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ObjectiveTo explore the molecular mechanism of Qidi Tangshen prescription (QDTS) in regulating podocyte pyroptosis in diabetes nephropathy (DN). MethodThrough in vivo experiment, db/db mice were divided into the model group, QDTS group (3.34 g·kg-1), valsartan capsule group (10.29 mg·kg-1), with db/m mice serving as the normal control. Each group consisted of 8 mice, and they underwent continuous intervention for 8 weeks. After the last administration, mice were euthanized, and kidney pathological changes were observed. Additionally, the expression levels of pyroptosis-related indicators, including NOD-like receptor protein 3 (NLRP3), Gasdermin D protein (GSDMD), and interleukin-1β (IL-1β) protein, were examined. Through in vitro experiment, mouse podocytes were divided into the normal glucose group (5.5 mmol·L-1 glucose), high glucose group (35 mmol·L-1 glucose), DMSO group (35 mmol·L-1 glucose+200 mg·L-1 DMSO), and QDTS group (35 mmol·L-1 glucose+200 mg·L-1 QDTS freeze-dried powder). After 48 hours of intervention, the expression levels of NLRP3, GSDMD, and IL-1β proteins were measured in podocytes. A drug-ingredient-target-disease interaction network for QDTS in the treatment of DN was constructed by network pharmacology methods. The key signaling pathways regulating podocyte pyroptosis were analyzed, and validation was conducted through in vivo and in vitro experiments. ResultCompared with normal group, glomerular hyperplasia and glomerular basement membrane thickening were observed in model group, and some segments were accompanied by obvious podocellular process fusion. The protein expressions of NLRP3, GSDMD and IL-1β in mouse kidney were increased, the protein expressions of mitogen-activated protein kinase 14 (MAPK14), V-Rel reticuloendotheliosis virus oncogene homology A (RELA) and Caspase-8 in mouse kidney were increased (P<0.05). Compared with model group, kidney pathological injury of mice in QDTS group was significantly reduced, and the expressions of NLRP3, GSDMD and IL-1β in kidney of mice in QDTS group and valsartan group were decreased (P<0.05). The protein expressions of MAPK14, RELA and Caspase-8 in kidney of mice in QDTS group and valsartan group were decreased (P<0.05). Network pharmacology results showed that there were 16 targets for QDTS to regulate DN cell pyrodeath, among which MAPK14, RELA and Caspase-8 were the key targets. Compared with normal glucose group, the protein expressions of NLRP3, GSDMD and IL-1β in high glucose group were increased (P<0.05), and the protein expressions of MAPK14, RELA and Caspase-8 in mouse podocytes were increased (P<0.05). Compared with high glucose group, the expressions of NLRP3, GSDMD and IL-1β in podocytes of mice in QDTS group were decreased (P<0.05), and the expressions of MAPK14, RELA and Caspase-8 in podocytes of mice in QDTS group were decreased (P<0.05). ConclusionQDTS reduces damage to DN podocytes, which is associated with its regulation of the MAPK14/RELA/Caspase-8 signaling pathway and inhibition of podocyte pyroptosis.
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ObjectiveTo explore the mechanism of Qidi Tangshen prescription (QDTS) in alleviating podocyte injury and reducing urinary protein in diabetic nephropathy (DN). MethodUsing network pharmacology methods, we collected the chemical components and targets of QDTS, as well as the targets related to DN. Subsequently, we constructed a "drug-ingredient-target-disease" network for QDTS in the treatment of DN to systematically elucidate the mechanism. The db/db mice were assigned into the model, QDTS (3.34 g·kg-1), and losartan capsules (10.29 mg·kg-1) groups, and db/m mice served as the normal group. Each group consisted of 8 mice, and they underwent continuous intervention for 8 weeks. After the last administration, mice were euthanized, and the urinary albumin excretion rate (UAER) and renal pathological changes were measured and observed. The expression levels of protein kinase B1 (Akt1), hypoxia-inducible factor-1 alpha (HIF-1α), phosphorylated B-cell lymphoma-extra-large (p-Bcl-xl), as well as autophagy-related indicators microtubule-associated protein 1 light chain 3 (LC3), ubiquitin-binding protein p62 (p62), and autophagy-related gene 6 homolog (Beclin1), were determined. Furthermore, mouse podocytes were divided into the normal glucose (5.5 mmol·L-1), high glucose (35 mmol·L-1), DMSO (35 mmol·L-1 glucose+200 mg·L-1 DMSO), and QDTS (35 mmol·L-1 glucose+200 mg·L-1 QDTS freeze-dried powder) groups. After 48 h of intervention, the protein levels of Akt1, HIF-1α, p-Bcl-xl, LC3, p62, and Beclin1 in podocytes were measured. ResultQDTS had 34 active components acting on 143 targets in the treatment of DN, and 55 targets were related to autophagy, in which Akt1, HIF-1α, and Bcl-xl were the key targets. Compared with the normal group, mice in the model group exhibited significantly increased UAER, glomerular hypertrophy, deposition of blue collagen fibers, thickening of the glomerular basement membrane, and noticeable fusion of podocyte foot processes in some segments. Furthermore, the modeling up-regulated the protein levels of p-Akt1, HIF-1α, and p62 and down-regulating the protein levels of p-Bcl-xl, LC3, and Beclin1 in the renal tissue (P<0.05). Compared with the model group, QDTS and losartan decreased UAER (P<0.05) and alleviated the pathological damage in the renal tissue. Moreover, QDTS and losartan down-regulated the protein levels of p-Akt1, HIF-1α, and p62 and up-regulated the protein levels of p-Bcl-xl, LC3, and Beclin1 in the renal tissue (P<0.05). In comparison to the normal glucose group, the high glucose group displayed up-regulated protein levels of p-Akt1, HIF-1α, and p62 and down-regulated protein levels of p-Bcl-xl, LC3, and Beclin1 in podocytes (P<0.05). Compared with the high glucose group, QDTS down-regulated the protein levels of p-Akt1, HIF-1α, and p62 and up-regulated the protein levels of p-Bcl-xl, LC3, and Beclin1 in podocytes (P<0.05). ConclusionQDTS alleviates podocyte damage and reduced urinary protein in DN by regulating the Akt1/HIF-1α/Bcl-xl signaling pathway, thereby enhancing podocyte autophagy.
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Objective To investigate the mechanism that Rubescensine A reduces the podocyte damage induced by high glucose(HG)through the autophagy pathway mediated by AMP activated protein kinase/silent information regulator 1(AMPK/SIRT1)pathway.Methods Human glomerular podocytes were cultured in vitro,and randomly divided into Control group(Con),HG group,hydroxychloroquine(HCQ)group,and Rapamycin(RAP)group.CCK-8 was used to detect cell viability.Western blotting was used to detect cell apoptosis and podocyte injury related protein expression in each group.The podocyte model induced by high glucose(HG)was treated with Rubescensine A(Rub A)at different concentrations and the optimal concentration was selected.Then,human glomerular podocytes were randomly divided into Con group,HG group,Rub A group,Compound C group,and Rub A+Compound C group.The expression of autophagy,AMPK/SIRT1 pathway related proteins were detected in each group.Results Compared with Con group,the podocyte viability and the protein expressions of Synaptopodin and Bcl-2 was significantly reduced(P<0.05),while the protein expressions of Desmin and Bax were significantly increased in HG group(P<0.05).Compared with the HG group,all indicators were relieved in RAP group.However,the levels of all indicators were worsened in HCQ group.Compared with Con group,the expression levels of Desminand Bax proteins in podocytes were significantly increased(P<0.05),and the podocyte viability,number of autophagosomes,the expression levels of Synaptopodin,Bcl-2,microtubule associated protein light chain 3(LC3)II/I,Beclin-1,p-AMPK/AMPK and SIRT1 proteins were significantly reduced in HG group(P<0.05).Compared with HG group and Rub A+Compound C group,the above indicators were improved in Rub A group.Compound C group reversed the protective effect of Rub A.Conclusion Rubescensine A can promote autophagy by activating AMPK/SIRT1 pathway,thereby reduce podocyte damage induced by high glucose.
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Injury to podocytes is an early event in diabetic nephropathy leading to proteinuria with possible progression to end-stage renal failure. The podocytes are unique and highly specialized cells that cover the outer layer of kidney ultrafiltration barrier and play an important role in glomerular function. In the past few decades, adult stem cells, such as mesenchymal stem cells (MSCs) with a regenerative and differentiative capacity have been extensively used in cell-based therapies. In addition to their capability for regeneration and differentiation, MSCs contributes to their milieu by paracrine action of a series of growth factors via antiapoptotic, mitogenic and other cytokine actions that actively participate in treatment of podocyte damage through prevention of podocyte effacement, detachment and apoptosis. It is hoped that novel stem cell-based therapies will be developed in the future to prevent podocyte injury, thereby reducing the burden of kidney disease.