tub2)genes.The three isolates were all identified as N.eucalypti.Pathogenicity tests of the three fungal isolates were conducted on grapevines shoots in vitro and in vivo.The results showed that all three fungal isolates caused severe rot lesions on the inoculated grapevine shoots,and N.eucalypti was re-isolated from the inoculated grapevine shoots.Therefore,N.eucalypti was confirmed as a causal agent of the grapevine shoot rot.This is the first report of N.eucalypti causing grapevine shoot disease in China.
基金This work was financially supported by Beijing Talent Program for Dr.Jiye Yan,CARS-29,Beijing science and technology project D17110001617002We thank Dr.Heng Gui for his support to submit Raw Illumina reads to the Sequence Read Archive(SRA)of National Center for Biotechnology Information(NCBI).
文摘Grapevines(Vitis vinifera)are colonized by ubiquitous microorganisms known as endophytes,which may have advantageous or neutral effects without causing disease symptoms.Certain endophytes are uncultivable,so culture-independent approaches such as next generation sequencing(NGS)can help for a better understanding of their ecology and distribution.To date,there are no studies which directly link NGS results with taxa derived from a culturing approach,integrating morphological and multi-gene phylogenetic analysis of endophytes.In this study,a culture-dependent and high-resolution culture-independent approach(next generation sequencing)were used to identify endophytes in grapevine stems.In the culture-dependent approach,a total of 94 isolates were recovered from 84 of 144 healthy grapevine stem fragments(colonization rate=58.3%).The study is unique as we used subsets of combined multi-gene regions to identify the endophytes to species level.Based on each multi-gene phylogenetic analysis,28 species belong to 19 genera(Acremonium,Alternaria,Arthrinium,Ascorhizoctonia,Aspergillus,Aureobasidium,Bipolaris,Botryosphaeria,Botrytis,Chaetomium,Cladosporium,Curvularia,Hypoxylon,Lasiodiplodia,Mycosphaerella,Nigrospora,Penicillium,Phoma,Scopulariopsis)were identified.A higher number of culturable fungi were obtained from 13 year-old vines,followed by eight and three yearold vines.In the culture-independent approach,a fungal richness of 59 operational taxonomic units(OTU)was detected,being highest in 13 year-old grapevines,followed by eight and three years.Even though the cultivation approach detected lower fungal richness,the results related to stem are consistent for fungal community composition and richness.Comparison of the fungal taxa identified by the two approaches resulted in an overlap of 53%of the fungal genera.Due to interspecific variability of the sequences from NGS,in many cases the OTUs(even with the highly abundant ones)were only assignable to order,family or genus level.Incorporating multi-gene phylogenies we successfully identified many of the NGS derived OTUs with poor taxonomic information in reference databases to the genus or species levels.Hence,this study signifies the importance of applying both culture-dependent and culture-independent approaches to study the fungal endophytic community composition in Vitis vinifera.This principle could also be applied to other host species and ecosystem level studies.
基金s This work was financially supported by Beijing Talent Programm for Jiye Yan,CARS-29 and JNKYT201605.
文摘This study is unique as it compares traditional and high-resolution culture-independent approaches using the same set of samples to study the saprotrophic fungi on Vitis vinifera.We identified the saprotrophic communities of table grape(Red Globe)and wine grape(Carbanate Gernischet)in China using both traditional and culture-independent techniques.The traditional approach used direct observations based on morphology,single spore isolation and phylogenetic analysis yielding 45 taxa which 19 were commonly detected in both cultivars.The same set of samples were then used for Illumina sequencing which analyzed ITS1 sequence data and detected 226 fungal OTUs,of which 176 and 189 belong to the cultivars Carbanate Gernischet and Red Globe,respectively.There were 139 OTUs shared between the two V.vinifera cultivars and 37 and 50 OTUs were specific to Carbanate Gernischet and Red Globe cultivars respectively.In the Carbanate Gernischet cultivar,Ascomycota accounted for 77%of the OTUs and in Red Globe,almost all sequenced were Ascomycota.The fungal taxa overlap at the genus and species level between the traditional and culture-independent approach was relatively low.In the traditional approach we were able to identify the taxa to species level,while in the culture-independent method we were frequently able to identify the taxa to family or genus level.This is remarkable as we used the same set of samples collected in China for both approaches.We recommend the use of traditional techniques to accurately identify taxa.Culture-independent method can be used to get a better understanding about the organisms that are present in a host in its natural environment.We identified primary and secondary plant pathogens and endophytes in the saprotrophic fungal communities,which support previous observations,that dead plant material in grape vineyards can be the primary sources of disease.Finally,based on present and previous findings,we provide a worldwide checklist of 905 fungal taxa on Vitis species,which includes their mode of life and distribution.
基金National Natural Science Foundation of China for supporting the project Biodiversity,Taxonomy,Phylogeny,Evolution and Phytogeography of phytopathogens in Dothideomycetes from Southern China(Grant No.31950410548)for funding this research.Ning Xie would like to thank Project of DEGP(2019KTSCX150)+29 种基金.Kevin D Hyde thanks the Thailand Research Fund for the grant RDG6130001 entitled“Impact of climate change on fungal diversity and biogeography in the Greater Mekong Subregion”.Rungtiwa Phookamsak thanks CAS President’s International Fellowship Initiative(PIFI)for young staff(Grant No.Y9215811Q1)the Yunnan Provincial Department of Human Resources and Social Security(Grant No.Y836181261)National Science Foundation of China(NSFC)project code 31850410489(Grant No.Y81I982211)for financial supportDhanushka Wanasinghe would like to thank CAS President’s International Fellowship Initiative(PIFI)for funding his postdoctoral research(number 2019PC0008)the 64th batch of China Postdoctoral Science Foundation(Grant No.Y913083271).Vemuri V.Sarma would like to thank SERB,Department of Science and Technology,Government of India,for funding a project(SERB/SB/SO/PS/18/2014 dt.19.5.2015)Ministry of Earth Sciences(MOES),Govt.of India for funding a project(Sanction order:MOES/36/OO1S/Extra/40/2014/PC-IV dt.14.01.2015)the Department of Biotechnology,Pondicherry University for facilitiesthe National Research Council of Thailand(projects no.61215320013 and No.61215320023)the Thailand Research Fund(project no.TRG6180001)Plant Genetic Conservation Project under the Royal Initiation of Her Royal High-ness Princess Maha Chakri Sirindhorn-Mae Fah Luang University.Alan JL Phillips acknowledges the support from UIDB/04046/2020 and UIDP/04046/2020 Centre grants from FCT,Portugal(to Bio-ISI).Saowaluck Tibpromma would like to thank the International Postdoctoral Exchange Fellowship Program(number Y9180822S1)CAS President’s International Fellowship Initiative(PIFI)(number 2020PC0009)the National Natural Science Foundation of China(Project Nos.31800010 and 31750001)for financial support.the National Natural Science Foundation of China(No.NSFC 31950410558)Guizhou Medical University(grant number FAMP201906K)tthe National Nat-ural Science Foundation of China(No.NSFC 31760013)the Scientific Research Foundation of Yunnan Provincial Department of Education(2017ZZX186)the Thousand Talents Plan,Youth Project of Yun-nan Provinces for finance supportthe 5th batch of Postdoctoral Orientation Training Personnel in Yunnan Province(Grant No.Y934283261)the 64th batch of China Postdoctoral Science Foundation(Grant No.Y913082271)M Niranjan thanks SERB,Govt.of India for a fellow-ship.Huang Zhang would like to thank Natural Science Foundation of China(NSF 31500017).Jadson DP Bezerra thanks the Conselho Nacional de Desenvolvimento Científico e Tecnológico(CNPq),the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior(CAPES,Finance Code 001)the Fundação de AmparoàCiência e Tecnologia de Pernambuco(FACEPE)for fellowship.B.Devadatha thanks MOES,Govt.of India for a fellowship.Hai-Xia Wu would like to the Fundamental Research Funds for the Central Non-profit Research Institution of CAF(Grant No.CAFYBB2019QB005)the Ten Thousand Talents Plan,Youth Top Project of Yunnan Provinces for finance support.Ausana Mapook thanks to Research and Research-ers for Industries(RRI)under Thailand Research Fund for a personal grant(PHD57I0012)Putarak Chomnunti would like to thank Mae Fah Luang University(Grant No.DR256201012003)Diversity-Based Economy Development Office and National Research Council of Thailand Research(Grant No.T2561022)for the financial support.Satinee Suetrong thanks the collaborative project between BIOTEC and Department of Marine and Coastal Resources(DMCR),Ministry of Natural Resources and Environmentunder a project:Marine Microbes for National Reserves:Alternative Ways of State Property.N.Chai-wan would like to thank the Thailand Research Fund(PHD60K0147).
文摘Numerous new taxa and classifications of Dothideomycetes have been published following the last monograph of families of Dothideomycetes in 2013.A recent publication by Honsanan et al.in 2020 expanded information of families in Dothideo-mycetidae and Pleosporomycetidae with modern classifications.In this paper,we provide a refined updated document on orders and families incertae sedis of Dothideomycetes.Each family is provided with an updated description,notes,including figures to represent the morphology,a list of accepted genera,and economic and ecological significances.We also provide phylogenetic trees for each order.In this study,31 orders which consist 50 families are assigned as orders incertae sedis in Dothideomycetes,and 41 families are treated as families incertae sedis due to lack of molecular or morphological evidence.The new order,Catinellales,and four new families,Catinellaceae,Morenoinaceae Neobuelliellaceae and Thyrinulaceae are introduced.Seven genera(Neobuelliella,Pseudomicrothyrium,Flagellostrigula,Swinscowia,Macroconstrictolumina,Pseudobogoriella,and Schummia)are introduced.Seven new species(Acrospermum urticae,Bogoriella complexoluminata,Dothiorella ostryae,Dyfrolomyces distoseptatus,Macroconstrictolumina megalateralis,Patellaria microspora,and Pseu-domicrothyrium thailandicum)are introduced base on morphology and phylogeny,together with two new records/reports and five new collections from different families.Ninety new combinations are also provided in this paper.
基金supported by the National Natural Science Foundation of China(Grant Nos 32100199,31900210,and 31970258)the Peking-Tsinghua Center for Life Sciences(to X.W.D)+4 种基金the Southern University of Science and Technology(to X.W.D)the Jiangsu Natural Science Foundation for Distinguished Young Scholars(Grant No.BK20211525)the Jiangsu"Innovativeand Entrepreneurial Talent"program(to D.X.)the Nanjing Agricultural University(start-up funding to D.X.)the Jiangsu Collaborative Innovation Center for Modern Crop Production(to D.X.).
文摘Light signaling precisely controls photomorphogenic development in plants.PHYTOCHROME INTERACTING FACTOR 4 and 5(PIF4 and PIF5)play critical roles in the regulation of this developmental process.In this study,we report CONSTITUTIVELY PHOTOMORPHOGENIC 1 SUPPRESSOR 6(CSU6)functions as a key regulator of light signaling.Loss of CSU6 function largely rescues the cop1-6 constitutively photomorphogenic phenotype.CSU6 promotes hypocotyl growth in the dark,but inhibits hypocotyl elongation in the light.CSU6 not only associates with the promoter regions of PIF4 and PIF5 to inhibit their expression in the morning,but also directly interacts with both PIF4 and PIF5 to repress their transcriptional activation activity.CSU6 negatively controls a group of PIF4-and PIF5-regulated gene expressions.Mutations in PIF4 and/or PIF5 are epistatic to the loss of CSU6,suggesting that CSU6 acts upstream of PIF4 and PIF5.Taken together,CSU6 promotes light-inhibited hypocotyl elongation by negatively regulating PIF4 and PIF5 transcription and biochemical activity.
基金This study was supported by grants from the National Natural Science Foundation of China(31871221 and 31621001)the State Key Laboratory of Protein and Plant Gene Research,and the Peking-Tsinghua Center for Life Sciences(to X.W.D.).
文摘When attacked by pathogens,plants need to reallocate energy from growth to defense to fend off the invaders,frequently incurring growth penalties.This phenomenon is known as the growth–defense tradeoff and is orchestrated by a hardwired transcriptional network.Altering key factors involved in this network has the potential to increase disease resistance without growth or yield loss,but the mechanisms underlying such changes require further investigation.By conducting a genome-wide association study(GWAS)of leaves infected by the hemi-biotrophic bacterial pathogen Pseudomonas syringae pv.tomato(Pst)DC3000,we discovered that the Arabidopsis transcription factor REPLUMLESS(RPL)is necessary for bacterial resistance.More importantly,RPL functions in promoting both disease resistance and growth.Transcriptome analysis revealed a cluster of genes in the GRETCHEN HAGEN 3(GH3)family that were significantly upregulated in rpl mutants,leading to the accumulation of indole-3-acetic acid-aspartic acid(IAA-Asp).Consistent with this observation,transcripts of virulence effector genes were activated by IAA-Asp accumulated in the rpl mutants.We found that RPL protein could directly bind to GH3 promoters and repress their expression.RPL also repressed flavonol synthesis by directly repressing CHI expression and thus activated the auxin transport pathway,which promotes plant growth.Therefore,RPL plays an important role in plant immunity and functions in the auxin pathway to optimize Arabidopsis growth and defense.
文摘In the section Biodiversity hotspots,the origin of most ascomycetous type collections was incorrectly worded.The original article has been corrected.
基金the Thailand Research Fund(Grant No.TRG6180001)the Mae Fah Luang University Fund(Grant No.631C15001)+42 种基金Plant Genetic Conserva-tion Project under the Royal Initiation of Her Royal Highness Princess Maha Chakri Sirindhorn-Mae Fah Luang Universitythe Mushroom Research Foundation.Kevin D.Hyde thanks the 2019 high-end foreign expert introduction plan to Kunming Institute of Botany(Granted by the Ministry of Science and Technology of the People’s Republic of China,Grant No.G20190139006)the future of specialist fungi in a changing climate:baseline data for generalist and specialist fungi associated with ants,Rhododendron species and Dra-caena species(Grant No.DBG6080013)Impact of climate change on fungal diversity and biogeography in the Greater Mekong Subregion(Grant No.RDG6130001)Dhanushka Wanasinghe thanks CAS President’s International Fellowship Initiative(PIFI)for funding his postdoctoral research(Grant No.2021FYB0005)the Postdoctoral Fund from Human Resources and Social Security Bureau of Yunnan Province.the National Natural Science Foundation of China(Nos.31870011,31750001,31770028 and 31970017).CAS President’s International Fellowship Initiative(PIFI)for young staff(Grant No.Y9215811Q1)Provincial Science and Tech-nology Department(grant no.202003AD150004)Yunnan Provincial Key Programs of Yunnan Eco-friendly Food International Cooperation Research Center(Grant No.2019ZG00908)Key Research Program of Frontier Sciences“Response of Asian mountain ecosystems to global change”,CAS,Grant No.QYZDY-SSWSMC014”the Agreement ENDESA and San Ignacio de Huinay Foundations and Consejo Superior de Investiga-ciones Científicas,CSIC(Projects No.2011HUIN10,2013CL0012)and DGICYT projects CGL2005-01192/BOS,CGL2009-07231,CGL2015-67459-P,CSIC project PIE202030E059the Polish Ministry of Science and Higher Education(grant No.N N305299640)the support from UIDB/04046/2020 and UIDP/04046/2020 Centre grants from FCT,Portugal(to BioISI).the University of Southern Queensland and the Grains Research and Development Corporation projects DAQ00186 and DAQ00194the Japan Society for the Promotion of Science(JSPS)for the award of post-doctoral fellowship and the research grants(No.185701000001 and No.18-06620)the National Natural Science Foundation of China(Nos.31500013,30770013)Talent Introduction Scientific Research Special Project of Hebei Agricultural University(YJ201849)the Ear-marked Fund for Hebei Edible Fungi Innovation Team of Modern Agro-industry Technology Research System(Project ID:HBCT2018050205).SERB,Department of Science and Technology,Government of India,for funding a project(SERB/SB/SO/PS/18/2014 dt.19.5.2015)the Department of Biotechnology,Pondicherry Univer-sity for facilitiesSERB,Department of Science and Technology,Government of India for providing financial support under the project YSS/2015/001590the Second Tibetan Plateau Scientific Expedition and Research(STEP)Program[Grant No.2019QZKK0503]the open research project of“Cross Cooperative Team”of the Germplasm Bank of Wild Species,Kunming Institute of Botany,Chinese Academy of Sciences[Grant No.292019312511043]Science and Technology Ser-vice Network Initiative,Chinese Academy of Sciences[KFJ-STS-QYZD-171]S.N.Wijesinghe would like to acknowledge Mae Fah Luang University,National Science Foundation of China(NSFC)pro-ject code 31851110759National Natural Science Foundation of China(No.31972222,31560489)Program of Introducing Talents of Discipline to Universities of China(111 Program,D20023)Talent Project of Guizhou Science and Technology Cooperation Platform([2017]5788-5,[2019]5641 and[2020]5001)Guizhou Science,Tech-nology Department International Cooperation Basic project([2018]5806)the National Natural Science Foundation of China(Project ID:31970021 and 32060005)Fungal Diversity Conservation and Utilization Innovation Team of Dali University(ZKLX2019213)for financial support.the National Natural Sci-ence Foundation of China(NSFC 32060013)Youth Science and Technology Talent Development Project from Guizhou Provincial Department of Education(QJHKYZ[2021]263)Dan-Feng Bao would like to thank the National Natural Science Foundation of China(Project ID:31660008 and 31860006)Fungal diversity conservation and uti-lization innovation team(ZKLX2019213)the Thailand Research Fund grant“impact of climate change on fungal diversity and bioge-ography in the Greater Mekong Sub-region(RDG6130001)”for finan-cial and laboratory support.Higher Educa-tion Commission,Pakistan for financial support through NRPU research project no.20-3383/NRPU/R&D/HEC/14/184.the Széchenyi 2020 Programme(Grant No.GINOP 2.2.1-15-2017-00042)the FWF and the Land Tirol for funding the MICINSNOW project(P31038)the Ministry of Ecology and Environment of China(Project No.2019HJ2096001006)the Science and Technology Support Project of Guizhou Province(Project No.20192451-2)for research support.Yusufjon Gafforov acknowledges Ministry of Innovative Development of the Republic of Uzbekistan(Project no.P3-2014-0830174425 and PЗ-20170921183)CAS President’s International Fellowship Initiative(PIFI)for a Visiting Scientist grant(no.:2018VBB0021).
文摘This article is the 13th contribution in the Fungal Diversity Notes series,wherein 125 taxa from four phyla,ten classes,31 orders,69 families,92 genera and three genera incertae sedis are treated,demonstrating worldwide and geographic distri-bution.Fungal taxa described and illustrated in the present study include three new genera,69 new species,one new com-bination,one reference specimen and 51 new records on new hosts and new geographical distributions.Three new genera,Cylindrotorula(Torulaceae),Scolecoleotia(Leotiales genus incertae sedis)and Xenovaginatispora(Lindomycetaceae)are introduced based on distinct phylogenetic lineages and unique morphologies.Newly described species are Aspergillus lan-naensis,Cercophora dulciaquae,Cladophialophora aquatica,Coprinellus punjabensis,Cortinarius alutarius,C.mammil-latus,C.quercoflocculosus,Coryneum fagi,Cruentomycena uttarakhandina,Cryptocoryneum rosae,Cyathus uniperidiolus,Cylindrotorula indica,Diaporthe chamaeropicola,Didymella azollae,Diplodia alanphillipsii,Dothiora coronicola,Efibula rodriguezarmasiae,Erysiphe salicicola,Fusarium queenslandicum,Geastrum gorgonicum,G.hansagiense,Helicosporium sexualis,Helminthosporium chiangraiensis,Hongkongmyces kokensis,Hydrophilomyces hydraenae,Hygrocybe boertmannii,Hyphoderma australosetigerum,Hyphodontia yunnanensis,Khaleijomyces umikazeana,Laboulbenia divisa,Laboulbenia triarthronis,Laccaria populina,Lactarius pallidozonarius,Lepidosphaeria strobelii,Longipedicellata megafusiformis,Lophiotrema lincangensis,Marasmius benghalensis,M.jinfoshanensis,M.subtropicus,Mariannaea camelliae,Mel-anographium smilaxii,Microbotryum polycnemoides,Mimeomyces digitatus,Minutisphaera thailandensis,Mortierella solitaria,Mucor harpali,Nigrograna jinghongensis,Odontia huanrenensis,O.parvispina,Paraconiothyrium ajrekarii,Par-afuscosporella niloticus,Phaeocytostroma yomensis,Phaeoisaria synnematicus,Phanerochaete hainanensis,Pleopunctum thailandicum,Pleurotheciella dimorphospora,Pseudochaetosphaeronema chiangraiense,Pseudodactylaria albicolonia,Rhexoacrodictys nigrospora,Russula paravioleipes,Scolecoleotia eriocamporesi,Seriascoma honghense,Synandromyces makranczyi,Thyridaria aureobrunnea,Torula lancangjiangensis,Tubeufia longihelicospora,Wicklowia fusiformispora,Xenovaginatispora phichaiensis and Xylaria apiospora.One new combination,Pseudobactrodesmium stilboideus is pro-posed.A reference specimen of Comoclathris permunda is designated.New host or distribution records are provided for Acrocalymma fici,Aliquandostipite khaoyaiensis,Camarosporidiella laburni,Canalisporium caribense,Chaetoscutula juniperi,Chlorophyllum demangei,C.globosum,C.hortense,Cladophialophora abundans,Dendryphion hydei,Diaporthe foeniculina,D.pseudophoenicicola,D.pyracanthae,Dictyosporium pandanicola,Dyfrolomyces distoseptatus,Ernakula-mia tanakae,Eutypa flavovirens,E.lata,Favolus septatus,Fusarium atrovinosum,F.clavum,Helicosporium luteosporum,Hermatomyces nabanheensis,Hermatomyces sphaericoides,Longipedicellata aquatica,Lophiostoma caudata,L.clematidis-vitalbae,Lophiotrema hydei,L.neoarundinaria,Marasmiellus palmivorus,Megacapitula villosa,Micropsalliota globocys-tis,M.gracilis,Montagnula thailandica,Neohelicosporium irregulare,N.parisporum,Paradictyoarthrinium diffractum,Phaeoisaria aquatica,Poaceascoma taiwanense,Saproamanita manicata,Spegazzinia camelliae,Submersispora variabi-lis,Thyronectria caudata,T.mackenziei,Tubeufia chiangmaiensis,T.roseohelicospora,Vaginatispora nypae,Wicklowia submersa,Xanthagaricus necopinatus and Xylaria haemorrhoidalis.The data presented herein are based on morphological examination of fresh specimens,coupled with analysis of phylogenetic sequence data to better integrate taxa into appropriate taxonomic ranks and infer their evolutionary relationships.
基金the Foreign Experts Bureau of Yunnan Province,Foreign Talents Program(2018,Grant No.YNZ2018002)Thailand Research grants entitled Biodiversity,phylogeny and role of fungal endophytes on above parts of Rhizophora apiculata and Nypa fruticans(Grant No.RSA5980068)+60 种基金the future of specialist fungi in a changing climate:baseline data for generalist and specialist fungi associated with ants,Rhododendron species and Dracaena species(Grant No.DBG6080013)Impact of climate change on fungal diversity and biogeography in the Greater Mekong Subregion(Grant No.RDG6130001)Chiang Mai University for the award of visiting ProfessorCAS President’s International Fellowship Initiative(PIFI)for funding his postdoctoral research(Grant No.2018PC0006)the National Science Foundation of China(NSFC,project code 31750110478)supported by the Graduate Program for the Undiscovered Taxa of Koreain part by the Project on Survey and Discovery of Indigenous Fungal Species of Korea funded by NIBR and Project on Discovery of Fungi from Freshwater and Collection of Fungarium funded by NNIBR of the Ministry of Environment(MOE)in part carried out with the support of Cooperative Research Program for Agriculture Science and Technology Development(PJ013744),Rural Development Administration,Republic of Koreain part supported by the BK21 plus program through the National Research Foundation(NRF)funded by the Ministry of Education of Korea.Jian-Kui Liu thanks the National Natural Science Foundation of China(NSFC 31600032)the CNPq(Conselho Nacional de Desenvolvimento Cientifico e Tecnologico)for a research grant(309058/2015-5)funding for collecting trips(401186/2014-8)a collaborative project with RL as Special Visiting Professor(314570/2014-4)Funding for phylogenetic work on Graphidaceae was provided by a grant from the National Science Foundation(NSF)to The Field Museum:DEB-1025861"ATM-Assembling a taxonomic monograph:The lichen family Graphidaceae"PI Thorsten Lumbsch,CoPI Robert Luckingthe CAPES,CNPq,and FAPEMIG for financial support and ICMBio/FLONA-Paraopeba for providing facilities and permits for the exploration surveys of the mycodiversity in their protected areasthe Graduate Program for the Biodiversity and Biotechnology Network of the Legal Amazon(UFPA-MPEG,Brazil)the Conselho Nacional de Desenvolvimento Cientifico Programa de Capacitacao for the scholarship to AMSS(Programa de Capacitacao Institucional 303073/2018-7)CNPq(Sisbiota 563342/2010-2,PROTAX 562106/2010-3)FACEPE(APQ 0788-2.03/12)for funding this researchsupport by a long-term research development project No.RVO 67985939 of the Czech Academy of Sciences,Institute of Botanyfinancial support from Conselho Nacional de Pesquisa e Desenvolvimento Cientifico(CNPq)National Natural Science Foundation of China(Project IDs GJL:31500013,RLZ:31470152 and 31360014)for financial supportjoint project of the Charles Darwin Foundation(CDF)and the Galapagos National Park(DPNG),part of a national biodiversity assessment"Biodiversidad Genetica del Ecuador"led by the Instituto Nacional de Biodiversidad del Ecuador(INABIO)Thailand Research Fund(TRF)Grant No.MRG6080089 entitledTaxonomy and phylogeny of foliar fungi from Mangrove and to Dr.Putarak Chomnuntithe Thailand Research Fund(No.TRG6180001)the National Research Council of Thailand(No.61215320023)Plant Genetic Conservation Project under the Royal Initiation of Her Royal Highness Princess Maha Chakri Sirindhorn-Mae Fah Luang Universitygrateful to Croatian Science Foundation for their financial support under the project HRZZ-IP-2018-01-1736(For-FungiDNA)the Royal Golden Jubilee PhD Program under Thailand Research Fund(RGJ)for a personal grant to C.Phukhamsakda(The scholarship no.PHD/0020/2557 to study towards a PhD)China-Thailand Joint Lab on Microbial Biotechnology(Most KY201701011)for financial supportCAS President’s International Fellowship Initiative(PIFI)for young staff(Grant No.2019FYC0003)the Research Fund from China Postdoctoral Science Foundation(Grant No.Y71B283261)the Yunnan Provincial Department of Human Resources and Social Security(Grant No.Y836181261)National Science Foundation of China(NSFC)project code 31850410489 for financial supportthe National Research Council of Thailand(Grant No.256108A3070006)for financial supportthe National Natural Science Foundation of China(No.31760014)the Science and Technology Foundation of Guizhou Province(No.[2016]2863)partially supported by Chiang Mai Universitythe Graduate Program for the Biodiversity and Biotechnology Network of the Legal Amazon(UFPA-MPEG),the Museu Paraense Emilio Goeldi(MPEG),the Universidade do Estado do Amapa and the Universidade Federal de Pernambuco for the logistical support of their laboratories and herbariaCNPq for the scholarship of AMSS(Programa de Capacitacao Institucional 303073/2018-7)CNPq(Sisbiota 563342/2010-2,PROTAX 562106/2010-3)and FACEPE(APQ 0788-2.03/12)for funding this researchthe ATM of the Paris'Museum and"l'Institut Ecologie et Environnement"(CNRS-INEE)for funding the field trip with Shelly Masi to Africaall the practical help and sharing her experiencemade possible through research permit 034/MENESR/DIRCAB/DGESRSTI/DRSTSPI/SSSTI/16 from the"Ministere de l'education nationale,de l’enseignement superieur et de la recherche scientifique"of the Central African Republicfinanced in part by the National Geographic Society(grants 6365-98,7921-05)in more recent years by the ATM-project"Past and present biodiversity"of the Museum national d’histoire naturelle(Dirs.Ph.Janvier and S.Peigne)University of Mauritius for research supportthe Thailand Research Fund(PHD60K0147)contribution number 2248 of the Charles Darwin Foundation for the Galapagos IslandsLakmali Dissanayake and Binu Samarakoon for their supportCAS President’s International Fellowship Initiative(PIFI)for funding his postdoctoral research(Number 2019PC0008)the National Science Foundation of China and the Chinese Academy of Sciences for financial support under the following grants:41761144055,41771063 and Y4ZK111B01CAS President’s International Fellowship Initiative(Grant No.2018VBB0021)German Academic Exchange Service Fellowship(Grant No.57314018)Ministry of innovative development of the Republic of Uzbekistan(Projects No.P3-2014-0830174425 and PP-20170921183)for funding his research projectsthe 5th batch of Postdoctoral Orientation Training Personnel in Yunnan Province(Grant No.Y934283261)the 64th batch of China Postdoctoral Science Foundation(Grant No.Y913082271)their kind support on manuscript writing.Jianchu Xu thanks Key Research Program of Frontier Sciences"Response of Asian mountain ecosystems to global change",CAS(Grant No.QYZDYSSW-SMC014)the 64th batch of China Postdoctoral Science Foundation(Grant No.Y913083271)the support from UID/MULTI/04046/2019 Research Unit grant from FCT,Portugal to BioISI.
文摘This article is the tenth series of the Fungal Diversity Notes,where 114 taxa distributed in three phyla,ten classes,30 orders and 53 families are described and illustrated.Taxa described in the present study include one new family(viz.Pseudoberkleasmiaceae in Dothideomycetes),five new genera(Caatingomyces,Cryptoschizotrema,Neoacladium,Paramassaria and Trochilispora)and 71 new species,(viz.Acrogenospora thailandica,Amniculicola aquatica,A.guttulata,Angustimassarina sylvatica,Blackwellomyces lateris,Boubovia gelatinosa,Buellia viridula,Caatingomyces brasiliensis,Calophoma humuli,Camarosporidiella mori,Canalisporium dehongense,Cantharellus brunneopallidus,C.griseotinctus,Castanediella meliponae,Coprinopsis psammophila,Cordyceps succavus,Cortinarius minusculus,C.subscotoides,Diaporthe italiana,D.rumicicola,Diatrypella delonicis,Dictyocheirospora aquadulcis,D.taiwanense,Digitodesmium chiangmaiense,Distoseptispora dehongensis,D.palmarum,Dothiorella styphnolobii,Ellisembia aurea,Falciformispora aquatic,Fomitiporia carpinea,F.lagerstroemiae,Grammothele aurantiaca,G.micropora,Hermatomyces bauhiniae,Jahnula queenslandica,Kamalomyces mangrovei,Lecidella yunnanensis,Micarea squamulosa,Muriphaeosphaeria angustifoliae,Neoacladium indicum,Neodidymelliopsis sambuci,Neosetophoma miscanthi,N.salicis,Nodulosphaeria aquilegiae,N.thalictri,Paramassaria samaneae,Penicillium circulare,P.geumsanense,P.mali-pumilae,P.psychrotrophicum,P.wandoense,Phaeoisaria siamensis,Phaeopoacea asparagicola,Phaeosphaeria penniseti,Plectocarpon galapagoense,Porina sorediata,Pseudoberkleasmium chiangmaiense,Pyrenochaetopsis sinensis,Rhizophydium koreanum,Russula prasina,Sporoschisma chiangraiense,Stigmatomyces chamaemyiae,S.cocksii,S.papei,S.tschirnhausii,S.vikhrevii,Thysanorea uniseptata,Torula breviconidiophora,T.polyseptata,Trochilispora schefflerae and Vaginatispora palmae).Further,twelve new combinations(viz.Cryptoschizotrema cryptotrema,Prolixandromyces australi,P.elongatus,P.falcatus,P.longispinae,P.microveliae,P.neoalardi,P.polhemorum,P.protuberans,P.pseudoveliae,P.tenuistipitis and P.umbonatus),an epitype is chosen for Cantharellus goossensiae,a reference specimen for Acrogenospora sphaerocephala and new synonym Prolixandromyces are designated.Twenty-four new records on new hosts and new geographical distributions are also reported(i.e.Acrostalagmus annulatus,Cantharellus goossensiae,Coprinopsis villosa,Dothiorella plurivora,Dothiorella rhamni,Dothiorella symphoricarposicola,Dictyocheirospora rotunda,Fasciatispora arengae,Grammothele brasiliensis,Lasiodiplodia iraniensis,Lembosia xyliae,Morenoina palmicola,Murispora cicognanii,Neodidymelliopsis farokhinejadii,Neolinocarpon rachidis,Nothophoma quercina,Peroneutypa scoparia,Pestalotiopsis aggestorum,Pilidium concavum,Plagiostoma salicellum,Protofenestella ulmi,Sarocladium kiliense,Tetraploa nagasakiensis and Vaginatispora armatispora).
基金supported by the Strategic Priority Research Program of the Chinese Academy of Sciences,Grant No.XDB31000000Naritsada Thongklang would like to thank Thailand research fund grants“Study of saprobic Agaricales in Thailand to find new industrial mushroom products”(Grant No.DBG6180015)+10 种基金Mae Fah Luang University grant“Optimal conditions for domestication and biological activities of selected species of Ganoderrma”(Grant No.621C1535)K.D.Hyde and Naritsada Thongklang would like to thanks to Thailand research fund grants“Domestication and bioactive evaluation of Thai Hymenopellis,Oudemansiella,Xerula and Volvariella species(basidiomycetes)”(Grant No.DBG6180033)K.D.Hyde thanks the financial support from the Visiting Professor grant at Chiang Mai University,Thailand and KIB.The authors acknowledge the contribution of M.M.Vasanthakumari,K.M.Manasa and P.Rajani,in various stages of preparation of the manuscript.Samantha C.Karunarathna thanks CAS President’s International Fellowship Initiative(PIFI)for funding his postdoctoral research(Number 2018PC0006)the National Science Foundation.Associate Professor R Jeewon thanks University of Mauritius for support.Binu C.Samarakoon offers her sincere gratitude to the“National Research Council of Thailand”(NRCT Grant No.256108A3070006)for the financial supportPeter E Mortimer would like to thank the National Science Foundation of China and the Chinese Academy of Sciences for financial support under the following Grants:41761144055,41771063,Y4ZK111B01M.Doilom would like to thank Chiang Mai University,the 5th batch of Postdoctoral Orientation Training Personnel in Yunnan Province and the 64th batch of China Postdoctoral Science Foundation.T.S.Suryanarayanan thanks the United States-India Educational Foundation(USIEF)New Delhi and the Fulbright Scholar Program(USA)for the award of a Fulbright-Nehru Senior Researcher grant to conduct research in the Department of Chemistry and Biochemistry,The Ohio State University,USA.Thanks to Research and Researchers for Industries Grant(PHD57I0015)for financial support to Boontiya Chuankid.Birthe Sandargo is grateful to the Deutsche Forschungsgemeinschaft(DFG)for a PhD grant.Clara Chepkirui is indebted to a PhD stipend from the German Academic Exchange Service(DAAD)and the Kenya National Council for Science and Technology(NACOSTI)Kevin D Hyde would also like to thank the National Research Council of Thailand grants Thailands’Fungal Diversity,Solving Problems and Creating Biotechnological Products(Grant No.61201321016)This work is partly supported by the Department of Biotechnology,Government of India,New Delhi(Chemical Ecology of the North East Region(NER)of India:A collaborative programme Linking NER and Bangalore ResearchersDBT-NER/Agri/24/2013)and Indian Council of Agricultural Research(ICAR-CAAST-Project F.No./NAHEP/CAAST/2018-19)Government of India,New Delhi.
文摘Fungi are an understudied,biotechnologically valuable group of organisms.Due to the immense range of habitats that fungi inhabit,and the consequent need to compete against a diverse array of other fungi,bacteria,and animals,fungi have developed numerous survival mechanisms.The unique attributes of fungi thus herald great promise for their application in biotechnology and industry.Moreover,fungi can be grown with relative ease,making production at scale viable.The search for fungal biodiversity,and the construction of a living fungi collection,both have incredible economic potential in locating organisms with novel industrial uses that will lead to novel products.This manuscript reviews fifty ways in which fungi can potentially be utilized as biotechnology.We provide notes and examples for each potential exploitation and give examples from our own work and the work of other notable researchers.We also provide a flow chart that can be used to convince funding bodies of the importance of fungi for biotechnological research and as potential products.Fungi have provided the world with penicillin,lovastatin,and other globally significant medicines,and they remain an untapped resource with enormous industrial potential.
基金National Key R&D Program of China(2021YFA0910800)National Natural Science Foundation of China(No.31601014)+7 种基金Basic and applied basic research fund of Guangdong Province(2121A1515012166)Stability Support Project for Universities in Shenzhen(20200812173625001)Project of DEGP(2019KTSCX150)for fundingSenanayake thanks to Paul Kirk,Samantha C.Karunarathna for data contribution.S.N.Wijesinghe would like to acknowledge Thailand Science Research and Innovation(TSRI)grant for Macrofungi diversity research from the Lancang-Mekong Watershed and Surrounding areas(Grant No.DBG6280009)Dhanushka Wanasinghe thanks the CAS President’s International Fellowship Initiative(PIFI)for funding his postdoctoral research(number 2021FYB0005)the Postdoctoral Fund from Human Resources and Social Security Bureau of Yunnan Province and the National Science Foundation of China.Saowaluck Tibpromma would like to thank the International Postdoctoral Exchange Fellowship Program(Number Y9180822S1)CAS President’s International Fellowship Initiative(PIFI)(Number 2020PC0009)China Postdoctoral Science Foundation and the Yunnan Human Resources,and Social Security Department Foundation for funding her postdoctoral research.Rungtiwa Phookamsak thanks to CAS President’s International Fellowship Initiative(PIFI)for young staff(Grant No.2019FYC0003)and“High-level Talent Support Plan”Young Top Talent Special Project of Yunnan Province.
文摘Sexual reproduction is the basic way to form high genetic diversity and it is beneficial in evolution and speciation of fungi.The global diversity of teleomorphic species in Ascomycota has not been estimated.This paper estimates the species number for sexual ascomycetes based on five different estimation approaches,viz.by numbers of described fungi,by fungus:substrate ratio,by ecological distribution,by meta-DNA barcoding or culture-independent studies and by previous estimates of species in Ascomycota.The assumptions were made with the currently most accepted,“2.2–3.8 million”species estimate and results of previous studies concluding that 90%of the described ascomycetes reproduce sexually.The Catalogue of Life,Species Fungorum and published research were used for data procurement.The average value of teleomorphic species in Ascomycota from all methods is 1.86 million,ranging from 1.37 to 2.56 million.However,only around 83,000 teleomorphic species have been described in Ascomycota and deposited in data repositories.The ratio between described teleomorphic ascomycetes to predicted teleomorphic ascomycetes is 1:22.Therefore,where are the undiscovered teleomorphic ascomycetes?The undescribed species are no doubt to be found in biodiversity hot spots,poorly-studied areas and species complexes.Other poorly studied niches include extremophiles,lichenicolous fungi,human pathogens,marine fungi,and fungicolous fungi.Undescribed species are present in unexamined collections in specimen repositories or incompletely described earlier spe-cies.Nomenclatural issues,such as the use of separate names for teleomorph and anamorphs,synonyms,conspecific names,illegitimate and invalid names also affect the number of described species.Interspecies introgression results in new species,while species numbers are reduced by extinctions.
基金Funding Open Access funding enabled and organized by Projekt DEAL.Funding was provided by Mae Fah Luang University(Grant No.:651A16029)Basic Research Fund(Grant No.:652A01001)+7 种基金Princess Srinagarindra’s Centenary Celebrations Foundation(Grant No.:64316001)National Research Council Thailand(Grant No.:NRCT5-TRG630010-01)Czech Academy of Sciences Long-term Research Development Project(Grant No.:61388971)Thailand Research Fund(Grant No.:PHD/0039/2560)Deutscher Akademischer Austauschdienst(Grant Nos.:57507870,PhD stipend),Czech Academy of Sciences(Grant No.:CZ.02.2.69/0.0/0.0/18_053/0017705)Chiang Mai University(Grant No.:FF65/067)STEP Program(CH)(Grant No.:2019QZKK0503)Kunming Institute of Botany,Chinese Academy of Sciences(Grant No.:292019312511043).
文摘Fungi are an understudied resource possessing huge potential for developing products that can greatly improve human well-being.In the current paper,we highlight some important discoveries and developments in applied mycology and interdisciplinary Life Science research.These examples concern recently introduced drugs for the treatment of infections and neurological diseases;application of–OMICS techniques and genetic tools in medical mycology and the regulation of mycotoxin production;as well as some highlights of mushroom cultivaton in Asia.Examples for new diagnostic tools in medical mycology and the exploitation of new candidates for therapeutic drugs,are also given.In addition,two entries illustrating the latest developments in the use of fungi for biodegradation and fungal biomaterial production are provided.Some other areas where there have been and/or will be significant developments are also included.It is our hope that this paper will help realise the importance of fungi as a potential industrial resource and see the next two decades bring forward many new fungal and fungus-derived products.
基金Project supported by the Beijing Municipal Science and Technology Plan Projects(No.D151100003915002)the Special Project for Innovation Ability Construction from the Beijing Academy of Agriculture and Forestry Sciences(No.KJCX20170415)+2 种基金the Beijing Agriculture Innovation Consortium(No.BAIC07-2018)the Science and Technology Innovation Ability Construction Fund from the Beijing Academy of Agriculture and Forestry Sciences(No.KJCX20170107)the Science and Technology Innovation Team of the Beijing Academy of Agriculture and Forestry Sciences(No.JNKST201607),China