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Allelochaeta elegans (CBS 187.81). A. Conidiomata on PDA. B. Chlamydospores. C. Conidia. Scale bars = 10 µm.
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The appendaged coelomycete genus Seimatosporium (Sporocadaceae, Sordariomycetes) and some of its purported synonyms Allelochaeta,Diploceras and Vermisporium are re-evaluated. Based on DNA data for five loci (ITS, LSU, rpb2, tub2 and tef1), Seimatosporium is shown to be paraphyletic. The ex-type species of Allelochaeta, Discostromopsis and Vermispor...
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... In the present study, we discovered the first species having nearly hyaline to pale brown conidia in Monochaetia, M. lithocarpicola (Fig. 5). This suggests that pigmentation might not be a robust characteristic to distinguish genera in Sporocadaceae, which was similarly observed for Allelochaeta (20). ...
Monochaetia is a pestalotioid genus, with members that are commonly known as leaf pathogens or saprobes; some strains were isolated from air, in which case their natural substrate is so far unknown. Fagaceae represents an ecologically and economically important plant family that is widely distributed in the Northern Hemisphere, including an important tree crop species, Castanea mollissima , which is widely cultivated in China. In the present study, diseased leaves of Fagaceae in China were investigated, and five new Monochaetia species were introduced based on morphology and phylogeny of combined ITS, LSU, tef1 , and tub2 loci.
... Seimatosporium species have been extensively studied on several hosts (Tanaka et al. 2011, Liu et (Weiss 1950, Nag Raj 1993, Cho & Shin 2004, Kobayashi 2007, Crous et al. 2018). Among them, Seim. ...
Rosa (Rosaceae) is an important ornamental and medicinal plant genus worldwide, with several species being cultivated in China. Members of Sporocadaceae (pestalotioid fungi) are globally distributed and include endophytes, saprobes but also plant pathogens, infecting a broad range of host plants on which they can cause important plant diseases. Although several Sporocadaceae species were recorded to inhabit Rosa spp., the taxa occurring on Rosa remain largely unresolved. In this study, a total of 295 diseased samples were collected from branches, fruits, leaves and spines of eight Rosa species (R. chinensis, R. helenae, R. laevigata, R. multiflora, R. omeiensis, R. rugosa, R. spinosissima and R. xanthina) in Gansu, Henan, Hunan, Qinghai, Shaanxi Provinces and the Ningxia Autonomous Region of China. Subsequently 126 strains were obtained and identified based on comparisons of DNA sequence data. Based on these results 15 species residing in six genera of Sporocadaceae were delineated, including four known species (Pestalotiopsis chamaeropis, Pes. rhodomyrtus, Sporocadus sorbi and Spo. trimorphus) and 11 new species described here as Monochaetia rosarum, Neopestalotiopsis concentrica, N. subepidermalis, Pestalotiopsis tumida, Seimatosporium centrale, Seim. gracile, Seim. nonappendiculatum, Seim. parvum, Seiridium rosae, Sporocadus brevis, and Spo. spiniger. This study also represents the first report of Pes. chamaeropis, Pes. rhodomyrtus and Spo. sorbi on Rosa. The overall data revealed that Pestalotiopsis was the most prevalent genus, followed by Seimatosporium, while Pes. chamaeropis and Pes. rhodomyrtus were the two most prevalent species. Analysis of Sporocadaceae abundance on Rosa species and plant organs revealed that spines of R. chinensis had the highest species diversity.
Citation: Peng C, Crous PW, Jiang N, et al. 2022. Diversity of Sporocadaceae (pestalotioid fungi) from Rosa in China. Persoonia 49: 201–260. https://doi.org/10.3767/persoonia.2022.49.07.
... Liu et al. (2019) recognized 30 monophyletic genera in Sporocadaceae including Seimatosporium, Sporocadus, Truncatella, and Xenoseimatosporium. Also studies by Jeewon et al. (2002Jeewon et al. ( , 2003, Lee et al. (2006), Barber et al. (2011), Tanaka et al. (2011), Crous et al. (2015Crous et al. ( , 2018, Senanayake et al. (2015), Jaklitsch et al. (2016), Maharachchikumbura et al. (2016), and Wijayawardene et al. (2016b) significantly improved our taxonomic understanding of pestalotioid species. ...
Grapevine trunk diseases (GTDs) are destructive fungal diseases and economically important threat to grapevine industry worldwide. During a survey of vineyards in the Kurdistan Province, 233 fungal isolates were obtained that associated with various external and internal trunk diseases symptoms. Based on sequence data and morphological characteristics, 24 species belonging to 19 genera were characterized. Botryosphaeriaceae species were the most prevalent identified fungi followed by Alternaria, Sporocadaceae, Phaeoacremonium, and Didymellaceae taxa. At the species level, Botryosphaeria doth-idea, Alternaria malorum, Phaeoacremonium aleophilum, Acremonium sclerotigenum, Alternaria chlamydosporigena, and Neoscytalidium dimidiatum were the most frequent identified species. Acremonium sclerotigenum, A. chlamydosporigena, A. malorum, Juxtiphoma eupyrena, and Paecilomyces formosus are new records associated with GTDs around the world. Among the four pestalotia-like species identified based on morphology and phylogenetic analyses of LSU, ITS, TEF1, and TUB2 sequence data, three species are newly described and introduced here as Seimatosporium marivanicum, Sporocadus kurdistanicus, and Xenoseimatosporium kurdistanicum. Furthermore, three new combinations are proposed, including Spo-rocadus corni, Spo. italicus, and Spo. pseudocorni. Pathogenicity of 15 species was studied on cultivars Rasha and Bidaneh Sefid in field conditions. The pathogenicity of Neoscytalidium novahollandiae, B. dothidea, Ph. aleophilum, and Phaeomoniella chlamydospora was confirmed in field conditions.
... Taxonomy of these fungi have been problematic and controversial in the past. In the past two decades, taxonomic studies based on DNA sequence data have contributed to clarify the ambiguities surrounding the systematic of pestalotioid fungi (Jeewon et al. 2002(Jeewon et al. , 2003Lee et al. 2006;Barber et al. 2011;Tanaka et al. 2011;Crous et al. 2015;Senanayake et al. 2015;Jaklitsch et al. 2016;Maharachchikumbura et al. 2016;Wijayawardene et al. 2016;Crous et al. 2018;Liu et al. 2019). In an extensive multigene phylogenetic study on coelomycetous fungi with appendage-bearing conidia Liu et al. (2019) discussed taxonomic history of these fungi in detail and placed them in the family Sporocadaceae, Xylariales. ...
Grapevine trunk diseases (GTDs) are destructive and important economically with worldwide distribution. In this survey 233 fungal isolates were obtained from grapevine cultivars showing trunk diseases symptoms in Kurdistan Province, Iran. Based on sequences data and morphology 24 species belong to 20 genera were characterized. Botryosphaeriaceae , Alternaria , Sporocadaceae and Phaeoacremonium members were the most prevalent identified fungal groups. At the species level Botryosphaeria dothidea , Alternaria malorum , Phaeoacremonium aleophilum and Acremonium sclerotigenum were the most frequent identified species. All species are new records in Kurdistan Province. Clonostachys rosea and Neoscytalidium novaehollandiae are new records on grapevine in Iran. Acremonium sclerotigenum , Alternaria chlamydosporigena , Ascochyta herbicola and Paecilomyces formosus are new records on grapevine around the world. In phylogenetic analyses based on LSU, ITS, TEF-1α and TUB2 sequence data four pestalotioid species belong to Sporocadaceae were identified. Of these, three species are new for science and introduced here as Seimatosporium marivanicum , Sporocadus kurdistani and Xenoseimatosporium kurdistanicum . Furthermore, three new combinations in Sporocadus are proposed.
... As this has led to problems with new combinations or genera and families subsequently based on these names also being rendered invalid, and thus we decided to validate these names below. Notes: Allelochaeta was treated by Crous et al. (2018a). Unfortunately, the holotype specimen was incorrectly cited and thus the epitype is consequently invalid. ...
One order, seven families, 28 new genera, 72 new species, 13 new combinations, four epitypes, and interesting new host and / or geographical records are introduced in this study. Pseudorobillardaceae is introduced for Pseudorobillarda (based on P. phragmitis). New genera include: Jeremyomyces (based on J. labinae) on twigs of Salix alba (Germany); Neodothidotthia (based on N. negundinicola) on Acer negundo (Ukraine); Neomedicopsis (based on N. prunicola) on fallen twigs of Prunus padus (Ukraine); Neophaeoappendicospora (based on N. leucaenae) on Leucaena leucocephala (France) (incl. Phaeoappendicosporaceae); Paradevriesia (incl. Paradevriesiaceae) (based on P. americana) from air (USA); Phaeoseptoriella (based on P. zeae) on leaves of Zea mays (South Africa); Piniphoma (based on P. wesendahlina) on wood debris of Pinus sylvestris (Germany); Pseudoconiothyrium (based on P. broussonetiae) on branch of Broussonetia papyrifera (Italy); Sodiomyces (based on S. alkalinus) from soil (Mongolia), and Turquoiseomyces (incl. Turquoiseomycetales and Turquoiseomycetaceae) (based on T. eucalypti) on leaves of Eucalyptus leptophylla (Australia); Typhicola (based on T. typharum) on leaves of Typha sp. (Germany); Xenodevriesia (incl. Xenodevriesiaceae) (based on X. strelitziicola) on leaves of Strelitzia sp. (South Africa). New species include: Bacillicladium clematidis on branch of Clematis vitalbae (Austria); Cercospora gomphrenigena on leaves of Gomphrena globosa (South Africa); Cyphellophora clematidis on Clematis vitalba (Austria); Exophiala abietophila on bark of Abies alba (Norway); Exophiala lignicola on fallen decorticated trunk of Quercus sp. (Ukraine); Fuscostagonospora banksiae on Banksia sp. (Australia); Gaeumannomycella caricicola on dead leaf of Carex remota (Germany); Hansfordia pruni on Prunus persica twig (Italy) (incl. Hansfordiaceae); Microdochium rhopalostylidis on Rhopalostylis sapida (New Zealand); Neocordana malayensis on leaves of Musa sp. (Malaysia); Neocucurbitaria prunicola on fallen twigs of Prunus padus (Ukraine); Neocucurbitaria salicis-albae on Salix alba twig (Ukraine); Neohelicomyces deschampsiae on culm base of dead leaf sheath of Deschampsia cespitosa (Germany); Pararoussoella juglandicola on twig of Juglans regia (Germany); Pezicula eucalyptigena on leaves of Eucalyptus sp. (South Africa); Phlogicylindrium dunnii on leaves of Eucalyptus dunnii (Australia); Phyllosticta hagahagaensis on leaf litter of Carissa bispinosa (South Africa); Phyllosticta austroafricana on leaf spots of unidentified deciduous tree host (South Africa); Pseudosigmoidea alnicola on Alnus glutinosa leaf litter (Germany); Pseudoteratosphaeria africana on leaf spot on unidentified host (Angola); Porodiplodia vitis on canes of Vitis vinifera (USA); Sodiomyces alkalinus from soil (Mongolia), Sodiomyces magadiensis and Sodiomyces tronii from soil (Kenya), Sympodiella quercina on fallen leaf of Quercus robur (Germany) and Zasmidium hakeicola on leaves of Hakea corymbosa (Australia). Epitypes are designated for: Cryptostictis falcata on leaves of E. alligatrix (Australia), Hendersonia phormii on leaves of Phormium tenax (New Zealand), Sympodiella acicola on needles of Pinus sylvestris (Netherlands), and Sphaeria scirpicola var. typharum on leaf of Typha sp. (Germany). Several taxa originally described from rocks are validated in this study. New taxa include: Extremaceae fam. nov., and new genera, Arthrocatena, Catenulomyces, Constantinomyces, Extremus, Hyphoconis, Incertomyces, Lapidomyces, Lithophila,Monticola, Meristemomyces, Oleoguttula, Perusta, Petrophila, Ramimonilia, Saxophila and Vermiconidia. New species include: Arthrocatena tenebrosa, Catenulomyces convolutus, Constantinomyces virgultus, C. macerans, C. minimus,C. nebulosus, C. virgultus, Exophiala bonariae, Extremus adstrictus, E. antarcticus, Hyphoconis sterilis, Incertomyces perditus, Knufia karalitana, K. marmoricola, K. mediterranea, Lapidomyces hispanicus, Lithophila guttulata, Monticola elongata, Meristemomyces frigidus, M. arctostaphyli, Neodevriesia bulbillosa, N. modesta, N. sardiniae, N. simplex, Oleoguttula mirabilis, Paradevriesia compacta, Perusta inaequalis, Petrophila incerta, Rachicladosporium alpinum, R. inconspicuum, R. mcmurdoi, R. monterosanum, R. paucitum, Ramimonilia apicalis, Saxophila tyrrhenica, Vermiconidia antarctica, V. calcicola, V. foris, and V. flagrans.
... Based on LSU and ITS phylogenetic analyses, Vermisporium was again synonymised under Seimatosporium (Barber et al. 2011, Tanaka et al. 2011. In a subsequent multi-locus phylogenetic study including type species, Crous et al. (2018) resurrected the older name Allelochaeta (syn. Discostromopsis, Vermisporium) to accommodate these taxa. ...
Species of Sporocadaceae are endophytic, plant pathogenic or saprobic, and associated with a wide range of host plants. Recent molecular studies that have attempted to address familial and generic boundaries of fungi belonging to Sporocadaceae were based on a limited number of samples and DNA loci. The taxonomy of this group of fungi is therefore still not fully resolved. The aim of the present study is to provide a natural classification for the Sporocadaceae based on multi-locus phylogenetic analyses, using LSU, ITS, tef-1α tub2 and rpb2 loci, in combination with morphological data. A total of 30 well-supported monophyletic clades in Sporocadaceae are recognised, representing 23 known and seven new genera. Typifications are proposed for the type species of five genera (Diploceras, Discosia, Monochaetia, Sporocadus and Truncatella) to stabilise the application of these names. Furthermore, Neotruncatella and Dyrithiopsis are synonymised under Hymenopleella, and the generic circumscriptions of Diploceras, Disaeta, Hymenopleella, Monochaetia, Morinia, Pseudopestalotiopsis, Sarcostroma, Seimatosporium, Synnemapestaloides and Truncatella are emended. A total of 51 new species, one nomina nova and 15 combinations are introduced.
This study documents the morphology and phylogeny of ascomycetes collected from karst landscapes of Guizhou Province, China. Based on morphological characteristics in conjunction with DNA sequence data, 70 species are identified and distributed in two classes (Dothideomycetes and Sordariomycetes), 16 orders, 41 families and 60 genera. One order Planisphaeriales, four families Leptosphaerioidaceae, Neoleptosporellaceae, Planisphaeriaceae and Profundisphaeriaceae, ten genera Conicosphaeria, Karstiomyces, Leptosphaerioides, Neoceratosphaeria, Neodiaporthe, Neodictyospora, Planisphaeria, Profundisphaeria, Stellatus and Truncatascus, and 34 species (Amphisphaeria karsti, Anteaglonium hydei, Atractospora terrestris, Conicosphaeria vaginatispora, Corylicola hydei, Diaporthe cylindriformispora, Dictyosporium karsti, Hysterobrevium karsti, Karstiomyces guizhouensis, Leptosphaerioides guizhouensis, Lophiotrema karsti, Murispora hydei, Muyocopron karsti, Neoaquastroma guizhouense, Neoceratosphaeria karsti, Neodiaporthe reniformispora, Neodictyospora karsti, Neoheleiosa guizhouensis, Neoleptosporella fusiformispora, Neoophiobolus filiformisporum, Ophioceras guizhouensis, Ophiosphaerella karsti, Paraeutypella longiasca, Paraeutypella karsti, Patellaria guizhouensis, Planisphaeria karsti, Planisphaeria reniformispora, Poaceascoma herbaceum, Profundisphaeria fusiformispora, Pseudocoleophoma guizhouensis, Pseudopolyplosphaeria guizhouensis, Stellatus guizhouensis, Sulcatispora karsti and Truncatascus microsporus) are introduced as new to science. Moreover, 13 new geographical records for China are also reported, which are Acrocalymma medicaginis, Annulohypoxylon thailandicum, Astrosphaeriella bambusae, Diaporthe novem, Hypoxylon rubiginosum, Ophiosphaerella agrostidis, Ophiosphaerella chiangraiensis, Patellaria atrata, Polyplosphaeria fusca, Psiloglonium macrosporum, Sarimanas shirakamiense, Thyridaria broussonetiae and Tremateia chromolaenae. Additionally, the family Eriomycetaceae was resurrected as a non-lichenized family and accommodated within Monoblastiales. Detailed descriptions and illustrations of all these taxa are provided.
Besides well-known grapevine trunk disease (GTD)-related pathogens, there is an increased interest in wood-colonizing fungi that infect grapevines. During 2017-2018, a survey was conducted in Cyprus and wood samples were collected from vines exhibiting typical GTD symptoms. Based on morphological and multilocus phylogenetic analyses (ITS, LSU, bt2, tef1-a), four species in the Sporocadaceae family were described and typified; two in the genus of Seimatosporium: Seim. cyprium sp. nov. and Seim. vitis-viniferae and two in Sporocadus: Spo. kurdistanicus and Spo. rosi-gena. The teleomorph of Seim. cyprium sp. nov. was also described. Pathogenicity trials with representative isolates of each species were performed on woody stems of two-year-old potted grapevines for 12 months under field conditions. All isolates were pathogenic, causing dark brown to black vascular discoloration, extending upward and downward from the inoculation point. Sporo-cadus isolates were significantly more aggressive than Seimatosporium with lesion lengths ranging from 9.24 to 6.90 and 4.13 to 4.00 cm, respectively. Successful re-isolations were also evident for all species and isolates. Seim. cyprium sp. nov. is a newly described species, while Spo. kurdistanicus and Spo. rosigena are reported for the first time in Europe on Vitis vinifera, suggesting the potential role of Sporocadaceae in the GTDs complex
Species of eucalypts are commonly cultivated for solid wood and pulp products. The expansion of commercially managed eucalypt plantations has chiefly been driven by their rapid growth and suitability for propagation across a very wide variety of sites and climatic conditions. Infection of foliar fungal pathogens of eucalypts is resulting in increasingly negative impacts on commercial forest industries globally. To assist in evaluating this threat, the present study provides a global perspective on foliar pathogens of eucalypts. We treat 110 different genera including species associated with foliar disease symptoms of these hosts. The vast majority of these fungi have been grown in axenic culture, and subjected to DNA sequence analysis, resolving their phylogeny. During the course of this study several new genera and species were encountered, and these are described. New genera include: Lembosiniella (L. eucalyptorum on E. dunnii, Australia), Neosonderhenia (N. eucalypti on E. costata, Australia), Neothyriopsis (N. sphaerospora on E. camaldulensis, South Africa), Neotrichosphaeria (N. eucalypticola on E. deglupta, Australia), Nothotrimmatostroma (N. bifarium on E. dalrympleana, Australia), Nowamyces (incl. Nowamycetaceae fam. nov., N. globulus on E. globulus, Australia), and Walkaminomyces (W. medusae on E. alba, Australia). New species include (all from Australia): Disculoides fraxinoides on E. fraxinoides, Elsinoe piperitae on E. piperita, Fusculina regnans on E. regnans, Marthamyces johnstonii on E. dunnii, Neofusicoccum corticosae on E. corticosa, Neotrimmatostroma dalrympleanae on E. dalrympleana, Nowamyces piperitae on E. piperita, Phaeothyriolum dunnii on E. dunnii, Pseudophloeospora eucalyptigena on E. obliqua, Pseudophloeospora jollyi on Eucalyptus sp., Quambalaria tasmaniae on Eucalyptus sp., Q. rugosae on E. rugosa, Sonderhenia radiata on E. radiata, Teratosphaeria pseudonubilosa on E. globulus and Thyrinula dunnii on E. dunnii. A new name is also proposed for Heteroconium eucalypti as Thyrinula uruguayensis on E. dunnii, Uruguay. Although many of these genera and species are commonly associated with disease problems, several appear to be opportunists developing on stressed or dying tissues. For the majority of these fungi, pathogenicity remains to be determined. This represents an important goal for forest pathologists and biologists in the future. Consequently, this study will promote renewed interest in foliar pathogens of eucalypts, leading to investigations that will provide an improved understanding of the biology of these fungi.
The Canadian beekeeping industry is spread across the country, with the greatest proportion of managed honey bee colonies occurring in the Prairie Provinces. Nationally, the number of beekeepers has recently been trending upwards. Simultaneously, agronomic and environmental plant pest incidents are increasing due to a number of factors, including the introduction of exotic organisms through international trade, which is a major pathway for the introduction of potentially invasive alien species and quarantine pests. Therefore, regulatory agencies are interested in developing high‐throughput tools to achieve earlier detection of unwanted species in order to expedite application of mitigating measures to limit the impacts of their introduction. This study evaluates the potential of pollen pellet contents collected by honey bees to monitor plant pests using metabarcoding, a high‐throughput sequencing (HTS) approach for monitoring complex environmental samples. The study used the ITS1 intergenic region to target oomycetes and fungi, the ATP9‐NAD9 spacer to specifically target Phytophthora species, and the ITS2 region to target plant species. From the HTS results, a number of plants that were detected corresponded to known hosts of certain pathogens or species closely related to potentially invasive plant species. Genera including phytopathogenic species found in the pollen samples comprised Fusarium sp., Ophiostoma sp., Peronospora sp., Phytophthora sp., and Pythium sp. Correlations, high entropy, and co‐occurrences between certain plants and oomycetes or fungi were observed. The potential for using honey bee‐collected pollen pellets to study phytopathogens in a given environment is demonstrated here, and this concept could represent a promising complementary tool for the surveillance of phytopathogens or unwanted plants with previously described air and insect sampling methods if the protocol was applied with additional genetic markers.
