During the Last Glacial Maximum (LGM), drastic environmental changes modified the topology of the Japanese Archipelago, impacting species distributions. An example is Fagus crenata, which has a present continuous distribution throughout Japan. However, by the end of the LGM it was restricted to southern refugia. Similarly, Dasyscyphella longistipitata (Leotiomycetes, Helotiales, Lachnaceae) occurs strictly on cupules of F. crenata, sharing currently an identical distribution. As the effects of the LGM remain poorly understood for saprobiotic microfungal species, herein we identified past structuring forces that shaped the current genetic diversity within D. longistipitata in relation to its host using a phylogeographic approach. We inferred present and past potential distributions through species distribution modeling, identifying environmental suitability areas in mid-southern Japan from which subsequent colonizations occurred. Our findings suggest that current high genetic diversity and lack of genetic structure within D. longistipitata are the result of recent multiple re-colonization events after the LGM.

Divergence, gene flow, geographic information systems, haplotype network, host distribution, intraspecific variation, species distribution modeling

Dramatic cyclical glacial advances and retreats characterize the Pleistocene (Bradley 1999). During this epoch the Japanese archipelago underwent important climate changes accompanied by the alternation of dry and wet conditions. Furthermore, by the end of the Pleistocene, during the Last Glacial Maximum (LGM), the advent of a strong cold dry period led to a significant sea level lowering that exposed the entire Seto Sea area (Tsukada 1983). Subsequently, during the Pleistocene-Holocene transition, a rapid warming trend led to an increment of sea level, transforming what had been a long appendage of the Asian continent into an entirely separated archipelago (Aikens and Akazawa 1996).

Strong evidence suggests that, during the LGM, Japan was extensively covered by coniferous forests of Pinus, Picea, Abies, and Tsuga. Small populations of Fagus, however, were limited to the Pacific coasts of Kyushu and Shikoku (Tsukada 1985). Pleistocene climate and geospatial changes modified the distribution of biomes in this region (Gotanda and Yasuda 2008), causing major migrations and extinctions (Kawamura 2007), and rearranging the geographic distribution of vegetation assemblages (Tsukada 1982b, c 1983).

The Japanese endemic canopy tree Fagus crenata has been extensively studied in this sense, representing an acknowledged model. Independent lines of evidence suggest that by the end of the LMG, the populations of F. crenata were restricted to environmentally stable southern areas (refugia) along the shoreline in southern areas of Japan, and then expanded northwards via two migration routes through the western and eastern shore of Japan (Tsukada 1982a; Tsukada 1982b; Tomaru et al. 1997, 1998; Koike et al. 1998; Fujii et al. 2002; Okaura and Harada 2002). Presently, F. crenata is widely distributed from the northern regions in Oshima Peninsula, Hokkaido to southern areas in the Osumi Peninsula, Kyushu, where it occurs sparsely in mountainous regions.

Although the LGM has long been a focal point for research in a wide range of plant and animal taxa, information on the microbial component remains lacking. Fungal phylogeographic analyses are recently increasing (e.g., to identify glacial refugia, re-colonization routes, and interglacial population expansions; Marske et al. 2009, Geml et al. 2010, Leavitt et al. 2013), yet the numbers are still limited (Lumbsch et al. 2008). Several methodological reasons may explain this, including limited taxon sampling, impediments in identification (because of the existence of close relatives with similar morphologies), difficulties in obtaining DNA material (in the case of unculturable symbionts, e.g., Hongoh 2011) and genetically heterogeneous nuclei (such as in some Basidiomycota members e.g. Booth 2014). So, in this sense, culturable and clearly delimited fungal species with wide distribution ranges represent advantageous phylogeographic study models.

Dasyscyphella longistipitata Hosoya (Leotiomycetes, Helotiales, Lachnaceae) overcomes the above-mentioned impediments. This culturable ascomycete is highly specific to F. crenata, sharing an identical wide geographical distribution throughout Japan (Ono and Hosoya 2001, Hosoya et al. 2010), and so far only known from Japan. Previous ITS-based phylogeographic analyses revealed that D. longistipitata forms a genetic continuum comprising three kindred clusters dominated by a single haplotype (named as H12 in Hosoya et al. 2010), which may suggest a recent population expansion (Bandelt et al. 1995; Ferreri et al. 2011). However, the small population numbers, uneven sampling, and a single genetic marker-based analysis hampered the interpretation of the results, leaving unanswered questions as to whether this species occupied the same refugia as its host during the LGM.

In this study, we reconstructed the historical demography of D. longistipitata based on genetic variation data, in addition to information on the geographical distribution and ecological attributes for D. longistipitata as well as for its host F. crenata. The correspondence between both species in their response to major past climate changes was assessed in order to attain a better understanding of the impacts of glacial cycling on the Japanese biota and neglected fungal taxa.

Saprophytic fungi (those obtaining nutrients from dead organic matter) are critical to the dynamics and resilience of ecosystems (Meyer 1994). However, there is tremendous specificity with regard to the types of chemical structure that individual species are capable of degrading (Rodriguez and Redman 1997). To date, the fungal species D. longistipitata has been exclusively reported from F. crenata cupules, sharing an identical geographical distribution (Hosoya et al. 2010; Ono and Hosoya 2001). Field efforts to obtain material from the co-distributed species Fagus japonica as an alternative host (Fang and Lechowicz 2006) have been unsuccessful. In addition to the well-known host specificity in many species of Lachnaceae (e.g., Tochihara and Hosoya 2019), overall this provides further evidence of the strong ecological relationship between D. longistipitata and F. crenata.

One of the most remarkable results of this study was the unexpected high genetic diversity in D. longistipitata (pi = 0.0094; Table 1, Fig. 4). Few population level genetic analyses are available for non-model fungal species, with most of the literature focusing on species of public interest such as phytopathogens (Bennett et al. 2019), human pathogens (Cogliati et al. 2019), insect pathogens (Tsui et al. 2019), and mycorrhiza (Savary et al. 2018). As a result, comparisons are difficult to obtain. Anyhow, the nucleotide diversity estimates for the concatenated ITS and beta-tubulin sequences of D. longistipitata were higher in relation to assorted pathogenic Ascomycota including C. scovillei, A. fumigatus, and C. montium (pi = 0.0027, 0.0003, and 0.0041, respectively). Considering that demographic history represents a determinant of genetic diversity, governing effective population size (Ellegren and Galtier 2016), the observed high genetic diversity within D. longistipitata may be related to a large effective population size accompanied by a distribution range expansion, resembling what has been reported for its host.

The estimated nucleotide diversity in D. longistipitata was lower compared to C. purpurea (pi = 0.0101), which is reasonable, as C. purpurea comprises three divergent lineages (Douhan et al. 2008). In this context, our results confirmed that D. longistipitata represents a well-defined taxonomic entity, useful as a model for phylogeographic studies. This statement is also supported by the ITS-based average genetic divergence (0.99%), agreeing with the canonical 1–3% (−5% Schmidt et al. 2013) threshold for intraspecific variation in fungi (Kõljalg et al. 2013), and specifically 1.96 % SD 3.73 for Ascomycota (Nilsson et al. 2008). Besides, our results did not detect genetic clustering (Fig. 3a), confirming this species forms a single and widely distributed genetic assemblage across Japan (Hosoya et al. 2010).

Several factors influence the genetic structure in fungal populations, due in part to the diverse ecological roles of these osmotrophs. For instance, Prospero et al. (2008) reported high overall F_ST = 0.43 in populations of the pathogenic fungus Armillaria ostoyae (Romagn.) Herink throughout ~200 km. In this case, biological traits such as host infection ability and reproductive cycle shaped the genetic structure. Furthermore, Barrès et al. (2008) described low but significant genetic structure in Melampsora populnea (Pers.) P. Karst. within continental populations in a similar geographic range to the present study. The authors noted positive isolation by distance associated with dispersal constraints, and host preference. In contrast, Velez et al. (2016) described the lack of large-scale geographic structure among populations of the cosmopolitan marine species Corollospora maritima Werderm., perhaps as a result of high dispersal potential, or meteorological phenomena like hurricanes.

Even though the sampled localities are distributed across a broad geographic range covering ~1700 km, our genetic structure estimates were practically negligible (Fig. 2, and Suppl. material 3: Table S2). In addition, the lack of correlation between haplotypes relationships and the spatial distribution (Fig. 4), as well as the absence of isolation-by-distance patterns suggest that the lack of structure in D. longistipitata is a consequence of the homogeneous distribution of the genetic diversity, instead of a similar genetic composition among localities. Even though dispersion mechanisms remain unknown for D. longistipitata, based on its host specificity and field observations, its occurrence as an endophyte is feasible. Under this assumption, a joint seed-vectored dispersion may be possible, opening the opportunity for a broader animal-mediated dispersal (Magyar et al. 2016). This would agree with former reports for the host F. crenata (Akashi 1997), and rapid dispersion rates (~100 m/yr) in Fagus species under climate change scenario to cope with environmental stress (McLachlan et al. 2005). However, greenhouse experimental and field evidence is required to support this hypothesis.

According to the negative values of the neutrality tests and the star-shaped connections in the haplotype network, the Bayesian Skyride plots revealed that both D. longistipitata and F. crenata underwent important recent demographic growth events. However, the effective-size of D. longistipitata was several orders of magnitude larger than F. crenata. For instance, assuming a fixed mutation rate of 1×10^-10 for both species, we would expect a current effective-size of ~36×10^9 for D. longistipitata, and 35,000 for F. crenata. Moreover, considering a generation time of 10 years for F. crenata along with a mutation rate range of 1×10^-11 to 1×10^-12 per site/year (which is feasible for the matk gene given the reported mutation rate and the slow evolution rates reported for Fagaceae family; Frascaria et al. 1993; Lavin et al. 2005; Barthet and Hilu 2007), the beginning of the demographic growth is estimated for 570 to 5,700 ya; hence stable population size for F. crenata would be dated within 2,700 to 27,000 ya. Nevertheless, approximating the time of demographic growth for D. longistipitata is problematic.

Aside from the lack of mutation rates for the genetic markers, and precise reports on the number of reproductive events per year (i.e., the generation time), our rough calculations on the estimates for population growth agree with the hypothesis of post-glacial demographic expansion. Furthermore, the demographic increase trend in D. longistipitata may be related to a higher mutation rate and shorter generation times. So, growth trends for D. longistipitata in the Skyride plots could correspond to a fraction of the time scale in F. crenata. In this sense, the mast seeding (large, synchronic seed production) in F. crenata (Hiroki and Matsubara 1995), could promote a rapid demographic growth, and high effective size in D. longistipitata.

The SDM analyses revealed several restricted areas of climatic stability distributed in mid-southern Japan (Fig. 6). This suggests that D. longistipitata and F. crenata populations might have had a limited distribution range due to unfavorable past climate conditions in the Pleistocene-Holocene transition, followed by an expansion driven by climatic suitability. According to this hypothesis, the SPREAD3 analysis mapped the origin of dispersion for D. longistipitata and F. crenata around the predicted areas of climatic suitability in mid-southern Japan (Figs 6, 7), in accordance to former work on chloroplast data of F. crenata (Fujii et al. 2002). The statement is also supported by occurrence of the most abundant haplotype (H12B4) in Tsukuba (Site 7), Suganuma (Site 6), and Mt. Atema (Site 4), located in mid Japan among 36.2 to 37.0 N in latitude. However, consecutive dispersion patterns showed slight discrepancies between both species (Fig. 7, Times 2 and 3). This may be attributed to 1) sampling bias or 2) fungal environmental/physiological constraints during ascomata development (e.g., humidity and temperature) as previously suggested (Carré 1964; Fukasawa 2012).

Modifications in species distribution ranges result from the interaction between ecological and evolutionary processes (Sexton et al. 2009). Our data suggest that drastic past environmental changes marked the genetic diversity within populations of D. longistipitata, as exhibited by the magnitude and distribution of the genetic diversity, and historical effective population size fluctuations. Overall, these findings agree with previous reports on the close ecological relationship between the fungus and F. crenata (which share an ecological background during Pleistocene-Holocene transition), and the influence of past environmental changes on suitable areas for its distribution.

Dasyscyphella longistipitata has been recognized as a fine woody debris decomposer, in particular of cupule litter, an essential component of litterfall in beech forests (Fukasawa et al. 2012). Hence it potentially plays an important role in nutrients cycling and the resilience of the ecosystem. We provide genetic diversity evidence at the population level for this saprophytic fungal species, which is relevant for the conservation and management of forests. Moreover, we confirmed the validity of using host (substrate) data to formulate phylogeographic hypothesis for substrate-specific organisms, which represents an interesting model to explore symbiont relationships under past and future climatic scenarios.

This project was funded by Grant-in-Aid for scientific research (C) 17570088. We thank Dr. A. Yabe for his valuable discussion about past distribution of Fagus crenata in Japan. We also appreciate sampling assistance by Kazuaki Tanaka, Harue Abe, Makoto Hashiya, Etsuko Kurokawa, Kentaro Hosaka, Takashi Shirouzu, Hideji Ushijima, Konomi Yanaga, Yoko Kimura, Daisuke Sakuma, Tomio Okino, Miyuki Kobayashi. This paper was written during a research stay of PV at the National Museum of Nature and Science, Tsukuba, with support of FY2018 JSPS Invitational Fellowship for Research in Japan (ID No. S18062). We acknowledge anonymous reviewers for constructive comments on earlier versions of the manuscript.