Your search keyword '"Alan J. L. Phillips"' showing total 124 results

1. Two new Botryosphaeria (Botryosphaeriales, Botryosphaeriaceae) species in China

Author

Jing-E Sun, Chao-Rong Meng, Alan J. L. Phillips, and Yong Wang

Subjects

Botany, QK1-989

Abstract

Five ascomycetous strains were isolated from dead branches and leaves of Salix (Salicaceae) and Osmanthus fragrans (Oleaceae), respectively. BLAST searches with ITS sequences in GenBank suggested a high degree of similarity to Botryosphaeria dothidea. To accurately identify these strains, we further analysed their morphological characteristics of asci, ascospores, all conidiophore cells and conidia. Phylogenetic relationships, based on ITS, rpb2, tef1 and tub2 gene sequences, confirmed our strains represented two novel species, which are introduced here as B. salicicola and B. osmanthuse spp. nov.

Published

2022

2. Palm Fungi and Their Key Role in Biodiversity Surveys: A Review

Author

Diana S. Pereira and Alan J. L. Phillips

Subjects

Arecaceae, biodiversity surveys, fungal biodiversity, fungal estimates, missing fungi, palm trees, Biology (General), QH301-705.5

Abstract

Over the past three decades, a wealth of studies has shown that palm trees (Arecaceae) are a diverse habitat with intense fungal colonisation, making them an important substratum to explore fungal diversity. Palm trees are perennial, monocotyledonous plants mainly restricted to the tropics that include economically important crops and highly valued ornamental plants worldwide. The extensive research conducted in Southeast Asia and Australasia indicates that palm fungi are undoubtedly a taxonomically diverse assemblage from which a remarkable number of new species is continuously being reported. Despite this wealth of data, no recent comprehensive review on palm fungi exists to date. In this regard, we present here a historical account and discussion of the research on the palm fungi to reflect on their importance as a diverse and understudied assemblage. The taxonomic structure of palm fungi is also outlined, along with comments on the need for further studies to place them within modern DNA sequence-based classifications. Palm trees can be considered model plants for studying fungal biodiversity and, therefore, the key role of palm fungi in biodiversity surveys is discussed. The close association and intrinsic relationship between palm hosts and palm fungi, coupled with a high fungal diversity, suggest that the diversity of palm fungi is still far from being fully understood. The figures suggested in the literature for the diversity of palm fungi have been revisited and updated here. As a result, it is estimated that there are about 76,000 species of palm fungi worldwide, of which more than 2500 are currently known. This review emphasises that research on palm fungi may provide answers to a number of current fungal biodiversity challenges.

Published

2023

3. Diaporthe Species on Palms: Molecular Re-Assessment and Species Boundaries Delimitation in the D. arecae Species Complex

Author

Diana S. Pereira, Sandra Hilário, Micael F. M. Gonçalves, and Alan J. L. Phillips

Subjects

coalescent models, GCPSR, leaf diseases, palm fungi, species boundaries, taxonomy, Biology (General), QH301-705.5

Abstract

Due to cryptic diversification, phenotypic plasticity and host associations, multilocus phylogenetic analyses have become the most important tool in accurately identifying and circumscribing species in the Diaporthe genus. However, the application of the genealogical concordance criterion has often been overlooked, ultimately leading to an exponential increase in novel Diaporthe spp. Due to the large number of species, many lineages remain poorly understood under the so-called species complexes. For this reason, a robust delimitation of the species boundaries in Diaporthe is still an ongoing challenge. Therefore, the present study aimed to resolve the species boundaries of the Diaporthe arecae species complex (DASC) by implementing an integrative taxonomic approach. The Genealogical Phylogenetic Species Recognition (GCPSR) principle revealed incongruences between the individual gene genealogies. Moreover, the Poisson Tree Processes’ (PTPs) coalescent-based species delimitation models identified three well-delimited subclades represented by the species D. arecae, D. chiangmaiensis and D. smilacicola. These results evidence that all species previously described in the D. arecae subclade are conspecific, which is coherent with the morphological indistinctiveness observed and the absence of reproductive isolation and barriers to gene flow. Thus, 52 Diaporthe spp. are reduced to synonymy under D. arecae. Recent population expansion and the possibility of incomplete lineage sorting suggested that the D. arecae subclade may be considered as ongoing evolving lineages under active divergence and speciation. Hence, the genetic diversity and intraspecific variability of D. arecae in the context of current global climate change and the role of D. arecae as a pathogen on palm trees and other hosts are also discussed. This study illustrates that species in Diaporthe are highly overestimated, and highlights the relevance of applying an integrative taxonomic approach to accurately circumscribe the species boundaries in the genus Diaporthe.

Published

2023

4. Nigrospora Species Associated with Various Hosts from Shandong Peninsula, China

Author

Yuanyuan Hao, Janith V. S. Aluthmuhandiram, K. W. Thilini Chethana, Ishara S. Manawasinghe, Xinghong Li, Mei Liu, Kevin D. Hyde, Alan J. L. Phillips, and Wei Zhang

Subjects

ascomycota, morphology, multi-gene phylogeny, new host records, xylariales, Botany, QK1-989

Abstract

Nigrospora is a monophyletic genus belonging to Apiosporaceae. Species in this genus are phytopathogenic, endophytic, and saprobic on different hosts. In this study, leaf specimens with disease symptoms were collected from host plants from the Shandong Peninsula, China. The fungal taxa associated with these leaf spots were studied using morphology and phylogeny based on ITS, TEF1, and TUB2 gene regions. In this article, we report on the genus Nigrospora with N. gorlenkoana, N. oryzae, N. osmanthi, N. rubi, and N. sphaerica identified with 13 novel host associations including crops with economic importance such as bamboo and Chinese rose.

Published

2020

5. Re-Evaluating Botryosphaeriales: Ancestral State Reconstructions of Selected Characters and Evolution of Nutritional Modes

Author

Achala R. Rathnayaka, K. W. Thilini Chethana, Alan J. L. Phillips, Jian-Kui Liu, Milan C. Samarakoon, E. B. Gareth Jones, Samantha C. Karunarathna, and Chang-Lin Zhao

Subjects

ancestral characters, BEAST, divergence times, morphology, phylogeny, Biology (General), QH301-705.5

Abstract

Botryosphaeriales (Dothideomycetes, Ascomycota) occur in a wide range of habitats as endophytes, saprobes, and pathogens. The order Botryosphaeriales has not been subjected to evaluation since 2019 by Phillips and co-authors using phylogenetic and evolutionary analyses. Subsequently, many studies introduced novel taxa into the order and revised several families separately. In addition, no ancestral character studies have been conducted for this order. Therefore, in this study, we re-evaluated the character evolution and taxonomic placements of Botryosphaeriales species based on ancestral character evolution, divergence time estimation, and phylogenetic relationships, including all the novel taxa that have been introduced so far. Maximum likelihood, maximum parsimony, and Bayesian inference analyses were conducted on a combined LSU and ITS sequence alignment. Ancestral state reconstruction was carried out for conidial colour, septation, and nutritional mode. Divergence times estimates revealed that Botryosphaeriales originated around 109 Mya in the early epoch of the Cretaceous period. All six families in Botryosphaeriales evolved in the late epoch of the Cretaceous period (66–100 Mya), during which Angiosperms also appeared, rapidly diversified and became dominant on land. Families of Botryosphaeriales diversified during the Paleogene and Neogene periods in the Cenozoic era. The order comprises the families Aplosporellaceae, Botryosphaeriaceae, Melanopsaceae, Phyllostictaceae, Planistromellaceae and Saccharataceae. Furthermore, current study assessed two hypotheses; the first one being “All Botryosphaeriales species originated as endophytes and then switched into saprobes when their hosts died or into pathogens when their hosts were under stress”; the second hypothesis states that “There is a link between the conidial colour and nutritional mode in botryosphaerialean taxa”. Ancestral state reconstruction and nutritional mode analyses revealed a pathogenic/saprobic nutritional mode as the ancestral character. However, we could not provide strong evidence for the first hypothesis mainly due to the significantly low number of studies reporting the endophytic botryosphaerialean taxa. Results also showed that hyaline and aseptate conidia were ancestral characters in Botryosphaeriales and supported the relationship between conidial pigmentation and the pathogenicity of Botryosphaeriales species.

Published

2023

6. Taxonomy and Multigene Phylogeny of Diaporthales in Guizhou Province, China

Author

Si-Yao Wang, Eric H. C. McKenzie, Alan J. L. Phillips, Yan Li, and Yong Wang

Subjects

Chrysofolia, Diaporthe, Foliocryphiaceae, one new genus, Pseudomastigosporella, seven new species, Biology (General), QH301-705.5

Abstract

In a study of fungi isolated from plant material in Guizhou Province, China, we identified 23 strains of Diaporthales belonging to nine species. These are identified from multigene phylogenetic analyses of ITS, LSU, rpb2, tef1, and tub2 gene sequence data coupled with morphological studies. The fungi include a new genus (Pseudomastigosporella) in Foliocryphiaceae isolated from Acer palmatum and Hypericum patulum, a new species of Chrysofolia isolated from Coriaria nepalensis, and five new species of Diaporthe isolated from Juglans regia, Eucommia ulmoides, and Hypericum patulum. Gnomoniopsis rosae and Coniella quercicola are newly recorded species for China.

Published

2022

7. Lasiodiplodia fici sp. nov., Causing Leaf Spot on Ficus altissima in China

Author

GuiYan Xia, Ishara S. Manawasinghe, Alan J. L. Phillips, ChunPing You, Ruvishika S. Jayawardena, Mei Luo, and Kevin D. Hyde

Subjects

one new species, banyan trees, Botryosphaeriaceae, pathogenicity, tropical forest plants, Medicine

Abstract

High temperatures and the seasonality in tropical ecosystems favours plant pathogens, which result in many fungal diseases. Among these, diseases caused by Botryosphaeriaceae species are prominent as dieback, canker and leaf spots. In this research, we isolated one leaf-spot-causing Botryosphaeriaceae species from Ficus altissima leaves, which were collected in Guangzhou, Guangdong Province, China. Isolation and identification of the pathogen were based on morphological and molecular aspects. Based on multigene phylogenetic analysis of combined internal transcribed spacer (ITS), translation elongation factor 1-α gene (tef1) and beta-tubulin gene (tub2), the fungus associated with leaf spots on F. altissima is described as Lasiodiplodia fici, a novel species. Pathogenicity assays were conducted by inoculating the fungus onto detached shoots and plants under controlled environmental conditions. The results revealed that the L. fici isolates can infect the plant tissues under stress conditions by developing disease symptoms on detached shoots within three days. However, when it was inoculated onto the leaves of the host and grown in natural conditions, the progression of the disease was slow. The putative pathogen was re-isolated, and Koch’s assumptions were satisfied. This is the first report of Lasiodiplodia species causing disease on Ficus altissima. Results from the present study will provide additional knowledge on fungal pathogens associated with forest and ornamental plant species.

Published

2022

8. Endophytic Diaporthe Associated With Citrus grandis cv. Tomentosa in China

Author

Zhangyong Dong, Ishara S. Manawasinghe, Yinghua Huang, Yongxin Shu, Alan J. L. Phillips, Asha J. Dissanayake, Kevin D. Hyde, Meimei Xiang, and Mei Luo

Subjects

nine new host records, two new species, Diaporthales, phylogeny, taxonomy, Microbiology, QR1-502

Abstract

Diaporthe species are associated with Citrus as endophytes, pathogens, and saprobes worldwide. However, little is known about Diaporthe as endophytes in Citrus grandis in China. In this study, 24 endophytic Diaporthe isolates were obtained from cultivated C. grandis cv. “Tomentosa” in Huazhou, Guangdong Province in 2019. The nuclear ribosomal internal transcribed spacer (ITS), partial sequences of translation elongation factor 1-α (tef1), β-tubulin (tub2), and partial calmodulin (cal) gene regions were sequenced and employed to construct phylogenetic trees. Based on morphology and combined multigene phylogeny, eleven Diaporthe species were identified including two new species, Diaporthe endocitricola and D. guangdongensis. These are the first report of D. apiculata, D. aquatica, D. arecae, D. biconispora, D. limonicola, D. masirevicii, D. passifloricola, D. perseae, and D. sennae on C. grandis. This study provides the first intensive study of endophytic Diaporthe species on C. grandis cv. tomentosa in China. These results will improve the current knowledge of Diaporthe species associated with C. grandis. The results obtained in this study will also help to understand the potential pathogens and biocontrol agents and to develop a platform in disease management.

Published

2021

9. Fungi vs. Fungi in Biocontrol: An Overview of Fungal Antagonists Applied Against Fungal Plant Pathogens

Author

Kasun M. Thambugala, Dinushani A. Daranagama, Alan J. L. Phillips, Sagarika D. Kannangara, and Itthayakorn Promputtha

Subjects

biocontrol agents, disease control, fungicides, plant diseases, plant pathogens, phylogeny, Microbiology, QR1-502

Abstract

Plant pathogens cause severe losses or damage to crops worldwide and thereby significantly reduce the quality and quantity of agricultural commodities. World tendencies are shifting towards reducing the usage of chemically synthesized pesticides, while various biocontrol methods, strategies and approaches are being used in plant disease management. Fungal antagonists play a significant role in controlling plant pathogens and diseases and they are used as Biocontrol Agents (BCAs) throughout the world. This review provides a comprehensive list of fungal BCAs used against fungal plant pathogens according to modern taxonomic concepts, and clarifies their phylogenetic relationships because thewrong names are frequently used in the literature of biocontrol. Details of approximately 300 fungal antagonists belonging to 13 classes and 113 genera are listed together with the target pathogens and corresponding plant diseases. Trichoderma is identified as the genus with greatest potential comprising 25 biocontrol agents that have been used against a number of plant fungal diseases. In addition to Trichoderma, nine genera are recognized as significant comprising five or more known antagonistic species, namely, Alternaria, Aspergillus, Candida, Fusarium, Penicillium, Pichia, Pythium, Talaromyces, and Verticillium. A phylogenetic analysis based on partial sequences of the 28S nrRNA gene (LSU) of fungal antagonists was performed to establish their phylogenetic relationships.

Published

2020

10. Importance of Molecular Data to Identify Fungal Plant Pathogens and Guidelines for Pathogenicity Testing Based on Koch’s Postulates

Author

Chitrabhanu S. Bhunjun, Alan J. L. Phillips, Ruvishika S. Jayawardena, Itthayakorn Promputtha, and Kevin D. Hyde

Subjects

disease severity, image analysis, pathogenicity, phylogeny, plant disease assessment, Medicine

Abstract

Fungi are an essential component of any ecosystem, but they can also cause mild and severe plant diseases. Plant diseases are caused by a wide array of fungal groups that affect a diverse range of hosts with different tissue specificities. Fungi were previously named based only on morphology and, in many cases, host association, which has led to superfluous species names and synonyms. Morphology-based identification represents an important method for genus level identification and molecular data are important to accurately identify species. Accurate identification of fungal pathogens is vital as the scientific name links the knowledge concerning a species including the biology, host range, distribution, and potential risk of the pathogen, which are vital for effective control measures. Thus, in the modern era, a polyphasic approach is recommended when identifying fungal pathogens. It is also important to determine if the organism is capable of causing host damage, which usually relies on the application of Koch’s postulates for fungal plant pathogens. The importance and the challenges of applying Koch’s postulates are discussed. Bradford Hill criteria, which are generally used in establishing the cause of human disease, are briefly introduced. We provide guidelines for pathogenicity testing based on the implementation of modified Koch’s postulates incorporating biological gradient, consistency, and plausibility criteria from Bradford Hill. We provide a set of protocols for fungal pathogenicity testing along with a severity score guide, which takes into consideration the depth of lesions. The application of a standard protocol for fungal pathogenicity testing and disease assessment in plants will enable inter-studies comparison, thus improving accuracy. When introducing novel plant pathogenic fungal species without proving the taxon is the causal agent using Koch’s postulates, we advise the use of the term associated with the “disease symptoms” of “the host plant”. Where possible, details of disease symptoms should be clearly articulated.

Published

2021

11. Molecular and Morphological Assessment of Septoria Species Associated with Ornamental Plants in Yunnan Province, China

Author

Yuan-Yan An, Monika C. Dayarathne, Xiang-Yu Zeng, Alan J. L. Phillips, Kevin D. Hyde, and Yong Wang

Subjects

GCPSR, molecular assessment, new taxa, Septoria, Biology (General), QH301-705.5

Abstract

The Karst landform is the main geographic characteristic in South China. Such areas are rich in vegetation and especially suitable for growth of shrubs and herbaceous plants. In this study, 11 Septoria strains were obtained from different plants’ leaves collected in the Kunming Botanical Garden, Yunnan Province, China. Based on single-gene and multi-gene analyses of five gene loci (tef1, rpb2, tub2, ITS, and LSU) and four gene regions (without LSU), these strains were found to belong to three independent phylogenetic lineages representing five species, including four novel taxa, and one new record for China. Five single gene trees were also provided to evaluate the effectiveness of each gene for discriminating the species, as a result of which tub2 was found to have the most suitable DNA barcode for rapid identification. Morphological descriptions, illustrations, and comparisons are provided for a more comprehensive assessment. Genealogical Concordance Phylogenetic Species Recognition (GCPSR) with a pairwise homoplasy index (PHI) test was used to evaluate the conclusions of the phylogenetic analyses.

Published

2021

12. Identification and Characterization of Colletotrichum Species Associated with Cherry Leaf Spot Disease in China

Author

Yueyan Zhou, Wei Zhang, Yameng Li, Shuxian Ji, Xinghong Li, Kevin D. Hyde, Kaichun Zhang, Alan J. L. Phillips, Ishara S. Manawasinghe, and Jiye Yan

Subjects

Plant Science, Agronomy and Crop Science

Abstract

Leaf spot is a common and serious disease of sweet cherry worldwide and has become a major concern in China. From 2018 to 2020, disease investigations were carried out in Beijing City, Sichuan, Shandong, and Liaoning Provinces in China, and 105 Colletotrichum isolates were obtained from diseased samples. Isolates were identified by morphological characterization coupled with multigene phylogenetic analyses based on six loci (internal transcribed spacer region, glyceraldehyde 3-phosphate dehydrogenase, calmodulin, actin, chitin synthase, and β-tubulin). A total of 13 Colletotrichum species were identified, namely Colletotrichum aenigma, C. gloeosporioides, C. fructicola, C. siamense, C. temperatum, C. conoides, C. hebeiense, C. sojae, C. plurivorum, C. karsti, C. truncatum, C. incanum, and C. dematium. Among these, C. aenigma (25.7%) was the most prominent species isolated from diseased leaves, followed by C. gloeosporioides (19.0%) and C. fructicola (12.4%). Pathogenicity was tested on detached leaves of cv. ‘Tieton’ and ‘Summit’ and young seedlings of cv. ‘Brooks’ under greenhouse conditions. All 13 species were pathogenic to cherry leaves, and C. aenigma, C. conoides, and C. dematium showed high levels of virulence. Seedlings inoculated with the isolates developed similar symptoms to those seen in the orchards. This study provides the first reports for 11 of the 13 Colletotrichum species on sweet cherry in the world, excluding C. aenigma and C. fructicola. This is the first comprehensive study of Colletotrichum species associated with cherry leaf spot in China, and the results will provide basic knowledge to develop sustainable control measures for cherry leaf spot.

Published

2023

13. Forecasting the number of species of asexually reproducing fungi (Ascomycota and Basidiomycota)

Author

Nalin N. Wijayawardene, Alan J. L. Phillips, Diana Santos Pereira, Dong-Qin Dai, André Aptroot, Josiane S. Monteiro, Irina S. Druzhinina, Feng Cai, Xinlei Fan, Laura Selbmann, Claudia Coleine, Rafael F. Castañeda-Ruiz, Martin Kukwa, Adam Flakus, Patricia Oliveira Fiuza, Paul M. Kirk, Kunhiraman C. Rajesh Kumar, Ilesha S. leperuma Arachchi, Nakarin Suwannarach, Li-Zhou Tang, Teun Boekhout, Chen Shuhui Tan, R. P. Prabath K. Jayasinghe, and Marco Thines

Subjects

Ecology, Ecology, Evolution, Behavior and Systematics

Published

2022

14. Caveats of the internal transcribed spacer region as a barcode to resolve species boundaries in Diaporthe

Author

Sandra Hilário, Artur Alves, Liliana Santos, and Alan J. L. Phillips

Subjects

Concerted evolution, Phylogenetic tree, Plants, Biology, biology.organism_classification, DNA, Ribosomal, DNA barcoding, Infectious Diseases, Taxon, Diaporthe, Evolutionary biology, Genus, Saccharomycetales, Genetics, Internal transcribed spacer, Clade, Phylogeny, Ecology, Evolution, Behavior and Systematics

Abstract

Species in Diaporthe are largely reported as important plant pathogens. Identification of species in this genus has been complemented by morphological and molecular features. However, one important factor delaying this process is the struggle to formulate robust species concepts to create adequate international phytosanitary measures. Regardless of the wide use of the internal transcribed spacer (ITS) rDNA region, established as the primary DNA barcode for fungi, the tendency for intraspecific variation has been reported, misleading interpretation of phylogenetic analyses. Therefore, the present study aimed to illustrate, using specific examples, how the ITS region may be problematic for species delimitation. We showed that the ITS region is highly variable, with strains of Diaporthe malorum and Diaporthe novem falling into more than one clade, which if analyzed on their own, would be likely recognized as distinct taxa. Divergent ITS paralogs were also proven to coexist within the genome of D. novem. We also suggest that ITS may have escaped from concerted evolution or has undergone a duplication event. Furthermore, this study reports for the first time the existence of a putative hybrid in the genus Diaporthe. Our findings offer new clues towards the intraspecific and intragenomic variation in the ITS region, raising questions about its value for barcoding, i.e., identifying species in the genus Diaporthe. Therefore, we recommend that the ITS region be analyzed cautiously and always compared for congruence prior to description of novel taxa.

Published

2022

15. Five new species of Neopestalotiopsis associated with diseased Eucalyptus spp. in Portugal

Author

Eugénio Diogo, Ana Catarina Silva, Helena Bragança, Alan J. L. Phillips, Carlos Valente, and Catarina I. Gonçalves

Subjects

Phylogenetic tree, biology, Girdling, Eucalyptus globulus, Eucalyptus spp, Botany, Introduced species, Neopestalotiopsis, biology.organism_classification, Clade, Agricultural and Biological Sciences (miscellaneous), Eucalyptus, Ecology, Evolution, Behavior and Systematics

Abstract

Eucalyptus globulus, an exotic species in Portugal, is one of the dominant and intensively managed forest species in the country. A disease syndrome characterised by leaf necrosis, stem girdling and cutting dieback in eucalyptus and associated with pestalotioid fungi has been detected in nurseries and young plantations in the last years. Twenty-seven isolates were recovered from diseased plants. Phylogenetic analysis based on internal transcribed spacers, partial translation elongation factor 1-α gene and partial β-tubulin gene sequence data grouped the isolates in five separate clades. Combining morphological, cultural and molecular data, five new species of Neopestalotiopsis are described, namely, Neopestalotiopsis eucalyptorum, Neopestalotiopsis hispanica, Neopestalotiopsis iberica, Neopestalotiopsis longiappendiculata and Neopestalotiopsis lusitanica.

Published

2021

16. Fungal diversity notes 1387–1511: taxonomic and phylogenetic contributions on genera and species of fungal taxa

Author

Saranyaphat Boonmee, Dhanushka N. Wanasinghe, Mark S. Calabon, Naruemon Huanraluek, Sajini K. U. Chandrasiri, Gareth E. B. Jones, Walter Rossi, Marco Leonardi, Sanjay K. Singh, Shiwali Rana, Paras N. Singh, Deepak K. Maurya, Ajay C. Lagashetti, Deepika Choudhary, Yu-Cheng Dai, Chang-Lin Zhao, Yan-Hong Mu, Hai-Sheng Yuan, Shuang-Hui He, Rungtiwa Phookamsak, Hong-Bo Jiang, María P. Martín, Margarita Dueñas, M. Teresa Telleria, Izabela L. Kałucka, Andrzej M. Jagodziński, Kare Liimatainen, Diana S. Pereira, Alan J. L. Phillips, Nakarin Suwannarach, Jaturong Kumla, Surapong Khuna, Saisamorn Lumyong, Tarynn B. Potter, Roger G. Shivas, Adam H. Sparks, Niloofar Vaghefi, Mohamed A. Abdel-Wahab, Faten A. Abdel-Aziz, Guo-Jie Li, Wen-Fei Lin, Upendra Singh, Rajendra P. Bhatt, Hyang Burm Lee, Thuong T. T. Nguyen, Paul M. Kirk, Arun Kumar Dutta, Krishnendu Acharya, V. Venkateswara Sarma, M. Niranjan, Kunhiraman C. Rajeshkumar, Nikhil Ashtekar, Sneha Lad, Nalin N. Wijayawardene, Darbe J. Bhat, Rong-Ju Xu, Subodini N. Wijesinghe, Hong-Wei Shen, Zong-Long Luo, Jing-Yi Zhang, Phongeun Sysouphanthong, Naritsada Thongklang, Dan-Feng Bao, Janith V. S. Aluthmuhandiram, Jafar Abdollahzadeh, Alireza Javadi, Francesco Dovana, Muhammad Usman, Abdul Nasir Khalid, Asha J. Dissanayake, Anusha Telagathoti, Maraike Probst, Ursula Peintner, Isaac Garrido-Benavent, Lilla Bóna, Zsolt Merényi, Lajos Boros, Bratek Zoltán, J. Benjamin Stielow, Ning Jiang, Cheng-Ming Tian, Esmaeil Shams, Farzaneh Dehghanizadeh, Adel Pordel, Mohammad Javan-Nikkhah, Teodor T. Denchev, Cvetomir M. Denchev, Martin Kemler, Dominik Begerow, Chun-Ying Deng, Emma Harrower, Tohir Bozorov, Tutigul Kholmuradova, Yusufjon Gafforov, Aziz Abdurazakov, Jian-Chu Xu, Peter E. Mortimer, Guang-Cong Ren, Rajesh Jeewon, Sajeewa S. N. Maharachchikumbura, Chayanard Phukhamsakda, Ausana Mapook, and Kevin D. Hyde

Subjects

Agaricomycetes, Laboulbeniomycetes, Ecology, Leotiomycetes, Basidiomycota, Mortierellomycetes, One reference specimen, 51 new records, 72 new taxa, Ascomycota, Bartheletiomycetes, Dothideomycetes, Eurotiomycetes, Exobasidiomycetes, Mortierellomycota, Mucoromycetes, Mucoromycota, One new combination, Phylogeny, Sordariomycetes, Taxonomy, Article, Mucoromycete, Ecology, Evolution, Behavior and Systematics

Abstract

This article is the 13th contribution in the Fungal Diversity Notes series, wherein 125 taxa from four phyla, ten classes, 31 orders, 69 families, 92 genera and three genera incertae sedis are treated, demonstrating worldwide and geographic distribution. Fungal taxa described and illustrated in the present study include three new genera, 69 new species, one new combination, one reference specimen and 51 new records on new hosts and new geographical distributions. Three new genera, Cylindrotorula (Torulaceae), Scolecoleotia (Leotiales genus incertae sedis) and Xenovaginatispora (Lindomycetaceae) are introduced based on distinct phylogenetic lineages and unique morphologies. Newly described species are Aspergillus lannaensis, Cercophora dulciaquae, Cladophialophora aquatica, Coprinellus punjabensis, Cortinarius alutarius, C. mammillatus, C. quercoflocculosus, Coryneum fagi, Cruentomycena uttarakhandina, Cryptocoryneum rosae, Cyathus uniperidiolus, Cylindrotorula indica, Diaporthe chamaeropicola, Didymella azollae, Diplodia alanphillipsii, Dothiora coronicola, Efibula rodriguezarmasiae, Erysiphe salicicola, Fusarium queenslandicum, Geastrum gorgonicum, G. hansagiense, Helicosporium sexualis, Helminthosporium chiangraiensis, Hongkongmyces kokensis, Hydrophilomyces hydraenae, Hygrocybe boertmannii, Hyphoderma australosetigerum, Hyphodontia yunnanensis, Khaleijomyces umikazeana, Laboulbenia divisa, Laboulbenia triarthronis, Laccaria populina, Lactarius pallidozonarius, Lepidosphaeria strobelii, Longipedicellata megafusiformis, Lophiotrema lincangensis, Marasmius benghalensis, M. jinfoshanensis, M. subtropicus, Mariannaea camelliae, Melanographium smilaxii, Microbotryum polycnemoides, Mimeomyces digitatus, Minutisphaera thailandensis, Mortierella solitaria, Mucor harpali, Nigrograna jinghongensis, Odontia huanrenensis, O. parvispina, Paraconiothyrium ajrekarii, Parafuscosporella niloticus, Phaeocytostroma yomensis, Phaeoisaria synnematicus, Phanerochaete hainanensis, Pleopunctum thailandicum, Pleurotheciella dimorphospora, Pseudochaetosphaeronema chiangraiense, Pseudodactylaria albicolonia, Rhexoacrodictys nigrospora, Russula paravioleipes, Scolecoleotia eriocamporesi, Seriascoma honghense, Synandromyces makranczyi, Thyridaria aureobrunnea, Torula lancangjiangensis, Tubeufia longihelicospora, Wicklowia fusiformispora, Xenovaginatispora phichaiensis and Xylaria apiospora. One new combination, Pseudobactrodesmium stilboideus is proposed. A reference specimen of Comoclathris permunda is designated. New host or distribution records are provided for Acrocalymma fici, Aliquandostipite khaoyaiensis, Camarosporidiella laburni, Canalisporium caribense, Chaetoscutula juniperi, Chlorophyllum demangei, C. globosum, C. hortense, Cladophialophora abundans, Dendryphion hydei, Diaporthe foeniculina, D. pseudophoenicicola, D. pyracanthae, Dictyosporium pandanicola, Dyfrolomyces distoseptatus, Ernakulamia tanakae, Eutypa flavovirens, E. lata, Favolus septatus, Fusarium atrovinosum, F. clavum, Helicosporium luteosporum, Hermatomyces nabanheensis, Hermatomyces sphaericoides, Longipedicellata aquatica, Lophiostoma caudata, L. clematidis-vitalbae, Lophiotrema hydei, L. neoarundinaria, Marasmiellus palmivorus, Megacapitula villosa, Micropsalliota globocystis, M. gracilis, Montagnula thailandica, Neohelicosporium irregulare, N. parisporum, Paradictyoarthrinium diffractum, Phaeoisaria aquatica, Poaceascoma taiwanense, Saproamanita manicata, Spegazzinia camelliae, Submersispora variabilis, Thyronectria caudata, T. mackenziei, Tubeufia chiangmaiensis, T. roseohelicospora, Vaginatispora nypae, Wicklowia submersa, Xanthagaricus necopinatus and Xylaria haemorrhoidalis. The data presented herein are based on morphological examination of fresh specimens, coupled with analysis of phylogenetic sequence data to better integrate taxa into appropriate taxonomic ranks and infer their evolutionary relationships.

Published

2021

17. Defining a species in fungal plant pathology: beyond the species level

Author

Anuruddha Karunarathna, Alan J. L. Phillips, Dulanjalee L. Harischandra, Mei Luo, Janith Weerasinghe, Zhangyong Dong, Łukasz Stępień, Kevin D. Hyde, Abhaya Balasuriya, Ishara S. Manawasinghe, Jianping Xu, Ratchadawan Cheewangkoon, and Jiye Yan

Subjects

Species complex, Pathology, medicine.medical_specialty, Ecology, Host (biology), Biodiversity, Biology, Subspecies, General purpose, Species level, medicine, Identification (biology), Plant quarantine, Ecology, Evolution, Behavior and Systematics

Abstract

In plant pathology, the correct naming of a species is essential for determining the causal agents of disease. Species names not only serve the general purpose of concise communication, but also are critical for effective plant quarantine, preventing the introduction of new pathogens into a territory. Many phytopathogenic genera have multiple species and, in several genera, disagreements between the multiple prevailing species concept definitions result in numerous cryptic species. Some of these species were previously called by various names; forma speciales (specialised forms), subspecies, or pathotypes. However, based on new molecular evidence they are being assigned into new species. The frequent name changes and lack of consistent criteria to delineate cryptic species, species, subspecies, forms, and races create increasing confusion, often making communication among biologists arduous. Furthermore, such ambiguous information can convey misleading evolutionary concepts and species boundaries. The aim of this paper is to review these concepts, clarify their use, and evaluate them by referring to existing examples. We specifically address the question, “Do plant pathogens require a different ranking system?” We conclude that it is necessary to identify phytopathogens to species level based on data from multiple approaches. Furthermore, this identification must go beyond species level to clearly classify hitherto known subspecies, forms and races. In addition, when naming phytopathogenic genera, plant pathologists should provide more information about geographic locations and host ranges as well as host specificities for individual species, cryptic species, forms or races. When describing a new phytopathogen, we suggest that authors provide at least three representative strains together with pathogenicity test results. If Koch’s postulates cannot be fulfilled, it is necessary to provide complementary data such as associated disease severity on the host plant. Moreover, more sequenced collections of species causing diseases should be published in order to stabilise the boundaries of cryptic species, species, subspecies, forms, and races.

Published

2021

18. Taxonomic and phylogenetic contributions to Celtis formosana, Ficus ampelas, F. septica, Macaranga tanarius and Morus australis leaf litter inhabiting microfungi

Author

Kevin D. Hyde, Eleni Gentekaki, Sajeewa S. N. Maharachchikumbura, D. Jayarama Bhat, Nimali I. de Silva, Kasun M. Thambugala, Itthayakorn Promputtha, Danushka S. Tennakoon, Alan J. L. Phillips, Chang-Hsin Kuo, and Dhanushka N. Wanasinghe

Subjects

Neofusicoccum, Lasiodiplodia, Microfungi, Ecology, biology, Pseudocercospora, Botany, Diaporthaceae, Botryosphaeriaceae, biology.organism_classification, Diplodia, Incertae sedis, Ecology, Evolution, Behavior and Systematics

Abstract

This article provides descriptions and illustrations of microfungi associated with the leaf litter of Celtis formosana, Ficus ampelas, F. septica, Macaranga tanarius and Morus australis collected from Taiwan. These host species are native to the island and Celtis formosana is an endemic tree species. The study revealed 95 species, consisting of two new families (Cylindrohyalosporaceae and Oblongohyalosporaceae), three new genera (Cylindrohyalospora, Neodictyosporium and Oblongohyalospora), 41 new species and 54 new host records. The newly described species are Acrocalymma ampeli (Acrocalymmaceae), Arthrinium mori (Apiosporaceae), Arxiella celtidis (Muyocopronaceae), Bertiella fici (Melanommataceae), Cercophora fici (Lasiosphaeriaceae), Colletotrichum celtidis, C. fici, C. fici-septicae (Glomerellaceae), Conidiocarpus fici-septicae (Capnodiaceae), Coniella fici (Schizoparmaceae), Cylindrohyalospora fici (Cylindrohyalosporaceae), Diaporthe celtidis, D. fici-septicae (Diaporthaceae), Diaporthosporella macarangae (Diaporthosporellaceae), Diplodia fici-septicae (Botryosphaeriaceae), Discosia celtidis, D. fici (Sporocadaceae), Leptodiscella sexualis (Muyocopronaceae), Leptospora macarangae (Phaeosphaeriaceae), Memnoniella alishanensis, M. celtidis, M. mori (Stachybotryaceae), Micropeltis fici, M. ficina (Micropeltidaceae), Microthyrium fici-septicae (Microthyriaceae), Muyocopron celtidis, M. ficinum, Mycoleptodiscus alishanensis (Muyocopronaceae), Neoanthostomella fici (Xylariales genera incertae sedis), Neodictyosporium macarangae (Sordariales genera incertae sedis), Neofusicoccum moracearum (Botryosphaeriaceae), Neophyllachora fici (Phyllachoraceae), Nigrospora macarangae (Apiosporaceae), Oblongohyalospora macarangae (Oblongohyalosporaceae), Ophioceras ficinum (Ophioceraceae), Parawiesneriomyces chiayiensis (Wiesneriomycetaceae), Periconia alishanica, P. celtidis (Periconiaceae), Pseudocercospora fici-septicae (Mycosphaerellaceae), Pseudoneottiospora cannabacearum (Chaetosphaeriaceae) and Pseudopithomyces mori (Didymosphaeriaceae). The new host records are Alternaria burnsii, A. pseudoeichhorniae (Pleosporaceae), Arthrinium hydei, A. malaysianum, A. paraphaeospermum, A. rasikravindrae, A. sacchari (Apiosporaceae), Bartalinia robillardoides (Sporocadaceae), Beltrania rhombica (Beltraniaceae), Cladosporium tenuissimum (Cladosporiaceae), Coniella quercicola (Schizoparmaceae), Dematiocladium celtidicola (Nectriaceae), Diaporthe limonicola, D. millettiae, D. pseudophoenicicola (Diaporthaceae), Dictyocheirospora garethjonesii (Dictyosporiaceae), Dimorphiseta acuta (Stachybotryaceae), Dinemasporium parastrigosum (Chaetosphaeriaceae), Discosia querci (Sporocadaceae), Fitzroyomyces cyperacearum (Stictidaceae), Gilmaniella bambusae (Ascomycota genera incertae sedis), Hermatomyces biconisporus (Hermatomycetaceae), Lasiodiplodia thailandica, L. theobromae (Botryosphaeriaceae), Memnoniella echinata (Stachybotryaceae), Muyocopron dipterocarpi, M. lithocarpi (Muyocopronaceae), Neopestalotiopsis asiatica, N. phangngaensis (Sporocadaceae), Ophioceras chiangdaoense (Ophioceraceae), Periconia byssoides (Periconiaceae), Pestalotiopsis dracaenea, P. formosana, P. neolitseae, P. papuana, P. parva, P. portugallica, P. trachycarpicola (Sporocadaceae), Phragmocapnias betle (Capnodiaceae), Phyllosticta capitalensis (Phyllostictaceae), Pseudopestalotiopsis camelliae-sinensis (Sporocadaceae), Pseudopithomyces chartarum, P. sacchari (Didymosphaeriaceae), Pseudorobillarda phragmitis (Pseudorobillardaceae), Robillarda roystoneae (Sporocadaceae), Sirastachys castanedae, S. pandanicola (Stachybotryaceae), Spegazzinia musae (Didymosphaeriaceae), Stachybotrys aloeticola, S. microspora (Stachybotryaceae), Strigula multiformis (Strigulaceae), Torula fici (Torulaceae), Wiesneriomyces laurinus (Wiesneriomycetaceae) and Yunnanomyces pandanicola (Sympoventuriaceae). The taxonomic placement of most taxa discussed in this study is based on morphological observation of specimens, coupled with multi-locus phylogenetic analyses of sequence data. In addition, this study provides a host-fungus database for future studies and increases knowledge of fungal diversity, as well as new fungal discoveries from the island.

Published

2021

19. Three new host records of endophytic Neofusicoccum species reported from Dendrobium orchid

Author

Putarak Chomnunti, Mingkwan Doilom, Xiao-Ya Ma, Ji-Chuan Kang, Alan J. L. Phillips, and Kevin D. Hyde

Subjects

Neofusicoccum, Dendrobium, Orchidaceae, biology, Phylogenetic tree, Host (biology), Botany, Plant Science, Internal transcribed spacer, Botryosphaeriaceae, biology.organism_classification, Ecology, Evolution, Behavior and Systematics, Dendrobium chrysanthum

Abstract

Neofusicoccum species are endophytes, saprobes and opportunistic pathogens of many economic and ornamental plants. There are few reports of Neofusicoccum species are available to be associated with orchids worldwide. In this study, five endophytic Neofusicoccum strains were isolated from Dendrobium orchid leaves and stems in southwestern China and northern Thailand. Morphological characteristics and phylogenetic analysis of the combined partial nuclear rDNA internal transcribed spacer (ITS), partial RNA polymerase Ⅱ second largest subunit (RPB2), part of the translation elongation factor 1 alpha (EF-1α) and beta-tubulin (TUB2) dataset revealed that these isolates belong to two species Neofusicoccum occulatum and N. parvum. This is the first record of Neofusicoccum occulatum associated with Dendrobium chrysanthum while N. parvum associated with D. harveyanum and D. moschatum.

Published

2021

20. Two new Morinia species from palms (Arecaceae) in Portugal

Author

Alan J. L. Phillips and Diogo R. S. Pereira

Subjects

Conidiomata, Taxon, biology, Phylogenetic tree, Host (biology), Phoenix reclinata, Botany, Key (lock), Arecaceae, biology.organism_classification, Palm, Agricultural and Biological Sciences (miscellaneous), Ecology, Evolution, Behavior and Systematics

Abstract

During the course of a study of palm fungi in Portugal, several Bartilinia-like taxa were isolated. Morphological characters and phylogenetic data derived from ITS and LSU sequences supported the establishment of two new Morinia species introduced here as M. trachycarpi and M. phoenicicola spp. nov. isolated from foliar diseases of ornamental palm trees in Lisbon, Portugal. The morphological concept of Morinia is broadened to include enclosed pycnidial conidiomata and conidia with wedge-shaped apical cells, new distinctive morphological characteristics observed in M. trachycarpi. Bartalinia robillardoides was also isolated and is presented here as a new host and geographical record on foliar lesions of Phoenix reclinata from Lisbon, Portugal. Comparative morphological data on species of Morinia, as well as a key to species in Morinia, are provided and discussed.

Published

2021

21. Refined families of Dothideomycetes: orders and families incertae sedis in Dothideomycetes

Author

Ausana Mapook, Digvijayini Bundhun, Kasun M. Thambugala, Jian-Kui Liu, Subashini C. Jayasiri, V. Venkateswara Sarma, Danushka S. Tennakoon, Ave Suija, Mekala Niranjan, Felix Schumm, Gareth E.B. Jones, Xiang-Yu Zeng, Gang Liu, Alan J. L. Phillips, Jadson D. P. Bezerra, Hiroyuki Kashiwadani, Nimali I. de Silva, Hong-Bo Jiang, Diana Sandamali, Rajesh Jeewon, Milan C. Samarakoon, Dhandevi Pem, Zong-Long Luo, Jing Yang, K. W. Thilini Chethana, Satinee Suetrong, Mingkwan Doilom, Ishara S. Manawasinghe, Jayarama D. Bhat, Huang Zhang, Sinang Hongsanan, Anuruddha Karunarathna, Nalin N. Wijayawardene, Hiran A. Ariyawansa, Ning Xie, Rungtiwa Phookamsak, Hai-Xia Wu, Yao Feng, Jutamart Monkai, Dulanjalee Harishchandra, Yong-Zhong Lu, Pranami D. Abeywickrama, Putarak Chomnunti, Dong-Qin Dai, Emmanuël Sérusiaux, Vinodhini Thiyagaraja, Ricardo Miranda-González, Chayanard Phukhamsakda, Saowaluck Tibpromma, André Aptroot, Chitrabhanu S. Bhunjun, Anusha H. Ekanayaka, Asha J. Dissanayake, Eric H. C. McKenzie, Napalai Chaiwan, Ruvishika S. Jayawardena, Shu-Hua Jiang, Jiesheng Zheng, Sheng-Nan Zhang, Chada Norphanphoun, Sergio Pérez-Ortega, Chanokned Senwanna, Qing Tian, Jin-Feng Zhang, Kevin D. Hyde, Jianchu Xu, Damien Ertz, Monika C. Dayarathne, Ning-Guo Liu, Cécile Gueidan, B. Devadatha, Dhanushka N. Wanasinghe, Dan-Feng Bao, Subodini N. Wijesinghe, Achala R. Rathnayaka, Robert Lücking, Saranyaphat Boonmee, and Kwang Hee Moon

Subjects

Taxon, Ecology, Phylogenetic tree, Pleosporomycetidae, biology, Phylogenetics, Evolutionary biology, Dothiorella, Dothideomycetidae, Dothideomycetes, biology.organism_classification, Incertae sedis, Ecology, Evolution, Behavior and Systematics

Abstract

Numerous new taxa and classifications of Dothideomycetes have been published following the last monograph of families of Dothideomycetes in 2013. A recent publication by Honsanan et al. in 2020 expanded information of families in Dothideomycetidae and Pleosporomycetidae with modern classifications. In this paper, we provide a refined updated document on orders and familiesincertae sedisof Dothideomycetes. Each family is provided with an updated description, notes, including figures to represent the morphology, a list of accepted genera, and economic and ecological significances. We also provide phylogenetic trees for each order. In this study, 31 orders which consist 50 families are assigned as ordersincertae sedisin Dothideomycetes, and 41 families are treated as familiesincertae sedisdue to lack of molecular or morphological evidence. The new order, Catinellales, and four new families,Catinellaceae,Morenoinaceae NeobuelliellaceaeandThyrinulaceaeare introduced. Seven genera (Neobuelliella,Pseudomicrothyrium,Flagellostrigula,Swinscowia,Macroconstrictolumina,Pseudobogoriella, andSchummia) are introduced. Seven new species (Acrospermum urticae,Bogoriella complexoluminata,Dothiorella ostryae,Dyfrolomyces distoseptatus,Macroconstrictolumina megalateralis,Patellaria microspora, andPseudomicrothyrium thailandicum) are introduced base on morphology and phylogeny, together with two new records/reports and five new collections from different families. Ninety new combinations are also provided in this paper.

Published

2020

22. Diversity, distribution and host association of Botryosphaeriaceae species causing oak decline across different forest ecosystems in Algeria

Author

Artur Alves, Youssef Djellid, Alan J. L. Phillips, Anabela Lopes, Aleš Eichmeier, Abdelghani Zitouni, Alla Eddine Mahamedi, Mounia Arkam, and Akila Berraf-Tebbal

Subjects

0106 biological sciences, 0301 basic medicine, biology, Phylogenetic tree, Host (biology), Species diversity, Botryosphaeria dothidea, Plant Science, Horticulture, Botryosphaeriaceae, biology.organism_classification, 01 natural sciences, Neofusicoccum, 03 medical and health sciences, 030104 developmental biology, Taxon, Seriata, Botany, Agronomy and Crop Science, 010606 plant biology & botany

Abstract

Botryosphaeriaceous fungi associated with holm (Q. ilex) and cork (Q. suber) oak trees exhibiting dieback symptoms and cankers in Algeria, were sampled in twelve regions with different ecological conditions. Based on phylogenetic analyses of ITS and tef1-α loci, 13 species were identified. Three species (Diplodia corticola, Dothiorella iberica and Botryosphaeria dothidea) were found to be common to both oak species, while Doth. sarmentorum, D. mutila, Neofusicoccum vitifusiforme, D. insularis, N. stellenboschiana, Doth. plurivora, D. seriata, D. rosacearum, N. parvum and N. terminaliae were found only on one of the hosts. All the Botryosphaeriaceae taxa inoculated on oak shoots produced brown vascular discolouration, and were shown to be pathogenic on both oak species. Diplodia corticola was the most widespread and frequent species showing the highest aggressiveness towards both hosts. Neofusicoccum stellenboschiana, D. insularis and Doth. plurivora are recorded for the first time on Q. suber and Q. ilex. In addition to altitude, the environmental factors temperature and drought appeared to be influential variables that could describe the occurrence and the geographic distribution of these fungal species.

Published

2020

23. Nigrospora Species Associated with Various Hosts from Shandong Peninsula, China

Author

Yuan-Yuan Hao, Mei Liu, Kevin D. Hyde, K. W. Thilini Chethana, Ishara S. Manawasinghe, Wei Zhang, Alan J. L. Phillips, Xinghong Li, and Janith V. S. Aluthmuhandiram

Subjects

Morphology (biology), Biology, Microbiology, 030308 mycology & parasitology, 03 medical and health sciences, Monophyly, Genus, lcsh:Botany, morphology, Botany, Xylariales, Shandong peninsula, new host records, China, 030304 developmental biology, ascomycota, 0303 health sciences, Ascomycota, fungi, food and beverages, biology.organism_classification, lcsh:QK1-989, Infectious Diseases, multi-gene phylogeny, xylariales, Nigrospora

Abstract

Nigrospora is a monophyletic genus belonging to Apiosporaceae. Species in this genus are phytopathogenic, endophytic, and saprobic on different hosts. In this study, leaf specimens with disease symptoms were collected from host plants from the Shandong Peninsula, China. The fungal taxa associated with these leaf spots were studied using morphology and phylogeny based on ITS, TEF1, and TUB2 gene regions. In this article, we report on the genus Nigrospora with N. gorlenkoana, N. oryzae, N. osmanthi, N. rubi, and N. sphaerica identified with 13 novel host associations including crops with economic importance such as bamboo and Chinese rose.

Published

2020

24. Microfungi associated with Clematis (Ranunculaceae) with an integrated approach to delimiting species boundaries

Author

Dhanushka N. Wanasinghe, Saowaluck Tibpromma, E. B. Gareth Jones, Kevin D. Hyde, Erio Camporesi, Jianchu Xu, Damien Ertz, Eric H. C. McKenzie, Mingkwan Doilom, Marc Stadler, Chayanard Phukhamsakda, Ruvishika S. Jayawardena, D. Jayarama Bhat, Anusha H. Ekanayake, Rekhani H. Perera, Alan J. L. Phillips, Chitrabhanu S. Bhunjun, Benjarong Thongbai, and HZI,Helmholtz-Zentrum für Infektionsforschung GmbH, Inhoffenstr. 7,38124 Braunschweig, Germany.

Subjects

Clematis, 0303 health sciences, Phaeosphaeriaceae, Microfungi, Ecology, biology, Plant Science, Dothideomycetes, biology.organism_classification, 030308 mycology & parasitology, 03 medical and health sciences, Diaporthe, Botany, Pleosporales, Didymellaceae, Didymosphaeria, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology

Abstract

The cosmopolitan plant genusClematiscontains many climbing species that can be found worldwide. The genus occurs in the wild and is grown commercially for horticulture. Microfungi onClematiswere collected from Belgium, China, Italy, Thailand and the UK. They are characterized by morphology and analyses of gene sequence data using an integrated species concept to validate identifications. The study revealed two new families, 12 new genera, 50 new species, 26 new host records with one dimorphic character report, and ten species are transferred to other genera. The new families revealed by multigene phylogeny are Longiostiolaceae and Pseudomassarinaceae in Pleosporales (Dothideomycetes). New genera areAnthodidymella(Didymellaceae),AnthosulcatisporaandParasulcatispora(Sulcatisporaceae),Fusiformispora(Amniculicolaceae),Longispora(Phaeosphaeriaceae),Neobyssosphaeria(Melanommataceae),Neoleptosporella(Chaetosphaeriales, generaincertae sedis),Neostictis(Stictidaceae),Pseudohelminthosporium(Neomassarinaceae),Pseudomassarina(Pseudomassarinaceae),Sclerenchymomyces(Leptosphaeriaceae) andXenoplectosphaerella(Plectosphaerellaceae). The newly described species areAlloleptosphaeria clematidis,Anthodidymella ranunculacearum,Anthosulcatispora subglobosa,Aquadictyospora clematidis,Brunneofusispora clematidis,Chaetosphaeronema clematidicola,C. clematidis,Chromolaenicola clematidis,Diaporthe clematidina,Dictyocheirospora clematidis,Distoseptispora clematidis,Floricola clematidis,Fusiformispora clematidis,Hermatomyces clematidis,Leptospora clematidis,Longispora clematidis,Massariosphaeria clematidis,Melomastia clematidis,M. fulvicomae,Neobyssosphaeria clematidis,Neoleptosporella clematidis,Neoroussoella clematidis,N. fulvicomae,Neostictis nigricans, Neovaginatispora clematidis,Parasulcatispora clematidis,Parathyridaria clematidis, P. serratifoliae,P. virginianae,Periconia verrucose,Phomatospora uniseriata,Pleopunctum clematidis,Pseudocapulatispora clematidis,Pseudocoleophoma clematidis,Pseudohelminthosporium clematidis,Pseudolophiostoma chiangraiense,P. clematidis,Pseudomassarina clematidis,Ramusculicola clematidis,Sarocladium clematidis,Sclerenchymomyces clematidis,Sigarispora clematidicola,S. clematidis,S. montanae,Sordaria clematidis,Stemphylium clematidis,Wojnowiciella clematidis,Xenodidymella clematidis,Xenomassariosphaeria clematidisandXenoplectosphaerella clematidis.The following fungi are recorded onClematisspecies for the first time:Angustimassarina rosarum,Dendryphion europaeum,Dermatiopleospora mariae,Diaporthe ravennica,D. rudis,Dichotomopilus ramosissimum,Dictyocheirospora xishuangbannaensis,Didymosphaeria rubi-ulmifolii,Fitzroyomyces cyperacearum,Fusarium celtidicola,Leptospora thailandica,Memnoniella oblongispora,Neodidymelliopsis longicolla,Neoeutypella baoshanensis,Neoroussoella heveae,Nigrograna chromolaenae,N. obliqua,Pestalotiopsis verruculosa,Pseudoberkleasmium chiangmaiense,Pseudoophiobolus rosae,Pseudoroussoella chromolaenae,P. elaeicola,Ramusculicola thailandica,Stemphylium vesicariumandTorula chromolaenae. The new combinations areAnthodidymella clematidis(≡ Didymella clematidis),A. vitalbina(≡ Didymella vitalbina),Anthosulcatispora brunnea(≡ Neobambusicola brunnea),Fuscohypha kunmingensis(≡ Plectosphaerella kunmingensis),Magnibotryascoma rubriostiolata(≡ Teichospora rubriostiolata),Pararoussoella mangrovei(≡ Roussoella mangrovei),Pseudoneoconiothyrium euonymi(≡ Roussoella euonymi),Sclerenchymomyces jonesii(≡ Neoleptosphaeria jonesii),Stemphylium rosae(≡ Pleospora rosae), andS. rosae-caninae(≡ Pleospora rosae-caninae). The microfungi onClematisis distributed in several classes of Ascomycota. The analyses are based on morphological examination of specimens, coupled with phylogenetic sequence data. To the best of our knowledge, the consolidated species concept approach is recommended in validating species.

Published

2020

25. Outline of Fungi and fungus-like taxa

Author

David L. Hawksworth, R. G. U. Jayalal, L. F. Zhang, G. A. da Silva, Samantha C. Karunarathna, Saowaluck Tibpromma, Kazuaki Tanaka, Saranyaphat Boonmee, I. V. Issi, Sajeewa S. N. Maharachchikumbura, Rajesh Jeewon, Oleg N. Shchepin, J. Ma, Fritz Oehl, P. B. Gannibal, Cristina Maria de Souza-Motta, Dhanushka N. Wanasinghe, Kunhiraman C. Rajeshkumar, A. A. Lateef, Ting-Chi Wen, L. K. T. Al-Ani, Kevin D. Hyde, Armin Mešić, Hans-Peter Grossart, Gabriela Heredia, Roshni Khare, Einar Timdal, Shubhi Avasthi, F. A. de Souza, Mounes Bakhshi, Richard A. Humber, Subhash Gaikwad, Dmitry V. Leontyev, Noha H. Youssef, Alexandre G. S. Silva-Filho, Sudhir Navathe, María Prieto, Marco Thines, Paul M. Kirk, Yuri Tokarev, Marc Stadler, P. O. Fiuza, André Aptroot, Damien Ertz, Monika C. Dayarathne, Julia Pawłowska, P. Liu, H. T. Lumbsch, Peter E. Mortimer, Elaine Malosso, Nalin N. Wijayawardene, Belle Damodara Shenoy, Huzefa A. Raja, Mikhail P. Zhurbenko, Somayeh Dolatabadi, Jos Houbraken, S. Mohammad, Zdenko Tkalčec, Andrei Tsurykau, Rampai Kodsueb, Mubashar Raza, Darbhe J. Bhat, Dsa Wijesundara, Jadson D. P. Bezerra, Javier Etayo, Walter P. Pfliegler, Leho Tedersoo, Jurga Motiejunaite, James D. Lawrey, Felipe Wartchow, Anusha H. Ekanayaka, Laura Selbmann, Sinang Hongsanan, Gothamie Weerakoon, Rafael F. Castañeda-Ruiz, Francis Q. Brearley, Enikő Horváth, R. L Zhao, B. O. Sharma, Y. Wang, Iván Sánchez-Castro, Martin Schnittler, Steven L. Stephenson, Y. Kang, Renate Radek, Eleni Gentekaki, Dagmar Triebel, F. R. Barbosa, Martina Réblová, Q. R. Li, Sayanh Somrithipol, Y. M. Li, D. K. A. Silva, L. Z. Tang, Hugo Madrid, Asha J. Dissanayake, Satinee Suetrong, Eric H. C. McKenzie, Mingkwan Doilom, E. S. Nassonova, J. C. Cavender, Neven Matočec, A. L. Firmino, R. K. Saxena, Olinto Liparini Pereira, J. Xu, V. Vázquez, M. Q. He, Xinlei Fan, Khadija Jobim, Martin Kukwa, Andrey Yurkov, R. F. Xu, K. Kolaríková, Lakmali S. Dissanayake, P. Alvarado, Rungtiwa Phookamsak, Dong-Qin Dai, Qing Tian, Ulrike Damm, D. W. Li, Pradeep K. Divakar, Jian-Kui Liu, Ajay Kumar Gautam, Viktor Papp, Peter M. Letcher, Pamela Rodriguez-Flakus, E. Kuhnert, F. Tian, I. Kusan, Makbule Erdoğdu, Alejandra Gabriela Becerra, B. T. Goto, Eric W.A. Boehm, K. Bensch, Sally C. Fryar, Yuri K. Novozhilov, Han Zhang, V. P. Hustad, André Luiz Cabral Monteiro de Azevedo Santiago, Danny Haelewaters, Gregorio Delgado, V. Dima, C. Y. Deng, Y. Z. Lu, Moslem Papizadeh, Ave Suija, Janusz Błaszkowski, Paul G. Mungai, Bryce Kendrick, Leonor Costa Maia, Gerhard Rambold, Adam Flakus, Alan J. L. Phillips, Josiane Santana Monteiro, Susumu Takamatsu, Ziraat Fakültesi, Makbule Erdoğdu / 0000-0001-8255-2041, Westerdijk Fungal Biodiversity Institute - Food and Indoor Mycology, Westerdijk Fungal Biodiversity Institute, Netherlands Institute for Neuroscience (NIN), Qujing Normal University, Abhilashi University, Jiwaji University, National Science and Technology Development Agency -NSTDA, University of Oslo, Universidade Federal da Paraíba, FRANCISCO ADRIANO DE SOUZA, CNPMS, Agroscope, Competence Div Plants & Plant Prod., Universidade Federal de Pernambuco, West Pomeranian University of Technology, Universidade Federal do Rio Grande do Norte, Universidade Federal de Mato Grosso, University of Ilorin, Kunming Institute of Botany, Mae Fah Luang University, ALVALAB, Shenzhen University, Hirosaki University, University of Electronic Science and Technology of China, Museu Paraense Emílio Goeldi, Leibnitz Institute of Freshwater Ecology and Inland Fisheries - IGB, University of Tartu, Helmholtz-Zentrum für Infektionsforschung GmbH, Institute of Microbiology Chinese Academy of Sciences, University of Mauritius, Russian Academy of Sciences, Universidad Rey Juan Carlos, University of Sri Lanka, K?r?ehir Ahi Evran University, Leibniz Institute, Ernst Moritz Arndt University Greifswald, Goethe University., USDA-ARS Emerging Pests and Pathogens Research, University of South Bohemia, National Fungal Culture Collection of India -NFCCI, State Key Laboratory of Mycology, Universidade Federal de Mato Grosso do Sul, Skovoroda Kharkiv National Pedagogical University, University Road, All-Russian Institute of Plant Protection, Universidade de Lisboa, University of Tuscia, University of Debrecen, Royal Botanic Gardens, Czech Academy of Sciences, University of North Carolina at Greensboro, Freie Universität Berlin, Szent István University, Eötvös Loránd University, Jiangxi Agricultural University, Flinders University, EMLab P&K Houston, Academy of Sciences, Chiang Mai University, Sabzevar University of New Technology, University of Warsaw, Pibulsongkram Rajabhat University, Universidad de Granada, Universidad Complutense de Madrid, CSIR-National Institute of Oceanography Regional Centre, Instituto de Investigaciones Fundamentales en AgriculturaTropical, BIOTEC, National Science and Technology Development Agency - NSTDA, Guizhou University, Valley Laboratory, Ru?er Boškovi? Institute, Pasteur Institute of Iran, Instituto de Ecolog? 'a A. C., Iranian Research Institute of Plant Protection, Oklahoma State University, Northwest Missouri State University, George Mason University, Universidade Federal de Uberlândia, The Natural History Museum, IES Zizur, Skorina Gomel State University, University of Málaga, Kenya Wildlife Service, Senckenberg Museum of Natural History Görlitz, Guizhou Medical University, Kunming University of Science and Technology, Universidad Nacional de Córdoba, Manchester Metropolitan University, Nature Research Centre, Agharkar Research Institute, National Institute of Fundamental Studies, Szafer Institute of Botany, Manaaki Whenua-Landcare Research, Jilin Agricultural University, Ohio University, Iranian Research Organization for Science and Technology -IROST, Guizhou Academy of Science, Universidade Federal de Viçosa, Beijing Forestry University, Leibniz University, Leibnitz Institute of Freshwater Ecology and Inland Fisheries -IGB, University of Baghdad, The University of Alabama, University of Arkansas, Botanic Garden Meise, The Field Museum, University of Gda?sk, Universidad Mayor, Mie University, Universität of Bayreuth, and Staatliche Naturwissenschaftliche Sammlungen Bayerns

Subjects

Plant Science, Blastocladiomycota, 030308 mycology & parasitology, purl.org/becyt/ford/1 [https], Glomeromycota, Genus, Neopereziida, Amblyosporida ord. nov, 0303 health sciences, Ascomycota, biology, ord. nov, Basal clades, Classification, FOUR NEW TAXA, GEN. NOV, CELLULAR SLIME-MOLDS, POLAR TUBE, SP.-NOV, Leotiomycetes, four new taxa, ascomycota, basal clades, basidiomycota, classification, emendation, microsporidia, Neopereziida ord. nov, Ovavesiculida ord. nov, Protosporangiaceae fam. nov, Redonographaceae stat nov, MOLECULAR PHYLOGENY, Four new taxa, BASAL CLADES, GENERIC NAMES, CLASSIFICATION, 03 medical and health sciences, Botany, MICROSPORIDIAN, NATURAL CLASSIFICATION, purl.org/becyt/ford/1.6 [https], Biology, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Fungo, Entomophthoromycota, Phylum, Basidiomycota, Biology and Life Sciences, Emendation, 15. Life on land, biology.organism_classification, SUB-ANTARCTIC ISLANDS, Microsporidia, Polar tube, SP-NOV, Amblyosporidae, LEVEL PHYLOGENETIC CLASSIFICATION

Abstract

This article provides an outline of the classification of the kingdom Fungi (including fossil fungi. i.e. dispersed spores, mycelia, sporophores, mycorrhizas). We treat 19 phyla of fungi. These are Aphelidiomycota, Ascomycota, Basidiobolomycota, Basidiomycota, Blastocladiomycota, Calcarisporiellomycota, Caulochytriomycota, Chytridiomycota, Entomophthoromycota, Entorrhizomycota, Glomeromycota, Kickxellomycota, Monoblepharomycota, Mortierellomycota, Mucoromycota, Neocallimastigomycota, Olpidiomycota, Rozellomycota and Zoopagomycota. The placement of all fungal genera is provided at the class-, order- and family-level. The described number of species per genus is also given. Notes are provided of taxa for which recent changes or disagreements have been presented. Fungus-like taxa that were traditionally treated as fungi are also incorporated in this outline (i.e. Eumycetozoa, Dictyosteliomycetes, Ceratiomyxomycetes and Myxomycetes). Four new taxa are introduced: Amblyosporida ord. nov. Neopereziida ord. nov. and Ovavesiculida ord. nov. in Rozellomycota, and Protosporangiaceae fam. nov. in Dictyosteliomycetes. Two different classifications (in outline section and in discussion) are provided for Glomeromycota and Leotiomycetes based on recent studies. The phylogenetic reconstruction of a four-gene dataset (18S and 28S rRNA, RPB1, RPB2) of 433 taxa is presented, including all currently described orders of fungi., Nalin N. Wijayawardene thanks Mushroom Research Foundation and National Science Foundation of China (No. NSFC 31950410558) for financially supporting this project. Kevin D. Hyde acknowledges the Foreign Experts Bureau of Yunnan Province, Foreign Talents Program (2018; grant no. YNZ2018002), Thailand Research grants entitled Biodiversity, phylogeny and role of fungal endophytes on above parts of Rhizophora apiculata and Nypa fruticans (grant no: RSA5980068), the future of specialist fungi in a changing climate: baseline data for generalist and specialist fungi associated with ants, Rhododendron species and Dracaena species (grant no: DBG6080013), Impact of climate change on fungal diversity and biogeography in the Greater Mekong Subregion (grant no: RDG6130001). H.T. Lumbsch thanks support by the Grainger Bioinformatics Center. E. Malosso is grateful to CAPES for financial support (grant no. 88881.062172/2014-01). B.T. Goto, G.A. Silva and K. Jobim, L.C. Maia acknowledges CNPq (Brazilian Scientific Council, grants no. 465.420/2014-1, 307.129/2015-2 and 408011/2016-5) and CAPES for support. The study was partially supported by the National Science Centre, Poland, under Grants No. 2015/17/D/NZ8/00778 and 2017/25/B/NZ8/00473 to Julia Pawłowska. The research of Martin Kukwa received support from the National Science Centre (NCN) in Poland (project no 2015/17/B/NZ8/02441). Alan J.L. Phillips acknowledges the support from UID/MULTI/04046/2019 Research Unit grant from FCT, Portugal to BioISI. H. Zhang is financially supported by the National Natural Science Foundation of China (Project ID: NSF 31500017). S. Boonmee would like to thank the Thailand Research Fund (Project No. TRG6180001). Dong-Qin Dai and Li-Zhou Tang would like to thank the National Natural Science Foundation of China (No. NSFC 31760013, NSFC 31260087, NSFC 31460561), the Scientific Research Foundation of Yunnan Provincial Department of Education (2017ZZX186) and the Thousand Talents Plan, Youth Project of Yunnan Provinces for support. R. Phookamsak, M. Doilom, D. N. Wanasinghe, S.C. Karunarathna and J.C. Xu express sincere appreciations to Key Research Program of Frontier Sciences of the Chinese Academy of Sciences (grant no. QYZDY-SSW-SMC014) for research financial support. R. Phookamsak thanks the Yunnan Provincial Department of Human Resources and Social Security (grant no. Y836181261), Chiang Mai University and National Science Foundation of China (NSFC) project code 31850410489 for research financial support. S.C. Kaunarathna thanks CAS President’s International Fellowship Initiative (PIFI) for funding his postdoctoral research (No. 2018PC0006) and the National Science Foundation of China (NSFC) for funding this work under the project code 31851110759. S. Tibpromma would like to thank the International Postdoctoral Exchange Fellowship Program (number Y9180822S1), CAS President’s International Fellowship Initiative (PIFI) (number 2020PC0009), China Postdoctoral Science Foundation and the Yunnan Human Resources, and Social Security Department Foundation for funding her postdoctoral research. Yuri S. Tokarev, Elena S. Nassonova and Irma V. Issi are indebtful to Yuliya Y. Sokolova (Institute of Cytology RAS, St. Petersbug, Russia) and Anastasia V. Simakova (Tomsk State University, Tomsk, Russia) for kind permission of reproduction of electron microscopy images of Metchnikovella incurvata and Crepidulospora beklemishevi, respectively. Yuri S. Tokarev and Irma V. Issi thank Russian Foundation of Basic Research, grant number 17-04-00871 (taxonomy of Rozellomycota). Elena S. Nassonova thank Russian Foundation of Basic Research, grant number 18-04-01359 (early evolution of Microsporidia, phylogeny of Metchnikovellida). Adam Flakus and Pamela Rodriguez-Flakus are greatly indebted to all staff of the Herbario Nacional de Bolivia, Instituto de Ecología, Universidad Mayor de San Andrés, La Paz and the SERNAP (http://sernap.gob.bo), for their generous cooperation providing permits, assistance and facilities support for scientific studies. The research of AF and PRF were financially supported by the National Science Centre (NCN) in Poland (DEC-2013/11/D/NZ8/03274). Adam Flakus and Pamela Rodriguez-Flakus received additional support under statutory funds from the W. Szafer Institute of Botany, Polish Academy of Sciences, Krakow, Poland. The authors would like to thank Yunnan Innovation Platform for Development and Utilization of Symbiotic Fungi Resources for finance support. Li-Fang Zhang would like to thank grant-in-aid from Science and Technology Department of Yunnan Province (2018FD080) for finance support. Chun-Ying Deng thanks the Biodiversity Survey and Assessment Project of the Ministry of Ecology and Environment, China (2019HJ2096001006). Yingqian Kang would like to thank Guizhou Scientific Plan Project [(2019) 2873]; Excellent Youth Talent Training Project of Guizhou Province [(2017) 5639]; Guiyang Science and Technology Project [(2017) No. 5-19]; Talent Base Project of Guizhou Province, China [FCJD2018-22]; Research Fund of Education Bureau of Guizhou Province, China [(2018) 481]. D. N. Wanasinghe would like to thank the CAS President’s International Fellowship Initiative (PIFI) for funding his postdoctoral research (number 2019PC0008), the National Science Foundation of China and the Chinese Academy of Sciences for financial support under the following grants: 41761144055, 41771063 and Y4ZK111B01. Yuri K. Novozhilov and Oleg N. Shchepin acknowledge support from the Russian Foundation of Basic Research, project 18-04-01232 А. Ivana Kušan, Neven Matočec, Armin Mešić and Zdenko Tkalčec are grateful to Croatian Science Foundation for their financial support under the project grant HRZZ-IP-2018-01-1736 (ForFungiDNA). K. Tanaka would like to thank the Japan Society for the Promotion of Science (JSPS 19K06802)

Published

2020

26. Pathogenicity of five Botryosphaeriaceae species isolated from Tectona grandis (teak): the pathogenic potential of Lasiodiplodia species

Author

S. Nalumpang, K. Yan, Kevin D. Hyde, H. Zhang, Mingkwan Doilom, Alan J. L. Phillips, J. C. Xu, C. To-anun, and Wei Dong

Subjects

Lasiodiplodia species, biology, Tectona, Botany, General Medicine, Botryosphaeriaceae, biology.organism_classification, Pathogenicity

Published

2020

27. Refined families of Dothideomycetes: Dothideomycetidae and Pleosporomycetidae

Author

Janith V. S. Aluthmuhandiram, Dhanushka N. Wanasinghe, E. B. G. Jones, Yin Lu, Cécile Gueidan, Jadson D. P. Bezerra, R. Phookamsak, Dulanjalee Harishchandra, Jutamart Monkai, Subashini C. Jayasiri, Jian-Kui Liu, D. S. Sandamali, Milan C. Samarakoon, Saranyaphat Boonmee, Satinee Suetrong, Kasun M. Thambugala, Ishara S. Manawasinghe, N. Chaiwan, Sirinapa Konta, G. Liu, Kwang Hee Moon, K. W. T. Chethana, Achala R. Rathnayaka, V. Venkateswara Sarma, Robert Lücking, M. Niranjan, Dan-Feng Bao, Y. Feng, Emmanuël Sérusiaux, N. I. de Silva, Anuruddha Karunarathna, Kevin D. Hyde, Nalin N. Wijayawardene, Danushka S. Tennakoon, Hai-Xia Wu, Subodini N. Wijesinghe, Mingkwan Doilom, Haiyan Zhang, Darbhe J. Bhat, Hiroyuki Kashiwadani, Alan J. L. Phillips, Jing Yang, Chitrabhanu S. Bhunjun, Jianchu Xu, Junyan Zhang, H. B. Jiang, S. N. Zhang, Sergio Pérez-Ortega, Pranami D. Abeywickrama, Rajesh Jeewon, André Aptroot, Ave Suija, Ausana Mapook, Felix Schumm, Digvijayini Bundhun, Damien Ertz, Monika C. Dayarathne, Ning-Guo Liu, B. Devadatha, Xiang Yu Zeng, Chanokned Senwanna, Qing Tian, Putarak Chomnunti, S. Hongsanan, J. S. Zheng, Chayanard Phukhamsakda, Dhandevi Pem, Zong-Long Luo, Hiran A. Ariyawansa, Ning Xie, Anusha H. Ekanayaka, Ruvishika S. Jayawardena, Shu-Hua Jiang, Dong-Qin Dai, Chada Norphanphoun, Vinodhini Thiyagaraja, Ricardo Miranda-González, Saowaluck Tibpromma, Asha J. Dissanayake, and Eric H. C. McKenzie

Subjects

Dothideales, Hysteriales, Myriangiales, 500 Naturwissenschaften und Mathematik::570 Biowissenschaften, Biologie::579 Mikroorganismen, Pilze, Algen, biology, Dothideomycetidae, Plant Science, Dothideomycetes, Capnodiales, biology.organism_classification, 6 new taxa, Pleosporomycetidae, Evolutionary biology, Mytilinidiales, new family, Pleosporales, Taxonomy (biology), Gloniales, Ecology, Evolution, Behavior and Systematics

Abstract

The class Dothideomycetes is the largest and most ecologically diverse class of fungi, comprising endophytes, epiphytes, saprobes, human and plant pathogens, lichens, and lichenicolous, nematode trapping and rock-inhabiting taxa. Members of this class are mainly characterized by bitunicate asci with fissitunicate dehiscence, and occur on broad range of hosts in aquatic and terrestrial habitats. Since the last monograph of families of Dothideomycetes in 2013, numerous novel species, genera, families and orders have been discovered. This has expanded information which has led to the modern classification in Dothideomycetes. In this paper, we provide a refined updated document on families of Dothideomycetes with emphasis on Dothideomycetidae and Pleosporomycetidae. We accept three orders with 25 families and four orders with 94 families in Dothideomycetidae and Pleosporomycetidae, respectively. The new family Paralophiostomataceae is introduced in Pleosporales. Each family is provided with an updated description, notes, including figures to represent the morphology, list of accepted genera, and economic and ecological significances. We also provide an overall phylogenetic tree of families in Dothideomycetes based on combined analysis of LSU, SSU, rpb-2 and tefl sequence data, and phylogenetic trees for each order in Dothideomycetidae and Pleosporomycetidae. Family-level trees are provided for the families which include several genera such as Mycosphaerellaceae and Teratosphaeriaceae. Two new genera (Ligninsphaeriopsis and Paralophiostoma) are introduced. Five new species (Biatrisopora borsei, Comoclathris galatellae, Ligninsphaeriopsis thailandica, Paralophiostoma hysterioides and Torula thailandica) are introduced based on morphology and phylogeny, together with nine new reports and seven new collections from different families.

Published

2020

28. Importance of Molecular Data to Identify Fungal Plant Pathogens and Guidelines for Pathogenicity Testing Based on Koch’s Postulates

Author

Ruvishika S. Jayawardena, Itthayakorn Promputtha, Alan J. L. Phillips, Chitrabhanu S. Bhunjun, and Kevin D. Hyde

Subjects

Microbiology (medical), General Immunology and Microbiology, Host (biology), Morphology (biology), Review, Computational biology, Disease, Biology, phylogeny, plant disease assessment, symbols.namesake, Infectious Diseases, Taxon, image analysis, Koch's postulates, symbols, Immunology and Allergy, pathogenicity, Medicine, Identification (biology), Bradford Hill criteria, disease severity, Molecular Biology, Organism

Abstract

Fungi are an essential component of any ecosystem, but they can also cause mild and severe plant diseases. Plant diseases are caused by a wide array of fungal groups that affect a diverse range of hosts with different tissue specificities. Fungi were previously named based only on morphology and, in many cases, host association, which has led to superfluous species names and synonyms. Morphology-based identification represents an important method for genus level identification and molecular data are important to accurately identify species. Accurate identification of fungal pathogens is vital as the scientific name links the knowledge concerning a species including the biology, host range, distribution, and potential risk of the pathogen, which are vital for effective control measures. Thus, in the modern era, a polyphasic approach is recommended when identifying fungal pathogens. It is also important to determine if the organism is capable of causing host damage, which usually relies on the application of Koch’s postulates for fungal plant pathogens. The importance and the challenges of applying Koch’s postulates are discussed. Bradford Hill criteria, which are generally used in establishing the cause of human disease, are briefly introduced. We provide guidelines for pathogenicity testing based on the implementation of modified Koch’s postulates incorporating biological gradient, consistency, and plausibility criteria from Bradford Hill. We provide a set of protocols for fungal pathogenicity testing along with a severity score guide, which takes into consideration the depth of lesions. The application of a standard protocol for fungal pathogenicity testing and disease assessment in plants will enable inter-studies comparison, thus improving accuracy. When introducing novel plant pathogenic fungal species without proving the taxon is the causal agent using Koch’s postulates, we advise the use of the term associated with the “disease symptoms” of “the host plant”. Where possible, details of disease symptoms should be clearly articulated.

Published

2021

29. One stop shop III: taxonomic update with molecular phylogeny for important phytopathogenic genera: 51–75 (2019)

Author

Ruvishika S. Jayawardena, Kevin D. Hyde, Eric H. C. McKenzie, Rajesh Jeewon, Alan J. L. Phillips, Rekhani H. Perera, Nimali I. de Silva, Sajeewa S. N. Maharachchikumburua, Milan C. Samarakoon, Anusha H. Ekanayake, Danushka S. Tennakoon, Asha J. Dissanayake, Chada Norphanphoun, Chuangen Lin, Ishara S. Manawasinghe, Qian Tian, Rashika Brahmanage, Putarak Chomnunti, Sinang Hongsanan, Subashini C. Jayasiri, F. Halleen, Chitrabhanu S. Bhunjun, Anuruddha Karunarathna, and Yong Wang

Subjects

Ecology, Ecology, Evolution, Behavior and Systematics

Published

2019

30. Fungal diversity notes 1036–1150: taxonomic and phylogenetic contributions on genera and species of fungal taxa

Author

Anuruddha Karunarathna, Touny Sorvongxay, Jacques Fournier, Martina Réblová, Sally C. Fryar, Yuan-Pin Xiao, Erio Camporesi, Rashika S. Brahmanage, Saranyaphat Boonmee, Thuong T. T. Nguyen, Chayanard Phukhamsakda, Sinang Hongsanan, William Kalhy Silva Xavier, Janith V. S. Aluthmuhandiram, Sun Jeong Jeon, Jing Yang, Yong Zhong Lu, Jos Houbraken, Hong-Bo Jiang, Jadson D. P. Bezerra, José Ewerton Felinto dos Santos, Anusha H. Ekanayaka, Yusufjon Gafforov, Napalai Chaiwan, D. Jayarama Bhat, V.P. Abreu, Jie Chen, Sheng-Nan Zhang, Helio Longoni Plautz, Nimali I. de Silva, Kevin D. Hyde, De-Ping Wei, Guangshuo Li, Rajesh Jeewon, Vinodhini Thiyagaraja, Jianchu Xu, Jens Christian Frisvad, André Aptroot, Rekhani H. Perera, Rui-Lin Zhao, Hyang Burm Lee, Kunthida Phutthacharoen, Neiva Tinti de Oliveira, Jian-Kui Liu, Milan C. Samarakoon, Robert Lücking, Thilini Chethana, Paul M. Kirk, Zong-Long Luo, Ruvishika S. Jayawardena, Peter E. Mortimer, Junmin Liang, Subashini C. Jayasiri, Dulanjalee Harishchandra, Digvijayini Bundhun, Buyck Bart, Renan do Nascimento Barbosa, Chada Norphanphoun, Damien Ertz, Monika C. Dayarathne, Samantha C. Karunarathna, Paras Nath Singh, Itthayakorn Promputtha, Sajeewa S. N. Maharachchikumbura, André Wilson Campos Rosado, Vinit Kumar, Jana Nekvindová, Eleni Gentekaki, Marcela Eugenia da Silva Cáceres, Yu Cheng Dai, Qiu Ju Shang, Hye Yeon Mun, Wei Dong, Xiang Yu Zeng, Armin Mešić, Indunil C. Senanayake, Chuan Gen Lin, Tuula Niskanen, E. B. Gareth Jones, Kare Liimatainen, Dan Feng Bao, Sirinapa Konta, Thays Gabrielle Lins de Oliveira, Olinto Liparini Pereira, Jin-Feng Zhang, Kasun M. Thambugala, Xiao Hong Ji, Timur S. Bulgakov, Pranami D. Abeywickrama, Ishara S. Manawasinghe, Oliane Maria Correia Magalhães, Qi Zhao, Walter Rossi, Cristina Maria de Souza-Motta, Xue Mei Tian, Valérie Hofstetter, Putarak Chomnunti, Guo Jie Li, Sanjay K. Singh, Ming Zeng, Adriene Mayra Soares, Dhandevi Pem, Ishani D. Goonasekara, Helen Maria Pontes Sotão, Frank Bungartz, Mingkwan Doilom, Rungtiwa Phookamsak, Ji Ye Yan, Emile Randrianjohany, Zdenko Tkalčec, Marco Leonardi, Chang Hsin Kuo, Dhanushka N. Wanasinghe, Ting-Chi Wen, Shi Ke Huang, Erandi Yasanthika, Danushka S. Tennakoon, Saisamorn Lumyong, Alan J. L. Phillips, Tatiana Baptista Gibertoni, Lei Cai, Westerdijk Fungal Biodiversity Institute - Food and Indoor Mycology, and Westerdijk Fungal Biodiversity Institute

Subjects

Leotiomycetes, Ascomycota, 71 new taxa, Basidiomycota, Dothideomycetes, Eurotiomycetes, Lecanoromycetes, Pezizomycetes, Phylogeny, Taxonomy, s<%2Fbold>%22">Dothideomycetes, Botany, Ecology, Evolution, Behavior and Systematics, Cantharellus, Fomitiporia, Ecology, biology, Coprinopsis, biology.organism_classification, Russula, Cortinarius, Dothiorella, Buellia

Abstract

This article is the tenth series of the Fungal Diversity Notes, where 114 taxa distributed in three phyla, ten classes, 30 orders and 53 families are described and illustrated. Taxa described in the present study include one new family (viz. Pseudoberkleasmiaceae in Dothideomycetes), five new genera (Caatingomyces, Cryptoschizotrema, Neoacladium, Paramassaria and Trochilispora) and 71 new species, (viz. Acrogenospora thailandica, Amniculicola aquatica, A. guttulata, Angustimassarina sylvatica, Blackwellomyces lateris, Boubovia gelatinosa, Buellia viridula, Caatingomyces brasiliensis, Calophoma humuli, Camarosporidiella mori, Canalisporium dehongense, Cantharellus brunneopallidus, C. griseotinctus, Castanediella meliponae, Coprinopsis psammophila, Cordyceps succavus, Cortinarius minusculus, C. subscotoides, Diaporthe italiana, D. rumicicola, Diatrypella delonicis, Dictyocheirospora aquadulcis, D. taiwanense, Digitodesmium chiangmaiense, Distoseptispora dehongensis, D. palmarum, Dothiorella styphnolobii, Ellisembia aurea, Falciformispora aquatic, Fomitiporia carpinea, F. lagerstroemiae, Grammothele aurantiaca, G. micropora, Hermatomyces bauhiniae, Jahnula queenslandica, Kamalomyces mangrovei, Lecidella yunnanensis, Micarea squamulosa, Muriphaeosphaeria angustifoliae, Neoacladium indicum, Neodidymelliopsis sambuci, Neosetophoma miscanthi, N. salicis, Nodulosphaeria aquilegiae, N. thalictri, Paramassaria samaneae, Penicillium circulare, P. geumsanense, P. mali-pumilae, P. psychrotrophicum, P. wandoense, Phaeoisaria siamensis, Phaeopoacea asparagicola, Phaeosphaeria penniseti, Plectocarpon galapagoense, Porina sorediata, Pseudoberkleasmium chiangmaiense, Pyrenochaetopsis sinensis, Rhizophydium koreanum, Russula prasina, Sporoschisma chiangraiense, Stigmatomyces chamaemyiae, S. cocksii, S. papei, S. tschirnhausii, S. vikhrevii, Thysanorea uniseptata, Torula breviconidiophora, T. polyseptata, Trochilispora schefflerae and Vaginatispora palmae). Further, twelve new combinations (viz. Cryptoschizotrema cryptotrema, Prolixandromyces australi, P. elongatus, P. falcatus, P. longispinae, P. microveliae, P. neoalardi, P. polhemorum, P. protuberans, P. pseudoveliae, P. tenuistipitis and P. umbonatus), an epitype is chosen for Cantharellus goossensiae, a reference specimen for Acrogenospora sphaerocephala and new synonym Prolixandromyces are designated. Twenty-four new records on new hosts and new geographical distributions are also reported (i.e. Acrostalagmus annulatus, Cantharellus goossensiae, Coprinopsis villosa, Dothiorella plurivora, Dothiorella rhamni, Dothiorella symphoricarposicola, Dictyocheirospora rotunda, Fasciatispora arengae, Grammothele brasiliensis, Lasiodiplodia iraniensis, Lembosia xyliae, Morenoina palmicola, Murispora cicognanii, Neodidymelliopsis farokhinejadii, Neolinocarpon rachidis, Nothophoma quercina, Peroneutypa scoparia, Pestalotiopsis aggestorum, Pilidium concavum, Plagiostoma salicellum, Protofenestella ulmi, Sarocladium kiliense, Tetraploa nagasakiensis and Vaginatispora armatispora).

Published

2019

31. One stop shop II: taxonomic update with molecular phylogeny for important phytopathogenic genera: 26–50 (2019)

Author

K. W. T. Chethana, Rajesh Jeewon, Ji-Chuan Kang, Wei Dong, L. M. Carris, Roger G. Shivas, Masoomeh Ghobad-Nejhad, Gladstone Alves da Silva, Dhanushka N. Wanasinghe, Asha J. Dissanayake, P. Abeywikrama, De-Ping Wei, Kevin D. Hyde, Sinang Hongsanan, Alistair R. McTaggart, Ruvishika S. Jayawardena, Rekhani H. Perera, Ning-Guo Liu, Alan J. L. Phillips, Tatiana Baptista Gibertoni, Naritsada Thongklang, Kunthida Phutthacharoen, Nalin N. Wijayawardena, Kyryll G. Savchenko, José Ribamar C. Oliveira-Filho, and Subashini C. Jayasiri

Subjects

Phyllosticta, food.ingredient, Corticiaceae, Fomitiporia, Ecology, biology, biology.organism_classification, Entyloma, Neofusicoccum, Calonectria, food, Botany, Erythricium, Botryosphaeria, Ecology, Evolution, Behavior and Systematics

Abstract

This paper is the second in a series focused on providing a stable platform for the taxonomy of phytopathogenic fungi. It focuses on 25 phytopathogenic genera: Alternaria, Bipolaris, Boeremia, Botryosphaeria, Calonectria, Coniella, Corticiaceae, Curvularia, Elsinoe, Entyloma, Erythricium, Fomitiporia, Fulviformes, Laetisaria, Limonomyces, Neofabraea, Neofusicoccum, Phaeoacremonium, Phellinotus, Phyllosticta, Plenodomus, Pseudopyricularia, Tilletia, Venturia and Waitea, using recent molecular data, up to date names and the latest taxonomic insights. For each genus a taxonomic background, diversity aspects, species identification and classification based on molecular phylogeny and recommended genetic markers are provided. In this study, varieties of the genus Boeremia have been elevated to species level. Botryosphaeria, Bipolaris, Curvularia, Neofusicoccum and Phyllosticta that were included in the One Stop Shop 1 paper are provided with updated entries, as many new species have been introduced to these genera.

Published

2019

32. Endophytic Diaporthe Associated With Citrus grandis cv. Tomentosa in China

Author

Mei Luo, Zhangyong Dong, Alan J. L. Phillips, Kevin D. Hyde, Yongxin Shu, Meimei Xiang, Ishara S. Manawasinghe, Yinghua Huang, and Asha J. Dissanayake

Subjects

0106 biological sciences, Microbiology (medical), lcsh:QR1-502, Biological pest control, two new species, Biology, phylogeny, 01 natural sciences, Microbiology, lcsh:Microbiology, 030308 mycology & parasitology, 03 medical and health sciences, taxonomy, Diaporthe, Phylogenetics, Botany, Internal transcribed spacer, Diaporthales, Original Research, 0303 health sciences, Phylogenetic tree, Ribosomal RNA, biology.organism_classification, nine new host records, Taxonomy (biology), 010606 plant biology & botany

Abstract

Diaporthe species are associated with Citrus as endophytes, pathogens, and saprobes worldwide. However, little is known about Diaporthe as endophytes in Citrus grandis in China. In this study, 24 endophytic Diaporthe isolates were obtained from cultivated C. grandis cv. “Tomentosa” in Huazhou, Guangdong Province in 2019. The nuclear ribosomal internal transcribed spacer (ITS), partial sequences of translation elongation factor 1-α (tef1), β-tubulin (tub2), and partial calmodulin (cal) gene regions were sequenced and employed to construct phylogenetic trees. Based on morphology and combined multigene phylogeny, eleven Diaporthe species were identified including two new species, Diaporthe endocitricola and D. guangdongensis. These are the first report of D. apiculata, D. aquatica, D. arecae, D. biconispora, D. limonicola, D. masirevicii, D. passifloricola, D. perseae, and D. sennae on C. grandis. This study provides the first intensive study of endophytic Diaporthe species on C. grandis cv. tomentosa in China. These results will improve the current knowledge of Diaporthe species associated with C. grandis. The results obtained in this study will also help to understand the potential pathogens and biocontrol agents and to develop a platform in disease management.

Published

2021

33. Fungal diversity notes 1277–1386: taxonomic and phylogenetic contributions to fungal taxa

Author

Hai-Sheng Yuan, Xu Lu, Yu-Cheng Dai, Kevin D. Hyde, Yu-He Kan, Ivana Kušan, Shuang-Hui He, Ning-Guo Liu, V. Venkateswara Sarma, Chang-Lin Zhao, Bao-Kai Cui, Nousheen Yousaf, Guangyu Sun, Shu-Yan Liu, Fang Wu, Chuan-Gen Lin, Monika C. Dayarathne, Tatiana Baptista Gibertoni, Lucas B. Conceição, Roberto Garibay-Orijel, Margarita Villegas-Ríos, Rodolfo Salas-Lizana, Tie-Zheng Wei, Jun-Zhi Qiu, Ze-Fen Yu, Rungtiwa Phookamsak, Ming Zeng, Soumitra Paloi, Dan-Feng Bao, Pranami D. Abeywickrama, De-Ping Wei, Jing Yang, Ishara S. Manawasinghe, Dulanjalee Harishchandra, Rashika S. Brahmanage, Nimali I. de Silva, Danushka S. Tennakoon, Anuruddha Karunarathna, Yusufjon Gafforov, Dhandevi Pem, Sheng-Nan Zhang, André L. C. M. de Azevedo Santiago, Jadson Diogo Pereira Bezerra, Bálint Dima, Krishnendu Acharya, Julieta Alvarez-Manjarrez, Ali H. Bahkali, Vinod K. Bhatt, Tor Erik Brandrud, Timur S. Bulgakov, E. Camporesi, Ting Cao, Yu-Xi Chen, Yuan-Yuan Chen, Bandarupalli Devadatha, Abdallah M. Elgorban, Long-Fei Fan, Xing Du, Liu Gao, Camila Melo Gonçalves, Luis F. P. Gusmão, Naruemon Huanraluek, Margita Jadan, Ruvishika S. Jayawardena, Abdul Nasir Khalid, Ewald Langer, Diogo X. Lima, Nelson Correia de Lima-Júnior, Carla Rejane Sousa de Lira, Jian-Kui (Jack) Liu, Shun Liu, Saisamorn Lumyong, Zong-Long Luo, Neven Matočec, M. Niranjan, José Ribamar Costa Oliveira-Filho, Viktor Papp, Eduardo Pérez-Pazos, Alan J. L. Phillips, Peng-Lei Qiu, Yihua Ren, Rafael F. Castañeda Ruiz, Kamal C. Semwal, Karl Soop, Carlos A. F. de Souza, Cristina Maria Souza-Motta, Li-Hua Sun, Meng-Le Xie, Yi-Jian Yao, Qi Zhao, and Li-Wei Zhou

Subjects

0303 health sciences, 03 medical and health sciences, 110 taxa, Agaricomycetes, Ascomycota, Basidiomycota, Mucoromycota, New combinations, New genera, New species, Phylogeny, Taxonomy, Ecology, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 030308 mycology & parasitology

Abstract

This is the twelfth contribution to the Fungal Diversity Notes series on fungal taxonomy, based on materials collected from many countries which were examined and described using the methods of morphology, anatomy, and strain culture, combined with DNA sequence analyses. 110 taxa are described and illustrated, including five new genera, 92 new species, eight new combinations and other taxonomic contributions (one new sequenced species, one new host and three new records) which are accommodated in 40 families and 1 incertae sedis in Dothideomycetes. The new genera are Amyloceraceomyces, Catenuliconidia, Hansenopezia, Ionopezia and Magnopulchromyces. The new species are Amyloceraceomyces angustisporus, Amylocorticium ellipsosporum, Arthrinium sorghi, Catenuliconidia uniseptata, Clavulina sphaeropedunculata, Colletotrichum parthenocissicola, Coniothyrium triseptatum, Cortinarius indorusseus, C. paurigarhwalensis, C. sinensis, C. subsanguineus, C. xiaojinensis, Diaporthe pimpinellae, Dictyosporella guizhouensis, Diplodia torilicola, Fuscoporia marquesiana, F. semiarida, Hansenopezia decora, Helicoarctatus thailandicus, Hirsutella hongheensis, Humidicutis brunneovinacea, Lentaria gossypina, L. variabilis, Lycoperdon lahorense, L. pseudocurtisii, Magnopulchromyces scorpiophorus, Moelleriella gracilispora, Neodevriesia manglicola, Neodidymelliopsis salvia, N. urticae, Neoroussoella magnoliae, Neottiella gigaspora, Ophiosphaerella chiangraiensis, Phaeotremella yunnanensis, Podosphaera yulii, Rigidoporus juniperinus, Rhodofomitopsis pseudofeei, Russula benghalensis, Scleroramularia vermispora, Scytinopogon minisporus, Sporormurispora paulsenii, Thaxteriellopsis obliqus, Tomentella asiae- orientalis, T. atrobadia, T. atrocastanea, T. aureomarginata, T. brevis, T. brunneoflava, T. brunneogrisea, T. capitatocystidiata, T. changbaiensis, T. citrinocystidiata, T. coffeae, T. conclusa, T. cystidiata, T. dimidiata, T. duplexa, T. efibulata, T. efibulis, T. farinosa, T. flavidobadia, T. fuscocrustosa, T. fuscofarinosa, T. fuscogranulosa, T. fuscopelliculosa, T. globospora, T. gloeocystidiata, T. griseocastanea, T. griseofusca, T. griseomarginata, T. inconspicua, T. incrustata, T. interrupta, T. liaoningensis, T. longiaculeifera, T. longiechinuli, T. megaspora, T. olivacea, T. olivaceobrunnea, T. pallidobrunnea, T. pallidomarginata, T. parvispora, T. pertenuis, T. qingyuanensis, T. segregata, T. separata, T. stipitata, T. storea, Trichoderma ceratophylletum, Tyromyces minutulus, Umbelopsis heterosporus and Xylolentia reniformis. The new combinations are Antrodiella descendena, Chloridium macrocladum, Hansenopezia retrocurvata, Rhodofomitopsis monomitica, Rh. oleracea, Fuscoporia licnoides, F. scruposa and Ionopezia gerardii. A new sequenced species (Graphis supracola), one new host (Aplosporella prunicola) and three new geographical records (Golovinomyces monardae, Paradictyoarthrinium diffractum and Prosthemium betulinum), are reported.

Published

2020

34. Fungal diversity notes 840–928: micro-fungi associated with Pandanaceae

Author

Mingkwan Doilom, Rungtiwa Phookamsak, Samiullah Khan, Alvin M. C. Tang, D. Jayarama Bhat, Saowaluck Tibpromma, Peter E. Mortimer, Asha J. Dissanayake, Eric H. C. McKenzie, Alan J. L. Phillips, Samantha C. Karunarathna, Sajeewa S. N. Maharachchikumbura, Kevin D. Hyde, Jianchu Xu, Danushka S. Tennakoon, Dhanushka N. Wanasinghe, Milan C. Samarakoon, Ruvishika S. Jayawardena, and Itthayakorn Promputtha

Subjects

0301 basic medicine, Lasiodiplodia, Freycinetia, Ecology, biology, Stictis, Dothideomycetes, Nectriaceae, Sordariomycetes, 030108 mycology & parasitology, Hyphomycetes, biology.organism_classification, 03 medical and health sciences, 030104 developmental biology, Botany, Ecology, Evolution, Behavior and Systematics, Pandanaceae

Abstract

This paper provides illustrated descriptions of micro-fungi newly found on Pandanaceae in China and Thailand. The fungi are accommodated in 31 families. New taxa described include a new family, seven new genera, 65 new species, 16 previously known species. A new family: Malaysiascaceae (Glomerellales). New genera are Acremoniisimulans (Plectosphaerellaceae), Pandanaceomyces, Pseudoachroiostachy (Nectriaceae), Pseudohyaloseta (Niessliaceae), Pseudoornatispora (Stachybotriaceae) and Yunnanomyces (Sympoventuriaceae). New species are Acremoniisimulans thailandensis, Beltrania krabiensis, Beltraniella pandanicola, B. thailandicus, Canalisporium krabiense, C. thailandensis, Clonostachys krabiensis, Curvularia chonburiensis, C. pandanicola, C. thailandicum, C. xishuangbannaensis, Cylindrocladiella xishuangbannaensis, Dictyochaeta pandanicola, Dictyocheirospora nabanheensis, D. pandanicola, D. xishuangbannaensis, Dictyosporium appendiculatum, Di. guttulatum, Di. hongkongensis, Di. krabiense, Di. pandanicola, Distoseptispora thailandica, D. xishuangbannaensis, Helicoma freycinetiae, Hermatomyces biconisporus, Lasiodiplodia chonburiensis, L. pandanicola, Lasionectria krabiense, Menisporopsis pandanicola, Montagnula krabiensis, Musicillium pandanicola, Neofusicoccum pandanicola, Neohelicomyces pandanicola, Neooccultibambusa thailandensis, Neopestalotiopsis chiangmaiensis, N. pandanicola, N. phangngaensis, Pandanaceomyces krabiensis, Paracylindrocarpon nabanheensis, P. pandanicola, P. xishuangbannaensis, Parasarcopodium hongkongensis, Pestalotiopsis krabiensis, P. pandanicola, Polyplosphaeria nabanheensis, P. pandanicola, P. xishuangbannaensis, Pseudoachroiostachys krabiense, Pseudoberkleasmium pandanicola, Pseudochaetosphaeronema pandanicola, Pseudohyaloseta pandanicola, Pseudoornatispora krabiense, Pseudopithomyces pandanicola, Rostriconidium pandanicola, Sirastachys phangngaensis, Stictis pandanicola, Terriera pandanicola, Thozetella pandanicola, Tubeufia freycinetiae, T. parvispora, T. pandanicola, Vermiculariopsiella hongkongensis, Volutella krabiense, V. thailandensis and Yunnanomyces pandanicola. Previous studies of micro-fungi on Pandanaceae have not included phylogenetic support. Inspiration for this study came from the book Fungi Associated with Pandanaceae by Whitton, McKenzie and Hyde in 2012. Both studies reveal that the micro-fungi on Pandanaceae is particularly rich in hyphomycetes. All data presented herein are based on morphological examination of specimens, coupled with phylogenetic sequence data to better integrate taxa into appropriate taxonomic ranks and infer their evolutionary relationships.

Published

2018

35. Tzeananiaceae, a new pleosporalean family associated with Ophiocordyceps macroacicularis fruiting bodies in Taiwan

Author

Ichen Tsai, Wei-Yu Chuang, Alan J. L. Phillips, and Hiran A. Ariyawansa

Subjects

0301 basic medicine, Asia, Tzeananiaceae, Coelomycetes, Ophiocordyceps, Hyphomycetes, Anamorphic Fungi, 03 medical and health sciences, Ascomycota, Molecular Systematics, lcsh:Botany, Botany, medicine, Pleosporineae, Pleosporales, Ophiocordyceps macroacicularis, Phoma-like, Phylogeny, Ecology, Evolution, Behavior and Systematics, Taxonomy, biology, fungi, Fungi, Dothideomycetes, 030108 mycology & parasitology, biology.organism_classification, lcsh:QK1-989, Conidiomata, medicine.drug_formulation_ingredient, Entomopathogenic fungi, 030104 developmental biology, Phoma, Multi-gene analysis, Research Article

Abstract

The order Pleosporales comprises a miscellaneous group of fungi and is considered to be the largest order of the class Dothideomycetes. The circumscription of Pleosporales has undergone numerous changes in recent years due to the addition of large numbers of families reported from various habitats and with a large amount of morphological variation. Many asexual genera have been reported in Pleosporales and can be either hyphomycetes or coelomycetes. Phoma-like taxa are common and have been shown to be polyphyletic within the order and allied with several sexual genera. During the exploration of biodiversity of pleosporalean fungi in Taiwan, a fungal strain was isolated from mycelium growing on the fruiting body of an Ophiocordyceps species. Fruiting structures that developed on PDA were morphologically similar to Phoma and its relatives in having pycnidial conidiomata with hyaline conidia. The fungus is characterised by holoblastic, cylindrical, aseptate conidiogenous cells and cylindrical, hyaline, aseptate, guttulated, thin-walled conidia. Phylogenetic analysis based on six genes, ITS, LSU, rpb2, SSU, tef1 and tub2, produced a phylogenetic tree with the newly generated sequences grouping in a distinct clade separate from all of the known families. Therefore, a new pleosporalean family Tzeananiaceae is established to accommodate the monotypic genus Tzeanania and the species T.taiwanensis in Pleosporales, Dothideomycetes. The Ophiocordyceps species was identified as O.macroacicularis and this is a new record in Taiwan.

Published

2018

36. Mycosphere Notes 225–274: types and other specimens of some genera of Ascomycota

Author

Kevin D. Hyde, Putarak Chomnunti, Saranyaphat Boonmee, Kasun M. Thambugala, Damien Ertz, Dinushani A. Daranagama, S. Hongsanan, Itthayakorn Promputtha, R. Phookamsak, Wei Dong, Dong-Qin Dai, Mingkwan Doilom, Wen-Jing Li, Rekhani H. Perera, Hiran A. Ariyawansa, J. C. Xu, K. Vinit, Sirinapa Konta, Peter E. Mortimer, Eric H. C. McKenzie, E. B. G. Jones, Chada Norphanphoun, Monika C. Dayarathne, L. Z. Tang, and Alan J. L. Phillips

Subjects

0301 basic medicine, biology, Zoology, Plant Science, Sordariomycetes, Dothideomycetes, 030108 mycology & parasitology, biology.organism_classification, Davidiellaceae, Roccellaceae, 03 medical and health sciences, Hysteriaceae, Myriangiales, Xylariales, Leptosphaeriaceae, Ecology, Evolution, Behavior and Systematics

Published

2018

37. Molecular and Morphological Assessment of Septoria Species Associated with Ornamental Plants in Yunnan Province, China

Author

Xiang-Yu Zeng, Alan J. L. Phillips, Yuan-Yan An, Yong Wang, Kevin D. Hyde, and Monika C. Dayarathne

Subjects

Microbiology (medical), QH301-705.5, Septoria, Plant Science, Biology, DNA barcoding, Article, new taxa, 030308 mycology & parasitology, 03 medical and health sciences, Botany, Ornamental plant, Botanical garden, Biology (General), molecular assessment, GCPSR, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 0303 health sciences, Phylogenetic tree, Vegetation, Herbaceous plant, biology.organism_classification, Taxon

Abstract

The Karst landform is the main geographic characteristic in South China. Such areas are rich in vegetation and especially suitable for growth of shrubs and herbaceous plants. In this study, 11 Septoria strains were obtained from different plants’ leaves collected in the Kunming Botanical Garden, Yunnan Province, China. Based on single-gene and multi-gene analyses of five gene loci (tef1, rpb2, tub2, ITS, and LSU) and four gene regions (without LSU), these strains were found to belong to three independent phylogenetic lineages representing five species, including four novel taxa, and one new record for China. Five single gene trees were also provided to evaluate the effectiveness of each gene for discriminating the species, as a result of which tub2 was found to have the most suitable DNA barcode for rapid identification. Morphological descriptions, illustrations, and comparisons are provided for a more comprehensive assessment. Genealogical Concordance Phylogenetic Species Recognition (GCPSR) with a pairwise homoplasy index (PHI) test was used to evaluate the conclusions of the phylogenetic analyses.

Published

2021

38. DISCOMYCETES: the apothecial representatives of the phylum Ascomycota

Author

Kevin D. Hyde, Anusha H. Ekanayaka, S. Hongsanan, Subashini C. Jayasiri, E. B. G. Jones, Qi Zhao, Alan J. L. Phillips, Hiran A. Ariyawansa, and Dinushani A. Daranagama

Subjects

0301 basic medicine, Ecology, Ascomycota, biology, Zoology, 030108 mycology & parasitology, biology.organism_classification, 03 medical and health sciences, Taphrinomycotina, Taxon, Cladogram, Discomycetes, Eurotiomycetes, Ecology, Evolution, Behavior and Systematics, Pezizomycotina, Lecanoromycetes

Abstract

Discomycetes are an artificial grouping of apothecia-producing fungi in the phylum Ascomycota. Molecular-based studies have revealed that the discomycetes can be found among ten classes of Ascomycota. The classification of discomycetes has been a major challenge due to the lack of a clear understanding of the important morphological characters, as well as a lack of reference strains. In this review, we provide a historical perspective of discomycetes, notes on their morphology (including both asexual and sexual morphs), ecology and importance, an outline of discomycete families and a synoptical cladogram of currently accepted families in Ascomycota showing their systematic position. We also calculated evolutionary divergence times for major discomycetous taxa based on phylogenetic relationships using a combined LSU, SSU and RPB2 data set from 175 strains and fossil data. Our results confirm that discomycetes are found in two major subphyla of the Ascomycota: Taphrinomycotina and Pezizomycotina. The taxonomic placement of major discomycete taxa is briefly discussed. The most basal group of discomycetes is the class Neolectomycetes, which diverged from other Taphrinomycotina around 417 MYA (216–572), and the most derived group of discomycetes, the class Lecanoromycetes, diverged from Eurotiomycetes around 340 MYA (282–414). Further clarifications based on type specimens, designation of epitypes or reference specimens from fresh collections, and multi-gene analyses are needed to determine the taxonomic arrangement of many discomycetes.

Published

2017

39. Phylogenetic revision of Camarosporium (Pleosporineae, Dothideomycetes) and allied genera

Author

Nalin N. Wijayawardene, Erio Camporesi, Johannes Z. Groenewald, Peter E. Mortimer, Timur S. Bulgakov, Dhanushka N. Wanasinghe, Kevin D. Hyde, Monika C. Dayarathne, Yusufjon Gafforov, Chayanard Phukhamsakda, Pedro W. Crous, Rajesh Jeewon, Samantha C. Karunarathna, Kasun M. Thambugala, Alan J. L. Phillips, Darbhe J. Bhat, E. B. G. Jones, and Westerdijk Fungal Biodiversity Institute - Evolutionary Phytopathology

Subjects

0301 basic medicine, biology, Ecology, Pleomorphism, Cucurbitaria, Dothideomycetes, 030108 mycology & parasitology, biology.organism_classification, Agricultural and Biological Sciences (miscellaneous), Muriformly septate, 03 medical and health sciences, Monophyly, Type species, lcsh:Biology (General), Evolutionary biology, Genus, Pleosporales, Taxonomy (biology), Clade, lcsh:QH301-705.5, Multigene phylogeny, Taxonomy

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.

Published

2017

40. Antifungal treatment of paper with calcium propionate and parabens: Short-term and long-term effects

Author

Maria Filomena Macedo, Alan J. L. Phillips, Sílvia Oliveira Sequeira, and Eurico J. Cabrita

Subjects

0301 basic medicine, chemistry.chemical_classification, biology, Methylparaben, Chaetomium globosum, Penicillium corylophilum, 030106 microbiology, 010401 analytical chemistry, Aspergillus niger, Cladosporium cladosporioides, biology.organism_classification, Penicillium chrysogenum, 01 natural sciences, Microbiology, 0104 chemical sciences, Biomaterials, 03 medical and health sciences, chemistry.chemical_compound, chemistry, Propionate, Waste Management and Disposal, Propylparaben

Abstract

A deacidifying/antifungal mixture composed of calcium propionate, methylparaben and propylparaben was tested against Aspergillus niger, Cladosporium cladosporioides, Chaetomium globosum, Penicillium chrysogenum and Penicillium corylophilum. The preventive treatment of paper samples resulted in a complete fungal growth inhibition on 4 of the 5 tested species. The antifungal properties of the formulation remained unaffected for a minimum period of one year. The disinfecting treatment with the mixture led to a total elimination of all tested fungal species. The effects of the tested formulation on paper were evaluated in terms of pH, colourimetry, folding endurance, FTIR and XRD, using moist heat artificial ageing. Aside from plain paper, paper previously colonized by A. niger was tested to evaluate the potential of the formulation in preventing deterioration caused by fungal metabolites. In plain paper, an effective deacidification and long-term prevention of mechanical resistance loss were achieved, although a slight paper discoloration occurred. On previously colonized by fungi, the treatment effectively prevented the deterioration caused by fungal metabolites.

Published

2017

41. Ranking higher taxa using divergence times: a case study in Dothideomycetes

Author

Sajeewa S. N. Maharachchikumbura, Kevin D. Hyde, Qi Zhao, Rajesh Jeewon, Martin Ryberg, Zuo-Yi Liu, Jian-Kui Liu, and Alan J. L. Phillips

Subjects

0301 basic medicine, Ecology, biology, Phylogenetic tree, Synonym, Zoology, Dothideomycetes, 030108 mycology & parasitology, biology.organism_classification, Divergence, 03 medical and health sciences, Taxon, Evolutionary biology, Pleosporales, Taxonomic rank, Molecular clock, Ecology, Evolution, Behavior and Systematics

Abstract

The current classification system for the recognition of taxonomic ranks among fungi, especially at high-ranking level, is subjective. With the development of molecular approaches and the availability of fossil calibration data, the use of divergence times as a universally standardized criterion for ranking taxa has now become possible. We can therefore date the origin of Ascomycota lineages by using molecular clock methods and establish the divergence times for the orders and families of Dothideomycetes. We chose Dothideomycetes, the largest class of the phylum Ascomycota, which contains 32 orders, to establish ages at which points orders have split; and Pleosporales, the largest order of Dothideomycetes with 55 families, to establish family divergence times. We have assembled a multi-gene data set (LSU, SSU, TEF1 and RPB2) from 391 taxa representing most family groups of Dothideomycetes and utilized fossil calibration points solely from within the ascomycetes and a Bayesian approach to establish divergence times of Dothideomycetes lineages. Two separated datasets were analysed: (i) 272 taxa representing 32 orders of Dothideomycetes were included for the order level analysis, and (ii) 191 taxa representing 55 families of Pleosporales were included for the family level analysis. Our results indicate that divergence times (crown age) for most orders (20 out of 32, or 63%) are between 100 and 220 Mya, while divergence times for most families (39 out of 55, or 71%) are between 20 and 100 Mya. We believe that divergence times can provide additional evidence to support establishment of higher level taxa, such as families, orders and classes. Taking advantage of this added approach, we can strive towards establishing a standardized taxonomic system both within and outside Fungi. In this study we found that molecular dating coupled with phylogenetic inferences provides no support for the taxonomic status of two currently recognized orders, namely Bezerromycetales and Wiesneriomycetales and these are treated as synonyms of Tubeufiales while Asterotexiales is treated as a synonym of Asterinales. In addition, we provide an updated phylogenetic assessment of Dothideomycetes previously published as the Families of Dothideomycetes in 2013 with a further ten orders and 35 families.

Published

2017

42. Drought × disease interaction in Eucalyptus globulus under Neofusicoccum eucalyptorum infection

Author

Artur Alves, Barbara Correia, Bruno B. Castro, Alan J. L. Phillips, Carla Barradas, Glória Pinto, and Universidade do Minho

Subjects

0106 biological sciences, 0301 basic medicine, Science & Technology, Neofusicoccum eucalyptorum, Plant physiological performance, fungi, food and beverages, Forestry, Plant Science, 15. Life on land, Horticulture, Biology, Pathogenicity, Stress interaction, 01 natural sciences, 6. Clean water, 03 medical and health sciences, 030104 developmental biology, Botryosphaeriaceae, Botany, Abiotic and biotic stress, Genetics, Agronomy and Crop Science, 010606 plant biology & botany

Abstract

Eucalyptus species are widely spread over the world, being extensively planted and exploited by industries. Drought and pathogens are known to affect the establishment and productivity of Eucalyptus plantations worldwide. The aim of this work was to evaluate the pathogenicity of Neofusicoccum eucalyptorum in drought-stressed and well-watered E.globulus plants. The effect of a previous drought priming step and the role of water status at the time of inoculation were evaluated. Lesion length, plant growth and physiological parameters (relative water content, water potential, photosynthetic pigments and lipid peroxidation) were determined. The results indicate that water-stressed plants were more susceptible to N.eucalyptorum than non-stressed ones. However, this response was particularly relevant when the plants were inoculated while water limitation was already occurring. Moreover, drought-primed plants were slightly more resistant to fungal infection than the non-primed ones. This study reinforces the importance of exploring droughtxdisease interaction in Eucalyptus and the underlying physiological responses involved in plant performance., This work was financed by European Funds through COMPETE and by National Funds through the Portuguese Foundation for Science and Technology (FCT) within project PANDORA (PTDC/AGR-FOR/3807/2012 - FCOMP-01-0124-FEDER-027979). The authors acknowledge FCT for financing CESAM (UID/AMB/50017/2013) and CBMA (UID/BIA/04050/2013), A.A. (FCT Investigator Programme - IF/00835/2013), C.B. (PhD grant - SFRH/BD/77939/2011), B.C. (PhD grant - SFRH/BD/86448/2012) and G.P. (post-doctoral grant - SFRH/BPD/101669/2014). A.J.L.P. acknowledges the support from Biosystems and Integrative Sciences Institute (BioISI, FCT/UID/Multi/04046/2013). The authors are thankful to Altri Florestal, SA for supplying the E.globulus clone used for pathogenicity trials., info:eu-repo/semantics/publishedVersion

Published

2017

43. Mating type genes in the genus Neofusicoccum : Mating strategies and usefulness in species delimitation

Author

Artur Alves, Anabela Lopes, and Alan J. L. Phillips

Subjects

0301 basic medicine, Species complex, Mating type, Polymerase Chain Reaction, 03 medical and health sciences, Peptide Elongation Factor 1, Ascomycota, Tubulin, Phylogenetics, Genus, DNA, Ribosomal Spacer, Genetics, Cluster Analysis, Internal transcribed spacer, Mating, DNA, Fungal, Phylogeny, Ecology, Evolution, Behavior and Systematics, DNA Primers, biology, Phylogenetic tree, Sequence Analysis, DNA, Genes, Mating Type, Fungal, biology.organism_classification, Neofusicoccum, 030104 developmental biology, Infectious Diseases

Abstract

The genus Neofusicoccum includes species with wide geographical and plant host distribution, some of them of economic importance. The genus currently comprises 27 species that are difficult to identify based on morphological features alone. Thus, species differentiation is based on phylogenetic species recognition using multigene genealogies. In this study, we characterised the mating type genes of Neofusicoccum species. Specific primers were designed to amplify and sequence MAT genes in several species and a PCR-based mating type diagnostic assay was developed. Homothallism was the predominant mating strategy among the species tested. Furthermore, the potential of mating type gene sequences for species delimitation was evaluated. Phylogenetic analyses were performed on both MAT genes and compared with multigene genealogies using sequences of the ribosomal internal transcribed spacer region, translation elongation factor 1-alpha and beta-tubulin. Phylogenies based on mating type genes could discriminate between the species analysed and are in concordance with the results obtained with the more conventional multilocus phylogenetic analysis approach. Thus, MAT genes represent a powerful tool to delimit cryptic species in the genus Neofusicoccum.

Published

2017

44. Clotrimazole and calcium hydroxide nanoparticles: A low toxicity antifungal alternative for paper conservation

Author

César A. T. Laia, Maria Filomena Macedo, Sílvia Oliveira Sequeira, Eurico J. Cabrita, and Alan J. L. Phillips

Subjects

0301 basic medicine, Archeology, Materials science, Materials Science (miscellaneous), Penicillium corylophilum, Cladosporium cladosporioides, 02 engineering and technology, Conservation, Microbiology, 03 medical and health sciences, chemistry.chemical_compound, medicine, Food science, Spectroscopy, chemistry.chemical_classification, Calcium hydroxide, biology, Clotrimazole, Aspergillus niger, 021001 nanoscience & nanotechnology, biology.organism_classification, Penicillium chrysogenum, Folding endurance, 030104 developmental biology, chemistry, Chemistry (miscellaneous), Azole, 0210 nano-technology, General Economics, Econometrics and Finance, medicine.drug

Abstract

Clotrimazole is a well-known antimycotic agent, listed in the World Health Organization List of essential medicines, with minimal health side effects acknowledged throughout a long certification period. In this study, clotrimazole in isopropanol was tested as a potential antifungal treatment for paper objects. The antifungal properties of this azole compound were evaluated against five of the most common fungal species affecting paper collections. The addition of a deacidifying agent, calcium hydroxide nanoparticles, resulted in a multipurpose formulation also aimed at neutralizing the deleterious effects of acids excreted by fungi. Clotrimazole showed antifungal activity against all tested fungal species and its effectiveness followed the ascending order: Chaetomium globosum Cladosporium cladosporioides Penicillium chrysogenum Aspergillus niger Penicillium corylophilum . The best relationship between minimal concentration and fungal inhibition was achieved for 0.05% clotrimazole. The impact of the tested formulation on paper preservation was evaluated in terms of pH, colour and folding endurance, using moist heat artificial ageing. Clotrimazole and calcium hydroxide nanoparticles protected the paper from acidification and loss of folding endurance in the long term, thus representing a non-aqueous alternative treatment for paper affected by fungi.

Published

2017

45. Families of Diaporthales based on morphological and phylogenetic evidence

Author

I.S. Manawasighe, Johannes Z. Groenewald, Rekhani H. Perera, Kevin D. Hyde, Pedro W. Crous, Wen-Jing Li, Indunil C. Senanayake, Rajesh Jeewon, Abdullah M. Al-Sadi, Alan J. L. Phillips, Erio Camporesi, Samantha C. Karunarathna, Narumon Tangthirasunun, Sajeewa S. N. Maharachchikumbura, D. Jayarama Bhat, Chada Norphanphoun, Qi-Rui Li, and Westerdijk Fungal Biodiversity Institute - Evolutionary Phytopathology

Subjects

0106 biological sciences, 0301 basic medicine, Systematics, Melanconidaceae, Biology, 01 natural sciences, 03 medical and health sciences, Multi-gene DNA phylogeny, New taxonomic arrangement, Phytopathogenic fungi, lcsh:QH301-705.5, Diaporthales, Phylogenetic tree, Ecology, Sydowiellaceae, Sordariomycetes, 030108 mycology & parasitology, biology.organism_classification, Agricultural and Biological Sciences (miscellaneous), lcsh:Biology (General), Evolutionary biology, Cosmopolitan distribution, Key (lock), 010606 plant biology & botany

Abstract

Diaporthalesis an important ascomycetous order comprising phytopathogenic, saprobic, and endophytic fungi, but interfamilial taxonomic relationships are still ambiguous. Despite its cosmopolitan distribution and high diversity with distinctive morphologies, this order has received relativelyiaceae,Macrohilaceae,Melanconidaceae,Pseudoplagiostomaceae,Schizoparmaceae,StilbosporaceaeandSydowiellaceae. Taxonomic uncertainties among genera are also clarified and recurrent discrepancies in the taxonomic position of families within theDiaporthalesare discussed. An updated outline and key to families and genera of the order is presented.

Published

2017

46. Diaporthe species associated with peach tree dieback in Hubei, China

Author

Artur Alves, Alan J. L. Phillips, Pedro W. Crous, and Liliana Santos

Subjects

Canker, Malus, biology, Rosaceae, food and beverages, Plant Science, biology.organism_classification, medicine.disease, Fragaria, Pyracantha, Diaporthe, Phomopsis, Botany, medicine, Internal transcribed spacer, Ecology, Evolution, Behavior and Systematics

Abstract

The family Rosaceae includes a large number of species ranging from herbaceous (Fragaria) to ornamental plants (Rosa and Pyracantha) and fruit trees (Malus and Pyrus). Diaporthe species have been associated with twig canker, shoot blight, dieback, wood decay and fruit rot on members of the Rosaceae. In this study a collection of isolates from several Rosaceae hosts were characterised by multi-locus sequence analyses using the internal transcribed spacer, translation elongation factor 1-alpha, beta-tubulin, histone H3 and calmodulin loci. The phylogenetic analyses of the combined five loci revealed that the isolates studied were distributed among four clades, of which two correspond to D. foeniculina and D. eres. The other two clades, closely related to D. passiflorae and D. leucospermi represent two new species, D. pyracanthae sp. nov. and D. malorum sp. nov., respectively. Further, pathogenicity assays have shown that of the four species tested, D. malorum was the most aggressive species on apple fruit and D. eres was the most aggressive species on detached pear twigs. A revision of all Diaporthe (and Phomopsis) names that have been associated with Rosaceae hosts as well as their current status as pathogens of members of this family is presented.

Published

2017

47. Phylogeny and morphology of Lasiodiplodia species associated with Magnolia forest plants

Author

Saisamorn Lumyong, Jian-Kui Liu, Nimali I. de Silva, Alan J. L. Phillips, and Kevin D. Hyde

Subjects

0106 biological sciences, 0301 basic medicine, Genetic Markers, Lasiodiplodia, China, Food Chain, lcsh:Medicine, Morphology (biology), Biology, Forests, 01 natural sciences, Article, Conidium, Fungal Proteins, 03 medical and health sciences, Fungal biology, Lasiodiplodia species, Peptide Elongation Factor 1, Ascomycota, Phylogenetics, Tubulin, Botany, DNA, Ribosomal Spacer, Endophytes, lcsh:Science, DNA, Fungal, Fungal ecology, Phylogeny, Multidisciplinary, Phylogenetic tree, Host (biology), lcsh:R, Fungal genetics, Sequence Analysis, DNA, 030108 mycology & parasitology, biology.organism_classification, Magnolia, lcsh:Q, 010606 plant biology & botany

Abstract

Two new species of Lasiodiplodia (Lasiodiplodia endophytica and Lasiodiplodia magnoliae) are described and illustrated from Magnolia forests in Yunnan, China. Endophytic and saprobic Lasiodiplodia pseudotheobromae and endophytic L. thailandica are new records from this host. The internal transcribed spacers (ITS), part of the translation elongation factor-1α (tef1) and partial β-tubulin (tub2) sequence data were analyzed to investigate the phylogenetic relationships of the new species with other Lasiodiplodia species. Lasiodiplodia magnoliae is phylogenetically sister to L. mahajangana and L. pandanicola but morphologically distinct from L. mahajangana in having larger conidia. Lasiodiplodia endophytica is most closely related to L. iraniensis and L. thailandica and the three species can be distinguished from one another by 2 base pair differences in ITS and three or four base pair differences in tef1. The new collections suggest that Magnolia forest plants are good hosts for Lasiodiplodia species with endophytic and saprobic life-styles.

Published

2019

48. Microfungi on Tamarix

Author

Dinushani A. Daranagama, Erio Camporesi, Kevin D. Hyde, Ali H. Bahkali, Timur S. Bulgakov, Zuo-Yi Liu, Prapassorn D. Eungwanichayapant, Kasun M. Thambugala, Darbhe J. Bhat, and Alan J. L. Phillips

Subjects

0301 basic medicine, Microfungi, Ecology, biology, Tamarix, Dothideomycetes, 030108 mycology & parasitology, biology.organism_classification, 03 medical and health sciences, Genus, Botany, Phoma, Pleosporales, Didymellaceae, Pleosporaceae, Ecology, Evolution, Behavior and Systematics

Abstract

Tamarix species are small trees that grow in various natural habitats and have a wide geographic distribution. Microfungal species previously found on Tamarix and recently collected in Italy and Russia were identified based on morphological characters and analyses of gene sequence data. The sexual morph of the coelomycetous genus Homortomyces was collected for the first time and is described and illustrated. A new family, Homortomycetaceae (Dothideomycetes, families incertae sedis) is introduced to accommodate Homortomyces. Two new genera Neomicrosphaeropsis (Didymellaceae) and Tamaricicola (Pleosporaceae) are introduced in this paper. Phoma tamaricicola was recollected and is placed in Neomicrosphaeropsis based on morphology and molecular data. Ten new species, Cytospora italica, C. unilocularis, Diaporthe ravennica, Eutypella tamaricis, Neomicrosphaeropsis italica, N. novorossica, N. rossica, Keissleriella tamaricicola, Paracamarosporium tamaricis and Tamaricicola muriformis are introduced, while Alternaria tenuissima, Dothiorella sarmentorum, Neofusicoccum luteum, Paraepicoccum amazonense, Pleospora herbarum and Pseudocamarosporium propinquum are reported for the first time on Tamarix spp. with descriptions and illustrations. Multi-gene analyses show that Paraepicoccum amazonense should be placed in Pleosporineae, Pleosporales, where it is closely related to Camarosporium sensu stricto. Several herbarium specimens were studied to illustrate other fungal species recorded on Tamarix species. A comprehensive account of microfungi on Tamarix is provided, which includes a list with data from the literature, as well as those identified in the present study. The taxonomic placement of most taxa discussed in this study is based on a modern taxonomic framework based on analysis of multi-gene sequence data.

Published

2016

49. Families of Sordariomycetes

Author

Ka-Lai Pang, Sinang Hongsanan, Satinee Suetrong, Sajeewa S. N. Maharachchikumbura, Indunil C. Senanayake, E. B. Gareth Jones, Sirinapa Konta, Qi Rui Li, Dinushani A. Daranagama, Wen Ying Zhuang, Saranyaphat Boonmee, Ishani D. Goonasekara, Nattawut Boonyuen, Ruvishika S. Jayawardena, Chada Norphanphoun, Itthayakorn Promputtha, Xingzhong Liu, Rekhani H. Perera, Marc Stadler, Nalin N. Wijayawardene, Jian-Kui Liu, Rungtiwa Phookamsak, Mohamed A. Abdel-Wahab, Ji-Chuan Kang, Melvina J. D’souza, Zuo Yi Liu, Yuan-Pin Xiao, Qiu Ju Shang, Asha J. Dissanayake, Eric H. C. McKenzie, Rajesh Jeewon, Kevin D. Hyde, Alan J. L. Phillips, J. Jennifer Luangsa-ard, Monika C. Dayarathne, Ali H. Bahkali, Abdullah M. Al-Sadi, Ting-Chi Wen, Shi Ke Huang, Jayarama D. Bhat, and Ratchadawan Cheewangkoon

Subjects

0301 basic medicine, Ecology, Lulworthiales, Hypocreales, royalty.order_of_chivalry, royalty, Sordariomycetes, 030108 mycology & parasitology, Biology, biology.organism_classification, Melanosporales, 03 medical and health sciences, Coronophorales, 030104 developmental biology, Ophiostomatales, Sordariales, Magnaporthales, Ecology, Evolution, Behavior and Systematics

Abstract

Sordariomycetes is one of the largest classes of Ascomycota that comprises a highly diverse range of fungi characterized mainly by perithecial ascomata and inoperculate unitunicate asci. The class includes many important plant pathogens, as well as endophytes, saprobes, epiphytes, coprophilous and fungicolous, lichenized or lichenicolous taxa. They occur in terrestrial, freshwater and marine habitats worldwide. This paper reviews the 107 families of the class Sordariomycetes and provides a modified backbone tree based on phylogenetic analysis of four combined loci, with a maximum five representative taxa from each family, where available. This paper brings together for the first time, since Barrs’ 1990 Prodromus, descriptions, notes on the history, and plates or illustrations of type or representative taxa of each family, a list of accepted genera, including asexual genera and a key to these taxa of Sordariomycetes. Delineation of taxa is supported where possible by molecular data. The outline is based on literature to the end of 2015 and the Sordariomycetes now comprises six subclasses, 32 orders, 105 families and 1331 genera. The family Obryzaceae and Pleurotremataceae are excluded from the class.

Published

2016

50. Fungal diversity notes 253–366: taxonomic and phylogenetic contributions to fungal taxa

Author

Guo Jie Li, Kevin D. Hyde, Rui Lin Zhao, Sinang Hongsanan, Faten Awad Abdel-Aziz, Mohamed A. Abdel-Wahab, Pablo Alvarado, Genivaldo Alves-Silva, Joseph F. Ammirati, Hiran A. Ariyawansa, Abhishek Baghela, Ali Hassan Bahkali, Michael Beug, D. Jayarama Bhat, Dimitar Bojantchev, Thitiya Boonpratuang, Timur S. Bulgakov, Erio Camporesi, Marcela C. Boro, Oldriska Ceska, Dyutiparna Chakraborty, Jia Jia Chen, K. W. Thilini Chethana, Putarak Chomnunti, Giovanni Consiglio, Bao Kai Cui, Dong Qin Dai, Yu Cheng Dai, Dinushani A. Daranagama, Kanad Das, Monika C. Dayarathne, Eske De Crop, Rafael J. V. De Oliveira, Carlos Alberto Fragoso de Souza, José I. de Souza, Bryn T. M. Dentinger, Asha J. Dissanayake, Mingkwan Doilom, E. Ricardo Drechsler-Santos, Masoomeh Ghobad-Nejhad, Sean P. Gilmore, Aristóteles Góes-Neto, Michał Gorczak, Charles H. Haitjema, Kalani Kanchana Hapuarachchi, Akira Hashimoto, Mao Qiang He, John K. Henske, Kazuyuki Hirayama, Maria J. Iribarren, Subashini C. Jayasiri, Ruvishika S. Jayawardena, Sun Jeong Jeon, Gustavo H. Jerônimo, Ana L. Jesus, E. B. Gareth Jones, Ji Chuan Kang, Samantha C. Karunarathna, Paul M. Kirk, Sirinapa Konta, Eric Kuhnert, Ewald Langer, Haeng Sub Lee, Hyang Burm Lee, Wen Jing Li, Xing Hong Li, Kare Liimatainen, Diogo Xavier Lima, Chuan Gen Lin, Jian Kui Liu, Xings Zhong Liu, Zuo Yi Liu, J. Jennifer Luangsa-ard, Robert Lücking, H. Thorsten Lumbsch, Saisamorn Lumyong, Eduardo M. Leaño, Agostina V. Marano, Misato Matsumura, Eric H. C. McKenzie, Suchada Mongkolsamrit, Peter E. Mortimer, Thi Thuong Thuong Nguyen, Tuula Niskanen, Chada Norphanphoun, Michelle A. O’Malley, Sittiporn Parnmen, Julia Pawłowska, Rekhani H. Perera, Rungtiwa Phookamsak, Chayanard Phukhamsakda, Carmen L. A. Pires-Zottarelli, Olivier Raspé, Mateus A. Reck, Sarah C. O. Rocha, André L. C. M. A. de Santiago, Indunil C. Senanayake, Ledo Setti, Qiu Ju Shang, Sanjay K. Singh, Esteban B. Sir, Kevin V. Solomon, Jie Song, Prasert Srikitikulchai, Marc Stadler, Satinee Suetrong, Hayato Takahashi, Takumasa Takahashi, Kazuaki Tanaka, Li Ping Tang, Kasun M. Thambugala, Donnaya Thanakitpipattana, Michael K. Theodorou, Benjarong Thongbai, Tuksaporn Thummarukcharoen, Qing Tian, Saowaluck Tibpromma, Annemieke Verbeken, Alfredo Vizzini, Josef Vlasák, Kerstin Voigt, Dhanushka N. Wanasinghe, Yong Wang, Gothamie Weerakoon, Hua An Wen, Ting Chi Wen, Nalin N. Wijayawardene, Sarunyou Wongkanoun, Marta Wrzosek, Yuan Pin Xiao, Jian Chu Xu, Ji Ye Yan, Jing Yang, Shu Da Yang, Yu Hu, Jin Feng Zhang, Jie Zhao, Li Wei Zhou, Derek Peršoh, Alan J. L. Phillips, and Sajeewa S. N. Maharachchikumbura

Subjects

0301 basic medicine, Neocallimastigomycota, Ecology, Evolution, Basidiomycota, Plant Science, 030108 mycology & parasitology, New species, Ascomycota, New genus, Oomycota, Phylogeny, Taxonomy, Zygomycota, Ecology, Evolution, Behavior and Systematics, 03 medical and health sciences, 030104 developmental biology, Behavior and Systematics

Published

2016