Hematopoietic mobilization in mice increases the presence of bone marrow-derived hepatocytes via in vivo cell fusion

Current status of stem cell therapy for liver diseases

Liver failure is one of the main causes of death worldwide and is a growing health problem. Since the discovery of stem cell populations capable of differentiating into specialized cell types, including hepatocytes, the possibility of their utilization in the regeneration of the damaged liver has been a focus of intense investigation. A variety of cell types were tested both in vitro and in vivo, but the definition of a more suitable cell preparation for therapeutic use in each type of liver lesions is yet to be determined. Here we review the protocols described for differentiation of stem cells into hepatocytes, the results of cell therapy in animal models of liver diseases, as well as the available data of the clinical trials in patients with advanced chronic liver disease.

Human progenitor cells with high aldehyde dehydrogenase activity efficiently engraft into damaged liver in a novel model

Human cord blood stem cells (hCBSCs) have been reported to generate hepatocyte-like cells and thus hold promise for repairing damaged liver. However, the frequency of hCBSC-derived hepatocytes varies tremendously between different studies, and it is still controversial as to whether hCBSC-derived cells can transdifferentiate into hepatocytes or simply fuse to recipient hepatocytes. We used the beta-glucuronidase-deficient nonobese diabetic/severe combined immunodeficient/mucopolysaccharidosis type VII (NOD/SCID/MPSVII) mouse model for better identification of engrafted cells. We transplanted lineage-depleted human umbilical cord blood-derived cells with high aldehyde dehydrogenase activity (ALDH(hi)Lin(-)) into irradiated NOD/SCID/MPSVII mice followed by carbon tetrachloride administration to induced liver damage. ALDH(hi)Lin(-) cells were efficiently engrafted in the recipient mouse livers and improved recovery of the mice from toxic insult. The percentage of human cells in these livers ranged between 3% and 14.2% using quantitative real-time polymerase chain reaction. Furthermore, human-originated cells expressing liver-specific alpha1-antitrypsin messenger RNA, albumin and hepatocyte nuclear factor 1 protein were detected in the recipient livers. Interestingly, human versus murine centromeric fluorescent in situ hybridization analysis on the liver sections demonstrated that most human cells were not fused to mouse cells. However, the majority of the human originated albumin-expressing cells also carried mouse genetic material, hence were the product of cell fusion.

CONCLUSION

hCBSCs or their progeny may home to the injured liver and release trophic factors that hasten tissue repair, whereas fusion of these cells with hepatocytes may occur rarely and contribute to a lesser extent to liver repair.

Stem cells in liver regeneration, fibrosis and cancer: the good, the bad and the ugly

The worldwide shortage of donor livers to transplant end stage liver disease patients has prompted the search for alternative cell therapies for intractable liver diseases, such as acute liver failure, cirrhosis and hepatocellular carcinoma (HCC). Under normal circumstances the liver undergoes a low rate of hepatocyte 'wear and tear' renewal, but can mount a brisk regenerative response to the acute loss of two-thirds or more of the parenchymal mass. A body of evidence favours placement of a stem cell niche in the periportal regions, although the identity of such stem cells in rodents and man is far from clear. In animal models of liver disease, adopting strategies to provide a selective advantage for transplanted hepatocytes has proved highly effective in repopulating recipient livers, but the poor success of today's hepatocyte transplants can be attributed to the lack of a clinically applicable procedure to force a similar repopulation of the human liver. The activation of bipotential hepatic progenitor cells (HPCs) is clearly vital for survival in many cases of acute liver failure, and the signals that promote such reactions are being elucidated. Bone marrow cells (BMCs) make, at best, a trivial contribution to hepatocyte replacement after damage, but other BMCs contribute to the hepatic collagen-producing cell population, resulting in fibrotic disease; paradoxically, BMC transplantation may help alleviate established fibrotic disease. HCC may have its origins in either hepatocytes or HPCs, and HCCs, like other solid tumours appear to be sustained by a minority population of cancer stem cells.

Cell fusion is a physiological process in mouse liver

A large portion of hepatocytes are polyploid cells, thought to arise through endoduplication followed by aborted cytokinesis. However, several recent reports describing liver cell fusion with exogenously derived bone marrow cells have been published. The exact significance of this finding is unclear, because the adopted protocols involve ablation regimens, damaged livers and artificial injections of adult cells. By creating chimeric mice bearing distinct reporter genes (LacZ and GFP), we show that in an unperturbed setting, hepatocytes carrying both markers can be detected via immunohistochemistry and polymerase chain reaction analysis. To further corroborate these findings with a direct visualization of the chromosome content at the single-cell level, we performed genotype analysis via fluorescence in situ hybridization on XY/XX chimeric mice with a Y chromosome-specific paint and an X chromosome-specific bacterial artificial chromosome clone probes.

CONCLUSION

This technique confirmed the occurrence of cell fusion in adult mouse liver.

IGF-I mediates regeneration of endocrine pancreas by increasing beta cell replication through cell cycle protein modulation in mice

AIMS/HYPOTHESIS

Recovery from diabetes requires restoration of beta cell mass. Igf1 expression in beta cells of transgenic mice regenerates the endocrine pancreas during type 1 diabetes. However, the IGF-I-mediated mechanism(s) restoring beta cell mass are not fully understood. Here, we examined the contribution of pre-existing beta cell proliferation and transdifferentiation of progenitor cells from bone marrow in IGF-I-induced islet regeneration.

METHODS

Streptozotocin (STZ)-treated Igf1-expressing transgenic mice transplanted with green fluorescent protein (GFP)-expressing bone marrow cells were used. Bone marrow cell transdifferentiation and beta cell replication were measured by GFP/insulin and by the antigen identified by monoclonal antibody Ki67/insulin immunostaining of pancreatic sections respectively. Key cell cycle proteins were measured by western blot, quantitative RT-PCR and immunohistochemistry.

RESULTS

Despite elevated IGF-I production, recruitment and differentiation of bone marrow cells to beta cells was not increased either in healthy or STZ-treated transgenic mice. In contrast, after STZ treatment, IGF-I overproduction decreased beta cell apoptosis and increased beta cell replication by modulating key cell cycle proteins. Decreased nuclear levels of cyclin-dependent kinase inhibitor 1B (p27) and increased nuclear localisation of cyclin-dependent kinase (CDK)-4 were consistent with increased beta cell proliferation. However, islet expression of cyclin D1 increased only after STZ treatment. In contrast, higher levels of cyclin-dependent kinase inhibitor 1A (p21) were detected in islets from non-STZ-treated transgenic mice.

CONCLUSIONS/INTERPRETATION

These findings indicate that IGF-I modulates cell cycle proteins and increases replication of pre-existing beta cells after damage. Therefore, our study suggests that local production of IGF-I may be a safe approach to regenerate endocrine pancreas to reverse diabetes.

Hepatic injury and the kinetics of bone marrow-derived hepatocyte transgene expression

BACKGROUND

Numerous congenital and acquired liver diseases could benefit from a successful hepatic cell therapy strategy. Hepatotypic cells derived from bone marrow have been recognized during liver injury, repair, and regeneration. To study this phenomenon, we compared the effect of several modes of experimental hepatic injury on hepatotypic protein expression in a mouse model after bone marrow transplantation.

METHODS

Male mice transgenic for the liver-specific protein human alpha-1 antitrypsin (hAAT) were used as bone marrow donors. Syngeneic wild-type recipient mice were subjected to 1 of 3 hepatic injuries: (1) sublethal irradiation, (2) injection of a hepatotoxic adenoviral construct, and (3) administration of a hepatotoxic diet. Bone marrow-derived hepatotypic (BMdH) transgene expression was determined by serial serum enzyme-linked immunosorbent assay for hAAT.

RESULTS

In both acute injury models, hAAT expression was detected as early as 1 week, whereas the control group never elicited hAAT expression. The adenovirus-treated group demonstrated transient hAAT level expression lasting up to 2 weeks postinjury, whereas the irradiated group maintained persistent hAAT expression through 4 months. In the chronic injury (hepatotoxin) model, hAAT expression persisted and was noted to increase over time to 200 to 300 ng/mL.

CONCLUSIONS

Irradiation favors long-term establishment of BMdH transgene expression, and chronic injury further promotes this phenomenon.

Critical review of clinical trials of bone marrow stem cells in liver disease

Morbidity and mortality from cirrhosis is increasing rapidly in the Western world. Currently the only effective treatment is liver transplantation, an increasingly limited and expensive resource. Consequently, there has been great hope that stem cells may offer new therapeutic approaches in the management of liver disease. In this review we critically appraise the 11 published clinical studies of bone marrow stem cells in liver disease, and focus on the unresolved issues regarding their role. We outline the different mechanisms by which stem cells may impact on liver disease, as well as highlight the importance of the type of stem cell chosen. There are multiple different stem cell populations that have, in rodent studies, been shown to have differing effects on liver regeneration and fibrogenesis/degradation. Thus, choice of cell should reflect the desired or expected mechanism of action. The importance, and methods, of studying the fate of stem cells infused in clinical studies is emphasized as we seek to translate observations in rodents into the clinical setting. Finally, we discuss which cohorts of patients with liver disease would benefit from stem cell therapy, as well as establish minimum criteria for future clinical trials of stem cells.

Stem cell-based therapy in gastroenterology and hepatology

Protagonists of a new scientific era, stem cells are promising tools on which regenerative medicine relies for the treatment of human pathologies. Stem cells can be obtained from various sources, including embryos, fetal tissues, umbilical cord blood, and also terminally differentiated organs. Once forced to expand and differentiate into functional progenies, stem cells may become suitable for cell replacement and tissue engineering. The manipulation and/or stimulation of adult stem cells seems to be particularly promising, as it could improve the endogenous regenerative potential without risks of rejection and overcome the ethical and political issues related to embryonic stem cell research. Stem cells are already leaving the bench and reaching the bedside, despite an incomplete knowledge of the genetic control program driving their fate and plasticity. In gastroenterology and hepatology, the first attempts to translate stem cell basic research into novel therapeutic strategies have been made for the treatment of several disorders, such as inflammatory bowel diseases, diabetes mellitus, celiachy and acute or chronic hepatopaties. Nonetheless, critical aspects need to be further addressed, including the long-term safety, tolerability and efficacy of cell-based treatments, as well as their carcinogenic potential. Aim of this review is to summarize the state-of-the-arts on gastrointestinal and hepatic stem cells and on stem cell-based therapies in gastroenterology and hepatology, highlighting both the benefits and the potential risks of these new tools for the treatment and prevention of human diseases.

Widespread nonhematopoietic tissue distribution by transplanted human progenitor cells with high aldehyde dehydrogenase activity

Transplanted adult progenitor cells distribute to peripheral organs and can promote endogenous cellular repair in damaged tissues. However, development of cell-based regenerative therapies has been hindered by the lack of preclinical models to efficiently assess multiple organ distribution and difficulty defining human cells with regenerative function. After transplantation into beta-glucuronidase (GUSB)-deficient NOD/SCID/mucopolysaccharidosis type VII mice, we characterized the distribution of lineage-depleted human umbilical cord blood-derived cells purified by selection using high aldehyde dehydrogenase (ALDH) activity with CD133 coexpression. ALDH(hi) or ALDH(hi)CD133+ cells produced robust hematopoietic reconstitution and variable levels of tissue distribution in multiple organs. GUSB+ donor cells that coexpressed human leukocyte antigen (HLA-A,B,C) and hematopoietic (CD45+) cell surface markers were the primary cell phenotype found adjacent to the vascular beds of several tissues, including islet and ductal regions of mouse pancreata. In contrast, variable phenotypes were detected in the chimeric liver, with HLA+/CD45+ cells demonstrating robust GUSB expression adjacent to blood vessels and CD45-/HLA- cells with diluted GUSB expression predominant in the liver parenchyma. However, true nonhematopoietic human (HLA+/CD45-) cells were rarely detected in other peripheral tissues, suggesting that these GUSB+/HLA-/CD45- cells in the liver were a result of downregulated human surface marker expression in vivo, not widespread seeding of nonhematopoietic cells. However, relying solely on continued expression of cell surface markers, as used in traditional xenotransplantation models, may underestimate true tissue distribution. ALDH-expressing progenitor cells demonstrated widespread and tissue-specific distribution of variable cellular phenotypes, indicating that these adult progenitor cells should be explored in transplantation models of tissue damage.

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.

Intra-portal transplantation of bone marrow stromal cells ameliorates liver fibrosis in mice

AIM: To investigate the effect of transplanted bone marrow stromal cells (BMSCs) on liver fibrosis in mice.

METHODS: BMSCs harvested from male BALB/c mice were cultured and transplanted into female syngenic BALB/c mice via portal vein. After partial hepatectomy, liver fibrosis was induced by diethylnitrosamine (DEN). Controls received BMSCs and non-supplemented drinking water, model group received DEN-spiked water, and experimental group received BMSCs and DEN. The mice were killed after three months. Alanine aminotransferase (ALT), aspartate aminotransferase (AST), hyaluronic acid (HA) and laminin (LN) in serum, hydroxyproline (Hyp) content in liver were assessed. Alpha-smooth muscle actin (α-SMA) in liver was tested by immunohistochemistry. Bone marrow-derived hepatocytes in liver sections were identified by fluorescent in situ hybridization (FISH).

RESULTS: BMSCs differentiated into hepatocyte-like phenotypes after hepatocyte growth factor (HGF) treatment in vitro. Serum ALT, AST, HA and LN were markedly reduced by transplanted BMSCs(208 ± 44 U/L vs 341 ± 66 U/L, 372 ± 84 U/L vs 506 ± 81 U/L, 289 ± 74 μg/L vs 362 ± 83 μg/L, 178 ± 48 μg/L vs 232 ± 63 μg/L). Liver Hyp level (900 ± 141 mg/g vs 1255 ± 205 mg/g) and α-SMA staining in mice receiving BMSCs were lower than those in the model group, consistent with the altered liver pathology. FISH analysis revealed the presence of donor-derived hepatocytes in the injured liver after cross-gender mouse BMSCs transplantation. About 10% of cells were bone marrow-derived cells in the injured liver after three months.

CONCLUSION: BMSCs transplanted via portal vein can convert into hepatocytes with replacement of the DEN-induced liver injury, restore liver function and reduce liver fibrosis.

Stem cells in liver regeneration and therapy

The liver has adapted to the inflow of ingested toxins by the evolutionary development of unique regenerative properties and responds to injury or tissue loss by the rapid division of mature cells. Proliferation of the parenchymal cells, i.e. hepatocytes and epithelial cells of the bile duct, is regulated by numerous cytokine/growth-factor-mediated pathways and is synchronised with extracellular matrix degradation and restoration of the vasculature. Resident hepatic stem/progenitor cells have also been identified in small numbers in normal liver and implicated in liver tissue repair. Their putative role in the physiology, pathophysiology and therapy of the liver, however, is not yet precisely known. Hepatic stem/progenitor cells also known as "oval cells" in rodents have been implicated in liver tissue repair, at a time when the capacity for hepatocyte and bile duct replication is exhausted or experimentally inhibited (facultative stem/progenitor cell pool). Although much more has to be learned about the role of stem/progenitor cells in the physiology and pathophysiology of the liver, experimental analysis of the therapeutic value of these cells has been initiated. Transplantation of hepatic stem/progenitor cells or in vivo pharmacological activation of the pool of hepatic stem cells may provide novel modalities for the therapy of liver diseases. In addition, extrahepatic stem cells (e.g. bone marrow cells) are being investigated for their contribution to liver regeneration. Hepatic progenitor cells derived from embryonic stem cells are included in this review, which also discusses future perspectives of stem cell-based therapies for liver diseases.

Application of liver stem cells for cell therapy

The worldwide shortage of donor livers to transplant end stage liver disease patients has prompted the search for alternative cell therapies for intractable liver disease. Embryonic stem cells can be readily differentiated into hepatocytes, and their transplantation into animals has improved liver function in the absence of teratoma formation: their use in bioartificial liver support is an obvious application. In animal models of liver disease, adopting strategies to provide a selective advantage for transplanted foetal or adult hepatocytes have proved highly effective in repopulating recipient livers, but the poor success of today's hepatocyte transplants can be attributed to the lack of a clinically applicable procedure to force a similar repopulation of the human liver. The activation of bipotential hepatic progenitor cells is clearly vital for survival in many cases of acute liver failure, but surprisingly little progress has been made with these cells in terms of transplantation. Finally there is the controversial subject of autologous bone marrow, and while the contribution of these indigenous cells to liver turnover seems at best, trivial, results from a small number of phase 1 studies of transplantation of bone marrow to cirrhotic patients have been moderately encouraging.

Effects of granulocyte colony stimulating-factor in a rat model of acute liver injury

BACKGROUND/AIM

Controversial experimental observations suggest that granulocyte colony stimulating-factor may promote hepatic regeneration after hepatectomy and chemical injury either by directly stimulating adult liver cells or facilitating the mobilization of bone marrow cells and their homing to the liver. We investigated whether different schedules of granulocyte colony stimulating-factor administration protect against experimental acute liver injury.

METHODS

Acute liver injury was induced in Sprague-Dawley fed rats by injecting a single intraperitoneal dose of carbon tetrachloride. Recombinant human granulocyte colony stimulating-factor or vehicle was given daily after intoxication (4 days) or before (7 days) and after carbon tetrachloride administration. Liver injury and regeneration were assessed 2 and 4 days after damage. Bone marrow cells mobilization was evaluated by the white blood cell count and the assessment of circulating clonogenic haematopoietic progenitors (colony forming unit-cells).

RESULTS

In this experimental model, although granulocyte colony stimulating-factor induced the significant mobilization of colony forming unit-cells, the study cytokine had no effect on liver injury (serum alanine amino transaminase level and necrotic index) and liver regeneration (mitotic index and bromodeoxyuridine incorporation), regardless of the administration schedule.

CONCLUSIONS

This study does not support the conclusion that: (1) granulocyte colony stimulating-factor exerts a protective effect against toxic-induced, non-lethal acute liver injury and (2) promotes hepatocyte regeneration.

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.

Characterization of the Potential Subpopulation of Bone Marrow Cells Involved in the Repair of Injured Liver Tissue

In vitro and in vivo studies have shown that bone marrow (BM) stem cells can differentiate into hepatocytes. However, it is not known whether such a differentiation event occurs during normal liver regeneration process. We investigated the role of endogenous BM cells in liver regeneration following acute injury and phenotypically characterized them. We showed that Lin(-)Sca-1(+) cells proliferate in the BM and subsequently mobilize in the peripheral blood in response to liver injury by CCl(4) or an injury simulating condition. In vitro studies confirmed that the damaged liver tissue was capable of inducing migration of a distinct population of BM cells, phenotypically characterized as Lin(-)CXCR4(+)OSMRbeta(+), which can differentiate into albumin and cytoketarin-18 expressing cells. In order to study the migration of BM cells to the regenerating liver, the hematopoietic system was reconstituted with green fluorescent protein (GFP)(+) BM cells by intra-bone marrow transplantation prior to liver damage. The BM-derived cells were found to express hepatocyte-specific genes and proteins in the regenerating liver. Quantitative polymerase chain reaction analysis for a recipient specific gene (sry) in sorted GFP(+)Alb(+) donor cells suggested that fusion was a rare event in this experimental model. In conclusion, we first demonstrated the potential phenotype of BM cells involved in regeneration of liver from acute injury, primarily by the process of direct differentiation. Disclosure of potential conflicts of interest is found at the end of this article.

The fate of recipient-derived hepatocytes in sex-mismatched liver allograft following liver transplantation

BACKGROUND

''Bone marrow-derived stem cells'' have attracted great attention as potential candidates for liver-directed gene therapy and as a tool for regenerative medicine. However, the fate of these cells is not well-known. The aim of this present study was to investigate the fate of ''recipient-derived repopulated hepatocytes'' in sex-mismatched liver allografts in individuals following liver transplantation during systematic longitudinally performed liver biopsies.

METHODS

Paraffin-embedded sex-mismatched liver biopsy samples of nine recipients (male/female ratio 5/4; mean age: 39.7 yr) were reviewed. Double labeling with immunohistochemistry for hepatocytes and recipient-specific bone marrow-derived cells and fluorescence in-situ hybridization for visualizing X and Y chromosomes were performed. These slides were examined systematically using an image analyzer system (Olympus microscope; Cyto-Vision, Applied Imaging, Biosciences Centre, Newcastle, UK). Only cells with two nuclear spots were considered for interpretation.

RESULTS

The mean times from transplantation to first biopsy and between the first and the second biopsies were 5.9 and 20.9 months respectively. The proportion of recipient-derived repopulated hepatocytes was significantly decreased in the late biopsies when compared with the early biopsies (p = 0.001). All nine samples of the first biopsies had demonstrated recipient-derived hepatocyte repopulation, with a mean of 2.0%, whereas only seven of nine samples of the second biopsies had demonstrated recipient-derived hepatocyte repopulation with a low mean of 0.5% (p = 0.001).

CONCLUSION

Based on these results, we suggest that ''recipient-specific bone marrow-derived hepatocyte repopulation'' in liver allograft during tissue injury is a relatively early event.

Association of stem cells and cancer stem cells with tumorigenesis

The research on cancer stem cells is a new hot spot in at present. The hypothesis indicates cancer stem cells, which were possibly the origin of the cancer, come from normal stem cells. For their special characters, normal stem cells can differentiate into tumor cells more easily than adult cells. Stem cells transform into malignant cancer stem cells possibly because of gene mutation, abnormal asymmetry and cell fusion. It is a main method to obtain cancer stem cells by flow cytometer using different protein markers and fluorescent probes. It is demonstrated that cancer stem cells are very powerful in self-renewal, proliferation, and differentiation. Targeting on cancer stem cells, early diagnosis for cancers might be achieved.

Bone marrow fails to differentiate into liver epithelium during murine development and regeneration

Recent reports have provided conflicting conclusions regarding the role for bone marrow (BM)-derived cells in the regeneration of liver. Our aim was to investigate the potential of BM to contribute to liver epithelium using different BM transplant models designed to explore differentiation during normal liver development and regeneration after toxic injury. BM cells from transgenic green fluorescent protein (GFP) mice were injected into neonatal and adult immunodeficient and neonatal immune-competent mice. Three distinct models of liver injury were employed to test the contribution of marrow to the regeneration of hepatocytes, cholangiocytes, and oval cells in immune-deficient adult animals after neonatal transplant. Immunohistochemistry was combined with flow cytometry (FACS) and reverse transcription (RT)-PCR to increase the sensitivity and specificity of the analyses. Although GFP+ marrow-derived cells were observed in the livers of all transplanted animals, immunohistochemistry failed to demonstrate any marrow derived hepatocytes or cholangiocytes. FACS confirmed that GFP+ marrow-derived cells in the liver maintained expression of CD45, a leukocyte marker. Gene expression studies of GFP+ cells isolated by FACS failed to demonstrate expression of liver specific genes in these marrow-derived cells.

CONCLUSION

Through highly sensitive and specific analyses, we were unable to demonstrate any evidence of transdifferentiation of BM-derived cells into epithelial hepatic tissue during the period of rapid growth in the neonatal period. Furthermore, although increased migration of hematopoietic cells to the liver occurred after toxic injury, these cells did not contribute directly to the replacement of hepatocytes, cholangiocytes, or oval cells.

The role of stem cells in physiology, pathophysiology, and therapy of the liver

The objectives of the present review is to update readers with the rapidly changing concepts in liver stem cell biology and related clinical applications. The liver has adapted to the inflow of ingested toxins by the evolutionary development of unique regenerative properties and responds to injury or tissue loss by rapid division of the mature cells, hepatocytes, and bile duct epithelial cells. Proliferation of the parenchymal cells is regulated by numerous cytokine/growth factor-mediated pathways and is timely synchronized with extracellular matrix degradation and the restoration of the vasculature. The putative role of stem cells in physiology, pathophysiology, and therapy is not yet precisely known but currently is under intensive investigation. Resident hepatic stem/ progenitor cells have been identified in small numbers and implicated in liver tissue repair, when hepatocyte and bile duct replication capacity is exhausted or experimentally inhibited. Several independent reports have suggested that bone marrow cells can give rise to different hepatic epithelial cells types, including hepatic stem cells, hepatocytes, and bile duct epithelium. These observations have resulted in the hypothesis that extrahepatic stem cells, specifically bone marrow-derived stem cells, are an important source for liver epithelial cell replacement, particularly during chronic injury. Most of published data, however, now suggest that they do not play a relevant role in replacement of epithelial cells in any known form of hepatic injury. In vitro differentiation protocols for various adult extrahepatic stem cells might eventually provide valuable sources of cells for transplantation and therapy. Amniotic epithelial stem cells, fetal liver progenitor cells as well as embryonic stem cells currently emerge as alternative stem cell sources and open new possibilities for cellular therapies of liver disease.

Feasibility and safety of autologous bone marrow mononuclear cell transplantation in patients with advanced chronic liver disease

AIM: To evaluate the safety and feasibility of bone marrow cell (BMC) transplantation in patients with chronic liver disease on the waiting list for liver transplantation.

METHODS: Ten patients (eight males) with chronic liver disease were enrolled to receive infusion of autologous bone marrow-derived cells. Seven patients were classified as Child-Pugh B and three as Child-Pugh C. Baseline assessment included complete clinical and laboratory evaluation and abdominal MRI. Approximately 50 mL of bone marrow aspirate was prepared by centrifugation in a ficoll-hypaque gradient. At least of 100 millions of mononuclear-enriched BMCs were infused into the hepatic artery using the routine technique for arterial chemoembolization for liver tumors. Patients were followed up for adverse events up to 4 mo.

RESULTS: The median age of the patients was 52 years (range 24-70 years). All patients were discharged 48 h after BMC infusion. Two patients complained of mild pain at the bone marrow needle puncture site. No other complications or specific side effects related to the procedure were observed. Bilirubin levels were lower at 1 (2.19 ± 0.9) and 4 mo (2.10 ± 1.0) after cell transplantation that baseline levels (2.78 ± 1.2). Albumin levels 4 mo after BMC infusion (3.73 ± 0.5) were higher than baseline levels (3.47 ± 0.5). International normalized ratio (INR) decreased from 1.48 (SD = 0.23) to 1.43 (SD = 0.23) one month after cell transplantation.

CONCLUSION: BMC infusion into hepatic artery of patients with advanced chronic liver disease is safe and feasible. In addition, a decrease in mean serum bilirubin and INR levels and an increase in albumin levels are observed. Our data warrant further studies in order to evaluate the effect of BMC transplantation in patients with advanced chronic liver disease.

Molecular Mechanism of Liver Development and Regeneration

The liver is the central organ for metabolism and has strong regenerative capability. Although the liver has been studied mostly biochemically and histopathologically, genetic studies using gene-targeting technology have identified a number of cytokines, intracellular signaling molecules, and transcription factors involved in liver development and regeneration. In addition, various in vitro systems such as fetal liver explant culture and primary culture of fetal liver cells have been established, and the combination of genetic and in vitro studies has accelerated investigation of liver development. Identification of the cell-surface molecules of liver progenitors has made it possible to identify and isolate liver progenitors, making the liver a unique model for stem cell biology. In this review, we summarize progresses in understanding liver development and regeneration.

Bone marrow-derived fibrocytes participate in pathogenesis of liver fibrosis

BACKGROUND/AIMS

Hepatic stellate cells (HSCs) play a key role in hepatic fibrogenesis. However, their origin is still unknown. We tested the hypothesis that bone marrow (BM) contributes to the population of HSCs.

METHODS

Chimeric mice transplanted with donor BM from collagen alpha1(I)-GFP+ reporter mice were subjected to the bile duct ligation (BDL)-induced liver injury.

RESULTS

In response to injury, BM-derived collagen-expressing GFP+ cells were detected in liver tissues of chimeric mice. However, these cells were not activated HSCs in that they did not express alpha-smooth muscle actin or desmin and could not be isolated with the HSC fraction. Meanwhile, the majority of these BM-derived cells co-expressed collagen-GFP+ and CD45+, suggesting that these cells represent a unique population of fibrocytes. Consistent with their lymphoid origin, the number of GFP+CD45+ fibrocytes found in BM and spleen of chimeric mice increased in response to injury. Fibrocytes cultured in the presence of TGF-beta1 differentiated into SMA+desmin+ collagen-producing myofibroblasts, potentially contributing to liver fibrosis.

CONCLUSIONS

In response to the BDL-induced liver injury: (i) HSCs do not originate in the BM; (ii) collagen-producing fibrocytes are recruited from the BM to damaged liver.

Hepatic Stem Cells: In Search of

The field of stem cell biology has exploded with the study of a wide range of cellular populations involving endodermal, mesenchymal, and ectodermal organs. One area of extensive study has included the identification of hepatic stem and progenitor cell subpopulations. Liver stem cells provide insights into the potential pathways involving liver regeneration that are independent of mature hepatocytes. Hepatic progenitor cells are either bipotent or multipotent and capable of multiple rounds of replication. They have been identified in fetal as well as adult liver. Various injury models have been used to expand this cellular compartment. The nomenclature, origin, and function of the hepatic progenitor cell populations are areas of ongoing debate. In this review, we will discuss the different definitions and functions of hepatic progenitor cells as well as the current research efforts examining their therapeutic potential.

In vivo expression of hepatocyte growth factor promotes differentiation of stem cells from umbilical cord blood into hepatocyte-like cells

AIM: To observe the hepatocyte growth factor-induced differentiation of CD34⁺ hematopoietic stem cells (HSC) from umbilical cord blood into hepatocyte-like cells.

METHODS: Systemic administration of naked plasmid containing HGF cDNA driven under cytomegalovirus promoter (pCMV-HGF) were injected rapidly via the tail vein of the NOD/SCID mice, and the level of HGF protein in the peripheral blood was detected by enzyme-linked immunosorbent assay. CD34⁺ human hematopoietic stem cells were isolated from umbilical cord blood by magnetic cell sorting method. 20 μL CCl₄ was administered into the mice to establish the model of acute liver damage and hepatocyte proliferation. pCMV-HGF injection and/or CD34⁺ human hematopoietic stem cells transplantation were performed on the model mice. Then the mortality of the mice and liver function recovery status were observed. Human specific mRNA and protein were also detected in the mice by reverse transcription polymerase chain reaction and immunohistochemistry, respectively (RT-PCR).

RESULTS: A remarkable enhancement of human HGF protein level was observed in the peripheral blood of the mice. The mortality and status of liver function were not significantly different between each experiment group. Path-ological examination showed that the mice received combined treatment HGF and HSC had the lightest liver injury, while the liver injury was not markedly different between the mice received HGF and HSC alone. Human albumin mRNA and protein were all expressed in the liver tissues underwent HSC transplantation with or without HGF, while in the mice with HGF injection, there were much more hepatocyte-like cells.

CONCLUSION: Stem cells from umbilical cord blood can differentiate into hepatocyte-like cells, and HGF can promote this process.

The fatty acid constitution and ordering state of membranes in dominant temperature-sensitive lethal mutation and wild-type Drosophila melanogaster larvae

The ordering state and changes in fatty acid composition of microsomal (MS) and mitochondrial (MC) membranes of two dominant temperature-sensitive (DTS) lethal mutations and the wild-type Oregon-R strain larvae of Drosophila melanogaster have been studied at 18 and 29 degrees C and after temperature-shift experiments. The membranes of wild-type larvae have a stable ordering state, with "S" values between 0.6 (18 degrees C) and 0.5 (29 degrees C) in both membranes which remained unchanged in shift experiments, although the ratios of saturated/unsaturated fatty acids were changed as expected. The strongly DTS mutation 1(2) 10DTS forms very rigid membranes at the restrictive temperature (29 degrees C) which cannot be normalized after shift down, while shift up or development at the permissive temperature results in normal ordering state. This mutant is less able to adjust MS and MC fatty acid composition in response to the growth temperature than the wild type. The less temperature-sensitive 1(2)2DTS allele occupies an intermediate state between Oregon-R and 1(2)10DTS in both respects. We assume and the genetical data suggest that the DTS mutant gene product is in competition with the wild-type product, resulting in a membrane structure which is not able to accommodate to the restrictive temperature.