2,3,7,8-tetrachlorodibenzo-p-dioxin induces transcriptional activity of the human polymorphic hs1,2 enhancer of the 3'Igh regulatory region

2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) is an environmental toxicant known to inhibit Ab secretion and Ig expression. Inhibition of Ig expression may be partially mediated through repression of the 3'Igh regulatory region (3'IghRR). TCDD inhibits mouse 3'IghRR activation and induces aryl hydrocarbon receptor binding to dioxin response elements within the 3'IghRR enhancers hs1,2 and hs4. The human hs1,2 enhancer (hu-hs1,2) is polymorphic as the result of the presence of one to four invariant sequences (ISs), which have been correlated with several autoimmune diseases. The IS also contains a dioxin response element core motif. Therefore, the objective was to determine whether hu-hs1,2 activity is sensitive to TCDD. Using a mouse B cell line (CH12.LX), we compared the effects of TCDD on mouse hs1,2 versus hu-hs1,2 activity. TCDD inhibited mouse hs1,2 similarly to the mouse 3'IghRR. In contrast, hu-hs1,2 was activated by TCDD, and antagonist studies supported an aryl hydrocarbon receptor-dependent activation, which was replicated in a human B cell line (IM-9). Absence of Pax5 binding sites is a major difference between the human and mouse hs1,2 sequence. Insertion of the high-affinity Pax5 site in hu-hs1,2 markedly blunted reporter activity but did not alter TCDD's effect (i.e., no shift from activation to inhibition). Additionally, deletional analysis demonstrated a significant IS contribution to hu-hs1,2 basal activity, but TCDD-induced activity was not strictly IS number dependent. Taken together, our results suggest that hu-hs1,2 is a significant target of TCDD and support species differences in hs1,2 regulation. Therefore, sensitivity of hu-hs1,2 to chemical-induced modulation may influence the occurrence and/or severity of human diseases associated with hu-hs1,2.     

Homologous elements hs3a and hs3b in the 3' regulatory region of the murine immunoglobulin heavy chain (Igh) locus are both dispensable for class-switch recombination

Immunoglobulin heavy chain (IgH) genes are formed, tested, and modified to yield diverse, specific, and high affinity antibody responses to antigen. The processes involved must be regulated, however, to avoid unintended damage to chromosomes. The 3' regulatory region of the Igh locus plays a major role in regulating class-switch recombination (CSR), the process by which antibody effector functions are modified during an immune response. Loss of all known enhancer-like elements in this region dramatically impairs CSR, but individual element deletions have no effect on this process. In the present study, we explored the hypothesis that an underlying functional redundancy in the homologous elements hs3a and hs3b was masking the importance of either element to CSR. Several transgenic mouse lines were generated, each carrying a bacterial artificial chromosome transgene that mimicked Igh locus structure but in which hs3a was missing and hs3b was flanked by loxP sites. Matings to Cyclization Recombination Enzyme-expressing mice established "pairs" of lines that differed only in the presence or absence of hs3b. Remarkably, CSR remained robust in the absence of both hs3a and hs3b, suggesting that the remaining two elements of the 3' regulatory region, hs1.2 and hs4, although individually dispensable for CSR, are, together, sufficient to support CSR.     

Identification of enhancer sequences 3' of the rabbit Ig kappa L chain loci

The rabbit is useful for studies of Ig L chain gene expression because of a great disparity in expression of two isotypic forms of the kappa L chain. Normally, K1 is expressed at high levels and K2 is almost silent; expression of K2 increases in mutant or experimentally allotype-suppressed animals. The reasons for the preferential utilization of the K1 isotype have not been fully elucidated. We were interested in looking for second enhancers 3' of the C kappa genes because the absence of a 3' enhancer in the K2 locus could explain the preferential utilization of the K1 isotype. However, we found a strong region of enhancer activity about 7 kb downstream of the C kappa 2 gene. Sequences in this region are highly conserved between rabbit, man, and mouse. There also appears to be a homologous 3' enhancer region in the rabbit K1 locus. We also confirmed earlier reports that the rabbit K1 intron enhancer is inactive in transient transfections into mouse B cells but find that the same construct has low but significant activity in a human B cell line. In a comparable construct the K2 intron enhancer is without activity suggesting possible differential activity of the intronic enhancers.     

IgM receptor-mediated transactivation of the IgH 3' enhancer couples a novel Elf-1-AP-1 protein complex to the developmental control of enhancer function.

The function of the temporally regulated B lymphocyte-specific immunoglobulin heavy chain (IgH) 3' enhancer has been linked to the IgH class switch machinery, but the physiological mechanism(s) of activation has not been discerned. Following crosslinking of the IgM receptor, we demonstrate that the enhancer is transactivated in the B lymphoma cell line BAL-17. In both induced primary B lymphocytes and BAL-17 cells, the enhancer activation is concomitant with the recruitment of a novel DNA binding complex, nuclear factor of activated B cells (NFAB). NFAB contains the tissue-restricted Ets protein Elf-1 and the AP-1 factors Jun-B and c-Fos, which bind to a novel 3' enhancer ETS-AP-1 motif. IgM receptor-mediated activation or stimulation by phorbol-ester in BAL-17 cells demonstrates that the ETS-AP-1 motif, when linked to a heterologous gene, can confer a ligand/receptor-dependent response. In NIH 3T3 cells, Elf-1 expression is required for efficient ETS-AP-1 promoter activity in response to stimulation by 12-O-tetradecanylphorbol 13-acetate. Our results suggest a biological role for Elf-1 in the regulation of IgH gene expression, attribute a functional role for receptor-induced AP-1 proteins in B lymphocytes and provide evidence for a direct link between IgM receptor-mediated signalling and 3' enhancer activation.     

Analysis of the 3' Cmu region of the rabbit Ig heavy chain locus

The immunoglobulin D (IgD) antibody class was, for many years, identified only in primates, rodents and teleost fish. The limited distribution of IgD among vertebrates suggested that IgD is a functionally redundant antibody class that has been lost by many vertebrate species during evolution. The recent identification of IgD in artiodactyls, however, suggests that IgD might be more widely expressed among vertebrates than previously thought, possibly serving a unique role in immunity. IgD expression has been searched for but not detected in rabbits. In order to search directly for a rabbit Cdelta locus encoding the constant region of IgD, we determined the nucleotide sequence of 13.5 kb of genomic DNA downstream of the rabbit Cmu locus. We did not find a rabbit Cdelta locus in this region, but found instead that this region is densely populated by repetitive elements, including a long interspersed DNA element repeat, six C repeats, and two processed pseudogenes. We conclude that the rabbit probably does not express IgD because there is no Cdelta locus immediately downstream of the rabbit Cmu locus.     

Germline deletion of Igh 3' regulatory region elements hs 5, 6, 7 (hs5-7) affects B cell-specific regulation, rearrangement, and insulation of the Igh locus

Regulatory elements located within an ～28-kb region 3' of the Igh gene cluster (3' regulatory region) are required for class switch recombination and for high levels of IgH expression in plasma cells. We previously defined novel DNase I hypersensitive sites (hs) 5, 6, 7 immediately downstream of this region. The hs 5-7 region (hs5-7) contains a high density of binding sites for CCCTC-binding factor (CTCF), a zinc finger protein associated with mammalian insulator activity, and is an anchor for interactions with CTCF sites flanking the D(H) region. To test the function of hs5-7, we generated mice with an 8-kb deletion encompassing all three hs elements. B cells from hs5-7 knockout (KO) (hs5-7KO) mice showed a modest increase in expression of the nearest downstream gene. In addition, Igh alleles in hs5-7KO mice were in a less contracted configuration compared with wild-type Igh alleles and showed a 2-fold increase in the usage of proximal V(H)7183 gene families. Hs5-7KO mice were essentially indistinguishable from wild-type mice in B cell development, allelic regulation, class switch recombination, and chromosomal looping. We conclude that hs5-7, a high-density CTCF-binding region at the 3' end of the Igh locus, impacts usage of V(H) regions as far as 500 kb away.