The Ig kappa L chain allelic groups among the Ig kappa haplotypes and Ig kappa crossover populations suggest a gene order

The Ig kappa complex locus of inbred mice found on chromosome 6 contains one constant (C kappa), five joining (J kappa), and 100 to 300 variable (V kappa) exons and spans an estimated 500 to 2000 kbp of DNA. The V kappa exons are organized into groups of highly homologous coding regions (approximately 300 bp) separated by approximately 10 kbp of intervening sequence. A group contains from 1 to 30 or more exons (exon refers to uninterrupted coding region DNA which is capable of encoding all or part of V kappa gene) that can be detected with specific DNA probes in conjunction with restriction endonuclease fragments (REF) from genomic DNA. Thirteen DNA probes specific for different V kappa exon groups and one DNA probe specific for J kappa and C kappa exons were used in conjunction with 55 inbred strains in an attempt to detect RFLP that could be used to establish Ig kappa allelic groups and Ig kappa haplotypes. Each probe detected two to four different REF patterns (allelic groups) among the panel of inbred mice examined. Size estimates of the REF were made, and each probe detected 4.2 to 107.7 kbp of DNA, including faint REF, 675.6 to 723.6 kbp of DNA could be detected within a single haplotype. Based on these allelic groups, seven haplotypes were identified among the 55 inbred strains of mice. No subline differences were detected, and the distribution of allelic groups implied common ancestry among many of the inbred strains examined. The DNA probes were also used in conjunction with recombinant inbred, congenic strains and backcross populations of mice. By using the analysis of known Ig kappa r populations, and assuming a common ancestry among the inbred strains, a gene order was predicted: Centromere-Hd-(Ig kappa-V11, Ig kappa-V24, Ig kappa-V9-26)-(Ig kappa-V1, Ig kappa-V9)-(Ig kappa-V4, Ig kappa-V8, Ig kappa-V10, Ig kappa-V12, 13, Ig kappa-V19)-(Ig kappa-V28, Rn7s-6)-Ig kappa-V23-(Ig kappa-V21, Ig kappa-J, Ig kappa-C)-(Ly2, Ly3)-wa-1.     

Mice triallelic for the Ig heavy chain locus: implications for VHDJH recombination

V(H)DJ(H) recombination has been extensively studied in mice carrying an Ig heavy chain rearranged transgene. In most models, inhibition of endogenous Ig rearrangement occurs, consistently with the feedback model of IgH recombination. Nonetheless, an incomplete IgH allelic exclusion is a recurrent observation in these animals. Furthermore, transgene expression in ontogeny is likely to start before somatic recombination, thus limiting the use of Ig-transgenic mice to access the dynamics of V(H)DJ(H) recombination. As an alternative approach, we challenged the regulation of somatic recombination with the introduction of an extra IgH locus in germline configuration. This was achieved by reconstitution of RAG2(-/-) mice with fetal liver cells trisomic for chromosome 12 (Ts12). We found that all three alleles can recombine and that the ratio of Ig allotype-expressing B cells follows the allotypic ratio in trisomic cells. Although these cells are able to rearrange the three alleles, the levels of Ig phenotypic allelic exclusion are not altered when compared with euploid cells. Likewise, we find that most VDJ rearrangements of the silenced allele are unable to encode a functional mu-chain, indicating that the majority of these cells are also genetically excluded. These results provide additional support for the feedback model of allelic exclusion.     

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.     

Unraveling the consecutive recombination events in the human IGK locus

In addition to the classical Vkappa-Jkappa, Vkappa-kappa deleting element (Kde), and intron-Kde gene rearrangements, atypical recombinations involving Jkappa recombination signal sequence (RSS) or intronRSS elements can occur in the Igkappa (IGK) locus, as observed in human B cell malignancies. In-depth analysis revealed that atypical JkappaRSS-intronRSS, Vkappa-intronRSS, and JkappaRSS-Kde recombinations not only occur in B cell malignancies, but rather reflect physiological gene rearrangements present in normal human B cells as well. Excision circle analysis and recombination substrate assays can discriminate between single-step vs multistep rearrangements. Using this combined approach, we unraveled that the atypical Vkappa-intronRSS and JkappaRSS-Kde pseudohybrid joints most probably result from ongoing recombination following an initial aberrant JkappaRSS-intronRSS signal joint formation. Based on our observations in normal and malignant human B cells, a model is presented to describe the sequential (classical and atypical) recombination events in the human IGK locus and their estimated relative frequencies (0.2-1.0 vs < 0.03). The initial JkappaRSS-intronRSS signal joint formation (except for Jkappa1RSS-intronRSS) might be a side event of an active V(D)J recombination mechanism, but the subsequent formation of Vkappa-intronRSS and JkappaRSS-Kde pseudohybrid joints can represent an alternative pathway for IGK allele inactivation and allelic exclusion, in addition to classical Ckappa deletions. Although usage of this alternative pathway is limited, it seems essential for inactivation of those IGK alleles that have undergone initial aberrant recombinations, which might otherwise hamper selection of functional Ig L chain proteins.     

The V-J-intergenic region of the human kappa locus

The 23-kb region between the V kappa and J kappa gene clusters was investigated in some detail. The region was found to be free of V kappa genes or V kappa gene-like structures, confirming the previous supposition that the V kappa gene B3 is the J kappa proximal V kappa gene. The B3-J kappa distance of 23 kb was found to be the same in the DNAs of several individuals. A HindIII restriction fragment length polymorphism was detected within this region. A sequence of 533 bp located approximately in the middle of the region has a highly homologous counterpart (called homox) on another chromosome. The two sequences are 96% identical. Possible mechanisms for the generation of such a duplicate are discussed.     

The human lambda L chain Ig locus. Recharacterization of JC lambda 6 and identification of a functional JC lambda 7

The human lambda L chain Ig gene complex consists of multiple JC gene segments. A seventh human lambda C region gene segment, C lambda 7, was found 2.7 kb downstream of C lambda 6 in this gene complex. A J lambda gene segment, J lambda 7, was found 1.2 kb upstream of C lambda 7 and contains potentially functional nonamer and heptamer recombination sites, an RNA splice site and J coding region. C lambda 7 maintains an open reading frame and encodes a new lambda isotype. C lambda 7 encodes Kern+ and Oz- determinants, but does not encode any of the Kern+Oz- myeloma proteins published to date. Nevertheless, we present evidence that JC lambda 7 is transcribed in normal lymphocytes and is functional. In contrast, we present new data that the C lambda 6 gene segment, reported by others to encode the Kern+Oz- protein, is non-functional due to a 4-bp insertion in our cosmid clone. The 4-bp insertion was characterized further in 32 genomic DNA samples by producing a distinctive restriction fragment length and verified by the DNA sequences of the polymerase chain reaction products of two different cell lines. We discuss the possibility that the Kern+Oz- myeloma proteins do not define an isotype and are not encoded by JC lambda 7 nor other non-allelic genes, and we discuss the level of expression of JC lamba 7 as compared to that of JC lambda 2 and JC lambda 3.     

Burkitt lymphoma cell lines are prone to recombination in the switch region of the Ig mu heavy chain locus

Different recombinations have been found at the Ig heavy chain gene loci in a number of sublines of the Burkitt lymphoma (BL) cell line Namalwa, following prolonged in vitro culture. The Namalwa sublines examined are DNA fingerprint-identical and derived from a monoclonal source. Recombinant DNA clones were used to map the Ig heavy chain gene mutations to a region between the VDJ and C mu segment of the locus. This region is associated with Ig heavy chain class switching in normal B cells. Of 24 clones established from one subline, three were found to have additional VDJ-C mu region mutations, indicating a high frequency of mutation at this locus.     

Differential accessibility at the kappa chain locus plays a role in allelic exclusion

Gene rearrangement in the immune system is always preceded by DNA demethylation and increased chromatin accessibility. Using a model system in which rearrangement of the endogenous immunoglobulin kappa locus is prevented, we demonstrate that these epigenetic and chromatin changes actually occur on one allele with a higher probability than the other. It may be this process that, together with feedback inhibition, serves as the basis for allelic exclusion.     

Block in development at the pre-B-II to immature B cell stage in mice without Ig kappa and Ig lambda light chain

Silencing individual C (constant region) lambda genes in a kappa(-/-) background reduces mature B cell levels, and L chain-deficient (lambda(-/-)kappa(-/-)) mice attain a complete block in B cell development at the stage when L chain rearrangement, resulting in surface IgM expression, should be completed. L chain deficiency prevents B cell receptor association, and L chain function cannot be substituted (e.g., by surrogate L chain). Nevertheless, precursor cell levels, controlled by developmental progression and checkpoint apoptosis, are maintained, and B cell development in the bone marrow is fully retained up to the immature stage. L chain deficiency allows H chain retention in the cytoplasm, but prevents H chain release from the cell, and as a result secondary lymphoid organs are B cell depleted while T cell levels remain normal.     

Gene targeting in the Ig kappa locus: efficient generation of lambda chain-expressing B cells, independent of gene rearrangements in Ig kappa.

The production of lambda chain-expressing B cells was studied in mice in which either the gene encoding the constant region of the kappa chain (C kappa) or the intron enhancer in the Ig kappa locus was inactivated by insertion of a neomycin resistance gene. The two mutants have similar phenotypes: in heterozygous mutant mice the fraction of lambda chain-bearing B cells is twice that in the wildtype. Homozygous mutants produce approximately 7 times more lambda-expressing B cells (and about 2.3 times fewer total B cells) in the bone marrow than their normal counterparts, suggesting that B cell progenitors can differentiate into either kappa- or lambda-producing cells and do the latter in the mutants. Whereas gene rearrangements in the Ig kappa locus are blocked in the case of enhancer inactivation, they still occur in that of the C kappa mutant, although in this mutant RS rearrangement is lower than in the wildtype. This indicates that gene rearrangements in the Ig lambda locus can occur in the absence of a putative positive signal resulting from gene rearrangements in Ig kappa, including RS recombination. Complementing these results, we also present data indicating that in normal B cell development kappa chain rearrangement can be preceded by lambda chain rearrangement and that the frequency of kappa/lambda double producers is small and insufficient to explain the massive production of lambda chain-expressing B cells in the mutants.     

Chromatin opening is tightly linked to enhancer activation at the kappa light chain locus

Enhancers play an important role in chromatin opening but the temporal relationship between enhancer activation and the generation of an accessible chromatin structure is poorly defined. Recombination enhancers are essential for chromatin opening and subsequent V(D)J recombination at immunoglobulin loci. In mice, the kappa light chain locus displays an open chromatin structure before the lambda locus yet the same proteins, PU.1/PIP, trigger full enhancer activation of both loci. Using primary B cells isolated from distinct developmental stages and an improved method to quantitatively determine hypersensitive site formation, we find the kappa and lambda recombination enhancers become fully hypersensitive soon after transition to large and small pre-B-II cells, respectively. This correlates strictly with the stages at which these loci are activated. Since these cells are short-lived, these data imply that there is a close temporal relationship between full enhancer hypersensitive site formation and locus chromatin opening.     

The role of rearrangement at the second Ig heavy chain locus in maintaining B cell tolerance to DNA

In recently generated B6.56R anti-DNA autoantibody-transgenic mice, it was noted that a substantial fraction of the B cells that had avoided DNA reactivity had done so through the rearrangement and usage of the endogenous, nontargeted H chain (HC) allele. This suggested that rearrangement at the second HC locus might be an important mechanism through which self-reactive B cells might successfully revise their initial Ag specificity. To test the importance of this mechanism in B cell tolerance, we generated B6.56R/56R mice that possessed the 56R anti-DNA H chain transgene inserted into both HC loci. These transgenic homozygotes developed higher titers of anti-DNA Abs, with an expanded population of B220(low)MHC class II(low) B cells, enriched for CD21(low)CD23(low) preplasmablasts. The analysis of hybridomas from these mice revealed that the only avenue by which these B cells could avoid DNA reactivity was through the use of the editor L chains, V(k)20 or V(k)21. Hence, in addition to LC editing, rearrangement and usage of the second HC locus/allele constitutes an important safety valve for B cells the primary BCR of which confers DNA reactivity. In contrast to these tolerance mechanisms, editing the first rearranged HC locus (through HC replacement) and somatic mutations appear to be less frequently used to edit/revise self-reactive B cells.     

Targeted disruption of the porcine immunoglobulin kappa light chain locus

Inactivation of the endogenous pig immunoglobulin (Ig) loci, and replacement with their human counterparts, would produce animals that could alleviate both the supply and specificity issues of therapeutic human polyclonal antibodies (PAbs). Platform genetics are being developed in pigs that have all endogenous Ig loci inactivated and replaced by human counterparts, in order to address this unmet clinical need. This report describes the deletion of the porcine kappa (??) light chain constant (C??) region in pig primary fetal fibroblasts (PPFFs) using gene targeting technology, and the generation of live animals from these cells via somatic cell nuclear transfer (SCNT) cloning. There are only two other targeted loci previously published in swine, and this is the first report of a targeted disruption of an Ig light chain locus in a livestock species. Pigs with one targeted C?? allele (heterozygous knockout or ±) were bred together to generate C?? homozygous knockout (?/?) animals. Peripheral blood mononuclear cells (PBMCs) and mesenteric lymph nodes (MLNs) from C?? ?/? pigs were devoid of ??-containing Igs. Furthermore, there was an increase in lambda (??) light chain expression when compared to that of wild-type littermates (C?? +/+). Targeted inactivation of the Ig heavy chain locus has also been achieved and work is underway to inactivate the pig lambda light chain locus.