The abundance and diversity of arbuscular mycorrhizal fungi are linked to the soil chemistry of screes and to slope in the Alpic paleo-endemic Berardia subacaulis

Casazza, Gabriele; Lumini, Erica; Ercole, Enrico; Dovana, Francesco; Guerrina, Maria; Arnulfo, Annamaria; Minuto, Luigi; Fusconi, Anna; Mucciarelli, Marco

doi:10.1371/journal.pone.0171866

Cited by 49 publications

(37 citation statements)

References 78 publications

(97 reference statements)

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“…In combination with Fig. 8a, it is showed that most AMF biomarkers were enriched at a soil depth of 0-20 cm in samples collected from the bottom of the slope, which may be a consequence of the fact that plant residues typically accumulate on the soil surface [28,30,31], particularly on relatively at bottom slope. Such residues created high soil, nutrient content, good ventilation and hydrothermal conditions, which is very conducive to the growth of soil microorganisms.…”

Section: Relationships Between Soil Amf Diversity and Soil Propertiessupporting

confidence: 53%

High-throughput Sequencing Analysis of the Rhizosphere Arbuscular Mycorrhizal Fungi (AMF) Community Composition Associated with Ferula Sinkiangensis

Luo

et al. 2020

Preprint

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Background: Ferula sinkiangensis is an important and increasingly endangered medicinal plant. Arbuscular mycorrhiza fungi (AMF) are microbes that live in the soil and can enhance nutrient uptake, stress resistance, and pathogen defens in host plants. The composition of AMF communities associated with Ferula sinkiangensis and the relationship between these fungi and other pertinent abiotic factors, however, remains uncertain. Herein, we collected samples of rhizosphere and surrounding soil at a range of depths (0-20, 20-40, and 40-60 cm) and a range of slop positions (bottom, middle, top). These samples were then subjected to analyses of soil physicochemical properties and high-throughput sequencing (Illumina MiSeq), enabling us to examine AMF community composition and diversity, as well as the relationship between these parameters and other abiotic factors. Results: Through this analysis, we determined that Glomus and Diversispora were enriched in all samples. AMF diversity and richness varied significantly as a function of slope position, with this variation primarily being tied to differences in Glomus and Diversispora abundance. In contrast, no significant relationship between soil depth and overall AMF composition was noted, although some AMF were found to be sensitive to depth. Many factors were found to significantly affect AMF community composition, including organic matter (OM), TN (total nitrogen), TK (total potassium), AN (ammonium nitrogen), NN (nitrate nitrogen), AK (available potassium), TDS (total soluble salt), pH, SM (soil water content), and AE (slope position). We further found that Shannon diversity index values in these communities were positively correlated with TP (total phosphorus), NN, and pH values (p<0.05), while TP, TDS, and pH were positively correlated with Chao1 values (p<0.05). Conclusion: In summary, these findings reveal that Glomus and Diversispora are key AMF genera found within the rhizosphere soil of Ferula sinkiangensis. These fungi are closely associated with specific environmental and soil physicochemical properties. And The physical and chemical properties of soil were significantly different (p<0.05) because of slope position. Together, our results provide a novel understanding of the relationship between AMF species and Ferula sinkiangensis, providing a theoretical basis for further studies of their development.

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Section: Relationships Between Soil Amf Diversity and Soil Propertiessupporting

confidence: 53%

High-throughput Sequencing Analysis of the Rhizosphere Arbuscular Mycorrhizal Fungi (AMF) Community Composition Associated with Ferula Sinkiangensis

Luo

et al. 2020

Preprint

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“…Previous studies have investigated AMF communities in the Alps, either based on spore morphology (Read and Haselwandter, ; Oehl et al ., ; Oehl and Körner, ) or on molecular techniques such as DNA fingerprinting and cloning‐sequencing (Sykorová et al ., ; Casazza et al ., ). With the emergence of next‐generation sequencing, and the bypass of cloning steps, it is now possible to study the species diversity and structure of AMF communities in natural populations.…”

Section: Discussionmentioning

confidence: 97%

Biotic and abiotic factors shape arbuscular mycorrhizal fungal communities associated with the roots of the widespread fern Botrychium lunaria (Ophioglossaceae)

Sandoz

Bindschedler

Dauphin

et al. 2020

Environ Microbiol Rep

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Arbuscular mycorrhizal fungi (AMF) play central roles in terrestrial ecosystems by interacting with both above and belowground communities as well as by influencing edaphic properties. The AMF communities associated with the roots of the fern Botrychium lunaria (Ophioglossaceae) were sampled in four transects at 2400 m a.s.l. in the Swiss Alps and analyzed using metabarcoding. Members of five Glomeromycota genera were identified across the 71 samples. Our analyses revealed the existence of a core microbiome composed of four abundant Glomus operational taxonomic units (OTUs), as well as a low OTU turnover between samples. The AMF communities were not spatially structured, which contrasts with most studies on AMF associated with angiosperms. pH, microbial connectivity and humus cover significantly shaped AMF beta diversity but only explained a minor fraction of variation in beta diversity. AMF OTUs associations were found to be significant by both cohesion and co-occurrence analyses, suggesting a role for fungus-fungus interactions in AMF community assembly. In particular, OTU co-occurrences were more frequent between different genera than among the same genus, rising the hypothesis of functional complementarity among the AMF associated to B. lunaria. Altogether, our results provide new insights into the ecology of fern symbionts in alpine grasslands.

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“…In contrast to the almost absence of a mycorrhizal colonization, we found that all the root samples surveyed in this study were frequently colonized by DSEs, which suggested that these fungi were one of the most common fungal colonizers of the roots of the 'nonmycorrhizal' plant families. Increasing evidence showed that DSEs are ubiquitous, occurring in a variety of habitats ranging from South African coastal plains and lowlands to tropical, temperate, subalpine, alpine, maritime Antarctic and arctic zones (Jumpponen & Trappe 1998;Peterson et al 2004;Vohník et al 2015;Casazza et al 2017;Hewitt et al 2017). In fact, the co-existence between DSE and AMF symbionts occupying terrestrial environments have been extensively documented, but more field surveys also supported that a given plant species in specific microhabitats tends to favor the colonization by DSE over AM fungi (Weishampel & Bedford 2006).…”

Section: Discussionmentioning

confidence: 99%

“…Increasing evidence reveals that a miscellaneous group of ascomycetous anamorphic fungi called dark septate endophytes (DSEs), a term broadly classified as conidial and sterile septate fungal endophytes with diverse morphological features such as dark septate hyphae and microsclerotia, dominantly colonize root tissues intracellularly and intercellularly from the tropics to arctic and alpine habitats (Jumpponen & Trappe 1998;Vohník et al 2015;Casazza et al 2017;Hewitt et al 2017). Even under some extreme environments, for example, old slag heaps resulting from the processing of zinc ores, DSE gradually becomes the most prevailing root colonizers with the decreasing AM colonization at increasing environmental stresses (Deram et al 2008(Deram et al , 2011.…”

Section: Introductionmentioning

confidence: 99%

Dark septate endophytes colonizing the roots of ‘non-mycorrhizal’ plants in a mine tailing pond and in a relatively undisturbed environment, Southwest China

Liu

Ding

et al. 2017

Journal of Plant Interactions

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Dark septate endophytes (DSEs), one of the most common fungal colonizers of roots, are considered to overlap in function with mycorrhizal fungi. However, there is little knowledge on the distribution and identity of DSEs in 'non-mycorrhizal' plants. In the current study, colonization and diversity of DSEs colonizing the roots of eight typically 'non-mycorrhizal' families were assessed. In total, 120 root samples of 31 plant species were all colonized by DSEs. Intensity of DSE colonization varied greatly among different plant species, with a range of 0.56-47.56%, 8.13% on average. Cladosporium, Cyphellophora and Phialophora were the dominant genera, with a relative abundance of more than 60% over a total of 90 isolates. Our results showed that diverse DSE species colonized the roots of 'non-mycorrhizal' plants, especially they were more common in degraded mine tailings than in the undisturbed site, but their integral roles to the functional roots are in need of further experimental demonstration.

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The abundance and diversity of arbuscular mycorrhizal fungi are linked to the soil chemistry of screes and to slope in the Alpic paleo-endemic Berardia subacaulis

Cited by 49 publications

References 78 publications

High-throughput Sequencing Analysis of the Rhizosphere Arbuscular Mycorrhizal Fungi (AMF) Community Composition Associated with Ferula Sinkiangensis

High-throughput Sequencing Analysis of the Rhizosphere Arbuscular Mycorrhizal Fungi (AMF) Community Composition Associated with Ferula Sinkiangensis

Biotic and abiotic factors shape arbuscular mycorrhizal fungal communities associated with the roots of the widespread fern Botrychium lunaria (Ophioglossaceae)

Dark septate endophytes colonizing the roots of ‘non-mycorrhizal’ plants in a mine tailing pond and in a relatively undisturbed environment, Southwest China

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