Tissue-specificity of apoptosis in hepatoma-derived cell lines.

Apoptosis is known to play a critical role in development and homeostasis in metazoans. Although apoptotic responses vary widely among cell types, the underlying mechanisms responsible for these differences are not known. In order to understand the molecular basis for these differences, we have studied a cell culture model comparing hepatoma cells to dedifferentiated cell lines derived from them. We recently reported evidence suggesting that a common regulatory locus affects both liver-specific function and sensitivity to lipopolysaccharide (LPS)-mediated apoptosis. Here, we show that dedifferentiated hepatoma cells undergo apoptosis in response to multiple compounds, including sorbitol (to induce hyperosmotic shock), TNF alpha and the microtubule damaging agent vinblastin. In contrast, the hepatoma parental cells fail to undergo apoptosis in response to any of the compounds tested. Further analysis of LPS-mediated cell death found that antioxidants N-acetylcysteine and alpha-tocopherol partially prevented apoptosis. Lastly, evidence is presented showing that LPS-mediated cell death of the hepatoma variant cell lines is caspase-dependent. These results suggest that pathways dictating hepatic phenotype also affect general cellular survival mechanisms in response to multiple agents. The dedifferentiated cells provide a model to examine the influence of cell-type specific expression on apoptotic signaling.

A common regulatory locus affects both HNF4/HNF1alpha pathway activation and sensitivity to LPS-mediated apoptosis in rat hepatoma cells.

Lipopolysaccharide (LPS) has been shown to protect certain cultured mammalian cells from undergoing programmed cell death (apoptosis) when exposed to tumor necrosis factor (TNF). However, LPS has also been reported to induce apoptosis in cultured endothelial cells, suggesting that apoptotic response mechanisms may be dependent upon cell type. In order to understand the influence of tissue-specific gene expression on apoptosis, we compared LPS-induced apoptosis in hepatoma cells with dedifferentiated hepatoma variant cells that have been selected for the loss of the liver-enriched HNF4/HNF1alpha transcriptional activation pathway. We report here that while human, rat and mouse hepatoma cell lines are resistant to LPS-mediated cell death, the HNF4-/HNF1alpha- rat hepatoma variant cells undergo rapid apoptosis (as determined by morphological analysis, DNA laddering and the TUNEL assay) upon exposure to LPS. Genetic rescue experiments show that restoration of the HNF4/HNF1alpha pathway via chromosome transfer render the hepatoma variant cells resistant to LPS-mediated apoptosis. However, the introduction of HNF1alpha alone failed to alter the apoptotic phenotype, suggesting that the defect(s) in the hepatoma variant cells that influence apoptotic responses lies upstream of HNF4/HNF1alpha expression. This study provides for the first time direct evidence of a common regulatory locus involved in activation of hepatic gene expression and sensitivity to LPS-mediated apoptosis.

GP73, a novel Golgi-localized protein upregulated by viral infection.

We report the isolation and characterization of GP73, a novel 73kDa human Golgi protein. The GP73 cDNA was cloned by differential screening of a cDNA library derived from the liver of a patient with adult giant-cell hepatitis (GCH), a rare form of hepatitis with presumed viral etiology. In vitro transcription-translation studies indicate that GP73 is an integral membrane protein, and immunolocalization experiments using epitope-tagged GP73 demonstrate that the protein is localized to the Golgi apparatus. Northern blot analysis of RNA from multiple human tissues reveals a single GP73 mRNA transcript with a size of approximately 3.0kb. Immunohistochemical studies using rabbit polyclonal antisera directed against recombinant GP73 demonstrate that the protein is preferentially expressed by epithelial cells in many human tissues. In normal livers, GP73 is consistently present in biliary epithelial cells, whereas hepatocytes show little or no signal. In contrast, livers of patients with GCH display strong GP73 immunoreactivity in multinucleated hepatocytes. GP73 mRNA and protein are expressed in highly differentiated HepG2 hepatoma cells after infection with adenovirus in vitro. We conclude that GP73 represents a novel, epithelial cell-specific integral membrane Golgi protein that can be upregulated in response to viral infection.

C1q-containing immune complexes purified from sera of juvenile rheumatoid arthritis patients mediate IL-8 production by human synoviocytes: role of C1q receptors.

Immune complexes that vary in size and composition are present in the sera and synovial fluid of juvenile rheumatoid arthritis (JRA) patients. They are believed to be potent inducers of the ongoing inflammatory process in JRA. However, the precise composition and role of these complexes in the pathophysiology of JRA remain unclear. We hypothesized that circulating ICs have the potential to interact with resident joint synovial fibroblasts (synoviocytes) and induce the expression of inflammatory cytokines. To test this hypothesis, cultures of synoviocytes from healthy individuals were treated with ICs isolated from the sera of JRA patients. Studies reported in this work demonstrate that IgM affinity-purified ICs from the sera of JRA patients contain IgM, C1q, IgG, and C3 to a variable extent. These ICs induce IL-8 mRNA and protein production in normal synoviocytes. Our data indicate that C1q in these ICs mediates, in part, IL-8 induction in synoviocytes. This is based on our findings of C1q-binding proteins for collagen stalks (cC1qR) and globular heads (gC1q-binding protein) of C1q in synoviocytes. In addition, collagen stalk and to some extent globular head fragments of C1q inhibit IC-mediated IL-8 induction in synoviocytes. Together, these findings provide evidence for a novel mechanism of IL-8 production by synoviocytes, which could play a key role in inflammation by recruiting leukocytes to synovial tissue and fluid-and subsequently contributing to joint disease.

Extinction of alpha1-antitrypsin expression in cell hybrids is independent of HNF1alpha and HNF4 and involves both promoter and internal DNA sequences.

In rat hepatoma x fibroblast somatic cell hybrids, extinction of rat alpha1-antitrypsin (alpha1AT) gene expression is accompanied by the loss of liver-enriched transcription factors hepatocyte nuclear factor 1 (HNF1alpha) and hepatocyte nuclear factor 4 (HNF4). Previous analysis showed that forced expression of functional HNF1alpha failed to prevent extinction of the rat alpha1AT locus in cell hybrids. Here I show that ectopic co-expression of HNF1alpha plus HNF4 fails to prevent extinction of either rat or human alpha1AT genes in cell hybrids. A 40 kb human alpha1AT minilocus integrated into the rat genome is fully silenced in cell hybrids in the presence of transacting factors. The integrated alpha1AT promoter, but not a viral or ubiquitously active promoter, is repressed 35-fold in the cell hybrids. In addition, position effects also contributed to extinction of many integrated transgenes in a cell type-dependent manner. Finally, internal DNA sequences within the human alpha1AT gene contributed dramatically to the extinction phenotype, resulting in a further 10- to 30-fold reduction in alpha1AT gene expression in cell hybrids. Thus, multiple mechanisms contribute to silencing of tissue-specific gene expression of the alpha1AT gene in cell hybrids.

Defective NF-kappaB signaling in dedifferentiated hepatoma cells.

Dedifferentiated rat hepatoma cells contain defects that result in the loss of hepatic gene expression, including the liver-enriched HNF4/HNF1alpha pathway. We examined induction of NF-kappaB, a key mediator of the inflammatory response, in hepatoma and dedifferentiated hepatoma cells. We show that exposure of dedifferentiated hepatoma cells, but not rat and human hepatoma cell lines, to proinflammatory cytokines or lipopolysaccharide resulted in rapid and sustained NF-kappaB induction. IkappaB-beta levels, but not NF-kappaB subunit p65 or IkappaB-alpha levels, were elevated compared with those for parental hepatoma cells. Interestingly, LPS-mediated activation of NF-kappaB was found to be independent of degradation of IkappaB-alpha or IkappaB-beta. Thus, these results suggest that loci responsible for maintaining hepatic gene expression also influence cellular responses to inflammatory agents.

Modulation of lipopolysaccharide-mediated activation in rat Kupffer cells by antioxidants.

Activation of Kupffer cells, the resident macrophage population of the liver, has been implicated in the pathogenesis of several types of liver injury. The aim of this study was to investigate whether the antioxidants N-acetylcysteine (NAC) and alpha-tocopherol succinate (alpha-TOC) suppress lipopolysaccharide (LPS)-induced activation of rat Kupffer cells. LPS activated NF-kappaB in Kupffer cells, and this response was inhibited by NAC and alpha-TOC. NAC and alpha-TOC also markedly suppressed LPS-induced tumor necrosis factor-alpha (TNF-alpha) mRNA levels and secretion. We further show that LPS was unable to increase TNF-alpha mRNA in drug-treated cells even when stimulation occurred after NAC or alpha-TOC were removed. These results indicate that antioxidants persistently suppress LPS activation in Kupffer cells, and suggest that the mechanism responsible for this involves more than mere quenching of free radical production. The demonstration that NAC and alpha-TOC have inhibitory effects on LPS-mediated Kupffer cell activation suggests that these compounds may have a beneficial effect in liver injury involving oxidative stress and endotoxemia.

Rescue of the HNF4 --> HNF1alpha pathway in hepatoma variant cells containing human chromosome 12.

Expression of liver-enriched trans-acting hepatocyte nuclear factors 1alpha (HNF1alpha) and 4 (HNF4) is correlated with the hepatic phenotype in cultured rat hepatoma cells. We have used a hepatoma variant cell line, H11, that specifically lacks the HNF4 --> HNF1alpha pathway as a model to understand mechanisms controlling hepatic gene expression. We have introduced randomly marked human chromosomes into H11 cells and have isolated a number of microcell hybrids that have rescued hepatic gene expression, including HNF4, HNF1alpha, and alpha1-antitrypsin. Chromosomal analysis of cell hybrids showed that the rescued hepatic phenotype correlated closely with the presence of human chromosome 12p sequences. Although the gene encoding HNF1alpha is located on chromosome 12q24, its retention was not required to rescue the hepatic phenotype. Thus, we suggest that a locus on human chromosome 12p plays an important role in maintenance of hepatic gene expression through activation of the HNF4 --> HNF1alpha pathway.

Hepatocyte nuclear factor-4 prevents silencing of hepatocyte nuclear factor-1 expression in hepatoma x fibroblast cell hybrids.

Hepatocyte nuclear factors-1alpha (HNF1alpha) and -4 (HNF4) are components of a liver-enriched transcription activation pathway which is thought to play a critical role in hepatocyte-specific gene expression, including activation of alpha1-antitrypsin gene expression. HNF1alpha, HNF4 and alpha1-antitrypsin (alpha1AT) genes are extinguished in hepatoma/fibroblast somatic cell hybrids, suggesting that fibroblasts contain a repressor-like activity. To determine the molecular basis for silencing of these genes in cell hybrids, ectopic expression of HNF1alpha and HNF4 was used. Results show that constitutive expression of HNF4 prevents extinction of HNF1alpha gene expression in hepatoma/fibroblast hybrids. In contrast, forced HNF1alpha expression failed to prevent extinction of the HNF4 locus in cell hybrids. Likewise, the alpha1AT gene remained silent in the presence of both HNF1alpha and HNF4. These results suggest that extinction of HNF1alpha is a simple lack-of-activation phenotype, whereas extinction of HNF4 andalpha1AT loci is more complex, perhaps involving negative regulation.

Selective loss of the hepatic phenotype due to the absence of a transcriptional activation pathway.

Liver-enriched trans-acting factors hepatocyte nuclear factor-1 alpha (HNF1 alpha) and -4 (HNF4) are components of a transcriptional activation pathway that is thought to play a major role in hepatic gene activation. We previously described the isolation and characterization of distinct classes of hepatoma variants which lack the HNF4-->HNF1 alpha pathway (1). In order to determine the influence of the HNF4-->HNF1 alpha pathway on hepatic gene expression, genetic rescue experiments were done using hepatoma variant line H11 as a model system. Results suggest that this pathway is required for basal expression of a number of endogenous hepatocyte-specific genes. Complementation groups were established by fusion of H11 cells with other variant lines. Lastly, introduction of human chromosome 20 (containing the HNF4 locus) or randomly-marked human chromosomes into H11 cells failed to rescue the hepatic phenotype, suggesting that what appears to be a 'simple' defect may involve multiple genetic loci.

Genetic analysis of a transcriptional activation pathway by using hepatoma cell variants.

A hierarchy of liver-enriched transcription factors plays an important role in activating expression of many hepatic genes. In particular, hepatocyte nuclear factor 4 (HNF-4) is a major activator of the gene encoding HNF-1, and HNF-1 itself activates expression of more than 20 liver genes. To dissect this activation pathway genetically, we prepared somatic cell variants that were deficient in expression of the liver-specific alpha 1-antitrypsin (alpha 1AT) gene, which requires both HNF-1 and HNF-4 for high-level gene activity. This was accomplished in two steps. First, hepatoma transfectants that stably expressed two selectable markers under alpha 1AT promoter control were prepared; second, variant sublines that could no longer express either transgene were isolated by direct selection. In this report, we demonstrate that the variants contain defects in the HNF-4/HNF-1 activation pathway. These defects functioned in trans, as expression of many liver genes was affected, but the variant phenotypes were recessive to wild type in somatic cell hybrids. Three different variant classes could be discriminated by their phenotypic responses to ectopic expression of either HNF-4 or HNF-1. Two variant clones appeared specifically deficient in HNF-4 expression, as transfection with an HNF-4 expression cassette fully restored their hepatic phenotypes. Another line activated HNF-1 in response to forced HNF-4 expression, but activation of downstream genes failed to occur. One clone was unresponsive to either HNF-1 or HNF-4. Using the variants, we demonstrate further that the chromosomal genes encoding alpha 1AT, aldolase B, and alpha-fibrinogen display strict requirements for HNF-1 activation in vivo, while other liver genes were unaffected by the presence or absence of HNF-1 or HNF-4. We also provide evidence for the existence of an autoregulatory loop in which HNF-1 regulates its own expression through activation of HNF-4.

Tissue-specific extinguisher loci in the murine genome: a screening study based on a rat/mouse microcell hybrid panel.

Extinction of tissue-specific traits in intertypic somatic cell hybrids is a well-known phenomenon. In the past few years, microcell hybrids have been used in attempts to dissect this phenotype genetically, and tissue-specific extinguisher loci have been mapped to two different mouse chromosomes. When transferred from fibroblast into hepatoma cells by microcell fusion, these loci down-regulate expression of specific liver genes in trans. However, other liver genes that are extinguished in genotypically complete hybrids seem not to be extinguished in monochromosomal hybrids. To assess the generality of monochromosomal extinction phenotypes, we assembled a collection of rat hepatoma/mouse fibroblast microcell hybrids that represent most of the mouse chromosome complement, and we screened them for expression of a large number of liver-specific genes. Phosphoenolpyruvate carboxykinase gene expression was down-regulated in hybrids containing mouse chromosome 7 or mouse chromosome 11, but other extinction phenotypes were not readily apparent. These results indicate that extinction of many liver genes may be a polygenic trait.

Direct selection of hepatoma cell variants deficient in alpha 1-antitrypsin gene expression.

Expression plasmids containing the human alpha 1-antitrypsin (alpha 1 AT) promoter fused to either adenine phosphoribosyltransferase (aprt) or xanthine-guanine phosphoribosyltransferase (gpt) coding sequences were sequentially introduced into APRT- HPRT- rat hepatoma cells. Stable transfectants expressing both transgenes were isolated and characterized. Nonexpressing variants were subsequently obtained by selecting against expression of one or both transgenes. Variants isolated by selecting against expression of either transgene alone generally displayed deficiency phenotypes in cis, as only three of 20 clones tested were affected for expression of alpha 1AT mRNA. In contrast, double selection yielded predominantly trans effects: 12 of 14 lines tested showed impaired ability to express their chromosomal alpha 1AT genes. Furthermore, expression of several other liver genes, including the gene encoding the HNF-1 trans-activator, was repressed in many of the variant lines. Thus, double selection using chimeric transgenes is a useful approach for generating variant cell lines deficient in expression of specific mammalian genes.

Extinction of alpha 1-antitrypsin gene expression in somatic cell hybrids: evidence for multiple controls.

Expression of the liver-specific alpha 1-antitrypsin (alpha 1AT) gene is extinguished in hepatoma/fibroblast hybrids. To define the mechanism of extinction, we identified DNA sequences involved in this process by transiently transfecting mutant alpha 1AT promoters into parental and hybrid cells. The wild-type alpha 1AT promoter (-554 to +44 bp) was highly expressed in rat hepatoma cells, but activity was 100-fold less in fibroblasts or cell hybrids. Mutations in this region failed to activate alpha 1AT expression in nonhepatic cells, but mutations in the binding site for liver factor B1 (LF-B1) reduced hepatic-specific expression greater than 100-fold. Furthermore, the hybrid cells failed to express LF-B1-binding activity and mRNA. This suggested that alpha 1AT extinction in hybrids might be an indirect, lack-of-activation phenotype mediated primarily through repression of LF-B1. To test this possibility, we stably transfected an LF-B1 expression cassette into parental and hybrid cells and monitored expression of transfected and endogenous alpha 1AT genes. Surprisingly, although constitutive LF-B1 expression could activate alpha 1AT-CAT transgenes in these cells, it neither prevented nor reversed extinction of the chromosomal alpha 1AT genes. We conclude that although extinction of the LF-B1 trans-activator accompanies alpha 1AT extinction in cell hybrids, it does not play a causal role in this process.

Negative regulation of the hepatitis B virus pre-S1 promoter by internal DNA sequences.

Expression of the surface antigen gene (S gene) of hepatitis B virus is directed by two distinct promoter elements with markedly different activities. The upstream (pre-S1) promoter produces a 2.4-kb transcript at very low levels while the downstream (pre-S2) promoter produces an approximately 2.1-kb transcript in relative abundance. We have constructed a series of internal deletion mutants to analyze differential regulation of the two S gene promoters. We show here that expression directed by the pre-S1 promoter is negatively regulated by DNA sequences containing the downstream pre-S2 promoter region. Nuclear run-on analysis indicates this down-regulation to be at the level of transcription. Furthermore, promoter repression does not appear to be due to products of the S gene region. Deletion mutagenesis studies have permitted the localization of a 61-bp region that may be involved in the apparent down-regulation of the pre-S1 promoter. These results suggest the use of an unusual regulatory mechanism by a dipromoter gene in which an active internal promoter may preclude efficient use of an upstream promoter.

The hepatitis B virus enhancer modulates transcription of the hepatitis B virus surface antigen gene from an internal location.

We have used a transient expression system to examine the influence of the hepatitis B virus enhancer on the transcription of the hepatitis B virus surface antigen (HBsAg) gene. This enhancer is located 3' to HBsAg coding sequences but is contained within the mature HBsAg transcripts. Removal of the enhancer resulted in a significant reduction in HBsAg gene expression in liver cells. By using an in vitro nuclear run-on assay, this effect was determined to be at the level of transcription. We have further noted that HBsAg expression can be restored by the reinsertion of the enhancer sequences in the enhancerless vector. However, this reconstitution of HBsAg expression appears to depend on location of the enhancer with regard to the HBsAg promoters.

A single dilution enzyme-linked immunosorbent assay for the quantitative detection of antibodies to bovine herpesvirus type 1.

Three serological assays were compared for detection of antibodies to bovine herpes-virus type 1. These were virus neutralization (VN), enhanced complement fixation (CF) and enzyme-linked immunosorbent assay (ELISA). The ELISA was developed using an infected cell lysate antigen and purified virus and was optimized in relation to antigen and antisera dilutions. The CF assay was enhanced by the addition of bovine complement. These 3 assays were compared for detection of: specific virus antibody titers; sero-conversions; early antibody response in experimentally-infected cattle. Both ELISA end-point titers and single dilution values were found to be more sensitive than the CF or VN assays for specific antibody level quantitation. With a single dilution ELISA test procedure a correlation was obtained between ELISA values and VN titers. Using the single dilution ELISA test the assay also detected antibodies in experimentally-infected cattle before either the VN or CF assays, and agreed with the VN test in 35/38 seroconversions found by 4-fold or more VN changes between acute and convalescent paired sera from naturally-infected animals. The single dilution ELISA was a rapid and sensitive test for routine antibody detection in bovine sera.