Negative regulation contributes to tissue specificity of the immunoglobulin heavy-chain enhancer.

We have identified in and around the immunoglobulin heavy-chain enhancer two apparently distinct negative regulatory elements which repress immunoglobulin H enhancer, simian virus 40 enhancer, and heterologous promoter activity in fibroblasts but not in myeloma cells. We propose that in nonlymphoid cells, negative regulatory elements prevent activation of the immunoglobulin H enhancer by ubiquitous stimulatory trans-acting factors.     

Nuclear factors binding to the human immunoglobulin heavy-chain gene enhancer.

The human immunoglobulin heavy chain (IgH) gene contains at least two tissue-specific regulatory regions, which are similar to the mouse IgH gene. One is the J-C enhancer and another is located in the 5' promoter region. Using an electrophoretic mobility shift assay and DNase I footprint, we have examined the interaction of factors in B cell nuclear extracts with the two regulatory regions of the human IgH gene. We have identified a nuclear factor in mouse B cell nuclear extracts which bound to specific sequence in the human IgH enhancer. This factor is apparently not present in mouse fibroblast nuclear extracts. We also found factor(s) which bound to the highly conserved octanucleotide sequence within the human IgH enhancer and 5' promoter regions.     

Complex protein binding within the mouse immunoglobulin heavy-chain enhancer.

We have begun to purify and characterize several proteins which bind to the mouse immunoglobulin heavy-chain enhancer to understand the molecular interactions important for enhancer activity. Three proteins which bind to different sites on the immunoglobulin heavy-chain enhancer have been chromatographically separated and partially purified. One protein binds a site which has not been reported previously and does not bind to other reported protein-binding sites on the immunoglobulin heavy-chain enhancer. Binding-site boundaries for the three partially purified proteins have been precisely mapped by methylation interference, DNase I footprinting, and orthophenanthroline/copper chemical nuclease footprinting. We have also characterized these three proteins with respect to dissociation rate constants.     

Binding in vitro of multiple cellular proteins to immunoglobulin heavy-chain enhancer DNA.

Seven protein-binding sites on the immunoglobulin heavy-chain (IgH) enhancer element have been identified by exonuclease III protection and gel retardation assays. It appears that the seven sites bind a minimum of four separate proteins. Three of these proteins also bind to other enhancers or promoters, but one protein seems to recognize exclusively IgH enhancer sequences. A complex of four binding sites, recognized by different proteins, is located within one 80-base-pair region of IgH enhancer DNA. Close juxtaposition of enhancer proteins may allow protein-protein interactions or be part of a mechanism for modulating enhancer protein activity. All IgH enhancer-binding proteins identified in this study were found in extracts from nonlymphoid as well as lymphoid cells. These data provide the first direct evidence that multiple proteins bind to enhancer elements and that while some of these proteins recognize common elements of many enhancers, others have more limited specificities.     

Functional analysis of defined mutations in the immunoglobulin heavy-chain enhancer in transgenic mice.

We have analyzed the effect of defined mutations in the mouse immunoglobulin heavy-chain enhancer after introduction into the germline of transgenic mice. We have tested a mutation of the enhancer octamer motif, a double mutation of the octamer motif and the microB-site, and a triple mutation in the microE2, microE3 and microE4-sites. All constructs are expressed in the spleen of transgenic mice. Furthermore, expression is exclusively detectable in lymphoid organs and not in several nonlymphoid tissues. Whereas mutations in the microE-sites have a more pronounced effect on transgene activity in thymocytes as compared to bone marrow and spleen cells, the octamer/microB double mutation shows significantly reduced expression levels only in B-cells. Finally, our results demonstrate that the intronic heavy-chain enhancer element does not contribute to the increase steady state levels of heavy-chain mRNA after stimulation of spleen cells with LPS.     

Complex regulation of the immunoglobulin mu heavy-chain gene enhancer: microB, a new determinant of enhancer function.

The B-lymphocyte-specific activity of the immunoglobulin mu heavy-chain gene enhancer has been attributed to the octamer motif (ATTTGCAT) present within the enhancer that binds a B-cell-specific factor designated NF-A2/OTF-2. However, significant residual enhancer activity even after deletion of this element has suggested the presence of a second critical functional determinant. We have used deletion and mutational analyses to define an element, microB (TTTGGGGAA), that is essential for B-cell-specific enhancer activity in S194 myeloma cells in the absence of the octamer. Transfection analysis in a panel of lymphoid cell lines suggests that the presence of either microB or octamer leads to considerable enhancer activity in cell lines representing later stages of B-cell differentiation, whereas both elements are needed for function in cell lines representing earlier stages. Furthermore, in contrast to the results in pre-B-cell lines, both microB and octamer elements function independently in certain T-cell lines in which the mu enhancer is active.     

B-lymphocyte targeting of gene expression in transgenic mice with the immunoglobulin heavy-chain enhancer.

A hybrid gene containing rabbit beta-globin structural sequences (-9 to +1650), and a chicken conalbumin gene promoter (+62 to -102) in the place of the beta-globin promoter (upstream from -9), was inactive in 5 different transgenic mouse line. Adding the mouse immunoglobulin heavy-chain (IgH) enhancer to this construction specifically stimulated expression in B-cells. These results show that IgH enhancer is specifically active in B-cells. Expression of the hybrid gene was low compared to the endogenous immunoglobulin heavy and light-chain genes. Substituting the mouse immunoglobulin kappa light-chain gene (Ig kappa) promoter (+4 to -800) for the heterologous conalbumin promoter was not sufficient to restore gene expression to level of the endogenous genes. In addition to the reproducible B cell expression, we also found inheritable unexpected expression in certain tissues, which varied from line to line.     

Rearrangement of rat immunoglobulin E heavy-chain and c-myc genes in the B-cell immunocytoma IR162.

Mammalian B-cell lymphoid malignancies frequently display aberrant translocations involving the c-myc proto-oncogene and one of the immunoglobulin loci. We have observed and characterized such a translocation in the immunoglobulin E-producing rat immunocytoma IR162 by using recombinant DNA technology. We show here for the first time that a c-myc gene has recombined with the excluded allele of the nonfunctional epsilon heavy-chain immunoglobulin gene. This recombination has resulted in the loss of 5'-proximal DNA and, consequently, potential regulatory information from the body of the c-myc structural gene via joining to the epsilon heavy-chain switch region in a head-to-head, i.e., 5'-to-5', configuration. As discussed in this report, these results, together with the previous results of others, have important implications for immunoglobulin heavy-chain class switching mechanisms controlling normal and abnormal translocations.     

Proteins binding to site C2 (muE3) in the immunoglobulin heavy-chain enhancer exist in multiple oligomeric forms.

We describe the purification to near homogeneity of proteins binding to site C2 (muE3) in the immunoglobulin heavy-chain enhancer. Proteins binding to this site produce four protein-DNA complexes which are distinguished by their mobility in gel retardation assays and their elution properties in an anion exchange column. DNA affinity-purified preparations of three chromatographically separated pools, containing different subsets of the four complexes, each contained three polypeptides of 42.5, 44, and 45 kilodaltons (kDa). UV crosslinking of protein to enhancer DNA demonstrated that site C2-binding activities in the three different pools bound DNA through proteins of similar sizes (about 45 kDa), even though the protein-DNA complexes formed by these binding activities were quite distinct. Gel exclusion chromatography and equilibrium binding analyses indicated that the distinct protein-DNA complexes were due to different oligomeric forms of the individual subunits and that a larger multimeric form bound with high affinity to the heavy-chain enhancer site C2, while a smaller species had a much lower affinity for heavy-chain enhancer sequences. Purified protein has been used to map high-affinity binding sites for site C2-binding proteins within an immunoglobulin heavy-chain promoter and at site KE3 in the kappa light-chain enhancer.