Rearranged and germline immunoglobulin kappa genes: different states of DNase I sensitivity of constant kappa genes in immunocompetent and nonimmune cells

The rearrangement of a variable (V) and a constant (C) gene appears to be a necessary prerequisite for immunoglobulin gene expression. Multiple different rearranged kappa genes were found in several mouse myelomas, although these cells produce only one type of kappa chain [Wilson, R., Miller, J., & Storb, U. (1979) Biochemistry 18, 5013--5021]. It is therefore of interest to understand how only one allele within a lymphoid cell becomes expressed, while the other allele remains nonfunctional ("allelic exclusion"). We have studied the chromatin conformation of kappa genes by making use of the preferential digestion of potentially active genes by DNase I described, for example, for globin genes [Weintraub, H., & Groudine, M. (1976) Science (Washington, D.C.) 193, 848--856]. The DNase I sensitivity of kappa genes in myeloma tumors, in a B cell lymphoma, and in liver was determined by hybridization with DNA on Southern blots. It was found that rearranged C kappa genes are DNase I sensitive in myelomas in which several kappa genes are rearranged, regardless of whether the rearranged genes code for the kappa chains synthesized by the cell. Furthermore, the C kappa gene in germline configuration is also DNase I sensitive in a B cell lymphoma; i.e., it is in the same chromatin state as the rearranged C kappa gene which probably codes for the kappa chains produced by the cell. The altered chromatin state appears to be localized: V kappa genes in germline context are not DNase I sensitive in myeloma or B lymphoma cells while C kappa genes present in a kappa gene cluster on the same chromosomes are sensitive. When rearranged, however, the V kappa genes are as sensitive to DNase I as are rearranged C kappa genes. V lambda and C lambda genes are not DNase I sensitive in kappa myelomas. Thus, commitment to kappa gene expression is apparently correlated with a chromatin conformation which confers increased DNase I sensitivity to the DNA in the vicinity of all C kappa genes in the cell. "Allelic exclusion" does not operate on the level of chromatin conformation which can be detected by altered DNase I sensitivity.     

Mapping of immunoglobulin variable region genes: relationship to the ''deletion'' model of immunoglobulin gene rearrangement

Five families of variable region genes of mouse kappa chains were analyzed by Southern blot hybridization to determine their relative chromosomal map positions. Map positions were deduced by Vk gene deletion from antibody-producing cells expressing upstream Vk genes and retention in cells expressing downstream genes. The Vk regions expressed in the myelomas M0PC167, MPC11, M0PC21 and ABPC20 are members of Vk families exhibiting one, three, six and six major germline hybridization bands respectively. The gene order of the five families in germline DNA was found to be VM167-VM11-(VM21, VA20)-VABE8-Jk-Ck. As expected in a deletion model of immunoglobulin gene rearrangement, a sequence located just 5' of J1 in germline DNA was found to be absent from some antibody producing cells which had not retained any germline Ck genes. However, other cell lines contained this sequence in rearranged contexts, suggesting that any deletion model of immunoglobulin V-J joining, as well as V gene mapping, must take into account the possibilities of stepwise rearrangements and reintegration of "deleted" DNA.     

Relationship between the rearrangement of immunoglobulin genes, the appearance of a B lymphocyte antigen, and immunoglobulin synthesis in murine pre-B cell lines

Eighteen Abelson virus-transformed immature B cell lines were established and immunoglobulin biosynthesis, expression of a B lymphocyte antigen detected by a monoclonal antibody, and rearrangement of immunoglobulin genes in these cell lines were studied. Only one cell line (A1) synthesized micro-chains but no light chains, and the other cell lines synthesized no detectable immunoglobulins. None of the cell lines established had detectable membrane-associated IgM. Fifteen cell lines expressed a B lymphocyte antigen on their cell surfaces. In three cell lines, however, the majority (greater than 99%) of cells did not express this antigen. Heavy chain genes were rearranged on both chromosomes in all the cell lines, although one heavy chain gene was deleted in three cell lines. In 12 of 18 cell lines, one or both kappa-chain genes were rearranged. In six cell lines, however, both kappa-chain genes remained in embryonic form; lambda-chain genes were in embryonic form in all the cell lines. These results suggested the hierarchy of Ig gene rearrangements, beginning with mu and proceeding to kappa and then to lambda. JH rearrangement was also shown to precede the appearance of a B lymphocyte antigen. In three cell lines (A1-A3), which were considered subclones derived from a single common precursor, it was suggested that one rearranged JH gene was functional, and the other was nonfunctional, indicating that allelic exclusion already operated in pre-B cells.     

Isolation of messenger RNA for an immunoglobulin kappa chain and enumeration of the genes for the constatn region of kappa chain in the mouse

The messenger RNA for an immunoglobulin light (kappa) chain was isolated from the mouse myeloma MOPC41 and shown to be almost twofold longer than necessary to code for its protein product. DNA complementary to the mRNA was synthesized with the RNA-directed DNA polymerase of Rous sarcoma virus. Although the individual chains of the cDNA² contained an average of only 270 nucleotides, the cDNA was heterogeneous in molecular weight, allowing the isolation of a fraction of the cDNA 620 nucleotides long. This large cDNA would be long enough to code for nearly all (95%) of the constant region if all the untranslated region of the mRNA were between the 3′ terminal poly(A) and the constant region. On the other hand, if all the untranslated region of the mRNA were at the 5′ terminus, this cDNA would code for 93% of the entire kappa chain.The specificity of nucleotide sequences in the cDNA was documented by molecular hybridization with both template RNA and RNA from various myelomas. The amount of hybridization obtained with myeloma RNA was approximately proportional to the amount of kappa chain protein produced by the various myeloma cells. In addition, there was no hybridization with RNA isolated from either BALB/c mouse liver or Escherichia coli.The genes for the constant region of the kappa chain were enumerated in the mouse genome by annealing cDNA to DNA from mouse liver and MOPC41 myeloma. The haploid genome of both tissues contained three to four genes for the constant region of kappa chain even when tested under conditions that would detect distantly related nucleotide sequences. The fact that there are only a few genes coding for the constant region of kappa chains implies that specialized genetic mechanisms are required for the generation of antibody diversity.     

Activity of multiple light chain genes in murine myeloma cells producing a single, functional light chain

Two cloned lambda 1-producing myelomas (HOPC-1, MOPC-104E) contain rearranged kappa genes and levels of mature-sized kappa RNA comparable to those found in kappa-producing myeloma cells. Another lambda 1-producing myeloma tumor line (HOPC-2020) and a lambda 1-containing B cell leukemia line (BCL1) also contain significant levels of kappa RNA. One lambda 11-producing line (MOPC-315) contains no detectable kappa RNA, but it also has no kappa genes in the embryonic configuration. kappa-related proteins are not detectable in the lambda 1-producing lines by standard procedures, but by sensitive methods at least two lines contain kappa protein fragments. The MOPC-104E line produces both a 14.5K kappa fragment that is not readily detectable because of its low rate of synthesis and short half-life (T 1/2 less than 5 min), and a major 16.5K protein that lacks kappa cross reactivity but is demonstrable by translation of purified MOPC-104E kappa RNA. The HOPC-1 kappa RNA also encodes a short-lived 14K kappa fragment. The MPC-11 line, which produces a mature kappa RNA and protein as well as an 800 base kappa fragment RNA and kappa protein fragment, has both kappa alleles rearranged, one apparently aberrantly between J and C kappa. Two different kappa RNA species, one the same size as the MPC-11 kappa fragment RNA, frequently are present in kappa RNA-containing Abelson murine leukemia virus-transformed lymphoid cells as well as in 18 and 19 day murine fetal liver. For light chains, neither allelic nor isotype exclusion is generally evident in myeloma and lymphoma cells; rather both produce only a single functional light chain. Models of light chain activation must explain restriction by considering the functional properties of the light chain rather than light chain gene expression.     

Deletion of the immunoglobulin kappa chain intron enhancer abolishes kappa chain gene rearrangement in cis but not lambda chain gene rearrangement in trans.

Immunoglobulins (Ig) secreted from a plasma cell contain either kappa or lambda light chains, but not both. This phenomenon is termed isotypic kappa-lambda exclusion. While kappa-producing cells have their lambda chain genes in germline configuration, in most lambda-producing cells the kappa chain genes are either non-productively rearranged or deleted. To investigate the molecular mechanism for isotypic kappa-lambda exclusion, in particular the role of the Ig kappa intron enhancer, we replaced this enhancer by a neomycin resistance (neoR) gene in embryonic stem (ES) cells. B cells heterozygous for the mutation undergo V kappa-J kappa recombination exclusively in the intact Ig kappa locus but not in the mutated Ig kappa locus. Homozygous mutant mice exhibited no rearrangements in their Ig kappa loci. However, splenic B cell numbers were only slightly reduced as compared with the wild-type, and all B cells expressed lambda chain bearing surface Ig. These findings demonstrate that rearrangement in the Ig kappa locus is not essential for lambda gene rearrangement. We also generated homozygous mutant mice in which the neoR gene was inserted at the 3' end of the Ig kappa intron enhancer. Unexpectedly, mere insertion of the neoR gene showed some suppressive effect on V kappa-J kappa recombination. However, the much more pronounced inhibition of V kappa-J kappa recombination by the replacement of the Ig kappa intron enhancer suggests that this enhancer is essential for V kappa-J kappa recombination.     

Induced kappa receptor editing shows no allelic preference in a mouse pre-B cell line

B cell Ag receptor editing is a process that can change kappa antigen recognition specificity of a B cell receptor through secondary gene rearrangements on the same allele. In this study we used a model mouse pre-B cell line (38B9) to examine factors that might affect allelic targeting of secondary rearrangements of the kappa locus. We isolated clones that showed both productive and nonproductive rearrangements of one kappa allele, while retaining the other kappa allele in the germline configuration (kappa(+)/kappa degrees or kappa(-)/kappa degrees ). In the absence of any selective pressures, subsequent rearrangement of the germline alleles occurred at the same frequency as secondary rearrangement of the productive or nonproductive rearranged alleles. Because 38B9 cells lack Ig heavy chains, we stably expressed mu heavy chain protein in 38B9 cells to determine whether heavy-light pairing might affect allelic targeting of secondary kappa rearrangements. Although the expression of heavy chain was found to both pair with and stabilize kappa protein in these cells, it had no effect on preferential targeting Vkappa-Jkappa receptor editing compared with rearrangement of a germline allele. These studies suggest that in the absence of selection to eliminate autoreactive Vkappa-Jkappa genes, there is no allelic preference for secondary rearrangement events in 38B9 cells.     

Deletion of the κ genes from mouse hybridomas established with NS-1 myelomas

Monoclonal antibodies (mAbs) of the IgG class produced by mouse hybridomas raised with NS-1 myelomas have been shown to contain two types of immunoglobulin light (κ) chains derived from the myelomas and antigen-stimulated spleen lymphocytes, and the hybridomas produce three mAb species with light chain heterogeneity (Abe and Inouye, 1993). In the present study, 9 hybridoma lines secreting homogeneous mAbs have been isolated from 63 lines cloned from an established hybridoma line producing three mAbs. They secrete homogeneous mAbs containing light chains derived from either myeloma or spleen cells. They contain either κ gene derived from the respective cells, and the other gene was deleted during the cultivation. The deletion frequency of the κ gene of myelomas is 3 times higher than that of spleen cells, although 80–85% of hybridomas reach the stable state containing both κ genes. This revised version was published online in July 2006 with corrections to the Cover Date.     

Immunologic memory to phosphocholine. V. Hybridomas representative of group II antibodies utilize V kappa 1-3 gene(s)

The anti-phosphocholine (PC) memory response of BALB/c mice to PC-KLH contains two groups of antibodies distinguished by fine specificity and by expression of the T15 idiotype that dominates Group I but not Group II anti-PC antibodies. The contribution of V kappa genes to this diversity was investigated by the analysis of L chains from PC-binding hybridoma proteins (PCBHP) representative of Group I and Group II. N-terminal amino acid sequence analysis was performed on the L chains of three independently derived Group II PCBHP up to residue 23 (PCG1-1) or 21 (aPC-111-1 and aPC-12-3). These three sequences differed from each other by only one or two residues, but differed by approximately 50% from the L chains of the Group I-like PC-binding myeloma proteins (PCBMP); the Group II sequences are closely related to V kappa 1-3. Isoelectric focusing analysis was also performed on the L chain of PCG1-1, as well as on L chains from PCBHP typical of Group I antibodies, and from an atypical PCBHP differing from Groups I and II in fine specificity. A Group I PCBHP and the atypical PCBHP expressed L chains related to V kappa 8 and V kappa 24, respectively. The L chains of another Group I PCBHP and of the Group II protein, PCG1-1, appeared different from those found in the PCBMP and from each other. The results indicate a more diverse expression of L chains in the memory anti-PC response than is represented by the PCBMP; both V kappa 8- and V kappa 24-derived L chains (and, presumably, somatic variants), as well as products of additional V kappa genes (V kappa 1-3), appear to be present in the anti-PC memory pool.     

The structural repertoire of the human V kappa domain.

In humans, the gene for the V kappa domain is produced by the recombination of one of 40 functional V kappa segments and one of five functional J kappa segments. We have analysed the sequences of these germline segments and of 736 rearranged V kappa genes to determine the repertoire of main chain conformations, or canonical structures, they encode. Over 96% of the sequences correspond to one of four canonical structures for the first antigen binding loop (L1) and one canonical structure for the second antigen binding loop (L2). Junctional diversity produces some variation in the length of the third antigen binding loop (L3) and in the identity of residues at the V kappa-J kappa join. However, this is limited and 70% of the rearranged sequences correspond to one of three known canonical structures for the L3 region. Furthermore, we show that the canonical structures selected during the primary response are conserved during affinity maturation: the key residues that determine the conformations of the antigen binding loops are unmutated or undergo conservative mutation. The implications of these results for immune recognition are discussed.     

Evolution of a multigene family of V kappa germ line genes

We have isolated a series of related V kappa germ line genes from a BALB/c sperm DNA library. DNA sequence analysis of four members of this V kappa 24 multigene family implies that three V kappa genes are functional whereas the fourth one (psi V kappa 24) is a pseudogene. The prototype gene (V kappa 24) encodes the variable region gene segment expressed in an immune response against phosphorylcholine. The other two functional genes (V kappa 24A and V kappa 24B) may be expressed against streptococcal group A carbohydrate. The time of divergence of the four genes was estimated by the rate of synonymous nucleotide changes. This implies that an ancestral gene has duplicated approximately 33-35 million years ago and a subsequent gene duplication event has occurred approximately 23 million years ago.     

Immunoglobulin kappa light chain gene promoter and enhancer are not responsible for B-cell restricted gene rearrangement.

We have produced transgenic mice which synthesize chimeric mouse-rabbit immunoglobulin (Ig) kappa light chains following in vivo recombination of an injected unrearranged kappa gene. The exogenous gene construct contained a mouse germ-line kappa variable (V kappa) gene segment, the mouse germ-line joining (J kappa) locus including the enhancer, and the rabbit b9 constant (C kappa) region. A high level of V-J recombination of the kappa transgene was observed in spleen of the transgenic mice. Surprisingly, a particularly high degree of variability in the exact site of recombination and the presence of non germ-line encoded nucleotides (N-regions) were found at the V-J junction of the rearranged kappa transgene. Furthermore, unlike endogenous kappa genes, rearrangement of the exogenous gene occurred in T-cells of the transgenic mice. These results show that additional sequences, other than the heptamer-nonamer signal sequences and the promoter and enhancer elements, are required to obtain stage- and lineage- specific regulation of Ig kappa light chain gene rearrangement in vivo.     

A double monoclonal IgG1 kappa and IgG2 kappa in a single myeloma patient. Variation in clonal products and therapeutic responses

Two electrophoretically homogeneous immunoglobulins were detected in the serum of a patient with multiple myeloma. The heavy chains were of different classes (gamma 1 and gamma 2). The light chains of both were kappa, but had different electrophoretic mobilities on polyacrylamide gels. Amino acid sequence analysis, carbohydrate determinations, and biosynthetic experiments indicated that the difference seen in their electrophoretic mobility was due to the glycosylation of one but not the other kappa-chain. The primary structure of both chains demonstrated that they both used a V kappa 1 and a J kappa 2 gene segment and the same C kappa allele, Km(1,2), and that both contained the same junctional three amino acid deletion. However, they varied by 19 amino acids in the first 94 amino terminal residues encoded for by the V kappa gene, with some of the substitutions requiring two base changes in the appropriate codons. Moreover, the malignant "clones" producing the two proteins differed in their responses to chemotherapy. These data indicate that, although the two clones producing the serum proteins were different at the time of study, they may have arisen from the same precursor clone.     

B lymphoblastoid cell lines with rearranged T cell receptor beta-chain genes retain conventional B cell surface antigen and Ig expression

Transformation of peripheral blood lymphocytes by co-incubation with EBV produces B lymphoblastoid cell lines, but rearrangement of TCR beta-chain genes was observed in three different cell lines derived from two individuals. Because rearrangement of TCR genes in B lymphocytes is considered a rare event, these B lymphoblastoid cell lines with rearranged TCR beta-genes were examined in detail to determine whether there were any additional characteristics to distinguish them from B lymphoblastoid cell lines with germ-line TCR beta-genes. All B lymphoblastoid cell lines contained rearranged Ig H and kappa L chain genes, secreted Ig, and expressed B and not T cell surface markers. Cell lines with rearranged TCR beta-genes had rearranged both IgH genes and had rearranged and subsequently deleted both kappa C region genes. Furthermore all three B lymphoblastoid cell lines with rearranged TCR beta-genes produced small amounts of Ig with lambda-L chains. Although the cellular mechanisms maintaining lineage-specific rearrangement events remain unknown, extensive Ig gene rearrangement and inefficient Ig production by B cells may be indicators of a cellular status where normally stringent lineage-specific control elements fail to function efficiently.     

The reported germline repertoire of human immunoglobulin kappa chain genes is relatively complete and accurate

We describe a bioinformatic analysis of germline and rearranged immunoglobulin kappa chain (IGK) gene sequences, performed in order to assess the completeness and reliability of the reported IGK repertoire. In contrast to the reported heavy-chain gene repertoire, which includes many dubious sequences, only five IGK variable gene (IGKV) alleles appear to have been reported in error. There was, however, insufficient evidence to justify removing these IGKV genes from the germline repertoire. Bioinformatic analysis of apparent mismatches between reported germline genes and 1,863 expressed IGK sequences suggested the existence of two unreported IGKV polymorphisms. Genomic screening of 12 individuals led to the confirmation of both of these polymorphisms, IGKV1-16*02 and IGKV2-30*02. We also show that in contrast to the heavy chain, the IGK repertoire is dominated by sequences that use just a handful of kappa variable (IGKV) and junction (IGKJ) gene pairs. There is also little modification of IGKV and IGKJ genes by the processes of exonuclease removal and N nucleotide addition. The expressed IGK repertoire therefore lacks diversity and the junction region is particularly constrained. Remarkably, the analysis of a dataset of 435 relatively unmutated rearranged kappa genes showed that ten amino acid sequences account for almost 10% of the rearrangements, with identical sequences being derived from as many as seven independent sources. Such dominant sequences are likely to have important roles in the operation of the humoral immune response.