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Jami F, Marincowitz S, Crous PW, Jacobsohn A, Wingfield MJ. A new Cytospora species pathogenic on Carpobrotus edulis in its native habitat. Fungal Syst Evol 2018; 2:37-43. [PMID: 32467886 PMCID: PMC7225577 DOI: 10.3114/fuse.2018.02.03] [Citation(s) in RCA: 2] [Impact Index Per Article: 0.3] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 11/07/2022] Open
Abstract
Carpobrotus edulis (Aizoaceae) is a fleshy creeper, native to South Africa and commonly found growing on coastal seashores. Recently this plant has been observed dying in large patches in areas close to Cape Town. Symptoms include a wilting of the leaves associated with death of the woody stems. The aim of this study was to identify the probable cause of this disease. Dead and dying stem tissues were found to be colonised by a species of Cytospora. Isolates of this fungus were identified based on DNA sequence data from the rDNA-ITS, translation elongation factor 1-α, β-tubulin and large subunit rDNA loci. Analyses of the data showed that the fungus is a new species of Cytospora, described here as Cytospora carpobroti sp. nov. Pathogenicity tests showed that C. carpobroti resulted in distinct lesions on inoculated stems but not the fleshy leaves. The origin of C. carpobroti is unknown and there is concern that it could be an introduced pathogen threatening the health of this important native plant.
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Guarnaccia V, Sandoval-Denis M, Aiello D, Polizzi G, Crous PW. Neocosmospora perseae sp. nov., causing trunk cankers on avocado in Italy. Fungal Syst Evol 2018; 1:131-140. [PMID: 32490364 PMCID: PMC7259237 DOI: 10.3114/fuse.2018.01.06] [Citation(s) in RCA: 15] [Impact Index Per Article: 2.5] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 12/25/2022] Open
Abstract
Trunk and branch cankers are among the most important diseases compromising avocado production worldwide. A novel species, Neocosmospora perseae sp. nov. is described isolated from trunk lesions on Persea americana in the main avocado producing area of Sicily, Italy. The new species is characterised using a polyphasic approach including morphological characters and a multilocus molecular phylogenetic analysis based on partial sequences of the translation elongation factor-1α, the internal transcribed spacer regions plus the large subunit of the rDNA cistron, and the RNA polymerase II second largest subunit. Pathogenicity tests and the fulfilment of Koch's postulates confirm N. perseae as a novel canker pathogen of Persea americana.
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Braun U, Nakashima C, Crous PW, Groenewald JZ, Moreno-Rico O, Rooney-Latham S, Blomquist CL, Haas J, Marmolejo J. Phylogeny and taxonomy of the genus Tubakia s. lat.. Fungal Syst Evol 2018; 1:41-99. [PMID: 32490362 PMCID: PMC7259437 DOI: 10.3114/fuse.2018.01.04] [Citation(s) in RCA: 29] [Impact Index Per Article: 4.8] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 11/07/2022] Open
Abstract
The genus Tubakia is revised on the basis of morphological and phylogenetic data. The phylogenetic affinity of Tubakia to the family Melanconiellaceae (Diaporthales) was recently postulated, but new analyses based on sequences retrieved from material of the type species of Tubakia, T. dryina, support a family of its own, viz. Tubakiaceae fam. nov. Our phylogenetic analyses revealed the heterogeneity of Tubakia s. lat. which is divided into several genera, viz., Tubakia s. str., Apiognomonioides gen. nov. (type species: Apiognomonioides supraseptata), Involutiscutellula gen. nov. (type species: Involutiscutellula rubra), Oblongisporothyrium gen. nov. (type species: Oblongisporothyrium castanopsidis), Paratubakia gen. nov. (type species: Paratubakia subglobosa), Racheliella gen. nov. (type species: Racheliella wingfieldiana sp. nov.), Saprothyrium gen. nov. (type species: Saprothyrium thailandense) and Sphaerosporithyrium gen. nov. (type species: Sphaerosporithyrium mexicanum sp. nov.). Greeneria saprophytica is phylogenetically closely allied to Racheliella wingfieldiana and is therefore reallocated to Racheliella. Particular emphasis is laid on a revision and phylogenetic analyses of Tubakia species described from Japan and North America. Almost all North American collections of this genus were previously referred to as T. dryina s. lat., which is, however, a heterogeneous complex. Several new North American species have recently been described. The new species Sphaerosporithyrium mexicanum, Tubakia melnikiana and T. sierrafriensis, causing leaf spots on several oak species found in the North-Central Mexican state Aguascalientes and the North-Eastern Mexican state Nuevo León, are described, illustrated, and compared with similar species. Several additional new species are introduced, including Tubakia californica based on Californian collections on various species of the genera Chrysolepis, Notholithocarpus and Quercus, and T. dryinoides, T. oblongispora, T. paradryinoides, and Paratubakia subglobosoides described on the basis of Japanese collections. Tubakia suttoniana nom. nov., based on Dicarpella dryina, is a species closely allied to T. californica and currently only known from Europe. Tubakia dryina, type species of Tubakia, is epitypified, and the phylogenetic position and circumscription of Tubakia are clarified. A revised, supplemented key to the species of Tubakia and allied genera on the basis of conidiomata is provided.
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Wanasinghe DN, Hyde KD, Jeewon R, Crous PW, Wijayawardene NN, Jones EBG, Bhat DJ, Phillips AJL, Groenewald JZ, Dayarathne MC, Phukhamsakda C, Thambugala KM, Bulgakov TS, Camporesi E, Gafforov YS, Mortimer PE, Karunarathna SC. Phylogenetic revision of Camarosporium ( Pleosporineae, Dothideomycetes) and allied genera. Stud Mycol 2017; 87:207-256. [PMID: 28966419 PMCID: PMC5607397 DOI: 10.1016/j.simyco.2017.08.001] [Citation(s) in RCA: 41] [Impact Index Per Article: 5.9] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 11/20/2022] Open
Abstract
A concatenated dataset of LSU, SSU, ITS and tef1 DNA sequence data was analysed to investigate the taxonomic position and phylogenetic relationships of the genus Camarosporium in Pleosporineae (Dothideomycetes). Newly generated sequences from camarosporium-like taxa collected from Europe (Italy) and Russia form a well-supported monophyletic clade within Pleosporineae. A new genus Camarosporidiella and a new family Camarosporidiellaceae are established to accommodate these taxa. Four new species, Neocamarosporium korfii, N. lamiacearum, N. salicorniicola and N. salsolae, constitute a strongly supported clade with several known taxa for which the new family, Neocamarosporiaceae, is introduced. The genus Staurosphaeria based on S. lycii is resurrected and epitypified, and shown to accommodate the recently introduced genus Hazslinszkyomyces in Coniothyriaceae with significant statistical support. Camarosporium quaternatum, the type species of Camarosporium and Camarosporomyces flavigena cluster together in a monophyletic clade with significant statistical support and sister to the Leptosphaeriaceae. To better resolve interfamilial/intergeneric level relationships and improve taxonomic understanding within Pleosporineae, we validate Camarosporiaceae to accommodate Camarosporium and Camarosporomyces. The latter taxa along with other species are described in this study.
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Key Words
- Ca. aborescentis (Phukhams. et al.) Phukhams., Wanas. & K.D. Hyde
- Ca. arezzoensis (Tibpromma et al.) Wanas. & K.D. Hyde
- Ca. celtidis (Shear) Thambugala, Wanas. & K.D. Hyde
- Ca. clematidis (Wijayaw. et al.) Wijayaw., Wanas. & K.D. Hyde
- Ca. elongata (Fr.) Wanas., Wijayaw. & K.D. Hyde
- Ca. eufemiana Wanas., Camporesi & K.D. Hyde
- Ca. halimodendri Wanas., Bulgakov & K.D. Hyde
- Ca. italica Wanas., Camporesi & K.D. Hyde
- Ca. laburni (Pers.) Wanas., Bulgakov, Camporesi & K.D. Hyde
- Ca. laburnicola (R.H. Perera et al.) Wanas. & K.D. Hyde
- Ca. mackenziei Wanas., Bulgakov & K.D. Hyde
- Ca. melnikii Wanas., Bulgakov & K.D. Hyde
- Ca. mirabellensis Wanas., Camporesi & K.D. Hyde
- Ca. moricola (Chethana et al.) Wanas. & K.D. Hyde
- Ca. premilcurensis Wanas., Camporesi & K.D. Hyde
- Ca. robiniicola (Wijayaw. et al.) Wijayaw., Wanas. & K.D. Hyde
- Ca. schulzeri Wanas., Bulgakov & K.D. Hyde
- Ca. spartii (Trail) Wijayaw., Wanas. & K.D. Hyde
- Camarosporiaceae Wanas., K.D. Hyde & Crous
- Camarosporidiella Wanas., Wijayaw. & K.D. Hyde
- Camarosporidiella caraganicola (Phukhams. et al.) Phukhams., Wanas. & K.D. Hyde
- Camarosporidiella elaeagnicola Wanas., Bulgakov & K.D. Hyde
- Camarosporidiella: Ca.
- Camarosporidiellaceae Wanas., Wijayaw., Crous & K.D. Hyde
- Camarosporium: Cm.
- Camarosporomyces: Cs.
- Cucurbitaria: Cu
- Multigene phylogeny
- Muriformly septate
- N. lamiacearum Dayar., E.B.G. Jones & K.D. Hyde
- N. obiones (Jaap) Wanas. & K.D. Hyde
- N. salicorniicola Dayarathne, E.B.G. Jones & K.D. Hyde
- N. salsolae Wanas., Gafforov & K.D. Hyde
- Neocamarosporiaceae Wanas., Wijayaw., Crous & K.D. Hyde
- Neocamarosporium chenopodii (Ellis & Kellerm.) Wanas. & K.D. Hyde
- Neocamarosporium korfii Wanas., E.B.G. Jones & K.D. Hyde
- Pleomorphism
- Pleosporales
- Staurosphaeria aloes (Crous & M.J. Wingf.) Crous
- Staurosphaeria lycii Rabenh
- Staurosphaeria lyciicola (Crous & R.K. Schumach.) Crous, Wanas. & K.D. Hyde
- Staurosphaeria rhamnicola Wanas., Yu. Sh. Gafforov & K.D. Hyde
- Taxonomy
- Wanas. & K.D. Hyde
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Abstract
The Didymellaceae is one of the most species-rich families in the fungal kingdom, and includes species that inhabit a wide range of ecosystems. The taxonomy of Didymellaceae has recently been revised on the basis of multi-locus DNA sequence data. In the present study, we investigated 108 Didymellaceae isolates newly obtained from 40 host plant species in 27 plant families, and various substrates from caves, including air, water and carbonatite, originating from Argentina, Australia, Canada, China, Hungary, Israel, Italy, Japan, South Africa, the Netherlands, the USA and former Yugoslavia. Among these, 68 isolates representing 32 new taxa are recognised based on the multi-locus phylogeny using sequences of LSU, ITS, rpb2 and tub2, and morphological differences. Within the Didymellaceae, five genera appeared to be limited to specific host families, with other genera having broader host ranges. In total 19 genera are recognised in the family, with Heracleicola being reduced to synonymy under Ascochyta. This study has significantly improved our understanding on the distribution and biodiversity of Didymellaceae, although the placement of several genera still need to be clarified.
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Key Words
- Allophomaoligotrophica Q. Chen, Crous & L. Cai
- Ascochytaboeremae L.W. Hou, Crous & L. Cai
- Ascochytapremilcurensis (Tibpromma et al.) Q. Chen, Crous & L. Cai
- Boeremiaexigua var. opuli Q. Chen, Crous & L. Cai
- Calophomarosae Q. Chen, Crous & L. Cai
- Didymellaaeria Q. Chen, Crous & L. Cai, D. aquatica Q. Chen, Crous & L. Cai, D. chloroguttulata Q. Chen, Crous & L. Cai, D. ellipsoidea Q. Chen, Crous & L. Cai, D. ilicicola Q. Chen, Crous & L. Cai, D. infuscatispora Q. Chen, Crous & L. Cai, D. macrophylla Q. Chen, Crous & L. Cai, D. ocimicola Q. Chen, Crous & L. Cai, D. pteridis L.W. Hou, Crous & L. Cai, D. sinensis Q. Chen, Crous & L. Cai, D. suiyangensis Q. Chen, Crous & L. Cai
- Didymellasegeticola (Q. Chen) Q. Chen, Crous & L. Cai
- Epicoccumcamelliae Q. Chen, Crous & L. Cai, E. dendrobii Q. Chen, Crous & L. Cai, E. duchesneae Q. Chen, Crous & L. Cai, E. hordei Q. Chen, Crous & L. Cai, E. italicum Q. Chen, Crous & L. Cai, E. latusicollum Q. Chen, Crous & L. Cai, E. layuense Q. Chen, Crous & L. Cai, E. poae Q. Chen, Crous & L. Cai, E. viticis Q. Chen, Crous & L. Cai
- Heterophomaverbascicola Q. Chen, Crous & L. Cai
- Host-associated
- Karst caves
- Multi-locus phylogeny
- Neoascochytaargentina L.W. Hou, Crous & L. Cai, Neoa. soli Q. Chen, Crous & L. Cai, Neoa. triticicola L.W. Hou, Crous & L. Cai
- Neodidymelliopsisachlydis L.W. Hou, Crous & L. Cai, Neod. longicolla L.W. Hou, Crous & L. Cai
- Phoma
- Stagonosporopsisbomiensis Q. Chen, Crous & L. Cai, S. papillata Q. Chen, Crous & L. Cai
- Taxonomy
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Abstract
In 2007 a new Stemphylium leaf spot disease of Beta vulgaris (sugar beet) spread through the Netherlands. Attempts to identify this destructive Stemphylium sp. in sugar beet led to a phylogenetic revision of the genus. The name Stemphylium has been recommended for use over that of its sexual morph, Pleospora, which is polyphyletic. Stemphylium forms a well-defined monophyletic genus in the Pleosporaceae, Pleosporales (Dothideomycetes), but lacks an up-to-date phylogeny. To address this issue, the internal transcribed spacer 1 and 2 and intervening 5.8S nr DNA (ITS) of all available Stemphylium and Pleospora isolates from the CBS culture collection of the Westerdijk Institute (N = 418), and from 23 freshly collected isolates obtained from sugar beet and related hosts, were sequenced to construct an overview phylogeny (N = 350). Based on their phylogenetic informativeness, parts of the protein-coding genes calmodulin and glyceraldehyde-3-phosphate dehydrogenase were also sequenced for a subset of isolates (N = 149). This resulted in a multi-gene phylogeny of the genus Stemphylium containing 28 species-clades, of which five were found to represent new species. The majority of the sugar beet isolates, including isolates from the Netherlands, Germany and the UK, clustered together in a species clade for which the name S. beticola was recently proposed. Morphological studies were performed to describe the new species. Twenty-two names were reduced to synonymy, and two new combinations proposed. Three epitypes, one lectotype and two neotypes were also designated in order to create a uniform taxonomy for Stemphylium.
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Hernández-Restrepo M, Gené J, Castañeda-Ruiz RF, Mena-Portales J, Crous PW, Guarro J. Phylogeny of saprobic microfungi from Southern Europe. Stud Mycol 2017. [PMID: 28626275 PMCID: PMC5470572 DOI: 10.1016/j.simyco.2017.05.002] [Citation(s) in RCA: 88] [Impact Index Per Article: 12.6] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 12/03/2022] Open
Abstract
During a survey of saprophytic microfungi on decomposing woody, herbaceous debris and soil from different regions in Southern Europe, a wide range of interesting species of asexual ascomycetes were found. Phylogenetic analyses based on partial gene sequences of SSU, LSU and ITS proved that most of these fungi were related to Sordariomycetes and Dothideomycetes and to lesser extent to Leotiomycetes and Eurotiomycetes. Four new monotypic orders with their respective families are proposed here, i.e. Lauriomycetales, Lauriomycetaceae; Parasympodiellales, Parasympodiellaceae; Vermiculariopsiellales, Vermiculariopsiellaceae and Xenospadicoidales, Xenospadicoidaceae. One new order and three families are introduced here to accommodate orphan taxa, viz. Kirschsteiniotheliales, Castanediellaceae, Leptodontidiaceae and Pleomonodictydaceae. Furthermore, Bloxamiaceae is validated. Based on morphology and phylogenetic affinities Diplococcium singulare, Trichocladium opacum and Spadicoides atra are moved to the new genera Paradiplococcium, Pleotrichocladium and Xenospadicoides, respectively. Helicoon fuscosporum is accommodated in the genus Magnohelicospora. Other novel genera include Neoascotaiwania with the type species N. terrestris sp. nov., and N. limnetica comb. nov. previously accommodated in Ascotaiwania; Pleomonodictys with P. descalsii sp. nov. as type species, and P. capensis comb. nov. previously accommodated in Monodictys; Anapleurothecium typified by A. botulisporum sp. nov., a fungus morphologically similar to Pleurothecium but phylogenetically distant; Fuscosclera typified by F. lignicola sp. nov., a meristematic fungus related to Leotiomycetes; Pseudodiplococcium typified by P. ibericum sp. nov. to accommodate an isolate previously identified as Diplococcium pulneyense; Xyladictyochaeta typified with X. lusitanica sp. nov., a foliicolous fungus related to Xylariales and similar to Dictyochaeta, but distinguished by polyphialidic conidiogenous cells produced on setiform conidiophores. Other novel species proposed are Brachysporiella navarrica, Catenulostroma lignicola, Cirrenalia iberica, Conioscypha pleiomorpha, Leptodontidium aureum, Pirozynskiella laurisilvatica, Parasympodiella lauri and Zanclospora iberica. To fix the application of some fungal names, lectotypes and/or epitypes are designated for Magnohelicospora iberica, Sporidesmium trigonellum, Sporidesmium opacum, Sporidesmium asperum, Camposporium aquaticum and Psilonia atra.
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Key Words
- Anapleurothecium Hern.-Restr., R.F. Castañeda & Gené
- Anapleurothecium botulisporum Hern.-Restr., R.F. Castañeda & Gené
- Biodiversity
- Brachysporiella navarrica Hern.-Restr., R.F. Castañeda & Gené
- Camposporium aquaticum Dudka
- Camposporium aquatium Dudka
- Castanediellaceae Hern.-Restr., Guarro & Crous
- Catenulostroma lignicola Hern.-Restr., J. Mena & Gené
- Cirrenalia iberica Hern.-Restr. & Gené
- Conioscypha pleiomorpha Hern.-Restr., R.F. Castañeda & Gené
- Dothideomycetes
- Eurotiomycetes
- Fuscosclera Hern.-Restr., J. Mena & Gené
- Fuscosclera lignicola Hern.-Restr., J. Mena & Gené
- Kirschsteiniotheliales Hern.-Restr., Gené, R.F. Castañeda & Crous
- Lauriomycetaceae Hern.-Restr., R.F. Castañeda & Guarro
- Lauriomycetales Hern.-Restr., R.F. Castañeda & Guarro
- Leotiomycetes
- Leptodontidiaceae Hern.-Restr., Crous & Gené
- Leptodontidium aureum Hern.-Restr., Guarro & Gené
- Magnohelicospora fuscospora (Linder) R.F. Castañeda, Hern.-Restr. & Gené
- Magnohelicospora iberica R.F. Castañeda, Hern.-Restr., Gené & Guarro
- Neoascotaiwania Hern.-Restr., R.F. Castañeda & Guarro
- Neoascotaiwania limnetica (H.S. Chang & S.Y. Hsieh) Hern.-Restr., R.F. Castañeda & Gené
- Paradiplococcium Hern.-Restr., J. Mena & Gené
- Paradiplococcium singulare (Hern.-Restr., J. Mena, Gené & Guarro) Hern.-Restr., J. Mena & Gené
- Parasympodiella lauri Hern.-Restr., Gene & Guarro
- Parasympodiellaceae Hern.-Restr., Gené, Guarro & Crous
- Parasympodiellales Hern.-Restr., Gené, R.F. Castañeda & Crous
- Pirozynskiella laurisilvatica Hern.-Restr., R.F. Castañeda & Gené
- Pleomonodictydaceae Hern.-Restr., J. Mena & Gené
- Pleomonodictys Hern.-Restr., J. Mena & Gené
- Pleomonodictys capensis (R.C. Sinclair, Boshoff & Eicker) Hern.-Restr., J. Mena & Gené
- Pleomonodictys descalsii Hern.-Restr., J. Mena & Gené
- Pleotrichocladium Hern.-Restr., R.F. Castañeda & Gené
- Pleotrichocladium opacum (Corda) Hern.-Restr., R.F. Castañeda & Gené
- Pseudodiplococcium Hern.-Restr., J. Mena & Gené
- Pseudodiplococcium ibericum Hern.-Restr., J. Mena & Gené
- Psilonia atra Corda
- Sordariomycetes
- Sporidesmium asperum Corda
- Sporidesmium opacum Corda
- Sporidesmium trigonellum Sacc.
- Systematics
- Vermiculariopsiellaceae Hern.-Restr., J. Mena, Gené & Crous
- Vermiculariopsiellales Hern.-Restr., J. Mena, Gené & Crous
- Xenospadicoidaceae Hern.-Restr., J. Mena & Gené
- Xenospadicoidales Hern.-Restr., J. Mena & Gené
- Xenospadicoides Hern.-Restr., J. Mena & Gené
- Xenospadicoides atra (Corda) Hern.-Restr., J. Mena & Gené
- Xyladictyochaeta Hern.-Restr., R.F. Castañeda & Gené
- Xyladictyochaeta lusitanica Hern.-Restr., R.F. Castañeda & Gené
- Zanclospora iberica Hern.-Restr., J. Mena & Gené
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Wang XW, Houbraken J, Groenewald JZ, Meijer M, Andersen B, Nielsen KF, Crous PW, Samson RA. Diversity and taxonomy of Chaetomium and chaetomium-like fungi from indoor environments. Stud Mycol 2016; 84:145-224. [PMID: 28082757 PMCID: PMC5226397 DOI: 10.1016/j.simyco.2016.11.005] [Citation(s) in RCA: 98] [Impact Index Per Article: 12.3] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 12/17/2022] Open
Abstract
During a study of indoor fungi, 145 isolates belonging to Chaetomiaceae were cultured from air, swab and dust samples from 19 countries. Based on the phylogenetic analyses of DNA-directed RNA polymerase II second largest subunit (rpb2), β-tubulin (tub2), ITS and 28S large subunit (LSU) nrDNA sequences, together with morphological comparisons with related genera and species, 30 indoor taxa are recognised, of which 22 represent known species, seven are described as new, and one remains to be identified to species level. In our collection, 69 % of the indoor isolates with six species cluster with members of the Chaetomium globosum species complex, representing Chaetomium sensu stricto. The other indoor species fall into nine lineages that are separated from each other with several known chaetomiaceous genera occurring among them. No generic names are available for five of those lineages, and the following new genera are introduced here: Amesia with three indoor species, Arcopilus with one indoor species, Collariella with four indoor species, Dichotomopilus with seven indoor species and Ovatospora with two indoor species. The generic concept of Botryotrichum is expanded to include Emilmuelleria and the chaetomium-like species B. muromum (= Ch. murorum) in which two indoor species are included. The generic concept of Subramaniula is expanded to include several chaetomium-like taxa as well as one indoor species. Humicola is recognised as a distinct genus including two indoor taxa. According to this study, Ch. globosum is the most abundant Chaetomiaceae indoor species (74/145), followed by Ch. cochliodes (17/145), Ch. elatum (6/145) and B. piluliferum (5/145). The morphological diversity of indoor Chaetomiaceae as well as the morphological characteristics of the new genera are described and illustrated. This taxonomic study redefines the generic concept of Chaetomium and provides new insight into the phylogenetic relationships among different genera within Chaetomiaceae.
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Vu D, Groenewald M, Szöke S, Cardinali G, Eberhardt U, Stielow B, de Vries M, Verkleij GJM, Crous PW, Boekhout T, Robert V. DNA barcoding analysis of more than 9 000 yeast isolates contributes to quantitative thresholds for yeast species and genera delimitation. Stud Mycol 2016; 85:91-105. [PMID: 28050055 PMCID: PMC5192050 DOI: 10.1016/j.simyco.2016.11.007] [Citation(s) in RCA: 185] [Impact Index Per Article: 23.1] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 10/28/2022] Open
Abstract
DNA barcoding is a global initiative for species identification through sequencing of short DNA sequence markers. Sequences of two loci, ITS and LSU, were generated as barcode data for all (ca. 9k) yeast strains included in the CBS collection, originally assigned to ca. 2 000 species. Taxonomic sequence validation turned out to be the most severe bottleneck due to the large volume of generated trace files and lack of reference sequences. We have analysed and validated CBS strains and barcode sequences automatically. Our analysis shows that there were 6 and 9.5 % of CBS yeast species that could not be distinguished by ITS and LSU, respectively. Among them, ∼3 % were indistinguishable by both loci. Except for those species, both loci were successfully resolving yeast species as the grouping of yeast DNA barcodes with the predicted taxonomic thresholds was more than 90 % similar to the grouping with respect to the expected taxon names. The taxonomic thresholds predicted to discriminate yeast species were 98.41 % for ITS and 99.51 % for LSU. To discriminate current yeast genera, thresholds were 96.31 % for ITS and 97.11 % for LSU. Using ITS and LSU barcodes, we were also able to show that the recent reclassifications of basidiomycetous yeasts in 2015 have made a significant improvement for the generic taxonomy of those organisms. The barcodes of 4 730 (51 %) CBS yeast strains of 1 351 (80 %) accepted yeast species that were manually validated have been released to GenBank and the CBS-KNAW website as reference sequences for yeast identification.
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Bensch K, Groenewald JZ, Braun U, Dijksterhuis J, de Jesús Yáñez-Morales M, Crous PW. Common but different: The expanding realm of Cladosporium. Stud Mycol 2015; 82:23-74. [PMID: 26955200 PMCID: PMC4774271 DOI: 10.1016/j.simyco.2015.10.001] [Citation(s) in RCA: 83] [Impact Index Per Article: 9.2] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 11/27/2022] Open
Abstract
The genus Cladosporium (Cladosporiaceae, Dothideomycetes), which represents one of the largest genera of dematiaceous hyphomycetes, has been intensively investigated during the past decade. In the process, three major species complexes (C. cladosporioides, C. herbarum and C. sphaerospermum) were resolved based on morphology and DNA phylogeny, and a monographic revision of the genus (s. lat.) published reflecting the current taxonomic status quo. In the present study a further 19 new species are described based on phylogenetic characters (nuclear ribosomal RNA gene operon, including the internal transcribed spacer regions ITS1 and ITS2, as well as partial actin and translation elongation factor 1-α gene sequences) and morphological differences. For a selection of the species with ornamented conidia, scanning electron microscopic photos were prepared to illustrate the different types of surface ornamentation. Surprisingly, during this study Cladosporium ramotenellum was found to be a quite common saprobic species, being widely distributed and occurring on various substrates. Therefore, an emended species description is provided. Furthermore, the host range and distribution data for several previously described species are also expanded.
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Key Words
- C. aggregatocicatricatum Bensch, Crous & U. Braun
- C. angustiherbarum Bensch, Crous & U. Braun
- C. angustiterminale Bensch, Crous & U. Braun
- C. austroafricanum Bensch, Crous & U. Braun
- C. austrohemisphaericum Bensch, Crous & U. Braun
- C. ipereniae Bensch, Crous & U. Braun
- C. limoniforme Bensch, Crous & U. Braun
- C. longicatenatum Bensch, Crous & U. Braun
- C. longissimum Bensch, Crous & U. Braun
- C. montecillanum Bensch, Crous & U. Braun
- C. parapenidielloides Bensch, Crous & U. Braun
- C. penidielloides Bensch, Crous & U. Braun
- C. pseudochalastosporoides Bensch, Crous & U. Braun
- C. puyae Bensch, Crous & U. Braun
- C. rhusicola Bensch, Crous & U. Braun
- C. ruguloflabelliforme Bensch, Crous & U. Braun
- C. rugulovarians Bensch, Crous & U. Braun
- C. versiforme Bensch, Crous & U. Braun
- Cladosporiaceae
- Cladosporium aciculare Bensch, Crous & U. Braun
- Emendation
- Phylogeny
- Taxonomic novelties
- Taxonomy
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Huang F, Groenewald JZ, Zhu L, Crous PW, Li H. Cercosporoid diseases of Citrus. Mycologia 2015; 107:1151-71. [PMID: 26432805 DOI: 10.3852/15-059] [Citation(s) in RCA: 11] [Impact Index Per Article: 1.2] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Journal Information] [Subscribe] [Scholar Register] [Received: 06/25/2015] [Accepted: 06/25/2015] [Indexed: 11/10/2022]
Abstract
Citrus leaves and fruits exhibiting disease symptoms ranging from greasy spot, yellow spot, small or large brown spot, black dot, and brown dot were sampled from Fujian, Guangdong, Guizhou, Hunan, Jiangxi, Yunnan, Zhejiang provinces and the Guangxi Zhuang Autonomous Region in China. In total 82 isolates representing various cercosporoid genera were isolated from these disease symptoms, which were supplemented with eight Citrus cercosporoid isolates collected from other countries. Based on a morphological and phylogenetic study using sequence data from the nuclear ribosomal DNA's ITS1-5.8S-ITS2 regions (ITS), and partial actin (act), β-tubulin (tub2), 28S nuclear ribosomal RNA (28S rDNA) and translation elongation factor 1-α (tef1) genes, these strains were placed in the following genera: Cercospora, Pallidocercospora, Passalora, Pseudocercospora, Verrucisporota and Zasmidium. All isolates tended to be sterile, except the Zasmidium isolates associated with citrus greasy spot-like symptoms, which subsequently were compared with phylogenetically similar isolates occurring on Citrus and other hosts elsewhere. From these results four Zasmidium species were recognized on Citrus, namely Z. indonesianum on Citrus in Indonesia, Z. fructicola and Z. fructigenum on Citrus in China and Z. citri-griseum, which appears to have a wide host range including Acacia, Citrus, Eucalyptus and Musa, as well as a global distribution.
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Abstract
The ascomycete family Nectriaceae (Hypocreales) includes numerous important plant and human pathogens, as well as several species used extensively in industrial and commercial applications as biodegraders and biocontrol agents. Members of the family are unified by phenotypic characters such as uniloculate ascomata that are yellow, orange-red to purple, and with phialidic asexual morphs. The generic concepts in Nectriaceae are poorly defined, since DNA sequence data have not been available for many of these genera. To address this issue we performed a multi-gene phylogenetic analysis using partial sequences for the 28S large subunit (LSU) nrDNA, the internal transcribed spacer region and intervening 5.8S nrRNA gene (ITS), the large subunit of the ATP citrate lyase (acl1), the RNA polymerase II largest subunit (rpb1), RNA polymerase II second largest subunit (rpb2), α-actin (act), β-tubulin (tub2), calmodulin (cmdA), histone H3 (his3), and translation elongation factor 1-alpha (tef1) gene regions for available type and authentic strains representing known genera in Nectriaceae, including several genera for which no sequence data were previously available. Supported by morphological observations, the data resolved 47 genera in the Nectriaceae. We re-evaluated the status of several genera, which resulted in the introduction of six new genera to accommodate species that were initially classified based solely on morphological characters. Several generic names are proposed for synonymy based on the abolishment of dual nomenclature. Additionally, a new family is introduced for two genera that were previously accommodated in the Nectriaceae.
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Key Words
- A. submerse (H.J. Huds.) L. Lombard & Crous
- Aquanectria L. Lombard & Crous
- Aquanectria penicillioides (Ingold) L. Lombard & Crous
- B. delphinoides (Schroers, Summerbell, O'Donnell & Lampr.) L. Lombard & Crous
- B. dimerum (Penz.) L. Lombard & Crous
- B. domesticum (Fr.) L. Lombard & Crous
- B. lunatum (Ellis & Everh.) L. Lombard & Crous
- B. nectrioides (Wollenw.) L. Lombard & Crous
- B. penzigii (Schroers, Summerbell & O'Donnell) L. Lombard & Crous
- Bisifusarium L. Lombard, Crous & W. Gams
- Bisifusarium biseptatum (Schroers, Summerbell & O'Donnell) L. Lombard & Crous
- C. aurantia (Penz. & Sacc.) Rossman, L. Lombard & Crous
- C. blumenaviae (Rehm) Rossman, L. Lombard & Crous
- C. cylindrospora (Ellis & Everh.) Rossman, L. Lombard & Crous
- C. gibberosa (Schroers) Rossman, L. Lombard & Crous
- C. manihotis (Rick) Rossman, L. Lombard & Crous
- C. parva (Schroers) Rossman, L. Lombard & Crous
- C. rusci (Lechat, Gardiennet & J. Fourn.) L. Lombard & Crous
- C. tonduzii (Speg.) Rossman, L. Lombard & Crous
- C. tornata (Höhn.) Rossman, L. Lombard & Crous
- Calonectria candelabra (Viégas) Rossman, L. Lombard & Crous
- Clonostachys apocyni (Peck) Rossman, L. Lombard & Crous
- Coccinonectria L. Lombard & Crous
- Coccinonectria pachysandricola (B.O. Dodge) L. Lombard & Crous
- Generic concepts
- Hydropisphaera fusigera (Berk. & Broome) Rossman, L. Lombard & Crous
- I. macroconidialis (Brayford & Samuels) Rossman, L. Lombard & Crous, Mariannaea catenulatae (Samuels) L. Lombard & Crous
- Ilyonectria destructans (Zinssm.) Rossman, L. Lombard & Crous
- Mariannaea humicola L. Lombard & Crous
- Mariannaea pinicola L. Lombard & Crous
- N. falciformis (Carrión) L. Lombard & Crous
- N. illudens (Berk.) L. Lombard & Crous
- N. ipomoeae (Halst.) L. Lombard & Crous
- N. monilifera (Berk. & Broome) L. Lombard & Crous
- N. phaseoli (Burkh.) L. Lombard & Crous
- N. plagianthi (Dingley) L. Lombard & Crous
- N. ramosa (Bat. & H. Maia) L. Lombard & Crous
- N. solani (Mart.) L. Lombard & Crous
- N. termitum (Höhn.) L. Lombard & Crous
- N. tucumaniae (T. Aoki, O'Donnell, Yos. Homma & Lattanzi) L. Lombard & Crous
- N. virguliformis (O'Donnell & T. Aoki) L. Lombard & Crous
- Nectriaceae
- Nectriopsis rexiana (Sacc.) Rossman, L. Lombard & Crous
- Neocosmospora ambrosia (Gadd & Loos) L. Lombard & Crous
- Neocosmospora rubicola L. Lombard & Crous
- Neonectria candida (Ehrenb.) Rossman, L. Lombard & Crous
- P. contagium L. Lombard & Crous
- Paracremonium L. Lombard & Crous
- Paracremonium inflatum L. Lombard & Crous
- Penicillifer diparietisporus (J.H. Miller, Giddens & A.A. Foster) Rossman, L. Lombard & Crous
- Phylogeny
- Pseudonectria foliicola L. Lombard & Crous
- Rectifusarium L. Lombard, Crous & W. Gams
- Rectifusarium robinianum L. Lombard & Crous
- Rectifusarium ventricosum (Appel & Wollenw.) L. Lombard & Crous
- Rectifusarium ventricosum Appel & Wollenw.
- S. aurifila (W.R. Gerard) Rossman, L. Lombard & Crous
- S. mammiforme (Chardón) L. Lombard & Crous
- S. oblongisporum (Y. Nong & W.Y. Zhuang) L. Lombard & Crous
- S. raripilum (Penz. & Sacc.) L. Lombard & Crous
- Sarcopodium flavolanatum (Berk. & Broome) L. Lombard & Crous
- Sphaerostilbella penicillioides (Corda) Rossman, L. Lombard & Crous
- Taxonomy
- Tilachlidiaceae L. Lombard & Crous
- Volutella asiana (J. Luo, X.M. Zhang & W.Y. Zhuang) L. Lombard & Crous
- Xenoacremonium L. Lombard & Crous
- Xenoacremonium falcatus L. Lombard & Crous
- Xenoacremonium recifei (Leão & Lôbo) L. Lombard & Crous
- Xenogliocladiopsis cypellocarpa L. Lombard & Crous
- Xenogliocladiopsis eucalyptorum Crous & W.B. Kendr.
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Wikee S, Lombard L, Nakashima C, Motohashi K, Chukeatirote E, Cheewangkoon R, McKenzie EHC, Hyde KD, Crous PW. A phylogenetic re-evaluation of Phyllosticta (Botryosphaeriales). Stud Mycol 2013; 76:1-29. [PMID: 24302788 PMCID: PMC3825230 DOI: 10.3114/sim0019] [Citation(s) in RCA: 79] [Impact Index Per Article: 7.2] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 12/03/2022] Open
Abstract
Phyllosticta is a geographically widespread genus of plant pathogenic fungi with a diverse host range. This study redefines Phyllosticta, and shows that it clusters sister to the Botryosphaeriaceae (Botryosphaeriales, Dothideomycetes), for which the older family name Phyllostictaceae is resurrected. In moving to a unit nomenclature for fungi, the generic name Phyllosticta was chosen over Guignardia in previous studies, an approach that we support here. We use a multigene DNA dataset of the ITS, LSU, ACT, TEF and GPDH gene regions to investigate 129 isolates of Phyllosticta, representing about 170 species names, many of which are shown to be synonyms of the ubiquitous endophyte P. capitalensis. Based on the data generated here, 12 new species are introduced, while epitype and neotype specimens are designated for a further seven species. One species of interest is P. citrimaxima associated with tan spot of Citrus maxima fruit in Thailand, which adds a fifth species to the citrus black spot complex. Previous morphological studies lumped many taxa under single names that represent complexes. In spite of this Phyllosticta is a species-rich genus, and many of these taxa need to be recollected in order to resolve their phylogeny and taxonomy.
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Slippers B, Boissin E, Phillips AJL, Groenewald JZ, Lombard L, Wingfield MJ, Postma A, Burgess T, Crous PW. Phylogenetic lineages in the Botryosphaeriales: a systematic and evolutionary framework. Stud Mycol 2013; 76:31-49. [PMID: 24302789 PMCID: PMC3825231 DOI: 10.3114/sim0020] [Citation(s) in RCA: 129] [Impact Index Per Article: 11.7] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 11/23/2022] Open
Abstract
The order Botryosphaeriales represents several ecologically diverse fungal families that are commonly isolated as endophytes or pathogens from various woody hosts. The taxonomy of members of this order has been strongly influenced by sequence-based phylogenetics, and the abandonment of dual nomenclature. In this study, the phylogenetic relationships of the genera known from culture are evaluated based on DNA sequence data for six loci (SSU, LSU, ITS, EF1, BT, mtSSU). The results make it possible to recognise a total of six families. Other than the Botryosphaeriaceae (17 genera), Phyllostictaceae (Phyllosticta) and Planistromellaceae (Kellermania), newly introduced families include Aplosporellaceae (Aplosporella and Bagnisiella), Melanopsaceae (Melanops), and Saccharataceae (Saccharata). Furthermore, the evolution of morphological characters in the Botryosphaeriaceae were investigated via analysis of phylogeny-trait association. None of the traits presented a significant phylogenetic signal, suggesting that conidial and ascospore pigmentation, septation and appendages evolved more than once in the family. Molecular clock dating on radiations within the Botryosphaeriales based on estimated mutation rates of the rDNA SSU locus, suggests that the order originated in the Cretaceous period around 103 (45-188) mya, with most of the diversification in the Tertiary period. This coincides with important periods of radiation and spread of the main group of plants that these fungi infect, namely woody Angiosperms. The resulting host-associations and distribution could have influenced the diversification of these fungi.
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de Gruyter J, Woudenberg JHC, Aveskamp MM, Verkley GJM, Groenewald JZ, Crous PW. Redisposition of phoma-like anamorphs in Pleosporales. Stud Mycol 2013; 75:1-36. [PMID: 24014897 PMCID: PMC3713885 DOI: 10.3114/sim0004] [Citation(s) in RCA: 189] [Impact Index Per Article: 17.2] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 11/07/2022] Open
Abstract
UNLABELLED The anamorphic genus Phoma was subdivided into nine sections based on morphological characters, and included teleomorphs in Didymella, Leptosphaeria, Pleospora and Mycosphaerella, suggesting the polyphyly of the genus. Recent molecular, phylogenetic studies led to the conclusion that Phoma should be restricted to Didymellaceae. The present study focuses on the taxonomy of excluded Phoma species, currently classified in Phoma sections Plenodomus, Heterospora and Pilosa. Species of Leptosphaeria and Phoma section Plenodomus are reclassified in Plenodomus, Subplenodomus gen. nov., Leptosphaeria and Paraleptosphaeria gen. nov., based on the phylogeny determined by analysis of sequence data of the large subunit 28S nrDNA (LSU) and Internal Transcribed Spacer regions 1 & 2 and 5.8S nrDNA (ITS). Phoma heteromorphospora, type species of Phoma section Heterospora, and its allied species Phoma dimorphospora, are transferred to the genus Heterospora stat. nov. The Phoma acuta complex (teleomorph Leptosphaeria doliolum), is revised based on a multilocus sequence analysis of the LSU, ITS, small subunit 18S nrDNA (SSU), β-tubulin (TUB), and chitin synthase 1 (CHS-1) regions. Species of Phoma section Pilosa and allied Ascochyta species were determined to belong to Pleosporaceae based on analysis of actin (ACT) sequence data. Anamorphs that are similar morphologically to Phoma and described in Ascochyta, Asteromella, Coniothyrium, Plectophomella, Pleurophoma and Pyrenochaeta are included in this study. Phoma-like species, which grouped outside the Pleosporineae based on a LSU sequence analysis, are transferred to the genera Aposphaeria, Paraconiothyrium and Westerdykella. The genera Medicopsis gen. nov. and Nigrograna gen. nov. are introduced to accommodate the medically important species formerly known as Pyrenochaeta romeroi and Pyrenochaeta mackinnonii, respectively. TAXONOMIC NOVELTIES New genera: Medicopsis Gruyter, Verkley & Crous, Nigrograna Gruyter, Verkley & Crous, Paraleptosphaeria Gruyter, Verkley & Crous, Subplenodomus Gruyter, Verkley & Crous. New species: Aposphaeria corallinolutea Gruyter, Aveskamp & Verkley, Paraconiothyrium maculicutis Verkley & Gruyter. New combinations: Coniothyrium carteri (Gruyter & Boerema) Verkley & Gruyter, C. dolichi (Mohanty) Verkley & Gruyter, C. glycines (R.B. Stewart) Verkley & Gruyter, C. multiporum (V.H. Pawar, P.N. Mathur & Thirum.) Verkley & Gruyter, C. telephii (Allesch.) Verkley & Gruyter, Heterospora (Boerema, Gruyter & Noordel.) Gruyter, Verkley & Crous, H. chenopodii (Westend.) Gruyter, Aveskamp & Verkley, H. dimorphospora (Speg.) Gruyter, Aveskamp & Verkley, Leptosphaeria errabunda (Desm.) Gruyter, Aveskamp & Verkley, L. etheridgei (L.J. Hutchison & Y. Hirats.) Gruyter, Aveskamp & Verkley, L. macrocapsa (Trail) Gruyter, Aveskamp & Verkley, L. pedicularis (Fuckel) Gruyter, Aveskamp & Verkley, L. rubefaciens (Togliani) Gruyter, Aveskamp & Verkley, L. sclerotioides (Sacc.) Gruyter, Aveskamp & Verkley, L. sydowii (Boerema, Kesteren & Loer.) Gruyter, Aveskamp & Verkley, L. veronicae (Hollós) Gruyter, Aveskamp & Verkley, Medicopsis romeroi (Borelli) Gruyter, Verkley & Crous, Nigrograna mackinnonii (Borelli) Gruyter, Verkley & Crous, Paraconiothyrium flavescens (Gruyter, Noordel. & Boerema) Verkley & Gruyter, Paracon. fuckelii (Sacc.) Verkley & Gruyter, Paracon. fusco-maculans (Sacc.) Verkley & Gruyter, Paracon. lini (Pass.) Verkley & Gruyter, Paracon. tiliae (F. Rudolphi) Verkley & Gruyter, Paraleptosphaeria dryadis (Johanson) Gruyter, Aveskamp & Verkley, Paralept. macrospora (Thüm.) Gruyter, Aveskamp & Verkley, Paralept. nitschkei (Rehm ex G. Winter) Gruyter, Aveskamp & Verkley, Paralept. orobanches (Schweinitz: Fr.) Gruyter, Aveskamp & Verkley, Paralept. praetermissa (P. Karst.) Gruyter, Aveskamp & Verkley, Plenodomus agnitus (Desm.) Gruyter, Aveskamp & Verkley, Plen. biglobosus (Shoemaker & H. Brun) Gruyter, Aveskamp & Verkley, Plen. chrysanthemi (Zachos, Constantinou & Panag.) Gruyter, Aveskamp & Verkley, Plen. collinsoniae (Dearn. & House) Gruyter, Aveskamp & Verkley, Plen. confertus (Niessl ex Sacc.) Gruyter, Aveskamp & Verkley, Plen. congestus (M.T. Lucas) Gruyter, Aveskamp & Verkley, Plen. enteroleucus (Sacc.) Gruyter, Aveskamp & Verkley, Plen. fallaciosus (Berl.) Gruyter, Aveskamp & Verkley, Plen. hendersoniae (Fuckel) Gruyter, Aveskamp & Verkley, Plen. influorescens (Boerema & Loer.) Gruyter, Aveskamp & Verkley, Plen. libanotidis (Fuckel) Gruyter, Aveskamp & Verkley, Plen. lindquistii (Frezzi) Gruyter, Aveskamp & Verkley, Plen. lupini (Ellis & Everh.) Gruyter, Aveskamp & Verkley, Plen. pimpinellae (Lowen & Sivan.) Gruyter, Aveskamp & Verkley, Plen. tracheiphilus (Petri) Gruyter, Aveskamp & Verkley, Plen. visci (Moesz) Gruyter, Aveskamp & Verkley, Pleospora fallens (Sacc.) Gruyter & Verkley, Pleo. flavigena (Constantinou & Aa) Gruyter & Verkley, Pleo. incompta (Sacc. & Martelli) Gruyter & Verkley, Pyrenochaetopsis pratorum (P.R. Johnst. & Boerema) Gruyter, Aveskamp & Verkley, Subplenodomus apiicola (Kleb.) Gruyter, Aveskamp & Verkley, Subplen. drobnjacensis (Bubák) Gruyter, Aveskamp & Verkley, Subplen. valerianae (Henn.) Gruyter, Aveskamp & Verkley, Subplen. violicola (P. Syd.) Gruyter, Aveskamp & Verkley, Westerdykella capitulum (V.H. Pawar, P.N. Mathur & Thirum.) de Gruyter, Aveskamp & Verkley, W. minutispora (P.N. Mathur ex Gruyter & Noordel.) Gruyter, Aveskamp & Verkley. New names: Pleospora angustis Gruyter & Verkley, Pleospora halimiones Gruyter & Verkley.
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Abstract
Alternaria is a ubiquitous fungal genus that includes saprobic, endophytic and pathogenic species associated with a wide variety of substrates. In recent years, DNA-based studies revealed multiple non-monophyletic genera within the Alternaria complex, and Alternaria species clades that do not always correlate to species-groups based on morphological characteristics. The Alternaria complex currently comprises nine genera and eight Alternaria sections. The aim of this study was to delineate phylogenetic lineages within Alternaria and allied genera based on nucleotide sequence data of parts of the 18S nrDNA, 28S nrDNA, ITS, GAPDH, RPB2 and TEF1-alpha gene regions. Our data reveal a Pleospora/Stemphylium clade sister to Embellisia annulata, and a well-supported Alternaria clade. The Alternaria clade contains 24 internal clades and six monotypic lineages, the assemblage of which we recognise as Alternaria. This puts the genera Allewia, Brachycladium, Chalastospora, Chmelia, Crivellia, Embellisia, Lewia, Nimbya, Sinomyces, Teretispora, Ulocladium, Undifilum and Ybotromyces in synonymy with Alternaria. In this study, we treat the 24 internal clades in the Alternaria complex as sections, which is a continuation of a recent proposal for the taxonomic treatment of lineages in Alternaria. Embellisia annulata is synonymised with Dendryphiella salina, and together with Dendryphiella arenariae, are placed in the new genus Paradendryphiella. The sexual genera Clathrospora and Comoclathris, which were previously associated with Alternaria, cluster within the Pleosporaceae, outside Alternaria s. str., whereas Alternariaster, a genus formerly seen as part of Alternaria, clusters within the Leptosphaeriaceae. Paradendryphiella is newly described, the generic circumscription of Alternaria is emended, and 32 new combinations and 10 new names are proposed. A further 10 names are resurrected, while descriptions are provided for 16 new Alternaria sections.
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Verkley GJM, Quaedvlieg W, Shin HD, Crous PW. A new approach to species delimitation in Septoria. Stud Mycol 2013; 75:213-305. [PMID: 24014901 PMCID: PMC3713889 DOI: 10.3114/sim0018] [Citation(s) in RCA: 69] [Impact Index Per Article: 6.3] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 11/07/2022] Open
Abstract
Septoria is a large genus of asexual morphs of Ascomycota causing leaf spot diseases of many cultivated and wild plants. Host specificity has long been a decisive criterium in species delimitation in Septoria, mainly because of the paucity of useful morphological characters and the high level of variation therein. This study aimed at improving the species delimitation of Septoria by adopting a polyphasic approach, including multilocus DNA sequencing and morphological analyses on the natural substrate and in culture. To this end 365 cultures preserved in CBS, Utrecht, The Netherlands, among which many new isolates obtained from fresh field specimens were sequenced. Herbarium material including many types was also studied. Full descriptions of the morphology in planta and in vitro are provided for 57 species. DNA sequences were generated for seven loci, viz. nuclear ITS and (partial) LSU ribosomal RNA genes, RPB2, actin, calmodulin, Btub, and EF. The robust phylogeny inferred showed that the septoria-like fungi are distributed over three main clades, establishing the genera Septoria s. str., Sphaerulina, and Caryophylloseptoria gen. nov. Nine new combinations and one species, Sphaerulina tirolensis sp. nov. were proposed. It is demonstrated that some species have wider host ranges than expected, including hosts from more than one family. Septoria protearum, previously only associated with Proteaceae was found to be also associated with host plants from six additional families of phanerogams and cryptogams. To our knowledge this is the first study to provide DNA-based evidence that multiple family-associations occur for a single species in Septoria. The distribution of host families over the phylogenetic tree showed a highly dispersed pattern for 10 host plant families, providing new insight into the evolution of these fungi. It is concluded that trans-family host jumping is a major force driving the evolution of Septoria and Sphaerulina.
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Groenewald JZ, Nakashima C, Nishikawa J, Shin HD, Park JH, Jama AN, Groenewald M, Braun U, Crous PW. Species concepts in Cercospora: spotting the weeds among the roses. Stud Mycol 2013; 75:115-70. [PMID: 24014899 PMCID: PMC3713887 DOI: 10.3114/sim0012] [Citation(s) in RCA: 180] [Impact Index Per Article: 16.4] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 11/24/2022] Open
Abstract
The genus Cercospora contains numerous important plant pathogenic fungi from a diverse range of hosts. Most species of Cercospora are known only from their morphological characters in vivo. Although the genus contains more than 5 000 names, very few cultures and associated DNA sequence data are available. In this study, 360 Cercospora isolates, obtained from 161 host species, 49 host families and 39 countries, were used to compile a molecular phylogeny. Partial sequences were derived from the internal transcribed spacer regions and intervening 5.8S nrRNA, actin, calmodulin, histone H3 and translation elongation factor 1-alpha genes. The resulting phylogenetic clades were evaluated for application of existing species names and five novel species are introduced. Eleven species are epi-, lecto- or neotypified in this study. Although existing species names were available for several clades, it was not always possible to apply North American or European names to African or Asian strains and vice versa. Some species were found to be limited to a specific host genus, whereas others were isolated from a wide host range. No single locus was found to be the ideal DNA barcode gene for the genus, and species identification needs to be based on a combination of gene loci and morphological characters. Additional primers were developed to supplement those previously published for amplification of the loci used in this study.
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Mirabolfathy M, Ahangaran Y, Lombard L, Crous PW. Leaf Blight of Buxus sempervirens in Northern Forests of Iran Caused by Calonectria pseudonaviculata. PLANT DISEASE 2013; 97:1121. [PMID: 30722506 DOI: 10.1094/pdis-03-13-0237-pdn] [Citation(s) in RCA: 6] [Impact Index Per Article: 0.5] [Reference Citation Analysis] [Abstract] [Track Full Text] [Subscribe] [Scholar Register] [Indexed: 06/09/2023]
Abstract
Buxus sempervirens subsp. hyrcana (Pojark.) Takht. (boxwood) is an evergreen shrub/tree in Caspian hyrcanian forests covering the Alborz mountain range of northern Iran. During the summer of 2012, a sudden leaf and twig blight disease of boxwood was observed throughout the northern forests of Iran. Disease symptoms included circular dark spots on leaves leading to defoliation, and longitudinal brown-black streaks on the shoots. Diseased plant material was collected from the Guilan and Mazandaran areas, placed in moist chambers, and incubated at 20°C to induce sporulation. Single conidia were plated onto half-strength potato dextrose agar supplemented with 250 mg/L streptomycin and incubated at 25°C under near-ultraviolet light. Isolates were transferred to carnation leaf agar and incubated at 25°C under near-ultraviolet for morphological characterization, and representative isolates were deposited into the culture collection of the CBS-KNAW Fungal Biodiversity Centre under accession numbers CBS 134431 and CBS 134432. Gross morphological characters were determined by mounting fungal structures in lactic acid and 50 measurements at 1,000× magnification were made for all taxonomically informative characters. The observed macroconidiophores consisted of a stipe bearing a penicillate suite of reproductive branches and a stipe extension, terminating in a naviculate vesicle. The stipe extensions were septate, hyaline (85 to 160 × 2 to 4 μm), terminating in a naviculate vesicle, 6 to 11 μm in diam. Conidia were cylindrical, rounded at both ends, straight, with one septum (55 to 68 × 4 to 6 μm). These morphological observations agreed to those provided for C. pseudonaviculata Lombard, M. J. Wingf. & Crous (1,2). To confirm morphological identification, DNA sequence data were generated for the ITS1-5.8S-ITS2 region of the rDNA, and a fragment of the translation elongation factor 1-alpha gene region (3). These sequences were compared to other sequences of C. pseudonaviculata in GenBank (100% similarity for both loci), which confirmed the morphological observations. Sequences were submitted to GenBank under the accession numbers KC736850 and KC736851 for ITS, and KC736852 and KC736853 for TEF. Koch's postulates were proven by spraying a 3 × 106 conidia/ml conidial suspension of isolate CBS 134431 onto 1-year-old B. sempervirens subsp. hyrcana plants until run-off, and covering them for 24 h with a plastic bag to maintain high humidity. Control plants were sprayed with sterile water. Ten plants were used for each treatment and maintained in a greenhouse at 20 to 22°C with 95% relative humidity. Symptoms similar to those observed in nature developed within 4 days of inoculation and the test fungus was successfully reisolated from the inoculated plants. No symptoms were observed on the control plants. Boxwood blight caused by C. pseudonaviculata, was first reported in the United Kingdom in the mid-1990s and has since become widespread, causing epidemics globally (1,2,4). To our knowledge, this study represents the first report of boxwood blight in its native environment and in Iran. References: (1) P. W. Crous et al. Sydowia 54:23, 2002. (2) B. Henricot and A. Culham. Mycologia 94:980, 2002. (3) L. Lombard et al. Stud. Mycol. 66:31, 2010. (4) M. R. Saracchi et al. J. Plant Pathol. 90:581, 2009.
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Serrato-Diaz LM, Latoni-Brailowsky EI, Rivera-Vargas LI, Goenaga R, Crous PW, French-Monar RD. First Report of Calonectria hongkongensis Causing Fruit Rot of Rambutan (Nephelium lappaceum). PLANT DISEASE 2013; 97:1117. [PMID: 30722508 DOI: 10.1094/pdis-01-13-0008-pdn] [Citation(s) in RCA: 1] [Impact Index Per Article: 0.1] [Reference Citation Analysis] [Abstract] [Track Full Text] [Subscribe] [Scholar Register] [Indexed: 06/09/2023]
Abstract
Fruit rot of rambutan is a pre- and post-harvest disease problem of rambutan orchards. In 2011, fruit rot was observed at USDA-ARS orchards in Mayaguez, Puerto Rico. Infected fruit were collected and 1 mm2 tissue sections were surface disinfested with 70% ethanol followed by 0.5% sodium hypochlorite. Infected fruit were rinsed with sterile, deionized, double-distilled water and transferred to acidified potato dextrose agar (APDA). Plates were incubated at 25 ± 1°C for 6 days. Three isolates of Calonectria hongkongensis (Cah), CBS134083, CBS134084, and CBS134085, were identified morphologically using taxonomic keys (2,3). In APDA, colonies of Cah produced raw sienna to rust-colored aerial mycelial growth. Conidiophores of Cah had a penicillate arrangement of primary to quaternary branches of 2 to 6 phialides. Conidia (n = 50) were cylindrical, hyaline, 1-septate, rounded at both ends, and 44 to 52 μm × 3.5 to 4.5 μm. Conidiophores produced terminal and lateral stipe extensions with terminal sphaeropedunculate vesicles that were 8 to 12 μm wide. Subglobose to ovoid perithecia, 300 to 500 μm × 200 to 350 μm and orange to red-brown, were produced in groups of 3. Asci were clavate and contained 8 ascospores aggregated at the top of the ascus. Ascospores (n = 50) were hyaline, guttulate, fusoid with rounded ends, straight to curved, 1-septate with constriction at the septum, and 28 to 36 μm × 4 to 7 μm. For molecular identification, the ITS rDNA, fragments of β-tubulin (BT), histone H3 (HIS3), and elongation factor (EF1-α) genes were amplified by PCR, sequenced, and compared using BLASTn with Calonectria spp. submitted to the NCBI GenBank. The sequences of Cah submitted to GenBank include accessions KC342208, KC342206, and KC342207 for ITS; KC342217, KC342215, and KC342216 for BT; KC342211, KC342209, and KC342210 for HIS3; and KC342214, KC342212, and KC342213 for EF1α. The sequences were >99% or identical with the ex-type specimen of Cah CBS 114828 for all genes used. Pathogenicity tests were conducted on 5 healthy superficially sterilized fruits per isolate. Both scalpel-wounded and unwounded fruit tissues were inoculated with 5-mm mycelial disks from 8-day-old pure cultures grown in APDA. Untreated controls were inoculated with APDA disks only. Fruits were kept in a humid chamber for 8 days at 25°C under 12 h of fluorescent light. The test was repeated once. Three days after inoculation (DAI), white mycelial growth was observed on the fruit. Five DAI, the fruit changed color from red to brown and yellowish mycelia colonized 50 to 62% of the fruit surface. Eight DAI, all the fruit turned brown, the mycelium growth covered the entire fruit, and conidiophores were produced on spinterns (hairlike appendages). Fruit rot of spinterns, exocarp (skin), endocarp (aril), and light brown discoloration were observed inside the fruit. Untreated controls showed no symptoms of fruit rot and no fungi were reisolated from tissue. Cah was reisolated from diseased tissue, fulfilling Koch's postulates. Calonectria spp. (or their Cylindrocladium asexual states) have been associated with lychee decline syndrome in North Vietnam (1). Both fruits belong to the Sapindaceae family. To our knowledge, this is the first report of Cah causing fruit rot of rambutan. References: (1) L. M. Coates et al. Diseases of Longan, Lychee and Rambutan. Pages 307-325 in: Diseases of Tropical Fruit Crops. R. C. Ploetz, ed. CABI Publishing, Cambridge, MA, 2003. (2) P. W. Crous. Taxonomy and Pathology of Cylindrocladium (Calonectria) and Allied Genera. APS Press, St Paul, MN, 2002. (3) P. W. Crous, et al. Stud. Mycol. 50:415, 2004.
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Wingfield MJ, Crous PW, Coutinho TA. A serious canker disease of Eucalyptus in South Africa caused by a new species of Coniothyrium. Mycopathologia 2012; 136:139-45. [PMID: 20882461 DOI: 10.1007/bf00438919] [Citation(s) in RCA: 40] [Impact Index Per Article: 3.3] [Reference Citation Analysis] [Abstract] [Track Full Text] [Journal Information] [Subscribe] [Scholar Register] [Received: 06/20/1996] [Accepted: 04/23/1997] [Indexed: 10/26/2022]
Abstract
Eucalyptus spp. are being propagated extensively as exotics in plantations in South Africa, and many other parts of the world. In South Africa, a number of diseases result in serious losses to this resource. This paper describes a new and very damaging stem canker disease, which has recently appeared on plantation-grown eucalyptus in South Africa. The disease, first noted in an isolated location in Zululand is now common in other parts of the country, and is typified by discrete necrotic lesions on stems. These lesions coalesce to form large, gum-impregnated cankers and malformed stems. The causal agent of the disease, as inferred from pathogenicity tests, is a new species of Coniothyrium described here as C. zuluense. This fungus is a serious impediment to eucalypt propagation in South Africa, and is most likely a threat to similar forest industries elsewhere in the world.
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Mirabolfathy M, Groenewald JZ, Crous PW. First Report of Pilidiella granati Causing Dieback and Fruit Rot of Pomegranate (Punica granatum) in Iran. PLANT DISEASE 2012; 96:461. [PMID: 30727099 DOI: 10.1094/pdis-10-11-0887] [Citation(s) in RCA: 11] [Impact Index Per Article: 0.9] [Reference Citation Analysis] [Abstract] [Track Full Text] [Subscribe] [Scholar Register] [Indexed: 06/09/2023]
Abstract
Iran is the largest producer of pomegranate (Punica granatum) in the world, with more than 60,000 ha currently in production. In the spring of 2011, a decline and dieback of young pomegranate trees (7 to 10 years old) were observed in the Kheir area of Fars Province. Dieback and twig blight developed toward the lower part of the stem, resulting in death of aerial tree parts and growing suckers from roots. Surface-disinfected tissues of diseased plants were plated on potato dextrose agar (PDA) and malt extract agar media. Isolates were separated into two groups that had either pale green or white aerial mycelia and sporulated after 5 to 7 days at 25°C. Pycnidia were globose and black with thin, membranous, pseudoparenchymatic walls, 80 to 140 μm in diameter. Conidia were hyaline, one-celled, elongate to fusiform, straight, and 11 to 17 × 4 to 6 μm (average 14 × 4.7 μm). Cardinal minimum growth temperatures were 8 to 10°C, optimum at 27 to 30°C, and maximum at 35°C. Radial growth rate at 30°C was 8 to 9 mm per day. Representative isolates were deposited in the CBS-KNAW Fungal Biodiversity Centre, the Netherlands (CPC 19625 = CBS 130974 and CPC 19626 = CBS 130975; GenBank JN815312 and JN815313, respectively). Genomic DNA was extracted with the UltraClean Microbial DNA Isolation Kit (MoBio Laboratories, Inc., Solana Beach, CA) and the internal transcribed spacer (ITS) region of the nrDNA operon of two isolates were sequenced as described previously (1). On the basis of morphology (3), the causal organism was identified as Pilidiella granati Sacc. This identification was corroborated by the ITS sequence data, which was identical for both colony types to GenBank HQ166057 (identities = 614 of 614 [100%]). Pathogenicity tests were conducted using two representative isolates from each group on 5-month-old P. granatum trees with 10 replicates under greenhouse conditions; 5-mm mycelial plugs from the edge of 7-day-old colonies on PDA were placed under the bark of twig wounds. Uncolonized PDA plugs were used as noninoculated controls. Pathogenicity was also tested on nonwounded fruit by placing colonized 5-mm-diameter mycelial plugs on surface-disinfected pomegranate fruits; noncolonized PDA plugs were used as controls. All treated fruit were placed in plastic bags and maintained at 25°C for 10 days. Isolates were found to be pathogenic on twigs after 2 months, giving rise to brown lesions that were 2 to 5 cm long. No lesions were observed on the controls. Furthermore, the fungus was reisolated from all infected tissues, satisfying Koch's postulates. On pomegranate fruit, the fungus colonized the fruit after 5 to 8 days, followed by the appearance of fruit rot symptoms leading to the formation of abundant pycnidia covering the skin after 10 days. No decay was observed in control inoculations. Pilidiella granati has previously been reported as a pathogen of P. granatum fruit from Europe, Asia, and the United States (2). To our knowledge, this is the first report of this pathogen causing dieback and fruit rot of pomegranate in Iran. References: (1) J. Frank et al. Persoonia 24:93, 2010. (2) L. Palou et al. Online publication. doi:10.5197/j.2044.0588.2010.022.021. New Dis. Rep. 22:21, 2010. (3) J. M. Van Niekerk et al. Mycol. Res. 108:283, 2004.
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Ruibal C, Gueidan C, Selbmann L, Gorbushina AA, Crous PW, Groenewald JZ, Muggia L, Grube M, Isola D, Schoch CL, Staley JT, Lutzoni F, de Hoog GS. Phylogeny of rock-inhabiting fungi related to Dothideomycetes. Stud Mycol 2011; 64:123-133S7. [PMID: 20169026 PMCID: PMC2816969 DOI: 10.3114/sim.2009.64.06] [Citation(s) in RCA: 129] [Impact Index Per Article: 9.9] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 11/10/2022] Open
Abstract
The class Dothideomycetes (along with Eurotiomycetes)
includes numerous rock-inhabiting fungi (RIF), a group of ascomycetes that
tolerates surprisingly well harsh conditions prevailing on rock surfaces.
Despite their convergent morphology and physiology, RIF are phylogenetically
highly diverse in Dothideomycetes. However, the positions of main
groups of RIF in this class remain unclear due to the lack of a strong
phylogenetic framework. Moreover, connections between rock-dwelling habit and
other lifestyles found in Dothideomycetes such as plant pathogens,
saprobes and lichen-forming fungi are still unexplored. Based on multigene
phylogenetic analyses, we report that RIF belong to Capnodiales
(particularly to the family Teratosphaeriaceae s.l.),
Dothideales, Pleosporales, and Myriangiales, as
well as some uncharacterised groups with affinities to
Dothideomycetes. Moreover, one lineage consisting exclusively of RIF
proved to be closely related to Arthoniomycetes, the sister class of
Dothideomycetes. The broad phylogenetic amplitude of RIF in
Dothideomycetes suggests that total species richness in this class
remains underestimated. Composition of some RIF-rich lineages suggests that
rock surfaces are reservoirs for plant-associated fungi or saprobes, although
other data also agree with rocks as a primary substrate for ancient fungal
lineages. According to the current sampling, long distance dispersal seems to
be common for RIF. Dothideomycetes lineages comprising lichens also
include RIF, suggesting a possible link between rock-dwelling habit and
lichenisation.
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Crous PW, Braun U, Schubert K, Groenewald JZ. Delimiting Cladosporium from morphologically similar genera. Stud Mycol 2011; 58:33-56. [PMID: 18490995 PMCID: PMC2104746 DOI: 10.3114/sim.2007.58.02] [Citation(s) in RCA: 128] [Impact Index Per Article: 9.8] [Reference Citation Analysis] [Abstract] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 12/21/2022] Open
Abstract
The genus Cladosporium is restricted to dematiaceous hyphomycetes
with a coronate scar type, and Davidiella teleomorphs. In the present
study numerous cladosporium-like taxa are treated, and allocated to different
genera based on their morphology and DNA phylogeny derived from the LSU nrRNA
gene. Several species are introduced in new genera such as
Hyalodendriella, Ochrocladosporium, Rachicladosporium,
Rhizocladosporium, Toxicocladosporium and
Verrucocladosporium. A further new taxon is described in
Devriesia (Teratosphaeriaceae). Furthermore, Cladosporium
castellanii, the etiological agent of tinea nigra in humans, is
confirmed as synonym of Stenella araguata, while the type species of
Stenella is shown to be linked to the Teratosphaeriaceae
(Capnodiales), and not the Mycosphaerellaceae as formerly
presumed.
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Arzanlou M, Groenewald JZ, Gams W, Braun U, Shin HD, Crous PW. Phylogenetic and morphotaxonomic revision of Ramichloridium and allied genera. Stud Mycol 2011; 58:57-93. [PMID: 18490996 PMCID: PMC2104745 DOI: 10.3114/sim.2007.58.03] [Citation(s) in RCA: 165] [Impact Index Per Article: 12.7] [Reference Citation Analysis] [Abstract] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 11/28/2022] Open
Abstract
The phylogeny of the genera Periconiella, Ramichloridium,
Rhinocladiella and Veronaea was explored by means of partial
sequences of the 28S (LSU) rRNA gene and the ITS region (ITS1, 5.8S rDNA and
ITS2). Based on the LSU sequence data, ramichloridium-like species segregate
into eight distinct clusters. These include the Capnodiales
(Mycosphaerellaceae and Teratosphaeriaceae), the
Chaetothyriales (Herpotrichiellaceae), the Pleosporales, and
five ascomycete clades with uncertain affinities. The type species of
Ramichloridium, R. apiculatum, together with R. musae,
R. biverticillatum, R. cerophilum, R. verrucosum, R. pini, and three new
species isolated from Strelitzia, Musa and forest soil,
respectively, reside in the Capnodiales clade. The human-pathogenic
species R. mackenziei and R. basitonum, together with R.
fasciculatum and R. anceps, cluster with Rhinocladiella
(type species: Rh. atrovirens, Herpotrichiellaceae,
Chaetothyriales), and are allocated to this genus. Veronaea
botryosa, the type species of the genus Veronaea, also resides
in the Chaetothyriales clade, whereas Veronaea simplex
clusters as a sister taxon to the Venturiaceae (Pleosporales), and is
placed in a new genus, Veronaeopsis. Ramichloridium
obovoideum clusters with Carpoligna pleurothecii (anamorph:
Pleurothecium sp., Chaetosphaeriales), and a new combination
is proposed in Pleurothecium. Other ramichloridium-like clades
include R. subulatum and R. epichloës (incertae sedis,
Sordariomycetes), for which a new genus, Radulidium is
erected. Ramichloridium schulzeri and its varieties are placed in a
new genus, Myrmecridium (incertae sedis, Sordariomycetes).
The genus Pseudovirgaria (incertae sedis) is introduced to
accommodate ramichloridium-like isolates occurring on various species of rust
fungi. A veronaea-like isolate from Bertia moriformis with
phylogenetic affinity to the Annulatascaceae (Sordariomycetidae) is
placed in a new genus, Rhodoveronaea. Besides
Ramichloridium, Periconiella is also polyphyletic.
Thysanorea is introduced to accommodate Periconiella papuana
(Herpotrichiellaceae), which is unrelated to the type species, P.
velutina (Mycosphaerellaceae).
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