Salinity controls soil microbial community structure and function in coastal estuarine wetlands

Zhang, Guangliang; Tebbe, Christoph C.; Zhao, Qingqing; Jia, Jia; Wang, Wei; Wang, Xin; Li, Yu

doi:10.1111/1462-2920.15281

Cited by 124 publications

(66 citation statements)

References 76 publications

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“…In our study, we found a great changes in soil salinity, indicating that salinity might be a main factor influencing ecosystem structure and function in the coastal saline lands, such as soil C cycling, plant growth, or microbial metobolism (Wong et al, 2010;Cho et al, 2018;Zhang et al, 2021a). Along the natural salinity gradient, SIC was higher at low salinity ( < 6 ‰) and declined as salinity increased, suggesting that salinity stress influences SIC dynamic through the variation in soil alkalinity or biologically respired CO 2 (Xie et al, 2009;Chi et al, 2018;Wang et al, 2019).…”

Section: Driving Factors Of Sic Shifts Spanning the Natural Salinity Gradientmentioning

confidence: 62%

“…Plants (e.g, maize and Phragmites) growing in low salinity soils exhibited high photosynthetic C fixation could increase plant C into soil through litter and root exudates, thus enhancing SOC accumulation; whereas plants (e.g, Tamarix chinensis and Suaeda salsa, with low photosynthetic C fixation) growing in high salinity soils resulted in the decline in SOC storage due to decreased litter and root exudates (Hessini et al, 2019;Xia et al, 2019). Additionally, soil microbial structure and functions (e.g., biomass and activity) are substantially affected by salinity (Rath et al, 2019;Zhang et al, 2021a). The previous researches have reported that low salinity soils could synthesize more microbial biomass than high salinity soils (Chen et al, 2021), which Fig.…”

Section: Microbial Residues Transforming Sic To Soc In Carbonaterich Saline Landsmentioning

confidence: 99%

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Microbial residues as the nexus transforming inorganic carbon to organic carbon in coastal saline soils

Shao

Dong

et al. 2021

Soil Ecol. Lett.

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Soil inorganic carbon (SIC), including mainly carbonate, is a key component of terrestrial soil C pool. Autotrophic microorganisms can assimilate carbonate as the main or unique C source, how microorganisms convert SIC to soil organic carbon (SOC) remains unclear. A systematic field survey (n = 94) was performed to evaluate the shift in soil C components (i.e., SIC, SOC, and microbial residues) along a natural salinity gradient (ranging from 0.5 ‰ to 19 ‰), and further to explore how microbial necromass as an indicator converting SIC into SOC in the Yellow River delta. We observed that SIC levels linearly decreased with increasing salinity, ranging from~12 g kg -1 (salinity < 6 ‰) tõ 10 g kg -1 (salinity >6 ‰). Additionally, the concentrations of SOC and microbial residues exponentially decreased from salinity < 6 ‰ to salinity >6 ‰, with the decline of 39% and 70%, respectively. Microbial residues and SOC was tightly related to the variations in SIC. The structural equation model showed the causality on explanation of SOC variations with SIC through microbial residues, which can contribute 89% of the variance in SOC storage combined with SIC. Taken together, these two statistical analyses can support that microbial residues can serve as an indicator of SIC transition to SOC. This study highlights the regulation of microbial residues in SIC cycling, enhancing the role of SIC playing in C biogeochemical cycles and enriching organic C reservoirs in coastal saline soils.

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Section: Driving Factors Of Sic Shifts Spanning the Natural Salinity Gradientmentioning

confidence: 62%

Section: Microbial Residues Transforming Sic To Soc In Carbonaterich Saline Landsmentioning

confidence: 99%

Microbial residues as the nexus transforming inorganic carbon to organic carbon in coastal saline soils

Shao

Dong

et al. 2021

Soil Ecol. Lett.

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“…Most of the time, estuaries are marked by horizontal salinity gradients (Telesh & Khlebovich, 2010; Zhang et al, 2020). Salinity usually decreases from the ocean toward the head of the estuary due to freshwater discharge.…”

Section: Resultsmentioning

confidence: 99%

Comparing the concentrations of heavy metals on two bivalve species in Santos Bay, Brazil: Subsidies to understanding the assimilation dynamic of bivalve contaminants

Souza

Vieira

Lima

et al. 2021

Water Environment Research

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Contaminant substances consist of chemical elements that present the potential to adversely impact the ecology of the environment, thus representing a threat to local fauna and flora. In this context, heavy metals are critical agents that, depending on the nature and level, are potentially toxic to living organisms. In order to evaluate the bioaccumulation of heavy metals in the Santos estuary and to determine the potential influence of salinity gradient on the heavy metal bioconcentration, the present study measured the concentrations of As, Cd, Pb, Cu, Cr, Fe, Ni, and Zn in two bivalve species (Crassostrea rhizophorae and Perna Perna) sampled at different sites of Santos Bay, in the southeastern region of Brazil. Throughout the study, the “sentinel species” used were effective in bioaccumulating contaminants. In oysters, based on the Brazilian legislation, critical limits were exceeded for As, Zn, Cu, and Cr. In the case of mussels, on the other hand, only for As, Zn, and Cr, the critical limits were overcome. In the present study, obtained data suggested salinity as a determinant parameter in As incorporation processes of bivalve mollusks. Practitioner Points The present study presents important results for the development of environmental management policies in estuarine environments. The present study points out differences between different organisms as biomonitors, providing subsidies for the decision of an effective biomonitoring program. The present study discusses values of contaminants as a danger to public health in Santos Bay, which can be extrapolated to other similar environments around the world.

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“…Soil microbial communities are considerably in uenced by biotic (e.g., the quantity and quality of plant materials) (Angel et al 2010) and abiotic (e.g., climate, soil type, and soil physicochemical properties) factors (Bainard et al 2016;Nguyen et al 2018). Plant properties, such as the aboveground and belowground biomass, strongly affect soil bacteria and archaea (Brotosudarmo et Similarly, soil salinity restricts the growth of bacteria and archaea by limiting water availability (Rath and Rousk 2015;Zhang et al 2021). Additionally, soil moisture is a vital driver of soil bacterial community composition, especially the proportion of aerobic and anaerobic bacteria, because it affects soil aeration conditions (Guo and Zhou 2020; Yang et al 2020;Sun et al 2021).…”

Section: Introductionmentioning

confidence: 99%

Alteration of Nutrient Substrates and Absence of Seawater Due to Coastal Embankments Affects Soil Microbial Communities in Salt Marshes of Eastern China

Feng

Qiao

Xia

et al. 2021

Preprint

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Aims: Although the influence of coastal embankments on soil physicochemical properties and carbon (C) and nitrogen (N) cycling has been widely studied, the mechanisms of their effects on the soil microbial ecology are still poorly understood. Thus, the aim of this study was to investigate variations in soil bacterial and archaeal communities between natural and embanked saltmarshes, as well as the determinants that drive these variations.Methods: 16S rRNA gene sequence analysis was performed to assess the impacts of embankments on the bacterial and archaeal communities of the invasive Spartina alterniflora Loisel., as well as native Suaeda salsa (L.) Pall. and Phragmites australis (Cav.) Trin. ex Steud. saltmarshes in the coastal China.Results: Embankments significantly decreased the Simpson diversity index of the S. alterniflora saltmarsh, while increasing the OTU richness in the P. australis saltmarsh. Additionally, the bacterial and archaeal community compositions in the embanked S. alterniflora and P. australis saltmarshes were considerably modified. However, no variations were found between the bacterial and archaeal communities of the natural and embanked S. salsa saltmarshes.Conclusions: These results were possibly because embankments decreased the soil nutrient substrates (e.g., soil organic C and N) dramatically in the S. alterniflora saltmarsh, while increased soil nutrient substrates significantly in the P. australis saltmarsh. However, embankments had a negligible effect on the soil nutrient substrates in the S. salsa saltmarsh. Moreover, embankments increased the abundance of Betaproteobacteria, and decreased the abundance of sulfur- and sodium-dependent bacteria due to the dramatic change in soil physicochemical properties.

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Salinity controls soil microbial community structure and function in coastal estuarine wetlands

Cited by 124 publications

References 76 publications

Microbial residues as the nexus transforming inorganic carbon to organic carbon in coastal saline soils

Microbial residues as the nexus transforming inorganic carbon to organic carbon in coastal saline soils

Comparing the concentrations of heavy metals on two bivalve species in Santos Bay, Brazil: Subsidies to understanding the assimilation dynamic of bivalve contaminants

Alteration of Nutrient Substrates and Absence of Seawater Due to Coastal Embankments Affects Soil Microbial Communities in Salt Marshes of Eastern China

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