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PLOS ONE  2013 

Historical Biogeography and Diversification of Truffles in the Tuberaceae and Their Newly Identified Southern Hemisphere Sister Lineage

DOI: 10.1371/journal.pone.0052765

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Abstract:

Truffles have evolved from epigeous (aboveground) ancestors in nearly every major lineage of fleshy fungi. Because accelerated rates of morphological evolution accompany the transition to the truffle form, closely related epigeous ancestors remain unknown for most truffle lineages. This is the case for the quintessential truffle genus Tuber, which includes species with socio-economic importance and esteemed culinary attributes. Ecologically, Tuber spp. form obligate mycorrhizal symbioses with diverse species of plant hosts including pines, oaks, poplars, orchids, and commercially important trees such as hazelnut and pecan. Unfortunately, limited geographic sampling and inconclusive phylogenetic relationships have obscured our understanding of their origin, biogeography, and diversification. To address this problem, we present a global sampling of Tuberaceae based on DNA sequence data from four loci for phylogenetic inference and molecular dating. Our well-resolved Tuberaceae phylogeny shows high levels of regional and continental endemism. We also identify a previously unknown epigeous member of the Tuberaceae – the South American cup-fungus Nothojafnea thaxteri (E.K. Cash) Gamundí. Phylogenetic resolution was further improved through the inclusion of a previously unrecognized Southern hemisphere sister group of the Tuberaceae. This morphologically diverse assemblage of species includes truffle (e.g. Gymnohydnotrya spp.) and non-truffle forms that are endemic to Australia and South America. Southern hemisphere taxa appear to have diverged more recently than the Northern hemisphere lineages. Our analysis of the Tuberaceae suggests that Tuber evolved from an epigeous ancestor. Molecular dating estimates Tuberaceae divergence in the late Jurassic (~156 million years ago), with subsequent radiations in the Cretaceous and Paleogene. Intra-continental diversification, limited long-distance dispersal, and ecological adaptations help to explain patterns of truffle evolution and biodiversity.

 References

[1]  Trappe J, Molina R, Luoma D, Cázares E, Pilz D, et al.. (2009) Diversity, Ecology, and Conservation of Truffle Fungi in Forests of the Pacific Northwest. In: United States Department of Agriculture FS, Pacific Northwest Research Station., editor. PNW-GTR-772: Portland, OR: USA. pp. 194.
[2]  Tedersoo L, May TW, Smith ME (2010) Ectomycorrhizal lifestyle in fungi: global diversity, distribution, and evolution of phylogenetic lineages. Mycorrhiza 20: 217–263.
[3]  Mello A, Murat C, Bonfante P (2006) Truffles: much more than a prized and local fungal delicacy. Fems Microbiology Letters 260: 1–8.
[4]  L?ss?e T, Hansen K (2007) Truffle trouble: what happened to the Tuberales?. Mycological Research 111: 1075–1099.
[5]  Padovan ACB, Sanson GFO, Brunstein A, Briones MRS (2005) Fungi evolution revisited: Application of the penalized likelihood method to a Bayesian fungal phylogeny provides a new perspective on phylogenetic relationships and divergence dates of ascomycota groups. Journal of Molecular Evolution 60: 726–735.
[6]  Bonito GM, Gryganskyi AP, Trappe JM, Vilgalys R (2010) A global meta-analysis of Tuber ITS rDNA sequences: species diversity, host associations and long-distance dispersal. Molecular Ecology 19: 4994–5008.
[7]  O’Donnell K, Cigelnik E, Weber NS, Trappe JM (1997) Phylogenetic relationships among ascomycetous truffles and the true and false morels inferred from 18S and 28S ribosomal DNA sequence analysis. Mycologia 89: 48–65.
[8]  Trappe JM (1979) The orders, families, and genera of hypogeous Ascomycotina (truffles and their relatives). Mycotaxon 9: 297–340.
[9]  Trail F (2007) Fungal cannons: explosive spore discharge in the Ascomycota. FEMS Microbiology Letters 276: 12–18.
[10]  Singer R, Harris B (1987) Mushrooms and Truffles: Botany, Cultivation, and Utilization: Lubrecht & Cramer Ltd. 389 p.
[11]  Alvarez IF, Parlade J, Trappe JM (1992) Loculotuber gennadii gen. et comb. nov. and Tuber multimaculatum sp. nov. Mycologia 84: 926–929.
[12]  Maser C, Nussbaum RA, Trappe JM (1978) Fungal small mammal interrelationships with emphasis on Oregon coniferous forests. Ecology 59: 799–809.
[13]  Claridge AW, Trappe JM (2005) Sporocarp mycophagy: nutritional, behavioral, evolutionary, and physiological aspects. In: Dighton J, White JM, Oudemans P, editors. The Fungal Community–its organization and role in the ecosystem. Boca Raton, FL: Taylor & Francis. 599–611.
[14]  Castellano MA, Trappe JM, Maser Z, Maser C (1989) Key to spores of the genera of hypogeous fungi of north temperate forest with special reference to animal mycophagy. Eureka, California Mad River Press. 186 p.
[15]  Frank JL, Anglin S, Carrington EM, Taylor DS, Viratos B, et al. (2009) Rodent dispersal of fungal spores promotes seedling establishment away from mycorrhizal networks on Quercus garryana. Botany-Botanique 87: 821–829.
[16]  Cázares E, Trappe JM (1994) Spore dispersal of ectomycorrhizal fungi on a glacier forefront by mammal mycophagy. Mycologia 86: 507–510.
[17]  Bruns TD, Fogel R, White TJ, Palmer JD (1989) Accelerated evolution of a false-truffle from a mushroom ancestor. Nature 339: 140–142.
[18]  Martin MP, Hogberg N, Llistosella J (1999) Macowanites messapicoides, a hypogeous relative of Russula messapica. Mycological Research 103: 203–208.
[19]  Berbee ML, Taylor JW (2010) Dating the molecular clock in fungi - how close are we? Fungal Biology 24: 1–16.
[20]  Jeandroz S, Murat C, Wang YJ, Bonfante P, Le Tacon F (2008) Molecular phylogeny and historical biogeography of the genus Tuber, the ‘true truffles’. Journal of Biogeography 35: 815–829.
[21]  Hosaka K, Castellano MA, Spatafora JW (2008) Biogeography of Hysterangiales (Phallomycetidae, Basidiomycota). Mycological Research 112: 448–462.
[22]  Kinoshita A, Sasaki H, Kazuhide N (2011) Phylogeny and diversity of Japanese truffles (Tuber spp.) inferred from sequences of four nuclear loci. Mycologia doi: 10.3852/10–138.
[23]  Bonito G, Trappe JM, Rawlinson P, Vilgalys R (2010) Improved resolution of major clades within Tuber and taxonomy of species within the Tuber gibbosum complex. Mycologia 102: 1042–1057.
[24]  Moncalvo JM, Vilgalys R, Redhead SA, Johnson JE, James TY, et al. (2002) One hundred and seventeen clades of euagarics. Molecular Phylogenetics and Evolution 23: 357–400.
[25]  Edgar RC (2004) MUSCLE: a multiple sequence alignment method with reduced time and space complexity. BMC Bioinformatics 5: 1–19.
[26]  Maddison WP, Maddison DR (2009) Mesquite: a modular system for evolutionary analysis. Version 2.6 ed, Available: http://mesquiteproject.org.
[27]  Swofford DL (2002) PAUP* Phylogenetic analysis using parsimony (*and other methods). 4.0 ed. Sunderland, Massachusetts: Sinauer Associates.
[28]  Ronquist F, Huelsenbeck JP (2003) MrBayes 3: Bayesian phylogenetic inference under mixed models. Bioinformatics 19: 1572–1574.
[29]  Lanfear R, Calcott B, Ho SYW, Guindon S (2012) PartitionFinder: Combined Selection of Partitioning Schemes and Substitution Models for Phylogenetic Analyses. Molecular Biology and Evolution 29: 1695–1701.
[30]  Drummond AJ, Rambaut A (2007) BEAST: Bayesian evolutionary analysis by sampling trees. BMC Evolutionary Biology 7: -.
[31]  Otalora MAG, Martinez I, Aragon G, Molina MC (2010) Phylogeography and divergence date estimates of a lichen species complex with a disjunct distribution pattern. American Journal of Botany 97: 216–223.
[32]  Clarke JT, Warnock RCM, Donoghue PCJ (2011) Establishing a time-scale for plant evolution. New Phytologist 192: 266–301.
[33]  Rambaut A, Drummond AJ (2007) Tracer v1.4. Available: http://beast.bio.ed.ac.uk/Tracer, editor.
[34]  Yan Y, Harris AJ, He X (2011) RASP (Reconstruct Ancestral State in Phylogenies). Available: http://mnhscueducn/soft/blog/RASP.
[35]  Newsholme C (1992) Willows: The genus Salix: Batsford Ltd. 1–224 p.
[36]  Spegazzini (1887) Anales Soc. Ci. Argent. 10.
[37]  Smith SA, Beaulieu JM, Donoghue MJ (2010) An uncorrelated relaxed-clock analysis suggests an earlier origin for flowering plants. Proceedings of the National Academy of Sciences of the United States of America 107: 5897–5902.
[38]  Marjanovic Z, Grebenc T, Markovic M, Glisic A, Milenkovic M (2010) Ecological specificities and molecular diversity of truffles (genus Tuber) originating from mid-west of the Balkan Peninsula. Sydowia 62: 67–87.
[39]  Alvarado P, Moreno G, Manjón JL (2012) Comparison between Tuber gennadii and T. oligospermum lineages reveals the existence of the new species T. cistophilum (Tuberaceae, Pezizales). Mycologia 104: 894–910.
[40]  Smith ME, Douhan GW, Fremier AK, Rizzo DM (2009) Are true multihost fungi the exception or the rule? Dominant ectomycorrhizal fungi on Pinus sabiniana differ from those on co-occurring Quercus species. New Phytologist 182: 295–299.
[41]  Wei XX, Yang ZY, Li Y, Wang XQ (2010) Molecular phylogeny and biogeography of Pseudotsuga (Pinaceae): Insights into the floristic relationship between Taiwan and its adjacent areas. Molecular Phylogenetics and Evolution 55: 776–785.
[42]  Guevara G, Bonito G, Trappe J, Cázares E, Williams G, et al. (in press) New North American truffles (Tuber spp.) and their ectomycorrhizal associations Mycologia.
[43]  Pérez F, Palfner G, Brunel N, Santelices R (2007) Synthesis and establishment of Tuber melanosporum Vitt. ectomycorrhizae on two Nothofagus species in Chile. Mycorrhiza 17: 627–632.
[44]  Bulman SR, Visnovsky SR, Hall IR, Guerin-Laguete A, Wang Y (2010) Molecular and morphological identiication of truffle-producing Tuber species in New Zealand. Mycological Progress 9: 205–214.
[45]  Comandini O, Contu M, Rinaldi AC (2006) An overview of Cistus ectomycorrhizal fungi. Mycorrhiza 16: 381–395.
[46]  Kutorga E, Matakrzytê M (2008) Hypogeous fungi of Lithuania: a preliminary checklist. Acta Mycologia 43: 133–138.
[47]  Wedén C, Sonny L, Burman R, Backlund A (2009) The Edible Truffle Choiromyces venosus and Its Use in Sweden. Acta Botanica Yunnanica Supplement XVI: 94–96.
[48]  Bidartondo MI, Burghardt B, Gebauer G, Bruns TD, Read DJ (2004) Changing partners in the dark: isotopic and molecular evidence of ectomycorrhizal liaisons between forest orchids and trees. Proceedings of the Royal Society of London Series B-Biological Sciences 271: 1799–1806.
[49]  Bell CD, Soltis DE, Soltis PS (2010) The age and diversification of the angiosperms re-revisited. American Journal of Botany 97: 1296–1303.
[50]  Matheny PB, Aime MC, Bougher NL, Buyck B, Desjardin DE, et al. (2009) Out of the Palaeotropics? Historical biogeography and diversification of the cosmopolitan ectomycorrhizal mushroom family Inocybaceae. Journal of Biogeography 36: 577–592.
[51]  Mindell RA, Stockey RA, Beard G (2007) Cascadiacarpa spinosa gen. et sp nov (Fagaceae): Castaneoid fruits from the Eocene of Vancouver Island, Canada. American Journal of Botany 94: 351–361.
[52]  Ramirez JL, Cevallos-Ferriz SRS (2000) Leaves of Salicaceae (Salix and Populus) from Oligocene sediments near Tepexi de Rodriguez, Puebla, Mexico. International Journal of Plant Sciences 161: 521–534.
[53]  Manos PS, Soltis PS, Soltis DE, Manchester SR, Oh SH, et al. (2007) Phylogeny of extant and fossil Juglandaceae inferred from the integration of molecular and morphological data sets. Systematic Biology 56: 412–430.
[54]  Sims HJ, Herendeen PS, Lupia R, Christopher RA, Crane PR (1999) Fossil flowers with Normapolles pollen from the Upper Cretaceous of southeastern North America. Review of Palaeobotany and Palynology 106: 131–151.
[55]  Ryberg M, Matheny PB (2012) Asynchronous origins of ectomycorrhizal clades of Agaricales. Proceedings of the Royal Society B-Biological Sciences 279: 2003–2011.
[56]  Matheny PB, Aime MC, Bougher NL, Buyck B, Desjardin DE, et al. (2009) Out of the Palaeotropics? Historical biogeoraphy and diversification of the cosmopolitan ectomycorrhizal mushroom family Inocybaceae. Journal of Biogeography 36: 577–592.
[57]  O’Donnell K, Rooney AP, Mills GL, Kuo M, Weber NS, et al. (2011) Phylogeny and historical biogeography of true morels (Morchella) reveals an early Cretaceous origin and high continental endemism and provincialism in the Holarctic. Fungal Genetics and Biology 48: 252–265.
[58]  Sung GH, Poinar GO, Spatafora JW (2008) The oldest fossil evidence of animal parasitism by fungi supports a Cretaceous diversification of fungal-arthropod symbioses. Molecular Phylogenetics and Evolution 49: 495–502.
[59]  Moreno G, Alvarado P, Manjon JL (2011) Phylogenetic affiliation of Choiromyces magnusii and C. venosus (Tuberaceae, Ascomycota) from Spain. Mycological Progress DOI 10.1007/s11557–011–0762–1.
[60]  Beaton G, Weste G (1977) Genus Labyrinthomyces. Transactions of the British Mycological Society 69: 243–247.
[61]  Beaton G, Malajczuk N (1986) A New Species and a Variety of Labyrinthomyces from Western-Australia. Transactions of the British Mycological Society 86: 503–507.
[62]  Trappe JM, Claridge AW, Claridge DL, Liddle L (2008) Desert truffles of the Australian autback: Ecology, ethnomycology, and taxonomy. Economic Botany 62: 497–506.
[63]  Gamundí IJ (1971) Algunos discomycetes de Chile. Bol. Soc. Argent. Bot. 13: 260–289.
[64]  Rifai MA (1968) The Australasian Pezizales in the herbarium of the Royal Botanic Gardens, Kew. Verh K Ned Akad Wet Natuurk Tweede Reeks 57: 1–295.
[65]  Warcup JH (1990) Taxonomy, culture and mycorrhizal associations of some zygosporic Endogonaceae. Mycological Research 94: 173–178.
[66]  Gamundí IJ (1971) Las Cyttariales sudamericanas (Fungi-Ascomycetes). Darwiniana 16: 461–510.
[67]  Zhang BC, Minter DW (1989) Gymnohydnotrya - a new hypogeous Ascomycete genus from Australia. Mycological Research 92: 192–198.
[68]  Warcup JH (1990) Occurrence of ectomycorrhizal and saprophytic discomycetes after awWild fire in a eucalypt forest. Mycological Research 94: 1065–1069.
[69]  Cook LG, Crisp MD (2005) Not so ancient: the extant crown group of Nothofagus represents a post-Gondwanan radiation. Proceedings of the Royal Society B-Biological Sciences 272: 2535–2544.

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