The precise mechanism of SKP in DKD remains incompletely understood. Utilizing a DKD animal model induced by intraperitoneal injection of STZ combined with HFD(21, 22), we evaluated renal function through crucial indicators such as 24h urine protein levels, urea nitrogen, and serum creatine. SKP exhibited significant improvement in renal injury in DKD mice, as evidenced by HE and PAS pathological staining, which revealed alleviation of renal tubular dilatation, vacuolar degeneration, and mild glomerular basement membrane thickening. Renal fibrosis is a major pathway in the progression of DKD, and may lead to ESRD. Excessive ROS production can trigger oxidative stress and accelerate fibrosis progression(23, 24). Meanwhile, it has been demonstrated that ferroptosis may be associated with fibrosis(25).We found that SKP could significantly reduce the expression of α-SMA, Fibronectin, and Vimentin in renal tissues of DKD mice. This was also confirmed by Masson and Sirius Red staining.
The study delved into the molecular mechanisms underlying SKP’s effects on ferroptosis. Excessive intracellular ROS and iron trigger lipid peroxidation of phospholipids, leading to ferroptosis (26). GPX4, a key negative regulator of ferroptosis(27), catalyzes GSH to remove ROS, thereby safeguarding cell membrane integrity and reducing ferroptosis(28). Malonaldehyde (MDA), as the end product of lipid peroxidation, serves as an indicator of oxidative stress severity(26). We then examined the above indicators and concluded that SKP could effectively reduce ROS and MDA levels and increase the expression of GSH and GPX4 in kidney of DKD mice. In addition, the histochemical results of GPX4 suggested that the expression of GPX4 in the renal tubules of normal mice was higher than that of DKD mice, it was significantly improved after SKP treatment. Prussian blue staining showed that iron deposition occurred in the renal tubules of DKD mice compared with the normal group. All these findings validate our hypothesis on SKP’s impact on DKD, shedding lights on its potential as a therapeutic intervention.
By analyzing active ingredients and targets of SKP through network pharmacology, we screened out interaction targets of SKP with DKD and ferroptosis: TP53, IL6, EGFR, CTNNB1, ESR1, JUN, MYC, HIF1A, MYC, JUN, PTGS2, CASP8, CAV1, AR, ERBB2, GSK3B, MDM2, MAPK1, HSPA5, RELA, NFE2L2, HMOX1, HSPB1, RB1, GJA1, GSTP1, BIRC5, PRKCB, DPP4, PCNA, ALOX5, TRPV1, ATP5B, DPEP1. Furthermore, quercetin, kaempferol, isorhamnetin, beta-sitosterol, luteolin, stigmasterol, and beta-carotene were identified as main active ingredients of SKP in the treatment of ferroptosis in DKD. Among them, quercetin can alleviate renal tubular cell death and inflammation in acute kidney injury by inhibiting ferroptosis(29). Kaempferol is considered to have anti-inflammatory and anti-oxidation effects(30), which can inhibit ferroptosis of hepatocytes by activating Nrf2 pathway(31). Isorhamnetin has anti-inflammatory and anti-cancer effects, and can also reduce MDA levels in the prefrontal cortex and hippocampus, thereby preventing oxidation(32). Beta-sitosterol, which has a positive effect on anti-oxidation and anti-inflammation(33). Luteolin can reduce renal anemia caused by renal fibrosis by regulating SIRT1/FOXO3 pathway(34). Stigmasterol has been shown to reduce inflammation(35). Additionally, beta-carotene has exhibited note-worthy anti-aging capabilities in both in vivo and in vitro studies(36). KEGG enrichment analysis pinpointed the HIF-1 signaling pathway as a key player in SKP’s treatment of DKD-associated ferroptosis. Molecular docking heat map results further underscored robust binding activity between important targets and the main active components. Drawing from insights gained through the network pharmacology and molecular docking analysis, a compelling hypothesis emerges: SKP’s mitigation of ferroptosis in diabetic nephropathy primarily hinges on the inhibition of HIF-1α/HO-1 signaling pathway. This proposed mechanism sheds light on the intricate interplay between SKP’s active ingredients, molecular targets, and crucial pathways, offering a comprehensive perspective on its therapeutic potential in managing diabetic kidney disease.
The regulatory factor Hypoxia-inducible factor-1 (HIF-1) plays a pivotal role in responding to Hypoxia, exsiting as a heterodimeric transcription factor comprising α subunit (HIF-1α) and β subunit (HIF-1β)(37, 38). Under normoxia conditions, HIF-1α triggers ubiquitin-proteasome pathway to cause degradation(39). However, in hypoxia environments, HIF-1α stabilizes, translocates into the nucleus, and forms a complex with Hif-1β. This complex binds to hypoxia-response element sites, regulating the expression of target genes(40, 41). Heme Oxygenase-1 (HO-1) stands as a downstream target gene of HIF-1α (42). It breaks down heme, generating metabolites like biliverdin, ferrous ion, carbon monoxide and biliverdin/bilirubin. Elevated HO-1 expression increases Fe2+ production, leading to Fenton reaction(43, 44), ROS overload and ultimately inducing ferroptosis(45)(Fig. 8). In our in vivo experiments, DKD mice exhibited significantly higher level of HIF-1α and HO-1 in their kidneys compared to normal mice. The observed reduction in ROS, HIF-1α and HO-1 expression with SKP suggests a potential attenuation of ferroptosis and alleviation of DKD through the inhibition of HIF-1α /HO-1 signaling.
Despite providing important insights into the mechanisms of SKP in DKD treatment, this study has limitations. For instance, the research is primarily based on animal models, and the results need further validation in human clinical trials. Future studies should also explore the effects and long-term safety of SKP in different types and stages of DKD treatment.