Markers of Hippo-Pathway Activity in Tumor Forming Liver Lesions

MST1/2 DKO abates salvianolic acid B's therapeutic effect on CCl4-induced liver injury mice

MST1 and MST2 (MST1/2) are core kinases of the Hippo/YAP signaling pathway in mammals and play key roles in various liver diseases. Deep molecular profiling has shown that the Hippo/YAP pathway interacts synergistically with TGF-β1/Smad2 signaling. Salvianolic acid B (SAB) is an ingredient extracted from Salvia miltiorrhiza that can be used to treat liver diseases. Previous studies have confirmed that SAB hold commendable efficacy against liver injury by inhibition of inflammatory response and Smad2C/2L phosphorylation. However, scientific evidence involving how mutations in the Hippo/YAP pathway are related to the hepatoprotective function of SAB in MST1/2 double knockout (MST1/2 DKO) mice remains vague. Nowadays, the MST1-/- MST2fl/fl Alb-Cre mice were generated to establish a CCl4-induced liver injury model to investigate the potential effects of MST1/2 gene knockout on inflammatory reactions and pSmad2C/pSmad2L signal transduction with the intervention of SAB. As it turns out, genotype identification and western blot assays confirmed that we have successfully obtained MST1-/- MST2fl/fl Alb-Cre mice. General observation, HE staining, and biochemical assays promulgated that genetic deletion of MST1/2 could diminish SAB's hepatoprotective effect on liver injury by promoting the phosphorylation of smad2C/2L and boosting the expression of the inflammatory factors IL- 6 and TNF-α. In summary, these results suggest that MST1/2 play a key role in mediating SAB's effects on liver injury.

Emerging treatment modalities for systemic therapy in hepatocellular carcinoma

Hepatocellular carcinoma (HCC) has long been a major global clinical problem as one of the most common malignant tumours with a high rate of recurrence and mortality. Although potentially curative therapies are available for the early and intermediate stages, the treatment of patients with advanced HCC remains to be resolved. Fortunately, the past few years have shown the emergence of successful systemic therapies to treat HCC. At the molecular level, HCC is a heterogeneous disease, and current research on the molecular characteristics of HCC has revealed numerous therapeutic targets. Targeted agents based on signalling molecules have been successfully supported in clinical trials, and molecular targeted therapy has already become a milestone for disease management in patients with HCC. Immunotherapy, a viable approach for the treatment of HCC, recognizes the antigens expressed by the tumour and treats the tumour using the immune system of the host, making it both selective and specific. In addition, the pipeline for HCC is evolving towards combination therapies with promising clinical outcomes. More drugs designed to focus on specific pathways and immune checkpoints are being developed in the clinic. It has been demonstrated that some drugs can improve the prognosis of patients with HCC in first- or second-line settings, and these drugs have been approved by the Food and Drug Administration or are nearing approval. This review describes targeting pathways and systemic treatment strategies in HCC and summarizes effective targeted and immune-based drugs for patients with HCC and the problems encountered.

Immunotherapeutic Targeting of GPC3 in Pediatric Solid Embryonal Tumors

Glypican 3 (GPC3) is a heparan sulfate proteoglycan and cell surface oncofetal protein which is highly expressed on a variety of pediatric solid embryonal tumors including the majority of hepatoblastomas, Wilms tumors, rhabdoid tumors, certain germ cell tumor subtypes, and a minority of rhabdomyosarcomas. Via both its core protein and heparan sulfate side chains, GPC3 activates the canonical Wnt/β-catenin pathway, which is frequently overexpressed in these malignancies. Loss of function mutations in GPC3 lead to Simpson-Golabi-Behmel Syndrome, an X-linked overgrowth condition with a predisposition to GPC3-expressing cancers including hepatoblastoma and Wilms tumor. There are several immunotherapeutic approaches to targeting GPC3, including vaccines, monoclonal antibodies, antibody-drug conjugates, bispecific antibodies, cytolytic T lymphocytes, and CAR T cells. These therapies offer a potentially novel means to target these pediatric solid embryonal tumors. A key pediatric-specific consideration of GPC3-targeted immunotherapeutics is that GPC3 can be physiologically expressed in normal tissues during the first year of life, particularly in the liver and kidney. In summary, this article reviews the current evidence for targeting childhood cancers with GPC3-directed immunotherapies.

Tankyrase inhibitors suppress hepatocellular carcinoma cell growth via modulating the Hippo cascade

Previous data indicate that Tankyrase inhibitors exert anti-growth functions in many cancer cell lines due to their ability to inactivate the YAP protooncogene. In the present manuscript, we investigated the effect of Tankyrase inhibitors on the growth of hepatocellular carcinoma (HCC) cell lines and the molecular mechanisms involved. For this purpose, we performed cell proliferation assay by colony-forming ability in seven human HCC cells subjected to XAV-939 and G007-LK Tankyrase inhibitors. Noticeably, the two Tankyrase inhibitors suppressed the HCC cell growth in a dose-dependent manner. Furthermore, we found that Tankyrase inhibitors synergized with MEK and AKT inhibitors to suppress HCC cell proliferation. At the molecular level, Tankyrase inhibitors significantly decreased YAP protein levels, reduced the expression of YAP target genes, and inhibited YAP/TEAD luciferase reporter activity. In addition, Tankyrase inhibitors administration was accompanied by upregulation of Angiomotin-like 1 (AMOTL1) and Angiomotin-like 2 (AMOTL2) proteins, two major negative regulators of YAP. Altogether, the present data indicate that XAV-939 and G007-LK Tankyrase inhibitors could suppress proliferation of hepatocellular carcinoma cells and downregulate YAP/TAZ by stabilizing AMOTL1 and AMOTL2 proteins, thus representing new potential anticancer drugs against hepatocellular carcinoma.