Ethyl ferulate suppresses post-myocardial infarction myocardial fibrosis by inhibiting transforming growth factor receptor 1.

BACKGROUND: With an increasing number of myocardial infarction (MI) patients, myocardial fibrosis is becoming a widespread health concern. It's becoming more and more urgent to conduct additional research and investigations into efficient treatments. Ethyl ferulate (EF) is a naturally occurring substance with cardioprotective properties. However, the extent of its impact and the underlying mechanism of its treatment for myocardial fibrosis after MI remain unknown. PURPOSE: The goal of this study was to look into how EF affected the signaling of the TGF-receptor 1 (TGFBR1) in myocardial fibrosis after MI. METHODS: Echocardiography, hematoxylin-eosin (HE) and Masson trichrome staining were employed to assess the impact of EF on heart structure and function in MI-affected mice in vivo. Cell proliferation assay (MTS), 5-Ethynyl-2'-deoxyuridine (EdU), and western blot techniques were employed to examine the influence of EF on native cardiac fibroblast (CFs) proliferation and collagen deposition. Molecular simulation and surface plasmon resonance imaging (SPRi) were utilized to explore TGFBR1 and EF interaction. Cardiac-specific Tgfbr1 knockout mice (Tgfbr1ΔMCK) were utilized to testify to the impact of EF. RESULTS: In vivo experiments revealed that EF alleviated myocardial fibrosis, improved cardiac dysfunction after MI and downregulated the TGFBR1 signaling in a dose-dependent manner. Moreover, in vitro experiments revealed that EF significantly inhibited CFs proliferation, collagen deposition and TGFBR1 signaling followed by TGF-ß1 stimulation. More specifically, molecular simulation, molecular dynamics, and SPRi collectively showed that EF directly targeted TGFBR1. Lastly, knocking down of Tgfbr1 partially reversed the inhibitory activity of EF on myocardial fibrosis in MI mice. CONCLUSION: EF attenuated myocardial fibrosis post-MI by directly suppressing TGFBR1 and its downstream signaling pathway.

ADRM1/RPN13 attenuates cartilage extracellular matrix degradation via enhancing UCH37-mediated ALK5 deubiquitination.

Osteoarthritis (OA) is the most common age-related joint disorder with no effective therapy, and its specific pathological mechanism remains to be fully clarified. Adhesion-regulating molecule 1 (ADRM1) has been proven to be involved in OA progression as a favorable gene. However, the exact mechanism of ADRM1 involved in OA were unknown. Here, we showed that the ADRM1 expression decreased in human OA cartilage, destabilization of the medial meniscus (DMM)-induced mouse OA cartilage, and interleukin (IL)-1ß-induced primary mouse articular chondrocytes. Global knockout (KO) ADRM1 in cartilage or ADRM1 inhibitor (RA190) could accelerate the disorders of extracellular matrix (ECM) homeostasis, thereby accelerated DMM-induced cartilage degeneration, whereas overexpression of ADRM1 protected mice from DMM-induced OA development by maintaining the homeostasis of articular cartilage. The molecular mechanism study revealed that ADRM1 could upregulate ubiquitin carboxy-terminal hydrolase 37 (UCH37) expression and bind to UCH37 to activate its deubiquitination activity. Subsequently, increased and activated UCH37 enhanced activin receptor-like kinase 5 (ALK5) deubiquitination to stabilize ALK5 expression, thereby maintaining ECM homeostasis and attenuating cartilage degeneration. These findings indicated that ADRM1 could attenuate cartilage degeneration via enhancing UCH37-mediated ALK5 deubiquitination. Overexpression of ADRM1 in OA cartilage may provide a promising OA therapeutic strategy.

Intermittent dosing of the transforming growth factor beta receptor 1 inhibitor, BMS-986260, mitigates class-based cardiovascular toxicity in dogs but not rats.

Small-molecule inhibitors of transforming growth factor beta receptor 1 (TGFßRI) have a history of significant class-based toxicities (eg, cardiac valvulopathy) in preclinical species that have limited their development as new medicines. Nevertheless, some TGFßRI inhibitors have entered into clinical trials using intermittent-dosing schedules and exposure limits in an attempt to avoid these toxicities. This report describes the toxicity profile of the small-molecule TGFßRI inhibitor, BMS-986260, in rats and dogs. Daily oral dosing for 10 days resulted in valvulopathy and/or aortic pathology at systemic exposures that would have been targeted clinically, preventing further development with this dosing schedule. These toxicities were not observed in either species in 1-month studies using the same doses on an intermittent-dosing schedule of 3 days on and 4 days off (QDx3 once weekly). Subsequently, 3-month studies were conducted (QDx3 once weekly), and while there were no cardiovascular findings in dogs, valvulopathy and mortality occurred early in rats. The only difference compared to the 1-month study was that the rats in the 3-month study were 2 weeks younger at the start of dosing. Therefore, a follow-up 1-month study was conducted to evaluate whether the age of rats influences sensitivity to target-mediated toxicity. Using the same dosing schedule and similar doses as in the 3-month study, there was no difference in the toxicity of BMS-986260 in young (8 weeks) or adult (8 months) rats. In summary, an intermittent-dosing schedule mitigated target-based cardiovascular toxicity in dogs but did not prevent valvulopathy in rats, and thus the development of BMS-986260 was terminated.