In biodiversity management, spatio-temporal heterogeneity is important to consider conserving high levels of habitat diversity and ecosystems. In this study, we investigated the relationship between landscape spatio-t...In biodiversity management, spatio-temporal heterogeneity is important to consider conserving high levels of habitat diversity and ecosystems. In this study, we investigated the relationship between landscape spatio-temporal heterogeneity and biodiversity in a mosaic-landscape, located in the Fontainebleau forest (France). The diversity of successional stages along a gradient from heathland to forest as well as the persistence of Calluna vulgaris (L.) Hull in different forest stands was examined in order to find how the numerous patches of European Heathland habitat embedded in this area should be maintained. The results indicated that in the areas of high spatio-temporal heterogeneity, a general increase is observed in species richness, in particular for vascular plants, bryophytes and carabids. C. vulgaris persisted in coniferous stands and young mixed stand but decreased under deciduous trees and old mixed stands. The Ellenberg’s values for light, nutrients and acidity, show the persistence of favorable enviromental conditions for heathland vegetation under coniferous stands and young mixed stands. These results enable us to offer recommendations to better manage mosaic-landscape biodiversity, and in particular, the heathland semi-natural habitats in the Fontainebleau forest and elsewhere in Europe.展开更多
Despite a large variety of processes that can control Mo and its potential to become an environmental tracer of euxinic environment, this element is not often studied in lakes. The aim of this paper is to identify mai...Despite a large variety of processes that can control Mo and its potential to become an environmental tracer of euxinic environment, this element is not often studied in lakes. The aim of this paper is to identify main seasonal biogeochemical processes that involve Mo in a well constrained freshwater system (Lake Pavin water-column) in order to evaluate their respective importance. In Lake Pavin, 4 main processes have been identified: 1) the transitional process represented by Mo assimilation of by phytoplankton in the epilimnion (nitrogen biological fixation and nitrate assimilation);2) transient process represented by dissolved Mo adsorption onto Fe and Mn metal oxides at oxic/anoxic interface (depth 50 - 60 m);3) Mo precipitation where apparent sulfide production rate is maximum, and from 80 m depths;4) release of dissolved Mo due to Mo benthic flux or input from a deep source.展开更多
For the very first time,morpho-anatomical features of both fruiting bodies as well as below-ground structures have been confronted with a newly produced multigene phylogeny of root symbiotic basidiomycetes using one o...For the very first time,morpho-anatomical features of both fruiting bodies as well as below-ground structures have been confronted with a newly produced multigene phylogeny of root symbiotic basidiomycetes using one of the most speciose genera of ectomycorrhizal fungi(Russula,Russulales)as an example.In this first of two papers,the authors focus more specifically on below-ground structures.Our five-gene phylogeny divides the genus in five main clades,here interpreted as representing seven subgenera,all significantly supported.Although more conserved than features of fruiting bodies,the anatomy of ectomycorrhiza does not allow for an unambiguous characterization of the main clades resolved by phylogenetic analysis,but the anatomy of ectomycorrhiza performs better to naturally classify the species of this genus.Features of fruiting bodies remain much more adequate for the delimitation of terminal clades and are irreplaceable for morphological species identification.Tropical taxa mostly nest in ancient lineages,but are also present in some terminal clades of otherwise temperate species groups.The shift from plectenchymatic to pseudoparenchymatic ECM outer mantle structures happened most likely already in the paleotropics,and is here hypothesized to have facilitated a major diversification of the genus with new hosts in the northern hemisphere.Available data as well as our own observations on below ground structures of several Lactifluus species suggests that this genus shares with Russula the absence of lactifers in ECM mantles and rhizomorphs,contrary to species of Lactarius where lactifers are always present.First observations on rhizomorphs of species in Multifurca confirm the presence of vessel-like and ladder-like hyphae,also found in the other agarioid genera of this family,while distinct lactifers are only present in the lactarioid,but not in russuloid members of this genus.展开更多
Collembola are among the most abundant and diverse soil animals contributing significantly to major ecosystem processes.Global climate changes in temperature and precipitation are likely to affect their community stru...Collembola are among the most abundant and diverse soil animals contributing significantly to major ecosystem processes.Global climate changes in temperature and precipitation are likely to affect their community structure and functioning and this is likely to differ along altitudinal gradients.In this study,changes in richness,abundance,and body size of onychiurin Collembola with altitude have been investigated in the Changbai Mountain range of northeast China.Sampling was carried out on a 30 km long transect along forested slopes of the Changbai Mountains.Standardized samples were taken from 800 to 1700 m at seven altitudinal levels.More than 5000 specimens of Onychiurinae representing 13 species were collected,making Onychiuridae(with the sole subfamily Onychiurinae in Changbai)the most abundant Collembolan family in the area.The number of species of Onychiurinae slightly increased along the altitudinal gradient.The average number of species per sample,but not the total abundance,changed significantly but not monotonically with altitude.Body size of Onychiurinae species decreased significantly with increasing altitude contradicting Bergmann’s rule.Furthermore,the abundance of the three body-size groups differentially responded to increasing altitude,with the abundance of the large body-size group decreasing and the abundance of the small body-size group increasing.Our results suggest that the distribution patterns of Collembola along the altitudinal gradient are complicated and may be linked to taxonomic groups and bioclimatic zones.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
Introduction:‘Nuisance species’(or‘invasive’species)are often proposed to be the second most important concern in the context of the current biodiversity crisis.Despite increasing evidence that exotic species do n...Introduction:‘Nuisance species’(or‘invasive’species)are often proposed to be the second most important concern in the context of the current biodiversity crisis.Despite increasing evidence that exotic species do not always become invasive,this perception is still common in the scientific community.This suggests that other issues are at stake in the concept of nuisance species rather than just the problems they raise,grounded mostly in ecological or economic arguments.Methods:We retraced the evolution of pigeon representation in France through an extensive review of ancient texts related to pigeons and reviewed more than 240 source texts,dating from the seventh century to the 1990s.We completed these data with literature on human-animal relationships and animal conceptions in religious,philosophical,scientific,and political currents of thought that were representative of Western and,specifically,French tradition.Results:We used the heated debate over pigeons(Columba livia)as pests as a case study by analyzing the ecological,social,economic,and political relations regarding pigeons.Through a historical perspective of the debate about and understanding of pigeons,we propose a new and complementary explanation for the modern thinking of pigeons as a nuisance species,based on what we termed their socio-nature characteristics.In particular,we used social representations theory to highlight the issues of human identity construction at stake in the construction of pigeons as a nuisance species.Conclusions:We invite the reader to consider the impact of such human self-definition on environmental stances,as it could constrain further developments or improvements of conservation perspectives.展开更多
This is the sixth in a series of papers where we bring collaborating mycologists together to produce a set of notes of several taxa of fungi.In this study we introduce a new family Fuscostagonosporaceae in Dothideomyc...This is the sixth in a series of papers where we bring collaborating mycologists together to produce a set of notes of several taxa of fungi.In this study we introduce a new family Fuscostagonosporaceae in Dothideomycetes.We also introduce the new ascomycete genera Acericola,Castellaniomyces,Dictyosporina and Longitudinalis and new species Acericola italica,Alternariaster trigonosporus,Amarenomyces dactylidis,Angustimassarina coryli,Astrocystis bambusicola,Castellaniomyces rosae,Chaetothyrina artocarpi,Chlamydotubeufia krabiensis,Colletotrichum lauri,Collodiscula chiangraiensis,Curvularia palmicola,Cytospora mali-sylvestris,Dictyocheirospora cheirospora,Dictyosporina ferruginea,Dothiora coronillae,Dothiora spartii,Dyfrolomyces phetchaburiensis,Epicoccum cedri,Epicoccum pruni,Fasciatispora calami,Fuscostagonospora cytisi,Grandibotrys hyalinus,Hermatomyces nabanheensis,Hongkongmyces thailandica,Hysterium rhizophorae,Jahnula guttulaspora,Kirschsteiniothelia rostrata,Koorchalomella salmonispora,Longitudinalis nabanheensis,Lophium zalerioides,Magnibotryascoma mali,Meliola clerodendri-infortunati,Microthyrium chinense,Neodidymelliopsis moricola,Neophaeocryptopus spartii,Nigrograna thymi,Ophiocordyceps cossidarum,Ophiocordyceps issidarum,Ophiosimulans plantaginis,Otidea pruinosa,Otidea stipitata,Paucispora kunmingense,Phaeoisaria microspora,Pleurothecium floriforme,Poaceascoma halophila,Periconia aquatica,Periconia submersa,Phaeosphaeria acaciae,Phaeopoacea muriformis,Pseudopithomyces kunmingnensis,Ramgea ozimecii,Sardiniella celtidis,Seimatosporium italicum,Setoseptoria scirpi,Torula gaodangensis and Vamsapriya breviconidiophora.We also provide an amended account of Rhytidhysteron to include apothecial ascomata and a J?hymenium.The type species of Ascotrichella hawksworthii(Xylariales genera incertae sedis),Biciliopsis leptogiicola(Sordariomycetes genera incertae sedis),Brooksia tropicalis(Micropeltidaceae),Bryochiton monascus(Teratosphaeriaceae),Bryomyces scapaniae(Pseudoperisporiaceae),Buelliella minimula(Dothideomycetes genera incertae sedis),Carinispora nypae(Pseudoastrosphaeriellaceae),Cocciscia hammeri(Verrucariaceae),Endoxylina astroidea(Diatrypaceae),Exserohilum turcicum(Pleosporaceae),Immotthia hypoxylon(Roussoellaceae),Licopolia franciscana(Vizellaceae),Murispora rubicunda(Amniculicolaceae)and Doratospora guianensis(synonymized under Rizalia guianensis,Trichosphaeriaceae)were reexamined and descriptions,illustrations and discussion on their familial placement are given based on phylogeny and morphological data.New host records or new country reports are provided for Chlamydotubeufia huaikangplaensis,Colletotrichum fioriniae,Diaporthe subclavata,Diatrypella vulgaris,Immersidiscosia eucalypti,Leptoxyphium glochidion,Stemphylium vesicarium,Tetraploa yakushimensis and Xepicula leucotricha.Diaporthe baccae is synonymized under Diaporthe rhusicola.A reference specimen is provided for Periconia minutissima.Updated phylogenetic trees are provided for most families and genera.We introduce the new basidiomycete species Agaricus purpurlesquameus,Agaricus rufusfibrillosus,Lactifluus holophyllus,Lactifluus luteolamellatus,Lactifluus pseudohygrophoroides,Russula benwooii,Russula hypofragilis,Russula obscurozelleri,Russula parapallens,Russula phoenicea,Russula pseudopelargonia,Russula pseudotsugarum,Russula rhodocephala,Russula salishensis,Steccherinum amapaense,Tephrocybella constrictospora,Tyromyces amazonicus and Tyromyces angulatus and provide updated trees to the genera.We also introduce Mortierella formicae in Mortierellales,Mucoromycota and provide an updated phylogenetic tree.展开更多
Since 2007,the quality of Russula descriptions has improved and the use of molecular support for species delimitation and the number of published new species has increased.However,the description style is not consiste...Since 2007,the quality of Russula descriptions has improved and the use of molecular support for species delimitation and the number of published new species has increased.However,the description style is not consistent and has regional or author-specific patterns.Most recent publications still favour descriptions of spores compared to hymenium and pileipellis elements,and usually only the spore size is provided with statistical support.This study proposes standards for descriptions of the microscopic structure of Russula species(Russulaceae,Agaricomycetes).We present the description template,the template measurements table,the specific terminology and the essential chemical reagents.The proposed standards were tested by mycologists from 11 countries who met at the Russula Microscopy Workshop in Slovakia.Descriptions of 26 species from 9 countries and four continents were prepared,among them R.amarissima,R.castanopsidis,R.seperina and R.subtilis are re-described and 15 species are introduced as new:R.abietiphila,R.amerorecondita,R.aurantioflava,R.echidna,R.flavobrunnescens,R.fluvialis,R.fortunae,R.garyensis,R.gemmata,R.laevis,R.madrensis,R.olivaceohimalayensis,R.purpureogracilis,R.sancti-pauli and R.wielangtae.Seven descriptions for candidate new species are provided without a formal name assignment.Pairwise comparison of species described in this study with available similar descriptions of related species suggests that microscopic characters from all parts of the basidiomata can be equally important for species recognition and they deserve the same treatment including number of measurements and statistics.The majority of recent studies does not recognise differences between the pileus margin and centre,but more than one-third of the species described in this study show distinct differences between the pileus areas,emphasizing the importance to specify the origin of pileipellis observations.This study proved that there is frequently insufficient difference in the ITS barcode between closely related species and that it is necessary to use more genetic markers combined with ecological and geographical data.展开更多
文摘In biodiversity management, spatio-temporal heterogeneity is important to consider conserving high levels of habitat diversity and ecosystems. In this study, we investigated the relationship between landscape spatio-temporal heterogeneity and biodiversity in a mosaic-landscape, located in the Fontainebleau forest (France). The diversity of successional stages along a gradient from heathland to forest as well as the persistence of Calluna vulgaris (L.) Hull in different forest stands was examined in order to find how the numerous patches of European Heathland habitat embedded in this area should be maintained. The results indicated that in the areas of high spatio-temporal heterogeneity, a general increase is observed in species richness, in particular for vascular plants, bryophytes and carabids. C. vulgaris persisted in coniferous stands and young mixed stand but decreased under deciduous trees and old mixed stands. The Ellenberg’s values for light, nutrients and acidity, show the persistence of favorable enviromental conditions for heathland vegetation under coniferous stands and young mixed stands. These results enable us to offer recommendations to better manage mosaic-landscape biodiversity, and in particular, the heathland semi-natural habitats in the Fontainebleau forest and elsewhere in Europe.
文摘Despite a large variety of processes that can control Mo and its potential to become an environmental tracer of euxinic environment, this element is not often studied in lakes. The aim of this paper is to identify main seasonal biogeochemical processes that involve Mo in a well constrained freshwater system (Lake Pavin water-column) in order to evaluate their respective importance. In Lake Pavin, 4 main processes have been identified: 1) the transitional process represented by Mo assimilation of by phytoplankton in the epilimnion (nitrogen biological fixation and nitrate assimilation);2) transient process represented by dissolved Mo adsorption onto Fe and Mn metal oxides at oxic/anoxic interface (depth 50 - 60 m);3) Mo precipitation where apparent sulfide production rate is maximum, and from 80 m depths;4) release of dissolved Mo due to Mo benthic flux or input from a deep source.
文摘For the very first time,morpho-anatomical features of both fruiting bodies as well as below-ground structures have been confronted with a newly produced multigene phylogeny of root symbiotic basidiomycetes using one of the most speciose genera of ectomycorrhizal fungi(Russula,Russulales)as an example.In this first of two papers,the authors focus more specifically on below-ground structures.Our five-gene phylogeny divides the genus in five main clades,here interpreted as representing seven subgenera,all significantly supported.Although more conserved than features of fruiting bodies,the anatomy of ectomycorrhiza does not allow for an unambiguous characterization of the main clades resolved by phylogenetic analysis,but the anatomy of ectomycorrhiza performs better to naturally classify the species of this genus.Features of fruiting bodies remain much more adequate for the delimitation of terminal clades and are irreplaceable for morphological species identification.Tropical taxa mostly nest in ancient lineages,but are also present in some terminal clades of otherwise temperate species groups.The shift from plectenchymatic to pseudoparenchymatic ECM outer mantle structures happened most likely already in the paleotropics,and is here hypothesized to have facilitated a major diversification of the genus with new hosts in the northern hemisphere.Available data as well as our own observations on below ground structures of several Lactifluus species suggests that this genus shares with Russula the absence of lactifers in ECM mantles and rhizomorphs,contrary to species of Lactarius where lactifers are always present.First observations on rhizomorphs of species in Multifurca confirm the presence of vessel-like and ladder-like hyphae,also found in the other agarioid genera of this family,while distinct lactifers are only present in the lactarioid,but not in russuloid members of this genus.
基金supported by the National Natural Science Foundation of China(grant numbers 41571052,41811530086,41811530279,31861133006)the 2013-2015 CoopIntEer CNRSNSFC projects between China and France+1 种基金the German Research Foundation(DFG,SCHE 376-42/1)the funding provided by Alexander von Humboldt Foundation(Germany).
文摘Collembola are among the most abundant and diverse soil animals contributing significantly to major ecosystem processes.Global climate changes in temperature and precipitation are likely to affect their community structure and functioning and this is likely to differ along altitudinal gradients.In this study,changes in richness,abundance,and body size of onychiurin Collembola with altitude have been investigated in the Changbai Mountain range of northeast China.Sampling was carried out on a 30 km long transect along forested slopes of the Changbai Mountains.Standardized samples were taken from 800 to 1700 m at seven altitudinal levels.More than 5000 specimens of Onychiurinae representing 13 species were collected,making Onychiuridae(with the sole subfamily Onychiurinae in Changbai)the most abundant Collembolan family in the area.The number of species of Onychiurinae slightly increased along the altitudinal gradient.The average number of species per sample,but not the total abundance,changed significantly but not monotonically with altitude.Body size of Onychiurinae species decreased significantly with increasing altitude contradicting Bergmann’s rule.Furthermore,the abundance of the three body-size groups differentially responded to increasing altitude,with the abundance of the large body-size group decreasing and the abundance of the small body-size group increasing.Our results suggest that the distribution patterns of Collembola along the altitudinal gradient are complicated and may be linked to taxonomic groups and bioclimatic zones.
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).
文摘Introduction:‘Nuisance species’(or‘invasive’species)are often proposed to be the second most important concern in the context of the current biodiversity crisis.Despite increasing evidence that exotic species do not always become invasive,this perception is still common in the scientific community.This suggests that other issues are at stake in the concept of nuisance species rather than just the problems they raise,grounded mostly in ecological or economic arguments.Methods:We retraced the evolution of pigeon representation in France through an extensive review of ancient texts related to pigeons and reviewed more than 240 source texts,dating from the seventh century to the 1990s.We completed these data with literature on human-animal relationships and animal conceptions in religious,philosophical,scientific,and political currents of thought that were representative of Western and,specifically,French tradition.Results:We used the heated debate over pigeons(Columba livia)as pests as a case study by analyzing the ecological,social,economic,and political relations regarding pigeons.Through a historical perspective of the debate about and understanding of pigeons,we propose a new and complementary explanation for the modern thinking of pigeons as a nuisance species,based on what we termed their socio-nature characteristics.In particular,we used social representations theory to highlight the issues of human identity construction at stake in the construction of pigeons as a nuisance species.Conclusions:We invite the reader to consider the impact of such human self-definition on environmental stances,as it could constrain further developments or improvements of conservation perspectives.
基金The authors extend their appreciation to the International Scientific Partnership Program ISPP at King Saud University for funding this research work through ISPP#0089.Kevin D.Hyde would like to thank the Molecular Biology Experimental Center for the help on molecular work,the Mushroom Research Foundation(MRF),Chiang Rai,Thailand,the Thailand Research Fund grant no RSA5980068 entitled Biodiversity,Phylogeny and role of fungal endophytes on above parts of Rhizophora apiculata and Nypa fruticans,the Chinese Academy of Sciences,Project Number 2013T2S0030for the award of Visiting Professorship for Senior International Scientists at Kunming Institute of Botany and Mae Fah Luang University for a grants“Biodiversity,phylogeny and role of fungal endophytes of Pandanaceae”(Grant number:592010200112)+11 种基金“Diseases of mangrove trees and maintenance of good forestry practice”(Grant number:60201000201 for supporting this study.K.D.Hyde is an Adjunct Professor at Chiang Mai University.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 Kevin D.Hyde and Marc Stadler,and the RGJ for a personal grant to Benjarong Thongbai(No.Ph.D/0138/2553 in 4.S.MF/53/A.3)is gratefully acknowledged.Satinee Suetrong thanks to Apilux Loilong for collecting samples.This work was supported by the TRF/BIOTEC program for Biodiversity Research and Training Grant BRT R_352112,R_249001,R_251006.For their continued interest and support we also thank BIOTEC,Prof.Morakot Tanticharoen,Dr.Kanyawim Kirtikara and Dr.Lily Eurwilaichitr.Rungtiwa Phookamsak expresses appreciation to The CAS President’s International Fellowship for Postdoctoral Researchers,project number 2017PB0072the Research Fund from China Postdoctoral Science Foundation(Grant No.Y71B283261)and Chiang Mai University for financial supportWe would like to thank DrsRobert Lucking,AndreAptroot and Cecile Gueidan for available suggestion.Saranyaphat Boonmee would like to thank the National Research Council of Thailand(no.2560A30702021)the Thailand Research Fund(Project No.TRG5880152)Chayanard Phukhamsakda would like to thank Royal Golden Jubilee Ph.D.Program under Thailand Research Fund,for the award of a scholarship no.PHD/0020/2557.Ausana Mapook is grateful to Research and Researchers for Industries(RRI)PHD57I0012.Ting-Chi Wen and Yuan-Pin Xiao are grateful to The National Natural Science Foundation of China(Nos.31460012 and 3161113034)Samantha C.Karunarathna thanks Yunnan Provincial Department of Human Resources and Social Security funded postdoctoral project(Number 179122)for supporting his postdoctoral research study.Ivana Kusan and Zdenko Tkalcec have been partially supported by Croatian Science Foundation under the project HRZZIP-11-2013-2202(ACCTA)We would also like to thank Roman Ozimec and Najla Bakovicfor collecting the samples and partially Oikon Ltd.for financing the fieldwork.We would like to thank Dr.Shaun Pennycook for checking most of the Latin names.Qing Tian and Putarak Chomnunti extend their sincere thanks to the National Research Council of Thailand(grant for Dothideomycetes No.2560A30702014)Putarak Chomnunti would like to thanks for Thailand Research Fund grant no.MRG6080089Dr.Rajesh Jeewon is grateful to University of Mauritius and Mae Fah Luang University for research support.Olinto L.Pereira thank the 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 areas.Young Woon Lim and Hyun Lee are grateful to the National Institute of Biological Resources(NIBR 20171104)Republic of Korea.The study was partially supported by the National Science Centre,Poland under grant No.2015/17/D/NZ8/00778 to Julia Pawłowska and UMO-2016/23/B/NZ8/00897 to Marta Wrzosek.Anna Bazzicalupo,Bart Buyck,Daniel Miller and Mary L.Berbee thank WTU and the Burke Museum for scanned images of Benjamin Woo’s datasheets and photographs of Russula specimens and for the loan of Woo’s specimens.Mary L.Berbee acknowledges support by Discovery Grant RGPIN-2016-03746National Science and Engineering Research Council of Canada.Anna Bazzicalupo acknowledges the student grants for field work and study abroad from the NSERC CREATE Training Program in Biodiversity Research,Sonoma County Mycological Association Student Grant,and Daniel E.Stuntz Memorial Foundation Individual Grant.The Key Research Program of Frontier Sciences of the Chinese Academy of Sciences(grant number QYZDY-SSW-SMC014)is also thanked for support.
文摘This is the sixth in a series of papers where we bring collaborating mycologists together to produce a set of notes of several taxa of fungi.In this study we introduce a new family Fuscostagonosporaceae in Dothideomycetes.We also introduce the new ascomycete genera Acericola,Castellaniomyces,Dictyosporina and Longitudinalis and new species Acericola italica,Alternariaster trigonosporus,Amarenomyces dactylidis,Angustimassarina coryli,Astrocystis bambusicola,Castellaniomyces rosae,Chaetothyrina artocarpi,Chlamydotubeufia krabiensis,Colletotrichum lauri,Collodiscula chiangraiensis,Curvularia palmicola,Cytospora mali-sylvestris,Dictyocheirospora cheirospora,Dictyosporina ferruginea,Dothiora coronillae,Dothiora spartii,Dyfrolomyces phetchaburiensis,Epicoccum cedri,Epicoccum pruni,Fasciatispora calami,Fuscostagonospora cytisi,Grandibotrys hyalinus,Hermatomyces nabanheensis,Hongkongmyces thailandica,Hysterium rhizophorae,Jahnula guttulaspora,Kirschsteiniothelia rostrata,Koorchalomella salmonispora,Longitudinalis nabanheensis,Lophium zalerioides,Magnibotryascoma mali,Meliola clerodendri-infortunati,Microthyrium chinense,Neodidymelliopsis moricola,Neophaeocryptopus spartii,Nigrograna thymi,Ophiocordyceps cossidarum,Ophiocordyceps issidarum,Ophiosimulans plantaginis,Otidea pruinosa,Otidea stipitata,Paucispora kunmingense,Phaeoisaria microspora,Pleurothecium floriforme,Poaceascoma halophila,Periconia aquatica,Periconia submersa,Phaeosphaeria acaciae,Phaeopoacea muriformis,Pseudopithomyces kunmingnensis,Ramgea ozimecii,Sardiniella celtidis,Seimatosporium italicum,Setoseptoria scirpi,Torula gaodangensis and Vamsapriya breviconidiophora.We also provide an amended account of Rhytidhysteron to include apothecial ascomata and a J?hymenium.The type species of Ascotrichella hawksworthii(Xylariales genera incertae sedis),Biciliopsis leptogiicola(Sordariomycetes genera incertae sedis),Brooksia tropicalis(Micropeltidaceae),Bryochiton monascus(Teratosphaeriaceae),Bryomyces scapaniae(Pseudoperisporiaceae),Buelliella minimula(Dothideomycetes genera incertae sedis),Carinispora nypae(Pseudoastrosphaeriellaceae),Cocciscia hammeri(Verrucariaceae),Endoxylina astroidea(Diatrypaceae),Exserohilum turcicum(Pleosporaceae),Immotthia hypoxylon(Roussoellaceae),Licopolia franciscana(Vizellaceae),Murispora rubicunda(Amniculicolaceae)and Doratospora guianensis(synonymized under Rizalia guianensis,Trichosphaeriaceae)were reexamined and descriptions,illustrations and discussion on their familial placement are given based on phylogeny and morphological data.New host records or new country reports are provided for Chlamydotubeufia huaikangplaensis,Colletotrichum fioriniae,Diaporthe subclavata,Diatrypella vulgaris,Immersidiscosia eucalypti,Leptoxyphium glochidion,Stemphylium vesicarium,Tetraploa yakushimensis and Xepicula leucotricha.Diaporthe baccae is synonymized under Diaporthe rhusicola.A reference specimen is provided for Periconia minutissima.Updated phylogenetic trees are provided for most families and genera.We introduce the new basidiomycete species Agaricus purpurlesquameus,Agaricus rufusfibrillosus,Lactifluus holophyllus,Lactifluus luteolamellatus,Lactifluus pseudohygrophoroides,Russula benwooii,Russula hypofragilis,Russula obscurozelleri,Russula parapallens,Russula phoenicea,Russula pseudopelargonia,Russula pseudotsugarum,Russula rhodocephala,Russula salishensis,Steccherinum amapaense,Tephrocybella constrictospora,Tyromyces amazonicus and Tyromyces angulatus and provide updated trees to the genera.We also introduce Mortierella formicae in Mortierellales,Mucoromycota and provide an updated phylogenetic tree.
基金supported by the project on the survey and excavation of Korean indigenous species of the National Institute of Biological Resources(grant number NIBR201902113)。
文摘Since 2007,the quality of Russula descriptions has improved and the use of molecular support for species delimitation and the number of published new species has increased.However,the description style is not consistent and has regional or author-specific patterns.Most recent publications still favour descriptions of spores compared to hymenium and pileipellis elements,and usually only the spore size is provided with statistical support.This study proposes standards for descriptions of the microscopic structure of Russula species(Russulaceae,Agaricomycetes).We present the description template,the template measurements table,the specific terminology and the essential chemical reagents.The proposed standards were tested by mycologists from 11 countries who met at the Russula Microscopy Workshop in Slovakia.Descriptions of 26 species from 9 countries and four continents were prepared,among them R.amarissima,R.castanopsidis,R.seperina and R.subtilis are re-described and 15 species are introduced as new:R.abietiphila,R.amerorecondita,R.aurantioflava,R.echidna,R.flavobrunnescens,R.fluvialis,R.fortunae,R.garyensis,R.gemmata,R.laevis,R.madrensis,R.olivaceohimalayensis,R.purpureogracilis,R.sancti-pauli and R.wielangtae.Seven descriptions for candidate new species are provided without a formal name assignment.Pairwise comparison of species described in this study with available similar descriptions of related species suggests that microscopic characters from all parts of the basidiomata can be equally important for species recognition and they deserve the same treatment including number of measurements and statistics.The majority of recent studies does not recognise differences between the pileus margin and centre,but more than one-third of the species described in this study show distinct differences between the pileus areas,emphasizing the importance to specify the origin of pileipellis observations.This study proved that there is frequently insufficient difference in the ITS barcode between closely related species and that it is necessary to use more genetic markers combined with ecological and geographical data.