Influence of phylogenetic conservatism and trait convergence on the interactions between fungal root endophytes and plants

Kia, Sevda Haghi; Glynou, Kyriaki; Nau, Thomas; Thines, Marco; Piepenbring, Meike

doi:10.1038/ismej.2016.140

Cited by 60 publications

(66 citation statements)

References 83 publications

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“…Hence, these groups seem to be important components of natural root‐endophytic communities, in which they may play relevant functions. Members of these lineages have distinctive sets of life history and functional traits suggestive of complementary niche occupancies, which may favor their frequent co‐occurrence in roots (Kia et al ., ).…”

Section: Discussionmentioning

confidence: 97%

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Facultative root‐colonizing fungi dominate endophytic assemblages in roots of nonmycorrhizal Microthlaspi species

et al. 2017

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There is increasing knowledge on the diversity of root-endophytic fungi, but limited information on their lifestyles and dependence on hosts hampers our understanding of their ecological functions. We compared diversity and biogeographical patterns of cultivable and noncultivable root endophytes to assess whether their occurrence is determined by distinct ecological factors. The endophytic diversity in roots of nonmycorrhizal Microthlaspi spp. growing across Europe was assessed using high-throughput sequencing (HTS) and compared with a previous dataset based on cultivation of endophytes from the same root samples. HTS revealed a large fungal richness undetected by cultivation, but which largely comprised taxa with restricted distributions and/or low representation of sequence reads. Both datasets coincided in a consistent high representation of widespread endophytes within orders Pleosporales, Hypocreales and Helotiales, as well as similar associations of community structure with spatial and environmental conditions. Likewise, distributions of particular endophytes inferred by HTS agreed with cultivation data in suggesting individual ecological preferences. Our findings support that Microthlaspi spp. roots are colonized mostly by saprotrophic and likely facultative endophytes, and that differential niche preferences and distribution ranges among fungi importantly drive the assembly of root-endophytic communities.

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Section: Discussionmentioning

confidence: 97%

“…This observation is reinforced by the variable morphological, physiological and functional traits of phylogenetically distant endophytic fungi that commonly co‐exist in Microthlaspi spp. roots (Kia et al ., ). Interspecies complementarity reduces competition, thereby promoting co‐occurrence in communities (Maherali & Klironomos, ).…”

Section: Discussionmentioning

confidence: 97%

Facultative root‐colonizing fungi dominate endophytic assemblages in roots of nonmycorrhizal Microthlaspi species

et al. 2017

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“…We carefully classified fungi into pathogens and mutualists, and by their host specificity, given the ambiguous life histories in fungi (e.g. switching from asymptomatic occurrence on many plant species to pathogenic behaviour on a very few; Aguilar‐Trigueros, Powell, Anderson, Antonovics, & Rillig, ; Kia et al., ; Kiers et al., ; Klironomos, ). Since the focus of our study was on fungi relevant for P. cembra , we retained exclusively fungal OTUs known to be associated with Pinus .…”

Section: Methodsmentioning

confidence: 99%

Spatial patterns of pathogenic and mutualistic fungi across the elevational range of a host plant

et al. 2018

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Fungi are both agents of disease and mutualistic partners of plants. Previous studies have tested the effects of abiotic or biotic factors on plant‐associated fungal communities in isolation. However, to better understand patterns of plant–fungal associations, the combined effects of abiotic and biotic drivers across environmental gradients may be important. We investigated the effects of temperature, pH, soil moisture, vegetation cover and distance to host plant on the occurrence and abundance of fungi associated with Swiss stone pine (Pinus cembra). We did this by DNA metabarcoding 288 soil samples taken across and beyond the elevation range of P. cembra (i.e. 1,850–2,250 m a.s.l.) in two valleys in the Swiss Alps. We modelled the effects of abiotic and biotic factors on DNA read abundance of pathogenic and mutualistic fungal operational taxonomic units (OTUs) associated with P. cembra. We also tested whether abiotic and biotic factors differentially affected fungi of varying host specificity (i.e. host generalists, host specialists). We found that the occurrences of both host generalist and specialist fungi exceeded the current elevational range of their host plant. Abiotic factors had only minor effects on the abundances of all fungal OTUs. However, we found positive effects of the host plant on the abundance of a host specialist pathogenic fungus, providing support for a Janzen–Connell effect of high pathogen accumulation close to conspecific host plants. We also found a positive response to the host plant in a specialist ectomycorrhizal fungus, suggesting an “inverse” Janzen–Connell effect. Synthesis. Our findings imply that negative distance dependence shapes not only the distribution of host‐specific fungal pathogens, but also host‐specific fungal mutualists. We conclude that the occurrence of both pathogenic and mutualistic fungi beyond the current elevational range of host plants may determine their potential range shifts under projected climate warming.

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“…However, fungi may produce thick‐walled spores in hypogeous fruiting bodies or highly compacted mycelia that provide them with fire resistance (Horton, Cázares & Bruns, ; Tedersoo, Hansen, Perry & Kjøller, ). As evidence suggests that microbial functional traits tend to be phylogenetically conserved (Goberna & Verdú, ; Kia et al., ; Martiny, Treseder & Pusch, ), it could be expected that, similar to plants, the overrepresentation of heat‐resistant microbes would reduce soil microbial phylogenetic diversity immediately after fire. However, existing evidence for bacteria and fungi points the opposite way, as fire increases the phylogenetic diversity of soil microbial communities (Pérez‐Valera et al., ; Rincón, Santamaría‐Pérez, Ocaña & Verdú, ).…”

Section: Introductionmentioning

confidence: 99%

Resilience to fire of phylogenetic diversity across biological domains

et al. 2018

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Fire alters the structure and composition of above- and belowground communities with concurrent shifts in phylogenetic diversity. The inspection of postfire trends in the diversity of ecological communities incorporating phylogenetic information allows to better understand the mechanisms driving fire resilience. While fire reduces plant phylogenetic diversity based on the recruitment of evolutionarily related species with postfire seed persistence, it increases that of soil microbes by limiting soil resources and changing the dominance of competing microbes. Thus, during postfire community reassembly, plant and soil microbes might experience opposing temporal trends in their phylogenetic diversity that are linked through changes in the soil conditions. We tested this hypothesis by investigating the postfire evolution of plant and soil microbial (fungi, bacteria and archaea) communities across three 20-year chronosequences. Plant phylogenetic diversity increased with time since fire as pioneer seeders facilitate the establishment of distantly related late-successional shrubs. The postfire increase in plant phylogenetic diversity fostered plant productivity, eventually recovering soil organic matter. These shifts over time in the soil conditions explained the postfire restoration of fungal and bacterial phylogenetic diversity, which decreased to prefire levels, suggesting that evolutionarily related taxa with high relative fitness recover their competitive superiority during community reassembly. The resilience to fire of phylogenetic diversity across biological domains helps preserve the evolutionary history stored in our ecosystems.

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Influence of phylogenetic conservatism and trait convergence on the interactions between fungal root endophytes and plants

Cited by 60 publications

References 83 publications

Facultative root‐colonizing fungi dominate endophytic assemblages in roots of nonmycorrhizal Microthlaspi species

Facultative root‐colonizing fungi dominate endophytic assemblages in roots of nonmycorrhizal Microthlaspi species

Spatial patterns of pathogenic and mutualistic fungi across the elevational range of a host plant

Resilience to fire of phylogenetic diversity across biological domains

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