Several members of the ETS family of transcription factors contribute to tumorigenesis in many different tissues, including breast epithelium. The ESX gene is an epithelial-specific Ets member that is particularly relevant to breast cancer. ESX is amplified in early breast cancers, it is overexpressed in human breast ductal carcinoma in situ, and there may be a positive feedback loop between the HER2/neu proto-oncogene and ESX. Despite this progress in our understanding of ESX, its ability to regulate tumor-related gene expression and to modulate breast cell survival, remain unknown. Here we show that HA-ESX stimulates the collagenase and HER2/neu promoters, but fails to activate an intact stromelysin promoter. However, HA-ESX activates, in a dose-dependent manner, a heterologous promoter containing eight copies of the Ets binding site derived from the stromelysin gene (p8Xpal-CAT). Analysis of the ability of constructs encoding nine Ets family members to activate the HER2/neu promoter revealed three patterns of gene activation: (1) no effect or repressed promoter activity (Elk-1 and NET); (2) intermediate activity (ER81, GABP, ESX, and HA-Ets-2); and, (3) maximal activity (Ets-1, VP-16-Ets-1, and EHF). Based on these observations, we also determined whether ESX is capable of conferring a survival phenotype upon immortalized, but nontransformed and ESX negative MCF-12A human breast cells. Using a colony formation assay, we found that HA-ESX and HA-Ets-2, mediated MCF-12A cell survival rates that approached those generated by oncogenic V12 Ras, whereas empty vector resulted in negligible colony formation. By contrast, in immortalized and transformed T47D breast cancer cells, which express both HER2/neu and ESX, we found that antisense and dominant-negative HA-ESX inhibited T47D colony formation, whereas control vector allowed formation of many colonies. These results are significant because they show that HA-ESX is able to differentially activate several malignancy-associated gene promoters, and that ESX expression is required for cellular survival of nontransformed MCF-12A and transformed T47D human mammary cells.
Pit-1, a pituitary-specific POU homeodomain transcription factor, specifies three anterior pituitary lineages; governs growth hormone, prolactin, and thyrotropin gene expression; and mediates basal and Rasstimulated prolactin promoter activity in GH 4 pituitary cells. Alternate splicing of the Pit-1 message produces the Pit-1 isoform, which contains a 26-amino acid insertion, the -domain, within the amino-terminal transactivation domain. The -domain functions as a molecular switch, such that Pit-1 blocks both basal and Rasstimulated prolactin promoter activity in GH 4 pituitary cells yet preferentially enhances protein kinase A-stimulated prolactin promoter activity in a HeLa reconstitution system. To determine whether the amino acid sequence of the -domain dictates function, we replaced it with five different 26-amino acid sequences. These mutants fail to block basal or Ras-stimulated rat prolactin promoter activity and fail to optimally enhance the protein kinase A response of prolactin promoter. These data demonstrate that the amino acid sequence of the -domain specifies its role as a molecular switch. Additionally, the presence of both Pit-1 and Pit-1 in pituitary cells allows diverse incoming signals to utilize structurally different forms of the same gene product, which can interact with distinct co-factors, integrating multiple signaling pathways at the level of the nucleus.
Pit-1/GHF-1 is a pituitary-specific, POU homeodomain transcription factor required for development of somatotroph, lactotroph, and thyrotroph cell lineages and regulation of the temporal and spatial expression of the growth hormone, prolactin (PRL), and thyrotropin- genes. Synergistic interaction of Pit-1 with a member of the Ets family of transcription factors, Ets-1, has been shown to be an important mechanism regulating basal and Ras-induced lactotroph-specific rat (r) PRL promoter activity. Pit-1/GHF-2, an alternatively spliced isoform containing a 26-amino acid insert (-domain) within its transcription-activation domain, physically interacts with Ets-1 but fails to synergize. By using a series of Pit-1 internal-deletion constructs in a transient transfection protocol to reconstitute rPRL promoter activity in HeLa cells, we have determined that the functional and physical interaction of Pit-1 and Ets-1 is mediated via the POU homeodomain, which is common to both Pit-1 and Pit-1. Although the Pit-1 homeodomain is both necessary and sufficient for direct binding to Ets-1 in a DNA-independent manner, an additional interaction surface was mapped to the -domain, specific to the Pit-1 isoform. Thus, the unique transcriptional properties of Pit-1 and Pit-1 on the rPRL promoter may be due to the formation of functionally distinct complexes of these two Pit-1 isoforms with Ets-1.
To generate a collection of conditionally defective poliovirus mutants, clustered charged-to-alanine mutagenesis of the RNA-dependent RNA polymerase 3D was performed. Clusters of charged residues in the polymerase coding region were replaced with alanines by deoxyoligonucleotide-directed mutagenesis of a full-length poliovirus cDNA clone. Following transfection of 27 mutagenized cDNA clones, 10 (37%) gave rise to viruses with temperature-sensitive (ts) phenotypes. Three of the ts mutants displayed severe ts plaque reduction phenotypes, producing at least 103-fold fewer plaques at 39.5°C than at 32.5°C; the other seven mutants displayed ts small-plaque phenotypes. Constant-temperature, single-cycle infections showed defects in virus yield or RNA accumulation at the nonpermissive temperature for eight stable ts mutants. In temperature shift experiments, seven of the ts mutants showed reduced accumulation of viral RNA at the nonpermissive temperature and showed no other ts defects. The mutations responsible for the phenotypes of most of these ts mutants lie in the N-terminal third of the 3D coding region, where no well-characterized mutations responsible for viable mutants had been previously identified. Clustered charged-to-alanine mutagenesis (S. H. Bass,
Poliovirus RNA-dependent RNA polymerase 3D and viral protein 3AB are both thought to be required for the initiation of RNA synthesis. These two proteins physically associate with each other and with viral RNA replication complexes found on virus-induced membranes in infected cells. An understanding of the interface between 3D and 3AB would provide a first step in visualizing the architecture of the multiprotein complex that is assembled during poliovirus infection to replicate and package the viral RNA genome. The identification of mutations in 3D that diminish 3D-3AB interactions without affecting other functions of 3D polymerase is needed to study the function of the 3D-3AB interaction in infected cells. We describe the use of the yeast two-hybrid system to isolate and characterize mutations in 3D polymerase that cause it to interact less efficiently with 3AB than wild-type polymerase. One mutation, a substitution of leucine for valine at position 391 (V391L), resulted in a 3AB-specific interaction defect in the two-hybrid system, causing a reduction in the interaction of 3D polymerase with 3AB but not with another viral protein or a host protein tested. In vitro, purified 3D-V391L polymerase bound to membrane-associated 3AB with reduced affinity. Poliovirus that contained the 3D-V391L mutation was temperature sensitive, displaying a pronounced conditional defect in RNA synthesis. We conclude that interaction between 3AB and 3D or 3D-containing polypeptides plays a role in RNA synthesis during poliovirus infection.
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