Pioglitazone protects blood vessels through inhibition of the apelin signaling pathway by promoting KLF4 expression in rat models of T2DM

The PTGS1 (rs1330344) CC Genotype Contributes to Susceptibility to Kawasaki Disease in Southern Chinese Children

Kawasaki disease (KD) is an acute systemic vascular disease complicated by coronary artery injury. Although polymorphisms in prostaglandin-endoperoxide synthase 1 (PTGS1) are being increasingly explored in cardiovascular diseases, little is known regarding the connection between PTGS1 polymorphisms and KD risk. We evaluated 834 KD patients and 1474 healthy controls to explore the relationship between PTGS1 polymorphisms (rs1330344 and rs5788) and KD risk. Our results showed that the rs1330344 CC genotype was significantly associated with KD risk and coronary artery injury in children with KD. In combined analysis, individuals with 1-2 unfavorable genotypes had an increased risk of KD, compared with those with no risk genotype. Stratified analysis indicated that the rs1330344 CC genotype is strongly associated with increased risk of KD in children aged ≤60 months and females. Moreover, carrying 1-2 of these SNP genotypes had a higher risk of KD than those who harbored none of them in children ≤60 months of age and females; the risk of coronary artery dilatations/small aneurysms and medium/giant aneurysms was also significantly increased in KD patients. In summary, the PTGS1 rs1330344 CC genotype is associated with increased susceptibility to KD, which may contribute to KD pathogenesis and serve as a genetic biomarker.

The Role of Apelin-APJ System in Diabetes and Obesity

Nowadays, diabetes and obesity are two main health-threatening metabolic disorders in the world, which increase the risk for many chronic diseases. Apelin, a peptide hormone, exerts its effect by binding with angiotensin II protein J receptor (APJ) and is considered to be linked with diabetes and obesity. Apelin and its receptor are widely present in the body and are involved in many physiological processes, such as glucose and lipid metabolism, homeostasis, endocrine response to stress, and angiogenesis. In this review, we summarize the literatures on the role of the Apelin-APJ system in diabetes and obesity for a better understanding of the mechanism and function of apelin and its receptor in the pathophysiology of diseases that may contribute to the development of new therapies.

Exogenous Hydrogen Sulfide Ameliorates Diabetic Myocardial Fibrosis by Inhibiting Cell Aging Through SIRT6/AMPK Autophagy

Stress aging of myocardial cells participates in the mechanism of myocardial fibrosis (MF). Previous studies have shown that hydrogen sulfide (H₂S) can improve MF, however the specific internal mechanism remains still unclear. Therefore, this study aims to explore whether H₂S can improve myocardial cell aging induced by high glucose and myocardial fibrosis in diabetic rats by activating autophagy through SIRT6/AMPK. We observed that HG (high glucose, 33 mM) induced down-regulation of endogenous H₂S-producing enzyme CSE protein expression, increased cell senescence, down-regulation of autophagy-related proteins Beclin1, Atg5, Atg12, Atg16L1, and inhibition of SIRT6/AMPK signaling pathway in H9c2 cardiomyocytes. H₂S (NaHS: 400 μM) could up-regulate CSE protein expression, inhibit cell senescence, activate autophagy and SIRT6/AMPK signaling pathway. On the contrary, no above phenomena was achieved upon addition of CSE inhibitor PAG (dl-propargylglycine: mmol/L). In order to further elucidate the relationship between H₂S and SIRT6/AMPK signaling pathway, dorsomorphin dihydrochloride (Dor), an inhibitor of AMPK signaling pathway, was added to observe the reversal of H₂S’s inhibitory effect on myocardial cell aging. At the same, streptozotocin (STZ; 40 mg/kg) was injected intraperitoneally to build an animal model of diabetic SD rats. The results showed that myocardial collagen fibers were significantly deposited, myocardial tissue senescent cells were significantly increased and the expression of CSE protein was down-regulated, while SIRT6/AMPK signaling pathway and cell autophagy were significantly inhibited. H₂S-treated (NaHS; 56 μmol/kg) could significantly reverse the above phenomenon. In conclusion, these findings suggest that exogenous H₂S can inhibit myocardial cell senescence and improve diabetic myocardial fibrosis by activating CSE and autophagy through SIRT6/AMPK signaling pathway.