CD-1db/db mice: A novel type 2 diabetic mouse model with progressive kidney fibrosis

The PKM2 activator TEPP-46 suppresses cellular senescence in hydrogen peroxide-induced proximal tubular cells and kidney fibrosis in CD-1db/db mice

AIM/INTRODUCTION

Senescence is a key driver of age-related kidney dysfunction, including diabetic kidney disease. Oxidative stress activates cellular senescence, induces abnormal glycolysis, and is associated with pyruvate kinase muscle isoform 2 (PKM2) dysfunction; however, the mechanisms linking PK activation to cellular senescence have not been elucidated. We hypothesized that PKM2 activation by TEPP-46 could suppress oxidative stress-induced renal tubular cell injury and cellular senescence.

MATERIALS AND METHODS

To investigate the effects of PKM2 activation on oxidative stress-induced cellular senescence, we conducted β-galactosidase staining and western blot analysis on human primary renal tubular cells (pRPTECs) treated with hydrogen peroxide with or without TEPP-46. IL-6 levels and glycolytic flux were measured. Cell viability and apoptosis were assessed via the MTS assay and caspase 3 cleavage. For in vivo experiments, we utilized CD-1db/db mice, a fibrotic type 2 diabetes model, which exhibit kidney fibrosis. After 4 weeks of TEPP-46 intervention, kidney fibrosis and the expression of senescence markers were analyzed.

RESULTS

In pRPTECs, hydrogen peroxide increased the number of β-galactosidase-positive cells, the expression of senescence markers (p16, p21, p53), and p38 phosphorylation; co-incubation with TEPP-46 suppressed these alterations. Hydrogen peroxide reduced cell viability, induced apoptosis, mesenchymal alterations, and increased lactate production and IL-6 secretion; co-incubation with TEPP-46 or a p38 inhibitor mitigated these effects. In CD-1db/db mice, TEPP-46 intervention suppressed apoptosis, fibrosis, and tended to reduce the levels of senescence-associated molecules in the kidney.

CONCLUSIONS

PKM2 activation could be a molecular target for protection against senescence-associated organ damage, including diabetic kidney disease.

Renal Angptl4 is a key fibrogenic molecule in progressive diabetic kidney disease

Angiopoietin-like 4 (ANGPTL4), a key protein involved in lipoprotein metabolism, has diverse effects. There is an association between Angptl4 and diabetic kidney disease; however, this association has not been well investigated. We show that both podocyte- and tubule-specific ANGPTL4 are crucial fibrogenic molecules in diabetes. Diabetes accelerates the fibrogenic phenotype in control mice but not in ANGPTL4 mutant mice. The protective effect observed in ANGPTL4 mutant mice is correlated with a reduction in stimulator of interferon genes pathway activation, expression of pro-inflammatory cytokines, reduced epithelial-to-mesenchymal transition and endothelial-to-mesenchymal transition, lessened mitochondrial damage, and increased fatty acid oxidation. Mechanistically, we demonstrate that podocyte- or tubule-secreted Angptl4 interacts with Integrin β1 and influences the association between dipeptidyl-4 with Integrin β1. We demonstrate the utility of a targeted pharmacologic therapy that specifically inhibits Angptl4 gene expression in the kidneys and protects diabetic kidneys from proteinuria and fibrosis. Together, these data demonstrate that podocyte- and tubule-derived Angptl4 is fibrogenic in diabetic kidneys.

Synthesis and activity of arylcoumarin derivatives with therapeutic effects on diabetic nephropathy

In the literature, daidzein has been reported to exhibit cardiovascular protective effects and hypoglycemic activity in mice. We sought to design and synthesize a novel compound, SJ-6, an analog of daidzein, with improved hypoglycemic properties. Although SJ-6 demonstrated favorable hypoglycemic effects, its pharmacokinetic limitations prompted us to design and synthesize prodrugs of SJ-6. We conducted a comprehensive evaluation of the prodrugs, including in vitro and in vivo studies, such as cytotoxicity, absorption, distribution, metabolism, excretion, and toxicity (ADMET) simulation analysis, in vitro blood-brain barrier (BBB) permeability evaluation, compound effect on insulin resistance, oral glucose tolerance test (OGTT), in vivo plasma concentration testing, acute toxicity test in rats, and long-term gavage administration experiment. Furthermore, we examined the antidiabetic nephropathy activity of our lead compound, compound 10, which demonstrated superior efficacy compared with the positive control drug, metformin hydrochloride. Our findings suggest that compound 10 represents a promising lead compound for the prevention and treatment of diabetic nephropathy.

Translation Animal Models of Diabetic Kidney Disease: Biochemical and Histological Phenotypes, Advantages and Limitations

Animal models play a crucial role in studying the pathogenesis of diseases, developing new drugs, identifying disease risk markers, and improving means of prevention and treatment. However, modeling diabetic kidney disease (DKD) has posed a challenge for scientists. Although numerous models have been successfully developed, none of them can encompass all the key characteristics of human DKD. It is essential to choose the appropriate model according to the research needs, as different models develop different phenotypes and have their limitations. This paper provides a comprehensive overview of biochemical and histological phenotypes, modeling mechanisms, advantages and limitations of DKD animal models, in order to update relevant model information and provide insights and references for generating or selecting the appropriate animal models to fit different experimental needs.

The Role of Tβ4-POP-Ac-SDKP Axis in Organ Fibrosis

Fibrosis is a pathological process in which parenchymal cells are necrotic and excess extracellular matrix (ECM) is accumulated due to dysregulation of tissue injury repair. Thymosin β4 (Tβ4) is a 43 amino acid multifunctional polypeptide that is involved in wound healing. Prolyl oligopeptidase (POP) is the main enzyme that hydrolyzes Tβ4 to produce its derivative N-acetyl-seryl-aspartyl-lysyl-proline (Ac-SDKP) which is found to play a role in the regulation of fibrosis. Accumulating evidence suggests that the Tβ4-POP-Ac-SDKP axis widely exists in various tissues and organs including the liver, kidney, heart, and lung, and participates in the process of fibrogenesis. Herein, we aim to elucidate the role of Tβ4-POP-Ac-SDKP axis in hepatic fibrosis, renal fibrosis, cardiac fibrosis, and pulmonary fibrosis, as well as the underlying mechanisms. Based on this, we attempted to provide novel therapeutic strategies for the regulation of tissue damage repair and anti-fibrosis therapy. The Tβ4-POP-Ac-SDKP axis exerts protective effects against organ fibrosis. It is promising that appropriate dosing regimens that rely on this axis could serve as a new therapeutic strategy for alleviating organ fibrosis in the early and late stages.

Fibrosis of the diabetic heart: Clinical significance, molecular mechanisms, and therapeutic opportunities

In patients with diabetes, myocardial fibrosis may contribute to the pathogenesis of heart failure and arrhythmogenesis, increasing ventricular stiffness and delaying conduction. Diabetic myocardial fibrosis involves effects of hyperglycemia, lipotoxicity and insulin resistance on cardiac fibroblasts, directly resulting in increased matrix secretion, and activation of paracrine signaling in cardiomyocytes, immune and vascular cells, that release fibroblast-activating mediators. Neurohumoral pathways, cytokines, growth factors, oxidative stress, advanced glycation end-products (AGEs), and matricellular proteins have been implicated in diabetic fibrosis; however, the molecular links between the metabolic perturbations and activation of a fibrogenic program remain poorly understood. Although existing therapies using glucose- and lipid-lowering agents and neurohumoral inhibition may act in part by attenuating myocardial collagen deposition, specific therapies targeting the fibrotic response are lacking. This review manuscript discusses the clinical significance, molecular mechanisms and cell biology of diabetic cardiac fibrosis and proposes therapeutic targets that may attenuate the fibrotic response, preventing heart failure progression.