SOX9 promotes hepatocyte proliferation via upregulating TGF-α expression during liver regeneration.

The Benevolent Bile: Bile Acids as Stimulants of Liver Regeneration

Cholangiocyte-to-Hepatocyte Differentiation: A Context-Dependent Process and an Opportunity for Regenerative Medicine.

Sinusoidal Endothelial Cells Coordinate Liver Regeneration and Angiogenesis via Angiopoietin-2: An Ode to Prometheus

Stem Cells and Liver Regeneration

Failure of Fibrotic Liver Regeneration in Mice Is Linked to a Severe Fibrogenic Response Driven by Hepatic Progenitor Cell Activation

Vascular endothelial growth factor and liver regeneration

315 FoxO3 REGULATES HEPATIC GLUCOSE PRODUCTION

New mechanisms involving the EGFR and FGF15/19 systems in liver regeneration and carcinogenesis

Amphiregulin: An early trigger of liver regeneration in mice

Disclosure: J.E. Gunton: None. Harendran Elangovan [1], Rebecca A. Stokes [1], Jeremy Keane [1], Sarinder Chahal [1], Caroline Samer [1], Miguel Agoncillo [1], Josephine Yu [1], Jennifer Chen [1], Michael Downes 2, Ronald M. Evans 2, Christopher Liddle [1],2, Jenny E. Gunton [1] [1]Centre for Diabetes, Obesity and Endocrinology, The Westmead Institute for Medical Research, University of Sydney, Westmead, NSW, Australia 2 Salk Institute for Biological Studies, La Jolla, CA. USA Background: Vitamin D signals through the vitamin D receptor (VDR) to induce its end-organ effects. Hepatic stellate cells control development of liver fibrosis in response to stressors and vitamin D signaling decreases fibrogenesis. VDR expression in hepatocytes, however, is low in healthy liver, and the role of VDR in hepatocyte proliferation is unclear. Methods: In these studies, hepatocyte-VDR null mice (hVDR) were used to assess the role of VDR and vitamin D signaling in hepatic regeneration. Mice underwent 2/3 partial hepatectomy and liver regeneration and function were studied. Results: hVDR mice had impaired liver regeneration with impaired hepatocyte proliferation. This was associated with significant differential changes in bile salts. Notably, mice lacking hepatocyte VDR had significant increases in expression of conjugated bile acids after partial hepatectomy, consistent with failure to normalize hepatic function by the 14-day time point tested. CDCA (chenodeoxycholate) is an FXR ligand, which was increased after surgery in controls but not in hVDR mice. FXR signaling is important for hepatocyte proliferation. Real-time PCR of hVDR and control livers showed significant changes in expression of cell cycle genes including cyclins D1 and E1 and cyclin-dependent kinase 2. Gene expression profiling of hepatocytes treated with vitamin D or control showed regulation of groups of genes involved in liver proliferation, hepatitis, liver hyperplasia / hyperproliferation and liver necrosis / cell death. Conclusions: Together these studies demonstrate an important functional role for VDR in hepatocytes during liver regeneration. Combined with the known profibrotic effects of impaired VDR signaling in stellate cells, these studies provide a mechanism whereby vitamin D deficiency would both reduce hepatocyte proliferation and permit fibrosis, leading to significant liver compromise. Presentation: 6/2/2024

Investigation of the Role of Glypican 3 in Liver Regeneration and Hepatocyte Proliferation

Following acute liver injury, hepatocytes divide to facilitate regeneration. However, during chronic injury, hepatocyte proliferation is typically blocked and repair is mediated through liver progenitor (oval) cells. Signalling of the p55 tumour necrosis factor (TNF) receptor is central to these processes. Two ligands for p55 are known: TNF and lymphotoxin-alpha (LTalpha). However, one study suggests that another exists that mediates liver injury following viral challenge. We have therefore investigated whether ligands other than TNF and LTalpha are required for liver regeneration following either acute or chronic injury. Wild-type and double TNF/LTalpha knockout (TNF-/-LTalpha-/-) mice were subjected to either partial hepatectomy (PHx) or a choline-deficient ethionine-supplemented (CDE) diet. Proliferating hepatocytes, oval cells and inflammatory cells were identified and quantified in liver sections by immunohistochemistry. Liver inflammatory cells were characterised by cell surface antigen expression. Liver damage and mortality were monitored. Both hepatocyte and oval cell proliferation was reduced in TNF-/-LTalpha-/- mice. Lymphocyte clusters were evident in all TNF-/-LTalpha-/- livers and were heterogeneous, comprising B and T lymphocytes. PHx evoked liver inflammation in TNF-/-LTalpha-/- but not wild-type mice, whereas no difference was apparent between genotypes in CDE experiments. Thus, TNF/LTalpha signalling mediates liver regeneration involving both hepatocytes and progenitor cells. The hyper-inflammatory response following PHx in TNF-/-LTalpha-/- animals, which is absent following CDE-induced injury, demonstrates that the two forms of liver injury evoke discrete inflammatory responses and provides a model in which such differences can be examined further.

Hepatocyte damage during liver injury instigates activation of macrophages and hepatic stellate cells (HSCs) resulting in liver inflammation and fibrosis respectively. Improving hepatocyte survival and proliferation thereby ameliorating inflammation and fibrosis represents a promising approach for the treatment of liver injury. In the liver, fibroblast growth factors (FGFs) play a crucial role in promoting hepatocyte proliferation and tissue regeneration. Among 22 FGFs, FGF7 induces hepatocyte survival and liver regeneration as shown previously in mouse models of cholestatic liver injury and partial hepatectomy. We hypothesized that FGF7 promotes hepatocyte survival and proliferation by interacting with FGFR2b, expressed on hepatocytes, and ameliorates liver injury (inflammation and early fibrogenesis) via paracrine mechanisms. To prove this hypothesis and to study the effect of FGF7 on hepatocytes and liver injury, we administered FGF7 exogenously to mice with acute carbon tetrachloride (CCl4)-induced liver injury. We thereafter studied the underlying mechanisms and the effect of exogenous FGF7 on hepatocyte survival and proliferation, and the consequent paracrine effects on macrophage-induced inflammation, and HSCs activation in vitro and in vivo. We observed that the expression of FGF7 as well as FGFR2 is upregulated during acute liver injury. Co-immunostaining of FGF7 and collagen-I confirmed that FGF7 is expressed by HSCs and is possibly captured by the secreted ECM. Immunohistochemical analysis of liver sections showed increased hepatocyte proliferation upon exogenous FGF7 treatment as determined by Ki67 expression. Mechanistically, exogenous FGF7 improved hepatocyte survival (and increased drug detoxification) via AKT and ERK pathways while maintaining hepatocyte quiescence restricting hepatocarcinogenesis via P27 pathways. Flow cytometry analysis revealed that improved hepatocyte survival and proliferation leads to a decrease in infiltrated monocytes-derived macrophages, as a result of reduced CCL2 (and CXCL8) expression by hepatocytes. Moreover, conditioned medium studies showed reduced collagen-I secretion by HSCs (indicative of HSCs activation) upon treatment with FGF7-treated hepatocytes conditioned medium. Altogether, we show that exogenous administration of FGF7 induces hepatocyte survival and proliferation and leads to amelioration of inflammatory response and fibrosis in acute liver injury via paracrine mechanisms. Our study further demonstrates that FGF7, FGF7 derivatives, or nano-engineered FGF7 may benefit patients with hepatic dysfunction.

Elucidating the Metabolic Regulation of Liver Regeneration

Gut microbiota promote liver regeneration through hepatic membrane phospholipid biosynthesis