Summary: | Continuing nitrogen (N) deposition has a wide-ranging impact on terrestrial ecosystems. To test the hypothesis that, under N deposition, bacterial communities could suffer a negative impact, and in a relatively short timeframe, an experiment was carried out for a year in an urban area featuring a cover of Bermuda grass (<i>Cynodon</i><i> </i><i>dactylon</i>) and simulating environmental N deposition. NH<sub>4</sub>NO<sub>3</sub> was added as external N source, with four dosages (N0 = 0 kg N ha<sup>−2</sup> y<sup>−1</sup>, N1 = 50 kg N ha<sup>−2</sup> y<sup>−1</sup>, N2 = 100 kg N ha<sup>−2</sup> y<sup>−1</sup>, N3 = 150 kg N ha<sup>−2</sup> y<sup>−1</sup>). We analyzed the bacterial community composition after soil DNA extraction through the pyrosequencing of the 16S rRNA gene amplicons. N deposition resulted in soil bacterial community changes at a clear dosage-dependent rate. Soil bacterial diversity and evenness showed a clear trend of time-dependent decline under repeated N application. Ammonium nitrogen enrichment, either directly or in relation to pH decrease, resulted in the main environmental factor related to the shift of taxa proportions within the urban green space soil bacterial community and qualified as a putative important driver of bacterial diversity abatement. Such an impact on soil life induced by N deposition may pose a serious threat to urban soil ecosystem stability and surrounding areas.
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