Ligand-Tethered Extracellular Vesicles Mediated RNA Therapy for Liver Fibrosis.

Liver fibrosis poses a significant global health burden, in which hepatic stellate cells (HSCs) play a crucial role. Targeted nanomedicine delivery systems directed at HSCs have shown immense potential in the treatment of liver fibrosis. Herein, a bioinspired material, engineered therapeutic miR-181a-5p (a miRNA known to inhibit fibrotic signaling pathways) and targeted moiety hyaluronic acid (HA) co-functionalized extracellular vesicles (EVs) are developed. HA is incorporated onto the surface of EVs using DSPE-PEG as a linker, allowing preferential binding to CD44 receptors, which are overexpressed on activated HSCs. Our results confirmed enhanced cellular uptake and improved payload delivery, as evidenced by the increased intracellular abundance of miR-181a-5p in activated HSCs and fibrotic livers. HA-equipped EVs loaded with miR-181a-5p (DPH-EVs@miR) significantly reduce HSC activation and extracellular matrix (ECM) deposition by inhibiting the TGF-β/Smad signaling pathway, thus alleviating the progression of liver fibrosis. Additionally, DPH-EVs@miR improves liver function, ameliorates inflammatory infiltration, and mitigates hepatocyte apoptosis, demonstrating superior hepatic protective effects. Collectively, this study reports a prospective nanovesicle therapeutic platform loaded with therapeutic miRNA and targeting motifs for liver fibrosis. The biomarker-guided EV-engineering technology utilized in this study provides a promising tool for nanomedicine and precision medicine.

Liu Y ，Chen S ，Huang H ，Midgley AC ，Han Z ，Han ZC ，Li Q ，Li Z ... -  《-》

Catalpol ameliorates liver fibrosis via inhibiting aerobic glycolysis by EphA2/FAK/Src signaling pathway.

Hepatic fibrosis is a pathological process in a variety of acute or chronic liver injuries. Catalpol (CAT), an iridoid glycoside found in Rehmannia glutinosa, has several pharmacological properties, including anti-inflammatory, antidiabetic and anti-fibrotic effects. Nevertheless, there is currently no report on whether CAT regulates the aerobic glycolysis of hepatic stellate cells (HSCs) to inhibit liver fibrosis. This study aimed to investigate the protective effects of CAT on hepatic fibrosis and elucidate its underlying mechanisms. To explore whether CAT improved liver fibrosis in vivo and in vitro, hepatic fibrosis was induced to mice by intraperitoneally injecting carbon tetrachloride (CCl4). Additionally, LX-2 cells were stimulated with transforming growth factor-β (TGF-β) to simulate fibrosis in vitro. Serum markers of liver injury were examined by using an automatic biochemical analyzer. Histopathological staining, Immunofluorescence (IF) staining, Western blot (WB) analysis, co-immunoprecipitation (Co-IP), drug affinity responsive target stability (DARTS), cellular thermal shift assay (CETSA), etc. were employed to identify the targeting between CAT and EphA2 and detect the expression of aerobic glycolysis related proteins, fiber markers and signaling pathways that are responsible for CAT's anti-fibrotic effects of CAT. Results showed that CAT significantly inhibited hepatic injury, fibrogenesis and inflammation in mice treated with CCl4. This was demonstrated by the enhancement of fibrosis markers, liver function indices, and histopathology. In addition, CAT significantly inhibited the activation of HSCs in TGF-β-induced LX-2 cells, as indicated by decreased proliferation, migration, and expression of collagen I and a-SMA. The study results also suggested that CAT may exert anti-fibrotic effects by inhibiting glycolysis in activated HSCs and in CCl4-treated mice. Mechanistically, CAT directly targets Ephrin type-A receptor 2 (EphA2) to reduce binding with focal adhesion kinases (FAK) and significantly inhibits the FAK/Src pathway. In addition, the pharmacological inhibition of EphA2 cannot further increase the therapeutic effects of CAT on liver fibrosis in vivo and in vitro. The study findings generally demonstrated that CAT presented a novel therapeutic method to treat hepatic fibrosis; this method which inhibits the aerobic glycolysis of activated HSCs through the EphA2/FAK/Src signaling pathway.

Zhang Q ，Ran T ，Li S ，Han L ，Chen S ，Lin G ，Wu H ，Wu H ，Feng S ，Chen J ，Zhang Q ，Zhao X ... -  《-》

Targeting the liver clock improves fibrosis by restoring TGF-β signaling.

Liver fibrosis is the major driver of hepatocellular carcinoma and liver disease-related death. Approved antifibrotic therapies are absent and compounds in development have limited efficacy. Increased TGF-β signaling drives collagen deposition by hepatic stellate cells (HSCs)/myofibroblasts. Here, we aimed to dissect the role of the circadian clock (CC) in controlling TGF-β signaling and liver fibrosis. Using CC-mutant mice, enriched HSCs and myofibroblasts obtained from healthy and fibrotic mice in different CC phases and loss-of-function studies in human hepatocytes and myofibroblasts, we investigated the relationship between CC and TGF-β signaling. We explored hepatocyte-myofibroblast communication through bioinformatic analyses of single-nuclei transcriptomes and performed validation in cell-based models. Using mouse models for MASH (metabolic dysfunction-associated steatohepatitis)-related fibrosis and spheroids from patients with liver disease, we performed proof-of-concept studies to validate pharmacological targetability and clinical translatability. We discovered that the CC oscillator temporally gates TGF-β signaling and this regulation is broken in fibrosis. We demonstrate that HSCs and myofibroblasts contain a functional CC with rhythmic expression of numerous genes, including fibrogenic genes. Perturbation studies in hepatocytes and myofibroblasts revealed a reciprocal relationship between TGF-β activation and CC perturbation, which was confirmed in patient-derived ex vivo and in vivo models. Pharmacological modulation of CC-TGF-β signaling inhibited fibrosis in mouse models in vivo as well as in patient-derived liver spheroids. The CC regulates TGF-β signaling, and the breakdown of this control is associated with liver fibrosis in patients. Pharmacological proof-of-concept studies across different models have uncovered the CC as a novel therapeutic target for liver fibrosis - a growing unmet medical need. Liver fibrosis due to metabolic diseases is a global health challenge. Many liver functions are rhythmic throughout the day, being controlled by the circadian clock (CC). Here we demonstrate that regulation of the CC is perturbed upon chronic liver injury and this perturbation contributes to fibrotic disease. By showing that a compound targeting the CC improves liver fibrosis in patient-derived models, this study provides a novel therapeutic candidate strategy to treat fibrosis in patients. Additional studies will be needed for clinical translation. Since the findings uncover a previously undiscovered profibrotic mechanism and therapeutic target, the study is of interest for scientists investigating liver disease, clinical hepatologists and drug developers.

Crouchet E ，Dachraoui M ，Jühling F ，Roehlen N ，Oudot MA ，Durand SC ，Ponsolles C ，Gadenne C ，Meiss-Heydmann L ，Moehlin J ，Martin R ，Brignon N ，Del Zompo F ，Teraoka Y ，Aikata H ，Abe-Chayama H ，Chayama K ，Saviano A ，Heide D ，Onea M ，Geyer L ，Wolf T ，Felli E ，Pessaux P ，Heikenwälder M ，Chambon P ，Schuster C ，Lupberger J ，Mukherji A ，Baumert TF ... -  《-》

Hyaluronic acid-modified extracellular vesicles for targeted doxorubicin delivery in hepatocellular carcinoma.

Hepatocellular carcinoma (HCC), a prevalent and deadly cancer, poses a significant challenge with current treatments due to limitations such as poor stability, off-target effects, and severe side effects. Extracellular vesicles (EVs), derived from tumor cells, have the remarkable ability to home back to their cells of origin and can serve as Trojan horses for drug delivery. CD44, a cell surface glycoprotein, promotes cancer stem cell-like properties and is linked to poor prognosis and resistance to chemotherapy in HCC. Therefore, targeting CD44-expressing HCC cells is of interest in the development of novel therapeutic strategies for the treatment of HCC. In this study, we developed tumor cell-derived EVs (TEVs) functionalized with hyaluronic acid (HA) to serve as natural carriers for the precise delivery of doxorubicin (Dox), which specifically targets HCC cells expressing CD44. Our results demonstrated that HA-engineered EVs (HA-EVs) significantly enhanced Dox accumulation within HCC cells. In a mouse model, HA-EVs effectively delivered Dox to tumors, suppressing their growth and progression while minimizing systemic toxicity. This study demonstrates the potential of HA-functionalized EVs as a novel and targeted therapeutic platform for HCC, offering a valuable strategy for improving drug delivery and patient outcomes. This study presents a promising strategy to advance targeted chemotherapy for HCC and address the challenges associated with conventional treatments. Engineered HA-functionalized EVs offer a tailored and efficient approach to increase drug delivery precision, underscoring their potential as a novel therapeutic platform in the realm of HCC treatment.

Liu Y ，Hinnant B ，Chen S ，Tao H ，Huang Z ，Qian M ，Zhou M ，Han Z ，Han ZC ，Zhang J ，Li Z ... -  《-》

Targeting CFTR restoring aggrephagy to suppress HSC activation and alleviate liver fibrosis.

Multiple studies have shown that hepatic fibrosis, a progressive condition that represents the endpoint of various chronic liver diseases, is primarily marked by the extensive activation of hepatic stellate cells (HSCs). However, the exact impact of cystic fibrosis transmembrane conductance regulator (CFTR) on HSCs during the development of hepatic fibrosis remains unclear. In our study, we measured CFTR levels in tissue samples and in HSCs activated by TGF-β stimulation. We established mouse models of liver fibrosis using carbon tetrachloride (CCl4) and bile duct ligation (BDL). In vitro, we investigated the specific mechanisms of CFTR action in HSCs by exploring aggrephagy. We employed co-immunoprecipitation (co-IP) experiments to identify potential downstream targets of CFTR. Finally, through rescue experiments, we examined the impact of GTPase-activating protein - binding protein 1 (G3BP1) on CFTR-mediated activation of hepatic stellate cells. In activated HSCs induced by TGF-β, the reduction of CFTR, various liver fibrosis models, and fibrotic tissue samples were identified. In vitro functional experiments confirmed that CFTR promoted the expression of fibrosis-related markers and aggrephagy in HSCs. Mechanistically, we found that CFTR directly interacts with G3BP1, thereby further promoting the TGF-β/Smad2/3 pathway. The inhibition of G3BP1 caused by CFTR knockdown reduced extracellular matrix deposition, contributing to alleviating liver fibrosis. We emphasize that CFTR activates aggrephagy and promotes HSC activation and hepatic fibrosis by targeting G3BP1, participating in the TGF-β/Smad2/3 signaling pathway. Overall, CFTR has been identified as a potential therapeutic target for liver fibrosis.

Zhang L ，Huang W ，Ma T ，Shi X ，Chen J ，Hu YL ，Liu YX ，Liu ZX ，Lu CH ... -  《-》