渔业科学杂志.com

  • 期刊 h 指数: 30
  • 期刊引用分数: 25.50
  • 期刊影响因子: 21.90
索引于
  • 学术期刊数据库
  • Genamics 期刊搜索
  • 全球影响因子 (GIF)
  • 中国知网(CNKI)
  • 引用因子
  • 电子期刊图书馆
  • 国际农业与生物科学中心 (CABI)
  • 研究期刊索引目录 (DRJI)
  • OCLC-WorldCat
  • 普罗奎斯特传票
  • 普布隆斯
  • 米亚尔
  • 高级科学索引
  • 谷歌学术
  • 化学文摘
  • 夏尔巴罗密欧
  • 秘密搜索引擎实验室
  • 研究之门
  • 残疾大学
分享此页面

抽象的

Saltwater Barrel Physiological Compensatory Mechanisms in Hypothermia

Olawale Onada

The freshwater drum, or Aplodinotus grunniens, is a common type of eurythermal freshwater fish in North America. New aquaculture opportunities emerged as a result of our team's significant advancements in artificial breeding and cultivation in 2019 and research into the physiological responses of the organisms to their surroundings. Its capacity to adapt to hypothermia and maintain metabolic homeostasis, on the other hand, is poorly understood. This experiment used cold stress for eight days at temperatures of 18 °C (LT18) and 10 °C (LT10), with a control temperature of 25 °C (Con), in order to investigate the effects of shortterm hypothermia on the physiology and metabolism of freshwater drum. LT18 and LT10 had significantly lower levels of free essential amino acids than Con after two days of cold stress. At LT10, both the activity of lipase (LPS) and the amount of total triglyceride (TG) in the plasma decreased over the course of two days. According to RNA-seq in the liver, metabolic-related signaling, particularly amino acid synthesis and lipid metabolism, was prevented by hypothermia. The PPAR signaling pathway is specifically connected to hypothermia-induced inhibition of lipid and amino acid metabolism. These findings confirmed that PPAR signaling maintains lipid and amino acid metabolic homeostasis under cold stress. These results theoretically support hypothermia resistance in the metabolic homeostasis of freshwater drums.

Keywords

Hypothermia; Lipid Metabolism; Amino Acid Metabolism; Ppar Signaling

免责声明: 此摘要通过人工智能工具翻译,尚未经过审核或验证