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Hungary has some of the best-researched hypogeous fungal flora in Europe, with a large number of genera and species already having been discovered in this country. In this study, we performed morphological and molecular analysis of unidentified hypogeous fungi samples collected from Hungary. We confirmed that they belong to the hypogeous earthstar species Geastrum nadalii (Paz et al., 2024), marking the first report of this species in this country and in a continental climate. We also assume that the habitat preference of this mushroom species is similar to the habitat preference of Mattirolomyces terfezioides, with both occurring in planted non-native Robinia pseudoacacia forests, suggesting that these are secondary habitats for these species. We also conclude that this Mediterranean species has appeared only recently in the Hungarian mycota.
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1. Introduction
Earthstars are a morphological and taxonomically diverse group of macrofungi. Despite their lack of commercial use, they are well-studied fungi, because of their unique morphological appearance [1]. Earthstars belong to the family Geastraceae. Most species in this family are considered saprotrophic, but there is evidence that some species can form ectomycorrhiza [2]. The basidiome of earthstars develops underground; then, throughout the maturation process, most earthstars grow above ground, and their exoperidium rips open and spores are released through a hole in the endoperidium [1]. However, there are species in which the fruitbody remains hypogeous, the exoperidium does not rip, and the endoperidium is underdeveloped or absent [3]. These taxa demonstrate the typical evolutionary line of hypogeous fungi [4]. Because they lose the ability to release their spores into the air, they usually develop an aromatic odor to attract vector animals [4].
The genus Radiigera was described by Sanford Myron Zeller in 1944 [5], with the type species as Radiigera fuscogleba. Later on, it was placed in the Geastraceae family and considered a close relative of the genus Geastrum [6]. But, in their 2014 article [7], Zamora et al. revised the systematics of Geastrum and Radiigera and merged the two genera into one. Since then, four former Radiigera species—R. bushnellii, R. flexuosa, R. fuscogleba, and R. taylorii—have been considered to belong to the genus Geastrum. Another former species, R. atrogleba, is now considered a synonym of Schenella simplex [8].
There is a very limited number of records of hypogeous Geastraceae samples in Europe. G. flexuosum has been identified in Sweden [3]. Another species, known as Radiigera romana, was described in Italy [9], and later renamed as Schenella romana [8]. Another specimen that has been found in Italy is Radiigera atrogleba, discovered in Montecchi, and Sarassini’s book [10] notes that it is extremely rare.
In this study, we confirmed the occurrence of a hypogeous Geastrum species in Hungary, based on morphological and molecular analysis, and examined its habitat preferences. In our herbarium, we had samples from the time span of 2013 to 2024. They were labeled as “Radiigera sp.”, although there are no previous reports of this genus and other hypogeous Geastraceae from Hungary, and according to our analysis, the samples were morphologically and phylogenetically different from the hypogeous Geastrum species known at the time. The samples were collected in a period lasting from September to December, from habitats in sandy soil deposited by the Danube, in planted man-made Robinia pseudoacacia forests (Robinietum cultum, [11]). We observed that all fungal nests were located near honey locust (Gleditsia triacanthos) trees. Other common woody plants that can be found nearby the basidiomata are Celtis occidentalis and Crataegus monogyna.
2. Materials and Methods
2.1. Study Area
All our collections were made in areas with sandy soil deposited by the river Danube (see Table 1 and Figure 1). These habitats are highly similar to those of the sand truffle (Mattirolomyces terfezioides), which is a well-known and valuable commercial truffle in Hungary, but there are many unanswered questions about its origin and habitat preferences [12], and it forms a mycorrhizal connection with the black locust tree (Robinia pseudoacacia) [13]. According to our collection data, this Geastrum species has only been found in the same habitats as the sand truffle in Hungary, in the Pest Plain and Kiskunság microregions.
2.2. Fungi Collection, Sampling
Fresh basidiomata were collected from natural habitats (see Figure 2), with the help of truffle hunters, members of the First Hungarian Truffle Society (EMSzE) with certificates, and trained truffling dogs, and were deposited in the society’s mycotheca (ZB) [14]. The fruitbodies were transferred to our lab, where some were examined when fresh, then dried and stored in our herbarium.
2.3. Soil Sampling
Soil samples were taken in the vicinity of the fruitbodies (less than 1 m from them) with the help of shovels. Four soil samples were taken from each mushroom habitat, approximately till 15 cm depth. Samples were packed in plastic bags, and after drying and sieving, they were sent to an accredited lab for soil analysis (Nemzeti Élelmiszerlánc-biztonsági Hivatal Élelmiszerlánc-biztonsági Laboratórium Igazgatóság Növény-és Talajvédelmi Nemzeti Referencia Laboratórium, Velence, Hungary). The examined soil parameters and results can be found in Supplement S2.
2.4. Morphological and Molecular Study
The samples’ macromorphological characteristics, including their basidiome shape, surface, color, and gleba color and shape, were examined with a Nikon SMZ-2T stereo microscope. PZO Biolar, Zeiss Ergaval, Nikon Optiphot-2, and Nikon SMZ-2T microscopes were used for measuring the micromorphological structures of the fungi, such as their peridium, columella, gleba, and spores. In addition to this, the Piximétre program was used to measure the spore sizes. The ultrastructure of the peridium, spores, and capillitia were examined under a scanning electron microscope. For this examination, the gleba of dried ascomata was scraped, and pieces of it were fixed onto a taped disk. The tissue fragments were gold-coated, and adhered spores were inspected under a Hitachi 2360N scanning electron microscope (SEM). Gleditsia roots were stained to investigate possible mycorrhizal connections, according to Vierheilig’s method [15].
Genomic DNA was isolated from dried basidiomata with the DNeasy Plant Mini Kit (Qiagen, Courtaboeuf, France), according to the manufacturer’s instructions, with a few modifications based on our experience. The amplified loci were Internal Transcribed Spacer (ITS) and Large Subunit (LSU) regions of the fungal nuclear ribosomal DNA locus. For the ITS, we used ITS1F/ITS4 primers, and for the LSU, we used LROR/LR5 primers for amplification of the genomic region of interest [16,17]. PCR was conducted under the following conditions: initial denaturation at 94 °C for 4.5 min; 33 cycles of denaturation at 94 °C for 30 s; annealing at 51 °C for 30 s; elongation at 72 °C for 45 s; and, after the last cycle, a final synthesis stage at 72 °C for 7 min. For gel electrophoresis of the amplification products, 1% agarose gel was used. Staining was performed with ethidium bromide. For the purification of the PCR products, we used the QIAquick® PCR Purification Kit. Sanger sequencing was carried out by BIOMI Ltd. (Gödöllő, Hungary).
The electropherograms were checked and edited using FinchTV 1.4.0 (
After this, the most taxonomically relevant sequences were gathered for further evaluation regarding the available ecological and distributional data. The final dataset contains our newly generated sequences and the selected reference sequences that were selected based on the current taxonomic results. RAxML 8.2.12 [23], as implemented on CIPRES [20], was used to perform Maximum Likelihood (ML) analysis using fast bootstrap (1000×). We used jModelTest [24] to find the optimal substitution model, which was the General Time Reversible model, for nucleotide substitutions, combined with a gamma distribution to account for rate heterogeneity across sites, and incorporating a proportion of invariable sites in the evolutionary model. The likelihood of the final tree was optimized under the GAMMA substitution model, and FigTree V. 1.4.4 [25] was used to visualize the phylogenetic tree (Figure 3). As an outgroup, Myriostoma coliforme (GenBank accession numbers: KF988337 and KF988348) was chosen.
The DNA extraction, PCR, sequence processing, and phylogenetic tree generation were conducted according to our lab protocol, in a similar way to work on other hypogeous fungi [26].
3. Results
3.1. Macromorphological Characteristics
The microscopy results showed that the basidiome forms below the soil surface, and does not rise visibly to the soil surface even when mature; it is 10–36 mm in diameter, spherical or slightly flattened spherical, sometimes slightly wrinkled, and smooth or slightly rough, and the surface is covered with an easily detachable mycelium and some rhizomorph-like structures.
Color of fresh basidiome: ocher cream—pale beige—rose ocher—pink—bright pink—purplish pink.
Dried material colors: clay buff (32), fawn (29), fulvous (12) (color key of the Royal Botanical Garden, Edinburgh (RBGE) 1969).
The smell is metallic in fresh material; this is not observed in the exsiccata.
The exoperidium is thin and brownish at the cut surface of the fruiting body.
The exoperidial layer adheres to the 1–2 mm thick mesoperidial layer or detaches from it after drying.
The outer part of the mesoperidium, a thinner band, is yellowish-brown, and the thicker inner part is whitish. The inner side of the mesoperidial layer directly borders the gleba.
The endoperidium is absent.
The gleba is dark gray-black, and cotton-like when mature, with a disintegrating spore mass.
The columella is well-developed, with a width of 4–7 mm and a length of 10 mm, and it extends halfway into the gleba (see Figure 3).
3.2. Micromorphological Characteristics
The total width of the peridium is 1632–2224 µm.
The exoperidium consists of two layers. The cortical external layer is 32–112 µm, with dense interwoven yellowish 2–5 µm wide hyphae and 0.5–0.7 µm thick cell walls; the hyphae are rarely branched. Internal layer: 144–320 µm, has an incompact structure, strongly coiled interwoven hyphae, pale yellow, rarely branched, septum not detected, cells 1.7–4 µm thick, cell walls 0.5–1.5 µm.
The width of the mesoperidium is 1504–1968 µm; the hyaline pseudoparenchymatous cells are of mixed type and of various shapes, with rounded corners, or completely spherical, with an irregular ovoid shape, sometimes with angular or pointed corners wedged between neighboring cells.
External mesoperidial layer textura globosa, with smaller subglobose cells of 2.5–10.9 × 3.3–18.3 µm, are arranged in a few cell rows at the border of the exoperidium and the mesoperidium. Deeper towards to the gleba, the internal layer is textura globosa to textura prismatica, with larger and larger shapeless angular cells of 5.9–30 × 8.3–43.3 µm located mixed in with the small subglobose cells.
Columella hyphae are hyaline or yellowish, rarely branched, (1.5–)2–3(–4) µm wide, 0.5–0.7(–1.0) µm wall thickness, septa rarely visible.
Capillitium is 1–2.5(–3.5) µm wide hyphal hyaline, clamp and septa not detected, sometimes undulating, sometimes widening, their wall thickness varies, 0.5–0.7 µm.
Spores are globose–subglobose, ornamented, brown, diameter: 3.2–5.1 µm (average 3.7–4.1 µm), Q: 1–1.1(–1.2) (see Figure 4). Ornamentation: slightly rounded, coarse warts, knotted (sometimes almost irregularly areolate-reticulate) 0.1–0.6 µm (average = 0.27–0.37 µm) (see Figure 5).
Basidium is not detected.
Crystals are not detected, not on hyphae nor on spores.
After staining of the Gleditsia roots, only arbuscular mycorrhizal structures were detected, which cannot be connected to the Geastrum genus.
3.3. Phlyogenetic Analysis
See Figure 6.
3.4. Soil Analysis
The results of the soil analysis can be found in Supplement S2.
4. Discussion
Based on the morphological and phylogenetic data, we can conclude that these hypogeous Geastrum samples belong to the recently described Geastrum nadalii species [27]. All previous records come from regions with a Mediterranean climate; the samples studied here constitute the first report from an area with a continental climate. Based on the phylogenetic data, we found that this species is most closely related to Geastrum violaceum, which has been identified in Brazil [28]. According to the molecular data, this species belongs to the Corollina section and the Plicostomata subsection [7]; however, this could not be confirmed morphologically due to a lack of crystals and a peristome, the shapes of which are the main morphological characteristics of this section. Among other European species, Geastrum morganii is the most closely related species. Because all the samples were collected from known Mattirolomyces habitats, we suggest that in Hungary, this species shares the same habitat with the sand truffle. The soil data was highly similar to that reported for sand truffle nests. We also noticed that this species always grows under or nearby honey locust trees (Gleditsia triacanthos), which is a plant introduced from North America, like the black locust (Robinia pseudoacacia). We did not find any special fungal structures at the actual time of sampling, besides arbuscular mycorrhizae in the honey locust roots, suggesting that this connection might not be mycorrhizal. Both fungal species have been identified in the Mediterranean, so we can conclude that planted Robinietum forests might be secondary habitats of both the sand truffle and Geastrum nadalii. These species are additional good examples of Mediterranean mushroom species spreading into northern Europe, as is well documented for some other truffle species, like Tuber magnatum [29,30,31].
5. Conclusions
Hungary has a rich and well-researched hypogeous mycota, and in this study, we confirmed the presence of a previously unknown species, Geastrum nadalii, the first hypogeous Geastrum to be identified in this country. Analysis of its growing sites showed that it shares habitat preferences with Mattirolomyces terfezioides, occurring in planted Robinia forests. We conclude that this species has appeared recently in Hungary, as most samples have been collected in the Mediterranean, and this species is currently spreading north in Europe. Our findings show that there are still many unidentified species of the hypogeous mycota, even in well-screened territories like the Carpathian Basin.
Conceptualization and methodology: Á.H., P.C., B.P., A.A.H., and Z.B.; field collections: Á.H., A.A.H., B.P., and Z.B.; morphological analysis: Á.H., P.C., and I.N.; phylogenetic analysis: B.P., A.A.H., P.C., and Á.H.; writing—manuscript preparation: Á.H., A.A.H., I.N., B.P., and Z.B.; supervision: Z.B.; project administration: Z.B. All authors have read and agreed to the published version of the manuscript.
The molecular data is publicly available in GenBank, and all other data is available in the manuscript.
The authors would like to express their gratitude to the truffle hunters, who helped in the collection of the samples. Furthermore, we express our thanks to Biomi Ltd. for the sequencing of our samples. We are very grateful to Károly Bóka for his help in the scanning electron microscopy work.
The authors have no conflicts of interest.
Footnotes
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Figure 1 Hypogeous Geastrum sampling sites in Hungary.
Figure 2 Basidiomata of examined samples, photographed in situ at the sampling site (photo: Zoltán Bratek) (scale 1 cm).
Figure 3 Section of fresh basidiome (scale 1 cm).
Figure 4 Spores of samples examined under a light microscope (magnification 300×, scale = 10 µm).
Figure 5 A spore of a sample examined under a scanning electron microscope (scale marked).
Figure 6 The phylogenetic tree of the Geastrum genus, based on Internal Transcribed Spacer (ITS) and 28S rRNA (LSU), with GenBank herbarium voucher codes in brackets (see in
Data of the collected basidiomata from Hungary identified as hypogeous Geastrum.
| Lab Herbarium Code | Geographical Microregion | Locality | Date of Collection | Number of Collected Basidiomata | GenBank Voucher | GenBank Accession Number |
|---|---|---|---|---|---|---|
| ZB4964 | Kiskunság | Near Kecskemét | 14 October 2013 | 1 | no | no |
| ZB5788 | Pest Plain | Ócsa | 16 October 2019 | 5 | no | no |
| ZB5906 | Pest Plain | Dunakeszi | 21 October 2021 | 2 | Rad1 | PQ784779 |
| ZB5972 | Szentendre Island | Szigetmonostor | 2 October 2022 | 9 | Rad2 | PQ784780 |
| ZB5978 | Pest Plain | Ócsa | 9 November 2022 | 12 | Rad3 | PQ784781 |
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