Environmental salinity variations have been proved to stimulate Na+-K+-ATPase (NKA) activity to regulate homeostasis in intestine of euryhaline teleosts. In addition liver can conduct metabolism for supplying intact energy demand. The non-essential amino acid, glutamate, is the most abundant amino acid in organisms. In euryhaline teleosts, glutamate accumulation and related metabolism have been observed in several vital tissues under salinity challenges. However, molecular evidences and related proper inferences regarding glutamate utilization are still in absence in teleost intestine and liver so far. 　　In this study, we used Japanese medaka (Oryzias latipes) as a model euryhaline teleost for salinity perturbation test. Under salinity challenges, transcripts expressions of glutamine transporters (SAT1) and glutamate (Glu)/glutamine (Gln) synthesis enzymes (GSL and GLUL) in intestine and liver were obviously stimulated and found to be respectively expressed in intestinal epithelial cells and hepatocytes. Moreover glutamate deamination would further lead to NH4+ production; therefore, those NH4+-derived urea cycle candidates, carbamoyl phosphate (CPS) and ornithine transcarbamylase (OTC) in intestine, argininosuccinate lyase (ASL), arginase (ARG) and agmatinase (AGMAT) in liver, were found to be up-regulated under ambient salinity challenges. Those results inferred that Glu/Gln metabolism, subsequent transport and further urea cycle activation from metabolic nitrogenous waste in intestine and liver of euryhaline teleosts may not only be vital for intact metabolic demand, but also for body osmolality maintenance in face of salinity challenges.