A linkage map of the mouse immunoglobulin lambda light chain locus

The mouse immunoglobulin lambda light chain locus has been linked using field inversion gel electrophoresis. The lambda light chain locus classically contains two V and four J-C gene segments in inbred mouse strains, and was physically mapped in the BALB/c cell line Wehi-3 which contains unrearranged lambda light chain gene segments. The locus is relatively small and spans 300 kb, as defined by a variety of single and double digests using methylation-sensitive restriction enzymes. The order of the lambda gene segments is V2-J2C2J4C4-V1-J3C3J1C1, as was originally proposed. No evidence for nonmethylated CpG rich areas (HTF islands) within the region was found. Fine mapping using the 1, 3 rearranged cell line J558 mapped the gap between the V and J-C gene segments in the lambda 1 gene cluster (VI-J3C3JIC1) to approximately 70 kb. The similar distance (60–100 kb) found in the lambda 2 gene cluster (V2-J2C2J4C4) is further evidence that duplication of an ancestral locus occurred.     

Nucleotide sequence of a chromosomal rearranged lambda 2 immunoglobulin gene of mouse.

The rearranged lambda 2 gene of the mouse plasmacytoma cell line MOPC315 has been cloned and sequenced. A comparison of its sequence with the sequence of the unrearranged (germ-line) V, J and C gene segments shows that the sequences of the V gene segments differ at six positions. The sequence of the J and C gene segments remained unchanged. These results add support to the hypothesis that somatic mutations occur in immunoglobulin in genes and that these mutations do not involve the C gene segment. The degree of homology of the elements of the lambda 2 gene with those of the lambda 1 gene and C lambda 3 and C lambda 4 gene fragments suggest a pathway of evolution by gene duplication of the immunoglobulin lambda light chain locus. According to this scheme the original structure V0-J0C0 gave rise to a structure V0-J1C1-J11C11 by duplication of the J0C0 region. A second duplication encompassing the whole region resulted in the present structure: V1-J3C3-J1C1/V2-J2C2-J4C4.     

Wild mice express an Ig V lambda gene that differs from any V lambda in BALB/c but resembles a human V lambda subgroup.

The lambda L chain locus in the inbred mouse strains commonly used in the laboratory contains a limited number of germ-line genes; only three V lambda and three functional J lambda-C lambda genes have been identified in BALB/c mice. Previous studies indicated that wild mice may have a considerably expanded number of C lambda genes, as judged by the number of DNA restriction fragments that hybridize to C lambda probes derived from BALB/c. In order to evaluate the expression of these putative lambda genes, we have determined sequences of cDNA encoding lambda-chains in hybridomas from wild mice of the subspecies Mus musculus musculus from two different geographic regions, Denmark and Czechoslovakia. Two of these hybridomas produce L chains with J and C regions that are very similar to those of BALB/c lambda 1 chains, but the V regions of these L chains are only approximately 40% identical in amino acid sequence to the known murine V lambda. Indeed, these wild mouse V lambda are closer in sequence to human V lambda than they are to BALB/c V lambda, especially to human V lambda of subgroup VI, with which they share an unusual two-residue insertion in framework 3; L chains bearing V regions of this rare human type have a marked tendency to enter into amyloid deposits. These findings suggest that similar V lambda may be widespread in mammalian populations, although analysis by Southern blotting indicates that they are not found in BALB/c mice. A third hybridoma produces a L chain whose V lambda resembles BALB/c V lambda 1. The J lambda and C lambda segments of the cDNA encoding all three hybridoma L chains are identical; evidently, of the several putative genes that hybridize to C lambda 1 probes, one is expressed preferentially.     

Somatic point mutations in unrearranged immunoglobulin gene segments encoding the variable region of lambda light chains.

Somatic point mutations are usually found in the coding and flanking regions of functionally and aberrantly rearranged immunoglobulin variable region gene segments. Mutations in the unrearranged V gene segments of myelomas or hybridomas have not been described so far. We have cloned and sequenced unrearranged V lambda gene segments from several cell lines. There were no nucleotide changes in four unrearranged V lambda segments: one V lambda 1 from a lambda 3-producing hybridoma and one V lambda 2 from a lambda 1-producing myeloma (J558) and two V lambda 2 from a kappa-producing myeloma (P3X63). However, we found somatic mutations in the unrearranged V lambda segments from the lambda 2-producing myeloma MOPC315. The unrearranged V lambda 1 gene segment had two mutations in the coding region and the unrearranged V lambda 2 had one mutation in the 3' flanking region. We also cloned and sequenced the unrearranged J lambda and C lambda gene segments of MOPC315 and found no sequence alterations. This is consistent with the notion that the overall mutation rate is not higher in this cell line. Therefore, we suggest that the somatic hypermutation system can use unrearranged V gene segments as substrates. The extensive sequencing required for this work revealed a number of errors in the reported nucleotide sequences of the Ig lambda locus in BALB/c mice.     

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.     

Aberrant recombination events in B cell lines derived from a kappa-deficient human.

We have analyzed the structure of Ig kappa chain genes in B cell lines derived from a human individual who cannot synthesize any kappa chains, and whose Igs all contain lambda chains (1). We have characterized secondary DNA recombination events at two kappa alleles which have undergone misaligned V-J recombinations. One such secondary recombination has joined the flanking sequences of a V kappa and a J kappa 2 gene segment as if it were the reciprocal product of a V-J kappa 2 recombination, and resulted in the displacement of the recombined VJ kappa 1 gene segments from the C kappa locus. The non-rearranged form of the V kappa fragment which had recombined with the J kappa 2 flank was cloned. Nucleotide sequencing of this fragment identified a V kappa gene that differed by at least 38% from all previously sequenced human V kappa genes. The other V-J kappa segment analyzed has undergone a secondary recombination at a different site from that described above, at a site within the intervening sequence between the J kappa and C kappa gene segments, similar to the location of secondary recombinations which have occurred in lambda + B cell lines from mice and humans (2,3). These results prove that multiple recombinations can occur at one J kappa-C kappa locus.     

C lambda 2 and C lambda 4 immunoglobulin light chain genes in a wild-derived inbred mouse strain

A genomic clone containing the lambda constant (C) region genes (C lambda 2S and C lambda 4S) has been isolated from a genomic library from the mouse strain SPE. SPE is an inbred strain derived from progenitors trapped near Grenada in Spain and has been classified as mus 3 or mus spretus. The sequence of the C lambda 2S gene is virtually identical to that of BALB/c both in the coding region and in flanking sequences, suggesting that it is an expressed gene in the SPE strain. By contrast, the C lambda 4S gene on the same cluster has diverged in sequence from that of BALB/c and contains a large deletion that precludes its normal expression. Whereas BALB/c J lambda 4 region contains substitutions that probably preclude its usage, the SPE J lambda 4 gene includes all sequences required for a functional J gene. Comparison of the C lambda 2S and C lambda 4S gene sequences with those available for BALB/c C lambda 3 and C lambda 1 confirms the close relationship between the C lambda 1-C lambda 4 and C lambda 2-C lambda 3 gene pairs. The C lambda 3 gene of BALB/c is more closely related to C lambda 2S than is C lambda 1 of BALB/c to C lambda 4S. If it is assumed that C lambda 1 and C lambda 2 are respective duplicates of C lambda 4 and C lambda 3 and that these duplications occurred at the same time, then the C lambda 2 gene has been under stronger selective pressure than C lambda 4.     

Murine lambda gene rearrangements: the stochastic model prevails over the ordered model.

The ontogeny of the immunoglobulin (Ig) gene rearrangement in mammalian B cells seems to be ordered. Heavy chain gene segments rearrange first, followed by light chain gene segments, kappa before lambda. The genomic organization of murine lambda locus does not preclude the simultaneous expression of two subtypes from the same chromosome. In order to distinguish between an ordered and a stochastic model of rearrangement, a panel of 67 B cell hybridomas secreting either lambda 1, lambda 2, lambda 3 or lambda x (recently described) were analysed for V lambda J lambda rearrangements. The results show that in 97% of cases, a single rearrangement occurred, favouring the stochastic model over the ordered one. Strikingly, the possibility of having a productive rearrangement if the first try results in an aberrant one is rare. We propose therefore, that the lambda Ig is not necessarily required to ensure allelic and subtypic exclusion mechanisms. Moreover, in 97% of the cases, at least one kappa allele is rearranged. Furthermore, the RS recombination has been detected in 77% of the cases. This suggests that, although the stimulation of kappa precedes that of lambda locus, the RS recombination acts as a transacting albeit dispensable lambda activator.     

The Ig light chain restricted B6.kappa(-)lambda(SEG) mouse strain suggests that the IGL locus genomic organization is subject to constant evolution

In laboratory mice, the different Ig lambda light chain subtypes (lambda 1, lambda 2, lambda x and lambda 3) are expressed on 60, 16, 16 and 8%, respectively, of the lambda-positive peripheral B cells. Eighteen years ago, our laboratory characterized a lambda 1(-) wild mouse strain: SPE ( Mus spretus). In this report, we describe the characterization of another wild-derived Mus spretus inbred strain, SEG, that presents the same characteristic, namely the absence of lambda 1 expression. An almost congenic strain, B6.lambda(SEG), was detected in a series of recombinant congenic strains carrying 2% of SEG/Pas genome in a C57BL/6J background. This B6.lambda(SEG) strain was crossed to Igh (a) C kappa (-) mice in order to derive two different additional congenic strains: B6.kappa(-)lambda(SEG) Igh (a) and B6.kappa(-)lambda(SEG) Igh (b). In this paper, we characterize the genomic organization and the expression of the SEG IGL locus. Altogether, our data show that the SEG IGL locus is constituted by a single functional IGLJ2SEG-IGLC2SEG, two pseudo IGLJ4SEG1/2-IGLC4SEG1/2 gene clusters and two V gene segments: IGLV2SEG and IGLVXSEG. In particular, we show the absence of IGLV1 and IGLVSD26 gene segments. IGLVSD26 was reported to be present in some Mus m. musculus mice and absent in BALB/c. Here, we confirm its presence not only in other Mus m. musculus mice but also in Mus spretus mice. Consequently, we propose that IGLVSD26-related gene segments define a new family that we name V lambda 4. The study of the organization of different IGL loci, in addition to the V lambda 4(+) reported here, could elucidate questions concerning the evolution of the lambda locus.     

Enhancer sequences located 3' of the mouse immunoglobulin lambda locus specify high-level expression of an immunoglobulin lambda gene in B cells of transgenic mice

In contrast to the mouse immunoglobulin heavy chain and kappa light chain genes, very little is known about the regulation of expression of the immunoglobulin lambda light chain locus. To identify elements responsible for lambda gene regulation we mapped DNaseI hypersensitive sites associated with a functionally rearranged lambda 1 gene in nuclei from the myeloma cell line J558L. Tissue-specific hypersensitive sites were identified 2.3 to 2.5 kb upstream of the CAP site of both the lambda 1 gene and the unrearranged variable (V) lambda 2 gene segments. DNA sequences flanking the lambda 1 gene were isolated and tested for their influence on expression of the lambda 1 gene after transfection into myeloma cells and after injection into fertilized mouse eggs. Two enhancer elements were identified downstream of the lambda 1 gene. A proximal element (located 4 to 10 kb 3' of the gene) enhanced expression of a lambda 1 gene in stable myeloma cell transfectants but had no effect on the expression of a heterologous reporter gene in transient assays. A second, distal element, located approximately 30 kb 3' of the gene, enhanced heterologous expression in J558L cells expressing a lambda gene but not in a non-lambda myeloma cell line (SP2/0-Ag14). Co-injection of cosmids containing the lambda 1 gene and both the proximal and distal downstream elements into fertilized mouse eggs resulted in high-level expression of the lambda 1 transgene in B cells of transgenic mice. The identification of these lambda regulatory elements, in addition to contributing to an understanding of lambda gene regulation per se, will facilitate the study of the regulation of differential expression of kappa and lambda light chain genes in the immune system.     

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.     

L chain isotype regulation in horse. I. Characterization of Ig lambda genes.

Analysis of 10 cDNA encoding lambda L chains of horse Ig indicated that this species may employ a relatively small number of variable region (V lambda) genes in the splenic B cell population. The V lambda sequences of all of the cDNA analyzed were closely related (> 88% identity at the nucleotide level) and were characterized by a deletion of the amino acid residue at position 3 compared with V lambda sequences so far described in other species. The 10 V lambda sequences could be grouped into three groups, V lambda 1 to V lambda 3, on the basis of a number of linked substitutions. Sequences within the groups showed the greatest divergence in the third cdr regions and at the V-J junctions. The junctional variation included amino acid substitutions on both sides of the V-J junction as well as the insertion or deletion of two to four amino acid residues. Four C lambda genes were identified in genomic blots of horse DNA, and three of these were found expressed in splenic cDNA. The fourth C lambda gene may represent a pseudogene, inasmuch as the associated J region possessed a defective heptamer joining sequence. Six of the nine possible V lambda-C lambda combinations were found in the cDNA analyzed, suggesting that genes belonging to groups V lambda 1 through V lambda 3 may rearrange to any one of three J lambda-C lambda genes. One V lambda germline gene was characterized and found to represent a distinct V lambda group (V lambda 4), not represented in the cDNA sequences analyzed. The number of germline V lambda genes was estimated to be 20 to 30, based on analysis of restriction fragments hybridizing with V lambda probes. On the basis of these data, we propose that the V lambda repertoire in horse may consist of relatively limited number of genes, of which only a few may be used at high frequency in the splenic B cell population. The results indicate that predominance of lambda-chains in horse Ig may not simply be due to the presence of a large germline V lambda gene repertoire.     

Mouse V lambda x gene sequence generates no junctional diversity and is conserved in mammalian species

The lambda x, a new mouse Ig lambda L chain, is produced by rearrangement of the V lambda x, J lambda 2, and C lambda 2 gene segments. The V lambda x amino acid sequence is as divergent to other V lambda as to Vk gene sequences. Additionally, its third hypervariable region (CDR3) is four amino acids longer than those of all other variable gene segments of murine L chain. We have cloned and sequenced the germ-line V lambda x gene and found that the unexpected CDR3 length is encoded by the V lambda x gene. Junctional diversity is prevented by a TAA termination codon localized at the V lambda x 3' extremity. Moreover, we show a striking conservation of the V lambda x sequence in various mammalian species. Portions of the V lambda x sequence display more than 70% of nucleotide sequence identity with rabbit and human variable regions. These results suggest that V lambda x predated the divergence of mammalian species.     

Physical linkage of mouse lambda genes by pulsed-field gel electrophoresis suggests that the rearrangement process favors proximate target sequences.

The first complete map of a mammalian immunoglobulin gene locus is presented. Mouse lambda genes were mapped by pulsed-field gel electrophoresis. The gene order is V2-Vx-C2-C4-V1-C3-C1. The distance between V2 or Vx and the C2-C4 cluster is 74 or 55 kilobases (kb), respectively, whereas that between V1 and C3-C1 is only 19 kb; V2 and C3-C1 are at least 190 kb apart. Thus, the distances between the lambda subloci are inversely proportional to their frequencies of rearrangement. The related gene lambda 5 is not within the 500 kb of the lambda locus mapped here.     

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.     

Association of human lambda light chain V/J/C segments: serologic analysis and primary structure of the lambda VI Bence Jones protein THO

The complete amino acid sequence of the human monoclonal lambda VI light chain Bence Jones protein THO was determined. We have found it to have remarkable similarities to the previously sequenced lambda VI Bence Jones protein SUT. Immunochemical analyses demonstrated that both lambda VI chains belong to a V lambda VI sub-subgroup. The 98-residue V gene-encoded segments of proteins THO and SUT are closely homologous and are distinguished from other lambda VI chains by a one-residue deletion at the V-J recombination site. Proteins THO and SUT have identical 13-residue J segments and therefore are encoded by the same J lambda gene. Further, both proteins have identical 105-residue C regions that by sequence represent products of the C lambda 3 (Kern-, Oz+) gene. The primary structure and serologic properties of proteins THO and SUT imply at the protein level of association between certain types of V lambda, J lambda, and C lambda segments.     

Variation in V lambda genes in the genus Mus

The complement of Ig V lambda genes in nine species of feral mice representing the four extant subgenera of the genus Mus was examined and compared with that of BALB/c inbred mice. Although all inbred strains examined have two V lambda genes, there is variation in the number of copies of V lambda genes in the wild mice. All feral representatives of M. musculus domesticus, from which inbred strains are derived, have at least three V lambda genes, indicating that a V lambda gene may have been lost during the inbreeding process. At least three V lambda genes are also found in representatives of three other M. musculus subspecies, including the stock of M. musculus musculus "Czech II" shown to have at least 12 C lambda genes. In comparing the complement of V lambda and C lambda genes in these animals, evidence is found that supports a mechanism of lambda gene reiteration involving duplication of a unit containing a V lambda and two C lambda genes. However, the possibility that C lambda gene amplification occurred independent of V lambda gene evolution cannot be ruled out. M. spicelegus and M. spretus, species that are semifertile with M. musculus, have one to three V lambda genes. Species more distantly related to M. musculus, such as M. cookii and M. platythrix, appear to have more (four to six) V lambda genes. Greater V lambda gene heterogeneity is also found in these animals. We propose that the ancestors of the subgenus Mus had more V lambda genes than are seen in modern species and that the paucity of V lambda genes in M. musculus, M. spicelegus, and M. spretus may be the result of V lambda gene deletion events that occurred since the divergence of the ancestor of these three species and those of the distantly related species.     

Sequences of mouse immunoglobulin light chain genes before and after somatic changes.

We have determined the nucleotide sequences of the germ line gene as well as a corresponding somatically mutated and rearranged gene coding for a mouse immunoglobulin lambdaI type light chain. These sequencing studies were carried out on three Eco RI-DNA fragments which had been cloned from BALB/c mouse embryos or a lambdaI chainsecreting myeloma, H2020. The embryonic DNA clone Ig 99lambda contains two protein-encoding segments, one for the majority of the hydrophobic leader (L) and the other for the rest of the leader and the variable (V) region of the lambda0 chain (Cohn et al., 1974); these segments are separated by a 93 base pair (bp) intervening sequence (I-small). The coding of the V region ends with His at residue 97. The second embryonic DNA clone Ig 25lambda includes a 39 bp DNA segment (J) coding for the rest of the conventionally defined V region (that is, up to residue 110), and also contains the sequence coding for the constant (C) region approximately 1250 untranslated bp (I-large) away from the J sequence. The J sequence is directly linked with the V-coding sequence in the myeloma DNA clone, Ig 303lambda, which has the various DNA segments arranged in the following order: 5' untranslated region, L, l-small, V linked with J, l-large, C, 3' untranslated sequence. The lg 303lambda V DNA sequence codes for the V region synthesized by the H2020 myeloma and is different from the lg 99lambda V DNA sequence by only two bases. No silent base change was observed between the two DNA clones for the entire sequence spanning the 5' untranslated regions and the V-coding segments. These results confirm the previously drawn conclusion that an active complete lambdaI gene arises by somatic recombination that takes place at the ends of the V-coding DNA segment and the J sequence. No sequence homology was observed at or near the sites of the recombination.