Uptake and clearance of plutonium-238 from liver cells transplanted into fat pads of F344 rats

This research is directed toward understanding the role of liver cells and the liver environment in plutonium biokinetics. Animals injected with liver cells and control animals received a single intraperitoneal injection of 37 kBq (1 microCi) 238Pu citrate and were serially sacrificed 1, 5, 10, 15, 30, 60 or 70 days later. Uptake, retention and distribution of Pu in intact liver and in liver cells growing in fat pads were determined. From these measurements, it was observed that the cells of the intact liver took up about twice as much 238Pu as liver cells transplanted into the fat pads of the same animal. The retention half-life was 8.3 days for the total activity in the liver, 20 days using tracks/cell measurements in the liver and 16 days for the tracks/cell measurements in the liver cells translocated to fat pads. When the data on tracks/cell were standardized relative to the amount of Pu present at 5 days after the injection, there was no significant difference between the retention of Pu in liver cells from intact animals and liver cells transplanted into the fat pads. About 20 per cent of the 5-day Pu liver burden in both liver cells and liver cells transplanted into fat pads was retained at 70 days. The smaller retention and clearance for liver cells in different environments indicate that uptake and clearance of Pu from the body is dependent, to a major extent, upon hepatocyte function.     

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.     

Stimulation of growth of primary cultured adult rat hepatocytes without growth factors by coculture with nonparenchymal liver cells

DNA synthesis of adult rat parenchymal hepatocytes alone in primary culture can be stimulated only by the addition of humoral growth factors to the culture medium. However, when parenchymal hepatocytes were cocultured with nonparenchymal liver cells from adult rats, their DNA synthesis was markedly stimulated in the absence of added growth factors or calf serum. DNA synthesis of parenchymal hepatocytes was not stimulated by conditioned medium from nonparenchymal liver cells and was greatest when the parenchymal cells were plated on 24-h cultures of nonparenchymal liver cells. A dead feeder layer of nonparenchymal cells was almost as effective as a feeder layer of viable nonparenchymal cells. These results suggest that the stimulation of DNA synthesis in parenchymal hepatocytes was not due to some soluble factors secreted by nonparenchymal liver cells but to an insoluble material(s) produced by the nonparenchymal liver cells. This insoluble material(s) was collagenase- and acid-sensitive, suggesting that it was a protein containing collagen. The effect of nonparenchymal liver cells was specific: coculture with hepatoma cells, liver epithelial cells, or Swiss 3T3 cells did not stimulate DNA synthesis in parenchymal hepatocytes. Added insulin and epidermal growth factor showed additive effects with nonparenchymal cells in the cocultures. These results suggest that DNA synthesis in parenchymal hepatocytes is stimulated not only by various humoral growth factors but also by cell-cell interaction between parenchymal and nonparenchymal hepatocytes, possibly endothelial cells. This cell-cell interaction may be important in repair of liver damage and liver regeneration.     

Association of NKT cells and granulocytes with liver injury after reperfusion of the portal vein

Reperfusion of the liver was conducted by clamping the portal vein for 30 min in mice, followed by unclamping. Unique variation in the number of lymphocytes was induced and liver injury occurred thereafter. The major expander cells in the liver were estimated to be natural killer T cells (i.e., NKT cells), whereas conventional T cells and NK cells increased only slightly or somewhat decreased in number and proportion at that time. Reflecting the expansion of NKT cells in the liver, a Th0-type of cytokine profile was detected in sera, and cytotoxic activity was enhanced in liver lymphocytes. In NKT cell-deficient mice including CD1d (-/-) mice and athymic nude mice, the magnitude of liver injury decreased up to 50% of that of control mice. It was also suspected that accumulating granulocytes which produce superoxides might be associated with liver injury after reperfusion. This might be due to stress-associated production of catecholamines. It is known that granulocytes bear surface adrenergic receptors and that they are activated by sympathetic nerve stimulation after stress. The present results therefore suggest that liver injury after reperfusion may be mainly caused by the activation of NKT cells and granulocytes, possibly by their cytotoxicity and superoxide production, respectively.     

Characterization of the interaction in vivo of tissue-type plasminogen activator with liver cells

The interaction in vivo of 125I-labeled tissue-type plasminogen activator (t-PA) with the rat liver and the various liver cell types was characterized. Intravenously injected 125I-t-PA was rapidly cleared from the plasma (t1/2 = 1 min), and 80% of the injected dose associated with the liver. After uptake, t-PA was rapidly degraded in the lysosomes. The interaction of 125I-t-PA with the liver could be inhibited by preinjection of the rats with ovalbumin or unlabeled t-PA. The intrahepatic recognition site(s) for t-PA were determined by subfractionation of the liver in parenchymal, endothelial, and Kupffer cells. It can be calculated that parenchymal cells are responsible for 54.5% of the interaction of t-PA with the liver, endothelial cells for 39.5%, and Kupffer cells for only 6%. The association of t-PA with parenchymal cells was not mediated by a carbohydrate-specific receptor and could only be inhibited by an excess of unlabeled t-PA, indicating involvement of a specific t-PA recognition site. The association of t-PA with endothelial cells could be inhibited 80% by the mannose-terminated glycoprotein ovalbumin, suggesting that the mannose receptor plays a major role in the recognition of t-PA by endothelial liver cells. An excess of unlabeled t-PA inhibited the association of 125I-t-PA to endothelial liver cells 95%, indicating that an additional specific t-PA recognition site may be responsible for 15% of the high affinity interaction of t-PA with this liver cell type. It is concluded that the uptake of t-PA by the liver is mainly mediated by two recognition systems: a specific t-PA site on parenchymal cells and the mannose receptor on endothelial liver cells. It is suggested that for the development of strategies to prolong the half-life of t-PA in the blood, the presence of both types of recognition systems has to be taken into account.     

Effects of laminin, fibronectin and type IV collagen on liver cell cultures

The effects on mouse liver cells of laminin, fibronectin and type IV collagen, all of which are the main matrix of the basement membrane, were studied. Laminin, a glycoprotein isolated from cultures of rat yolk sac carcinoma cells, promoted the attachment of mouse fetal liver cells to laminin-coated dishes, but did not have a strong influence upon the attachment of normal adult liver cells. On the other hand, fibronectin which was purified from mouse plasma promoted the attachment of adult liver cells but not that of fetal liver cells. The number of neonatal liver cells attached to the surfaces coated was intermediate between those of fetal and adult liver cells in each matrix. DNA synthesis and cell proliferation during the culture of full-term fetal liver cells in laminin-coated dishes were higher than those in fibronectin- or type IV collagen-coated dishes. The amount of alpha-fetoprotein secreted in the laminin-coated dishes was more than in other groups. No differences in secretion of albumin into media, however, were observed in either group. These results suggest that laminin may be necessary for cell growth, tissue organization and cell differentiation during the normal development of liver in vivo.     

Distribution of gangliosides in parenchymal and non-parenchymal cells of rat liver

Parenchymal and non-parenchymal cells were isolated from rat liver with purities of more than 90%. Total and ganglioside sialic acid contents were higher in non-parenchymal cells than in parenchymal cells. Thin-layer chromatography of gangliosides showed that the main component in rat liver was ganglioside GM3 and that this was abundant in non-parenchymal cells. Parenchymal cells had ganglioside GD1b as the main component and less GM3 than non-parenchymal cells. These results suggested that the main ganglioside of rat liver, GM3, arises mainly from non-parenchymal cells.     

Conditioned media of Kupffer and endothelial liver cells influence protein phosphorylation in parenchymal liver cells. Involvement of prostaglandins.

The possible role of Kupffer and endothelial liver cells in the regulation of parenchymal-liver-cell function was assessed by studying the influence of conditioned media of isolated Kupffer and endothelial cells on protein phosphorylation in isolated parenchymal cells. The phosphorylation state of three proteins was selectively influenced by the conditioned media. The phosphorylation state of an Mr-63,000 protein was decreased and the phosphorylation state of an Mr-47,000 and an Mr-97,000 protein was enhanced by these media. These effects could be mimicked by adding either prostaglandin E1, E2 or D2. Both conditioned media and prostaglandins stimulated the phosphorylase activity in parenchymal liver cells, suggesting that the Mr-97,000 phosphoprotein might be phosphorylase. Parenchymal liver cells secrete a phosphoprotein of Mr-63,000 and pI 5.0-5.5. The phosphorylation of this protein is inhibited by Kupffer- and endothelial-liver-cell media, and prostaglandins E1, E2 and D2 had a similar effect. The data indicate that Kupffer and endothelial liver cells secrete factors which influence the protein phosphorylation in parenchymal liver cells. This forms further evidence that products from non-parenchymal liver cells, in particular prostaglandin D2, might regulate glucose homoeostasis and/or other specific metabolic processes inside parenchymal cells. This stresses the concept of cellular communication inside the liver as a way by which the liver can rapidly respond to extrahepatic signals.     

Age-related variation in the proportion and activity of murine liver natural killer cells and their cytotoxicity against regenerating hepatocytes

We investigated the distribution of liver NK cells in mice of various ages and their cytotoxicity against regenerating hepatocytes. Liver NK cells were identified by asialo GM1 antibody in mononuclear cell suspension from the liver, whereas NK activity was assayed against YAC-1 target cells. Mononuclear cells in the liver consisted of more than 25% NK cells with potent NK activity in C3H/He mice, 8 wk of age. The strain-specific distribution (C3H/He greater than C57BL/6 greater than DBA/2) of liver NK cells was the same as those in the spleen and blood. The proportion of liver NK cells and the level of NK activity in C3H/He mice were further demonstrated to vary depending on age, in that both the proportion and the function were generated at 4 wk of age, reached a maximum between the 6th and 8th wk, and then rapidly decreased around the 9th wk. The appearance of an increased number of NK cells in the liver seemed to coincide with the slowing of the rapid increase of murine liver weight. We then investigated whether liver NK cells mediated their cytotoxicity against regenerating hepatocytes. Both specific 51Cr-release assay and single cell cytotoxicity assay demonstrated that liver NK cells were significantly cytotoxic against regenerating hepatocytes in partially hepatectomized liver, but to a lesser extent against normal hepatocytes in resting liver. Morphologic study revealed that normal liver predominantly consisted of hepatocytes with binuclei (greater than 60%) but that regenerating liver mainly consisted of hepatocytes with a single nucleus (greater than 70%). One-nucleus hepatocytes were more susceptible to the cytotoxicity of liver NK cells. A comparative study of restoration kinetics of the liver weight and the number of liver NK cells after partial hepatectomy also showed a unique relationship. These results raise the possibility that liver NK cells might be responsible for regulating hepatocyte growth.     

Expression of glutamine synthetase in macrophages.

We studied the expression of glutamine synthetase in liver macrophages (Kupffer cells, KCs) in situ and in culture. Glutamine synthetase was detectable at the mRNA and protein level in freshly isolated and short-term-cultured rat liver macrophages. Enzyme activity and protein content were about 9% of that in liver parenchymal cells. In contrast, glutamine synthetase mRNA levels in liver macrophages apparently exceeded those in parenchymal liver cells (PCs). By use of confocal laser scanning microscopy and specific macrophage markers, immunoreactive glutamine synthetase was localized to macrophages in normal rat liver and normal human liver in situ. All liver macrophages stained positive for glutamine synthetase. In addition, macrophages in rat pancreas contained immunoreactive glutamine synthetase, whereas glutamine synthetase was not detectable at the mRNA and protein level in blood monocytes and RAW 264.7 mouse macrophages. No significant amounts of glutamine synthetase were found in isolated rat liver sinusoidal endothelial cells (SECs). The data suggest a constitutive expression of glutamine synthetase not only, as previously believed, in perivenous liver parenchymal cells but also in resident liver macrophages.     

Uptake of beta-hexosaminidase by nonparenchymal liver cells and peritoneal macrophages

The uptake of beta-hexosaminidase (EC 3.2.1.30) in nonparenchymal liver cells (i.e. endothelial and Kupffer's cells) and peritoneal macrophages has been determined by an enzymatic assay. A considerable uptake was noted in nonparenchymal liver cells, whereas no measurable uptake was seen in peritoneal macrophages. The endothelial cells were more active in the uptake of beta-hexosaminidase than were the Kupffer's cells. The uptake of beta-hexosaminidase by nonparenchymal liver cells showed saturation kinetics and was competitively inhibited by mannan. These findings support the concept that a cell surface receptor on nonparenchymal liver cells mediates uptake of beta-hexosaminidase and suggests a difference in the receptor mechanisms on liver and peritoneal macrophages.     

Cellular communication inside the liver. Binding, conversion and metabolic effect of prostaglandin D2 on parenchymal liver cells.

The major eicosanoid produced within the rat liver, prostaglandin (PG) D2, wa studied for its ability to interact with the various liver cell types. It appeared that PGD2 bound specifically to parenchymal liver cells, whereas the binding of PGD2 to Kupffer and endothelial liver cells was quantitatively unimportant. Maximally 700 pg of PGD2/mg of parenchymal-cell protein could be bound by a high-affinity site (1 x 10(6) PGD2-binding sites/cell). The recognition site for PGD2 is probably a protein because trypsin treatment of the cells virtually abolished the high-affinity binding. High-affinity binding of PGD2 was a prerequisite for the induction of a metabolic effect in isolated parenchymal liver cells, i.e. the induction of glycogenolysis. High-affinity binding of PGD2 by parenchymal cells was coupled to the conversion of PGD2 into three metabolites, whereas no conversion of PGD2 by Kupffer and endothelial liver cells was noticed. The temperature-sensitivity of the conversion of PGD2 was consistent with a conversion of PGD2 on or in the vicinity of the cell membrane. One of the PGD2 metabolites could be identified as 9 alpha, 11 beta-PGF2. It can be calculated that the conversion rate of PGD2 by parenchymal liver cells exceeds the production rate of PGD2 by Kupffer plus endothelial liver cells, indicating that PGD2 is meant to exert its activity within the liver. The present finding that PGD2 formed by the non-parenchymal liver cells is recognized by a specific receptor on parenchymal liver cells and that binding, conversion and metabolic effect of PGD2 are interlinked by this receptor provides further support for the specific role of PGD2 in the intercellular communication in the liver.     

Selective retention of activated CD8+ T cells by the normal liver.

Activation-induced cell death resulting in peripheral deletion of CD8+ T cells is associated with the accumulation of large numbers of apoptotic T cells in the liver. The hypothesis that this accumulation results from the intrahepatic trapping of T cells from the circulating pool predicts that the liver should retain T cells, which subsequently undergo apoptosis. Here we test this prediction. Perfusion of the liver with lymphocyte mixtures showed retention of activated, but neither resting nor apoptosing, T cells. This trapping was selective for CD8+ cells and was mediated primarily by ICAM-1 constitutively expressed on sinusoidal endothelial cells and Kupffer cells. T cells trapped in the liver became apoptotic. The normal liver is therefore a "sink" for activated T cells.     

Comparative proteomic analysis of primary mouse liver c-Kit-(CD45/TER119)- stem/progenitor cells

Liver stem/progenitor cells play a key role in liver development and maybe also in liver cancer development. In our previous study a population of c-Kit-(CD45/TER119)- liver stem/progenitor cells in mouse fetal liver, was successfully sorted with large amount (10(6)-10(7)) by using immuno-magnetic microbeads. In this study, the sorted liver stem/progenitor cells were used for proteomic study. Proteins of the sorted liver stem/progenitor cells and unsorted fetal liver cells were investigated using two-dimensional electrophoresis. A two-dimensional proteome map of liver stem/progenitor cells was obtained for the first time. Proteins that exhibited significantly upregulation in liver stem/progenitor cells were identified by peptide mass fingerprinting and peptide sequencing. Nineteen protein spots corresponding to 12 different proteins were identified as showing significant upregulation in liver stem/progenitor cells and seem to play important roles in such cells in cell metabolism, cell cycle regulation, and stress. An interesting finding is that most of the upregulated proteins were overexpressed in various cancers (11 of 12, including 6 in human hepatocellular carcinoma (HCC)) and involved in cancer development as reported in previous studies. Some of the identified proteins were validated by real-time PCR, Western blotting, and immunostaining. Taken together, the data presented provide a significant new protein-level insight into the biology of liver stem/progenitor cells, a key population of cells that might be also involved in liver cancer development.     

Cytofluorimetric study of the content of glycogen and its fractions in rat liver cells in the course of the 1st week of postnatal ontogeny]

A cytofluorometric study of the total glycogen and its fractions in rat liver cells using the fluorescent PAS reaction was made during 1--7 days of the postnatal development. It was established that glycogen content was small on the first two days of development. The glycogen content increases only on the third day after birth. The glycogen of the rat liver cells during a first week of the postnatal development is different from that detected in adult liver cells in two aspects: in 3 day old hepatocytes soluble and stable glycogen fractions are equal, while in adult rat liver cells the former makes 80--90%; during the first week of the postnatal development, the stable fraction of rat liver cell is more labile, while in the adult rat liver the soluble fraction of glycogen is more labiles.     

Polymerized albumin receptor on rat liver cells.

The polymerized albumin hypothesis was proposed for the mechanism of a hepatitis B virus (HBV) infection of human liver parenchymal cells on the basis that a receptor for polymerized albumin treated with glutaraldehyde was detected on isolated human liver parenchymal cells. However, some controversy exists regarding this hypothesis, because a receptor for formaldehyde-treated bovine serum albumin (f-BSA) has been found on liver non-parenchymal cells. Therefore, we characterized the uptake of polymerized rat serum albumin (p-RSA) and f-BSA by rat liver in vivo, and their bindings to liver cells in vitro. Most p-RSA and f-BSA was taken up by the liver after intravenous administration, and the uptake of p-RSA was inhibited by a 1,000-fold excess of f-BSA. In addition, more than 80% of p-RSA taken up by the liver was found in the non-parenchymal cells, and the remainder was found in the parenchymal cells. P-RSA as well as f-BSA could bind to isolated rat liver parenchymal and non-parenchymal cells. Furthermore, p-RSA and f-BSA could bind to isolated rat liver cell plasma membranes, and these bindings were completely inhibited by 1,000-fold excess of either f-BSA or p-RSA. These results indicate that there is a receptor, which can recognize both p-RSA and f-BSA, on not only rat liver non-parenchymal cells but also the parenchymal cells. It is also indicated that the receptor on the parenchymal cells as well as the non-parenchymal cells is involved in the in vivo uptake of p-RSA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Internalization of retinol-binding protein in parenchymal and stellate cells of rat liver

We have studied uptake of retinol-binding protein (RBP) by rat liver cells. First, we compared the in vivo uptake in different liver cells of 125I-labeled RBP with that of other well-known ligands. We found that the ligands studied were recognized differently by the various cell types in the liver, and that RBP was most efficiently taken up by parenchymal and stellate cells. We then studied the in vivo uptake of RBP in liver cells by immunocytochemistry at the electron microscopic level using ultrathin cryosections. Ten min after injection, RBP was localized to parenchymal cells and stellate cells. In these cells, RBP was detected on the cell surface and in vesicles near the cell surface. RBP was observed mainly in association with the membrane in these vesicles. Two hours after injection, RBP was localized not only on the cell surface and in vesicles close to the cell surface, but also in larger vesicles located deeper in the cytoplasm of these cells. RBP in larger vesicles was observed at a distance from the vesicular membrane. Finally, we compared the distribution of endocytosed RBP in liver parenchymal cells with that of asialo-orosomucoid, a ligand known to be internalized by receptor-mediated endocytosis. We detected both ligands on the cell surface and in small vesicles located close to the cell surface and in larger vesicles located deeper in the cytoplasm. Asialo-orosomucoid and RBP were seldom observed in the same small vesicles, but the larger vesicles contained both ligands. These data suggest that RBP is internalized in parenchymal and stellate cells of the liver by receptor-mediated endocytosis.     

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.     

Cutting edge: contribution of NK cells to the homing of thymic CD4+NKT cells to the liver

In contrast to peripheral lymphoid organs, in the liver a high proportion of T cells are CD4+NKT cells. We have previously reported that LFA-1 plays a pivotal role in the homing of thymic CD4+NKT cells to the liver. In the present study, we further assessed which cell type participates in the homing of thymic CD4+NKT cells to the liver. The accumulation of donor thymocyte-derived CD4+NKT cells in the liver of SCID mice that had been reconstituted with thymocytes from C57BL/6 mice was severely impaired by in vivo depletion of NK cells, but not Kupffer cells in recipients. These results suggest that NK cells participate in the homing of thymic CD4+NKT cells to the liver. We assume that LFA-1 expressed on NK cells is involved in this mechanism.     

细胞角蛋白19启动子调控的双报告载体的构建及其在肝干/祖细胞分化研究中的应用

肝干/祖细胞是肝细胞和胆管上皮细胞(biliary epithelial cells,BECs)共同的前体细胞,为了对这一前体细胞的分化情况进行研究,利用报告基因来监测肝干/祖细胞的分化走向．首先,通过PCR方法从肝癌细胞系HepG2的全基因组中克隆了细胞角蛋白19(CK19)启动子片段,构建了CK19启动子调控的海肾荧光素酶和红色荧光蛋白(red fluorescent protein,RFP)双报告载体(pSicoR-CK19-hrl-mrfp)．其次,将上述慢病毒载体转染肝干/祖细胞后,通过流式细胞分选获得稳定转染的细胞株．再次,将上述细胞株与表达“上皮形态发生素”(Epimorphin,EPM)的PT67细胞共培养后,整合有pSicoR-CK19-hrl-mrfp表达载体的肝干/祖细胞不仅形态发生了变化,而且排列为二维环状结构,另外还检测到由CK19启动子启动表达的海肾荧光素酶和RFP,细胞形态和基因表型都证明肝干/祖细胞经诱导已经分化成为BECs．与此形成对照的是肝干/祖细胞与不表达EPM的PT67细胞共培养后,没有观测到上述的变化．所以,CK19启动子调控的双报告载体不仅可以实时地显示肝原始细胞在不同的诱导环境下的分化走向,而且还可以定量地检测CK19启动子活性的变化情况．总之,这一载体的成功构建将为研究肝干/祖细胞的分化提供了便捷的工具,同时也有助于筛选可诱导肝干/祖细胞定向分化的分子．