Plant family identity distinguishes patterns of carbon and nitrogen stable isotope abundance and nitrogen concentration in mycoheterotrophic plants associated with ectomycorrhizal fungi

Hynson, Nicole A.; Schiebold, Julienne M.-I.; Gebauer, Gerhard

doi:10.1093/aob/mcw119

Cited by 43 publications

(68 citation statements)

References 87 publications

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“…The extent to which OMFs contribute to the support of mature photosynthetic orchids is still an open question and likely varies among species and habitats (Girlanda et al ., ; Sommer et al ., ; Selosse & Martos, ; McCormick & Jacquemyn, ; Liebel et al ., ; Hynson et al ., ). Fungi almost certainly play an important role during periods of vegetative dormancy, a widespread phenomenon where plants, including many orchids, fail to produce any aboveground tissues, but remain physiologically active, during one or more growing seasons (Shefferson et al ., , , , ; Shefferson, ).…”

Section: Effects Of Orchid Mycorrhizal Fungi Abundance On Orchidsmentioning

confidence: 97%

Mycorrhizal fungi affect orchid distribution and population dynamics

2018

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Symbioses are ubiquitous in nature and influence individual plants and populations. Orchids have life history stages that depend fully or partially on fungi for carbon and other essential resources. As a result, orchid populations depend on the distribution of orchid mycorrhizal fungi (OMFs). We focused on evidence that local-scale distribution and population dynamics of orchids can be limited by the patchy distribution and abundance of OMFs, after an update of an earlier review confirmed that orchids are rarely limited by OMF distribution at geographic scales. Recent evidence points to a relationship between OMF abundance and orchid density and dormancy, which results in apparent density differences. Orchids were more abundant, less likely to enter dormancy, and more likely to re-emerge when OMF were abundant. We highlight the need for additional studies on OMF quantity, more emphasis on tropical species, and development and application of next-generation sequencing techniques to quantify OMF abundance in substrates and determine their function in association with orchids. Research is also needed to distinguish between OMFs and endophytic fungi and to determine the function of nonmycorrhizal endophytes in orchid roots. These studies will be especially important if we are to link orchids and OMFs in efforts to inform conservation.

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Section: Effects Of Orchid Mycorrhizal Fungi Abundance On Orchidsmentioning

confidence: 97%

Mycorrhizal fungi affect orchid distribution and population dynamics

2018

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“…After the pioneering work of Gebauer and Meyer () and Trudell et al (), many studies have applied stable isotope analyses to assess the trophic modes of plants (e.g. Bidartondo, Burghardt, Gebauer, Bruns, & Read, ; Abadie et al, ; Tedersoo, Pellet, Kõljalg, & Selosse, ; Zimmer et al, ; Hynson, Preiss, Gebauer, & Bruns, ; Johansson, Mikusinska, Ekblad, & Eriksson, ; Hynson, Schiebold, & Gebauer, ; Jacquemyn, Waud, et al, ). Bidartondo et al (), for example, analysed isotope signatures in several orchid species inhabiting forest habitats and showed that orchids that associated primarily with rhizoctonia fungi were not significantly enriched in 13 C, whereas orchids associated with ectomycorrhizal fungi showed both significant enrichment in 13 C and 15 N. Similarly, Hynson et al () showed evidence for mycoheterotrophy on ectomycorrhizal fungi in several species of the tribe Pyroleae.…”

Section: Trophic Modes: a Continuum From Autotrophy To Mycoheterotrophy?mentioning

confidence: 99%

“…Due to its cryptic manifestation, partial mycoheterotrophy has so far only been confirmed for over 20 species of Orchidaceae (Hynson et al, ; Schiebold et al, ), although it seems much more likely that many more orchid species, if not all, show evidence of partial mycoheterotrophy (Schiebold et al, ). Further evidence for partial mycoheterotrophy has been found in c. 8 species of Ericaceae (within Pyrola, Orthilia and possibly Chimaphila and Moneses ), a single species of Burmanniaceae ( Burmannia coelestis ), and has been suggested for Gentianaceae ( Bartonia virginica and Obolaria virginica ) (Cameron & Bolin, ; but see Hynson, Madsen, et al, ; Hynson, Weiss, et al, ).…”

Section: Multiple Origins Of Full Mycoheterotrophymentioning

confidence: 99%

Mycorrhizal symbioses and the evolution of trophic modes in plants

Jacquemyn

Merckx

2019

Journal of Ecology

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Since the early colonization of land, plants depend, to various extents, on mycorrhizal fungi to meet their nutrient demands. In most mycorrhizal symbioses, plants provide sugars derived from photosynthesis to the fungi, whereas the fungi provide essential minerals to the plant. However, in some plants, the flow of carbon has reversed and the fungi provide carbon to the plants. These plants are called mycoheterotrophs. However, it remains unclear how and under which circumstances trophic modes change and whether transitions in trophic modes are associated with changes in mycorrhizal communities. Here, we review the available literature on mycorrhizal associations and trophic modes in plants. We first outline how trophic modes can be determined and how they differ across plants. We then investigate the evolutionary context under which mycoheterotrophy originated. We also examine the mycorrhizal communities associating with autotrophic, partially mycoheterotrophic and fully mycoheterotrophic plants within different plant families and investigate whether commonalities can be observed. Our overview shows that mycoheterotrophy has originated more than 40 times through evolutionary time and can be found in a wide range of plant groups, including liverworts, lycophytes, ferns, monocots and dicots. Partial mycoheterotrophy appears to be much more common than previously anticipated and represents an almost continuous gradient between autotrophy and full mycoheterotrophy. Comparison of the mycorrhizal communities associating with autotrophic, partial and full mycoheterotrophic plants indicates that, although they share some commonalities, shifts from autotrophy to full mycoheterotrophy are accompanied by either losses or shifts in mycorrhizal partners, suggesting that full or partial loss of photosynthesis selects for different mycorrhizal communities. Synthesis. Partial mycoheterotrophy appears to be much more common than previously thought and represents an almost continuous gradient from autotrophy to full mycoheterotrophy. Evolution to full mycoheterotrophy is challenging as it requires specific adaptations and often a switch to other mycorrhizal partners. More detailed analyses of the functionality of different mycorrhizal systems co‐occurring in the roots of a single plant and the costs of mycorrhizal switching are needed to understand the precise mechanisms leading to full mycoheterotrophy.

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“…In terrestrial communities, plant foliage forms the base of many food chains. Foliage isotope values vary across spatial and temporal scales depending on climate, disturbance, and nutrient availability (Amundson et al, 2003;Craine et al, 2009;Pardo and Nadelhoffer, 2010;Popa-Lisseanu et al, 2015;Moreno et al, 2016;Taki et al, 2017) and with physiological differences between plant species, including variation in photosynthetic pathways (Basu et al, 2015;Courty et al, 2015;Taki et al, 2017) and mycorrhizal associations (Evans, 2001;Craine et al, 2009;Hynson et al, 2016). At longer time scales changes in atmospheric baselines, climate, and habitat succession can all cause progressive change in foliage isotopic signatures (Evans and Belnap, 1999;FoxDobbs et al, 2007;Wang et al, 2007;Taki et al, 2017).…”

Section: Introductionmentioning

confidence: 99%