Microdiversity characterizes prevalent phylogenetic clades in the glacier-fed stream microbiome

Fodelianakis, Stilianos; Washburne, Alex D.; Bourquin, Massimo; Pramateftaki, Paraskevi; Kohler, Tyler J.; Styllas, Michael; Tolosano, Matteo; Staercke, Vincent De; Schön, Martina; Busi, Susheel Bhanu; Brandani, Jade; Wilmes, Paul; Peter, Hannes; Battin, Tom J.

doi:10.1038/s41396-021-01106-6

Cited by 31 publications

(66 citation statements)

References 95 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…deterministic and stochastic processes) could simultaneously be influencing community assembly. Other recent approaches have developed models to assign community assembly processes separately to different ‘bins’ of OTUs (Ning et al 2020; Fodelianakis et al 2021), though these methods risk overstating relationships between community processes and perhaps idiosyncratic OTU bins.…”

Section: Methodsmentioning

confidence: 99%

Disturbance by soil mixing decreases microbial richness and supports homogenizing community assembly processes

West

Whitman

2022

Preprint

View full text Add to dashboard Cite

The spatial heterogeneity of soil’s microhabitats warrants the study of ecological patterns and community assembly processes in the context of community coalescence, or the combining and restructuring of communities and their environment. By mixing soil at various frequencies in a 16-week lab incubation, we explored the effects of mixing disturbance on soil bacterial richness, community composition, and community assembly processes. We hypothesized that well-mixed soil would harbor less richness, dominated by homogenizing dispersal and homogeneous selection. Using 16S rRNA gene sequencing, we inferred ecological processes, estimated richness and differential abundance, calculated compositional dissimilarity, and constructed co-occurrence networks. Findings supported our hypotheses, with >20% decrease in soil bacterial richness in well-mixed soil. While soil mixing resulted in increasingly dissimilar communities compared to unmixed soil (Bray-Curtis dissimilarity; 0.75 vs. 0.25), well-mixed soil communities were increasingly self-similar. Our results imply that vast soil diversity may be attributed to the unmixed and spatially heterogeneous nature of soil, and also provide insight into soil communities following coalescence events. By isolating and better understanding the effect of spatial heterogeneity and dysconnectivity on soil microbial communities, we may better extrapolate how anthropogenic disturbances, such as climate change or land use change, may affect broad soil functions.One sentence summarySoil mixing decreases bacterial richness as several taxa dominate the community, providing evidence for homogenizing community assembly processes.

show abstract

Section: Methodsmentioning

confidence: 99%

Disturbance by soil mixing decreases microbial richness and supports homogenizing community assembly processes

West

Whitman

2022

Preprint

View full text Add to dashboard Cite

show abstract

“…However, while capable of identifying assembly processes at levels below the entire community, this approach still investigates processes impacting assembly at the subcommunity level rather than measuring the degree which an individual feature impacts or is impacted by assembly. Fodelianakis et al (2021) instead took an approach, called "phyloscore analysis" that focuses instead on the ecological contributions of specific taxa within a microbial community. Likewise, βNTI feat focuses on individual features to measure their ecological contribution to community dynamics and highlights a point of complementarity across community, subcommunity, and feature-level foci (Table 1).…”

Section: Communitymentioning

confidence: 99%

“…Importantly, given that βNTI feat does not rely on abundance or taxonomicbased distance metrics, it is able to overcome many of the limitations associated with SIMPER (Warton et al, 2012). When compared to the phyloscore metric described by Fodelianakis et al (2021), it is much more similar though differs in some mathematical specifics (namely the null implementation) and in its application across different scales.…”

Section: Communitymentioning

confidence: 99%

Inferring the Contribution of Microbial Taxa and Organic Matter Molecular Formulas to Ecological Assembly

et al. 2022

View full text Add to dashboard Cite

Understanding the mechanisms underlying the assembly of communities has long been the goal of many ecological studies. While several studies have evaluated community wide ecological assembly, fewer have focused on investigating the impacts of individual members within a community or assemblage on ecological assembly. Here, we adapted a previous null model β-nearest taxon index (βNTI) to measure the contribution of individual features within an ecological community to overall assembly. This new metric, called feature-level βNTI (βNTIfeat), enables researchers to determine whether ecological features (e.g., individual microbial taxa) contribute to divergence, convergence, or have insignificant impacts across spatiotemporally resolved metacommunities or meta-assemblages. Using βNTIfeat, we revealed that unclassified microbial lineages often contributed to community divergence while diverse groups (e.g., Crenarchaeota, Alphaproteobacteria, and Gammaproteobacteria) contributed to convergence. We also demonstrate that βNTIfeat can be extended to other ecological assemblages such as organic molecules comprising organic matter (OM) pools. OM had more inconsistent trends compared to the microbial community though CHO-containing molecular formulas often contributed to convergence, while nitrogen and phosphorus-containing formulas contributed to both convergence and divergence. A network analysis was used to relate βNTIfeat values from the putatively active microbial community and the OM assemblage and examine potentially common contributions to ecological assembly across different communities/assemblages. This analysis revealed that P-containing formulas often contributed to convergence/divergence separately from other ecological features and N-containing formulas often contributed to assembly in coordination with microorganisms. Additionally, members of Family Geobacteraceae were often observed to contribute to convergence/divergence in conjunction with both N- and P-containing formulas, suggesting a coordinated ecological role for family members and the nitrogen/phosphorus cycle. Overall, we show that βNTIfeat offers opportunities to investigate the community or assemblage members, which shape the phylogenetic or functional landscape, and demonstrate the potential to evaluate potential points of coordination across various community types.

show abstract

“…Metabarcoding library preparation and sequencing. The prokaryotic 16S rRNA gene metabarcoding library preparation was performed as described in Fodelianakis et al 70 , targeting the V3-V4 hypervariable region of the 16S rRNA gene with the 341F/785R primers and following Illumina guidelines for 16S metagenomic library preparation for the MiSeq system. The eukaryotic 18S rRNA gene metabarcoding library preparation was performed likewise but using the TAReuk454F-TAReukREV3 primers to target the 18S rRNA gene V4 loop 71 .…”

Section: Dna Extraction and Purificationmentioning

confidence: 99%

“…Metabarcoding analyses. The 16S rRNA gene metabarcoding data were analysed using a combination of Trimmomatic 72 and QIIME2 73 as described in Fodelianakis et al 70 , with the exception that here the latest SILVA database 74 v138.1 was used for taxonomic classification of 16S rRNA and 18S rRNA gene amplicons. Non-bacterial ASVs including those affiliated to archaea, chloroplasts and mitochondria were discarded from the 16S rRNA amplicon dataset in all downstream analyses.…”

Section: Dna Extraction and Purificationmentioning

confidence: 99%

Genomic and metabolic adaptations of biofilms to ecological windows of opportunities in glacier-fed streams

Busi

Bourquin

Fodelianakis

et al. 2021

Preprint

Self Cite

View full text Add to dashboard Cite

Microorganisms dominate life in cryospheric ecosystems. In glacier-fed streams (GFSs), ecological windows of opportunities allow complex microbial biofilms to develop and transiently form the basis of the food web, thereby controlling key ecosystem processes. Here, using high-resolution metagenomics, we unravel strategies that allow biofilms to seize this opportunity in an ecosystem otherwise characterized by harsh environmental conditions. We found a diverse microbiome spanning the entire tree of life and including a rich virome. Various and co-existing energy acquisition pathways point to diverse niches and the simultaneous exploitation of available resources, likely fostering the establishment of complex biofilms in GFSs during windows of opportunity. The wide occurrence of rhodopsins across metagenome-assembled genomes (MAGs), besides chlorophyll, highlights the role of solar energy capture in these biofilms. Concomitantly, internal carbon and nutrient cycling between photoautotrophs and heterotrophs may help overcome constraints imposed by the high oligotrophy in GFSs. MAGs also revealed mechanisms potentially protecting bacteria against low temperatures and high UV-radiation. The selective pressure of the GFS environment is further highlighted by the phylogenomic analysis, differentiating the representatives of the genus Polaromonas, an important component of the GFS microbiome, from those found in other ecosystems. Our findings reveal key genomic underpinnings of adaptive traits that contribute to the success of complex biofilms to exploit environmental opportunities in GFSs, now rapidly changing owing to global warming.

show abstract

Microdiversity characterizes prevalent phylogenetic clades in the glacier-fed stream microbiome

Cited by 31 publications

References 95 publications

Disturbance by soil mixing decreases microbial richness and supports homogenizing community assembly processes

Disturbance by soil mixing decreases microbial richness and supports homogenizing community assembly processes

Inferring the Contribution of Microbial Taxa and Organic Matter Molecular Formulas to Ecological Assembly

Genomic and metabolic adaptations of biofilms to ecological windows of opportunities in glacier-fed streams

Contact Info

Product

Resources

About