The fungal rat race: mycophagy among rodent communities in eastern Australia
Todd F. Elliott A * , Kelsey Elliott B and Karl Vernes AA Ecosystem Management, School of Environmental and Rural Science, University of New England, Armidale, NSW 2351, Australia.
B Integrative Studies Department, Warren Wilson College, Swannanoa, NC 28778, USA.
Wildlife Research 50(7) 526-536 https://doi.org/10.1071/WR22062
Submitted: 28 March 2022 Accepted: 3 July 2022 Published: 26 July 2022
© 2023 The Author(s) (or their employer(s)). Published by CSIRO Publishing. This is an open access article distributed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND)
Abstract
Context: Rodents in many parts of the world perform an important ecosystem function as dispersers of mycorrhizal fungal spores. These fungi are vital to nutrient uptake in plant communities, but many of the fungal taxa that form these associations have fruiting bodies that are reliant on animals for their spore dispersal.
Aims: Numerous studies have focused on the ecological importance of Australian marsupials (especially members of the Potoroidae) for the dispersal of these ecologically important fungi. We chose to focus this study on the role of murid rodents in the dispersal of these fungi in eastern Australia.
Methods: To compare fungal taxa in murid diets, we trapped rodents in three regions of eastern Australia; our study sites spanned over 2000 km from temperate eucalypt forests to tropical eucalypt and tropical rainforest habitats. We performed microanalysis on all scats to determine whether fungi were consumed and which taxa were being eaten. Statistical analysis was conducted to investigate trends in levels of mycophagy among species and habitats.
Key results: We examined 10 rodent species, and all were shown to ingest mycorrhizal fungi to varying degrees. The diversity, abundance and specific fungal taxa consumed varied depending on the site and forest type. In drier forests dominated by Eucalyptus spp., the fungal taxa consumed and dispersed were primarily ectomycorrhizal; in wetter rainforest habitats, the fungal diversity consumed was far lower and included primarily vesicular arbuscular fungi. We provide the first evidence of mycophagy by grassland melomys (Melomys burtoni) and Cape York melomys (Melomys capensis).
Conclusions: Our findings highlight the importance of rodents as dispersers of mycorrhizal fungi across a variety of habitats from temperate to tropical forests of eastern Australia.
Implications: This study increases the existing knowledge of rodent diets and habitat requirements. It also provides a new angle for mammal conservation efforts, given the vital nature of the ecosystem service provided by these small and frequently overlooked mammals.
Keywords: hypogeous fungi, mammal diets, mammal ecology, Melomys, mycorrhizae, Pseudomys oralis, Rattus, spore dispersal, Uromys, Zyzomys argurus.
Introduction
A wide array of vertebrates, including mammals, birds and reptiles, consume fungi and disperse fungal spores through their scats (Fogel and Trappe 1978; Claridge and May 1994; Nuske et al. 2017a; Elliott et al. 2019a, 2019b, 2022; Caiafa et al. 2021). Animal-facilitated fungal dispersal directly affects many aspects of ecosystems around the world in a variety of ways, including plant nutrient uptake, fungal community structure, selection of fungal fruiting morphologies, soil bioturbation, soil microbial community composition and overall nutrient cycling (Cázares and Trappe 1994; Johnson 1996; Maser et al. 2008; Elliott and Marshall 2016; Dundas et al. 2018; Valentine et al. 2018; Miranda et al. 2019; Nuske et al. 2019; Vašutová et al. 2019; Elliott et al. 2022). Many animals are capable of contributing to some or all of these ecosystem functions; however, certain groups are more ubiquitous and play a more significant role. Rodents are one such group. With 2590 species (Hamilton and Leslie 2021), rodents are the most diverse and widespread order of mammals, and many of these species consume fungi. Rodents generally pass spores through their digestive systems quicker than do larger mammals and often have smaller home ranges/movement patterns (Danks 2012; Danks et al. 2020; Elliott et al. 2020). However, given their incredible abundance and adaptability to populate a multitude of habitats (Wilson et al. 2017), rodents have been found to be important fungal dispersers in most terrestrial ecosystems that have been studied (Elliott et al. 2022).
As a result of human modifications of ecosystems, many rodent species, particularly in Australia, have experienced population declines or extinctions (Smith and Quin 1996; Firth et al. 2010; Cove et al. 2017; Waller et al. 2017; Roycroft et al. 2021; Vernes et al. 2021). In some cases, introduced rodents have been shown to perform some of the fungal dispersal ecosystem services that were once provided by lost species (Vernes and McGrath 2009). In most systems, the full ecological effect of a loss in rodent diversity is not known in relation to its impacts on fungal dispersal. The significance of rodents as important fungal spore dispersers is gradually becoming more widely recognised, but it still remains incompletely studied. A recent global review indicated that more than 220 rodent species incorporate fungi into their diet (Elliott et al. 2022). Despite their ecological significance, threatened or extinct rodents rarely generate the same conservation attention as do larger, more charismatic animals.
Rodents eat many types of fungi, but sequestrate species are a particularly important food source for them (Fogel and Trappe 1978; Maser et al. 2008; Elliott et al. 2020; Stephens and Rowe 2020; Stephens et al. 2020; Elliott and Vernes 2021). Sequestrate fungi produce fruiting bodies that are enclosed in a skin (called a peridium), and they often fruit below ground. Unlike non-sequestrate fungi, it is usually impossible for sequestrate taxa to forcibly discharge their spores into air currents (Thiers 1984). At maturity, these fungi usually produce strong aromas that enable their detection by rodents and other animals (Stephens et al. 2020). After eating the fruiting bodies, these mycophagists subsequently disperse viable fungal spores through their scats (Vašutová et al. 2019; Elliott et al. 2022). Most sequestrate fungi also form mycorrhizal associations with plants and are essential to plant nutrient uptake (Tedersoo et al. 2010). Through these associations, mycophagous rodents are contributing to the health and diversity of fungal communities, the nutrient uptake of numerous plant species and the future food supplies of other vertebrates and invertebrates that also eat the fungi they are dispersing.
In Australia, much of the focus on these ecological associations has been directed towards mycophagous marsupials (Nuske et al. 2017a); however, this study focuses on the importance of ecosystem services provided by rodents. We investigate the levels of mycophagy across three disjunct rodent communities and measure differences among species, geographic region and habitat type. We also provide the first evidence of fungal consumption among two additional species of rodents.
Materials and methods
We selected study sites that had experienced low levels of recent disturbance, particularly in relation to land clearing. We also chose locations with relatively intact mammal communities that shared similar physiographic features despite the relatively large geographic distances between them.
At all trapping sites, we used a combination of Elliott and cage traps and followed standard live-trapping protocols approved by the University of New England Animal Ethics Committee (see AEC18-065, AEC09-129 and AEC12-114). Traps were set in the late afternoon and baited with peanut butter and vanilla paste that was either mixed with rolled oats or spread on bread. Traps were left overnight, after which we began checking for captures just before daylight the following morning. Any animals in traps were transferred to clean cloth bags to be examined, identified, weighed and sexed. To ensure identification of re-captures, we clipped a small patch of fur off the flank of each animal so that we would be able to determine whether we caught that individual in the future. The animal was photographed (Fig. 1) and then released. Scats were collected from within the trap and either placed in 70% alcohol or a paper envelope. Traps were cleaned after each capture to ensure that there was no contamination between captures. We had a total of 5181 trap-nights during this study.
Our southern-most site was on the New England Tablelands of north-eastern New South Wales, near Mount Hyland Nature Reserve (Fig. 2). Traps were at two sites, one within a 1 km radius of the central GPS point of 30°10′09″S, 152°28′13″E and the other within 800 m of 30°12′42″S, 152°26′05″E. Trapping at sites in New South Wales was conducted in June, August and November of 2009, April 2010 and February 2012 and between July and August 2019. During the 2009–12 trapping season in New South Wales, there was a total of 3450 trap-nights using Elliott Type A traps; in 2019, there were 820 trap-nights using Elliott Type A traps, 112 trap-nights using Elliott Type B traps and 10 trap-nights using cage traps. Combining all trap types during both trapping seasons, we had a total of 4392 trap nights in north-eastern New South Wales.
Two study sites were selected on the Atherton Tablelands of tropical Queensland (Fig. 2). The first site was located in Dinden National Park, and the second ran between Dinden and Davies Creek national parks. Traps were set at the first site along transects within 1.5 km of 17°06′42″S, 145°37′12″E and at the second site along transects within 2.5 km of 17°00′54″S, 145°34′59″E. Trapping at these sites was conducted in early August 2020. We used a combination of Elliott A traps and cage traps. At the first site, there were 100 trap-nights using Elliott A traps and 27 trap-nights using cage traps; at the second site, there were 136 trap-nights using Elliott A traps and 69 trap-nights using cage traps. We had a total of 332 trap-nights across both sites on the Atherton Tablelands.
The third and most northern site was within Kutini-Payamu (Iron Range) National Park on the northern end of the Cape York Peninsula (Fig. 2). Traps were set along transects within a 2.5 km radius of the central GPS point 12°42′49″S, 143°17′15″E. Trapping at this site was conducted in late August 2020. There were 350 trap-nights with Elliott A traps and 107 trap-nights with cage traps. We had a total of 457 trap-nights on Cape York.
Scat samples were collected from each individual (multiple pellets were collected whenever possible and then mixed to ensure accurate representation). Samples were either permanent-mounted or wet-mounted on glass slides and analysed at ×400 magnification to determine presence and species richness of fungal spores. To avoid reporting incidental consumption of spores that happened to be in the environment, only spores found to occur frequently (a minimum of five times) in each sample were considered, and these were identified on the basis of recognition of standard microscopic characters. Any ambiguous identities were confirmed through comparison with spores of identified fungal fruiting body collections made by the authors in the same or similar habitats. Given the large geographic range and the number of fungi in the region that remain undescribed, we did not attempt to refine the fungal identification beyond family or genus level. We would also prefer to underestimate, rather than overestimate, the significance of these animals as dispersers. Because we were focused on the diversity of fungi consumed by the rodents, we use some older nomenclatural concepts that help outline the diversity of taxa. For example, we mention the genera Thaxterogaster and Quadrispora. Taxonomic studies have shown that members of these historically sequestrate genera belong in Cortinarius (Gasparini 2014; Pastor et al. 2019; Nouhra et al. 2021). We agree with these taxonomic revisions, but in the context of this study, we mention these names in reference to spores that are members of the Cortinariaceae but have characters indicating that they are likely to belong to sequestrate taxa. The taxa that we list as Cortinarius could also be sequestrate, but we have no evidence to indicate their fruiting habits.
All analyses were performed in R ver. 4.0.3 (R Core Team 2020). Sites were designated as being either tropical (Atherton Tablelands and Kutini-Payamu) or temperate (New England Tablelands), and forest type was classed as either wet sclerophyll or rainforest. However, because forest type and latitude are interlinked, we combined these into a single factor (‘habitat’) that described both the forest type and its latitudinal position. For samples containing fungus, ANOVAs using the ‘lmer’ function in the packages lme4 and lmerTest were used to compare taxon richness per sample among rodent species and habitat (tropical wet sclerophyll forest, temperature wet sclerophyll forest and tropical rainforest). Season (summer, autumn, winter and spring, with each equinox/solstice marking seasonal cut-points) and year of collection were random effects in the model. Post hoc contrasts (Tukey) were performed using the package emmeans.
Multivariate analyses available in the package vegan (Oksanen et al. 2020) were used to explore trends in consumption of each individual fungal taxon among species, habitats and seasons. We first used the ‘outlier’ function to identify extreme outliers on the basis of nearest neighbour criterion (Wildi 2017); no outliers were identified. We then constructed a Bray–Curtis similarity matrix using presence–absence values for each of the 194 samples that contained fungi (rows) and the 29 taxa that occurred in the samples (columns) and applied non-metric multidimensional scaling (NMDS) to visualise and interpret these data. The NMDS was calculated using the function ‘metaMDS’ in the package vegan (Oksanen et al. 2020) within R (R Core Team 2020), using the Bray–Curtis dissimilarity matrix with weighted averages and a maximum number of 50 random starts. The function ‘envfit’ was then used to fit factors (species, season and habitat) to the ordination using 10 000 permutations, which showed associations between clusters of points and each factor. Data were plotted using the function ‘ordellipse’ that created ellipses encompassing the standard deviation of points coded by species, season and habitat, and ‘ordspider’ that overlaid a ‘spider’ diagram connecting each point to its group centroid (Oksanen et al. 2020).
To further visualise the differences in diet among species and habitats, we compiled a matrix of the percentage occurrence of fungal taxa in each mammal species × habitat combination, and then analysed these data by using hierarchical cluster based on Ward’s minimum-variance method on a distance matrix computed using Euclidean distances. We used only winter (June–August) samples for this analysis, because winter captures contained the greatest diversity of fungus, and tropical sites were sampled only in winter. The results of the cluster analysis were displayed as an unrooted tree by using the function ‘as.phylo’ within the package ‘Ape’.
Results
Patterns in dietary diversity
Across all sites, we had a total of 253 rodent captures, representing 10 rodent species. At sites in northern New South Wales, we trapped fawn-footed melomys (Melomys cervinipes), bush rat (Rattus fuscipes), swamp rat (Rattus lutreolus) and Hastings River mouse (Pseudomys oralis). At the Atherton Tableland sites, we trapped fawn-footed melomys, house mouse (Mus musculus), bush rat, giant white-tailed rat (Uromys caudimaculatus) and common rock rat (Zyzomys argurus). At the sites in Kutini-Payamu, we trapped grassland melomys (Melomys burtoni), Cape York melomys (Melomys capensis), Cape York rat (Rattus leucopus) and giant white-tailed rat.
All species trapped in this study consumed fungi to varying degrees. We identified a total of 38 distinct spore types (taxa) across the sites (Table 1). Fungi were found to be an important dietary component; however, the levels of mycophagy and the taxa consumed depended on a combination of species of rodents and the habitat they occupied. Taxon richness per sample varied significantly with species (F8,176 = 8.7, P < 0.005) and habitat (F2,156 = 29.4, P < 0.0001). Species differences were driven by bush rats consuming significantly more fungal taxa than fawn-footed melomys (P < 0.0001), Hastings River mice (P = 0.002), swamp rats (P = 0.02) and common rock rats (P = 0.005), and rock rats consuming significantly more taxa than giant white-tailed rats (P = 0.007). Samples from rodents inhabiting tropical rainforest sites also contained fewer fungi than those from either tropical wet sclerophyll forest or temperate wet sclerophyll forest (P < 0.0001), and what fungi they did eat were predominately Glomeromycota. When members of the Glomeromycota were present in scats, they were usually in large numbers, which led us to believe that this represented deliberate consumption of this group. There was no significant difference in the number of fungal taxa per sample from rodents inhabiting either tropical or temperate wet sclerophyll forest (P = 0.43), and at these sites, ectomycorrhizal fungi were the most common fungi in rodent diets. The majority of fungal taxa consumed belong to groups that form sequestrate and/or hypogeous fruiting morphologies.
Non-metric multidimensional scaling (2D stress = 0.11) showed significant differences in dietary composition among the different species of rodents (r2 = 0.28; P < 0.001; Fig. 3a), but the strongest differences were with season (r2 = 0.42; P < 0.001; Fig. 3b), driven by winter diets being distinct from diets in other seasons (Fig. 3b), and habitat (r2 = 0.33; P < 0.001; Fig. 3c), where there were clear differences among diets in the three habitat types (Fig. 3c).
Cluster analysis (which included only winter diets) identified several distinct clusters primarily on the basis of a combination of species and habitat (Fig. 4). The diet of bush rats, irrespective of habitat, clustered with temperate wet sclerophyll diets of Hastings River mice and fawn-footed melomys. Tropical wet sclerophyll diets and tropical rainforest diets formed largely distinct clusters, with the exception of Cape York melomys from rainforest clustering with tropical sclerophyll diets of other rodents.
Mycophagy by other mammals
In the process of conducting fieldwork, we also sampled seven additional mammals (all marsupials) as a result of accidental captures or finding roadkill. At the site in New South Wales, we sampled three brown antechinus (Antechinus stuartii; one individual consumed fungi), one long-nosed bandicoot (Perameles nasuta; consumed fungi), one red-legged pademelon (Thylogale stigmatica; consumed fungi) and one mountain brushtail possum (Trichosurus cunninghami; did not consume fungi). In northern Queensland, we sampled five northern bettongs (Bettongia tropica; all consumed fungi) and eight northern brown bandicoots (Isoodon macrourus; five consumed fungi). At the site on Cape York, we sampled one northern brown bandicoot (I. macrourus; consumed fungi) and one red-cheeked dunnart (Sminthopsis virginiae; did not consume fungi). We mention these incidental observations because they add to knowledge about mycophagy among Australian mammals and show that marsupials, alongside rodents, are mycophagists in these systems. Multiple previous studies have been conducted to investigate and/or review mycophagy among many of these taxa (e.g. Claridge and May 1994; Reddell et al. 1997; Vernes et al. 2015; Nuske et al. 2017a, 2017b; Elliott et al. 2022).
Discussion
Our study is the most comprehensive study to date of fungal consumption by rodents in Australia, both in terms of the number of rodent taxa studied and the geographical breadth covered by our sampling. The results showed that rodents are dispersing a great diversity of fungal spores in both tropical and temperate forest communities in eastern Australia, and that many different species of rodents are consumers of sequestrate fungi. For two of these, the grassland melomys and Cape York melomys, our work is the first to demonstrate fungal consumption. Some species such as the bush rat and fawn-footed melomys are widespread, and occurred at both our tropical and temperate study sites, in both wet sclerophyll forest and rainforest. These rodents demonstrated that fungi are eaten from temperate regions through to the tropics, but that consumption was strongly influenced by habitat type, with eucalpyt-dominated forest returning much greater dietary richness of fungi than tropical rainforest.
Our study provided a snapshot of fungal consumption during the height of the 2019 and 2020 fruiting season. Fungal consumption by mammals in eastern Australia has been shown by multiple studies to vary among seasons, and to peak in winter (Taylor 1992; Vernes et al. 2001, 2015; Vernes 2014; Elliott et al. 2020). Cluster analysis of winter samples demonstrated a strong clustering of murid species on the basis of the habitat type from which they came, with clusters being most closely tied to forest type, rather than species, or geographical location (i.e. temperate or tropical). However, there were some exceptions. Bush rats from tropical rainforest, tropical wet sclerophyll forest, and temperate wet sclerophyll forest clustered with other rodents from temperate wet sclerophyll forest, whereas the Cape York melomys (M. capensis) from tropical rainforest clustered with other rodents from tropical wet sclerophyll forest. These results indicated two things. First, bush rats are well known mycophagists, with several studies showing that they are probably among the most mycophagous of Australian rodents (Vernes and Dunn 2009; Nuske et al. 2017b). Because of the great diversity of taxa in their diet irrespective of habitat type, they clustered with rodents from the forest type that also collectively returned the greatest fungal diversity. Second, this observation is likely to indicate that both R. fuscipes and M. capensis had a relatively higher fungal consumption than did other rainforest rodents, and probably indicates that they foraged more widely than the other rainforest species, extending their movements into adjacent sclerophyll forest dominated by ectomycorrhizal taxa. Vernes and Dunn (2009) showed that in north-eastern New South Wales, R. fuscipes moved across rainforest boundaries and was spreading fungal spores through its mycophagous feeding habits.
Although difficult to prove within the context of this study, seasonal changes in fungal consumption are likely to be a reflection of food availability rather than preference. For example, the mammal community in Kutini-Payamu was the least mycophagous within our study. These differences could be due to seasonality, but we suspect that habitat is likely to be a more significant factor. We believe this in part because a long-term study of the long-nosed echymipera (Echymipera rufescens) in Kutini-Payamu (Shevill 1999; Shevill and Johnson 2007) showed that fungal consumption by this species tended to peak in September.
There is substantial experimental data indicating that mycorrhizal fungal spores survive transit through the digestive system of various Australian murid rodents (McGee and Baczocha 1994; Reddell et al. 1997), as well as rodents in other regions of the world (Trappe and Maser 1976; Colgan and Claridge 2002; Caldwell et al. 2005; Ori et al. 2018; Elliott et al. 2022). We found no evidence in the literature that the digestive system of rodents or any other mammal prevents the germination of fungal spores. On the basis of our microscopic analysis of spores, we saw no evidence of spore degradation that would negatively affect spore germination rates. Three of the species we include in this study, fawn-footed melomys, bush rat and giant white-tailed rat, have been experimentally shown to pass viable mycorrhizal spores (Reddell et al. 1997) and it is highly likely that the other seven species share this ability.
The movement pattern and passage rate of an animal directly affect its spore dispersal potential. These factors inevitably vary among individuals and species, but larger mammals generally have greater movement patterns, larger home ranges and slower passage rates compared with smaller mammals (Swihart et al. 1988; Danks 2012). The giant white-tailed rat (U. caudimaculatus) was the largest species in our study; although we are unaware of any detailed studies examining the size of its home range, Wellesley-Whitehouse (1983) reported that an individual travelled 500 m overnight between trap sites. Further study of more individuals in more areas will likely show a greater range in movement patterns. The mean retention time of fungal spores for this species is 48.4 h, and some spores linger as long as 120 h in the digestive system (Comport and Hume 1998). Giant white-tailed rats have the potential to disperse fungal spores at least 500 m in a night, and depending on maximum retention times and movement patterns, they could likely disperse spores much farther over the 120 h window. More data are needed to accurately estimate maximum dispersal potential. Movement patterns and passage rates of the other rodent species in our study vary, but they are generally poorly studied. Smaller rodents would typically have faster passage rates, which would be likely to translate into smaller potential dispersal areas. However, the ecological importance of small versus large dispersal distances may balance out if estimates account for species abundance and distribution. The Hastings River mouse (P. oralis) was estimated to retain fungal spores up to 95–100 h after ingestion and to move spores as far as 1256 m (Elliott et al. 2020). It is important to remember that this does not mean 1256 m from the point of ingestion, but is within the species’ home range. We suspect that given their slightly smaller size, the three Rattus species in this study would have a dispersal potential similar to but slightly smaller than what was calculated for P. oralis. The other five even smaller species we examined would be likely to have a dispersal potential smaller than that of the Rattus spp. More data on passage rates and movement patterns are needed to reliably estimate or model the dispersal potential of these rodents and their impacts on mycorrhizal fungal distribution.
Fungal spore dispersal distance has been modelled only for swamp wallabies (Wallabia bicolor); despite their much larger size, this species’ maximum spore dispersal distance was estimated to be 1265 m from the point of ingestion (Danks et al. 2020). Regardless of the specifics of how far rodents are dispersing fungal spores, it is apparent that they are regularly moving mycorrhizal fungi at least hundreds of metres from where they are ingested. This is ecologically significant because many of the mycorrhizal fungi they eat form sequestrate fruiting bodies that are enclosed in a skin and often fruit below the soil surface (Maser et al. 2008). This fruiting habit makes the fungi reliant on animals for spore dispersal, and having their spores moved even a few metres from where they were fruiting is significant for their dispersal and the associated plant communities.
Our study highlights the importance of murid rodents in maintaining healthy mycorrhizal fungal communities through the consumption of a diversity of fungal taxa and subsequent dispersal of these fungi through their scats. With extinctions and/or losses in the abundance of many mycophagous marsupial communities (Nuske et al. 2017a), it is important to understand the key ecosystem services provided by Australian rodent communities. We urge researchers working with murids and other rodents in Australia and beyond to direct more attention toward understanding the fungal components of these animals’ diets. In most regions of the world, only a handful of rodent species have been thoroughly studied and are recognised as being highly important mycophagous species and spore dispersers (Fogel and Trappe 1978; Elliott et al. 2022). There are hundreds of other rodent species that are likely to be equally important but remain unrecognised as spore dispersers. We hope this study of murid rodent mycophagy will stimulate more research interest into rodent mycophagy around the world.
Data availability
Data is available from the authors on reasonable request.
Conflicts of interest
The authors declare no conflicts of interest.
Declaration of funding
The fieldwork for this project was made possible by two University of New England Robine Enid Wilson Grants and funding from the Holsworth Wildlife Research Endowment from the Ecological Society of Australia to TFE. The School of Environmental and Rural Science at the University of New England also provided facilities and an international post graduate research fellowship to TFE.
Acknowledgements
We express gratitude to the Traditional Owners of the sites where this research took place. We especially want to thank the Northern Kuuku Ya’u Kanthanampu Aboriginal Corporation RNTBC Land Trust for granting us access permits to Kutini-Payamu. We appreciate Rosemary Yates for allowing us to conduct fieldwork on her private conservation property at Motherland Mount Hyland in NSW. Stuart Green assisted with the early rounds of trapping at Mount Hyland.
References
Caiafa, MV, Jusino, MA, Wilkie, AC, Díaz, IA, Sieving, KE, and Smith, ME (2021). Discovering the role of Patagonian birds in the dispersal of truffles and other mycorrhizal fungi. Current Biology 31, 5558–5570.e3.| Discovering the role of Patagonian birds in the dispersal of truffles and other mycorrhizal fungi.Crossref | GoogleScholarGoogle Scholar |
Caldwell, I, Vernes, KA, and Barlocher, F (2005). The northern flying squirrel (Glaucomys sabrinus) as a vector for inoculation of red spruce (Picea rubens) seedlings with ectomycorrhizal fungi. Sydowia 57, 166–178.
Cázares, E, and Trappe, JM (1994). Spore dispersal of ectomycorrhizal fungi on a glacier forefront by mammal mycophagy. Mycologia 86, 507–510.
| Spore dispersal of ectomycorrhizal fungi on a glacier forefront by mammal mycophagy.Crossref | GoogleScholarGoogle Scholar |
Claridge, AW, and May, TW (1994). Mycophagy among Australian mammals. Australian Journal of Ecology 19, 251–275.
| Mycophagy among Australian mammals.Crossref | GoogleScholarGoogle Scholar |
Colgan, W, and Claridge, AW (2002). Mycorrhizal effectiveness of Rhizopogon spores recovered from faecal pellets of small forest-dwelling mammals. Mycological Research 106, 314–320.
| Mycorrhizal effectiveness of Rhizopogon spores recovered from faecal pellets of small forest-dwelling mammals.Crossref | GoogleScholarGoogle Scholar |
Comport, SS, and Hume, ID (1998). Gut morphology and rate of passage of fungal spores through the gut of a tropical rodent, the giant white-tailed rat (Uromys caudimaculatus). Australian Journal of Zoology 46, 461–471.
| Gut morphology and rate of passage of fungal spores through the gut of a tropical rodent, the giant white-tailed rat (Uromys caudimaculatus).Crossref | GoogleScholarGoogle Scholar |
Cove, MV, Simons, TR, Gardner, B, Maurer, AS, and O’Connell, AF (2017). Evaluating nest supplementation as a recovery strategy for the endangered rodents of the Florida Keys. Restoration Ecology 25, 253–260.
| Evaluating nest supplementation as a recovery strategy for the endangered rodents of the Florida Keys.Crossref | GoogleScholarGoogle Scholar |
Danks, MA (2012). Gut-retention time in mycophagous mammals: a review and a study of truffle-like fungal spore retention in the swamp wallaby. Fungal Ecology 5, 200–210.
| Gut-retention time in mycophagous mammals: a review and a study of truffle-like fungal spore retention in the swamp wallaby.Crossref | GoogleScholarGoogle Scholar |
Danks, MA, Simpson, N, Elliott, TF, Paine, CET, and Vernes, K (2020). Modeling mycorrhizal fungi dispersal by the mycophagous swamp wallaby (Wallabia bicolor). Ecology and Evolution 10, 12920–12928.
| Modeling mycorrhizal fungi dispersal by the mycophagous swamp wallaby (Wallabia bicolor).Crossref | GoogleScholarGoogle Scholar |
Dundas, SJ, Hopkins, AJM, Ruthrof, KX, Tay, NE, Burgess, TI, Hardy, GESJ, and Fleming, PA (2018). Digging mammals contribute to rhizosphere fungal community composition and seedling growth. Biodiversity and Conservation 27, 3071–3086.
| Digging mammals contribute to rhizosphere fungal community composition and seedling growth.Crossref | GoogleScholarGoogle Scholar |
Elliott, TF, and Marshall, PA (2016). Animal-fungal interactions 1: notes on bowerbird’s use of fungi. Australian Zoologist 38, 59–61.
| Animal-fungal interactions 1: notes on bowerbird’s use of fungi.Crossref | GoogleScholarGoogle Scholar |
Elliott, TF, and Vernes, K (2021). Notes on the diets of four rodent species from Goodenough Island. Australian Mammalogy 43, 256–259.
| Notes on the diets of four rodent species from Goodenough Island.Crossref | GoogleScholarGoogle Scholar |
Elliott, TF, Jusino, MA, Trappe, JM, Lepp, H, Ballard, G-A, Bruhl, JJ, and Vernes, K (2019a). A global review of the ecological significance of symbiotic associations between birds and fungi. Fungal Diversity 98, 161–194.
| A global review of the ecological significance of symbiotic associations between birds and fungi.Crossref | GoogleScholarGoogle Scholar |
Elliott, TF, Bower, DS, and Vernes, K (2019b). Reptilian mycophagy: a global review of mutually beneficial associations between reptiles and macrofungi. Mycosphere 10, 776–797.
| Reptilian mycophagy: a global review of mutually beneficial associations between reptiles and macrofungi.Crossref | GoogleScholarGoogle Scholar |
Elliott, TF, Townley, S, Johnstone, C, Meek, P, Gynther, I, and Vernes, K (2020). The endangered Hastings River mouse (Pseudomys oralis) as a disperser of ectomycorrhizal fungi in eastern Australia. Mycologia 112, 1075–1085.
| The endangered Hastings River mouse (Pseudomys oralis) as a disperser of ectomycorrhizal fungi in eastern Australia.Crossref | GoogleScholarGoogle Scholar |
Elliott, TF, Truong, C, Jackson, S, Zúñiga, CL, Trappe, JM, and Vernes, K (2022). Mammalian mycophagy: a global review of ecosystem interactions between mammals and fungi. Fungal Systematics and Evolution 9, 99–159.
| Mammalian mycophagy: a global review of ecosystem interactions between mammals and fungi.Crossref | GoogleScholarGoogle Scholar |
Firth, RSC, Brook, BW, Woinarski, JCZ, and Fordham, DA (2010). Decline and likely extinction of a northern Australian native rodent, the Brush-tailed Rabbit-rat Conilurus penicillatus. Biological Conservation 143, 1193–1201.
| Decline and likely extinction of a northern Australian native rodent, the Brush-tailed Rabbit-rat Conilurus penicillatus.Crossref | GoogleScholarGoogle Scholar |
Fogel, R, and Trappe, JM (1978). Fungus consumption (mycophagy) by small animals. Northwest Science 52, 1–31.
Gasparini, B (2014). Cortinarius (Agaricales) revised taxonomy: new species names or combinations. Mycosphere 5, 541–544.
| Cortinarius (Agaricales) revised taxonomy: new species names or combinations.Crossref | GoogleScholarGoogle Scholar |
Hamilton, MJ, and Leslie, DM (2021). Celebrating five decades of Mammalian Species, highlighted by the publication of the 1,000th account. Journal of Mammalogy 102, 681–684.
| Celebrating five decades of Mammalian Species, highlighted by the publication of the 1,000th account.Crossref | GoogleScholarGoogle Scholar |
Johnson, CN (1996). Interactions between mammals and ectomycorrhizal fungi. Trends in Ecology & Evolution 11, 503–507.
| Interactions between mammals and ectomycorrhizal fungi.Crossref | GoogleScholarGoogle Scholar |
Maser C, Claridge AW, Trappe JM (2008) ‘Trees, truffles, and beasts: how forests function.’ (Rutgers University Press: New Brunswick, NJ, USA)
McGee, PA, and Baczocha, N (1994). Sporocarpic Endogonales and Glomales in the scats of Rattus and Perameles. Mycological Research 98, 246–249.
| Sporocarpic Endogonales and Glomales in the scats of Rattus and Perameles.Crossref | GoogleScholarGoogle Scholar |
Miranda, V, Rothen, C, Yela, N, Aranda-Rickert, A, Barros, J, Calcagno, J, and Fracchia, S (2019). Subterranean desert rodents (genus Ctenomys) create soil patches enriched in root endophytic fungal propagules. Microbial Ecology 77, 451–459.
| Subterranean desert rodents (genus Ctenomys) create soil patches enriched in root endophytic fungal propagules.Crossref | GoogleScholarGoogle Scholar |
Nouhra, E, Kuhar, F, Truong, C, Pastor, N, Crespo, E, Mujic, A, Caiafa, MV, and Smith, ME (2021). Thaxterogaster revisited: a phylogenetic and taxonomic overview of sequestrate Cortinarius from Patagonia. Mycologia 113, 1022–1055.
| Thaxterogaster revisited: a phylogenetic and taxonomic overview of sequestrate Cortinarius from Patagonia.Crossref | GoogleScholarGoogle Scholar |
Nuske, SJ, Vernes, K, May, TW, Claridge, AW, Congdon, BC, Krockenberger, A, and Abell, SE (2017a). Redundancy among mammalian fungal dispersers and the importance of declining specialists. Fungal Ecology 27, 1–13.
| Redundancy among mammalian fungal dispersers and the importance of declining specialists.Crossref | GoogleScholarGoogle Scholar |
Nuske, SJ, Vernes, K, May, TW, Claridge, AW, Congdon, BC, Krockenberger, A, and Abell, SE (2017b). Data on the fungal species consumed by mammal species in Australia. Data in Brief 12, 251–260.
| Data on the fungal species consumed by mammal species in Australia.Crossref | GoogleScholarGoogle Scholar |
Nuske, SJ, Anslan, S, Tedersoo, L, Congdon, BC, and Abell, SE (2019). Ectomycorrhizal fungal communities are dominated by mammalian dispersed truffle-like taxa in north-east Australian woodlands. Mycorrhiza 29, 181–193.
| Ectomycorrhizal fungal communities are dominated by mammalian dispersed truffle-like taxa in north-east Australian woodlands.Crossref | GoogleScholarGoogle Scholar |
Oksanen J, Guillaume Blanchet F, Friendly M, Kindt R, Legendre P, McGlinn D, Minchin PR, O’Hara RB, Simpson GL, Solymos P, Stevens MHH, Szoecs E, Wagner H (2020) vegan: community ecology package. R package version 2.5-7. Available at https://CRAN.R-project.org/package=vegan
Ori, F, Trappe, J, Leonardi, M, Iotti, M, and Pacioni, G (2018). Crested porcupines (Hystrix cristata): mycophagist spore dispersers of the ectomycorrhizal truffle Tuber aestivum. Mycorrhiza 28, 561–565.
| Crested porcupines (Hystrix cristata): mycophagist spore dispersers of the ectomycorrhizal truffle Tuber aestivum.Crossref | GoogleScholarGoogle Scholar |
Pastor, N, Chiapella, J, Kuhar, F, Mujic, AB, Crespo, EM, and Nouhra, ER (2019). Unveiling new sequestrate Cortinarius species from northern Patagonian Nothofagaceae forests based on molecular and morphological data. Mycologia 111, 103–117.
| Unveiling new sequestrate Cortinarius species from northern Patagonian Nothofagaceae forests based on molecular and morphological data.Crossref | GoogleScholarGoogle Scholar |
R Core Team (2020) ‘R: a language and environment for statistical computing.’ (R Foundation for Statistical Computing: Vienna, Austria). Available at https://www.R-project.org/
Reddell, P, Spain, AV, and Hopkins, M (1997). Dispersal of spores of mycorrhizal fungi in scats of native mammals in tropical forests of northeastern Australia. Biotropica 29, 184–192.
| Dispersal of spores of mycorrhizal fungi in scats of native mammals in tropical forests of northeastern Australia.Crossref | GoogleScholarGoogle Scholar |
Roycroft, E, MacDonald, AJ, Moritz, C, Moussalli, A, Portela Miguez, R, and Rowe, KC (2021). Museum genomics reveals the rapid decline and extinction of Australian rodents since European settlement. Proceedings of the National Academy of Sciences 118, e2021390118.
| Museum genomics reveals the rapid decline and extinction of Australian rodents since European settlement.Crossref | GoogleScholarGoogle Scholar |
Shevill DI (1999) ‘The ecology of the Rufus Spiny Bandicoot, Echymipera rufescens australis (Peters and Doria) (Marsupialia: Peramelidae) in Lowland Rainforest of Iron Range National Park, Cape York Peninsula.’ (James Cook University, School of Tropical Biology)
Shevill, DI, and Johnson, CN (2007). Diet and breeding of the rufous spiny bandicoot Echymipera rufescens australis, Iron Range, Cape York Peninsula. Australian Mammalogy 29, 169–175.
| Diet and breeding of the rufous spiny bandicoot Echymipera rufescens australis, Iron Range, Cape York Peninsula.Crossref | GoogleScholarGoogle Scholar |
Smith, AP, and Quin, DG (1996). Patterns and causes of extinction and decline in Australian conilurine rodents. Biological Conservation 77, 243–267.
| Patterns and causes of extinction and decline in Australian conilurine rodents.Crossref | GoogleScholarGoogle Scholar |
Stephens, RB, and Rowe, RJ (2020). The underappreciated role of rodent generalists in fungal spore dispersal networks. Ecology 101, e02972.
| The underappreciated role of rodent generalists in fungal spore dispersal networks.Crossref | GoogleScholarGoogle Scholar |
Stephens, RB, Trowbridge, AM, Ouimette, AP, Knighton, WB, Hobbie, EA, Stoy, PC, and Rowe, RJ (2020). Signaling from below: rodents select for deeper fruiting truffles with stronger volatile emissions. Ecology 101, e02964.
| Signaling from below: rodents select for deeper fruiting truffles with stronger volatile emissions.Crossref | GoogleScholarGoogle Scholar |
Swihart, RK, Slade, NA, and Bergstrom, BJ (1988). Relating body size to the rate of home range use in mammals. Ecology 69, 393–399.
| Relating body size to the rate of home range use in mammals.Crossref | GoogleScholarGoogle Scholar |
Taylor, RJ (1992). Seasonal changes in the diet of the Tasmanian bettong (Bettongia gaimardi), a mycophagous marsupial. Journal of Mammalogy 73, 408–414.
| Seasonal changes in the diet of the Tasmanian bettong (Bettongia gaimardi), a mycophagous marsupial.Crossref | GoogleScholarGoogle Scholar |
Tedersoo, L, May, TW, and Smith, ME (2010). Ectomycorrhizal lifestyle in fungi: global diversity, distribution, and evolution of phylogenetic lineages. Mycorrhiza 20, 217–263.
| Ectomycorrhizal lifestyle in fungi: global diversity, distribution, and evolution of phylogenetic lineages.Crossref | GoogleScholarGoogle Scholar |
Thiers, HD (1984). The secotioid syndrome. Mycologia 76, 1–8.
| The secotioid syndrome.Crossref | GoogleScholarGoogle Scholar |
Trappe, JM, and Maser, C (1976). Germination of spores of Glomus macrocarpus (Endogonaceae) after passage through a rodent digestive tract. Mycologia 68, 433–436.
| Germination of spores of Glomus macrocarpus (Endogonaceae) after passage through a rodent digestive tract.Crossref | GoogleScholarGoogle Scholar |
Valentine, LE, Ruthrof, KX, Fisher, R, Hardy, GESJ, Hobbs, RJ, and Fleming, PA (2018). Bioturbation by bandicoots facilitates seedling growth by altering soil properties. Functional Ecology 32, 2138–2148.
| Bioturbation by bandicoots facilitates seedling growth by altering soil properties.Crossref | GoogleScholarGoogle Scholar |
Vašutová, M, Mleczko, P, López-García, A, Maček, I, Boros, G, Ševčík, J, Fujii, S, Hackenberger, D, Tuf, IH, Hornung, E, Páll-Gergely, B, and Kjøller, R (2019). Taxi drivers: the role of animals in transporting mycorrhizal fungi. Mycorrhiza 29, 413–434.
| Taxi drivers: the role of animals in transporting mycorrhizal fungi.Crossref | GoogleScholarGoogle Scholar |
Vernes, K (2014). Seasonal truffle consumption by long-nosed bandicoots (Perameles nasuta) in a mixed rainforest–open forest community in north-eastern New South Wales. Australian Mammalogy 36, 113–115.
| Seasonal truffle consumption by long-nosed bandicoots (Perameles nasuta) in a mixed rainforest–open forest community in north-eastern New South Wales.Crossref | GoogleScholarGoogle Scholar |
Vernes, K, and Dunn, L (2009). Mammal mycophagy and fungal spore dispersal across a steep environmental gradient in eastern Australia. Austral Ecology 34, 69–76.
| Mammal mycophagy and fungal spore dispersal across a steep environmental gradient in eastern Australia.Crossref | GoogleScholarGoogle Scholar |
Vernes, K, and McGrath, K (2009). Are introduced black rats (Rattus rattus) a functional replacement for mycophagous native rodents in fragmented forests? Fungal Ecology 2, 145–148.
| Are introduced black rats (Rattus rattus) a functional replacement for mycophagous native rodents in fragmented forests?Crossref | GoogleScholarGoogle Scholar |
Vernes, K, Castellano, M, and Johnson, CN (2001). Effects of season and fire on the diversity of hypogeous fungi consumed by a tropical mycophagous marsupial. Journal of Animal Ecology 70, 945–954.
| Effects of season and fire on the diversity of hypogeous fungi consumed by a tropical mycophagous marsupial.Crossref | GoogleScholarGoogle Scholar |
Vernes, K, Cooper, T, and Green, S (2015). Seasonal fungal diets of small mammals in an Australian temperate forest ecosystem. Fungal Ecology 18, 107–114.
| Seasonal fungal diets of small mammals in an Australian temperate forest ecosystem.Crossref | GoogleScholarGoogle Scholar |
Vernes, K, Elliott, TF, and Jackson, SM (2021). 150 years of mammal extinction and invasion at Koonchera Dune in the Lake Eyre Basin of South Australia. Biological Invasions 23, 593–610.
| 150 years of mammal extinction and invasion at Koonchera Dune in the Lake Eyre Basin of South Australia.Crossref | GoogleScholarGoogle Scholar |
Waller, NL, Gynther, IC, Freeman, AB, Lavery, TH, and Leung, LK-P (2017). The Bramble Cay melomys Melomys rubicola (Rodentia: Muridae): a first mammalian extinction caused by human-induced climate change? Wildlife Research 44, 9–21.
| The Bramble Cay melomys Melomys rubicola (Rodentia: Muridae): a first mammalian extinction caused by human-induced climate change?Crossref | GoogleScholarGoogle Scholar |
Wellesley-Whitehouse H (1983) White-tailed rat Uromys caudimaculatus. In ‘The Australian Museum complete book of Australian Mammals’. (Ed. R Strahan) pp. 371. (Angus and Robertson: Sydney, NSW, Australia)
Wildi O (2017) ‘Data analysis in vegetation ecology.’ 3rd edn. (CABI: Wallingford, UK)
Wilson DE, Lacher TE, Mittermeier RA (Eds) (2017) ‘Handbook of the mammals of the world. Vol. 7. Rodents II.’ (Lynx Editions: Barcelona, Spain)