Effects of Mao tea from Nankun Mountain on nonalcoholic fatty liver disease in mice.
Weitao ZhangLianshun FengPeng LiAoyi WangChunyan DaiYajuan QiJunfeng LuXiaojun XuPublished in: Food & function (2024)
Non-alcoholic fatty liver disease (NAFLD) poses a significant health threat due to its potential progression to liver fibrosis, cirrhosis, and even liver cancer. Without proper management, NAFLD can lead to severe complications and significantly impact overall health and longevity. This study explores the potential anti-steatosis effects of Nankun Mountain Mao tea (MT) on hepatic lipid accumulation using both in vitro and in vivo models. In vitro experiments reveal that MT reduces lipid accumulation in hepatocytes and counteracts hepatic steatosis induced by palmitic acid and oleic acid. In vivo investigations on high-fat diet (HFD)-fed and high-fat, fructose, and cholesterol (HFFC)-fed mice demonstrate that MT administration alleviates hepatic steatosis by reducing lipid accumulation, enhancing liver function, and mitigating inflammation. Transcriptomic analyses unveil the molecular mechanisms underlying the impact of MT on lipid metabolism and inflammation. It turns out that MT inhibits de novo lipid synthesis and NF-κB pathway against NAFLD. Furthermore, target prediction analysis identifies potential bioactive components group (BCG) within MT that may contribute to its anti-steatosis properties. Validation studies on primary hepatocytes confirm the effectiveness of these bioactive components in diminishing lipid accumulation and inflammation, suggesting their role in the therapeutic efficacy of MT against NAFLD.
Keyphrases
- high fat diet
- liver fibrosis
- insulin resistance
- oxidative stress
- high fat diet induced
- adipose tissue
- healthcare
- public health
- mental health
- randomized controlled trial
- type diabetes
- genome wide
- signaling pathway
- human health
- systematic review
- immune response
- mouse model
- fatty acid
- risk assessment
- health promotion
- skeletal muscle
- early onset
- inflammatory response
- climate change
- social media
- dna methylation
- single molecule
- pi k akt