The evolutionary ecology of myco‐heterotrophy

Bidartondo, Martin I.

doi:10.1111/j.1469-8137.2005.01429.x

Cited by 277 publications

(294 citation statements)

References 128 publications

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“…Fungal endophytes in the genus Phialocephala and the order Helotiales, which may contain some EM species (Vrålstad et al 2002), also appear to be common associates of Pyroleae, though their functional role within the plant roots is unclear. Pyroloids also associate with EM fungal genera and species such as Russula (Zimmer et al 2007;Vincenot et al 2008 and this study), Tricholoma (Tedersoo et al 2007;Vincenot et al 2008) and Rhizopogon salebrosus (this study) that are known to form mycorrhizas with other ericaceous myco-heterotrophs (Bidartondo 2005).…”

Section: Discussionmentioning

confidence: 99%

“…This tripartite interaction between a myco-heterotrophic plant, an autotrophic plant and a shared mycorrhizal fungus is an epiparasitism where the potential fitness costs to the fungus are still unknown (Bidartondo 2005). All mycoheterotrophic epiparasitisms are thought to have evolved from initial tripartite associations between two autotrophic plants sharing at least one mycorrhizal fungus (Bidartondo 2005). However, the ordering of the steps that lead to one plant defaulting on the mycorrhizal mutualism remains the subject of debate.…”

Section: Introductionmentioning

confidence: 99%

“…In the latter group, there are some species that act as carbon sinks and gain carbon via mycorrhizal fungi that they share with surrounding autotrophic plants. This tripartite interaction between a myco-heterotrophic plant, an autotrophic plant and a shared mycorrhizal fungus is an epiparasitism where the potential fitness costs to the fungus are still unknown (Bidartondo 2005). All mycoheterotrophic epiparasitisms are thought to have evolved from initial tripartite associations between two autotrophic plants sharing at least one mycorrhizal fungus (Bidartondo 2005).…”

Section: Introductionmentioning

confidence: 99%

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Evidence of a myco-heterotroph in the plant family Ericaceae that lacks mycorrhizal specificity

Hynson

Bruns

2009

Proc. R. Soc. B.

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Myco-heterotrophy is one of the longest-studied aspects of the mycorrhizal symbiosis, but there remain many critical, unanswered questions regarding the ecology and physiology of myco-heterotrophic plants and their associated fungi. The vast majority of all myco-heterotrophs studied to date have exhibited specificity towards narrow lineages of fungi, but it is unclear whether the loss of photosynthesis in these plants is contingent upon fungal specialization. Here, we examine the fungal associates of the myco-heterotroph Pyrola aphylla (Ericaceae) and its closest green relative Pyrola picta to determine the pattern of mycorrhizal specialization. Our findings show that both plant species associate with a range of root-inhabiting fungi, the majority of which are ectomycorrhizal taxa. This study provides the first example of a eudicotyledonous myco-heterotroph that is a mycorrhizal generalist, indicating that the loss of photosynthesis in myco-heterotrophs is not contingent upon fungal specialization.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Evidence of a myco-heterotroph in the plant family Ericaceae that lacks mycorrhizal specificity

Hynson

Bruns

2009

Proc. R. Soc. B.

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“…Consistent with this finding, several generalist mycorrhizal species have evolved to exploit plant C without providing any benefits (Graham and Abbott 2000;Burleigh et al 2002;Smith et al 2003Smith et al , 2004Koch et al 2006;Violi et al 2007). In contrast, although plants provide up to 20% of their fixed C to their mycorrhizal partners, the benefits of acquiring limiting soil P can result in a net increase in photosynthetic rate that more than defrays this cost (Kaschuk et al 2009), such that plant cheaters appear to be restricted to highly specialized mycoheterophic species that specialize in low-light environments in the forest understory (Bidartondo 2005). In this context, allocating C to mycorrhizal fungi is costly only if the fungal partner fails to offset this investment with a sufficient augmentation of host photosynthetic rate; that is, when a plant associates with cheater fungi (with cost K).…”

Section: Applying the Model To The Mycorrhizal Mutualismmentioning

confidence: 99%

The Coexistence of Hosts with Different Abilities to Discriminate against Cheater Partners: An Evolutionary Game-Theory Approach

Steidinger

Bever

2014

The American Naturalist

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Evolutionary theory predicts that mutualisms based on the reciprocal exchange of costly services should be susceptible to exploitation by cheaters. Consistent with theory, both cheating and discrimination against cheaters are ubiquitous features of mutualisms. Several recent studies have confirmed that host species differ in the extent that they are able to discriminate against cheaters, suggesting that cheating may be stabilized by the existence of susceptible hosts (dubbed "givers"). We use an evolutionary gametheoretical approach to demonstrate how discriminating and giver hosts associating with mutualist and cheater partners can coexist. Discriminators drive the proportion of cheaters below a critical threshold, at which point there is no benefit to investing resources into discrimination. This promotes givers, who benefit from mutualists but allow cheater populations to rebound. We then apply this model to the plant-mycorrhizal mutualism and demonstrate it is one mechanism for generating host-specific responses to mycorrhizal fungal species necessary to generate negative plant-soil feedbacks. Our model makes several falsifiable, qualitative predictions for plant-mycorrhizal population dynamics across gradients of soil phosphorus availability and interhost differences in ability to discriminate. Finally, we suggest applications and limitations of the model with regard to coexistence in specific biological systems.

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“…However, most mutualistic symbioses involve complex patterns of interactions among multiple species pools rather than pairwise specialization (Borowicz and Juliano 1991;Bruns et al 2002;Clay and Schardl 2002;Thompson 2005;Ollerton 2006;Herre et al 2008). Less intimate symbioses characterized by host sharing or symbiont switching frequently produce intricate patterns of complete or partial discord between symbiont phylogenies (e.g., termites and their fungal cultivars [Aanen et al 2002], figs and fig wasps [Machado et al 2005;Herre et al 2008;Jackson et al 2008], yucca moths and yucca [Smith et al 2008], squid and their bioluminescent symbionts [Dunlap et al 2007], lichen symbioses [Piercey-Normore and DePriest 2001;Rikkinen et al 2002], and mycorrhizal symbioses [Bidartondo 2005;Shefferson et al 2007]). A major goal of current efforts is to understand the coevolutionary dynamics of complex mutualistic interactions (Ollerton 2006;Guimarães et al 2007;Jousselin et al 2008).…”

Section: Introductionmentioning

confidence: 99%

Comparative Dating of Attine Ant and Lepiotaceous Cultivar Phylogenies Reveals Coevolutionary Synchrony and Discord

Mikheyev

Mueller

Abbot

2010

The American Naturalist

109

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JSTOR is a not-for-profit service that helps scholars, researchers, and students discover, use, and build upon a wide range of content in a trusted digital archive. We use information technology and tools to increase productivity and facilitate new forms of scholarship. For more information about JSTOR, please contact support@jstor.org.. abstract: The mutualistic symbiosis between fungus-gardening ants and their cultivars has made fundamental contributions to our understanding of the coevolution of complex species interactions. Reciprocal specialization and vertical symbiont cotransmission are thought to promote a pattern of largely synchronous coevolutionary diversification in attines. Here we test this hypothesis by inferring the first time-calibrated multigene phylogeny of the lepiotaceous attine cultivars and comparing it with the recently published fossilanchored phylogeny of the attine ants. While this comparison reveals some possible cases of synchronous origins of ant and fungal clades, there were a number of surprising asynchronies. For example, leafcutter cultivars appear to be significantly younger than the corresponding ant genera. Similarly, a clade of fungi interacting with primitive fungus-gardening ants-thought to be ancestral to the more derived leaf-cutter symbionts-appears instead to be a more recent acquisition from free-living stock. These macroevolutionary patterns are consistent with recent population-level studies suggesting occasional acquisition of novel cultivar types from environmental sources and horizontal transmission of cultivars between different ant species. Horizontal transmission events, even if rare, appear to form loose ecological connections between diffusely coevolving ant and fungus lineages that permit punctuated changes in the topology of the mutualistic ant-fungus interaction network.

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The evolutionary ecology of myco‐heterotrophy

Cited by 277 publications

References 128 publications

Evidence of a myco-heterotroph in the plant family Ericaceae that lacks mycorrhizal specificity

Evidence of a myco-heterotroph in the plant family Ericaceae that lacks mycorrhizal specificity

The Coexistence of Hosts with Different Abilities to Discriminate against Cheater Partners: An Evolutionary Game-Theory Approach

Comparative Dating of Attine Ant and Lepiotaceous Cultivar Phylogenies Reveals Coevolutionary Synchrony and Discord

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