Calcium signals induce liver stem cells to acquire a cardiac phenotype.

Heart failure is a major cause of premature death and disability in the United States. Stem cell therapy has attracted great interest for the treatment of myocardial infarction and heart failure. Some tissue-specific adult-derived stem cells demonstrate plasticity in that they are multipotent, react to inductive signals provided by a new micro-environment, and acquire the phenotype of cells endogenous to the new micro-environment. The mechanism through which this phenotype is acquired is unknown. We have demonstrated that a liver-derived clonal stem cell line, WB F344, differentiate into cardiomyocytes in vivo and in vitro. Using a coculture model of neonatal heart cells and WB F344 cells, we have found that cytosolic communication between the two cell types results in calcium-induced transcription of cardiac transcription factors and appears to usher in the cardiac phenotype. Functional gap junctions and IP3 receptors appear to be required for this process. We propose that the observed low frequency of stem cell differentiation into cardiomyocytes when transplanted into the injured heart is due, in part, to their inability to establish functioning intercellular communications with healthy cardiomyocytes and receive instructive signals needed to activate a cardiac gene program.

Mechanisms controlling the acquisition of a cardiac phenotype by liver stem cells.

The mechanisms underlying stem cell acquisition of a cardiac phenotype are unresolved. We studied early events during the acquisition of a cardiac phenotype by a cloned adult liver stem cell line (WB F344) in a cardiac microenvironment. WB F344 cells express a priori the transcription factors GATA4 and SRF, connexin 43 in the cell membrane, and myoinositol 1,4,5-triphosphate receptor in the perinuclear region. Functional cell-cell communication developed between WB F344 cells and adjacent cocultured cardiomyocytes in 24 h. De novo cytoplasmic [Ca(2+)](c) and nuclear [Ca(2+)](nu) oscillations appeared in WB F344 cells, synchronous with [Ca(2+)](i) transients in adjacent cardiomyocytes. The [Ca(2+)] oscillations in the WB F344 cells, but not those in the cardiomyocytes, were eliminated by a gap junction uncoupler and reappeared with its removal. By 24 h, WB F344 cells began expressing the cardiac transcription factors Nkx2.5, Tbx5, and cofactor myocardin; cardiac proteins 24 h later; and a sarcomeric pattern 4-6 days later. Myoinositol 1,4,5-triphosphate receptor inhibition suppressed WB F344 cell [Ca(2+)](nu) oscillations but not [Ca(2+)](c) oscillations, and L-type calcium channel inhibition eliminated [Ca(2+)] oscillations in cardiomyocytes and WB F344 cells. The use of these inhibitors was associated with a decrease in Nkx2.5, Tbx5, and myocardin expression in the WB F344 cells. Our findings suggest that signals from cardiomyocytes diffuse through shared channels, inducing [Ca(2+)] oscillations in the WB F344 cells. We hypothesize that the WB F344 cell [Ca(2+)](nu) oscillations activate the expression of a cardiac specifying gene program, ushering in a cardiac phenotype.

Functional genomics of hepatocellular carcinoma.

The majority of DNA-microarray based gene expression profiling studies on human hepatocellular carcinoma (HCC) has focused on identifying genes associated with clinicopathological features of HCC patients. Although notable success has been achieved, this approach still faces significant challenges due to the heterogeneous nature of HCC (and other cancers) as well as the many confounding factors embedded in gene expression profile data. However, these limitations are being overcome by improved bioinformatics and sophisticated analyses. Also, application of cross comparison of multiple gene expression data sets from human tumors and animal models are facilitating the identification of critical regulatory modules in the expression profiles. The success of this new experimental approach, comparative functional genomics, suggests that integration of independent data sets will enhance our ability to identify key regulatory elements in tumor development. Furthermore, integrating gene expression profiles with data from DNA sequence information in promoters, array-based CGH, and expression of non-coding genes (i.e., microRNAs) will further increase the reliability and significance of the biological and clinical inferences drawn from the data. The pace of current progress in the cancer profiling field, combined with the advances in high-throughput technologies in genomics and proteomics, as well as in bioinformatics, promises to yield unprecedented biological insights from the integrative (or systems) analysis of the combined cancer genomics database. The predicted beneficial impact of this "new integrative biology" on diagnosis, treatment and prevention of liver cancer and indeed cancer in general is enormous.

Hematopoietic cells as hepatocyte stem cells: a critical review of the evidence.

The authors reviewed 77 published reports available before August 1, 2005 that examined the ability of hematopoietic cells to generate hepatocytes in the liver. A list of these publications and a synopsis of each are available on-line. We interpret the evidence provided by this data set to suggest that one or more types of hematopoietic cells may rarely acquire the hepatocyte phenotype in the liver (frequency < or =10(-4)), although the nature of the hematopoietic cells involved and the mechanisms responsible for acquisition of a hepatocyte phenotype are still controversial. Hematopoietic stem cells do not appear to be direct precursors of hepatocytes, which, instead, can be generated from cells of the macrophage-monocyte lineage. Fusion between hepatocytes and transplanted hematopoietic cells has been substantiated as a mechanism by which hepatocytes that carry a bone marrow tag are generated, but direct transdifferentiation of hematopoietic cells has not been demonstrated. In conclusion, hematopoietic cells contribute little to hepatocyte formation under either physiological or pathological conditions, although they may provide cytokines and growth factors that promote hepatocyte functions by paracrine mechanisms. Cells of the endodermal hepatocyte lineage are far more potent generators of hepatocytes than are hematopoietic cells.

Acquired cell-to-cell coupling and "cardiac-like" calcium oscillations in adult stem cells in a cardiomyocyte microenvironment.

Adult-derived stem cells have recently been found to respond in vivo to inductive signals from the microenvironment and to differentiate into a phenotype that is characteristic of cells in that microenvironment. We examined the differentiation potential of an adult liver stem cell line (WBF344) in a cardiac microenvironment in vitro. WBF344 cells were established from a single cloned non-parenchymal epithelial cell isolated from a normal male adult rat liver. Genetically modified, WBF344 cells that express beta-galactosidase, green fluorescent protein (GFP) or mitochondrial red fluorescent protein (DsRed) were co-cultured with rat neonatal cardiac cells. After 4-14 days, we identified WBF344-derived cardiomyocytes that were elongated, binucleated and expressed the cardiac specific proteins cardiac troponin T, cardiac troponin I and N cadherin. These WBF344-derived cardiomyocytes also exhibited myofibrils, sarcomeres, and a nascent sarcoplasmic reticulum. Furthermore, rhythmically beating WBF344-derived cardiomyocytes displayed "cardiac-like" calcium transients similar to the surrounding neonatal cardiomyocytes. Fluorescent recovery after photobleaching demonstrated that WBF344-derived cardiomyocytes were electrically coupled with adjacent neonatal cardiomyocytes through gap junctions (GJs). Collectively, these results support the conclusion that these adult-derived liver stem cells respond to signals generated in a cardiac microenvironment in vitro acquiring a cardiomyocyte phenotype and function. The identification of micro-environmental signals that appear to cross germ layer and species specificities should prove valuable in understanding the regulation of normal development and stem cell differentiation in vivo.

Comparative functional genomics for identifying models of human cancer.

Genetically modified mice with overexpressed and/or deleted genes have been used extensively to model human cancer. However, it is uncertain as to what extent the mouse models reproduce the corresponding cancers in humans. We have compared the global gene expression patterns in human and mouse hepatocellular carcinomas (HCCs) in an attempt to identify the mouse models that most extensively reproduce the molecular pathways in the human tumors. The comparative analysis of the gene expression patterns in murine and human HCC indicates that certain genetic mouse models closely reproduce the gene expression patterns of HCC in humans, while others do not. Identification of mouse models that reproduce the molecular features of specific human cancers (or subclasses of specific human cancers) promises to accelerate both the understanding of the molecular pathogenesis of cancer and the discovery of therapeutic targets. We propose that this method, comparative functional genomics, could be effectively applied to the analysis of mouse models for other human cancers.

Adult-derived liver stem cells acquire a cardiomyocyte structural and functional phenotype ex vivo.

We examined the differentiation potential of an adult liver stem cell line (WB F344) in a cardiac microenvironment, ex vivo. WB F344 cells were established from a single cloned nonparenchymal epithelial cell isolated from a normal male adult rat liver. Genetically modified, WB F344 cells that express beta-galactosidase and green fluorescent protein or only beta-galactosidase were co-cultured with dissociated rat or mouse neonatal cardiac cells. After 4 to 14 days, WB F344-derived cardiomyocytes expressed cardiac-specific proteins and exhibited myofibrils, sarcomeres, and a nascent sarcoplasmic reticulum. Further, rhythmically beating WB F344-derived cardiomyocytes displayed calcium transients. Fluorescent recovery after photobleaching demonstrated that WB F344-derived cardiomyocytes were coupled with adjacent neonatal cardiomyocytes and other WB F344-derived cardiomyocytes. Fluorescence in situ hybridization experiments suggested that fusion between WB F344 cells and neonatal mouse cardiomyocytes did not take place. Collectively, these results support the conclusion that these adult-derived liver stem cells respond to signals generated in a cardiac microenvironment ex vivo acquiring a cardiomyocyte phenotype and function. The identification ex vivo of microenvironmental signals that appear to cross germ layer and species specificities should prove valuable in understanding the molecular basis of adult stem cell differentiation and phenotypic plasticity.

Overview of recent experimental studies on liver stem cells.

Since our review of the experimental evidence for liver epithelial stem cells in 1997, a large body of new data has been added. The new studies have focused on the analysis of differentiation of candidate liver stem cells when they are transplanted into the liver in vivo and when cultured in vitro under defined conditions. The new studies that we review substantiate the existence of stem cells that can generate new lineages of hepatocytes and cholangiocytes, especially in severely damaged livers. However, the recent studies have introduced new areas of controversy about the essential nature of liver stem cells and about appropriate methods to analyze their properties and functions. Whether the major stem cell for hepatocytes and cholangiocytes is an endodermal epithelial cell that resides in the liver or a mesodermal cell from bone marrow is a current area of controversy. Another controversial topic concerns the appropriateness of cell culture to analyze liver epithelial cells. Both of these situations are addressed, if not yet conclusively solved, by the new data. From our review of recent data, we conclude that the major liver stem cell is an epithelial cell that is a liver resident, and that cell culture is a valuable, even necessary, adjunct for analyzing the properties of liver stem cells and for eventually identifying the molecular mechanisms that regulate their activation, proliferation, and differentiation.

Molecular pathogenesis of human hepatocellular carcinoma.

Hepatocarcinogenesis is a slow process during which genomic changes progressively alter the hepatocellular phenotype to produce cellular intermediates that evolve into hepatocellular carcinoma. During the long preneoplastic stage, in which the liver is often the site of chronic hepatitis, cirrhosis, or both, hepatocyte cycling is accelerated by upregulation of mitogenic pathways, in part through epigenetic mechanisms. This leads to the production of monoclonal populations of aberrant and dysplastic hepatocytes that have telomere erosion and telomerase re-expression, sometimes microsatellite instability, and occasionally structural aberrations in genes and chromosomes. Development of dysplastic hepatocytes in foci and nodules and emergence of hepatocellular carcinoma are associated with the accumulation of irreversible structural alterations in genes and chromosomes, but the genomic basis of the malignant phenotype is heterogeneous. The malignant hepatocyte phenotype may be produced by the disruption of a number of genes that function in different regulatory pathways, producing several molecular variants of hepatocellular carcinoma. New strategies should enable these variants to be characterized.

Isolation, short-term culture, and transplantation of small hepatocyte-like progenitor cells from retrorsine-exposed rats.

BACKGROUND: Complete liver regeneration after partial hepatectomy (PH) in rats treated with the pyrrolizidine alkaloid retrorsine can be accomplished through the activation, expansion, and differentiation of a novel population of small hepatocyte-like progenitor cells (SHPCs). These cells have not been isolated in pure form, established in primary culture, or transplanted into syngeneic rats to examine their differentiation potential. METHODS: Primary liver cells enriched for SHPCs were prepared by differential centrifugation of primary liver cell dispersions from retrorsine-exposed rats 6-8 days and 13-15 days after PH. Isolated SHPCs were characterized for cell size, morphology, and expression of cell type-specific markers (including hepatocyte and bile duct-oval cell markers), and established in short-term primary culture. Isolated SHPCs were transplanted into the livers of syngeneic rats to evaluate their ability to engraft and differentiate into mature hepatocytes. RESULTS: SHPCs obtained from retrorsine-exposed rats 6-8 days and 13-15 days after PH were small (10-12 microm in diameter), morphologically resembled hepatocytes, and were predominantly H.4 antigen-positive, alpha-fetoprotein-positive, and OV6-negative. SHPCs did not proliferate in culture and could not be passaged, but short-term cultures were established using protein substrates (collagen or laminin) and defined medium containing epidermal growth factor and nicotinamide. After transplantation into the livers of syngeneic hosts, SHPCs insert into hepatic plates and give rise to differentiated hepatocyte progeny. The SHPC-derived hepatocyte progeny express a differentiated phenotype (albumin-positive, transferrin-positive, alpha-fetoprotein-negative) and are able to proliferate in vivo in response to the growth stimulus provided by PH. CONCLUSIONS: The results demonstrate that enriched SHPC populations can be isolated from retrorsine-exposed rats and established in short-term culture, and they can engraft and differentiate after transplantation into the livers of syngeneic rats.

Cholestasis induces murine hepatocyte apoptosis and DNA synthesis with preservation of the immediate-early gene response.

BACKGROUND: Major hepatic resection in patients with unrelieved obstructive jaundice carries an increased risk of postoperative liver failure. We hypothesized that cholestasis induces hepatocyte apoptosis and impairs hepatic regeneration by inhibiting up-regulation of the known immediate-early response genes, nuclear factor kappa B (NF-kappaB) and activating protein-1 (AP-1). The aim of this study was to determine whether the immediate-early gene response in hepatic regeneration remains intact in extrahepatic cholestasis. METHODS: Eight-week-old BALB/c mice underwent either sham operation (SO) or common bile duct ligation (BDL). Two-thirds partial hepatectomy (PH) was performed at 4 and 7 days, with remnant liver harvested 0, 15, 30, or 60 minutes after PH. Serum analysis for markers of cholestasis and histopathology was obtained. Proliferating cell nuclear antigen and terminal deoxyuridine triphosphate nick end labeling (TUNEL) immunohistochemistry for detection of DNA synthesis and apoptosis, respectively, was performed 4, 7, or 10 days after SO or BDL. Liver samples from 0, 15, 30, or 60 minutes after PH were analyzed for NF-kappaB and AP-1 DNA binding activity by using electrophoretic mobility shift assays. RESULTS: Increased serum bilirubin level and hematoxylin-eosin-stained liver sections confirmed cholestasis in BDL mice. BDL induced marked DNA synthesis and hepatocyte apoptosis in prehepatectomy liver at both 4 and 7 days. Substantially higher basal levels of both NF-kappaB and AP-1 binding activity were present in BDL compared with SO mice. Fold induction of NF-kappaB and AP-1, however, was similar between BDL and SO mice. Cholestasis induced hepatocyte DNA synthesis and apoptosis. Basal NF-kappaB and AP-1 DNA binding activity was increased in BDL mice, but fold induction of these immediate-early genes did not differ from controls. CONCLUSIONS: Although basal NF-kappaB and AP-1 DNA binding is increased in cholestasis, the immediate-early gene response to PH remains intact in BDL mice.

Suppression of tumorigenicity of rat liver tumor cells by human chromosome 13: evidence against the involvement of pRb and BRCA2.

Aberrations of chromosome 13, including large-scale deletions and rearrangements, have been implicated in the development of a significant fraction of human hepatocellular carcinomas, suggesting that liver tumor suppressor genes may be located on this chromosome. In this study, we have employed a microcell hybrid-based model system to investigate the presence of liver tumor suppressor loci on human chromosome 13. The parental GN6TF rat liver epithelial tumor cells are highly tumorigenic in vivo and exhibit altered cellular morphology and growth characteristics in vitro. The GN6TF cells form tumors in 100% of syngeneic animals with short latency, are not contact inhibited or anchorage-dependent in cell culture, and do not express mRNAs for rat Rb1 and BRCA2. Microcell-mediated introduction of human chromosome 13 into the rat liver tumor cell line GN6TF resulted in the generation of clonal microcell hybrid (MCH) cell lines that differentially exhibited tumor suppression and/or alteration of other transformation-associated phenotypes in vitro. Two GN6TF-13neo MCH lines exhibited characteristics indicative of suppression by the human chromosome, including a normalized cellular morphology and growth pattern, loss of anchorage-independent growth potential, partial restoration of contact inhibition, reduction in tumorigenic potential in vivo, and dramatic elongation of tumor latency. In contrast, three GN6TF-13neo MCH cell lines were minimally affected by the introduction of the human chromosome and were nearly indistinguishable from the parental GN6TF tumor cells, exhibiting a highly aggressive tumorigenic phenotype in vivo. Both suppressed and non-suppressed GN6TF-13neo MCH cell lines express Rb1 and BRCA2 mRNA in vitro, and tumors derived from the non-suppressed GN6TF-13neo MCH cell lines continue to express Rb1 and BRCA2 mRNA in vitro, and express pRb in vivo. The results suggest that: i) human chromosome 13 contains a liver tumor suppressor locus, ii) expression of Rb1 and/or BRCA2 is insufficient to produce tumor suppression in this rat liver tumor cell line, and iii) that the human chromosome 13 liver tumor suppressor may represent a novel tumor suppressor gene, distinct from Rb1 and BRCA2.