Anti-diabetic drug canagliflozin hinders skeletal muscle regeneration in mice.

Canagliflozin is an antidiabetic medicine that inhibits sodium-glucose cotransporter 2 (SGLT2) in proximal tubules. Recently, it was reported to have several noncanonical effects other than SGLT2 inhibiting. However, the effects of canagliflozin on skeletal muscle regeneration remain largely unexplored. Thus, in vivo muscle contractile properties recovery in mice ischemic lower limbs following gliflozins treatment was evaluated. The C2C12 myoblast differentiation after gliflozins treatment was also assessed in vitro. As a result, both in vivo and in vitro data indicate that canagliflozin impairs intrinsic myogenic regeneration, thus hindering ischemic limb muscle contractile properties, fatigue resistance recovery, and tissue regeneration. Mitochondrial structure and activity are both disrupted by canagliflozin in myoblasts. Single-cell RNA sequencing of ischemic tibialis anterior reveals a decrease in leucyl-tRNA synthetase 2 (LARS2) in muscle stem cells attributable to canagliflozin. Further investigation explicates the noncanonical function of LARS2, which plays pivotal roles in regulating myoblast differentiation and muscle regeneration by affecting mitochondrial structure and activity. Enhanced expression of LARS2 restores the differentiation of canagliflozin-treated myoblasts, and accelerates ischemic skeletal muscle regeneration in canagliflozin-treated mice. Our data suggest that canagliflozin directly impairs ischemic skeletal muscle recovery in mice by downregulating LARS2 expression in muscle stem cells, and that LARS2 may be a promising therapeutic target for injured skeletal muscle regeneration.

High molecular weight fibroblast growth factor-2 as a promising prognostic biomarker to predict the occurrence of heart failure in atrial fibrillation patients.

Heart failure (HF) has a significant effect on the prognosis of the patients with atrial fibrillation (AF), and also it is an important risk factor for overall mortality. High molecular weight fibroblast growth factor-2 (Hi-FGF-2) is emerging as a prognostic marker with HF and AF. The aim of this study was to prove that Hi-FGF-2 would predict occurrence of HF in the patients with AF. Subjects diagnosed with paroxysmal AF (Group paAF), persistent AF (Group peAF) and sinus rhythm (Group SR) were enrolled in the study. Serum Hi-FGF-2 concentration was measured by ELISA at baseline. Multivariable logistic models and receiver operating characteristic (ROC) curve analysis were established to predict the prognosis of AF subjects. 260 patients were enrolled in the study: 104 (40.0%) admitted for sinus rhythm (Group SR) and 156 (60.0%) with AF (Group paAF and Group peAF). The Hi-FGF-2 levels were much lower in the Group SR (58.2 ± 27.1 ng/L) than in the Group AF. Furthermore, the Group peAF (84.3 ± 34.1 ng/L) had higher Hi-FGF-2 levels than the Group paAF (72.9 ± 35.8 ng/L). Serum Hi-FGF-2 levels were classified into trisection in the multivariable logistic model (T1 < 57.3 ng/L, 57.3 < T2 < 86.5 ng/L, and T3 > 86.5 ng/L). Hi-FGF-2 showed good predictive ability for new-onset HF in the patients with AF. The occurrence of HF was associated significantly with increased tertile of serum Hi-FGF-2 levels (T2: OR 5.922, 95% CI 1.109-31.626, P = 0.037 and T3: OR 8.262, 95% CI 1.735-39.343, P = 0.008). ROC curve analysis showed that the area under curves for Hi-FGF-2 were 0.720 (P < 0.0001). Hi-FGF-2 has a significant meaning in AF subjects. Further to this, higher circulating Hi-FGF-2 was highly related to persistent AF, and Hi-FGF-2 may be an independent risk factor of occurrence HF in AF subjects.

Possible roles of platelet-derived microparticles in atherosclerosis.

Platelets and platelet-derived microparticles (PMPs) play important roles in cardiovascular diseases, especially atherosclerosis. Continued research has revealed that PMPs have numerous functions in atherosclerosis, not only in thrombosis formation, but also by induction of inflammation. PMPs also induce formation of foam cells. Recent evidence strongly indicates a significant role of PMPs in atherosclerosis. Here, current research on the function of PMPs in atherosclerosis is reviewed.