Targeted and untargeted metabolomics provide insight into the consequences of glycine‐N‐methyltransferase deficiency including the novel finding of defective immune function
Abstract Fatty liver disease is increasing along with the prevalence of obesity and type‐2 diabetes. Hepatic fibrosis is a major health complication for which there are no efficacious treatment options available. A better understanding of the fundamental mechanisms that contribute to the accumulatio...
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2020-09-01
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| Series: | Physiological Reports |
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| Online Access: | https://doi.org/10.14814/phy2.14576 |
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doaj-322d55e88cf44132b297130b64f4ac532020-11-25T03:15:24ZengWileyPhysiological Reports2051-817X2020-09-01818n/an/a10.14814/phy2.14576Targeted and untargeted metabolomics provide insight into the consequences of glycine‐N‐methyltransferase deficiency including the novel finding of defective immune functionBrandon J. Eudy0Caitlin E. McDermott1Xiuli Liu2Robin P. daSilva3Department of Food Science and Human Nutrition University of Florida Gainesville FL USADepartment of Food Science and Human Nutrition University of Florida Gainesville FL USADepartment of Pathology, Immunology and Laboratory Medicine University of Florida Gainesville FL USADepartment of Food Science and Human Nutrition University of Florida Gainesville FL USAAbstract Fatty liver disease is increasing along with the prevalence of obesity and type‐2 diabetes. Hepatic fibrosis is a major health complication for which there are no efficacious treatment options available. A better understanding of the fundamental mechanisms that contribute to the accumulation of fibrosis is needed. Glycine‐N‐methyltransferase (GNMT) is a critical enzyme in one‐carbon metabolism that serves to regulate methylation and remethylation reactions. GNMT knockout (GNMT‐/‐) mice display spontaneous hepatic fibrosis and later develop hepatocellular carcinoma. Previous literature supports the idea that hypermethylation as a consequence of GNMT deletion contributes to the hepatic phenotype observed. However, limited metabolomic information is available and the underlying mechanisms that contribute to hepatic fibrogenesis in GNMT‐/‐ mice are still incomplete. Therefore, our goals were to use dietary intervention to determine whether increased lipid load exacerbates steatosis and hepatic fibrosis in this model and to employ both targeted and untargeted metabolomics to further understand the metabolic consequences of GNMT deletion. We find that GNMT mice fed high‐fat diet do not accumulate more lipid or fibrosis in the liver and are in fact resistant to weight gain. Metabolomics analysis confirmed that pan‐hypermethylation occurs in GNMT mice resulting in a depletion of nicotinamide intermediate metabolites. Further, there is a disruption in tryptophan catabolism that prevents adequate immune cell activation in the liver. The chronic cellular damage cannot be appropriately cleared due to a lack of immune checkpoint activation. This mouse model is an excellent example of how a disruption in small molecule metabolism can significantly impact immune function.https://doi.org/10.14814/phy2.14576aryl hydrocarbon receptorfibrosisNADone‐carbon metabolismtryptophan |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Brandon J. Eudy Caitlin E. McDermott Xiuli Liu Robin P. daSilva |
| spellingShingle |
Brandon J. Eudy Caitlin E. McDermott Xiuli Liu Robin P. daSilva Targeted and untargeted metabolomics provide insight into the consequences of glycine‐N‐methyltransferase deficiency including the novel finding of defective immune function Physiological Reports aryl hydrocarbon receptor fibrosis NAD one‐carbon metabolism tryptophan |
| author_facet |
Brandon J. Eudy Caitlin E. McDermott Xiuli Liu Robin P. daSilva |
| author_sort |
Brandon J. Eudy |
| title |
Targeted and untargeted metabolomics provide insight into the consequences of glycine‐N‐methyltransferase deficiency including the novel finding of defective immune function |
| title_short |
Targeted and untargeted metabolomics provide insight into the consequences of glycine‐N‐methyltransferase deficiency including the novel finding of defective immune function |
| title_full |
Targeted and untargeted metabolomics provide insight into the consequences of glycine‐N‐methyltransferase deficiency including the novel finding of defective immune function |
| title_fullStr |
Targeted and untargeted metabolomics provide insight into the consequences of glycine‐N‐methyltransferase deficiency including the novel finding of defective immune function |
| title_full_unstemmed |
Targeted and untargeted metabolomics provide insight into the consequences of glycine‐N‐methyltransferase deficiency including the novel finding of defective immune function |
| title_sort |
targeted and untargeted metabolomics provide insight into the consequences of glycine‐n‐methyltransferase deficiency including the novel finding of defective immune function |
| publisher |
Wiley |
| series |
Physiological Reports |
| issn |
2051-817X |
| publishDate |
2020-09-01 |
| description |
Abstract Fatty liver disease is increasing along with the prevalence of obesity and type‐2 diabetes. Hepatic fibrosis is a major health complication for which there are no efficacious treatment options available. A better understanding of the fundamental mechanisms that contribute to the accumulation of fibrosis is needed. Glycine‐N‐methyltransferase (GNMT) is a critical enzyme in one‐carbon metabolism that serves to regulate methylation and remethylation reactions. GNMT knockout (GNMT‐/‐) mice display spontaneous hepatic fibrosis and later develop hepatocellular carcinoma. Previous literature supports the idea that hypermethylation as a consequence of GNMT deletion contributes to the hepatic phenotype observed. However, limited metabolomic information is available and the underlying mechanisms that contribute to hepatic fibrogenesis in GNMT‐/‐ mice are still incomplete. Therefore, our goals were to use dietary intervention to determine whether increased lipid load exacerbates steatosis and hepatic fibrosis in this model and to employ both targeted and untargeted metabolomics to further understand the metabolic consequences of GNMT deletion. We find that GNMT mice fed high‐fat diet do not accumulate more lipid or fibrosis in the liver and are in fact resistant to weight gain. Metabolomics analysis confirmed that pan‐hypermethylation occurs in GNMT mice resulting in a depletion of nicotinamide intermediate metabolites. Further, there is a disruption in tryptophan catabolism that prevents adequate immune cell activation in the liver. The chronic cellular damage cannot be appropriately cleared due to a lack of immune checkpoint activation. This mouse model is an excellent example of how a disruption in small molecule metabolism can significantly impact immune function. |
| topic |
aryl hydrocarbon receptor fibrosis NAD one‐carbon metabolism tryptophan |
| url |
https://doi.org/10.14814/phy2.14576 |
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