The potentially new species were initially named Diversispora 448, Scutellospora 431, and Scutellospora 437 (numbers are from an AMF database maintained by J. Błaszkowski). These isolates, as well as A. gedanensis, were characterized based on spores extracted from trap cultures because numerous attempts to grow the fungi in single-species cultures failed. The trap cultures were established from field mixtures of rhizosphere soils and root fragments collected under the following plant species. The field host of Diversispora 448 was Ammophila arenaria (L.) Link. The plant colonized maritime sand dunes near Przebrno (54°22'30.3''N 19°23'13.6''E) located on the Vistula Spit in northern Poland. The soil sample was collected by P. Niezgoda on July 10, 2020. The data relating to the climatic and soil chemical properties of Vistula Spit are detailed in Błaszkowski et al. (2002). Scutellospora 431 and Scutellospora 437 were hosted in the field by A. arenaria, which colonized maritime sand dunes of the Voidokoilia beach (36°57'46''N 21°39'45''E) located on the Peloponnese peninsula, Greece. The soil sample was collected by J. Błaszkowski on September 8, 2015. Data relating to the climate and soil chemical properties of the sampled site are detailed in Błaszkowski et al. (2019a). In the field, A. gedanensis was associated with the roots of Festuca rubra L. growing among trees inhabiting a moist site located near Władysławowo (54°47'00''N 18°26'17''E) on the Hel Peninsula in northern Poland. The host plant was sampled by J. Błaszkowski on July 18, 2022. The trap and single-species cultures were established and grown, spores extracted, and mycorrhizal structures stained, as described in Błaszkowski et al. (2006, 2009). In all the attempts aimed at establishing single-species cultures, 5–15 spores of each isolate were used.

Morphological features of spores, as well as phenotypic and histochemical characters of spore wall and germinal wall layers of A. gedanensis, Diversispora 448, Scutellospora 431, and Scutellospora 437 were characterized based on at least 50–100 spores of each isolate mounted in water, lactic acid, polyvinyl alcohol/lactic acid/glycerol (PVLG, Omar et al., 1979), and a mixture of PVLG and Melzer's reagent (1:1, v/v). Spores for study and photography were prepared as described in Błaszkowski (2012) and Błaszkowski et al. (2012). The types of spore wall and germinal wall layers have been defined by Walker (1983), Morton (1986), Morton et al. (1995), and Błaszkowski (2012). Color names were obtained from Kornerup and Wanscher (1983). The nomenclature of fungi and the authors of fungal names were taken from the Index Fungorum website (http://www.indexfungorum.org/AuthorsOfFungalNames.htm). The term “glomerospores” was used for spores produced by AMF, as proposed by Goto and Maia (2006).

The voucher specimens of the proposed new species [spores permanently mounted in PVLG and a mixture of PVLG and Melzer's reagent (1:1, v/v) on slides] were deposited at ZT Myc (ETH Zurich, Switzerland; holotypes) and in the Laboratory of Plant Protection, Department of Environmental Management (LPPDEM), West Pomeranian University of Technology in Szczecin, Poland (isotypes and A. gedanensis specimens).

Genomic DNA of A. gedanensis, Diversispora 448, Scutellospora 431, and Scutellospora 437 was extracted from single or 2–5 spores. The method of processing the spores prior to PCR, conditions and primers used for PCR, as well as cloning and sequencing of PCR products to obtain 45S sequences of the four isolates were as those described by Błaszkowski et al. (2021). A nested PCR with the primers RPB1-4F2/RPB1-5R1 and RPB1-4F3/RPB1-5R2 was used to obtain rpb1 sequences from Diversispora 448 like in Błaszkowski et al. (2022). Both 45S and rpb1 sequences were deposited in GenBank (OR669295, OR669296, OR669014–OR669021, OR669025–OR669038).

To confirm the BLAST results indicating the analyzed AMF as undescribed species of Diversisporaceae (Diversispora 448) and Scutellosporaceae (Scutellospora 431, Scutellospora 437), as well as to determine the positions of these isolates within these families and A. gedanensis among sequenced Acaulospora species, five alignments were prepared. The phylogeny of Diversispora 448 was reconstructed based on the analyses of the 45S and rpb1 sequences, while the phylogenies of the other isolates were reconstructed from the 45S sequences alone. The 45S and rpb1 sequence sets were aligned separately in MAFFT 7 with the E-INS-i option.

For Diversispora 448, the ingroup of the 45S alignment consisted of 85 sequences of 22 Diversispora species and Diversispora 448, and the outgroup was Corymbiglomus corymbiforme, Desertispora omaniana, Redeckera megalocarpum, and Sieverdingia tortuosa. The species of the outgroup represented the most closely related genera to Diversispora selected through prior analyses of members of all genera of Diversisporaceae. The 45S alignment with Scutellospora 431 and Scutellospora 437 contained 28 sequences of 6 Scutellospora species and the 2 potentially new species in the ingroup and Orbispora pernambucana in the outgroup. The ingroup of the A. gedanensis 45S alignment counted 118 sequences, representing 48 Acaulospora species, and the outgroup included Sacculospora baltica and S. felinovii sequences.

The Diversispora 448 rpb1 alignment included 36 rpb1 sequences that characterized 18 Diversispora species of the Diversispora 448 45S alignment and Diversispora 448, i.e., all Diversispora species having sequences of the two loci. The Diversispora 448 45S+rpb1 alignment was created by concatenation of the 45S and rpb1 alignments.

The percentage genetic distances of A. gedanensis, Diversispora 448, Scutellospora 431, and Scutellospora 437 from their closest relatives were calculated in BioEdit (Hall, 1999). All comparisons were performed on sequences of the same length.

The phylogenetic positions of A. gedanensis, Diversispora 448, Scutellospora 431, and Scutellospora 437 were reconstructed based on Bayesian inference (BI) and maximum likelihood (ML) phylogenetic analyses of the 45S and 45S+rpb1 alignments, performed via CIPRES Science Gateway 3.1 (Miller et al., 2010). The 45S and rpb1 alignments were divided into five and three partitions, respectively (45S into 18S, ITS1, 5.8S, ITS2, and 28S; rpb1 into two exons and one intron). In both BI and ML analyses, the nucleotide substitution model GTR+I+G was used for each nucleotide partition (Abadi et al., 2019).

The BI reconstruction was done in MrBayes 3.2 (Ronquist et al., 2012) based on four Markov chains run over one million generations, sampling every 1,000 generations with a burn-in at 30% of sampled trees. The ML phylogenetic tree inference was performed with RAxML-NG 1.0.1 (Kozlov et al., 2019), using a maximum likelihood/1000 bootstrapping run and ML estimated proportion of invariable sites and base frequencies. The alignments and tree files are available as online resources (Supplementary Tables 2–13).

Clades were considered supported when the Bayesian posterior probabilities and the ML bootstrap values were ≥0.95 and ≥70%, respectively. The phylogenetic trees were visualized and edited in MEGA6 (Tamura et al., 2013).

The occurrence of A. gedanensis, Diversispora 448, Scutellospora 431, and Scutellospora 437 in other ecosystems worldwide was checked by comparing 45S sequences of these species/isolates with environmental sequences deposited in GenBank and retrieved using BLASTn. It was assumed that the sequences shown could represent the same species/isolates as the four AMF discussed here when their similarity was >96%.

Of the 45S and rpb1 sequences analyzed, 22 and 2, respectively, were newly obtained in this study. The numbers of analyzed sequences and species/isolates, as well as the numbers of base pairs, variable, and parsimony informative sites of each of the alignments studied are presented in Supplementary Table 1.

The topologies of the 45S and 45S+rpb1 trees generated by BI and ML analyses of sequences of Acaulospora, Diversispora, and Scutellospora members were identical (Figures 1, 3, 7, and Supplementary Figure S1). In the trees with 45S+rpb1 and 45S sequences (Figure 1, Supplementary Figure S1), Diversispora 448 grouped in a clade sister to D. densissima sequences, and in both these trees, the Diversispora 448 clade obtained full BI (=1.0) and very high ML (=99% and 97%, respectively) supports. Analyses of 45S sequences of Scutellospora 431 and Scutellospora 437 indicated that they were sister species and closely related to Scutellospora ovalis. Each of the potentially new species obtained full BI (=1.0) and full (=100% for Scutellospora 437) or high (=84% for Scutellospora 431) ML supports (Figure 3).

The divergence of 45S sequences of Diversispora 448 from those of D. densissima ranged from 5.0% to 6.7%. The range of differences between 45S sequences of Scutellospora 431 and Scutellospora 437 was 3.6–5.3%.

Acaulospora gedanensis was placed in a basal clade sister to a clade consisting of two subclades, one with A. brasiliensis and the second with A. pustulata (Figure 7). The A. gedanensis clade was fully (BI =1.0) and strongly (ML = 89%) supported. Also, the clades with A. brasiliensis and A. pustulata, as well as the node linking the A. gedanensis clade with the A. brasiliensis and the A. pustulata clade obtained full BI and very high ML (98%−100%) supports.

Acaulospora gedanensis and A. brasiliensis differed in terms of the nucleotide composition of the 45S sequences by 3.2%−7.4% and A. gedanensis and A. pustulata by 3.4%−4.4%.

The results of phylogenetic analyses and comparisons of sequences described above confirmed our supposition resulting from the preliminary morphological and molecular studies of the three fungi considered here that they are undescribed species and showed the closest relatives of A. gedanensis. Consequently, Diversispora 448, Scutellospora 431, and Scutellospora 437 have been described below as D. vistulana sp. nov., S. graeca sp. nov., and S. intraundulata sp. nov., respectively. As for A. gedanensis, its morphology was compared with the original one characterized by Błaszkowski (1988, 2012) and the morphology of the species closely related phylogenetically (Figure 3).

Diversispora vistulana Niezgoda, B.T. Goto, Magurno et Błaszk., sp. nov.

Figures 2A–H.

MycoBank No. MB 851412.

Etymology: Latin, vistulana, referring to the Vistula Bar, where the new species was originally found.

Specimens examined: POLAND. Spores from a trap culture inoculated with a field-collected mixture of the rhizosphere soil and root fragments of Ammophila arenaria growing in maritime sand dunes near Przebrno (54°22'30.3''N 19°23'13.6''E) on the Vistula Spit in northern Poland, July 10, 2020, P. Niezgoda (holotype slide with spores no. ZTMyc 0067007, isotype slides with spores no. 3910–3917, LPPDSE).

Diagnosis: Differs from (A) D. densissima, the closest phylogenetic relative (Figure 1, Supplementary Figure S1) in (i) the color of spores and their subtending hyphae, (ii) the number of spore wall layers, (iii) morphometric features of the spore wall and the spore subtending hypha, and (iv) nucleotide composition of sequences of the 45S nuc rDNA region and the rpb1 gene (see Discussion for details); (B) D. insculpta, D. peridiata, and D. sabulosa, forming yellow-colored spores with the spore wall consisting of two permanent layers—a hyaline outer layer and a colored laminate inner layer—in morphometric features of spores, the spore wall, and the spore subtending hypha (Błaszkowski, 2012; Błaszkowski et al., 2015; Symanczik et al., 2018), and (iv) the phylogenetic position in Diversisporaceae (Figure 1, Supplementary Figure S1).

Description: Glomerospores (= spores) formed singly in soil, arise blastically at the tips of sporogenous subtending hyphae (Figures 2A, E–H). Spores are pale yellow (3A4) to dark yellow (4C8); globose to subglobose; (93–)102(−110) μm in diameter; frequently ovoid; 87–103 × 103–154 μm; with one subtending hypha (Figures 2A–H). The spore wall is composed of two permanent layers (Figures 2B–H). Layer 1, forming the spore surface, is uniform (not containing visible sublayers), semi-rigid, hyaline, usually uniform in thickness, (0.8–)1.2(−1.8) μm thick, sometimes with slightly thinner and thicker segments, then slightly wavy when viewed in cross-section, rarely with a slightly deteriorated upper surface, and always tightly adherent to the upper surface of spore wall layer 2 (Figures 2B–H). Layer 2 is laminate, smooth, semi-rigid, pale yellow (3A4) to dark yellow (4C8), (2.6–)3.3(−4.4) μm thick, consisting of very thin (< 0.5 μm) laminae, and tightly adherent to and not separating from each other in even vigorously crushed spores (Figures 2B–H). None of spore wall layers 1 and 2 stains in Melzer's reagent (Figures 2D, F, G). Subtending hypha is hyaline to pale yellow (3A4); straight or recurved, cylindrical or slightly constricted at the spore base; (4.6–)11.1(−13.1) μm wide at the spore base (Figures 2E–G); rarely irregular (Figure 2H); and not braking in crushed spores. The wall of subtending hypha is hyaline; (1.8–)3.4(−6.4) μm thick at the spore base; and consists of two layers that are continuous with spore wall layers 1 and 2 (Figures 2F–H). The pore is (0.6–)2.8(−7.0) μm wide at the spore base and open or occluded by a straight or slightly curved septum which is continuous with some outermost laminae of spore wall layer 2 (Figures 2E, H). The spore content is a hyaline oily substance. Germination unknown.

Ecology and distribution: In the field, D. vistulana probably lived in arbuscular mycorrhizal symbiosis with roots of A. arenaria in maritime sand dunes near Przebrno (54°22'30,3''N 19°23'13,6''E) located on the Vistula Spit in northern Poland, but no molecular analyses were performed to confirm this supposition. Numerous attempts at growing this species in single-species cultures with P. lanceolata as the host plant failed. According to BLASTn search and our phylogenetic analyses, D. vistulana appears to have a disjunct distribution since only two sequences (JF439143 with 97.18% of identity and coverage = 100% from China and EU350809 with 97.36% of identity and coverage = 34% from Netherlands: Island Terschelling, Atlantic Coast) clustered in the clade with 45S sequences of the new species (data not shown).

Scutellospora graeca Błaszk., Niezgoda, B.T. Goto & Magurno, sp. nov.

Figures 4A–H

MycoBank No. MB 851413

Etymology: Latin, graeca, referring to the country, Greece, in which the species was originally found.

Specimens examined: GREECE. Spores from a trap culture inoculated with a field-collected mixture of the rhizosphere soil and root fragments of Ammophila arenaria inhabiting a maritime sand dune site of the beach Voidokoilia (36°57'N 21°39'E), the Peloponnese Peninsula, Greece, September 8, 2015, J. Błaszkowski (holotype slide with spores no. ZTMyc 0067008, isotype slides with spores no. 3918–3932, LPPDSE).

Diagnosis: Differs from (A) S. intraundulata, the closest phylogenetic relative (Figure 3), in: (i) spore color, (ii) the thickness of the spore wall, (iii) having a laminate spore wall layer 2 that is uniform in thickness in its different regions (vs. often with local depressions on the lower surface), and (iv) nucleotide composition of sequences of the 45S nuc rDNA region (see Discussion for details); (B) other smooth-spored Scutellospora species, i.e., S. arenicola, S. calospora, S. dipurpurescens, and S. deformata, in (i) spore color and size, (ii) the permanence of spore wall layer 1 and the reactivity of spore wall layer 2 in Melzer's reagent, (iii) the thickness of spore wall layer 2, (iv) the composition and phenotypic and histochemical properties of germinal wall 1, (v) the composition of germinal wall 2 (Morton and Koske, 1988; Koske and Halvorson, 1989; Guillén et al., 2021; https://invam.ku.edu/species-descriptions), and (vi) the phylogenetic position among sequenced Scutellospora species (Figure 3).

Description: Glomerospores (= spores) formed singly in soil, terminally, rarely laterally, on bulbous sporogenous cells (Figures 4A, B, G). Spores are yellowish gray (3B2) to light yellow (4A4); ovoid; 109–162 × 164–228 μm; rarely globose; (140–)156(−168) μm in diameter; with a spore wall, two germinal walls, and a germination shield formed on the upper surface of germinal wall 2 (Figures 4A–H). The spore wall is composed of three permanent layers (spore wall layers 1–3; Figures 4B–F). Layer 1, forming the spore surface, is uniform, smooth, semi-rigid, hyaline, (1.0–)1.3(−1.5) μm thick, and always tightly adherent to layer 2 (Figures 4B–E). Layer 2 is laminate, smooth on the upper and lower surfaces, semi-rigid, yellowish gray (3B2) to light yellow (4A4), (2.8–)4.4(−7.0) μm thick, consisting of very thin (< 0.5 μm) laminae, tightly adherent to and not separating from each other in even vigorously crushed spores (Figures 4B–E). Layer 3 is uniform, smooth, hyaline to yellowish white (3A2), flexible to semi-flexible, (0.8–)1.0(−1.3) μm thick, usually slightly separating from the lower surface of layer 2 in even moderately crushed spores (Figures 4B, D, E), and staining reddish-white (10A2) to pale red (11A3) in Melzer's reagent (Figures 4D, E). Germinal wall 1 consists of one layer that is flexible, hyaline, (0.8–)1.0(−1.3) μm thick, and usually difficult to detect in spores crushed in PVLG; generally, it is well visible in spores crushed in PVLG+Melzer's reagent where it stains reddish-white (10A2) to pale red (12A3) (Figures 4D, E). Germinal wall 2 is composed of three smooth, hyaline layers (germinal wall 2 layers 1–3; Figures 4B–F). Layer 1 coriaceous sensu Walker (1986), (1.0–)2.4(−3.8) μm thick, is always inseparably covering layer 2 (Figures 4D–F), and is sometimes difficult to see in spores crushed in PVLG (Figures 4B, C) because of the lack of contrast with layer 2. Layer 2 is flexible, (1.3–)1.6(−1.8) μm thick in spores crushed in water, always plastic, amorphous sensu Morton (1986), strongly swelling, up to 48.0 μm thick, in spores crushed in lactic acid and PVLG (Figures 4B–F), and staining pastel pink (11A4) to violet brown (11F8) in Melzer's reagent (Figures 4D–F). Layer 3 is flexible, (0.8–)0.9(−1.0) μm thick, loosely associated with the lower surface of layer 2, and often pushed partly or completely out from under this layer in spores vigorously crushed in PVLG and PVLG+Melzer's reagent (Figures 4B–D, F). The sporogenous cell is concolorous or slightly lighter than the spore, usually ovoid, 13.8–59.0 × 18.8–38.4 μm, rarely globose, with a wall composed of two permanent layers that are continuous with spore wall layers 1 and 2; the sporogenous cell wall layer (scwl) 1 is hyaline, 0.8–1.3 μm thick, while scwl 2 is 2.0–3.3 μm thick (Figures 4A, B, G). The germination shields are hyaline, ellipsoidal, 24.6–47.0 × 6.8–38.4 μm, and bi-lobed (Figure 4H); the shields have one germ pore, are 4.0–6.4 μm in diameter, and located in the center of the shield; the shield wall is flexible to semi-flexible and 1.0–1.3 μm thick. The spore contains a hyaline oily substance. Auxiliary cells were not found.

Ecology and distribution: In the field, S. graeca probably lived in arbuscular mycorrhizal symbiosis with roots of A. arenaria, but no molecular analyses were performed to confirm this supposition. GenBank searches, using BLASTn, and our phylogenetic analyses (data not shown) revealed only two sequences, which suggested the presence of AMF identical to S. gracea and S. intraundulata, the latter described below, in other localities. The sequences were GU322902 with 99.28% identity and coverage = 49% from chalk grassland soil in the Netherlands and JX096615 with 96.87% identity and coverage = 87% from Qinghai-Tibet Plateau, China.

Scutellospora intraundulata Błaszk., Niezgoda, B.T. Goto & Magurno, sp. nov.

Figures 5A–H, 6A, B

MycoBank No. MB 851414

Etymology: Latin, intraundulata, referring to the wavy lower surface of the laminate spore wall layer 2 of the species.

Specimens examined: GREECE. Spores from a trap culture inoculated with a field-collected mixture of the rhizosphere soil and root fragments of Ammophila arenaria inhabiting a maritime sand dune site of the beach Voidokoilia (36°57'N 21°39'E), the Peloponnese Peninsula, Greece, September 8, 2015, J. Błaszkowski (holotype slide with spores no. ZTMyc 0067009, isotype slides with spores no. 3933–3950, LPPDSE).

Diagnosis: For differences from S. graeca, the phylogenetic sister species (Figure 3), see the Diagnosis subsection under S. graeca (also, see Discussion for details). It differs from Dentiscutata colliculosa having a laminate spore wall layer with local depressions on its lower surface in (i) the size and color of spores, (ii) the composition of the spore wall and the phenotypic properties of the spore wall layer covering the laminate layer of this wall, (iii) the composition and the phenotypic properties of germinal wall 1, (iv) the features of the germination shield, and (v) the phylogenetic position among other sequenced species producing gigasporoid spores (Goto et al., 2010; also see Discussion for details).

Description: Forming glomerospores (= spores) and auxiliary cells in soil (Figure 5A). Spores are formed singly, terminally, and rarely laterally on bulbous sporogenous cells (Figures 5A, G). The spores are pale yellow (4A3) to golden yellow (5B8); globose; (128–)179(−220) μm in diameter; less often ovoid; 124–220 × 158–250 μm; with a spore wall, two germinal walls, and a germination shield on the upper surface of germinal wall 2 (Figures 5A–H, 6A, B). The spore wall is composed of three permanent layers (spore wall layers 1–3; Figures 5B–D, G, 6A, B). Layer 1, forming the spore surface, is uniform, smooth, semi-rigid, hyaline, (1.0–)1.5(−2.0) μm thick, always tightly adherent to the upper surface of layer 2 (Figures 5B–D, G, 6A, B), and often turning grayish yellow (4B3–B5) in Melzer's reagent (Figures 5B–D). Layer 2 is laminate, smooth on the upper surface, often with slight, local depressions, widely spaced on the lower surface, with the edge of this layer being wavy when observed in a cross view. It is semi-rigid, pale yellow (4A3) to golden yellow (5B8), (8.0–)10.4(−13.0) μm thick in thicker regions, (6.0–)7.9(−10.0) μm thick in thinner regions, consisting of very thin (< 0.5 μm) laminae, tightly adherent to and not separating from each other in even vigorously crushed spores (Figures 5B–D, G, 6A, B). Layer 3 is uniform, smooth, pale yellow (4A3), flexible to semi-flexible, approximately 1.0 μm thick, usually slightly separating from the lower surface of layer 2 in even moderately crushed spores (Figures 5B, C, 6B), staining reddish-white (10A2) to pale red (11A3) in Melzer's (Figures 5B, C, 6B). Germinal wall 1 consists of one layer that is flexible, hyaline, approximately 1.0 μm thick, usually difficult to observe in spores crushed in PVLG, but better visible in spores crushed in PVLG+Melzer's reagent where it stains reddish-white (10A2–12A) in Melzer's (Figures 5B, C, 6B). Germinal wall 2 is composed of three smooth, hyaline layers (germinal wall 2 layers 1–3; Figures 5B, C, E, F, 6A, B). Layer 1 is coriaceous sensu Walker (1986), (1.0–)1.7(−2.3) μm thick, always inseparably covering layer 2, and sometimes difficult to see in spores crushed in PVLG due to the lack of contrast with layer 2 (Figures 5B, C, E, F, 6A, B). Layer 2 is flexible, (1.0–)2.6(−4.3) μm thick in spores crushed in water and PVLG+Melzer's reagent, always plastic, amorphous sensu Morton (1986), strongly swelling (up to 29.0 μm thick) in spores crushed in lactic acid and PVLG (Figures 5B, C, E, F, 6A, B), and staining pastel pink (11A4) to violet brown (11F8) in Melzer's (Figures 5B, C, E, F, 6A, B). Layer 3 is flexible, (1.0–)1.1(−1.3) μm thick, loosely attached to the lower surface of layer 2, and often pushed partly or completely out from under this layer in spores vigorously crushed in PVLG and PVLG+Melzer's reagent (Figures 5B, C, E, F, 6A, B). The sporogenous cell is concolorous or slightly lighter than the spore, usually ovoid, 22.3–33.5 × 24.0–53.5 μm, rarely globose, with a wall composed of two permanent layers continuous with spore wall layers 1 and 2; the sporogenous cell wall layer (scwl) 1 is hyaline, 1.0–1.3 μm thick, scwl2 is pale yellow (4A3) to light yellow (4A4) and 1.5–3.8 μm thick (Figures 5A, E, G). The germination shields are hyaline, ellipsoidal to oblong, 87.8–144.4 × 42.3–79.5 μm, with two lobes of different sizes, one germ pore, 4.0–5.5 μm in diameter, located in the center of the shield or slightly below it, and one germ tube initiation located at the edge of the shield (Figures 5A, H, 6A, B); the shield wall is flexible to semi-flexible and 1.0–1.3 μm thick. The spore contains a hyaline oily substance. The auxiliary cells are hyaline, knobby, 7.5–8.8 × 14.6–16.5 μm, and formed on tips of straight or spirally coiled hyphae; both structures stain reddish-white (9A2) to pale red (9A3) in Melzer's.

Ecology and distribution: In the field, S. intraundulata probably lived in arbuscular mycorrhizal symbiosis with roots of A. arenaria, but no molecular analyses were performed to confirm this supposition. Many attempts at growing this species in single-species cultures with P. lanceolata as the host plant failed. Remarks on the possible occurrence of S. intraundulata in other sites are presented in the “Ecology and distribution” section under S. graeca (see above).

Acaulospora gedanensis Błaszk.

Karstenia 27: 38. 1988.

Figures 7, 8A–H, 9A, B.

MycoBank No. MB 133511.

Etymology: Latin, gedanensis, referring to the Gdańsk Province in which the fungus was originally found.

Specimens examined: POLAND. Chałupy, under Festuca ovina, 23.08.1985, Błaszkowski J., 137 (holotype; DPP), 138–154 (isotypes; DPP); near Władysławowo, under Festuca rubra, July 18, 2022; Błaszkowski J., 3951–3968; Osłonino, among roots of Juncus conglomeratus, 3.04.1989, Błaszkowski J., 1856–1885; Chłapowo, in the root zone of Juniperus communis, 28.09.1988, Błaszkowski J., 1226–1229; Tatra Mountains, under Leucanthemum waldsteinii growing in Dolina Ku Dziurze valley, 1.100 m a.s.l., June–July 2003, and beneath Senecio macrophyllus growing in Szeroki Żleb gully in Chochołowska valley, 1.130 m a.s.l., leg. Zubek Sz., Błaszkowski J., unnumb. coll.

Diagnosis: Differs from (A) A. brasiliensis and A. pustulata, the phylogenetically closest species (Figure 7), in: (i) that the upper surface of spore wall layer 1 of A. gedanensis is usually smooth, rarely ornamented with small outgrowths (vs. always ornamented with relatively larger outgrowths in A. brasiliensis and A. pustulata), (ii) color and size of spores, as well as the morphometric features of the spore and germinal walls and the phenotypic properties of germinal wall 1 (to A. brasiliensis), (iii) the composition and flexibility of germinal wall 1 and the lack of granular ornamentation on the upper surface of germinal wall 2 layer 1 (to A. pustulata), and (iv) nucleotide composition of sequences of the 45S nuc rDNA region (see Discussion for details); (B) A. flavopapillosa and A. tortuosa, producing acaulosporoid spores with spore wall layer 1 ornamented on the upper surface, in (i) spore size, (ii) the morphology of the ornamentation, (iii) the composition and phenotypic properties of germinal walls 1 and 2 (Palenzuela et al., 2013; Corazon-Guivin et al., 2022), and (iv) the phylogenetic position to other sequenced Acaulospora species (Figure 7).

Description: Glomerospores (= spores) are formed singly in soil, laterally, either directly on the neck of a sporiferous saccule (sessile spores) or at the top of a short branch (pedicel) of the neck; the sporiferous saccules are hyaline, globose to subglobose, 60–70 μm in diameter, with a single-layered wall, 0.8–1.0 μm thick, continuous with the neck wall and spore wall layer 1, forming the spore surface; necks 36–60 μm long, tapering from a 17–20 μm diameter at the saccules to a 6–15 μm diameter at the point of spore attachments; the neck's wall is 0.8–1.0 μm thick (Figures 8A–C). Spores have a slightly raised, circular thickening of layer 2 of the spore wall (cicatrix) or a cylindrical to slightly funnel-shaped pedicel, 1.3–10.0 μm long, 5.0–9.4 μm wide, with a wall 1.4–2.0 μm thick, and continuous with spore wall layer 1 when observed in a cross view (Figures 8B, C); the cicatrix and pedicel surround a circular (2.0–3.5 μm in diameter) slight depression in layer 2 of the spore wall when seen in a plan view (Figure 8D). The sporiferous saccules usually collapse or fall off in mature spores. The spores are pale yellow (3A3) to lemon yellow (3B8), globose to subglobose, (55–)65(−75) μm in diameter, with a spore wall and two germinal walls (Figures 8A–H, 9A, B). The spore wall has three layers (spore wall layers 1–3; Figures 8E, G, H, 9A, B). Layer 1 is semi-permanent, rarely strongly deteriorated or completely sloughed off, hyaline, and (0.8–)1.3(−1.6) μm thick; the upper surface of this layer usually is smooth when intact or slightly roughened when deteriorated, rarely covered with blister-like outgrowths, 1.2–2.8 μm high and 1.8–7.6 μm wide when seen in cross and plan views, respectively (Figures 8C, E, G, H, 9A, B); in a plan view, the outgrowths are circular to ellipsoidal and more or less uniformly distributed (Figure 8F). Layer 2 is permanent, laminate, smooth, semi-rigid, pale yellow (3A3) to lemon yellow (3B8), and (2.2–)3.6(−4.3) μm thick (Figures 8C, E, G, H, 9A, B). Layer 3 is uniform, smooth, flexible to semi-flexible, concolorous with layer 2, 0.8–1.0 μm thick, and rarely separating from the lower surface of layer 2 in even vigorously crushed spores; therefore, it is usually difficult to detect (Figures 8G, H, 9A). The germinal wall 1 has one rigid, fragile, hyaline, 0.3–0.5 μm thick layer, often breaking in even moderately crushed spores (Figures 8E, G, H, 9A, B). Germinal wall 2 consists of two flexible to semi-flexible, smooth, hyaline layers (germinal wall 2 layers 1 and 2), 1.0–1.8 μm thick and 0.8–1.3 μm thick, respectively, always easily separating from one another in crushed spores (Figures 8E, G, H, 9A, B). None of the layers of the spore wall and germinal walls stain in Melzer's reagent (Figures 8B–E, G, H). A germination orb was not found, and germination is unknown.

Ecology and distribution: Associated in the field with vesicular-arbuscular mycorrhizal roots of Festuca ovina, Helictotrichon pubescens, Juncus conglomeratus, Juniperus communis, Rosa rugosa (Błaszkowski, 1988, 1993a,b, 1994), Leucanthemum waldsteinii, Thymus pulcherrimus (Zubek et al., 2008), Senecio macrophyllus (Zubek, pers. comm.), and F. rubra (this study). All attempts to establish this species in one-species cultures with P. lanceolata as the host plant failed. It occurred in maritime sand dunes near Chałupy on the Hel Peninsula, a forest near Żelistrzewo, a wet meadow in Osłonino, an uncultivated meadow located approximately 100 m from the Baltic Sea in Chłapowo (all sites located in Pomeranian voivodeship; Błaszkowski, 1988, 1993a,b, 1994), and in Tatra Mountains (Zubek et al., 2008). Apart from Poland, it was found only in Austria (Błaszkowski, pers. observ.) and Brazil (Lugo et al., 2023). Bayesian inference and ML analyses of sequences deposited in GenBank showed that no sequence with >96% identity to the A. gedanensis 45S sequences clustered with this species (data not shown).