Stellate Cells Research Articles

N6-methyladenosine modification of circDcbld2 in Kupffer cells promotes hepatic fibrosis via targeting miR-144-3p/Et-1 axis

Kupffer cells (KCs), as residents and sentinels of the liver, are involved in the formation of hepatic fibrosis (HF). However, the biological functions of circular RNAs (circRNAs) in KCs to HF have not been determined. In this study, the expression levels of circRNAs, microRNAs, and messenger RNAs (mRNAs) in KCs from a mouse model of HF mice were investigated using microarray and circRNA-Seq analyses. circDcbld2 was identified as a candidate circRNA in HF, as evidenced by its up-regulation in KCs. Silver staining and mass spectrometry showed that Wtap and Igf2bp2 bind to cirDcbld2. The suppression of circDcbld2 expression decreased the KC inflammatory response and oxidative stress and inhibited hepatic stellate cell (HSCs) activation, attenuating mouse liver fibrogenesis. Mechanistically, Wtap mediated the N6-methyladenosine (m6A) methylation of circDcbld2, and Igf2bp2 recognized m6A-modified circDcbld2 and increased its stability. circDcbld2 contributes to the occurrence of HF by binding miR-144-3p/Et-1 to regulate the inflammatory response and oxidative stress. These findings indicate that circDcbld2 functions via the m6A/circDcbld2/miR-144-3p/Et-1 axis and may act as a potential biomarker for HF treatment.

Mouse liver blood flow is regulated by hepatic stellate cells in response to the sympathetic neurotransmitter norepinephrine

BackgroundThere is no clear information on the regulation of liver blood flow by the autonomic nervous system. We conducted this study to investigate whether quiescent hepatic stellate cells (qHSCs) regulate liver blood flow in response to the sympathetic neurotransmitter norepinephrine (NE). MethodsqHSCs isolated from mice were cultured in Dulbecco's modified Eagle medium without fetal bovine serum for 1 day on collagen gel. NE-induced qHSC contraction was evaluated using the quantitative single-cell contraction measurement method that we had developed previously. For the measurement of liver perfusion pressure in situ, a buffer solution was perfused from the portal vein in mice. ResultsNE-induced a reversible contraction of qHSCs. This contraction was suppressed by the nonmuscle myosin II inhibitor blebbistatin, the myosin light chain kinase inhibitor ML-9, the Rho kinase inhibitor H-1152, the calmodulin inhibitor W-7, the store-operated calcium channel inhibitor YM-58483, and the IP3 receptor inhibitor xestospongin C. In contrast, the transient receptor potential C channel inhibitor SKF96365 did not affect the NE-induced contraction. ConclusionThese results suggest that qHSCs contract in response to NE. New & noteworthyThe present study provides direct evidence for the first time that norepinephrine (NE) induces a reversible contraction of isolated single quiescent hepatic stellate cells (qHSCs) and further suggests that the NE-mediated qHSC contraction participates in the regulation of liver blood flow in vivo.

Dual-Ligand-Functionalized Nanostructured Lipid Carriers as a novel Dehydrocavidine delivery system for Liver fibrosis Therapy

BackgroundLiver fibrosis is a common stage of various chronic liver diseases, often developing into liver cirrhosis, and even liver cancer. Activated hepatic stellate cells (aHSCs) have been shown to promote the development of liver fibrosis. Therefore, dual-targeted combination therapy for liver may be an effective strategy for the treatment of liver fibrosis. PurposeIn this study, the novel nanostructured lipid carriers (GA&GalNH2-DC-NLCs) were prepared for Dehydrocavidine (DC), glycyrrhetinic acid (GA) and galactose-PEG2000-NH2 (GalNH2) were selected as targeted ligand-modified nanostructured lipid carriers (NLCs), which enables dual-targeting to the liver for the treatment of liver fibrosis. Study designTo study the targeting effect of GA&GalNH2-DC-NLCs on liver and its therapeutic effect on liver fibrosis, we established aHSC-T6 cell model and rat model of liver fibrosis for study. ResultsGA&GalNH2-DC-NLCs promoted drug liver targeting efficiency and apoptosis rate by upregulating the expression of Bax. It showed that compared with no and/or GA-modified NLCs and GalNH2-modified NLCs, GA&GalNH2-DC-NLCs exhibited less extracellular matrix (ECM) deposition, induced apoptosis of aHSCs, and stronger anti-fibrosis effects in vivo. This may be due the fact that GA or GalNH2-modifified NLCs simultaneously block HSCs activation and inhibit the IL-6/STAT3 pathway. ConclusionGA&GalNH2-DC-NLCs is thus a potential strategy for liver fibrosis treatment.

Ginsenoside compound K restrains hepatic fibrotic response by dual-inhibition of GLS1 and LDHA

BackgroundLiver fibrosis is a dynamic process marked by the accumulation of extracellular matrix due to hepatic stellate cells (HSCs) activation. Ginsenoside compound K (CK), a rare derivative of its parent ginsenosides, is known to significantly ameliorate metabolic disorders. PurposeThe aim of this study was to elucidate the protective effects of CK against liver fibrosis with a focus on metabolic regulation. MethodsWe established liver fibrosis models in mice using carbon tetrachloride (CCl4) challenge, bile duct ligation, or a methionine-choline deficient diet, with continuous oral administration of CK at specified doses and intervals. Simultaneously, we examined the impact of CK on metabolic regulation in cultured HSCs and investigated the associated mechanisms. ResultsCK was found to alleviate liver injury and curb fibrotic responses in mouse models, as well as decrease elevated levels of liver enzyme. Metabolomic analysis in vitro highlighted the crucial roles of pyruvate and glutamine metabolism in metabolic remodeling. Immunohistochemical staining indicated significantly elevated expressions of lactate dehydrogenase A (LDHA) (p = 0.014) and glutaminase 1 (GLS1) (p = 0.024) in liver cirrhosis patients. Comparable alterations were noted in the liver of model mice and in cultured HSCs. Molecular docking and bio-layer interferometry demonstrated that CK interacts with and inhibits the activities of LDHA and GLS1. As expected, CK attenuated glycolysis and glutaminolysis, reducing HSC growth dependently on lactate and α-ketoglutarate (α-KG). Upon HSC activation, metabolism is reprogrammed with Myc as a key regulator, transcriptionally controlling LDHA, GLS1, and glutamine transporters SLC1A5 and SLC38A5. CK inhibited Myc induction, integrating glycolysis and glutaminolysis regulation to counteract the fibrotic response. ConclusionCK inhibited LDHA and GLS1 activities, thereby inhibiting hepatic fibrosis. These findings offer new insights into the role of ginsenosides in liver protection, especially regarding metabolic disorders.

Methionine restriction reduced growth performance and exacerbated lipid deposition in hybrid grouper (Epinephelus fuscoguttatus ♀ × E. lanceolatus ♂) under high-lipid diets by suppressing the lipid degradation pathways with the single-cell RNA-seq analysis

The experiment mainly focused on the liver of the hybrid grouper (Epinephelus fuscoguttatus ♀ × E. lanceolatus ♂) with low methionine levels by single-cell RNA-seq under high-lipid diets. Both weight gain rate (WGR) and specific growth rate (SGR) in the MR group were obviously lower than the C group, and the intraperitoneal fat (IPF) in the MR group was obviously enhanced than HL and C groups, which led to more visible growth inhibition and lipid deposition. By using the scRNA-seq analysis, nine cell types were classified as: liver parenchymal cells, erythrocytes, hepatic stellate cells, cholangiocytes, macrophages, T cells, epidermal cells, eosinophil and fibroblasts. Lipid and carbohydrate metabolisms were mainly enriched in liver parenchymal cells. The lipid degradation pathways were obviously inhibited in the MR group, such as cholesterol degradation pathway. The lipid degradation genes were obviously decreased in the MR group. In conclusion, methionine restriction might suppress the lipid degradation pathways in liver parenchymal cells, led to obvious lipid deposition.

Magnoflorine ameliorates hepatic fibrosis and hepatic stellate cell activation by regulating ferroptosis signaling pathway

Magnoflorine ameliorates hepatic fibrosis and hepatic stellate cell activation by regulating ferroptosis signaling pathway

The periaxonal space as a conduit for cerebrospinal fluid flow to peripheral organs

Mechanisms controlling the movement of the cerebrospinal fluid (CSF) toward peripheral nerves are poorly characterized. We found that, in addition to the foramina Magendie and Luschka for CSF flow toward the subarachnoid space and glymphatic system, CSF outflow could also occur along periaxonal spaces (termed "PAS pathway") from the spinal cord to peripheral organs, such as the liver and pancreas. When interrogating the latter route, we found that serotonin, acting through 5-HT2B receptors expressed in ependymocytes that line the central canal, triggered Ca2+ signals to induce polymerization of F-actin, a cytoskeletal protein, to reduce the volume of ependymal cells. This paralleled an increased rate of PAS-mediated CSF redistribution toward peripheral organs. In the liver, CSF was received by hepatic stellate cells. CSF efflux toward peripheral organs through the PAS pathway represents a mechanism dynamically connecting the nervous system with the periphery. Our findings are compatible with the traditional theory of CSF efflux into the glymphatic system to clear metabolic waste from the cerebral parenchyma. Thus, we extend the knowledge of CSF flow and expand the understanding of connectivity between the CNS and peripheral organs.

Precision-cut liver slices as an ex vivo model to evaluate antifibrotic therapies for liver fibrosis and cirrhosis.

Considering the lack of successful treatment options and poor prognosis for cirrhosis and cirrhosis-induced HCC, new platforms to investigate antifibrotic therapies are urgently needed. Precision-cut liver slice (PCLS) is a powerful ex vivo culture model that can supplement and potentially replace the traditional models. PCLS were prepared from 4 different murine cirrhotic models (choline-deficient, l-amino acid-defined, high-fat diet, thioacetamide, diethylnitrosamine, and carbon tetrachloride) and compared with in vivo murine experiments, in vitro hepatic stellate cells, and human cirrhotic PCLS. PCLS viability in culture was stable for 72 hours. Treatment of erlotinib, an EGF receptor inhibitor, significantly inhibited profibrogenic gene expressions in PCLS from choline-deficient, l-amino acid-defined, high-fat diet or thioacetamide-induced cirrhotic rats. Erlotinib treatment of PCLS from diethylnitrosamine or carbon tetrachloride-induced cirrhotic rats inhibited the expression of profibrogenic genes, which was consistent with the impact of erlotinib on these genes in in vivo diethylnitrosamine or carbon tetrachloride-induced cirrhosis. In addition, in hepatic stellate cells at PCLS from normal mice, erlotinib treatment inhibited TGF-β1-upregulated expression of Acta2. Similar expression results were observed in in vitro hepatic stellate cells. Expression of key regulators of fibrosis progression and regression were also significantly altered. Changes in profibrogenic gene expression under erlotinib treatment were also corroborated with human cirrhotic PCLS. Responses to antifibrotic interventions can be detected and quantified with PCLS at the gene expression level. The antifibrotic effects of erlotinib are consistent between PCLS models of murine cirrhosis and those observed in vivo and in vitro. These results were verified in human cirrhotic PCLS. PCLS is an excellent model for assessing antifibrotic therapies that are aligned with the principles of replacement, reduction, and refinement (3Rs), and it will benefit preclinical and clinical research for human fibrosis and cirrhosis.

Multi-Modal Analysis of human Hepatic Stellate Cells identifies novel therapeutic targets for Metabolic Dysfunction-Associated Steatotic Liver Disease

Background and aimsMetabolic dysfunction-associated steatotic liver disease (MASLD) ranges from Metabolic dysfunction-associated steatotic liver (MASL) to Metabolic dysfunction-associated steatohepatitis (MASH) with fibrosis. Activation of Hepatic Stellate Cells (HSCs) into fibrogenic myofibroblasts plays a critical role in the pathogenesis of MASH liver fibrosis. We compared transcriptome and chromatin accessibility of human HSCs from NORMAL, MASL, and MASH livers at single cell resolution. We aimed to identify genes that are upregulated in activated HSCs and to determine which of these genes are key in the pathogenesis of MASH fibrosis. Methods18 human livers were profiled using single-nucleus (sn)RNA-seq and snATAC-seq. High priority targets were identified, then tested in 2D human HSC cultures, 3D human liver spheroids, and HSC-specific gene knockout mice. ResultsMASH-enriched activated (A) HSC subclusters are the major source of extracellular matrix proteins. We identified a set of concurrently upregulated and more accessible core genes (GAS7, SPON1, SERPINE1, LTBP2, KLF9, EFEMP1) that drive activation of (A) HSC subclusters. Expression of these genes was regulated via crosstalk between lineage-specific (JUNB/AP1), cluster-specific (RUNX1/2) and signal-specific (FOXA1/2) transcription factors. The pathological relevance of the selected targets, such as SERPINE1 (PAI-1), was demonstrated using dsiRNA-based HSC-specific gene knockdown or pharmacological inhibition of PAI-1 in 3D human MASH liver spheroids, and HSC-specific Serpine1 knockout mice. ConclusionThis study identified novel gene targets and regulatory mechanisms underlying activation of MASH fibrogenic HSCs and demonstrated that genetic or pharmacological inhibition of select genes suppressed liver fibrosis. Impact and implicationsHere we present snRNA-seq and snATAC-seq analysis of human HSCs from NORMAL, MASL, and MASH livers. We identified additional subclusters that were not detected by previous studies and characterized the mechanism by which HSCs activate in the MASH livers, including the transcriptional machinery that activates HSCs into myofibroblasts. For the first time, we described the pathogenic role of activated HSC-derived PAI-1 (a product of SERPINE1 gene) in the development of MASH liver fibrosis. Targeting of RUNX1/2-SERPINE1 axis may provide a novel strategy for treatment of liver fibrosis in patients.

PKMζ, a brain-specific PKCζ isoform, is required for glycolysis and myofibroblastic activation of hepatic stellate cells.

TGFβ1 induces plasma membrane (PM) accumulation of glucose transporter 1 (Glut1) required for glycolysis of hepatic stellate cells (HSCs) and HSC activation. This study aimed to understand how Glut1 is anchored/docked onto the PM of HSCs. HSC expression of protein kinase M zeta isoform (PKMζ) was detected by RT-PCR, Western blotting, and immunofluorescence. PKMζ level was manipulated by shRNA or overexpression; HSC activation was assessed by cell expression of activation markers; PM Glut1, glucose uptake, and glycolysis of HSCs were analyzed by biotinylation, 2-NBDG-based assay, and Seahorse Glycolysis Stress Test. Phospho-mutants of vasodilator-stimulated phosphorylated protein (VASP) were created by site-directed mutagenesis. TGFβ transcriptome was obtained by RNA sequencing. Single-cell RNA sequencing datasets and immunofluorescence were leveraged to analyze PKMζ expression in cancer-associated fibroblasts (CAFs) of colorectal liver metastases. Function of HSC PKMζ was determined by tumor/HSC co-implantation study. Primary human and murine HSCs express PKMζ, but not full-length PKCζ. PKMζ knockdown suppresses whereas PKMζ overexpression potentiates PM accumulation of Glut1, glycolysis, and HSC activation induced by TGFβ1. Mechanistically, PKMζ binds to and induces VASP phosphorylation at serines 157 and 239 facilitating anchoring/docking of Glut1 onto the PM of HSCs. PKMζ expression is increased in the CAFs of murine and patient colorectal liver metastases compared to quiescent HSC. Targeting PKMζ suppresses transcriptome, CAF activation of HSCs, and colorectal tumor growth in mice. Since HSCs are also a major contributor of liver fibrosis, our data highlight PKMζ and VASP as targets to inhibit metabolic reprogramming, HSC activation, liver fibrosis, and the pro-metastatic microenvironment of the liver.

Chondromyxoid Fibroma of Phalanges

Chondromyxoid fibroma (CMF) is a rare, benign metaphyseal bone tumour characterised by a combination of chondroid, myxoid, and fibrous elements, which can affect any bone at any age, without a gender predilection. We report the case of CMF in a 47-year-old lady who presented with swelling of the left little finger to a tertiary care hospital at Kolkata, India, in May 2024. Imaging showed presence of a lobulated lesion arising from the middle phalanx of the left little finger, extending to involve the base of the distal phalanx. Fine needle aspiration cytology of the lesion was indicative of a moderately cellular myxoid lesion. Histopathology remains crucial for diagnosis, which revealed a lobulated tumour with zones of spindle to stellate cells, associated with abundant myxoid and chondroid matrix in the intercellular areas. Treatment involves complete local excision with tumor free margins, as recurrence can occur with local curettage.

Stromal Reprogramming Optimizes KRAS-Specific Chemotherapy Inducing Antitumor Immunity in Pancreatic Cancer.

Pancreatic ductal adenocarcinoma (PDAC) is a clinically challenging cancer and is often characterized with rich stroma and mutated KRAS, which determines the tumor microenvironment (TME) and therapy response. Turning immunologically "cold" PDAC into "hot" is an unmet need to improve the therapeutic outcome. Herein, we propose a programmable strategy by sequential delivery of pirfenidone (PFD) and nanoengineered KRAS specific inhibitor (AMG510) and gemcitabine (GEM) liposomes. PFD could achieve precise reduction of the extracellular matrix (ECM) by reprogramming pancreatic stellate cells (PSCs). Subsequently, targeting the KRAS-directed oncogenic signaling pathway effectively inhibited tumor proliferation and migration, which sensitized a chemotherapeutic drug and promoted immunogenic cell death (ICD). In preclinical mouse models of PDAC, PFD mediated stromal modulation enhanced the deep penetration of nanoparticles and improved their subsequent performance in tumor growth inhibition. The molecular mechanisms elucidated that the stroma intervention and KRAS signal pathway regulation reshaped the immunosuppression of PDAC and optimized cytotoxic T-cell-mediated antitumor immunity with sustained antitumor memory. Overall, our study provides a practical strategy with clinical translational promise for immunologically cold tumor PDAC treatment.

Formononetin Induces Ferroptosis in Activated Hepatic Stellate Cells to Attenuate Liver Fibrosis by Targeting NADPH Oxidase 4.

Ferroptosis is a newly discovered type of cell death that exerts a crucial role in hepatic fibrosis. Formononetin (FMN), a natural isoflavone compound mainly isolated from Spatholobus suberectus Dunn, shows multiple biological activities, including antioxidant, anti-inflammatory, and hepatoprotection. This research aims to explore the regulatory mechanism of FMN in liver fibrosis and the relationship between NADPH oxidase 4 (NOX4) and ferroptosis. The effects of FMN on HSC ferroptosis were evaluated in rat model of CCl4-induced hepatic fibrosis. In vitro, N-acetyl-L-cysteine (NAC) and deferoxamine (DFO) were used to block ferroptosis and then explored the anti-fibrotic effect of FMN. The target protein of FMN was identified by bio-orthogonal click chemistry reaction as well as drug affinity responsive target stability (DARTS), cellular thermal shift (CETSA), surface plasmon resonance (SPR) assays, and isothermal titration calorimetry (ITC) analysis. Here, we found that FMN exerted anti-fibrotic effects via inducing ferroptosis in activated HSCs. NAC and DFO prevented FMN-induced ferroptotic cell death and collagen reduction. Furthermore, FMN bound directly to NOX4 through possible active amino acid residues sites, and increased NOX4-based NADPH oxidase activity to enhance levels of NADP+/NADPH, thus promoting ferroptosis of activated HSCs and relieving liver fibrosis. These results demonstrate that the direct target and mechanism by which FMN improves liver fibrosis, suggesting that FMN may be a natural candidate for further development of liver fibrosis therapy.

OPN-Mediated Crosstalk Between Hepatocyte E4BP4 and Hepatic Stellate Cells Promotes MASH-Associated Liver Fibrosis.

Stressed hepatocytes promote liver fibrosis through communications with hepatic stellate cells (HSCs) during chronic liver injury. However, intra-hepatocyte players that facilitate such cell-to-cell communications are largely undefined. It is previously reported that hepatocyte E4BP4 is potently induced by ER stress and hepatocyte deletion of E4bp4 protects mice from high-fat diet-induced liver steatosis. Here how hepatocyte E4bp4 deficiency impacts the activation of HSCs and the progression toward MASH-associated liver fibrosis is examined. Hepatic E4BP4 is increased in mouse models of NASH diet- or CCl4-induced liver fibrosis. Hepatocyte-specific E4bp4 deletion protected mice against NASH diet-induced liver injury, inflammation, and fibrosis without impacting liver steatosis. Hepatocyte E4BP4 overexpression activated HSCs in a medium transfer experiment, whereas hepatocyte E4bp4 depletion did the opposite. RNA-Seq analysis identified the pro-fibrogenic factor OPN as a critical target of E4BP4 within hepatocytes. Antibody neutralization or shRNA depletion of Opn abrogated hepatocyte E4BP4-induced HSC activation. E4BP4 interacted with and stabilized YAP, an established activator of OPN. Loss of hepatic Yap blocked OPN induction in the liver of Ad-E4bp4-injected mice. Hepatocyte E4BP4 induces OPN via YAP to activate HSCs and promote liver fibrosis during diet-induced MASH. Inhibition of the hepatocyte E4BP4-OPN pathway could offer a novel therapeutic avenue for treating MASLD/MASH.

ARP2/3 complex affects myofibroblast differentiation and migration in pancreatic ductal adenocarcinoma.

The ARP2/3 complex, which orchestrates actin cytoskeleton organization and lamellipodia formation, has been implicated in the initiation of pancreatic ductal adenocarcinoma (PDAC). This study aims to clarify its impact on the activity of cancer-associated fibroblasts (CAFs), key players in PDAC progression, and patient outcomes. Early pancreatic carcinogenesis was modeled in p48Cre; LSL-KrasG12D mice with caerulein-induced pancreatitis, complemented by in vitro studies on human immortalized pancreatic stellate cells (PSCs) and primary PDAC-derived CAFs. Data were gained from microarray analysis, RNA sequencing (RNA-seq), and single-cell RNA sequencing (sc-RNA-seq), with subsequent bioinformatics analysis. We uncovered a specific transcriptional signature associated with fibroblast migration in early pancreatic carcinogenesis and linked it to poor survival in patients with PDAC. A pivotal role of the ARP2/3 complex in CAF migration was identified. Inhibition of the ARP2/3 complex markedly decreased CAF motility and induced significant morphological changes in vitro. Furthermore, its inhibition also hindered TGFβ1-mediated myofibroblastic CAF differentiation but had no effect on IL-1-mediated inflammatory CAF differentiation. Our findings position the ARP2/3 complex as central to the migration and differentiation of myofibroblastic CAF. Targeting this complex presents a promising new therapeutic avenue for PDAC treatment.

Modulation of Notch signaling pathway in activated hepatic stellate cells does not ameliorate the outcome of liver fibrosis in carbon tetrachloride and DDC-feeding models.

Recent research suggests a possible role of Notch signaling pathway in development of liver fibrosis, but exact cellular and molecular mechanisms are still not well defined. Methods: We modulated Notch signaling in activated hepatic stellate cells/myofibroblasts using the model of inducible activation or inhibition of Notch signaling selective for αSMA positive cells in murine models of toxic fibrosis induced by CCl4 and cholestatic fibrosis induced by DDC supplemented feeding. Our results confirm that Notch signaling pathway is activated in both CCL4 and DDC model of liver fibrosis and that αSMA positive myofibroblasts are of activated hepatic stellate cells origin. However, neither the inhibition of canonical Notch signaling (in tamoxifen treated αSMACreER/RBP-Jfl/fl mice) nor its overactivation (in tamoxifen treated αSMACreER/NICD1 mice) changed the degree of liver fibrosis in comparison to the control groups in either of the investigated models. Furthermore, after the withdrawal of the fibrogenic treatment the degree of resolution of fibrosis was similar between the animals with Notch overactivation and controls. In addition to genetic manipulation, we investigated the effect of antibodies against NOTCH1 and NOTCH2 on the development of liver fibrosis. Treatment with antibodies had effects on thymus and spleen respectively, but failed to ameliorate liver fibrosis. In conclusion, our data demonstrate that modulation of Notch activity in activated HSC is not sufficient to change the outcome of liver fibrosis. The results obtained with inhibitory antibodies further demonstrate limitations of targeting Notch 1 and 2 receptors as antifibrotic therapy. Notch pathway remains a potential target for the treatment of liver fibrosis, but future studies should be directed to Notch 3 signaling and/or targeting different populations of cells.

E2F2 Reprograms Macrophage Function By Modulating Material and Energy Metabolism in the Progression of Metabolic Dysfunction-Associated Steatohepatitis.

Macrophages are essential for the development of steatosis, hepatic inflammation, and fibrosis in metabolic dysfunction-associated steatohepatitis(MASH). However, the roles of macrophage E2F2 in the progression of MASH have not been elucidated. This study reveals that the expression of macrophage E2F2 is dramatically downregulated in MASH livers from mice and humans, and that this expression is adversely correlated with the severity of the disease. Myeloid-specific E2F2 depletion aggravates intrahepatic inflammation, hepatic stellate cell activation, and hepatocyte lipid accumulation during MASH progression. Mechanistically, E2F2 can inhibit the SLC7A5 transcription directly. E2F2 deficiency upregulates the expression of SLC7A5 to mediate amino acids flux, resulting in enhanced glycolysis, impaired mitochondrial function, and increased macrophages proinflammatory response in a Leu-mTORC1-dependent manner. Moreover, bioinformatics analysis and CUT &Tag assay identify the direct binding of Nrf2 to E2F2 promoter to promote its transcription and nuclear translocation. Genetic or pharmacological activation of Nrf2 effectively activates E2F2 to attenuate the MASH progression. Finally, patients treated with CDK4/6 inhibitors demonstrate reduced E2F2 activity but increased SLC7A5 activity in PBMCs. These findings indicated macrophage E2F2 suppresses MASH progression by reprogramming amino acid metabolism via SLC7A5- Leu-mTORC1 signaling pathway. Activating E2F2 holds promise as a therapeutic strategy for MASH.

Pathological Microenvironment-Remodeling Nanoparticles to Alleviate Liver Fibrosis: Reversing Hepatocytes-Hepatic Stellate Cells Malignant Crosstalk.

During the onset and malignant development of liver fibrosis, the pernicious interplay between damaged hepatocytes and activated hepatic stellate cells (HSCs) induce a self-perpetuating vicious cycle, deteriorating fibrosis progression and posing a grave threat to public health. The secretions released by damaged hepatocytes and activated HSCs interact through autocrine or paracrine mechanisms, involving multiple signaling pathways. This interaction creates a harsh microenvironment and weakens the therapeutic efficacy of single-cell-centric drugs. Herein, a malignant crosstalk-blocking strategy is prompted to remodel vicious cellular interplay and reverse pathological microenvironment to put an end to liver fibrosis. Collagenases modified, bardoxolone and siTGF-β co-delivered nanoparticles (C-NPs/BT) are designed to penetrate the deposited collagen barriers and further regulate the cellular interactions through upregulating anti-oxidative stress capacity and eliminating the pro-fibrogenic effects of TGF-β. The C-NPs/BT shows successful remodeling of vicious cellular crosstalk and significant disease regression in animal models. This study presents an innovative strategy to modulate cellular interactions for enhanced anti-fibrotic therapy and suggests a promising approach for treating other chronic liver diseases.

Correlation between portal hypertension and somatic constitution: rationale behind the concept

This review summarizes recent data on the correlation of somatic constitution and portal hypertension.Somatotype reflects the constitutional composition of the human body. Excess endomorphic component (i.e. obesity) increases the risk of portal hypertension (PH - elevated pressure in the portal system above 12 mmHg) development. Among the prehepatic and posthepatic PH causes only congestive hepatopathy, a consequence of heart failure, is connected with obesity. A number of pathways connect the hepatic PH causes with obesity. Firstly, the action of proinflammatory cytokines produced by adipose tissue in greater amount in obesity promotes fatty acid uptake and storage by hepatocytes, leading to elevated oxidative stress and metabolic dysfunctions, activation of stellate cells, that differentiate into myofibroblasts and produce components of the intercellular matrix such as collagen into the perisinusoidal space resulting in fibrosis. Secondly, insulin resistance associated with obesity promotes dysfunction of the hepatic microcirculatory blood vessels, hyperlipidemia and liver steatosis. Thirdly, AMISS (Absence of Meal-induced Insulin Sensitization Syndrome), caused by regular high-carbohydrate and low-protein food consumption, manifested in decreased postprandial secretion of hepatic hormone hepatalin, which increases glucose uptake by skeletal and cardiac muscle, results in prolonged postprandial hyperglycemia, compensatory hyperinsulinemia and hyperlipidemia, leading to increased insulin resistance and a prediabetic state, associated with steatohepatosis. Thus, excess endomorphic component is to be regarded as a prognostic factor for portal hypertension.

GDF2 and BMP10 coordinate liver cellular crosstalk to maintain liver health

The liver is the largest solid organ in the body and is primarily composed of hepatocytes (HCs), endothelial cells (ECs), Kupffer cells (KCs), and hepatic stellate cells (HSCs), which spatially interact and cooperate with each other to maintain liver homeostasis. However, the complexity and molecular mechanisms underlying the crosstalk between these different cell types remain to be revealed. Here, we generated mice with conditional deletion of Gdf2 (also known as Bmp9) and Bmp10 in different liver cell types and demonstrated that HSCs were the major source of GDF2 and BMP10 in the liver. Using transgenic ALK1 (receptor for GDF2 and BMP10) reporter mice, we found that ALK1 is expressed on KCs and ECs other than HCs and HSCs, and GDF2 and BMP10 secreted by HSCs promote the differentiation of KCs and ECs and maintain their identity. Pdgfb expression was significantly upregulated in KCs and ECs after Gdf2 and Bmp10 deletion, ultimately leading to HSCs activation and liver fibrosis. ECs express several angiocrine factors, such as BMP2, BMP6, Wnt2, and Rspo3, to regulate HC iron metabolism and metabolic zonation. We found that these angiocrine factors were significantly decreased in ECs from Gdf2/Bmp10HSC-KO mice, which further resulted in liver iron overload and disruption of HC zonation. In summary, we demonstrated that HSCs play a central role in mediating liver cell-cell crosstalk via the production of GDF2 and BMP10, highlighting the important role of intercellular interaction in organ development and homeostasis.