Comparative study of nutritional mode and mycorrhizal fungi in green and albino variants of <i>Goodyera velutina</i>, an orchid mainly utilizing saprotrophic rhizoctonia

Suetsugu, Kenji; Yamato, Masahide; Matsubayashi, Jun; Tayasu, Ichiro

doi:10.1111/mec.15213

Cited by 29 publications

(34 citation statements)

References 44 publications

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“…Our novel discovery will facilitate the progress of further studies focused on mycoheterotrophic evolution using albino mutants in not only Orchidaceae, but also now in Ericaceae. Such studies should provide valuable findings in terms of comparison with the many findings obtained from Orchidaceae (e.g., Abadie et al., ; Roy et al., ; Suetsugu et al., , ; Lallemand et al., ). Further, the albino mutants were fortunately found within the P. japonica species complex, which exhibits morphological similarities and continuous leaf size variation between partially mycoheterotrophic and nearly fully mycoheterotrophic species (Shutoh et al., , ).…”

Section: Discussionmentioning

confidence: 92%

“…Such mutants are known mainly in Orchidaceae, especially in Epipactis (e.g., Salmia, ) and Cephalanthera (e.g., Julou et al., ). The discovery of such albino orchids has provided an ideal model for investigating the evolution of mycoheterotrophy within similar genetic backgrounds (e.g., Abadie et al., ; Roy et al., ; Suetsugu et al., ). Recently, they were also used for studies focusing on genomics or metabolomics (Suetsugu et al., ; Lallemand et al., ).…”

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confidence: 99%

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Evidence for newly discovered albino mutants in a pyroloid: implication for the nutritional mode in the genus Pyrola

Shutoh

Tajima²,

Matsubayashi

et al. 2020

American J of Botany

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Premise Difficulties in comparing extremely divergent features in fully mycoheterotrophic plants with those in closely related chlorophyllous plants have complicated attempts to reveal the evolutionary patterns and processes of fully mycoheterotrophic plants. Albino mutants of partially mycoheterotrophic plants, generally observed in Orchidaceae, have provided an ideal model for investigating the evolution of mycoheterotrophy within similar genetic backgrounds. In 2018, we found a putative albino population of Pyrola (Ericaceae). Here we aimed to reveal the identity of the albino pyroloid and confirm its fully mycoheterotrophic status. Methods To reveal the putative albino pyroloid's identity, we examined its morphology and sequenced its chloroplast DNA. In addition, we assessed the trophic status of the putative albino pyroloid by analyzing chlorophyll fluorescence, chlorophyll concentration, and natural 13C and 15N abundances. Results We identified albino individuals as P. japonica—otherwise a partially mycoheterotrophic species. We confirmed their albino status by their considerably lower chlorophyll fluorescence and concentrations than those of sympatrically occurring chlorophyllous plants. 13C abundance in the albino individuals was significantly higher than in the green individuals of P. japonica. Conclusions This first report of albino mutants from partially mycoheterotrophic species in angiosperms other than orchids will play a valuable role in further studies focused on mycoheterotrophy. For instance, their δ13C and δ15N values represent a reference for fully mycoheterotrophic plants in Pyrola. Our findings also indicate the strong dependence of some leafy Pyrola species on fungal C during their entire life cycle.

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Section: Discussionmentioning

confidence: 92%

mentioning

confidence: 99%

Evidence for newly discovered albino mutants in a pyroloid: implication for the nutritional mode in the genus Pyrola

Shutoh

Tajima²,

Matsubayashi

et al. 2020

American J of Botany

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“…These fungi are involved in initial or partial mycoheterotrophy in leafy Orchidaceae species (Schiebold et al 2018;Stöckel et al 2014). Although rhizoctonia fungi are involved in mycoheterotrophy with the albino forms of usually chlorophyllous orchid species (Suetsugu et al 2019), saprophytic rhizoctonia fungi are only occasionally associated with fully mycoheterotrophic species. This suggests that rhizoctonia fungi possess insufficient physiological functionality to support the growth of full MHPs (Martos et al 2009).…”

Section: Diversity Of Mycobionts In Sap-mhpsmentioning

confidence: 99%

Evolutionary histories and mycorrhizal associations of mycoheterotrophic plants dependent on saprotrophic fungi

2021

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Mycoheterotrophic plants (MHPs) are leafless, achlorophyllous, and completely dependent on mycorrhizal fungi for their carbon supply. Mycorrhizal symbiosis is a mutualistic association with fungi that is undertaken by the majority of land plants, but mycoheterotrophy represents a breakdown of this mutualism in that plants parasitize fungi. Most MHPs are associated with fungi that are mycorrhizal with autotrophic plants, such as arbuscular mycorrhizal (AM) or ectomycorrhizal (ECM) fungi. Although these MHPs gain carbon via the common mycorrhizal network that links the surrounding autotrophic plants, some mycoheterotrophic lineages are associated with saprotrophic (SAP) fungi, which are free-living and decompose leaf litter and wood materials. Such MHPs are dependent on the forest carbon cycle, which involves the decomposition of wood debris and leaf litter, and have a unique biology and evolutionary history. MHPs associated with SAP fungi (SAP-MHPs) have to date been found only in the Orchidaceae and likely evolved independently at least nine times within that family. Phylogenetically divergent SAP Basidiomycota, mostly Agaricales but also Hymenochaetales, Polyporales, and others, are involved in mycoheterotrophy. The fungal specificity of SAP-MHPs varies from a highly specific association with a single fungal species to a broad range of interactions with multiple fungal orders. Establishment of symbiotic culture systems is indispensable for understanding the mechanisms underlying plant–fungus interactions and the conservation of MHPs. Symbiotic culture systems have been established for many SAP-MHP species as a pure culture of free-living SAP fungi is easier than that of biotrophic AM or ECM fungi. Culturable SAP-MHPs are useful research materials and will contribute to the advancement of plant science.

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“…Ceratobasidioid fungi have been previously found to associate with several other orchids including both tropical and temperate species [ 32 – 34 ]. Members of this fungal family have been recognized as important associates in epiphytic orchids belonging to different genera, such as Oncidium [ 35 ], Ionopsis and Tolumnia [ 36 , 37 ], as well as in terrestrial orchids, of both forest and meadow habitats, including Goodyera [ 38 – 40 ], Anacamptis , Cephalanthera and Orchis [ 16 , 34 , 41 ]. Although mycorrhizal associations with Ceratobasidiaceae involve orchids with very different biogeographical and ecological features, the great majority of orchid species that have been found to establish a trophic relationship with Ceratobasidiaceae fungi belong to the same physiological category of green orchids, including species with different degrees of photosynthetic capability, from fully autotrophic to mixotrophic species [ 8 , 42 , 43 ].…”

Section: Discussionmentioning

confidence: 99%

Molecular evidence supports simultaneous association of the achlorophyllous orchid Chamaegastrodia inverta with ectomycorrhizal Ceratobasidiaceae and Russulaceae

Pecoraro¹,

Wang²,

Venturella³

et al. 2020

BMC Microbiol

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Background: Achlorophyllous orchids are mycoheterotrophic plants, which lack photosynthetic ability and associate with fungi to acquire carbon from different environmental sources. In tropical latitudes, achlorophyllous forest orchids show a preference to establish mycorrhizal relationships with saprotrophic fungi. However, a few of them have been recently found to associate with ectomycorrhizal fungi and there is still much to be learned about the identity of fungi associated with tropical orchids. The present study focused on mycorrhizal diversity in the achlorophyllous orchid C. inverta, an endangered species, which is endemic to southern China. The aim of this work was to identify the main mycorrhizal partners of C. inverta in different plant life stages, by means of morphological and molecular methods. Results: Microscopy showed that the roots of analysed C. inverta samples were extensively colonized by fungal hyphae forming pelotons in root cortical cells. Fungal ITS regions were amplified by polymerase chain reaction, from DNA extracted from fungal mycelia isolated from orchid root samples, as well as from total root DNA. Molecular sequencing and phylogenetic analyses showed that the investigated orchid primarily associated with ectomycorrhizal fungi belonging to a narrow clade within the family Ceratobasidiaceae, which was previously detected in a few fully mycoheterotrophic orchids and was also found to show ectomycorrhizal capability on trees and shrubs. Russulaceae fungal symbionts, showing high similarity with members of the ectomycorrhizal genus Russula, were also identified from the roots of C. inverta, at young seedling stage. Ascomycetous fungi including Chaetomium, Diaporthe, Leptodontidium, and Phomopsis genera, and zygomycetes in the genus Mortierella were obtained from orchid root isolated strains with unclear functional role.

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Comparative study of nutritional mode and mycorrhizal fungi in green and albino variants of Goodyera velutina, an orchid mainly utilizing saprotrophic rhizoctonia

Cited by 29 publications

References 44 publications

Evidence for newly discovered albino mutants in a pyroloid: implication for the nutritional mode in the genus Pyrola

Evidence for newly discovered albino mutants in a pyroloid: implication for the nutritional mode in the genus Pyrola

Evolutionary histories and mycorrhizal associations of mycoheterotrophic plants dependent on saprotrophic fungi

Molecular evidence supports simultaneous association of the achlorophyllous orchid Chamaegastrodia inverta with ectomycorrhizal Ceratobasidiaceae and Russulaceae

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