Cross-binding of factors to functionally different promoter elements in c-fos and skeletal actin genes.

A conserved 28-base-pair element in the skeletal actin promoter was sufficient to activate muscle-specific expression when placed upstream of a TATA element. This muscle regulatory element (MRE) is similar in structure to the serum response element (SRE), which is present in the promoters of the c-fos proto-oncogene and the nonmuscle actin genes. The SRE can function as a constitutive promoter element. Though the MRE and SRE differed in their tissue-specific expression properties, both elements bound to the same protein factors in vitro. These proteins are the serum response factor (SRF) and the muscle actin promoter factors 1 and 2 (MAPF1 and MAPF2). The SRF and MAPF proteins were resolved by chromatographic procedures, and they differed in their relative affinities for each element. The factors were further distinguished by their distinct, but overlapping, methylation interference footprint patterns on each element. These data indicate that the differences in tissue-specific expression may be due to a complex interaction of protein factors with these sequences.     

Maximal serum stimulation of the c-fos serum response element requires both the serum response factor and a novel binding factor, SRE-binding protein.

We have previously reported on the presence of a CArG motif at -100 in the Rous sarcoma virus long terminal repeat which binds an avian nuclear protein termed enhancer factor III (EFIII) (A. Boulden and L. Sealy, Virology 174:204-216, 1990). By all analyses, EFIII protein appears to be the avian homolog of the serum response factor (SRF). In this study, we identify a second CArG motif (EFIIIB) in the Rous sarcoma virus long terminal repeat enhancer at -162 and show only slightly lower binding affinity of the EFIII/SRF protein for this element in comparison with c-fos serum response element (SRE) and EFIII DNAs. Although all three elements bind the SRF with similar affinities, serum induction mediated by the c-fos SRE greatly exceeds that effected by the EFIII or EFIIIB sequence. We postulated that this difference in serum inducibility might result from binding of factors other than the SRF which occurs on the c-fos SRE but not on EFIII and EFIIIB sequences. Upon closer inspection of nuclear proteins which bind the c-fos SRE in chicken embryo fibroblast and NIH 3T3 nuclear extracts, we discovered another binding factor, SRE-binding protein (SRE BP), which fails to recognize EFIII DNA with high affinity. Competition analyses, methylation interference, and site-directed mutagenesis have determined that the SRE BP binding element overlaps and lies immediately 3' to the CArG box of the c-fos SRE. Mutation of the c-fos SRE so that it no longer binds SRE BP reduces serum inducibility to 33% of the wild-type level. Conversely, mutation of the EFIII sequence so that it binds SRE BP with high affinity results in a 400% increase in serum induction, with maximal stimulation equaling that of the c-fos SRE. We conclude that binding of both SRE BP and SRF is required for maximal serum induction. The SRE BP binding site coincides with the recently reported binding site for rNF-IL6 on the c-fos SRE. Nonetheless, we show that SRE BP is distinct from rNF-IL6, and identification of this novel factor is being pursued.     

A family of muscle gene promoter element (CArG) binding activities in Xenopus embryos: CArG/SRE discrimination and distribution during myogenesis.

The CArG box is an essential promoter sequence for cardiac muscle actin gene expression in Xenopus embryos. To assess the role of the CArG motif in promoter function during Xenopus development, the DNA-binding activities present in the embryo that interact with this sequence have been investigated. A family of four Embryo CArG box1 Factors (ECFs) was separated by a 2-step fractionation procedure. These factors were distinct from the previously described C-ArG box binding activity Serum Response Factor (SRF). ECF1 was the most prominent binding activity in cardiac actin-expressing tissues, and bound the CArG box in preference to a Serum Response Element (SRE). SRF was also detectable in muscle, but it bound preferentially to an SRE. The properties of ECF3 were similar to those of ECF1, but it was much less prominent in cardiac actin-expressing tissues. The properties of the two other factors were distinctive: ECF2 was of relatively low affinity and high abundance, whilst ECF4 bound non-specifically to ends of DNA. The binding activity (or activities) that interacted with the CArG box was found to be influenced by both the concentrations of the other CArG box binding activities and the sequence of the site. Although there was no evidence for a muscle-specific CArG box binding activity, the properties of ECF1 suggest that it could play a role in the expression of the cardiac actin gene during Xenopus development.     

Sequences at the 3' side of the c-fos SRE mediate gene expression via an Sob1-dependent, TCF-independent pathway.

We previously described a 110-kDa tyrosine phosphoprotein, Sob 1, that regulates formation of the DNA binding complex Band A at the c-fos serum response element (SRE) during T cell activation. Using competition and mutant oligonucleotide analysis, we have determined that both the core CArG box of the c-fos SRE and the 3' sequences flanking the CArG box are necessary for stable Band A complex formation. Moreover, using transient transfection and reporter assays, we show that mutations affecting Band A complex formation in vitro also impaired serum induction of c-fos gene expression in vivo. Since mutation at this site has no effect on SRF binding, our results suggest that in combination with SRE/SRF, Sob 1-regulated factor(s) bind at the 3' side of SRE to form Band A, and this confers maximal serum induction of c-fos gene expression via the SRE.     

Functional serum response elements upstream of the growth factor-inducible gene zif268.

The zif268 gene, which encodes a protein with three typical zinc finger sequences, is induced in mouse 3T3 cells by serum, phorbol 12-myristate 13-acetate platelet-derived growth factor, and fibroblast growth factor. The induction is coordinate with that of c-fos. The 5'-flanking region of zif268 contains sequences that resemble known regulatory elements, including four CC(A or T)6GG sequences similar to the core serum response elements (SREs) found upstream of c-fos and actin genes. To determine whether the zif268 SRE-like elements mediate induction, CAT (chloramphenicol acetyltransferase) plasmids with different lengths of zif268 upstream sequences were tested for inducibility in 3T3 cells by serum, platelet-derived growth factor, or phorbol 12-myristate 13-acetate. In addition, double-stranded oligonucleotides corresponding to each of the four zif268 putative SREs were tested individually for responsiveness when placed upstream of a thymidine kinase gene promoter. Each of the four SREs conferred inducibility by the agents tested, and multiple SREs resulted in greater inducibility than did a single element. Each of the zif268 SREs also competed with the c-fos SRE for binding by serum response factor present in HeLa cell nuclear extract. We conclude that the zif268 SRE-like sequences are functional and probably account for the coordinate induction of zif268 and c-fos.     

A zebrafish homolog of the serum response factor gene is highly expressed in differentiating embryonic myocytes.

Serum response factor (SRF) was identified as an activity binding upon serum stimulation of HeLa cells to a motif known as the serum response element in the c-fos promoter. This element is also found in the regulatory regions of many muscle-specific genes. We have characterized srf expression during early zebrafish embryogenesis. In addition to low-level expression in many or even all cells, elevated levels of srf RNA and protein are transiently expressed in skeletal muscle lineages during their differentiation.