Abstract
Salinity is a key environmental factor regulating lipid metabolism in marine oleaginous protists. This study examined the impact of NaCl concentration on growth, glucose utilization, and lipid biosynthesis in Thraustochytrium sp. ATCC 26185. Moderate salinity (20 g/L) enhanced biomass and glucose uptake, while high salinity (45 g/L) induced osmotic stress yet significantly promoted squalene accumulation (17.27 mg/g), a 3.26-fold increase compared with 0 g/L NaCl (5.29 mg/g). Integrated transcriptomic and metabolomic analyses revealed that salinity-dependent activation of glycolysis, the TCA cycle, and the pentose phosphate pathway increased cellular ATP, NADH, and NADPH levels. Under salt stress, the mevalonate (MVA) pathway was transcriptionally upregulated, with key enzymes, including ACAT, HMGR, and IDI, showing marked induction, which supports enhanced carbon flux toward squalene biosynthesis. Despite SQS downregulation, squalene accumulation increased, likely due to elevated precursor availability and reduced flux to downstream sterol pathways. Concurrently, high salinity repressed expression of ACC, FAS-α, and FAS-β, reducing saturated fatty acid levels, while upregulation of PKSB-favored polyunsaturated fatty acid (PUFA) synthesis. These findings suggest that high-salt stress triggers transcriptional reprogramming, redirecting acetyl-CoA from fatty acid synthesis toward squalene and PUFA production. This study offers new insights into the metabolic plasticity of thraustochytrids and highlights salinity modulation as a promising strategy for enhancing high-value lipid yields in marine biotechnology.