Serine Palmitoyltransferase Gene Silencing Prevents Ceramide Accumulation and Insulin Resistance in Muscles in Mice Fed a High-Fat Diet.
Monika ImierskaPiotr ZabielskiKamila Roszczyc-OwsiejczukEmilia SokołowskaKarolina PogodzińskaIwona KojtaAgnieszka Urszula Błachnio-ZabielskaPublished in: Cells (2022)
Skeletal muscles account for ~80% of insulin-stimulated glucose uptake and play a key role in lipid metabolism. Consumption of a high-fat diet (HFD) contributes to metabolic changes in muscles, including the development of insulin resistance. The studies carried out to date indicate that the accumulation of biologically active lipids, such as long-chain acyl-CoA, diacylglycerols and ceramides, play an important role in the development of insulin resistance in skeletal muscles. Unfortunately, it has not yet been clarified which of these lipid groups plays the dominant role in inducing these disorders. In order to explore this topic further, we locally silenced the gene encoding serine palmitoyltransferase (SPT) in the gastrocnemius muscle of animals with HFD-induced insulin resistance. This enzyme is primarily responsible for the first step of de novo ceramide biosynthesis. The obtained results confirm that the HFD induces the development of whole-body insulin resistance, which results in inhibition of the insulin pathway. This is associated with an increased level of biologically active lipids in the muscles. Our results also demonstrate that silencing the SPT gene with the shRNA plasmid reduces the accumulation of ceramides in gastrocnemius muscle, which, in turn, boosts the activity of the insulin signaling pathway. Furthermore, inhibition of ceramide synthesis does not significantly affect the content of other lipids, which suggests the leading role of ceramide in the lipid-related induction of skeletal muscle insulin resistance.
Keyphrases
- high fat diet
- insulin resistance
- skeletal muscle
- type diabetes
- high fat diet induced
- fatty acid
- adipose tissue
- glycemic control
- polycystic ovary syndrome
- metabolic syndrome
- signaling pathway
- escherichia coli
- copy number
- oxidative stress
- genome wide
- blood glucose
- crispr cas
- epithelial mesenchymal transition
- weight loss
- stress induced
- high glucose
- induced apoptosis
- protein kinase
- sensitive detection
- blood pressure
- genome wide analysis