Alternate wetting and drying(AWD)system,in which water has been reduced by approximately 35%with an increased occurrence of beneficial arbuscular mycorrhizal(AM)symbiosis and no negative impact on rice yield,was propo...Alternate wetting and drying(AWD)system,in which water has been reduced by approximately 35%with an increased occurrence of beneficial arbuscular mycorrhizal(AM)symbiosis and no negative impact on rice yield,was proposed to utilize water and nutrients more sustainable.In this study,we selected six rice cultivars(Centauro,Loto,Selenio,Vialone nano,JSendra and Puntal)grown under AWD conditions,and investigated their responsiveness to AM colonization and how they select diverse AM taxa.In order to investigate root-associated AM fungus communities,molecular cloning-Sanger sequencing on small subunit rDNA data were obtained from five out of the six rice cultivars and compared with Next Generation Sequencing(NGS)data,which were previously obtained in Vialone nano.The results showed that all the cultivars were responsive to AM colonization with the development of AM symbiotic structures,even if with differences in the colonization and arbuscule abundance in the root systems.We identified 16 virtual taxa(VT)in the soil compartment and 7 VT in the root apparatus.We emphasized that the NGS analysis gives additional value to the results thanks to a more in-depth reading of the less represented AM fungus taxa.展开更多
The rising claim for more environmental friendly and healthy agriculture is a strong incentive to find alternative strategies to replace the use of mineral fertilizer and pesticide. Arbuscular mycorrhizal fungi (AMF),...The rising claim for more environmental friendly and healthy agriculture is a strong incentive to find alternative strategies to replace the use of mineral fertilizer and pesticide. Arbuscular mycorrhizal fungi (AMF), a main component of soil microbiota, represent a promising tool as providers of key ecological services. The present work represented one of the first attempts to study, under a morphological and molecular point of view, the AMF communities associated to some strategic crops in Vietnam. The findings about the AMF morphotypes dominant in different crop systems could be a starting point for the development of well performing and adapted inocula suitable for the application in field.展开更多
Given the attention drawn since several decades by arbuscular mycorrhizal fungi (AMF) as potential biological alternatives to chemicals in a low-input agriculture, much effort has been spent in the investigation of me...Given the attention drawn since several decades by arbuscular mycorrhizal fungi (AMF) as potential biological alternatives to chemicals in a low-input agriculture, much effort has been spent in the investigation of mechanisms influencing the dynamics inside AMF communities. In the present study we evaluated the influence of different crop rotations on the AMF soil community, after a 50 y long-term field experiment established at Martonvásár, Hungary. Four types of crop rotation were chosen for sampling: corn monocropping, corn-alfalfa, corn-wheat, and corn-spring barley-peas-wheat. Community composition of AMF in soil was analyzed with a molecular approach amplifying a portion of 28S rDNA. The crop rotation practice didn’t show an influence on identity of the species composing AMF assemblages, but on the other hand seemed to affect positively the true diversity, defined as number of MOTUs present in the communities.展开更多
This article is the 17th in the Fungal Diversity Notes series which allows the researchers to publish fungal collections with updated reports of fungus-host and fungus-geography.Herein we report 97 taxa with four new ...This article is the 17th in the Fungal Diversity Notes series which allows the researchers to publish fungal collections with updated reports of fungus-host and fungus-geography.Herein we report 97 taxa with four new genera distributed in three phyla(Ascomycota,Glomeromycota and Mucoromycota),11 classes,38 orders and 62 families collected from various regions worldwide.This collection is further classified into taxa from 69 genera with four novel genera namely Jinshana,Lithophyllospora,Parapolyplosphaeria and Stegonsporiicola.Furthermore,71 new species,21 new records,one new combination and four novel phylogenetic placements are provided.The new species comprise Acrocalymma estuarinum,Aggregatorygma isidiatum,Alleppeysporonites elsikii,Amphibambusa aquatica,Apiospora hongheensis,Arthrobotrys tachengensis,Calonectria potisiana,Collariella hongheensis,Colletotrichum squamosae,Corynespora chengduensis,Diaporthe beijingensis,Dicellaesporites plicatus,Dicellaesporites verrucatus,Dictyoarthrinium endophyticum,Distoseptispora chiangraiensis,Dothiora eucalypti,Epicoccum indicum,Exesisporites chandrae,Fitzroyomyces pseudopandanicola,Fomitiporia exigua,Fomitiporia rondonii,Fulvifomes subthailandicus,Gigaspora siqueirae,Gymnopus ailaoensis,Hyalorbilia yunnanensis,Hygrocybe minimiholatra,H.mitsinjoensis,H.parviholatra,H.solis,H.vintsy,Helicogermslita kunmingensis,Jinshana tangtangiae,Kirschsteiniothelia dujuanhuensis,Lamproderma subcristatum,Leucoagaricus madagascarensis,Leucocoprinus mantadiaensis,Lithophyllospora australis,Marasmius qujingensis,Melomastia aquilariae,Monoporisporites jansoniusii,M.pattersonii,Monoporisporites valdiyae,Mucispora maesotensis,Mucor soli,Muyocopron yunnanensis,Nigrospora tomentosae,Ocellularia psorirregularis,Ophiocordyceps duyunensis,Oxneriaria nigrodisca,Oxydothis aquatica,O.filiforme,Phacidiella xishuangbannaensis,Phlebiopsis subgriseofuscescens,Pleurothecium takense,Pleurotus tuber-regium,Pseudochaetosphaeronema puerensis,Pseudodactylaria guttulate,Racheliella chinensis,Rhexoacrodictys fangensis,Roussoella neoaquatica,Rubroboletus pruinosus,Sanghuangporus subzonatus,Scytalidium assmuthi,Shrungabeeja kudremukhensis,Spirographa skorinae,Stanjehughesia bambusicola,Stegonsporiicola aurantiaca,Umbelopsis hingganensis,Vararia tenuata,Verruconis pakchongensis,Wongia bandungensis,and Zygosporium cymodoceae.The new combination is Parapolyplosphaeria thailandica(≡Polyplosphaeria thailandica).The 21 new hosts,geographical and habitat records comprise Acrocalymma fici,Apiculospora spartii,Aspergillus subramanianii,Camposporium ramosum,Clonostachys rogersoniana,Colletotrichum brevisporum,C.plurivorum,Collybiopsis gibbosa,Dictyosporium tratense,Distoseptispora adscendens,Exosporium livistonae,Ganoderma gibbosum,Graphis mikuraensis,Gymnosporangium paraphysatum,Lasiodiplodia thailandica,Moesziomyces bullatus,Penicillium cremeogriseum,P.echinulonalgiovense,P.javanicum,P.lanosocoeruleum,P.polonicum,and Pleurotus tuber-regium.Graphis chlorotica,G.panhalensis and G.parilis are given as novel phylogenetic placements.In addition,we provide the morphology of Tarzetta tibetensis which was missing in the previous Fungal Diversity Notes 1611–1716.Identification of characterization of all these taxa are supported by morphological and multigene phylogenetic analyses.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
基金AGER-Fondazioni in rete per la ricerca agroalimentare(https://www.progettoager.it/)(Grant No.2010-2369)by Joint Programming Initiative on Agriculture,Food Security and Climate Change(FACCE-JPI)project Green Rice(Sustainable and environmental friendly rice cultivation systems in Europe).
文摘Alternate wetting and drying(AWD)system,in which water has been reduced by approximately 35%with an increased occurrence of beneficial arbuscular mycorrhizal(AM)symbiosis and no negative impact on rice yield,was proposed to utilize water and nutrients more sustainable.In this study,we selected six rice cultivars(Centauro,Loto,Selenio,Vialone nano,JSendra and Puntal)grown under AWD conditions,and investigated their responsiveness to AM colonization and how they select diverse AM taxa.In order to investigate root-associated AM fungus communities,molecular cloning-Sanger sequencing on small subunit rDNA data were obtained from five out of the six rice cultivars and compared with Next Generation Sequencing(NGS)data,which were previously obtained in Vialone nano.The results showed that all the cultivars were responsive to AM colonization with the development of AM symbiotic structures,even if with differences in the colonization and arbuscule abundance in the root systems.We identified 16 virtual taxa(VT)in the soil compartment and 7 VT in the root apparatus.We emphasized that the NGS analysis gives additional value to the results thanks to a more in-depth reading of the less represented AM fungus taxa.
基金supported by the TÉT-10-1-2011-0648“Hungarian-Vietnamese intergovernmental cooperation program”by 53/2011/HĐ-NĐT(MOST-VietNam)by the TÁMOP 4.2.2/B-10/1-2010-011“Develop-ment of a complex educational assistance/support system for talented students and prospective researchers at the Szent István University”project.
文摘The rising claim for more environmental friendly and healthy agriculture is a strong incentive to find alternative strategies to replace the use of mineral fertilizer and pesticide. Arbuscular mycorrhizal fungi (AMF), a main component of soil microbiota, represent a promising tool as providers of key ecological services. The present work represented one of the first attempts to study, under a morphological and molecular point of view, the AMF communities associated to some strategic crops in Vietnam. The findings about the AMF morphotypes dominant in different crop systems could be a starting point for the development of well performing and adapted inocula suitable for the application in field.
文摘Given the attention drawn since several decades by arbuscular mycorrhizal fungi (AMF) as potential biological alternatives to chemicals in a low-input agriculture, much effort has been spent in the investigation of mechanisms influencing the dynamics inside AMF communities. In the present study we evaluated the influence of different crop rotations on the AMF soil community, after a 50 y long-term field experiment established at Martonvásár, Hungary. Four types of crop rotation were chosen for sampling: corn monocropping, corn-alfalfa, corn-wheat, and corn-spring barley-peas-wheat. Community composition of AMF in soil was analyzed with a molecular approach amplifying a portion of 28S rDNA. The crop rotation practice didn’t show an influence on identity of the species composing AMF assemblages, but on the other hand seemed to affect positively the true diversity, defined as number of MOTUs present in the communities.
基金National Natural Science Foundation of China(Nos.32370021 and 31860008)the Innovative team program of the Department of Education of Guangdong Province(Nos.2022KCXTD015 and 2022ZDJS020)+75 种基金the Project of Fungi Investigation in Tomur Mountains National Nature Reserve(2021-01-139-2)the National Natural Science Foundation of China(No.32100012)the Science and Technology Bureau of Guangzhou City(202201011618)to acknowledge Zhongkai University of Agriculture and Engineering,talent funding(Grant number KA210319288)the Guangzhou Science and Technology Plan Project(2023A04J1427)the Key Laboratory of Green Prevention and Control on Fruits and Vegetables in South China,Guangdong(KA21031C502)Zhongkai University of Agriculture and Engineering,Guangzhou,Guangdong,China(KA22016B746)for financial research supportthe UP System Balik PhD Program(OVPAA-BPhD-2022-02)Yunnan Department of Sciences and Technology of China(Grant No:202101AS070045,202205AM070007,202302AE090023,202303AP140001)the financial support provided by the Distinguished Scientist Fellowship Program(DSFP)at King Saud University in Riyadh,Saudi ArabiaScience&Engineering Research Board(SERB),Department of Science&Technology(DST)Govt.of India(Scheme No.CRG/2020/006053)Institution of Eminence(IoE)Scheme,Ministry of Human Resource and Development(MHRD),Govt.of India(No.R/Dev/D/IoE/Incentive/2021-22/32387)for providing financial supportGenivaldo Alves-Silva,Elisandro R.Drechsler-Santos,Rosa M.B.da Silveira,and Aristóteles Góes-Neto are supported by Conselho Nacional de Desenvolvimento Científico e Tecnológico(CNPq)(Grant No.153025/2022-0,310150/2022-1,308122/2019-4,308880/2022-6,respectively)the CNPq and FAPESC under the PROTAX program(Grant No.FAPESC 2021TR390,Grant No.CNPq 441821/2020-0)and M.E.Engels for collectionsde Desenvolvimento Científico e Tecnológico(CNPq),Brazil,that provided research grants to B.T.Goto(proc.306632/2022-5)support from the National Science and Technology Council is acknowledged(101-2621-B-019-001-MY3)supported by Prof.Dr.M.Schnittler(University of Greifswald,Germany),through the DFG project RESPONSE(RTG2010)study by Ralaiveloarisoa Asupported by the Today’s Flora for Tomorrow project funded by a generous donor through the Kew Foundation,and by a grant from the Bentham-Moxon Trustsupported by the Bulgarian National Science Fund(Grant no.KP-06-N51/10/16.11.2021)the herbarium at the Botanic Garden and Botanical Museum Berlin received support from the SYNTHESYS Plus Project http://www.synthesys.info,which is financed by the H2020 Research Infrastructures Programme(Grant no.DE-TAF-8193)providing tuition fee scholarship.The Center for Yunnan Plateau Biological Resources Protection and Utilization,College of Biological Resource and Food Engineering,Qujing Normal University is thanked for the facilities provided for the research worksupported by the National Natural Science Foundation of China(No.32060012)Muhammad Usman and Abdul Nasir Khalid would like to thank Dr.Kamran Habib,Dr.Muhammad Ali,Mr.Mohammad Aijaz Ahmad and Mr.Muhammad Shafiq for accompanying during the collection surveythe Science and Engineering Research Board(SERB)the Department of Science and Technology,Government of India,for their financial support through CRG/2020/000668 projectthe MACS Agharkar Research Institute in Pune,for providing the lab resources and motivating us in our research workFunding Scheme for Research and Innovation grant for the project“Discovery of new antivirals using cultures of filamentous fungi collected in Europe and Thailand as compound sources(JFS20ST-127 Antiviralfun,P2150844)”BIOTEC-Novartis collaboration for microbial bioprospecting project(P20-52031)to CSIR-HRDG,India,for providing her with financial assistance as part of the JRF fellowship(09/0670(13602)/2022-EMR-I)to Javier Etayo(Pamplona)for his valuable suggestionsNational Science Foundation of China(No.31870528)support from Iran National Science Foundation(INSF,no.4000655)Coordenação de Aperfeiçoamento de Pessoal de Nível Superior-Brasil(CAPES)-Finance Code 001 who provided a visiting professorship to the first authorsupporting this work with a PhD’s scholarship to LAS(140847/2019-7)a research grant to MESC(307569/2019-5)and for financial support in the Universal project(Process:437097/2018-8ERDF-A way of making Europe(Grant PID2021-128068NB-100)the Department of Biotechnology(DBT),Government of India(Grant no.BT/PR/0054/NDB/52/94/2007)support under the project‘Establishment of Microbial Culture Collection(NCMR-NCCS).’Gajanan Mane is thankful to the University Grants Commission,Delhi(India)for the senior research fellowship(File No.16-6(Dec.2017)/2018(NET/CSIR)Rohit Sharma thanks the Department of Biotechnology(DBT),Government of India(Grant no.BT/PR25490/NER/95/1220/2017 dated 28.06.2018),for financial supportthe grant from the Guangdong Rural Science and Technology Commissioner project(KTP20210313)the Key Laboratory of Green Prevention and Control on Fruits and Vegetables in South China,Guangdong(KA21031C501)the Innovative Team program of the Department of Education of Guangdong Province(2023KCXTD018/2022KCXTD015)Extramural Research-SERB,DST(EMR/2016/003078)Government of India for the financial assistanceto‘The PCCF’of the Tamil Nadu Forest Department for providing permission(E2/20458/2017)assistance and support during field visit in the Eastern Ghats.Malarvizhi Kaliyaperumal and Kezhocuyi Kezo thank RUSA 2.0(Theme-1,Group-1/2021/49)for providing grantthe Tamil Nadu State Council for Higher Education,Chennai(RGP/2019-20/MU/HECP-0040)for financial assistancethe National Science Foundation of China(No.31870528)support under statutory funds from the W.Szafer Institute of Botany,Polish Academy of Sciencesto ICMBio(Instituto Chico Mendes de Conservação da Biodiversidade)and IF(Instituto Florestal)for the collecting permits#38466-2 and#260108-001.102/2015,respectivelyinanced in part by Coordination of Improvement of Higher Education Personnel-Brazil(CAPES)-Finance Code 001 and by the National Council for Scientific and Technological Development(to LFPG and Proc.305269/2018-6 to AR)to LFPG and Proc.305269/2018-6 to AR)the Program CAPES-PrInt,process number 88887.310463/2018-00Mobility numbers#88887.468939/2019-00 and#88887.571230/2020-00the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior CAPES(processes numbers CAPES 88887.360774/2019-00)Conselho Nacional Desenvolvimento Científico e Tecnológico CNPq(ONDACBC:465764/2014-2 and NEXUS:441305/2017-2)the Fundação de AmparoàCiência e Tecnologia de Pernambuco-FACEPE(BFP-0046-5.01/20,APQ-0350-2.12/19 and APQ 1527-5.01/22)the Conselho Nacional de Desenvolvimento Científico e Tecnológico-CNPq(Proc.312606/2022-2)the National Natural Science Foundation of China(Project ID:32060005)and the Yunnan Fundamental Research Project(202201AW070001)the National Natural Science Foundation of China(No.32260004)Yunnan Revitalization Talents Support Plan(High-End Foreign Experts Program)the Key Laboratory of Yunnan Provincial Department of Education of the Deep-Time Evolution on Biodiversity from the Origin of the Pearl River for their support.Xing-Can Peng and Ting-Chi Wen acknowledge the support by the National Natural Science Foundation of China(No.32060012)Department of Sciences and Technology of China(No.202202AE090091)the National Natural Science Foundation of China(Grant No.32200015)the foundation of the Guangzhou bureau of science and technology(Grant No.2023A04J1425)Thailand Science Research and Innovation(TSRI)for the grant“Biodiversity,taxonomy,phylogeny and evolution of Colletotrichum on Avocado,Citrus,Durian and Mango in northern Thailand”(Grant no.652A01003)the National Natural Science Foundation of China(No.NSFC 32260004)and the Yunnan Revitalization Talents Support Plan(Young Talents Program and High-End Foreign Experts Program)The Center for Yunnan Plateau Biological Resources Protection and Utilization,College of Biological Resource and Food Engineering,Qujing Normal University for the facilities provided for the research workthe National Natural Science Foundation of China(Grant no.31600019)the Modern Agricultural Industry Technology System Flower Innovation Team of Guangdong Province(Grant no.2023KJ121)the Project of Educational Commission of Guangdong Province of China(Grant no.2021KTSCX045)the research productivity fellowship(Grant No.303834/2020-0)the Eminent scholar offered by Kyun Hee Universitythe Chinese Research Fund,Grant number E1644111K1,titled“Flexible introduction of the high-level expert program,Kunming Institute of Botany,Chinese Academy of Sciences”for financial supportthe Italian National Antarctic Research Program for funding Antarctic campaingssupport to the Mycological Section of the MNA and the Culture Collection of Antarctic fungi(MNA-CCFEE),University of Tuscia,Italy.
文摘This article is the 17th in the Fungal Diversity Notes series which allows the researchers to publish fungal collections with updated reports of fungus-host and fungus-geography.Herein we report 97 taxa with four new genera distributed in three phyla(Ascomycota,Glomeromycota and Mucoromycota),11 classes,38 orders and 62 families collected from various regions worldwide.This collection is further classified into taxa from 69 genera with four novel genera namely Jinshana,Lithophyllospora,Parapolyplosphaeria and Stegonsporiicola.Furthermore,71 new species,21 new records,one new combination and four novel phylogenetic placements are provided.The new species comprise Acrocalymma estuarinum,Aggregatorygma isidiatum,Alleppeysporonites elsikii,Amphibambusa aquatica,Apiospora hongheensis,Arthrobotrys tachengensis,Calonectria potisiana,Collariella hongheensis,Colletotrichum squamosae,Corynespora chengduensis,Diaporthe beijingensis,Dicellaesporites plicatus,Dicellaesporites verrucatus,Dictyoarthrinium endophyticum,Distoseptispora chiangraiensis,Dothiora eucalypti,Epicoccum indicum,Exesisporites chandrae,Fitzroyomyces pseudopandanicola,Fomitiporia exigua,Fomitiporia rondonii,Fulvifomes subthailandicus,Gigaspora siqueirae,Gymnopus ailaoensis,Hyalorbilia yunnanensis,Hygrocybe minimiholatra,H.mitsinjoensis,H.parviholatra,H.solis,H.vintsy,Helicogermslita kunmingensis,Jinshana tangtangiae,Kirschsteiniothelia dujuanhuensis,Lamproderma subcristatum,Leucoagaricus madagascarensis,Leucocoprinus mantadiaensis,Lithophyllospora australis,Marasmius qujingensis,Melomastia aquilariae,Monoporisporites jansoniusii,M.pattersonii,Monoporisporites valdiyae,Mucispora maesotensis,Mucor soli,Muyocopron yunnanensis,Nigrospora tomentosae,Ocellularia psorirregularis,Ophiocordyceps duyunensis,Oxneriaria nigrodisca,Oxydothis aquatica,O.filiforme,Phacidiella xishuangbannaensis,Phlebiopsis subgriseofuscescens,Pleurothecium takense,Pleurotus tuber-regium,Pseudochaetosphaeronema puerensis,Pseudodactylaria guttulate,Racheliella chinensis,Rhexoacrodictys fangensis,Roussoella neoaquatica,Rubroboletus pruinosus,Sanghuangporus subzonatus,Scytalidium assmuthi,Shrungabeeja kudremukhensis,Spirographa skorinae,Stanjehughesia bambusicola,Stegonsporiicola aurantiaca,Umbelopsis hingganensis,Vararia tenuata,Verruconis pakchongensis,Wongia bandungensis,and Zygosporium cymodoceae.The new combination is Parapolyplosphaeria thailandica(≡Polyplosphaeria thailandica).The 21 new hosts,geographical and habitat records comprise Acrocalymma fici,Apiculospora spartii,Aspergillus subramanianii,Camposporium ramosum,Clonostachys rogersoniana,Colletotrichum brevisporum,C.plurivorum,Collybiopsis gibbosa,Dictyosporium tratense,Distoseptispora adscendens,Exosporium livistonae,Ganoderma gibbosum,Graphis mikuraensis,Gymnosporangium paraphysatum,Lasiodiplodia thailandica,Moesziomyces bullatus,Penicillium cremeogriseum,P.echinulonalgiovense,P.javanicum,P.lanosocoeruleum,P.polonicum,and Pleurotus tuber-regium.Graphis chlorotica,G.panhalensis and G.parilis are given as novel phylogenetic placements.In addition,we provide the morphology of Tarzetta tibetensis which was missing in the previous Fungal Diversity Notes 1611–1716.Identification of characterization of all these taxa are supported by morphological and multigene phylogenetic analyses.
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.
