Hepatic heme metabolism in selenium-deficient rats: effect of phenobarbital.

Hepatic heme metabolism was examined in selenium (Se)-deficient and Se-adequate (control) rats. Administration of phenobarbital stimulated heme synthesis in the liver in both Se-deficient and Se-adequate rats. In contrast to these results, phenobarbital increased microsomal heme oxygenase (MHO) activity six- to eightfold in Se-deficient but not control rats. These data suggest that the previously reported abnormalities of cytochrome P-450 induction in Se-deficient rats are related to increased degradation of hepatic heme.     

All-In-One: Advanced preparation of Human Parenchymal and Non-Parenchymal Liver Cells

Background & Aims

Liver cells are key players in innate immunity. Thus, studying primary isolated liver cells is necessary for determining their role in liver physiology and pathophysiology. In particular, the quantity and quality of isolated cells are crucial to their function. Our aim was to isolate a large quantity of high-quality human parenchymal and non-parenchymal cells from a single liver specimen.

Methods

Hepatocytes, Kupffer cells, liver sinusoidal endothelial cells, and stellate cells were isolated from liver tissues by collagenase perfusion in combination with low-speed centrifugation, density gradient centrifugation, and magnetic-activated cell sorting. The purity and functionality of cultured cell populations were controlled by determining their morphology, discriminative cell marker expression, and functional activity.

Results

Cell preparation yielded the following cell counts per gram of liver tissue: 2.0±0.4×10⁷ hepatocytes, 1.8±0.5×10⁶ Kupffer cells, 4.3±1.9×10⁵ liver sinusoidal endothelial cells, and 3.2±0.5×10⁵ stellate cells. Hepatocytes were identified by albumin (95.5±1.7%) and exhibited time-dependent activity of cytochrome P450 enzymes. Kupffer cells expressed CD68 (94.5±1.2%) and exhibited phagocytic activity, as determined with 1μm latex beads. Endothelial cells were CD146⁺ (97.8±1.1%) and exhibited efficient uptake of acetylated low-density lipoprotein. Hepatic stellate cells were identified by the expression of α-smooth muscle actin (97.1±1.5%). These cells further exhibited retinol (vitamin A)-mediated autofluorescence.

Conclusions

Our isolation procedure for primary parenchymal and non-parenchymal liver cells resulted in cell populations of high purity and quality, with retained physiological functionality in vitro. Thus, this system may provide a valuable tool for determining liver function and disease.     

Subcellular localization of iron and heme metabolism related proteins at early stages of erythrophagocytosis

Background

Senescent red blood cells (RBC) are recognized, phagocytosed and cleared by tissue macrophages. During this erythrophagocytosis (EP), RBC are engulfed and processed in special compartments called erythrophagosomes. We previously described that following EP, heme is rapidly degraded through the catabolic activity of heme oxygenase (HO). Extracted heme iron is then either exported or stored by macrophages. However, the cellular localization of the early steps of heme processing and iron extraction during EP remains to be clearly defined.

Methodology/Principal Findings

We took advantage of our previously described cellular model of EP, using bone marrow-derived macrophages (BMDM). The subcellular localization of both inducible and constitutive isoforms of HO (HO-1 and HO-2), of the divalent metal transporters (Nramp1, Nramp2/DMT1, Fpn), and of the recently identified heme transporter HRG-1, was followed by fluorescence and electron microscopy during the earliest steps of EP. We also looked at some ER [calnexin, glucose-6-phosphatase (G6Pase) activity] and lysosomes (Lamp1) markers during EP. In both quiescent and LPS-activated BMDM, Nramp1 and Lamp1 were shown to be strong markers of the erythrophagolysosomal membrane. HRG-1 was also recruited to the erythrophagosome. Furthermore, we observed calnexin labeling and G6Pase activity at the erythrophagosomal membrane, indicating the contribution of ER in this phagocytosis model. In contrast, Nramp2/DMT1, Fpn, HO-1 and HO-2 were not detected at the membrane of erythrophagosomes.

Conclusions/Significance

Our study highlights the subcellular localization of various heme- and iron-related proteins during early steps of EP, thereby suggesting a model for heme catabolism occurring outside the phagosome, with heme likely being transported into the cytosol through HRG1. The precise function of Nramp1 at the phagosomal membrane in this model remains to be determined.     

Induction of hepatic heme oxygenase activity by bromobenzene

Hepatic heme oxygenase, an enzyme which converts heme to carbon monoxide and bile pigment in vitro, is inducible by heme but also by large “toxic” doses of such nonheme substances as hormones, endotoxin, and heavy metal ions. When we gave rats a single hepatotoxic dose of allyl alcohol, ethionine, acetaminophen, furosemide, or endotoxin, hepatic heme oxygenase activity rose modestly (two- to fivefold) after 20 h. In contrast, administration of bromobenzene (5 mmol/kg) induced heme oxygenase in the liver an average of 15-fold after 20 h but was without effect on the enzyme in the kidney or spleen. The change in heme oxygenase was accompanied by a loss in cytochrome P-450 concentration and, in rats labeled with 5-δ-amino[¹⁴C]levulinic acid, an increased rate of degradation of hepatic [¹⁴C]heme to ¹⁴CO. Induction of heme oxygenase by bromobenzene was blocked by cycloheximide, an inhibitor of protein synthesis, but not by actinomycin D, an inhibitor of RNA synthesis. This suggests that bromobenzene stimulates de novo enzyme synthesis at the step of translation. Subtoxic doses of bromobenzene (less than 1 mmol/kg) gave proportionately greater induction of heme oxygenase. Furthermore, induction of the enzyme remained unaffected when bromobenzene hepatotoxicity was blocked by pretreatment of rats with SKF-525A, 3-methylcholanthrene, or cysteine (which supplements liver sulfhydryl content), or when hepatotoxicity was enhanced by pretreatment with phenobarbital or with diethylmaleate (which depletes hepatic glutathione). These data suggest that with induction of heme oxygenase by bromobenzene, neither liver cell necrosis nor alteration in hepatic sulfhydryl metabolism is indispensible. The latter characteristic differs from induction of the enzyme by metal ions in which depletion of sulfhydryl-containing constituents has been thought to be essential. We conclude that bromobenzene is a novel inducer of heme oxygenase activity in the liver, differing from other nonheme substances in potency and specificity for the liver, and in utilizing mechanism(s) which require neither production of hepatotoxicity, depletion of hepatic glutathione, nor sensitivity to actinomycin D.     

Cytochrome P-450 heme and the regulation of hepatic heme oxygenase activity

The degradation of cytochrome P-450 heme in the liver has been studied by a new approach. In rats, hepatic heme was labeled by administration of a tracer pulse of [5-¹⁴C]δ-aminolevulinic acid (ALA), and its degradation was analyzed in terms of labeled carbon monoxide (¹⁴CO) excretion, which is a specific degradation product of the labeled heme. Within minutes after administration of [5-¹⁴C]ALA, 14CO was detectable and increased after 2 h to an “early peak,” reflecting the elimination of labeled heme from a rapidly turning over pool in the liver. Beyond the early peak, the rate of ¹⁴CO production decreased in a log-linear manner, consistent with the degradation of heme in stable hepatic hemoproteins. From the rate at which ¹⁴CO production declined during this phase, from the predominant labeling of cytochrome P-450 heme by the administered [5-¹⁴C]ALA and from the known turnover characteristics of this hemoprotein in the liver, it could be inferred that production of ¹⁴CO—between 16 and 30 h after administration of labeled ALA—largely reflected degradation of cytochrome P-450 heme. This approach, which permits serial measurements in a single animal, was used to study the effect on cytochrome P-450 heme of administered heme or endotoxin, both of which are potent stimulators of hepatic heme oxygenase activity. Both of these substances caused marked acceleration of the degradation of cytochrome P-450 heme, the effect occurring over the same dose range as that for stimulation of hepatic heme oxygenase. The findings suggest that stimulation of this enzyme activity in the liver is closely related to the rate of degradation of cytochrome P-450 heme.     

In Vitro Generation of Functional Liver Organoid-Like Structures Using Adult Human Cells

In this study we used differentiated adult human upcyte^® cells for the in vitro generation of liver organoids. Upcyte^® cells are genetically engineered cell strains derived from primary human cells by lenti-viral transduction of genes or gene combinations inducing transient proliferation capacity (upcyte^® process). Proliferating upcyte^® cells undergo a finite number of cell divisions, i.e., 20 to 40 population doublings, but upon withdrawal of proliferation stimulating factors, they regain most of the cell specific characteristics of primary cells. When a defined mixture of differentiated human upcyte^® cells (hepatocytes, liver sinusoidal endothelial cells (LSECs) and mesenchymal stem cells (MSCs)) was cultured in vitro on a thick layer of Matrigel™, they self-organized to form liver organoid-like structures within 24 hours. When further cultured for 10 days in a bioreactor, these liver organoids show typical functional characteristics of liver parenchyma including activity of cytochromes P450, CYP3A4, CYP2B6 and CYP2C9 as well as mRNA expression of several marker genes and other enzymes. In summary, we hereby describe that 3D functional hepatic structures composed of primary human cell strains can be generated in vitro. They can be cultured for a prolonged period of time and are potentially useful ex vivo models to study liver functions.     

Distribution of hepatic phosphofructokinase isozymes in parenchymal and sinusoidal cells.

The distribution profile of the isozymes of phosphofructokinase (PFK) in different cell types of rat liver is established using the techniques of electrophoresis and immunodiffusion. Agarose gel electrophoresis of the extracts of parenchymal cells, Kupffer or sinusoidal cells, and whole liver indicated that two PFK isozymes are present in whole liver and that the faster moving hepatic PFK isozyme is present only in parenchymal cells; whereas, the slower moving hepatic PFK isozyme is only in sinusoidal cells. Immunodiffusion studies using antiserum specific for the major hepatic PFK isozyme (PFK-L₂) revealed that PFK-L₂ is present only in whole liver or parenchymal cell extracts and is absent from sinusoidal cells. It is apparent that the other hepatic PFK isozyme (PFK-L₁) is normally found only in sinusoidal cells.     

小鼠肝血窦内皮细胞分离与鉴定新方法

目的:改进小鼠原代肝血窦内皮细胞的分离方法。方法:经过小鼠肝脏的原位灌洗、消化制备单细胞悬液、差速离心、密度梯度离心以及免疫磁珠分选等步骤,分离获得小鼠原代肝血窦内皮细胞,再通过流式细胞仪鉴定、细胞内吞功能染色以及对细胞超微结构的电子显微镜观察,对分离出的肝血窦内皮细胞进行鉴定。结果:肝血窦内皮细胞的平均得率为5.6×10~6个/只小鼠,细胞活性比率约为96%左右;细胞流式鉴定结果显示新鲜分离出的肝血窦内皮细胞VEGFR3阳性率达到95.8%,VEGFR2+CD31+双阳性细胞阳性率达到93.7%。分选出的LSECs能够有效吞噬FITC-FSA和Dil-Ac-LDL。培养1天后肝血窦内皮细胞的微观结构,可见其特征性的窗孔和筛板。结论:本文总结的分离方法可以稳定、高效地获得小鼠原代肝血窦内皮细胞。     

δ-aminolevulinic acid transport and synthesis,porphyrin synthesis and heme catabolism in chick embryo liver and heart cells

Liver and heart represent two organs with markedly different needs for heme as related to their metabolic roles. To examine these diferences chick embryo heart and liver cells were compared with respect to transport of δ-aminolevulinic acid and activity of δ-aminolevulinic acid synthetase, porphyrin synthesis and heme oxygenase. Heart cells were found to have a low rate of δ-aminolevulinic acid uptake, a high resting level of δ-aminolevulinic acid synthetase activity and a lower level of heme oxygenase activity as compared with liver cells. The hepatic cell uptake of δ-aminolevulinic acid was 6–25-times that of heart cells. The embryonal heart cell appears to be a balanced autonomous system for the synthesis and degradation of heme. The embryonal liver cell represents a cell system permeable to exogenous δ-aminolevulinic acid, which is also responsive to and inducible by external stimuli.     

Seven Steps to Stellate Cells

Hepatic stellate cells are liver-resident cells of star-like morphology and are located in the space of Disse between liver sinusoidal endothelial cells and hepatocytes^1,2. Stellate cells are derived from bone marrow precursors and store up to 80% of the total body vitamin A^{1, 2}. Upon activation, stellate cells differentiate into myofibroblasts to produce extracellular matrix, thus contributing to liver fibrosis³. Based on their ability to contract, myofibroblastic stellate cells can regulate the vascular tone associated with portal hypertension⁴. Recently, we demonstrated that hepatic stellate cells are potent antigen presenting cells and can activate NKT cells as well as conventional T lymphocytes⁵. Here we present a method for the efficient preparation of hepatic stellate cells from mouse liver. Due to their perisinusoidal localization, the isolation of hepatic stellate cells is a multi-step process. In order to render stellate cells accessible to isolation from the space of Disse, mouse livers are perfused in situ with the digestive enzymes Pronase E and Collagenase P. Following perfusion, the liver tissue is subjected to additional enzymatic treatment with Pronase E and Collagenase P in vitro. Subsequently, the method takes advantage of the massive amount of vitamin A-storing lipid droplets in hepatic stellate cells. This feature allows the separation of stellate cells from other hepatic cell types by centrifugation on an 8% Nycodenz gradient. The protocol described here yields a highly pure and homogenous population of stellate cells. Purity of preparations can be assessed by staining for the marker molecule glial fibrillary acidic protein (GFAP), prior to analysis by fluorescence microscopy or flow cytometry. Further, light microscopy reveals the unique appearance of star-shaped hepatic stellate cells that harbor high amounts of lipid droplets. Taken together, we present a detailed protocol for the efficient isolation of hepatic stellate cells, including representative images of their morphological appearance and GFAP expression that help to define the stellate cell entity.Download video file.^{(41M, mov)}     

Ultrastructural and functional study of the liver pigment cells from Rana esculenta L.

Summary A study of the liver pigment cells of Rana esculenta L. has been performed on both liver in toto and cells in culture. Ultrastructural and cytochemical analyses showed a close relationship between this visceral pigment cell system and the cells of hepatic macrophage lineage. Like the latter, the liver pigment cells present phagocytic activity, in the sinusoids and in vitro, and give a positive response to tests for peroxidase and lipase. The liver pigment cells are isolated, together with the Kupffer cells, from the sinusoidal cell fraction of the liver. In culture, they maintain their melanogenetic ability, demonstrated by the presence of dopaoxidase activity in the soluble, membranous, and melanosome fractions. Analysis of the cultures showed that as culture time increased, so did melanosome dopaoxidase activity, the number of pigmented fields, and the level of pigmentation of the cells. The values of dopaoxidase activity of the pigment cells in culture show the same seasonal oscillations as the system in toto, indicating that the cells maintain an internal clock, at least in the first 72 h of culture. There is evidence that the pigment cells are macrophages which can express a melanogenetic function. Our results and other experimental data provide a basis for hypothesizing that the pigment cells in Rana esculenta L. liver may derive from, or have a common origin with, the Kupffer cells.     

Matrix Metalloproteinase-2 (MMP-2) Gene Deletion Enhances MMP-9 Activity,Impairs PARP-1 Degradation,and Exacerbates Hepatic Ischemia and Reperfusion Injury in Mice

Hepatic ischemia and reperfusion injury (IRI) is an inflammatory condition and a significant cause of morbidity and mortality after surgery. Matrix metalloproteinases (MMPs) have been widely implicated in the pathogenesis of inflammatory diseases. Among the different MMPs, gelatinases (MMP-2 and MMP-9) are within the most prominent MMPs detected during liver IRI. While the role of MMP-9 in liver damage has been fairly documented, direct evidence of the role for MMP-2 activity in hepatic IRI remains to be established. Due to the lack of suitable inhibitors to target individual MMPs in vivo, gene manipulation is as an essential tool to assess MMP direct contribution to liver injury. Hence, we used MMP-2^-/- deficient mice and MMP-2^+/+ wild-type littermates to examine the function of MMP-2 activity in hepatic IRI. MMP-2 expression was detected along the sinusoids of wild-type livers before and after surgery and in a small population of leukocytes post-IRI. Compared to MMP-2^+/+ mice, MMP-2 null (MMP-2^-/-) mice showed exacerbated liver damage at 6, 24, and 48 hours post-reperfusion, which was fatal in some cases. MMP-2 deficiency resulted in upregulation of MMP-9 activity, spontaneous leukocyte infiltration in naïve livers, and amplified MMP-9-dependent transmigration of leukocytes in vitro and after hepatic IRI. Moreover, complete loss of MMP-2 activity impaired the degradation of poly (ADP-ribose) polymerase (PARP-1) in extensively damaged livers post-reperfusion. However, the administration of a PARP-1 inhibitor to MMP-2 null mice restored liver preservation to almost comparable levels of MMP-2^+/+ mice post-IRI. Deficient PARP-1 degradation in MMP-2-null sinusoidal endothelial cells correlated with their increased cytotoxicity, evaluated by the measurement of LDH efflux in the medium. In conclusion, our results show for the first time that MMP-2 gene deletion exacerbates liver IRI. Moreover, they offer new insights into the MMP-2 modulation of inflammatory responses, which could be relevant for the design of new pharmacological MMP-targeted agents to treat hepatic IRI.     

Intravascular Immune Surveillance by CXCR6+ NKT Cells Patrolling Liver Sinusoids

We examined the in vivo behavior of liver natural killer T cells (NKT cells) by intravital fluorescence microscopic imaging of mice in which a green fluorescent protein cDNA was used to replace the gene encoding the chemokine receptor CXCR6. NKT cells, which account for most CXCR6⁺ cells in liver, were found to crawl within hepatic sinusoids at 10–20 μm/min and to stop upon T cell antigen receptor activation. CXCR6-deficient mice exhibited a selective and severe reduction of CD1d-reactive NKT cells in the liver and decreased susceptibility to T-cell-dependent hepatitis. CXCL16, the cell surface ligand for CXCR6, is expressed on sinusoidal endothelial cells, and CXCR6 deficiency resulted in reduced survival, but not in altered speed or pattern of patrolling of NKT cells. Thus, NKT cells patrol liver sinusoids to provide intravascular immune surveillance, and CXCR6 contributes to liver-based immune responses by regulating their abundance.     

Early labeled heme synthesis in normal rats and rats with iron deficiency anemia

Heme synthesis from [2-¹⁴C]glycine was studied in liver and red blood cells. In normal rats liver contained two early [¹⁴C] heme peaks maximal at 1 and 4.5 h, followed by a long plateau of heme labeling. These phases were present in both microsomes and mitochondria. Cycloheximide suppressed formation of the first but not the second heme component. All phases of hepatic heme labelling were reduced in iron-deficient rats, with better preservation of the microsomal fraction. In iron-deficient rats responding to iron therapy, the first peak merged with an enlarged and premature second component; the increase was most marked in mitochondria. Thus, labeled heme metabolism was less perturbed in microsomes than mitochondria in both of these conditions. Peripheral blood also contained a [¹⁴C]heme peak at 1 h in all experimental groups. This was highest with the increased eythroid response observed in irontreated rats. The first heme peak, present in both hepatic and erythroid cells, may represent a pool of free or unassigned heme. The later heme component may reflect formation of hemoproteins, which could be related directly or indirectly to the initial, rapid turnover heme component.     

Intravascular immune surveillance by CXCR6+ NKT cells patrolling liver sinusoids

We examined the in vivo behavior of liver natural killer T cells (NKT cells) by intravital fluorescence microscopic imaging of mice in which a green fluorescent protein cDNA was used to replace the gene encoding the chemokine receptor CXCR6. NKT cells, which account for most CXCR6⁺ cells in liver, were found to crawl within hepatic sinusoids at 10–20 μm/min and to stop upon T cell antigen receptor activation. CXCR6-deficient mice exhibited a selective and severe reduction of CD1d-reactive NKT cells in the liver and decreased susceptibility to T-cell-dependent hepatitis. CXCL16, the cell surface ligand for CXCR6, is expressed on sinusoidal endothelial cells, and CXCR6 deficiency resulted in reduced survival, but not in altered speed or pattern of patrolling of NKT cells. Thus, NKT cells patrol liver sinusoids to provide intravascular immune surveillance, and CXCR6 contributes to liver-based immune responses by regulating their abundance.     

Cell-passage activity is required for the malarial parasite to cross the liver sinusoidal cell layer

Liver infection is an obligatory step in malarial transmission, but it remains unclear how the sporozoites gain access to the hepatocytes, which are separated from the circulatory system by the liver sinusoidal cell layer. We found that a novel microneme protein, named sporozoite microneme protein essential for cell traversal (SPECT), is produced by the liver-infective sporozoite of the rodent malaria parasite, Plasmodium berghei. Targeted disruption of the spect gene greatly reduced sporozoite infectivity to the liver. In vitro cell invasion assays revealed that these disruptants can infect hepatocytes normally but completely lack their cell passage ability. Their apparent liver infectivity was, however, restored by depletion of Kupffer cells, hepatic macrophages included in the sinusoidal cell layer. These results show that malarial sporozoites access hepatocytes through the liver sinusoidal cell layer by cell traversal motility mediated by SPECT and strongly suggest that Kupffer cells are main routes for this passage. Our findings may open the way for novel malaria transmission-blocking strategies that target molecules involved in sporozoite migration to the hepatocyte.     

Transcriptome atlas of glutamine family amino acid metabolism‐related genes in eight regenerating liver cell types

To explore glutamine family amino acid metabolism of eight liver cell types in rat liver regeneration, eight kinds of rat regenerating liver cells were isolated by using the combination of Percoll density gradient centrifugation and immunomagnetic bead methods, then Rat Genome 230 2.0 Array was used to detect the expression profiles of the genes associated with metabolism of glutamine family amino acid in rat liver regeneration and finally how these genes involved in activities of eight regenerating liver cell types were analysed by the methods of bioinformatics and systems biology. The results showed that in the priming stage of liver regeneration, hepatic stellate cells and sinusoidal endothelial cells transformed proline and glutamine into glutamate; hepatocytes, hepatic stellate cells, sinusoidal endothelial cells and dendritic cells catabolized glutamate to 2‐oxoglutarate or succinate; hepatic stellate cells and sinusoidal endothelial cells catalysed glutamate into glutamyl‐tRNA for protein synthesis; urea cycle, which degraded from arginine, was enhanced in biliary epithelia cells, sinusoidal endothelial cells and dendritic cells; synthesis of polyamines from arginine was enhanced in biliary epithelia cells, sinusoidal endothelial cells, Kupffer cells and dendritic cells; the content of NO was increased in sinusoidal endothelial cells and dendritic cells; degradation of proline was enhanced in hepatocytes and biliary epithelia cells. In the progress stage, biliary epithelia cells converted glutamine into GMP and glucosamine 6‐phosphate; oval cells converted glutamine into glucosamine 6‐phosphate; hepatic stellate cells converted glutamine into NAD; the content of NO, which degraded from arginine, was increased in biliary epithelia cells, oval cells, pit cells and dendritic cells. In the termination stage, oval cells converted proline into glutamate; glutamate degradation, which degraded from arginine, was enhanced in hepatocytes and dendritic cells; the content of NO was increased in oval cells, sinusoidal endothelial cells, pit cells and dendritic cells. The synthesis of creatine phosphate was enhanced in hepatocytes, biliary epithelia cells, pit cells and dendritic cells in both progress and termination stages. In summary, glutamine family amino acid metabolism has some differences in liver regeneration in different liver cells.     

Differential cellular and subcellular localization of heme-binding protein 23/peroxiredoxin I and heme oxygenase-1 in rat liver.

Heme-binding protein 23 (HBP23), also termed peroxiredoxin (Prx) I, and heme oxygenase-1 (HO-1) are distinct antioxidant stress proteins that are co-ordinately induced by oxidative stress. HBP23/Prx I has thioredoxin-dependent peroxidase activity with high binding affinity for the pro-oxidant heme, while HO-1 is the inducible isoform of the rate-limiting enzyme of heme degradation. We investigated the cellular and subcellular localization of both proteins in rat liver. Whereas by immunohistochemistry (IHC) a uniformly high level of HBP23/Prx I expression was observed in liver parenchymal and different sinusoidal cells, HO-1 expression was restricted to Kupffer cells. By immunoelectron microscopy using the protein A-gold technique, HBP23/Prx I immunoreactivity was detected in cytoplasm, nuclear matrix, mitochondria, and peroxisomes of parenchymal and non-parenchymal liver cell populations. In contrast, the secretory pathway, i.e., the endoplasmic reticulum and Golgi complex, was free of label. As determined by immunocytochemical (ICC) studies in liver cell cultures and by Western and Northern blotting analysis, HBP23/Prx I was highly expressed in cultures of isolated hepatocytes and Kupffer cells. In contrast, HO-1 was constitutively expressed only in Kupffer cell cultures but was also inducible in hepatocytes. These data suggest that HBP23/Prx I and HO-1 may have complementary antioxidant functions in different cell populations in rat liver.     

Maturation of rat dendritic cells during intrahepatic translocation evaluated using monoclonal antibodies and electron microscopy

Specific populations of hepatic sinusoidal cells were stained with monoclonal antibodies that recognize monocytes/macrophages (ED1), tissue macrophages (Kupffer cells) (ED2), MHC class II (Ia) antigen (MRC OX6), and dendritic cells/γ,δ T-cells (MRC OX62) and analyzed by light and electron microscopy. The majority of ED1⁺ and/or ED2⁺ cells were localized to the hepatic parenchyma, whereas OX6⁺ and/or OX62⁺ cells were more densely distributed within Glisson’s sheath than in the hepatic parenchyma. Double-immunoperoxidase staining of normal liver for ED1, ED2, and OX6 identified dendritic cells (DC) of two different phenotypes, ED1⁺ED2^–OX6⁺ and ED1^–ED2^–OX6⁺. DC can be classified into three different types based on ultrastructural characteristics. The first type (type I) is characterized by one or more long cytoplasmic processes and a well-developed lysosomal system. The second type (type II) has an inconspicuous lysosomal system, abundant hyaloplasm, and characteristic short cytoplasmic processes. The third type (type I–II) has cytologic features intermediate between those of type I and type II DC. At the electron-microscopic level, these three cell types are found in the sinusoidal lumen, whereas the majority of type II DC are located in the space of Disse and Glisson’s sheath. Furthermore, some OX6-labeled elongated DC appeared to traverse the lumen of sinusoids through endothelial pores to enter the space of Disse. One hour after intravenous injection of latex particles (0.81 μm in diameter), numerous latex-laden dendritic cells (ED1⁺OX6⁺, type I and type I–II) were detected in the lumen of hepatic sinusoids, but not in the space of Disse or Glisson’s sheath. These findings suggest that normal rat liver contains resident dendritic cells which downregulate phagocytic activity and mature into potent accessory cells during migration from the portal vein toward the central vein. These DC then traverse the sinusoidal lumen to the hepatic lymph system via the space of Disse. Received: 8 May 1998 / Accepted: 15 June 1998     

Tri-iodothyronine differentially induces Kupffer cell ED1/ED2 subpopulations

Thyroid calorigenesis is carried out by activation of cytochrome-c oxidase, as well as by induction of mitochondrial and nuclear genes that code for cell respiratory apparatus components and uncoupling proteins. These effects operate increments in basal metabolic rate and also lead to increased production of oxygen and nitrogen reactive species in liver parenchymal cells. The hepatic antioxidant system is also compromised, since superoxide dismutase and catalase activities, glutathione content and lipid soluble antioxidants are reduced. Liver macrophages contribute to the hepatic oxidative stress observed in T(3)-treated rats, and both Kupffer cell hyperplasia and hypertrophy are reported. Kupffer cells constitute the main fixed macrophage population in the body and are a heterogeneous group of cells, derived from a less numerous population of local precursors, which are morphologically fairly distinguishable from the mature lineage elements. ED1 and ED2 antigens have been particularly useful in the characterization of Kupffer cell subpopulations. In particular, antibodies against these antigens provided evidence that T(3)- induced Kupffer cell hyperplasia causes a shift on liver macrophage population phenotype, leaning towards younger cell types. Despite the fact that sinusoidal environment itself stimulates the proliferation of macrophage precursors and their differentiation into Kupffer cells, increased Kupffer cell turnover rates modify the sinusoidal environment and may imply further functional effects. Thus, Kupffer cell hyperplasia secondary to increased T(3) levels is potentially a pro-inflammatory event, which involves both, the expansion of Kupffer cell precursor population by means of circulating monocyte recruitment, and the differentiation of preexisting local Kupffer cell precursors into mature liver macrophages.