Exploration of the Synergistic Regulation Mechanism in Cerebral Ganglion and Heart of on Energy Metabolism and Antioxidant Homeostasis Maintenance under Alkalinity Stress.

(1) The development and utilization of the vast saline-alkali land worldwide is an important way to solve the worsening food crisis. , due to its strong osmotic regulation capability and its characteristics of being suitable for culturing in alkaline water, has become a potential aquaculture species in saline-alkali water. The brain and heart are the key tissues for signal transduction and energy supply under environmental stress. (2) This study is the first to explore the synergistic regulatory molecular mechanism by integrated analysis on cerebral ganglion proteomics and heart metabolomics of under alkalinity stress. (3) The results indicate that the cerebral ganglion and heart of were closely related in response to acute alkalinity stress. The differential regulatory pathways mainly involved regulation of energy metabolism, amino acid metabolism, and homeostasis maintenance. Importantly, alkalinity stress induced the regulation of antioxidants and further adjusted longevity and rhythm in the cerebral ganglion and heart, reflecting that the cerebral ganglion and heart may be the key tissues for the survival of under an alkalinity environment. (4) This study provides a theoretical reference for research on the regulation mechanism of under alkalinity condition and contributes to the development of aquaculture in saline-alkali water.