Alpha-Ketoglutarate Alleviates Neuronal Apoptosis Induced by Central Insulin Resistance through Inhibiting S6K1 Phosphorylation after Subarachnoid Hemorrhage.
Peng-Fei DingQi ZhuBin ShengHeng YangHua-Jie XuTao TaoZheng PengXiang-Xin ChenXiao-Jian LiYan ZhouHua-Sheng ZhangYong-Yue GaoZong ZhuangChun-Hua HangWei LiPublished in: Oxidative medicine and cellular longevity (2022)
Neuronal apoptosis after subarachnoid hemorrhage (SAH) is believed to play an important role in early brain injury after SAH. The energy metabolism of neuron is closely related to its survival. The transient hyperglycemia caused by insulin resistance (IR) after SAH seriously affects the prognosis of patients. However, the specific mechanisms of IR after SAH are still not clear. Studies have shown that α -KG takes part in the regulation of IR and cell apoptosis. In this study, we aim to investigate whether α -KG can reduce IR after SAH, improve the disorder of neuronal glucose metabolism, alleviate neuronal apoptosis, and ultimately play a neuroprotective role in SAH-induced EBI. We first measured α -KG levels in the cerebrospinal fluid (CSF) of patients with SAH. Then, we established a SAH model through hemoglobin (Hb) stimulation with HT22 cells for further mechanism research. Furthermore, an in vivo SAH model in mice was established by endovascular perforation. Our results showed that α -KG levels in CSF significantly increased in SAH patients and could be used as a potential prognostic biomarker. In in vitro model of SAH, we found that α -KG not only inhibited IR-induced reduction of glucose uptake in neurons after SAH but also alleviated SAH-induced neuronal apoptosis. Mechanistically, we found that α -KG inhibits neuronal IR by inhibiting S6K1 activation after SAH. Moreover, neuronal apoptosis significantly increased when glucose uptake was reduced. Furthermore, our results demonstrated that α -KG could also alleviate neuronal apoptosis in vivo SAH model. In conclusion, our study suggests that α -KG alleviates apoptosis by inhibiting IR induced by S6K1 activation after SAH.
Keyphrases
- cerebral ischemia
- subarachnoid hemorrhage
- brain injury
- cell cycle arrest
- oxidative stress
- endoplasmic reticulum stress
- cell death
- insulin resistance
- diabetic rats
- high glucose
- cerebrospinal fluid
- ejection fraction
- signaling pathway
- type diabetes
- adipose tissue
- endothelial cells
- prognostic factors
- spinal cord
- cell proliferation
- high fat diet
- polycystic ovary syndrome
- drug induced
- patient reported outcomes
- risk assessment
- climate change
- mouse model
- blood glucose
- patient reported
- human health
- stress induced