Concrete structures are some of the largest constructions in human civilization.Their manufacture releases CO_(2)into atmosphere,which is partially readsorbed by standing structures,and further release occurs when the...Concrete structures are some of the largest constructions in human civilization.Their manufacture releases CO_(2)into atmosphere,which is partially readsorbed by standing structures,and further release occurs when they are demolished.Concrete is chemically similar to basaltic minerals,both adsorb CO_(2)where they are exposed on the earth's surface.Sequestration of CO_(2)is beneficial to reduce atmospheric concentrations,and thus limit future temperature increases.Therefore,multiple options are being examined for CO_(2)sequestration.For the first time,we compare the CO_(2)sequestration capacity of these two materials.We review previous work quantifying CO_(2)sequestration capacity of both materials and for the first time,compare their potential quantitative roles.Costs of that are compiled,to the extent they have been examined.Costly grinding of these materials to small particle sizes accelerates CO_(2)sequestration,and mycorrhizae in agricultural soils might reduce the associated costs.Both these materials can improve nutrient status in agricultural soils,and limit acidification from external nitrogen fertilization.Limitations are discussed in terms of land-use and material availability,and soil pH conditions.We call for further experiments with these materials that compare CO_(2)sequestration and other biogeochemical processes in agricultural systems across climates,carried out especially where such materials are conveniently available.展开更多
Sexual morph of didymellaceous taxa are characterized by their ascomata with relatively thin peridium,cylindric-clavate to clavate,short-pedicellate or apedicellate asci,hyaline to brown,1-septate to muriform ascospor...Sexual morph of didymellaceous taxa are characterized by their ascomata with relatively thin peridium,cylindric-clavate to clavate,short-pedicellate or apedicellate asci,hyaline to brown,1-septate to muriform ascospores.Its asexual morphs are coelomycetous and comprising pycnidial or acervulus conidiomata,phialidic,hyaline conidiogenous cells and hyaline or pale brown,septate or aseptate conidia.The majority of these cosmopolitan species are plant associated fungi which can be pathogens on a wide range of hosts and some species are of particular relevance for quarantine measures.Recent studies have significantly improved the taxonomy and systematics of didymellaceous taxa based on molecular phylogenetics.In contrast to the accurate and detailed studies on the asexual morphs which are common obligate pathogens,information on their usually saprobic sexual morphs is still limited.Among these phenotypically diverse species,spore characteristics are quite unique as most have hyaline spores with 0-1 septum,while only Neomicrosphaeropsis and Didymellocamarosporium are reported as producing pigmented,muriform spores.These dematiaceous muriform spores are characteristic of a considerable number of species that may be quite divergent in other characters.During taxonomic investigations on the diversity of didymellaceous taxa,we have isolated species from Alhagi pseudalhagi,Coronilla emerus,Cytisus sp.,Elaeagnus angustifolia and Spartium junceum in Italy,Russia and Uzbekistan.A comprehensive phylogeny,based on four loci(ITS,LSU,rpb2 and tub2)is used to infer species relationships.Comprehensive morphological descriptions and in-depth phylogenetic investigations of five new species viz.Ascochyta coronillae-emeri,Microsphaeropsis spartii-juncei,Neomicrosphaeropsis alhagi-pseudalhagi,N.cytisicola and N.elaeagni are presented.展开更多
A study was undertaken to collect and identify saprobic fungi associated with Musa spp.(banana)from Taiwan(China),and Thailand.Samples were collected during the dry season and their morpho-molecular relationships were...A study was undertaken to collect and identify saprobic fungi associated with Musa spp.(banana)from Taiwan(China),and Thailand.Samples were collected during the dry season and their morpho-molecular relationships were investigated.Five brown pleosporalean hyphomycetous taxa in Periconiaceae and Torulaceae viz.Periconia cortaderiae,P.delonicis,Torula chromolaenae,T.fici,and T.masonii were identified for the first time from Musa spp.(Musaceae).Phylogenetic analyses of a combined SSU,LSU,ITS,RPB2 and TEF DNA sequence dataset further justified the taxonomic placements of these five taxa in the above mentioned families.Periconia delonicis is reported for the first time on a monocotyledonous host and T.masonii is the first geographical record from Taiwan(China).展开更多
Arbuscular mycorrhizal fungi(AMF)provide benefits to most crop species via enhanced nutrient uptake,increased drought and abiotic stress resistance,and reduced effects of pathogens and pests.Much remains unclear regar...Arbuscular mycorrhizal fungi(AMF)provide benefits to most crop species via enhanced nutrient uptake,increased drought and abiotic stress resistance,and reduced effects of pathogens and pests.Much remains unclear regarding the specific mechanisms influencing these processes,and the critical roles of AMF are often overlooked in planning agroecological systems.There is growing consensus,however,around the important roles AMF play in improving plant resilience and crop yield while also enhancing the functioning of soil microbial communities.Heterogeneous practices across all scales complicate the successful integration of AMF in agroecological systems.AMF symbioses with crops are passive,or stimulated by incorporation of crop wastes in soil,soil inoculation with AMF spores,or the planting inoculated of seeds.Here we suggest that AMF can have highest beneficial impacts in areas with low levels of agrochemical inputs.We argue that areas with intensive agrochemical inputs can also be made more sustainable with AMF enhancements.展开更多
We are studying seed and fruit inhabiting fungi in Thailand and this paper introduces a new species,Diaporthe collariana,from Magnolia champaca fruits,collected in Chiang Rai Province.Molecular analysis of a combined ...We are studying seed and fruit inhabiting fungi in Thailand and this paper introduces a new species,Diaporthe collariana,from Magnolia champaca fruits,collected in Chiang Rai Province.Molecular analysis of a combined ITS,TEF1,TUB and CAL sequence DNA and morphological data provide evidence to justify the new species.Diaporthe collariana is characterized by producing alpha and beta conidia,and conidiogenous cells with prominent,flared collarettes.The new species is compared with closely related species in the genus.展开更多
We are studying seed pod fungi associated with Delonix regia in Thailand and in this paper we provide an illustrated account of Parascedosporium putredinis,which is a new record for Thailand.Phylogenetic analysis of c...We are studying seed pod fungi associated with Delonix regia in Thailand and in this paper we provide an illustrated account of Parascedosporium putredinis,which is a new record for Thailand.Phylogenetic analysis of combined ITS and LSU sequence data and morphological similarities provide evidence for its identification.We illustrate the synnematal stage and lateral,solitary conidiophores of P.putredinis obtained in vitro on MEA.We also provide ITS,LSU,SSU,and tef sequence data for P.putredinis,which are deposited in GenBank.展开更多
Bamboos not only provide socio-economic benefits to communities within the region,but also provide ecosystem services such as soil-water conservation,stabilization of sandy soils and restoration of soil nutrients.Bamb...Bamboos not only provide socio-economic benefits to communities within the region,but also provide ecosystem services such as soil-water conservation,stabilization of sandy soils and restoration of soil nutrients.Bambusicolous ascomycetes refer to ascomycetous fungi living on any substrate of bamboo.As the largest group of fungi on bamboo,they play a significant ecological value in species composition and the structure of the fungal community,circulation of materials and energy flow of nutritional elements.In an effort to document the bambusicolous Ascomycota found in China,we assessed all major sources of academic literature,journal papers,and the USDA database(https://nt.ars-grin.gov/fungaldatabases/fungushost/fungushost.cfm)for reports of these fungi from China.As a result,we produced a systematic and comprehensive checklist of bambusicolous Ascomycota in China.Current names of fungi,bamboo host name,bamboo substrate,details of collected localities,references and latest classification for every bambusicolous ascomycete in China are also provided.In addition,we focused on the species richness of bambusicolous Ascomycota in China with an emphasis on southwest China.展开更多
Exploration of natural sources for novel bioactive compounds has been an emerging field of medicine over the past decades,providing drugs or lead compounds of considerable therapeutic potential.This research has provi...Exploration of natural sources for novel bioactive compounds has been an emerging field of medicine over the past decades,providing drugs or lead compounds of considerable therapeutic potential.This research has provided exciting evidence on the isolation of microbe-derived metabolites having prospective biological activities.Mushrooms have been valued as traditional sources of natural bioactive compounds for many centuries and have been targeted as promising therapeutic agents.Many novel biologically active compounds have been reported as a result of research on medicinal mushrooms.In this review,we compile the information on bioactive structure-elucidated metabolites from macrofungi discovered over the last decade and highlight their unique chemical diversity and potential benefits to novel drug discovery.The main emphasis is on their anti-Alzheimer,antidiabetic,anti-malarial,anti-microbial,anti-oxidant,antitumor,anti-viral and hypocholesterolemic activities which are important medicinal targets in terms of drug discovery today.Moreover,the reader’s attention is brought to focus on mushroom products and food supplements available in the market with claimed biological activities and potential human health benefits.展开更多
Ophiobolus is a large genus of Phaeosphaeriaceae comprising more than 350 possible species,most of which are saprobes on herbaceous plants in Europe and North America.Ophiobolus species are polyphyletic and the type o...Ophiobolus is a large genus of Phaeosphaeriaceae comprising more than 350 possible species,most of which are saprobes on herbaceous plants in Europe and North America.Ophiobolus species are polyphyletic and the type of Ophiobolus is not represented in GenBank.Therefore,an increased taxon sampling of ophiobolus-like taxa and epitypification of the type species,O.disseminans is reported.Multigene phylogenetic analyses of combined LSU,SSU,TEF1-a and ITS sequence data position O.disseminans in a sister clade with O.ponticus and several Entodesmium species in Phaeosphaeriaceae with high support.Therefore,Entodesmium is synonymized under Ophiobolus.Premilcurensis with it type species,P.senecionis also clusters within the Ophiobolus clade and is synonymized under Ophiobolus.Ophiobolus rossicus sp.nov.is introduced and a reference specimen is designated for O.ponticus.Other ophiobolus-like taxa(Ophiobolus sensu lato)can be distinguished as three main groups,which are introduced as new genera.Ophiobolopsis is introduced to accommodate the new species,Ophiobolopsis italica.The new genus Paraophiobolus is introduced to accommodate P.arundinis sp.nov.and P.plantaginis comb.nov.This genus is characterized by hyaline to pale yellowish ascospores,some green-yellowish at maturity,with a swollen cell,terminal appendages and ascospores not separating into part spores.Pseudoophiobolus gen.nov.is introduced to accommodate six new species and two new combinations,viz.Ps.achilleae,Ps.erythrosporus,Ps.galii,Ps.italicus,Ps.mathieui,Ps.rosae,Ps.subhyalinisporus and Ps.urticicola.Pseudoophiobolus is characterized by subhyaline to pale yellowish or yellowish ascospores,with a swollen cell,lack of terminal appendages and ascospores that do not separate into part spores and is related to Nodulosphaeria.An updated tree for Phaeosphaeriaceae based on multigene analysis is also provided.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
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
Insects first began evolving hundreds of millions of years ago,and aided by gut microbes,they have been consuming hydrocarbon polymers ever since.Few man-made plastic polymers are chemically novel,so it is reasonable ...Insects first began evolving hundreds of millions of years ago,and aided by gut microbes,they have been consuming hydrocarbon polymers ever since.Few man-made plastic polymers are chemically novel,so it is reasonable that insect/microbe systems can be found or developed to degrade them rapidly.However,remediation of global plastic waste problems should involve more than just conversion into CO_(2).Some industryscale microbial enzymatic degradation of plastic polymers may yield valuable monomers,but the plastic waste starting material must be of uniform chemistry and clean.This adds cost to the process.Many insect species can be utilized for animal feed as well as human food.Some of these insects have the capability to degrade plastic polymers.However,valorizing plastic wastes by producing edible insects or useful frass has largely been overlooked.Here we assemble the current knowledge of plastic degradation rates by insects.In addition,we also show the first instance of insect degradation of polyurethane and the first identification and isolation of insect gut fungi as directly aiding insect degradation.展开更多
Fungi are one of the most diverse groups of organisms with an estimated number of species in the range of 2–3 million.The higher-level ranking of fungi has been discussed in the framework of molecular phylogenetics s...Fungi are one of the most diverse groups of organisms with an estimated number of species in the range of 2–3 million.The higher-level ranking of fungi has been discussed in the framework of molecular phylogenetics since Hibbett et al.,and the definition and the higher ranks(e.g.,phyla)of the‘true fungi’have been revised in several subsequent publications.Rapid accumulation of novel genomic data and the advancements in phylogenetics now facilitate a robust and precise foundation for the higher-level classification within the kingdom.This study provides an updated classification of the kingdom Fungi,drawing upon a comprehensive phylogenomic analysis of Holomycota,with which we outline well-supported nodes of the fungal tree and explore more contentious groupings.We accept 19 phyla of Fungi,viz.Aphelidiomycota,Ascomycota,Basidiobolomycota,Basidiomycota,Blastocladiomycota,Calcarisporiellomycota,Chytridiomycota,Entomophthoromycota,Entorrhizomycota,Glomeromycota,Kickxellomycota,Monoblepharomycota,Mortierellomycota,Mucoromycota,Neocallimastigomycota,Olpidiomycota,Rozellomycota,Sanchytriomycota,and Zoopagomycota.In the phylogenies,Caulochytriomycota resides in Chytridiomycota;thus,the former is regarded as a synonym of the latter,while Caulochytriomycetes is viewed as a class in Chytridiomycota.We provide a description of each phylum followed by its classes.A new subphylum,Sanchytriomycotina Karpov is introduced as the only subphylum in Sanchytriomycota.The subclass Pneumocystomycetidae Kirk et al.in Pneumocystomycetes,Ascomycota is invalid and thus validated.Placements of fossil fungi in phyla and classes are also discussed,providing examples.展开更多
Fungi are one of the most diverse groups of organisms with an estimated number of species in the range of 2-3 million.The higher-level ranking of fungi has been discussed in the framework of molecular phylogenetics si...Fungi are one of the most diverse groups of organisms with an estimated number of species in the range of 2-3 million.The higher-level ranking of fungi has been discussed in the framework of molecular phylogenetics since Hibbett et al.,and the definition and the higher ranks(e.g.,phyla)of the‘true fungi’have been revised in several subsequent publications.Rapid accumulation of novel genomic data and the advancements in phylogenetics now facilitate a robust and precise foundation for the higher-level classification within the kingdom.This study provides an updated classification of the kingdom Fungi,drawing upon a comprehensive phylogenomic analysis of Holomycota,with which we outline well-supported nodes of the fungal tree and explore more contentious groupings.We accept 19 phyla of Fungi,viz.Aphelidiomycota,Ascomycota,Basidiobolomycota,Basidiomycota,Blastocladiomycota,Calcarisporiellomycota,Chytridiomycota,Entomophthoromycota,Entorrhizomycota,Glomeromycota,Kickxellomycota,Monoblepharomycota,Mortierellomycota,Mucoromycota,Neocal-limastigomycota,Olpidiomycota,Rozellomycota,Sanchytriomycota,and Zoopagomycota.In the phylogenies,Caulochy-triomycota resides in Chytridiomycota;thus,the former is regarded as a synonym of the latter,while Caulochytriomycetes is viewed as a class in Chytridiomycota.We provide a description of each phylum followed by its classes.A new subphylum,Sanchytriomycotina Karpov is introduced as the only subphylum in Sanchytriomycota.The subclass Pneumocystomycetidae Kirk et al.in Pneumocystomycetes,Ascomycota is invalid and thus validated.Placements of fossil fungi in phyla and classes are also discussed,providing examples.展开更多
Sordariomycetes is one of the largest classes of Ascomycota and is characterised by perithecial ascomata and inoperculate unitunicate asci.The class includes many important plant pathogens,as well as endophytes,saprob...Sordariomycetes is one of the largest classes of Ascomycota and is characterised by perithecial ascomata and inoperculate unitunicate asci.The class includes many important plant pathogens,as well as endophytes,saprobes,epiphytes,and fungicolous,lichenized or lichenicolous taxa.The class includes freshwater,marine and terrestrial taxa and has a worldwide distribution.This paper provides an updated outline of the Sordariomycetes and a backbone tree incorporating asexual and sexual genera in the class.Based on phylogeny and morphology we introduced three subclasses;Diaporthomycetidae,Lulworthiomycetidae and Meliolomycetidae and five orders;Amplistromatales,Annulatascales,Falcocladiales,Jobellisiales and Togniniales.The outline is based on literature to the end of 2014 and the backbone tree published in this paper.Notes for 397 taxa with information,such as new family and genera novelties,novel molecular data published since the Outline of Ascomycota 2009,and new links between sexual and asexual genera and thus synonymies,are provided.The Sordariomycetes now comprises six subclasses,28 orders,90 families and 1344 genera.In addition a list of 829 genera with uncertain placement in Sordariomycetesis also provided.展开更多
This article provides morphological descriptions and illustrations of microfungi associated with the invasive weed,Chro-molaena odorata,which were mainly collected in northern Thailand.Seventy-seven taxa distributed i...This article provides morphological descriptions and illustrations of microfungi associated with the invasive weed,Chro-molaena odorata,which were mainly collected in northern Thailand.Seventy-seven taxa distributed in ten orders,23 families(of which Neomassarinaceae is new),12 new genera(Chromolaenicola,Chromolaenomyces,Longiappendispora,Pseudocapulatispora,Murichromolaenicola,Neoophiobolus,Paraleptospora,Pseudoroussoella,Pseudostaurosphaeria,Pseudothyridariella,Setoarthopyrenia,Xenoroussoella),47 new species(Aplosporella chromolaenae,Arthrinium chromolae-nae,Chromolaenicola chiangraiensis,C.lampangensis,C.nanensis,C.thailandensis,Chromolaenomyces appendiculatus,Diaporthe chromolaenae,Didymella chromolaenae,Dyfrolomyces chromolaenae,Leptospora chromolaenae,L.phraeana,Longiappendispora chromolaenae,Memnoniella chromolaenae,Montagnula chiangraiensis,M.chromolaenae,M.chromo-laenicola,M.thailandica,Murichromolaenicola chiangraiensis,M.chromolaenae,Muyocopron chromolaenae,M.chromo-laenicola,Neomassarina chromolaenae,Neoophiobolus chromolaenae,Neopyrenochaeta chiangraiensis,N.chromolaenae,N.thailandica,N.triseptatispora,Nigrograna chromolaenae,Nothophoma chromolaenae,Paraleptospora chromolaenae,P.chromolaenicola,Patellaria chromolaenae,Pseudocapulatispora longiappendiculata,Pseudoroussoella chromolaenae,Pseudostaurosphaeria chromolaenae,P.chromolaenicola,Pseudothyridariella chromolaenae,Pyrenochaetopsis chromolae-nae,Rhytidhysteron chromolaenae,Setoarthopyrenia chromolaenae,Sphaeropsis chromolaenicola,Tremateia chiangraiensis,T.chromolaenae,T.thailandensis,Xenoroussoella triseptata,Yunnanensis chromolaenae),12 new host records,three new taxonomic combinations(Chromolaenicola siamensis,Pseudoroussoella elaeicola,Pseudothyridariella mahakashae),and two reference specimens(Torula chromolaenae,T.fici)are described and illustrated.Unlike some other hosts,e.g.bamboo(Poaceae)and Pandanaceae,the dominant group of fungi on Siam weed were Dothideomycetes.Only 15 species previously recorded from northern Thailand were found in this study.Most of the taxa are likely to have jumped hosts from surrounding plants and are unlikely to be a specialist to Siam weed.Most fungal families found on Siam weed had divergence estimates with stem ages in the Cretaceous,which coincided with the expected origin of the host family(Asteraceae).This further indicates that the species have jumped hosts,as it is unlikely that the taxa on the alien Siam weed came from the Americas with its host.They may,however,have jumped from other Asteraceae hosts.In a preliminary screening 40(65%)of the 62 species tested showed antimicrobial activity and thus,the fungi associated with C.odorata may be promising sources of novel bioactive compound discovery.We provide a checklist of fungi associated with C.odorata based on the USDA Systematic Mycology and Microbiology Laboratory(SMML)database,relevant literature and our study.In total,130 taxa(116 identified and 14 unidentified species)are distributed in 20 orders,48 families and 85 genera.Pseudocercospora is the most commonly encountered genus on Siam weed.展开更多
Dothideomycetes comprise a highly diverse range of fungi characterized mainly by asci with two wall layers(bitunicate asci)and often with fissitunicate dehiscence.Many species are saprobes,with many asexual states com...Dothideomycetes comprise a highly diverse range of fungi characterized mainly by asci with two wall layers(bitunicate asci)and often with fissitunicate dehiscence.Many species are saprobes,with many asexual states comprising important plant pathogens.They are also endophytes,epiphytes,fungicolous,lichenized,or lichenicolous fungi.They occur in terrestrial,freshwater and marine habitats in almost every part of the world.We accept 105 families in Dothideomycetes with the new families Anteagloniaceae,Bambusicolaceae,Biatriosporaceae,Lichenoconiaceae,Muyocopronaceae,Paranectriellaceae,Roussoellaceae,Salsugineaceae,Seynesiopeltidaceae and Thyridariaceae introduced in this paper.Each family is provided with a description and notes,including asexual and asexual states,and if more than one genus is included,the type genus is also characterized.Each family is provided with at least one figure-plate,usually illustrating the type genus,a list of accepted genera,including asexual genera,and a key to these genera.A phylogenetic tree based on four gene combined analysis add support for 64 of the families and 22 orders,including the novel orders,Dyfrolomycetales,Lichenoconiales,Lichenotheliales,Monoblastiales,Natipusillales,Phaeotrichales and Strigulales.The paper is expected to provide a working document on Dothideomycetes which can be modified as new data comes to light.It is hoped that by illustrating types we provide stimulation and interest so that more work is carried out in this remarkable group of fungi.展开更多
A comprehensive account of fungal classification from freshwater habitats is outlined and discussed in the present review based on literature of biodiversity studies and recent morpho-phylogenetic analyses.A total of ...A comprehensive account of fungal classification from freshwater habitats is outlined and discussed in the present review based on literature of biodiversity studies and recent morpho-phylogenetic analyses.A total of 3,870 freshwater fungal species are listed with additional details on the isolation source,habitat,geographical distribution,and molecular data.The Ascomycota(2,968 species,1,018 genera)dominated the freshwater fungal taxa wherein Sordariomycetes(823 species,298 genera)had the largest number,followed by Dothideomycetes(677 species,229 genera),Eurotiomycetes(276 species,49 genera),and Leotiomycetes(260 species,83 genera).Other phyla included in the updated classification of freshwater fungi are:Chytridiomycota(333 species,97 genera),Rozellomycota(221 species,105 genera),Basidiomycota(218 species,100 genera),Blastocladiomycota(47 species,10 genera),Monoblepharomycota(29 species,6 genera),Mucoromycota(19 spe-cies,10 genera),Aphelidiomycota(15 species,3 genera),Entomophthoromycota(6 species,4 genera),Mortierellomycota(5 species,3 genera),Olpidiomycota(4 species,1 genus),Zoopagomycota(3 species,2 genera),and Sanchytriomycota(2 species,2 genera).The freshwater fungi belong to 1,361 genera,386 families and 145 orders.The Pleosporales and Laboulbeniaceae are the largest freshwater fungal order and family comprised of 391 and 185 species,respectively.The most speciose genera are Chitonomyces(87,Laboulbeniomycetes),Verrucaria(50,Eurotiomycetes),Rhizophydium(52,Rhizophydiomycetes),Penicillium(47,Eurotiomycetes),and Candida(42,Saccharomycetes).展开更多
基金supported by the National Natural Science Foundation of China(NSFC Grant No.32001296)the Youth Innovation Promotion Association of CAS,China(Grant No.2022396),and Chinese Academy of Sciences President's International Fellowship Initiative.
文摘Concrete structures are some of the largest constructions in human civilization.Their manufacture releases CO_(2)into atmosphere,which is partially readsorbed by standing structures,and further release occurs when they are demolished.Concrete is chemically similar to basaltic minerals,both adsorb CO_(2)where they are exposed on the earth's surface.Sequestration of CO_(2)is beneficial to reduce atmospheric concentrations,and thus limit future temperature increases.Therefore,multiple options are being examined for CO_(2)sequestration.For the first time,we compare the CO_(2)sequestration capacity of these two materials.We review previous work quantifying CO_(2)sequestration capacity of both materials and for the first time,compare their potential quantitative roles.Costs of that are compiled,to the extent they have been examined.Costly grinding of these materials to small particle sizes accelerates CO_(2)sequestration,and mycorrhizae in agricultural soils might reduce the associated costs.Both these materials can improve nutrient status in agricultural soils,and limit acidification from external nitrogen fertilization.Limitations are discussed in terms of land-use and material availability,and soil pH conditions.We call for further experiments with these materials that compare CO_(2)sequestration and other biogeochemical processes in agricultural systems across climates,carried out especially where such materials are conveniently available.
基金the Committee for Coordination Science and Technology Development under the Cabinet of Ministers of Uzbekistan for research support(#P3-2014-0830174425).
文摘Sexual morph of didymellaceous taxa are characterized by their ascomata with relatively thin peridium,cylindric-clavate to clavate,short-pedicellate or apedicellate asci,hyaline to brown,1-septate to muriform ascospores.Its asexual morphs are coelomycetous and comprising pycnidial or acervulus conidiomata,phialidic,hyaline conidiogenous cells and hyaline or pale brown,septate or aseptate conidia.The majority of these cosmopolitan species are plant associated fungi which can be pathogens on a wide range of hosts and some species are of particular relevance for quarantine measures.Recent studies have significantly improved the taxonomy and systematics of didymellaceous taxa based on molecular phylogenetics.In contrast to the accurate and detailed studies on the asexual morphs which are common obligate pathogens,information on their usually saprobic sexual morphs is still limited.Among these phenotypically diverse species,spore characteristics are quite unique as most have hyaline spores with 0-1 septum,while only Neomicrosphaeropsis and Didymellocamarosporium are reported as producing pigmented,muriform spores.These dematiaceous muriform spores are characteristic of a considerable number of species that may be quite divergent in other characters.During taxonomic investigations on the diversity of didymellaceous taxa,we have isolated species from Alhagi pseudalhagi,Coronilla emerus,Cytisus sp.,Elaeagnus angustifolia and Spartium junceum in Italy,Russia and Uzbekistan.A comprehensive phylogeny,based on four loci(ITS,LSU,rpb2 and tub2)is used to infer species relationships.Comprehensive morphological descriptions and in-depth phylogenetic investigations of five new species viz.Ascochyta coronillae-emeri,Microsphaeropsis spartii-juncei,Neomicrosphaeropsis alhagi-pseudalhagi,N.cytisicola and N.elaeagni are presented.
基金supported by Key Research Project“Agroforestry Systems for restoration and bio-industry technology development(grant no.2017YFC0505101)”.We also thank Biology Experimental Center,Germplasm Bank of Wild Species,Kunming Institute of Botany,Chinese Academy of Sciences for providing the facilities of molecular laboratory.Binu C.Samarakoon is grateful to Danushka Tennakoon for collecting the specimens from Taiwan(China),Dr.Dhanushka N.Wanasinghe and Junfu Li for the valuable comments and suggestions on the morphological studies of Periconia and Torula.Rungtiwa Phookamsak thanks CAS President’s International Fellowship Initiative(PIFI)for young staff(grant no.Y9215811Q1)the National Science Foundation of China(NSFC)project code 31850410489(grant no.Y81I982211)+3 种基金Chiang Mai University for financial support.Samantha C.Karunarathna thanks CAS President’s International Fellowship Initiative(PIFI)young staff under the grant number:2020FYC0002the National Science Foundation of China(NSFC)for funding this work under the project code 31851110759Jianchu Xu thanks Key Research Program of Frontier Sciences of the Chinese Academy of Sciences(grant no.QYZDY-SSW-SMC014)the Strategic Priority Research Program of Chinese Academy of Sciences for supporting this research.
文摘A study was undertaken to collect and identify saprobic fungi associated with Musa spp.(banana)from Taiwan(China),and Thailand.Samples were collected during the dry season and their morpho-molecular relationships were investigated.Five brown pleosporalean hyphomycetous taxa in Periconiaceae and Torulaceae viz.Periconia cortaderiae,P.delonicis,Torula chromolaenae,T.fici,and T.masonii were identified for the first time from Musa spp.(Musaceae).Phylogenetic analyses of a combined SSU,LSU,ITS,RPB2 and TEF DNA sequence dataset further justified the taxonomic placements of these five taxa in the above mentioned families.Periconia delonicis is reported for the first time on a monocotyledonous host and T.masonii is the first geographical record from Taiwan(China).
基金Ministry of Sciences and Technology of China 2017YFC0505101,NSFC-CGIAR 31861143002Yunnan Provincial Science and Technology Department 202003AD150004+3 种基金PEM thanks the National Science Foundation of China for financial support from grants 41761144055 and 41771063HG was supported by Yunnan Fundamental Research Projects(2019FB063)NSFC Grant 32001296Austin Smith substantially clarified our presentation.
文摘Arbuscular mycorrhizal fungi(AMF)provide benefits to most crop species via enhanced nutrient uptake,increased drought and abiotic stress resistance,and reduced effects of pathogens and pests.Much remains unclear regarding the specific mechanisms influencing these processes,and the critical roles of AMF are often overlooked in planning agroecological systems.There is growing consensus,however,around the important roles AMF play in improving plant resilience and crop yield while also enhancing the functioning of soil microbial communities.Heterogeneous practices across all scales complicate the successful integration of AMF in agroecological systems.AMF symbioses with crops are passive,or stimulated by incorporation of crop wastes in soil,soil inoculation with AMF spores,or the planting inoculated of seeds.Here we suggest that AMF can have highest beneficial impacts in areas with low levels of agrochemical inputs.We argue that areas with intensive agrochemical inputs can also be made more sustainable with AMF enhancements.
基金The Research of Featured Microbial Resources and Diversity Investigation in Southwest Karst area(Project No.2014FY120100)is thanked for financial supportthe Chinese Academy of Sciences,project number 2013T2S0030,for the award of a Visiting Professorship for Senior International Scientists at Kunming Institute of Botanyextend their appreciation to the International Scientific Partnership Program ISPP at King Saud University for funding this research work through ISPP#0089.
文摘We are studying seed and fruit inhabiting fungi in Thailand and this paper introduces a new species,Diaporthe collariana,from Magnolia champaca fruits,collected in Chiang Rai Province.Molecular analysis of a combined ITS,TEF1,TUB and CAL sequence DNA and morphological data provide evidence to justify the new species.Diaporthe collariana is characterized by producing alpha and beta conidia,and conidiogenous cells with prominent,flared collarettes.The new species is compared with closely related species in the genus.
基金Featured Microbial Resources and Diversity Investigation in Southwest Karst area(Project No.2014FY120100)is thanked for financial supportthe Chinese Academy of Sciences,project number 2013T2S0030,for the award of a Visiting Professorship for Senior International Scientists at Kunming Institute of Botanysupported by the Thailand Research Fund,‘The future of specialist fungi in a changing climate:baseline data for generalist and specialist fungi associated with ants,Rhododendron species and Dracaena species’(Project No.DBG6080013)。
文摘We are studying seed pod fungi associated with Delonix regia in Thailand and in this paper we provide an illustrated account of Parascedosporium putredinis,which is a new record for Thailand.Phylogenetic analysis of combined ITS and LSU sequence data and morphological similarities provide evidence for its identification.We illustrate the synnematal stage and lateral,solitary conidiophores of P.putredinis obtained in vitro on MEA.We also provide ITS,LSU,SSU,and tef sequence data for P.putredinis,which are deposited in GenBank.
文摘Bamboos not only provide socio-economic benefits to communities within the region,but also provide ecosystem services such as soil-water conservation,stabilization of sandy soils and restoration of soil nutrients.Bambusicolous ascomycetes refer to ascomycetous fungi living on any substrate of bamboo.As the largest group of fungi on bamboo,they play a significant ecological value in species composition and the structure of the fungal community,circulation of materials and energy flow of nutritional elements.In an effort to document the bambusicolous Ascomycota found in China,we assessed all major sources of academic literature,journal papers,and the USDA database(https://nt.ars-grin.gov/fungaldatabases/fungushost/fungushost.cfm)for reports of these fungi from China.As a result,we produced a systematic and comprehensive checklist of bambusicolous Ascomycota in China.Current names of fungi,bamboo host name,bamboo substrate,details of collected localities,references and latest classification for every bambusicolous ascomycete in China are also provided.In addition,we focused on the species richness of bambusicolous Ascomycota in China with an emphasis on southwest China.
基金This study was supported by the grant of the 1551 French-Thai cooperation PHC SIAM 2011(project 25587RA)and the Mae Fah Luang University funded grant“Taxonomy,Phylogeny and cultivation of Lentinus species in northern Thailand”(MFU/54101020048)this study was financially supported by the project“Value added products from basidiomycetes:Putting Thailand’s biodiversity to use”(BRN049/2553)by the National Research Council of Thailand(NRCT)to study medicinal fungi+1 种基金the National Research Council of Thailand(NRCT),project-Taxonomy,Phylogeny and cultivation of Lentinus species in northern Thailand(NRCT/55201020007)the Thailand Research Fund grant-Taxonomy,Phylogeny and biochemistry of Thai Basidiomycetes(BRG 5580009).The authors would also like to acknowledge University Malaya research grants:CG037-2013 Phylogeny,taxonomy,relationships and biotechnological potential of sooty moulds and RG203-12SUS Isolation and structural elucidation of antimicrobial compounds for saprophytic and endophytic fungi of Peninsular Malaysia through bioassay guided fractionation of secondary metabolites extract.
文摘Exploration of natural sources for novel bioactive compounds has been an emerging field of medicine over the past decades,providing drugs or lead compounds of considerable therapeutic potential.This research has provided exciting evidence on the isolation of microbe-derived metabolites having prospective biological activities.Mushrooms have been valued as traditional sources of natural bioactive compounds for many centuries and have been targeted as promising therapeutic agents.Many novel biologically active compounds have been reported as a result of research on medicinal mushrooms.In this review,we compile the information on bioactive structure-elucidated metabolites from macrofungi discovered over the last decade and highlight their unique chemical diversity and potential benefits to novel drug discovery.The main emphasis is on their anti-Alzheimer,antidiabetic,anti-malarial,anti-microbial,anti-oxidant,antitumor,anti-viral and hypocholesterolemic activities which are important medicinal targets in terms of drug discovery today.Moreover,the reader’s attention is brought to focus on mushroom products and food supplements available in the market with claimed biological activities and potential human health benefits.
基金Rungtiwa Phookamsak thanks to the CAS President’s International Fellowship for Postdoctoral Researchers(Project No.2017PB0072)the Research Fund from China Postdoctoral Science Foundation(grant no.Y71B283261)+2 种基金Chiang Mai University for financial support.Kevin D.Hyde would like to thank the Thailand Research Fund grant no RSA5980068 entitled Biodiversity,phylogeny and role of fungal endophytes on above parts of Rhizophora apiculata and Nypa fruticans and the Chinese Academy of Sciences,Project No.2013T2S0030for the award of Visiting Professorship for Senior International Scientists at Kunming Institute of Botany.Financial support by the German Academic Exchange Service(DAAD)and the Thai Royal Golden Ph.D.Jubilee-Industry program(RGJ)for a joint TRF-DAAD PPP(2012-2014)academic exchange grant to K.D.Hyde and M.Stadler.Peter E Mortimer thanks to the National Science Foundation of China(NSFC)for funding this work under the project codes 41761144055 and 41771063Chayanard Phukhamsakda(PHD/0020/2557)acknowledges the Royal Golden Jubilee Ph.D.Program under the Thailand Research Fund.Shi-ke Huang is particularly grateful to Dr.Qi Zhao for his support and great help.Qiu Ju Shang,Jun-Fu Li and Nimali I.de Silva and other colleagues from Centre of Excellence in Fungal Research,Mae Fah Luang University,Chiang Rai,Thailand are thanked for their assistance in phylogenetic analyses.Shaun Pennycook is thanked for suggestion on fungal names.
文摘Ophiobolus is a large genus of Phaeosphaeriaceae comprising more than 350 possible species,most of which are saprobes on herbaceous plants in Europe and North America.Ophiobolus species are polyphyletic and the type of Ophiobolus is not represented in GenBank.Therefore,an increased taxon sampling of ophiobolus-like taxa and epitypification of the type species,O.disseminans is reported.Multigene phylogenetic analyses of combined LSU,SSU,TEF1-a and ITS sequence data position O.disseminans in a sister clade with O.ponticus and several Entodesmium species in Phaeosphaeriaceae with high support.Therefore,Entodesmium is synonymized under Ophiobolus.Premilcurensis with it type species,P.senecionis also clusters within the Ophiobolus clade and is synonymized under Ophiobolus.Ophiobolus rossicus sp.nov.is introduced and a reference specimen is designated for O.ponticus.Other ophiobolus-like taxa(Ophiobolus sensu lato)can be distinguished as three main groups,which are introduced as new genera.Ophiobolopsis is introduced to accommodate the new species,Ophiobolopsis italica.The new genus Paraophiobolus is introduced to accommodate P.arundinis sp.nov.and P.plantaginis comb.nov.This genus is characterized by hyaline to pale yellowish ascospores,some green-yellowish at maturity,with a swollen cell,terminal appendages and ascospores not separating into part spores.Pseudoophiobolus gen.nov.is introduced to accommodate six new species and two new combinations,viz.Ps.achilleae,Ps.erythrosporus,Ps.galii,Ps.italicus,Ps.mathieui,Ps.rosae,Ps.subhyalinisporus and Ps.urticicola.Pseudoophiobolus is characterized by subhyaline to pale yellowish or yellowish ascospores,with a swollen cell,lack of terminal appendages and ascospores that do not separate into part spores and is related to Nodulosphaeria.An updated tree for Phaeosphaeriaceae based on multigene analysis is also provided.
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Key Research Program of the Ministry of Sciences and Technology(Grant No.2017YFC0505101)of ChinaChinese Academy of Sciences,President’s International Fellowship Initiative(CAS-PIFI),Grant No.2019PC0011,2017PC0035+7 种基金Key Research Program of Frontier Sciences,CAS,Grant No.QYZDY-SSW-SMC014We thank the National Science Foundation of China(NSFC)for funding this work under the project codes Y4ZK111B01,41761144055,3181101433,41771063,31650410651,41761144055 and 31550110215We are thankful to Zhijia Gu,Key Laboratories for Plant Diversity and Biogeography of East China,Kunming Institute of Botany,Chinese Academy of Sciences for scanning electron microscopy.G.G.O.Dossa thanks China Postdoctoral Foundation Grant No.2017M613021the young international staff Chinese Academy of Sciences(CAS)president international fellowship initiative(PIFI)grants#2019FYB0001 and 2017PC0035Heng Gui would thank the CPSF-CAS Joint Foundation for Excellent Postdoctoral Fellows(Grant No.2017LH029)the China Postdoctoral Science Foundation(Grant No.2018M633435)the 2018 Yunnan Province Postdoctoral Science Research Foundation.Heng Gui would also like to thank the support from the Human Resources and Social Security Department of Yunnan Province,German Academic Exchange Service(DAAD)under the program:Research Stays for University Academics and Scientists,2018(Ref.No.91691203)the China Scholarship Council under the State Scholarship Fund(Ref.No.201804910259).
文摘Insects first began evolving hundreds of millions of years ago,and aided by gut microbes,they have been consuming hydrocarbon polymers ever since.Few man-made plastic polymers are chemically novel,so it is reasonable that insect/microbe systems can be found or developed to degrade them rapidly.However,remediation of global plastic waste problems should involve more than just conversion into CO_(2).Some industryscale microbial enzymatic degradation of plastic polymers may yield valuable monomers,but the plastic waste starting material must be of uniform chemistry and clean.This adds cost to the process.Many insect species can be utilized for animal feed as well as human food.Some of these insects have the capability to degrade plastic polymers.However,valorizing plastic wastes by producing edible insects or useful frass has largely been overlooked.Here we assemble the current knowledge of plastic degradation rates by insects.In addition,we also show the first instance of insect degradation of polyurethane and the first identification and isolation of insect gut fungi as directly aiding insect degradation.
基金provide by National Natural Science Foundation of China(Nos.32460002,31960005,32000009,32170019,NSFC 32260004)ussian Science Foundation(Nos.24-44-00099,23-74-00071,24-44-00099)+14 种基金National Research Council of Thailand(No.N42A650547)National Institute of Nursing Research(1P20GM152333-01)National Science Foundation(2029478)Japan Society for the Promotion of Science(JSPS,23K05900)National Science Foundation of China(32150410362)Croatian Science Foundation(HRZZIP-2022-10-5219)RSF(21-74-20089)ZIN RAS(122031100260-0)Science and Technology Human Resource Development Project(R3RJ2)Asian Development Bank,Conselho Naional de Desenvolvimento Científico e Tecnológico(306632/2022-5),zygosporic fungi in the Atlantic Forest of Pernambuco and Paraiba,Brazil(FACEPE–APQ-1346-2.12/22),Agriculture Sci-Tech Renovation(XJNKYWDZC–2022004)Research Foundation—Flanders(1206024N),FWF(P31038)Talent Recruitment Plan of Yunnan Province“High-End Foreign Experts,National Centre for Research and Development,Poland”(Tango-IV-C/0005/2019)CAS President’s International Fellowship Initiative(2021FYB0005)Smart Yunnan Project(E13K281261)High-Level Talent Recruitment Plan of Yunnan Provinces.
文摘Fungi are one of the most diverse groups of organisms with an estimated number of species in the range of 2–3 million.The higher-level ranking of fungi has been discussed in the framework of molecular phylogenetics since Hibbett et al.,and the definition and the higher ranks(e.g.,phyla)of the‘true fungi’have been revised in several subsequent publications.Rapid accumulation of novel genomic data and the advancements in phylogenetics now facilitate a robust and precise foundation for the higher-level classification within the kingdom.This study provides an updated classification of the kingdom Fungi,drawing upon a comprehensive phylogenomic analysis of Holomycota,with which we outline well-supported nodes of the fungal tree and explore more contentious groupings.We accept 19 phyla of Fungi,viz.Aphelidiomycota,Ascomycota,Basidiobolomycota,Basidiomycota,Blastocladiomycota,Calcarisporiellomycota,Chytridiomycota,Entomophthoromycota,Entorrhizomycota,Glomeromycota,Kickxellomycota,Monoblepharomycota,Mortierellomycota,Mucoromycota,Neocallimastigomycota,Olpidiomycota,Rozellomycota,Sanchytriomycota,and Zoopagomycota.In the phylogenies,Caulochytriomycota resides in Chytridiomycota;thus,the former is regarded as a synonym of the latter,while Caulochytriomycetes is viewed as a class in Chytridiomycota.We provide a description of each phylum followed by its classes.A new subphylum,Sanchytriomycotina Karpov is introduced as the only subphylum in Sanchytriomycota.The subclass Pneumocystomycetidae Kirk et al.in Pneumocystomycetes,Ascomycota is invalid and thus validated.Placements of fossil fungi in phyla and classes are also discussed,providing examples.
基金provide by National Natural Science Foundation of China(Nos.32460002,31960005,32000009,32170019,NSFC 32260004)Russian Science Foundation(Nos.24-44-00099,23-74-00071,24-44-00099)+17 种基金National Research Council of Thailand(No.N42A650547)National Institute of Nursing Research(1P20GM152333-01)National Science Foundation(2029478)Japan Society for the Promotion of Science(JSPS,23K05900)National Science Foundation of China(32150410362)Croatian Science Foundation(HRZZ-IP-2022-10-5219)RSF(21-74-20089)ZIN RAS(122031100260-0)Science and Technology Human Resource Development Project(R3RJ2)Asian Development Bank,Conselho Naional de Desenvolvimento Científico e Tecnológico(306632/2022-5)zygosporic fungi in the Atlantic Forest of Pernambuco and Paraíba,Brazil(FACEPE-APQ-1346-2.12/22)Agriculture Sci-Tech Renovation(XJNKYWDZC-2022004)Research Foundation-Flanders(1206024N)FWF(P31038)Talent Recruitment Plan of Yunnan Province“High-End Foreign Experts”,National Centre for Research and Development,Poland(Tango-Ⅳ-C/0005/2019)CAS President’s International Fellowship Initiative(2021FYB0005)Smart Yunnan Project(E13K281261)High-Level Talent Recruitment Plan of Yunnan Provinces.
文摘Fungi are one of the most diverse groups of organisms with an estimated number of species in the range of 2-3 million.The higher-level ranking of fungi has been discussed in the framework of molecular phylogenetics since Hibbett et al.,and the definition and the higher ranks(e.g.,phyla)of the‘true fungi’have been revised in several subsequent publications.Rapid accumulation of novel genomic data and the advancements in phylogenetics now facilitate a robust and precise foundation for the higher-level classification within the kingdom.This study provides an updated classification of the kingdom Fungi,drawing upon a comprehensive phylogenomic analysis of Holomycota,with which we outline well-supported nodes of the fungal tree and explore more contentious groupings.We accept 19 phyla of Fungi,viz.Aphelidiomycota,Ascomycota,Basidiobolomycota,Basidiomycota,Blastocladiomycota,Calcarisporiellomycota,Chytridiomycota,Entomophthoromycota,Entorrhizomycota,Glomeromycota,Kickxellomycota,Monoblepharomycota,Mortierellomycota,Mucoromycota,Neocal-limastigomycota,Olpidiomycota,Rozellomycota,Sanchytriomycota,and Zoopagomycota.In the phylogenies,Caulochy-triomycota resides in Chytridiomycota;thus,the former is regarded as a synonym of the latter,while Caulochytriomycetes is viewed as a class in Chytridiomycota.We provide a description of each phylum followed by its classes.A new subphylum,Sanchytriomycotina Karpov is introduced as the only subphylum in Sanchytriomycota.The subclass Pneumocystomycetidae Kirk et al.in Pneumocystomycetes,Ascomycota is invalid and thus validated.Placements of fossil fungi in phyla and classes are also discussed,providing examples.
基金This research was supported by Featured microbial resources and diversity investigation in Southwest Karst area(2014FY120100).The authors extend their sincere appreciations to the Deanship of Scientific Research at King Saud University for its funding this Prolific Research Group(PRG-1436-09).Kevin D.Hyde thanks the Chinese Academy of Sciences,project number 2013T2S0030,for the award of Visiting Professorship for Senior International Scientists at Kunming Institute of Botany.B.D.Shenoy acknowledges the funding to visit Mae Fah Luang University,Chiang Rai under Indo-Thailand Bilateral Programme(THAI-1205).Y.P.Xiao and T.C.Wen are grateful to The National Natural Science Foundation of China(No.31460012&No.31200016).Shi-Ke Huang and J.C.Kang are grateful to the Agricultural Science and Technology Foundation of Guizhou Province(Nos.NY[2013]3042),the International Collaboration Plan of Guizhou Province(No.G[2012]7006)and the Innovation Team Construction for Science And Technology of Guizhou Province(No.[2012]4007)from the Science and Technology Department of Guizhou Province,China.
文摘Sordariomycetes is one of the largest classes of Ascomycota and is characterised by perithecial ascomata and inoperculate unitunicate asci.The class includes many important plant pathogens,as well as endophytes,saprobes,epiphytes,and fungicolous,lichenized or lichenicolous taxa.The class includes freshwater,marine and terrestrial taxa and has a worldwide distribution.This paper provides an updated outline of the Sordariomycetes and a backbone tree incorporating asexual and sexual genera in the class.Based on phylogeny and morphology we introduced three subclasses;Diaporthomycetidae,Lulworthiomycetidae and Meliolomycetidae and five orders;Amplistromatales,Annulatascales,Falcocladiales,Jobellisiales and Togniniales.The outline is based on literature to the end of 2014 and the backbone tree published in this paper.Notes for 397 taxa with information,such as new family and genera novelties,novel molecular data published since the Outline of Ascomycota 2009,and new links between sexual and asexual genera and thus synonymies,are provided.The Sordariomycetes now comprises six subclasses,28 orders,90 families and 1344 genera.In addition a list of 829 genera with uncertain placement in Sordariomycetesis also provided.
基金Ausana Mapook was financially supported by Research and Researchers for Industry Program(RRI)PHD57I0012,Thailand and the German Academic Exchange Service(DAAD)for a joint TRF-DAAD(PPP 2017–2018)academic exchange grant to Kevin D.Hyde and Marc Stadler.Kevin D.Hyde thanks to 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 Number G20190139006)Thailand Research grants entitled Biodiversity,phylogeny and role of fungal endophytes on above parts of Rhizophora apiculata and Nypa fruticans(Grant No:RSA5980068)+1 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).
文摘This article provides morphological descriptions and illustrations of microfungi associated with the invasive weed,Chro-molaena odorata,which were mainly collected in northern Thailand.Seventy-seven taxa distributed in ten orders,23 families(of which Neomassarinaceae is new),12 new genera(Chromolaenicola,Chromolaenomyces,Longiappendispora,Pseudocapulatispora,Murichromolaenicola,Neoophiobolus,Paraleptospora,Pseudoroussoella,Pseudostaurosphaeria,Pseudothyridariella,Setoarthopyrenia,Xenoroussoella),47 new species(Aplosporella chromolaenae,Arthrinium chromolae-nae,Chromolaenicola chiangraiensis,C.lampangensis,C.nanensis,C.thailandensis,Chromolaenomyces appendiculatus,Diaporthe chromolaenae,Didymella chromolaenae,Dyfrolomyces chromolaenae,Leptospora chromolaenae,L.phraeana,Longiappendispora chromolaenae,Memnoniella chromolaenae,Montagnula chiangraiensis,M.chromolaenae,M.chromo-laenicola,M.thailandica,Murichromolaenicola chiangraiensis,M.chromolaenae,Muyocopron chromolaenae,M.chromo-laenicola,Neomassarina chromolaenae,Neoophiobolus chromolaenae,Neopyrenochaeta chiangraiensis,N.chromolaenae,N.thailandica,N.triseptatispora,Nigrograna chromolaenae,Nothophoma chromolaenae,Paraleptospora chromolaenae,P.chromolaenicola,Patellaria chromolaenae,Pseudocapulatispora longiappendiculata,Pseudoroussoella chromolaenae,Pseudostaurosphaeria chromolaenae,P.chromolaenicola,Pseudothyridariella chromolaenae,Pyrenochaetopsis chromolae-nae,Rhytidhysteron chromolaenae,Setoarthopyrenia chromolaenae,Sphaeropsis chromolaenicola,Tremateia chiangraiensis,T.chromolaenae,T.thailandensis,Xenoroussoella triseptata,Yunnanensis chromolaenae),12 new host records,three new taxonomic combinations(Chromolaenicola siamensis,Pseudoroussoella elaeicola,Pseudothyridariella mahakashae),and two reference specimens(Torula chromolaenae,T.fici)are described and illustrated.Unlike some other hosts,e.g.bamboo(Poaceae)and Pandanaceae,the dominant group of fungi on Siam weed were Dothideomycetes.Only 15 species previously recorded from northern Thailand were found in this study.Most of the taxa are likely to have jumped hosts from surrounding plants and are unlikely to be a specialist to Siam weed.Most fungal families found on Siam weed had divergence estimates with stem ages in the Cretaceous,which coincided with the expected origin of the host family(Asteraceae).This further indicates that the species have jumped hosts,as it is unlikely that the taxa on the alien Siam weed came from the Americas with its host.They may,however,have jumped from other Asteraceae hosts.In a preliminary screening 40(65%)of the 62 species tested showed antimicrobial activity and thus,the fungi associated with C.odorata may be promising sources of novel bioactive compound discovery.We provide a checklist of fungi associated with C.odorata based on the USDA Systematic Mycology and Microbiology Laboratory(SMML)database,relevant literature and our study.In total,130 taxa(116 identified and 14 unidentified species)are distributed in 20 orders,48 families and 85 genera.Pseudocercospora is the most commonly encountered genus on Siam weed.
基金We also thank Siriporn Luesuwan for arranging the loan of specimens from various herbaria.A.Ariyawansa and J.C Kang are grateful to the International collaboration plan of Science and Technology at Guizhou Province(contract No.[2012]7006)the construction of innovation talent team of Science and Technology at Guizhou Province(contract No.[2012]4007)+19 种基金China.D.J.Bhat is thankful to MFU for a Visiting Professorship during the tenure of which this paper was finalized.D.L.Hawksworth contributed to this work while in receipt of support from the Spanish Ministerio de Ciencia e Innovación(CGL2011-25003)Haixia Wu would like to thank the Grant for Essential Scientific Research of National Non-profit Institute to funds for research(No.CAFYBB2007002)thanks Xiaoming Chen,Ying Feng and Chen Hang(The Research Institute of Resource Insects,Chinese Academy of Forestry,China)for their valuable help.Jian-Kui Liu would like to thank Manfred Binder for providing valuable suggestions and kind assistance on phylogenetic analysisWe would like to thank MFU grant No.56101020032 for funding to study taxonomy and phylogeny of selected families of DothideomycetesJiye Yan and Xinghong Li would like to thank CARS-30 for funds.K.Tanaka would like to thank the Japan Society for the Promotion of Science(JSPS,25440199)for financial supportK.L.Pang would like to thank National Science Council of Taiwan for financial support(NSC101-2621-B-019-001-MY3).L.Muggia is grateful to the Austrian Science Foundation for financial support(FWF,P24114-B16 and Herta-Firnberg Project T481-B20)M.Doilom would like to thank the Thailand Research Fund through the Royal Golden Jubilee(RGJ)Ph.D.Program grant No.Ph.D./0072/2553 in 4.S.M.F./53/A.2MP Nelsen and R Lücking are grateful to the NSF(DEB 0715660“Neotropical Epiphytic Microlichens-An Innovative Inventory of a Highly Diverse yet Little Known Group of Symbiotic Organisms”DEB 0717476“Systematics of Dothideomycetes”)MP Nelsen also acknowledges a Brown Family Fellowship through the Field Museum,a William Harper Rainey Fellowship through the University of Chicago,and support through the Committee on Evolutionary Biology at the University of Chicago.R.Phookamsak would like to thank the Royal Golden Jubilee Ph.D.Program(PHD/0090/2551)under the Thailand Research Fund for scholarship supportS.A.Alias would like to thank Program Rakan University Malaya(PRPUM)-Phylogeny,Taxonomy,Relationships and Biotechnological Potential of Sooty Moulds.S.Boonmee also thanks Amy Y.Rossman and the U.S.Department of Agriculture Agricultural Research Service,Systematic Mycology and Microbiology Lab(SMML)USA for laboratory,funding support and advice on her work.S.Boonmee and P.Chomnunti would like to thank TRF/BIOTEC program Biodiversity Research and Training Grant BRT R_251181,BRT R_253012the Mushroom Research Foundation,Chiang Rai Province for funding support.S.Wikee would like to thank the Thailand Research Fund through the Royal Golden Jubilee Ph.D.Program agreement No PhD/0198/2552S.Wikee and JK Liu would like to thank The National Research Council of Thailand(NRCT)for the award of grant No 55201020002 to study the genus Phyllosticta in ThailandS.Suetrong acknowledges the financial support by TRF/BIOTEC program Biodiversity Research and Training Grant BRT R_351004 and BRT R_325015 to study marine fungi of ThailandSuetrong also thanks Morakot Tanticharoen,Kanyawim Kirtikara and Lily Eurwilaichitr,BIOTEC,Bangkok for their continued interest and support.Supalak Yacharoen,J.Monkai and K.D.Hyde would like to thank the Thailand Research Fund(BRG5280002)for financial supportGareth Jones is supported by the Distinguished Scientist Fellowship Program(DSFP),King Saud University,Saudi Arabia.Y.Wang would like to thank The International Scientific Cooperated Project of Guizhou Province(No[2013]7004)Yongxiang Liu would like to thank the Guizhou Research Fund(QKHZYZ[2010]5031 and QNKYYZX[2012]010)for financial supportHarrie Sipman is thanked for comments on part of the manuscript.
文摘Dothideomycetes comprise a highly diverse range of fungi characterized mainly by asci with two wall layers(bitunicate asci)and often with fissitunicate dehiscence.Many species are saprobes,with many asexual states comprising important plant pathogens.They are also endophytes,epiphytes,fungicolous,lichenized,or lichenicolous fungi.They occur in terrestrial,freshwater and marine habitats in almost every part of the world.We accept 105 families in Dothideomycetes with the new families Anteagloniaceae,Bambusicolaceae,Biatriosporaceae,Lichenoconiaceae,Muyocopronaceae,Paranectriellaceae,Roussoellaceae,Salsugineaceae,Seynesiopeltidaceae and Thyridariaceae introduced in this paper.Each family is provided with a description and notes,including asexual and asexual states,and if more than one genus is included,the type genus is also characterized.Each family is provided with at least one figure-plate,usually illustrating the type genus,a list of accepted genera,including asexual genera,and a key to these genera.A phylogenetic tree based on four gene combined analysis add support for 64 of the families and 22 orders,including the novel orders,Dyfrolomycetales,Lichenoconiales,Lichenotheliales,Monoblastiales,Natipusillales,Phaeotrichales and Strigulales.The paper is expected to provide a working document on Dothideomycetes which can be modified as new data comes to light.It is hoped that by illustrating types we provide stimulation and interest so that more work is carried out in this remarkable group of fungi.
基金Thailand Research Fund“The future of specialist fungi in a changing climate:baseline data for generalist and specialist fungi associated with ants,Rhodo-dendron species and Dracaena species”(DBG6080013)“Impact of climate change on fungal diversity and biogeography in the Greater Mekong Sub-region”(RDG6130001).
文摘A comprehensive account of fungal classification from freshwater habitats is outlined and discussed in the present review based on literature of biodiversity studies and recent morpho-phylogenetic analyses.A total of 3,870 freshwater fungal species are listed with additional details on the isolation source,habitat,geographical distribution,and molecular data.The Ascomycota(2,968 species,1,018 genera)dominated the freshwater fungal taxa wherein Sordariomycetes(823 species,298 genera)had the largest number,followed by Dothideomycetes(677 species,229 genera),Eurotiomycetes(276 species,49 genera),and Leotiomycetes(260 species,83 genera).Other phyla included in the updated classification of freshwater fungi are:Chytridiomycota(333 species,97 genera),Rozellomycota(221 species,105 genera),Basidiomycota(218 species,100 genera),Blastocladiomycota(47 species,10 genera),Monoblepharomycota(29 species,6 genera),Mucoromycota(19 spe-cies,10 genera),Aphelidiomycota(15 species,3 genera),Entomophthoromycota(6 species,4 genera),Mortierellomycota(5 species,3 genera),Olpidiomycota(4 species,1 genus),Zoopagomycota(3 species,2 genera),and Sanchytriomycota(2 species,2 genera).The freshwater fungi belong to 1,361 genera,386 families and 145 orders.The Pleosporales and Laboulbeniaceae are the largest freshwater fungal order and family comprised of 391 and 185 species,respectively.The most speciose genera are Chitonomyces(87,Laboulbeniomycetes),Verrucaria(50,Eurotiomycetes),Rhizophydium(52,Rhizophydiomycetes),Penicillium(47,Eurotiomycetes),and Candida(42,Saccharomycetes).
