Bacterial community structure and assembly dynamics hinge on plant litter quality.

Litter decomposition is a fundamental ecosystem process controlling the biogeochemical cycling of energy and nutrients. Using a 360-day lab incubation experiment to control for environmental factors, we tested how litter quality (low C/N deciduous vs. high C/N coniferous litter) governed the assembly and taxonomic composition of bacterial communities and rates of litter decomposition. Overall, litter mass loss was significantly faster in soils amended with deciduous (DL) rather than coniferous (CL) litter. Communities degrading DL were also more taxonomically diverse and exhibited stochastic assembly throughout the experiment. By contrast, alpha-diversity rapidly declined in communities exposed to CL. Strong environmental selection and competitive biological interactions induced by molecularly complex, nutrient poor CL were reflected in a transition from stochastic to deterministic assembly after 180 days. Constraining how the diversity and assembly of microbial populations modulates core ecosystem processes, such as litter decomposition, will become increasingly important under novel climate conditions, and as policymakers and land managers emphasize soil carbon sequestration as a key natural climate solution.

Copiotrophic taxa in pig manure mitigate nitrogen limitation of soil microbial communities.

Microbial nitrogen (N) limitation is a common problem in terrestrial ecosystems. Pig manure, a type of solid waste, is increasingly applied to improve soil N availability in agriculture through inputs of organic matter and inorganic N. Pig manure application also introduces a lot of exogenous microorganisms, which have distinctly different N requirements and metabolic properties, into the resident soil microbial community. However, the impacts of these manure-borne microorganisms on soil N cycling have not been well determined. Here, we investigated effects of manure-borne microorganisms on the N limitation of soil microorganisms using an ecoenzymatic stoichiometry analysis. We monitored microbial communities over a 90-day period in a laboratory-controlled experiment with four treatments: (1) non-sterilized soil mixed with non-sterilized manure (S-M), (2) non-sterilized soil mixed with sterilized manure (S-sM), (3) sterilized soil mixed with non-sterilized manure (sS-M), and (4) non-sterilized soil without manure addition (S, the control). The microbial N limitations were significantly mitigated in both S-M and sS-M. By contrast, the S-sM and S showed high levels of microbial N limitation, likely stemming from differences in the microbial functional composition. We found chitin-degrading bacteria were the dominant copiotrophic manure-borne bacteria associated with N mineralization, and they may improve soil N availability. We further identified several copiotrophic manure-borne bacteria in S-M and sS-M, and their abundances had significantly negative correlation with the level of N limitation and significantly positive correlation with the stoichiometric homeostasis. As these copiotrophic taxa can maintain homeostasis through regulating enzymatic activities, our results indicate that copiotrophic taxa in pig manure contribute to the mitigation of soil microbial N limitation. Our study also highlights the invasiveness capacity of manure-borne microorganisms in soil and evaluates the biotic effects of manure application on soil N cycling.

The potential role of fertilizer-derived exogenous bacteria on soil bacterial community assemblage and network formation.

Manure fertilization contributes to crop production and sustainable agriculture by introducing large amounts of nutrients and exogenous microbes into soil. However, the contribution of exogenous microbes in shaping soil bacterial community and network structure after fertilization are still controversial. In this study, bacterial communities and network structure that received unsterilized (R + C) or sterilized (R + SC) manure fertilizers, as well as no fertilizer control (R), were characterized using high throughput sequencing. Results showed that the relative abundance of fertilizer-derived OTUs decreased from 10.4% to 4.6% after 90 days incubation, while the Bray-Curtis distance between the control and fertilization group (R + C and R + SC) gradually increased with the culture time. It can be supposed that manure fertilization altered soil bacterial communities by interfering the growth of indigenous bacteria rather than the colonization of fertilizer-derived bacteria. Network analysis showed that a subset of the fertilizer-derived OTUs identified as Xanthomonadales order and Promicromonospora, Constrictibacter genera acted as connectors between modules. They enhanced the interactions not only between soil-derived OTUs and fertilizer-derived OTUs, but also within indigenous bacteria, supported that the introduction of fertilizer-derived exogenous bacteria contributes large to soil bacterial network association. Moreover, fertilizer-derived OTUs presented to be positively correlated with soil pH, while majority soil-derived OTUs presented to be negatively correlated with various physicochemical variables (pH, DOC, NO3-, and LAP). Our study highlighted the critical role of fertilizer-derived bacteria in regulating indigenous soil microbial community and network formation after fertilization.