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Mixotrophy in orchids: facts, questions, and perspectives

Marc‐André Selosse, Pierre‐Louis Alaux, Lara Deloche, Étienne Delannoy, Julita Minasiewicz, Spyros Tsiftsis, Tomas Figura, Florent Martos

2025New Phytologist10 citationsDOIOpen Access PDF

Abstract

Summary While orchids germinate thanks to carbon from their symbiotic fungi, variable carbon exchanges exist between adult orchids and their mycorrhizal fungi. Although some truly autotrophic orchids reward their fungi with carbon at adulthood, some species remain achlorophyllous and fully dependent on fungal carbon (mycoheterotrophy). Others are photosynthetic but also import fungal carbon: The so‐called mixotrophic (MX) orchids rely on fungi of diverse taxonomy and ecology. Here, we classify MX nutrition of orchids into three types. Type I mixotrophy associates with diverse Asco‐ and Basidiomycota that are either saprotrophic or ectomycorrhizal, entailing enrichment of the orchids in 2 H, 13 C, and 15 N. The two other types associate with rhizoctonias, a polyphyletic assemblage of Basidiomycotas that is ancestrally mycorrhizal in orchids. Type II mixotrophy associates with rhizoctonias that secondarily evolved into saprotrophic or ectomycorrhizal ecology, and thus enrich the orchid in 2 H, 13 C, and 15 N. Type III mixotrophy, which remains debated, associates with rhizoctonias that have retained their ancestral lifestyle, that is saprotrophic and/or endophytic in nonorchids, and only entail orchid enrichment in 2 H and 15 N. Based on a case study of achlorophyllous variants in Mediterranean Ophrys and on published data, we discuss the distinct nature and research perspectives of type III mixotrophy.

Topics & Concepts

BiologyOrchidaceaeMixotrophBotanyEcologyAutotrophHeterotrophBacteriaGeneticsPlant and animal studiesMycorrhizal Fungi and Plant InteractionsEcology and Vegetation Dynamics Studies
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