Genistein stimulates the viability and prevents myofibroblastic transformation in human trabecular meshwork cells stimulated by TGF-β

Mechanistic Insights Into GDFMD-Mediated Inhibition of Liver Fibrosis via miRNA-29b-3p Upregulation in Wilson's Disease

Background: Wilson's disease (WD) is an abnormal copper metabolism disease. GanDouFuMu decoction (GDFMD) is a traditional Chinese medicine, whicn has shown good therapeutic effects in clinical treatment of WD liver fibrosis;but its regulatory mechanism is still unclear. Methods: The serum of WD patients before and after GDFMD treatment were collected, the four items of liver fibrosis were detected by ELISA. The hepatic stellate cell (HSC) activities were assesed via CCK8 assay. The mRNA levels were evaluated by qPCR. The protein levels were checked by western blot. The autophygosomes were observed by transmission electron microscope (TEM). The transdifferentiation ability of HSCs into myofibroblasts was evaluated with anti-α-SMA antibody by immunofluorescence (IF). In copper-laden rats with WD, the autophagy levels, and fibrosis level were observed by IF. Results: The four items of liver fibrosis levels were decreased. GDFMD could increase the HSCs cell activity. GDFMD could increase miRNA-29b-3p levels, which was decreased by TGF-β1. miRNA-29b-3p inhibitors could reversed the suppression response of GDFMD on the the protein expression of ULK1, beclin1, LC3, α-SMA, and Col1. GDFMD blocked the transdifferentiation of HSCs into myofibroblasts, inhibited liver fibrosis. Conclusion: GDFMD blocked the transdifferentiation of HSCs into myofibroblasts by upregulating miRNA-29b-3p, and then inhibited liver fibrosis in WD.

Genistein inhibited endocytosis and fibrogenesis in keloid via CTGF signaling pathways

BACKGROUND

This study aimed to evaluate soy isoflavones' effect and potential use-specifically genistein-in treating human keloid fibroblast cells (KFs) and in a keloid tissue culture model.

METHODS

To investigate the effects of genistein on keloid, a wound-healing assay was performed to detect cell migration. Flow cytometry was used to measure apoptosis. Western blotting and immunofluorescence staining were performed to detect the expression of target proteins. KF tissues were isolated, cultured, and divided into the control, silenced connective tissue growth factor (CTGF) proteins, and shNC (negative control) groups.

RESULTS

Genistein suppressed cell proliferation and migration, triggering the cell cycle at the G2/M phase and increasing the expression of p53 dose-dependent in keloids. Genistein inhibited the expression of COL1A1, FN, and CTGF mRNA and protein. Knockdown CTGF reduced the migrated ability in KFs. Genistein also abated TGF-β1-induced keloid fibrosis through the endocytosis model. Separated and cultured the keloid patient's tissues decreased the cell migration ability by genistein treatment and was time-dose dependent.

CONCLUSIONS

This study indicated that genistein-induced p53 undergoes cell cycle arrest via the CTGF pathway-inhibited keloid cultured cells, and genistein suppressed the primary keloid cell migration, suggesting that our research provides a new strategy for developing drugs for treating keloids.