Homologous recombination between transferred and chromosomal immunoglobulin kappa genes.

Homologous recombination between transferred and chromosomal DNAs provides a means of introducing well-defined, predetermined changes in the chromosomal genes. Here we report that this approach can be used to specifically modify the immunoglobulin genes in mouse hybridoma cells. The test system is based on the Sp6 hybridoma, which synthesizes immunoglobulin M (kappa) specific for the hapten 2,4,6-trinitrophenyl (TNP). As recipient cells, we used the Sp6-derived mutant hybridoma igk14, which has a deletion of the kappa TNP gene and consequently does not synthesize TNP-specific immunoglobulin M. igk14 retains the mu TNP gene and two additional rearranged kappa genes, denoted kappa M21B1 and kappa M21G. As a transfer vector, we used pSV2neo bearing the functionally rearranged TNP-specific V kappa segment. Following DNA transfer by electroporation, we isolated rare transformants which produced normal amounts of the functional kappa TNP chain. Analysis of the DNA of these transformants indicated that in all cases, a functional kappa TNP gene had been formed as the result of a homologous integrative recombination event with the igk14 kappa M21B1 gene. These results suggest that homologous recombination might be used for mapping and introducing immunoglobulin gene mutations and for more conveniently engineering specifically altered immunoglobulins.     

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.     

Do antibody binding techniques identify polysomes synthesizing a specific protein?

Specific binding of antibody directed against MOPC-21 myeloma protein to MOPC-21 polysomes has been demonstrated. It was also shown that this same antibody bound specifically to the ribosomal subunits of these polysomes, suggesting that the antibody is not binding exclusively to the nascent polypeptide chains on the polysomes. The antibody was bound specifically to polysomes of a nonproducing variant XC1 which had been isolated in the presence of MOPC-21 myeloma protein while the antibody was not bound to XC1 polysomes isolated in the absence of myeloma protein. This suggests that the myeloma protein is adsorbed to the polysomes during the isolation procedure.     

A rearranged DNA sequence possibly related to the translocation of immunoglobulin gene segments.

A 5.3 kb EcoRI fragment (T3, abbreviations in ref. 2) has been cloned from DNA of a kappa light chain producing mouse myeloma. The fragment hybridizes to the k' flanking sequences of the J1 gene segment but not to C gene sequences of kappa light chain DNA. Restriction nuclease mapping and partial nucleotide sequencing showed that the fragment consists of sequences from the 5' side of the J1 and form the 3' side of a V gene segment, which apparently had been linked in a genomic rearrangement process. These rearranged flanking sequences are not the flanking sequences of the V and J gene segments which had been joined to form the two kappa light chain genes of the myeloma. Fragments with the hybridization properties of T3 have been found also in two other kappa and one lambda chain producing myelomas. The linking of flanking sequences in the myeloma genome is discussed with respect to the mechanism of recombination between V and J gene segments.     

Somatic DNA rearrangement generates functional rat immunoglobulin kappa chain genes: the J kappa gene cluster is longer in rat than in mouse

The kappa immunoglobulin (Ig) genes from rat kidney and from rat myeloma cells were cloned and analyzed. In kidney DNA one C kappa species is observed by Southern blotting and cloning in phage vectors; this gene most likely represents the embryonic configuration. In the IR52 myeloma DNA two C kappa species are observed: one in the same configuration seen in kidney and one which has undergone a rearrangement. This somatic rearrangement has brought the expressed V region to within 2.7 kb 5' of the C kappa coding region; the rearrangement site is within the J kappa cluster which we have mapped. The rat somatic Ig rearrangement, therefore, closely resembles that seen in mouse Ig genes. In the rat embryonic fragment two J kappa segments were mapped at 2 and 4.3 kb 5' from the C kappa coding region. Therefore, the rat J kappa cluster extends over about 2.3 kb, a region much longer than the 1.4 kb of the mouse and human J kappa clusters. In the region between C kappa and the expressed J kappa of IR52 myeloma DNA, and XbaI site present in the embryonic kappa gene has been lost. A somatic mutation has therefore occurred in the intervening sequence DNA approx. 0.7 kb 3' from the V/J recombination site. Southern blots of rat kidney DNA hybridized with different rat V kappa probes showed non-overlapping sets of bands which correspond to different subgroups, each composed of 8-10 closely related V kappa genes.     

Characterization of allelic V kappa-1 region genes in inbred strains of mice

Germ line genes encoding mouse Ig kappa-chains belonging to the V kappa-1 group have been isolated from BALB/c, NZB, and CE, three inbred strains of differing kappa haplotype. The V kappa-1A and V kappa-1C germ line genes isolated from BALB/c (Ig kappa c) were identical to those previously described. These are the two major V kappa-1 germ line genes in BALB/c and together account for 40 of the 53 expressed V kappa-1 sequences that have been reported to date. Allelic differences in a single germ line variable region gene (V kappa-1A) in different strains of mice explain the differences in L chain IEF patterns previously associated with the Ig kappa-Ef2 locus. The rearranged kappa-gene expressed in the BALB/c myeloma MOPC-460 has been isolated and found to represent a V kappa-1A somatic variant differing by three nucleotides from the germ line V kappa-1A gene. Germ line genes isolated from NZB (Ig kappa b) and CE (Ig kappa f) show greater than 95% identity with the BALB/c genes over the 1700 nucleotides compared. Comparison by region indicated the greatest conservation of sequence occurs in and around the leader exon followed by the V-region exon. The NZB gene encodes the amino acid sequence found in the myeloma PC-2205, previously designated V kappa-1B. The V kappa-1 gene isolated from CE is likely an allele of the BALB/c V kappa-1C gene as the two share greater than 96% identity over 1700 nucleotides. The CE gene has been designated V kappa-1Cf. Ancient remnants of LINE-1 repetitive elements were detected approximately 400 bp downstream of all of the V kappa-1 genes. These possess greater homology with repetitive elements found near other kappa genes than they do with the native L1Md sequence.     

Identical nature of the differences between normal and myeloma IgG in the mouse and man determined by the monolayer method

The surface denaturation kinetics of mouse normal IgG and IgGl kappa secreted by myeloma MOPC-21 was studied in monomolecular layers at the air-water interface. Based on the denaturation kinetics data the orientation of the native IgG molecules was determined relative to the interface surface, which turned out to be horizontal for normal IgG and vertical for myelomic ones. As regards the orientation in the monolayers and the rate of surface denaturation, the mouse normal IgG were found to be similar to normal IgG from other species. Like human myelomic IgG, MOPC-21 IgGl kappa differed from normal IgG in both the orientation and lesser native structure stability.     

Synthesis and glycosylation of the MOPC-46B immunoglobulin in kappa chain in Xenopus laevis oocytes.

Polyadenylated mRNA isolated from MOPC-46B plasmacytoma, which secretes a glycosylated kappa chain, was injected into $\text{Xenopus laevis}$ oocytes. Analysis of the resulting product showed that [1-¹⁴C]mannose was incorporated into the MOPC-46B kappa chain. Light chains synthesized in oocytes injected with mRNA from MOPC-321 plasmacytoma, which secretes a nonglycosylated kappa chain, failed to incorporate label from [1-¹⁴C]mannose. Thus, protein glycosylation in the oocyte is apparently specific in that carbohydrate is incorporated only into the kappa chain synthesized as a glycoprotein by myeloma cells. It is thus evident that the general signals for glycosylation have remained stable during independent evolution of the amphibia and mammalia.     

Comparison of V kappa gene family expression in adult and fetal B cells

The functional B cell repertoires from adult and fetal mice were compared by examining V kappa gene family expression in individual cells. In addition, because little is known about the relative use of the various V kappa gene families in an immune response, adult B cells from several different strains of mice were analyzed. This was accomplished by stimulating B cells with the polyclonal activator, LPS. Activated cells were then analyzed for V kappa gene family expression at the single cell level by in situ hybridization using radiolabeled V kappa gene probes. It was found that all V kappa gene families tested were represented in the LPS-induced adult repertoire with V kappa 1, V kappa 4,5 and V kappa 19 being expressed to the largest degree in all strains tested. The LPS-induced adult V kappa gene family repertoire was then compared to the fetal repertoire and some differences were observed. In particular, a lower proportion of fetal B cells expressed V kappa 1 and a higher proportion of fetal B cells expressed V kappa 4,5 and V kappa 10. Importantly, compared with the adult response there was no evidence in the fetal response for an increased expression of V kappa 21, the family that maps closest to J kappa,C kappa. This is in contrast to what has been shown previously with H chain V region exons in which there was a clear preference for the VH gene families that mapped closest to DH.     

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.     

Myeloma with multiple rearranged immunoglobulin kappa genes: only one kappa gene codes for kappa chains

In many myelomas more than one kappa gene is rearranged (2-5). We are reporting here the results of studies undertaken to determine whether all the rearranged genes are expressed. It was found that in the myeloma NS-1 three different rearranged kappa genes exist. In a subline of NS-1 and several hybridomas produced by fusion of mouse spleen cells with NS-1 it was found that production of NS-1 kappa chains was correlated with the presence of one of the three kappa genes. Loss of this "expressed" gene eliminated the synthesis of the NS-1 kappa chains, loss of one of the other two rearranged kappa genes did not. It is hypothesized, that allelic exclusion (20) of kappa genes generally operates by the functional rearrangement of one kappa gene; other rearrangements are relatively frequent, at least in myelomas, but mostly they are nonfunctional and thus scrambled antibody molecules do not arise.     

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.     

Evolution of immunoglobulin kappa chain variable region genes in vertebrates

The major source of immunoglobulin diversity is variation in DNA sequence among multiple copies of variable region (V) genes of the heavy- and light-chain multigene families. In order to clarify the evolutionary pattern of the multigene family of immunoglobulin light kappa chain V region (V kappa) genes, phylogenetic analyses of V kappa genes from humans and other vertebrate species were conducted. The results obtained indicate that the V kappa genes so far sequenced can be grouped into three major monophyletic clusters, the cartilaginous fish, bony fish and amphibian, and mammalian clusters, and that the cartilaginous fish cluster first separated from the rest of the V kappa genes and then the remaining two clusters diverged. The mammalian V kappa genes can further be divided into 10 V kappa groups, 7 of which are present in the human genome. Human and mouse V kappa genes from different V kappa groups are intermingled rather than clustered on the chromosome, and there are a large number of pseudogenes scattered on the chromosome. This indicates that the chromosomal locations of V kappa genes have been shuffled many times by gene duplication, deletion, and transposition in the evolutionary process and that many genes have become nonfunctional during this process. This mode of evolution is consistent with the model of birth-and-death evolution rather than with the model of concerted evolution. An analysis of duplicate V kappa functional genes and pseudogenes in the human genome has indicated that pseudogenes evolve faster than functional genes but that the rate of nonsynonymous nucleotide substitution in the complementarity-determining regions of V kappa genes has been enhanced by positive Darwinian selection.      

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.     

Changes in the orientation of mouse myeloma immunoglobulin G in monolayers after treatment with sodium deoxycholate

Molecules of normal mouse IgG are oriented horizontally in monolayers at air-water interface unlike the molecules of mouse IgG1 kappa secreted by MOPC-21 myeloma which have vertical orientation. Sodium desoxycholate processing of both preparations at concentrations below the critical micelle concentration resulted in abnormal IgG1 kappa preservation and normal IgG acquisition of vertical orientation in monolayers. When sodium desoxycholate was used for IgG modification at concentration higher than the critical micelle concentration both normal and abnormal IgG had horizontal orientation in monolayers.