Abstract
Globally soil salinity is one of the most devastating environmental stresses affecting agricultural systems and causes huge economic losses each year. High soil salinity causes osmotic stress, nutritional imbalance and ion toxicity to plants and severely affects crop productivity in farming systems. Freezing saline water irrigation and plastic mulching techniques were successfully developed in our previous study to desalinize costal saline soil. Understanding how microbial communities respond during saline soil amelioration is crucial, given the key roles soil microbes play in ecosystem succession. In the present study, the community composition, diversity, assembly and potential ecological functions of archaea, bacteria and fungi in coastal saline soil under amelioration practices of freezing saline water irrigation, plastic mulching and the combination of freezing saline water irrigation and plastic mulching were assessed through high-throughput sequencing. These amelioration practices decreased archaeal and increased bacterial richness while leaving fungal richness little changed in the surface soil. Functional prediction revealed that the amelioration practices, especially winter irrigation with saline water and film mulched in spring, promoted a community harboring heterotrophic features. β-null deviation analysis illustrated that amelioration practices weakened the deterministic processes in structuring coastal saline soil microbial communities. These results advanced our understanding of the responses of the soil microbiome to amelioration practices and provided useful information for developing microbe-based remediation approaches in coastal saline soils.
Highlights
High salt concentrations are one of the key factors limiting crop growth in coastal saline soil (Zhang et al, 2015)
Soil electrical conductivity (EC) in the 0–10 cm layer was significantly lower in the ameliorated soils than in the Control, suggesting that the amelioration practices successfully reduced the salt concentration in the surface soil
Soil moisture (SM) varied little among treatments and soil layers, and SM in the treatments including mulching (M and water and film mulched in spring (WIM)) was higher than that of without mulching (WI), indicating that mulching was effective in the maintenance of soil moisture
Summary
High salt concentrations are one of the key factors limiting crop growth in coastal saline soil (Zhang et al, 2015). Previous research has revealed that as the temperature gradually increases in the spring, the ice salinity declines with decreasing ice volume (Guo and Liu, 2015), possibly due to the brine pockets draining from the ice under the influence of gravity (Gu et al, 2012) and/or flushed out by relatively fresh surface meltwater (Notz and Worster, 2009) During this process, salinity gradually declined in the percolated meltwater, which infiltrated into the underlying saline soil and eventually resulted in a relatively low salinity in the surface soil to facilitate seed germination and crop growth. Mulching could reduce soil-water evaporation and thereby prevent soluble salt from moving up with water flow and accumulating in the topsoil (Sadegh-Zadeh et al, 2009; Fall, 2017)
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