The Oct-2 protein binds cooperatively to adjacent octamer sites

Transcription factors NFI and NFIII/oct-1 function independently, employing different mechanisms to enhance adenovirus DNA replication

Initiation of adenovirus DNA replication is strongly enhanced by two transcription factors, nuclear factor I (NFI) and nuclear factor III (NFIII/oct-1). These proteins bind to two closely spaced recognition sequences in the origin. We produced NFI and NFIII/oct-1, as well as their biologically active, replication-competent DNA-binding domains (NFI-BD and the POU domain), in a vaccinia virus expression system and purified these polypeptides to apparent homogeneity. By DNase I footprinting and gel retardation, we show that the two proteins, as well as their purified DNA-binding domains, bind independently and without cooperative effects to their recognition sequences. By using a reconstituted system consisting of the purified viral proteins (precursor terminal protein-DNA polymerase complex (pTP-pol) and DNA-binding protein, we show that NFIII/oct-1 or the POU domain stimulates DNA replication in the absence of NFI or NFI-BD and vice versa. When added together, the enhancing effect of the two transcription factors was independent and nonsynergistic. Interestingly, stimulation by NFI or NFI-BD was strongly dependent on the concentration of the pTP-pol complex. At low pTP-pol concentrations, NFI or NFI-BD stimulated up to 50-fold, while at high concentrations, the stimulation was less than twofold, indicating that the need for NFI can be overcome by high pTP-pol concentrations. In contrast, stimulation by NFIII/oct-1 or the POU domain was much less dependent on the pTP-pol concentration. These data support a model in which NFI enhances initiation through an interaction with pTP-pol. Glutaraldehyde cross-linking experiments indicate contacts between pTP-pol and NFI but not NFIII/oct-1. The site of interaction is located in the NFI-BD domain.

The promoter of the human interleukin-2 gene contains two octamer-binding sites and is partially activated by the expression of Oct-2

The gene encoding interleukin-2 (IL-2) contains a sequence 52 to 326 nucleotides upstream of its transcriptional initiation site that promotes transcription in T cells that have been activated by costimulation with tetradecanoyl phorbol myristyl acetate (TPA) and phytohemagglutinin (PHA). We found that the ubiquitous transcription factor, Oct-1, bound to two previously identified motifs within the human IL-2 enhancer, centered at nucleotides -74 and -251. Each site in the IL-2 enhancer that bound Oct-1 in vitro was also required to achieve a maximal transcriptional response to TPA plus PHA in vivo. Point mutations within either the proximal or distal octamer sequences reduced the response of the enhancer to activation by 54 and 34%, respectively. Because the murine T-cell line EL4 constitutively expresses Oct-2 and requires only TPA to induce transcription of the IL-2 gene, the effect of Oct-2 expression on activation of the IL-2 promoter in Jurkat T cells was determined. Expression of Oct-2 potentiated transcription 13-fold in response to TPA plus PHA and permitted the enhancer to respond to the single stimulus of TPA. Therefore, both the signal requirements and the magnitude of the transcription response of the IL-2 promoter can be modulated by Oct-2.

Short interspersed repeats from Xenopus that contain multiple octamer motifs are related to known transposable elements

We have identified in an intron of an X. laevis alpha-tubulin gene a member of a novel family of short (226-431 bp) interspersed repetitive elements. We have isolated other members of this family, which we term Ocr, from ovary cDNA and genome libraries and have identified another two in the published sequences of an H1B histone gene cluster and an actin gene intron. The termini of the Ocr elements are formed by a 19 bp inverted repeat that has clear sequence homologies to those of certain large transposable elements, such as 1723 (Xenopus) and Ac (maize). However, the Ocr elements do not appear to be deletion derivatives of larger transposons. The internal regions of the Ocr elements contain multiple copies of the octamer motif (ATTTGCAT) arranged as divergently-orientated dyads. We have shown by a gel mobility shift assay that these octamer dyads specifically bind what is presumably an OTF-type activator protein in oocyte nuclear extracts. We speculate that short interspersed repetitive families of this type may be generated by a mechanism of replicative transposition that uses a DNA intermediate and involves the interaction of DNA-binding proteins also utilised in other cellular processes.

Single cell assay of a transcription factor reveals a threshold in transcription activated by signals emanating from the T-cell antigen receptor

Stimulation of T lymphocytes through their antigen receptor leads to the appearance of several transcription factors, including NF-AT and NF-kappa B, which are involved in regulating genes required for immunologic activation. To investigate the activity of a single transcription factor in individual viable cells, we have applied an assay that uses the fluorescence-activated cell sorter to quantitate beta-galactosidase (beta-gal). We have analyzed the distribution of NF-AT transcriptional activity among T cells undergoing activation by using a construct in which three tandem copies of the NF-AT-binding site directs transcription of the lacZ gene. Unexpectedly, stimulation of cloned stably transfected Jurkat T cells leads to a bimodal pattern of beta-gal expression in which some cells express no beta-gal and others express high levels. This expression pattern cannot be accounted for by cell-cycle position or heritable variation. Further results, in which beta-gal activity is correlated with NF-AT-binding activity, indicate that the concentration of NF-AT must exceed a critical threshold before transcription initiates. This threshold likely reflects the NF-AT concentration-dependent assembly of transcription complexes at the promoter. Similar constructs controlled by NF-kappa B or the entire interleukin-2 enhancer show bimodal expression patterns during induction, suggesting that thresholds set by the concentration of transcription factors may be a common property of inducible genes.

The promoter of the human interleukin-2 gene contains two octamer-binding sites and is partially activated by the expression of Oct-2

The gene encoding interleukin-2 (IL-2) contains a sequence 52 to 326 nucleotides upstream of its transcriptional initiation site that promotes transcription in T cells that have been activated by costimulation with tetradecanoyl phorbol myristyl acetate (TPA) and phytohemagglutinin (PHA). We found that the ubiquitous transcription factor, Oct-1, bound to two previously identified motifs within the human IL-2 enhancer, centered at nucleotides -74 and -251. Each site in the IL-2 enhancer that bound Oct-1 in vitro was also required to achieve a maximal transcriptional response to TPA plus PHA in vivo. Point mutations within either the proximal or distal octamer sequences reduced the response of the enhancer to activation by 54 and 34%, respectively. Because the murine T-cell line EL4 constitutively expresses Oct-2 and requires only TPA to induce transcription of the IL-2 gene, the effect of Oct-2 expression on activation of the IL-2 promoter in Jurkat T cells was determined. Expression of Oct-2 potentiated transcription 13-fold in response to TPA plus PHA and permitted the enhancer to respond to the single stimulus of TPA. Therefore, both the signal requirements and the magnitude of the transcription response of the IL-2 promoter can be modulated by Oct-2.

MyoD binds cooperatively to two sites in a target enhancer sequence: occupancy of two sites is required for activation

MyoD is a master regulatory gene for myogenesis. Its product, the MyoD protein, appears to act by binding to muscle-specific enhancer sequences. We show that MyoD binds cooperatively to two sites in the muscle-specific creatine kinase enhancer; this is dramatically reflected in dissociation-rate measurements. A deletion of the acidic N terminus (residues 3-56) results in a protein that binds normally to single sites but fails to bind cooperatively to two adjacent sites, suggesting a role of the N terminus in cooperative interactions. In transfection assays, a reporter gene flanked by a single MyoD binding site fails to be activated by cotransfected MyoD expression vectors. In contrast, a reporter with two or more MyoD binding sites is activated by wild-type MyoD but not by N-terminally deleted MyoD. A reporter gene with a single binding site, although not activated by MyoD, can nonetheless compete for expression with a reporter gene containing three sites. Thus, in vivo, a single site can bind MyoD, but occupancy of two or more sites is required for subsequent transcriptional activation.

Identification of an octamer-binding site in the human kappa light-chain enhancer

Octamer motifs contribute to the function and tissue specificity of immunoglobulin heavy- and light-chain gene promoters and the heavy-chain enhancer. A variant octamer-binding site within a conserved region of the human kappa light-chain gene enhancer which contributes to the function of this enhancer has been identified.

Synergistic activation of transcription by multiple binding sites for NF-kappa B even in absence of co-operative factor binding to DNA

Regulation of eukaryotic genes is largely governed by multiple cis-acting DNA sequences recognized by specific transcription factors. The transcription factor NF-kappa B has been implicated as an important regulator of cellular and viral genes, including those of immunoglobulin kappa light chain, interleukin-2, beta-interferon, HIV-1 and cytomegalovirus. We have analyzed the effect of increasing the number of NF-kappa B sites, located directly upstream from the TATA box. Four copies of the sequence gave a more than 100-fold stimulation relative to a single copy, suggesting that NF-kappa B proteins act synergistically to bring about this dramatic increase in transcription. By DNase I footprinting we demonstrated factor binding to two adjacent NF-kappa B sites in vitro. However, we found no evidence for co-operative binding to these DNA sites. We propose that the high transcriptional activity results from another type of co-operation, based on multiple weak interactions of the NF-kappa B factors with another component of the transcription apparatus, perhaps RNA polymerase II itself.

Identification of an octamer-binding site in the human kappa light-chain enhancer

Octamer motifs contribute to the function and tissue specificity of immunoglobulin heavy- and light-chain gene promoters and the heavy-chain enhancer. A variant octamer-binding site within a conserved region of the human kappa light-chain gene enhancer which contributes to the function of this enhancer has been identified.

The POU-specific domain of Pit-1 is essential for sequence-specific, high affinity DNA binding and DNA-dependent Pit-1-Pit-1 interactions

Pit-1 is a member of a family of transcription factors sharing two regions of homology: a highly conserved POU-specific (POUS) domain and a more divergent homeodomain (POUHD). Analysis of mutant Pit-1 proteins suggests that, while the POUHD is required and sufficient for low affinity DNA binding, the POUS domain is necessary for high affinity binding and accurate recognition of natural Pit-1 response elements. Pit-1 is monomeric in solution but associates as a dimer on its DNA response element, exhibiting DNA-dependent protein-protein interactions requiring the POUS domain. Analysis of alpha-helical domains and conserved structures in Pit-1 suggests that POU domain proteins interact with their DNA recognition sites differently than classic homeodomain proteins, with both the POUHD and the POUS domain contacting DNA. Transcriptional activity of Pit-1 on enhancer elements is conferred primarily by a Ser- and Thr-rich N-terminal region unrelated to other known transcription-activating motifs.

A novel enhancer in the immunoglobulin lambda locus is duplicated and functionally independent of NF kappa B

As a first step toward defining the elements necessary for lambda immunoglobulin gene regulation, DNase I hypersensitive sites were mapped in the mouse lambda locus. A hypersensitive site found 15.5 kb downstream of C lambda 4 was present in all the B-cell but not in the T-cell lines tested. This site coincided with a strong B-cell-specific transcriptional enhancer (E lambda 2-4). This novel enhancer is active in myeloma cells, regardless of the status of endogenous lambda genes, but is inactive in a T-cell line and in fibroblasts. The enhancer E lambda 2-4 functions in the absence of the transcription factor NF kappa B, which is necessary for kappa enhancer function. No evidence could be found for NF kappa B binding by this element. Rearrangement of V lambda 2 to JC lambda 3 or JC lambda genes deletes E lambda 2-4; however, a second strong enhancer was found 35 kb downstream of C lambda 1, which cannot be eliminated by lambda gene rearrangements. The second lambda enhancer (E lambda 3-1) is 90% homologous to the E lambda 2-4 sequence in the region determined to comprise the active enhancer and likewise lacks the consensus binding site for NF kappa B. The data support a model for the independent activation of kappa and lambda gene expression based on locus-specific regulation at the enhancer level.

Cooperative interactions between transcription factors Sp1 and OTF-1

We have examined whether the functional synergism between transcription factors Sp1 and OTF-1 involves cooperativity in binding. To demonstrate cooperativity, synthetic enhancers were constructed in which Sp1-binding sites were combined with various OTF-1-binding sites that differed in their binding affinities. The ability of these constructions to activate transcription from the human U2 small nuclear RNA promoter was measured. The results showed that an Sp1-binding site stimulated transcription 2-fold when combined with a high-affinity binding site for OTF-1. When combined with a low-affinity OTF-1-binding site, in contrast, a 20-fold stimulation of transcription was observed. The stimulatory effect of Sp1 was moreover influenced by the distance between the Sp1- and OTF-1-binding sites and the functional cooperation was mirrored by the cooperative formation of OTF-1- and Sp1-specific protein-DNA complexes in vitro. We conclude from these results that the functional cooperation between OTF-1 and Sp1 involves physical interactions between the two transcription factors resulting in cooperative binding. The results thus reveal a mechanism by which Sp1 can modulate transcription.

Interaction of the Escherichia coli Gal repressor protein with its DNA operators in vitro

The binding of Escherichia coli Gal repressor to linear DNA fragments containing two binding sites (OE and OI) within the gal operon was analyzed in vitro with quantitative footprint and mobility-shift techniques. In vivo analysis of the regulation of the gal operon [Haber, R., & Adhya, S. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 9683-9687] has suggested the role of a regulatory "looped complex" mediated by the association of Gal repressor dimers bound at OE and OI. The binding of Gal repressor to a single site can be described by a model in which monomer and dimer are in equilibrium and only the dimer binds to DNA. At pH 7.0, 25 mM KCl, and 20 degrees C, the binding and dimerization free energies are comparable, suggesting that the equilibrium governing the formation of dimers may be important to regulation. The two intrinsic binding constants, delta GI and delta GE, and a constant describing cooperativity, delta GIE, were determined by footprint titration analysis as a function of pH, [KCl], and temperature. Only at 4 and 0 degrees C was delta GIE negative, signifying cooperative binding. These results are thought to be due to a weak dimer to tetramer association interface. delta GE and delta GI had maximal values between pH 6 and pH 7. The dependence of these constants on [KCl] corresponded to the displacement of approximately 2 ion equiv. The temperature dependence could be described by a change in the heat capacity, delta Cp, of -2.3 kcal mol-1 deg-1. Mobility-shift titration experiments conducted at 20 and 0 degrees C yielded values for delta GIE that were consistent with those resolved from the footprint analysis. Unique values of delta GIE were determined by analysis of mobility-shift titrations of Gal repressor with wild-type operator subject to the constraint that delta GE = delta GI: a procedure that eliminates the need to simultaneously analyze wild-type titrations with titrations of OE- and OI- operators.

The progesterone receptor stimulates cell-free transcription by enhancing the formation of a stable preinitiation complex

Highly purified chicken progesterone receptor (cPR) is shown to stimulate RNA synthesis directly in an in vitro transcription assay. Stimulation of transcription by cPR requires the presence of progesterone response elements (PREs) in the template and can be specifically inhibited by addition of competitor oligonucleotides containing PREs. Binding of receptor to two PREs is cooperative and leads to synergistic (27-fold) stimulation of transcription. A purified fusion protein containing the DNA binding domain of cPR linked to yeast ubiquitin was produced in E. coli and also functions in the transcription assay. Using this in vitro transcription system, we demonstrate that hormone-free cPR activated by salt treatment induces transcription of a test gene in a hormone-independent manner. Finally, we present evidence that the progesterone receptor acts by facilitating the formation of a stable preinitiation complex at the target gene promoter and thus augments the initiation of transcription by RNA polymerase II.