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

Octamer independent activation of transcription from the kappa immunoglobulin germline promoter

Previous analyses of immunoglobulin V region promoters has led to the discovery of a common octamer motif which is functionally important in the tissue-specific and developmentally regulated transcriptional activation of immunoglobulin genes. The germline promoters (Ko) located upstream of the J region gene segments of the kappa locus also contain an octamer motif (containing a single base pair mutation and referred to as the variant octamer) which has been shown previously to bind Oct-1 and Oct-2 transcription factors in vitro. To further elucidate the role of this variant octamer motif in the regulation of germline transcription from the unrearranged kappa locus, we have quantitated the relative binding affinity of Oct-1 and Oct-2 for the variant octamer motif and determined the functional role of this octamer motif in transcriptional activation. We find that, although the variant octamer motif binds Oct-1 and Oct-2 in vitro with 5-fold lower affinity than the consensus octamer motif, mutation of the variant octamer motif to either a consensus octamer or non-octamer motif has no effect on transcriptional activation from the germline promoter. We also find significant differences in activation of germline and V region promoters by kappa enhancers. Our results suggest that the germline promoters and V region promoters differ in their dependence on octamer for activation and respond differently to enhancer activation. These findings have important implications in regulation of germline transcription as well as concomitant activation of the V-J recombination of the kappa light chain locus.

Functional differences between the Oct2 transactivation domains determine the transactivation potential of individual Oct2 isoforms

The lymphocyte specific transcription factor Oct2 is involved in mediating the B-cell specific transcriptional activity of the octamer motif. Mutational analyses in the context of the complete Oct2 protein had indicated that Oct2 contains two transactivation domains. These two domains appeared to be redundant for activation from a promoter proximal position, whereas stimulation from a remote enhancer position specifically required the C-terminal transactivation domain and an additional B-cell restricted activity. We have generated fusion proteins between the DNA binding domain of the yeast Gal4 transcription factor and individual Oct2 protein domains to analyze their transactivation potential separately. We show that both N- and C-terminal domains can stimulate transcription from a promoter proximal position independently. However, only the C-terminal transactivation domain activates from a distance and it can only do so in B-cells. The C-terminal transactivation domain represents a composite transactivation domain. Whereas removal of just 9 aminoacids from the extreme C-terminus lead to a complete inactivation of this domain deletions from the other side resulted in a gradual loss of activity. We also characterized the transactivation potential of different N-terminal regions of Oct2 generated by alternative splicing. We show that the N-terminus of one of the isoforms, Oct2.3, contains a negative regulatory domain (NRD), which can inactivate the neighbouring glutamine-rich transactivation in cis. The presence of this NRD affects the overall phosphorylation state of the Oct2 protein. This result suggests that the mechanism of inactivation might involve differential protein phosphorylation.

Negative regulation of immunoglobulin kappa light-chain gene transcription by a short sequence homologous to the murine B1 repetitive element

B-cell-specific expression of the immunoglobulin kappa light-chain (Ig kappa) gene is in part accomplished by negative regulatory influences. Here we describe a new negatively acting element (termed kappa NE) immediately upstream of the NF-kappa B-binding site in the Ig kappa intronic enhancer. The 27-bp kappa NE sequence is conserved in the corresponding positions in the rabbit and human Ig kappa genes, and the human kappa NE homolog was shown to have a similar negative regulatory activity. Data base searches using the mouse kappa NE sequence revealed a striking homology to murine B1 repetitive sequences. A sequence homologous to kappa NE and B1 was also noted in a previously identified silencer element in the murine T-cell receptor alpha locus. The homologous T-cell receptor alpha locus sequence, but notably not a corresponding 27-bp B1 consensus sequence, showed a negative regulatory potential similar to that of kappa NE. The negative effect of kappa NE by itself was not cell type specific but became so when paired with its 5'-flanking sequence in the Ig kappa enhancer. A short (30-bp) fragment upstream of kappa NE (termed kappa BS) was found to be necessary and sufficient for abolishing the negative effect of kappa NE in B cells. Point mutations in a T-rich motif within the kappa BS sequence allowed the transcriptional repression by kappa NE to be evident in B cells as well as other cells. As suggested by this cell-independent negative activity, proteins binding to the mouse and human kappa NE sequences were identified in all cell types tested.

Negative regulation of immunoglobulin kappa light-chain gene transcription by a short sequence homologous to the murine B1 repetitive element

B-cell-specific expression of the immunoglobulin kappa light-chain (Ig kappa) gene is in part accomplished by negative regulatory influences. Here we describe a new negatively acting element (termed kappa NE) immediately upstream of the NF-kappa B-binding site in the Ig kappa intronic enhancer. The 27-bp kappa NE sequence is conserved in the corresponding positions in the rabbit and human Ig kappa genes, and the human kappa NE homolog was shown to have a similar negative regulatory activity. Data base searches using the mouse kappa NE sequence revealed a striking homology to murine B1 repetitive sequences. A sequence homologous to kappa NE and B1 was also noted in a previously identified silencer element in the murine T-cell receptor alpha locus. The homologous T-cell receptor alpha locus sequence, but notably not a corresponding 27-bp B1 consensus sequence, showed a negative regulatory potential similar to that of kappa NE. The negative effect of kappa NE by itself was not cell type specific but became so when paired with its 5'-flanking sequence in the Ig kappa enhancer. A short (30-bp) fragment upstream of kappa NE (termed kappa BS) was found to be necessary and sufficient for abolishing the negative effect of kappa NE in B cells. Point mutations in a T-rich motif within the kappa BS sequence allowed the transcriptional repression by kappa NE to be evident in B cells as well as other cells. As suggested by this cell-independent negative activity, proteins binding to the mouse and human kappa NE sequences were identified in all cell types tested.

Oct2 transactivation from a remote enhancer position requires a B-cell-restricted activity

Previous cotransfection experiments had demonstrated that ectopic expression of the lymphocyte-specific transcription factor Oct2 could efficiently activate a promoter containing an octamer motif. Oct2 expression was unable to stimulate a multimerized octamer enhancer element in HeLa cells, however. We have tested a variety of Oct2 isoforms generated by alternative splicing for the capability to activate an octamer enhancer in nonlymphoid cells and a B-cell line. Our analyses show that several Oct2 isoforms can stimulate from a remote position but that this stimulation is restricted to B cells. This result indicates the involvement of either a B-cell-specific cofactor or a specific modification of a cofactor or the Oct2 protein in Oct2-mediated enhancer activation. Mutational analyses indicate that the carboxy-terminal domain of Oct2 is critical for enhancer activation. Moreover, this domain conferred enhancing activity when fused to the Oct1 protein, which by itself was unable to stimulate from a remote position. The glutamine-rich activation domain present in the amino-terminal portion of Oct2 and the POU domain contribute only marginally to the transactivation function from a distal position.

Oct2 transactivation from a remote enhancer position requires a B-cell-restricted activity

Previous cotransfection experiments had demonstrated that ectopic expression of the lymphocyte-specific transcription factor Oct2 could efficiently activate a promoter containing an octamer motif. Oct2 expression was unable to stimulate a multimerized octamer enhancer element in HeLa cells, however. We have tested a variety of Oct2 isoforms generated by alternative splicing for the capability to activate an octamer enhancer in nonlymphoid cells and a B-cell line. Our analyses show that several Oct2 isoforms can stimulate from a remote position but that this stimulation is restricted to B cells. This result indicates the involvement of either a B-cell-specific cofactor or a specific modification of a cofactor or the Oct2 protein in Oct2-mediated enhancer activation. Mutational analyses indicate that the carboxy-terminal domain of Oct2 is critical for enhancer activation. Moreover, this domain conferred enhancing activity when fused to the Oct1 protein, which by itself was unable to stimulate from a remote position. The glutamine-rich activation domain present in the amino-terminal portion of Oct2 and the POU domain contribute only marginally to the transactivation function from a distal position.

Two conserved essential motifs of the murine immunoglobulin lambda enhancers bind B-cell-specific factors

Two highly homologous enhancers associated with the two murine immunoglobulin lambda constant-region clusters were recently identified. In order to better understand the molecular basis for the developmental stage- and cell-type-restricted expression of lambda genes, we have undertaken an analysis of the putative regulatory domains of these enhancers. By using a combination of DNase I footprinting, electrophoretic mobility shift assay, and site-specific mutations, four candidate protein binding sites have been identified at analogous positions in both enhancers. A mutation of any of these sites decreases enhancer activity. Two of the sites, lambda A and lambda B, are essential for enhancer function, and both of these sites appear to bind both B-cell-specific and general factors. Nevertheless, isolated lambda A and lambda B sites show no evidence of inherent transactivating potential, alone or together, even when present in up to three copies. We suggest that the generation of transactivating signals from these enhancers may require the complex interaction of multiple B-cell-specific and nonspecific DNA-binding factors.

Identification of USF as the ubiquitous murine factor that binds to and stimulates transcription from the immunoglobulin lambda 2-chain promoter

To study the specificity and identity of NF-lambda 2, a ubiquitous murine nuclear factor that interacts specifically with the promoter of the lambda 2-chain gene and stimulates its transcription, competition experiments were carried out using DNA fragments from various immunoglobulin regulatory elements. The results showed that a fragment containing the H-chain enhancer competed efficiently for the binding of NF-lambda 2. Dissection of the H-chain enhancer revealed that the microE3 motif contributed the competing ability. Additionally, a regulatory region found in the adenovirus major late promoter, which interacts with the human general transcription factor USF, competed very efficiently for binding to NF-lambda 2. This region contains a sequence, CACGTGAC, which is identical to a region within the NF-lambda 2 motif. The pattern of complexes formation using oligonucleotide probes corresponding to the NF-lambda 2 and USF motifs were identical, and they both differed from that displayed by the E3 probes. Antisera against different domains of USF also react specifically with NF-lambda 2 showing that this factor is antigenically related, if not identical, to USF. Furthermore, the activity of the lambda 2 promoter in an in vitro transcription assay was significantly reduced when the nuclear extract used was USF-depleted. Addition of exogenous USF to this extract restored the transcription activity. Therefore, we conclude that NF-lambda 2 is the murine homologue of USF.

Two conserved essential motifs of the murine immunoglobulin lambda enhancers bind B-cell-specific factors

Two highly homologous enhancers associated with the two murine immunoglobulin lambda constant-region clusters were recently identified. In order to better understand the molecular basis for the developmental stage- and cell-type-restricted expression of lambda genes, we have undertaken an analysis of the putative regulatory domains of these enhancers. By using a combination of DNase I footprinting, electrophoretic mobility shift assay, and site-specific mutations, four candidate protein binding sites have been identified at analogous positions in both enhancers. A mutation of any of these sites decreases enhancer activity. Two of the sites, lambda A and lambda B, are essential for enhancer function, and both of these sites appear to bind both B-cell-specific and general factors. Nevertheless, isolated lambda A and lambda B sites show no evidence of inherent transactivating potential, alone or together, even when present in up to three copies. We suggest that the generation of transactivating signals from these enhancers may require the complex interaction of multiple B-cell-specific and nonspecific DNA-binding factors.

Regulation and a possible stage-specific function of Oct-2 during pre-B-cell differentiation

The Oct-2 gene appears to encode a developmental regulator of immunoglobulin gene transcription. We demonstrate that the Oct-2 gene is expressed at low levels in a variety of transformed pre-B-cell lines and is induced specifically in these cells by lipopolysaccharide signalling. This work extends an earlier observation in the pre-B-cell line 70Z/3 and therefore suggests that the inducible expression of the Oct-2 gene, like that of the kappa gene, is a characteristic feature of the pre-B stage of B-cell development. In 70Z/3 cells, the lymphokine interleukin-1 also induces the expression of the Oct-2 and kappa loci. Interestingly, expression of the Oct-2 gene is rapidly induced at the transcriptional level and may not require de novo protein synthesis. Since the changes in the activity of the Oct-2 locus completely correlate with the changes of the activity of the kappa locus, the two genes may be transcriptionally regulated by a common trans-acting factor. In 70Z/3 cells, transforming growth factor beta, an inhibitor of kappa-gene induction, blocks the upregulation of Oct-2 but not the activation of NF-kappa B. These results suggest that the combinatorial action of increased levels of Oct-2 and activated NF-kappa B may be necessary for the proper stage-specific expression of the kappa locus.

Regulation and a possible stage-specific function of Oct-2 during pre-B-cell differentiation

The Oct-2 gene appears to encode a developmental regulator of immunoglobulin gene transcription. We demonstrate that the Oct-2 gene is expressed at low levels in a variety of transformed pre-B-cell lines and is induced specifically in these cells by lipopolysaccharide signalling. This work extends an earlier observation in the pre-B-cell line 70Z/3 and therefore suggests that the inducible expression of the Oct-2 gene, like that of the kappa gene, is a characteristic feature of the pre-B stage of B-cell development. In 70Z/3 cells, the lymphokine interleukin-1 also induces the expression of the Oct-2 and kappa loci. Interestingly, expression of the Oct-2 gene is rapidly induced at the transcriptional level and may not require de novo protein synthesis. Since the changes in the activity of the Oct-2 locus completely correlate with the changes of the activity of the kappa locus, the two genes may be transcriptionally regulated by a common trans-acting factor. In 70Z/3 cells, transforming growth factor beta, an inhibitor of kappa-gene induction, blocks the upregulation of Oct-2 but not the activation of NF-kappa B. These results suggest that the combinatorial action of increased levels of Oct-2 and activated NF-kappa B may be necessary for the proper stage-specific expression of the kappa locus.

Silencing of the expression of the immunoglobulin kappa gene in non-B cells

Although the activating factor NF-kappa B can be present in the nucleus of many cell types, transcription and rearrangement of the immunoglobulin kappa chain gene is restricted to cells of the B lineage. Part of this specificity is determined by sequences within the major intron of the kappa gene that specifically silence gene expression in non-B cells (T cells and HeLa cells). These sequences are found in a 232-bp fragment located 5' of the NF-kappa B binding sequence of the enhancer. When this fragment is added back upstream of an active NF-kappa B site, it specifically decreases the expression of a linked gene by more than 10-fold in activated T cells but it has no effect on expression in B cells. The kappa silencer region acts in an orientation- and distance-independent manner and appears to be composed of multiple negative elements. The kappa silencer may act to restrict transcription and rearrangement of the C kappa locus to cells of the B lineage.

Silencing of the expression of the immunoglobulin kappa gene in non-B cells

Although the activating factor NF-kappa B can be present in the nucleus of many cell types, transcription and rearrangement of the immunoglobulin kappa chain gene is restricted to cells of the B lineage. Part of this specificity is determined by sequences within the major intron of the kappa gene that specifically silence gene expression in non-B cells (T cells and HeLa cells). These sequences are found in a 232-bp fragment located 5' of the NF-kappa B binding sequence of the enhancer. When this fragment is added back upstream of an active NF-kappa B site, it specifically decreases the expression of a linked gene by more than 10-fold in activated T cells but it has no effect on expression in B cells. The kappa silencer region acts in an orientation- and distance-independent manner and appears to be composed of multiple negative elements. The kappa silencer may act to restrict transcription and rearrangement of the C kappa locus to cells of the B lineage.