In Vitro Symbiotic Germination: A Revitalized Heuristic Approach for Orchid Species Conservation

Pujasatria, Galih Chersy; Miura, Chihiro; Kaminaka, Hironori

doi:10.3390/plants9121742

Cited by 13 publications

(12 citation statements)

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“…However, many orchid species are listed as endangered owing to habitat degradation and dependence on other organisms, i.e., pollinators (Suetsugu et al 2015;Freitas et al 2020). Moreover, establishing orchids in the natural habitat is always complicated, even in suitable conditions (Pujasatria et al 2020). Due to its unique, one-of-a-kind traits, orchid seed germination is often hard to occur naturally.…”

Section: Introductionmentioning

confidence: 99%

“…Consequently, orchids' seeds are nearly impossible to germinate without nutritional support. For seeds to successfully germinate and grow into mature plants, they must establish orchid mycorrhizal (OM) symbiosis (Arditti and Ghani 2000; Barthlott et al 2014;Yeh et al 2019;Pujasatria et al 2020). Colonization of orchid mycorrhizal fungi (OMF) starts at seed germination and may last until adulthood.…”

Section: Introductionmentioning

confidence: 99%

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Orchid mycorrhizal fungi and ascomycetous fungi in epiphytic Vanda falcata roots occupy different niches during growth and development

Pujasatria

Nishiguchi²,

Miura

et al. 2022

Mycorrhiza

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Epiphytic orchids are commonly found in exposed environments, which plausibly lead to different root fungal community structures from terrestrial orchids. Until recently, no studies have been conducted to show the fungal community structure during the growth of a photosynthetic and epiphytic orchid in its natural growing state. In this study, the Vanda falcata (commonly known as Neofinetia falcata), one of Japan's ornamental orchids, was used to characterize the fungal community structure at different developmental stages. Amplicon sequencing analysis showed that all development stages contain a similar fungal community: Ascomycota dominates half of the community while one-third of the community is Basidiomycota. Rhizoctonia-like fungi, a term to group the most common basidiomycetous fungi that form orchid mycorrhiza, exist even in a smaller portion (around a quarter) compared to other Basidiomycota members. While ascomycetous fungi exhibit pathogenicity, two Ceratobasidium strains isolated from young and adult plants could initiate seed germination in vitro. It was also found that the colonization of mycorrhizal fungi was concentrated in the lower part of the root where it directly attaches to the phorophyte bark, while ascomycetous fungi were distributed in the velamen but never colonized cortical cells.Additionally, lower root parts attached to the bark have denser exodermal passage cells, and these cells were colonized only by mycorrhizal fungi that further infiltrated the cortical area.Therefore, we propose that physical regulation of fungal entry to partition the ascomycetes and mycorrhizal fungi results in the balanced mycorrhizal symbiosis in this orchid.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Orchid mycorrhizal fungi and ascomycetous fungi in epiphytic Vanda falcata roots occupy different niches during growth and development

Pujasatria

Nishiguchi²,

Miura

et al. 2022

Mycorrhiza

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“…Most orchids associate with Rhizoctonia- like fungi, a broad term for several genera resembling the anamorphic morphology of Rhizoctonia . As symbionts, there are three genera in this group: Ceratobasidium, Serendipita (often associated with Sebacina sensu lato ), and Tulasnella (Rasmussen et al 2015; Yeh et al 2019; Pujasatria et al 2020). Originally, those fungi are saprophytic, endophytic, or even pathogenic.…”

Section: Introductionmentioning

confidence: 99%

“…Originally, those fungi are saprophytic, endophytic, or even pathogenic. However, among those genera, many species were isolated from orchid roots and proved to be mycorrhizal upon co-inoculation with seeds of respective orchid species (Pujasatria et al 2020).…”

Section: Introductionmentioning

confidence: 99%

Regulation of balanced root fungal community of Vanda falcata (Orchidaceae) by partitioning its mycorrhizal fungi and ascomycetous fungi across growth and development

Pujasatria

Nishiguchi²,

Miura

et al. 2022

Preprint

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Epiphytic orchids are commonly found in exposed environments, which plausibly lead to different root fungal community structures from terrestrial orchids. Until recently, no studies have been conducted to show the fungal community structure during the growth of a photosynthetic and epiphytic orchid in its natural growing state. In this study, the Vanda falcata (commonly known as Neofinetia falcata), one of Japan's ornamental orchids, was used to characterize the fungal community structure at different developmental stages. Amplicon sequencing analysis showed that all development stages contain a similar fungal community: Ascomycota dominates half of the community while one-third of the community is Basidiomycota. Rhizoctonia-like fungi, a term to group the most common basidiomycetous fungi that form orchid mycorrhiza, exist even in a smaller portion (around a quarter) compared to other Basidiomycota members. While ascomycetous fungi exhibit pathogenicity, two Ceratobasidium strains isolated from young and adult plants could initiate seed germination in vitro. It was also found that the colonization of mycorrhizal fungi was concentrated in the lower part of the root where it directly attaches to the phorophyte bark, while ascomycetous fungi were distributed in the velamen but never colonized cortical cells. Additionally, lower root parts attached to the bark have denser exodermal passage cells, and these cells were colonized only by mycorrhizal fungi that further infiltrated the cortical area. Therefore, we propose that physical regulation of fungal entry to partition the ascomycetes and mycorrhizal fungi results in the balanced mycorrhizal symbiosis in this orchid.

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“…Mycorrhizal dependency is the largest hurdle to overcome in orchid propagation as the mycorrhizae provide most of the minerals, nutrients, vitamins, and water needed for germination and seedling development (Herrera et al, 2019 ) and vary in the specificity of their relationship with their orchid hosts (McCormick et al, 2018 ; Li et al, 2021 ). In vitro symbiotic germination has been used for orchid propagation (Pujasatria et al, 2020 ), however, successful propagation requires extensive knowledge of the specific orchid–mycorrhizal interaction, as well as the ability to isolate and grow the fungus, which can take considerable time and effort. Mycorrhizae isolated from the roots of mature plants may not be suitable for inducing seed germination (McCormick et al, 2021 ; Zhao et al, 2021 ), and many orchid mycorrhizal fungi are unculturable axenically, making symbiotic germination impossible (Li et al, 2021 ).…”

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confidence: 99%

The challenges of growing orchids from seeds for conservation: An assessment of asymbiotic techniques

et al. 2022

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Lewis Knudson first successfully germinated orchid seeds asymbiotically on artificial medium in 1922. While many orchid species have since been grown asymbiotically, the tremendous variation in how species respond to artificial medium and growth conditions ex situ has also become apparent in the past century. In this study, we reviewed published journal articles on asymbiotic orchid seed germination to provide a summary of techniques used and to evaluate if these differ between terrestrial and epiphytic species, to identify areas where additional research is needed, and to evaluate whether asymbiotic germination could be used more often in ex situ conservation. We found articles reporting successful asymbiotic germination of 270 species and 20 cultivars across Orchidaceae. Researchers often used different techniques with epiphytic versus terrestrial species, but species‐specific responses to growth media and conditions were common, indicating that individualized protocols will be necessary for most species. The widespread success in generating seedlings on artificial media suggests that asymbiotic techniques should be another tool for the conservation of rare orchid species. Further advances are needed in understanding how to introduce mycorrhizae to axenically grown orchids and to maximize the viability of seedlings reintroduced into natural habitats to fully utilize these methods for conservation.

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In Vitro Symbiotic Germination: A Revitalized Heuristic Approach for Orchid Species Conservation

Cited by 13 publications

References 94 publications

Orchid mycorrhizal fungi and ascomycetous fungi in epiphytic Vanda falcata roots occupy different niches during growth and development

Orchid mycorrhizal fungi and ascomycetous fungi in epiphytic Vanda falcata roots occupy different niches during growth and development

Regulation of balanced root fungal community of Vanda falcata (Orchidaceae) by partitioning its mycorrhizal fungi and ascomycetous fungi across growth and development

The challenges of growing orchids from seeds for conservation: An assessment of asymbiotic techniques

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