Autoimmune antigen Ku is enriched on oligonucleotide columns distinct from those containing the octamer binding protein DNA consensus sequence

During purification of the AP1 complex from the T cell line MLA144 we enriched for a complex which bound to an oligonucleotide column containing the AP1 DNA consensus sequence and co-eluted with a fraction required for AP1 binding activity. This complex although co-eluting with AP1 binding activity had previously been determined to be non-specific in its DNA binding properties. Further investigation determined that the complex was a heterodimer of 85 and 70 kDa which was antigenically related to the autoimmune antigen Ku. It is important to be aware of the abundance and avidity of the Ku complex to bind oligonucleotide columns when purifying sequence specific binding proteins.     

Purification of the c-fos enhancer-binding protein.

We have purified the c-fos enhancer-binding protein from HeLa cell nuclear extracts. The key purification steps involved chromatography on a nonspecific DNA affinity column, from which binding activity and other protein were eluted at low salt concentrations, followed by chromatography on a specific oligonucleotide affinity column, from which the enhancer binding activity was specifically eluted at high salt concentrations. The purified protein had a strong affinity for the c-fos enhancer dyad symmetry sequence, with an equilibrium dissociation constant of 3.3 x 10(-11) M. This affinity was at least 50,000-fold stronger than that found for nonspecific DNA sequences.     

Distinct factors bind the AP-1 consensus sites in gibbon ape leukemia virus and simian virus 40 enhancers.

We have demonstrated that the gibbon ape leukemia virus (GALV) enhancer AP-1 element and the simian virus 40 AP-1 enhancer element bind different factors in HeLa nuclear extracts. A 39-kilodalton HeLa nuclear protein and the c-fos protein bind to the GALV element. Antibodies to c-fos abolish binding to the GALV AP-1 site. In contrast, anti-c-fos immunoglobulin fails to inhibit formation of the simian virus 40-specific complex from extracts of HeLa cells. Thus, AP-1-binding complexes are subject to compositional variation at different binding sites.     

Identification of phorbol ester response elements in the promoter of Epstein-Barr virus putative lytic switch gene BZLF1

The product of the Epstein-Barr virus BZLF1 gene encodes a protein which is related to c-fos, it has been shown to bind specifically to a consensus AP-1 site, and its expression in latently Epstein-Barr virus-infected lymphocytes is sufficient to trigger the viral lytic cycle. We identified several elements within the BZLF1 promoter (Zp) which are responsive to the phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA), an inducer of the viral lytic cycle. These elements fall into two classes based on the factors which bind to these sequences and their resulting functional behavior. Four of the elements are homologous (ZI elements) and share homology to a protein-binding domain in the promoter region of the coordinately expressed BRLF1 gene. When cloned upstream of heterologous promoters, the ZI elements function as silencers which exhibit TPA-inducible enhancer activity. A distinct TPA-responsive element (ZII) is located near the TATA box and shares homology with the AP-1-binding site in the c-jun promoter. A synthetic oligonucleotide with a sequence corresponding to the ZII element effectively competes for binding of nuclear factors to the c-jun AP-1 site. Furthermore, we found that a complex of c-jun and c-fos bound to the ZII domain.     

Binding of a cellular protein to the gibbon ape leukemia virus enhancer.

The gibbon ape leukemia virus (GALV) contains enhancer activity within its long terminal repeat. In the GALV Seato strain this activity resides in a 48-base-pair (bp) repeated element. We demonstrate the existence of a cellular protein which binds in this region of the Seato strain. A sensitive method for enriching protein-DNA complexes from crude extracts coupled with exonuclease and DNase footprint analysis revealed the specific binding of this protein to a 21-bp region within each repeated element. A 22-bp oligonucleotide fragment defined solely by the 21-bp footprint binds a protein in vitro and displays enhancer activity in vivo, suggesting that this protein is a major determinant of GALV enhancer activity. The protein is present in three cell lines which are positive for enhancer activity and is not detected in Jurkat cells, which are negative for enhancer activity. Only GALV long-terminal-repeat variants which support high levels of enhancer activity in vivo compete with this protein for specific binding in vitro, suggesting a potential role for the protein in determining enhancer activity. This protein binding is not inhibited by competition with heterologous retroviral enhancers, demonstrating that it is not a ubiquitous retroviral enhancer binding protein.     

Two different factors bind to the alpha-domain of the polyoma virus enhancer, one of which also interacts with the SV40 and c-fos enhancers.

Two nuclear factors from mouse 3T6 cells bind to a 22-bp segment constituting the alpha-domain of the polyoma virus enhancer. Binding of each factor can be competed out selectively by the appropriate double-stranded oligonucleotide, indicating that this binding is not strictly cooperative. Sequence homology between the two binding sites and the similar size of the protected regions may indicate that both factors, PEA1 and PEA2, are closely related. The binding site of PEA1 is centered on a sequence showing strong homology to the SV40 enhancer, the binding site of PEA2 is located immediately adjacent to it and shows a strong homology to the c-fos enhancer. Surprisingly, both SV40 and c-fos enhancers interact with PEA1, probably due to the presence of an extra base pair relative to c-fos in the PEA2 site. Factor PEA1 is probably identical to the recently described activator protein 1 (AP1).     

Purification of a 130-kDa T cell glycoprotein that binds human interleukin 4 with high affinity

The interleukin 4 (IL-4) receptor was purified from the gibbon T cell line MLA 144. These cells were found to express high numbers of human IL-4-binding proteins (5000-6000 sites/cell) with an affinity constant (Kd) similar to that measured in human cell lines (Kd = 40-70 pM). Affinity cross-linking of 125I-IL-4 to human cell lines and MLA 144 cells demonstrated the labeling of three proteins of approximately 130, 75, and 65 kDa. Human IL-4-binding sites were solubilized from MLA 144 cells using Triton X-100 and then purified by carboxymethyl chromatography, which removed 50% of the protein without loss of IL-4-binding activity. Then sequential affinity purification over wheat germ agglutinin and a single IL-4 Affi-Gel 10 column resulted in a final 8000-fold purification of the IL-4 receptor. When analyzed on a silver-stained sodium dodecyl sulfate-polyacrylamide gel, the purified receptor migrated as a single molecular species of 130 +/- 5 kDa. Identification of the 130-kDa protein as the IL-4 receptor was demonstrated by cross-linking experiments and specific binding of 125I-IL-4 to nitrocellulose membranes after electrophoretic transfer of the purified receptor on sodium dodecyl sulfate-polyacrylamide gel.