Project description:The mechanisms of hepatic stellate cell (HSC) activation and the development of liver fibrosis remains largely unknow. Here, we revealed a fibrosis related mechanism of hepatocytes-HSCs crosstalk regulated by hepatocyte LONP1. We demonstrate that hepatocyte LONP1 expression is decreased in HFD-fed mice and MASH patients. Liver-specific LONP1 deficiency increases orotic acid level and aggravates MASH-induced liver fibrosis in mice. We have identified DHODH as a substrate that is selectively degraded by LONP1 in an ATP-dependent manner. Moreover, activation of LONP1 reduces orotic acid levels and alleviates MASH-induced fibrosis in mice. Mechanistically, LONP1 mediates DHODH turnover, maintaining lower orotic acid levels to inhibit ATF3-mediated HSC proliferation and activation, thereby preventing liver fibrosis. Furthermore, plasma orotic acid levels are negatively correlated with liver LONP1 levels in humans. Therefore, targeting LONP1-mediated hepatocyte-HSC communication may represent a promising therapeutic strategy for MASH-induced liver fibrosis.

Project description:The lack of an appropriate preclinical model of metabolic dysfunction-associated steatotic liver disease (MASLD) that recapitulates the whole disease spectrum impedes exploration of disease pathophysiology and the development of effective treatment strategies. Considering the fact that MASLD patients accompanying type 2 diabetes mellitus (T2DM) have high risk of developing metabolic dysfunction-associated steatohepatitis (MASH), advanced fibrosis, and HCC, we treated low-dose streptozotocin (STZ; 40 mg/kg) for 5 consecutive days and subsequently fed a high-fat diet (HFD) to male C57BL/6J mice at 7 weeks of age (STZ+HFD). STZ+HFD mice gradually developed fatty liver, MASH, hepatic fibrosis, and hepatocellular carcinoma (HCC) in the context of metabolic dysfunction. In particular, from 20 weeks of age, MASH was evident, and from 32 weeks of age, advanced fibrosis was developed. At 38 weeks, a proportion of STZ+HFD mice developed HCC, which was subsequently observed in all mice up to 68 weeks of age. Furthermore, the hepatic transcriptomic features of STZ+HFD mice closely reflected those of obese patients with T2DM, MASH and MASLD-related HCC. Notably, dietary changes and tirzepatide administration alleviated MASH, hepatic fibrosis, and hepatic tumorigenesis in STZ+HFD mice. In conclusion, a murine model recapitulating the main histopathologic, transcriptomic, and metabolic alterations observed in MASLD patients with metabolic dysfunction was successfully established.

Project description:We applied RNA sequencing (RNA-seq) to study the gene expression profile in the liver of mice fed the CDAA-HFD for 3 weeks (n=9), 6 weeks (n=10), 12 weeks (n=8) and 20 weeks (n=8) and lean chow controls (n=8). At all timepoints, CDAA-HFD mice displayed a widespread increase in the expression of MASH candidate genes related to inflammation, hepatocellular injury and ECM organization as compared to chow-fed controls. Gene expression was further studied in response to chow reversal (n=9), semaglutide (n=9) and lanifibranor (n=10) as compared to Vehicle (n=10). Chow reversal and lanifibranor, induced wide-spread transcriptional changes in MASH candidate genes while semaglutide showed only discrete effects on candidate genes.

Project description:Background and Aims: Germline mutations in CIDEB, a lipid droplet (LD)-associated protein, confer protection against various liver diseases in humans. Whether liver-specific inhibition of CIDEB will bring clinical benefits remains to be determined. We aim to establish preclinical proof of concept by testing GalNac-conjugated Cideb siRNAs in animal models for obesity and MASH and to develop siRNA drug candidates for clinical investigations. Method: Surrogate siRNAs targeting mouse Cideb were designed and evaluated via a panel of assays. In vivo administration of the surrogate siRNAs was conducted in diet-induced obesity model and CDAA-HFD model for MASH. Plasma and liver lipid levels were measured, and liver histopathological features were analyzed. RNA-Seq analysis of liver tissues was performed to gain a comprehensive mechanistic understanding of Cideb target biology. Concurrently, humanized CIDEB knock-in mice were generated as a research tool to aid human therapeutic siRNAs discovery and development. Results: Single administration of a potent surrogate siRNA resulted in more than 80% target knockdown up to two weeks. In the DIO model, Cideb knockdown led to significant reductions of plasma total cholesterol (TC) and triglyceride (TG) levels, a significant decrease in hepatic macro-steatosis and notable body weight loss. In the CDAA-HFD model, Cideb siRNA treatment significantly reduced liver weight as well as liver TC and TG levels. Furthermore, remarkable reductions of hepatic steatosis and total NAS score were observed with a concomitant amelioration of liver fibrosis. Transcriptome analyses revealed key mechanisms upon Cideb inactivation beyond lipid metabolism. Conclusion: CIDEB exhibits significant potential as a therapeutic target for the treatment of MASH. Liver-targeting siRNA candidates are being developed to test the therapeutic hypothesis in humans.

Project description:Background and Aims: Metabolic dysfunction–associated steatotic liver disease (MASLD) affects a heterogeneous group of patients. Among them, those with a cholestatic profile show worse outcomes. Here, we investigated whether E2F2 is involved in MASLD-associated cholestasis and, if so, the role of miRNAs. Methods: E2f2-knockout (E2f2 AQ5 −/−) and wild-type (WT) mice were fed a cholinedeficient high-fat diet (ChD-HFD) or an HFD after injection of diethylnitrosamine (DEN-HFD) to induce metabolic dysfunction–associated steatohepatitis (MASH). E2F2 was overexpressed in the liver by AAV8. Cholestasis was induced by bile duct ligation or by a 3,5-diethoxycarbonyl-1,4-dihydrocollidine-enriched diet. MicroRNA sequencing was performed. Two biopsy-proven MASLD patient cohorts were used. Results: E2F2 deficiency resulted in increased synthesis and excretion of cholesterol, phosphatidylcholine, and bile acids, reducing their storage in the liver while increasing their presence in feces. This was consistent with increased expression of genes involved in biliary lipid metabolism, reduced inflammation and fibrosis, and the generation of a distinct miRNA profile, thereby preventing MASH. Liver-specific induction of E2F2 in vivo hampered the transcriptional program involved in biliary lipid metabolism and upregulated miR-34a-5p, which was downregulated in E2f2−/− mice. The protective effects observed in E2f2−/− mice were lost when a miR-34a-5p mimic was used. Hepatic miR-34a-5p levels were elevated in patients with advanced fibrosis, inflammation, steatosis score, cholelithiasis, and increased serum bile acids and biliary lipids. E2f2 deficiency conferred protection against cholestatic liver injury. Conclusions: E2F2 deficiency protects against MASH and cholestasis, preventing cholesterol accumulation, fibrosis, and inflammation through modulation ofmiR- 34a-5p. This could provide therapeutic benefits for patients with cholestatic MASH.

Project description:Background & Aims: Fibrosis drives liver-related mortality in metabolic dysfunction-associated steatohepatitis (MASH), yet we have limited medical therapies to target MASH-fibrosis progression. Here we report that mannose, a simple sugar, attenuates MASH steatosis and fibrosis in two robust murine models and human liver slices. Methods: The well-validated FAT-MASH murine model for liver steatosis and fibrosis was employed. Mannose was supplied in the drinking water at the start (“Prevention” group) or at week 6 of the 12-week MASH regimen (“Therapy” group). The in vivo anti-fibrotic effects of mannose supplementation were tested in a second model of carbon tetrachloride (CCl4)-induced liver fibrosis. A quantitative and automated digital pathology approach was used to comprehensively assess steatosis and fibrosis phenotypes. Mannose was also tested in vitro in human and primary mouse hepatocytes conditioned with free fatty acids alone or with fructose, and Human Precision Cut Liver Slices (hPCLS) from patients with end-stage MASH cirrhosis. Results: Oral mannose supplementation improved liver fibrosis in vivo in both FAT-MASH and CCl4 mouse models, as well as in hPCLS MASH samples. Mannose also reduced liver steatosis in FAT-MASH mice, and in human and mouse hepatocytes in vitro. Ketohexokinase (KHK), the main enzyme in fructolysis, was decreased with mannose in whole mouse liver, cultured hepatocytes, and hPCLS. Removal of fructose or overexpression of KHK each abrogated the anti-steatotic effects of mannose. Conclusions: This study identifies mannose as a novel therapeutic candidate for MASH that mitigates steatosis by dampening hepatocyte KHK expression and exerts independent anti-fibrotic effects in two mouse models and human liver tissue slices.

Project description:Background and aims: The incidence of metabolic dysfunction-associated steatohepatitis (MASH) and associated liver fibrosis is rapidly increasing, while pharmacological treatment options remain limited. Despite great efforts in developing novel MASH therapeutics, many investigative therapeutics that reduced fibrosis in preclinical models ultimately lacked efficacy in clinical trials. Therefore, we explored the possibility to predict the efficacy of investigative therapeutics on fibrogenic drive in the early stages of disease development and before effects on pathology become evident. Methods: Ldlr-/-.Leiden mice were fed a high-fat diet (HFD) to induce obesity and MASH. Mice were subsequently treated for four weeks with various therapeutics with established efficacy (obeticholic acid) or lack of efficacy (cenicriviroc, pioglitazone) to study their anti-fibrotic potential. Next, expression of a fibrogenic gene signature was evaluated, which predicts profibrotic processes preceding histopathologic fibrosis. The predictions were validated in parallel with a long-term experiment reaching histological fibrosis endpoints. Results: Cenicriviroc and pioglitazone did not affect HFD-induced fibrosis signature, indicative of no effect of these treatments on active fibrosis processes. Consistently, in the long-term treatment study, both cenicriviroc and pioglitazone did not affect HFD-induced histologically measured fibrosis. In contrast, obeticholic acid improved the early fibrogenic gene signature indicating a less fibrotic state compared with untreated HFD controls. These early gene expression changes aligned with long-term histological fibrosis endpoints and clinical data on these investigative therapeutics. Conclusions: This study highlights the potential of using short-term studies and applying a fibrogenic gene signature as an early screening tool to investigate the efficacy of investigative drugs on MASH-associated fibrosis. This signature, which is based on the active fibrosis processes in humans, may allow rapid screening of therapeutics and their combinations in translational mouse models to save time and resources.

Project description:Background and aims: The incidence of metabolic dysfunction-associated steatohepatitis (MASH) and associated liver fibrosis is rapidly increasing, while pharmacological treatment options remain limited. Despite great efforts in developing novel MASH therapeutics, many investigative therapeutics that reduced fibrosis in preclinical models ultimately lacked efficacy in clinical trials. Therefore, we explored the possibility to predict the efficacy of investigative therapeutics on fibrogenic drive in the early stages of disease development and before effects on pathology become evident. Methods: Ldlr-/-.Leiden mice were fed a high-fat diet (HFD) to induce obesity and MASH. Mice were subsequently treated for four weeks with various therapeutics with established efficacy (obeticholic acid) or lack of efficacy (cenicriviroc, pioglitazone) to study their anti-fibrotic potential. Next, expression of a fibrogenic gene signature was evaluated, which predicts profibrotic processes preceding histopathologic fibrosis. The predictions were validated in parallel with a long-term experiment reaching histological fibrosis endpoints. Results: Cenicriviroc and pioglitazone did not affect HFD-induced fibrosis signature, indicative of no effect of these treatments on active fibrosis processes. Consistently, in the long-term treatment study, both cenicriviroc and pioglitazone did not affect HFD-induced histologically measured fibrosis. In contrast, obeticholic acid improved the early fibrogenic gene signature indicating a less fibrotic state compared with untreated HFD controls. These early gene expression changes aligned with long-term histological fibrosis endpoints and clinical data on these investigative therapeutics. Conclusions: This study highlights the potential of using short-term studies and applying a fibrogenic gene signature as an early screening tool to investigate the efficacy of investigative drugs on MASH-associated fibrosis. This signature, which is based on the active fibrosis processes in humans, may allow rapid screening of therapeutics and their combinations in translational mouse models to save time and resources.

Project description:Obesity and fatty liver diseases-metabolic dysfunction-associated steatotic liver disease (MASLD and MASH) affect over a third of the global population and are exacerbated in individuals with reduced functional aldehyde dehydrogenase 2 (ALDH2), observed in approximately 560 million people. Current treatment to prevent disease progression to cancer remains inadequate, requiring innovative approaches. We observe that Aldh2-/- and Aldh2-/-Sptbn1+/- (ASKO) mice develop phenotypes of human Metabolic Syndrome (MetS) and MASH with altered lipid metabolism and TGF-β signaling, leading to pro-fibrotic and pro-oncogenic phenotypes, which is restored to normal with siRNA to SPTBN1. Significantly, therapeutic inhibition of SPTBN1 blocks MASH and fibrosis in a human 3D MASH model. This study identifies SPTBN1 as a critical regulator of the functional phenotype of toxic aldehyde-induced MASH and a potential therapeutic target.

Project description:Obesity and fatty liver diseases—metabolic dysfunction-associated steatotic liver disease (MASLD) and metabolic dysfunction-associated steatohepatitis (MASH)—affect over one-third of the global population and are exacerbated in individuals with reduced functional aldehyde dehydrogenase 2 (ALDH2), observed in approximately 560 million people. Current treatment to prevent disease progression to cancer remains inadequate, requiring innovative approaches. We observe that Aldh2KO and Aldh2KO/Sptbn1 KO/WT mice develop phenotypes of human metabolic syndrome (MetS) and MASH with accumulation of endogenous aldehydes such as 4-hydroxynonenal (4-HNE). Mechanistic studies demonstrate aberrant transforming growth factor b (TGF-b) signaling through 4-HNE modification of the SMAD3 adaptor SPTBN1 (b2-spectrin) to proQ8 fibrotic and pro-oncogenic phenotypes, which is restored to normal with small interfering RNA (siRNA) to SPTBN1. Significantly, therapeutic inhibition of SPTBN1 blocks MASH and fibrosis in a human model. This study identifies SPTBN1 as a critical regulator of the functional phenotype of toxic aldehyde-induced MASH and a potential therapeutic Q2 target.