Sci Rep. 2025 Aug 4;15(1):28460. doi: 10.1038/s41598-025-13705-w.
ABSTRACT
Soil microbiome plays a crucial role in ecosystem; however, the responses of the soil microbiome to nonconventional irrigation water sources remain poorly understood. This study employed 16 S rRNA sequencing to investigate microbial community shifts in soil samples collected from four geographically distinct locations affected by different irrigation water sources: saline ground water affected by seawater (SW), a brackish water lake (BW), a wastewater drain (WW), and a freshwater canal that receives inflows from multiple agricultural drains (FW). Our findings revealed distinct microbial signatures shaped by water quality, with Firmicutes dominating WW soils (49.2%) due to metal resistance (DESeq2, p = 3.67 × 10– 4), whereas Chloroflexi and Cyanobacteria thrived in BW environments (LEfSe, LDA > 4, p = 8.23 × 10– 6), reflecting adaptations to chloride-rich conditions. FW soils enriched Acidobacteria and Verrucomicrobia, which are associated with moderate salinity and nutrient cycling, whereas SW samples harbored halotolerant Actinobacteria and Deinococcus-Thermus (DESeq2, p = 1.47x– 05). Statistical analyses revealed key potential biomarkers, including Streptococcus (WW, DESeq2 p = 3.67x– 24), RB41 (BW, LEfSe p = 1.62x– 13), and Candidatus_Udaeobacter (SW, DESeq2 p = 1.47x– 05). Physicochemical drivers such as salinity (R² =0.319, p = 0.00041) and heavy metals (Pb/Mn in WW) strongly influence community structure. Notably, WW irrigation reduced alpha diversity (Shannon index: 4.79-5.41 vs. 6.65-7.43 in FW; Kruskal-Wallis p = 0.0056), highlighting pollutant-induced stress. These findings highlight the balance between water reuse and soil health, offering a foundation for microbiome-driven bioremediation approaches in arid environments. By utilizing native, stress-resilient microbial communities, our research promotes sustainable agricultural practices in water-limited regions.
PMID:40760076 | DOI:10.1038/s41598-025-13705-w
