Palmitic acid induces lipid droplet accumulation and senescence in nucleus pulposus cells via ER-stress pathway.
Xi ChenKun ChenJun HuYijun DongMenglong ZhengJiang JiangQingsong HuWen-Zhi ZhangPublished in: Communications biology (2024)
Intervertebral disc degeneration (IDD) is a highly prevalent musculoskeletal disorder affecting millions of adults worldwide, but a poor understanding of its pathogenesis has limited the effectiveness of therapy. In the current study, we integrated untargeted LC/MS metabolomics and magnetic resonance spectroscopy data to investigate metabolic profile alterations during IDD. Combined with validation via a large-cohort analysis, we found excessive lipid droplet accumulation in the nucleus pulposus cells of advanced-stage IDD samples. We also found abnormal palmitic acid (PA) accumulation in IDD nucleus pulposus cells, and PA exposure resulted in lipid droplet accumulation and cell senescence in an endoplasmic reticulum stress-dependent manner. Complementary transcriptome and proteome profiles enabled us to identify solute carrier transporter (SLC) 43A3 involvement in the regulation of the intracellular PA level. SLC43A3 was expressed at low levels and negatively correlated with intracellular lipid content in IDD nucleus pulposus cells. Overexpression of SLC43A3 significantly alleviated PA-induced endoplasmic reticulum stress, lipid droplet accumulation and cell senescence by inhibiting PA uptake. This work provides novel integration analysis-based insight into the metabolic profile alterations in IDD and further reveals new therapeutic targets for IDD treatment.
Keyphrases
- induced apoptosis
- endoplasmic reticulum stress
- single cell
- signaling pathway
- cell cycle arrest
- oxidative stress
- high throughput
- dna damage
- fatty acid
- mass spectrometry
- cell death
- stem cells
- bone marrow
- stress induced
- mesenchymal stem cells
- physical activity
- gene expression
- weight gain
- transcription factor
- reactive oxygen species
- artificial intelligence
- body mass index
- dna methylation
- diabetic rats
- tandem mass spectrometry