Ligand-dependent regulation of vascular endothelial growth factor and erythropoietin expression by a plasmid-based autoinducible GeneSwitch system.

We investigated the ability of an improved mifepristone-dependent GeneSwitch system to regulate the expression of genes for two therapeutic proteins: vascular endothelial growth factor (VEGF) and erythropoietin. The GeneSwitch system consisted of two plasmids, one encoding the chimeric GeneSwitch protein, the other an inducible transgene. When the constitutive CMV promoter of the GeneSwitch plasmid was replaced by an autoinducible promoter consisting of four copies of GAL4 DNA binding sites linked to a minimal thymidine kinase promoter, the tightness of transgene regulation was improved by an order of magnitude. Quantitative RT-PCR analysis of GeneSwitch mRNA confirmed that the autoinducible promoter was responsive to mifepristone. We demonstrated the ability of the improved GeneSwitch system to regulate the expression of VEGF or erythropoietin in a biologically relevant manner after delivery of plasmids to the hind-limb muscle of adult mice. This ability of the autoinducible GeneSwitch system to regulate the expression of therapeutic proteins in mice indicates its potential for use in human gene therapy applications.

Ligand-dependent regulation of plasmid-based transgene expression in vivo.

As gene therapy advances, the ability to regulate transgene expression will become paramount for safety and efficacy. In this study, we investigate the ability of the mifepristone-dependent GeneSwitch system to regulate the expression of trangenes delivered to mice by nonviral methods. Two plasmids, one encoding the chimeric GeneSwitch protein, the other an inducible transgene for secreted human placental alkaline phosphatase (SEAP), were delivered to the hind-limb muscles of adult mice. Modulation of the level of secretion of the transgene product into serum was achieved by intraperitoneal administration of low doses of the drug mifepristone (MFP). The EC50 for induction of transgene expression by MFP was 0.03 +/- 0.005 mg/kg. The maximal level of transgene expression after induction was equal to or higher than that displayed by a plasmid driven by the CMV enhancer/promoter. The average magnitude of induction was 14- to 19-fold. Multiple rounds of drug-dependent regulation of transgene expression in vivo were demonstrated. In BALB/c mice, the ability to regulate transgene expression persisted for approximately 3 weeks, until the appearance of neutralizing antibodies to the secreted transgene product. In immune-deficient mice, the ability to repetitively regulate transgene expression persisted for at least 5 weeks. Although the dynamic range of regulation needs improvement, the plasmid-based GeneSwitch system has features that are attractive for gene therapy applications.

Inhibition of mature IL-1 beta production in murine macrophages and a murine model of inflammation by WIN 67694, an inhibitor of IL-1 beta converting enzyme.

The proinflammatory cytokine IL-1 beta is synthesized by activated monocytes and macrophages as a 31-kDa, biologically inactive precursor that is proteolytically processed to the biologically active 17-kDa mature molecule by the IL-1 beta converting enzyme (ICE). WIN 67694, Z-Val-Ala-Asp-CH2O(CO)[2,6-(CI2)]Ph, is a potent, selective inhibitor of human ICE. In activated murine peritoneal macrophages, WIN 67694 inhibited the release of mature IL-1 beta with an IC50 of 1.8 microM without any effect on the release of IL-1 alpha, IL-6, or TNF-alpha. The effect was specific to mature IL-1 beta release; the ICE inhibitor did not effect IL-1 beta RNA levels or precursor protein synthesis. In vivo, WIN 67694 was also able to inhibit selectively the release of IL-1 beta in a dose-dependent manner in a subcutaneous tissue chamber implant model of inflammation. IL-1 beta levels in tissue chamber fluid were inhibited 35 and 55% at 10 and 100 mg/kg, respectively. IL-1 alpha, IL-6, and TNF-alpha levels were not affected. The ability to selectively inhibit mature IL-1 beta release in vivo with ICE inhibitors will allow for detailed studies of the role of IL-1 beta and ICE in inflammatory diseases.

Down-regulation of calcitonin gene transcription by vitamin D requires two widely separated enhancer sequences.

Transcription of the calcitonin (CT) gene is down-regulated by vitamin D in normal and transformed thyroid C cells. DNA transfer techniques have been previously used to map and characterize a cAMP-induced enhancer at nucleotides -255 to -129 and an enhancer of basal transcription at -1060 to -905 in the CT 5' flanking DNA. The same methods were used to identify a negative response element for vitamin D. Deletion mutants of a genomic fragment of CT extending from nucleotides -1460 to +90 were attached to a promoterless GH gene and transfected individually into the medullary thyroid carcinoma cell line TT. CT nucleotides -1460 to -129 induced significant basal transcription of the GH reporter gene in TT cells. Basal transcription was elevated 3-fold to 4-fold by treatment with cAMP analog. The biologically active metabolite of vitamin D3, 1,25-dihydroxyvitamin D3, had a minor (20%) inhibitory effect on basal transcription but inhibited more than 60% of the cAMP-induced transcription. We further investigated the cAMP-induced response and found that transcriptional activity of the downstream cAMP-induced enhancer was greatly synergized in the presence of the upstream enhancer of basal transcription. The latter enhancer contained three functional CANNTG sequences designated E1 (nucleotides -1060 to -1030), E2 (nucleotides -940 to -920), and E3 (nucleotides -920 to -900). E2 and E3 were essential for maximal cAMP-induced transcription. Detailed mapping of the vitamin D response showed that a minimum requirement for inhibition of the cAMP-induced enhancer by vitamin D was a sequence overlapping E3 (nucleotides -920 to -829). We conclude that a negative response element to vitamin D is located between nucleotides -920 and -829 in the CT 5' flanking DNA. It is possible that vitamin D inhibits transcription by interfering with the synergistic interaction between the cAMP-induced enhancer and the enhancer of basal transcription.

Transcription of the human calcitonin gene is mediated by a C cell-specific enhancer containing E-box-like elements.

The calcitonin (CT) gene is expressed normally in thyroidal C-cells and in a restricted population of cells in the central and peripheral nerve system. To define the cis-elements within the 5'-flanking DNA of the human CT gene which mediate this cell-specific expression, we used DNA transfer techniques and a transient transfection approach. We found that a DNA sequence located between -1290 and -820 of the CT 5'-flanking DNA functioned as an enhancer of basal transcription in C-cells (from medullary thyroid carcinoma) but not in rat glioma (C6), hamster insulinoma (HIT), fibroblasts (3T3), or epithelial cells (HeLa and CV1). Further mapping revealed the presence of at least two elements within the enhancer region; an upstream element (USE, located between -1060 and -1030) which could not function independently but its removal caused 70-80% loss of enhancer activity and a downstream element (DSE, located at -1033 to -920) which functioned independently as a cell-specific enhancer but with reduced activity. The binding pattern of nuclear proteins from C-cells to the enhancer elements was studied by an electrophoretic mobility shift assay. A protein-DNA complex was formed with the USE which could be competed, specifically, by an oligonucleotide containing the microE2 motif of the immunoglobulin gene enhancer. A similar complex was formed with the DSE fragment. Nuclear proteins from HeLa cells failed to form complexes with USE. Moreover, the binding pattern of proteins derived from HeLa cells to DSE was different from that of C-cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Transfection of calcitonin gene regulatory elements into a cell culture model of the C cell.

Calcitonin gene expression in the TT cell line can be regulated by phorbol esters, cAMP, glucocorticoids, and 1,25-dihydroxyvitamin D3. To further study the regulation of this gene we have sequenced 1460 bases 5' to the start of calcitonin gene transcription. This DNA sequence contains cis consensus elements for both phorbol ester- and cAMP-responsive elements. To study the role of these elements, calcitonin 5' flanking DNA was coupled to the human growth hormone gene as a reporter and transiently transfected into TT cells, a human thyroid C cell line. Treatment of transfected TT cells stimulated a two- to fivefold increase in reported gene product expression, confirming the existence of functional cAMP- and phorbol ester-dependent enhancers within the calcitonin 5' flanking sequence.

Transcriptional regulation of the human calcitonin gene: a progress report.

We have applied DNA transfer techniques to study the transcriptional regulation of the calcitonin (CT) gene in a C-cell line (TT) derived from a human medullary thyroid carcinoma. TT cells were transfected with a fusion gene containing the CT gene promoter and 5'-flanking DNA attached to the promoter-less growth hormone gene (reporter). We quantitated the reporter gene product to monitor transcriptional activation by the CT promoter and deletion mutants of the 5'-flanking DNA. We found that the proximal CT promoter which includes the DNA sequence from +1 to -129 bp upstream from the CT transcription start site did not induce transcription in C-cells or in NIH 3T3 cells. The attachment of additional 5'-flanking DNA, extending up to -1460 bp enhanced transcription up to twelvefold in TT cells but had no effect on transcription in 3T3 cells. Deletion of a sequence located at -1290 to -820 bp on the CT 5'-flanking DNA abolished the transcription of the reporter gene. Attachment of the DNA sequence located between -1333 to -731 to the fusion gene, containing the CT promoter (+1 to -129) and the reporter gene, restored transcription of the reporter gene in TT cells. We conclude that an enhancer of CT transcription, which is active in C-cells but not in 3T3 cells, is located between -1290 and -820 of the CT 5'-flanking DNA.