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Byssoloma orientale (Pilocarpaceae, Ascomycota), a new species from East Asia

Published online by Cambridge University Press:  16 November 2023

Kento Miyazawa*
Affiliation:
Degree Programs in Life and Earth Sciences, Graduate School of Science and Technology, University of Tsukuba, Tsukuba, Ibaraki, 305-8572, Japan
Yoshihito Ohmura
Affiliation:
Department of Botany, National Museum of Nature and Science, Tsukuba, 305-0005, Japan School of Integrative and Global Majors, University of Tsukuba, Tsukuba, Ibaraki, 305-8572, Japan
*
Corresponding author: Kento Miyazawa; Email: [email protected]

Abstract

A new species, Byssoloma orientale K. Miyaz. & Y. Ohmura, is described from East Asia. It is characterized by a minutely farinose light green thallus, apothecia with a well-developed byssoid margin that spreads laterally over the thallus surface, a pure black apothecial disc caused by the presence of an aeruginous pigment in the epithecium, (7–)9–12(–17)-septate cylindrical colourless ascospores, and oblong conidia. This species grows on living leaves as well as on tree bark. The molecular phylogenetic position of B. orientale within this genus was inferred based on mtSSU sequences, and the species was shown to be closely related to B. vanderystii, which has up to 7-septate ascospores and an absence of aeruginous pigment in the epithecium.

Type
Standard Paper
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of the British Lichen Society

Introduction

Byssoloma Trevis. is the type genus of the Pilocarpaceae (lichenized Ascomycota) and is mainly distributed in tropical and subtropical regions worldwide (Lücking Reference Lücking2008). At present, 58 species are recognized worldwide, growing mainly on living leaves and bark, sometimes on rocks and on the thalli of other lichens (Santesson Reference Santesson1952; James Reference James1971; Vězda Reference Vězda1975, Reference Vězda1986, Reference Vězda1987, Reference Vězda1994; Sérusiaux Reference Sérusiaux1978, Reference Sérusiaux1979, Reference Sérusiaux1996, Reference Sérusiaux1998; Kalb & Vězda Reference Kalb and Vězda1990, Reference Kalb and Vězda1994; Coppins et al. Reference Coppins, James and Hawksworth1992; Sipman & Aptroot Reference Sipman and Aptroot1992; Fárkas & Vězda Reference Fárkas and Vězda1993; Malcolm & Vězda Reference Malcolm and Vězda1995; Ekman Reference Ekman1996; Kondratyuk Reference Kondratyuk and Wasser1996; Aptroot et al. Reference Aptroot, Diederich, Sérusiaux and Sipman1997; Lücking et al. Reference Lücking, Sérusiaux, Maia and Pereira1998, Reference Lücking, Sérusiaux and Santesson2002; Thor et al. Reference Thor, Lücking and Matsumoto2000; Sérusiaux et al. Reference Sérusiaux, Gómez-Bolea, Longán and Lücking2002; Schubert et al. Reference Schubert, Lücking and Lumbsch2003; Lücking Reference Lücking2006, Reference Lücking2008, Reference Lücking2013; Messuti & de la Rosa Reference Messuti and de la Rosa2007; Lumbsch et al. Reference Lumbsch, Ahti, Altermann, de Paz G, Aptroot, Arup, Bárcenas Peña, Bawingan, Benatti and Betancourt2011; Breuss Reference Breuss2013, Reference Breuss2014; Cáceres et al. Reference Cáceres, Santos, Mendonça, Mota and Aptroot2013; Aptroot Reference Aptroot2014; van den Boom Reference van den Boom2016; Elix & McCarthy Reference Elix and McCarthy2018; Wang et al. Reference Wang, van den Boom, Sangvichien and Wei2020a). The genus Byssoloma is characterized by its byssoid apothecial margin (inconspicuous in some species) and I+ dark blue asci with a tubular structure at the apices (‘Byssoloma type’ in Hafellner (Reference Hafellner1984)), pyriform or oblong conidia, and mainly transversely 1–7-septate ascospores, sometimes up to 19(–23)-septate in some species (Sérusiaux Reference Sérusiaux1993; Lücking Reference Lücking2008).

During the study of Byssoloma specimens housed in the herbarium of the National Museum of Nature and Science (TNS), Tsukuba, Japan, several specimens collected in Japan and China were recognized as an undescribed species. The aim of this study is to describe and illustrate the new species Byssoloma orientale, and to discuss the variation within the species and the differences with similar taxa.

Materials and Methods

Morphology and chemistry

Morphological observations and photography were performed using a dissecting microscope (SZX16; Olympus, Tokyo, Japan) and a differential interference contrast microscope (BX51; Olympus) equipped with a digital camera (EOS Kiss X10i; Canon, Tokyo, Japan). Anatomical examinations were carried out using hand-cut sections mounted in GAW (glycerin:ethanol: water = 1:1:1) solution (Asahina Reference Asahina1936). The digital images in Fig. 2A & B were prepared using CombineZP image stacking software developed by Alan Hadley (GNU Public License).

Ascus amyloidity was examined using Lugol's solution (I) and K reaction for fungal tissues was tested using 5% KOH solution. Secondary substances were analyzed using high-performance thin-layer chromatography (HPTLC) following Schumm & Elix (Reference Schumm and Elix2015). The solvent B′ (n-hexane:methyl tert-butyl ether:formic acid, 140:72:18) (Culberson & Johnson Reference Culberson and Johnson1982) was used for HPTLC. The spot colour was checked under 254 and 366 nm wavelength of UV and visible light, before and after spraying with 10% sulphuric acid on the HPTLC plate and charring at 90 °C for 20 min.

DNA extraction, PCR amplification and sequencing

DNA extraction for PCR was performed following a modified method of Izumitsu et al. (Reference Izumitsu, Hatoh, Sumita, Kitade, Morita, Gafur, Ohta, Kawai, Yamanaka and Neda2012) (see Miyazawa et al. Reference Miyazawa, Ohmura and Yamaoka2022). Partial sequences of the small subunit of the mitochondrial ribosomal RNA gene (mtSSU) were amplified using the primers mrSSU1 and mrSSU3R (Zoller et al. Reference Zoller, Scheidegger and Sperisen1999) according to the following protocol. PCR was performed in a 15 μl reaction solution containing 2 μl DNA template, 7.5 μl GenRED PCR Mix Plus (Nippon Gene, Tokyo, Japan), 1.5 μl of each primer (2 pmol μl−1), and 2.5 μl of distilled water. PCR conditions followed the method of Wang et al. (Reference Wang, Sangvichien, Wei and Wei2020b), using a TaKaRa PCR Thermal Cycler Dice® Touch (TaKaRa, Tokyo, Japan). The PCR products were checked by electrophoresis on a 1.5% agarose gel stained with Midori Green Direct DNA Stain (Nippon Genetics, Tokyo, Japan) and visualized using WSE-5200 Printgraph 2M (ATTO Corporation, Tokyo, Japan). PCR products were purified using the ExoSAP-IT™ PCR Product Cleanup Reagent (Thermo Fisher Scientific, Massachusetts, USA). A volume of 13 μl of PCR products with 2 μl of four times diluted ExoSAP-IT™ was incubated at 37 °C for 15 min, then 80 °C for 15 min.

DNA sequencing was performed either on an Applied Biosystems™ 3500xL Genetic Analyzer (Thermo Fisher Scientific) using the BigDye® Terminator v. 3.1 Cycle Sequencing Kit (Thermo Fisher Scientific) following the manufacturer's instructions, or through a DNA sequencing service provided by Eurofins Genomics in Tokyo, Japan.

Molecular phylogenetic analyses

The five mtSSU sequences of Byssoloma orientale from Japanese material were aligned with the 37 registered sequences of selected taxa in GenBank (Table 1) using MAFFT v. 7 (Katoh et al. Reference Katoh, Rozwicki and Yamada2019) with default settings. For the outgroup, the sequences of Byssolecania hymenocarpa (Vain.) Kalb et al. (MK957152 and MK957159) and Byssolecania sp. (MK957170) from GenBank were used to enable a comparison with the phylogenetic tree generated by Wang et al. (Reference Wang, van den Boom, Sangvichien and Wei2020a). The final alignment of 631 sites was used for the molecular phylogenetic analyses, after removing sites with gaps and missing data.

Table 1. Voucher information, GenBank Accession numbers and references for Byssoloma and related taxa used in the phylogenetic analysis (Fig. 1). New sequences obtained in this study are in bold.

Figure 1. Maximum likelihood (ML) tree of mtSSU sequences from selected taxa in Byssoloma showing the phylogenetic position of Byssoloma orientale collected from Japan (in bold). Byssolecania spp. are used as an outgroup. Maximum likelihood and neighbour-joining (NJ) support values (≥70) are presented for each node (ML/NJ). Branches highly supported (≥90) by both analyses are indicated with bold black lines. Alphanumeric codes indicate the GenBank number, voucher number and country code (CH = China; EC = Ecuador; JP = Japan; PT = Portugal; SR = Suriname; TH = Thailand).

The maximum likelihood (ML) phylogenetic tree was generated with the Tamura 3-parameter model (Tamura Reference Tamura1992) plus gamma distribution which was selected as the best-fitting model. Bootstrap values (≥70%) with 1000 replicates for ML and the neighbour-joining method (NJ) are shown on each branch (Fig. 1). A branch with high bootstrap values (≥90%) in both analyses is indicated with a bold black line. All calculations were conducted in MEGA X (Kumar et al. Reference Kumar, Stecher, Li, Knyaz and Tamura2018).

Results and Discussion

Within the Japanese material of the new species Byssoloma orientale, there are five variable sites and five gap sites in the 825 aligned sites of mtSSU. The identity among five samples was 99.4–99.9%. Since no discernible differences in morphology were observed, these genetic differences were treated as variations within a species.

The ML phylogenetic tree is shown in Fig. 1. The topology of our phylogenetic tree including the sequences of B. orientale and other Japanese Byssoloma taxa registered in Miyazawa et al. (Reference Miyazawa, Ohmura and Yamaoka2022) shows no conflict with that of Wang et al. (Reference Wang, van den Boom, Sangvichien and Wei2020a). The samples of B. orientale formed a monophyletic clade with high support values (ML/NJ = 100/100) and sister to B. vanderystii Sérus. with high support (ML/NJ = 99/99).

Taxonomic Treatment

Byssoloma orientale K. Miyaz. & Y. Ohmura sp. nov.

MycoBank No.: MB 849345

Differs from B. vanderystii Sérus. by the pure black disc of the epithecium which has a dense accumulation of aeruginous pigment, and by the longer and (7–)9–12(–17)-septate ascospores (18.3–49.2 × 2.0–4.0 μm).

Type: Japan, Ryukyu Islands (Okinawa Pref.), Takae, Higashi-son, Kunigami-gun (26°39′59″N, 128°14′46″E), on leaf of Arenga engleri along a stream, 75 m elev., 15 November 2022, K. Miyazawa 1178 (TNS—holotype TNS-L-132526). GenBank Accession no.: LC773156 (mtSSU).

(Fig. 2)

Figure 2. Byssoloma orientale collected from Japan. A, thallus with apothecia (holotype, TNS). B, pycnidia on thallus (holotype, TNS). C, a vertical section of thallus with photobiont cells (holotype, TNS); h = hyphae of mycobiont, p = photobiont cell, ls = leaf surface. D, section of apothecium (K. Miyazawa et al. 792, TNS). E, ascus with ascospores stained by Lugol's solution (K. Miyazawa et al. 792, TNS). F, apical structure of ascus stained by Lugol's solution (K. Miyazawa et al. 792, TNS). G, ascospores with various numbers of septa (K. Miyazawa et al. 792, TNS). H, conidia (holotype, TNS). Scales: A = 1 mm; B = 200 μm; C = 10 μm; D = 50 μm; E & F = 20 μm; G = 15 μm; H = 5 μm. In colour online.

Thallus crustose, irregular in shape, continuous, 20–60 mm across, 5–15 μm thick, minutely farinose, light green. Photobiont trebouxioid, ellipsoid, (3.6–)4.2–5.3(–5.5) × (2.3–)2.8–3.8(–4.7) μm (n = 30).

Apothecia sessile, rounded, 0.4–1.2 mm diam., 85–130 μm tall; margin well developed, densely byssoid, persistent, spreading laterally over thallus surface, 50–300 μm wide, white, sometimes brownish white, composed of loosely woven colourless hyphae; disc slightly to strongly convex, pure black; epithecium with abundant aeruginous pigment, 1.5–4.5 μm tall; hymenium 40–65 μm tall, colourless, with or without aeruginous pigment; hypothecium 40–65 μm tall, reddish brown, K+ purple; apothecial base brownish black, K−; paraphyses branched and sometimes anastomosing, 0.6–1.7 μm wide, often apically thickened (up to 2.2 μm wide). Asci clavate, 8-spored, I+ dark blue with the tubular structure at the apices, tholus amyloid (‘Byssoloma-type’ in Hafellner (Reference Hafellner1984)), 32–60 × 9–13 μm. Ascospores cylindrical, (7–)9–12(–17)-septate, with or without slight constriction at septa, colourless, (18.3–)21.0–35.5(–49.2) × (2.0–)2.4–3.3(–4.0) μm (n = 30), 6–16.5 times as long as wide.

Pycnidia flask-shaped, 100–140 μm diam., greyish black, covered by whitish loose hyphal tissue. Conidia oblong without constriction, aseptate, colourless, (3.7–)4.4–5.1(–5.6) × (0.9–)1.1–1.3(–1.6) μm (n = 100), 2.5–5 times as long as wide.

Chemistry

No secondary substance was detected with HPTLC.

Etymology

The epithet ‘orientale’ is a Latin adjective that refers to the Far East, where the new species was collected from Japan and China.

Habitat and distribution

This species grows on living leaves of Arenga engleri, as well as on bark of evergreen broadleaf trees, in conserved rainforests of southern Japan at elevations of 40–300 m and central China at elevations of 400–500 m.

Notes

Byssoloma orientale is similar to B. vanderystii in the byssoid apothecial margin spreading laterally over the thallus surface (Fig. 2A), the 7–17-septate ascospores (Fig. 2G) and the oblong conidia (Fig. 2H), whereas other Byssoloma species typically have 3–5-septate ascospores and pyriform conidia. Morphological and molecular phylogenetic analyses in this study show that B. orientale is closely related to B. vanderystii but that the two species are genetically independent. Byssoloma orientale differs from B. vanderystii in having longer ascospores with more septa (18.3–49.2 × 2.0–4.0 μm, (7–)9–12(–17) septa vs 22–33 × 2.0–3.5 μm, 7 septa in B. vanderystii) (Sérusiaux Reference Sérusiaux1979; Lücking Reference Lücking2008; Miyazawa et al. Reference Miyazawa, Ohmura and Yamaoka2022) and in the accumulation of aeruginous pigment in the epithecium resulting in a pure black disc appearance.

Byssoloma orientale resembles B. kakouettae (Sérus.) Lücking & Sérus. and B. laurisilvae Breuss in having ascospores with more than 7 septa. However, B. kakouettae, which is reported from Macaronesia and Western Europe, differs from B. orientale in having no apothecial margin extending laterally over the thallus surface, an orange to black disc without a pigmented epithecium, larger ascospores (40–67 × 2.5–6 μm) with up to 19(–23) septa, no well-branched paraphyses, and narrow and bifusiform to obpyriform conidia (Sérusiaux Reference Sérusiaux1993; Sérusiaux et al. Reference Sérusiaux, Gómez-Bolea, Longán and Lücking2002; van den Boom Reference van den Boom2021). Byssoloma laurisilvae, reported from the Canary Islands, differs from B. orientale in having apothecial margins not extending into the thallus surface, a yellowish to ochre disc without a pigmented epithecium, longer ascospores (40–48(–55) × (3.5–)4–5 μm) with 11–16 septa, and bifusiform conidia (Breuss Reference Breuss2013; van den Boom Reference van den Boom2021).

Byssoloma orientale might be confused with B. chlorinum (Vain.) Zahlbr. because both have a light green farinose thallus, a pure black disc and a byssoid apothecial margin which spreads laterally over the thallus surface (Fig. 2A). However, B. chlorinum differs in having 3-septate ascospores and pycnidia that produce pyriform conidia (Lücking Reference Lücking2008; Miyazawa et al. Reference Miyazawa, Ohmura and Yamaoka2022). The differences between the two species are also supported by the results of the molecular phylogenetic analysis in this study (Fig. 1).

Additional specimens examined

China: Jianxi Sang Province: Yichun Region, Yifeng Co., Mazhishango, Jiulingshan Mts (Guanshan Nature Reserve), on tree bark along river, 400–500 m elev., 1995, H. Kashiwadani 41330 (TNS).—Japan: Kyushu, Hyuga Prov. (Miyazaki Pref.): Inohae Valley, Kitagawachi, Kitagou-cho, Nichinan-city (31°43′N, 131°22′E), on twig of Machilus japonica, c. 100 m elev., 2021, K. Miyazawa 938, K. Gibu & A. Ohmaki (TNS). Ryukyu Islands (Okinawa Pref.): Takae, Higashi-son, Kunigami-gun (26°39′59′′N, 128°14′46′′E), on leaf of Arenga engleri along a stream, 75 m elev., 2022, K. Miyazawa 1177 pr. p. (in collection of Byssoloma vanderystii) (TNS); ibid., on trunk of broadleaf tree along a stream, K. Miyazawa 1183 (TNS), K. Miyazawa 1184 (TNS); Genka, Nago-city (26°36′55–59ʺN, 128°03′46–49ʺE), on trunk of broadleaf tree along Genka River, 40 m elev., 2021, K. Miyazawa 792, K. Gibu & T. Nada (TNS); along the mountain path, Mt Katsuu, Nago-city (26°37′53ʺN, 127°56′14ʺE), on trunk of evergreen broadleaf tree, 300 m elev., 2023, K. Miyazawa 1301 (TNS).

Acknowledgements

We thank two anonymous reviewers for the careful reading of our manuscript and for providing valuable comments; K. Gibu for coordinating the field investigations on Okinawa Island; I. Okane for helping us to obtain the necessary permissions for our collections on Okinawa Island. Permissions to collect on Okinawa Island were kindly granted by the Okinawa Amami Nature Conservation Office, Kyushu Regional Environment Office, the Ministry of the Environment Government of Japan (no. 2102242), and for Inohae Valley by the Miyazaki Nambu Forest Management Station, Forestry Agency, and the Ministry of Agriculture, Forestry and Fisheries Government of Japan (no. 1). This study was partly supported by JSPS KAKENHI (no. 22J20567) to KM.

Author ORCIDs

Kento Miyazawa, 0009-0002-0629-5551; Yoshihito Ohmura, 0000-0003-2557-2761.

References

Aptroot, A (2014) Two new genera of Arthoniales from New Caledonia and the Solomon Islands, with the description of eight further species. Bryologist 117, 282289.CrossRefGoogle Scholar
Aptroot, A, Diederich, P, Sérusiaux, E and Sipman, HJM (1997) Lichens and lichenicolous fungi from New Guinea. Bibliotheca Lichenologica 64, 1220.Google Scholar
Asahina, Y (1936) Mikrochemischer Nachweis der Flechtenstoffe (I). Journal of Japanese Botany 12, 516525.Google Scholar
Breuss, O (2013) Byssoloma laurisilvae und Thelotrema lueckingii, zwei neue Flechtenarten aus Madeira. Österreichische Zeitschrift für Pilzkunde 22, 99105.Google Scholar
Breuss, O (2014) Weitere Flechtenfunde aus Madeira. Stapfia 101, 4751.Google Scholar
Cáceres, MES, Santos, MWO, Mendonça, CO, Mota, DA and Aptroot, A (2013) New lichen species of the genera Porina and Byssoloma from an urban Atlantic rainforest patch in Sergipe, NE Brazil. Lichenologist 45, 379382.Google Scholar
Coppins, BJ, James, PW and Hawksworth, DL (1992) New species and combinations in the lichen flora of Great Britain and Ireland. Lichenologist 24, 351369.Google Scholar
Culberson, CF and Johnson, A (1982) Substitution of methyl tert-butyl ether for diethyl ether in the standardized thin-layer chromatographic method for lichen products. Journal of Chromatography 238, 483487.Google Scholar
Ekman, S (1996) The corticolous and lignicolous species of Bacidia and Bacidina in North America. Opera Botanica 127, 1148.Google Scholar
Elix, JA and McCarthy, PM (2018) Ten new lichen species (Ascomycota) from Australia. Australasian Lichenology 82, 2059.Google Scholar
Fárkas, E and Vězda, A (1993) Five new foliicolous lichen species. Folia Geobotanica et Phytotaxonomica 28, 321330.Google Scholar
Hafellner, J (1984) Studien in Richtung einer naturlicheren Gliederung der Sammelfamilien Lecanoraceae und Lecideaceae. Beiheft zur Nova Hedwigia 79, 241371.Google Scholar
Izumitsu, K, Hatoh, K, Sumita, T, Kitade, Y, Morita, A, Gafur, A, Ohta, A, Kawai, M, Yamanaka, T, Neda, H, et al. (2012) Rapid and simple preparation of mushroom DNA directly from colonies and fruiting bodies for PCR. Mycoscience 53, 396401.Google Scholar
James, PW (1971) New or interesting British lichens: 1. Lichenologist 5, 114148.Google Scholar
Kalb, K and Vězda, A (1990) Die Flechtengattung Byssoloma in der Neotropis (eine taxonomisch-phytogeographische Studie). Nova Hedwigia 51, 435451.Google Scholar
Kalb, K and Vězda, A (1994) Beiträge zur Kenntnis der foliicolen Flechten australischer Regenwälder IV. Bulletin de la Société Linnéenne de Provence 45, 235246.Google Scholar
Katoh, K, Rozwicki, J and Yamada, KD (2019) MAFFT online service: multiple sequence alignment, interactive sequence choice and visualization. Briefings in Bioinformatics 20, 11601166.Google Scholar
Kondratyuk, SY (1996) Four new species of lichenicolous fungi. In Wasser, SP (ed.), Botany and Mycology for the Next Millennium: Collection of Scientific Articles Devoted to the 70th Anniversary of Academician K. M. Sytnik. Kyiv: M. G. Kholodny Institute of Botany, National Academy of Sciences of Ukraine, pp. 309315.Google Scholar
Kumar, S, Stecher, G, Li, M, Knyaz, C and Tamura, K (2018) MEGA X: Molecular Evolutionary Genetics Analysis across computing platforms. Molecular Biology and Evolution 35, 15471549.Google Scholar
Lücking, R (2006) Foliicolous lichens from French Guiana (northeastern South America). Cryptogamie, Mycologie 27, 121147.Google Scholar
Lücking, R (2008) Foliicolous lichenized fungi. Flora Neotropica Monograph 103, 1866.Google Scholar
Lücking, R (2013) Platygrapha permutans Nyl. is an earlier name for Byssoloma rubrireagens Kalb & Vězda. Lichenologist 45, 579580.Google Scholar
Lücking, R, Sérusiaux, E, Maia, LC and Pereira, CG (1998) A revision of the names of foliicolous lichenized fungi published by Batista and co-workers between 1960 and 1975. Lichenologist 30, 121191.Google Scholar
Lücking, R, Sérusiaux, E and Santesson, R (2002) Ceratopycnidium citricola is Byssoloma lueckingii. Lichenologist 34, 270272.Google Scholar
Lumbsch, HT, Ahti, T, Altermann, S, de Paz G, Amo, Aptroot, A, Arup, U, Bárcenas Peña, A, Bawingan, PA, Benatti, MN, Betancourt, L, et al. (2011) One hundred new species of lichenized fungi: a signature of undiscovered global diversity. Phytotaxa 18, 1127.Google Scholar
Malcolm, WM and Vězda, A (1995) Two new saxicolous species of the lichen genus Byssoloma from New Zealand. Mycotaxon 55, 357362.Google Scholar
Messuti, MI and de la Rosa, IN (2007) Byssoloma rubromarginatum (Pilocarpaceae: Ascomycota), a new corticolous species from Nothofagus forests in Argentina. Mycological Progress 6, 235238.Google Scholar
Miyazawa, K, Ohmura, Y and Yamaoka, Y (2022) Noteworthy foliicolous lichens collected from Iriomote Island, southern Japan. Taiwania 67, 155163.Google Scholar
Santesson, R (1952) Foliicolous lichens I. A revision of the taxonomy of the obligately foliicolous, lichenized fungi. Symbolae Botanicae Upsalienses 12, 1590.Google Scholar
Schubert, R, Lücking, R, Lumbsch, HT (2003) New species of foliicolous lichens from ‘La Amistad’ Biosphere Reserve, Costa Rica. Willdenowia 33, 459465.CrossRefGoogle Scholar
Schumm, F and Elix, JA (2015) Atlas of Images of Thin Layer Chromatograms of Lichen Substances. Norderstedt: Books on Demand GmbH.Google Scholar
Sérusiaux, E (1978) Contribution a l'etude des lichens du Kivu (Zaire), du Rwanda et du Burundi. II. Espèces nouvelles de lichens foliicoles. Lejeunia 90, 118.Google Scholar
Sérusiaux, E (1979) Two new foliicolous lichens from tropical Africa. Lichenologist 11, 181185.Google Scholar
Sérusiaux, E (1993) New taxa of foliicolous lichens from Western Europe and Macaronesia. Nordic Journal of Botany 13, 447461.Google Scholar
Sérusiaux, E (1996) Foliicolous lichens from Madeira, with the description of a new genus and two new species and a world-wide key of foliicolous Fellhanera. Lichenologist 28, 197227.Google Scholar
Sérusiaux, E (1998) Deux nouvelles espèces de Byssoloma Trev. (Lichens, Pilocarpaceae) d'Europe occidentale et de Macaronésie. Cryptogamie, Bryologie, Lichénologie 19, 197209.Google Scholar
Sérusiaux, E, Gómez-Bolea, A, Longán, A and Lücking, R (2002) Byssoloma llimonae sp. nov., from continental Spain, Madeira and the Canary Islands. Lichenologist 34, 183188.Google Scholar
Sipman, HJM and Aptroot, A (1992) Results of a botanical expedition to Mount Roraima, Guyana. II. Lichens. Tropical Bryology 5, 79108.Google Scholar
Tamura, K (1992) Estimation of the number of nucleotide substitutions when there are strong transition-transversion and G + C-content biases. Molecular Biology and Evolution 9, 678687.Google Scholar
Thor, G, Lücking, R and Matsumoto, T (2000) The foliicolous lichens of Japan. Symbolae Botanicae Upsalienses 32, 172.Google Scholar
van den Boom, PPG (2016) Lichens and lichenicolous fungi of the Azores (Portugal), collected on São Miguel and Terceira with the descriptions of seven new species. Acta Botanica Hungarica 58, 199222.Google Scholar
van den Boom, PPG (2021) Foliicolous lichens and their lichenicolous fungi in Macaronesia and Atlantic Europe. Bibliotheca Lichenologica 111, 1197.Google Scholar
Vězda, A (1975) Foliikole Flechten aus Tanzania (Ost-Afrika). Folia Geobotanica et Phytotaxonomica 10, 383432.CrossRefGoogle Scholar
Vězda, A (1986) Neue Gattungen der Familie Lecideaceae s. lat. (Lichenes). Folia Geobotanica et Phytotaxonomica 21, 199219.Google Scholar
Vězda, A (1987) Foliikole Flechten aus Zaire (III). Die Gattung Byssoloma Trevisan. Folia Geobotanica et Phytotaxonomica 22, 7183.Google Scholar
Vězda, A (1994) Neue foliikole Flechten II. Nova Hedwigia 58, 123143.Google Scholar
Wang, WC, van den Boom, PPG, Sangvichien, E and Wei, JC (2020 a) A molecular study of the lichen genus Byssoloma Trevisan (Pilocarpaceae) with descriptions of three new species from China. Lichenologist 52, 387396.Google Scholar
Wang, WC, Sangvichien, E, Wei, TZ and Wei, JC (2020 b) A molecular phylogeny of Pilocarpaceae Zahlbr., including a new species of Tapellaria Müll. Arg. and new records of foliicolous lichenized fungi from Thailand. Lichenologist 52, 377385.Google Scholar
Zoller, S, Scheidegger, C and Sperisen, C (1999) PCR primers for the amplification of mitochondrial small subunit ribosomal DNA of lichen-forming ascomycetes. Lichenologist 31, 511516.Google Scholar
Figure 0

Table 1. Voucher information, GenBank Accession numbers and references for Byssoloma and related taxa used in the phylogenetic analysis (Fig. 1). New sequences obtained in this study are in bold.

Figure 1

Figure 1. Maximum likelihood (ML) tree of mtSSU sequences from selected taxa in Byssoloma showing the phylogenetic position of Byssoloma orientale collected from Japan (in bold). Byssolecania spp. are used as an outgroup. Maximum likelihood and neighbour-joining (NJ) support values (≥70) are presented for each node (ML/NJ). Branches highly supported (≥90) by both analyses are indicated with bold black lines. Alphanumeric codes indicate the GenBank number, voucher number and country code (CH = China; EC = Ecuador; JP = Japan; PT = Portugal; SR = Suriname; TH = Thailand).

Figure 2

Figure 2. Byssoloma orientale collected from Japan. A, thallus with apothecia (holotype, TNS). B, pycnidia on thallus (holotype, TNS). C, a vertical section of thallus with photobiont cells (holotype, TNS); h = hyphae of mycobiont, p = photobiont cell, ls = leaf surface. D, section of apothecium (K. Miyazawa et al. 792, TNS). E, ascus with ascospores stained by Lugol's solution (K. Miyazawa et al. 792, TNS). F, apical structure of ascus stained by Lugol's solution (K. Miyazawa et al. 792, TNS). G, ascospores with various numbers of septa (K. Miyazawa et al. 792, TNS). H, conidia (holotype, TNS). Scales: A = 1 mm; B = 200 μm; C = 10 μm; D = 50 μm; E & F = 20 μm; G = 15 μm; H = 5 μm. In colour online.