Resilience in soil bacterial communities of the boreal forest from one to five years after wildfire across a severity gradient

Whitman, Thea; Woolet, Jamie; Sikora, Miranda C.; Johnson, Dana B.; Whitman, Ellen

doi:10.1101/2022.04.21.487669

Cited by 2 publications

(2 citation statements)

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“…We quantified the total relative abundance of taxa assigned to each of the strategies using our laboratory experiments in a dataset of natural wildfires in the same region [8, 73]. Briefly, soils were collected from organic and mineral horizons in the field, one year and five years post-fire, across a range of burn severities including unburned sites, and spanning the same vegetation communities and soil types from which cores were collected for the laboratory experiments.…”

Section: Methodsmentioning

confidence: 99%

An empirical approach to developing and testing a traits-based fire ecology framework for bacterial response to wildfires

Johnson

Woolet

Yedinak

et al. 2022

Preprint

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Globally, wildfires represent major disturbances, burning millions of hectares annually. Wildfires can restructure soil microbial communities via changes in soil properties and microbial mortality. Fire-induced changes in bacterial communities may influence soil carbon cycling, and recovery to pre-burn community composition and function may take years. We investigated carbon cycling, soil properties, and the importance of three fire-adaptive strategies – fire survival, fast growth, and affinity for post-fire soil environmental conditions – in structuring soil bacterial communities following burns of varying temperatures in boreal forest soils. To identify taxa with each strategy, we simulated burns and incubated soils, tracking respiration and sequencing DNA and rRNA. We then quantified their abundances in the field following wildfires of varying burn severities. The importance of these strategies varies over time and with burn severity. Fire survival has a small but persistent effect on structuring burned soil communities. Fast growing bacteria rapidly colonize the post-fire soil but return to pre-burn relative abundances between one and five years post-fire. Taxa with an affinity for the post-fire environment thrive post-fire, but the effect of this strategy declines by five years post-fire, suggesting that other factors such as vegetation recovery or bacterial dispersal may influence community composition over decadal timescales.Graphical Abstract

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Section: Methodsmentioning

confidence: 99%

An empirical approach to developing and testing a traits-based fire ecology framework for bacterial response to wildfires

Johnson

Woolet

Yedinak

et al. 2022

Preprint

Self Cite

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“…Currently, most research evaluating post-fire microbiomes is based on single timepoint sampling (Dove & Hart, 2017; Pressler et al, 2019); thus, the succession of pyrophilous microbes is nearly unknown. However, recent research consisting of 2-3 sampling time points suggests that bacteria and fungi experience rapid post-fire community changes (Ferrenberg et al, 2013; Qin & Liu, 2021; Whitman et al, 2022), indicating that higher temporal resolution sampling is needed to understand bacterial and fungal successional trajectories.…”

Section: Introductionmentioning

confidence: 99%

Rapid bacterial and fungal successional dynamics in first year after Chaparral wildfire

Pulido-Chavez

Randolph

Zalman

et al. 2021

Preprint

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The rise in wildfire frequency in the western United States has increased interest in secondary succession. However, despite the role of soil microbial communities in plant regeneration and establishment, microbial secondary succession is poorly understood owing to a lack of measurements immediately post-fire and at high temporal resolution. To fill this knowledge gap, we collected soils at 2 and 3 weeks and 1, 2, 3, 4, 6, 9, and 12 months after a chaparral wildfire in Southern California. We assessed bacterial and fungal biomass with qPCR of 16S and 18S and richness and composition with Illumina MiSeq sequencing of the 16S and ITS2 amplicons. We found that fire severely reduced bacterial biomass by 47% and richness by 46%, but the impacts were stronger for fungi, with biomass decreasing by 86% and richness by 68%. These declines persisted for the entire post-fire year, but bacterial biomass and richness oscillated in response to precipitation, whereas fungal biomass and richness did not. Fungi and bacteria experienced rapid succession, with 5-6 compositional turnover periods. As with plants, fast-growing surviving microbes drove successional dynamics. For bacteria, succession was driven by the phyla Firmicutes and Proteobacteria, with the Proteobacteria Massilia dominating all successional time points, and the Firmicutes (Domibacillus and Paenibacillus) dominating early- to mid-successional stages (1-4.5 months), while the Proteobacteria Noviherbaspirillum dominated late successional stages (4.5-1 year). For fungi, succession was driven by the phyla Ascomycota, but ectomycorrhizal basidiomycetes, and the heat-resistant yeast, Geminibasidium were present in the early successional stages (1 month). However, pyrophilous filamentous Ascomycetes Pyronema, Penicillium, and Aspergillus, dominated all post-fire time points. While wildfires vastly decrease bacterial and fungal biomass and richness, similar to plants, pyrophilous bacteria and fungi increase in abundance and experience rapid succession and compositional turnover in the first post-fire year, with potential implications for post-fire chaparral regeneration

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Resilience in soil bacterial communities of the boreal forest from one to five years after wildfire across a severity gradient

Cited by 2 publications

References 84 publications

An empirical approach to developing and testing a traits-based fire ecology framework for bacterial response to wildfires

An empirical approach to developing and testing a traits-based fire ecology framework for bacterial response to wildfires

Rapid bacterial and fungal successional dynamics in first year after Chaparral wildfire

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