Trees, fungi and bacteria: tripartite metatranscriptomics of a root microbiome responding to soil contamination

González, Emmanuel; Pitre, Frédéric E.; Pagé, Antoine; Marleau, Julie; Nissim, Werther Guidi; St‐Arnaud, Marc; Labrecque, Michel; Joly, Simon; Yergeau, Étienne; Brereton, Nicholas J. B.

doi:10.1186/s40168-018-0432-5

Cited by 93 publications

(80 citation statements)

References 223 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Default recommended annotation uses four sequence repositories with strict BLASTn criteria (>99% identity and coverage) providing each amplicon with up to four pools of labels from: NCBI‐curated bacterial and Archaea RefSeq, NCBI nr/nt, SILVA and Ribosomal Database Project (RDP). Annotation selection against the four databases is based on de novo metatranscriptomics strategy (Brereton et al ., ; Gonzalez et al ., ), where all potential annotation is retained to allow for informed annotation selection and downstream interpretation. BLASTn returns with a query identity and coverage <99% are discarded and the highest identity/coverage scores are selected per query.…”

Section: Methodsmentioning

confidence: 99%

“…BLASTn returns with a query identity and coverage <99% are discarded and the highest identity/coverage scores are selected per query. When the highest identity/coverage for a given high‐count sequence is shared amongst different blast returns from a database, all are retained as equally ‘good’ annotation and designated as ambiguous hits (borrowed from the idea of secondary annotation in metatranscriptomics [Brereton et al ., ; Gonzalez et al ., )]. Accurately reporting ambiguity is important as fragments of a specific 16S rRNA gene [or a gene's entire sequence (Vetrovsky and Baldrian, )] are sometimes 100% similar between known species; the relative utility of a specific amplicon as a barcode therefore varies based on the species present in a sample as well as the technology used for sequencing and data processing.…”

Section: Methodsmentioning

confidence: 99%

See 1 more Smart Citation

ANCHOR: a 16S rRNA gene amplicon pipeline for microbial analysis of multiple environmental samples

González

Pitre

Brereton

2019

Environmental Microbiology

View full text Add to dashboard Cite

SummaryAnalysis of 16S ribosomal RNA (rRNA) gene amplification data for microbial barcoding can be inaccurate across complex environmental samples. A method, ANCHOR, is presented and designed for improved species‐level microbial identification using paired‐end sequences directly, multiple high‐complexity samples and multiple reference databases. A standard operating procedure (SOP) is reported alongside benchmarking against artificial, single sample and replicated mock data sets. The method is then directly tested using a real‐world data set from surface swabs of the International Space Station (ISS). Simple mock community analysis identified 100% of the expected species and 99% of expected gene copy variants (100% identical). A replicated mock community revealed similar or better numbers of expected species than MetaAmp, DADA2, Mothur and QIIME1. Analysis of the ISS microbiome identified 714 putative unique species/strains and differential abundance analysis distinguished significant differences between the Destiny module (U.S. laboratory) and Harmony module (sleeping quarters). Harmony was remarkably dominated by human gastrointestinal tract bacteria, similar to enclosed environments on earth; however, Destiny module bacteria also derived from nonhuman microbiome carriers present on the ISS, the laboratory's research animals. ANCHOR can help substantially improve sequence resolution of 16S rRNA gene amplification data within biologically replicated environmental experiments and integrated multidatabase annotation enhances interpretation of complex, nonreference microbiomes.

show abstract

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

ANCHOR: a 16S rRNA gene amplicon pipeline for microbial analysis of multiple environmental samples

González

Pitre

Brereton

2019

Environmental Microbiology

View full text Add to dashboard Cite

show abstract

“…These mechanisms are thought to enable holobionts to adapt within a single or a few generations (Voss et al, 2015;Rosenberg and Zilber-Rosenberg, 2016). It has recently been shown that the response of willows to stressful conditions (soil contamination) results in large shifts in the metatranscriptome of root and rhizosphere bacterial and fungal communities, but not in the plant root transcriptome (Gonzalez et al, 2018;Yergeau et al, 2018). Taken together, these results emphasize the importance of the plant microbiota in the response to environmental stresses and confirms that microbiota manipulation is a viable alternative to optimize phytoremediation (El Amrani et al, 2015;Quiza et al, 2015).…”

Section: Microbes As Hydrocarbon Degradersmentioning

confidence: 65%

“…The rhizosphere microbes, especially bacteria, are thought to be the major players in organic contaminant degradation during rhizoremediation (Bell et al, 2014a,b;El Amrani et al, 2015), and recent plant-microbe metatranscriptomic studies confirmed that the hydrocarbon degradation genes expressed in the root-rhizosphere environment were mostly linked to bacteria (Gonzalez et al, 2018;Yergeau et al, 2018) (Box 1). Petroleum hydrocarbon contamination is often composed of a mixture of saturated aliphatic (alkanes) and aromatic hydrocarbons (including polycyclic aromatic hydrocarbons, PAHs).…”

Section: (A) (B)mentioning

confidence: 99%

Rhizoremediation of petroleum hydrocarbons: a model system for plant microbiome manipulation

Correa-García

Pande

Séguin

et al. 2018

Microbial Biotechnology

101

View full text Add to dashboard Cite

SummaryPhytoremediation is a green and sustainable alternative to physico‐chemical methods for contaminated soil remediation. One of the flavours of phytoremediation is rhizoremediation, where plant roots stimulate soil microbes to degrade organic contaminants. This approach is particularly interesting as it takes advantage of naturally evolved interaction mechanisms between plant and microorganisms and often results in a complete mineralization of the contaminants (i.e. transformation to water and CO 2). However, many biotic and abiotic factors influence the outcome of this interaction, resulting in variable efficiency of the remediation process. The difficulty to predict precisely the timeframe associated with rhizoremediation leads to low adoption rates of this green technology. Here, we review recent literature related to rhizoremediation, with a particular focus on soil organisms. We then expand on the potential of rhizoremediation to be a model plant‐microbe interaction system for microbiome manipulation studies.

show abstract

“…Transcripts with E values < 1e‐6 were kept. The E ‐value cut‐off was selected based on previous studies (Hesse et al ., ; Quandt et al ., ; Comtet‐Marre et al ., ; Meiser et al ., ; Gonzalez et al ., ) and after manual examination of a subset of sequences and their BLASTX results. To gain more taxonomic information and to confirm that the selected transcripts really belong to fungi, transcripts were first translated into proteins with Transdecoder (Haas et al ., ) and an additional round of BLASTP against the NCBI Non‐Redundant (NR) protein database was performed, saving the top five hits.…”

Section: Methodsmentioning

confidence: 99%

Differential gene expression associated with fungal trophic shifts along the senescence gradient of the moss Dicranum scoparium

Chen

Liao

Bellenger

et al. 2019

Environmental Microbiology

View full text Add to dashboard Cite

Summary Bryophytes harbour microbiomes, including diverse communities of fungi. The molecular mechanisms by which perennial mosses interact with these fungal partners along their senescence gradients are unknown, yet this is an ideal system to study variation in gene expression associated with trophic state transitions. We investigated differentially expressed genes of fungal communities and their host Dicranum scoparium across its naturally occurring senescence gradient using a metatranscriptomic approach. Higher activity of fungal nutrient‐related (carbon, nitrogen, phosphorus and sulfur) transporters and Carbohydrate‐Active enZyme (CAZy) genes was detected toward the bottom, partially decomposed, layer of the moss. The most prominent variation in the expression levels of fungal nutrient transporters was from inorganic nitrogen‐related transporters, whereas the breakdown of organonitrogens was detected as the most enriched gene ontology term for the host D. scoparium, for those transcripts having higher expression in the partially decomposed layer. The abundance of bacterial rRNA transcripts suggested that more living members of Cyanobacteria are associated with the photosynthetic layer of D. scoparium, while members of Rhizobiales are detected throughout the gametophytes. Plant genes for specific fungal–plant communication, including defense responses, were differentially expressed, suggesting that different genetic pathways are involved in plant‐microbe crosstalk in photosynthetic tissues compared to partially decomposed tissues.

show abstract

Trees, fungi and bacteria: tripartite metatranscriptomics of a root microbiome responding to soil contamination

Cited by 93 publications

References 223 publications

ANCHOR: a 16S rRNA gene amplicon pipeline for microbial analysis of multiple environmental samples

ANCHOR: a 16S rRNA gene amplicon pipeline for microbial analysis of multiple environmental samples

Rhizoremediation of petroleum hydrocarbons: a model system for plant microbiome manipulation

Differential gene expression associated with fungal trophic shifts along the senescence gradient of the moss Dicranum scoparium

Contact Info

Product

Resources

About