Effects of dietary salt and water salinity on the dynamics of major gut microbiota (Cetobacterium), antioxidant status, and immune response in Nile Tilapia

Nile tilapia farming in brackish water may provide an alternative for food security. This study evaluated the effects of dietary salt supplementation and water salinity on growth, antioxidant activity, immune response, and gut microbiota. After 44 days, fish in freshwater receiving 5 % NaCl (CD-5.0) showed higher total immunoglobulin, lysozyme, and ACH₅₀ than those at 2.5 % NaCl (CD-2.5) (P < 0.05); antioxidant parameters did not differ (P > 0.05). qRT-PCR analysis revealed downregulation of pro-inflammatory genes (on-cc1, tnfα, and tnfβ) and upregulation of adaptive immune genes (igm and mhcII) in the CD-5.0 group (P < 0.05). At day 130, fish receiving 5 % dietary salt reared in freshwater and under gradually increasing water salinity (0 → 15 or 25 ppt) exhibited significantly higher growth compared to those fed 2.5 % dietary salt in freshwater (P < 0.05). These fish also displayed improved health status with attenuated proinflammatory (on-cc1, tnfα, tnfβ, on-cxc1, il-1β) and stress (hsp70) responses alongside enhanced adaptive immune (igm, mhcII) function. Microbiome shifts in the CD-5.0 + 25 ppt group were evident by Day 91 and more pronounced by Day 130 as indicated by the Shannon, Simpson, and PCoA indices. Notably, the core microbiota (Cetobacterium) abundance increased in this group (P < 0.05) correlating with growth improvement and health. Collectively, dietary salt supplementation—combined with gradual increases in water salinity—enhances Nile tilapia acclimation by modulating immunity, growth, and gut microbiota. These features support the feasibility of farming in brackish or high-salinity systems.