Department of Cardiovascular Medicine, First Affiliated Hospital of Xi'an Jiaotong University, Xi'an, China.
Key Laboratory of Molecular Cardiology of Shaanxi Province, Xi'an, China.
Hypertens Res. 2024 Oct;47(10):2811-2825. doi: 10.1038/s41440-024-01814-4. Epub 2024 Aug 8.
Recent evidence suggests that necroptosis may contribute to the development of kidney injury. Renalase is a novel secretory protein that exerts potent prosurvival and anti-inflammatory effects. We hypothesized that renalase could protect the kidney from salt-induced injury by modulating necroptosis. High salt and renalase treatments were administered to Dahl salt-sensitive (SS) rats, renalase knockout (KO) mice, and HK-2 cells. Furthermore, a cohort of 514 eligible participants was utilized to investigate the association between single nucleotide polymorphisms (SNPs) in the genes RIPK1, RIPK3, and MLKL, and the risk of subclinical renal damage (SRD) over 14 years. A high-salt diet significantly increased the expression of key components of necroptosis, namely RIPK1, RIPK3, and MLKL, as well as the release of inflammatory factors in SS rats. Treatment with recombinant renalase reduced both necroptosis and inflammation. In renalase KO mice, salt-induced kidney injury was more severe than in wild-type mice, but supplementation with renalase attenuated the kidney injury. In vitro experiments with HK-2 cells revealed high salt increased necroptosis and inflammation. Renalase exhibited a dose-dependent decrease in salt-induced necroptosis, and this cytoprotective effect was negated by the knockdown of PMCA4b, which is the receptor of renalase. Furthermore, the cohort study showed that SNP rs3736724 in RIPK1 and rs11640974 in MLKL were significantly associated with the risk of SRD over 14 years. Our analysis shows that necroptosis plays a significant role in the development of salt-induced kidney injury and that renalase confers its cytoprotective effects by inhibiting necroptosis and inflammation.
最近的证据表明,坏死性凋亡可能有助于肾损伤的发展。肾酶是一种新型分泌蛋白,具有强大的促生存和抗炎作用。我们假设肾酶可以通过调节坏死性凋亡来保护肾脏免受盐诱导的损伤。给 Dahl 盐敏感(SS)大鼠、肾酶敲除(KO)小鼠和 HK-2 细胞给予高盐和肾酶治疗。此外,利用 514 名符合条件的参与者队列来研究 RIPK1、RIPK3 和 MLKL 基因中的单核苷酸多态性(SNP)与亚临床肾脏损伤(SRD)风险之间的关联超过 14 年。高盐饮食显著增加了坏死性凋亡的关键组成部分,即 RIPK1、RIPK3 和 MLKL 的表达,以及 SS 大鼠中炎症因子的释放。重组肾酶的治疗降低了坏死性凋亡和炎症。在肾酶 KO 小鼠中,盐诱导的肾脏损伤比野生型小鼠更严重,但肾酶的补充减轻了肾脏损伤。体外实验用 HK-2 细胞揭示高盐增加了坏死性凋亡和炎症。肾酶表现出剂量依赖性降低盐诱导的坏死性凋亡,而 PMCA4b 的敲低(肾酶的受体)则否定了这种细胞保护作用。此外,队列研究表明,RIPK1 中的 SNP rs3736724 和 MLKL 中的 SNP rs11640974 与 14 年以上的 SRD 风险显著相关。我们的分析表明,坏死性凋亡在盐诱导的肾脏损伤的发展中起重要作用,肾酶通过抑制坏死性凋亡和炎症发挥其细胞保护作用。
