Conservation of the immunoglobulin C lambda 5 gene in the Mus gene.

A gene encoding the lambda 5 light chain constant region was isolated from a genomic library from the SPE mouse strain (C lambda 5S). SPE is an inbred wild mouse strain belonging to the Mus 3 or Mus spretus group that has been genetically isolated from Mus 1 (the group to which laboratory mice belong) for a period of 1-3 million years. The sequence of the C lambda 5S gene shows strong homology to C lambda 5 of (C57BL/6J x DBA/2)F1 both in the coding region (98% identity) and in the 5'- and 3'-flanking regions (98 and 95% identity, respectively). Sequence comparison of C lambda 5 genes with C lambda 1 of BALB/c shows only few substitutions in the C lambda 5 coding regions and suggests that the three genes have a common ancestor. These data indicate that the C lambda 5 gene has evolved under strong selective pressure and probably encodes a functional gene product. The conservation of the C lambda 5 gene in various Mus species was observed by high stringency Southern blot analyses using a C lambda 5S probe on DNA sample from members of four different groups of wild mice. All the laboratory and wild mouse strains tested, including those with amplified sets of C lambda 1 and C lambda 2 hybridizing sequences, showed only single C lambda 5 hybridizing fragments. Little variation in size of restriction fragments detected with the C lambda 5 probe was seen in the different Mus species suggesting a high degree of conservation.(ABSTRACT TRUNCATED AT 250 WORDS)     

A rabbit Ig lambda L chain C region gene encoding C21 allotopes

Southern blot analyses of germ-line DNA obtained from rabbits expressing lambda chains of C7 and/or C21 allotypes were performed with a rabbit C lambda region-specific probe; a 12-kbp EcoRI- and a 2-kbp BamHI-hybridizing fragment were detected only in the DNA from rabbits expressing the C21 allotype. The 12-kbp EcoRI fragment was cloned and shown to contain two C lambda region-encoding genes in the same orientation. Each is preceded by a J lambda gene segment. Nonamer-12-bp spacer-heptamer recombination signal sequences were found 5' of each J lambda segment, and splicing signals were identified at the 3' ends of the J lambda segments and the 5' ends of the corresponding C lambda genes. The C lambda 5 gene, which exhibits a sequence identical with that found in several cDNA clones, is carried by the 2-kbp BamHI fragment missing from the genomic DNA of rabbits which do not express the C21 allotype. The second C lambda gene, C lambda 6, lies 3' of C lambda 5, in a 1.6-kbp BamHI fragment which is present in genomic DNAs of all tested rabbits, irrespective of their phenotype. Its sequence is identical with that found in one cDNA clone and differs from that of C lambda 5 in 17 base positions resulting in four amino acid substitutions. A fragment of a cDNA, with a J-C region sequence identical with that encoded by the J lambda 5-C lambda 5 gene pair, was subcloned into a plasmid expression vector. The resulting polypeptide product could be specifically immunoprecipitated by anti-C21 but not anti-C7 alloantisera, showing that some, if not all, C21 allotopes are encoded by the C lambda 5 gene. In contrast, the C lambda 6 gene product was not precipitable, either by anti-C7 or by anti-C21 alloantisera, although it was readily immunoprecipitated by a goat anti-rabbit lambda chain antiserum.     

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.     

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.     

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.     

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.     

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.     

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.     

Unraveling of the polymorphic C lambda 2-C lambda 3 amplification and the Ke+Oz- polymorphism in the human Ig lambda locus

Two polymorphisms of the human Ig(lambda) (IGL) locus have been described. The first polymorphism concerns a single, 2- or 3-fold amplification of 5.4 kb of DNA in the C(lambda)2-C(lambda)3 region. The second polymorphism is the Mcg(-)Ke(+)Oz(-) isotype, which has only been defined via serological analyses in Bence-Jones proteins of multiple myeloma patients and was assumed to be encoded by a polymorphic C(lambda)2 segment because of its high homology with the Mcg(-)Ke(-)Oz(-) C(lambda)2 isotype. It has been speculated that the Mcg(-)Ke(+)Oz(-) isotype might be encoded by a C(lambda) gene segment of the amplified C(lambda)2-C(lambda)3 region. We now unraveled both IGL gene polymorphisms. The amplification polymorphism appeared to result from a duplication, triplication, or quadruplication of a functional J-C(lambda)2 region and is likely to have originated from unequal crossing over of the J-C(lambda)2 and J-C(lambda)3 region via a 2.2-kb homologous repeat. The amplification polymorphism was found to result in the presence of one to five extra functional J-C(lambda)2 per genome regions, leading to decreased Ig(kappa):Ig(lambda) ratios on normal peripheral blood B cells. Via sequence analysis, we demonstrated that the Mcg(-)Ke(+)Oz(-) isotype is encoded by a polymorphic C(lambda)2 segment that differs from the normal C(lambda)2 gene segment at a single nucleotide position. This polymorphism was identified in only 1.5% (2 of 134) of individuals without J-C(lambda)2 amplification polymorphism and was not found in the J-C(lambda)2 amplification polymorphism of 44 individuals, indicating that the two IGL gene polymorphisms are not linked.     

Amino acid sequence diversity in mouse lambda 2 variable regions

The lambda-chains of immunoglobulins from BALB/c mice constitute the simplest system presently available for studying patterns of variable-region diversity. The limited number of V lambda and J lambda germ-line gene segments facilitates comparison of expressed and germ-line sequences. We report here the complete amino acid sequence of the variable regions of three lambda 2 chains and of one chain representing a V lambda 2----J lambda 3 rearrangement. Together with the previously determined sequence of the lambda 2 chain from myeloma MOPC-315, the results illustrate the following types of variable-region diversification: expression of a single V gene segment with more than one J segment, variability at the V-J junction, and presumably, somatic mutation in V and in J. The extent of somatic diversification in these lambda 2 chains is limited, consistent with results obtained previously with lambda 1 chains.     

Intergenic exchange maintains identity between two human lambda light chain immunoglobulin gene intron sequences.

Evidence for gene conversion or unequal double crossover in the human lambda light chain immunoglobulin locus is presented. The high level of J2C2-J3C3 intron cross-hybridization, the identity of the J lambda and J lambda 3 coding and intron sequences, the presence of multiple base differences between the C lambda 2 and C lambda 3 coding regions, and the presence of both the unconverted and converted alleles in the normal gene pool, suggest that a recombinational event has resulted in the conversion of the J lambda 2 coding and intron sequences to those of J lambda 3 and its flanking sequences. Intergenic exchanges, such as the one described here, may provide a mechanism to maintain sequence homogeneity and functionality among the duplicated members of the human lambda gene family.     

Mouse immunoglobulin gene rearrangements. The sequence of a nonexpressed lambda 3-chain gene

A functionally defective lambda 3-immunoglobulin chain gene has been cloned from plasmacytoma HOPC-1 (gamma 2b, lambda 1). The lambda 3 gene resulted from the juxtaposition of the germline V lambda 1 sequence with a J lambda 3 C lambda 3 gene segment. DNA sequencing of the rearranged V lambda 1 J lambda 3 exon showed the presence of a single base pair deletion at the site of V-J joining. The alteration in the reading frame caused by this deletion generated a stop codon at the 3' end of J lambda 3, thus rendering this gene nonfunctional for light chain production. In addition, a one-point mutation in the J lambda 3-C lambda 3 intron distinguishes the rearranged gene from the unrearranged counterpart. The implications that this rearrangement has in terms of the mechanism of somatic mutations and of selective proliferation of B cells mediated by antigen stimulation are discussed.     

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.     

Further evidence that BALB/c and C57BL/6 gamma 2a genes originate from two distinct isotypes.

Gene conversion by the corresponding gamma 2b gene has been proposed to explain the multiple differences between the nucleic acid sequences of BALB/c (Igh-1a) and C57BL/6 (Igh-1b) gamma 2a immunoglobulin allelic genes. However, genetic analysis indicates that duplicated forms of gamma 2a genes are not only present in Eastern Asia, but also in European wild mouse populations which suggests a widespread phenomenon. In order to verify whether the gamma 2a-related isotypic genes, namely gamma 2c and gamma 2a, could correspond to those present as alleles in domestic mice (Igh-1b and Igh-1a), a genomic library from Mus m.musculus strain (MAI) was constructed. Extensive mapping of the recombinant phages and Southern blot analysis with several restriction enzymes gave the complete organization of these loci: gamma 2b (18 kb) gamma 2c (17 kb) gamma 2a (14 kb) epsilon. The homology in flanking, coding and intervening region sequences indicates that MAI gamma 2c and gamma 2a related genes correspond to C57BL/6 and BALB/c Igh-1 alleles respectively. Also, Southern blot analysis using several probes derived from exonic and intronic regions between gamma 2b and gamma 2a genes shows a 2.0- to 3.0-kb difference in the distance between gamma 2b and gamma 2a genes of BALB/c strain as compared to C57BL/6. Taken together, these results indicate that BALB/c and C57BL/6 gamma 2a genes could originate from different isotypes.     

Conserved organization of the murine immunoglobulin epsilon gene region: restriction endonuclease maps and switch-region nucleotide sequence

Various inbred mouse strains showed remarkable conservation of organization in the epsilon germline region as determined by restriction mapping. Restriction fragment length polymorphisms (RFLP) were seen in the epsilon gene region for only two of eight restriction enzymes tested. Furthermore, the RFLP did not correlate with the IgE-response phenotype for the murine strains SJL, SJA, C57BL/6, BALB/c, A/ST, and A/J. The IgE class-switch region (S epsilon) DNA from an SJL genomic clone was sequenced and was compared with S epsilon sequences from BALB/c mice. These S epsilon sequences were at least 95% homologous. Most of the S epsilon sequence differences observed between the two strains were single base pair substitutions, deletions, or insertions. The largest difference between the S epsilon sequences resulted from an insertion of seven contiguous bases seen in the SJL S epsilon region.     

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.     

Organization of the murine Ig-related lambda 5 gene transcribed selectively in pre-B lymphocytes.

lambda 5 is an immunoglobulin lambda light chain-related gene which is selectively transcribed in murine pre-B lymphocytes to yield a 1.2 kb poly(A)+ mRNA. Comparison of the nucleotide sequence of a 1 kb cDNA clone with the sequence of a genomic clone isolated from 70Z/3 murine pre-B lymphoma cells shows lambda 5 is composed of three exons spanning a 3.75 kb DNA segment. Conserved splice signal sequences at all exon/intron boundaries and the presence of a long open reading frame indicate that a functional mRNA molecule can be made. Exon I contains a cap-site and a potential ATG start codon as well as sequences encoding a signal peptide. This gene could encode a lambda 5 protein of 209 amino acids which has, however, not yet been identified. The 3' portion of exon II and all of exon III shows strong sequence homologies to J lambda L and C lambda L exons. Homology to the lambda L chain genes is lost in the 5' portion of exon II and throughout exon I. In exon I short homologies to leader sequences and to VH framework 1 sequences are seen.     

A new erythrocytic antigen of C57BL/10 (B10) mice

A new antigen, detectable on murine erythrocytes by hemagglutination assay with a (BALB/cCrl X SWR/J)F1 anti-B10.D2n/Sn alloantiserum, is described. Among the inbred and congenic mouse strains tested for reactivity with the antiserum, only the immunizing strain, B10.D2, and its congenic resistant partner, C57BL/10 (B10), reacted. Three other C57 strains, C57BL/6J, C57BL/6By, and C57L, were negative for the antigen. F1 hybrids between B10 and BALB/c, an antigen-negative strain, were positive for the antigen indicating that its expression is dominant. Typing of 39 (BALB/c X (BALB/c X B10)F1) and 62 [BALB/c X B10)F1 X BALB/c) backcross mice revealed that a single gene controls expression of the antigen. The gene is autosomal and not linked to H-2, Ly-4, or the c (albino) or b coat color genes.     

Organization of the constant-region gene family of the mouse immunoglobulin heavy chain

We cloned overlapping DNA segments that encompass the region from the immunoglobulin JH segments to the C gamma 3 gene of BALB/c mouse. We have now cloned the entire region (about 200 kilobases) of the constant-region gene family of the immunoglobulin heavy chain, the organization of which is 5'-JH-6.5 kb-C mu-4.5 kb-C delta-55 kb-C gamma 3-34 kb-C gamma 1-21 kb-C gamma 2b-15 kb-C gamma 2a-14 kb-C epsilon-12 kb-C alpha-3'. Using these cloned DNAs, we have characterized several structural features of the constant-region gene loci. There are no other J region segments except for those at the 5' side of the C mu gene. The S region is 5' to each CH gene except for the C delta gene, and the nucleotide sequences of the S region share some homology. There is no reasonably conserved pseudogene. There are at least two species of reiterated sequences scattered in these loci. Cloning and Southern blot hybridization analyses indicate that the general organizations of the heavy-chain gene loci of BALB/c and C57BL/6 mice, which have many different serological markers, are fundamentally similar but different in the lengths of S regions. Restriction enzyme cleavage maps of the whole constant-region gene loci were constructed with respect to eight restriction endonucleases.     

Polymorphism of C lambda genes and units of duplication in the genus Mus

The number of Ig C lambda genes in nine geographically widespread species from the four subgenera in the genus Mus was estimated from the number of Bam HI and Eco RI restriction fragments that hybridize under high stringency conditions to cDNA probes of BALB/c inbred mouse origin (Mus musculus domesticus). Three closely related species in the subgenus Mus, M. musculus, M. spretus, and M. spicelegus, show considerable variation in the number of C lambda genes. Estimates of gene numbers in these animals range from two C lambda genes in M. spretus from Puerto Real, Spain to 12 C lambda genes in M. musculus musculus from Studenec, Czechoslovakia. Strains of mice carrying either six or 10 C lambda genes were derived from a single population of M. musculus domesticus from Centreville, MD. The hybridization patterns of mice exhibiting C lambda gene amplification indicate that duplications are of relatively recent origin and probably occurred by reiteration of a DNA segment closely related to the 6.5 kb [C lambda 3 - C lambda 1] unit found in BALB/c inbred mice. Three more distantly related species in the subgenus Mus, and a species representing the Nannomys subgenus all appear to carry only four C lambda genes. DNA of species representing the Coelomys and Pyromys subgenera hybridized weakly to the C lambda cDNA probes, but these animals also have no more than four C lambda genes. Thus, there may be a base number of four C lambda genes in most species in the genus Mus. All inbred strains of mice so far examined also have only four C lambda genes, but no feral M. musculus examined have fewer than six C lambda genes. One explanation of the discrepancy in the number of genes between inbred and feral M. musculus is that C lambda genes were deleted during the process of inbreeding.