Fungal Planet description sheets: 1478-1549

Novel species of fungi described in this study include those from various countries as follows: Australia, Aschersonia mackerrasiae on whitefly, Cladosporium corticola on bark of Melaleuca quinquenervia, Penicillium nudgee from soil under Melaleuca quinquenervia, Pseudocercospora blackwoodiae on leaf spot of Persoonia falcata, and Pseudocercospora dalyelliae on leaf spot of Senna alata. Bolivia, Aspicilia lutzoniana on fully submersed siliceous schist in high-mountain streams, and Niesslia parviseta on the lower part and apothecial discs of Erioderma barbellatum onatwig. Brazil, Cyathus bonsai on decaying wood, Geastrum albofibrosum from moist soil with leaf litter, Laetiporus pratigiensis on a trunk of a living unknown hardwood tree species, and Scytalidium synnematicum on dead twigs of unidentified plant. Bulgaria, Amanita abscondita on sandy soil in a plantation of Quercus suber. Canada, Penicillium acericola on dead bark of Acer saccharum, and Penicillium corticola on dead bark of Acer saccharum. China, Colletotrichum qingyuanense on fruit lesion of Capsicum annuum. Denmark, Helminthosphaeria leptospora on corticioid Neohypochnicium cremicolor. Ecuador (Galapagos), Phaeosphaeria scalesiae on Scalesia sp. Finland, Inocybe jacobssonii on calcareouss oils in dry forests and park habitats. France, Cortinarius rufomyrrheus on sandy soil under Pinus pinaster, and Periconia neominutissima on leaves of Poaceae. India, Coprinopsis fragilis on decaying bark of logs, Filoboletus keralensis on unidentified woody substrate, Penicillium sankaranii from soil, Physisporinus tamilnaduensis on the trunk of Azadirachta indica, and Poronia nagaraholensis on elephant dung. Iran, Neosetophoma fic on infected leaves of Ficus elastica. Israel, Cnidariophoma eilatica (incl. Cnidariophoma gen. nov.) from Stylophora pistillata. Italy, Lyophyllum obscurum on acidic soil. Namibia, Aureobasidium faidherbiae on dead leaf of Faidherbia albida, and Aureobasidium welwitschiae on dead leaves of Welwitschia mirabilis. Netherlands, Gaeumannomycella caricigena on dead culms of Carex elongata, Houtenomyces caricicola (incl. Houtenomyces gen. nov.) on culms of Carex disticha, Neodacampia ulmea (incl. Neodacampia gen. nov.) on branch of Ulmus laevis, Niesslia phragmiticola on dead standing culms of Phragmites australis, Pseudopyricularia caricicola on culms of Carex disticha, and Rhodoveronaea nieuwwulvenica on dead bamboo sticks. Norway, Arrhenia similis half-buried and moss-covered pieces of rotting wood in grass-grownpath. Pakistan, Mallocybe ahmadii on soil. Poland, Beskidomyces laricis (incl. Beskidomyces gen. nov.) from resin of Larix decidua ssp. polonica, Lapidomyces epipinicola from sooty mould community on Pinus nigra, and Leptographium granulatum from a gallery of Dendroctonus micans on Picea abies. Portugal, Geoglossum azoricum on mossy areas of laurel forest areas planted with Cryptomeria japonica, and Lunasporangiospora lusitanica from a biofilm covering a bio deteriorated limestone wall. Qatar, Alternaria halotolerans from hypersaline sea water, and Alternaria qatarensis from water sample collected from hypersaline lagoon. South Africa, Alfaria thamnochorti on culm of Thamnochortus fraternus, Knufia aloeicola on Aloe gariepensis, Muriseptatomyces restionacearum (incl.Muriseptatomyces gen. nov.) on culms of Restionaceae, Neocladosporium arctotis on nest of cases of bagworm moths(Lepidoptera, Psychidae) on Arctotis auriculata, Neodevriesia scadoxi on leaves of Scadoxus puniceus, Paraloratospora schoenoplecti on stems of Schoenoplectus lacustris, Tulasnella epidendrea from the roots of Epidendrum × obrienianum, and Xenoidriella cinnamomi (incl. Xenoidriella gen. nov.) on leaf of Cinnamomum camphora. South Korea, Lemonniera fraxinea on decaying leaves of Fraxinus sp. frompond. Spain, Atheniella lauri on the bark of fallen trees of Laurus nobilis, Halocryptovalsa endophytica from surface-sterilised, asymptomatic roots of Salicornia patula, Inocybe amygdaliolens on soil in mixed forest, Inocybe pityusarum on calcareous soil in mixed forest, Inocybe roseobulbipes on acidic soils, Neonectria borealis from roots of Vitis berlandieri × Vitis rupestris, Sympoventuria eucalyptorum on leaves of Eucalyptus sp., and Tuber conchae fromsoil. Sweden, Inocybe bidumensis on calcareous soil. Thailand, Cordyceps sandindaengensis on Lepidoptera pupa, buried in soil, Ophiocordyceps kuchinaraiensis on Coleoptera larva, buried in soil, and Samsoniella winandae on Lepidoptera pupa, buriedinsoil. Taiwan region (China), Neophaeosphaeria livistonae on dead leaf of Livistona rotundifolia. Türkiye, Melanogaster anatolicus on clay loamy soils. UK, Basingstokeomyces allii (incl. Basingstokeomyces gen. nov.) on leaves of Allium schoenoprasum. Ukraine, Xenosphaeropsis corni on recently dead stem of Cornus alba. USA, Nothotrichosporon aquaticum (incl. Nothotrichosporon gen. nov.) from water, and Periconia philadelphiana from swab of coil surface. Morphological and culture characteristics for these new taxa are supported by DNA barcodes.The work of P.W. Crous and colleagues benefitted from funding by the European Union’s Horizon 2020 research and innovation program (RISE) under the Marie Skłodowska-Curie grant agreement No. 101008129, project acronym ‘Mycobiomics’, and the Dutch NWO Roadmap grant agreement No. 2020/ENW/00901156, project ‘Netherlands Infrastructure for Ecosystem and Biodiversity Analysis – Authoritative and Rapid Identification System for Essential biodiversity information’(acronym NIEBAARISE). G. Gulden, B. Rian and I. Saar thank K. Bendiksen at the fungarium and G. Marthinsen at NorBol, both Natural History Museum, University of Oslo for valuable help with the collections, and the sequencing of our finds of A. similis from 2022. Sincere thanks to A. Voitk for assistance with the colour plate and review of the manuscript. I. Saar was supported by the Estonian Research Council (grant PRG1170). P. Rodriguez-Flakus and co-authors are greatly indebted to their colleagues and all staff of the Herbario Nacional de Bolivia, Instituto de Ecología, Universidad Mayor de SanAndrés, La Paz, for their generous long-term cooperation. Their research was financially supported by the National Science Centre (NCN) in Poland (grants numbers 2018/02/X/NZ8/02362 and 2021/43/B/NZ8/02902). Y.P. Tan and colleagues thank M.K. Schutze (Department of Agriculture and Fisheries, Queensland, Australia) for determining the identity of the insect hosts for Aschersonia mackerrasiae. The Australian Biological Resources Study funded the project that led to the discovery of Aschersonia mackerrasiae. K.G.G. Ganga acknowledges support from the University Grants Commission (UGC), India, in the form of a UGC research fellowship (Ref No. 20/12/2015(ii) EU-V), and the authorities of the University of Calicut for providing facilities to conduct this study. S. Mahadevakumar acknowledges the Director, KSCSTE - Kerala Forest Research Institute and Head of Office, Botanical Survey of India,Andaman and Nicobar Regional Centre, Port Blair for the necessary support and M. Madappa, Department of Studies in Botany, University of Mysore for technical assistance. A.R. Podile thanks the Department of Science and Technology, Govt. of India for the JC Bose Fellowship (Grant No. JCB/2017/000053) & MoE and IOE-Directorate-UOH for project (Grant No.UOH-IOE-RC3-21-065). Financial support was provided to R. de L. Oliveira and K.D. Barbosa by the Coordenação deAperfeiçoamento de Pessoal de Nível Superior - Brazil (CAPES) – Finance code 001, and to I.G. Baseia and M.P. Martín by the National Council for Scientific and Technological Development (CNPq) under CNPq-Universal 2016 (409960/2016-0) and CNPq-visiting researcher (407474/2013-7). E. Larsson acknowledges the Swedish Taxonomy Initiative, SLU Artdatabanken, Uppsala, Sweden. H.Y. Mun and J. Goh were supported by a grant from the Nakdonggang National Institute of Biological Resources (NNIBR), funded by the Ministry of Environment (MOE) of the Republic of Korea (NNIBR202301106). J. Trovão and colleagues were financed by FEDER - Fundo Europeu de Desenvolvimento Regional funds through the COMPETE 2020 - Operational Programme for Competitiveness and Internationalisation (POCI), and by Portuguese funds through FCT- Fundação para a Ciência e a Tecnologia in the framework of the project POCI-01-0145-FEDER-PTDC/EPH-PAT/3345/ 2014. Their research was carried out at the R & D Unit Centre for Functional Ecology – Science for People and the Planet (CFE), with reference UIDB/04004/2020, financed by FCT/MCTES through national funds (PIDDAC). João Trovão was supported by POCH - Programa Operacional Capital Humano (co-funding by the European Social Fund and national funding by MCTES), through a ‘FCT- Fundação para a Ciência e Tecnologia’ PhD research grant (SFRH/ BD/132523/2017). O. Kaygusuz and colleagues thank the Research Fund of the Isparta University ofApplied Sciences for their financial support under the project number 2021-ILK1-0155. They also thank N. Sánchez Biezma of the Department of Drawing and Scientific Photography at the Alcalá University for his help in the digital preparation of the photographs. The research of M. Spetik and co-authors was supported by project No. IGAZF/2021-SI1003. V. Darmostuk and colleagues acknowledge our colleagues and all staff of the Herbario Nacional de Bolivia, Instituto de Ecología, Universidad Mayor de San Andrés, La Paz, for their generous long-term cooperation. They would also like to thank the SERNAP (http://sernap.gob.bo), and all protected areas staff, for providing permits for scientific studies, as well as their assistance and logistical support during the field works. This research was financially supported by the National Science Centre (NCN) in Poland (grant number DEC-2013/11/D/NZ8/ 03274). M. Kaliyaperumal and co-authors thank the Centre of Advanced Studies in Botany, University of Madras for the laboratory facilities. M. Kaliyaperumal thanks the Extramural Research-SERB, DST (EMR/2016/003078), Government of India, for financial assistance. M. Kaliyaperumal and K. Kezo thanks RUSA 2.0 (Theme-1, Group-1/2021/49) for providing a grant. M. Shivannegowda and colleagues thank C.R. Santhosh, Department of Studies in Microbiology, University of Mysore, Manasagangotri, Mysuru for technical support. They also thank K.R. Sridhar, Mangalore University, Karnataka, India and S.S.N. Maharachchikumbura, University of Electronic Science and Technology of China, Chengdu for their support and helping with technical inputs. The study of G.G. Barreto and co-authors was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brazil (CAPES - Finance Code 001), and the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq - Proc. 131503/2019-7; Proc. 312984/2018-9); the authors also thank to Programa de Pós-Graduação em Botânica – PPGBOT. L.F.P. Gusmão thanks to Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) for a research grant. T. Nkomo and colleagues thank the National Research Foundation of SouthAfrica for funding this study, with additional funding from the Forestry and Agricultural Biotechnology Institute and the University of Pretoria. G. Delgado is grateful to W. Colbert and S. Ward (Eurofins Built Environment) for continual encouragement and provision of laboratory facilities. J.G. Maciá-Vicente acknowledges support from the Landes-Offensive zur Entwicklung Wissenschaftlich-ökonomischer Exzellenz (LOEWE) of the state of Hesse within the framework of the Cluster for Integrative Fungal Research (IPF) of Goethe University Frankfurt. F. Esteve-Raventós and colleagues acknowledge P. Juste and J.C. Campos for the loan of some collections for study and N. Subervielle and L. Hugot (Conservatoire Botanique National de Corse, Office de l’Environnement de la Corse, Corti) for their assistance. They also acknowledge the Balearic Mycology Group (FCB) for their permanent help in the search for collections in the Balearic Islands, and Y. Turégano for obtaining some of the sequences presented here, and L. Parra for his suggestions and help on nomenclatural issues. S. Mongkolsamrit and colleagues were financially supported by the Platform Technology Management Section, National Centre for Genetic Engineering and Biotechnology (BIOTEC), Project Grant No. P19-50231. S. De la Peña-Lastra and colleagues thank the Atlantic Islands National Maritime-Terrestrial Park authorities and guards. A. Mateos and co-authors would like to thank Secretaria Regional doAmbiente eAlterações Climáticas Açores for the permission granted for the sampling (Licença nº 16/2021/ DRAAC). To the ECOTOX group for co-funding the trip. J. Mack & D.P. Overy were funded byAgriculture &Agri-Food Canada (Project ID#002272: Fungal and Bacterial Biosystematics-bridging taxonomy and “omics” technology in agricultural research and regulation) and are grateful for molecular sequencing support from the Molecular Technologies Laboratory (MTL) at the Ottawa Research & Development Centre of Agriculture & Agri-Food Canada. The study of P. Czachura was funded by the National Science Centre, Poland, under the project 2019/35/N/NZ9/04173. The study of M. Piątek and coauthors was funded by the National Science Centre, Poland, under the project 2017/27/B/NZ9/02902. O. Yarden and L. Granit were funded by the Israel Science Foundation (grant number 888/19). H. Taşkın and colleagues received support from the BulgarianAcademy of Sciences and the Scientific and Technological Research Council of Türkiye (Bilateral grant agreement between BAS and TÜBİTAK, project number 118Z640). The authors would also like to thank S. Şahin (İzmir, Türkiye) for conveying one of the localities of A. abscondita. Andrew Miller would like to thank the Roy J. Carver Biotechnology Center at the University of Illinois for Sanger sequencing. E.R. Osieck thanks Staatsbosbeheer for permission to collect fungi in Nieuw Wulven, in the Netherlands. P. van ‘t Hof and co-authors thank the Galapagos Genetic Barcode project supported by UK Research and Innovation, Global Challenges Research Fund, Newton Fund, University of Exeter, Galapagos Science Center, Universidad San Francisco de Quito, Galapagos Conservation Trust, and Biosecurity Agency of Galapagos (ABG).Peer reviewe

A new species of barssia (Ascomycota, helvellaceae) from Turkey

A new species of the genus Barssia was identified from Turkey using both morphological and phylogenetic analysis of the ribosomal internal transcribed spacer region (ITS rDNA) and nuclear ribosomal large subunit (LSU rDNA) gene sequences. Macroscopic and microscopic features of the fresh samples were photographed and a diagnostic key of the genus Barssia was built considering characteristics of known species. © TÜBİTAK.Firat University Scientific Research Projects Management Unit: FBA-2017-8059 2015Z062 Türkiye Bilimsel ve Teknolojik Araştirma KurumuThe authors would like to thank the Scientific and Technological Research Council of Turkey (TÜBİTAK), 1002-Short Term R&D Funding Program (Project Code: 2015Z062), and the Çukurova University Scientific Research Projects Coordinating Office (Project Code: FBA-2017-8059) for supporting this study

Volatile Constituents of The Edible Tricholoma terreum in Marmara Region of Turkey

Tricholoma terreum is a fungal species which is also commonly consumed and widespread in Turkey. Seventeen aroma compounds were identified with Headspace Solid-Phase Microextraction/Gas Chromatography/Mass Spectrometry (HS-SPME/GC-MS). Major aroma compounds in T. terreum were as follows; 1-octen-3-ol (37.08 %), (E)-2-octen-1-ol (19.68 %), hexanal (16.00 %), 3-octanone (3.36 %), acetic acid (2.63 %) and (E)-2-octenal (2.27 %). This study is the first report on the volatile aroma compounds of T. terreum in Turkey. © 2017 Har Krishan Bhalla & Sons

Comparison of volatile compounds of fresh Boletus edulis and B. pinophilus in Marmara region of Turkey

Boletus edulis and B. pinophilus are commonly consumed edible species of Boletus spp. in Turkey, which are also exported to some European countries. In this study, twenty-three volatile compounds were determined with Headspace Solid-Phase Microextraction / Gas Chromatography / Mass Spectrometry (HS-SPME/GC/MS) in both B. edulis and B. pinophilus. 1- octen-3-ol (79.75), 2-octen-1-ol (13.18), 1-octen-3-one (2.52), (E)-2-octenal (1.21) in B. edulis and 1-octen-3-ol (55.97), 2- octen-1-ol (13.55), 3-octanone (7.43), (E)-2-octenal (6.79), 1-octen-3-one (5.80) and 1,7,7-trimethyl-heptan-2-one (2.04), 2- propenoic acid (1.95) and 1,3-octadiene (1.75) in B. pinophilus were identified as main volatile aroma compounds (%), respectively. The present study is the first report on the volatile constituents of B. edulis and B. pinophilus collected from Turkey

First report on the volatile composition of tricholoma anatolicum in comparison with tricholoma caligatum

Tricholoma anatolicum collected from Turkey is consumed by public and exported to Japan every year. It was previously identified as Tricholoma caligatum until it was recognized as a new species. In the existing literature, there is no information on the aromatic composition of T. anatolicum. Therefore, in this study it was aimed to identify the volatile composition of T. anatolicum together with T. caligatum. Species identification was confirmed using molecular analyses based on ITS rDNA sequencing. Volatile compounds of both mushroom species were extracted using liquid-liquid extraction method and determined by Gas Chromatography-Mass Spectrometry-Flame Ionization Detector (GC-MS-FID). In the two Tricholoma species, 31 volatiles were obtained and grouped in seven chemical classes. The amounts of alcohols, volatile acids and esters were found to be higher in T. anatolicum, whereas the amounts of terpenes were detected as higher in T. caligatum. 1-Octen-3-ol responsible for the mushroom-like odour was only found in T. anatolicum. © 2019 ACG Publications. All rights reserved.FYL-2018-10495 Ministry of Water ResourcesThe authors would like to express their thanks to Mr Şaban Güneri (Republic of Turkey Ministry of Forest and Water Resources) for his aid in collecting mushroom samples, and to the Cukurova University, Scientific Research Projects Coordinating Office for supporting financially this study though grant FYL-2018-10495

Cryptomarasmius corbariensis (Physalacriaceae, agaricales) in Turkey with first molecular data on the species from Eurasia

Cryptomarasmius corbariensis (Roum.) T.S.Jenkinson & Desjardin, a species confined primarily to litter of olive trees, is recorded for the first time from Asia and Turkey, based on identification by ITS sequences and morphological characters. Description and illustrations are included. An overview of the distribution is provided and briefly discussed with emphasis on the possibly wider extent than currently known. © 2017 J. Cramer in Gebr. Borntraeger Verlagsbuchhandlung, Stuttgart, Germany.T.C. Gida Tarim ve Hayvancilik Bakanligi: TAGEM/13/AR-GE/16The authors would like to thank to the Republic of Turkey Ministry of Food, Agriculture and Livestock-General Directorate of Agricultural Research and Policy Projects Coordinating Office (TAGEM/13/AR-GE/16) for supporting this study and would like to express their sincere gratitude to Dr. Evren CABİ (Tekirdağ, Turkey) for providing laboratory facilities

Detection and molecular analysis of moxifloxacin mic values of mycobacterium tuberculosis strains isolated from clinical specimens [Klinik Örneklerden elde edilen mycobacterium tuberculosis İzolatlarının moksifloksasin mİk değerlerinin tespiti ve moleküler analizi]

PubMedID: 31414626Tuberculosis (TB) is a chronic, granulomatous and necrotizing disease caused by microorganisms belonging to the Mycobacterium tuberculosis complex group. In 2017, 6.4 million new TB cases have been reported according to the World Health Organization 2018 Global Tuberculosis Report. TB remains among the major health problems of our time due to the increasing drug resistance problem and the difficulties in definitive diagnosis in recent years. It is stated by clinicians that intensive use of quinolone group drugs with oral form in simple indications such as respiratory or urinary tract infections may lead to resistance and this may result in treatment failures. The aim of this study was to determine the moxifloxacin susceptibility of M.tuberculosis isolates obtained from clinical specimens by phenotypical methods, to determine the resistance rates of moxifloxacin and to investigate the relationship between phenotypical resistance and mutations in the gyrA gene. A hundred (n= 100) consecutive non-multidrug resistant and 37 non-consecutive multidrug resistant M.tuberculosis strains isolated from the clinical specimens of patients with pulmonary tuberculosis were included in the study. The moxifloxacin susceptibility of the isolates was determined by using Löwenstein-Jensen medium and their epidemiological properties were investigated and also mutations detected by gyrA region were compared with drug susceptibility rates. Of the 137 isolates tested for phenotypical susceptibility, 25 (18.2%) were found to be resistant to moxifloxacin. Resistance rate among non-multidrug resistant and multidrug resistant isolates were determined as 17% and 21.6%, respectively. According to the results of the sequencing analysis, of the gyrA regions of all the isolates included in the study, a single base mutation was found in a total of six samples. The location positions of the mutations were determined as D94Y, D94G, A90V, G88A and among two strains as D89N. Two of the isolates with mutations were found to be phenotypically susceptible to moxifloxacin. In our study, it was found that moxifloxacin resistance in M.tuberculosis isolates was higher than similar studies and it was found that different mechanisms may be responsible for the existing resistance other than the mutations in the gyrA gene. It was concluded that the data obtained from the study should be shared with all clinicians in the country due to the possibility of resistance development to this group of drugs in a short time and considering this drug will have an important role in the treatment of TB, it should be used more limited in non-specific indications. Further studies using larger case groups and isolates are needed for the continuation of the research. © 2019 Ankara Microbiology Society. All rights reserved

Chemical Characterization, Phytotoxic, Antimicrobial and Insecticidal Activities of Vitex agnus-castus’ Essential Oil from East Mediterranean Region

Essential oil of Vitex agnus-castus’ leaves was analysed GC and GC-MS. The oil was predominantly rich in 1,8-cineole (24.38 %), sabinene (22.77 %), trans-ß-farnesene (8.50 %), ?-pinene (7.14 %), ß-caryophyllene (6.49 %) and 1-terpinen-4-ol (5.23 %). In the phytotoxicity assay, the highest concentration of the oil (40 µL) completely inhibited the germinations of Lactuca sativa and Lepidium sativum. In the antimicrobial assays, essential oil was more active on yeast species and gram positive bacteria. The results of the insecticidal assays were also significant as the mortalities were 70 % and 96.67 % on Acanthoscelides obtectus and Tribolium castaneum at 34 µL L-1 and 136 µL L-1 oil (24 h), respectively. Essential oil of V. agnus-castus could be suggested as a potential source of bioagents for prokaryotic and eukaryotic organisms in concern. © 2015, Har Krishan Bhalla & Sons