Cell type-specificity elements of the immunoglobulin heavy chain gene enhancer

Enhancers, enhancers – from their discovery to today’s universe of transcription enhancers

Transcriptional enhancers are short (200–1500 base pairs) DNA segments that are able to dramatically boost transcription from the promoter of a target gene. Originally discovered in simian virus 40 (SV40), a small DNA virus, transcription enhancers were soon also found in immunoglobulin genes and other cellular genes as key determinants of cell-type-specific gene expression. Enhancers can exert their effect over long distances of thousands, even hundreds of thousands of base pairs, either from upstream, downstream, or from within a transcription unit. The number of enhancers in eukaryotic genomes correlates with the complexity of the organism; a typical mammalian gene is likely controlled by several enhancers to fine-tune its expression at different developmental stages, in different cell types and in response to different signaling cues. Here, I provide a personal account of how enhancers were discovered more than 30 years ago, and also address the amazing development of the field since then.

Optimization of the Gal4-UAS system in an Anopheles gambiae cell line

The development of the bipartite Gal4-UAS system in Anopheles gambiae would improve the functional characterization of genes in this important malaria vector. Towards this aim, we used Gal4 driver plasmids to successfully activate expression of the reporter gene, luciferase, from UAS responder plasmids when cotransfected into an An. gambiae cell line. To optimize Gal4-regulated gene expression in mosquitoes, we compared the efficiency of a series of alternative Gal4 transactivators to drive reporter gene expression from responder plasmids incorporating different numbers of tandemly arrayed Gal4 binding sites or upstream activation sequences (UAS). The results indicated that the native Gal4 is only weakly active in these cells. Modified forms of Gal4, including those carrying minimal VP16 activation domains, as well as a deleted form of Gal4, give up to 20-fold greater activity than the native protein, when used in conjunction with a responder plasmid having 14 UAS repeats. The identification of Gal4-UAS vectors that are efficiently expressed in a mosquito cell line should facilitate the transfer of this versatile expression system to An. gambiae, and potentially to other insects of medical importance.

Transcription factor Spi-B binds unique sequences present in the tandem repeat promoter/enhancer of JC virus and supports viral activity

Progressive multifocal leukoencephalopathy (PML) is an often fatal demyelinating disease caused by lytic infection of oligodendrocytes with JC virus (JCV). The development of PML in non-immunosuppressed individuals is a growing concern with reports of mortality in patients treated with mAb therapies. JCV can persist in the kidneys, lymphoid tissue and bone marrow. JCV gene expression is restricted by non-coding viral regulatory region sequence variation and cellular transcription factors. Because JCV latency has been associated with cells undergoing haematopoietic development, transcription factors previously reported as lymphoid specific may regulate JCV gene expression. This study demonstrates that one such transcription factor, Spi-B, binds to sequences present in the JCV promoter/enhancer and may affect early virus gene expression in cells obtained from human brain tissue. We identified four potential Spi-B-binding sites present in the promoter/enhancer elements of JCV sequences from PML variants and the non-pathogenic archetype. Spi-B sites present in the promoter/enhancers of PML variants alone bound protein expressed in JCV susceptible brain and lymphoid-derived cell lines by electromobility shift assays. Expression of exogenous Spi-B in semi- and non-permissive cells increased early viral gene expression. Strikingly, mutation of the Spi-B core in a binding site unique to the Mad-4 variant was sufficient to abrogate viral activity in progenitor-derived astrocytes. These results suggest that Spi-B could regulate JCV gene expression in susceptible cells, and may play an important role in JCV activity in the immune and nervous systems.

Role of defective Oct-2 and OCA-B expression in immunoglobulin production and Kaposi's sarcoma-associated herpesvirus lytic reactivation in primary effusion lymphoma

Primary effusion lymphoma (PEL) is a distinct type of B-cell non-Hodgkin lymphoma characterized by the presence of Kaposi's sarcoma-associated herpesvirus (KSHV/human herpesvirus 8). Despite having a genotype and gene expression signature of highly differentiated B cells, PEL does not usually express surface or cytoplasmic immunoglobulin (Ig). We show the lack of Oct-2 and OCA-B transcription factors to be responsible, at least in part, for this defect in Ig production. Like Ig genes, ORF50, the key regulator of the switch from latency to lytic reactivation, contains an octamer motif within its promoter. We therefore examined the impact of Oct-2 and OCA-B on ORF50 activation. The binding of Oct-1 to the ORF50 promoter has been shown to significantly enhance ORF50 transactivation. We found that Oct-2, on the other hand, inhibited ORF50 expression and consequently lytic reactivation by competing with Oct-1 for the octamer motif in the ORF50 promoter. Our data suggest that Oct-2 downregulation in infected cells would be favorable to KSHV in allowing for efficient viral reactivation.

Transcriptional regulation of the salivary histatin gene: finding of a strong positive regulatory element and its binding protein

Histatins are salivary proteins found and expressed in human salivary glands. They play a role in the non-immune system of antimicrobial defense, for instance, against Candida albicans. The transcriptional regulatory sequences of the histatin gene, HIS1, have remained obscure for a long time. Here, we cloned the putative promoter from human genomic DNA and tested it in a luciferase reporter system. This promoter is much more active in salivary gland cells than in other cell types. Analysis of deletion mutants revealed that the region encompassing -2254 to -1748 is a strong positive transcriptional element, and its functional core sequence (termed HTN27 box) works in correct and reverse orientations in synergy with downstream sequences, the region spanning -680 to +28 and a proximal promoter. The plus single-stranded HTN27 box is specifically bound by a 100 kDa protein that is present in HSG cells, but not in HeLa cells. These findings indicate that the regulation of the histatin gene expression may be intricate, and it seems to have a cell-type preference in the salivary gland cells.

Open reading frame UL26 of human cytomegalovirus encodes a novel tegument protein that contains a strong transcriptional activation domain

A selection strategy, the activator trap, was used in order to identify genes of human cytomegalovirus (HCMV) that encode strong transcriptional activation domains in mammalian cells. This approach is based on the isolation of activation domains from a GAL4 fusion library by means of selective plasmid replication, which is mediated in transfected cells by a GAL4-inducible T antigen gene. With this screening strategy, we were able to isolate two types of plasmids encoding transactivating fusion proteins from a library of random HCMV DNA inserts. One plasmid contained the exon 3 of the HCMV IE-1/2 gene region, which has previously been identified as a strong transcriptional activation domain. In the second type of plasmid, the open reading frame (ORF) UL26 of HCMV was fused to the GAL4 DNA-binding domain. By quantitative RNA mapping using S1 nuclease analysis, we were able to classify UL26 as a strong enhancer-type activation domain with no apparent homology to characterized transcriptional activators. Western blot analysis with a specific polyclonal antibody raised against a prokaryotic UL26 fusion protein revealed that two protein isoforms of 21 and 27 kDa are derived from the UL26 ORF in both infected and transfected cells. Both protein isoforms, which arise via alternative usage of two in-frame translational start codons, showed a nuclear localization and could be detected as early as 6 h after infection of primary human fibroblasts. By performing Western blot analysis with purified virions combined with fractionation experiments, we provide evidence that pUL26 is a novel tegument protein of HCMV that is imported during viral infection. Furthermore, we observed transactivation of the HCMV major immediate-early enhancer-promoter by pUL26, whereas several early and late promoters were not affected. Our data suggest that pUL26 is a novel tegument protein of HCMV with a strong transcriptional activation domain that could play an important role during initiation of the viral replicative cycle.

Functional analysis of the OCA-B promoter

OCA-B was identified as a B cell-specific coactivator that functions with either Oct-1 or Oct-2 to mediate efficient cell type-specific transcription via the octamer site (ATGCAAAT) both in vivo and in vitro. Mice lacking OCA-B exhibit normal Ag-independent B cell maturation. In contrast, Ag-dependent functions, including production of secondary Ig isotypes and germinal center formation, are greatly affected. To better understand OCA-B expression and, ultimately, the defects observed in the OCA-B knockout mice, we have cloned the OCA-B promoter and examined its function in both transformed and primary B cells. We show here that the OCA-B promoter is developmentally regulated, with activity increasing throughout B cell differentiation. Through physical and functional assays, we have found an activating transcription factor/cAMP response element binding protein binding site (or cAMP response element) that is crucial for OCA-B promoter activity. Furthermore, we demonstrate that IL-4 and anti-CD40 induce both the OCA-B promoter and octamer-dependent promoters, thus implicating OCA-B in B cell signaling events in the nucleus.

Mef2 Proteins, Required for Muscle Differentiation, Bind an Essential Site in the Ig λ Enhancer

The Ig λ light chain gene enhancer has two unique essential motifs, λA and λB. The transcription factors that bind the λB motif have been identified as Pu.1 and Pu.1-interacting partner (Pip). We report here that the λA site includes a binding site for the myocyte-specific enhancer factor 2 (Mef2) family of transcription factors. Mef2 proteins were first described in muscle cells and, in vertebrates, include four known members designated A to D. Using a λA electrophoretic-mobility shift assay (EMSA), in conjunction with a high affinity Mef2 binding site and anti-Mef2 Abs, we show that members of the Mef2 family are present in nuclear extracts of λ-producing B cells and bind the λA site. Functional assays using the chloramphenicol acetyltransferase (CAT) reporter construct containing three copies of the λA motif demonstrate that the λA sequence can function as an enhancer in conjunction with the thymidine kinase (TK) promoter and is regulated by Mef2 proteins. Extrapolating from other systems where transcriptional regulation by Mef2 has been studied, other transcription factors may be involved along with Mef2 in transcriptional regulation at the λA site.

Locus control regions, chromatin activation and transcription

The past year has seen interesting advances in our understanding of the action of locus control regions. For the first time, the chromosomal distance was described in detail as a parameter in positive/negative regulation of transcription via gene competition. A number of publications have also described negative regulatory elements which restrict the action of locus control regions and other regulatory regions to specific genes and/or specific tissues. The emerging picture indicates that several very different types of negative regulation ensure that transcriptional activation occurs only in the appropriate cells.

Substitution of Ala564 in the first zinc cluster of the deoxyribonucleic acid (DNA)-binding domain of the androgen receptor by Asp, Asn, or Leu exerts differential effects on DNA binding

In the androgen receptor of a patient with androgen insensitivity, the alanine residue at position 564 in the first zinc cluster of the DNA-binding domain was substituted by aspartic acid. In other members of the steroid receptor family, either valine or alanine is present at the corresponding position, suggesting the importance of a neutral amino acid residue at this site. The mutant receptor was transcriptionally inactive, which corresponded to the absence of specific DNA binding in gel retardation assays, and its inactivity in a promoter interference assay. Two other receptor mutants with a mutation at this same position were created to study the role of position 564 in the human androgen receptor on DNA binding in more detail. Introduction of asparagine at position 564 resulted in transcription activation of a mouse mammary tumor virus promoter, although at a lower level compared with the wild-type receptor. Transcription activation of an (ARE)2-TATA promoter was low, and binding to different hormone response elements could not be visualized. The receptor with a leucine residue at position 564 was as active as the wild-type receptor on a mouse mammary tumor virus promoter and an (ARE)2-TATA promoter, but interacted differentially with several hormone response elements in a gel retardation assay. The results of the transcription activation and DNA binding studies could partially be predicted from three-dimensional modeling data. The phenotype of the patient was explained by the negative charge, introduced at position 564.

The cyclin-dependent kinase-activating kinase (CAK) assembly factor, MAT1, targets and enhances CAK activity on the POU domains of octamer transcription factors

Octamer binding transcription factors (Oct factors) play important roles in activation of transcription of various genes but, in some cases, require cofactors that interact with the DNA binding (POU) domain. In the present study, a yeast two-hybrid screen with the Oct-1 POU domain as a bait identified MAT1 as a POU domain-binding protein. MAT1 is known to be required for the assembly of cyclin-dependent kinase (CDK)-activating kinase (CAK), which is functionally associated with the general transcription factor IIH (TFIIH). Further analyses showed that MAT1 interacts with POU domains of Oct-1, Oct-2, and Oct-3 in vitro in a DNA-independent manner. MAT1-containing TFIIH was also shown to interact with POU domains of Oct-1 and Oct-2. MAT1 is shown to enhance the ability of a recombinant CDK7-cyclin H complex (bipartite CAK) to phosphorylate isolated POU domains, intact Oct-1, and the C-terminal domain of RNA polymerase II, but not the originally defined substrate, CDK2. Phosphopeptide mapping indicates that the site (Ser385) of a mitosis-specific phosphorylation that inhibits Oct-1 binding to DNA is not phosphorylated by CAK. However, one CAK-phosphorylated phosphopeptide comigrates with a Cdc2-phosphorylated phosphopeptide previously shown to be mitosis-specific, suggesting that, in vitro, CAK is able to phosphorylate at least one site that is also phosphorylated in vivo. These results suggest (i) that interactions between POU domains and MAT1 can target CAK to Oct factors and result in their phosphorylation, (ii) that MAT1 not only functions as a CAK assembly factor but also acts to alter the spectrum of CAK substrates, and (iii) that a POU-MAT1 interaction may play a role in the recruitment of TFIIH to the preinitiation complex or in subsequent initiation and elongation reactions.

Molecular analysis of the androgen-receptor gene in a family with receptor-positive partial androgen insensitivity: an unusual type of intronic mutation

In the coding part and the intron-exon boundaries of the androgen-receptor gene of a patient with partial androgen insensitivity, no mutation was found. The androgen receptor of this patient displayed normal ligand-binding parameters and migrated as a 110-112-kD doublet on SDS-PAGE in the absence of hormone. However, after culturing of the patient's genital skin fibroblasts in the presence of hormone, the slower-migrating 114-kD protein, which reflects hormone-dependent phosphorylation, was hardly detectable. Furthermore, receptor protein was undetectable in the nuclear fraction of the fibroblasts, after treatment with hormone, which is indicative of defective DNA binding. By sequencing part of intron 2, a T-->A mutation was found 11 bp upstream of exon 3. In our screening of 102 chromosomes from unrelated individuals, this base-pair substitution was not found, indicating that it was not a polymorphism. mRNA analysis revealed that splicing involved a cryptic splice site, located 71/70 bp upstream of exon 3, resulting in generation of mRNA with an insert of 69 nucleotides. In addition, a small amount of a transcript with a deleted exon 3 and a very low level of wild-type transcript were detected. Translation of the extended transcript resulted in an androgen-receptor protein with 23 amino acid residues inserted between the two zinc clusters, displaying defective DNA binding and defective transcription activation.

A three-protein-DNA complex on a B cell-specific domain of the immunoglobulin mu heavy chain gene enhancer

The lymphoid-specific immunoglobulin mu heavy chain gene intron enhancer (muE) contains multiple binding sites for trans-acting nuclear factors. We have used a combination of in vitro and in vivo assays to reconstruct protein-DNA interactions on a minimal B cell-specific mu enhancer that contains three motifs, muA, muB, and muE3. Using ETS-domain proteins that transactivate the minimal enhancer in non-lymphoid cells, we show that (i) PU.1 binds coordinately to both muA and muB sites in vitro and (ii) in the presence of Ets-1, this factor binds to the muA site and PU.1 to the muB site. Two factors, TFE3 and USF, bind to the muE3 element. When the ETS proteins are present together with muE3 binding proteins, a three-protein-DNA complex is generated. Furthermore, we provide evidence for protein-protein interactions between Ets-1 and PU.1 proteins that bind to muA and muB sites, and between Ets-1 and TFE3 bound to the muA and mu3 sites. We propose that this domain of the mu enhancer is assembled into a nucleoprotein complex that contains two tissue-restricted ETS domain proteins that recognize DNA from the same side of the helix and one ubiquitously expressed bHLH-leucine zipper protein that binds between them, recognizing its site from a different side of the helix.

In vivo transcriptional regulation of the human immunodeficiency virus in the central nervous system in transgenic mice

Human immunodeficiency virus type 1 (HIV-1) causes infections of the central nervous system (CNS) and has been implicated as the causative agent of AIDS-associated encephalopathy and the AIDS dementia complex. The development of in vivo models of HIV-1-mediated gene expression has shown that the HIV long terminal repeat (LTR) from the viral isolate HIV(JR-CSF) specifically supports gene expression in adult and developing CNS. To determine the molecular basis for HIV-1 developmental CNS gene expression, in vivo footprinting analysis by the ligation-mediated PCR technique was performed on CNS tissue from the brain stem of a transgenic mouse. The association of cellular proteins in the CNS with sequences in the LTR was found over sequences that defined the TATA region, the Sp-1 and NF-kappaB sites, and two upstream regions (-111 to -150 and -260 to -300). A purine-rich sequence at positions -256 to -296 of the HIV(JR-CSF) LTR but not of the HIV(IIIB) LTR specifically bound protein in nuclear extracts of newborn brain tested in electrophoretic mobility shift assays. No specific protein binding was observed to this region in liver or HeLa cell nuclear extracts. This suggests the presence of a newly identified transcription factor involved in regulation of HIV-1 gene expression in the CNS.

Cloning and characterization of the murine B-cell specific transcriptional coactivator Bob1

From a murine B-cell cDNA-library we have cloned a cDNA encoding the murine B-cell specific coactivator mBob1. The protein is the murine homologue to the recently described human coactivator Bob1 (hBob1), also referred to as OBF-1 or OCA-B. We have also characterized the genomic mBob1 clone. Analysis of its intron-exon structure has allowed identification of a C-terminal splice variant. mBob1 is B-cell restricted, and is found in all B-cell lines representing different stages of B-cell differentiation. mBob1 interacts with the octamer transcription factors Oct-1 and Oct-2 and stimulates transcription mediated by these factors.

Functional characterization of the murine homolog of the B cell-specific coactivator BOB.1/OBF.1

B cell-specific transcriptional promoter activity mediated by the octamer motif requires the Oct1 or Oct2 protein and additional B cell-restricted cofactors. One such cofactor, BOB.1/OBF.1, was recently isolated from human B cells. Here, we describe the isolation and detailed characterization of the murine homolog. Full-length cDNAs and genomic clones were isolated, and the gene structure was determined. Comparison of the deduced amino acids shows 88% sequence identity between mouse and human BOB.1/OBF.1. The NH2-terminal 126 amino acids of BOB.1/OBF.1 are both essential and sufficient for interaction with the POU domains of either Oct1 or Oct2. This protein-protein interaction does not require the simultaneous binding of Oct proteins to DNA, and high resolution footprinting of the Oct-DNA interaction reveals that binding of BOB.1/OBF.1 to Oct1 or Oct2 does not alter the interaction with DNA. BOB.1/OBF.1 can efficiently activate octamer-dependent promoters in fibroblasts; however, it fails to stimulate octamer-dependent enhancer activity. Fusion of subdomains of BOB.1/OBF.1 with the GAL4 DNA binding domain reveals that both NH2- and COOH-terminal domains of BOB.1/OBF.1 contribute to full transactivation function, the COOH-terminal domain is more efficient in this transactivation assay. Consistent with the failure of full-length BOB.1/OBF.1 to stimulate octamer-dependent enhancer elements in non B cells, the GAL4 fusions likewise only stimulate from a promoter-proximal position.

Real-time analysis of Oct protein-octamer interaction and transcription complex assembly

Specific interactions between the protein-binding sequence of the immunoglobulin transcription regulatory element, the octamer, and Oct proteins have been investigated using a biosensor based on surface plasmon resonance. By analysis of in vitro translated Oct1 and Oct2A with a consensus octamer probe, it was shown that the affinity constant, association rate constant and dissociation rate constant of Oct1 were higher than for Oct2A. The biggest difference was in the association rate constants, but this difference was reduced when an octamer motif containing a point mutation was used as a probe. Elements in the octamer flanking sequence could increase the on-rate of Oct proteins to a mutated octamer while not decreasing the off-rate. Oct-octamer interaction in whole nuclear extracts could be detected readily in the biosensor and adapter interactions with template bound proteins were revealed. Thus, biosensor analysis represent a fast and convenient alternative approach to study specific protein-DNA and protein-protein interactions in analysis of transcriptional regulation.

Direct evidence that the POU family transcription factor Oct-2 represses the cellular tyrosine hydroxylase gene in neuronal cells

The POU family transcription factor Oct-2 was originally identified in B lymphocytes but has been shown to be expressed in neuronal cells, although it is absent in most other cell types. Cotransfection of Oct-2 expression vectors into nonneuronal cells with a tyrosine hydroxylase promoter/reporter plasmid suggests that Oct-2 can repress this promoter in this artificial situation. Here we report that reduction of endogenous Oct-2 levels in a neuronal cell line by an antisense approach results in an increase in endogenous tyrosine hydroxylase levels. In contrast, the level of the neuronal marker protein PGP9.5 remains unchanged in the antisense lines whereas that of the neuronal nitric oxide synthase decreases. Hence, the tyrosine hydroxylase gene is a natural target for repression by Oct-2 in neuronal cells. The significance of this effect is discussed in terms of the processes that regulate tyrosine hydroxylase gene expression and the role of Oct-2 in neuronal cells.

Molecular principles of Oct2-mediated gene activation in B cells

The octamer motif is a crucial regulatory element for immunoglobulin promoter and enhancer function. We have investigated the molecular mechanisms that underlie octamer-mediated gene activation in B cells. This B cell-specific transcriptional regulation is subject to a novel type of regulatory mechanism. We could demonstrate that octamer-dependent transcription is not only regulated by specific DNA-binding transcription factors, but in addition requires the activity of B cell-restricted cofactors. Both octamer-dependent promoter and enhancer activation depend on such a combination of transcription factor and cofactors. However, the exact requirements differ for these two situations. Promoter activity can be achieved with either one of two distinct transcription factors, Oct1 and/or Oct2, together with the cofactor OCA-B1. In contrast, only Oct2 in conjunction with an additional cofactor, OCA-B2, can confer enhancer activity.

OBF-1, a novel B cell-specific coactivator that stimulates immunoglobulin promoter activity through association with octamer-binding proteins

Recent biochemical and genetic studies indicate that in addition to the octamer-binding proteins Oct-1 and Oct-2, other B cell components are required for lymphoid-restricted, octamer site-mediated immunoglobulin gene promoter activity. Using a genetic screen in yeast, we have isolated B cell-derived cDNAs encoding Oct-binding factor 1 (OBF-1), a novel protein that specifically associates with Oct-1 and Oct-2. Biochemical studies demonstrate that OBF-1 has no intrinsic DNA-binding activity and recognizes the POU domains of Oct-1 and Oct-2, but not those of Oct-4 and Oct-6. The OBF-1 mRNA is expressed in a highly cell-specific manner, being most abundant in B cells and essentially absent in most of the other cells or tissues tested. Furthermore, expression of OBF-1 in HeLa cells selectively stimulates the activity of a natural immunoglobulin promoter in an octamer site-dependent manner. Thus, OBF-1 has all the properties expected for a B cell-specific transcriptional coactivator protein.

Involvement of the Ets family factor PU.1 in the activation of immunoglobulin promoters

The B cell-specific expression of immunoglobulin (Ig) genes is controlled by the concerted action of variable (V) region promoters and intronic or 3' enhancers, all of which are active in a lymphoid-specific manner. A crucial highly conserved element of the V region promoters is the octamer site -ATTTGCAT-, which can be bound by ubiquitous (Oct-1) as well as B cell-specific (Oct-2) factors. Another less conserved element found in many Ig promoters is pyrimidine-rich and has been shown to be functionally important, in particular for those Ig promoters that have only an imperfect octamer site. In this study we have analyzed the factors binding specifically to the pyrimidine-rich motif of the V kappa 19 promoter, a light chain gene promoter with an imperfect octamer site. Using nuclear extracts prepared from B cells, we detected two sets of specific complexes in electrophoretic mobility shift experiments. One complex appears to be ubiquitous but enriched in lymphoid cells and represents the binding of a potentially novel factor with an apparent molecular mass of approximately 50 kDa. The other complex was found only with extracts from pre-B or B cells as well as from a macrophage cell line and appears to be caused by the binding of PU.1, a factor of the Ets family. We show that on this Ig promoter Oct factors (Oct-1 or Oct-2) and PU.1 can bind concomitantly but without synergism. By transfection experiments in non-B cells we demonstrate that PU.1 is indeed able to activate this promoter in concert with Oct-2. Furthermore, we show that PU.1 can bind with varying affinities to the pyrimidine-rich elements of several other Ig promoters. These data suggest a more general role for PU.1 or other members of the Ets family in the activation of Ig promoters.

Stimulation of kappa transcription by a decamer-dependent, synergistic mechanism

The intact SP6 kappa promoter stimulated transcription 30 times more efficiently than did a control promoter consisting of a TATA motif as the only promoter element. Mutation of the SP6 kappa promoter decamer in two positions reduced the transcriptional stimulation activity by over 90%. Promoters containing the SP6 kappa promoter octamer or a consensus octamer in front of a TATA box were ineffective immunoglobulin promoters and stimulated at the most 15% of maximal transcription. Identical results were obtained after transfection of untransformed mouse splenic B cells stimulated by lipopolysaccharide, that express high levels of Oct2A, or of S194 cells that express negligible levels of Oct2A. Selective mutations in the penta-decamer (pd), kappa Y or early B cell factor (EBF) elements of the promoter reduced transcriptional stimulation by 20-30% in untransformed B cells. In S194 plasmacytoma cells the EBF mutation was functionally silent while the kappa Y and pd mutations reduced transcriptional activation by 60-70% in this cell line. A mutation in a TATA-proximal E-box motif did not alter the functional activity of the promoter in either cell population. It can be concluded that kappa promoter function is highly dependent on complex interactions between individual promoter elements and that the decamer motif is pivotal for these interactions. The relative functional activity of a given promoter varied according to the target cell population used for the functional assay.

Basal components of the transcription apparatus (RNA polymerase II, TATA-binding protein) contain activation domains: is the repetitive C-terminal domain (CTD) of RNA polymerase II a "portable enhancer domain"?

Regions rich in serine, threonine, and proline residues can be found in transcriptional activation domains, as well as in the N-terminal parts of mammalian TATA-binding proteins, where they are interrupted by polyglutamine stretches. Likewise, the C-terminal domain of the largest subunit of RNA polymerase II contains multiple repeats of the consensus heptapeptide sequence YSPTSPS. To test directly for possible activation functions, we fused the GAL4 DNA-binding domain to the N-terminal domain of human TBP or subdomains of it, and to the C-terminal domain (CTD) of mouse RNA polymerase II or synthetic polymers of a CTD consensus repeat. We found that these chimeric proteins were able to activate transcription when bound to a GAL4 site in front of the TATA box, a function characteristic of transcription factors. However, while subdomains of TBP functioned only from a position close to the TATA box ("promoter" position), multiple repeats of the CTD consensus sequence were also able to mediate transcriptional activation from a remote ("enhancer") position. Our findings suggest that a region of TBP that is unique to mammals functionally cooperates with "proximal" activation domains of promoter-bound transcription factors. They also imply that the C-terminal domain of RNA polymerase II includes a function that is otherwise confined to remote activation domains of enhancer-bound transcription factors. We suggest that the CTD of RNA polymerase II contains a "portable" remote activation domain that may also facilitate chromatin opening within the transcription unit.

Positive transcriptional control elements within the SP6 kappa promoter decamer 3' flanking sequence

The SP6 kappa promoter decamer 3' flanking sequence was shown to contain several positive control elements for transcriptional stimulation which together increased transcriptional stimulation one order of magnitude. One was mapped to an A nucleotide immediately 3' of the decamer consensus motif. The mechanism was to increase the binding affinity of Oct2 for the decamer core motif by a direct interaction between the Oct2 protein and the template, since in vitro transcribed and translated Oct2 showed an identical binding preference when compared to the corresponding gene products in nuclear extracts. By mutation analysis it was shown that the functional activity of the SP6 kappa promoter 3' flanking sequence with regard to transcriptional stimulation was dependent on the presence of such a high affinity Oct binding site. Deletion analysis showed that the POU-Homeo domain of Oct2 sufficed for the flanking sequence mediated affinity increase for decamer elements and that amino or carboxy terminal variations in Oct2 did not influence this interaction. The flanking sequence element also increased Oct1 binding to the same decamer motif. The A 3' of the decamer increased affinity of Oct2 binding to a consensus as well as a mutated decamer. These data illustrate how flanking sequence elements can compensate mutations in the decamer core motif present in a majority of kappa promoters.

Analysis of Oct2-isoform expression in lipopolysaccharide-stimulated B lymphocytes

Oct2-isoform expression in splenic B cells stimulated with lipopolysaccharide or lipopolysaccharide plus phorbol-di-butyrate was analysed by cDNA cloning. The frequency of Oct2-positive clones was 1/15,000 in both libraries. Two new isoforms were found that generate novel amino- or carboxy-terminal sequences. An isoform lacking exon 11 destroyed the carboxy-terminal leucin-zipper region and introduced a frame shift creating a novel, proline-rich carboxy terminus. A new exon containing a highly basic region (4c) was characterized, between exons 4 and 5. This exon was inserted between glutamine-rich regions 2 and 3, carboxy terminal of a tentative leucine-zipper structure. In addition, a new combination isoform containing Oct2a's amino terminal insert (exon 7a) and Oct2b's carboxy terminal insert (exon 13) was found that created a novel large isoform, Oct2ab. More frequent use of the classical Oct2a and Oct2b isoforms was observed in the lipopolysaccharide-stimulated B cells, while a preference for the Oct2ab and Oct2ba isoforms was observed in lipopolysaccharide plus phorbol-di-butyrate-treated cells.

Identification and promoter activity of DNase I hypersensitive sites in the region of the Hox-1.3 gene

The Hox genes encode transcriptional regulatory proteins that play a critical role in rostrocaudal specification in the developing embryo. The genes lie in four clusters in the mouse and human genome and are arranged such that a colinear relation exists between a gene's position in the cluster and the time of activation of the gene's expression. We have analyzed the Hox-1.3 region within the Hox-1 gene cluster for DNase I hypersensitive sites to identify putative regulatory sequences. Fragments identified in this way were then analyzed for transcriptional activity using gene transfer experiments in embryonal carcinoma (EC) cells. Three DNase I hypersensitive sites were identified, one of which includes the Hox-1.3 promoter and another, located 550 bp upstream, which enhances the Hox-1.3 promoter activity. The third occurs in the intron and may represent a Hox binding site. Significantly, the DNase I hypersensitive site pattern of this region of the Hox-1 cluster is not altered when F9 stem cells are differentiated with retinoic acid, suggesting that sequential activation of Hox genes by retinoic acid is not due to a sequential opening of the chromatin structure in the Hox gene region.

Transcriptional regulation of the N-myc gene: identification of positive regulatory element and its double- and single-stranded DNA binding proteins

The N-myc gene is amplified and overexpressed in neuroblastoma, retinoblastoma and small cell lung carcinoma, and is considered to be related to cell proliferation and/or differentiation. The transcriptional regulatory sequences of the c-myc gene have been already identified, while those of N-myc have remained obscure for a long time. In this report, we have identified several positive and negative transcriptional regulatory elements in the upstream region of the mouse N-myc gene. Among them, an activating sequence spanning -860 to -797 bp (63 bp) could be reduced to a functional core of 21 bp from -846 to -826. This sequence, termed N21 box, worked as a positive transcriptional element when linked directly upstream (but not downstream) of the putative N-myc promoter in HeLa, not in IMR32 cells. At least two proteins, of 42 kDa and 100 kDa, bound to the double-stranded N21 box, and were expressed in HeLa as well as in IMR32 cells. Moreover, the plus strand of N21 box could be specifically bound by a species of 42 kDa from either cell type and by a 37 kDa protein found only in HeLa cells. These proteins may be factors binding to positive transcriptional regulatory elements and may have a role in the regulation of N-myc expression.

The immunoglobulin mu enhancer core establishes local factor access in nuclear chromatin independent of transcriptional stimulation

Factor access in chromatin has been proposed to be facilitated by transcriptional enhancers. With the aim of uncoupling factor access from transcriptional stimulation by protein-protein contacts, we analyzed the potential of enhancer fragments to confer accessibility upon a linked promoter for prokaryotic T7 RNA polymerase. Access to the T7 promoter in pre-B cells from transgenic mice was examined by transcribing chromatin of isolated nuclei with T7 RNA polymerase. A 95-bp immunoglobulin mu enhancer core element was necessary and sufficient to confer accessibility upon the T7 promoter independent of its chromosomal position. This enhancer-dependent factor access could be uncoupled from an active transcriptional state of the transgene and was not accompanied by the formation of pronounced DNase I hypersensitive sites. Additional mu enhancer sequences comprising previously identified matrix attachment regions and a cryptic promoter were required to induce DNase I hypersensitivity. Together, these data provide evidence that the 95-bp mu enhancer core can establish localized factor access in nuclear chromatin independent of detectable transcription by endogenous polymerases and suggest that multiple steps are involved in the alteration of chromatin structure.

Recognition of the surface of a homeo domain protein

Homeo domain proteins exhibit distinct biological functions with specificities that cannot be predicted by their sequence specificities for binding DNA. Recognition of the surface of the Oct-1 POU homeo domain provides a general model for the contribution of selective protein-protein interactions to the functional specificity of the homeo domain family of factors. The assembly of Oct-1 into a multiprotein complex on the herpes simplex virus alpha/IE enhancer is specified by the interactions of its homeo domain with ancillary factors. This complex (C1 complex) is composed of the viral alpha TIF protein (VP16), Oct-1, and one additional cellular component, the C1 factor. Variants of the Oct-1 POU homeo domain were generated by site-directed mutagenesis, which altered the residues predicted to form the exposed surface of the domain-DNA complex. Proteins with single amino acid substitutions on the surface of either helix 1 or 2 of the Oct-1 POU homeo domain had decreased abilities to form the C1 complex. The behavior of these mutants in a cooperative DNA-binding assay with alpha TIF suggested that the Oct-1 POU homeo domain is principally recognized by alpha TIF in the C1 complex. The preferential recognition of Oct-1 over the closely related Oct-2 protein is critically influenced by a single residue on the surface of helix 1 because the introduction of this residue into the Oct-2 POU homeo domain significantly enhanced its ability to form a C1 complex.

A novel B cell-derived coactivator potentiates the activation of immunoglobulin promoters by octamer-binding transcription factors

A novel B cell-restricted activity, required for high levels of octamer/Oct-dependent transcription from an immunoglobulin heavy chain (IgH) promoter, was detected in an in vitro system consisting of HeLa cell-derived extracts complemented with fractionated B cell nuclear proteins. The factor responsible for this activity was designated Oct coactivator from B cells (OCA-B). OCA-B stimulates the transcription from an IgH promoter in conjunction with either Oct-1 or Oct-2 but shows no significant effect on the octamer/Oct-dependent transcription of the ubiquitously expressed histone H2B promoter and the transcription of USF- and Sp1-regulated promoters. Taken together, our results suggest that OCA-B is a tissue-, promoter-, and factor-specific coactivator and that OCA-B may be a major determinant for B cell-specific activation of immunoglobulin promoters. In light of the evidence showing physical and functional interactions between Oct factors and OCA-B, we propose a mechanism of action for OCA-B and discuss the implications of OCA-B for the transcriptional regulation of other tissue-specific promoters.

The upstream region of the mouse N-myc gene: identification of an enhancer element that functions preferentially in neuroblastoma IMR32 cells

The various members of the myc gene family, including c-myc and N-myc, are supposed to play a role in the regulation of cell cycle and proliferation. Whereas c-myc is expressed nearly ubiquitously, the N-myc gene product is found mainly in actively proliferating neural tissues such as early development tissues or in retinoblastomas and neuroblastomas. In this report, the upstream region of mouse N-myc gene was ligated to pSVPCAT, which carries the simian virus 40 (SV40) promoter and bacterial chloramphenicol acetyltransferase (CAT) gene, and transcriptional activities were examined by CAT and S1 protection assays after transfection of the DNAs into human cervical carcinoma HeLa or neuroblastoma IMR32 cells. Several regulatory regions were identified: two promoting regions (-980 to -860 and -279 to +108) and an inhibiting one (-860 to -797). The region spanning positions -980 to -860 increased CAT expression independently of orientation and distance to the SV40 promoter, indicating that the element is a typical enhancer. Moreover, the expression levels from this enhancer were higher in IMR32 cells than in HeLa cells, indicating that action has, if not cell-type specificity, cell-type preference. These findings may provide useful bases for the understanding of the cell-type specific regulation of N-myc expression.

A pre-B- and B cell-specific DNA-binding protein, EBB-1, which binds to the promoter of the VpreB1 gene

The VpreB1 protein is thought to be expressed on the surface of pre-B cells in association with lambda 5 and mu heavy chain, and to play an important role on B cell differentiation. The expression of VpreB1 and lambda 5 is pre-B cell specific, and regulated at the initiation of transcription. We have identified at least two sequence-specific DNA-binding proteins which bind to the region -191 to -74 of the promoter of the mouse VpreB1 gene. These DNA-binding proteins also bind to the promoter of the mouse lambda 5 gene. One of the two DNA-binding proteins, called EBB-1, is restricted to pre-B and B cells, but not detected in plasma cells, T cells and cells of other lineages. Transient transfection analysis of reporter constructs revealed that the binding sites of these proteins play a significant role in the activity of the promoter, especially the binding site of EBB-1. Taken together these results suggest that EBB-1 might be one of the crucial factors which regulates a series of intracellular events in B cell differentiation.

Transcription factor requirements for U2 snRNA-encoding gene activation in B lymphoid cells

Transcription of a human U2 small nuclear RNA(snRNA)-encoding gene in HeLa cells requires a distal enhancer element, which is composed of one octamer motif (Oct) and three Sp 1-binding sites. To study the transcription factor requirement in B-cells, different U2 enhancer constructions were transfected into the lymphoid cell line, BJA-B. The results showed that the activation of U2 snRNA transcription in B-cells also requires an enhancer comprising both the Oct and at least one Sp 1-binding site. Deletion of all the Sp 1-binding sites from the enhancer reduces transcription by 80-90% in HeLa, as well as in BJA-B cells, whereas the removal of the octamer-binding site reduces transcription to levels below detection in both cell types. Enhancers containing a single Oct have, nevertheless, the capacity to partially activate U2 snRNA transcription in both HeLa cells, in which only OTF-1 is expressed, and in BJA-B cells in which OTF-2 is the predominantly expressed octamer-binding factor. The most likely interpretation of our results is that both the ubiquitous transcription factor, OTF-1, and the B-cell-specific transcription factor, OTF-2, can activate U2 snRNA transcription. The results also revealed a similar functional cooperation between the transcription factors which bind to the Oct and the adjacent Sp 1-binding site in BJA-B cells, as has been observed in HeLa cells, since a template which contains a weak binding site for OTFs expresses wild-type levels of U2 snRNA in both cell types when the weak octamer-binding site is combined with a Sp 1-binding site.

A nexus between Oct-4 and E1A: implications for gene regulation in embryonic stem cells

Oct-4 is a transcription factor expressed in the pluripotent progenitor cells of the early mouse embryo. Additional factors are required for the distal activation of genes in differentiated cells containing ectopically expressed Oct-4. Here we show that Oct-4 and E1A are sufficient for distance-independent activation of the basal transcription machinery. The ratio of Oct-4 to E1A is critical for transcriptional activation, because higher levels of either factor are less efficient. Activation depends on a transactivation domain linked to the POU domain of Oct-4 and also on the conserved domain 3 of the 289RE1A protein. This domain is required for binding to the C-terminal part of Oct-4 including the POU domain. Our results indicate that E1A can serve as a bridging factor between Oct-4 and the basal initiation complex, and we postulate that an E1A-like factor acts as a cellular bridging factor of Oct-4 in pluripotent cells.

Cloning, expression, and transcriptional properties of the human enhancer factor TEF-1

We describe the cDNA encoding the SV40 transcriptional enhancer factor 1 (TEF-1) and show that its translation initiates exclusively at an AUU codon in vivo. Cloned TEF-1, which is unrelated to other known transcription factors, specifically binds the SV40 GT-IIC and Sph enhansons. Cloned TEF-1 does not activate these enhansons in lymphoid MPC11 cells where they are known to be inactive, but represses the endogenous HeLa TEF-1 activity in vivo and in vitro. Repression is also observed with chimeras where the DNA-binding domain of the GAL4 activator replaces that of TEF-1, showing that repression results from interference/squelching. Such chimeras stimulate transcription in HeLa, but not in MPC11, cells in vivo and in HeLa cell extracts in vitro. However, high concentrations result in self-interference/squelching. These results strongly suggest that the trans-activation function of TEF-1 is mediated by a highly limiting, possible cell-specific, titratable transcriptional intermediary factor(s).

Every enhancer works with every promoter for all the combinations tested: could new regulatory pathways evolve by enhancer shuffling?

The promoters and enhancers of cell type-specific genes are often conserved in evolution, and hence one might expect that a given enhancer has evolved to work best with its own promoter. While this expectation may be realized in some cases, we have not found evidence for it. A total of 27 combinations of different promoters and enhancers were tested by transfection into cultured cells. We found that the relative efficiency of the enhancers is approximately the same, irrespective of the type of promoter used, i.e., there was no strong preference for any given enhancer/promoter combination. Notably, we do not see particularly strong transcription when the immunoglobulin kappa enhancer (or the immunoglobulin heavy chain enhancer) is used to activate a kappa gene promoter. We propose that a generally permissive enhancer/promoter interaction is of evolutionary benefit for higher eukaryotes: by enhancer shuffling, genes could be easily brought under a new type of inducibility/cell type specificity.

Transcription factor OTF-1 interacts with two distinct DNA elements in the A gamma-globin gene promoter

A DNA region (site II) in the promoter of the human A gamma-globin gene (-182 to -168) is involved in transcriptional regulation. At least two nuclear proteins bind to this region: the erythroid-specific factor NF-E1/GF-1 and another factor present in many cell lines. In the present study, we demonstrate that the ubiquitous factor binding to site II has immunological identity with the octamer transcription factor OTF-1, which has been implicated in the regulation of expression of genes such as histone H2b and small nuclear RNA. In addition, we show that OTF-1 binds to site I (-291 to -267), a purine-rich region upstream of site II. Interestingly, OTF-1 binds to sites I and II with equal affinity. This was unexpected since the 14 bp site I binding site AAGAATAAATTAGA (-291 to -278), determined by methylation interference, does not show obvious similarities to the canonical octamer binding site for OTF-1 in site II (ATGCAAAT). Interaction of OTF-1 with functionally active binding sites in the gamma-globin promoter suggests that this factor has a role in gamma-globin transcription.

Characterization of the murine Hox-2.3 promoter: involvement of the transcription factor USF (MLTF)

The murine homeobox-containing gene Hox-2.3 contains a basal promoter in a 210-bp region upstream of the transcription start site. In vitro studies of DNA-protein interactions in this region, and in a 1.3-kb upstream region which is known to play a role in tissue specific expression in vivo, led to the identification of DNA elements interacting with nuclear proteins from embryocarcinoma cells. Among the factors binding to the basal promoter is the upstream stimulating factor (USF), also known as major late transcription factor (MLTF). A single point mutation in its binding site abolishes binding in vitro and leads to 50% reduction of the transcriptional activity as measured in receptor gene experiments, showing that it is an activator of Hox-2.3 expression.

Ubiquitous transcription factor OTF-1 mediates induction of the MMTV promoter through synergistic interaction with hormone receptors

Steroid hormones induce transcription from the mouse mammary tumor virus (MMTV) promoter by complex mechanisms requiring binding of the hormone receptors to the hormone responsive element (HRE) of the long terminal repeat region. Here we show that the MMTV promoter contains two degenerated octamer motifs immediately upstream of the TATA box that together bind OTF-1 (Oct-1, NFIII) with an affinity similar to the octamer consensus. In transfection experiments, mutation of these octamer motifs interferes with the hormonal response of the MMTV promoter. In vitro, these mutations do not influence basal transcription but completely abolish the stimulatory effect of purified progesterone receptor. Progesterone receptor and glucocorticoid receptor bound to the HRE facilitate binding of OTF-1 to the two octamer motifs. Thus, OTF-1 is a natural mediator of hormonal induction of the MMTV promoter and acts through cooperation with the hormone receptors for binding to DNA.

Immediate early protein of pseudorabies virus is a general transactivator but stimulates only suboptimally utilized promoters. A clue to specificity?

Pseudorabies virus, a herpesvirus, encodes an immediate early (IE) protein that is known to be a general and strong transactivator of transcription. We have tested the activity of this IE protein with a set of well-defined promoters containing a TATA box and one type of upstream factor binding site (for Sp1, NF-kappa B, heavy metal responsive factors, octamer factors or glucocorticoid receptor). All promoters were strongly activated by IE protein, i.e. the IE protein did not preferentially activate transcription via a particular type of upstream element. Activation did not require a bona fide TATA box, since a promoter construct with three Sp1 sites but no TATA box was also activated. Our data are not compatible with a model in which IE protein would bypass the need for upstream factors. Rather, the properties of IE protein, especially a failure to induce strong transcription from a promoter with only a TATA box but no upstream sequences, mimic the action of a remotely placed, cis-active, enhancer DNA. The IE protein was found to have no effect on transcription units that are expressed to their maximal potential, irrespective of whether this was high or low. Such optimal transcription conditions are observed in the presence of a strong enhancer, or with multiple tandem copies of an upstream binding site and/or a high concentration of the corresponding factor. The property of stimulating only "suboptimally" utilized promoters may be exploited by pseudorabies virus to restrict the specificity of the IE protein to the viral early promoters and a subset of cellular promoters.

Ubiquitous and cell-type-specific protein interactions with human papillomavirus type 16 and type 18 enhancers

We have studied the protein-DNA interactions of human papillomavirus types 16 and 18 constitutive enhancer elements using DNasel footprinting experiments with nuclear extracts from four cervical carcinoma cell lines (C33A, HeLa, SiHa, and CaSki) and one fibroblast cell line (143B). Among nine footprints for the HPV 16 enhancer region, six footprints contain nuclear factor 1 (NF1) binding GCCAA motif. In vitro competition experiments suggest that the same factors are shared by all six of these motifs. Two other sequence motifs have consensus sequences for transcription factor AP1. Another sequence motif, for which uv crosslinking studies reveal interaction with four protein molecules, is a strong positive modulator of HPV 16 enhancer function in vivo and shares 100% homology to a sequence motif, GTTTTAA, in the tissue-specific enhancer of the c-mos oncogene. Footprints on the HPV 18 enhancer show five protected regions with homologies to NF1, AP1 and EFII transcription factor binding motifs. One sequence motif of the HPV 18 enhancer has three repeats of a TTTTA sequence contained within the c-mos sequence motif and interacts with at least four different individual polypeptides, as judged by uv crosslinking experiments.

A POU-domain transcription factor in early stem cells and germ cells of the mammalian embryo

The murine oct-3 gene encodes a transcription factor containing a POU-specific domain and a homeodomain. In marked contrast to other homeodomain-encoding genes, oct-3 is expressed in the totipotent and pluripotent stem cells of the pregastrulation embryo and is down-regulated during differentiation to endoderm and mesoderm, suggesting that it has a role in early development. The oct-3 gene is also expressed in primordial germ cells and in the female germ line.

The early expression of some human autoantibody-associated heavy chain variable region genes is controlled by specific regulatory elements

Recent molecular cloning studies have revealed that some autoantibodies may be encoded directly by germline Ig variable (V) genes without any somatic mutation, suggesting strongly that such autoantibodies are physiologically important. Independent analyses of Ig gene expression in a human fetal liver showed that only nine heavy chain V (Vh) genes were used, out of a potential germline Vh gene repertoire of 100-200. We have observed that four of these nine Vh genes encode sequences identical or almost identical to human autoantibody heavy chains. This unexpected overlap implies that some autoantibodies are expressed preferentially during early development. Recent structural analyses of two Vh3 genes expressed in fetal liver revealed many more enhancer-like sequences in the flanking regions than expected for a typical Vh gene. It is hypothesized that these autoantibody-related Vh genes may contain various combinations of cis regulatory elements which influence their specific expression during early ontogenic development. Furthermore, these observations are consistent with network hypotheses, which suggest that early B-cell development is driven by reactivity with self. The cis regulatory elements in the autoantibody genes may act in concert with the positional effects that have been shown to facilitate Vh gene engagement.