Tissue-specific regulation of human alpha 1-antitrypsin gene expression in transgenic mice

Impaired regulation of hepatic glucose production in mice lacking the forkhead transcription factor Foxo1 in liver

The hallmark of type 2 diabetes is excessive hepatic glucose production. Several transcription factors and coactivators regulate this process in cultured cells. But gene ablation experiments have yielded few clues as to the physiologic mediators of this process in vivo. We show that inactivation of the gene encoding forkhead protein Foxo1 in mouse liver results in 40% reduction of glucose levels at birth and 30% reduction in adult mice after a 48 hr fast. Gene expression and glucose clamp studies demonstrate that Foxo1 ablation impairs fasting- and cAMP-induced glycogenolysis and gluconeogenesis. Pgc1alpha is unable to induce gluconeogenesis in Foxo1-deficient hepatocytes, while the cAMP response is significantly blunted. Conversely, Foxo1 deletion in liver curtails excessive glucose production caused by generalized ablation of insulin receptors and prevents neonatal diabetes and hepatosteatosis in insulin receptor knockout mice. The data provide a unifying mechanism for regulation of hepatic glucose production by cAMP and insulin.

TWEAK induces liver progenitor cell proliferation

Progenitor ("oval") cell expansion accompanies many forms of liver injury, including alcohol toxicity and submassive parenchymal necrosis as well as experimental injury models featuring blocked hepatocyte replication. Oval cells can potentially become either hepatocytes or biliary epithelial cells and may be critical to liver regeneration, particularly when hepatocyte replication is impaired. The regulation of oval cell proliferation is incompletely understood. Herein we present evidence that a TNF family member called TWEAK (TNF-like weak inducer of apoptosis) stimulates oval cell proliferation in mouse liver through its receptor Fn14. TWEAK has no effect on mature hepatocytes and thus appears to be selective for oval cells. Transgenic mice overexpressing TWEAK in hepatocytes exhibit periportal oval cell hyperplasia. A similar phenotype was obtained in adult wild-type mice, but not Fn14-null mice, by administering TWEAK-expressing adenovirus. Oval cell expansion induced by 3,5-diethoxycarbonyl-1,4-dihydrocollidine (DDC) was significantly reduced in Fn14-null mice as well as in adult wild-type mice with a blocking anti-TWEAK mAb. Importantly, TWEAK stimulated the proliferation of an oval cell culture model. Finally, we show increased Fn14 expression in chronic hepatitis C and other human liver diseases relative to its expression in normal liver, which suggests a role for the TWEAK/Fn14 pathway in human liver injury. We conclude that TWEAK has a selective mitogenic effect for liver oval cells that distinguishes it from other previously described growth factors.

Chimeric transcriptional control units for improved liver-specific transgene expression

Hepatocyte-directed delivery of therapeutic genes is a major field of gene therapy. An important issue in this context is the availability of promoters units providing for maximum transcriptional activity and specificity. Although a number of liver-specific promoters and transcriptional control elements have been identified and used for gene delivery, no systematic study has been performed to identify the best suitable combination of known liver-specific promoter and enhancer elements. We now report the results of a comparative investigation addressing this issue. We tested a total of 25 synthetic transcriptional control units consisting of either of the four core promoters from liver-specific genes linked in various combinations and configurations to hepatocyte-specific enhancer elements. These constructs were analyzed for transcriptional activity in different cell types in cell culture and in mouse liver in vivo. The data lead to the clear conclusion that a combination of the alcohol dehydrogenase 6 (ADH6) basal promoter linked to two tandem copies of an apoplipoprotein E enhancer element is the transcriptional control unit of choice for the liver-specific expression of transgenes.

Chromosomal elements regulate gene activity and chromatin structure of the human serpin gene cluster at 14q32.1

The human serine protease inhibitor (serpin) gene cluster at 14q32.1 contains a number of genes that are specifically expressed in hepatic cells. Cell-specific enhancers have been identified in several of these genes, but elements involved in locus-wide gene and chromatin control have yet to be defined. To identify regulatory elements in this region, we prepared a series of mutant chromosomal alleles by homologous recombination and transferred the specifically modified human chromosomes to hepatic cells for functional tests. We report that deletion of an 8-kb DNA segment upstream of the human alpha1-antitrypsin gene yields a mutant serpin allele that fails to be activated in hepatic cells. Within this region, a 2.3-kb DNA segment between kb -8.1 and -5.8 contains a previously unrecognized control region that is required not only for serpin gene activation but also for chromatin remodeling of the entire locus.

Differential influence of the E4 adenoviral genes on viral and cellular promoters

BACKGROUND

Strong and stable transgene expression is fundamental to the success of recombinant adenovirus vectors in human gene therapy. However, control of transgene expression is a complex process, involving both viral and cellular factors. In this study, the influence of the E4 adenoviral region on the activity of various promoters was investigated in vitro and in vivo.

METHODS

Pairs of isogenic E1o and E1oE4o vectors were generated and compared. Levels of transgene expression were determined by Northern blot, ELISA and FACS analysis. Initiation of transcription was studied by nuclear run-on assays.

RESULTS

Similar to the viral CMV and RSV promoters, the activity of the ubiquitous cellular PGK promoter required the presence of the E4 genes in vitro and in vivo. In contrast, transgene expression from selected liver- and tumor-specific promoters did not require E4 functions.

CONCLUSION

Together with the reported low liver toxicity of E1oE4o vectors, the independence of E4 of liver-specific promoters renders such vectors interesting alternatives to the use of gutless vectors.

Priming of hepatitis C virus-specific cytotoxic T lymphocytes in mice following portal vein injection of a liver-specific plasmid DNA

The immunology of hepatitis C virus (HCV) infection should be studied in the context of HCV antigen expression in the liver, because HCV primarily infects this organ. Indeed, the nature, function, and fate of T cells primed after antigen expression in the liver might differ from those primed when antigens are expressed systemically or in other organs, because the nature of the antigen-presenting cells (APCs) involved may be different. In addition, the normal liver contains a resident population of lymphocytes that differ from those present at other sites. Thus, we investigated whether HCV-specific CD8(+) cytotoxic T cells (CTLs) could be elicited following portal vein (PV) injection of plasmid DNA in mice whose hepatic veins were transiently occluded. We show that PV injection of mice with "naked" DNA expressing the HCV-NS5a protein, under the control of a liver-specific enhancer/promoter, resulted in NS5a expression in the liver and the priming of HCV-specific CTLs. These results suggested that such a model might be relevant to the study of HCV-specific immune responses primed during natural infection.

Identification of a key regulatory element for the basal activity of the human insulin-like growth factor II gene promoter P3

Transcription of the human insulin-like growth factor II (IGF-II) gene is under the control of four promoters (P1-P4) that are differentially active during growth and development. Promoter 3 (P3) is the most active promoter during fetal development as well as in most adult tissues. P3 is also the most active promoter in tumour tissues and cell lines expressing IGF-II. Transient transfections of HeLa and Hep3B cells with truncated promoter constructs revealed that the region between -289 and -183 relative to the transcription start site supports basal promoter activity in both cell lines. Footprint experiments showed that the region between positions -192 and -172 (P3-4) is the only element bound by nuclear proteins. P3-4 is bound by five proteins, of which three proteins (proteins 3, 4 and 5) bind specifically and are expressed at the same levels in HeLa and Hep3B cells. Electrophoretic mobility shift assays and differential footprint experiments revealed the presence of two protein-binding regions within the P3-4 element. Proteins 4 and 5 bind box A (-193 to -188), whereas box B (-183 to -172) is bound by protein 3. From transcription experiments in vitro it can be concluded that Box A is essential for P3 activity. Box A is part of a region 11 dG residues long and is protected by proteins 4 and 5 that bind a contiguous set of six dG residues. DNA-binding of proteins 4 and 5 to box A requires the presence of Zn2+ ions. Thus structural and functional analysis reveals that the P3-4 element is a key regulatory element of P3 that contains two separate binding sites for proteins essential for the basal activity of IGF-II P3.

Restricted tissue-specific but correct developmental expression mediated by a short human alpha 1AT promoter fragment in transgenic mice

The tissue-specific and developmental pattern of expression controlled by the proximal promoter (position-348 to +15) derived from the human alpha-1-antitrypsin (h alpha 1AT) gene was studied in transgenic mice. The short promoter segment was linked to the chloramphenicol acetyltransferase (CAT) reporter gene. The transgene showed highly specific expression in the liver and the correct developmental pattern of regulation. Interestingly, this short promoter targets expression to the liver with a greater specificity than that reported for larger alpha 1AT promoter fragments.

Evolution of gene regulation as revealed by differential regulation of the chicken lysozyme transgene and the endogenous mouse lysozyme gene in mouse macrophages

Lysozyme gene expression is a marker for macrophage differentiation in vertebrates. We have previously shown that expression of the complete chicken lysozyme gene domain in macrophages of transgenic mice is directly correlated to the copy number of integrated transgenes. Thus, the chicken lysozyme locus in the mouse acts as an independent regulatory unit irrespective of its random position in the host genome. This finding allowed a comparative analysis of the regulation of the endogenous mouse lysozyme M gene and the chicken lysozyme transgene in the same animal. We demonstrate by transcript analysis of total tissue RNA and by in situ hybridization, that both genes are expressed in macrophages. In macrophages of the same animal the regulation of both genes in response to external signals was distinctly different: the lysozyme transgene responded to various agents influencing macrophage activation, in contrast, mouse lysozyme RNA levels remained unchanged under these conditions. Thus, as in chicken macrophages, the chicken lysozyme expression level in mouse macrophages is coupled to the macrophage activation status, while the mouse lysozyme is not. Our results suggest, that the cis-regulatory elements of lysozyme genes have evolved more rapidly than the function and expression of the trans-acting factors involved in the regulation of macrophage-specific gene activation.

Transgenic animal studies on the evolution of genetic regulatory circuitries

The ability to transfer genes from one species to another provides a powerful method to study genetic regulatory differences between species in a homogeneous genetic background. A survey of several transgenic animal experiments indicates that the vast majority of regulatory differences observed between species are due to differences in the cis-acting elements associated with the genes under study. A corollary is that in almost all cases the host species provides the necessary regulatory proteins for expression of the transgenes in specific tissues in which the endogenous homolog is not expressed. Although the details of the cis-acting differences are unknown for most cases, it appears that these differences may consist of the acquisition or loss of unique elements or subtle variation of conserved elements. It is unknown whether much of this variation is directly related to adaptive evolution. The identification of the promoter/enhancer elements responsible for these differences is an important first step in examining the functional significance of this variation.

Gene transfer into mammalian somatic cells in vivo

Direct gene transfer into mammalian somatic tissues in vivo is a developing technology with potential application for human gene therapy. During the past 2 years, extensive progress and numerous breakthroughs have been made in this area of research. Genetically engineered retroviral vectors have been used successfully to infect live animals, effecting foreign gene expression in liver, blood vessels, and mammary tissues. Recombinant adenovirus and herpes simplex virus vectors have been utilized effectively for in vivo gene transfer into lung and brain tissues, respectively. Direct injection or particle bombardment of DNA has been demonstrated to provide a physical means for in situ gene transfer, while carrier-mediated DNA delivery techniques have been extended to target specific organs for gene expression. These technological developments in conjunction with the initiation of the NIH human gene therapy trials have marked a milestone in developing new medical treatments for various genetic diseases and cancer. Various in vivo gene transfer techniques should also provide new tools for basic research in molecular and developmental genetics.

Time-course development of differentiated hepatocarcinoma and lung metastasis in transgenic mice

A precise targeting of the SV40 T early region expression in the liver of transgenic mice was obtained using 700 bp of the antithrombin III regulatory sequences to control oncogene expression. In the strain expressing the highest level of large T antigen (Tag), the incidence of hepatocarcinoma was 100%. The evolution was reproducible and characterized by a marked cytolysis occurring as early as 4 weeks, when no morphological and histological modifications were visible, a preneoplastic state marked by a progression from hyperplasia to proliferative nodules composed of highly differentiated cells exhibiting a high Tag expression, which elicited tumor formation in nude mice and could proliferate in vitro, and hepatocellular carcinoma associated, in 10% of the cases, with lung metastasis. These transgenic mice constituted a useful model for therapeutic assays and fundamental studies on carcinogenesis.

Mouse hepatocytes migrate to liver parenchyma and function indefinitely after intrasplenic transplantation

One approach to gene therapy for hepatic diseases is to remove hepatocytes from an affected individual, genetically alter them in vitro, and reimplant them into a receptive locus. Although returning hepatocytes to the liver itself would be advantageous, the feasibility of this approach has never been evaluated due to the inability to distinguish donor from host hepatocytes. To unambiguously identify transplanted hepatocytes after transplantation, and to better quantitate their number and degree of liver function, two transgenic mouse lines were generated in a C57BL/6 background. The first expresses the Escherichia coli beta-galactosidase gene from the relatively liver-specific human alpha 1-antitrypsin (hAAT) promoter and allows transgenic hepatocytes to be readily identified after 5-bromo-4-chloro-3-indolyl beta-D-galactoside staining; the second produces the hAAT protein under control of the same promoter, which enables hepatocyte survival and maintenance of liver function to be quantitated by measuring the serum levels of hAAT. Hepatocytes isolated from transgenic donors were transplanted into nontransgenic C57BL/6 recipients by intrasplenic injection. Surprisingly, a large fraction of these cells were identified within the liver parenchyma but not the spleen at 2 months after transplantation. The high levels of serum hAAT detected in transplant recipients were stable for greater than 6 months, suggesting that established cells will survive indefinitely. These results have important implications for liver organogenesis and hepatic gene therapy.

Hepatitis B virus transactivator X protein is not tumorigenic in transgenic mice

The hepatitis B virus X protein acts as a transcriptional transactivator in vitro. To elucidate possible biological effects of X protein on liver cells in vivo, we generated four lines of transgenic mice carrying the X gene open reading frame under the control of the human alpha-1-antitrypsin regulatory region. The plasmid construct used to introduce the transgene was shown to encode a 16-kDa X protein with transactivating capability. The expression of X protein was detectable in liver tissue of transgenic animals of three of the lines by immunoblot analysis; levels of expression were highest in the first month after birth of the animals. Over 80 animals from the expressing lines were examined histologically. Most transgenic mice, some of which were observed for up to 2 years, remained normal. However, a few transgenic animals developed mild focal hepatitis, nuclear pleomorphism, focal necrosis, and/or nodular hyperplasia in the liver. Increased mitotic activity of hepatocytes also was observed. We conclude that, at the level of expression achieved in these transgenic mice, the hepatitis B virus transcriptional transactivator X protein alone does not appear to mediate the development of serious liver damage or hepatocellular carcinomas.

Tissue-specific expression of the rat growth hormone gene is due to the interaction of multiple promoter, not enhancer, elements

Expression of the rat growth hormone (rGH) gene is highly tissue-specific, being limited to a subset of cells in the anterior pituitary. DNA sequences within 237 bp of the transcription start site of the rGH gene play a major role in directing the expression of this gene in the pituitary. Transfection studies in cultured rat pituitary (GC) cells demonstrate that optimal expression of rGH requires the binding of at least two non-tissue-specific factors whose contribution to rGH expression is dependent on the binding of the pituitary-specific factor, Pit-1. Although the segment of DNA containing the elements to which these factors bind can direct pituitary-specific expression of a gene lacking upstream promoter elements, it cannot confer stimulation to either a heterologous or homologous promoter when placed downstream from the coding sequences. These results suggest that expression of the rGH gene exclusively in the pituitary is due to the activity of a tissue-specific promoter element, not an enhancer.

Heterologous protein expression by transimmortalized differentiated liver cell lines derived from transgenic mice (hepatomas/alpha 1 antitrypsin/ONC mouse)

A number of therapeutic plasma proteins are synthesized by human hepatocytes. Since many of these proteins undergo liver-specific post-translational modifications which are required for full biological activity, it may therefore be necessary to develop hepatocyte-based expression systems for their production. Using transgenic mice we have developed a transimmortalisation technique for the isolation of differentiated hepatic cell lines, already engineered to secrete human alpha 1 antitrypsin (alpha 1 AT), a plasma protein which is produced mainly in liver cells. This was achieved by co-expression of the mouse c-myc proto-oncogene and a genomic copy of the human alpha 1 AT gene, both under the control of the human alpha 1 AT promoter. Transgenic mice carrying this construct developed hepatomas producing human alpha 1 AT. Under defined culture conditions, cell lines secreting active alpha 1 AT were derived from these tumours. These cells maintain a differentiated hepatic phenotype and continue to secrete human alpha 1 AT for at least 40 generations.