The evolution of fungus-growing termites and their mutualistic fungal symbionts

Aanen, Duur K.; Eggleton, Paul; Rouland-Lefèvre, Corinne; Frøslev, Tobias Guldberg; Rosendahl, Søren; Boomsma, Jacobus J.

doi:10.1073/pnas.222313099

Cited by 382 publications

(534 citation statements)

References 31 publications

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“…This would imply that the fungal symbionts have not been selected to invest in antagonistic traits, but this prediction remains to be tested. The few studies that have addressed within-nest variation of fungal symbionts, have found single cultures within single nests (Aanen et al 2002;Katoh et al 2002), consistent with the hypothesis that recurrent bottlenecking within nests reduces fungal within-nest variation. However, more research is needed to confirm this hypothesis, especially for species with multiple separate fungus combs per nest.…”

Section: Discussionmentioning

confidence: 60%

As you reap, so shall you sow: coupling of harvesting and inoculating stabilizes the mutualism between termites and fungi

Aanen¹

2006

Biol. Lett.

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At present there is no consensus theory explaining the evolutionary stability of mutualistic interactions. However, the question is whether there are general 'rules', or whether each particular mutualism needs a unique explanation. Here, I address the ultimate evolutionary stability of the 'agricultural' mutualism between fungus-growing termites and Termitomyces fungi, and provide a proximate mechanism for how stability is achieved. The key to the proposed mechanism is the within-nest propagation mode of fungal symbionts by termites. The termites suppress horizontal fungal transmission by consuming modified unripe mushrooms (nodules) for food. However, these nodules provide asexual gut-resistant spores that form the inoculum of new substrate. This within-nest propagation has two important consequences: (i) the mutualistic fungi undergo severe, recurrent bottlenecks, so that the fungus is likely to be in monoculture and (ii) the termites 'artificially' select for high nodule production, because their fungal food source also provides the inoculum for the next harvest. I also provide a brief comparison of the termitefungus mutualism with the analogous agricultural mutualism between attine ants and fungi. This comparison shows that-although common factors for the ultimate evolutionary stability of mutualisms can be identified-the proximate mechanisms can be fundamentally different between different mutualisms.

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Section: Discussionmentioning

confidence: 60%

As you reap, so shall you sow: coupling of harvesting and inoculating stabilizes the mutualism between termites and fungi

Aanen¹

2006

Biol. Lett.

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“…They developed a sophisticated mutualistic symbiosis with a kind of fungi ( Termitomyces spp., Basidiomycotina), which they cultivate on combs constructed from faecal material within their nests (Johnson et al 1981; Wood and Thomas 1989). This symbiosis firstly occurred with no reversions to free-living states (Aanen et al 2002) at least 31 million years ago (Nobre et al 2011) and is obligate for both partners: the termites provide a constant, highly regulated growth environment for their fungal symbionts, while the fungi provide food for the termites. Fungi are cultivated on combs constructed from faecal material within termites’ nests (Wood and Thomas 1989).…”

Section: Introductionmentioning

confidence: 99%

Diversity, phenology and distribution of Termitomyces species in Côte d’Ivoire

et al. 2018

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The mutualistic symbiosis between termites of the Macrotermitinae subfamily (Isoptera: Termitidae) and fungi of the genus Termitomyces (Basidiomycota: Lyophyllaceae) is of great ecological and socio-economic importance. Seasonal fruit bodies of the symbiotic fungi are regularly collected and sold in Côte d’Ivoire. However, there are very few studies on their diversity, phenology, distribution and especially the socio-economic scope of the fruit bodies of these fungi at a national scale. This study aims at (i) assessing the diversity of Termitomyces fruit bodies in Côte d’Ivoire and (ii) mapping their fructification areas through a determination of their spatiotemporal distribution according to a climatic and phytogeographic gradients. Using ethnomycological surveys all over the Ivorian territory, information was collected from rural populations on the fructification of Termitomyces and their socio-economic importance. Based on these surveys, sampling efforts of these fungi were properly structured and oriented. The results revealed a diversity of 16 species of Termitomyces, including 9 species new to Côte d’Ivoire and 2 probably new to science. Five species were found in the forest zone, nine in theGuinean savannah zone and four in the Sudano-Guinean zone. Termitomyces’s fructifications were observed throughout the year, with specific period for each species. All listed species are regularly consumed by populations. However, only Termitomyces letestui (Pat.) R. Heim and Termitomyces schimperi (Pat.) R. Heim are marketed on a relatively large scale.

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“…Through horizontal transmission, a given fungal species can establish symbiotic relationship with several termite species within a genus (Aanen et al 2002). Evidence for the dominant role of horizontal transmission of Termitomyces genotypes has been found in sequence analyses of Termitomyces .…”

Section: Macrofungi In Mutualistic Relationships With Animalsmentioning

confidence: 99%

“…Furthermore, by analyzing the relationships between several termite species from Asia and their associated Termitomyces fungi, Taprab et al (2002) discovered that the symbiotic fungal species and their distribution paralleled those of the termites. Similarly, Aanen et al (2002) investigated 32 termite species in 9 genera from Asia and Africa and their associated Termitomyces fungi. The results showed that the symbiosis has a single African origin, with no evidence for secondary domestication of other fungi or the reversal of mutualistic fungi to a free-living state.…”

Section: Macrofungi In Mutualistic Relationships With Animalsmentioning

confidence: 99%

“…The results showed that the symbiosis has a single African origin, with no evidence for secondary domestication of other fungi or the reversal of mutualistic fungi to a free-living state. The two phylogenetic trees, one for termites and the other one for fungi, both showed five main clades with an one-to-one correspondence (Aanen et al 2002). Together, these studies suggest that major splits have occurred simultaneously in the termites and fungi in their long co-evolutionary process.…”

Section: Macrofungi In Mutualistic Relationships With Animalsmentioning

confidence: 99%

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Diversity, population genetics, and evolution of macrofungi associated with animals

Tang

Zhang

et al. 2015

Mycology

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Macrofungi refers to all fungi that produce visible fruiting bodies. These fungi are evolutionarily and ecologically very divergent. Evolutionarily, they belong to two main phyla, Ascomycota and Basidiomycota, and many of them have relatives that cannot form visible fruiting bodies. Ecologically, macrofungi can be associated with dead organic matter, plants, and animals. Here we review our current understanding of population structure and biogeography of macrofungi associated with animals. Their interactions, functions, and patterns of coevolution are described and discussed. Our focus is on studies using molecular markers. Our analyses suggest that the types of fungi–animal associations play an important role in the structure of these animal-associated fungal populations.

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The evolution of fungus-growing termites and their mutualistic fungal symbionts

Cited by 382 publications

References 31 publications

As you reap, so shall you sow: coupling of harvesting and inoculating stabilizes the mutualism between termites and fungi

As you reap, so shall you sow: coupling of harvesting and inoculating stabilizes the mutualism between termites and fungi

Diversity, phenology and distribution of Termitomyces species in Côte d’Ivoire

Diversity, population genetics, and evolution of macrofungi associated with animals

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