Realgar­induced KRAS mutation lung cancer cell death via KRAS/Raf/MAPK mediates ferroptosis.

KRAS is a biomarker for non­small cell lung cancer­targeted therapy, but there is currently no effective KRAS­targeting medication. Realgar is an impelling anticancer drug, however its significance in KRAS mutant lung cancer is uncertain. According to our findings, the IC50 of H23 (KRAS mutant) cells is 2.99 times lower than that of H1650 (non­KRAS mutant) cells. Flow cytometry and the Hoechst 33258 staining assay revealed that H1650 cells treated with 4 µg/ml realgar had an apoptotic rate of 8.2%, while H23 cells had a rate of 21.46%. Accordingly, realgar was more sensitive to KRAS mutant cells. Transcriptome sequencing test indicated that there were 481 different expression genes in H23 cells treated with realgar. In H23 cells treated with realgar, mitochondria shrank, inner membrane folding was disturbed, and mitochondrial membrane potential crushed. Realgar boosted intracellular Fe2+, reactive oxygen species, malondialdehyde and glutathione levels, which were all reversed by ferroptosis inhibitor Fer­1. Realgar decreased phosphorylated p­Raf, p­ERK1/2 and increased p­p38 and p­JNK, whereas only p­Raf was abolished by Fer­1. Raf inhibitor Sorafenib accelerated the realgar­induced ferroptosis. On H23 cells treated with realgar, the expression of GPX4, SCL7A11 decreased while ACSL4 expression increased; this effect could also be amplified by Sorafenib. In conclusion, the present study indicated that realgar may induce ferroptosis by regulating the Raf, and hence plays a role in anti­KRAS mutant lung cancer.

A Review of the Pharmacological Action of Astragalus Polysaccharide.

Astragalus membranaceus (A. membranaceus) is a type of traditional Chinese medicine with a long history of clinical application. It is used in the improvement and treatment of various diseases as medicine and food to invigorate the spleen and replenish qi. The main components of A. membranaceus are Astragalus polysaccharide (APS), flavonoids compounds, saponins compounds, alkaloids, etc. APS is the most important natural active component in A. membranaceus, and possesses multiple pharmacological properties. At present, APS possess the huge potential to develop a drug improving or treating different diseases. In this review, we reveal the potential approaches of pre-treating and preparation on APS as much as possible and the study on content of APS and its chemical composition including different monosaccharides. More importantly, this paper summarize pharmacological actions on immune regulation, such as enhancing the immune organ index, promoting the proliferation of immune cells, stimulating the release of cytokines, and affecting the secretion of immunoglobulin and conduction of immune signals; anti-aging; anti-tumor by enhancing immunity, inducing apoptosis of tumor cells and inhibiting the proliferation and transfer of tumor cells; antiviral effects; regulation of blood glucose such as type I diabetes mellitus, type II diabetes mellitus and diabetic complications; lipid-lowering; anti-fibrosis; antimicrobial activities and anti-radiation. It provided theoretical basis for the further research such as its structure and mechanism of action, and clinical application of APS.