Hepatic "stem" cells: coming full circle

Activation, proliferation, and differentiation of a distinct phenotype of cells, called oval cells, are observed after severe hepatic injuries in which the proliferation of existing hepatocytes is inhibited. Under those conditions, oval cells can act as bipotential progenitors of the two types of epithelial cells within the liver, hepatocytes and bile ductular cells. Oval cells are also believed to play a role in the hepatocellular carcinoma and cholangiocarcinoma development; although circumstantial data are available, no direct evidence exists to support this theory. Oval cells have usually been thought to be the progeny of an hepatic stem cell, native to the liver. Recently, however, we, as well as others, have obtained clear evidence that in the rodents, hepatic oval cells, or at least a fraction of them, can derive from a precursor cell of bone marrow origin. The rodent data have been supported by recent findings that human bone marrow cells are capable of becoming hepatocytes and cholangiocytes as well. Having shown that oval cells can be derived from an extrahepatic source, we now have the technology to address many unanswered questions in oval cell origin, fate, and physiology through the use of sex-mismatched bone marrow transplants.     

The origin and liver repopulating capacity of murine oval cells

The appearance of bipotential oval cells in chronic liver injury suggests the existence of hepatocyte progenitor/stem cells. To study the origin and properties of this cell population, oval cell proliferation was induced in adult mouse liver by 3,5-diethoxycarbonyl-1,4-dihydrocollidine (DDC) and a method for their isolation was developed. Transplantation into fumarylacetoacetate hydrolase (Fah) deficient mice was used to determine their capacity for liver repopulation. In competitive repopulation experiments, hepatic oval cells were at least as efficient as mature hepatocytes in repopulating the liver. In mice with chimeric livers, the oval cells were not derived from hepatocytes but from liver nonparenchymal cells. This finding supports a model in which intrahepatic progenitors differentiate into hepatocytes irreversibly. To determine whether oval cells originated from stem cells residing in the bone marrow, bone marrow transplanted wild-type mice were treated with DDC for 8 months and oval cells were then serially transferred into Fah mutants. The liver repopulating cells in these secondary transplant recipients lacked the genetic markers of the original bone marrow donor. We conclude that hepatic oval cells do not originate in bone marrow but in the liver itself, and that they have valuable properties for therapeutic liver repopulation.     

Liver regeneration in a retrorsine/CCl4-induced acute liver failure model: do bone marrow-derived cells contribute?

BACKGROUND/AIMS: Adult bone marrow contains progenitors capable of generating hepatocytes. Here a new liver failure model is introduced to assess whether bone marrow-derived progeny contribute to liver regeneration after acute hepatotoxic liver failure. METHODS: Retrorsine was used to inhibit endogenous hepatocyte proliferation, before inducing acute liver failure by carbon tetrachloride. Bone marrow chimeras were generated before inducing liver failure to trace bone marrow-derived cells. Therefore, CD45 and major histocompatibility complex (MHC) class I dimorphic rat models were applied. RESULTS: Early after acute liver failure a multilineage inflammatory infiltrate was observed, mainly consisting of granulocytes. In long-term experiments small numbers of CD90+/CD45- cells of donor origin occurred in clusters associated with portal triads. Bone marrow cell infusion was not able to enhance liver regeneration. Cellular hypertrophy was the predominant way of liver mass regeneration in models applying retrorsine. CONCLUSIONS: Retrorsine pretreatment did not affect sensitivity for carbon tetrachloride. A multilineage inflammatory infiltrate was observed in rats whether pretreated with retrorsine or not. Few donor cells co-expressing CD90 (THY 1) were present in recipient livers, which may resemble donor-derived hematopoietic progenitors or oval cells. No other donor cells within liver parenchyma were detected. This is in contrast to other cell infusion models of acute cell death.     

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.     

Bone marrow-derived hepatic oval cells differentiate into hepatocytes in 2-acetylaminofluorene/partial hepatectomy-induced liver regeneration

BACKGROUND AND AIMS: The ability of the bone marrow cells to differentiate into liver, pancreas, and other tissues led to the speculation that these cells might be the source of adult stem cells found in these organs. The present study analyzed whether the bone marrow cells are a source of hepatic oval cells involved in rat liver regeneration induced by 2-acetylaminofluorene (2-AAF) and 70% partial hepatectomy (PHx). METHODS: Three groups of mutant F344 dipeptidyl peptidase IV-deficient (DPPIV(-)) rats were required for the study. Groups A and B received the mitotic inhibitor monocrotaline, followed by male F344 (DPPIV(+)) bone marrow transplantation. Next, group A received PHx only, while group B received the 2-AAF/PHx required for the oval cell activation. The last group C was used to analyze the effects of monocrotaline on transplanted bone marrow cells. These rats underwent transplantation with bone marrow cells and were then treated with monocrotaline. Subsequently, the animals were treated with 2-AAF/PHx. RESULTS: In group A, DPPIV(+) hepatocytes were found in the liver. Group B showed that approximately 20% of the oval cell population expressed both donor marker (DPPIV) and alpha-fetoprotein, and some differentiated into hepatocytes. In contrast, animals in group C failed to significantly induce oval cells with the donor DPPIV antigen. In addition, X/Y-chromosome analysis revealed that fusion was not contributing to differentiation of donor-derived oval cells. CONCLUSIONS: Our results suggest that under certain physiologic conditions, a portion of hepatic stem cells might arise from the bone marrow and can differentiate into hepatocytes.     

Physiological variations of stem cell factor and stromal‐derived factor‐1 in murine models of liver injury and regeneration

Background/Aims: Stem cell factor (SCF) and stromal‐derived factor‐1 (SDF‐1) regulate the regenerative response to liver injury, possibly through activation of liver progenitor ‘oval’ cells and recruitment of circulating, marrow‐derived progenitors. Methods: We performed a detailed analysis of SCF, SDF‐1 and oval cell proliferation induced by tyrosinaemia, 3,5‐diethoxycarbonyl‐1,4‐dihydrocollidine (DDC) or liver irradiation in mice by ELISA and immunofluorescence. Results: Liver injury in the tyrosinaemia mouse is characterized by a dramatic decline in plasma SCF and absence of oval cell proliferation. In contrast, DDC induces bile duct (BD) and oval cell proliferation, and a modest decline in plasma SCF. Focal liver irradiation increases plasma SCF, but not oval cell density. In normal mouse liver, SCF is localized primarily to Kupffer cells, cholangiocytes and arterial smooth muscle, with little or no expression in hepatocytes. However, SCF appears in hepatocyte nuclei after injury, where its function is unknown. In all three models, SDF‐1 is expressed exclusively in BD epithelium, indicating that tissue SDF‐1 levels are proportional to the total mass of oval cells and cholangiocytes. However, increased plasma levels of SDF‐1 in fumaryl acetoacetate hydroxylase‐null mice were not accompanied by oval cell proliferation. Conclusion: Changes in SCF and SDF‐1 varied with the nature of liver injury and were not directly related to oval cell proliferation.     

Origin of hepatocellular carcinoma: role of stem cells

The question of whether hepatocellular carcinoma (HCC) arises from the differentiation block of stem cells or dedifferentiation of mature cells remains controversial. Recently, researchers suggested that HCC may originate from the transdifferentiation of bone marrow cells. Interestingly, there are four levels of cells in the hepatic stem cell lineage: bone marrow cells, hepato-pancreas stem cells, oval cells and hepatocytes. Hematopoietic stem cells and the liver are known to have a close relationship in early development. Bone marrow stem cells could differentiate into oval cells, which could differentiate into hepatocytes and duct cells. The development of pancreatic and liver buds in embryogenesis suggests the existence of a common progenitor cell to both the pancreas and liver. Cellular events during hepatocarcinogenesis illustrate that HCC may arise from cells at various stages of differentiation in the hepatic stem cell lineage.     

The role of bone marrow stem cells in liver regeneration

Hepatic oval cells involved in some forms of liver regeneration express many markers also found on hematopoietic stem cells (HSCs). In addition, multiple independent reports have demonstrated that bone marrow cells can give rise to several hepatic epithelial cell types, including oval cells, hepatocytes, and duct epithelium. These observations have resulted in the hypothesis that bone marrow resident stem cells, specifically HSCs, are an important source for liver epithelial cell replacement, particularly during chronic injury. The function of such stem cells in hepatic injury responses is the topic of this article. Taken together, the published data on the role of bone marrow stem cells in liver damage suggest that they do not play a significant physiological role in the replacement of epithelial cells in any known form of hepatic injury. Fully functional bone marrow-derived hepatocytes exist but are extremely rare and are generated by cell fusion, not stem cell differentiation. Nonetheless, bone marrow-derived cells may play important indirect roles in liver regeneration. First, they may serve as a source for the replacement of endothelial cells. Second, hematopoietic cells, including lymphocytes, neutrophils, macrophages, and platelets, may provide crucial factors required for efficient healing of damaged liver.     

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.     

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.     

Differential roles of stromal cells, interleukin-7, and kit-ligand in the regulation of B lymphopoiesis.

Newly formed B lymphocytes are a population of rapidly renewed cells in the bone marrow of mammals and their steady state production presumably depends on a cascade of regulatory cells and cytokines. Although considerable information has been forthcoming about the role of interleukin-7 (IL-7) in potentiating pre-B-cell proliferation, few studies have addressed the possibility that multiple cytokines are involved in the progression of early events in cellular differentiation and proliferation in this hematopoietic lineage. Our laboratory previously described pre-B-cell differentiation mediated by the bone marrow stromal cell line S17. In this study, we further delineate the role of stromal cells in differentiation and proliferation of pre-B cells. These experiments show that the stromal cell line S17 potentiates the proliferative effect of IL-7 on B-lineage cells and that this S17-derived potentiator can be replaced with recombinant kit-ligand (KL). Our results further show that pre-B-cell formation from B220-, Ig- progenitor cells and expression of mu heavy chain of immunoglobulin is uniquely dependent on the presence of S17 stromal cells and cannot be reproduced with IL-7, KL, or costimulation with both IL-7 and KL. These data contribute to a rapidly evolving model of stromal cell regulation of B-cell production in the marrow and suggest unique roles for IL-7, KL, and as yet uncharacterized stromal cell-derived lymphokines in this process.     

Heterogeneity and plasticity of hepatocyte lineage cells

It is hypothesized that the liver has 3 levels of cells in the hepatic lineage that respond to injury or carcinogenesis: 1) the mature hepatocyte, which responds to partial hepatectomy (PH), to centrolobular injury, such as that induced by carbon tetrachloride (CCl(4)), and to dimethylnitrosamine (DEN) hepatocarcinogenesis; 2) the ductular "bipolar" progenitor cell, which responds to centrolobular injury when the proliferation of hepatocytes is inhibited, and to N-2-acetylaminofluorene (AAF) hepatocarcinogenesis; and 3) the putative periductular stem cell, which responds to periportal injury, such as induced by allyl alcohol and to choline-deficiency models of hepatocarcinogenesis. Hepatocytes are numerous, respond rapidly by 1 or 2 cell cycles, but can only produce other hepatocytes. The ductular progenitor cells are less numerous, may proliferate for longer times than hepatocytes, and are generally considered "bipolar," i.e., can give rise to biliary cells or hepatocytes. Periductular stem cells are rare in the liver, have a very long proliferation potential, and may be multipotent, but their full potential has yet to be defined. Extrahepatic (bone marrow) origin of the periductular stem cells is supported by recent data showing that hepatocytes may express genetic markers of donor hematopoietic cells after bone marrow transplantation. Thus, experimental models of liver injury and of hepatocarcinogenesis may call forth a cellular response at different levels in the hepatic lineage (heterogeneity), and these cells have different potential to form cells of other types (plasticity).     

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.     

Characterization of TGF-β1-binding proteins in human bone marrow stromal cells

The proliferation and differentiation of haemopoietic progenitor cells is dependent on their close relation with bone marrow stromal cells, which constitute a source of cytokines as well as expressing receptors for both the cytokines and progenitor cell adhesion molecules necessary for regulated haemopoiesis. We have generated human bone marrow stromal cell cultures and analysed the TGF-β1 receptor components expressed by these cells. [¹²⁵I]TGF-β1-affinity labelling experiments showed the involvement of type I and II receptors in the binding of TGF-β1, as demonstrated by specific immunoprecipitation of [¹²⁵I]TGF-β1–receptor complexes. In addition, large TGF-β1-labelled complexes displaying an electrophoretic mobility similar to betaglycan were also observed in these experiments. Endoglin, another component of the TGF-βreceptor system, was detected by flow cytometry on the surface of cultured marrow stromal cells, and in the human bone marrow stromal cell line Str-5, and was immunoprecipitated from surface-iodinated cells. Endoglin on the stromal cells was able to bind TGF-β1, as demonstrated by specific immunoprecipitation of [¹²⁵I]TGF-β1–endoglin complexes using anti-endoglin antibodies. The results presented provide evidence that bone marrow stromal cells are fully capable of responding to TGF-β1. Given the important role of TGF-βas a regulator of the synthesis of cytokines and cytokine receptors, as well as cell adhesion molecules, these data indicate that the binding of TGF-β1 by stromal cells might represent an important step in the regulation of the proliferation and differentiation of haemopoietic progenitor cells.     

The role of stem cell factor (c-kit ligand) and inflammatory cytokines in pulmonary mast cell activation

Mast cells play a critical role in allergic airway responses via IgE- specific activation and release of potent inflammatory mediators. In the present study, we have isolated and characterized primary mast cell lines derived from the upper airways of normal mice. The primary mast cell lines were grown and maintained by incubation with interleukin-3 (IL-3) and stem cell factor (SCF) and shown to be c-kit (SCF receptor) positive by flow cytometry. Subsequently, we examined the proliferation of both airway and bone marrow derived mast cell lines in response to inflammatory and hematopoietic cytokines, including SCF, IL-1, IL-3, interferon-gamma, IL-4, and IL-10. The results from the pulmonary mast cell lines were compared with those from bone marrow derived mast cells. Pulmonary mast cell lines were capable of proliferating in response to IL-3, IL-4, IL-10, and SCF, whereas the combination of SCF with the other cytokines did not increase the response over SCF alone. In contrast, the bone marrow-derived mast cells proliferated strongest to SCF or IL-3, but only modestly to IL-4 and IL-10. Furthermore, the combination of SCF with IL-3, but not the other cytokines, exhibited an increase in bone marrow-derived mast cell proliferation. Cytokine- specific stimulation of histamine release in the airway-derived and bone marrow-derived mast cells showed parallel results. SCF was the only cytokine shown to induce substantial histamine release. However, when certain nonhistamine releasing cytokines were combined with SCF, a synergistic increase in histamine release was induced in upper airway, but not bone marrow-derived mast cells. The results of these studies suggest that cytokines differentially modulate induction of proliferation and degranulation of bone marrow and upper airway-derived mast cells and may further indicate a cytokine activational cascade in tissue mast cells.     

Connective tissue growth factor is expressed in bone marrow stromal cells and promotes interleukin-7-dependent B lymphopoiesis

Hematopoiesis occurs in a complex bone marrow microenvironment in which bone marrow stromal cells provide critical support to the process through direct cell contact and indirectly through the secretion of cytokines and growth factors. We report that connective tissue growth factor (Ctgf, also known as Ccn2) is highly expressed in murine bone marrow stromal cells. In contrast, connective tissue growth factor is barely detectable in unfractionated adult bone marrow cells. While connective tissue growth factor has been implicated in hematopoietic malignancies, and is known to play critical roles in skeletogenesis and regulation of bone marrow stromal cells, its role in hematopoiesis has not been described. Here we demonstrate that the absence of connective tissue growth factor in mice results in impaired hematopoiesis. Using a chimeric fetal liver transplantation model, we show that absence of connective tissue growth factor has an impact on B-cell development, in particular from pro-B to more mature stages, which is linked to a requirement for connective tissue growth factor in bone marrow stromal cells. Using in vitro culture systems, we demonstrate that connective tissue growth factor potentiates B-cell proliferation and promotes pro-B to pre-B differentiation in the presence of interleukin-7. This study provides a better understanding of the functions of connective tissue growth factor within the bone marrow, showing the dual regulatory role of the growth factor in skeletogenesis and in stage-specific B lymphopoiesis.     

Derivation of hepatocytes from bone marrow cells in mice after radiation-induced myeloablation

Following a report of skeletal muscle regeneration from bone marrow cells, we investigated whether hepatocytes could also derive in vivo from bone marrow cells. A cohort of lethally irradiated B6D2F1 female mice received whole bone marrow transplants from age-matched male donors and were sacrificed at days 1, 3, 5, and 7 and months 2, 4, and 6 posttransplantation (n = 3 for each time point). Additionally, 2 archival female mice of the same strain who had previously been recipients of 200 male fluorescence-activated cell sorter (FACS)-sorted CD34(+)lin(-) cells were sacrificed 8 months posttransplantation under the same protocol. Fluorescence in situ hybridization (FISH) for the Y-chromosome was performed on liver tissue. Y-positive hepatocytes, up to 2.2% of total hepatocytes, were identified in 1 animal at 7 days posttransplantation and in all animals sacrificed 2 months or longer posttransplantation. Simultaneous FISH for the Y-chromosome and albumin messenger RNA (mRNA) confirmed male-derived cells were mature hepatocytes. These animals had received lethal doses of irradiation at the time of bone marrow transplantation, but this induced no overt, histologically demonstrable, acute hepatic injury, including inflammation, necrosis, oval cell proliferation, or scarring. We conclude that hepatocytes can derive from bone marrow cells after irradiation in the absence of severe acute injury. Also, the small subpopulation of CD34(+)lin(-) bone marrow cells is capable of such hepatic engraftment.     

Bone marrow stromal cells produce thrombopoietin and stimulate megakaryocyte growth and maturation but suppress proplatelet formation

Production of blood cells is regulated by the interplay of various cytokines and bone marrow stromal cells. Recently, a ligand for the orphan receptor Mpl was identified as thrombopoietin (TPO), which specifically regulates megakaryocyte differentiation, and it was reported to be expressed mainly in liver and kidney. As it was found that thrombopoietin is also produced in bone marrow stromal cells, we studied further the roles of bone marrow stromal cells on megakaryocytopoiesis and platelet formation. The stromal cells stimulated growth and maturation of bone-marrow-derived megakaryocytes in the presence of thrombopoietin, and also supported growth of BaF3 cells expressing exogenous Mpl without thrombopoietin. Thrombopoietin induces drastic morphological change of megakaryocytes in bone marrow cells in vitro, ie, the formation of lengthy beaded cytoplasmic processes (proplatelet formation). However, when the purified megakaryocytes were cocultured with the stromal cells with or without thrombopoietin, most of the megakaryocytes adhered to the stromal cells and remained unchanged, while free megakaryocytes induced proplatelet formation. These observations indicated that the stromal cells in a hematopoietic microenvironment in bone marrow secrete thrombopoietin and stimulate proliferation and maturation of megakaryocytes, but the interaction of megakaryocytes with the stromal cells may suppress proplatelet formation.     

Characterization of the differentiation capacity of rat-derived hepatic stem cells

The liver in an adult rat maintains a balance between cell gain and cell loss. Although normally proliferatively quiescent, hepatocyte loss such as that caused by partial hepatectomy (PH) invokes a rapid regenerative response to restore liver mass. This restoration of moderate cell loss and "wear and tear" renewal is largely achieved by hepatocyte self-replication. Furthermore, hepatocyte transplants in rats, in which a selective pressure for the transplanted cells can be applied, have shown that a certain proportion of hepatocytes can undergo significant clonal expansion, suggesting that hepatocytes themselves are the functional stem cells of the liver. Fetal liver may also harbor bipotential stem cells capable of sustained clonal expansion. More severe liver injury activates a potential stem cell compartment located within the canals of Hering, giving rise to cords of bipotential oval cells that can differentiate into hepatocytes and biliary epithelial cells. Other cell populations with hepatic potential reside in the bone marrow; whether these hematopoietic cells can function as stem cells for the rat liver remains to be confirmed. Pancreatic cells have also been found to have hepatocytic potential.