Distribution of lysosomal enzymes in different types of rat liver cells.

Eight lysosomal enzymes were measured in different types of rat liver cells. Hepatocytes were purified by low speed centrifugation of a cell suspension obtained by treating the perfused liver with collagenase. Nonparenchymal cells (NPC) were purified by centrifugation after treating the initial cell suspension with pronase, which selectively destroys the parenchymal cells (PC). Kupffer cells were found to attach selectively to tissue culture dishes after overnight culture of an NPC suspension. The specific activity of lysosomal enzymes was generally higher in NPC than in hepatocytes, but the different enzymes were concentrated to different degrees in the NPC. Specific activity of acid phosphatase was 1.7 times higher in NPC than in hepatocytes. Specific activity of acid DNAase, on the other hand, was 8 times higher in NPC than in hepatocytes. Other enzymes showed intermediate values. Assuming that 30% of the liver cells are nonparenchymal it may be calculated that from 7% (acid phosphatase) to 25% (acid DNAase) of the hepatic lysosomal enzymes are present in the NPC. The pattern of lysosomal enzymes in cultured Kupffer cells was similar to that of the NPC from which the Kupffer cells were derived. Cathepsin D and β-glucuronidase were, however, elevated in Kupffer cells as compared with NPC. The enzyme pattern in Kupffer cells was almost identical with that of rat peritoneal macrophages.     

Newly administered [3H]retinol is transferred from hepatocytes to stellate cells in liver for storage

We have recently shown that newly administered vitamin A (retinol) is initially taken up by the parenchymal cells of the liver, and subsequently (within 1-2 h) transferred to non-parenchymal liver cells (NPC) (Blomhoff et al., ref. [10]). In the present study we have separated the NPC by different methods to determine the cell type responsible for this uptake of [3H]retinol. When liver cells were prepared between 5 and 18 h after intraduodenal administration of [3H]retinol, the radioactive retinol was recovered mainly in the stellate cells. Other liver cells (i.e., hepatocytes, endothelial cells and Kupffer cells) contained only small amounts of [3H]retinol. Further, fluorescence microscopy studies indicated that stellate cells contain large quantities of retinol. Our results show that newly administered [3H]retinol, which is initially located in the hepatocytes, is transferred to the stellate cells and stored there.     

Abnormal binding of soluble IgG immune complexes to hepatic nonparenchymal cells of autoimmune mice

Because the liver is the major organ responsible for removal of soluble immune complexes (IC), the surface binding characteristics of preformed model IC to unstimulated mouse liver nonparenchymal cells (NPC) in suspension were studied. NPC of non-autoimmune C3H/FeJ, C3H/HeJ, A/J, DBA/2 and the autoimmune NZB/W F1 and MRL/lpr female mice of various ages were isolated by perfusion of the portal vein with collagenase followed by separation of NPC from hepatocytes with a metrizamide gradient. Thirty-five percent of NPC of all mouse strains were nonspecific esterase-positive and phagocytosed latex beads. Radiolabeled mouse IgG anti-DNP covalently cross-linked stable IC were separated by gel filtration and bound to NPC under various conditions. Marked differences were noted in maximal number of IC bound per cell between the autoimmune and non-autoimmune mouse strains: 3.3 to 4.0 X 10(5) in the non-autoimmune strains vs 0.3 to 1.4 X 10(5) molecules of IC bound per cell in the autoimmune strains at 1 to 6 mo. Insignificant differences were noted in Ka by Scatchard plot analysis (3.5 to 5.0 X 10(8) M-1) and rate of reversibility of binding as determined by dissociation of surface-bound IC with an excess of heat-aggregated gamma-globulin (T 1/2:1.5 to 2 min). These data demonstrate a decreased number of available binding sites for IC in unstimulated NPC from NZB/W F1 and MRL/lpr female mice throughout their life spans. Although the findings are consistent with saturation of binding sites of the NPC with native IC, the abnormality found in the 1-mo-old autoimmune mice (who do not have detectable autoantibodies) suggests a primary defect in FC receptor expression or an altered state of activation of NPC that may contribute to the disease process.     

Effect of cell concentration on the uptake of amino acids by rat liver parenchymal cells in suspension.

The accumulation of several amino acids in the acid-soluble fraction and their incorporation into protein in rat liver parenchymal cell suspensions, has been shown to depend on the concentration of cells in the incubation medium; the uptake, both in the acid-soluble and the acid-insoluble fractions, decreased as the cell concentration increased from 0.03 X 10(6) cells/ml upwards, reaching a plateau at high cell concentrations (3-5 X 10(6) cells/ml). The uptake values at high cell concentrations were the same as those obtained in liver slices in which a similar effect was not observed. Evidence is presented which suggests that this phenomenon is mediated by a material released from the cells in suspension, which is inhibitory to enhancement of the uptake of amino acids by these cells over and above the value obtained in normal, adult liver slices.     

Hepatic retinol metabolism. Distribution of retinoids, enzymes, and binding proteins in isolated rat liver cells

The main retinoids and some binding proteins and enzymes involved in retinol metabolism have been quantified in different types of rat liver cells. Hepatic perisinusoidal stellate cells contained 28-34 nmol of retinoids/10(6) cells, and parenchymal liver cells contained 0.5-0.8 nmol of retinoids/10(6) cells, suggesting that as much as 80% of more of total liver retinoids might be stored in stellate cells with the rest stored in parenchymal cells. Isolated endothelial cells and Kupffer cells contained very low levels of retinoids. More than 98% of the retinoids recovered in stellate cells were retinyl esters. Isolated parenchymal and stellate cell preparations both contained considerable retinyl palmitate hydrolase and acyl-CoA:retinol acyltransferase activities. Parenchymal cells accounted for about 75-80% of the total hepatic content of these two enzyme activities, with the rest located in stellate cells. On a cell protein basis, the concentrations of both of these activities were much greater in stellate cells than in parenchymal cells. In contrast, cholesteryl oleate and triolein hydrolase activities were fairly evenly distributed in all types of liver cells. Large amounts of cellular retinol binding proteins were also found in parenchymal and stellate cells. Although parenchymal cells accounted for more than 90% of hepatic cellular retinol binding protein, the concentration of the protein in stellate cells (per unit protein) was 22 X greater than that in parenchymal cells. Stellate cells were also enriched in cellular retinoic acid binding protein. Thus, both parenchymal and stellate cells contain substantial amounts of retinoids and of the enzymes and intracellular binding proteins involved in retinol metabolism. Stellate cells are particularly enriched in these several components.     

Role of liver endothelial and Kupffer cells in clearing low density lipoprotein from blood in hypercholesterolemic rabbits.

The role of liver endothelial and Kupffer cells in the hepatic uptake of cholesterol-rich low density lipoprotein (LDL) was studied in rabbits fed a diet containing 2% (w/w) cholesterol for 3 weeks. 125I-labeled tyramine cellobiose-labeled cholesterol-rich LDL was injected intravenously into rabbits, and parenchymal and nonparenchymal liver cells were isolated 24 h after injection. The hepatic uptake was 9 +/- 3% of injected dose in cholesterol-fed rabbits 24 h after injection, as compared to 36 +/- 9% in control-fed rabbits (n = 6 in each group; significant difference, P less than 0.005). Endothelial and Kupffer cells took up 2.7 +/- 0.5% and 1.2 +/- 0.8% of injected dose in the hypercholesterolemic rabbits, as compared to 1.9 +/- 0.8% and 0.8 +/- 0.3% in control animals. The amount accounted for by the parenchymal cells was markedly reduced in the cholesterol-fed rabbits to 7.3 +/- 2.7% of injected dose, as compared to 32.8 +/- 7.6% in controls (P less than 0.02). On a per cell basis, the nonparenchymal cells of cholesterol-fed rabbits took up as much LDL as the parenchymal cells (0.6 +/- 0.2, 0.7 +/- 0.1, and 0.6 +/- 0.4% of injected dose per 10(9) parenchymal, endothelial, and Kupffer cells, respectively). This is in marked contrast to the control animals, in which parenchymal cells took up about 6 times more LDL per cell than endothelial and Kupffer cells (3.2 +/- 0.9, 0.7 +/- 0.3, and 0.5 +/- 0.1% of injected dose per 10(9) cells). Thus, 30% of the hepatic uptake of LDL in the cholesterol-fed rabbits took place in nonparenchymal cells, as compared to 6% in controls. Consistent with these data, the concentrations of cholesteryl ester in endothelial and Kupffer cells in rabbits fed the high cholesterol diet were about twofold higher than in parenchymal cells (428 +/- 74 and 508 +/- 125 micrograms/mg protein, respectively, vs. 221 +/- 24 micrograms/mg protein in parenchymal cells). In contrast to cells from normal rabbits, Kupffer and endothelial cells from cholesterol-fed rabbits accumulated significant amounts of Oil Red O-positive material (neutral lipids). Electron microscopic examination of these cells in situ as well as in culture revealed numerous intracellular lipid droplets. Slot blot hybridization of RNA from liver parenchymal, endothelial, and Kupffer cells showed that cholesterol feeding reduced the level of mRNA specific for the apoB,E receptor to a small and insignificant extent in all three cell types (to 70-80% of that observed in control animals).(ABSTRACT TRUNCATED AT 400 WORDS)     

Classification of the isolated hepatocytes

At this present, enzyme perfusion method is a routine technique to isolate hepatocytes from rat liver for the physiological and pathological experiments. This study described a way of the classification of freshly isolated hepatocytes. First of all, the hepatocytes were fractionated with parenchymal and non-parenchymal cells by low speed centrifugation. And then these cells were subfractionated with a newly developed Percoll linear density gradient method. The fractionated parenchymal cells were divided with cells of periportal and centrilobular areas, respectively. Furthermore, their characteristics were confirmed functionally and morphologically. Non-parenchymal cells (NPC) include Kupffer cells, endothelial cells and fat storing cells (FSC, Ito cells). These isolated NPC are fractionated with a method as mentioned above or centrifugal alutriation method. In this paper, fractionation and classification of Kupffer cells and FSC were discussed with the measurement of fluorescent intensity of vitamin A and the morphological observation of cytoskeleton in culture. Especially, transport of vitamin A into FSC were detected autoradiographically.     

Characteristics of lipoprotein receptors of the isolated liver parenchymal cells prepared from the streptozotocin-induced diabetic rats

Characteristics of lipoprotein receptors of the isolated liver parenchymal cells prepared from the streptozotocin-induced diabetic rats were investigated. Streptozotocin-induced diabetic rats fed 1.0% cholesterol showed the exaggerated hypercholesterolemia as compared to control rats fed 1.0% cholesterol. The present study was designed to elucidate the role of lipoprotein receptor mechanisms of liver parenchymal cells in the diabetic dyslipoproteinemia. 125I-labeled lipoproteins (rat beta-VLDL, human LDL2 or rat HDL3) were incubated with liver parenchymal cells isolated by liver perfusion using collagenase. According to the Scatchard analysis, the apparent dissociation constant (kd) and maximum beta-VLDL binding (Bmax) for the higher affinity binding site in the diabetic rats (n = 6) were (11.9 +/- 5.1) X 10(2) ng/ml and 307.5 +/- 145.2 ng/10(6) cells, respectively. These binding characteristics of the diabetic rats were not significantly different from the control rats. Furthermore, there were no significant differences in the binding characteristics of human LDL2 and rat HDL3 between the diabetic rats and the control rats. The data presented suggest that significant role of alteration of lipoprotein receptor characteristics in liver parenchymal cells is not played in the diabetic dyslipoproteinemia.     

Featured Article: Isolation,characterization, and cultivation of human hepatocytes and non-parenchymal liver cells

Primary human hepatocytes (PHH) are considered to be the gold standard for in vitro testing of xenobiotic metabolism and hepatotoxicity. However, PHH cultivation in 2D mono-cultures leads to dedifferentiation and a loss of function. It is well known that hepatic non-parenchymal cells (NPC), such as Kupffer cells (KC), liver endothelial cells (LEC), and hepatic stellate cells (HSC), play a central role in the maintenance of PHH functions. The aims of the present study were to establish a protocol for the simultaneous isolation of human PHH and NPC from the same tissue specimen and to test their suitability for in vitro co-culture. Human PHH and NPC were isolated from tissue obtained by partial liver resection by a two-step EDTA/collagenase perfusion technique. The obtained cell fractions were purified by Percoll density gradient centrifugation. KC, LEC, and HSC contained in the NPC fraction were separated using specific adherence properties and magnetic activated cell sorting (MACS®). Identified NPC revealed a yield of 1.9 × 10⁶ KC, 2.7 × 10⁵ LEC and 4.7 × 10⁵ HSC per gram liver tissue, showing viabilities >90%. Characterization of these NPC showed that all populations went through an activation process, which influenced the cell fate. The activation of KC strongly depended on the tissue quality and donor anamnesis. KC became activated in culture in association with a loss of viability within 4–5 days. LEC lost specific features during culture, while HSC went through a transformation process into myofibroblasts. The testing of different culture conditions for HSC demonstrated that they can attenuate, but not prevent dedifferentiation in vitro. In conclusion, the method described allows the isolation and separation of PHH and NPC in high quality and quantity from the same donor.     

The uptake of homologous ribonucleic acid by rat-liver parenchymal cells in suspension

1. Native or partially degraded RNA derived from intact rat liver, or from the parenchymal-cell or the non-parenchymatous fraction of liver, has been shown to be transported into rat parenchymal cells in suspension, without prior degradation to acid-soluble components, when the cell suspension is incubated with the RNA at 37 degrees . The amount of RNA of exogenous origin present in the parenchymal cells in an acid-precipitable form increased rapidly up to 30-60min., after which it gradually decreased, indicating intracellular degradation to acid-soluble components of the RNA taken up by the cells. 2. The RNA taken up by the parenchymal cells from the medium, and the acid-soluble products of its degradation within the cells, could be released back into the medium. 3. The RNA of exogenous origin present in acid-precipitable form in the parenchymal cells represented up to 5% of the RNA of the cells after 60min. of incubation. 4. When the concentration of RNA in the medium was less than 200mug./ml., over 10% of the RNA was transported in an acid-precipitable form in 60min. into the parenchymal cells incubated at a concentration of 2.3x10(6)/ml. 5. Ribonuclease inhibited the uptake of exogenous RNA by the parenchymal cells, whereas 2,4-dinitrophenol, sodium azide, protamine sulphate and polyvinyl sulphate had no significant effect. 6. The uptake of exogenous RNA by liver slices proceeded at a rate which was 4-20% of that obtained in the parenchymal-cell suspensions; the RNA taken up did not appear to become degraded, unlike that taken up by the cell suspensions. 7. It is concluded that dispersion of liver tissue to a suspension of single cells increases the permeability of the parenchymal cells to macromolecular RNA and creates conditions that lead to a rapid degradation of the RNA taken up.     

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.     

Preparation of rat liver cells : III. Enzymatic requirements for tissue dispersion

Isolated perfused rat livers were dispersed by a two-step procedure of Ca²⁺ removal (probably including the removal of a Ca²⁺-dependent adhesion factor) followed by enzymatic treatment. Collagenase, crude or purified, converted all of the parenchymal tissue to a suspension of cells which were 95% intact. Other enzymes such as hyaluronidase, lysozyme and trypsin were ineffective. Since hypoxic conditions during enzymatic treatment did not affect cellular viability, the oxygenation apparatus can be omitted to facilitate sterile preparation of cells.Purification of the parenchymal cells by differential centrifugation reduced contamination by non-parenchymal cells from 10–20% initially to 1–2% finally, with 40% of the parenchymal cells recovered and no loss in viability. The purified cells were 20% binucleated and had the same biochemical composition as intact liver tissue. The cells were active in the synthesis of RNA, protein, glycogen and various metabolites, and showed sensitivity towards steroid and polypeptide hormones. Many of the freshly isolated cells had marked constriction furrows which disappeared upon incubation.     

Receptor-mediated uptake of homologous low-density lipoproteins by isolated liver parenchymal cells of fetal rats

Summary The binding and uptake of gold-labeled homologous, apolipoprotein E-free low-density lipoproteins (LDL) by isolated fetal rat liver parenchymal cells in suspension were studied ultrastructurally and morphometrically. Binding experiments using ¹²⁵I-labeled LDL were also performed. After a 2-h preincubation in a lipoprotein-free medium and a subsequent 1-h postincubation in the presence of LDL-gold, fetal liver parenchymal cells exhibit a binding of 248±17 gold conjugates/100 m plasma membrane and an uptake of 235±17 gold conjugates/100 m² cytoplasm. Compared with values obtained from freshly isolated nonpreincubated cells, these data correspond to a 15-fold and an 18-fold increase in total binding and uptake of LDL-gold, respectively. Competition experiments reveal that this increase is mainly a result of a 23-fold stimulation of specific binding and a 44-fold stimulation of receptor-mediated uptake of LDL-gold. The ¹²⁵I-LDL binding experiments give a K_d value of 6.3×10^-8 M and a maximum binding capacity of 17.3 fmol LDL/10⁶ cells. Our data provide evidence, further to our in vivo studies, that fetal rat liver parenchymal cells possess high-affinity binding sites for native homologous apolipoprotein E-free LDL. These sites may correspond to B, E receptors of adult rat liver parenchymal cells.     

Perisinusoidal fat-storing cells are the main vitamin A storage sites in rat liver

Highly purified sinusoidal (fat-storing, Kupffer and endothelial cells) and parenchymal cells were isolated to assess the cellular distribution of vitamin A in liver of adult vitamin A-sufficient rats. A modified simple procedure was developed for the purification of fat-storing cells from rat liver. This was achieved by a single centrifugation step in a two-layer density Nycodenz gradient. Endothelial and Kupffer cells were obtained from the same gradient and further purified by centrifugal elutriation. Reverse-phase HPLC analysis showed that fat-storing cells contained about 300-fold the amount of retinyl esters present in parenchymal cells on a mg cell protein basis. In fat-storing cells, the same retinyl esters, viz. retinyl palmitate, retinyl stearate and retinyl oleate, were present as in whole liver. It was also observed that, within 12 h after intravenous injection of chylomicron [3H]retinyl ester, most of the radioactivity had accumulated in the fat-storing cells. It is concluded that fat-storing cells are the main storage sites for vitamin A in rat liver.     

The interaction in vivo of transferrin and asialotransferrin with liver cells.

Rat transferrin or asialotransferrin doubly radiolabelled with 59Fe and 125I was injected into rats. A determination of extrahepatic and hepatic uptake indicated that asialotransferrin delivers a higher fraction of the injected 59Fe to the liver than does transferrin. In order to determine in vivo the intrahepatic recognition sites for transferrin and asialotransferrin, the liver was subfractionated into parenchymal, endothelial and Kupffer cells by a low-temperature cell isolation procedure. High-affinity recognition of transferrin (competed for by an excess of unlabelled transferrin) is exerted by parenchymal cells as well as endothelial and Kupffer cells with a 10-fold higher association (expressed per mg of cell protein) to the latter cell types. In all three cell types iron delivery occurs, as concluded from the increase in cellular 59Fe/125I ratio at prolonged circulation times of transferrin. It can be calculated that parenchymal cells are responsible for 50-60% of the interaction of transferrin with the liver, 20-30% is associated with endothelial cells and about 20% with Kupffer cells. For asialotransferrin a higher fraction of the injected dose becomes associated with parenchymal cells as well as with endothelial and Kupffer cells. Competition experiments in vivo with various sugars indicated that the increased interaction of asialotransferrin with parenchymal cells is specifically inhibited by N-acetylgalactosamine whereas mannan specifically inhibits the increased interaction of asialotransferrin with endothelial and Kupffer cells. Recognition of asialotransferrin by galactose receptors from parenchymal cells or mannose receptors from endothelial and Kupffer cells is coupled to active 59Fe delivery to the cells. It is concluded that, as well as parenchymal cells, liver endothelial and Kupffer cells are also quantitatively important intrahepatic sites for transferrin and asialotransferrin metabolism, an interaction exerted by multiple recognition sites on the various cell types.     

4 in 1: Antibody‐free protocol for isolating the main hepatic cells from healthy and cirrhotic single rat livers

Liver cells isolated from pre‐clinical models are essential tools for studying liver (patho)physiology, and also for screening new therapeutic options. We aimed at developing a new antibody‐free isolation method able to obtain the four main hepatic cell types (hepatocytes, liver sinusoidal endothelial cells [LSEC], hepatic macrophages [HMΦ] and hepatic stellate cells [HSC]) from a single rat liver. Control and cirrhotic (CCl₄ and TAA) rat livers (n = 6) were perfused, digested with collagenase and mechanically disaggregated obtaining a multicellular suspension. Hepatocytes were purified by low revolution centrifugations while non‐parenchymal cells were subjected to differential centrifugation. Two different fractions were obtained: HSC and mixed LSEC + HMΦ. Further LSEC and HMΦ enrichment was achieved by selective adherence time to collagen‐coated substrates. Isolated cells showed high viability (80%‐95%) and purity (>95%) and were characterized as functional: hepatocytes synthetized albumin and urea, LSEC maintained endocytic capacity and in vivo fenestrae distribution, HMΦ increased expression of inflammatory markers in response to LPS and HSC were activated upon in vitro culture. The 4 in 1 protocol allows the simultaneous isolation of highly pure and functional hepatic cell sub‐populations from control or cirrhotic single livers without antibody selection.     

Retinoids, retinoid-binding proteins, and retinyl palmitate hydrolase distributions in different types of rat liver cells

A study was conducted to determine the levels and distributions of retinoids, retinol-binding protein (RBP), retinyl palmitate hydrolase (RPH), cellular retinol-binding protein (CRBP), and cellular retinoic acid-binding protein (CRABP) in different types of isolated liver cells. Highly purified fractions of parenchymal, fat-storing (stellate), endothelial, and Kupffer cells were isolated in high yield from rat livers. The retinoid content of each fraction was measured by HPLC analysis. RBP, CRBP, and CRABP were measured by sensitive and specific radioimmunoassays, and RPH activity was measured by a sensitive microassay. The concentrations of each parameter expressed per 10(6) parenchymal or fat-storing cells were, respectively: retinoids, 1.5 and 83.9 micrograms of retinol equivalents; RBP, 138 and 7.4 ng; RPH, 826 and 1152 pmol FFA formed hr-1; CRBP, 470 and 236 ng; and CRABP, 5.6 and 8.7 ng. When these data were expressed on the basis of per unit mass of cellular protein, the concentrations of RPH, CRBP, and CRABP in the fat-storing cells, which contain 10-fold less protein than the large parenchymal cells, were seen to be greatly enriched over parenchymal cells. The parenchymal cells contained approximately 9% of the total retinoids, 98% of the total RBP, 90% of the total RPH activity, 91% of the total CRBP, and 71% of the total CRABP found in the liver. The fat-storing cells accounted for approximately 88% of the total retinoids, 0.7% of the total RBP, 10% of the RPH activity, 8% of the total CRBP, and 21% of the CRABP in the liver. The endothelial and Kupffer cell fractions contained very low levels of all of these parameters. Thus, the large and abundant parenchymal cells account for greater than 70% of the liver's RBP, RPH, CRBP, and CRABP; but the much smaller and less abundant fat-storing cells contain the majority of hepatic retinoids and greatly enriched concentrations of RPH, CRBP, and CRABP.     

Identification of metallothionein in parenchymal and non-parenchymal liver cells of the adult rat.

Parenchymal and non-parenchymal cells were isolated from the livers of control, starved, Zn2+-injected and Cd2+-injected rats. Parenchymal cells were prepared by differential centrifugation after perfusion of the liver with collagenase. Non-parenchymal cells were separated from parenchymal cells by unit-gravity sedimentation and differential centrifugation. Yields of 2 x 10(8) non-parenchymal cells with greater than 95% viability and less than 0.2% contamination with parenchymal cells were obtained without exposing cells to Pronase. Metallothioneins-I and -II were identified in parenchymal cells and non-parenchymal cells from Zn2+-treated rats. The metallothionein contents of parenchymal cells, non-parenchymal cells and intact liver were quantified by a competitive 203Hg-binding assay. Administration of heavy-metal salts significantly increased the metallothionein content of both cell populations, although the concentration of the protein was approx. 2.5-fold greater in parenchymal cells than in non-parenchymal cells. Overnight starvation increased the metallothionein content of parenchymal cells without altering that of non-parenchymal cells. The potential significance of this differential response by different liver cell types with regard to the influence of Zn2+ on stress-mediated alterations in hepatic metabolism is discussed.     

Fluid endocytosis in isolated rat parenchymal and non-parenchymal liver cells

Fluid endocytosis in rat liver parenchymal (hepatocytes) and non-parenchymal cells was studied by measuring uptake of [¹²⁵I]polyvinylpyrrolidone (PVP). Radioactive sucrose preparations were also tested but turned out to be unsuitable because of impurities of radioactive glucose and fructose. Fluid endocytosis was temperature dependent without any transition temperature. The rate of endocytosis was inhibited by inhibitors of the glycolytic and the respiratory pathway. Colchicine, but not cytochalasin B, inhibited the uptake of [¹²⁵I]PVP in hepatocytes. Therefore, intact microtubuli, but not microfilaments may be required for normal rate of fluid endocytosis in hepatocytes. Colchicine reduced the rate of fluid endocytosis in the non-parenchymal liver cells. Subcellular fractionation by isopycnic centrifugation in sucrose gradients indicated that [¹²⁵I]PVP taken up by the hepatocytes accumulated in the lysosomes. The rate of uptake expressed as volume of fluid internalized per unit time (endocytic index) was calculated to 0.08 μl/h/10⁶ cells for hepatocytes and 0.07 μl/h/10⁶ cells for non-parenchymal liver cells.     

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.