Protein kinase C isozymes differentially regulate promoters containing PEA-3/12-O-tetradecanoylphorbol-13-acetate response element motifs.

To investigate the regulation of promoters containing classical phorbol ester response sequences (PEA-3/12-O-tetradecanoylphorbol-13-acetate response element motifs) by protein kinase C (PKC) isozymes, co-transfections were performed in human dermal fibroblasts with a plasmid containing either the human collagenase promoter or the porcine urokinase plasminogen activator (uPA) promoter linked to the chloramphenicol acetyltransferase gene and a plasmid expressing an individual PKC isozyme. Using this experimental design, seven PKC isozymes were analyzed for their ability to trans-activate the collagenase and uPA promoters. Our results demonstrate that only PKC delta, epsilon, and eta trans-activated the collagenase promoter and that binding of Ap-1 family members to the collagenase 12-O-tetradecanoylphorbol-13-acetate response element (TRE) was not responsible for the isozyme-specific trans-activation. In contrast, the uPA promoter was stimulated by all of the PKC isozymes examined (PKC alpha, betaII, gamma, delta, epsilon, zeta, and eta). These results indicate that PKC isozymes differentially regulate promoters containing PEA-3/TRE motifs and suggest that individual isozymes play unique roles within the cell.

Tyrosine phosphorylation regulates the DNA binding activity of a nuclear factor 1-like repressor protein.

We have previously identified an ubiquitous repressor binding site that binds a nuclear factor 1 (NF-1)-like transcription factor designated BEF-1. The DNA binding activity of BEF-1, a 98-kDa protein, is increased by the oncoproteins of adenovirus, the early region 1a proteins (E1a), which results in the induction of further repression. Using the prototype repressor sequence, first identified in the enhancer of the human polyoma virus BKV-P2 we have shown that phosphorylation of BEF-1 is required for its DNA binding activity. We demonstrate here that the inhibition of DNA binding by BEF-1 dephosphorylated with potato acid phosphatase or calf intestinal alkaline phosphatase was reversed by sodium orthovanadate, a specific inhibitor of phosphotyrosyl-protein phosphatases. In addition, BEF-1 binding activity, but not the binding of related factor NF-1, could be inhibited by dephosphorylation with a specific phosphotyrosine phosphatase. We found that both polyclonal and monoclonal phosphotyrosine-specific antibodies blocked binding of the repressor protein to the BEF-1 site. Moreover, BEF-1 activity could be adsorbed on an anti-phosphotyrosine antibody column and specially eluted with phosphotyrosine. In transfection studies in HeLa cells, which contain high levels of BEF-1, we show that E1a-induced repression mediated by BEF-1 was relieved with the tyrosine kinase inhibitors genistein and tyrphostin. Together, these results demonstrate that a phosphotyrosine on the BEF-1 repressor protein regulates DNA binding activity and thus regulates repression of the BKV-P2 enhancer. This report represents the first demonstration that the phosphorylated state of a tyrosine can control gene expression by altering the DNA binding activity of a transcription factor.

Repression of enhancer activity by the adenovirus E1A tumor protein(s) is mediated through a novel HeLa cell nuclear factor.

We have examined the mechanism for the host cell-dependent repression of enhancer activity by the adenovirus early region 1A (E1A) proteins. The enhancer used in this study, from the human BK virus P2, functions efficiently in cis to activate expression from the adenovirus major late promoter in the human kidney cell line, 293, and in a monkey kidney cell line, MK2. In addition, enhancer activity can be stimulated by the E1A gene products in these cells. However, cis-enhancer activity is repressed in the HeLa cell line, and we demonstrate here that further repression can be induced by the E1A proteins. We show that the binding site for the negative regulatory factor involved in cis-repression, designated BK virus enhancer factor 1 (BEF-1), is also required for E1A-induced repression. Using gel mobility retardation assays, we demonstrated a 4-fold increase in active BEF-1 in nuclear extracts containing the E1A proteins. However, the E1A proteins did not change the binding pattern or the strength of binding of BEF-1 to its target sequence. BEF-1 was identified as a 98-kDa nuclear factor, and phosphorylation was shown to be important for DNA binding. Three potential nuclear factor 1 (NF-1) sites are present in the BEF-1-binding site. Using a known NF-1 site as competitor DNA in a gel mobility retardation assay, we provide evidence that BEF-1 may be a newly identified NF-1 family member. In addition, the sequence TGA present in the repressor-binding site was shown to be essential for high affinity binding of BEF-1. Overall, our data demonstrate that an enhancer can be repressed by the trans-activation of a negative regulatory factor.

Detection of an IE responsive element(s) in the BamHI J fragment of human cytomegalovirus AD169.

The BamHI J fragment of human cytomegalovirus (HCMV) AD169 located at 0.815 to 0.855 map units in the unique short component of the genome was demonstrated to be responsive to the HCMV IE proteins by using a transient chloramphenicol acetyltransferase (cat) gene expression system. The BamHI J fragment was cloned into a cat gene expression plasmid and then cotransfected with a plasmid that expresses the immediate early (IE) genes of HCMV AD169 into the HCMV permissive cell line MRC-5. The results indicated that the BamHI J fragment enhanced cat gene expression 10-fold when the HCMV IE proteins were present. The BamHI J fragment was demonstrated to have properties of an inducible enhancer. In the presence of the HCMV IE proteins, it enhances cat gene expression when positioned in either orientation both upstream and downstream from the cat gene; it enhances transcription from the herpes simplex virus type 1 (HSV-1) thymidine kinase gene and the simian virus 40 (SV40) early gene promoters; and it requires a cis-positioned promoter for enhancer activity.

E1A-induced enhancer activity of the poly(dG-dT).poly(dA-dC) element (GT element) and interactions with a GT-specific nuclear factor.

The alternating sequence poly(dG-dT).poly(dA-dC) is a highly repeated sequence in the eucaryotic genome. We have examined the effect of trans-acting early viral proteins on the ability of the GT element to stimulate transcription of the adenovirus major late promoter (MLP). We find that the GT element alone does not activate expression from the MLP in either the presence or absence of another enhancer element. However, in the presence of the E1A gene products of either adenovirus type 5 or 2, the GT element activated expression from the MLP. The stimulatory activity of the GT element in the presence of E1A had the properties of an enhancer element, and the trans-activating effect on the GT element was additive in conjunction with the E1A-responsive BK virus enhancer. We also have demonstrated that a specific nuclear factor(s) binds to the GT element. However, the E1A protein(s) do not affect the initial factor interaction(s) with the GT element. Overall, our data demonstrate that trans modulation of promoter activity can be mediated through the GT element.