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Article

Bryorutstroemia (Rutstroemiaceae, Helotiales), a New Genus to Accommodate the Neglected Sclerotiniaceous Bryoparasitic Discomycete Helotium fulvum

1
Independent Researcher, Blaihofstr. 42, D-72074 Tübingen, Germany
2
Department of Botany, Faculty of Science, Palacký University Olomouc, Šlechtitelů 27, CZ-78371 Olomouc, Czech Republic
3
Centre of the Region Haná for Biotechnological and Agricultural Research, Crop Research Institute, Šlechtitelů 29, CZ-78371 Olomouc, Czech Republic
*
Author to whom correspondence should be addressed.
Life 2023, 13(4), 1041; https://doi.org/10.3390/life13041041
Submission received: 30 January 2023 / Revised: 21 March 2023 / Accepted: 7 April 2023 / Published: 18 April 2023

Abstract

:
The new genus Bryorutstroemia is established for the red-brown, stipitate, bryoparasitic discomycete Helotium fulvum Boud. Combined phylogenetic analysis of ITS and LSU rDNA and EF1α revealed that Bryorutstroemia fulva belongs to the sclerotiniaceous clade, which comprises the paraphyletic families Rutstroemiaceae and Sclerotiniaceae. Bryorutstroemia formed with Clarireedia a supported clade (Rutstroemiaceae s.l.), though with high distance. Bryorutstroemia closely resembles other Rutstroemiaceae in having uninucleate ascospores with high lipid content and an ectal excipulum of textura porrecta, but is unique because of its bryophilous lifestyle and is extraordinary with its thick-walled inamyloid ascus apex. Although B. fulva was described in 1897, very few records came to our notice. The present study summarizes the known distribution of the species, including 25 personal collections from the years 2001–2022. Bryorutstroemia fulva was most often encountered on Dicranella heteromalla, and rarely on other members of Dicranales or Grimmiales, while inducing necrobiosis of the leaves. A detailed description based on mainly fresh apothecia is provided together with a rich photographic documentation. Six new combinations are proposed based on our phylogenetic results and unpublished personal morphological studies: Clarireedia asphodeli, C. calopus, C. gladioli, C. henningsiana, C. maritima, and C. narcissi.

1. Introduction

Helotium fulvum was described by Boudier in 1897 based on his collection from Forêt de Carnelle north of Paris (France) [1]. The apothecia grew on sandy soil among Phascum, Dicranella, and other small mosses. They consistently arose from leaf axils (leaf bases) at the tip of stems of what was obviously a Dicranella. Reliable reports of the species in the literature are very sparse up to now and include collections from Great Britain [2] and Belgium [3]. During an ascomycete foray in Luxembourg in April 2001 [4], the first author collected and documented a single apothecium on Dicranella, which remained undetermined for many years. Because of its very short stipe, large, ellipsoid, multiguttulate ascospores, and large, inamyloid asci, an affinity with the genus Mniaecia Boud. was considered, despite its reddish-brown colour. Further fresh collections from Sweden (Småland), France (Bretagne), Germany (Sachsen), Czech Republic (regions of Ústí nad Labem, Liberec, Hradec Králové, Vysočina, Olomouc, Moravian-Silesian and Zlín), Poland (Silesia), and Hungary (near Budapest) all deviated from our first record in possessing comparatively long stipes. Apart from the brown, stipitate apothecia, a ± gelatinized ectal excipulum of textura (prismatica-)porrecta with ochre-brown, partially encrusted cortical cells pointed to a relationship with the genus Rutstroemia P. Karst. The aim of our work was to clarify the phylogenetic position of Helotium fulvum, summarize its known distribution, and provide a detailed description based on recent collections.

2. Materials and Methods

2.1. Sampling and Observation

Macro- and microscopic characters were studied from fresh apothecia, predominantly from living (*) elements following the standards of vital taxonomy [5], in comparison also with samples from dead (†) elements. Apothecia were rehydrated after different intervals for testing their drought tolerance. Tap water (H2O) was used as a mounting medium. Colour reactions were tested with IKI and KOH. The latter was also applied for testing pigment solubility, resistance of oil drops (LBs), and iodine reactions under KOH-pre-treatment. CX21 (Olympus, Czech Group, Prague, Czech Republic) and Zeiss Standard 14 microscopes, with magnifications of 40×, 100×, 400×, and 1000×, were used in our study. Measurements were conducted in tap water, either directly or on photographs using the Piximètre 5.10 software [6] or by calculating from scales prepared using a Zeiss calibration slide.
Collections are deposited in the herbaria of PRA (Z. Palice), PRM (Z. Sochorová), and UPS (R. Isaksson), and in the private herbaria of H.O. Baral (H.B.), M. Lüderitz (M.L.), C. Németh (C.N.), and J.P. Priou (J.P.P.).
The following abbreviations are used: H2O = tap water, KOH = potassium hydroxide (~5%), LBs = lipid bodies (oil drops), VBs = refractive KOH-soluble vacuolar bodies, IKI = ~1% iodine (I2) in 3% KI (potassium iodide), MLZ = Melzer’s reagent, OCI = lipid content, PVA = polyvinyl acetate, idem = the same, ibid. = from the same geographical region, l.c. = reference cited, doc. vid. = documentation seen, non vid. = no documentation seen. Values in {} indicate the number of collections, thereby numbers after a slash refer to uncertain hosts.

2.2. DNA Extraction, PCR Amplification and Sequencing

DNA was extracted from dried apothecia using the CTAB method described by Doyle et Doyle [7]. Apothecia were homogenised using a pestle and incubated in 300 µL of extraction buffer at 65 °C for one hour. The extract was subsequently purified in chloroform-isoamyl alcohol mixture (24:1), precipitated by isopropanol, washed in 70% ethanol, dried and finally dissolved in water and incubated with RNase for 30 min at 37 °C. DNA quality was checked using agarose gel electrophoresis. Three genomic regions including the internal transcribed spacers (ITS = ITS1-5.8S-ITS2 region) and the 28S subunit (LSU) of ribosomal DNA (rDNA) plus the translation elongation factor-1alpha (EF1α) were amplified and sequenced with the primers ITS1F [8] / ITS4 [9], LR0R/LR6 [10], and EF1-983F/EF1-1567R [11], respectively. PCR was performed with EliZyme FAST Taq MIX Red (Elisabeth Pharmacon, Brno, Czech Republic) following a standard protocol with 37 cycles and annealing temperature of 54 °C. The PCR products were purified by precipitation with polyethylene glycol (10% PEG 6000 and 1.25 M NaCl in the precipitation mixture) and sequenced from both directions using the same primer pairs by the Sanger method at Macrogen Europe, Amsterdam, the Netherlands.

2.3. Phylogenetic Analysis

Specimens used in the phylogenetic analysis are listed in Table 1. Newly generated sequences were edited using the Geneious software (ver. 7.1.7., Biomatters, Auckland, New Zealand). Alignment was achieved with MAFFT plugin and subsequently manually checked. Phylogeny was reconstructed using the Maximum Likelihood (ML) method with the substitution model GTR+G+I tested by bootstrapping, using 1000 pseudoreplicates in MEGA (ver. 6.06) [12]. Bayesian phylogeny inference (BI) was computed in MrBayes (ver. 3.2.4) [13] using the GTR+I+G (for ITS), SYM+I+G (LSU) and GTR+G (EF1α) substitution model, as determined by AICc in PartitionFinder 2.1.1 [14]. Besides the combined trees, single gene trees were calculated. The analysis was run for 15 million generations in four independent runs, sampling every 1000th generation and excluding the first 50% of generations as burn-in, and temperature parameter was set to 0.05 for better chain mixing. The Basic Local Alignment Search Tool (BLAST) [15] was used for searching similar sequences in publicly available sequence databases [16].
Maximum Likelihood (ML) phylogenetic analysis was performed in MEGA6 with the settings ‘use all sites, nearest-neighbour-interchange, weak branch swap filter’. Distance analyses were performed with MEGA6 using the settings ‘p-distances, transitions + transversions, uniform rates, pairwise deletion’.

3. Results

3.1. Taxonomy

Bryorutstroemia Sochorová and Baral, gen. nov.—MycoBank MB 847031
Diagnosis: Differs from Rutstroemia and Clarireedia by its inamyloid asci, bryoparasitic habitat, and genetic profile.
Etymology: named after the bryicolous habitat and the similarity with the genus Rutstroemia.
Type: Bryorutstroemia fulva (Boud.) Sochorová, Baral and Priou
Bryorutstroemia fulva (Boud.) Sochorová, Baral and Priou, comb. nov.—MycoBank MB 847033
Basionym: Helotium fulvum Boud., Bull. Soc. mycol. Fr. 13(1): 16 (1897)
Hymenoscyphus fulvus (Boud.) Hengstm., in Arnolds et al., Overzicht paddest. Nederl.: 654 (1985)
Etymology: after the red-brown apothecial colour caused by brown wall deposits on paraphyses and cortical hyphae of ectal excipulum.
Holotype: France, Île-de-France, Val d’Oise, Paris, Forêt de Carnelle, on Dicranella cf. heteromalla, II.1896, É. Boudier (doc. vid.).
Apothecia (0.4–)0.5–1(–1.5) mm diam. when fresh {16}, receptacle 0.25–0.33 mm thick at lower flanks, 0.2–0.26 mm thick at margin {3}, singly or rarely in fascicles of two to four fused at the base, non-gelatinous; disc rounded in upper view, flat, eventually slightly convex, light to mostly bright to deep reddish- to purplish-brown (carmine-brown), also ochre-brown to dark brown, non-translucent, margin distinct, not protruding, even, exterior concolorous, flesh pale brown; mostly with a distinct stipe (0.1–)0.5–1.5(–1.8) × (0.12–)0.15–0.3(–0.55) mm {12}, cylindrical or widened above or sometimes below, pale to deep red-brown, basal (1/10–)1/4–1/3 of stipe blackish-brown {15}, base inserted in leaf axils at tip of stem, seemingly superficial. Asci *(150–)170–220(–233) × (17–)18–24(–27) µm {8}, †(100–)110–155(–165) × (12–)13–17(–18) µm {4}, cylindric-clavate, eight-spored, spores *obliquely biseriate, pars sporifera *(50–)60–70(–87) µm long if all eight ascospores fully developed, living mature asci protruding 20–50 µm beyond paraphyses; apex */†obtuse or slightly to strongly conical, dome immature †(4–)5–7(–10) µm thick (*2–2.5 µm), mature †3–7 µm (*1–1.2 µm) {9}, IKI– {22}, MLZ– {5}, when KOH-pretreated IKI–/MLZ– {1}, dome hemispherically protruding into ascoplasm, without apical chamber, lateral ascus wall †0.5–1 µm thick, subapically †1.2–1.5 µm; base with medium to long stalk, arising from simple septa {21} with basal downward-oriented protuberance {11}, sometimes bifurcate by one branch forming the protuberance {4}. Ascospores *(14–)16–25(–27.5) × (6–)7–10(–11) µm {13} [*Q = 2.27–2.76–4.2 (n = 50), *Me = 23.1 × 8.4 µm, Z.S. 2/2021; *Q = 2.16–2.57 (n = 20), C.N. 103], †(14.5–)16–22(–24.7) × (5.5–)6–8(–9) µm {3} [†Q = 2.1–2.6–3(–3.8) (n = 50), †Me = 18.6 × 7.2 µm, Z.S. 2/2021], ellipsoid, also cylindric-ellipsoid or ellipsoid- to fusoid-clavate, homopolar, straight, ends obtuse, smooth; containing numerous LBs of (0.5–)0.8–2(–2.5) µm diam. (multiguttulate) {22}, LBs in young spores much smaller and more numerous, OCI 4.5–5 {20}, leaving an area occupied by the single nucleus, when freshly ejected sometimes surrounded by a sheath that separates from the spore wall {7} (Figure 7: 1e,3,6); overmature spores one-septate {12}, hyaline, rarely germinating with one hypha at the pole or more laterally. Paraphyses cylindrical-filiform throughout, sometimes slightly clavate above, rarely slightly capitate, spathulate, or narrowly obtusely-sublanceolate, straight to slightly flexuous, sometimes curved under a wide arc, hyaline, terminal cell *21–53 {4} × (1.7–)2–3(–3.4) µm {6}, †(14–)19–45(–50) {3} × (1.5–)2–2.5(–3) µm {4}, without VBs {15}, sometimes with groups of LBs {1}, embedded above in (very) pale fox-brownish, smooth, gel-like exudate, lower cells *16–30 × 1.7–3.1 µm {2}, †1.8–2 µm wide {1}; sparsely to frequently branched in middle part. Subhymenium hyaline, *17–33 µm thick, non-gelatinized, cells angular, subglobose or irregular, *5–11 × 3–8 µm. Medullary excipulum with pale brass-ochre to brownish intercellular exudate, non-gelatinized, *90–150 µm thick in centre, *60–120 µm at lower flanks, in receptacle of dense textura intricata with tendency to an upward orientation, cells *8–24 × 2.5–5.5(–11) µm {2}, thin-walled, sharply delimited from ectal excipulum by a thin, parallel, pale brown layer of t. porrecta; in stipe of vertically oriented hyaline to pale brown t. porrecta, cells cylindrical, *(13–)20–60(–75) × (3.5–)5–6(–11) µm {2}. Ectal excipulum in receptacle of hyaline to pale ochre-brown, thin-walled, *not or slightly (†medium to strongly) gelatinized, textura (prismatica-)porrecta from base to margin, oriented at a (0–)10–30(–50)° angle to the surface (often very irregularly, Figure 5: 3b), *(30–)40–55 µm thick at lower flanks, cells *(10–)15–33(–48) × 3.5–7(–9) µm {2}, †19–28 × 3.5–6 µm {1}; *20–40 µm thick near margin, smaller-celled, bright reddish-brown, marginal cortical cells *12–16 × 3–3.5 µm {1}, ± flexuous, forming hair-like elements; cortical cells of similar size, with pale to bright ochre- to red-brown, thin, smooth {2} or granular to ridge-like encrustation {6} (Figure 6: 1a,2a), in surface view straight to sometimes ± undulating, often with short, scattered lateral protrusions, *5–14 × 3.5–5 µm {3}; in stipe of not to slightly gelified t. porrecta oriented parallel to the surface, formed by cylindrical, often anastomosing or branching, thin- to thick-walled (*0.2–0.7 µm) cells *12–40 × 2.7–7(–9.5) µm {1}; cortical cells as on receptacle. Tissues without crystals, without IKI reaction, excipular pigment in KOH not changing colour, not dissolved {3}. Anchoring hyphae sparse, brown, forming chains of †8–12 × 5–6.5 µm large cells, walls †~0.5–0.8 µm thick {1}. Anamorph unknown.
Habitat: on leaf axils of living or mainly dead individuals of Bucklandiella heterosticha {1}, Dicranella cerviculata {1}, D. heteromalla {35/2}, Dicranella sp. {1}, Dicranum scoparium {2}, causing yellowish discolouration of the host, mosses growing on rocks or equally often on sandy to loamy or humous soil. Associated (± remotely): Mniaecia cf. gemmata {3}, M. jungermanniae {4}. Drought tolerance: only a few ascospores survived when dry apothecia were examined after 10 days up to 2 ⅓ months. Altitude: 10–530(–835) m above sea level. Phenology: X–VII(VIII–IX) (throughout the year, especially in winter and spring). Geology: Bretagne: acidic quartzite, sandstone, argillaceous siltite, shale-like schist (Ordovician, Brioverian); Luxembourg: Lower Lias (sandstone); Czechia and Poland: acidic sandstone, alluvial sediments, gneiss, migmatite, granulite.
Specimens included: Sweden: Småland, Jönköpings län, 4 km WNW of Sävsjö, 3.5 km SSW of Bringetofta, 0.5 km SSE of Rickelstorp, 245 m, Bucklandiella heterosticha on silicate stonewall, 13.XII.2020, R. Isaksson (UPS F-990878).—1.3 km SSE of Rickelstorp, 235 m, on Dicranum scoparium on silicate stonewall, 29.XII.2020, R. Isaksson (doc. vid.).—Great Britain: Scotland, East Lothian, SSE of Haddington, Gifford, ~120 m, on Dicranella heteromalla, 18.X.1964, D.M. Henderson (E, non vid.).—idem, 25.X.1965.—idem, X.1968.—idem, 10.X.1969.—Southwest England, West Gloucestershire, 30 km N of Bristol, Rodmore Grove, 140 m, host not stated, 1.IX.1991, A. Yelland (non vid.) [17].—Netherlands: Groningen, 2.5 km S of Vlagtwedde, 1 km NW of Weende, Liefstinghsbroek, 10 m, on D. heteromalla, 2.II.2022, J. Boers (unpreserved, doc. vid.).—Belgium: Vlaanderen, Antwerpen, 11.5 km NE of Antwerpen, 4 km NE of Schoten, La Garenne, 12 m, on D. cerviculata, 24.II.1992, J. Slembrouck and H. De Meulder (H.B. 4632).—France: Bretagne, Côtes-d’Armor, 4.5 km WNW of Mur-de-Bretagne/Guerléda, 1 km SW of Caurel, Lac de Guerlédan, 133 m, on D. heteromalla, 7.III.2005, J.P. Priou (J.P.P. 15051).—Ille-et-Vilaine, 4.5 km E of La Gacilly, 1.2 km SE of Sixt-sur-Aff, Dessous Le Guerche, D255, 66 m, on D. heteromalla, 3.III.2006, J.P. Priou (J.P.P. 26054, H.B. 8083).—Morbihan, 3 km SW of La Gacilly, 2.8 km NW of Glénac, route de La Forêt Neuve, 80 m, on D. heteromalla, 6.IV.2004, J.P. Priou (J.P.P. 24120).—3.7 km S of Montfort-sur-Meu, 2 km WSW of Talensac, 110 m, on D. heteromalla, 19.III.2021, J.P. Priou (J.P.P. 2021050, non vid.)—Île-de-France, Val d’Oise, ~29 km N of Paris, Forêt de Carnelle, ~200 m, on D. cf. heteromalla, II.1896, É. Boudier (holotype, doc. vid.).—Luxembourg: Gutland, Petite Suisse, 11.5 km WNW of Echternach, 2.2 km W of Beaufort, Esselbur, Elteschmuer S of Tinnes, 405 m, on D. cf. heteromalla, 25.IV.2001, H.O. Baral (H.B. 6917 [PVA-slide]).—Germany: Niedersachsen, 5 km ESE of Ratzeburg, ~2.8 km WSW of Mustin, SW of Garrensee, NW of Garrenseeholz, on D. heteromalla, 9.III.1995, M. Lüderitz (M.L., non vid.) [18].—Sachsen, 8.5 km SSW of Zittau, 0.8 km S of Kurort Oybin, 465 m, on D. heteromalla on a sandstone rock, 15.V.2021, Z. Sochorová (ex Z.S. 44/2021, PRM 956027).—Bayern, Oberbayern, near Ingolstadt, ~400 m, on D. heteromalla, 31.VIII.1979, J. Poelt (Plantae Graecensis 255, PDD 60714, non vid.)— Poland: Lower Silesian Voivodeship, 16 km SE of Wałbrzych, 1.6 km SE of Walim, Owl Mountains landscape park, 775 m, on D. heteromalla on soil, 17.IV.2022, Z. Sochorová (ex Z.S. 1/2022, PRM 957650).—Czech Republic: Ústí nad Labem region, Děčín district, 5 km N of Jetřichovice, České Švýcarsko National Park, Křinice valley, ENE of Jankův kopec, 348 m, on D. heteromalla on soil, 10.XI. 2021, Z. Palice, I. Marková and P. Uhlík (ex Z.P. 32329, PRA, vid.).—Liberec region, Česká Lípa district, 6.5 km NNE of Česká Lípa, 1.3 km NW of Svojkov, 1 km SSW of Sloup v Čechách, group of rocks above the road no. 268, 350 m, on D. heteromalla on a sandstone rock, 1.I.2021, Z. Sochorová (ex Z.S. 2/2021, PRM 956016, sq.: ITS OP035812).—idem, 28.II.2021 (ex Z.S. 11/2021, PRM 956020).—10 km ENE Mimoň, 2.8 km SE of Hamr na Jezeře, Divadlo Nature Monument, 375 m, on D. heteromalla on a sandstone rock, 27.II.2021, Z. Sochorová (ex Z.S. 8/2021, PRM 956018).—3.2 km S of Hamr na Jezeře, 2.7 km NE Svébořice, Stohánek Nature Monument, 350 m, on D. heteromalla on a sandstone rock, 27.II.2021, Z. Sochorová (ex Z.S. 9/2021, PRM 956019, sq.: ITS + LSU OP035829, EF1α OP058104).—Liberec district, 21 km WNW of Liberec, 4 km N of Jablonné v Podještědí, 1.2 km SW of Petrovice, 410 m, on D. heteromalla on soil, 4.III.2021, Z. Sochorová (ex Z.S. 17/2021, PRM 956023).—2.1 km NE of Jablonné v Podještědí, 345 m, on D. heteromalla, 4.VII.2021, Z. Sochorová (ex Z.S. 61/2021, PRM 956032).—idem, 15.XI.2021 (ex Z.S. 153/2021, PRM 956457).—1.8 km NE of Jablonné v Podještědí, at St. Zdislava’s spring, 335 m, on D. heteromalla, 4.VII.2021, Z. Sochorová (ex Z.S. 62/2021, PRM 956033).—2 km ENE of Jablonné v Podještědí, 1 km S Lvová, 365 m, on D. heteromalla on a sandstone rock, 1.III.2021, Z. Sochorová (ex Z.S. 15/2021, PRM 956021).—4.5 km E of Jablonné v Podještědí, 0.5 km N of Janovice v Podještědí, 260 m NNW of cemetery, 370 m, on D. heteromalla on a sandstone rock, 3.III.2021, Z. Sochorová (ex Z.S. 16/2021, PRM 956022).—9 km SW of Liberec, 0.8 km SE of Rozstání pod Ještědem, Horka forest park, 460 m, on D. heteromalla, 3.VII.2021, Z. Sochorová (ex Z.S. 60/2021, PRM 956031).—3 km SW of Česká Lípa, Peklo National Nature Monument, 270 m, on D. heteromalla, 16.XI.2021, Z. Sochorová (ex Z.S. 158/2021, PRM 956458).—Jablonec nad Nisou district, 2.3 km WNW of Koberovy, 1 km NW of Besedice, 445 m, on D. heteromalla on soil, on sandstone bedrock, 26.II.2021, Z. Sochorová (ex Z.S. 7/2021, PRM 956017, sq.: ITS + LSU OP035830, EF1α OP058105).—Hradec Králové region, Náchod district, Broumovské stěny National Nature Reserve, 6 km SSW of Broumov, 1.6 km ENE of Slavný, 650 m, on D. heteromalla on soil on sandstone bedrock, 18.IV.2022, Z. Sochorová (ex Z.S. 2/2022, PRM 957651).—idem, 0.9 km ENE of Slavný, Zaječí rokle, 605 m (ex Z.S. 4/2022, PRM 957652).—Vysočina region, Havlíčkův Brod district, Údolí Doubravy Nature Reserve, 3.5 km ESE of Chotěboř, 820 m WNW of Bílek railway station, 545 m, on D. heteromalla on soil over migmatite to orthogneiss, 21.V.2021, Z. Sochorová (ex Z.S. 48/2021, PRM 956029).—ibid., 600 m WNW of Bílek railway station, 545 m, on D. heteromalla on soil, 21.V.2021, Z. Sochorová (ex Z.S. 47/2021, PRM 956028).—Olomouc region, Olomouc district, Dolany u Olomouce, W of Nové Sady, 305 m, on D. heteromalla on soil, 28.III.2021, Z. Sochorová (ex Z.S. 18/2021, PRM 956024).—ibid., S of Nové Sady, 340 m, on D. heteromalla on soil-stony bedrock, 28.III.2021, Z. Sochorová (ex Z.S. 19/2021, PRM 956025, sq.: ITS + LSU OP035828, EF1α OP058103).—Šumperk district, 4.6 km NW of Staré Město, 1 km NNW of the church in Stříbrnice, 835 m, on D. heteromalla on soil, 30.V.2021, Z. Sochorová (ex Z.S. 58/2021, PRM 956030).—Moravian-Silesian region, Opava district, 2 km NW of Těškovice, 360 m, on D. heteromalla on soil, 4.IV.2021, Z. Sochorová (ex Z.S. 23/2021, PRM 956026).—Zlín region, Zlín district, 5 km SE of Bystřice, 2 km SSE of Hostýn, 690 m, on D. heteromalla on soil, 28.X.2022, Z. Sochorová (ex Z.S. 136/2022, PRM 958329).—Hungary: Pest county, Budakeszi district, 12 km WNW of Budapest, 3 km W of Budakeszi, 320 m, on Dicranum scoparium on soil, 8.XII.2020, C. Németh (C.N. 103, sq.: ITS + LSU OP035831, EF1α OP058106).

3.2. Phylogeny

ITS sequences were obtained from five collections of B. fulva, while LSU and EF1α were obtained from four (Table 1). The S1506-intron is absent in all of them, according to the used ITS1F primer. The five sequences are fully identical in the overlapping parts. In BLASTn searches in GenBank, B. fulva had the highest ITS similarity to members of the Clarireedia clade: Clarireedia narcissi (90%), C. monteithiana and C. jacksonii (89.5%), C. asphodeli, C. calopus, C. henningsiana, C. homoeocarpa, C. maritima, and C. paspali (88–89%). Also in the LSU D1–D2 domain the highest similarity (95%) was to members of Clarireedia but also to Piceomphale, followed by other rutstroemiaceous taxa, including Rutstroemia firma (92.5–93.5%).
Helotium fulvum was only once recombined into another genus when Hengstmengel [19] suggested a relationship with the genus Hymenoscyphus. Our phylogenetic analysis of nuITS+LSU rDNA + EF1α (Figure 9 and Figure S4), in which we used Hymenoscyphus scutula (Pers.) W. Phillips (isolate G.M. 2014-12-25.2, ITS + LSU: MK674606) as outgroup, indicated a high distance between B. fulva and that species. Instead, B. fulva nested in the strongly supported sclerotiniaceous lineage as circumscribed by Baral [20] p. 173, a group which currently includes two families, Rutstroemiaceae and Sclerotiniaceae. Two further families in our dataset, Cenangiaceae and Chlorociboriaceae, clustered outside the sclerotiniaceous lineage.
In our Bayesian analysis, the paraphyletic family Rutstroemiaceae appears in three different clades (Figure 9 and Figure 10). One clade (Rutstroemiaceae s.str.) comprises species growing on wood and bark but also on the leaves of trees; it includes two strongly supported subclades, one containing the type species of Rutstroemia, R. firma, and four other Rutstroemia spp., but also Torrendiella setulata, the other containing Lambertella subrenispora and Lanzia allantospora.
A different, strongly supported clade comprises species growing on monocots and also on dung. It represents the recently established genus Clarireedia L.A. Beirn et al. [21], with the type species C. homoeocarpa (F.T. Benn.) L.A. Beirn et al. (≡ Sclerotinia homoeocarpa F.T. Benn.), and includes species currently assigned to Rutstroemia but also Ciboria, Sclerotinia, and Stromatinia. Within Clarireedia, C. paspali clustered in our ITS+LSU analysis closest to B. fulva despite its comparatively high ITS distance (Figure 10), perhaps because the specimen lacks LSU, whereas in our ITS+LSU+EF1α analysis it clustered supported with other Clarireedia spp. (Figure 9).
The following new combinations are proposed to harmonize the nomenclature of species on monocots which cluster in the supported Clarireedia clade. The listed taxonomic synonyms are to be taken as tentative and require type studies for clarification. C. henningsiana (= R. paludosa) is here understood as a species on Cyperaceae and Juncaceae characterized by simple-septate asci, whereas C. calopus (= C. bennettii) and C. maritima represent species on Poaceae characterized by asci arising from croziers, C. maritima also by asci with inamyloid, moderately thick-walled apex (pers. obs.). We tentatively regarded R. cuniculi as a synonym of C. calopus because available ITS sequences in GenBank differed from those of C. calopus by only one nucleotide.
Clarireedia asphodeli (Duvernoy and Maire) Baral and Sochorová, comb. nov.—MycoBank MB 847034
Basionym: Ciboria asphodeli Duvernoy and Maire, in Maire, Bull. trimest. Soc. mycol. Fr. 44: 54 (1928)
≡ Rutstroemia asphodeli (Duvernoy and Maire) R. Galán and Matočec, in Galán et al., Mycologia 107(4): 799 (2015)
Clarireedia gladioli (Drayton) Baral and Sochorová, comb. nov.—MycoBank MB 847035
Basionym: Sclerotinia gladioli Drayton, Phytopathology 24: 397 (1934)
≡ Stromatinia gladioli (Drayton) Whetzel, Mycologia 37(6): 674 (1945)
Clarireedia henningsiana (Plöttn.) Baral and Sochorová, comb. nov.—MycoBank MB 847036
Basionym: Ciboria henningsiana Plöttn., in Maire, Verh. bot. Ver. Prov. Brandenb. 41: X (1899)
= Rutstroemia paludosa (E.K. Cash and R.W. Davidson) J.W. Groves and M.E. Elliott, Can. J. Bot. 39: 225 (1961)
= Ciboria blanda Svrček, Česká Mykol. 12(4): 225 (1958)
Clarireedia maritima (Roberge ex Desm.) Baral and Sochorová, comb. nov.—MycoBank MB 847037
Basionym: Peziza maritima Roberge ex Desm., Ann. Sci. Nat., Bot., sér. 3 3: 366 (1845)
Rutstroemia maritima (Roberge ex Desm.) Dennis, Persoonia 3(1): 52 (1964)
Clarireedia narcissi (Drayton and J.W. Groves) Baral and Sochorová, comb. nov.—MycoBank MB 847038
Basionym: Stromatinia narcissi Drayton and J.W. Groves, Mycologia 44(1): 126 (1952)
Clarireedia calopus (Fr.) Baral and Sochorová, comb. nov.—MycoBank MB 847039
Basionym: Peziza calopus Fr., Observ. mycol. (Havniae) 2: 307 (1818)
Rutstroemia calopus (Fr.) Rehm, Rabenh. Krypt.-Fl., Edn 2 (Leipzig) 1.3(lief. 39): 768 (1893) [1896]
= Clarireedia bennettii C. Salgado, L.A. Beirn, B.B. Clarke and J.A. Crouch, in Salgado-Salazar et al., Fungal Biology 122(8): 769 (2018)
= Rutstroemia cuniculi (Boud.) M.E. Elliott, Can. J. Bot. 45(4): 521 (1967)
A third clade is formed by the type species of Lambertella, L. corni-maris, and two more Lambertella spp., but also includes Bicornispora seditiosa, and with less support Rutstroemia longipes and Martininia panamaensis. A further, strongly supported clade represents the family Sclerotiniaceae, which includes in the present analysis members of Ciboria, Dumontinia, Monilinia, Pycnopeziza, Schroeteria, Sclerencoelia, and Sclerotinia, with partly high distances among the species.
Four species of the sclerotiniaceous lineage clustered outside the four above-mentioned clades (Figure 9 and Figure 10): Bryorutstroemia fulva formed with Clarireedia a strongly supported clade, though with high distance. Scleromitrula shiraiana is morphologically similar to Ciboria but it clustered unsupported in Figure 9 but formed a moderately supported sister clade to Rutstroemia s.str. in Figure 10. As in other published analyses [22], Piceomphale bulgarioiodes clustered with “Cenangiumacuum distant from all other sclerotiniaceous taxa, despite its morphological similarity with Ciboria and an ascus structure of the Sclerotinia-type. The two species form the “Piceomphale-clade”, which is difficult to assign to a family, but may be better recognized in the sclerotiniaceous lineage than in Cenangiaceae to which Encoelia furfuracea belongs [22].
A phylogenetic tree generated with MEGA6 (ML, GTR+G+I, 1000 replicates, Figure S4), based on the very same dataset as in Figure 9, gave a similar tree topology though with only weak support for Rutstroemia s.str. and moderate support for Lambertella s.str. Again, B. fulva clustered sister to Clarireedia, though with only moderate support and by forming with C. paspali an unsupported clade. Contrary to the Bayesian analysis, Martininia panamaensis clustered strongly supported with Lambertella in the ML ITS+LSU analysis of Baral et al. [23] but unresolved in Figure S4, and Scleromitrula shiraiana clustered unresolved in both Baral et al. [23] and in Figure S4.

4. Discussion

4.1. Morphological Remarks

Bryorutstroemia fulva is characterized by deep reddish-brown, stipitate or rarely subsessile apothecia, a gelatinized ectal excipulum of textura porrecta covered by ochre-brown cortical hyphae with short outgrowths, inamyloid asci arising from simple septa, and large, multiguttulate, ellipsoid ascospores. Especially the latter varied among the collections, particularly in width, some being predominantly narrowly ellipsoid, the others more broadly ellipsoid. The living paraphyses usually looked empty and colourless by lacking vacuolar bodies (VBs), but sometimes they contained groups of lipid bodies (LBs). The pale to bright ochre-brown cortical hyphae of the receptacle and stipe often had an encrusted surface but were occasionally smooth.
In order to summarize the most important differences between Bryorutstroemia and related genera, the following key is provided. It needs to be taken as provisional, as the taxonomy of Rutstroemiaceae is still insufficiently solved and nomenclatural changes in the circumscription of the family and its members can be expected.
 
Provisional key to the recognized genera of Rutstroemiaceae s.l.
  • 1. Asci (†) with prominent, inamyloid apical wall thickening; ascospores permanently hyaline; growing on bryophytes........ Bryorutstroemia
  • 1. Ascus apex (†) with amyloid apical ring of the Sclerotinia-type, rarely faintly amyloid or inamyloid, but then only moderately thick-walled; growing on phanerogams........ 2
  • 2. On monocotyledons........ Clarireedia
  • 2. On dicotyledons or gymnosperms........ 3
  • 3. Apothecia externally with prominent, septate, thick-walled setae........ Torrendiella
  • 3. Apothecia without setae........ 4
  • 4. Ascospores permanently hyaline........ Rutstroemia (including Dencoeliopsis), Lanzia
  • 4. Ascospores turning brown with age, either within the living asci or when overmature........ Bicornispora, Lambertella, Martininia

4.2. Phylogenetic Remarks

Based solely on cultural isolates, Salgado-Salazar et al. described three new species in the new genus Clarireedia in 2018 [21] and Hu et al. added a fourth species, C. paspali Jian Hu and Lamour in 2019 [24]. Because teleomorphs were absent in their samples, the authors overlooked close relationships of their Clarireedia spp. with old taxa recognized in Rutstroemia. For instance, their wide concept of Clarireedia bennettii C. Salgado et al. encompasses ITS sequences which fully match GenBank uploads under the names R. calopus (Fr.) Rehm, R. henningsiana (Plöttn.) Dennis, and R. paludosa (E.K. Cash and R.W. Davidson) J.W. Groves and M.E. Elliott, here classified as Clarireedia calopus and C. henningsiana (Figure 9 and Figure 10).
The type clade of Clarireedia homoeocarpa is closely related to R. maritima (Roberge ex Desm.) Dennis and R. asphodeli (Duvernoy and Maire) R. Galán and Matočec, here classified as Clarireedia maritima and C. asphodeli, whereas the remaining three species (Clarireedia jacksonii C. Salgado et al., C. monteithiana C. Salgado et al., C. paspali) represent a distinct group of genotypes which includes strains that are misnamed as Sclerotinia homoeocarpa in GenBank (based on our ML analysis of ITS rDNA, not shown).
Delimitation of the families Sclerotiniaceae and Rutstroemiaceae within the sclerotiniaceous lineage is still not clear in all respects. In the morphology-based classification defined by ascospores with a low vs. high lipid content coupled with globose vs. prismatic excipular cells, respectively, both families are paraphyletic (Figure 9 and Figure 10). Hereafter, Scleromitrula, Martininia, and Piceomphale share characters with the core clade of Sclerotiniaceae, while Lambertella and Clarireedia share characters with the core clade of Rutstroemiaceae. Additionally, Bryorutstroemia shares characters with Rutstroemiaceae, for which it could represent an ancestor on a phylogenetically old host, although the tree topology of Figure 9 suggests an evolution from mainly woody plants to monocots and mosses. The current concept that characterizes Rutstroemiaceae by a stroma and Sclerotiniaceae by sclerotia [25] largely coincides with the morphology-based concept, but both concepts include some problematic genera.
The difficulty of conducting phylogenetic analysis on sclerotiniaceous fungi based on rDNA data alone became obvious when trying to resolve the position of Schroeteria [23]. Multigene analyses probably better resolve phylogenetic affinities in this group. However, in a preliminary analysis of the EF1α gene with MEGA6 (TN+G, not shown), which comprised members of Helotiales (mainly sclerotiniaceous taxa), Pezizales, Phacidiales, Rhytismatales, Dothideomycetes, Eurotiomycetes, and Sordariomycetes, B. fulva clustered with Sordariomycetes, though with a high distance. B. fulva formed a clade with Clarireedia only when non-helotialean sequences were excluded from the analysis (Figure S3). Despite this curious result, BLAST search (megablast) for EF1α (strain Z.S. 19/2021) yielded Rutstroemia firma as the second most similar species (85.3%, query cover 61%), with the highest similarity of 88% (query cover 51%) to Spathularia (Rhytismatales) and 83.5–83.6% (query cover 68%) to Sordaria (Sordariomycetes) and Lasiobolidium (Pezizales). BLASTn search, however, yielded R. firma on top with 84.4% similarity (80% query cover). The EF1α sequences obtained from B. fulva strongly deviate at various positions from any other group of Ascomycota, which impedes a reasonable conclusion about its phylogenetic relationships. EF1α sequences obtained from four collections of B. fulva in this study were about the same length of 500 nucleotides and fully identical (except for nine ambiguities in C.N. 103), thus confirming the reliability of the result.

4.3. Ecological Remarks

Bryorutstroemia fulva is a necrotrophic parasite, causing bleaching of the host tissues. These striking substrate discolourations help one to spot the apothecia in the field (Figure 3), similarly as in several other species of bryophilous Helotiales, such as Belonioscyphella hypnorum [26], Bryoscyphus dicrani (pers. obs.), B. hyalotectus [27], and Roseodiscus subcarneus [28]. In the present study, B. fulva has been collected on mosses of the family Dicranaceae (Dicranales), mostly D. heteromalla. Only a single collection from Sweden grew on a moss from a different family and order, Bucklandiella heterosticha (≡ Racomitrium heterostichum, Grimmiaceae, Grimmiales). Suitable localities are shaded surfaces of acidic bedrock, very often in planted spruce forests. In several collections B. fulva grew more or less remotely associated with Mniaecia jungermanniae, a common hepaticolous ascomycete with deep blue apothecia (observed in collections J.P.P. 24120, Z.S. 23/2021, 44/2021, 48/2021), and M. cf. gemmata with whitish apothecia (J.P.P. 15051, Z.S. 18/2021, 23/2021).
We have encountered B. fulva mainly during the colder season, i.e., from November to May, but three of our records were from July. Collections from August by J. Poelt [29], September by A. Yelland [17], and October by D.M. Henderson [29] also exist. Although only a few records have been published, B. fulva seems to be common in colline to montane regions with acidic bedrock, which was exemplified in the present study for Czechia (24 collections during 2021–2022). The presently known distribution (Figure 11) is certainly incomplete. However, as the most frequent host D. heteromalla prefers acidic pH and grows most often on acidic forest soil or less often on sandy soil or directly on silicate boulders [30], the fungus might be rarer in areas with neutral to basic soil.
In France (Bretagne), the Netherlands, Luxembourg, Germany, Poland (Silesia), and Czechia the host was always Dicranella, which mainly grew on acidic sandstone (Figure 2: 1a), but also on sandy or loamy soil over sandstone, slate (Ordovician shale), silt, orthogneiss, migmatite, or granulite, etc. Sometimes the moss grew on soil on an uprooted fallen tree. The vegetation was preferably an acidic pure coniferous forest (predominantly Picea but also Pinus), also mixed with Betula or Fagus, etc. In Divadlo, the main vegetation was a Vaccinio myrtilli-Pinetum sylvestris, in Stohánek (Figure 3: 1) a Vaccinio vitis-idaeae-Quercetum with Pinus sylvestris and Quercus petraea, less often Q. robur, with admixture of Betula pendula, Sorbus aucuparia, and Frangula alnus, but also Dicrano-Pinion with the dominant P. sylvestris admixed with Quercus petraea, Betula pendula, Frangula alnus or Sorbus aria. Collections were often from the margins of forest pathways and also in ditches at the edges of roads. At the French sites the host moss occurred in close association with Diplophyllum albicans, Calypogeia, and Cephalozia, etc. Especially when growing on rock, the plant community in which Bryorutstroemia fulva parasitizes Dicranella may be classified as Dicranellion heteromallae [31]. In Sweden B. fulva grew on Bucklandiella (Figure 8: 2a) or Dicranum covering silicate stonewalls, and at the Hungarian site it grew in cushions of D. scoparium occurring scattered on open soil in an acidophilous Quercus petraea forest (Figure 8: 1a).
Figure 1. Bryorutstroemia fulva as illustrated under the name Helotium fulvum by (a) Boudier (1897 [1] pl. III fig. III), (b) Dennis (1978 [2] pl. XVIII U), (c) Ellis et Ellis (1988 [32] fig. 5), and (d) De Meulder (1992 [3] p. 80).
Figure 1. Bryorutstroemia fulva as illustrated under the name Helotium fulvum by (a) Boudier (1897 [1] pl. III fig. III), (b) Dennis (1978 [2] pl. XVIII U), (c) Ellis et Ellis (1988 [32] fig. 5), and (d) De Meulder (1992 [3] p. 80).
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Figure 2. Bryorutstroemia fulva on Dicranella cf. heteromalla. (a) fresh apothecium formed in leaf axils at tip of plant; (b) hair-like marginal elements; (c) ectal excipular cells in surface view; (d) mature ascus; (e) upper part of paraphyses; (f) apex of immature ascus with prominent wall thickening expanding into the ascoplasm; (g) mature ascospores containing numerous LBs. Living state, except for f (in IKI).—Del. H.O. Baral.
Figure 2. Bryorutstroemia fulva on Dicranella cf. heteromalla. (a) fresh apothecium formed in leaf axils at tip of plant; (b) hair-like marginal elements; (c) ectal excipular cells in surface view; (d) mature ascus; (e) upper part of paraphyses; (f) apex of immature ascus with prominent wall thickening expanding into the ascoplasm; (g) mature ascospores containing numerous LBs. Living state, except for f (in IKI).—Del. H.O. Baral.
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Figure 3. Bryorutstroemia fulva on Dicranella growing on sandstone in northern Bohemia. (1a,2a) collection sites; (1b,2b,c,3,4a,b) apothecia in leaf axils of bleached leaves.—(1) Stohánek (Z.S. 9/2021), (2) Sloup v Čechách (Z.S. 11/2021), (3) Petrovice (Z.S. 17/2021), (4) Sloup v Čechách (Z.S. 2/2021). Phot. Z. Sochorová.
Figure 3. Bryorutstroemia fulva on Dicranella growing on sandstone in northern Bohemia. (1a,2a) collection sites; (1b,2b,c,3,4a,b) apothecia in leaf axils of bleached leaves.—(1) Stohánek (Z.S. 9/2021), (2) Sloup v Čechách (Z.S. 11/2021), (3) Petrovice (Z.S. 17/2021), (4) Sloup v Čechách (Z.S. 2/2021). Phot. Z. Sochorová.
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Figure 4. Bryorutstroemia fulva in leaf axils of Dicranella (from northern Bohemia, Bretagne, and Luxembourg) or Dicranum (from Hungary). (1ac,2,5,6a,b) apothecia in reflected light; (3,4a,b,6c) apothecia in transmitted light (4b showing protruding mature asci); (4c) median section of apothecium; (7) lower part of leaf with brown fungal tissue. (15,6a,b) fresh apothecia, (6c) rehydrated apothecium; (4ac,6c) in water, (7) in PVA.—(14) phot. Z. Sochorová: (1) Sloup v Čechách (Z.S. 11/2021), (2) Janovice v Podještědí (Z.S. 16/2021), (3) Jablonné v Podještědí (Z.S. 15/2021), (4) Sloup v Čechách (Z.S. 2/2021); (5) phot. C. Németh: Budakeszi (C.N. 103), (6a,b) phot. J.P. Priou, (6c) H.O. Baral: Sixt-sur-Aff (J.P.P. 26054, H.B. 8083), (7) phot. H.O. Baral: Beaufort (H.B. 6917).
Figure 4. Bryorutstroemia fulva in leaf axils of Dicranella (from northern Bohemia, Bretagne, and Luxembourg) or Dicranum (from Hungary). (1ac,2,5,6a,b) apothecia in reflected light; (3,4a,b,6c) apothecia in transmitted light (4b showing protruding mature asci); (4c) median section of apothecium; (7) lower part of leaf with brown fungal tissue. (15,6a,b) fresh apothecia, (6c) rehydrated apothecium; (4ac,6c) in water, (7) in PVA.—(14) phot. Z. Sochorová: (1) Sloup v Čechách (Z.S. 11/2021), (2) Janovice v Podještědí (Z.S. 16/2021), (3) Jablonné v Podještědí (Z.S. 15/2021), (4) Sloup v Čechách (Z.S. 2/2021); (5) phot. C. Németh: Budakeszi (C.N. 103), (6a,b) phot. J.P. Priou, (6c) H.O. Baral: Sixt-sur-Aff (J.P.P. 26054, H.B. 8083), (7) phot. H.O. Baral: Beaufort (H.B. 6917).
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Figure 5. Bryorutstroemia fulva on Dicranella (from northern Bohemia). Median section of apothecia: (1,2) receptacle, (3a,b) upper stipe and lower flanks, (3c) lower flanks, (3d,e) margin. Living state.—(1) Divadlo (Z.S. 8/2021); (2) Besedice (Z.S. 7/2021); (3) Sloup v Čechách (Z.S. 2/2021). Phot. Z. Sochorová.
Figure 5. Bryorutstroemia fulva on Dicranella (from northern Bohemia). Median section of apothecia: (1,2) receptacle, (3a,b) upper stipe and lower flanks, (3c) lower flanks, (3d,e) margin. Living state.—(1) Divadlo (Z.S. 8/2021); (2) Besedice (Z.S. 7/2021); (3) Sloup v Čechách (Z.S. 2/2021). Phot. Z. Sochorová.
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Figure 6. Bryorutstroemia fulva on Dicranella (from northern Bohemia). Apothecial stipe in surface view (1a,c,2a) and median section (1b,2b). Living state.—(1) Sloup v Čechách (Z.S. 2/2021); (2) Divadlo (Z.S. 8/2021). Phot. Z. Sochorová.
Figure 6. Bryorutstroemia fulva on Dicranella (from northern Bohemia). Apothecial stipe in surface view (1a,c,2a) and median section (1b,2b). Living state.—(1) Sloup v Čechách (Z.S. 2/2021); (2) Divadlo (Z.S. 8/2021). Phot. Z. Sochorová.
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Figure 7. Bryorutstroemia fulva. (1a,b,5b,c,7a,8a) mature asci; (1c,d,5c left,7b,8b) immature asci; (5b right) young asci; (5a,b,d) paraphyses; (1e,2,3,6,7a) mature ascospores; (1f,4) overmature ascospores. Living state, except for (7a) asci, in H2O, (7b,8) in IKI.—(14) from northern Bohemia, on Dicranella (phot. Z. Sochorová), (1) Z.S. 2/2021, (2) Z.S. 15/2021, (3) Z.S. 16/2021, (4) Z.S. 17/2021; (5) Hungary, on Dicranum (phot. C. Németh, C.N. 103); (6) Sweden, on Bucklandiella (phot. R. Isaksson, UPS F-990878); (7,8) France, on Dicranella, (7) phot. J.P. Priou, J.P.P. 15051, (8) H.O. Baral, H.B. 8083.
Figure 7. Bryorutstroemia fulva. (1a,b,5b,c,7a,8a) mature asci; (1c,d,5c left,7b,8b) immature asci; (5b right) young asci; (5a,b,d) paraphyses; (1e,2,3,6,7a) mature ascospores; (1f,4) overmature ascospores. Living state, except for (7a) asci, in H2O, (7b,8) in IKI.—(14) from northern Bohemia, on Dicranella (phot. Z. Sochorová), (1) Z.S. 2/2021, (2) Z.S. 15/2021, (3) Z.S. 16/2021, (4) Z.S. 17/2021; (5) Hungary, on Dicranum (phot. C. Németh, C.N. 103); (6) Sweden, on Bucklandiella (phot. R. Isaksson, UPS F-990878); (7,8) France, on Dicranella, (7) phot. J.P. Priou, J.P.P. 15051, (8) H.O. Baral, H.B. 8083.
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Figure 8. Bryorutstroemia fulva. (1a) collection site in Quercus petraea forest, (1b–e) apothecia in cushions of Dicranum scoparium (Hungary, phot. C. Németh, C.N. 103); (2a,b) Bucklandiella hetero-sticha on silicate stonewall (Sweden, phot. R. Isaksson, UPS F-990878).
Figure 8. Bryorutstroemia fulva. (1a) collection site in Quercus petraea forest, (1b–e) apothecia in cushions of Dicranum scoparium (Hungary, phot. C. Németh, C.N. 103); (2a,b) Bucklandiella hetero-sticha on silicate stonewall (Sweden, phot. R. Isaksson, UPS F-990878).
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Figure 9. Bayesian analysis of the sclerotiniaceous lineage which comprises Rutstroemiaceae s.l. and Sclerotiniaceae s.l., based on ITS1-5.8S-ITS2 and LSU D1–D3 rDNA and EF1α. The chosen outgroup comprises members of Cenangiaceae, Chlorociboriaceae, and Helotiaceae.
Figure 9. Bayesian analysis of the sclerotiniaceous lineage which comprises Rutstroemiaceae s.l. and Sclerotiniaceae s.l., based on ITS1-5.8S-ITS2 and LSU D1–D3 rDNA and EF1α. The chosen outgroup comprises members of Cenangiaceae, Chlorociboriaceae, and Helotiaceae.
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Figure 10. Bayesian analysis of the sclerotiniaceous lineage based on ITS1-5.8S-ITS2 and LSU D1–D3 rDNA.
Figure 10. Bayesian analysis of the sclerotiniaceous lineage based on ITS1-5.8S-ITS2 and LSU D1–D3 rDNA.
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Figure 11. Known distribution of Bryorutstroemia fulva in Europe (white dots referring to the collections cited under “Specimens included”).
Figure 11. Known distribution of Bryorutstroemia fulva in Europe (white dots referring to the collections cited under “Specimens included”).
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4.4. Literature Reports

Boudier [1] described the apothecia of H. fulvum with a diameter and height of 0.5–1.5 mm, asci 150–200 × 17–18 µm, paraphyses apically slightly widened to 3–4 µm, eguttulate, and ascospores oblong-ellipsoid, subinaequilateral, rarely somewhat curved, *16–21 × 7–10 µm, multiguttulate (see Figure 1a). He illustrated bright reddish-brown apothecia but described them as brown to yellow-brown (“brunneo-fulvum”) or fawn-brownish (“fauve brunâtre”), with hymenium and stipe base the most deeply coloured. He apparently did not test the asci with iodine and did not observe overmature spores as he stated that the spores were never septate. When taking the ascus width in Boudier’s drawing as 17 µm, ascus length becomes 250 µm, spores in the asci 18–21 × 7–7.5 µm, and paraphysis width about 4 µm. Evaluation of the scales based on the 225× and 820× magnifications yield values of *295 × 18.5 µm for the ascus, *21–22 × 7–8.5 µm for the free ascospores, and 4 µm for the paraphysis, suggesting some scale and length/width error in Boudier’s drawing regarding ascus length (Figure 1a).
British records of H. fulvum from leaf axils of Dicranella heteromalla were figured by Dennis [2] (as ‘D. heteromera’) and Ellis et Ellis [32], but no collection data were given (see Figure 1b,c). The database of the British Mycological Society [17] indicates two collections, one from Gloucestershire made in 1991 and one without data. Dennis mentioned the negative ascus iodine reaction and considered an affinity with Rutstroemia, but also referred to a “small group of similar species parasitic on bryophytes, for which a separate genus may perhaps be needed” (Dennis probably meant the later erected genus Bryoscyphus Spooner). The almost identical measurements by Dennis and Ellis et Ellis (l.c., asci 150–180 × 13–16 µm, ascospores 16–21 × 6–9 µm) concur well with the present data. The ascospores were illustrated with two large and some smaller LBs, probably because the material was studied in a rehydrated state.
Much earlier, Dennis ([33] p. 58) compared H. fulvum, based on Boudier’s description, with a collection on Lycopodium from Norway which he identified as Poculopsis ogrensis Kirschst. This species he combined as Allophylaria ogrensis (Kirschst.) Dennis, although the inner ectal excipulum was drawn with thin-walled cells and the texture described as very soft. Contrary to H. fulvum, the apothecia were yellow when fresh but turned dark brown on drying, and the much shorter asci had an amyloid ring. At that time, Dennis did not know H. fulvum by personal study. For A. ogrensis, he saw some similarities with the Sclerotiniaceae (as Ciborioideae), but the absence of a substratal blackening or a sclerotium excluded such a relationship.
De Meulder [3] described and illustrated a personal collection of H. fulvum on Dicranella cerviculata collected in 1992 in Belgium (Figure 1d). Ten days after this collection was made, the first author received a part of the dried specimen from the collector. Despite the short time span, no living elements could be found. The obtained measurements differed from De Meulder’s data by much narrower paraphyses (†2–2.2 vs. †3–4 µm), slightly shorter asci (†130–158 × 14–18 vs. †137.5–175 × 12.5–18 µm), and distinctly narrower ascospores (†15–20 × 6–7.5 vs. *15.5–22.75 × 7.5–8.7 µm). De Meulder might have studied a rehydrated apothecium with still living spores, judging from the larger size, and also from the included partly large LBs which were likely formed by the fusion of smaller ones during rehydration. Paraphysis width is hardly over 1.5 µm when evaluated from De Meulder’s drawing, hence his given width of 3–4 µm should be an error or a mere copy of Boudier’s data, whereas values around †1.5–2.5 µm would have been closer to what was here observed in the other collections.

4.5. Misinterpretations

Under the name Helotium fulvum, Velenovský ([34] p. 209) gave an unillustrated record on Hylocomium splendens, H. squarrosum (≡ Rhytidiadelphus squarrosus), and Hypnum cupressiforme. When revising the cited collection, Svrček ([35] p. 149, pl. 19 fig. 7) found only Hylocomium splendens inside the voucher, with apothecia on the leaves, and concluded that it is a species very different from H. fulvum, for which he could not give a name. The ascospores were much more slender (†17–19 × 4–4.5 µm), with two large guttules, and the inamyloid asci much smaller (†90–100 × 6–10 µm, Velenovský: †100–120 × 5–8 µm) compared to Boudier’s H. fulvum, with a strongly inflated foot (crozier?). The apothecia were 1–1.5 mm diam., blackish-brown, sessile or short-stalked. Svrček’s description suggests a species of Hymenoscyphus s.l. Another specimen found in Velenovský’s herbarium under the name H. fulvum was on Rhytidiadelphus squarrosus, and Svrček (l.c.) identified it as Hymenoscyphus rhytidiadelphi (≡ Bryoscyphus rhytidiadelphi).
Bryorutstroemia fulva may be confused with Bryoscyphus dicrani because of a similar ascospore size and shape and inamyloid asci. However, confusion is only possible when comparing herbarium specimens in which B. dicrani may attain a reddish-brownish colour due to secondary pigmentation of the multiguttulate contents of paraphyses and excipular cells. In the living state, B. dicrani has white apothecia, binucleate ascospores with a lower lipid content (OCI 2–3), and multiguttulate paraphyses and cortical excipular cells due to strongly refractive vacuolar bodies (VBs). A further difference lies in the asci which are also inamyloid but arise from croziers.
Hengstmengel [19] studied a collection on Brachythecium rutabulum from the Netherlands (Drenthe, Rolde, Deurzerbroek). We have seen no documentation of this collection, but we consider the possibility that it might be a misidentification, judging from the deviating host.

4.6. Other Bryicolous Species of the Sclerotiniaceous Lineage

Bryorutstroemia fulva is exceptional within the sclerotiniaceous lineage by its ecological restriction to acrocarpous mosses. Only a very small number of other bryicolous discomycetes with a clear affinity to the sclerotiniaceous lineage are known up to now. One of them is Sclerotinia atrostipitata Svrček from Czechia, which was described as emerging from a 2 mm large subglobose sclerotium among rhizoids of Ceratodon purpureus, with globose excipular cells, amyloid asci, and comparatively small, ellipsoid-ovoid, eguttulate ascospores [36]. Svrček’s remark of an attachment of the sclerotium to the moss rhizoids might be an argument for a real connection to the moss, but interactions at the cellular level have not been assessed. The North American Sclerotinia incondita (Ellis) Sacc. mentioned by Svrček likewise grew among mosses, but its description which includes four-spored asci is too brief to permit any conclusion.

Supplementary Materials

The following supplementary Bayesian analyses are available online at https://www.mdpi.com/article/10.3390/life13041041/s1; Figure S1: Bayesian analysis of ITS1-5.8S-ITS2 region; Figure S2: Bayesian analysis of D1–D2 domain of LSU rDNA; Figure S3: Bayesian analysis of EF1α; Figure S4: combined Maximum Likelihood analysis of dataset of Figure 9. For further data see legend to Figure 9 (as outgroup for S3 we selected Chlorociboria glauca).

Author Contributions

H.-O.B.: fieldwork, microscopy, writing the manuscript, illustrating the material; Z.S.: fieldwork, microscopy, writing the manuscript, photographic documentation; M.S.: sequencing, phylogenetic analysis. All authors have read and agreed to the published version of the manuscript.

Funding

Zuzana Sochorová was funded by IGA UP PrF-2023-001 and Michal Sochor by the Ministry of Agriculture of the Czech Republic, institutional support MZE-RO0423.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Names of the new species and combinations were formally registered in MycoBank. Newly generated sequences were deposited in GenBank.

Acknowledgments

We thank Csaba Németh for providing data and photos of his collection from Hungary and for identification of the host moss in a part of the collections, Jannes Boers, Robin Isaksson, Zdeněk Palice, and Jean-Paul Priou for providing data on their collections, and Hubert De Meulder (†) for sending his Belgian specimen to the first author in 1992. Bernard Declercq kindly provided De Meulder’s paper and an excerpt of Arnolds et al. Tereza Tejklová, the curator of HR, is thanked for providing specimens of the sclerotiniaceous clade for sequencing. Chris Yeates and Georges Greiff are thanked for linguistic suggestions.

Conflicts of Interest

The authors declare no conflict of interest.

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Table 1. Sequences included in phylogenetic analysis (T = type). Newly generated sequences in bold. - = gene region missing, ? = data missing, # = as Rutstroemia cuniculi.
Table 1. Sequences included in phylogenetic analysis (T = type). Newly generated sequences in bold. - = gene region missing, ? = data missing, # = as Rutstroemia cuniculi.
SpeciesCollection NumberCountryHostITSLSUEF1α
Bicornispora seditiosaAH 44702 TSpainAcer monspessulanumKF499362KF499362MW001933
Bryorutstroemia fulvaC.N. 103HungaryDicranum scopariumOP035831OP035831OP058106
Bryorutstroemia fulvaZ.S. 2/2021Czech RepublicDicranella heteromallaOP035812--
Bryorutstroemia fulvaZ.S. 7/2021Czech RepublicDicranella heteromallaOP035830OP035830OP058105
Bryorutstroemia fulvaZ.S. 9/2021Czech RepublicDicranella heteromallaOP035829OP035829OP058104
Bryorutstroemia fulvaZ.S. 19/2021Czech RepublicDicranella heteromallaOP035828OP035828OP058103
“Cenangium” acuumKL 243GermanyPinus sylvestrisLT158439KX090822KX090674
Chlorociboria glaucaKL 238FranceSalix sp.LT158438KX090821KX090673
Ciboria amentaceaHR 98838Czech RepublicAlnus sp.OP901951OP897698OP958788
Ciboria americanaHR 102055Czech Republicindet. gallOP901952OP897699OP958784
Ciboria betulae1145.P NorwayBetula sp.Z81427Z81403 -
Ciboria conformataHR B008890Czech RepublicAlnus glutinosaOP902277OP897705OP958790
Ciboria coryliHR B008735Czech RepublicCorylus avellanaOP902275OP897703OQ023970
Ciboria viridifuscaHR B006315Czech RepublicAlnus glutinosaOP901954OP897702OP958783
Clarireedia asphodeliF142282SpainAsphodelus fistulosusKJ941085KJ941065 -
Clarireedia bennettiiCBS 309.37unknownindet. PoaceaeMF964321--
Clarireedia calopusCBS 854.97Netherlandsindet. PoaceaeKF545314AB926155-
Clarireedia calopus #CBS 465.73Great Britainrabbit dungKF588375MH878367-
Clarireedia gladioliCBS 265.28 TunkownGladiolus sp.MH855008MH866477-
Clarireedia henningsianaHR B013053Czech RepublicScirpus sylvaticusOP901955OP897706OP958787
Clarireedia homoeocarpaCBS 310.37Great BritainFestuca sp.MF964322MH867420-
Clarireedia maritimaH.B. 6860SpainAmmophila arenariaKF588372KJ941063-
Clarireedia narcissiCBS 339.33NetherlandsNarcissus sp.MH855451MH866916-
Clarireedia paspaliXC5ChinaPaspalum vaginatumMH392087-MH444193
Clarireedia sp.BVVUSABromus tectorumMT850272MG937748NJPS01000062
Dumontinia tuberosaTU109263EstoniaAnemone nemorosaLT158412KX090843KX090697
Encoelia furfuraceaKL 107EstoniaCorylus avellanaLT158416KX090798KX090653
Hymenoscyphus scutulaG.M. 2014-12-25.2Luxembourgindet. herbMK674606 MK674606 -
Lambertella corni-marisCLX4075 USAMalus sp.KC958562KC964858 -
Lambertella palmeriAH 7655SpainQuercus rotundifoliaKF499365KF499365-
Lambertella pyrolaeTNS-F 40132 TJapanPyrola incarnataAB926081AB926164 -
Lambertella subrenisporaCBS 811.85JapanAster ageratoidesMH861915DQ470978DQ471101
Lanzia allantosporaCBS 124334New ZealandAgathis australisAB926099AB926154-
Martininia panamaensisCBS 207.47Panamaindet. logMH856219MH867749-
Monilinia fructicola2014/FC48HungaryPrunus persicaLT615175LT615175-
Monilinia oxycocci1087.P NorwayVaccinium oxycoccosZ73789Z73754-
Piceomphale bulgarioidesHR B004019Czech RepublicPicea abiesOP901953OP897701OP958786
Pycnopeziza sejourneiKL 267FranceHedera helixLT158443KX090827KX090679
Rutstroemia bolaris1526.P NorwayBetula pubescensZ80894Z81419 -
Rutstroemia elatinaHR B000521Czech RepublicAbies sp.OP902274OP897700OP958785
Rutstroemia firmaKL 290Estoniaindet. angiospermLT158448KX090830KX090682
Rutstroemia longipesTNS: F-40097JapanDaphniphyllum macropodumAB926073AB926142-
Rutstroemia luteovirescensHR B008840Czech RepublicAcer platanoidesOP902276OP897704OP958789
Rutstroemia tiliaceaKL 160GermanyTilia sp.LT158423KX090808KX090661
Schroeteria decaisneanaA.U. 2273GermanyVeronica hederifoliaMZ048345 MZ048345 -
Schroeteria delastrinaV.K. P1652-26GermanyVeronica arvensisMW915645MW915645-
Sclerencoelia fraxinicolaKL 156 GermanyFraxinus excelsiorLT158420KX090805KX090659
Scleromitrula shiraianaHirayama062001??AY789408AY789407-
Sclerotinia sclerotiorum1980 UF-70USAbean podsCP017820 CP017820 -
Torrendiella setulataH.B. 9775CanadaAcer spicatumKF588367KJ941052-
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Baral, H.-O.; Sochorová, Z.; Sochor, M. Bryorutstroemia (Rutstroemiaceae, Helotiales), a New Genus to Accommodate the Neglected Sclerotiniaceous Bryoparasitic Discomycete Helotium fulvum. Life 2023, 13, 1041. https://doi.org/10.3390/life13041041

AMA Style

Baral H-O, Sochorová Z, Sochor M. Bryorutstroemia (Rutstroemiaceae, Helotiales), a New Genus to Accommodate the Neglected Sclerotiniaceous Bryoparasitic Discomycete Helotium fulvum. Life. 2023; 13(4):1041. https://doi.org/10.3390/life13041041

Chicago/Turabian Style

Baral, Hans-Otto, Zuzana Sochorová, and Michal Sochor. 2023. "Bryorutstroemia (Rutstroemiaceae, Helotiales), a New Genus to Accommodate the Neglected Sclerotiniaceous Bryoparasitic Discomycete Helotium fulvum" Life 13, no. 4: 1041. https://doi.org/10.3390/life13041041

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