Direct and indirect effects of native range expansion on soil microbial community structure and function

Collins, Courtney G.; Carey, Chelsea J.; Aronson, Emma L.; Kopp, Christopher W.; Diez, Jeffrey M.

doi:10.1111/1365-2745.12616

Cited by 57 publications

(52 citation statements)

References 103 publications

(127 reference statements)

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“…Many field studies on plant invasions and soil communities have shown that exotic plant species have distinct soil communities compared to native plants growing in adjacent areas (Kourtev et al 2002a, Kourtev et al 2002b, Scharfy et al 2009, Collins et al 2016, Stefanowicz et al 2016, Gibbons et al 2017. Consistent with these results, in our experiment we also observe that the composition of the rhizosphere bacterial community differed by plant origin in all four plant pairs when plants were grown in their own field soils ( Fig.…”

Section: Discussionsupporting

confidence: 91%

Plant-soil interactions of range-expanding plants

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Section: Discussionsupporting

confidence: 91%

Plant-soil interactions of range-expanding plants

Freixa¹

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“…Copiotrophic phyla adapted for rapid growth and higher potential for labile carbon metabolism in high nutrient conditions are Betaproteobacteria, Bacteroidetes, Firmicutes, and Actinobacteria. Oligotrophic phyla adapted for slow growth and higher potential for carbon storage are Acidobacteria and Verrucomicrobia (Fierer et al 2007, Collins et al 2016. Other phyla cannot be categorized into either group.…”

Section: Resultsmentioning

confidence: 99%

“…For example, nitrogen fertilization causes a consistent decrease in soil bacterial diversity and microbial biomass carbon, independent of nitrogen application rates or crop types (Dai et al 2018). Nitrogen fertilization is also related to increased relative abundances of Proteobacteria and Actinobacteria (Ramirez et al 2010, Zhou et al 2017, Dai et al 2018, which include taxa that are adapted to high nitrogen demand and labile carbon pool metabolism (Fierer et al 2007, Collins et al 2016. Conversely, in North American remnant prairies, where plant organic material inputs control the growth of these copiotrophic taxa, Verrucomicrobia, which are thought to specialize in recalcitrant carbon degradation, are more predominant members of the community (Fierer et al 2013).…”

Section: Introductionmentioning

confidence: 99%

Soil microbial restoration strategies for promoting climate‐ready prairie ecosystems

Docherty

Gutknecht

2019

Ecological Applications

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Tractable practices for soil microbial restoration in tallgrass prairies reclaimed from agriculture are a critical gap in traditional ecological restoration. Long‐term fertilization and tilling permanently alter soil bacterial and fungal communities, requiring microbe‐targeted restoration methods to improve belowground ecosystem services and carbon storage in newly restored prairies. These techniques are particularly important when restoring for climate‐ready ecosystems, adapted to altered temperature regimes. To approach these issues, we conducted a multi‐factorial greenhouse experiment to test the effects of plant species richness, soil amendment and elevated temperature on soil microbial diversity, growth, and function. Treatments consisted of three seedlings of one plant species (Andropogon gerardii) or one seedling each of three plant species (A. gerardii, Echinacea pallida, Coreopsis lanceolata). Soil amendments included cellulose addition, inoculation with a microbial community collected from an undisturbed remnant prairie, and a control. We assessed microbial communities using extracellular enzyme assays, Illumina sequencing of the bacterial 16S rRNA gene, predicted bacterial metabolic pathways from sequence data and phospholipid fatty acid analysis (PLFA), which includes both bacterial and fungal lipid abundances. Our results indicate that addition of cellulose selects for slow‐growing bacterial taxa (Verrucomicrobia) and fungi at ambient temperature. However, at elevated temperature, selection for slow‐growing bacterial taxa is enhanced, while selection for fungi is lost, indicating temperature sensitivity among fungi. Cellulose addition was a more effective means of altering soil community composition than addition of microbial communities harvested from a remnant prairie. Soil water content was typically higher in the A. gerardii treatment alone, regardless of temperature, but at ambient temperature only, predicted metagenomics pathways for bacterial carbon metabolism were more abundant with A. gerardii. In summary, these results from a mesocosm test case indicate that adding cellulose to newly restored soil and increasing the abundance of C4 grasses, such as A. gerardii, can select for microbial communities adapted for slow growth and carbon storage. Further testing is required to determine if these approaches yield the same results in a field‐level experiment.

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“…Consistent with Grime's (, ) concept that community biomass is inversely proportional to plant stress, intermediate elevations had the highest plant cover and biomass (Figure , Table ), and therefore the lowest net impact of abiotic and resource stress. However, high elevations also have higher soil moisture, soil organic C and N, as well as microbial biomass and activity than lower elevations (Collins, Carey, Aronson, Kopp, & Diez, ), suggesting higher resource stress at low elevations. Further, while Callaway et al.…”

Section: Discussionmentioning

confidence: 99%

Plant community response to Artemisia rothrockii (sagebrush) encroachment and removal along an arid elevational gradient

Kopp

Cleland

2018

J Vegetation Science

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Questions Shrub expansion into alpine ecosystems worldwide raises important questions regarding the influence of shrub encroachment on alpine species diversity. The stress gradient hypothesis (SGH) predicts interactions will be competitive when resources are plentiful and the environment is benign, but that facilitative interactions will dominate when conditions are stressful. We asked how Artemisia rothrockii (sagebrush) encroachment in an arid mountain range is affecting alpine plant species there and how the plant community responds to the experimental removal of sagebrush at three sites along an elevational gradient. Location The White Mountains, California, USA (37°30′N, 118°10′W). Methods A shrub removal experiment was established at three elevations (2,900, 3,100 and 3,750 m) to evaluate how sagebrush interacts with alpine and sub‐alpine plant communities. Results The study sites experienced a strong drought over the 4 yrs of the experiment and plant cover declined overall. However, in the sagebrush removal treatment, cover of co‐occurring species increased at both the high‐elevation and low‐elevation sites, with no differences observed at the mid‐elevation site. Conclusions We observed the greatest inhibitory effects of sagebrush at high and low elevations, where plants experience the largest temperature and moisture stress, respectively, and no evidence of facilitation anywhere along the elevational gradient. These results demonstrate that while sagebrush has important influences on herbaceous species composition in the White Mountains, they are inconsistent with the classic predictions of the SGH.

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Direct and indirect effects of native range expansion on soil microbial community structure and function

Cited by 57 publications

References 103 publications

Plant-soil interactions of range-expanding plants

Plant-soil interactions of range-expanding plants

Soil microbial restoration strategies for promoting climate‐ready prairie ecosystems

Plant community response to Artemisia rothrockii (sagebrush) encroachment and removal along an arid elevational gradient

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