ABSTRACT
Per- and polyfluoroalkyl substances (PFASs) are a new type of persistent organic pollutants with global attention. They have shown multiple toxic effects due to their persistent accumulation in human body through exposure to environmental media such as drinking water, food, atmosphere, and soil. However, the bone toxicity of PFASs has not attracted enough attention. It is believed that the exposure and accumulation of PFASs in human have a significant impact on the bone health, especially hindering the healthy bone development in infants and adolescents, and aggravating the occurrence of bone loss and fracture in the elder populations. This paper will review the research progress of the effects of PFASs exposure on bone health indicators such as bone mineral density, and discuss the mechanisms of PFAS in bone toxicity. This review will provide references for revealing the effects of PFASs exposure on bone health and their toxic mechanisms.
ABSTRACT
Objective To investigate the active ingredients and components that inhibiting cathepsin K activity in Erzhi Wan, a classic kidney-tonifying formula. Methods Then-butanol, dichloromethane, ethyl acetate and petroleum ether parts and 30 active components in Erzhi Wan were screened by established high throughput fluorescence methods of inhibit the binding activity of CTSK with Z-FR-MCA substrate, the formation of CTSK and chondroitin sulfate A (CSA) complex activity, and the activity of substrate type I collagen degradation by CTSK. Molecular docking and insoluble collagen substrate binding assays were applied to verify the potential CTSK inhibitors. Results The n-butanol and petroleum ether parts of Erzhi Wan inhibited the formation of CTSK and CSA* complex by more than 90%, the petroleum ether part inhibited the binding of CTSK to substrate Z-FR-MCA by more than 90%, the collagen degradation inhibition rate of CTSK in n-butanol part was more than 95% and that in petroleum ether part was 58.6%. Among the 30 active components, 11 showed that the inhibition rate of CTSK and CSA* complex formation was more than 50%, and 5 components with the inhibition rate of Z-FR-MCA binding activity more than 50%. Finally, there were four components including eclalbasaponin Ⅸ, (-)-epicatechin gallate, nuezhenoside and wedelolactone. The inhibition rate of collagen degradation was more than 50%. Eclipta saponin IX inhibited the binding rate between collagen fibers and CTSK, up to 60%, but all of them failed to dock with CTSK active site. Conclusion There are active components that inhibiting cathepsin K in Erzhi Wan, which mainly exists in the n-butanol ingredients, but the active components is not an active-site inhibitor. It might inhibit the binding of CTSK with oligosaccharides by binding to other sites of CTSK, and then reduce the collagen degradation activity of CTSK.
ABSTRACT
Bromodomain containing protein 4 (BRD4), as an epigenetic reader, can specifically bind to the acetyl lysine residues of histones and has emerged as an attractive therapeutic target for various diseases, including cancer, cardiac remodeling and heart failure. Herein, we described the discovery of hit 5 bearing 4-phenylquinazoline skeleton through a high-throughput virtual screen using 2,003,400 compound library (enamine). Then, structure-activity relationship (SAR) study was performed and 47 new 4-phenylquinazoline derivatives toward BRD4 were further designed, synthesized and evaluated, using HTRF assay set up in our lab. Eventually, we identified compound C-34, which possessed better pharmacokinetic and physicochemical properties as well as lower cytotoxicity against NRCF and NRCM cells, compared to the positive control JQ1. Using computer-based molecular docking and cellular thermal shift assay, we further verified that C-34 could target BRD4 at molecular and cellular levels. Furthermore, treatment with C-34 effectively alleviated fibroblast activation in vitro and cardiac fibrosis in vivo, which was correlated with the decreased expression of BRD4 downstream target c-MYC as well as the depressed TGF-β1/Smad2/3 signaling pathway. Taken together, our findings indicate that novel BRD4 inhibitor C-34 tethering a 4-phenylquinazoline scaffold can serve as a lead compound for further development to treat fibrotic cardiovascular disease.