SCOPE: A compromised nutritional status in methyl-group donors may provoke several molecular alterations triggering the development of nonalcoholic fatty liver disease (NAFLD) in humans and experimental animals. In this study, we investigated a role and the underlying molecular mechanisms of methionine metabolic pathway malfunctions in the pathogenesis of NAFLD. METHODS AND RESULTS: We fed female Swiss albino mice a control (methionine-adequate) diet and two experimental (methionine-deficient or methionine-supplemented) diets for 10 weeks, and the levels of one-carbon metabolites, expression of one-carbon and lipid metabolism genes in the livers were evaluated. We demonstrate that both experimental diets increased hepatic levels of S-adenosyl-l-homocysteine and homocysteine, altered expression of one-carbon and lipid metabolism genes, and caused lipid accumulation, especially in mice fed the methionine-deficient diet. Markers of oxidative and ER stress response were also elevated in the livers of mice fed either diet. CONCLUSION: Our findings indicate that both dietary methionine deficiency and methionine supplementation can induce molecular abnormalities in the liver associated with the development of NAFLD, including deregulation in lipid and one-carbon metabolic pathways, and induction of oxidative and ER stress. These pathophysiological events may ultimately lead to lipid accumulation in the livers, triggering the development of NAFLD.
SCOPE: A compromised nutritional status in methyl-group donors may provoke several molecular alterations triggering the development of nonalcoholic fatty liver disease (NAFLD) in humans and experimental animals. In this study, we investigated a role and the underlying molecular mechanisms of methionine metabolic pathway malfunctions in the pathogenesis of NAFLD. METHODS AND RESULTS: We fed female Swiss albino mice a control (methionine-adequate) diet and two experimental (methionine-deficient or methionine-supplemented) diets for 10 weeks, and the levels of one-carbon metabolites, expression of one-carbon and lipid metabolism genes in the livers were evaluated. We demonstrate that both experimental diets increased hepatic levels of S-adenosyl-l-homocysteine and homocysteine, altered expression of one-carbon and lipid metabolism genes, and caused lipid accumulation, especially in mice fed the methionine-deficient diet. Markers of oxidative and ER stress response were also elevated in the livers of mice fed either diet. CONCLUSION: Our findings indicate that both dietary methioninedeficiency and methionine supplementation can induce molecular abnormalities in the liver associated with the development of NAFLD, including deregulation in lipid and one-carbon metabolic pathways, and induction of oxidative and ER stress. These pathophysiological events may ultimately lead to lipid accumulation in the livers, triggering the development of NAFLD.
Authors: Igor P Pogribny; Kostiantyn Dreval; Iryna Kindrat; Stepan Melnyk; Leandro Jimenez; Aline de Conti; Volodymyr Tryndyak; Marta Pogribna; Juliana Festa Ortega; S Jill James; Ivan Rusyn; Frederick A Beland Journal: FASEB J Date: 2018-01-03 Impact factor: 5.191
Authors: Alec M Judd; Melinda K Matthews; Rachel Hughes; Madeline Veloz; Corinne E Sexton; John M Chaston Journal: Appl Environ Microbiol Date: 2018-08-17 Impact factor: 4.792
Authors: Hui Peng; Huiting Xu; Jie Wu; Jiangyuan Li; Yi Zhou; Zehuan Ding; Stefan K Siwko; Xianglin Yuan; Kevin L Schalinske; Gianfranco Alpini; Ke K Zhang; Linglin Xie Journal: Liver Int Date: 2021-02-16 Impact factor: 8.754
Authors: Anna Pastore; Anna Alisi; Gianna di Giovamberardino; Annalisa Crudele; Sara Ceccarelli; Nadia Panera; Carlo Dionisi-Vici; Valerio Nobili Journal: Int J Mol Sci Date: 2014-11-17 Impact factor: 5.923