Opposing roles of gp130-mediated STAT-3 and ERK-1/ 2 signaling in liver progenitor cell migration and proliferation

Gp130-mediated IL-6 signaling may play a role in oval cell proliferation in vivo. Levels of IL-6 are elevated in livers of mice treated with a choline-deficient ethionine-supplemented (CDE) diet that induces oval cells, and there is a reduction of oval cells in IL-6 knockout mice. The CDE diet recapitulates characteristics of chronic liver injury in humans. In this study, we determined the impact of IL-6 signaling on oval cell-mediated liver regeneration in vivo. Signaling pathways downstream of gp130 activation were also dissected. Numbers of A6(+ve) liver progenitor oval cells (LPCs) in CDE-treated murine liver were detected by immunohistochemistry and quantified. Levels of oval cell migration and proliferation were compared in CDE-treated mouse strains that depict models of gp130-mediated hyperactive ERK-1/2 signaling (gp130(deltaSTAT)), hyperactive STAT-3 signaling (gp130(Y757F) and Socs-3(-/deltaAlb)) or active ERK-1/2 as well as active STAT-3 signaling (wild-type). The A6(+ve) LPC numbers were increased with IL-6 treatment in vivo. The gp130(Y757F) mice displayed increased A6(+ve) LPCs numbers compared with wild-type and gp130(deltaSTAT) mice. Numbers of A6(+ve) LPCs were also increased in the livers of CDE treated Socs-3(-/deltaAlb) mice compared with their control counterparts. Lastly, inhibition of ERK-1/2 activation in cultured oval cells increased hyper IL-6-induced cell growth. For the first time, we have dissected the gp130-mediated signaling pathways, which influence liver progenitor oval cell proliferation. Conclusion: Hyperactive STAT-3 signaling results in enhanced oval cell numbers, whereas ERK-1/2 activation suppresses oval cell proliferation.     

Remarkable heterogeneity displayed by oval cells in rat and mouse models of stem cell-mediated liver regeneration

The experimental protocols used in the investigation of stem cell-mediated liver regeneration in rodents are characterized by activation of the hepatic stem cell compartment in the canals of Hering followed by transit amplification of oval cells and their subsequent differentiation along hepatic lineages. Although the protocols are numerous and often used interchangeably across species, a thorough comparative phenotypic analysis of oval cells in rats and mice using well-established and generally acknowledged molecular markers has not been provided. In the present study, we evaluated and compared the molecular phenotypes of oval cells in several of the most commonly used protocols of stem cell-mediated liver regeneration-namely, treatment with 2-acetylaminofluorene and partial (70%) hepatectomy (AAF/PHx); a choline-deficient, ethionine-supplemented (CDE) diet; a 3,5-diethoxycarbonyl-1,4-dihydro-collidin (DDC) diet; and N-acetyl-paraaminophen (APAP). Reproducibly, oval cells showing reactivity for cytokeratins (CKs), muscle pyruvate kinase (MPK), the adenosine triphosphate-binding cassette transporter ABCG2/BCRP1 (ABCG2), alpha-fetoprotein (AFP), and delta-like protein 1/preadipocyte factor 1 (Dlk/Pref-1) were induced in rat liver treated according to the AAF/PHx and CDE but not the DDC protocol. In mouse liver, the CDE, DDC, and APAP protocols all induced CKs and ABCG2-positive oval cells. However, AFP and Dlk/Pref-1 expression was rarely detected in oval cells. CONCLUSION: Our results delineate remarkable phenotypic discrepancies exhibited by oval cells in stem cell-mediated liver regeneration between rats and mice and underline the importance of careful extrapolation between individual species.     

Transforming growth factor-beta differentially regulates oval cell and hepatocyte proliferation

Oval cells are hepatocytic precursors that proliferate in late-stage cirrhosis and that give rise to a subset of human hepatocellular carcinomas. Although liver regeneration typically occurs through replication of existing hepatocytes, oval cells proliferate only when hepatocyte proliferation is inhibited. Transforming growth factor-beta (TGF-beta) is a key inhibitory cytokine for hepatocytes, both in vitro and in vivo. Because TGF-beta levels are elevated in chronic liver injury when oval cells arise, we hypothesized that oval cells may be less responsive to the growth inhibitory effects of this cytokine. To examine TGF-beta signaling in vivo in oval cells, we analyzed livers of rats fed a choline-deficient, ethionine-supplemented (CDE) diet for phospho-Smad2. Phospho-Smad2 was detected in more than 80% of hepatocytes, but staining was substantially reduced in oval cells. Ki67 staining, in contrast, was significantly more common in oval cells than hepatocytes. To understand the inverse relationship between TGF-beta signaling and proliferation in oval cells and hepatocytes, we examined TGF-beta signaling in vitro. TGF-beta caused marked growth inhibition in primary hepatocytes and the AML12 hepatocyte cell line. Two oval cell lines, LE/2 and LE/6, were less responsive. The greater sensitivity of the hepatocytes to TGF-beta-induced growth inhibition may result from the absence of Smad6 in these cells. CONCLUSION: Our results indicate that oval cells, both in vivo and in vitro, are less sensitive to TGF-beta-induced growth inhibition than hepatocytes. These findings further suggest an underlying mechanism for the proliferation of oval cells in an environment inhibitory to hepatocytic proliferation.     

Interferon-gamma exacerbates liver damage, the hepatic progenitor cell response and fibrosis in a mouse model of chronic liver injury

BACKGROUND/AIMS: Several previous studies have suggested that interferon gamma (IFNgamma) may play a key role during hepatic progenitor cell (HPC) mediated liver regeneration. However to date, no studies have directly tested the ability of IFNgamma to mediate the HPC response in an in vivo model. METHODS/RESULTS: Administration of IFNgamma to mice receiving a choline deficient, ethionine (CDE) supplemented diet to induce chronic injury resulted in an augmented HPC response. This was accompanied by increased inflammation, altered cytokine expression and hepatic fibrosis. Serum alanine aminotransferase activity, hepatocyte apoptosis and Bak staining were significantly increased in IFNgamma-treated, CDE-fed mice, demonstrating that liver damage was exacerbated in these animals. Administration of IFNgamma to control diet fed mice did not induce liver damage, however it did stimulate hepatic inflammation. CONCLUSIONS: Our results suggest that IFNgamma increases the HPC response to injury by stimulating hepatic inflammation and aggravating liver damage. This is accompanied by an increase in hepatic fibrogenesis, supporting previous reports which suggest that the HPC response may drive fibrogenesis during chronic liver injury.     

Impaired liver regeneration and increased oval cell numbers following T cell-mediated hepatitis

The regeneration of liver tissue following transplantation is often complicated by inflammation and tissue damage induced by a number of factors, including ischemia and reperfusion injury and immune reactions to the donor tissue. The purpose of the current study is to characterize the effects of T cell-mediated hepatitis induced by concanavalin A (ConA) on the regenerative response in vivo. Liver regeneration following a partial (70%) hepatectomy (pHx) was associated with elevations in serum enzymes and the induction of key cell cycle proteins (cyclin D, cyclin E, and Stat3) and hepatocyte proliferation. The induction of T cell-mediated hepatitis 4 days before pHx increased serum enzymes 48 hours after pHx, reduced early cyclin D expression and Stat3 activation, and suppressed hepatocyte proliferation. This inhibition of proliferation was also associated with increased expression of p21, the activation of Smad2, the induction of transforming growth factor beta and interferon gamma expression, and reduced hepatic interleukin 6 production. Moreover, the ConA pretreatment increased the numbers of separate oval cell-like CD117(+) cells and hematopoietic-like Sca-1(+) cell populations 48 hours following pHx. The depletion of natural killer (NK) cells, an important component of the innate immune response, did not affect liver injury or ConA-induced impairment of hepatocyte proliferation but did increase the numbers of both CD117-positive and Sca-1-positive cell populations. Finally, splenocytes isolated from ConA-pretreated mice exerted cytotoxicity toward autologous bone marrow cells in an NK cell-dependent manner. CONCLUSION: T cell-mediated hepatitis alters early cytokine responses, reduces hepatocellular regeneration, and induces NK cell-sensitive oval cell and hematopoietic-like cell expansion following pHx.     

Attenuated liver progenitor (oval) cell and fibrogenic responses to the choline deficient, ethionine supplemented diet in the BALB/c inbred strain of mice

BACKGROUND/AIMS: Liver regeneration following chronic injury is associated with inflammation, the proliferation of liver progenitor (oval) cells and fibrosis. Previous studies identified interferon-gamma as a key mediator of oval cell proliferation. Interferon-gamma is known to regulate Th1 cell activities during immune challenge. Therefore, we hypothesised that progenitor cell-mediated regeneration is associated with a Th1 immune response. METHODS: C57Bl/6 (normal Th1 response) and BALB/c mice (deficient in Th1 signalling) were placed on a carcinogenic diet to induce liver injury, progenitor cell proliferation and fibrosis. RESULTS: Serum transaminases and mortality were elevated in BALB/c mice fed the diet. Proliferation of liver progenitor cells was significantly attenuated in BALB/c animals. The pattern of cytokine expression and inflammation differed between strains. Liver fibrosis and hepatic stellate cell activation were significantly inhibited in BALB/c mice compared to C57Bl/6. In addition, interferon-gamma knockout mice also showed reduced fibrosis compared to wild type. These findings are in contrast to published results, in which interferon-gamma is shown to be anti-fibrogenic. CONCLUSIONS: Our data demonstrate that the hepatic progenitor cell response to a CDE diet is inhibited in mice lacking Th1 immune signalling and further show that this inhibition is associated with reduced liver fibrosis.     

Response of sinusoidal mouse liver cells to choline-deficient ethionine-supplemented diet

Background  

Proliferation of oval cells, the bipotent precursor cells of the liver, requires impeded proliferation and loss of hepatocytes as well as a specific micro-environment, provided by adjacent sinusoidal cells of liver. Despite their immense importance for triggering the oval cell response, cells of hepatic sinusoids are rarely investigated. To elucidate the response of sinusoidal liver cells we have employed a choline-deficient, ethionine-supplemented (CDE) diet, a common method for inducing an oval cell response in rodent liver. We have utilised selected expression markers commonly used in the past for phenotypic discrimination of oval cells and sinusoidal cells: cytokeratin, E-cadherin and M2-pyruvate kinase for oval cells; and glial fibrillary acidic protein (GFAP) was used for hepatic stellate cells (HSCs).     

Extracellular ATP activates c-jun N-terminal kinase signaling and cell cycle progression in hepatocytes

Partial hepatectomy leads to an orchestrated regenerative response, activating a cascade of cell signaling events necessary for cell cycle progression and proliferation of hepatocytes. However, the identity of the humoral factors that trigger the activation of these pathways in the concerted regenerative response in hepatocytes remains elusive. In recent years, extracellular ATP has emerged as a rapidly acting signaling molecule that influences a variety of liver functions, but its role in hepatocyte growth and regeneration is unknown. In this study, we sought to determine if purinergic signaling can lead to the activation of c-jun N-terminal kinase (JNK), a known central player in hepatocyte proliferation and liver regeneration. Hepatocyte treatment with ATPgammaS, a nonhydrolyzable ATP analog, recapitulated early signaling events associated with liver regeneration-that is, rapid and transient activation of JNK signaling, induction of immediate early genes c-fos and c-jun, and activator protein-1 (AP-1) DNA-binding activity. The rank order of agonist preference, UTP>ATP>ATPgammaS, suggests that the effects of extracellular ATP is mediated through the activation of P2Y2 receptors in hepatocytes. ATPgammaS treatment alone and in combination with epidermal growth factor (EGF) substantially increased cyclin D1 and proliferating cell nuclear antigen (PCNA) protein expression and hepatocyte proliferation in vitro. Extracellular ATP as low as 10 nM was sufficient to potentiate EGF-induced cyclin D1 expression. Infusion of ATP by way of the portal vein directly activated hepatic JNK signaling, while infusion of a P2 purinergic receptor antagonist prior to partial hepatectomy inhibited JNK activation. In conclusion, extracellular ATP is a hepatic mitogen that can activate JNK signaling and hepatocyte proliferation in vitro and initiate JNK signaling in regenerating liver in vivo. These findings have implications for enhancing our understanding of novel factors involved in the initiation of regeneration, liver growth, and development.     

Differential regulation of rodent hepatocyte and oval cell proliferation by interferon gamma

Hepatocytes and intrahepatic progenitor cells (oval cells) have similar responses to most growth factors but rarely proliferate together. Oval cells constitute a reserve compartment that is activated when hepatocyte proliferation is inhibited. Interferon gamma (IFN-gamma) increases in liver injury that involves oval cell responses, but it is not upregulated during liver regeneration after partial hepatectomy. Based on these observations, we used well-characterized lines of hepatocytes (AML-12 cells) and oval cells (LE-6 cells) to investigate the potential mechanisms that regulate differential growth responses in hepatocytes and oval cells. We show that IFN-gamma blocks hepatocyte proliferation in vivo, and that in combination with either tumor necrosis factor (TNF) or lipopolysaccharide (LPS), it causes cell cycle arrest in hepatocytes but stimulates oval cell proliferation in cultured cells. The hepatocyte cell cycle arrest is reversible, is p53-independent, and is not associated with apoptosis. Treatment of AML-12 hepatocytes with IFN-gamma/LPS or IFN-gamma/TNF, but not with individual cytokines, induced NO synthase and generated NO, while similarly treated oval cells produced little if any NO. Generation of NO by an NO donor reproduced the inhibitory effect of the cytokine combinations on AML-12 cell replication, while NO inhibitors abolish the replication deficiency. In conclusion, we propose that IFN-gamma, in conjunction with TNF or LPS, can both inhibit hepatocyte proliferation through the generation of NO and stimulate oval cell replication. The response of hepatocytes and oval cells to cytokine combinations may contribute to the differential proliferation of these cells in hepatic growth processes.     

A modified choline-deficient, ethionine-supplemented diet protocol effectively induces oval cells in mouse liver

Several reliable and reproducible methods are available to induce oval cells in rat liver. Effective methods often involve inhibiting proliferation in hepatocytes using an alkylating agent, then subjecting the rat to partial hepatectomy (PH). The surgery is difficult to perform reproducibly in mice. Approaches that do not include partial hepatectomy, such as administration of D-galactosamine, are ineffective in mice. We found that a choline-deficient, ethionine-supplemented (CDE) diet, which is very effective in rats, leads to high morbidity and mortality when administered to mice. This article outlines an alternative protocol by which a CDE diet can be administered to mice. This diet is shown to be highly effective for oval cell induction, without causing high mortality. It takes less time and is at least as effective as other commonly used protocols for inducing oval cells in mice.     

Cell signaling in oxidative stress-induced liver injury

Oxidative stress is a common mechanism of liver injury. Recent investigations have demonstrated that oxidant-induced liver injury is mediated by the direct effects of reactive oxygen species on signal transduction pathways. Although the function of cell signaling in this form of injury is complex and likely variable depending on the type and duration of oxidative stress, common regulatory pathways of hepatocyte oxidant injury have been identified that include the mitogen-activated protein kinases extracellular signal-regulated kinase 1/2 (ERK1/2) c-Jun N-terminal kinase (JNK), and the nuclear factor kappaB (NF-kappaB) pathway. Studies in cultured hepatocyte and rodent models of oxidative stress have demonstrated that ERK1/2 typically induces resistance to oxidant stress, whereas JNK promotes cell death. The effects of NF-kappaB activation are more complex and cell-type specific. A further understanding of the signaling pathways that regulate oxidant-induced liver injury may suggest new therapies for hepatic diseases resulting from oxidative stress.     

Regulation of hepatic oval cell proliferation by adenoviral mediated hepatocyte growth factor gene transfer and signal transduction inhibitors

BACKGROUND/AIMS: To rescue patients with severe liver injury, it is critical to develop the efficient regulatory system of hepatic stem cell proliferation in vitro. Our aims are to examine whether combination of adenovirus-mediated hepatocyte growth factor (HGF) gene transfer with signal transduction inhibitors can regulate cell proliferation of oval cells. METHODOLOGY: We examined the effects of treatment with adenoviral mediated HGF gene transfer and signal transduction inhibitors including LY294002, rapamycin and U0126 on proliferation OC/CDE22 hepatic oval cells and expression of signal transduction molecules. RESULTS: Infection with pAxCAHGF expanded the cells by 8-fold at 2 days, by 18-fold at 3 days and by 55-fold at 4 days. The addition of inhibitors inhibited pAxCAHGF-induced cell proliferation by LY294002 or rapamycin (P < 0.01, each). U0126 also inhibited growth of hepatic oval cells (P < 0.01). pAxCAHGF treatment induced phosphorylation of AKT. Treatment with rapamycin resulted in enhanced phosphorylation of AKT, and phosphorylation of AKT was induced by pAxCAHGF plus U0126. CONCLUSIONS: Autocrine expression of HGF with signal transduction inhibitors can regulate proliferation of OC/CDE22 hepatic oval cells. In addition, the AKT pathway is important for HGF-stimulated hepatic oval cell proliferation.     

Isolation of fetal liver oval cells in physiologic conditions form their natural niche

The liver is characterized by a remarkable ability to proliferate and self-renew. In the situation of mild or moderate liver damage, hepatocytes carry out regeneration. Nevertheless, when liver damage is far too much extensive and the number of residual mature hepatocytes is not enough to accomplish regeneration, or likewise when mature hepatocyte proliferation is inhibited, hepatic regeneration depends on the activation of liver stem cells that give rise to oval cells. The population of liver stem cells is scant in normal liver. It is considered that in fetal liver this population is just over 1% of the cells. For this reason, it is necessary to isolate and enrich them for their study. With this goal several models of hepatic damage that permit the isolation of oval cells af ter the induction of massive hepatic injure have been developed. Here we present a simple methodology that allows the isolation of oval cells from rat fetal liver without prior induction of liver damage. The use of oval cell 2 (OC2) and oval cell 3 (OC3) antigens as molecular markers allowed the highly precise characterization of this cell population. Furthermore, the in vitro culture in presence of HGF yielded a substantial enrichment of the oval cell population.     

Ductular proliferation in liver tissues with severe chronic hepatitis B： An immunohistochemical study

AIM: To clarify the pathogenesis of ductular proliferation and its possible association with oval cell activation and hepatocyte regeneration. METHODS: Immunohistochemical staining and image analysis of the ductular structures in the liver tissues from 11 patients with severe chronic hepatitis B and 2 healthy individuals were performed. The liver specimens were sectioned serially, and then cytokeratin 8 (CK8), CK19, OV6, proliferating cell nuclear antigens (PCNA), glutathione-S-transferase (GST),α-fetal protein (AFP) and albumin were stained immunohistochemically. RESULTS: Typical and atypical types of ductular proliferation were observed in the portal tracts of the liver tissues in all 11 patients. The proliferating ductular cells were positive for CK8, CK19, OV6 and PCNA staining. Some atypical ductular cells displayed the morphological and immunohistochemical characteristics of hepatic oval cells. Some small hepatocyte-like cells were between hepatic oval cells and mature hepatocytes morphometri-cally and immunohistochemically. CONCLUSION: The proliferating ductules in the liver of patients with severe chronic liver disease may have different origins. Some atypical ductular cells are actually activated hepatic oval cells. Atypical ductular proliferation is related to hepatocyte regeneration and small hepatocyte-like cells may be intermediate transient cells between hepatic oval cells and mature hepatocytes.     

CXC chemokine signaling in the liver: impact on repair and regeneration

The process of liver repair and regeneration following hepatic injury is complex and relies on a temporally coordinated integration of several key signaling pathways. Pathways activated by members of the CXC family of chemokines play important roles in the mechanisms of liver repair and regeneration through their effects on hepatocytes. However, little is known about the signaling pathways used by CXC chemokine receptors in hepatocytes. Here we review our current understanding of the pathways involved in both CXC chemokine receptor signaling in other cell types, most notably neutrophils, and similar pathways operant during hepatocyte proliferation/liver regeneration to formulate a basis for the function of CXC chemokine receptor signaling in hepatocytes.     

Granulocyte-colony stimulating factor promotes liver repair and induces oval cell migration and proliferation in rats

BACKGROUND AND AIMS: Hepatic regeneration is a heterogeneous phenomenon involving several cell populations. Oval cells are considered liver stem cells, a portion of which derive from bone marrow (BM). Recent studies have shown that granulocyte-colony stimulating factor (G-CSF) may be effective in facilitating liver repair. However, it remains unclear if G-CSF acts by mobilizing BM cells, or if it acts locally within the liver microenvironment to facilitate the endogenous restoration program. In the present study, we assessed the involvement of G-CSF during oval cell activation. METHODS: Dipeptidyl-peptidase-IV-deficient female rats received BM transplants from wild-type male donors. Four weeks later, rats were subjected to the 2-acetylaminofluorene/partial hepatectomy model of oval cell-mediated liver regeneration, followed by administration of either nonpegylated G-CSF or pegylated G-CSF. Control animals did not receive further treatments after surgery. The magnitude of oval cell reaction, the entity of BM contribution to liver repopulation, as well as the G-CSF/G-CSF-receptor expression levels were evaluated. In addition, in vitro proliferation and migration assays were performed on freshly isolated oval cells. RESULTS: Oval cells were found to express G-CSF receptor and G-CSF was produced within the regenerating liver. G-CSF administration significantly increased both the magnitude of the oval cell reaction, and the contribution of BM to liver repair. Finally, G-CSF acted as a chemoattractant and a mitogen for oval cells in vitro. CONCLUSIONS: We have shown that G-CSF facilitates hepatic regeneration by increasing the migration of BM-derived progenitors to the liver, as well as enhancing the endogenous oval cell reaction.