Trade-offs between microbiome diversity and productivity in a stratified microbial mat

Bernstein, Hans C.; Brislawn, Colin; Renslow, Ryan; Dana, Karl; Morton, Beau R.; Lindemann, Stephen R.; Song, Hyun‐Seob; Atçı, Erhan; Beyenal, Haluk; Fredrickson, James K.; Jansson, Janet; Moran, James J.

doi:10.1038/ismej.2016.133

Cited by 27 publications

(38 citation statements)

References 51 publications

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“…Homogenous selection appeared to act more strongly on the bacterial components of the community in later stages of succession when the biofilm community had presumably sampled the majority of taxa from the nearby environment. We note that founder speciesas well as other abundant taxa identified in this studywere identical or highly related to some of the most common taxa reported by previous studies performed in the Hot Lake ecosystem in different years (Bernstein et al 2017a, Lindemann et al 2013, Mobberley et al 2017, Moran et al 2014. This indicates that, although the phyla are shown to decrease during this 79-day succession period, these taxa are likely stable and persistent within the ecosystem.…”

Section: Discussionsupporting

confidence: 88%

“…The images also qualitatively show uptake of 13 C-label increases with the arrival of frequent diatom-like cell structures. While it is not surprising that microalgae act as primary producers, the finding does adds context to this unique hypersaline ecosystem where previous reports have mostly attributed primary production by cyanobacteria (Bernstein et al 2017a, Lindemann et al 2013, Moran et al 2014; but see (Bernstein et al 2017b). The importance of microalgae to the ecosystem is also supported by our identification of founder species, including photosynthetic eukaryotes (Charophyta or Pseudonitzchia) make up at least 40% of 18S OTUs in any given sample.…”

Section: Discussionsupporting

confidence: 82%

“…The microbial ecosystem was chosen because of a priori knowledge of seasonal community development presented in a previous study that ascertained a distinct mat-development period during summer months (June-August) (Lindemann et al 2013). The microbiome characterized from the mat during this growth period remained remarkably similar, in terms of members and relative abundance of taxa, across multiple related studies (Bernstein et al 2017a, Bernstein et al 2017b, Mobberley et al 2017, Moran et al 2014. Our first goal was to determine the structure and function (autotrophy and diazotrophy) of the community from the colonization period through to the season's typical maturation period.…”

Section: Introductionmentioning

confidence: 99%

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Forfeiting the founder effect: turnover defines biofilm community succession

Brislawn

2018

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Microbial community succession is a fundamental process that effects underlying functions of almost all ecosystems; yet the roles and fates of the most abundant colonizers are poorly understood. Does early abundance spur long term persistence? How do deterministic and stochastic processes influence the roles of founder species? We performed a succession experiment within a hypersaline microbial mat ecosystem to investigate how ecological processes contributed to the turnover of founder species. Bacterial and micro-eukaryotic founder species were identified from primary succession and tracked through a defined maturation period using 16S and 18S rRNA gene amplicon sequencing in combination with high resolution imaging that utilized stable isotope tracers to evaluate basic functional capabilities. The majority of the founder species did not maintain high relative abundances in later stages of succession.Turnover (versus nestedness) was the dominant process shaping the final community structure. We also asked if different ecological processes acted on bacteria versus eukaryotes during successional stages and found that deterministic and stochastic forces corresponded more with eukaryote and bacterial colonization, respectively. Our results show that taxa from different kingdoms, that share habitat in the tight spatial confines of a biofilm, were influenced by different ecological forces and time scales of succession.

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Section: Discussionsupporting

confidence: 88%

Section: Discussionsupporting

confidence: 82%

Section: Introductionmentioning

confidence: 99%

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Forfeiting the founder effect: turnover defines biofilm community succession

Brislawn

2018

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“…These results are therefore consistent with PAR structuring communities largely by influencing the distribution of photoautotrophs. This trend of cyanobacteria in top layers and proteobacteria in underlying layers is found in other microbial mat ecosystems (Kunin et al 2008;Harris et al 2013;Bernstein et al 2017;Maier et al 2018) , raising the possibility that alpha diversity in microbial ecosystems is generally more dependent on the distribution of net primary producers than heterotrophs.…”

Section: Effects Of [O 2 ] and Par On Community Composition And Divermentioning

confidence: 75%

“…Species-energy theory is likely applicable to microbial ecosystems based on recent experimental work investigating the effects of increased carbon substrate availability on community composition and diversity in a groundwater system (Zhou et al 2014) . Other laboratory and field studies also suggest that microbial diversity increases with energy availability (Bernstein et al 2017) and [O 2 ] (Spietz et al 2015) . However, the actual energy available to a community is a complex function of both the biogeochemistry of the environment ( e.g.…”

Section: Introductionmentioning

confidence: 93%

Energetic and Environmental Constraints on the Community Structure of Benthic Microbial Mats in Lake Fryxell, Antarctica

Dillon

Hawes

Jungblut

et al. 2019

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Ecological communities are commonly thought to be controlled by the dynamics of energy flow through environments. Two of the most important energetic constraints on all communities are photosynthetically active radiation (PAR) and oxygen concentration ([O 2 ]). Microbial mats growing on the bottom of Lake Fryxell, Antarctica, span environmental gradients in PAR and [O 2 ], which we used to test the extent to which each controls community structure. Metagenomic analyses showed variation in the diversity and relative abundances of Archaea, Bacteria, and Eukaryotes across three [O 2 ] and PAR conditions. Where [O 2 ] saturated the mats or was absent from the overlying water, PAR structured the community. Where [O 2 ] varied within mats, microbial communities changed across covarying PAR and [O 2 ] gradients. Diversity negatively correlated with [O 2 ] and PAR through mat layers in each habitat suggesting that, on the millimeter-scale, communities are structured by the optimization of energy use. In contrast, [O 2 ] positively correlated with diversity and affected the distribution of dominant populations across the three habitats, suggesting that meter-scale diversity is structured by energy availability. The benthic microbial communities in Lake Fryxell are thus structured by energy flow in a scale-dependent manner.

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