<i>In vitro</i> evidence of root colonization suggests ecological versatility in the genus <i>Mycena</i>

Thoen, Ella; Harder, Christoffer Bugge; Kauserud, Håvard; Botnen, Synnøve Smebye; Vik, Unni; Taylor, Andy F. S.; Menkis, Audrius; Skrede, Inger

doi:10.1111/nph.16545

Cited by 44 publications

(43 citation statements)

References 77 publications

(139 reference statements)

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“…1b ). This is consistent with recent estimates (78–110 7 and mean 125 1 Mya) and overlaps with the initial rise and diversification of angiosperms 22 , suggesting that they are ecologically associated with fungi acting as saprotrophs or mycorrhizal partners 3 . Finally, the age of bioluminescence which was also the age of functional luciferase in fungi was estimated to originate around 160 million years ago during the late Jurassic ( Fig.…”

Section: Resultssupporting

confidence: 90%

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Mycena genomes resolve the evolution of fungal bioluminescence

Lee

Lin

et al. 2020

Preprint

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24Mushroom-forming fungi in the order Agaricales represent an independent origin of 25 bioluminescence in the tree of life, yet the diversity, evolutionary history, and timing of 26 the origin of fungal luciferases remain elusive. We sequenced the genomes and 27transcriptomes of five bonnet mushroom species (Mycena spp.), a diverse lineage 28comprising the majority of bioluminescent fungi. We show that bioluminescence 29 evolved in the common ancestor of Mycena spp. and the marasmioid clade of 30Agaricales and was maintained through at least 160 million years of evolution. We 31revealed Mycena exhibit two-speed genomes and resolve how the luciferase cluster was 32 derived by duplication and translocation, frequently rearranged and lost in most Mycena 33 species, but conserved in the Armillaria lineage. Luciferase cluster members were co-34 expressed across developmental stages, with highest expression in fruiting body caps 35and stipes, suggesting fruiting-related adaptive functions. Our results contribute to 36 understanding a de novo origin of bioluminescence and the corresponding gene cluster 37 in a diverse group of enigmatic fungal species. 38

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Section: Resultssupporting

confidence: 90%

“…1a ), and a gilled or porioid hymenophore 2 . Mycena also have a diversity of life history strategies; while many species are saprotrophic, they can be pathogens as well as mycorrhizal 3 . Despite its vast diversity of lifestyles and phenotypes, there are many outstanding questions concerning the basic biology, ecology and genomics of this genus.…”

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confidence: 99%

Mycena genomes resolve the evolution of fungal bioluminescence

Lee

Lin

et al. 2020

Preprint

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“…High temperatures that are measured in the region in summer [27] and closeness to a water body (flooding or exposure to airborne water from river surface evaporation) may have favored the decomposition of SOM in June/August and, therefore, the establishment of root associations with fungi with high decomposing abilities that would increase plant N intake [110]. It has been confirmed that some saprotrophic fungi (also detected here) can indeed establish a facultative biotrophic relationship with roots [81,88,111]. On the other hand, alkaline soil environment (as detected here) has rarely been connected to ECM domination [7,112].…”

Section: Dominance Of Saprotrophs and Symbiotrophs Across The Seasonssupporting

confidence: 70%

“…and Sebacina sp., as well as endophytes like Cladophialophora sp., Humicola sp., Mycena sp., Mortierella sp.) were commonly detected in ectomycorizomes of black truffle-producing habitats [72,81]. However, Cennococum sp., Entholoma sp., Phallus sp., which were common in autumn black truffle-producing soils are assumed to be more frequent in dry or acidic soils [13,72].…”

Section: Root-associated Fungal Communities In Balkan Riparian Forestmentioning

confidence: 99%

“…Highly porous, low aggregated soil with very low total N pool probably trapped in scarce OM ( Supplementary Table S1) may have caused a general shortage of N availability in the upper soil layer of this site in warm seasons [7,107]. Endophytes can transform organic nitrogen to inorganic forms in the rhizosphere, making the nutrient available to their hosts [81,108,109]. High temperatures that are measured in the region in summer [27] and closeness to a water body (flooding or exposure to airborne water from river surface evaporation) may have favored the decomposition of SOM in June/August and, therefore, the establishment of root associations with fungi with high decomposing abilities that would increase plant N intake [110].…”

Section: Dominance Of Saprotrophs and Symbiotrophs Across The Seasonsmentioning

confidence: 99%

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Root-Associated Mycobiome Differentiate between Habitats Supporting Production of Different Truffle Species in Serbian Riparian Forests

et al. 2020

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Balkan lowlands bordering with the Pannonia region are inhabited by diverse riparian forests that support production of different truffle species, predominantly the most prized white truffle of Piedmont (Tuber magnatum Pico), but also other commercial species (T.macrosporum Vitt., T. aestivum Vitt.). Surprisingly, little is known about the native root-associated mycobiome (RAM) of these lowland truffle-producing forests. Therefore, in this study we aim at exploring and comparing the RAMs of three different truffle-producing forests from Kolubara river plane in Serbia. Molecular methods based on next generation sequencing (NGS) were used to evaluate the diversity of root-associated fungal communities and to elucidate the influence of environmental factors on their differentiation. To our knowledge, this is the first study from such habitats with a particular focus on comparative analysis of the RAM in different truffle-producing habitats using a high-throughput sequencing approach. Our results indicated that the alpha diversity of investigated fungal communities was not significantly different between different truffle-producing forests and within a specific forest type, while the seasonal differences in the alpha diversity were only observed in the white truffle-producing forests. Taxonomic profiling at phylum level indicated the dominance of fungal OTUs belonging to phylum Ascomycota and Basidiomycota, with very minor presence of other phyla. Distinct community structures of root-associated mycobiomes were observed for white, mixed, and black truffle-producing forests. The core mycobiome analysis indicated a fair share of fungal genera present exclusively in white and black truffle-producing forest, while the core genera of mixed truffle-producing forests were shared with both white and black truffle-producing forests. The majority of detected fungal OTUs in all three forest types were symbiotrophs, with ectomycorrhizal fungi being a dominant functional guild. Apart from assumed vegetation factor, differentiation of fungal communities was driven by factors connected to the distance from the river and exposure to fluvial activities, soil age, structure, and pH. Overall, Pannonian riparian forests appear to host diverse root-associated fungal communities that are strongly shaped by variation in soil conditions.

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Mushroom Pigments and Their Applications

Téllez‐Téllez¹,

Díaz‐Godínez²

2022

Biomolecules From Natural Sources

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In vitro evidence of root colonization suggests ecological versatility in the genus Mycena

Cited by 44 publications

References 77 publications

Mycena genomes resolve the evolution of fungal bioluminescence

Mycena genomes resolve the evolution of fungal bioluminescence

Root-Associated Mycobiome Differentiate between Habitats Supporting Production of Different Truffle Species in Serbian Riparian Forests

Mushroom Pigments and Their Applications

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