1
|
Concordance of multigene genealogy along with morphological evidence unveils five novel species and two new records of boletoid mushrooms (fungi) from India. Sci Rep 2024; 14:9298. [PMID: 38654032 DOI: 10.1038/s41598-024-59781-2] [Citation(s) in RCA: 0] [Impact Index Per Article: 0] [Reference Citation Analysis] [Abstract] [Key Words] [MESH Headings] [Track Full Text] [Journal Information] [Subscribe] [Scholar Register] [Received: 12/11/2023] [Accepted: 04/15/2024] [Indexed: 04/25/2024] Open
Abstract
Agaricales, Russulales and Boletales are dominant orders among the wild mushrooms in Basidiomycota. Boletaceae, one of the major functional elements in terrestrial ecosystem and mostly represented by ectomycorrhizal symbionts of trees in Indian Himalaya and adjoining hills, are extraordinarily diverse and represented by numerous genera and species which are unexplored or poorly known. Therefore, their hidden diversity is yet to be revealed. Extensive macrofungal exploration by the authors to different parts of Himalaya and surroundings, followed by through morphological studies and multigene molecular phylogeny lead to the discovery of five new species of wild mushrooms: Leccinellum bothii sp. nov., Phylloporus himalayanus sp. nov., Phylloporus smithii sp. nov., Porphyrellus uttarakhandae sp. nov., and Retiboletus pseudoater sp. nov. Present communication deals with morphological details coupled with illustrations and phylogenetic inferences. Besides, Leccinellum sinoaurantiacum and Xerocomus rugosellus are also reported for the first time from this country.
Collapse
|
2
|
Identification of Lasiodiplodia species inciting stem rot of dragon fruit in India through polyphasic approach. 3 Biotech 2023; 13:333. [PMID: 37681113 PMCID: PMC10480115 DOI: 10.1007/s13205-023-03754-1] [Citation(s) in RCA: 0] [Impact Index Per Article: 0] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Journal Information] [Subscribe] [Scholar Register] [Received: 02/14/2023] [Accepted: 08/22/2023] [Indexed: 09/09/2023] Open
Abstract
Lasiodiplodia species commonly thrive as endophytes, saprobes, and plant pathogens in tropical and subtropical regions. Association of Lasiodiplodia species causing stem rot in dragon fruit in the coastal belt of Odisha, eastern India, has been illustrated here. The stem rot disease was characterized by yellowing of the stem, followed by softening of the stem tissues with fungal fructifications of the pathogen in the affected tissues. On the basis of macro- and micromorphological characteristics, the four fungal isolates recovered from diseased stems were identified initially as Lasiodiplodia species. By comparing DNA sequences within the NCBI GenBank database as well as performing a multigene phylogenetic analysis involving the internal transcribed spacer region (ITS-rDNA), β-tubulin (β-tub), and elongation factor-alpha (EF1-α) genes, the identity of Lasiodiplodia isolates was determined. The isolate CHES-21-DFCA was identified as Lasiodiplodia iraniensis (syn: L. iranensis) and the remaining three isolates, namely CHES-22-DFCA-1, CHES-22-DFCA-2, and CHES-22-DFCA-3, as L. theobromae. Although pathogenicity studies confirmed both L. iraniensis and L. theobromae were responsible for stem rot in dragon fruit, L. iraniensis was more virulent than L. theobromae. This study established the association of Lasiodiplodia species with stem rot in dragon fruit using a polyphasic approach. Further investigations are required, particularly related to on host-pathogen-weather interaction and spatiotemporal distribution across the major dragon fruit-growing areas of the country to formulate prospective disease management strategies. This is the first report on these two species of Lasiodiplodia inflicting stem rot in Hylocereus species in India.
Collapse
|
3
|
First report of Colletotrichum siamense causing leaf spot on Manglietia decidua in the world. PLANT DISEASE 2022; 107:562. [PMID: 35815959 DOI: 10.1094/pdis-04-22-0774-pdn] [Citation(s) in RCA: 1] [Impact Index Per Article: 0.5] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Subscribe] [Scholar Register] [Indexed: 06/15/2023]
Abstract
Manglietia decidua Q. Y. Zheng is a deciduous broad-leaved plant and native to Jiangxi province, China. It is cultivated for its timber and urban landscaping (Xiong et al., 2014). In September 2019, a new foliar disease was observed on approx. 25% of 121 M. decidua trees in Jiangxi Agricultural University (N28°45'56″, E115°50'21″), Nanchang city, Jiangxi Province, China. The disease site belongs to the subtropical monsoon humid climate, with rainfall (1,600-1,700 mm) and red soil region. Initially, infection appeared on the leaf margins or tips as water-soaked, irregular lesions, then expanded to the center, developed into large black-brown, irregular necrotic lesions. Finally, the lesions fall off the leaves. To identify the pathogen, 15 diseased leaves were collected from 5 trees (3 leaves per tree) randomly. Small pieces (5 × 5 mm) cut from the lesion margins were surfaced sterilized (70% ethanol for 30 s, 3% NaOCl for 1 min, rinsed 3 times with sterile water), and placed on potato dextrose agar (PDA) at 25 °C. Among the isolated fungi, Colletotrichum-like colonies were about 91%, and 18 monoconidial isolates were obtained. Isolates HML-1, HML-4, and HML-7 were selected and preserved for further studies. Colonies on PDA were white, cottony, and grayish-white on the reverse side. Setae absent. Acervuli were brown, circular. Conidiophores were clear, septate, non-branching or branching at the base, conidiogenous cells were enteroblastic, phialidic, colorless, cylindrical, ampulliform. Conidia were elliptical, single-celled, straight, hyaline, and measured 13.3-17.9 × 4.3-5.7 µm (14.8 ± 1.2 × 4.8 ± 0.4 µm, n = 100). Appressoria were oval to irregular, dark brown, and ranged from 5.3-9.1 × 4.4-6.3 µm (7.2 ± 0.3 × 5.1 ± 0.2 µm, n=100). Morphological characteristics matched the description of Colletotrichum gloeosporioides sensu lato (Weir et al. 2012). The internal transcribed spacer regions (ITS), glyceraldehyde-3-phosphate dehydrogenase (GAPDH), actin (ACT), chitin synthase (CHS-1), calmodulin (CAL), and beta-tubulin 2 (TUB2) were sequenced (Weir et al., 2012), and deposited in GenBank (ITS: OL757565-OL757567; ACT: OL627398-OL627400; CHS-1: OL757358-OL757360; GAPDH: OL757361-OL757363; CAL: OL757355-OL757357; TUB2: OL757364-OL757366). Six loci were concatenated, and the aligned sequences (2056 bp) were 99.9%, 99.8% homologous to C. siamense ICMP 18574 and ex-type ICMP18578, respectively. In the maximum-likelihood phylogenetic tree, the highest log likehihood was -9259.74, and 3 isolates were in the C. siamense clade. Based on the phylogeny and morphology, 3 isolates were identified as C. siamense. The pathogenicity of 3 isolates was tested on 12 M. decidua plants (variety: Yi lin ke) grown in the field. Healthy leaves were wounded slightly with a needle (Φ=0.5 mm) and inoculated with 10 µL of spore suspension (106 conidia/mL). Controls were treated with ddH2O (Si et al. 2021). All the treated leaves were covered with plastic bags to keep a high-humidity environment for 2 days. The experiments were repeated twice. Within 9 days, all the inoculated points showed similar symptoms to those observed in the field, whereas controls were asymptomatic. The same isolate was re-isolated from the lesions, whereas no fungus was isolated from control leaves. Manglietia decidua is an ancient and endangered plant, threatened with southern blight (Sclerotium rolfsii) (Yi et al. 2021a), root rot (Calonectria ilicicola) (Yi et al. 2021b). This is the first report of the newly emerging disease caused by C. siamense in the world. The potential threat should be evaluated for conservation in the future. This study provided crucial information for epidemiological studies and appropriate control strategies.
Collapse
|
4
|
Phylogenetic Position of Trichomycterus payaya and Examination of Osteological Characters Diagnosing the Neotropical Catfish Genus Ituglanis (Siluriformes: Trichomycteridae). Zool Stud 2022; 60:e43. [PMID: 35003337 DOI: 10.6620/zs.2021.60-43] [Citation(s) in RCA: 2] [Impact Index Per Article: 1.0] [Reference Citation Analysis] [Abstract] [Key Words] [Journal Information] [Subscribe] [Scholar Register] [Received: 03/02/2021] [Accepted: 05/21/2021] [Indexed: 11/18/2022]
Abstract
The Trichomycterinae is among the most diverse catfish groups in the world, with interesting ecological specializations; however, the taxonomy of Trichomycterinae is still problematic, mainly due to unclear limits and diagnoses of the eight included genera. Herein we infer the phylogenetic position and generic placement of Trichomycterus payaya, a recently described species from north-eastern Brazil, with unique morphological features among congeners. A multigene analysis including fragments of two nuclear and two mitochondrial genes (total of 2974 bp) for 53 trichomycterine taxa and three outgroups clearly supports inclusion of T. payaya in Ituglanis, a trichomycterine genus containing 29 valid species, which is corroborated by osteological characters. An examination of osteological characters used to diagnose Ituglanis in its original description indicates that a rudimentary or absent posterior cranial fontanel is synapomorphic for Ituglanis, but this is reversed in I. payaya; an anteriorly directed antero-lateral extremity of the sphenotic-prootic-pterosphenoid complex and a narrow and long lateral process of the parurohyal are synapomorphic for Ituglanis, but homoplastically occurring in other trichomycterids; and the presence of a deep medial concavity on the autopalatine is ambiguous to diagnose Ituglanis by occurring in other closely related trichomycterine taxa. Ituglanis is also distinguishable from other trichomycterines by a unique shape of the metapterygoid and by a reduced number of ribs. The analysis supports a clade, comprising I. payaya and I. paraguassuensis, that is endemic to the Chapada Diamantina, in the semiarid Caatinga of north-eastern Brazil, reinforcing the importance of this region for trichomycterid diversification. By integrating molecular analysis and comparative morphology, the present study provides a more solid basis for delimiting Ituglanis, creating a better taxonomical resolution of the Trichomycterinae, although much more research is necessary to reach a consistent generic classification for the entire subfamily.
Collapse
|
5
|
Nitzschia anatoliensis sp. nov., a cryptic diatom species from the highly alkaline Van Lake (Turkey). PeerJ 2021; 9:e12220. [PMID: 34733585 PMCID: PMC8544256 DOI: 10.7717/peerj.12220] [Citation(s) in RCA: 1] [Impact Index Per Article: 0.3] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Received: 08/04/2020] [Accepted: 09/06/2021] [Indexed: 12/02/2022] Open
Abstract
In this article we describe Nitzschia anatoliensis Górecka, Gastineau & Solak sp. nov., an example of a diatom species inhabiting extreme habitats. The new species has been isolated and successfully grown from the highly alkaline Van Lake in East Turkey. The description is based on morphology (light and scanning electron microscopy), the sequencing of its organellar genomes and several molecular phylogenies. This species could easily be overlooked because of its extreme similarity to Nitzschia aurariae but molecular phylogenies indicate that they are only distantly related. Furthermore, molecular data suggest that N. anatoliensis may occur in several alkaline lakes of Asia Minor and Siberia, but was previously misidentified as Nitzschia communis. It also revealed the very close genetic proximity between N. anatoliensis and the endosymbiont of the dinotom Kryptoperidinium foliaceum, providing additional clues on what might have been the original species of diatoms to enter symbiosis.
Collapse
|
6
|
Multiple independent losses of cell mouth in phylogenetically distant endosymbiotic lineages of oligohymenophorean ciliates: A lesson from Clausilocola. Mol Phylogenet Evol 2021; 166:107310. [PMID: 34506949 DOI: 10.1016/j.ympev.2021.107310] [Citation(s) in RCA: 1] [Impact Index Per Article: 0.3] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Journal Information] [Subscribe] [Scholar Register] [Received: 06/25/2021] [Revised: 09/02/2021] [Accepted: 09/04/2021] [Indexed: 01/27/2023]
Abstract
The cell mouth is a property of the vast majority of free-living and endosymbiotic/epibiotic ciliates of the class Oligohymenophorea. Cytostome, however, naturally absents in the whole endosymbiotic subclass Astomatia and was naturally or experimentally lost in a few members of the subclass Hymenostomatia. This poses a question of how homoplastic might be the lack of oral structures in the oligohymenophorean evolution. To address this question, we used two mitochondrial genes, five nuclear markers, and detailed morphological data from an enigmatic mouthless ciliate, Clausilocola apostropha, which we re-discovered after more than half of a century. According to the present phylogenetic analyses, astomy evolved at least three times independently and in different time frames of the oligohymenophorean phylogeny, ranging from the Paleozoic to the Cenozoic period. Mouthless endosymbionts inhabiting mollusks (represented by Clausilocola), planarians (Haptophrya), and annelids ('core' astomes) never clustered together. Haptophrya grouped with the scuticociliate genus Conchophthirus, 'core' astomes were placed in a sister position to the scuticociliate orders Philasterida and Pleuronematida, and Clausilocola was robustly nested within the hymenostome family Tetrahymenidae. The tetrahymenid origin of Clausilocola is further corroborated by the existence of mouthless Tetrahymena mutants and the huge phenotypic plasticity in the cytostome size in tetrahymenids.
Collapse
|
7
|
Molecular systematics and taxonomic overview of the bird's nest fungi (Nidulariaceae). Fungal Biol 2021; 125:693-703. [PMID: 34420696 DOI: 10.1016/j.funbio.2021.04.003] [Citation(s) in RCA: 6] [Impact Index Per Article: 2.0] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Journal Information] [Subscribe] [Scholar Register] [Received: 02/01/2021] [Revised: 04/08/2021] [Accepted: 04/19/2021] [Indexed: 11/23/2022]
Abstract
Fungi in the Nidulariaceae, otherwise known as 'bird's nest fungi', are among the least studied groups of Agaricomycetes (Basidiomycota). Bird's nest fungi are globally distributed and typically grow on woody debris or animal dung as saprotrophs. This group of fungi is morphologically diverse with ca. 200 described species. Phylogenetic relationships of bird's nest fungi were investigated with four commonly used loci (ITS, LSU, tef, and rpb2). The family was resolved as a monophyletic group with Squamanitaceae as a potential sister taxon. Cyathus and Crucibulum each formed its own independent and well-supported clade. Nidula and Nidularia formed a clade together, but each genus is polyphyletic. Two Mycocalia species included in our analyses were on their own separate branches, indicating that this genus is also polyphyletic. Misidentifications were detected in most genera, suggesting that species concepts need to be revisited and refined throughout Nidulariaceae. Several bird's nest fungi species have global geographical distributions whereas others may have more limited ranges. Basic morphological characters of bird's nest fungi have likely been lost or gained multiple times. The phylogenetic placement of Crucibulum is unclear and the sister lineage of bird's nest fungi is not conclusive. Further studies with data from rare species and additional informative genes are needed to fully resolve the topology of Nidulariaceae and identify its sister group with more certainty.
Collapse
|
8
|
The genus Arthrinium (Ascomycota, Sordariomycetes, Apiosporaceae) from marine habitats from Korea, with eight new species. IMA Fungus 2021; 12:13. [PMID: 34059142 PMCID: PMC8168325 DOI: 10.1186/s43008-021-00065-z] [Citation(s) in RCA: 13] [Impact Index Per Article: 4.3] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Received: 07/10/2020] [Accepted: 04/28/2021] [Indexed: 11/10/2022] Open
Abstract
Species of Arthrinium are well-known plant pathogens, endophytes, or saprobes found in various terrestrial habitats. Although several species have been isolated from marine environments and their remarkable biological activities have been reported, marine Arthrinium species remain poorly understood. In this study, the diversity of this group was evaluated based on material from Korea, using morphological characterization and molecular analyses with the internal transcribed spacer (ITS) region, β-tubulin (TUB), and translation elongation factor 1-alpha (TEF). A total of 41 Arthrinium strains were isolated from eight coastal sites which represented 14 species. Eight of these are described as new to science with detailed descriptions.
Collapse
|
9
|
Re-examination of species limits in Aspergillus section Flavipedes using advanced species delimitation methods and description of four new species. Stud Mycol 2021; 99:100120. [PMID: 35003383 PMCID: PMC8688885 DOI: 10.1016/j.simyco.2021.100120] [Citation(s) in RCA: 13] [Impact Index Per Article: 4.3] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 01/27/2023] Open
Abstract
Since the last revision in 2015, the taxonomy of section Flavipedes evolved rapidly along with the availability of new species delimitation techniques. This study aims to re-evaluate the species boundaries of section Flavipedes members using modern delimitation methods applied to an extended set of strains (n = 90) collected from various environments. The analysis used DNA sequences of three house-keeping genes (benA, CaM, RPB2) and consisted of two steps: application of several single-locus (GMYC, bGMYC, PTP, bPTP) and multi-locus (STACEY) species delimitation methods to sort the isolates into putative species, which were subsequently validated using DELINEATE software that was applied for the first time in fungal taxonomy. As a result, four new species are introduced, i.e. A. alboluteus, A. alboviridis, A. inusitatus and A. lanuginosus, and A. capensis is synonymized with A. iizukae. Phenotypic analyses were performed for the new species and their relatives, and the results showed that the growth parameters at different temperatures and colonies characteristics were useful for differentiation of these taxa. The revised section harbors 18 species, most of them are known from soil. However, the most common species from the section are ecologically diverse, occurring in the indoor environment (six species), clinical samples (five species), food and feed (four species), droppings (four species) and other less common substrates/environments. Due to the occurrence of section Flavipedes species in the clinical material/hospital environment, we also evaluated the susceptibility of 67 strains to six antifungals (amphotericin B, itraconazole, posaconazole, voriconazole, isavuconazole, terbinafine) using the reference EUCAST method. These results showed some potentially clinically relevant differences in susceptibility between species. For example, MICs higher than those observed for A. fumigatus wild-type were found for both triazoles and amphotericin B for A. ardalensis, A. iizukae, and A. spelaeus whereas A. lanuginosus, A. luppiae, A. movilensis, A. neoflavipes, A. olivimuriae and A. suttoniae were comparable to or more susceptible as A. fumigatus. Finally, terbinafine was in vitro active against all species except A. alboviridis.
Collapse
|
10
|
An overview of Favolus from the Neotropics, including four new species. Mycologia 2021; 113:759-775. [PMID: 33945432 DOI: 10.1080/00275514.2021.1878797] [Citation(s) in RCA: 0] [Impact Index Per Article: 0] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 10/21/2022]
Abstract
Favolus is a monophyletic genus of polypores that causes white rot of various woody plants. The genus has a worldwide distribution and is ecologically and economically important. Several taxa have been described or reported from the Neotropics, and F. brasiliensis, described originally from Brazil, is the type species for the genus. Based on molecular investigations, F. brasiliensis is now known to represent a species complex. The species is morphologically and phylogenetically circumscribed and epitypified here, and F. rugulosus is proposed as a new related species. Favolus grammocephalus and Polyporus philippinensis, initially described from Asia, have also recently been recorded from the Neotropics, so these taxa were included in this investigation employing morphological and multigene (mitochondrial, ribosomal, and protein-coding regions) phylogenetic analyses. These latter two species do not occur in the Neotropics, but the misapplied names actually represent three new species: F. pseudogrammocephalus, F. radiatifibrillosus, and F. yanomami. Nine species of Favolus are documented now for the Neotropics. Detailed descriptions of F. brasiliensis and all new taxa are provided, along with comments, illustrations, a map of potential distribution, and a key for neotropical species of Favolus.
Collapse
|
11
|
Abstract
The Capnodiales, which includes fungi known as the sooty moulds, represents the second largest order in Dothideomycetes, encompassing morphologically and ecologically diverse fungi with different lifestyles and modes of nutrition. They include saprobes, plant and human pathogens, mycoparasites, rock-inhabiting fungi (RIF), lichenised, epi-, ecto- and endophytes. The aim of this study was to elucidate the lifestyles and evolutionary patterns of the Capnodiales as well as to reconsider their phylogeny by including numerous new collections of sooty moulds, and using four nuclear loci, LSU, ITS, TEF-1α and RPB2. Based on the phylogenetic results, combined with morphology and ecology, Capnodiales s. lat. is shown to be polyphyletic, representing seven different orders. The sooty moulds are restricted to Capnodiales s. str., while Mycosphaerellales is resurrected, and five new orders including Cladosporiales, Comminutisporales, Neophaeothecales, Phaeothecales and Racodiales are introduced. Four families, three genera, 21 species and five combinations are introduced as new. Furthermore, ancestral reconstruction analysis revealed that the saprobic lifestyle is a primitive state in Capnodiales s. lat., and that several transitions have occurred to evolve lichenised, plant and human parasitic, ectophytic (sooty blotch and flyspeck) and more recently epiphytic (sooty mould) lifestyles.
Collapse
|
12
|
Botryosphaeriaceae associated with Acacia heterophylla (La Réunion) and Acacia koa (Hawaii). Fungal Biol 2019; 123:783-790. [PMID: 31627854 DOI: 10.1016/j.funbio.2019.07.001] [Citation(s) in RCA: 2] [Impact Index Per Article: 0.4] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Journal Information] [Subscribe] [Scholar Register] [Received: 07/10/2018] [Revised: 06/28/2019] [Accepted: 07/16/2019] [Indexed: 11/22/2022]
Abstract
Acacia koa and A. heterophylla are commonly occurring native trees on the Hawaiian Islands and La Réunion, respectively. A recent phylogenetic study suggested that A. heterophylla renders A. koa paraphyletic, and that the former likely arose from the Hawaiian Islands around 1.4 million years ago. An intriguing question is whether their microbiota is similar, although they occur naturally in two very distant geographical locations. In this study, we compared the fungi in the Botryosphaeriaceae isolated from natural populations of A. koa and A. heterophylla. These fungi were chosen because they commonly occur on woody plants and some are important pathogens. They are also known to have been moved globally on asymptomatic plant materials. Isolates were identified based on comparisons of DNA sequence data for the rDNA-ITS, TEF1-α and β-tubulin loci. Ten Botryosphaeriaceae species were identified, of which four species were specific to A. koa from the Hawaiian Islands and five to A. heterophylla in La Réunion. Only one species, Neofusicoccumparvum, which is known to have a wide global distribution, was common to both hosts. The overall results of this study suggest that although A. koa and A.heterophylla share a recent evolutionary history, they have established independent microbiota, at least in terms of the Botryosphaeriaceae.
Collapse
|
13
|
A multigene phylogeny to infer the evolutionary history of Chaetocerotaceae (Bacillariophyta). Mol Phylogenet Evol 2019; 140:106575. [PMID: 31362084 DOI: 10.1016/j.ympev.2019.106575] [Citation(s) in RCA: 12] [Impact Index Per Article: 2.4] [Reference Citation Analysis] [Abstract] [Key Words] [MESH Headings] [Track Full Text] [Journal Information] [Subscribe] [Scholar Register] [Received: 05/06/2019] [Revised: 07/25/2019] [Accepted: 07/26/2019] [Indexed: 01/06/2023]
Abstract
The diatom family Chaetocerotaceae (Bacillariophyta) is common in the marine plankton worldwide, especially in coastal areas and upwelling zones. Its defining character constitutes hollow processes, called setae, which emerge from the valves of the vegetative cells. The family comprises two extant genera: Bacteriastrum and Chaetoceros. Current systematics is based on morphological features of vegetative cells and resting spores and is summarised in a classification scheme subdividing Bacteriastrum in two sections, Isomorpha and Sagittata, and Chaetoceros in three subgenera: Hyalochaete, Chaetoceros (Phaeoceros) and Bacteriastroidea, and further into 22 sections. Phylogenies inferred from single molecular markers (18S and partial 28S rDNA) show only partial topological agreement and many poorly or unresolved basal ramifications. Since classification should not only satisfy practical needs but also reflect well-supported evolutionary relationships of the taxa under investigation, we inferred a multigene phylogeny of the family Chaetocerotaceae amplifying five genes of 100 strains encompassing six Bacteriastrum and 60 Chaetoceros species. We also compared the phylogenetic signal of nuclear, plastid and mitochondrial compartments to ascertain if the inferred tree topologies were congruent. Our results provided a robust multigene phylogeny of the family Chaetocerotaceae, offering a solid framework to test the validity of the traditional taxonomical classification. The genera Bacteriastrum and Chaetoceros were resolved as sister clades, whilst the subgenus Hyalochaete was found to be paraphyletic. Consequently, we rejected the subdivision in subgenera and only considered sections. Most of the already recognised sections were found to be monophyletic. We emended one section, rejected seven and erected three new ones. As a consequence of our proposed changes, all the sections investigated are supported by morphological and molecular characters alike. Thus, a natural classification is feasible for this important and very diverse marine planktonic family.
Collapse
|
14
|
Improved taxon sampling and multigene phylogeny of unicellular chlamydomonads closely related to the colonial volvocalean lineage Tetrabaenaceae-Goniaceae-Volvocaceae (Volvocales, Chlorophyceae). Mol Phylogenet Evol 2018; 130:1-8. [PMID: 30266459 DOI: 10.1016/j.ympev.2018.09.013] [Citation(s) in RCA: 7] [Impact Index Per Article: 1.2] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Journal Information] [Subscribe] [Scholar Register] [Received: 04/26/2018] [Revised: 09/13/2018] [Accepted: 09/21/2018] [Indexed: 11/23/2022]
Abstract
In the green algal order Volvocales (Chlorophyceae), flagellate colonial forms have evolved at least four times. One of these colonial lineages, Tetrabaenaceae-Goniaceae-Volvocaceae (TGV), which belongs to the clade Reinhardtinia, is closely related to several unicellular chlamydomonads in the genera Chlamydomonas and Vitreochlamys. However, the unicellular sister of TGV has not been specified. Here, the largest ever 18S rRNA phylogenetic tree of Reinhardtinia was constructed including several newly isolated chlamydomonads, and a clade (core-Reinhardtinia) including 32 unicellular lineages and three colonial families were recognized. Interrelationships within core-Reinhardtinia were barely resolved in the tree, and therefore combined 18S-atpB-psaA-psaB-psbC-rbcL gene phylogenetic analyses were performed with selected representatives of 29 of the 32 unicellular lineages and three colonial families. The 29 unicellular lineages were clustered into five metaclades and an unassigned lineage; the metaclade that includes Chlamydomonas pila was resolved, with moderate support, as the sister clade to TGV. To examine possible biases from specific gene(s), long-branch taxa, and the heterogeneous base composition, phylogenetic analyses using several smaller data sets were also performed. Light microscopy of C. pila and its relatives indicated that any early steps towards colony evolution appeared after divergence of TGV from the C. pila lineage.
Collapse
|
15
|
Zombie-ant fungi across continents: 15 new species and new combinations within Ophiocordyceps. I. Myrmecophilous hirsutelloid species. Stud Mycol 2018; 90:119-160. [PMID: 29910522 PMCID: PMC6002356 DOI: 10.1016/j.simyco.2017.12.002] [Citation(s) in RCA: 52] [Impact Index Per Article: 8.7] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 11/20/2022] Open
Abstract
Ophiocordyceps species infecting ants - the so-called zombie-ant fungi - comprise one of the most intriguing and fascinating relationships between microbes and animals. They are widespread within tropical forests worldwide, with relatively few reports from temperate ecosystems. These pathogens possess the ability to manipulate host behaviour in order to increase their own fitness. Depending on the fungal species involved the infected ants are manipulated either to leave the nest to ascend understorey shrubs, to die biting onto vegetation, or descend from the canopy to die at the base of trees. Experimental evidence has demonstrated that the behavioural change aids spore dispersal and thus increases the chances of infection, because of the existing behavioural immunity expressed inside ant colonies that limits fungal development and transmission. Despite their undoubted importance for ecosystem functioning, these fungal pathogens are still poorly documented, especially regarding their diversity, ecology and evolutionary relationships. Here, we describe 15 new species of Ophiocordyceps with hirsutella-like asexual morphs that exclusively infect ants. These form a monophyletic group that we identified in this study as myrmecophilous hirsutelloid species. We also propose new combinations for species previously described as varieties and provide for the first time important morphological and ecological information. The species proposed herein were collected in Brazil, Colombia, USA, Australia and Japan. All species could readily be separated using classic taxonomic criteria, in particular ascospore and asexual morphology.
Collapse
Key Words
- Behaviour manipulation
- Camponotini
- Entomopathogenic fungi
- Host association
- Hypocreales
- Insect pathogen
- Multigene phylogeny
- O. albacongiuae Araújo, H.C. Evans & D.P. Hughes
- O. blakebarnesii Araújo, H.C. Evans & D.P. Hughes
- O. camponoti-chartificis Araújo, H.C. Evans & D.P. Hughes
- O. camponoti-femorati Araújo, H.C. Evans & D.P. Hughes
- O. camponoti-floridani Araújo, H.C. Evans & D.P. Hughes
- O. camponoti-hippocrepidis Araújo, H.C. Evans & D.P. Hughes
- O. camponoti-nidulantis Araújo, H.C. Evans & D.P. Hughes
- O. camponoti-renggeri Araújo, H.C. Evans & D.P. Hughes
- O. camponoti-sexguttati Araújo, H.C. Evans & D.P. Hughes
- O. daceti Araújo, H.C. Evans & D.P. Hughes
- O. kimflemingiae Araújo, H.C. Evans & D.P. Hughes
- O. monacidis (H.C. Evans & Samson) Araújo, H.C. Evans & D.P. Hughes
- O. naomipierceae Araújo, H.C. Evans & D.P. Hughes
- O. oecophyllae Araújo, S. Abell, T. Marney, R. Shivas H.C. Evans & D.P. Hughes
- O. ootakii Araújo, H.C. Evans & D.P. Hughes.
- O. satoi Araújo, H.C. Evans & D.P. Hughes
- Ophiocordyceps
- Ophiocordyceps dolichoderi (H.C. Evans & Samson) Araújo, H.C. Evans & D.P. Hughes
- Ophiocordyceps unilateralis
- Zombie-ant fungi
Collapse
|
16
|
Two new Sporothrix species from Protea flower heads in South African Grassland and Savanna. Antonie Van Leeuwenhoek 2017; 111:965-979. [PMID: 29214366 DOI: 10.1007/s10482-017-0995-3] [Citation(s) in RCA: 6] [Impact Index Per Article: 0.9] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Journal Information] [Subscribe] [Scholar Register] [Received: 05/02/2017] [Accepted: 12/01/2017] [Indexed: 11/29/2022]
Abstract
The inflorescences and infructescences of African Protea trees provide habitat for a large diversity of Sporothrix species. Here we describe two additional members, Sporothrix nsini sp. nov. and Sporothrix smangaliso sp. nov., that are associated with the infructescences of various Protea species from grasslands and savannas in the KwaZulu-Natal, North-West, Gauteng and Mpumalanga provinces of South Africa. Their description raises the number of described Protea-associated Sporothrix species to twelve. S. smangaliso sp. nov. is distantly related to other Protea-associated species and, in phylogenies using multiple markers (ITS, beta-tubulin and calmodulin), groups with taxa such as Sporothrix bragantina from Brazil and Sporothrix curviconia from the Ivory Coast. S. nsini sp. nov. resolved as sister to a clade containing four other Protea-associated species within the Sporothrix stenoceras complex. S. nsini sp. nov. was collected from within the same infructescences of Protea caffra that also contained the closely related S. africana and S. protearum. This highlights the need to study and understand the factors that influence host selection and speciation of Sporothrix in this atypical niche.
Collapse
|
17
|
Abstract
The taxonomy of the coelomycetes has undergone dramatic changes in recent years, but remains controversial due to the high number of taxa involved, their poor morphological differentiation, the rare occurrence of the sexual morphs, and rapid loss of fertility in vitro. In the present study, we revisited the families Cucurbitariaceae and Didymellaceae (Pleosporales, Dothideomycetes), which include numerous plant pathogens, endophytic species associated with a wide host range, and saprobes. The taxonomy of two of the most relevant genera, i.e. Phoma and Pyrenochaeta, remains ambiguous after several phylogenetic studies, and needs further revision. We have studied a total of 143 strains of coelomycetes from clinical or environmental origin, by combining the LSU, ITS, tub2 and rpb2 sequences for a multi-locus analysis and a detailed morphological comparison. The resulting phylogenetic tree revealed that some fungi previously considered as members of Cucurbitariaceae represented five different families, and four of them, Neopyrenochaetaceae, Parapyrenochaetaceae, Pseudopyrenochaetaceae and Pyrenochaetopsidaceae, are proposed here as new. Furthermore, 13 new genera, 28 new species, and 20 new combinations are proposed within the Pleosporineae. Moreover, four new typifications are introduced to stabilise the taxonomy of these fungi.
Collapse
Key Words
- Allocucurbitaria Valenzuela-Lopez, Stchigel, Guarro & Cano
- Allocucurbitaria botulispora Valenzuela-Lopez, Stchigel, Guarro & Cano
- Allophoma cylindrispora Valenzuela-Lopez, Cano, Guarro & Stchigel
- Cu. pneumoniae Valenzuela-Lopez, Stchigel, Crous, Guarro & Cano
- Cucurbitariaceae
- Cumuliphoma Valenzuela-Lopez, Stchigel, Crous, Guarro & Cano
- Cumuliphoma indica Valenzuela-Lopez, Cano, Crous, Guarro & Stchigel
- Cumuliphoma omnivirens (Aveskamp et al.) Valenzuela-Lopez, Stchigel, Crous, Guarro & Cano
- D. keratinophila Valenzuela-Lopez, Cano, Guarro & Stchigel
- Didymella brunneospora Valenzuela-Lopez, Cano, Crous, Guarro & Stchigel
- Didymellaceae
- Ec. pomi (Horne) Valenzuela-Lopez, Cano, Crous, Guarro & Stchigel
- Ectophoma Valenzuela-Lopez, Cano, Crous, Guarro & Stchigel
- Ectophoma multirostrata (P.N. Mathur et al.) Valenzuela-Lopez, Cano, Crous, Guarro & Stchigel
- Ep. keratinophilum Valenzuela-Lopez, Cano, Guarro & Stchigel
- Ep. ovisporum Valenzuela-Lopez, Stchigel, Crous, Guarro & Cano
- Ep. pneumoniae Valenzuela-Lopez, Stchigel, Guarro & Cano
- Epicoccum catenisporum Valenzuela-Lopez, Stchigel, Crous, Guarro & Cano
- Epicoccum proteae (Crous) Valenzuela-Lopez, Stchigel, Crous, Guarro & Cano
- Juxtiphoma Valenzuela-Lopez, Cano, Crous, Guarro & Stchigel
- Juxtiphoma eupyrena (Sacc.) Valenzuela-Lopez, Cano, Crous, Guarro & Stchigel
- Multigene phylogeny
- Neoa. tardicrescens Valenzuela-Lopez, Cano, Crous, Guarro & Stchigel
- Neoascochyta cylindrispora Valenzuela-Lopez, Cano, Guarro & Stchigel
- Neocu. hakeae (Crous) Valenzuela-Lopez, Crous, Stchigel, Guarro & Cano
- Neocu. irregularis Valenzuela-Lopez, Cano, Guarro & Stchigel
- Neocu. keratinophila (Verkley et al.) Valenzuela-Lopez, Stchigel, Guarro & Cano
- Neocucurbitaria aquatica Valenzuela-Lopez, Crous, Stchigel, Guarro & Cano
- Neocucurbitaria cava (Schulzer) Valenzuela-Lopez, Crous, Stchigel, Guarro & Cano
- Neopy. inflorescentiae (Crous et al.) Valenzuela-Lopez, Crous, Stchigel, Guarro & Cano
- Neopy. telephoni (Rohit Sharma et al.) Valenzuela-Lopez, Crous, Stchigel, Guarro & Cano
- Neopyrenochaeta Valenzuela-Lopez, Crous, Stchigel, Guarro & Cano
- Neopyrenochaeta acicola (Moug. & Lév.) Valenzuela-Lopez, Crous, Stchigel, Guarro & Cano
- Neopyrenochaeta fragariae Valenzuela-Lopez, Crous, Stchigel, Guarro & Cano
- Neopyrenochaetaceae Valenzuela-Lopez, Crous, Cano, Guarro & Stchigel
- Neopyrenochaetopsis Valenzuela-Lopez, Cano, Guarro & Stchigel
- Neopyrenochaetopsis hominis Valenzuela-Lopez, Cano, Guarro & Stchigel
- New taxa
- Nothophoma variabilis Valenzuela-Lopez, Cano, Guarro & Stchigel
- Paracucurbitaria Valenzuela-Lopez, Stchigel, Guarro & Cano
- Paracucurbitaria corni (Bat. & A.F. Vital) Valenzuela-Lopez, Stchigel, Guarro & Cano
- Paracucurbitaria italica Valenzuela-Lopez, Crous, Stchigel, Guarro & Cano
- Parapy. protearum (Crous) Valenzuela-Lopez, Crous, Stchigel, Guarro & Cano
- Parapyrenochaeta Valenzuela-Lopez, Crous, Stchigel, Guarro & Cano
- Parapyrenochaeta acaciae (Crous et al.) Valenzuela-Lopez, Crous, Stchigel, Guarro & Cano
- Parapyrenochaetaceae Valenzuela-Lopez, Crous, Stchigel, Guarro & Cano
- Phoma
- Pleosporales
- Pleosporineae
- Pseudopyrenochaeta Valenzuela-Lopez, Crous, Stchigel, Guarro & Cano
- Pseudopyrenochaeta lycopersici (R.W. Schneid. & Gerlach) Valenzuela-Lopez, Crous, Stchigel, Guarro & Cano
- Pseudopyrenochaeta terrestris Valenzuela-Lopez, Crous, Cano, Guarro & Stchigel
- Pseudopyrenochaetaceae Valenzuela-Lopez, Crous, Stchigel, Guarro & Cano
- Py. botulispora Valenzuela-Lopez, Cano, Guarro & Stchigel
- Py. confluens Valenzuela-Lopez, Cano, Guarro & Stchigel
- Py. globosa Valenzuela-Lopez, Cano, Guarro & Stchigel
- Py. paucisetosa Valenzuela-Lopez, Cano, Guarro & Stchigel
- Py. setosissima Valenzuela-Lopez, Cano, Crous, Guarro & Stchigel
- Py. uberiformis Valenzuela-Lopez, Cano, Guarro & Stchigel
- Pyrenochaeta
- Pyrenochaetopsidaceae Valenzuela-Lopez, Crous, Cano, Guarro & Stchigel
- Pyrenochaetopsis
- Pyrenochaetopsis americana Valenzuela-Lopez, Cano, Guarro & Stchigel
- Remotididymella Valenzuela-Lopez, Crous, Cano, Guarro & Stchigel
- Remotididymella anthropophila Valenzuela-Lopez, Cano, Guarro & Stchigel
- Remotididymella destructiva (Plowr.) Valenzuela-Lopez, Cano, Crous, Guarro & Stchigel
- Similiphoma Valenzuela-Lopez, Crous, Cano, Guarro & Stchigel
- Similiphoma crystallifera (Gruyter et al.) Valenzuela-Lopez, Crous, Cano, Guarro & Stchigel
- Taxonomy
- Vacuiphoma Valenzuela-Lopez, Cano, Crous, Guarro & Stchigel
- Vacuiphoma bulgarica (Aveskamp et al.) Valenzuela-Lopez, Cano, Crous, Guarro & Stchigel
- Vacuiphoma oculihominis Valenzuela-Lopez, Stchigel, Guarro & Cano
- Xenodidymella saxea (Aveskamp et al.) Valenzuela-Lopez, Crous, Cano, Guarro & Stchigel
- Xenopyrenochaetopsis Valenzuela-Lopez, Crous, Stchigel, Guarro & Cano
- Xenopyrenochaetopsis pratorum (P.R. Johnst. & Boerema) Valenzuela-Lopez, Crous, Stchigel, Guarro & Cano
Collapse
|
18
|
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.
Collapse
Key Words
- Ca. aborescentis (Phukhams. et al.) Phukhams., Wanas. & K.D. Hyde
- Ca. arezzoensis (Tibpromma et al.) Wanas. & K.D. Hyde
- Ca. celtidis (Shear) Thambugala, Wanas. & K.D. Hyde
- Ca. clematidis (Wijayaw. et al.) Wijayaw., Wanas. & K.D. Hyde
- Ca. elongata (Fr.) Wanas., Wijayaw. & K.D. Hyde
- Ca. eufemiana Wanas., Camporesi & K.D. Hyde
- Ca. halimodendri Wanas., Bulgakov & K.D. Hyde
- Ca. italica Wanas., Camporesi & K.D. Hyde
- Ca. laburni (Pers.) Wanas., Bulgakov, Camporesi & K.D. Hyde
- Ca. laburnicola (R.H. Perera et al.) Wanas. & K.D. Hyde
- Ca. mackenziei Wanas., Bulgakov & K.D. Hyde
- Ca. melnikii Wanas., Bulgakov & K.D. Hyde
- Ca. mirabellensis Wanas., Camporesi & K.D. Hyde
- Ca. moricola (Chethana et al.) Wanas. & K.D. Hyde
- Ca. premilcurensis Wanas., Camporesi & K.D. Hyde
- Ca. robiniicola (Wijayaw. et al.) Wijayaw., Wanas. & K.D. Hyde
- Ca. schulzeri Wanas., Bulgakov & K.D. Hyde
- Ca. spartii (Trail) Wijayaw., Wanas. & K.D. Hyde
- Camarosporiaceae Wanas., K.D. Hyde & Crous
- Camarosporidiella Wanas., Wijayaw. & K.D. Hyde
- Camarosporidiella caraganicola (Phukhams. et al.) Phukhams., Wanas. & K.D. Hyde
- Camarosporidiella elaeagnicola Wanas., Bulgakov & K.D. Hyde
- Camarosporidiella: Ca.
- Camarosporidiellaceae Wanas., Wijayaw., Crous & K.D. Hyde
- Camarosporium: Cm.
- Camarosporomyces: Cs.
- Cucurbitaria: Cu
- Multigene phylogeny
- Muriformly septate
- N. lamiacearum Dayar., E.B.G. Jones & K.D. Hyde
- N. obiones (Jaap) Wanas. & K.D. Hyde
- N. salicorniicola Dayarathne, E.B.G. Jones & K.D. Hyde
- N. salsolae Wanas., Gafforov & K.D. Hyde
- Neocamarosporiaceae Wanas., Wijayaw., Crous & K.D. Hyde
- Neocamarosporium chenopodii (Ellis & Kellerm.) Wanas. & K.D. Hyde
- Neocamarosporium korfii Wanas., E.B.G. Jones & K.D. Hyde
- Pleomorphism
- Pleosporales
- Staurosphaeria aloes (Crous & M.J. Wingf.) Crous
- Staurosphaeria lycii Rabenh
- Staurosphaeria lyciicola (Crous & R.K. Schumach.) Crous, Wanas. & K.D. Hyde
- Staurosphaeria rhamnicola Wanas., Yu. Sh. Gafforov & K.D. Hyde
- Taxonomy
- Wanas. & K.D. Hyde
Collapse
|
19
|
Phytogeographic patterns and cryptic diversity in an aposematic toad from NW Argentina. Mol Phylogenet Evol 2017; 116:248-256. [PMID: 28750851 DOI: 10.1016/j.ympev.2017.07.013] [Citation(s) in RCA: 1] [Impact Index Per Article: 0.1] [Reference Citation Analysis] [Abstract] [Key Words] [MESH Headings] [Track Full Text] [Journal Information] [Subscribe] [Scholar Register] [Received: 12/29/2016] [Revised: 07/19/2017] [Accepted: 07/20/2017] [Indexed: 11/15/2022]
Abstract
The Yungas Redbelly Toad, Melanophryniscus rubriventris, is patchily distributed in Argentina, confined to the upland portion (1000-2000m above sea level) of the montane forests of northern and central regions of Salta, and in central-eastern and south-eastern Jujuy. This species is known for its striking aposematic color variation across its geographic distribution, and was once treated as a complex of three subspecies based on distinctive color patterns. Here we assess the geographical genetic variation within M. rubriventris and quantify divergence in color and pattern among individuals sampled from Northwestern Argentina. We compare multi-gene phylogeography of M. rubriventris to patterns of dorsal and ventral coloration to test whether evolutionary affinities predict variation in warning color. Our results reveal two well-supported species lineages: one confined to the extreme northern portion of our sampling area, and the other extending over most of the Argentine portion of the species' range, within which there are two populations. However, these well-supported evolutionary relationships do not mirror the marked variation in warning coloration. This discordance between DNA genealogy and warning color variation may reflect selection brought about by differences in local predation pressures, potentially coupled with effects of sexual selection and thermoregulation.
Collapse
|
20
|
Phylogenetics of Australasian gall flies (Diptera: Fergusoninidae): Evolutionary patterns of host-shifting and gall morphology. Mol Phylogenet Evol 2017; 115:140-160. [PMID: 28757445 DOI: 10.1016/j.ympev.2017.07.023] [Citation(s) in RCA: 1] [Impact Index Per Article: 0.1] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Journal Information] [Subscribe] [Scholar Register] [Received: 06/29/2017] [Accepted: 07/26/2017] [Indexed: 11/20/2022]
Abstract
This study investigated host-specificity and phylogenetic relationships in Australian galling flies, Fergusonina Malloch (Diptera: Fergusoninidae), in order to assess diversity and explore the evolutionary history of host plant affiliation and gall morphology. A DNA barcoding approach using COI data from 203 Fergusonina specimens from 5gall types on 56 host plant species indicated 85 presumptive fly species. These exhibited a high degree of host specificity; of the 40 species with multiple representatives, each fed only on a single host genus, 29 (72.5%) were strictly monophagous, and 11 (27.5%) were reared from multiple closely related hosts. COI variation within species was not correlated with either sample size or geographic distance. However variation was greater within oligophagous species, consistent with expectations of the initial stages of host-associated divergence during speciation. Phylogenetic analysis using both nuclear and mitochondrial genes revealed host genus-restricted clades but also clear evidence of multiple colonizations of both host plant genus and host species. With the exception of unilocular peagalls, evolution of gall type was somewhat constrained, but to a lesser degree than host plant association. Unilocular peagalls arose more often than any other gall type, were primarily located at the tips of the phylogeny, and did not form clades comprising more than a few species. For ecological reasons, species of this gall type are predicted to harbor substantially less genetic variation than others, possibly reducing evolutionary flexibility resulting in reduced diversification in unilocular gallers.
Collapse
|
21
|
New endophytic Toxicocladosporium species from cacti in Brazil, and description of Neocladosporium gen. nov. IMA Fungus 2017; 8:77-97. [PMID: 28824841 PMCID: PMC5493539 DOI: 10.5598/imafungus.2017.08.01.06] [Citation(s) in RCA: 18] [Impact Index Per Article: 2.6] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Received: 03/16/2017] [Accepted: 04/24/2017] [Indexed: 11/09/2022] Open
Abstract
Brazil harbours a unique ecosystem, the Caatinga, which belongs to the tropical dry forest biome. This region has an important diversity of organisms, and recently several new fungal species have been described from different hosts and substrates within it. During a survey of fungal endophyte diversity from cacti in this forest, we isolated cladosporium-like fungi that were subjected to morphological and multigene phylogenetic analyses including actA, ITS, LSU, rpb2 and tub2 gene sequences. Based on these analyses we identified two new species belonging to the genus Toxicocladosporium, described here as T. cacti and T. immaculatum spp. nov., isolated from Pilosocereus gounellei subsp. gounellei and Melocactus zehntneri, respectively. To improve the species recognition and assess species diversity in Toxicocladosporium we studied all ex-type strains of the genus, for which actA, rpb2 and tub2 barcodes were also generated. After phylogenetic reconstruction using five loci, we differentiated 13 species in the genus. Toxicocladosporium velox and T. chlamydosporum are synonymized based on their phylogenetic position and limited number of unique nucleotide differences. Six strains previously assigned to T. leucadendri, including the ex-type strain (CBS 131317) of that species, were found to belong to an undescribed genus here named as Neocladosporium gen. nov., with N. leucadendri comb. nov. as type species. Furthermore, this study proposes the actA, ITS, rpb2 and tub2 as main phylogenetic loci to recognise Toxicocladosporium species.
Collapse
|
22
|
A new species of Scopulariopsis and its synergistic effect on pathogenicity of Verticillium dahliae on cotton plants. Microbiol Res 2017; 201:12-20. [PMID: 28602397 DOI: 10.1016/j.micres.2017.04.006] [Citation(s) in RCA: 5] [Impact Index Per Article: 0.7] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Journal Information] [Subscribe] [Scholar Register] [Received: 06/12/2016] [Revised: 01/30/2017] [Accepted: 04/08/2017] [Indexed: 12/16/2022]
Abstract
A new species, Scopulariopsis gossypii, was found to be present in the vascular bundles of cotton plants (Gossypium hirsutum) infected by Verticillium dahliae which is an economically important pathogen in Hangzhou, China. The fungus was only present in the diseased plants, but it never became isolated from the healthy plants. Scanning electron microscopy showed that the fungus was present in parenchyma cells enclosing vessels in dark brown vascular tissues of stems, and produced asexual conidia within the tissues. Phylogenetic analysis of combined nuclear ribosomal D1/D2 region of the 28S rDNA as well as translation elongation factor 1-alpha (TEF1) and beta-tubulin (TUB) gene showed that S. gossypii represents an undescribed species of Scopulariopsis, Microascaceae. In this study, characteristics of sexual and asexual stages of the fungus were described, illustrated and compared with similar taxa. In addition, the molecular and morphological analyses indicated that S. gossypii was a distinct species of Scopulariopsis. The pathogenicity tests proved by inoculation of wounded roots confirmed that S. gossypii was an opportunistic pathogen causing leaf interveinal chlorosis and vascular browning of cotton plants. However S. gossypii did not infect host with undamaged roots. Moreover, coinoculation with S. gossypii and V. dahliae significantly increased disease severity.
Collapse
|
23
|
Abstract
Aspergillus is one of the economically most important fungal genera. Recently, the ICN adopted the single name nomenclature which has forced mycologists to choose one name for fungi (e.g. Aspergillus, Fusarium, Penicillium, etc.). Previously two proposals for the single name nomenclature in Aspergillus were presented: one attributes the name "Aspergillus" to clades comprising seven different teleomorphic names, by supporting the monophyly of this genus; the other proposes that Aspergillus is a non-monophyletic genus, by preserving the Aspergillus name only to species belonging to subgenus Circumdati and maintaining the sexual names in the other clades. The aim of our study was to test the monophyly of Aspergilli by two independent phylogenetic analyses using a multilocus phylogenetic approach. One test was run on the publicly available coding regions of six genes (RPB1, RPB2, Tsr1, Cct8, BenA, CaM), using 96 species of Penicillium, Aspergillus and related taxa. Bayesian (MrBayes) and Ultrafast Maximum Likelihood (IQ-Tree) and Rapid Maximum Likelihood (RaxML) analyses gave the same conclusion highly supporting the monophyly of Aspergillus. The other analyses were also performed by using publicly available data of the coding sequences of nine loci (18S rRNA, 5,8S rRNA, 28S rRNA (D1-D2), RPB1, RPB2, CaM, BenA, Tsr1, Cct8) of 204 different species. Both Bayesian (MrBayes) and Maximum Likelihood (RAxML) trees obtained by this second round of independent analyses strongly supported the monophyly of the genus Aspergillus. The stability test also confirmed the robustness of the results obtained. In conclusion, statistical analyses have rejected the hypothesis that the Aspergilli are non-monophyletic, and provided robust arguments that the genus is monophyletic and clearly separated from the monophyletic genus Penicillium. There is no phylogenetic evidence to split Aspergillus into several genera and the name Aspergillus can be used for all the species belonging to Aspergillus i.e. the clade comprising the subgenera Aspergillus, Circumdati, Fumigati, Nidulantes, section Cremei and certain species which were formerly part of the genera Phialosimplex and Polypaecilum. Section Cremei and the clade containing Polypaecilum and Phialosimplex are proposed as new subgenera of Aspergillus. The phylogenetic analysis also clearly shows that Aspergillus clavatoflavus and A. zonatus do not belong to the genus Aspergillus. Aspergillus clavatoflavus is therefore transferred to a new genus Aspergillago as Aspergillago clavatoflavus and A. zonatus was transferred to Penicilliopsis as P. zonata. The subgenera of Aspergillus share similar extrolite profiles indicating that the genus is one large genus from a chemotaxonomical point of view. Morphological and ecophysiological characteristics of the species also strongly indicate that Aspergillus is a polythetic class in phenotypic characters.
Collapse
|
24
|
Abstract
The taxonomy of the synnematous genera Cephalotrichum, Doratomyces and Trichurus, and other related genera Gamsia, Wardomyces and Wardomycopsis, has been controversial and relies mainly on morphological criteria. These are microascaceous saprobic fungi mostly found in air and soil and with a worldwide distribution. In order to clarify their taxonomy and to delineate generic boundaries within the Microascaceae, we studied 57 isolates that include clinical, environmental and all the available ex-type strains of a large set of species by means of morphological, physiological and molecular phylogenetic analyses using DNA sequence data of four loci (the ITS region, and fragments of rDNA LSU, translation elongation factor 1α and β-tubulin). The results demonstrate that Cephalotrichum, Doratomyces and Trichurus are congeneric and the genus Cephalotrichum is accepted here with Echinobotryum as a further synonym. The genera Acaulium and Fairmania, typified by A. albonigrescens and F. singularis, respectively, are distinct from Microascus and Scopulariopsis, Gamsia is distinct from Wardomyces, and Wardomycopsis is confirmed as a separate genus in the Microascaceae. Two new species of Cephalotrichum are described as C. brevistipitatum and C. hinnuleum. Nine new combinations are proposed, i.e. Acaulium acremonium, A. caviariforme, Cephalotrichum asperulum, C. columnare, C. cylindricum, C. dendrocephalum, C. gorgonifer, Gamsia columbina and Wardomyces giganteus. A neotype is designed for C. stemonitis. Lectotypes and epitypes are designated for A. acremonium, A. albonigrescens, C. gorgonifer, C. nanum and W. anomalus. Cephalotrichum cylindricum, C. microsporum, F. singularis and Gamsia columbina are also epitypified with new specimens. Descriptions of the phenotypic features and dichotomous keys for identification are provided for accepted species in the different genera.
Collapse
|
25
|
Abstract
Species of Coleophoma have been reported as plant pathogenic, saprobic or endophytic on a wide host range. The genus is characterised by having pycnidial conidiomata, phialidic conidiogenous cells intermingled among paraphyses, and cylindrical conidia. Coleophoma has had a confusing taxonomic history with numerous synonyms, and its phylogeny has remained unresolved. The aim of the present study was to use a polyphasic approach incorporating morphology, ecology, and molecular data of the partial large subunit of nrDNA (LSU), the internal transcribed spacer region with intervening 5.8S nrDNA (ITS), partial β-tubulin (tub2), and translation elongation factor 1-alpha (tef1) gene sequences to resolve its taxonomy and phylogeny. Based on these results the genus was found to be polyphyletic, with taxa tentatively identified as Coleophoma clustering in Dothideomycetes and Leotiomycetes. Species corresponding to the concept of Coleophoma s.str. (Dermateaceae, Helotiales, Leotiomycetes) were found to form a distinct clade, with five new species. Furthermore, Coleophoma was found to be linked to the newly established sexual genus, Parafabraea, which is reduced to synonymy. Isolates occurring on Ilex aquifolium in the Netherlands also clustered in Dermateaceae, representing a novel genus, Davidhawksworthia. In the Dothideomycetes, several taxa clustered in Dothiora (Dothideaceae, Dothideales), which is shown to have Dothichiza and Hormonema-like asexual morphs, with four new species. Furthermore, Pseudocamaropycnis is introduced as a new genus (Mytilinidiaceae, Mytilinidiales), along with Briansuttonomyces (Didymellaceae, Pleosporales) and Dimorphosporicola (Pleosporaceae, Pleosporales).
Collapse
|
26
|
Phylogeny of yeasts and related filamentous fungi within Pucciniomycotina determined from multigene sequence analyses. Stud Mycol 2015; 81:27-53. [PMID: 26955197 PMCID: PMC4777782 DOI: 10.1016/j.simyco.2015.08.002] [Citation(s) in RCA: 75] [Impact Index Per Article: 8.3] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 11/26/2022] Open
Abstract
In addition to rusts, the subphylum Pucciniomycotina (Basidiomycota) includes a large number of unicellular or dimorphic fungi which are usually studied as yeasts. Ribosomal DNA sequence analyses have shown that the current taxonomic system of the pucciniomycetous yeasts which is based on phenotypic criteria is not concordant with the molecular phylogeny and many genera are polyphyletic. Here we inferred the molecular phylogeny of 184 pucciniomycetous yeast species and related filamentous fungi using maximum likelihood, maximum parsimony and Bayesian inference analyses based on the sequences of seven genes, including the small subunit ribosomal DNA (rDNA), the large subunit rDNA D1/D2 domains, the internal transcribed spacer regions (ITS 1 and 2) of rDNA including the 5.8S rDNA gene; the nuclear protein-coding genes of the two subunits of DNA polymerase II (RPB1 and RPB2) and the translation elongation factor 1-α (TEF1); and the mitochondrial gene cytochrome b (CYTB). A total of 33 monophyletic clades and 18 single species lineages were recognised among the pucciniomycetous yeasts employed, which belonged to four major lineages corresponding to Agaricostilbomycetes, Cystobasidiomycetes, Microbotryomycetes and Mixiomycetes. These lineages remained independent from the classes Atractiellomycetes, Classiculomycetes, Pucciniomycetes and Tritirachiomycetes formed by filamentous taxa in Pucciniomycotina. An updated taxonomic system of pucciniomycetous yeasts implementing the 'One fungus = One name' principle will be proposed based on the phylogenetic framework presented here.
Collapse
|
27
|
Phylogeny of tremellomycetous yeasts and related dimorphic and filamentous basidiomycetes reconstructed from multiple gene sequence analyses. Stud Mycol 2015; 81:1-26. [PMID: 26955196 PMCID: PMC4777771 DOI: 10.1016/j.simyco.2015.08.001] [Citation(s) in RCA: 109] [Impact Index Per Article: 12.1] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Download PDF] [Figures] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 12/01/2022] Open
Abstract
The Tremellomycetes (Basidiomycota) contains a large number of unicellular and dimorphic fungi with stable free-living unicellular states in their life cycles. These fungi have been conventionally classified as basidiomycetous yeasts based on physiological and biochemical characteristics. Many currently recognised genera of these yeasts are mainly defined based on phenotypical characters and are highly polyphyletic. Here we reconstructed the phylogeny of the majority of described anamorphic and teleomorphic tremellomycetous yeasts using Bayesian inference, maximum likelihood, and neighbour-joining analyses based on the sequences of seven genes, including three rRNA genes, namely the small subunit of the ribosomal DNA (rDNA), D1/D2 domains of the large subunit rDNA, and the internal transcribed spacer regions (ITS 1 and 2) of rDNA including 5.8S rDNA; and four protein-coding genes, namely the two subunits of the RNA polymerase II (RPB1 and RPB2), the translation elongation factor 1-α (TEF1) and the mitochondrial gene cytochrome b (CYTB). With the consideration of morphological, physiological and chemotaxonomic characters and the congruence of phylogenies inferred from analyses using different algorithms based on different data sets consisting of the combined seven genes, the three rRNA genes, and the individual protein-coding genes, five major lineages corresponding to the orders Cystofilobasidiales, Filobasidiales, Holtermanniales, Tremellales, and Trichosporonales were resolved. A total of 45 strongly supported monophyletic clades with multiple species and 23 single species clades were recognised. This phylogenetic framework will be the basis for the proposal of an updated taxonomic system of tremellomycetous yeasts that will be compatible with the current taxonomic system of filamentous basidiomycetes accommodating the ‘one fungus, one name’ principle.
Collapse
|
28
|
Root of Dictyostelia based on 213 universal proteins. Mol Phylogenet Evol 2015; 92:53-62. [PMID: 26048704 DOI: 10.1016/j.ympev.2015.05.017] [Citation(s) in RCA: 13] [Impact Index Per Article: 1.4] [Reference Citation Analysis] [Abstract] [Key Words] [Track Full Text] [Journal Information] [Subscribe] [Scholar Register] [Received: 07/18/2014] [Revised: 05/18/2015] [Accepted: 05/19/2015] [Indexed: 01/03/2023]
Abstract
Dictyostelia are common soil microbes that can aggregate when starved to form multicellular fruiting bodies, a characteristic that has also led to their long history of study and widespread use as model systems. Ribosomal RNA phylogeny of Dictyostelia identified four major divisions (Groups 1-4), none of which correspond to traditional genera. Group 1 was also tentatively identified as sister lineage to the other three Groups, although not consistently or with strong support. We tested the dictyostelid root using universal protein-coding genes identified by exhaustive comparison of six completely sequenced dictyostelid genomes, which include representatives of all four major molecular Groups. A set of 213 genes are low-copy number in all genomes, present in at least one amoebozoan outgroup taxon (Acanthamoeba castellanii or Physarum polycephalum), and phylogenetically congruent. Phylogenetic analysis of a concatenation of the deduced protein sequences produces a single topology dividing Dictyostelia into two major divisions: Groups 1+2 and Groups 3+4. All clades in the tree are fully supported by maximum likelihood and Bayesian inference, and all alternative roots are unambiguously rejected by the approximately unbiased (AU) test. The 1+2, 3+4 root is also fully supported even after deleting clusters with strong individual support for this root, or concatenating all clusters with low support for alternative roots. The 213 putatively ancestral amoebozoan proteins encode a wide variety of functions including 21 KOG categories out of a total of 25. These comprehensive analyses and consistent results indicate that it is time for full taxonomic revision of Dictyostelia, which will also enable more effective exploitation of its unique potential as an evolutionary model system.
Collapse
|
29
|
Abstract
Families and genera assigned to Tremellomycetes have been mainly circumscribed by morphology and for the yeasts also by biochemical and physiological characteristics. This phenotype-based classification is largely in conflict with molecular phylogenetic analyses. Here a phylogenetic classification framework for the Tremellomycetes is proposed based on the results of phylogenetic analyses from a seven-genes dataset covering the majority of tremellomycetous yeasts and closely related filamentous taxa. Circumscriptions of the taxonomic units at the order, family and genus levels recognised were quantitatively assessed using the phylogenetic rank boundary optimisation (PRBO) and modified general mixed Yule coalescent (GMYC) tests. In addition, a comprehensive phylogenetic analysis on an expanded LSU rRNA (D1/D2 domains) gene sequence dataset covering as many as available teleomorphic and filamentous taxa within Tremellomycetes was performed to investigate the relationships between yeasts and filamentous taxa and to examine the stability of undersampled clades. Based on the results inferred from molecular data and morphological and physiochemical features, we propose an updated classification for the Tremellomycetes. We accept five orders, 17 families and 54 genera, including seven new families and 18 new genera. In addition, seven families and 17 genera are emended and one new species name and 185 new combinations are proposed. We propose to use the term pro tempore or pro tem. in abbreviation to indicate the species names that are temporarily maintained.
Collapse
Key Words
- A. cacaoliposimilis (J.L. Zhou, S.O. Suh & Gujjari) Kachalkin, A.M. Yurkov & Boekhout
- A. dehoogii (Middelhoven, Scorzetti & Fell) A.M. Yurkov & Boekhout
- A. domesticum (Sugita, A. Nishikawa & Shinoda) A.M. Yurkov & Boekhout
- A. dulcitum (Berkhout) A.M. Yurkov & Boekhout
- A. gamsii (Middelhoven, Scorzetti, Sigler & Fell) A.M. Yurkov & Boekhout
- A. gracile (Weigmann & A. Wolff) A.M. Yurkov & Boekhout
- A. laibachii (Windisch) A.M. Yurkov & Boekhout
- A. lignicola (Diddens) A.M. Yurkov & Boekhout
- A. loubieri (Morenz) A.M. Yurkov & Boekhout
- A. montevideense (L.A. Queiroz) A.M. Yurkov & Boekhout
- A. mycotoxinivorans (O. Molnár, Schatzm. & Prillinger) A.M. Yurkov & Boekhout
- A. scarabaeorum (Middelhoven, Scorzetti & Fell) A.M. Yurkov & Boekhout
- A. siamense (Nakase, Jindam., Sugita & H. Kawas.) Kachalkin, A.M. Yurkov & Boekhout
- A. sporotrichoides (van Oorschot) A.M. Yurkov & Boekhout
- A. vadense (Middelhoven, Scorzetti & Fell) A.M. Yurkov & Boekhout
- A. veenhuisii (Middelhoven, Scorzetti & Fell) A.M. Yurkov & Boekhout
- A. wieringae (Middelhoven) A.M. Yurkov & Boekhout
- A. xylopini (S.O. Suh, Lee, Gujjari & Zhou) Kachalkin, A.M. Yurkov & Boekhout
- Apiotrichumbrassicae (Nakase) A.M. Yurkov & Boekhout
- Bandonia A.M. Yurkov, X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Bandoniamarina (van Uden & Zobell) A.M. Yurkov, X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Bu. foliicola (Q.M. Wang, F.Y. Bai, Boekhout & Nakase) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Bu. hainanense (Q.M. Wang, F.Y. Bai, Boekhout & Nakase) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Bu. panici (Fungsin, M. Takash. & Nakase) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Bu. pseudovariabile (F.Y. Bai, M. Takash. & Nakase) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Bu. sanyaense (Q.M. Wang, F.Y. Bai, Boekhout & Nakase) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Bu. setariae (Nakase, Tsuzuki, F.L. Lee & M. Takash.) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Bu. siamense (Fungsin, M. Takash. & Nakase) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Bu. variabile (Nakase & M. Suzuki) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Bu. wuzhishanense (Q.M. Wang, F.Y. Bai, Boekhout & Nakase) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Bulleraceae X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Bulleribasidiaceae X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Bulleribasidiumbegoniae (Nakase, Tsuzuki, F.L. Lee & M. Takash.) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Carc. polyporina (D.A. Reid) A.M. Yurkov
- Carcinomycesarundinariae (Fungsin, M. Takash. & Nakase) A.M. Yurkov
- Carlosrosaea A.M. Yurkov, X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Carlosrosaeavrieseae (Landell, Brandão, Safar, Gomes, Félix, Santos, Pagani, Ramos, Broetto, Mott, Valente & Rosa) A.M. Yurkov, X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Cr. luteus (Roberts) Boekhout, Liu, Bai & M. Groenew.
- Cryptococcusdepauperatus (Petch) Boekhout, Liu, Bai & M. Groenew.
- Cu. curvatus (Diddens & Lodder) A.M. Yurkov, X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Cu. cutaneum (de Beurmann, Gougerot & Vaucher) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Cu. cyanovorans (Motaung, Albertyn, J.L.F. Kock et Pohl) A.M. Yurkov, X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Cu. daszewskae (Takash., Sugita, Shinoda & Nakase) A.M. Yurkov, X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Cu. debeurmannianum (Sugita, Takash., Nakase & Shinoda) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Cu. dermatis (Sugita, Takash., Nakase, Ichikawa, Ikeda & Shinoda) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Cu. guehoae (Middelhoven, Scorzettii & Fell) A.M. Yurkov, X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Cu. haglerorum (Middelhoven, Á. Fonseca, S.C. Carreiro, Pagnocca & O.C. Bueno) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Cu. jirovecii (Frágner) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Cu. moniliiforme (Weigmann & A. Wolff) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Cu. mucoides (E. Guého & M.T. Smith) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Cu. oleaginosus (J.J. Zhou, S.O. Suh & Gujjari) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Cu. smithiae (Middelhoven, Scorzetti, Sugita & Fell) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Cu. terricola (Sugita, M. Takash. & Nakase) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Cutaneotrichosporon X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Cutaneotrichosporonarboriformis (Sugita, M. Takash., Sano, Nishim., Kinebuchi, S. Yamag. & Osanai) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Dimennazyma X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Dimennazyma cistialbidi (Á. Fonseca, J. Inácio & Spenc.-Mart.) A.M. Yurkov, X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Effuseotrichosporon A.M. Yurkov, X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Effuseotrichosporon vanderwaltii (Motaung, Albertyn, Kock, C.F. Lee, S.O. Suh, M. Blackwell & C.H. Pohl) A.M. Yurkov, X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Fil. magnum (Lodder & Kreger-van Rij) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Fil. oeirense (Á. Fonseca, Scorzetti & Fell) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Fil. stepposum (Golubev & J.P. Samp.) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Fil. wieringae (Á. Fonseca, Scorzetti & Fell) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Filobasidium chernovii (Á. Fonseca, Scorzetti & Fell) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Fon. mujuensis (K.S. Shin & Y.H. Park) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Fon. tronadorensis (V. De Garcia, Zalar, Brizzio, Gunde-Cim. & van Brook) A.M. Yurkov
- Fonsecazyma X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Fonsecazyma betulae (K. Sylvester, Q.M. Wang, C. T. Hittinger) A.M. Yurkov, A.V. Kachalkin & Boekhout
- Gelidatrema A.M. Yurkov, X.Z. Liu, F.Y. Bai
- Gelidatrema spencermartinsiae (Garcia, Brizzio, Boekhout, Theelen, Libkind & van Broock) A.M. Yurkov, X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Gen. armeniaca (Á. Fonseca & J. Inácio) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Gen. bromeliarum (Landell & P. Valente) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Gen. tibetensis (F.Y. Bai & Q.M. Wang) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Genolevuria X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Genolevuria amylolytica (Á. Fonseca, J. Inácio & Spenc.-Mart.) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Gof. agrionensis (Russo, Libkind, Samp. & van Broock) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Gof. gastrica (Reiersöl & di Menna) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Gof. gilvescens (Chernov & Babeva) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Gof. iberica (Gadanho & J.P. Samp.) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Gof. metallitolerans (Gadanho & J.P. Samp.) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Goffeauzyma X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Goffeauzyma aciditolerans (Gadanho & J.P. Samp.) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Haglerozyma X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Haglerozymachiarellii (Pagnocca, Legaspe, Rodrigues & Ruivo) A. M. Yurkov, X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Het. bachmannii (Diederich & M.S. Christ.) Millanes & Wedin
- Het. physciacearum (Diederich) Millanes & Wedin
- Heterocephalacriaarrabidensis (Á. Fonseca, Scorzetti & Fell) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Itersoniliapannonica (Niwata, Takash., Tornai-Lehoczki, T. Deák & Nakase) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Jelly fungi
- Ko. distylii (Hamam., Kuroy. & Nakase) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Ko. fuzhouensis (J.Z. Yue) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Ko. lichenicola (Prillinger, G. Kraep. & Lopandic) X.Z. Liu, F.Y. Bai
- Ko. mexicana (Lopandic, O. Molnár & Prillinger) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Ko. ogasawarensis (Hamam., Kuroy. & Nakase) X.Z. Liu, F.Y. Bai, Groenew. & Boekhout
- Ko. sichuanensis (Prillinger, G. Kraep. & Lopandic) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Kockovaellachinensis (Prillinger, G. Kraep. & Lopandic) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Kockovaellaprillingeri (Prillinger, G. Kraep. & Lopandic) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Kr. tahquamenonensis (Wang, Hulfachor, Sylvester and Hittinger) A.M. Yurkov
- Krasilnikovozyma X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Krasilnikovozymahuempii (C. Ramírez & A. E. González) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Kw. dejecticola (Thanh, Hai & Lachance) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Kw. dendrophila (Van der Walt & D.B. Scott) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Kw. pini (Golubev & Pfeiffer) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Kw. shivajii (S.R. Ravella, S.A. James, C.J. Bond, I.N. Roberts, K. Cross, Retter & P.J. Hobbs) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Kwoniellabestiolae (Thanh, Hai & Lachance) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- M. Groenew. & Boekhout
- M. cryoconiti (Margesin & Fell) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- M. niccombsii (Thomas-Hall) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Morphology
- Mrakiaaquatica (E.B.G. Jones & Slooff) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Mrakiaceae X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Multigene phylogeny
- Naem. microspora (Lloyd) Millanes & Wedin
- Naemateliaaurantialba (Bandoni & M. Zang) Millanes & Wedin
- Naemateliaceae X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Nag. albida (Saito) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Nag. albidosimilis (Vishniac & Kurtzman) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Nag. antarctica (Vishniac & Kurtzman) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Nag. bhutanensis (Goto & Sugiy.) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Nag. cerealis (Passoth, A.-C. Andersson, Olstorpe, Theelen, Boekhout & Schnürer) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Nag. diffluens (Zach) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Nag. friedmannii (Vishniac) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Nag. liquefaciens (Saito & M. Ota) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Nag. onofrii (Turchetti, Selbmann & Zucconi) A.M. Yurkov
- Nag. randhawae (Z.U. Khan, S.O. Suh. Ahmad, F. Hagen, Fell, Kowshik, Chandy & Boekhout) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Nag. uzbekistanensis (Á. Fonseca, Scorzetti & Fell) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Nag. vaughanmartiniae (Turchetti, Blanchette & Arenz) A.M. Yurkov
- Nag. vishniacii (Vishniac & Hempfling) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Naganishiaadeliensis (Scorzetti, I. Petrescu, Yarrow & Fell) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Niel. melastomae (Nakase, Tsuzuki, F.L. Lee & M. Takash.) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Nielozyma X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Nielozymaformosana (Nakase, Tsuzuki, F.L. Lee & M. Takash.) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- P. mycophaga (G.W. Martin) Millanes & Wedin
- Pap. aspenensis (K. Ferreira-Paim, T.B. Ferreira, L. Andrade-Silva, D.J. Mora, D.J. Springer, J. Heitman, F.M. Fonseca, D. Matos, M.S.C. Melhem & M.L. Silva-Vergara) X.Z. Liu, F.Y. Bai, A.M. Yurkov & Boekhout
- Pap. aurea (Saito) M. Takash., Sugita, Shinoda & Nakase) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Pap. baii (A.M. Yurkov, M.A. Guerreiro & Á. Fonseca) A.M. Yurkov
- Pap. flavescens (Saito) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Pap. fonsecae (V. de García, Zalar, Braizzio, Gunde-Cim. & van Brollck) A.M. Yurkov
- Pap. frias (V. de García, Zalar, Braizzio, Gunde-Cim. & van Brollck) A.M. Yurkov
- Pap. fuscus (J.P. Samp., J. Inácio, Fonseca & Fell) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Pap. hoabinhensis (D.T. Luong, M. Takash., Ty. Dung & Nakase) A.M. Yurkov
- Pap. japonica (J.P. Samp., Fonseca & Fell) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Pap. laurentii (Kuff.) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Pap. mangalensis (Fell, Statzell & Scorzett) A.M. Yurkov
- Pap. nemorosus (Golubev, Gadanho, J.P. Samp. & N.W. Golubev) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Pap. perniciosus (Golubev, Gadanho, J.P. Samp. & N.W. Golubev) X.Z. Liu, F.Y. Bai
- Pap. pseudoalba (Nakase & M. Suzuki) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Pap. rajasthanensis (Saluja & G.S. Prasad) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Pap. ruineniae (A.M. Yurkov, M.A. Guerreiro & Á. Fonseca) A.M. Yurkov
- Pap. taeanensis (K.S. Shin & Y.H. Park) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Pap. terrestris (Crestani, Landell, Faganello, Vainstein, Vishniac & P. Valente) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Pap. wisconsinensis (Crestani, Landell, Faganello, Vainstein, Vishniac & P. Valente) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Papiliotremaanemochoreius (C.H. Pohl, Kock, P.W.J. van Wyk & Albertyn) F.Y. Bai, M. Groenew. & Boekhout
- Ph. mycetophiloides (Kobayasi) Millanes & Wedin
- Ph. neofoliacea (Chee J. Chen) Millanes & Wedin
- Ph. simplex (H.S. Jacks. & G.W. Martin) Millanes & Wedin
- Ph. skinneri (Phaff & Carmo Souza) A.M. Yurkov & Boekhout
- Phaeotremellaceae A.M. Yurkov & Boekhout
- Phaeotremellafagi (Middelhoven & Scorzetti) A.M. Yurkov & Boekhout
- Pis. cylindrica (Á. Fonseca, Scorzetti & Fell) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Pis. fildesensis (T. Zhang & L.-Y. Yu) A.M. Yurkov
- Pis. filicatus (Golubev & J.P. Samp.) Kachalkin
- Pis. silvicola (Golubev & J.P. Samp.) X.Z. Liu, F.Y. Bai, Groenew. & Boekhout
- Pis. sorana (Hauerslev) A.M. Yurkov
- Pis. taiwanensis (Nakase, Tsuzuki & M. Takash.) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Piskurozyma X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Piskurozymacapsuligena (Fell, Statzell, I.L. Hunter & Phaff) A.M. Yurkov
- Piskurozymaceae X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Ps. lacticolor (Satoh & Makimura) A.M. Yurkov
- Ps. moriformis (Berk.) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Ps. nivalis (Chee J. Chen) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Pseudotremella X.Z. Liu, F.Y. Bai, A.M. Yurkov, M. Groenew. & Boekhout
- Pseudotremellaallantoinivorans (Middelhoven) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- R. complexa (Landell, Pagnocca, Sette, Passarini, Garcia, Ribeiro, Lee, Brandao, Rosa & Valente) X.Z. Liu, F.Y. Bai, M. Groenew., Boekhout & A.M. Yurkov
- R. fermentans (Lee) X.Z. Liu, F.Y. Bai, M. Groenew., Boekhout & A.M. Yurkov
- R. glucofermentans (S.O. Suh & Blackwell) X.Z. Liu, F.Y. Bai, M. Groenew., Boekhout & A.M. Yurkov
- R. nanyangensis (F.L. Hui & Q.H. Niu) X.Z. Liu, F.Y. Bai, M. Groenew., Boekhout & A.M. Yurkov
- R. noutii (Boekhout, Fell, Scorzett & Theelen) X.Z. Liu, F.Y. Bai, M. Groenew., Boekhout & A.M. Yurkov
- R. tunnelae (Boekhout, Fell, Scorzetti & Theelen) X.Z. Liu, F.Y. Bai, M. Groenew., Boekhout & A.M. Yurkov
- R. visegradensis (Peter & Dlauchy) X.Z. Liu, F.Y. Bai, M. Groenew., Boekhout & A.M. Yurkov
- Ranks
- Rhynchogastremaaquatica (Brandao, Valente, Pimenta & Rosa) X.Z. Liu, F.Y. Bai, M. Groenew., Boekhout & A.M. Yurkov
- Sait. ninhbinhensis (Luong, Takash., Dung & Nakase) A.M. Yurkov
- Sait. paraflava (Golubev & J.P. Samp.) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Sait. podzolica (Babeva & Reshetova) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Saitozyma X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Saitozymaflava (Saito) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Sol. fuscescens (Golubev) A.M. Yurkov
- Sol. keelungensis (C.F. Chang & S.M. Liu) A.M. Yurkov
- Sol. phenolicus (Á. Fonseca, Scorzetti & Fell) A.M. Yurkov
- Sol. terreus (Di Menna) A.M. Yurkov
- Sol. terricola (T.A. Pedersen) A.M. Yurkov
- Solicoccozyma X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Solicoccozymaaeria (Saito) A.M. Yurkov
- Sugitazyma A.M. Yurkov, X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Sugitazymamiyagiana (Nakase, Itoh, Takem. & Bandoni) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Tausoniapullulans (Lindner) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Taxonomy
- Tremellayokohamensis (Alshahni, Satoh & Makimura) A.M. Yurkov
- Tremellomycetes
- Trimorphomycessakaeraticus (Fungsin, M. Takash. & Nakase) X.Z. Liu, F.Y. Bai, M. Groenew., Boekhout & A.M. Yurkov
- Trimorphomycetaceae X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Van. meifongana (C.F. Lee) Kachalkin, A.M. Yurkov & Boekhout
- Van. nantouana (C.F. Lee) Kachalkin, A.M. Yurkov & Boekhout
- Van. thermophila (Vogelmann, Chaves & Hertel) Kachalkin, A.M. Yurkov & Boekhout
- Vanrijafragicola (M. Takash., Sugita, Shinoda & Nakase) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Vis. dimennae (Fell & Phaff) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Vis. foliicola (Q.M. Wang & F.Y. Bai) A.M. Yurkov
- Vis. globispora (B.N. Johri & Bandoni) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Vis. heimaeyensis (Vishniac) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Vis. nebularis (Vishniac) A.M. Yurkov
- Vis. peneaus (Phaff, Mrak & O.B. Williams) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Vis. psychrotolerans (V. de García, Zalar, Brizzio, Gunde-Cim. & van Broock) A.M. Yurkov
- Vis. taibaiensis (Q.M. Wang & F.Y. Bai) A.M. Yurkov
- Vis. tephrensis (Vishniac) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Vis. victoriae (M.J. Montes, Belloch, Galiana, M.D. García, C. Andrés, S. Ferrer, Torr.-Rodr. & J. Guinea) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Vishniacozyma X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Vishniacozymacarnescens (Verona & Luchetti) X.Z. Liu, F.Y. Bai, M. Groenew. & Boekhout
- Yeasts
Collapse
|
30
|
Abstract
Species belonging to Penicillium section Aspergilloides have a world-wide distribution with P. glabrum, P. spinulosum and P. thomii the most well-known species of this section. These species occur commonly and can be isolated from many substrates including soil, food, bark and indoor environments. The taxonomy of these species has been investigated several times using various techniques, but species delimitation remains difficult. In the present study, 349 strains belonging to section Aspergilloides were subjected to multilocus molecular phylogenetic analyses using partial β-tubulin (BenA), calmodulin (CaM) and RNA polymerase II second largest subunit (RPB2) sequences. Section Aspergilloides is subdivided into 12 clades and 51 species. Twenty-five species are described here as new and P. yezoense, a species originally described without a Latin diagnosis, is validated. Species belonging to section Aspergilloides are phenotypically similar and most have monoverticillate conidiophores and grow moderately or quickly on agar media. The most important characters to distinguish these species were colony sizes on agar media, growth at 30 °C, ornamentation and shape of conidia, sclerotium production and stipe roughness.
Collapse
|