Comparison of some permeability properties of rat liver slices, liver cells in suspension, and in vivo-produced aggregates of dispersed liver cells.

It has been reported earlier that when rat liver is dispersed to a single cell suspension, the parenchymal cells lose the ability to take up pyrimidine bases but acquire the ability to take up RNAase and macromolecular nucleic acids. It is now shown that these changes are largely reversed on intraperitoneal reaggregation of the parenchymal cells and that, in these respects, the aggregates behave more like the organized tissue than like the dispersed cells.     

Kinetic aspects of hemoglobin.haptoglobin-receptor interaction in rat liver plasma membranes, isolated liver cells, and liver cells in primary culture

125I-Hemoglobin.haptoglobin injected intravenously into rats was incorporated into liver parenchymal cells as evidenced by a cell separation technique. A mixture of freshly isolated liver parenchymal and nonparenchymal cells failed to internalize and degrade the 125I-hemoglobin.haptoglobin added, although it retained the ability to bind the molecule. The liver parenchymal cells in primary culture also lacked the ability to degrade 125I-hemoglobin.haptoglobin, although they bound the molecule more extensively as compared with the freshly isolated liver cells. It was confirmed that the 125I-hemoglobin.haptoglobin which was bound to the freshly isolated liver parenchymal cells localized on the outer surface of liver plasma membranes. Scatchard plots revealed the existence of two binding sites for 125I-hemoglobin-haptoglobin on the isolated liver plasma membrane: an apparent high affinity binding site (Kd = 1.3 X 10(-7) M) and an apparent low affinity binding site (Kd = 4.0 X 10(-6) M) at 37 degrees C. In contrast, freshly isolated liver parenchymal cells had only an apparent low affinity binding site (Kd = 1.4 X 10(-6) M) at 37 degrees C. Impairment of the apparent high affinity binding site during the isolation procedure with collagenase seemed to be related to loss of the ability to internalize and degrade the 125I-hemoglobin.haptoglobin molecules into the freshly isolated liver parenchymal cells or liver parenchymal cells in primary culture.     

Stem cells, cell transplantation and liver repopulation

Liver transplantation is currently the only therapeutic option for patients with end-stage chronic liver disease and for severe acute liver failure. Because of limited donor availability, attention has been focused on the possibility to restore liver mass and function through cell transplantation. Stem cells are a promising source for liver repopulation after cell transplantation, but whether or not the adult mammalian liver contains hepatic stem cells is highly controversial. Part of the problem is that proliferation of mature adult hepatocytes is sufficient to regenerate the liver after two-thirds partial hepatectomy or acute toxic liver injury and participation of stem cells is not required. However, under conditions in which hepatocyte proliferation is blocked, undifferentiated epithelial cells in the periportal areas, called "oval cells", proliferate, differentiate into hepatocytes and restore liver mass. These cells are referred to as facultative liver stem cells, but they do not repopulate the normal liver after their transplantation. In contrast, epithelial cells isolated from the early fetal liver can effectively repopulate the normal liver, but they are already traversing the hepatic lineage and may not be true stem cells. Mesenchymal stem cells and embryonic stem cells can be induced to differentiate along the hepatic lineage in culture, but at present these cells are inefficient in repopulating the liver. This review will characterize these various cell types and compare the properties of these cells and the conditions under which they do or do not repopulate the liver following their transplantation.     

Hormonal control of glycogenolysis in parenchymal liver cells by Kupffer and endothelial liver cells

Conditioned media of isolated Kupffer and endothelial liver cells were added to incubations of parenchymal liver cells, in order to test whether secretory products of Kupffer and endothelial liver cells could influence parenchymal liver cell metabolism. With Kupffer cell medium an average stimulation of glucose production by parenchymal liver cells of 140% was obtained, while endothelial liver cell medium stimulated with an average of 127%. The separation of the secretory products of Kupffer and endothelial liver cells in a low and a high molecular weight fraction indicated that the active factor(s) had a low molecular weight. Media, obtained from aspirin-pretreated Kupffer and endothelial liver cells, had no effect on the glucose production by parenchymal liver cells. Because aspirin blocks prostaglandin synthesis, it was tested if prostaglandins could be responsible for the effect of media on parenchymal liver cells. It was found that prostaglandin (PG) E1, E2, and D2 all stimulated the glucose production by parenchymal liver cells, PGD2 being the most potent. Kupffer and endothelial liver cell media as well as prostaglandins E1, E2, and D2 stimulated the activity of phosphorylase, the regulatory enzyme in glycogenolysis. The data indicate that prostaglandins, present in media from Kupffer and endothelial liver cells, may stimulate glycogenolysis in parenchymal liver cells. This implies that products of Kupffer and endothelial liver cells may play a role in the regulation of glucose homeostasis by the liver.     

Dendritic cells and liver fibrosis

Dendritic cells are a relative rare population of specialized antigen presenting cells that are distributed through most lymphoid and non-lymphoid tissues and play a critical role in linking the innate and adaptive arms of the immune system. The liver contains a heterogeneous population of dendritic cells that may contribute to liver inflammation and fibrosis through a number of mechanisms. This review summarizes current knowledge on the development and characterization of liver dendritic cells and their potential impact on liver fibrosis. This article is part of a Special Issue entitled: Fibrosis: Translation of basic research to human disease.     

Stem cells and liver engineering

Human hepatocytes, suitable for treatment of patients with liver failure, for the creation of bioartificial (BAL) devices, or for studies for toxicity and metabolization studies in the pharmaceutical industry, are in short supply due to the lack of donor organs. Therefore, methods that allow ex vivo expansion of hepatocytes with mature function are being pursued. One cell source, believed to be a possible inexhaustible source of hepatocytes, is pluripotent stem cells (PSCs). However, directed differentiation of PSCs to cells with features of adult hepatocytes is not yet possible. Differentiated progeny remains mixed and PSC progeny does not have a number of the functional features of mature hepatocytes. In this review article, we will address tools being developed that allow for the identification of mature hepatocytes, in a non-invasive manner; to perform lineage tracing of PSC progeny; and novel culture systems being created for the in vitro differentiation of PSCs to hepatocyte like cells, and for the maintenance of primary liver derived hepatocytes or PSC-derived hepatic progeny in culture. As conventional two-dimensional (2D) static culture conditions poorly recapitulate the in vivo cellular environment, we will discuss bioreactor systems for liver tissue engineering, both macro-scale and micro-scale culture systems.     

Synchronization of proliferating cells in the liver, gastric glands and duodenum

Multiple injections (5-6 times) of hydroxyurea to hepatectomized rats lead to synchronization of 78% of proliferating cells in the regenerating liver. The amount of DNA-synthesizing cells of the foveolar epithelium of the pyloric glands of the gastric mucosa increases 2.7-fold, the proliferation in slowly renewing Brunner glands of the duodenum is dramatically activated.     

Induction and degradation of Zn-, Cu- and Cd-thionein in Chang liver cells

Human liver cells (Chang liver) were exposed to 5 micrograms Zn, 2.5 micrograms Cu or 1 microgram Cd/ml in cultured medium. These exogeneous heavy metals were accumulated by the cells and induced de novo synthesis of metallothionein after a 3-h incubation period. The production of Zn-, Cu- or Cd-thionein started in the cells with accumulation of 1 nmol Zn, 0.3 nmol Cu and 0.1 nmol Cd/mg cytosol protein and subsequently the amounts of metal-binding thioneins increased in agreement with the relative amount of metal accumulated in the cytosol over a 24-h period. When cells containing Zn- or Cu-thionein were placed in metal free medium, 70% or 25% of the zinc or copper bound to each original metallothionein was released after 3 h; bound metals decreased to 85% and 65% respectively after 24 h. The disappearance of metal from metallothionein correlated with increases of metal in the medium. On the other hand, 35S-counts incorporated into Zn- and Cu-thionein decreased only to 40% and 15% of the levels in the original metallothionein after 3 h; 35S-counts decreased to 65% and 45%, respectively, after 24 h, indicating that metals bound to metallothionein decreased more quickly than 35S-counts. These results suggest that metals were released from metallothionein and were excreted into the medium. However, 35S- and 109Cd-counts in Cd-thionein changed very little, if at all, in the cells even after a 24-h incubation period. Our data strongly suggest that Zn- and Cu-thionein are degraded in the cells, but that Cd-thionein remains longer than either Zn- or Cu-thionein. When cells containing Zn-thionein were incubated in metal-free medium, Zn-thionein was digested in the cells and peptide fragments ranging about 200-400 daltons were excreted from the cells.     

Time-related distribution profiles of sulfated glycosaminoglycans in cells, cell surfaces, and media of cultured rat liver fat-storing cells

Fat-storing cells (perisinusoidal lipocytes, Ito cells), the principal proteoglycan-producing cell type in liver, were maintained for various times in primary and secondary culture to monitor the amount and pattern of [35S]sulfate-labeled glycosaminoglycans (GAG) in the cells, on the cell surface, and in the medium. In parallel with the phenotypic modulation of fat-storing cells toward myofibroblast-like cells, intracellular GAG decrease progressively, whereas cell surface-bound and medium GAG increase several-fold. These changes are associated with time-dependent alterations of the pattern of GAG in the various compartments. Dermatan sulfate is the most prominent intracellular GAG type in primary cultures, but on the cell surface and in the medium chondroitin sulfate prevails and reaches almost 70% of all medium GAG in secondary cultures. The results point to a highly dynamic expression of the specific types of GAG in the cellular and extracellular compartments of fat-storing cell cultures that seems to accompany the spontaneous transformation into myofibroblast-like cells. The latter one is a mainly chondroitin sulfate-producing cell type, whereas the initial fat-storing cell generates predominantly dermatan sulfate.     

Expression of liver and placental alkaline phosphatases in Chang liver cells

This paper presents evidence that a protein characteristic of differentiated liver cells, liver alkaline phosphatase, is synthesized by the Chang liver cell line. Liver alkaline phosphatase was demonstrated by immumochemical assay, ³²P-labeling and polyacrylamide gel electrophoresis, immunofluorescence microscopy, and the fluorescence-activated cell sorter. The synthesis of the liver enzyme by the Chang liver cells is interpreted to indicate fidelity of the Chang cells to their origin from human liver tissue. Chang liver cells also synthesize a phosphatase which is similar if not indentical to the placental alkaline phosphatase. Since a placental-type alkaline phosphatase has been observed in a number of non-trophoblastic cell lines and also in some neoplasms, it does not seem reliable as an index of the origins of the cell line. Because of the claims that Chang liver cells are actually HeLa cells, HeLa cells were studied in tandem with the Chang cells. The results showed that the HeLa cells do not make the liver type phosphatase. The data are discussed in relation to the question of HeLa cell contamination of the Chang cell line and the validity of criteria normally used to identify cell lines.