BETA-glucuronidase and chloroacetate-esterase staining discriminates rat liver sinusoidal endothelial cells from Kupffer cells in primary culture

Beta-glucuronidase and N-AS-D-chloroacetate esterase cytochemistry have been applied to rat liver sinusoidal endothelial cells and Kupffer cells. Both staining procedures allowed a clear-cut differentiation of either cell type. Kupffer cells which had been stained with beta-glucuronidase showed a positive reaction, whereas sinusoidal endothelial cells were completely negative. If the chloroacetate reaction was used, the former stained diffusely while the latter showed a characteristic granular staining pattern. Identity and purity of sinusoidal endothelial cells and Kupffer cells was validated by transmission and scanning electron microscopy as well as by the pattern of released eicosanoids which is characteristic for either cell type. These two staining techniques are a valuable addition to the peroxidase reaction commonly applied for differentiation.     

利用NASH大鼠原代肝细胞与原代Kupffer细胞共培养建立NASH原代细胞模型*

目的: 通过分离并提纯非酒精性脂肪性肝炎(NASH)大鼠原代肝细胞以及原代Kupffer细胞建立体外NASH原代细胞模型,为研究NASH提供可靠的细胞实验技术支持。方法: 选择SD大鼠40只,随机分为2组(n=20):对照组和NASH组,对照组大鼠利用普通饲料喂养,NASH组大鼠利用高脂饲料(88%基础饲料+10%猪油+ 2%胆固醇)喂养,6～8周后,利用NASH评分表,病理观察下肝组织切片脂肪变+小叶内炎症+气球样变评分≥4 分,表明大鼠NASH模型的成功建立,利用胶原酶原位灌注法分离并提纯NASH模型大鼠原代肝细胞以及原代Kupffer细胞,利用CK-18及CD68免疫荧光以及墨汁吞墨实验进行细胞鉴定,利用油红O染色、试剂盒测定谷丙转氨酶(ALT)、谷草转氨酶(AST)含量观察NASH大鼠原代肝细胞脂质累积和肝功情况,Western blot检测原代Kupffer细胞炎症因子表达情况,最后采用原代肝细胞:原代Kupffer细胞=6∶1比例共培养,显微镜下观察细胞状态。结果: 实验成功分离并提纯NASH原代肝细胞以及原代Kupffer细胞,通过油红O染色,NASH组大鼠原代肝细胞存在明显的脂肪沉积,且NASH组大鼠原代肝细胞中AST、ALT明显高于对照组,存在明显肝损伤(P＜0.05),Western blot测定原代Kupffer细胞TNF-α、IL-1β以及MCP-1,NASH组大鼠明显高于对照组(P＜0.05)。结论: 通过胶原酶原位灌注法可以成功分离NASH大鼠原代肝细胞以及原代Kupffer细胞,同时成功建立比例共培养大鼠体外原代细胞NASH模型。     

Kupffer Cell Isolation for Nanoparticle Toxicity Testing

The large majority of in vitro nanotoxicological studies have used immortalized cell lines for their practicality. However, results from nanoparticle toxicity testing in immortalized cell lines or primary cells have shown discrepancies, highlighting the need to extend the use of primary cells for in vitro assays. This protocol describes the isolation of mouse liver macrophages, named Kupffer cells, and their use to study nanoparticle toxicity. Kupffer cells are the most abundant macrophage population in the body and constitute part of the reticulo-endothelial system (RES), responsible for the capture of circulating nanoparticles. The Kupffer cell isolation method reported here is based on a 2-step perfusion method followed by purification on density gradient. The method, based on collagenase digestion and density centrifugation, is adapted from the original protocol developed by Smedsrød et al. designed for rat liver cell isolation and provides high yield (up to 14 x 10⁶ cells per mouse) and high purity (>95%) of Kupffer cells. This isolation method does not require sophisticated or expensive equipment and therefore represents an ideal compromise between complexity and cell yield. The use of heavier mice (35-45 g) improves the yield of the isolation method but also facilitates remarkably the procedure of portal vein cannulation. The toxicity of functionalized carbon nanotubes f-CNTs was measured in this model by the modified LDH assay. This method assesses cell viability by measuring the lack of structural integrity of Kupffer cell membrane after incubation with f-CNTs. Toxicity induced by f-CNTs can be measured consistently using this assay, highlighting that isolated Kupffer cells are useful for nanoparticle toxicity testing. The overall understanding of nanotoxicology could benefit from such models, making the nanoparticle selection for clinical translation more efficient.     

Isolation and culture of rat embryonic neural cells: a quick protocol

We are describing a quick method to dissociate and culture hippocampal or cortical neurons from E15-17 rat embryos. The procedure can be applied successfully to the isolation of mouse and human primary neurons and neural progenitors. Dissociated neurons are maintained in serum-free medium up to several weeks. These cultures can be used for nucleofection, immunocytochemistry, nucleic acids preparation, as well as electrophysiology. Older neuronal cultures can also be transfected with a good efficiency rate by lentiviral transduction and, less efficiently, with calcium phosphate or lipid-based methods such as lipofectamine.     

The fate of lipopolysaccharide in cultured rat Kupffer cells

Cultured rat Kupffer cells were incubated in presence of biologically tritiated Salmonella abortus equi lipopolysaccharide. Uptake of lipopolysaccharide increased rapidly during the first 2 h of incubation and then levelled off. Within the first h of incubation 10(6) Kupffer cells were able to ingest up to 18 micrograms lipopolysaccharide. Kupffer cells metabolised lipopolysaccharide and released lipopolysaccharide-related substances, but neither the cell-associated lipopolysaccharide nor the released lipopolysaccharide products were detoxified, as measured by the mouse lethality test.     

Ischaemic preconditioning modulates the activity of Kupffer cells during in vivo reperfusion injury of rat liver

This work was performed to elucidate further the main cellular events underlying the protective effect of ischaemic preconditioning in an in vivo rat liver model of 90 min ischaemia followed by 30 min reperfusion. A significant attenuation of the various aspects of post-ischaemic injury, namely necrosis and the levels of hydrogen peroxide and 5- and 15-hydroperoxyeicosatetraenoic acids, was afforded by the prior application of a short cycle of ischaemia/reperfusion (10 + 10 min) or when rats were previously treated with gadolinium chloride. However, when preconditioning was applied on Kupffer cell-depleted livers, no additional level of ischaemic tolerance was obtained. In terms of cellular pathology, this result could be suggestive of Kupffer cells as the target of the preconditioning phenomenon during the warm ischaemia/reperfusion injury. Accordingly, modulation of Kupffer cell activity was associated with a well-preserved hepatocyte integrity, together with low levels of pro-oxidant generation during reperfusion. As activated Kupffer cells can generate and release potentially toxic substances, their modulation by ischaemic preconditioning could help to provide new surgical and/or pharmacological strategies to protect the liver against reperfusion damage.     

Characterization of rat and human Kupffer cells after cryopreservation

Kupffer cells (KC) are the resident macrophages of the liver and represent about 80% of the total fixed macrophage population. They are involved in disease states such as endotoxin shock, alcoholic liver diseases and other toxic-induced liver injury. They release physiologically active substances such as eicosanoids and inflammatory cytokines (IL-1, IL-6, TNFalpha), and produce free radical species. Thus, KC are attractive targets for anti-inflammatory therapies and potential candidates responsible for differences in inflammation in liver disease seen between different individuals. However, to perform parallel in vitro experiments with KC from different donors a suitable method for conservation of KC would be necessary. Therefore, the present study evaluated, whether rat and human KC can be frozen, stored and recovered without losing their functional integrity. Rat and human KC were isolated and either cultured under standard conditions (fresh KC) or cryopreserved in special freezing medium (cryopreserved KC). At least 24 h later, cryopreserved KC were thawed, brought into suspension and seeded in the same density as fresh cells for subsequent experiments. Viability of cultured KC was analyzed by trypan blue exclusion. LPS (or PBS as control) stimulation was performed at different time points and cytokine release was analyzed with IL-6 and TNFalpha ELISAs, respectively. Phagocytic capacity was investigated by using a specific phagocytosis assay and FACS analysis. The recovery rate after thawing was around 57% for rat and around 65% for human cryopreserved KC. The results indicate, that KC can successfully be cryopreserved with an adequate recovery rate of viable cells. The properties of fresh and frozen KC can also be compared after thawing. Freshly isolated and cryopreserved cultured KC showed near-normal morphology and did not differ in the cultivation profiles over a period of 72 h. One to three days after seeding, frozen rat or human KC also retained inducible functions such as the production of TNFalpha or IL-6 after LPS challenge. Finally, regardless if they were cryopreserved or not, no differences in the phagocytic activities of the cells were obtained. Taken together, it is concluded that cryopreservation of KC does not change the physiological characteristics of the cells in vitro. Therefore, the method used here for cryopreservation of especially human KC allows the accumulation of KC from several donors for parallel in vitro experiments.     

Identification of G6PDH-active sinusoidal cells as Kupffer cells in the rat liver

Summary The aim of this study was to identify the G6PDH-active sinusoidal cells in the rat liver described by Rieder et al. (1978). Because of their number and distribution in the liver parenchyma, endothelial cells and pit cells could be excluded. Fat-storing cells were specifically marked by vital staining with vitamin A and identified by fluorescence microscopy. Kupffer cells could be detected after vital staining with carmine. Both staining methods allowed a subsequent incubation for the demonstration of G6PDH activity in the same unfixed cryostat section. Whereas more than 80% of the fluorescent particles were found outside the enzyme-positive cells, all G6PDH-active cells contained carmine particles. After counting the G6PDH-active cells, an estimation of 0.217 × 10⁸ cells/g liver tissue was obtained. The results indicate that high G6PDH activity is common to all Kupffer cells, and is therefore a highly specific marker enzyme for this class of sinusoidal liver cells.The essential parts of this study will be presented as an Inaugural-Dissertation to the Medical Faculty of the University of Freiburg by W. HosemannSupported by a grant from the SFB 46 (Molgrudent)     

小鼠Kupffer细胞分离及细胞培养

目的 采用在体胶原酶灌注、不连续密度梯度离心、选择性贴壁3步法分离Kupffer细胞（Kupffer cells,KCs）,探讨其在分离小鼠KCs的应用及其对KCs生物活性的影响.方法 根据原位灌注和梯度离心方法不同随机分为4组：无胶原酶原位灌注＋3层梯度离心组（A）、无胶原酶原位灌注＋双层梯度离心组（B）、胶原酶原位灌注＋3层梯度离心组（C）和胶原酶原位灌注＋双层梯度离心组（D）.采用F4/80（BM8）免疫染色及吞墨实验判断细胞纯度和功能、台盼蓝拒染实验判断细胞的活力,探讨不同方法KCs分离的效果及细胞活性.结果 刚分离的KCs细胞近似圆形,接种l h后收获细胞纯度较高,但细胞得率相对较低.培养4 h后KCs得率相对较高,培养28 d仍能存活.免疫荧光可显示分离的为KCs,台盼蓝染色显示各组细胞的活力均在90 %左右,在体胶原酶灌注和双层梯度离心可以增加KCs的得率,双层梯度离心法可以增加分离KCs的纯度.结论 在体胶原酶灌注对提高KCs得率较为重要,在体胶原酶灌注、不连续密度梯度离心、选择性贴壁3步法分离小鼠KCs的的方法简便、高效、稳定,培养的KCs具有良好的细胞生物学性状.     

Enhanced tumour growth in the rat liver after selective elimination of Kupffer cells

The evidence that Kupffer cells are capable of controlling metastatic growth in the liver in vivo is largely circumstantial. The best approach when studying natural cytotoxicity activities of Kupffer cells is to investigate the effect of Kupffer cell elimination on tumour growth. Until now it has not been possible to eliminate Kupffer cells without affecting other cell populations. We have recently developed a new method to eliminate Kupffer cells selectively: intravenous injection of liposome-encapsulated (dichloromethylene)bisphosphonate (Cl₂MDP-liposomes) leads to effective elimination of all Kypffer cells, without affecting non-phagocytic cells. Wag/Rij rats were injected with Cl₂MDP-liposomes. After 48 h, rats were inoculated with syngeneic CC531 colon carcinoma cells by injection in the portal system. The results show a strongly enhanced tumour growth in the liver of the Cl₂MDP-liposometreated rats. In these animals, livers were almost completely replaced by tumour and had increased in weight, whereas in the control groups only a few (four to eight) small (1-mm) tumour nodules were found. These data show that selective elimination of Kupffer cells results in enhanced tumour growth in the liver, implying that Kupffer cells play a crucial role in controlling tumour growth in the liver.     

Culture of bovine hepatocytes: a non-perfusion technique for cell isolation

In this work we have studied the isolation and culture of mature bovine hepatocytes on plastic dishes without exogenous matrix. The liver has been disaggregated in a collagenase solution instead of undergoing a perfusion step. After a few days in culture, the plates showed several clusters of different cell types. Although the average yield was 1.60±0.57×10⁸ viable liver cells per gram of tissue, these cultures were formed by non-parenchymal cells and only very few or none by parenchymal cells. In these cultures, actin structures used as a marker for Stellate (Ito) cells have been visualized by immunocytochemical techniques. In order to increase the proportion of parenchymal cells a centrifugation on Percoll, which separates cell sub-populations, has been introduced. Though the yield was lower than in the previous method, these pre-purified cultures were only composed of hepatocytes. It has been shown that these cells exhibited albumin synthesis, which is a specific hepatocytes function. In addition, these cultures were capable of producing metabolites of 7-ethoxycoumarin at a higher rate than non purified cell cultures. Therefore this simplified procedure for the isolation and culture of functional and viable hepatocytes may be applied for in vitro studies in bovine.     

Structural changes produced in Kupffer cells in the rat liver by injection of lipopolysaccharide

Summary The fine structure of Kupffer cells has been studied at various times after an intravenous injection of lipopolysaccharide of Salmonella abortus equii. The most prominent effects were: an increase in the number and dimensions of phagocytic vacuoles (often containing ingested LPS and neutrophilic granulocytes); mitochondrial damage, including disintegration of the matrix and cristae; an increase in the amount of dilated, lucent rough endoplasmic reticulum; presence of fat droplets in the cytoplasm. Five days after injection of lipopolysaccharide, the Kupffer cells had resumed their normal ultrastructure.Several minutes after injection of lipopolysaccharide, platelets adhered to the Kupffer and endothelial cells. Between one and six hours, neutrophilic granulocytes accumulated in the liver sinusoids. The resulting obstruction of the hepatic microcirculation most probably affected cellular ultrastructure by ischaemia. At three days, the number of Kupffer cells was doubled, and increased further at later time intervals.     

Establishment of immortalized rat Kupffer cell lines

BACKGROUND: Kupffer cells have been implicated in the pathogenesis of various liver diseases. Primary cultures of Kupffer cells have a very limited life span, tend to de-differentiate and become senescent, and therefore are not suitable for cell signaling studies. AIM: To establish immortalized rat Kupffer cell lines that facilitate mechanistic studies of cell signaling and signal transduction. METHODS: Rat Kupffer cells were sub-cultured with EGF to obtain rat Kupffer Cell line 1 (RKC1), and subsequently transfected with Simian Virus 40 Large T-antigen expression vector to obtain rat Kupffer Cell line 2 (RKC2). RESULTS: RKC1 and RKC2 are similar to primary Kupffer cells as they express the molecular markers ED1, ED2, ED3, and F4/80, and upregulate TNF-alpha, IL-6, IL-1beta, Fas /FasL, and NF-kappaB, as well as TLR4 in response to LPS or pancreatic elastase. Additionally, RKC1 and RKC2 maintain phagocytic properties of latex beads and exhibit increased telomerase and stabilized p53 activity. CONCLUSION: Immortalized RKC1 and RKC2 cells maintain properties of primary Kupffer cells and can be valuable tools in evaluating the role of Kupffer cells in immune diseases and in liver-cell based drug discovery.     

Development of a cytokine-producing immortalized murine Kupffer cell line

Kupffer cells (KC) play a critical role in both liver physiology and the pathogenesis of various liver diseases. Isolated primary KC have a limited lifespan in culture, and due to the relatively low number obtained, limit their study in vitro. Here, a cytokine-producing immortalized KC (ImKC) line was established from transgenic mice that express the thermolabile mutant tsA58 of the Simian virus 40 large T antigen under the control of the H-2k^b promoter. Primary KC were obtained using a three step procedure: liver perfusion, centrifugal elutriation, and sorting for F4/80⁺ cells. ImKC were identified within the small-intermediate population of KC that maintained stable expression of F4/80, and the surface antigens CD11b, CD14 and TLR4. ImKC grow at IFNγ-independent manner at 37 °C and exhibited a doubling time of ∼24 h when cultured in RPMI 1640 with 5% FBS. Our observations indicate that both activation of telomerase and expression of P53 are markedly increased, suggesting that enhanced telomerase activity and P53 expression may contribute to the immortalization of this cell population. ImKC cells maintained a high capacity to phagocytose FITC-latex beads, and bind/phagocytose erythrocytes. In addition, similar to primary KC, ImKC responded to stimulation with lipopolysaccharide (LPS: 0.1–1 μg/ml) by upregulating mRNA levels of TNFα (23-fold), IL-6 (28-fold), and IL-1β (1459-fold), as measured by qRT-PCR. Protein levels of TNFα and IL-6 were also increased, 10-fold and 12-fold, respectively. Reactive oxygen species (ROS) and nitric oxide (NO) production were significantly enhanced in ImKC following an LPS challenge. Furthermore, LPS elicited a marked increase in mitogen activated protein kinase (MAPK) phospho-(ERK1/2, JNK) and NF-κB p50 with decreased IκBα in ImKC, as assessed by Western blot. Collectively, these results demonstrate that the ImKC line retains critical characteristics of primary KC, and thus provides a useful tool to assess the role of KC in liver injury and chronic diseases.