Mucosal addressin cell adhesion molecule (MAdCAM-1) expression is upregulated in the cirrhotic liver and immunolocalises to the peribiliary plexus and lymphoid aggregates.

BACKGROUND: Enhanced cell expression of MAdCAM-1 is critical in tissue recruitment of lymphocytes in response to stimuli expressing the α4ß7 integrin. MAdCAM-1 is well characterized in gut mucosa with emerging evidence of hepatic expression. AIMS: (i) Compare quantitative/semi-quantitatively MAdCAM-1 expression in relation to early and advanced liver diseases (ii) Define the fine structure of vascular plexuses/lymphatics in the portal tract on which MAdCAM-1 is expressed. METHODS: Using alkaline phosphatase anti-alkaline phosphatase methodology on paraffin embedded tissue sections (n=28) from cirrhotic individuals who underwent orthotopic liver transplant, we evaluated MAdCAM-1 expression and compared with pre-cirrhotic, fulminant hepatitis B, and non-cirrhotic portal hypertension tissue sections. The positive controls included normal colon tissue with negative controls without primary antibody and isotype-matched purified IgG. We developed a real time PCR to quantify levels of MAdCAM-1 mRNA in our samples. RESULTS: MAdCAM-1 was expressed in 27/28 of the cirrhotic sections, localized primarily to septal areas within (i) endothelium of the peribiliary vascular plexus (PBP) (ii) lymphoid aggregates, with absence from normal, non-cirrhotic portal hypertension and pre-cirrhotic livers. There was significant upregulation of MAdCAM-1 mRNA in cirrhosis (p<0.011), consistent with immunohistochemical analysis. CONCLUSIONS: MAdCAM-1 is up-regulated in cirrhosis with expression on PBP and lymphoid aggregates. MAdCAM-1 is likely to contribute to the localization and recruitment of α4ß7 lymphocytes during the pathogenesis of cirrhosis. MAdCAM-1 could be a useful marker of advanced liver disease. Further studies with respect to the expression of MAdCAM-1 in the presence of reversible and non-reversible stages of liver disease may be of merit.

The use of 3-aminophthalimide as a pro-chemiluminescent label in chemiluminescence and fluorescence-based cellular assays.

We present a labeling system for direct chemiluminescence-based cellular bioassays using the stable pro-chemiluminescent, luminol precursor, 3-aminophthalimide (API). API-coupled reporter molecules are detected chemiluminometrically after treatment with hydrazine, which converts the API label to luminol. API derivatives containing a variety of functional groups are readily synthesized, allowing for ease of coupling via the imide nitrogen to a host of reporter molecules. The fluorescent nature of APIs further allows for dual fluorescence and chemiluminescence studies. To highlight the utility of this label, we show that API-labeled insulin can be successfully utilized in cellular binding and transport assays and that an API-coupled mitochondrial probe (API-triphenylphosphonium(+)) can be used to both fluorescently and chemiluminometrically investigate mitochondrial function. We also assess the use of API as a polysaccharide and nucleic acid label, and we show that API-labeled palmitic acid undergoes cellular transport and lipid metabolism.

Cells for bioartificial liver devices: the human hepatoma-derived cell line C3A produces urea but does not detoxify ammonia.

Extrahepatic bioartificial liver devices should provide an intact urea cycle to detoxify ammonia. The C3A cell line, a subclone of the hepatoma-derived HepG2 cell line, is currently used in this context as it produces urea, and this has been assumed to be reflective of ammonia detoxification via a functional urea cycle. However, based on our previous findings of perturbed urea-cycle function in the non-urea producing HepG2 cell line, we hypothesized that the urea produced by C3A cells was via a urea cycle-independent mechanism, namely, due to arginase II activity, and therefore would not detoxify ammonia. Urea was quantified using (15)N-ammonium chloride metabolic labelling with gas chromatography-mass spectrometry. Gene expression was determined by real-time reverse transcriptase-PCR, protein expression by western blotting, and functional activities with radiolabelling enzyme assays. Arginase inhibition studies used N(omega)-hydroxy-nor-L-arginine. Urea was detected in C3A conditioned medium; however, (15)N-ammonium chloride-labelling indicated that (15)N-ammonia was not incorporated into (15)N-labelled urea. Further, gene expression of two urea cycle genes, ornithine transcarbamylase and arginase I, were completely absent. In contrast, arginase II mRNA and protein was expressed at high levels in C3A cells and was inhibited by N(omega)-hydroxy-nor-L-arginine, which prevented urea production, thereby indicating a urea cycle-independent pathway. The urea cycle is non-functional in C3A cells, and their urea production is solely due to the presence of arginase II, which therefore cannot provide ammonia detoxification in a bioartificial liver system. This emphasizes the continued requirement for developing a component capable of a full repertoire of liver function.

Fat-loaded HepG2 spheroids exhibit enhanced protection from Pro-oxidant and cytokine induced damage.

The mechanisms by which steatosis renders hepatocytes susceptible to damage in non-alcoholic steatohepatitis (NASH) are unclear although fat accumulation is believed to increase hepatocyte susceptibility to inflammatory cytokines and oxidative stress. We therefore investigated the susceptibility of steatotic, hepatocyte-derived cells to TNFalpha and the pro-oxidant, t-butylhydroperoxide (TBH). HepG2 spheroids rendered steatotic by fat-loading with 0.15 mM oleic or palmitic acid for 48 h and treated with TNFalpha or TBH for 18 h exhibited surprisingly lower levels of cytotoxicity, and increased anti-oxidant activity (superoxide dismutase (SOD)) compared with non fat-loaded controls. The protective effect of steatosis was significantly reversed by the inhibition of AMP-activated kinase (AMPK) since spheroids transfected with a kinase-dead AMPKalpha2 subunit, exhibited a significant increase in TBH-induced cytotoxicity when fat-loaded. In conclusion, our findings suggest that fat-loaded hepatocyte-derived cells are surprisingly less susceptible to cytokine and pro-oxidant induced damage via an adaptive mechanism dependent, in part, on AMPK activity.

Ornithine transcarbamylase and arginase I deficiency are responsible for diminished urea cycle function in the human hepatoblastoma cell line HepG2.

A possible cell source for a bio-artificial liver is the human hepatblastoma-derived cell line HepG2 as it confers many hepatocyte functions, however, the urea cycle is not maintained resulting in the lack of ammonia detoxification via this cycle. We investigated urea cycle activity in HepG2 cells at both a molecular and biochemical level to determine the causes for the lack of urea cycle expression, and subsequently addressed reinstatement of the cycle by gene transfer. Metabolic labelling studies showed that urea production from 15N-ammonium chloride was not detectable in HepG2 conditioned medium, nor could 14C-labelled urea cycle intermediates be detected. Gene expression data from HepG2 cells revealed that although expression of three urea cycle genes Carbamoyl Phosphate Synthase I, Arginosuccinate Synthetase and Arginosuccinate Lyase was evident, Ornithine Transcarbamylase and Arginase I expression were completely absent. These results were confirmed by Western blot for arginase I, where no protein was detected. Radiolabelled enzyme assays showed that Ornithine Transcarbamylase functional activity was missing but that Carbamoyl Phosphate Synthase I, Arginosuccinate Synthetase and Arginosuccinate Lyase were functionally expressed at levels comparable to cultured primary human hepatocytes. To restore the urea cycle, HepG2 cells were transfected with full length Ornithine Transcarbamylase and Arginase I cDNA constructs under a CMV promoter. Co-transfected HepG2 cells displayed complete urea cycle activity, producing both labelled urea and urea cycle intermediates. This strategy could provide a cell source capable of urea synthesis, and hence ammonia detoxificatory function, which would be useful in a bio-artificial liver.

Proliferation rates of HepG2 cells encapsulated in alginate are increased in a microgravity environment compared with static cultures.

This study investigates the effect of rotary culture compared with static culture on the proliferation, cell viability, synthetic function and detoxificatory capacity of HepG2 cells encapsulated in 1% alginate. Cell viability and alginate bead morphology were maintained in the rotary culture system at day 10, while cell number showed a 4.5-fold increase compared with static culture. Protein production was increased in rotary cultures with a 4.1-fold increase in total albumin and a 4.4-fold increase in alpha1 antitrypsin levels in rotary compared with static culture at day 10. CYP4501A1/2 activity was maintained between the two culture systems. In conclusion, rotary culture increases proliferation rates leading to improved bead packing and a concomitant increase in total protein synthesis, along with maintenance of detoxificatory capacity. This allows a greater level of hepatic function to be expressed in a given volume, offering clear advantages for the design of liver support systems.

Hepatocyte progenitors in man and in rodents--multiple pathways, multiple candidates.

In severe injury, liver-cell progenitors may play a role in recovery, proliferating, and subsequently differentiating into mature liver cells. Identifying these progenitors has major therapeutic potential for ex vivo pharmaceutical testing, bioartificial liver support, tissue engineering and gene therapy protocols. Potential liver-cell progenitors have been identified from bone marrow, peripheral blood, cord blood, foetal liver, adult liver and embryonic stem cells. Differences and similarities are found among cells isolated from rodents and humans. This review will discuss identifying markers and differentiation potential in in vitro and in vivo models of these putative progenitors in both humans and rodents.

Altered mitochondrial function and cholesterol synthesis influences protein synthesis in extended HepG2 spheroid cultures.

Cultures of hepatocytes and HepG2 cells provide useful in vitro models of liver specific function. In this study, we investigated metabolic and biosynthetic function in 3-D HepG2 spheroid cultures, in particular to characterise changes on prolonged culture. We show that HepG2 cells cultured in spheroids demonstrate a reduction in mitochondrial membrane potential and respiration following 10 days of culture. This coincides with a modest reduction in glycolysis but an increase in glucose uptake where increased glycogen synthesis occurs at the expense of the intracellular ATP pool. Lowered biosynthesis coincides with and is linked to mitochondrial functional decline since low glucose-adapted spheroids, which exhibit extended mitochondrial function, have stable biosynthetic activity during extended culture although biosynthetic function is lower. This indicates that glucose is required for biosynthetic output but sustained mitochondrial function is required for the maintenance of biosynthetic function. Furthermore, we show that cholesterol synthesis is markedly increased in spheroids cf. monolayer culture and that inhibition of cholesterol synthesis by lovastatin extends mitochondrial and biosynthetic function. Therefore, increased cholesterol synthesis and/or its derivatives contributes to mitochondrial functional decline in extended HepG2 spheroid cultures.

Alginate-encapsulated human hepatoblastoma cells in an extracorporeal perfusion system improve some systemic parameters of liver failure in a xenogeneic model.

Previous studies have demonstrated that alginate encapsulation of proliferating hepatocyte-derived cell lines (e.g., HepG2 cells) enhances the expression of differentiated hepatocyte function compared with conventional monolayer culture. Furthermore, such capsules have the advantage of cryopreservability, and can be readily manipulated, e.g., for the charging of extracorporeal devices. We utilize a rabbit model of acute liver failure caused by acetaminophen administration to rabbits pretreated to enhance cytochrome p450 enzyme activity, and demonstrate that encapsulated HepG2 cells, in an extracorporeal chamber, perfused by rabbit plasma separated on-line at a rate of 2-5 mL/min, and perfused over cells at 40-60 mL/min, improve systemic parameters of liver failure (diastolic blood pressure and transjugular venous oxygen saturation). Such encapsulated cells have the potential to be developed for extracorporeal liver support systems for acute liver failure.

Epithelial colonies cultured from human explanted liver in subacute hepatic failure exhibit hepatocyte, biliary epithelial, and stem cell phenotypic markers.

The liver in subacute hepatic failure may become enriched for hepatic progenitor cells. Liver tissue from such a patient was collagenase digested and, from the nonparenchymal cell fraction, epithelioid colonies were developed. Albumin and alpha-1-antitrypsin (AAT) were secreted for greater than 120 days from these colonies. Reverse transcription-polymerase chain reaction showed expression of markers of both hepatocyte and biliary epithelial phenotypes (cytokeratins 7, 18, and 19, albumin and AAT, hepatocyte growth factor receptor, transforming growth factor beta receptor type II, gamma-glutamyl transpeptidase, biliary glycoprotein). The cell cycle regulator p21 was also expressed. The POU domain transcription factor octamer-binding protein 4 was present in these cells, but not in RNA or cDNA prepared from adult human liver. These markers were maintained even after 165 days culture. Proliferating epithelial-like cells with combined hepatocyte- and biliary-epithelial-specific functional markers and a stem cell marker can be isolated from the nonparenchymal fraction of liver cells in subacute hepatic failure.

Modulation of hepatocyte function in an immortalized human hepatocyte cell line following exposure to liver-failure plasma.

For hepatocytes to function effectively in a bioartificial liver device, maintained function in the milieu of plasma from patients with liver failure will be required. We have investigated the effect of plasma obtained at plasmapheresis from patients with acute liver failure on the performance of the human hepatocyte cell line HHY41 in liver-failure plasma, normal plasma, and culture medium. Cytotoxicity of plasma, DNA synthesis by thymidine incorporation, oxidative status, and cytochrome P450 functions were assayed after a 16 h culture with normal plasma, liver-failure plasma, or culture medium. Some, but not all, samples of liver-failure plasma were deleterious to the performance of the cell line, inducing cytotoxicity and oxidative stress, with diminished DNA synthesis, protein synthesis, and cytochrome P4501A activity. Strategies to minimize the toxic effects of liver-failure plasma may improve the performance of liver cells in extracorporeal liver-support devices.