Land use in urban areas impacts the composition of soil bacterial communities involved in nitrogen cycling. A case study from Lefkosia (Nicosia) Cyprus

Stephanou, Coralea; Omirou, Michalis; Philippot, Laurent; Zissimos, Andreas M.; Christoforou, Irene C.; Trajanoski, Slave; Oulas, Anastasis; Ioannides, Ioannis M.

doi:10.1038/s41598-021-87623-y

Cited by 15 publications

(4 citation statements)

References 65 publications

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“…Our findings of increases in richness of abundant bacterial phyla such as Proteobacteria and Bacteroidota, and less abundant phyla, such as Nitrospira and Gemmatimonadota, in response to urbanity, mimic findings from previous studies (Wang et al, 2018;Delgado-Baquerizo et al, 2021;Stephanou et al, 2021). We also observed urbanity increasing the richness of the Actinobacteria, previously shown to be a significant phylum in cities across China (Xu et al, 2014).…”

Section: Discussionsupporting

confidence: 90%

Soil microbial communities shift along an urban gradient in Berlin, Germany

Whitehead

Roy²,

Hempel³

et al. 2022

Front. Microbiol.

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The microbial communities inhabiting urban soils determine the functioning of these soils, in regards to their ability to cycle nutrients and support plant communities. In an increasingly urbanized world these properties are of the utmost importance, and the microbial communities responsible are worthy of exploration. We used 53 grassland sites spread across Berlin to describe and explain the impacts of urbanity and other environmental parameters upon the diversity and community composition of four microbial groups. These groups were (i) the Fungi, with a separate dataset for (ii) the Glomeromycota, (iii) the Bacteria, and (iv) the protist phylum Cercozoa. We found that urbanity had distinct impacts on fungal richness, which tended to increase. Geographic distance between sites and soil chemistry, in addition to urbanity, drove microbial community composition, with site connectivity being important for Glomeromycotan communities, potentially due to plant host communities. Our findings suggest that many microbial species are well adapted to urban soils, as supported by an increase in diversity being a far more common result of urbanity than the reverse. However, we also found distinctly separate distributions of operational taxonomic unit (OTU)s from the same species, shedding doubt of the reliability of indicator species, and the use of taxonomy to draw conclusion on functionality. Our observational study employed an extensive set of sites across an urbanity gradient, in the region of the German capital, to produce a rich microbial dataset; as such it can serve as a blueprint for other such investigations.

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Section: Discussionsupporting

confidence: 90%

Soil microbial communities shift along an urban gradient in Berlin, Germany

Whitehead

Roy²,

Hempel³

et al. 2022

Front. Microbiol.

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“…This upregulated function was notably associated with taxa within the Actinobacteria and Firmicutes phyla. Beyond the impact of fire, vegetation type can significantly influence bacterial communities, stemming from variations in soil characteristics and pre-existing bacterial assemblies before the fire event [50]. Our observation of increased Acidobacteriota and Firmicutes abundance in the shrub ecosystem post-fire only suggests that specific bacterial groups thrive under certain ecosystem conditions.…”

Section: Discussionmentioning

confidence: 77%

Wildfire Effects on the Soil Respiration and Bacterial Microbiota Composition in Mediterranean-Type Ecosystems

Dalias,

Hadjisterkotis,

Omirou

et al. 2024

Fire

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This work provides insights into the effect of fire on soil processes in Mediterranean-type ecosystems in Cyprus. Soil samples from mountainous sites that were subjected to a summer wildfire and adjacent control samples were collected. Incubations were used to estimate basal respiration and isolate soil CO2 release of heterotrophic microorganisms from autotrophic root respiration and heterotrophic respiration from litter decomposition. Physicochemical property changes, bacteria community changes using DNA extraction and 16S rRNA gene analysis, and the effects of ash and fresh litter addition were studied to reveal the microbial composition and the post-fire soil function. Laboratory incubation showed that burned soils constantly showed higher microbial respiration rates compared with control unburned areas, even six months after a fire. Adding ash to unburned samples increased microbial respiration, suggesting that increased nutrient availability positively corelates with the increased release of CO2 from fire-affected soil. Elevated temperatures due to the wildfire exerted significant effects on the composition of soil bacterial microbiota. Nevertheless, the wildfire did not affect the alpha-diversity of soil bacteria. New communities of microorganisms are still able to decompose fresh plant material after a fire, but at a slower rate than natural pre-fire populations.

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“…This upregulated function was notably associated with taxa within the Actinobacteria and Firmicutes phyla. Beyond the impact of fire, vegetation type can significantly influence bacterial communities, stemming from variations in soil characteristics and pre-existing bacterial assemblies before the fire event (Stephanou et al, 2021). Our observation of increased Acidobacteriota and Firmicutes abundance in the shrub ecosystem post-fire only, suggests that specific bacterial groups thrive under certain ecosystem conditions.…”

Section: Discussionmentioning

confidence: 80%

Soil Respiration and Bacterial Changes after a Wildfire in Mediterranean-Type Ecosystems

Dalias,

Hadjisterkotis,

Omirou

et al. 2024

Preprint

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The work provides insights on the effect of fire on soil processes in Mediterranean-type ecosystems of Cyprus. Soil samples from mountainous sites that were subjected to a summer wildfire and adjacent control samples were collected. Incubations were used to estimate basal respiration and isolate soil CO2 release of heterotrophic microorganisms from autotrophic root respiration and heterotrophic respiration from litter decomposition. Physicochemical properties changes, bacteria community changes using DNA extraction and 16S rRNA gene analysis, and the effects of ash and fresh litter addition were studied to reveal the microbial composition and the post-fire soil function. Laboratory incubation showed that burned soils constantly showed higher microbial respiration rates compared with control unburned areas, even six months after fire. Adding ash to unburned samples increased microbial respiration, suggesting that increased nutrient availability positively corelates with increased release of CO2 from fire-affected soil. Elevated temperatures due to the wildfire exerted significant effects on the composition of soil bacterial community. Nevertheless, the wildfire did not affect the alpha-diversity of soil bacteria. New communities of microorganisms are still able to decompose fresh plant material after fire, but at a slower rate than natural pre-fire populations.

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Land use in urban areas impacts the composition of soil bacterial communities involved in nitrogen cycling. A case study from Lefkosia (Nicosia) Cyprus

Cited by 15 publications

References 65 publications

Soil microbial communities shift along an urban gradient in Berlin, Germany

Soil microbial communities shift along an urban gradient in Berlin, Germany

Wildfire Effects on the Soil Respiration and Bacterial Microbiota Composition in Mediterranean-Type Ecosystems

Soil Respiration and Bacterial Changes after a Wildfire in Mediterranean-Type Ecosystems

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