An immunoglobulin promoter displays cell-type specificity independently of the enhancer

A gene-specific non-enhancer sequence is critical for expression from the promoter of the small heat shock protein gene αB-crystallin

BACKGROUND

Deciphering of the information content of eukaryotic promoters has remained confined to universal landmarks and conserved sequence elements such as enhancers and transcription factor binding motifs, which are considered sufficient for gene activation and regulation. Gene-specific sequences, interspersed between the canonical transacting factor binding sites or adjoining them within a promoter, are generally taken to be devoid of any regulatory information and have therefore been largely ignored. An unanswered question therefore is, do gene-specific sequences within a eukaryotic promoter have a role in gene activation? Here, we present an exhaustive experimental analysis of a gene-specific sequence adjoining the heat shock element (HSE) in the proximal promoter of the small heat shock protein gene, αB-crystallin (cryab). These sequences are highly conserved between the rodents and the humans.

RESULTS

Using human retinal pigment epithelial cells in culture as the host, we have identified a 10-bp gene-specific promoter sequence (GPS), which, unlike an enhancer, controls expression from the promoter of this gene, only when in appropriate position and orientation. Notably, the data suggests that GPS in comparison with the HSE works in a context-independent fashion. Additionally, when moved upstream, about a nucleosome length of DNA (-154 bp) from the transcription start site (TSS), the activity of the promoter is markedly inhibited, suggesting its involvement in local promoter access. Importantly, we demonstrate that deletion of the GPS results in complete loss of cryab promoter activity in transgenic mice.

CONCLUSIONS

These data suggest that gene-specific sequences such as the GPS, identified here, may have critical roles in regulating gene-specific activity from eukaryotic promoters.

Organ-specific and light-induced expression of plant genes

Light plays a pivotal role in the development of plants. The photoregulation of plant genes involves recognition of light quality and quantity by phytochrome and other light receptors. Two gene families, rbcS and Cab, which code for abundant proteins active in photosynthesis, the small subunit of ribulose bisphosphate carboxylase and the chlorophyll a/b binding protein, show a 20-to 50-fold increase in transcript abundance in the light. Analyses in calli and transgenic plants of deletions of the rbcS gene and of chimeric constructions has allowed localization of two regions involved in light-induced transcription. One element is confined to a 33-base pair region surrounding the TATA box. In addition, an enhancer-like element contained within a 240-base pair fragment can confer phytochrome-induced transcription and organ specificity on nonregulated promoters.

Cloning of the chicken immunoglobulin joining (J)-chain gene and characterization of its promoter region

Three overlapping genomic clones of the chicken immunoglobulin joining (J) chain were isolated and then characterized using restriction enzyme analysis, Southern blot analysis with cDNA probes, and DNA sequencing. The gene consisted of four exons separated by a 2.6-kb intron 1, a 0.9-kb intron 2, and a 0.5-kb intron 3. A transcriptional initiation site was identified by a primer extension method using mRNA and cDNA, indicating that exon 1 was 86 bp encoding 20 amino acid residues. A TATA box was positioned at 29 approximately 25 bp upstream of exon 1. Exons, 2, and 3 consisted of 133 bp and 81 bp, encoding 43 and 26 amino acid residues of the mature protein, respectively. Exon 4 consisted of 202 bp encoding 66 amino acid residues and 1.2 kb of untranslated sequence. Deletion mutants of a 4.1-kb genomic fragment containing exon 1 showed high levels of promoter activities when examined in luciferase reporter assays following transfection into the DT-40 chicken B-cell line. These results suggest that the chicken J-chain gene consists of four exons and three introns and that the transcriptional regulatory elements may be present within 3.8 kb upstream of exon 1.

Differentiation-Specific, Octamer-Dependent Costimulation of κ Transcription

By mutational analysis of the octamer-TATA box intervening region in the mouse SP6 κ promoter, we have mapped two octamer-dependent, costimulatory regions, A and B. The A region was active in late B cells only, while the B region was active throughout B cell differentiation. The B region was TATA proximal and contained a heptamer and an E box of the E2A type that is common in Vκ promoters. Mutation of the heptamer element did not decrease transcriptional stimulation from this region, but mutations in, or immediately 5′ of, the E box core sequence did. A protein binding to this region could be detected in nuclear extracts. The complex could only partially be competed with a μE5 binding site and could not be supershifted with Abs raised to E2A gene products, indicating that it may represent a novel E-box binding complex. The A region was located proximal to the octamer and contained a CCCT element that is conserved both with regard to position and sequence in human VκII promoters. By mutational analysis, the transcriptional stimulatory activity was mapped to the CCCT element that also is part of an early B cell factor (EBF) binding site. In late B cells, a novel protein (FA), which did not bind to the EBF binding site in the mb1 promoter, interacted with the A region. This protein was found to be expressed at lower levels in early B cells as well as in HeLa cells. Thus, the octamer-flanking sequence contains positive control elements that may act independently but that differ in the stage of B cell differentiation at which they are active. One of these factors is an example of an ubiquitously expressed transcription factor that participate in differentiation-specific transcriptional activation.

Genetic analysis of transcription factors implicated in B lymphocyte development

The transcription factors Oct-2, NF-kappa B and PU.1 have been implicated in regulating the development of B lymphocytes. Genetic approaches have been used to analyze the developmental functions of these regulatory proteins. Using gene targeting in murine embryonic stem cells, PU.1 is shown to be required for the development of progenitor B cells. Strikingly, PU.1 is also essential for the development of T lymphoid, granulocytic and monocytic progenitors. Transcription factors of the NF-kappa B/Rel family, which appear to regulate immunoglobulin kappa gene expression, are shown to be a target of the viral transforming protein (v-abl) which arrests B lineage development at the precursor B stage. This suggests a mechanism by which v-abl blocks precursor B cell differentiation. The Oct-2 transcription factor was considered to represent a development regulator of immunoglobulin gene expression. Using gene targeting in a murine B cell, Oct-2 is shown to be dispensable for immunoglobulin gene expression. This suggests the existence of an alternate pathway, involving the ubiquitous related protein, Oct-1, in immunoglobulin gene regulation.

Regulation of immunoglobulin gene transcription

Analysis of the immunoglobulin gene suggests that their expression is controlled through the combinatorial action of tissue- and stage-specific factors (OTF-2, TF-microB, NF-kappa B), as well as more widely expressed E motif-binding factors such as E47/E12. Two basic issues cloud understanding of how these factors are involved in immunoglobulin gene regulation. First, cloning of these factors shows them to be members of families of proteins, all with similar DNA-binding specificities. OTF-2 is a member of the POU domain family, NF-kappa B is a related protein, and the microE5/kappa E2-binding factors are members of the bHLH family. Second, these binding sites and associated factors are involved in the regulation of many genes, not only the immunoglobulin genes, and in fact not only lymphoid-specific genes. These facts complicate understanding which member of a family is in fact responsible for interaction with, and activation of, a particular binding element in an enhancer/promoter. Recently, more detailed analysis of the interactions between such proteins and their related binding sites suggest that a certain level of specificity may in fact be encoded by the DNA element such that one family member of a protein is preferentially bound, or alternatively that the protein-DNA interactions that occur give subtle alterations in protein conformation that unmask an activation or protein-protein interactive domain. An additional level of regulation is imparted by combinatorial mechanisms such as adjacent DNA-binding elements and factors that may alter activity, as well as "cofactors" that, by forming a complex with the bound factor, affect its activation of a gene in a particular cell type. A third level of specificity may be obtained by factors such as NF-kappa B and the bHLH family due to their ability to create heterogeneous complexes, creating unique complexes in a tissue- or stage-specific manner. The multiple functions transcription factors such as NF-kappa B and OTF-2 play in the transcriptional regulation of multiple genes seems complex in contrast to a one factor, one gene regulation model. However, this type of organization may limit the number of factors lymphocytes would require if each lymphoid-specific gene were activated by a unique factor. Thus what appears to be complexity at the molecular level may reflect an economical organization at the cellular level. Investigation of the key factors controlling these genes suggests an ordered cascade of transcription factors becomes available in the cell during B cell differentiation.(ABSTRACT TRUNCATED AT 400 WORDS)

The plasmacytoma J558L lacks constitutively active NF-kappa B and is deficient in early response gene activation

In mature B cells the nuclear factor NF-kappa B which binds within the kappa enhancer is constitutively present in the nucleus. However, the lambda light chain producing myeloma J558L has been found to lack constitutively functional NF-kappa B. Deoxycholate released functional NF-kappa B from cytoplasmic extracts and functional NF-kappa B was present in J558L following cycloheximide but not phorbol ester treatment. J558L was also unable to respond to phorbol ester stimulation with synthesis of mRNA from the early response gene TIS11. J558L differs from S107, another myeloma which was found to be deficient in the synthesis of NF-kappa B but not in the activation of TIS11. Somatic cell hybrids were used to further define the defect in J558L; hybrids were made with the myelomas S107 and S194 and the pre-B cell line 70Z/3. In general, complementation of the defect in J558L was observed; however there was not a direct correlation between the levels of TIS11 mRNA and NF-kappa B expression in the somatic cell hybrids, suggesting that the pathways of activation of these genes, while possibly sharing common elements, are not identical. The defect in J558L was surprising given that it has frequently been used for the expression of transfected light chain genes.

Functional modularity in the SP6 kappa promoter

The requirements of the SP6 kappa promoter for transcriptional activation were studied in nontransformed murine B lymphocytes stimulated with lipopolysaccharide. Three different DNA motifs, besides the TATA-box, were needed for restoration of transcriptional activation to the same magnitude as seen with the native SP6 kappa promoter. The decamer motif (TNCTTTGCAT) was found to induce transcription alone and point-mutation of this element reduced transcription to negligible levels, although the other two required elements were present. The penta-decamer element (TGCAG/CCTGTGNCCAG) did not stimulate transcription alone, but activated transcription synergistically in conjunction with the decamer motif. This synergism required the presence of a third pyrimidine rich element (CCCT) in the decamer 3' flanking sequence. The pyrimidine rich element could partly be substituted for by an E-box core motif (CANNTG) 3' of, but not by the kappa Y motif (CTTCCTTA) 5' of, the decamer. Proteins interacting specifically with the penta-decamer element were detected by band-shift assay. The decamer 3' flanking sequence of the SP6 kappa promoter was found to modify the binding of endogenous Oct2 isoforms to the decamer motif i B lymphocytes, but not in CHO cells transfected with various Oct2 isoforms. Thus, complex protein/DNA interactions can be observed in the SP6 kappa promoter which correlate functionally with a synergism in transcriptional activation.

The endogenous Mtv-8 provirus resides within the V kappa locus

The endogenous Mtv-8 provirus previously has been mapped within approximately 0.52 centimorgan from several V kappa markers on mouse chromosome 6. Using Southern blotting and DNA from a recombinant backcross mouse from the C57BL/6 (Mtv-8 positive) and C58 (Mtv-8 negative) strains, Mtv-8 was localized to the same side of the crossover point as immunoglobulin kappa (Ig kappa)-V24 but on the opposite side of the crossover from Ig kappa-V10 and Ig kappa-V21. Molecular cloning and characterization of cellular DNA adjacent to Mtv-8 revealed a functional V kappa 9 gene approximately 4.6 kb downstream and in the same transcriptional orientation as the provirus. These data suggest that Mtv-8 is within the centromere-proximal portion of the V kappa locus.

Functional characterization of the developmentally controlled immunoglobulin kappa 3' enhancer: regulation by Id, a repressor of helix-loop-helix transcription factors

We have functionally characterized an enhancer element (kappa E3') which lies 8.5 kb downstream of the immunoglobulin kappa gene. The activity of this enhancer is developmentally controlled. It is inactive at the pre-B-cell stage but active at the B-cell and plasma cell stages. This enhancer is also functional in S107 plasmacytoma cells, which lack NF-kappa B and therefore intron enhancer activity. The activity of the kappa E3' enhancer therefore provides an explanation for the transcriptional activity of endogenous kappa genes in S107 cells in the absence of intron enhancer function. We have identified a 132-bp segment of the kappa E3' enhancer that retains 75% of the activity of the entire enhancer observed in plasmacytoma cells. Within this 132-bp core, there are at least two functional elements, one of which binds to a B-cell-specific nuclear factor. This element contains a potential binding site for the B-cell- and macrophage-specific transcription factor PU.1. The kappa intron and kappa E3' enhancers were also found to be regulatable by Id, an inhibitor of helix-loop-helix transcription factors. The site of action of Id on the kappa E3' enhancer was mapped to a 25-bp region which contains a potential binding site for a helix-loop-helix transcription factor. A possible model for the developmental control of kappa gene transcription is discussed.

Functional characterization of the developmentally controlled immunoglobulin kappa 3' enhancer: regulation by Id, a repressor of helix-loop-helix transcription factors

We have functionally characterized an enhancer element (kappa E3') which lies 8.5 kb downstream of the immunoglobulin kappa gene. The activity of this enhancer is developmentally controlled. It is inactive at the pre-B-cell stage but active at the B-cell and plasma cell stages. This enhancer is also functional in S107 plasmacytoma cells, which lack NF-kappa B and therefore intron enhancer activity. The activity of the kappa E3' enhancer therefore provides an explanation for the transcriptional activity of endogenous kappa genes in S107 cells in the absence of intron enhancer function. We have identified a 132-bp segment of the kappa E3' enhancer that retains 75% of the activity of the entire enhancer observed in plasmacytoma cells. Within this 132-bp core, there are at least two functional elements, one of which binds to a B-cell-specific nuclear factor. This element contains a potential binding site for the B-cell- and macrophage-specific transcription factor PU.1. The kappa intron and kappa E3' enhancers were also found to be regulatable by Id, an inhibitor of helix-loop-helix transcription factors. The site of action of Id on the kappa E3' enhancer was mapped to a 25-bp region which contains a potential binding site for a helix-loop-helix transcription factor. A possible model for the developmental control of kappa gene transcription is discussed.

Promoters with the octamer DNA motif (ATGCAAAT) can be ubiquitous or cell type-specific depending on binding affinity of the octamer site and Oct-factor concentration

Immunoglobulin (Ig) gene promoters contain the octamer sequence motif ATGCAAAT which is recognized by cellular transcription factors (Oct factors). Besides the ubiquitous Oct-1 factor, there is also a group of related factors (Oct-2 factors) encoded by a separate gene. The Oct-2 gene is regulated in a cell-type specific manner, and the protein is present in large amounts in B lymphocytes. We have previously shown that simple composite promoters of an octamer/TATA box type are poorly active in non-B cells but are strongly responsive to ectopic expression of Oct-2A factor, a major representative of the lymphocyte Oct-2 factors. In the present study we have tested the activity of a number of composite promoters and natural Ig promoters, and their response to Oct-1 and Oct-2 factors. Unexpectedly, we find that octamer/TATA promoters with a high affinity octamer site direct ubiquitous expression. By contrast, promoter constructions that behave in a B cell-specific manner tend to have a weak octamer binding site. These promoters are responsive to ectopic expression of additional Oct-factor, irrespective of whether it is Oct-1 or Oct-2. Using natural Ig promoters rather than composite promoters, we find that an IgH promoter is well transcribed in non-B cells via the ubiquitous Oct-1 factor, while Ig kappa and Ig lambda light chain promoters require additional Oct factor for maximal expression. It seems therefore likely that during B cell differentiation, Ig heavy chain promoters can be activated by Oct-1, before the appearance of Oct-2 factors. Oct-2 factors then would serve to boost the expression from Ig light chain promoters, which are known to be activated only after successful heavy chain gene rearrangement.

Interaction of a nuclear protein with a palindromic sequence of the mouse immunoglobulin lambda 2-chain gene promoter is important for its transcription

By using a gel mobility retardation assay, we detected the formation of three major complexes from the binding of nuclear proteins to the promoter of the immunoglobulin lambda 2-chain gene. Two of the complexes were generated by the presence of an unidentified nuclear factor(s) called herein NF-lambda 2. Although the sequences between lambda 2- and lambda 1-chain gene promoters are very similar, the lambda 1-chain promoter did not compete for the binding of NF-lambda 2 efficiently. The binding site of NF-lambda 2 was localized by DNase I footprinting to a 14-bp region which is about 30 bp upstream of the immunoglobulin octamer motif. This region, referred to as the NF-lambda 2 motif, is within an 18-bp region of twofold rotational symmetry. Experiments with oligomers containing either the NF-lambda 2 or the octamer motifs as competitors for binding and DNase I footprinting, showed that the third complex is the product of the simultaneous binding of an octamer-binding protein and NF-lambda 2. Changing the sequence of the NF-lambda 2 motif to that of the lambda 1-chain counterpart abolished the binding ability of NF-lambda 2. Concomitantly, the level of chloramphenicol acetyltransferase expression driven by the mutated lambda 2 promoter decreased by two- to fivefold when compared with that of the wild-type promoter. It is therefore concluded that the interaction of NF-lambda 2 with the NF-lambda 2 motif stimulates transcription of the lambda 2-chain gene.

Interaction of a nuclear protein with a palindromic sequence of the mouse immunoglobulin lambda 2-chain gene promoter is important for its transcription

By using a gel mobility retardation assay, we detected the formation of three major complexes from the binding of nuclear proteins to the promoter of the immunoglobulin lambda 2-chain gene. Two of the complexes were generated by the presence of an unidentified nuclear factor(s) called herein NF-lambda 2. Although the sequences between lambda 2- and lambda 1-chain gene promoters are very similar, the lambda 1-chain promoter did not compete for the binding of NF-lambda 2 efficiently. The binding site of NF-lambda 2 was localized by DNase I footprinting to a 14-bp region which is about 30 bp upstream of the immunoglobulin octamer motif. This region, referred to as the NF-lambda 2 motif, is within an 18-bp region of twofold rotational symmetry. Experiments with oligomers containing either the NF-lambda 2 or the octamer motifs as competitors for binding and DNase I footprinting, showed that the third complex is the product of the simultaneous binding of an octamer-binding protein and NF-lambda 2. Changing the sequence of the NF-lambda 2 motif to that of the lambda 1-chain counterpart abolished the binding ability of NF-lambda 2. Concomitantly, the level of chloramphenicol acetyltransferase expression driven by the mutated lambda 2 promoter decreased by two- to fivefold when compared with that of the wild-type promoter. It is therefore concluded that the interaction of NF-lambda 2 with the NF-lambda 2 motif stimulates transcription of the lambda 2-chain gene.

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.

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.

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.

Muscle-specific activity of the skeletal troponin I promoter requires interaction between upstream regulatory sequences and elements contained within the first transcribed exon

Expression of the skeletal troponin I (sTnI) gene is regulated transcriptionally in a muscle-specific fashion. We show here that the region of the sTnI gene between -160 and +61 (relative to the transcription initiation site) is able to direct expression of the bacterial chloramphenicol acetyltransferase (CAT) gene is muscle cultures at a level approximately 100 times higher than in fibroblast cultures. RNA analysis demonstrated that transcription of the CAT gene was initiated at the same site as transcription of the endogenous sTnI gene and that CAT activity levels were approximately proportional to CAT mRNA levels. Deletion analysis demonstrated that the region between nucleotides -160 and -40 contained sequences essential for full promoter activity. Surprisingly, 3' deletion analysis indicated that the first exon (-6 to +61) of the sTnI gene was also required for full activity of the sTnI promoter in skeletal muscle cells. Chimeric promoter experiments, in which segments of the sTnI and the herpes simplex virus thymidine kinase promoter were interchanged, indicated that reconstitution of a muscle-specific promoter required inclusion of both the upstream and exon I regions of the sTnI gene. Exon I, and the region immediately upstream, showed DNase protection over sequence motifs related to those found in other genes, including the tar region of human immunodeficiency virus type 1. These results demonstrate that expression of the sTnI promoter in embryonic skeletal muscle cells requires complex interaction between two separate promoter regions, one of which resides within the first 61 transcribed nucleotides of the gene.

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.

Muscle-specific activity of the skeletal troponin I promoter requires interaction between upstream regulatory sequences and elements contained within the first transcribed exon

Expression of the skeletal troponin I (sTnI) gene is regulated transcriptionally in a muscle-specific fashion. We show here that the region of the sTnI gene between -160 and +61 (relative to the transcription initiation site) is able to direct expression of the bacterial chloramphenicol acetyltransferase (CAT) gene is muscle cultures at a level approximately 100 times higher than in fibroblast cultures. RNA analysis demonstrated that transcription of the CAT gene was initiated at the same site as transcription of the endogenous sTnI gene and that CAT activity levels were approximately proportional to CAT mRNA levels. Deletion analysis demonstrated that the region between nucleotides -160 and -40 contained sequences essential for full promoter activity. Surprisingly, 3' deletion analysis indicated that the first exon (-6 to +61) of the sTnI gene was also required for full activity of the sTnI promoter in skeletal muscle cells. Chimeric promoter experiments, in which segments of the sTnI and the herpes simplex virus thymidine kinase promoter were interchanged, indicated that reconstitution of a muscle-specific promoter required inclusion of both the upstream and exon I regions of the sTnI gene. Exon I, and the region immediately upstream, showed DNase protection over sequence motifs related to those found in other genes, including the tar region of human immunodeficiency virus type 1. These results demonstrate that expression of the sTnI promoter in embryonic skeletal muscle cells requires complex interaction between two separate promoter regions, one of which resides within the first 61 transcribed nucleotides of the gene.

Regulation of kappa immunoglobulin gene transcription in vitro

An in vitro transcription system has been established with a whole-cell extract from the human Burkitt's lymphoma, Daudi, cell line. The B cell extract has been compared with a HeLa cell extract in an effort to study lymphocyte-specific regulatory factors of kappa light chain gene transcription. Both extracts were capable of transcribing Vk genes and other RNA polymerase II dependent genes. Alpha-amanitin at [0.1 micrograms/ml] completely inhibited the accumulation of transcripts in both systems. At low DNA template concentrations the kappa intronic enhancer stimulated Vk promoter transcription 3-7 fold in B cell extracts. The enhancer-dependent transcription was abolished by excising the enhancer from the test plasmid with Eco R1. Both Vk promoter and enhancer-dependent transcription in HeLa extracts was undetectable at low [DNA]. These results demonstrate that kappa enhancer stimulation of Vk transcription in vitro is observed in B cell extracts only under conditions of low DNA template concentration.

Identification of a novel factor that interacts with an immunoglobulin heavy-chain promoter and stimulates transcription in conjunction with the lymphoid cell-specific factor OTF2

The tissue-specific expression of the MOPC 141 immunoglobulin heavy-chain gene was studied by using in vitro transcription. B-cell-specific transcription of this gene was dependent on the octamer element 5'-ATGCAAAG-3', located in the upstream region of this promoter and in the promoters of all other immunoglobulin heavy- and light-chain genes. The interaction of purified octamer transcription factors 1 and 2 (OTF1 and OTF2) with the MOPC 141 promoter was studied by using electrophoretic mobility shift assays and DNase I footprinting. Purified OTF1 from HeLa cells and OTF1 and OTF2 from B cells bound to identical sequences within the heavy-chain promoter. The OTF interactions we observed extended over the heptamer element 5'-CTCAGGA-3', and it seems likely that the binding of the purified factors involves cooperation between octamer and heptamer sites in this promoter. In addition to these elements, we identified a second regulatory element, the N element with the sequence 5'-GGAACCTCCCCC-3'. The N element could independently mediate low levels of transcription in both B-cell and HeLa-cell extracts, and, in conjunction with the octamer element, it can promote high levels of transcription in B-cell extracts. The N element bound a transcription factor, NTF, that is ubiquitous in cell-type distribution, and NTF was distinct from any of the previously described proteins that bind to similar sequences. Based on these results, we propose that NTF and OTF2 interactions (both with their cognate DNA elements and possibly at the protein-protein level) may be critical to B-cell-specific expression and that these interactions provide additional pathways for regulating gene expression.

Identification of a novel factor that interacts with an immunoglobulin heavy-chain promoter and stimulates transcription in conjunction with the lymphoid cell-specific factor OTF2

The tissue-specific expression of the MOPC 141 immunoglobulin heavy-chain gene was studied by using in vitro transcription. B-cell-specific transcription of this gene was dependent on the octamer element 5'-ATGCAAAG-3', located in the upstream region of this promoter and in the promoters of all other immunoglobulin heavy- and light-chain genes. The interaction of purified octamer transcription factors 1 and 2 (OTF1 and OTF2) with the MOPC 141 promoter was studied by using electrophoretic mobility shift assays and DNase I footprinting. Purified OTF1 from HeLa cells and OTF1 and OTF2 from B cells bound to identical sequences within the heavy-chain promoter. The OTF interactions we observed extended over the heptamer element 5'-CTCAGGA-3', and it seems likely that the binding of the purified factors involves cooperation between octamer and heptamer sites in this promoter. In addition to these elements, we identified a second regulatory element, the N element with the sequence 5'-GGAACCTCCCCC-3'. The N element could independently mediate low levels of transcription in both B-cell and HeLa-cell extracts, and, in conjunction with the octamer element, it can promote high levels of transcription in B-cell extracts. The N element bound a transcription factor, NTF, that is ubiquitous in cell-type distribution, and NTF was distinct from any of the previously described proteins that bind to similar sequences. Based on these results, we propose that NTF and OTF2 interactions (both with their cognate DNA elements and possibly at the protein-protein level) may be critical to B-cell-specific expression and that these interactions provide additional pathways for regulating gene expression.

Analysis of the expression of murine lambda genes transfected into immunocompetent cell lines

Hybridoma cell lines were transfected with plasmids containing either a rearranged lambda 1 or a rearranged lambda 2 mouse gene. The levels of lambda-chains synthesized by these transfectants were very low or undetectable. Activation of the expression of the lambda 2 gene was achieved artificially by deleting a portion of the region upstream of the promoter. Analogous deletions in the fragment containing the lambda 1 gene did not result in gene activation suggesting that the upstream sequences of lambda 1 and lambda 2 genes have diverged enough to allow differential regulation of their expression. However, both genes were activated by insertion, at a position upstream of the promoter, of a fragment containing the K-chain gene enhancer. These results suggest that the complete set of sequence elements that mediate lambda gene activation during normal B-cell differentiation are not all contained in the fragments of genomic DNA cloned so far, and thus, at least some of them must be located at a considerable distance from the promoter.

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

A 215-base-pair (bp) region of the mouse MOPC 41 kappa light-chain immunoglobulin gene enhancer has been analyzed for specific binding of lymphoid and nonlymphoid nuclear factors. Mobility shift assays with a series of overlapping DNA fragments have mapped DNA-binding sites for three unique factors. The B-cell-specific (OTF-2) and ubiquitous (OTF-1) octamer-binding transcription factors specifically bound to a site centered about 136 bp 5' of the nuclear factor NF-kappa B site. A third specific factor, NF-kappa E, bound to a site that was about 75 bp 5' of the NF-kappa B site and within a region important for enhancer function. This novel factor was found in both mature B and HeLa cell nuclei. B-cell OTF-2, B-cell OTF-1, and HeLa OTF-1 bound to the kappa enhancer and kappa promoter octamer sites with similar affinities despite a 2-bp difference in the kappa enhancer octamer sequence. However, DNase I footprint analyses indicated that affinity-purified OTF-2 bound both to the enhancer OTF site and, surprisingly, to 80 bp of A + T-rich flanking sequence. Moreover, methylation interference studies demonstrated distinct differences in OTF interactions between the consensus octamer in the kappa promoter and the nonconsensus octamer identified in the enhancer. This novel observation of an OTF-binding site in the kappa enhancer provides a common link with the OTF sites in the promoter-proximal regions of all kappa promoters and thus mirrors the structural arrangement of OTF sites found in the promoters and enhancers of immunoglobulin heavy-chain genes.

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

A 215-base-pair (bp) region of the mouse MOPC 41 kappa light-chain immunoglobulin gene enhancer has been analyzed for specific binding of lymphoid and nonlymphoid nuclear factors. Mobility shift assays with a series of overlapping DNA fragments have mapped DNA-binding sites for three unique factors. The B-cell-specific (OTF-2) and ubiquitous (OTF-1) octamer-binding transcription factors specifically bound to a site centered about 136 bp 5' of the nuclear factor NF-kappa B site. A third specific factor, NF-kappa E, bound to a site that was about 75 bp 5' of the NF-kappa B site and within a region important for enhancer function. This novel factor was found in both mature B and HeLa cell nuclei. B-cell OTF-2, B-cell OTF-1, and HeLa OTF-1 bound to the kappa enhancer and kappa promoter octamer sites with similar affinities despite a 2-bp difference in the kappa enhancer octamer sequence. However, DNase I footprint analyses indicated that affinity-purified OTF-2 bound both to the enhancer OTF site and, surprisingly, to 80 bp of A + T-rich flanking sequence. Moreover, methylation interference studies demonstrated distinct differences in OTF interactions between the consensus octamer in the kappa promoter and the nonconsensus octamer identified in the enhancer. This novel observation of an OTF-binding site in the kappa enhancer provides a common link with the OTF sites in the promoter-proximal regions of all kappa promoters and thus mirrors the structural arrangement of OTF sites found in the promoters and enhancers of immunoglobulin heavy-chain genes.

The Oct-2 protein binds cooperatively to adjacent octamer sites

Recombinant proteins derived from the cloned human oct-2 gene were used to investigate cooperative binding by Oct-2 to adjacent DNA-binding sites. Oct-2, a B-cell-specific transcription factor, binds tightly to the octamer sequence in immunoglobulin promoters. A second apparently unrelated consensus sequence in heavy chain promoters, the heptamer site, also is recognized by the Oct-2 protein but with 1000-fold lower affinity. Simultaneous occupancy of both the octamer and heptamer sites is favored by cooperative interactions. The heptamer site is probably recognized by the same binding surface in the Oct-2 protein as the octamer site and thus is conserved as a lower-affinity binding site. This permits the immunoglobulin promoter to respond to a much broader range of levels of Oct-2 protein. Substitution of prototype octamer sequences for heptamer sequences yields a probe with two octamer sites spaced by 2 nucleotides, which also binds Oct-2 protein cooperatively. Only the POU domain in the Oct-2 protein is required for this cooperative interaction. Similar protein-protein interactions between bound Oct-2 proteins may promote promoter-enhancer synergism in the heavy chain gene.

Site-specific cleavage of supercoiled DNA by ascorbate/Cu(II)

We have investigated ascorbate/Cu(II) cleavage of double-stranded DNA in the presence and absence of DNA negative torsion. We found that ascorbate/Cu(II) cleavage shows a site-specificity that is dependent on negative torsion and is influenced by the nature of the salt, ionic strength, and pH. This provides strong evidence for involvement of local DNA conformation in ascorbate/Cu(II) specific cleavage sites, that differs from the previous reports on cleavage of linear double-stranded DNA and secondary structures assumed by single-stranded DNA. The data indicate specific binding of Cu(II) ions to sites in the negatively supercoiled DNA. Fining mapping of the cleavage sites does not reveal any known DNA conformation, nor does it indicate any sequence identity among the sites cleaved. However, identification of a major site of cleavage of supercoiled DNA at physiological ionic strength, pH and temperature, along with fact that ascorbate and Cu(II) are normal cell constituents, suggests the torsion-dependent, site-specific interactions could have biological significance.

Transcription of the chicken histone H5 gene is mediated by distinct tissue-specific elements within the promoter and the 3' enhancer

Molecular genetic analysis of a number of vertebrate erythroid cell-specific genes has identified at least two types of cis-acting regulatory sequences which control the complex developmental pattern of gene expression during erythroid cell maturation. Tissue-specific cellular enhancers have been identified 3' to three erythroid cell-specific genes, and additional regulatory elements have been identified in the promoters of many erythroid genes. We show that the histone H5 enhancer, like the adult beta-globin enhancer, is involved in mediating the developmental induction of histone H5 mRNA as erythroid cells mature. We also describe the preliminary characterization of a tissue-specific regulatory element within the 5' region of the H5 locus and describe investigations of the interaction between this element and the histone H5 enhancer in mediating histone H5 regulation.

Tissue-specific genetic variation in the level of mouse alcohol dehydrogenase is controlled transcriptionally in kidney and posttranscriptionally in liver

Tissue-specific genetic variation in expression of the alcohol dehydrogenase, encoded by the Adh-1 gene, is found between C57BL/6J (B6) mice and B6.S congenic mice. B6.S mice contain a variant Adh-1 allele derived from a wild Danish strain in a B6 genetic background. B6 mice have nearly twice the alcohol dehydrogenase activity in liver but less than half the activity in kidney as B6.S mice. These tissue-specific genetic changes in alcohol dehydrogenase expression are manifest at the level of Adh-1-encoded mRNA. The regulatory site(s) involved act cis in both kidney and liver. These strains also differ in the extent to which androgen induces mRNA encoded by kidney Adh-1, with androgen increasing these levels 17-fold and 7.4-fold in the B6 and B6.S kidney, respectively. To identify the regulatory mechanism(s) underlying this strain variation in Adh-1 transcription in the B6 and B6.S kidney, liver, and androgen-induced kidney. For both uninduced and induced kidney, a difference in the transcription rate alone accounts for the strain difference in mRNA concentration. In contrast, because the Adh-1 transcription rate in liver does not differ significantly between B6 and B6.S mice, strain-specific variation in posttranscriptional regulation must be operative. Taken together these results indicate that the variation in Adh-1 expression between B6 and B6.S mice results from changes in both transcriptional and posttranscriptional control, and these controls are differentially operative in kidney and liver.

An enhancer associated with the mouse immunoglobulin lambda 1 gene is specific for lambda light chain producing cells

We have developed a system to study transcriptional regulation of the lambda immunoglobulin gene in a natural setting -- lambda light chain producing lymphoid cells. This assay system has allowed the detection of an enhancer element located 3' of the lambda gene coding sequence. The enhancer can stimulate transcription from the lambda promoter as well as from other immunoglobulin and unrelated promoters. Like all enhancers, the lambda enhancer can function in either orientation with respect to a promoter, but it is significantly more active in one orientation than in the other. The lambda enhancer is unusual in spanning at least 4000 bp of DNA sequence and containing several distinct subelements that have independent enhancer activity. The enhancer is also remarkable because it functions in lambda light chain producing cells but not in kappa chain producing cells. This fact can be interpreted to support a model of immunoglobulin gene rearrangement in which rearrangement follows and depends on transcriptional activation.

Octamer transcription factors 1 and 2 each bind to two different functional elements in the immunoglobulin heavy-chain promoter

Immunoglobulin heavy-chain genes contain two conserved sequence elements 5' to the site of transcription initiation: the octamer ATGCAAAT and the heptamer CTCATGA. Both of these elements are required for normal cell-specific promoter function. The present study demonstrates that both the ubiquitous and lymphoid-cell-specific octamer transcription factors (OTF-1 and OTF-2, respectively) interact specifically with each of the two conserved sequence elements, forming either homo- or heterodimeric complexes. This was surprising, since the heptamer and octamer sequence motifs bear no obvious similarity to each other. Binding of either factor to the octamer element occurred independently. However, OTF interaction with the heptamer sequence appeared to require the presence of an intact octamer motif and occurred with a spacing of either 2 or 14 base pairs between the two elements, suggesting coordinate binding resulting from protein-protein interactions. The degeneracy in sequences recognized by the OTFs may be important in widening the range over which gene expression can be modulated and in establishing cell type specificity.

New B-lymphocyte-specific enhancer-binding protein

We report the discovery of a new B-lymphocyte-specific enhancer-binding protein. A series of gel retardation assays using fragments that scan the -2172 to -1180 region of the major histocompatibility complex class II gene E alpha reveal a site (W) that serves as the recognition sequence for two nuclear proteins, one B-cell restricted and the other ubiquitously occurring. Certain characteristics of the NF-W1 and NF-W2 pair recall the OTF-2/NF-A2 and OTF-1/NF-A1 pair that binds to the immunoglobulin octamer, but we demonstrate that the two protein pairs are distinguishable by several criteria. NF-W1 and NF-W2 interact differentially with their common GTTGCATC binding site, display a different affinity for it, and have molecular weights that differ by about 20,000. Yet, proteolysis experiments and cross-linking analyses indicate that the two W complexes show structural relatedness.

Transcription of the chicken histone H5 gene is mediated by distinct tissue-specific elements within the promoter and the 3' enhancer

Molecular genetic analysis of a number of vertebrate erythroid cell-specific genes has identified at least two types of cis-acting regulatory sequences which control the complex developmental pattern of gene expression during erythroid cell maturation. Tissue-specific cellular enhancers have been identified 3' to three erythroid cell-specific genes, and additional regulatory elements have been identified in the promoters of many erythroid genes. We show that the histone H5 enhancer, like the adult beta-globin enhancer, is involved in mediating the developmental induction of histone H5 mRNA as erythroid cells mature. We also describe the preliminary characterization of a tissue-specific regulatory element within the 5' region of the H5 locus and describe investigations of the interaction between this element and the histone H5 enhancer in mediating histone H5 regulation.

Octamer transcription factors 1 and 2 each bind to two different functional elements in the immunoglobulin heavy-chain promoter

Immunoglobulin heavy-chain genes contain two conserved sequence elements 5' to the site of transcription initiation: the octamer ATGCAAAT and the heptamer CTCATGA. Both of these elements are required for normal cell-specific promoter function. The present study demonstrates that both the ubiquitous and lymphoid-cell-specific octamer transcription factors (OTF-1 and OTF-2, respectively) interact specifically with each of the two conserved sequence elements, forming either homo- or heterodimeric complexes. This was surprising, since the heptamer and octamer sequence motifs bear no obvious similarity to each other. Binding of either factor to the octamer element occurred independently. However, OTF interaction with the heptamer sequence appeared to require the presence of an intact octamer motif and occurred with a spacing of either 2 or 14 base pairs between the two elements, suggesting coordinate binding resulting from protein-protein interactions. The degeneracy in sequences recognized by the OTFs may be important in widening the range over which gene expression can be modulated and in establishing cell type specificity.

New B-lymphocyte-specific enhancer-binding protein

We report the discovery of a new B-lymphocyte-specific enhancer-binding protein. A series of gel retardation assays using fragments that scan the -2172 to -1180 region of the major histocompatibility complex class II gene E alpha reveal a site (W) that serves as the recognition sequence for two nuclear proteins, one B-cell restricted and the other ubiquitously occurring. Certain characteristics of the NF-W1 and NF-W2 pair recall the OTF-2/NF-A2 and OTF-1/NF-A1 pair that binds to the immunoglobulin octamer, but we demonstrate that the two protein pairs are distinguishable by several criteria. NF-W1 and NF-W2 interact differentially with their common GTTGCATC binding site, display a different affinity for it, and have molecular weights that differ by about 20,000. Yet, proteolysis experiments and cross-linking analyses indicate that the two W complexes show structural relatedness.

B-cell control region at the 5' end of a major histocompatibility complex class II gene: sequences and factors

Transcription of major histocompatibility complex class II genes is elaborately regulated. Mouse class II genes are transcribed primarily in B cells, peripheral macrophages and interdigitating cells, and thymic cortical and medullary cells. In this study, we began to identify the DNA sequences and protein factors that control expression of a class II gene in B cells, addressing in particular how closely they resemble those that regulate immunoglobulin gene expression. We describe a region upstream of the E alpha gene that is crucial for its transcription in the B cells of transgenic mice but is less important in cultured B-cell lines. The sequence of this region reveals several familiar motifs, including a second X-Y pair reminiscent of that residing in the promoter-proximal region of all class II genes, a B motif strikingly homologous to that associated with the immunoglobulin kappa gene enhancer, several Ephrussi motifs, and a Pu box-like sequence very similar to that implicated in simian virus 40 and lymphotrophic papovavirus expression in B cells. Careful study of the proteins that bind specifically to these different motifs prompts us to suggest that major histocompatibility complex class II and immunoglobulin genes rely on quite different factors to achieve B-cell-specific expression.

B-cell control region at the 5' end of a major histocompatibility complex class II gene: sequences and factors

Transcription of major histocompatibility complex class II genes is elaborately regulated. Mouse class II genes are transcribed primarily in B cells, peripheral macrophages and interdigitating cells, and thymic cortical and medullary cells. In this study, we began to identify the DNA sequences and protein factors that control expression of a class II gene in B cells, addressing in particular how closely they resemble those that regulate immunoglobulin gene expression. We describe a region upstream of the E alpha gene that is crucial for its transcription in the B cells of transgenic mice but is less important in cultured B-cell lines. The sequence of this region reveals several familiar motifs, including a second X-Y pair reminiscent of that residing in the promoter-proximal region of all class II genes, a B motif strikingly homologous to that associated with the immunoglobulin kappa gene enhancer, several Ephrussi motifs, and a Pu box-like sequence very similar to that implicated in simian virus 40 and lymphotrophic papovavirus expression in B cells. Careful study of the proteins that bind specifically to these different motifs prompts us to suggest that major histocompatibility complex class II and immunoglobulin genes rely on quite different factors to achieve B-cell-specific expression.

Octamer-binding proteins from B or HeLa cells stimulate transcription of the immunoglobulin heavy-chain promoter in vitro

The B-cell-type specificity of the immunoglobulin (Ig) heavy-chain and light-chain promoters is mediated by an octanucleotide (OCTA) element, ATGCAAAT, that is also a functional component of other RNA polymerase II promoters, such as snRNA and histone H2B promoters. Two nuclear proteins that bind specifically and with high affinity to the OCTA element have been identified. NF-A1 is present in a variety of cell types, whereas the presence of NF-A2 is essentially confined to B cells, leading to the hypothesis that NF-A2 activates cell-type-specific transcription of the Ig promoter and NF-A1 mediates the other responses of the OCTA element. Extracts of the B-cell line, BJA-B, contain high levels of NF-A2 and specifically transcribe Ig promoters. In contrast, extracts from HeLa cells transcribed the Ig promoter poorly. Surprisingly, addition of either affinity-enriched NF-A2 or NF-A1 to either a HeLa extract or a partially purified reaction system specifically stimulates the Ig promoter. This suggests that the constitutive OCTA-binding factor NF-A1 can activate transcription of the Ig promoter and that B-cell-specific transcription of this promoter, at least in vitro, is partially due to a quantitative difference in the amount of OCTA-binding protein. Because NF-A1 can stimulate Ig transcription, the inability of this factor to activate in vivo the Ig promoter to the same degree as the snRNA promoters probably reflects a difference in the context of the OCTA element in these two types of promoters.

Analysis of the upstream regions governing expression of the chicken cardiac troponin T gene in embryonic cardiac and skeletal muscle cells

The chicken gene encoding cardiac troponin T (cTNT) is expressed in both cardiac and skeletal muscle during early embryonic development, but is specifically repressed in skeletal muscle during fetal development. To determine if the cis-acting sequences governing transcription of a single gene in these two related cell types are the same, we have transfected promoter/upstream segments of the cTNT gene coupled to the bacterial chloramphenicol acetyltransferase gene into primary cultures of early embryonic cardiac and skeletal muscle cells. Using this assay system, chloramphenicol acetyltransferase activity directed by the cTNT promoter/upstream region was between two and three orders of magnitude higher in cardiac or skeletal muscle cells than in fibroblast cells, indicating that cis elements responsible for cell-specific expression reside in this region of the cTNT gene. Deletion experiments showed that a 67-nucleotide DNA segment residing between 268 and 201 nucleotides upstream of the cTNT transcription initiation site is required for cTNT promoter activity in embryonic cardiac cells. This region is not required in embryonic skeletal muscle cells because a cTNT promoter construction containing only 129 upstream nucleotides is transcriptionally active in these cells. These results demonstrate that different cis-acting sequences are required for cTNT expression in early embryonic cardiac and skeletal muscle cells. Nonessential regions residing farther upstream, on the other hand, affected the level of expression of these minimum regions in a similar manner in both cell types. The data from these experiments indicate, therefore, that transcription of the cTNT promoter in early embryonic cardiac and skeletal muscle cells is governed both by common and divergent regulatory elements in cis and in trans.

Cloning of a lymphoid-specific cDNA encoding a protein binding the regulatory octamer DNA motif

An octamer DNA sequence plays a critical role in directing transcription of immunoglobulin genes in B lymphocytes. A new technique of direct binding of radioactive DNA was used to screen a complementary DNA expression library from the BJAB cell line in lambda gt11 phage to derive molecular cDNA clones representing a putative B lymphocyte-specific octamer binding protein. The plaques were screened with DNA containing four copies of the octamer sequence and positive phage recombinants were identified. The fusion protein produced on inducing a lysogen of one phage bound to a monomeric octamer probe. The cDNA insert from this phage hybridized to messenger RNA found in B lymphocytes, but not in most other cells. Thus, this cDNA derives from a gene (oct-2) that specifies an octamer binding protein expressed preferentially in B lymphocytes, proving that, for at least one gene, a cell-specific transcription factor exists and its amount is controlled through messenger RNA availability.