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Journal ArticleDOI

A fine-scale spatial analysis of fungal communities on tropical tree bark unveils the epiphytic rhizosphere in orchids.

Rémi Petrolli1, Conrado Augusto Vieira1, Marcin Jakalski2, Melissa Faust Bocayuva, Clément Vallé1, Everaldo da Silva Cruz, Marc-André Selosse2, Marc-André Selosse1, Florent Martos1, Maria Catarina Megumi Kasuya 
University of Paris1, University of Gdańsk2
01 Sep 2021-New Phytologist (John Wiley & Sons, Ltd)-Vol. 231, Iss: 5, pp 2002-2014
TL;DR: In this article, the authors conducted environmental metabarcoding of the ITS-2 region to understand the spatial structure of fungal communities of the bark of tropical trees, with a focus on epiphytic orchid mycorrhizal fungi.
Abstract: Approximately 10% of vascular plants are epiphytes and, even though this has long been ignored in past research, are able to interact with a variety of fungi, including mycorrhizal taxa. However, the structure of fungal communities on bark, as well as their relationship with epiphytic plants, is largely unknown. To fill this gap, we conducted environmental metabarcoding of the ITS-2 region to understand the spatial structure of fungal communities of the bark of tropical trees, with a focus on epiphytic orchid mycorrhizal fungi, and tested the influence of root proximity. For all guilds, including orchid mycorrhizal fungi, fungal communities were more similar when spatially close on bark (i.e. they displayed positive spatial autocorrelation). They also showed distance decay of similarity with respect to epiphytic roots, meaning that their composition on bark increasingly differed, compared to roots, with distance from roots. We first showed that all of the investigated fungal guilds exhibited spatial structure at very small scales. This spatial structure was influenced by the roots of epiphytic plants, suggesting the existence of an epiphytic rhizosphere. Finally, we showed that orchid mycorrhizal fungi were aggregated around them, possibly as a result of reciprocal influence between the mycorrhizal partners.

Summary (3 min read)

Jump to: [1. Introduction][2.1 Study area][2.2 Bark and root sampling][2.3 High-throughput sequencing of fungal communities][2.5 Fungal functional guilds][2.6 Statistical analyses][3.1 Roots and bark harbored distinct, but partially overlapping fungal communities][3.2 All fungal communities were spatially structured][3.3 Epiphytic roots influenced all fungal communities][4.1 Features of bark fungal communities compared to the soil's][4.5 Fungal communities could modulate epiphytic plant population dynamics] and [4.6 Conclusion and perspectives]

1. Introduction

  • The authors hypothesized that (i) as described in soils, these communities have no random distribution on the bark .
  • Due to the ability of many fungi to colonize plant roots, (ii) their distribution should be modulated by the distance to roots of vascular epiphytes.
  • Particularly, (iii) communities of OMF should be aggregated around their orchid hosts.

2.1 Study area

  • The elevation provides frequent fogs throughout the year, and the humidity is around 80%, even in the dry season.
  • The climate of the region is humid subtropical mesothermic, with temperatures ranging from 17 to 23°C and annual rainfall averaging 1300 mm (Rolim & Ribeiro, 2001) .
  • This forest is characterized by medium to large trees, and a high diversity of orchid species, the majority of which are epiphytic (Lana et al., 2018) .

2.2 Bark and root sampling

  • Two trees belonging to Siparuna sp. (Siparunaceae; tree 1) and Himathanthus sucuuba (Apocynaceae; tree 2) were selected in February 2015 and February 2016 (95 m away from each other) respectively because they had epiphytic orchids growing on their lower trunk, namely Isochilus linearis and Epidendrum armeniacum.
  • Bark was also collected under each root sample.
  • All samples were frozen at -20°C within few hours in the nearby field laboratory of the Serra do Brigadeiro State Park headquarters for downstream molecular analyses.
  • Two additional thin sections of orchid roots surrounding each sampled piece were collected to check for mycorrhizal fungal colonization on the following day under the microscope and all, without exception, displayed hyphal coils in at least one of each inspection section.

2.3 High-throughput sequencing of fungal communities

  • Tagging system negative controls were performed at this step (Hornung et al., 2019; Zinger et al., 2019) , i.e., pairs of barcoded primers were intentionally omitted in the final sequencing to control for cross-contamination.
  • Plate designs were randomized in order to avoid possible cross-contamination leading to misinterpretation in subsequent spatial analysis.
  • After visualization on gel, the positive amplicons were purified with NucleoMag® NGS Clean-up and Size Select (Macherey-Nagel, GmbH & Co KG.), quantified by fluorescence with Qubit TM dsDNA High-Sensitivity (Invitrogen TM ), and pooled in equimolar ratios prior to library preparation and 2x250 bp paired-end sequencing on an Illumina MiSeq platform at Fasteris (Geneva, Switzerland).
  • Three positive controls (mock community) and three negative controls (ultrapure water) were used per PCR trial , resulting in a total of 36 positive and 36 negative controls in total.

2.5 Fungal functional guilds

  • OTUs found in at least one orchid root sample were considered as endophytes.
  • Among them, those Basidiomycota belonging to Tulasnellaceae, Ceratobasidiaceae (Veldre et al., 2013) , Serendipitaceae (Weiß et al., 2016) , and Atractiellales (Kottke et al., 2010) were recognized as orchid mycorrhizal fungi (OMF) (Dearnaley et al., 2012) .
  • Besides, trophic guilds were assigned to all OTUs using FunGuild (Zanne et al., 2019) : the authors chose to keep those which were either exclusively saprotrophs, symbiotrophs, plant pathogens, or lichenized fungi.
  • For the remaining OTUs, guilds provided by FunGuild were validated based on the author's expertise.
  • The OMF were kept in a separate category despite their saprotrophic and symbiotrophic ability (Dearnaley et al., 2012; Selosse & Martos, 2014) .

2.6 Statistical analyses

  • As the similarities between samples are not independent of one another, coefficients of the binomial GLM were obtained using a leave-one-out Jackknife procedure as described in (Millar et al., 2011) .
  • The significance of the distance decay of similarity was tested using a permutational Mantel test (Spearman method, 9999 permutations; Anderson et al., 2013) , while the significance of the distance decay of richness was assessed by ANOVA (F-test).

3.1 Roots and bark harbored distinct, but partially overlapping fungal communities

  • Among the 31 OMF OTUs that were found, encompassing the four OMF families (see 2.5, Fig. 3 ), only five OTUs were shared between the two trees after rarefaction (Table S4 ) and only one OTU (Tulasnellaceae, TUL-1) when considering the roots only (Table S4 , S5).
  • The sharing of OMF between grids was not statistically different to that of other fungi, meaning that the trees harbored different fungal communities overall.
  • On grid 2, where two orchid species co-exist, OMF OTUs belonging to Ceratobasidiaceae (CER-1) and Serendipitaceae (SER-1) were shared between the two species when they were spatially close (Table S5 , Fig. S1 ).

3.2 All fungal communities were spatially structured

  • Spatial autocorrelation of single OTUs showed that only OMF on grid 2 tend to be more frequently spatially clustered than other fungi (Table S6 ).
  • OMF families showed vertical stratification on grid 2 that covered a greater height on the tree (1.7 m), whereas this pattern was not obvious on grid 1 (covering 0.7 m only; Fig. S9 ).

3.3 Epiphytic roots influenced all fungal communities

  • The Jaccard similarity between roots and bark fungal compositions significantly decreased with increasing distance from the roots for the whole fungal community on both grids (Fig. 5 ).
  • This was also observed for endophytes on both grids, for non-OMF symbiotrophs on grid 1 only, and for OMF, plant pathogens and saprotrophs on grid 2 only (Table 1, Fig. 5 ; see also Fig. S10 and Table S8 for details).
  • The distance decay of bark fungal richness showed contrasting results with either non-significant or opposite results between grids (Fig. S12 -14, Table S9 ).
  • By comparing the density distribution of OMF versus endophytes (distance from roots beyond which 80% of the occurrences of a given OTU are limited), the OMF were not statistically closer to roots than other endophytes (Wilcox tests, W = 370, p = 0.423 and W = 1142, p = 0.397 for grid 1 and 2, respectively).

4.1 Features of bark fungal communities compared to the soil's

  • This thinness allowed us to exhaustively sample fungal communities at a given position.
  • Whether these communities are spatially structured or are either homogeneously or randomly distributed remained an open question, which the authors investigated in this study.

4.5 Fungal communities could modulate epiphytic plant population dynamics

  • Here, the OMF were more spatially clustered than any other fungi (Table S6 ), reflected in the vertical stratification on grid 2 (Fig. S9 ), which suggests that they could strongly constrain orchid seed germination.
  • In soil, it has also been proposed that the patchiness of orchid individuals (Jacquemyn et al., 2007) could be due to that of their mycorrhizal partners (Jacquemyn et al., 2012) .

4.6 Conclusion and perspectives

  • The authors observed a vertical niche differentiation for OMF communities, but not for other fungal guilds, probably because their sampling design was not appropriate to investigate such vertical gradients.
  • Yet, a possible trend for lower vertical than horizontal structure was observed.

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A ne-scale spatial analysis of fungal communities on
tropical tree bark unveils the epiphytic rhizosphere in
orchids
Remi Petrolli, Conrado Augusto Vieira, Marcin Jakalski, Melissa F Bocayuva,
Clément Vallé, Everaldo da Silva Cruz, Marc-andré Selosse, Florent Martos,
Maria Catarina M. Kasuya
To cite this version:
Remi Petrolli, Conrado Augusto Vieira, Marcin Jakalski, Melissa F Bocayuva, Clément Vallé, et al.. A
ne-scale spatial analysis of fungal communities on tropical tree bark unveils the epiphytic rhizosphere
in orchids. New Phytologist, Wiley, In press, �10.1111/nph.17459�. �hal-03279090�
1
A fine-scale spatial analysis of fungal communities on tropical tree bark unveils the
1
epiphytic rhizosphere in orchids
2
3
REMI PETROLLI
1*
, CONRADO AUGUSTO VIEIRA
1,2*
, MARCIN JAKALSKI
3
, MELISSA
4
F. BOCAYUVA
2
, CLEMENT VALLE
1
, EVERALDO DA SILVA CRUZ
2
, MARC-ANDRÉ
5
SELOSSE
1,2,3
§
, FLORENT MARTOS
1
§
, MARIA CATARINA M. KASUYA
2
§
6
7
1
Institut de Systématique, Évolution, Biodiversité (ISYEB), Muséum national d’Histoire
8
naturelle, CNRS, Sorbonne Université, EPHE, CP 39, 57 rue Cuvier, F-75005 Paris, France
9
2
Department of Microbiology, Viçosa Federal University (UFV), P. H. Rolfs street CEP:
10
36570-900, Viçosa, Minas Gerais, Brazil
11
3
University of Gdańsk, Faculty of Biology, ul. Wita Stwosza 59, 80-308 Gdańsk, Poland
12
*
These authors contributed equally to this work.
13
§
These authors supervised equally this work.
14
15
Rémi Petrolli (Corresponding author)
16
Muséum National d’Histoire Naturelle
17
UMR 7205, Institut de Systématique, Évolution et Biodiversité (ISYEB),
18
12 rue Buffon, CP 39, 75005 Paris, France
19
Email : remi.petrolli@mnhn.fr
20
21
6162 words: 842 words (Introduction), 1916 words (M&M), 1146 words (Results) and 2258
22
words (Discussion). 5 colored figures, 1 table, and 23 supplementary figures and tables.
23
24
We declare no conflict of interest regarding this work.
25
2
Abstract
26
Approximately 10% of vascular plants are epiphytes and, even though this has long
27
been ignored in past research, can interact with a variety of fungi, including mycorrhizal
28
ones. However, the structure of fungal communities on bark, as well as their relationship
29
with epiphytic plants, is largely unknown.
30
To fill this gap, we conducted environmental metabarcoding of ITS-2 region to
31
understand the spatial structure of fungal communities of the bark of tropical trees, with
32
a focus on epiphytic orchid mycorrhizal fungi, and tested the influence of root
33
proximity.
34
For all guilds, including orchid mycorrhizal fungi, fungal communities were more
35
similar when spatially closed on bark, i.e., displayed positive spatial autocorrelation.
36
They also showed distance decay of similarity from epiphytic roots, meaning that their
37
composition on bark increasingly differed, compared to roots, with distance from roots.
38
We first showed that all the investigated fungal guilds presented a spatial structure at
39
very small scales. This spatial structure was influenced by the roots of epiphytic plants,
40
suggesting the existence of an epiphytic rhizosphere. Finally, we showed that orchid
41
mycorrhizal fungi were aggregated around them, possibly resulting from a reciprocal
42
influence between the mycorrhizal partners.
43
44
45
Key words
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epiphytism; fungal guilds; metabarcoding; fungal spatial distribution; orchid mycorrhizal fungi;
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Tulasnellaceae
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49
50
3
1. Introduction
51
52
Although globally distributed, microorganisms present a highly variable local richness and a
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spatial structure at every scale (from centimeters to thousands of kilometers), especially in soils
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(Green et al., 2004; Green & Bohannan, 2006). Much of the soil microbial biodiversity appears
55
to be intrinsically linked with plants in the rhizosphere and controls their community structure
56
by monitoring soil-root interactions (Bever et al., 2010). Reciprocally, soil microorganisms that
57
develop nutritional and protective symbioses with roots are especially structured by host
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presence and diversity (Peay et al., 2013) such as the mycorrhizal fungi that associate with
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approximately 90% of the vascular land flora (Van Der Heijden et al., 2015; Brundrett &
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Tedersoo, 2018). Fungal metabarcoding studies in soils have shown that the mycorrhizal taxa
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are not randomly distributed, but exhibit spatial structure at rather fine scales, in temperate as
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in tropical systems (Anderson et al., 2014; Bahram et al., 2016; Coince et al., 2013; Pickles et
63
al., 2010; Tedersoo et al., 2010; Zhang et al., 2017), i.e., a patchiness due to host distribution,
64
but also other factors such as spore dispersal and community interactions (Hanson et al., 2012).
65
However, the characterization of the underground distribution of soil fungi (mycorrhizal fungi,
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saprotrophs or pathogens) is complicated by the three-dimensional nature of soils, since
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differences may exist between soil horizons (Anderson et al., 2014; Bahram et al., 2015).
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69
Unlike soils, tree barks can be easily investigated as their multiple layers can be sampled and
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sequenced at once, especially on young trees where the bark is usually thin. Thus, young barks
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can be seen as virtually two-dimensional and are ideal systems for surveying the spatial
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distribution of fungal communities and mycorrhizal taxa around their epiphytic plant hosts.
73
Indeed, ca. 10% of vascular plant species root on barks in the tropical wet forests around the
74
globe (Zotz, 2016). These plants have long been considered as essentially non-mycorrhizal in
75
4
such aerial substrates (Lehnert et al., 2017; Brundrett & Tedersoo, 2018; but see Rowe &
76
Pringle, 2005) and their fungal partners have thus so far largely been ignored. However, there
77
is now growing interest in the field of epiphytic fungal endophytes which could strongly
78
influence the dynamics of epiphyte plant populations (Leroy et al., 2019). One symbiosis that
79
regularly occurs in the epiphytic habitats is the orchid mycorrhiza (Martos et al., 2012; Herrera
80
et al., 2018; Novotná et al., 2018). Epiphytic orchids, representing no less than 80% of this
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hyper-diverse plant family (with over 25 000 species (Givnish et al., 2015)), harbor typical
82
hyphal coils within their root cortical cells, which are formed by the same families but different
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species of saprotrophic basidiomycetes (Dearnaley et al., 2012; Martos et al., 2012; Xing et al.,
84
2019) compared to soil. The fungi are also required for germination of the minute, nutrient-
85
poor orchid seeds (Smith & Read, 2008). It was therefore hypothesized that the distribution of
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orchids must be constrained by that of their mycorrhizal fungi (McCormick & Jacquemyn,
87
2014; McCormick et al., 2018)
88
89
The distribution of orchid mycorrhizal fungi (OMF) has been investigated in soils (Jacquemyn
90
et al., 2014, 2017; McCormick & Jacquemyn, 2014; McCormick et al., 2016, 2018; Voyron et
91
al., 2017), but only marginally on barks (Kartzinel et al., 2013), perhaps because most studies
92
focus on temperate and Mediterranean ecosystems where orchids are strictly terrestrial. For
93
example, two recent studies (Waud et al., 2016b,a) showed a decline in abundance and
94
similarity composition of OMF with distance from adult orchids, which likely explains the
95
patchy distribution of grassland orchids (Jacquemyn et al., 2007, 2014). Still in grassland
96
habitats, Voyron et al., (2017) found that communities of OMF are more similar in nearby soil,
97
i.e., display spatial autocorrelation (Hanson et al., 2012). As for the epiphytic environment,
98
very little is known on the spatial distribution of mycorrhizal fungi on bark [but see (Izuddin et
99
al., 2019) for a first approach]. Similarly, the evolution of their community structure by distance
100
Citations
More filters
Journal ArticleDOI
Structure and specialization of mycorrhizal networks in phylogenetically diverse tropical communities

[...]

Benoît Perez-Lamarque, Rémi Petrolli, Christine Strullu-Derrien, Dominique Strasberg, Hélène Morlon, Marc-André Selosse, Florent Martos 
20 Jul 2022-Environmental microbiome
TL;DR: The root mycobiome plays a fundamental role in plant nutrition and protection against biotic and abiotic stresses as discussed by the authors , and it is known that the numerous fungi involved in root symbioses are often shared between neighboring plants, thus forming complex plant-fungus interaction networks of weak specialization.
Abstract: The root mycobiome plays a fundamental role in plant nutrition and protection against biotic and abiotic stresses. In temperate forests or meadows dominated by angiosperms, the numerous fungi involved in root symbioses are often shared between neighboring plants, thus forming complex plant-fungus interaction networks of weak specialization. Whether this weak specialization also holds in rich tropical communities with more phylogenetically diverse sets of plant lineages remains unknown. We collected roots of 30 plant species in semi-natural tropical communities including angiosperms, ferns, and lycophytes, in three different habitat types on La Réunion island: a recent lava flow, a wet thicket, and an ericoid shrubland. We identified root-inhabiting fungi by sequencing both the 18S rRNA and the ITS2 variable regions. We assessed the diversity of mycorrhizal fungal taxa according to plant species and lineages, as well as the structure and specialization of the resulting plant-fungus networks.The 18S and ITS2 datasets are highly complementary at revealing the root mycobiota. According to 18S, Glomeromycotina colonize all plant groups in all habitats forming the least specialized interactions, resulting in nested network structures, while Mucoromycotina (Endogonales) are more abundant in the wetland and show higher specialization and modularity compared to the former. According to ITS2, mycorrhizal fungi of Ericaceae and Orchidaceae, namely Helotiales, Sebacinales, and Cantharellales, also colonize the roots of most plant lineages, confirming that they are frequent endophytes. While Helotiales and Sebacinales present intermediate levels of specialization, Cantharellales are more specialized and more sporadic in their interactions with plants, resulting in highly modular networks.This study of the root mycobiome in tropical environments reinforces the idea that mycorrhizal fungal taxa are locally shared between co-occurring plants, including phylogenetically distant plants (e.g. lycophytes and angiosperms), where they may form functional mycorrhizae or establish endophytic colonization. Yet, we demonstrate that, irrespectively of the environmental variations, the level of specialization significantly varies according to the fungal lineages, probably reflecting the different evolutionary origins of these plant-fungus symbioses. Frequent fungal sharing between plants questions the roles of the different fungi in community functioning and highlights the importance of considering networks of interactions rather than isolated hosts.

7 citations

Journal ArticleDOI
Compatible and Incompatible Mycorrhizal Fungi With Seeds of Dendrobium Species: The Colonization Process and Effects of Coculture on Germination and Seedling Development

[...]

Guang-Hui Ma, Xiang-Gui Chen, Marc-André Selosse, Jiang-Yun Gao
10 Mar 2022-Frontiers in Plant Science
TL;DR: Zhang et al. as discussed by the authors compared the fungal colonization process among two compatible and two incompatible fungi during seed germination of Dendrobium officinale and found that compatible fungi could effectively promote seed growth up to seedlings, while incompatible fungi may stimulate germination but do not support subsequent seedling development.
Abstract: Orchids highly rely on mycorrhizal fungi for seed germination, and compatible fungi could effectively promote germination up to seedlings, while incompatible fungi may stimulate germination but do not support subsequent seedling development. In this study, we compared the fungal colonization process among two compatible and two incompatible fungi during seed germination of Dendrobium officinale. The two compatible fungi, i.e., Tulasnella SSCDO-5 and Sebacinales LQ, originally from different habitats, could persistently colonize seeds and form a large number of pelotons continuously in the basal cells, and both fungi promoted seed germination up to seedling with relative effectiveness. In contrast, the two incompatible fungi, i.e., Tulasnella FDd1 and Tulasnella AgP-1, could not persistently colonize seeds. No pelotons in the FDd1 treatment and only a few pelotons in the AgP-1 treatment were observed; moreover, no seedlings were developed at 120 days after incubation in either incompatible fungal treatment. The pattern of fungal hyphae colonizing seeds was well-matched with the morphological differentiation of seed germination and seedling development. In the fungal cocultural experiments, for both orchids of D. officinale and Dendrobium devonianum, cocultures had slightly negative effects on seed germination, protocorm formation, and seedling formation compared with the monocultures with compatible fungus. These results provide us with a better understanding of orchid mycorrhizal interactions; therefore, for orchid conservation based on symbiotic seed germination, it is recommended that a single, compatible, and ecological/habitat-specific fungus can be utilized for seed germination.

6 citations

Posted ContentDOI
Structure and specialization of mycorrhizal networks in phylogenetically diverse tropical communities

[...]

Benoît Perez-Lamarque, Rémi Petrolli, Christine Strullu-Derrien, Dominique Strasberg, Hélène Morlon, Marc-André Selosse, Florent Martos 
11 May 2022-bioRxiv
TL;DR: In this article , the root mycobiome plays a fundamental role in plant nutrition and protection against biotic and abiotic stresses, and the diversity of mycorrhizal fungal taxa according to plant species and lineages, as well as the structure and specialization of the resulting plant-fungus networks.
Abstract: Background The root mycobiome plays a fundamental role in plant nutrition and protection against biotic and abiotic stresses. In temperate forests or meadows dominated by angiosperms, the numerous fungi involved in root symbioses are often shared between neighboring plants, thus forming complex plant-fungus interaction networks of weak specialization. Whether this weak specialization also holds in rich tropical communities with more phylogenetically diverse sets of plant lineages remains unknown. We collected roots of 30 plant species in semi-natural tropical communities including angiosperms, ferns, and lycophytes, in three different habitat types on La Réunion island: a recent lava flow, a wet thicket, and an ericoid shrubland. We identified root-inhabiting fungi by sequencing both the 18S rRNA and the ITS2 variable regions. We assessed the diversity of mycorrhizal fungal taxa according to plant species and lineages, as well as the structure and specialization of the resulting plant-fungus networks. Results The 18S and ITS2 datasets are highly complementary at revealing the root mycobiota. According to 18S, Glomeromycotina colonize all plant groups in all habitats forming the least specialized interactions, resulting in nested network structures, while Mucoromycotina ( Endogonales ) are more abundant in the wetland and show higher specialization and modularity compared to the former. According to ITS2, mycorrhizal fungi of Ericaceae and Orchidaceae , namely Helotiales , Sebacinales , and Cantharellales , also colonize the roots of most plant lineages, confirming that they are frequent endophytes. While Helotiales and Sebacinales present intermediate levels of specialization, Cantharellales are more specialized and more sporadic in their interactions with plants, resulting in highly modular networks. Conclusions This study of the root mycobiome in tropical environments reinforces the idea that mycorrhizal fungal taxa are locally shared between co-occurring plants, including phylogenetically distant plants (e.g. lycophytes and angiosperms), where they may form functional mycorrhizae or establish endophytic colonization. Yet, we demonstrate that, irrespectively of the environmental variations, the level of specialization significantly varies according to the fungal lineages, probably reflecting the different evolutionary origins of these plant-fungus symbioses. Frequent fungal sharing between plants questions the roles of the different fungi in community functioning and highlights the importance of considering networks of interactions rather than isolated hosts.

4 citations

Journal ArticleDOI
Mycobiome detection from a single subterranean gametophyte using metabarcoding techniques

[...]

Ko-Hsuan Mandy Chen, Qiao‐Yi Xie, Chiung-Chih Chang, Li-Yaung Kuo
14 Mar 2022-Applications in Plant Sciences
TL;DR: In this article , the mycobiome of the achlorophyllous gametophytes of Ophioderma pendulum using a high-throughput metabarcoding approach was examined.
Abstract: Abstract Premise Several ferns and lycophytes produce subterranean gametophytes, including the Ophioglossaceae, Psilotaceae, and some members of the Schizaeaceae, Gleicheniaceae, and Lycopodiaceae. Despite the surge in plant‐microbiome research, which has been particularly boosted by high‐throughput sequencing techniques, the microbiomes of these inconspicuous fern gametophytes have rarely been examined. The subterranean gametophytes are peculiar due to their achlorophyllous nature, which makes them rely on fungi to obtain nutrients. Furthermore, the factors that shape the fungal communities (mycobiomes) of fern gametophytes have not been examined in depth. Methods and Results We present a workflow to study the mycobiome of the achlorophyllous gametophytes of Ophioderma pendulum using a high‐throughput metabarcoding approach. Simultaneously, each gametophyte was investigated microscopically to detect fungal structures. Two primer sets of the nuclear ITS sequence targeting general fungi were applied, in addition to a primer set that specifically targets the nuclear small subunit ribosomal rDNA region of arbuscular mycorrhizal fungi. Both the microscopic and metabarcoding approaches revealed many diverse fungi inhabiting a single gametophyte of O. pendulum. Discussion This study provides methodological details and discusses precautions for the mycobiome investigation of achlorophyllous gametophytes. This research is also the first to uncover the mycobiome assembly of an achlorophyllous gametophyte of an epiphytic fern.

4 citations

Journal ArticleDOI
What role does the seed coat play during symbiotic seed germination in orchids: an experimental approach with Dendrobium officinale

[...]

Xiang-Gui Chen, Yi Hua Wu, Neng-Qi Li, Jiang-Yun Gao
29 Jul 2022-BMC Plant Biology
TL;DR: In this article , the effects of compatible and incompatible fungi on seed germination, protocorm formation, seedling development, and colonization patterns in Dendrobium officinale were compared.
Abstract: Orchids require specific mycorrhizal associations for seed germination. During symbiotic germination, the seed coat is the first point of fungal attachment, and whether the seed coat plays a role in the identification of compatible and incompatible fungi is unclear. Here, we compared the effects of compatible and incompatible fungi on seed germination, protocorm formation, seedling development, and colonization patterns in Dendrobium officinale; additionally, two experimental approaches, seeds pretreated with NaClO to change the permeability of the seed coat and fungi incubated with in vitro-produced protocorms, were used to assess the role of seed coat played during symbiotic seed germination.The two compatible fungi, Tulasnella sp. TPYD-2 and Serendipita indica PI could quickly promote D. officinale seed germination to the seedling stage. Sixty-two days after incubation, 67.8 ± 5.23% of seeds developed into seedlings with two leaves in the PI treatment, which was significantly higher than that in the TPYD-2 treatment (37.1 ± 3.55%), and massive pelotons formed inside the basal cells of the protocorm or seedlings in both compatible fungi treatments. In contrast, the incompatible fungus Tulasnella sp. FDd1 did not promote seed germination up to seedlings at 62 days after incubation, and only a few pelotons were occasionally observed inside the protocorms. NaClO seed pretreatment improved seed germination under all three fungal treatments but did not improve seed colonization or promote seedling formation by incompatible fungi. Without the seed coat barrier, the colonization of in vitro-produced protocorms by TPYD-2 and PI was slowed, postponing protocorm development and seedling formation compared to those in intact seeds incubated with the same fungi. Moreover, the incompatible fungus FDd1 was still unable to colonize in vitro-produced protocorms and promote seedling formation.Compatible fungi could quickly promote seed germination up to the seedling stage accompanied by hyphal colonization of seeds and formation of many pelotons inside cells, while incompatible fungi could not continuously colonize seeds and form enough protocorms to support D. officinale seedling development. The improvement of seed germination by seed pretreatment may result from improving the seed coat hydrophilicity and permeability, but seed pretreatment cannot change the compatibility of a fungus with an orchid. Without a seed coat, the incompatible fungus FDd1 still cannot colonize in vitro-produced protocorms or support seedling development. These results suggest that seed coats are not involved in symbiotic germination in D. officinale.

3 citations

References
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Journal ArticleDOI
Time to re-think fungal ecology? Fungal ecological niches are often prejudged.

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Marc-André Selosse1, Marc-André Selosse2, Laure Schneider-Maunoury1, Florent Martos1
University of Paris1, University of Gdańsk2
01 Feb 2018-New Phytologist

102 citations

Journal ArticleDOI
Mycorrhizal fungi affect orchid distribution and population dynamics

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Melissa K. McCormick1, Dennis F. Whigham1, Armando Canchani‐Viruet2, Armando Canchani‐Viruet1
Smithsonian Environmental Research Center1, Metropolitan University2
01 Sep 2018-New Phytologist
TL;DR: 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 is highlighted.
Abstract: 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.

94 citations

Journal ArticleDOI
Coexisting orchid species have distinct mycorrhizal communities and display strong spatial segregation.

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Hans Jacquemyn1, Rein Brys1, Vincent S. F. T. Merckx2, Michael Waud1, Bart Lievens1, Thorsten Wiegand3 
Katholieke Universiteit Leuven1, Naturalis2, Helmholtz Centre for Environmental Research - UFZ3
01 Apr 2014-New Phytologist
TL;DR: It is suggested that mycorrhizal fungi are important factors driving niche partitioning in terrestrial orchids and may therefore contribute to orchid coexistence.
Abstract: Summary Because orchids are dependent on mycorrhizal fungi for germination and establishment of seedlings, differences in the mycorrhizal communities associating with orchids can be expected to mediate the abundance, spatial distribution and coexistence of terrestrial orchids in natural communities. We assessed the small-scale spatial distribution of seven orchid species co-occurring in 25 × 25 m plots in two Mediterranean grasslands. In order to characterize the mycorrhizal community associating with each orchid species, 454 pyrosequencing was used. The extent of spatial clustering was assessed using techniques of spatial point pattern analysis. The community of mycorrhizal fungi consisted mainly of members of the Tulasnellaceae, Thelephoraceae and Ceratobasidiaceae, although sporadically members of the Sebacinaceae, Russulaceae and Cortinariaceae were observed. Pronounced differences in mycorrhizal communities were observed between species, whereas strong clustering and significant segregation characterized the spatial distribution of orchid species. However, spatial segregation was not significantly related to phylogenetic dissimilarity of fungal communities. Our results indicate that co-occurring orchid species have distinctive mycorrhizal communities and show strong spatial segregation, suggesting that mycorrhizal fungi are important factors driving niche partitioning in terrestrial orchids and may therefore contribute to orchid coexistence.

92 citations

Journal ArticleDOI
Soilborne fungi have host affinity and host-specific effects on seed germination and survival in a lowland tropical forest

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Carolina Sarmiento1, Paul Camilo Zalamea1, James W. Dalling1, James W. Dalling2, Adam S. Davis3, Simon Maccracken Stump4, Jana M. U'Ren4, A. Elizabeth Arnold4 
Smithsonian Tropical Research Institute1, University of Illinois at Urbana–Champaign2, United States Department of Agriculture3, University of Arizona4
24 Oct 2017-Proceedings of the National Academy of Sciences of the United States of America
TL;DR: It is shown that communities of seed-associated fungi are structured more by plant species than by soil type, forest characteristics, or time in soil, which implicates them directly in the processes that have emerged as critical for diversity maintenance in species-rich tropical forests.
Abstract: The Janzen–Connell (JC) hypothesis provides a conceptual framework for explaining the maintenance of tree diversity in tropical forests. Its central tenet—that recruits experience high mortality near conspecifics and at high densities—assumes a degree of host specialization in interactions between plants and natural enemies. Studies confirming JC effects have focused primarily on spatial distributions of seedlings and saplings, leaving major knowledge gaps regarding the fate of seeds in soil and the specificity of the soilborne fungi that are their most important antagonists. Here we use a common garden experiment in a lowland tropical forest in Panama to show that communities of seed-infecting fungi are structured predominantly by plant species, with only minor influences of factors such as local soil type, forest characteristics, or time in soil (1–12 months). Inoculation experiments confirmed that fungi affected seed viability and germination in a host-specific manner and that effects on seed viability preceded seedling emergence. Seeds are critical components of reproduction for tropical trees, and the factors influencing their persistence, survival, and germination shape the populations of seedlings and saplings on which current perspectives regarding forest dynamics are based. Together these findings bring seed dynamics to light in the context of the JC hypothesis, implicating them directly in the processes that have emerged as critical for diversity maintenance in species-rich tropical forests.

84 citations

Journal ArticleDOI
Ericaceous plant–fungus network in a harsh alpine–subalpine environment

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Hirokazu Toju1, Akifumi S. Tanabe, Hiroshi S. Ishii2
Kyoto University1, University of Toyama2
01 Jul 2016-Molecular Ecology
TL;DR: The results lead to the hypothesis that ericaceous plants in harsh environments can host unexpectedly diverse root‐associated fungal taxa, constituting networks whose structures are similar to those of previously reported ectomycorrhizal networks but not to Those of arbuscular mycorrhIZal ones.
Abstract: In terrestrial ecosystems, plant species and diverse root‐associated fungi form complex networks of host–symbiont associations. Recent studies have revealed that structures of those below‐ground plant–fungus networks differ between arbuscular mycorrhizal and ectomycorrhizal symbioses. Nonetheless, we still remain ignorant of how ericaceous plant species, which dominate arctic and alpine tundra, constitute networks with their root‐associated fungi. Based on a high‐throughput DNA sequencing data set, we characterized the statistical properties of a network involving 16 ericaceous plant species and more than 500 fungal taxa in the alpine–subalpine region of Mt. Tateyama, central Japan. While all the 16 ericaceous species were associated mainly with fungi in the order Helotiales, they varied remarkably in association with fungi in other orders such as Sebacinales, Atheliales, Agaricales, Russulales and Thelephorales. The ericaceous plant–fungus network was characterized by high symbiont/host preferences. Moreover, the network had a characteristic structure called ‘anti‐nestedness’, which has been previously reported in ectomycorrhizal plant–fungus networks. The results lead to the hypothesis that ericaceous plants in harsh environments can host unexpectedly diverse root‐associated fungal taxa, constituting networks whose structures are similar to those of previously reported ectomycorrhizal networks but not to those of arbuscular mycorrhizal ones.

82 citations

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Frequently Asked Questions (1)
Q1. What are the contributions in "A fine-scale spatial analysis of fungal communities on tropical tree bark unveils the epiphytic rhizosphere in orchids" ?

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Trending Questions (2)
What help does a tree give to the orchids?

The paper does not explicitly mention the help that a tree gives to orchids. The paper focuses on the spatial structure of fungal communities on tree bark and their relationship with epiphytic plants, including orchids.

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Is the tree affected by the presence of the orchids?

The paper does not directly address the question of whether the tree is affected by the presence of orchids. The paper focuses on the spatial structure of fungal communities on tree bark and their relationship with epiphytic plants, specifically orchids.

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