Glycosidases of rat Kupffer cells, hepatocytes and peritoneal macrophages.

The acid glycosidase content of rat liver Kupffer cells was compared with that of hepatocytes and resident peritoneal macrophages. Homogenates of all these cells were able to hydrolyze the p-nitrophenyl glycosides of N-acetylglucosamine, N-acetylgalactosamine, glucose, galactose, fucose and mannose, but not xylose. Activity was greatest against the N-acetylglucosaminoside. With Kupffer cell homogenates, most of the glycosidases behaved as if they were lysosomal enzymes. When expressed as rates of hydrolysis per 10(6) cells, activities against a given substrate by homogenates from the three cell types generally agreed within a factor of 2-4. Significant differences between cell types were found, however, when ratios of glycosidase activities were compared. Furthermore, even though the quantity of glycosidase per cell was similar in Kupffer cells and hepatocytes, the glycosidase concentrations were much higher in the former cells, since Kupffer cells are much smaller than hepatocytes.     

The involvement of parenchymal,Kupffer and endothelial liver cells in the hepatic uptake of intravenously injected liposomes effects of lanthanum and gadolinium salts

¹²⁵I-labeled albumin or poly(vinyl pyrrolidone) encapsulated in intermediate size multilamellar or unilamellar liposomes with 30–40% of cholesterol were injected intravenously into rats. In other experiments liposomes containing phosphatidyl[Me-¹⁴C]choline were injected. 1 h after injection parenchymal or non-parenchymal cells were isolated. Non-parenchymal cells were separated by elutriation centrifugation into a Kupffer cell fraction and an endothelial cell fraction. From the measurements of radioactivities in the various cell fractions it was concluded that the liposomes are almost exclusively taken up by the Kupffer cells. Endothelial cells did not contribute at all and hepatocytes only to a very low extent to total hepatic uptake of the ¹²⁵I-labels. Of the ¹⁴C-label, which orginates from the phosphatidylcholine moiety of the liposomes, much larger proportions were recovered in the hepatocytes. A time-dependence study suggested that besides the involvement of phosphatidylcholine exchange between liposomes and high density lipoprotein, a process of intercellular transfer of lipid label from Kupffer cells to the hepatocytes may be involved in this phenomenon. Lanthanum or gadolinium salts, which effectively block Kupffer cell activity, failed to accomplish an increase in the fraction of liposomal material recovered in the parenchymal cells. This is compatible with the notion that liposomes of the type used in these experiments have no, or at most very limited, access to the liver parenchyma following their intravenous administration to rats.     

Intrahepatic uptake and processing of intravenously injected small unilamellar phospholipid vesicles in rats

Small unilamellar vesicles consisting of sphingomyelin, cholesterol and phosphatidylserine in a molar ratio of 4:5:1 containing [³H]inulin as a marker of the aqueous space or [Me-¹⁴C]choline-labeled sphingomyelin as a marker of the lipid phase were injected intravenously into rats. After separation of the non-parenchymal cells into a Kupffer cell fraction and an endothelial cell fraction by elutriation centrifugation analysis of the radioactivity contents demonstrated that Kupffer cells were actively involved in the uptake of the vesicles whereas endothelial cells did not contribute at all. Uptake by total parenchymal cells was also substantial but, on a per cell base, significantly lower than that by the Kupffer cells. By comparising the fate of the [³H]inulin label and the [¹⁴C]sphingomyelin label it was concluded that release of liposomal lipid degradation products especially occurred from Kupffer cells rather than from parenchymal cells. In both cell types, however, substantial proportions of the ¹⁴C-label accumulated in the phosphatidylcholine fraction, indicating intracellular degradation of sphingomyelin and subsequent phosphatidylcholine synthesis. Treatment of the animals with the lysosomotropic agent chloroquine prior to liposome injection effectively blocked the conversion of the choline-labeled sphingomyelin into phosphatidylcholine in both cell types. This observation indicates that uptake of the vesicles occurred by way of an endocytic mechanism.     

Studies of lysosomal function: I. Metabolism of some complex lipids by isolated hepatocytes and Kupffer cells

The enzymatic hydrolysis of four complex lipids was measured in extracts of rat hepatocytes and Kupffer cells. Sphingomyelin, glucocerebroside, ceramide trihexoside, and G_Ml-ganglioside were hydrolyzed by extracts of both cell types. Hepatocytes contain 90% or more of the complex lipid hydrolases present in liver. The activities of ten additional acid hydrolases are located predominately in hepatocytes with only a small fraction of the total activity present in Kupffer cells.     

TRANSCELLULAR BIOSYNTHESIS OF CYSTEINYL LEUKOTRIENES BY KUPFFER CELL—HEPATOCYTE COOPERATION IN RAT LIVER

We previously proposed that an enzymatic cooperation between Kupffer cells and hepatocytes may play an important role in cysteinyl leukotriene (LT) production in rat liver. Anin vitrotranscellular synthesis cysteinyl LTs by a Kupffer cell—hepatocyte coculture system was characterized here. Kupffer cells alone, with A23187 stimulation, did not generate cysteinyl LTs until supplemented either with isolated hepatocytes or with LTC₄synthase and glutathione, indicating that Kupffer cells can synthesize LTA₄but not convert it into LTC₄. In contrast, hepatocytes converted the LTA₄into cysteinyl LTs and further degraded the cysteinyl LTs. Cysteinyl LT production by the Kupffer cell—hapatocyte coculture system was optimized by addition of 1–3% serum albumin to the culture and by bringing the cell—cell distance closer to less than 3μ. Tumour necrosis factor also stimulated cysteinyl LT production by the coculture system. From these results, it is expected that the Kupffer cell—hepatocyte transcellular system for cysteinyl LT production actually functionsin vivo.     

Peptide Pheromone Plantaricin A Produced by Lactobacillus plantarum Permeabilizes Liver and Kidney Cells

Certain antimicrobial peptides from multicellular animals kill a variety of tumor cells at concentrations not affecting normal eukaryotic cells. Recently, it was reported that also plantaricin A (PlnA), which is a peptide pheromone with strain-specific antibacterial activity produced by Lactobacillus plantarum, permeabilizes cancerous rat pituitary cells (GH₄ cells), whereas normal rat anterior pituitary cells are resistant to the peptide. To examine whether the preferential permeabilization of cancerous cells is a general feature of PlnA, we studied its effect on primary cultures of cells from rat liver (hepatocytes, endothelial, and Kupffer cells) and rat kidney cortex, as well as two epithelial cell lines of primate kidney origin (Vero cells from green monkey and human Caki-2 cells). The Vero cell line is derived from normal cells, whereas the Caki-2 cell line is derived from a cancerous tumor. The membrane effects were studied by patch clamp recordings and microfluorometric (fura-2) monitoring of the cytosolic concentrations of Ca²⁺ ([Ca²⁺]_i) and fluorophore. In all the tested cell types except Kupffer cells, exposure to 10–100 μM PlnA induced a nearly instant permeabilization of the membrane, indicated by the following criteria: increased membrane conductance, membrane depolarization, increased [Ca²⁺]_i, and diffusional loss of fluorophore from the cytosol. At a concentration of 5 μM, PlnA had no effect on any of the cell types. The Kupffer cells were permeabilized by 500 μM PlnA. We conclude that the permeabilizing effect of PlnA is not restricted to cancerous cells.     

Lectin binding sites in normal and phenobarbitale/halothane treated rat liver

Summary The content of carbohydrate residues of both normal and phenobarbitale-halothane-hypoxia exposed rat liver has been examined by means of lectin histochemistry. Eight biotinylated lectins specific to galactose, N-acetyl-galactosamine, N-acetyl-glucosamine, fucose and mannose were applied to paraffin sections of rat liver at light microscopic levels. The most distinct binding was observed at the structures of the perisinusoidal functional unit: Kupffer cells are bound by S-WGA, SBA and PNA. Bile canaliculi display binding sites for RCA I and WGA. Cytoplasm of hepatocytes appears lectin-negative, except for PSA. The enhanced reaction of S-WGA, PNA and SBA after the preincubation of the sections with neuraminidase indicates the occurance of sialic acid in Kupffer cells. The phenobarbitale-halothane-hypoxia exposed rat liver shows centrolobular degeneration of hepatocytes with a diminished amount of hepatocytes and Kupffer cells as well. The lectin binding pattern of sinusoidal walls, membranes of hepatocytes and bile canaliculi remains the same compared to that of normal rat liver. This finding suggests that at least the carbohydrate content of membranes in the liver resists severe destruction under phenobarbitale-halothane-hypoxia. It is assumed that there exists a connection between intact carbohydrate residues and the regeneration of liver parenchyma.     

Apolipoprotein E is secreted by cultured lipocytes of the rat liver

Hepatic lipocytes, the retinoid-storing cells of the liver, share several characteristics with vascular smooth muscle cells. To determine whether they also share the characteristic of apolipoprotein E secretion, we have compared the relative mRNA expression and protein secretion of apolipoprotein E, apolipoprotein A-I, and apolipoprotein A-IV in early primary cultures of lipocytes, hepatocytes, and Kupffer cells. Expression of apolipoprotein mRNAs was detected using the polymerase chain reaction and oligonucleotide primers specific for apolipoprotein E, apolipoprotein A-I, and apolipoprotein A-IV. Cellular mRNA concentrations were compared by dot blot analysis, and apolipoprotein secretion was assessed by immunoblot analysis of culture media. Apolipoprotein E mRNA was found in all three cell types, whereas apolipoprotein A-I and A-IV mRNAs were detected only in hepatocytes. Hepatocyte, lipocyte, and Kupffer cell media all contained a Mr approximately 36,000 protein identified by an antibody specific for rat apolipoprotein E. The relative concentration of apolipoprotein E mRNA per microgram of total cellular RNA in lipocytes, hepatocytes, and Kupffer cells was 1.0, 3.0, and 1.6, respectively. The relative secretion of apolipoprotein E per cell was also lowest in lipocytes, being twofold greater in hepatocytes and 1.4-fold greater in Kupffer cells. The secretion of apolipoprotein E by lipocytes is not only an additional smooth muscle cell-like characteristic of the hepatic lipocyte, but also raises the possibility of retinol mobilization upon apolipoprotein secretion.     

Salt-Adaptation of Tobacco BY2 Cells Induces Change in Glycoform of N-Glycans: Enhancement of Exo- and Endo-Glycosidase Activities by Salt-Adaptation

In this report, we describe that a salt adaptation of plant cells induces glycoform changes in N-glycoproteins. Intracellular and cell-wall glycopeptides were prepared from glycoproteins expressed in wild-type BY2 cells and salt-adapted cells. N-Glycans were liberated from those glycopeptides by hydrazinolysis, and the released oligosaccharides were N-acetylated and pyridylaminated. The structures of pyridylaminated (PA-) N-glycans were analyzed by a combination of two-dimensional sugar-chain mapping, MS analysis, and exoglycosidase digestion. In both wild-type cells and salt-adapted cells, the plant complex type structure was predominant among N-glycans expressed on glycoproteins, but we found that the Man2Xyl1Fuc1GlcNAc2 structure was significantly expressed on intracellular and cell-wall glycoproteins of the salt-adapted cells. Furthermore, enhancement of the specific activities of α-mannosidase and β-N-acetylglucosaminidase was observed in the salt-adapted BY2 cells, suggesting that the glycoform changes are due to changes in glycosidase activities.     

Maintenance of liver function in long term culture of hepatocytes following In Vitro or In Vivo Ha-ras EJ transfection

Collagenase isolated rat hepatocytes were transfected with liposome encapsulated pEJ (LE-pEJ), a plasmid carrying the human cellular activated Ha-ras^EJ oncogene. A proliferative cell line was cloned from these cells transfected in vitro. It secreted per day 0.87 µg albumin and 0.32 µg transferrin per 10⁶ cells, and 11.06 nmol free and conjugated bile acids (BA) per mg protein. Also, it metabolized 2-acetylaminoflourene (2-AFAF) into N- and ring-hydroxylated metabolites and 2-aminofluorene at rates of 1.50, 9.73, and 1.98 nmol/mg cell protein/24 hr, respectively. Rats were i.v. injected with both LE-pEJ and LE-p17hGHnneo carrying the hGH cDNA gene, and secreted hGH in the plasma which induced the synthesis of anti-hGH antibodies. A cell line was cloned from cultures of primary hepatocytes isolated from the liver of transfected rats. After 2 to 3 months in culture, this cell line secreted per day 18.9 µg albumin and 11.0 µg transferrin per 10⁶ cells, 38.75 nmol total BA per mg cell protein, and up to 31 ng hGHper 10⁶ cells without cloning hGH recombinant cells. A 24 hr control culture of primary hepatocytes isolated from non transfected rats secreted 25.5 µg albumin and 11.7 µg transferrin per 10⁶ cells, and produced 21.64 nmol total BA and 2.13 nmol N-OH-2-AFAF per mg cell protien. Hence, Ha-ras ^EJ transfection of either hepatocytes in vitro or liver cells in vivo, initiated cell cycles leading to presumptive proliferating hepatocytes which express liver function.Abbreviations BWE basal Williams' medium E - FBS fetal bovine serum - F10 or F12 basal Ham's F10 or F12 medium - Ha-ras ^EJ EJ allele of the human cellular ras oncogen of Harvey - hGH human growth hormone - hsp heat shock protein gene - LE-p liposome encapsulated plasmid - N-OH-2-AFAF N-hydroxy-2-acetylaminofluorene - RLECC rat liver epithelial cell - SF serum-free - SS serum-supplemented - UGG serum substitute UGltroser G® - 1-OH-, 3-OH-2-AFAFF 1-hydroxy-, 3-hydroxy-2-acetylaminofluorene - 2-AFAF 2-acetylaminofluorene - 2-AFF 2-aminofluorene     

Arg-Gly-Asp (RGD) sequence conjugated in a synthetic copolymer bearing a sugar moiety for improved culture of parenchymal cells (hepatocytes)

A copolymer, including a Gly-Arg-Gly-Asp-Ser (GRGDS) sequence and sugar moieties, was synthesized for the culturing of parenchymal cells (hepatocytes). Hepatocyte cells attached to poly[N-p-vinylbenzyl-d-maltonamide-co-6-(p-vinylbenzamido)-hexanoic acid-GRGDS] [poly(VMA-co-VBRGD)]-coated dishes grew approximately 60% better than on other polymer-coated surface for 12 h. Also, about 80% greater albumin secretion (0.38 pg ml^–1) and about 70% greater urea synthesis (0.495 pg ml^–1) from hepatocytes were produced in this matrix as compared with unstimulated cells. The behaviour of hepatocytes on poly(VMA-co-VBGRGDS)-coated dishes was not distinct from those attached to a collagen. The conjugation of the adhesion molecules of the RGD peptide in the poly(VMA-co-VBGRGDS) copolymer therefore specifically interacts with integrin families on the hepatocyte cell membrane.     

Uridine catabolism in Kupffer cells, endothelial cells, and hepatocytes

Kupffer cells, endothelial cells, and hepatocytes were separated by centrifugal elutriation. The rate of uracil formation from [2-14C]uridine, the first step in uridine catabolism, was monitored in suspensions of the three different liver cell types. Kupffer cells demonstrated the highest rate of uridine phosphorolysis. 15 min after the addition of the nucleoside the label in uracil amounted to 51%, 13%, and 19% of total radioactivity in the medium of Kupffer cells, endothelial cells, and hepatocytes, respectively. If corrected for Kupffer cell contamination, hepatocyte suspensions demonstrated similar activities as endothelial cells. In contrast to non-parenchymal cells, hepatocytes continuously cleared uracil from the incubation medium. The lack of uracil consumption by Kupffer cells and endothelial cells points to uracil as the end-product of uridine catabolism in these cells. Kupffer cells and endothelial cells did not produce radioactive CO2 upon incubation in the presence of [2-14C]uridine. Hepatocytes, however, were able to degrade uridine into CO2, beta-alanine, and ammonia as demonstrated by active formation of volatile radioactivity from the labeled nucleoside. There was almost no detectable formation of thymine from thymidine or of cytosine, uracil, or uridine from cytidine by any of the different cell types tested. These results are in line with low thymidine phosphorolysis and cytidine deamination in rat liver. Our studies suggest a co-operation of Kupffer cells, endothelial cells, and hepatocytes in the breakdown of uridine from portal vein blood with uridine phosphorolysis predominantly occurring in Kupffer cells and with uracil catabolism restricted to parenchymal liver cells.     

Quantification and regulation of apolipoprotein E expression in rat Kupffer cells

Apolipoprotein E (apoE) is synthesized by a wide variety of cells including cells of the monocyte-macrophage lineage. In order to assess the quantitative significance of apoE synthesis in a mature tissue macrophage, apoE synthesis was compared in Kupffer cells and hepatocytes isolated from rat liver. Immunoreactive apoE synthesized by both cell types exhibited identical isoform patterns when examined by high-resolution two-dimensional gel analysis. ApoE synthesis was not detected in hepatic endothelial cells. Northern blot analysis using a rat apoE cDNA probe demonstrated a single mRNA species of approximately 1200 nucleotides in freshly isolated hepatocytes and Kupffer cells. The absolute content of apoE mRNA in each cell type was determined with a DNA-excess solution hybridization assay. The apoE mRNA content (pg/microgram RNA) for Kupffer cells and hepatocytes was 35.7 and 98.8, respectively. Accounting for cellular RNA content and the population size of each cell type in the liver, Kupffer cells were calculated to contain about 0.7% of liver apoE mRNA; hepatocytes account almost quantitatively for the remainder. These results suggest that Kupffer cells are not major contributors to the plasma apoE pool. After intravenous injection of bacterial endotoxin, apoE mRNA was decreased in freshly isolated Kupffer cells whereas whole liver showed no change in apoE mRNA. Endotoxin treatment had no effect on the apoE mRNA content in several peripheral tissues. These results indicate that apoE expression in vivo is differentially regulated by endotoxin in Kupffer cells as compared to hepatocytes or apoE-producing cells in peripheral tissues.     

Glucocorticoids suppress and oestrogens enhance the lipopolysaccharide-induced increase in putrescine and N-acetylspermidine in mouse liver

Previously we reported that administration of lipopolysaccharide (LPS) to mice increased the hepatic levels of putrescine (PUT) and N¹-acetylspermidine (N¹-acetyl-SPD). In the current study, we examined the in vivo effects of some steroid hormones on the LPS-induced increase in PUT and N¹-acetyl-SPD. Corticosterone, hydrocortisone and dexamethasone suppressed the LPS-induced increase in PUT and N¹-acetyl-SPD in mouse liver in a dose-dependent manner, dexamethasone being the most effective among them. On the other hand, oesterone and oestradiol-17β enhanced the LPS-induced increase in PUT and N¹-acetyl-SPD in a dose-dependent manner. Oestradiol-17α and 16β-ethyl-oestradiol, as an inactive oestradiol isomer and an antioestrogen, respectively, likewise enhanced the increase in PUT and N¹-acetyl-SPD concentrations induced by LPS. 16α-hydroxy-oestradiol (oestriol), 16α-hydroxyestrone, 2-hydroxyoestradiol, 2-hydroxyoestrone, progesterone, testosterone, diethylstilboestrol and nonsteroidal antioestrogen such as tamoxifen and nafoxidine had no effect on the increase. Oestradiol-17β enhanced and corticosterone had little on the carbon tetrachloride-induced increase in PUT and N¹-acetyl-SPD. These results suggest that glucocorticoids suppress the increase by preventing the immunological injury by Kupffer cells on hepatocytes and that the stimulatory effect of oestrogens may not be associated with their oestrogenic activities mediated by the oestrogen receptor system.     

The effect of kupffer cell stimulation or depression on the development of liver metastases in the rat

Summary Tumour cells from a squamous carcinoma (approximately 2.5×10⁵) were injected intraportally into a syngeneic strain of rats to produce liver metastases 14 days later. Kupffer cells were stimulated by Corynebacterium parvum (7 mg or 1 mg i.v.) and zymosan (10 mg intraportally). Kupffer cell activity was depressed by the administration of silica, gadolinium chloride or human red cells. The animals in each group were sacrificed at 14 days, the livers removed and the number of visible surface metastases counted and compared. (Mann-Whitney U-test).Kupffer cell stimulation significantly reduced the number of surface liver metastases in all animals (P0.0048). In contrast depression of Kupfer cell activity significantly increased the number of metastases in all animals (P0.0045), suggesting that the activity of these cells has an important effect on the development of liver metastases.     

Isolation and characterization of rat primary lung cells

Summary Lung cell culture may be useful as anin vitro alternative to study the susceptibility of the lung to various toxic agents. Lungs from female Wistar rats were enzymatically digested by recirculating perfusion through the pulmonary artery with a sequence of solutions containing deoxyribonuclease, chymopapain, pronase, collagenase, and elastase. Lung tissue was microdissected and resuspended and the cells obtained were washed by centrifugation. By this isolation method, 2×10⁸ cells per rat lung were obtained with an average viability of 97%. Lung cells cultured in medium containing antibiotics and serum maintained a viability of >70% for 5 d. Rat primary lung cells were exposed to various toxic agents and their viability was assessed by formazan production capacity after 18 h of incubation. Compared to rat and mouse hepatocyte cultures (EC⁵⁰=5.8 mM), rat primary lung cells were much more susceptible to hydrogen peroxide (EC₅₀=0.6 mM). All cell types were equally sensitive to the more potent toxicanttert-butylhydroperoxide (EC₅₀=0.1 mM). Paraquat was more toxic to lung cells (EC₅₀=0.03 mM) than to rat (EC₅₀=2.8 mM) and mouse (EC₅₀=0.2 mM) hepatocytes. In contrast, rat lung cells were less sensitive to sodium nitroprusside (EC₅₀=2.6 mM) compared to rat (EC₅₀=0.2 mM) and mouse (EC₅₀=0.03 mM) hepatocytes. Nitrofurantoin and menadione (at EC₅₀=0.04 mM and 0.006 mM, respectively) were more toxic to rat lung and liver cells than to murine hepatocytes (EC₅₀=0.2 mM and 0.04 mM, respectively). Our findings demonstrate the applicability of this rat primary lung cell culture for studying the effects of lung toxicants. Parts of the study had been presented orally at the meeting of the German Society of Toxicology and Pharmacology in Mainz (FRG), March 15–17, 1994.     

Influx of macrophages into livers of rats treated with hepatotoxicants (thioacetamide, allyl alcohol, d-galactosamine) induces expression of HSP25

Treatment of rats with a single dose of thioacetamide (TAA) provokes centrilobular inflammation and a significant expression of heat shock protein HSP25 in hepatocytes surrounding the area of inflammation. The HSP25 accumulation in hepatocytes adjacent to inflammatory regions was confirmed by identification of positive hepatocytes concentrated at periportal areas after treatment of rats with allyl alcohol (AA) or distributed diffusely throughout liver lobule after treatment with d-galactosamine (d-gal). In our model of TAA-treated rats the use of the anti-inflammatory drug—indomethacin, and the redox-regulating drug—N-acethylcysteine (NAC), significantly attenuated TAA-induced HSP25 expression and evoked morphological changes of recruited ED1⁺ macrophages. Treatment of rats with gadolinium chloride (GdCl₃) decreased considerably the number of Kupffer cells (ED2⁺ macrophages) without affecting significantly the number and morphology of ED1⁺ macrophages as well as the expression pattern of TAA-induced HSP25. Our data shows for the first time that ED1⁺ macrophages recruited into the liver by treatment with TAA play a significant role in HSP25 induction in hepatocytes.     

Membrane lipids of hepatocytes,Kupffer cells and endothelial cells

The membrane lipid composition of isolated hepatocytes, Kupffer cells and endothelial cells was determined. The hepatocytes are characterized by a lower quantity of gangliosides, cholesterol, sphingomyelin and a reduced cholesterol/phospholipid molar ratio when compared to the two other liver cell types. The main gangliosides of Kupffer and endothelial cells are the GM3 species, and those of hepatocytes are of the polysialogangliosides species.     

Uptake and transport of glucagon by rat liver: evidence for transcytotic pathway

Summary The binding of¹²⁵I-glucagon to the cell surface and the pathway of intracellular transport of this hormone by rat hepatocytes in vivo were studied by light and EM autoradiography. Radiolabeled glucagon injected into the blood stream was taken up predominantly by the hepatocytes. Negligible radioactivity was found to be associated with other cell types such as endothelial or Kupffer cells. Our results indicate that at early time points after injection glucagon has been preferentially interacting with the sinusoidal domain of the hepatocytes and found to be associated with coated pits and uncoated vesicles corresponding to endosomes. At 15–20 min time intervals glucagon grains were found within hepatocyte interior. Later, at 30 min after injection glucagon grains accumulate in the Golgi-lysosomal region of hepatocyte often in close proximity to the opening of the bile canaliculi. Accordingly a portion of internalized¹²⁵I-glucagon was found to be released into the bile thereby indicating that a transcytotic pathway may be involved in this peptide's clearance process.     

In vitro induction of tumor necrosis factor-α by ochratoxin A (OTA) from rat liver: role of Kupffer cells

Tumor necrosis factor-α (TNF-α) is released from blood-free perfused rat liver by the fungal metabolite ochratoxin A. Here we have identified Kupffer cells as the sole source of OTA-mediated cytokine release. If single cell preparation of Kupffer cells, hepatocytes, or sinusoidal endothelial cells were prepared from rat livers, only Kupffer cells released TNF-α upon incubation with 2.5 μmol/l OTA. OTA failed to induce TNF-α release in the blood-free perfused isolated rat liver when Kupffer cells were blockedin vitro by 15 μmol/l gadolinium chloride. When rats were pretreatedin vivo with the Kupffer cell depleting clodronate liposomes, OTA-mediated TNF-α release was abrogated in the isolated perfused liver model.