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Meliola xylopiae-sericieae on Xylopia sericea. A. Mycelial seta. B. Tips of two mycelial setae. C. Ascospores with middle cell large. D. Superficial hyphae with conidiogenous cells and appressoria. E. Superficial hyphae with two-celled alternately disposed lateral appressoria. Bars 5 25 mm.
Source publication
Continuing the study of black mildews in fragments of the Atlantic forest, three new species and five new records are described herein. Irenopsis luheaegrandiflorae, Meliola vicosensis and Meliola xylopia-sericiae are new species. Cecropia hololeuca, Piper gaudichaudianum and Trichilia lepidota are new hosts for Asteridiella leucosykeae, Asteridiel...
Citations
... Modern members of Meliolaceae are commonly shade and moisture-loving and survive generally under warm and humid tropical climate with a MAT (mean annual temperature) from 21 to 26 C and mean annual precipitation of 1000 mme2000 mm (Schmiedeknecht 1995;Kirk et al., 2008;Piepenbring et al., 2011;Pinho et al., 2013;Justavino et al., 2015;Ma et al., 2015). So, fossil species of Meliolaceae might have thrived under similar climatic conditions for its growth and development during the time of deposition. ...
Here, we report the in-situ occurrence of a new fossil-species of Meliolinites (fossil Meliolaceae), Meliolinites bhutanensis sp. nov. on the cuticle fragments of a compressed angiosperm dicot leaf recovered from the middle Siwalik (Formation II: latest Miocene to Pliocene) of Bhutan, eastern Himalaya. This unique foliicolous new fossil fungal species features well-preserved mycelia consisting of superficial, brown to dark brown, septate, thick-walled, branching hyphae with bi-cellular appressoria, unicellular phialides, and a characteristic long, slightly curved hyphal seta. The web-like, brown to dark brown fungal colonies also include globose to sub-globose, dark brown ascomata, and oblong to broadly cylindrical, 5-celled, 4-septate, brown to dark brown, mature ascospores. As almost all features of different stages in the life cycle (ascospores, mature germinating ascospores, superficial lateral hyphae, hyphal seta, hyphopodia, mycelial colony, and ascomata) of this new fossil-species are found, we have proposed the first time a possible life cycle of fossil-species of Meliolaceae. The in-situ evidence of M. bhutanensis on the host leaf cuticle indicates the possible existence of a host-ectoparasite relationship in Bhutan sub-Himalaya's ancient warm and humid tropical evergreen forest during the deposition. So, M. bhutanensis might have thrived generally under warm and humid climate conditions for its growth and development in the Mio-Pliocene time, which is in conformity with our recently published quantitative climatic data by CLAMP (Climate Leaf Analysis Multivariate Program) analysis.
... Groups of fungi once considered biotrophic, such as Microthyriaceae and Chaetothyriaceae, have been recently isolated in a systematic way (Chomnunti et al., 2012;Wu et al., 2011;Le Renard et al., 2020). Powdery mildew, mildew, and meliolaceous fungi (Ascomycota, Meliolales) remain biotrophic and without successful cultivation (Göker et al., 2007;Rodriguez and Piepenbring, 2007;Beakes et al., 2012;Pinho et al., 2012aPinho et al., , 2012bPinho et al., , 2013Braun and Cook, 2012;Soares and Dianese, 2013). ...
Although asterinaceous fungi have been studied for many years, all previous attempts to isolate, cultivate, and propagate these fungi in vitro have failed. This paper provides the first reports of in vitro isolation of representative strains of species belonging to four fungi from different genera belonging to Asterinales. To confirm if the sequences of DNA obtained from the mycelia are the same obtained in the direct extraction, a phylogenetic analysis of nuc LSU rDNA was performed. This paper reports for the first time the success of in vitro culturing of asterinaceous fungi using the ascospores ejection technique, opening perspectives of studies of genetics, physiology, among other aspects of the biology for this very understudied group of fungi.
... Other nectrioid fungi associated with living plants were discovered mainly from Brazil by Alfenas et al. ( 2013 ) and Crous et al. ( 1993Crous et al. ( , 1998. Sooty molds and other epiphyllous fungi were treated by Pinho et al. ( 2012aPinho et al. ( , 2012bPinho et al. ( , 2013Pinho et al. ( , 2014, Rodríguez-Hernández ( 1985 ), Rodríguez-Hernández and Camino ( 1987 ), Rodríguez and Piepenbring ( 2007 ), and Rodríguez et al. ( 2015 ). Several interesting novel genera as Alveariospora , Echinoconidiophorum , Globoconidiopsis , Globoconidium , ...
In the last 30 years, 3757 taxa and 104 genera of microfungi have been described from the Central and South American Neotropic. The Neotropical zone in Central and South America is a megadiverse ecozone where a large number of undescribed fungal taxa remain to be discovered. This chapter reviewed the studies conducted on diversity of microfungi from different substrates and habitats in the Neotropic in the past 30 years and discussed the generic novelties described from these studies. At the same time, the methodology of sample collection, preparation, and incubation used in these studies is provided in detail.
Meliolaceae is an obligate biotrophic fungal family which cannot be cultured in artificial media. This has resulted in a lack of DNA sequence data in public databases to better resolve species taxonomy. The main criterion for specific classification, therefore, relied heavily on host association. Fresh collections from living leaves of Croton persimilis and Tamarindus indica with black colonies in Mae Fah Luang University, Thailand yielded a new species, Irenopsis crotonicola sp. nov., and a new record of Meliola tamarindi. These taxa are described and phenotypic comparisons are made with known species. To better classify the putative novel species that cannot be cultivated, we outline the protocol to extract DNA from fruiting bodies and generate new phylogenetic data. The results indicate that this direct DNA extraction method is suitable to yield quality DNA sufficient for polymerase chain reaction (PCR) amplifications of several commonly used DNA regions in fungal systematics. The 28S rDNA phylogram generated confirms the position of our taxa within Meliolaceae and indicate a close relationship of I. crotonicola sp. nov. to I. walsurae. Sequences of tef, β-tubulin, and GPDH regions of Meliolaceae are provided as well.
Meliolales is the largest order of epifoliar fungi, characterized by branched, dark brown, superficial mycelium with two-celled hyphopodia; superficial, globose to subglobose, dark brown perithecia, and septate, dark brown ascospores. The assumption of host-specificity means this group a highly diverse and it is imperative to identify the host before attempting to identify a fungal collection. This paper has compiled information from fungal and plant databases, including all fungal species of Meliolales and their host information from protologues. Current names of plants and corresponding fungi with integration of their synonyms are made into an alphabetical checklist, and references are provided. Exclusions and spelling conflicts of fungal species are also listed. Statistics show that the order comprises 2403 species (including 106 uncertain species), infecting among 194 host families, with an additional 20 excluded records. This checklist will be useful for the future identifications and classifications of Meliolales.
This is a continuity of a series of taxonomic papers where materials are examined, described and novel combinations are proposed where necessary to improve our traditional species concepts and provide updates on their classification. In addition to extensive morphological descriptions and appropriate asexual and sexual connections, DNA sequence data are also analysed from concatenated datasets (rDNA, TEF-α, RBP2 and β-Tubulin) to infer phylogenetic relationships and substantiate systematic position of taxa within appropriate ranks. Wherever new species or combinations are being proposed, we apply an integrative approach (morphological and molecular data as well as ecological features wherever applicable). Notes on 125 fungal taxa are compiled in this paper, including eight new genera, 101 new species, two new combinations, one neotype, four reference specimens, new host or distribution records for eight species and one alternative morphs. The new genera introduced in this paper are Alloarthopyrenia, Arundellina, Camarosporioides, Neomassaria, Neomassarina, Neotruncatella, Paracapsulospora and Pseudophaeosphaeria. The new species are Alfaria spartii, Alloarthopyrenia italica, Anthostomella ravenna, An. thailandica, Arthrinium paraphaeospermum, Arundellina typhae, Aspergillus koreanus, Asterina cynometrae, Bertiella ellipsoidea, Blastophorum aquaticum, Cainia globosa, Camarosporioides phragmitis, Ceramothyrium menglunense, Chaetosphaeronema achilleae, Chlamydotubeufia helicospora, Ciliochorella phanericola, Clavulinopsis aurantiaca, Colletotrichum insertae, Comoclathris italica, Coronophora myricoides, Cortinarius fulvescentoideus, Co. nymphatus, Co. pseudobulliardioides, Co. tenuifulvescens, Cunninghamella gigacellularis, Cyathus pyristriatus, Cytospora cotini, Dematiopleospora alliariae, De. cirsii, Diaporthe aseana, Di. garethjonesii, Distoseptispora multiseptata, Dis. tectonae, Dis. tectonigena, Dothiora buxi, Emericellopsis persica, Gloniopsis calami, Helicoma guttulatum, Helvella floriforma, H. oblongispora, Hermatomyces subiculosa, Juncaceicola italica, Lactarius dirkii, Lentithecium unicellulare, Le. voraginesporum, Leptosphaeria cirsii, Leptosphaeria irregularis, Leptospora galii, Le. thailandica, Lindgomyces pseudomadisonensis, Lophiotrema bambusae, Lo. fallopiae, Meliola citri-maximae, Minimelanolocus submersus, Montagnula cirsii, Mortierella fluviae, Muriphaeosphaeria ambrosiae, Neodidymelliopsis ranunculi, Neomassaria fabacearum, Neomassarina thailandica, Neomicrosphaeropsis cytisi, Neo. cytisinus, Neo. minima, Neopestalotiopsis cocoës, Neopestalotiopsis musae, Neoroussoella lenispora, Neotorula submersa, Neotruncatella endophytica, Nodulosphaeria italica, Occultibambusa aquatica, Oc. chiangraiensis, Ophiocordyceps hemisphaerica, Op. lacrimoidis, Paracapsulospora metroxyli, Pestalotiopsis sequoiae, Peziza fruticosa, Pleurotrema thailandica, Poaceicola arundinis, Polyporus mangshanensis, Pseudocoleophoma typhicola, Pseudodictyosporium thailandica, Pseudophaeosphaeria rubi, Purpureocillium sodanum, Ramariopsis atlantica, Rhodocybe griseoaurantia, Rh. indica, Rh. luteobrunnea, Russula indoalba, Ru. pseudoamoenicolor, Sporidesmium aquaticivaginatum, Sp. olivaceoconidium, Sp. pyriformatum, Stagonospora forlicesenensis, Stagonosporopsis centaureae, Terriera thailandica, Tremateia arundicola, Tr. guiyangensis, Trichomerium bambusae, Tubeufia hyalospora, Tu. roseohelicospora and Wojnowicia italica. New combinations are given for Hermatomyces mirum and Pallidocercospora thailandica. A neotype is proposed for Cortinarius fulvescens. Reference specimens are given for Aquaphila albicans, Leptospora rubella, Platychora ulmi and Meliola pseudosasae, while new host or distribution records are provided for Diaporthe eres, Di. siamensis, Di. foeniculina, Dothiorella iranica, Do. sarmentorum, Do. vidmadera, Helvella tinta and Vaginatispora fuckelii, with full taxonomic details. An asexual state is also reported for the first time in Neoacanthostigma septoconstrictum. This paper contributes to a more comprehensive update and improved identification of many ascomycetes and basiodiomycetes.
The order Meliolales comprises the families Armatellaceae and Meliolaceae. These are black mildews that grow on the surface of host plants, often regarded as minor plant pathogens. In this study, types or specimens of 17 genera of Armatellaceae and Meliolaceae were borrowed from herbaria and re-examined. Armatella is accepted in Armatellaceae and Amazonia, Appendiculella, Asteridiella, Cryptomeliola, Endomeliola, Irenopsis and Meliola are accepted in the family Meliolaceae. Laeviomeliola is synonymized under Meliola. Ceratospermopsis, Ectendomeliola, Haraea, Hypasteridium, Leptascospora, Metasteridium, Ophiociliomyces, Ophioirenina, Ophiomeliola, Parasteridium, Pauahia, Pleomeliola, Pleomerium, Prataprajella, Ticomyces, Urupe and Xenostigme are excluded from Meliolaceae, and are treated as doubtful genera or placed in ascomycetes genera incertae sedis. The type species of each genus is re-described and illustrated with photomicrographs. Notes are provided and comparisons made. Two new species of Meliola and one new species of Irenopsis are also introduced with molecular data and we provide the most populated phylogenetic tree of Meliolomycetidae to date. Meliola thailandicum was found on Dimocarpus longan (Sapindales) and Acacia auriculiformis (Fabales) and confirmed to be the same species in the molecular analyses. This has important implications as the several hundred Meliola species are recognized based on host associations. Thus the same species being recorded from two unrelated hosts sheds doubt on Meliola species being host-specific.
Three new species of Meliolaceae, Appendiculella monsterae on Monstera deliciosa (Araceae), Asteridiella nitidae on Buddleja nitida (Scrophulariaceae), and Irenopsis chrysophylli on Chrysophyllum sp. (Sapotaceae), are described based on material collected in Panama. Eighteen species of Meliolaceae are reported for the first time for Panama, which include four first records for the Americas, viz. Ast. formosensis, Meliola indica, and M. pisoniae, previously known only from Asia, and M. dissotidis hitherto known only from Africa. Six species of plants are cited as hosts for meliolaceous fungi for the first time. In a phylogenetic hypothesis based on 28S nrDNA sequences, the position of Meliolales, including Appendiculella, Asteridiella, Endomeliola, Irenopsis, and Meliola, is found to be basal to Sordariomycetidae, Hypocreomycetidae, and Xylariomycetidae within Sordariomycetes. The five genera of Meliolaceae form a strongly supported clade. We suggest adopting the concept of the subclass Meliolomycetidae. The monophyly of Asteridiella cannot be confirmed. A hypothetical close relationship between Asteridiella and Appendiculella is not supported, but Endomeliola appears closely related to a species of Asteridiella. Two Meliola species on the same host family are closely related.
Five new Meliola species, collected in the Brazilian Cerrado on five fabaceous hosts, Albizia polyantha, Andira humilis, Eriosema congestrum, Sweetia fruticosa, and Vigna sp. were described, illustrated, and are here designated as Meliola albiziae-polyanthae, M. andirae-humilis, M. eriosemae, M. sweetiae, and M. bodoquensis, respectively.
The rubber tree (Hevea brasiliensis) is host to several fungal species, including Irenopsis heveae as described by Hansford in 1961, which causes black mildew on leaves. One specimen of Irenopsis heveae from the state of Espírito Santo and two from the state of Pará were analyzed and showed some morphological differences. Some structures are similar to morphological characteristics as described and illustrated by Vincens in 1915 for Meliola heveae. Morphological comparisons with the type specimen of I. heveae and the alignment of the nucleotide sequences of the 28S rDNA region, however, indicate that the three samples belong to the same species. According to these data M. heveae and I. heveae are heterotypic synonyms with M. heveae being the older name. As the name I. heveae is already occupied by Hansford, Irenopsis vincensii is proposed as new name for the black mildew on H. brasiliensis. This is the first contribution of molecular sequence data for this species.
