Non‐invasive omics analysis delineates molecular changes in water‐only fasting and its sex‐discriminating features in metabolic syndrome patients
Yanyu Jiang,
Zhimei Tang,
Xiaogang Zhu,
Biying Xiao,
Hechuan Tian,
Xingxing Lei,
Huan Peng,
Jun Qin,
Yanmei Zhang,
Robert M. Hoffman,
Xiaorong Hu,
Qiu Chen,
Guang Ji,
Lijun Jia
Affiliations
Yanyu Jiang
Cancer Institute Longhua Hospital Shanghai University of Traditional Chinese Medicine Shanghai China
Zhimei Tang
Hospital of Chengdu University of Traditional Chinese Medicine Sichuan China
Xiaogang Zhu
Dujiangyan Diabetes Hospital Sichuan China
Biying Xiao
Cancer Institute Longhua Hospital Shanghai University of Traditional Chinese Medicine Shanghai China
Hechuan Tian
Cancer Institute Longhua Hospital Shanghai University of Traditional Chinese Medicine Shanghai China
Xingxing Lei
Hospital of Chengdu University of Traditional Chinese Medicine Sichuan China
Huan Peng
Hospital of Chengdu University of Traditional Chinese Medicine Sichuan China
Jun Qin
State Key Laboratory of Proteomics Beijing Proteome Research Center National Center for Protein Sciences (Beijing) Beijing Institute of Lifeomics Beijing China
Yanmei Zhang
Department of Laboratory Medicine Huadong Hospital Fudan University Shanghai China
Robert M. Hoffman
Department of Surgery University of California San Diego San Diego California USA
Xiaorong Hu
Dujiangyan Diabetes Hospital Sichuan China
Qiu Chen
Hospital of Chengdu University of Traditional Chinese Medicine Sichuan China
Guang Ji
Institute of Digestive Diseases Longhua Hospital Shanghai University of Traditional Chinese Medicine Shanghai China
Lijun Jia
Cancer Institute Longhua Hospital Shanghai University of Traditional Chinese Medicine Shanghai China
Abstract Fasting has been grown in popularity with multiple potential benefits. However, very few studies dynamically monitor physiological and pathological changes during long‐term fasting using noninvasive methods. In the present study, we recruited 37 individuals with metabolic syndrome to engage in a 5‐day water‐only fasting regimen, and simultaneously captured the molecular alterations through urinary proteomics and metabolomics. Our findings reveal that water‐only fasting significantly mitigated metabolic syndrome‐related risk markers, such as body weight, body mass index, abdominal circumference, blood pressure, and fasting blood glucose levels in metabolic syndrome patients. Indicators of liver and renal function remained within the normal range, with the exception of uric acid. Notably, inflammatory response was inhibited during the water‐only fasting period, as evidenced by a decrease in the human monocyte differentiation antigen CD14. Intriguingly, glycolysis, tricarboxylic acid cycle, and oxidative phosphorylation underwent a sex‐dependent reprogramming throughout the fasting period, whereby males exhibited a greater upregulation of carbohydrate metabolism‐related enzymes than females. This disparity may be attributed to evolutionary pressures. Collectively, our study sheds light on the beneficial physiological effects and novel dynamic molecular features associated with fasting in individuals with metabolic syndrome using noninvasive methods.
