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.     

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.     

Serologically defined V region subgroups of human lambda light chains

The availability of numerous antisera prepared against lambda-type Bence Jones proteins and lambda chains of known amino acid sequence has led to the differentiation and classification of human lambda light chains into one of five V lambda subgroups. The five serologically defined subgroups, V lambda I, V lambda II, V lambda III, V lambda IV, and V lambda VI, correspond to the chemical classification that is based on sequence homologies in the first framework region (FR1). Proteins designated by sequence as lambda V react with specific anti-lambda II antisera and are thus included in the V lambda II subgroup classification. The isotypic nature of the five V lambda subgroups was evidenced through analyses of lambda-type light chains that were isolated from the IgG of normal individuals. Based on analyses of 116 Bence Jones proteins, the frequency of distribution of the lambda I, lambda II/V, lambda III, lambda IV, and lambda VI proteins in the normal lambda chain population is estimated to be 27%, 37%, 23%, 3%, and 10%, respectively. This distribution of V lambda subgroups was comparable to that found among 82 monoclonal Ig lambda proteins. Considerable V lambda intragroup antigenic heterogeneity was also apparent. At least two sub-subgroups were identified among each of the five major V lambda subgroups, implying the existence of multiple genes in the human V lambda genome. The V lambda classification of 54 Ig lambda proteins obtained from patients with primary or multiple myeloma-associated amyloidosis substantiated the preferential association of lambda VI light chains with amyloidosis AL and the predominance of the normally rare V lambda VI subgroup in this disease.     

The immunoglobulin lambda locus in rat consists of two C lambda genes and a single V lambda gene

The immunoglobin lambda locus of the rat has been studied. Germ-line V lambda and C lambda genes were isolated from recombinant-phage libraries and characterized by nucleotide sequencing. The results showed that the lambda locus of the rat contains one single V lambda gene and two C lambda genes, thus representing one of the least complex lambda loci so far characterized. The two C lambda genes are separated by a spacer approx. 3 kb long. Two J segments are located at the 5' side of each C lambda gene. One of the C lambda genes (C lambda 1) probably represents a pseudogene, as the J lambda 1 segments have non-functional recombination and splice signals. The organization of the rat lambda locus resembles that of mouse, except that only one cluster is present in the rat. Thus since the evolutionary separation of the rat and mouse species ten MYR ( = 10(6) years) ago, either one cluster has been lost from the rat, or duplicated in the mouse.     

Integration of the transposon-like element ETn upstream of V lambda 2 in the cell line P3X63Ag8

The cell line P3X63Ag8 and hybridomas obtained with it contain two rearranged V lambda 2 EcoRI fragments--6.8 kb and 7.4 kb in size. Southern blot analysis, molecular cloning, and mapping revealed that the rearrangements are related to one another and are not due to normal VJ joining. Sequence analysis indicated that the rearrangement was due to the integration of the transposon like element ETn upstream of V lambda 2. Because a normal embryonic V lambda 2 is still retained in this cell line one of the rearranged fragments must be due to a secondary event after the aneuploidization of the plasmacytoma. RNA dot blot analysis showed that the transposon is strongly expressed not only in embryonic cells but also in plasmacytomas, B lymphomas and T cell lines.     

Effects of V lambda gene diversity on generation of antigen-specific lymphocytes

Previous studies have shown that dextran B1355 (DEX)- and (4-hydroxy-3-nitrophenyl) acetyl (NP)-coupled antigens triggered, respectively, BALB/c and C57BL/6 (B6) lymphocytes in which the V lambda 1 gene and a specific VH gene (VHDEX and VHNPb) have functionally rearranged. In this paper, we studied whether the closely-related V lambda 2 gene can be utilized in association with these VH genes to generate antigen-specific lymphocytes. We found that the VHDEX gene was restrictedly utilized by the V1 lambda 1 gene to generate anti-DEX lymphocytes, and in contrast, both the V lambda 1 and V lambda 2 genes were utilized together with a VHNPb germline gene to form anti-NP lymphocytes. Southern blot and DNA sequencing of an anti-NP hybridoma confirmed that the germline form of the (186-2) VHNPb gene can be used in association with either the V lambda 1 or V lambda 2 genes.     

Regional mapping of two human immunoglobulin V lambda genes and analysis of the V lambda locus in chronic myeloid leukaemia.

The human immunoglobulin V lambda locus has been studied in relation to chromosomal translocations involving chromosome 22. DNA probes for two V lambda genes which belong to different subgroups and do not cross hybridize, were used to show that both V lambda genes are located on the Philadelphia chromosome in chronic myeloid leukaemia (CML). Both genes map in band 22q11 to a region that is bounded on the distal side by the breakpoints for CML 9:22 translocations and on the proximal side by the breakpoint for an X:22 translocation. We have found no evidence for rearrangements or amplification of either V lambda gene in CML, in either the chronic or acute phases of the disease. In K562 cells which are derived from the pleural effusion of a patient with Ph1-positive CML, there appears to be no rearrangement of the V lambda genes, but they are both amplified about four times. We have estimated that the minimum size for the amplification unit in K562 cells is 186 kb.     

Autoimmune mice and stimulated normal mice make lambda 1 with increased V region diversity

Previous studies of the genetic bases of murine SLE have defined gene segments that encode the H chain and the kappa L chain of anti-DNA, anti-Sm, and anti-IgG autoantibodies. As a result of these studies, the genetic origins of autoantibody H chains and kappa L chains are better understood, but little remains known about the genetic bases of autoantibody lambda-chains. Thus, we have analyzed serologically the germ-line and somatic origins of lambda 1 L chains in antibodies of normal mice and in both antibodies and autoantibodies of autoimmune mice. This study finds an increased lambda 1 diversity in both Ag-stimulated mice and autoimmune mice. This study also finds that the lambda 1 L chains in antibodies of unstimulated normal mice have the gene segment-encoded variable region, V lambda 1. In contrast, additional genetic processes appear to make the lambda 1 V regions of antibodies in Ag-stimulated normal mice and the lambda 1 V regions of both antibodies and autoantibodies in autoimmune mice. The increased lambda 1 diversity that we found in both Ag-stimulated mice and autoimmune mice might be caused by mutational processes creating antibody diversities. Therefore, the same somatic processes might be able to make both antibody and autoantibody lambda 1 diversities.     

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.     

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.     

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.     

Chromosomal orientation of the lambda light chain locus: V lambda is proximal to C lambda in 22q11.

We have demonstrated that the chromosomal breakpoint at 22q11 of a Burkitt lymphoma cell line (PA682) with an 8;22 translocation interrupts the variable region of the lambda light chain locus. In these cells, all of the C lambda and some V lambda sequences translocate to the 8q+ chromosome whereas some V lambda sequences remain on the 22q-. These results indicate that the lambda light chain locus on the long arm of chromosome 22 is oriented such that V lambda is proximal to C lambda.     

Absence of Ig V region gene somatic hypermutation in advanced Burkitt's lymphoma

Somatic hypermutation of rearranged Ig V region gene plays a major role in generating antibody diversity. Recently, V mutation has been established as a major mechanism of tumor escape from anti-Id immunotherapy. We cloned and sequenced the expressed Ig H and L chain V regions from a case of B acute lymphoblastic leukemia in order to evaluate B cell stages associated with V region mutation, and to determine which tumors would be better suited to Id directed immunotherapy. A consensus VH and V lambda sequence representing tumor at diagnosis was obtained by conventional cDNA cloning in lambda gt10 from a heterohybridoma. Primers which flanked both V regions were used in a modified polymerase chain reaction to generate multiple independent sequences from tumor cells harvested at relapse. In order to exclude mutations due to infidelity of the amplification procedure, single cDNA templates of known sequence were also amplified. The polymerase chain reaction proved to be an effective procedure to obtain multiple clones, but replication in M13 was associated with a low rate of base misincorporation. The results indicate that there is no evidence for biologically significant ongoing mutation in this t(8;14) B cell tumor when comparing sequences at diagnosis and relapse. Thus, V somatic mutation may be restricted to a discrete B cell stage whose malignant counterpart is follicular lymphoma.     

Arrangement of lambda light chain genes in mutant clones of the MOPC 315 mouse myeloma cells

The synthesis of lambda light chains and the arrangement of the lambda-chain genes was examined in cells of the mouse myeloma MOPC 315, which is an alpha lambda 2 producer, and in several mutants derived from it. The mutants produce lambda 2 chains only (MOPC 315.26, MOPC 315.34, and MOPC 315.37) or fail to produce alpha and lambda 2 chains (MOPC 315.25 and MOPC 315.36). Messenger RNA from the lambda 2 chain-producing cells directed the synthesis of a lambda 2 chain precursor and a fragment of the lambda 1 chain (lambda 1 F) in a wheat embryo cellfree system, whereas mRNA from the cells that do not produce lambda 2 chains directed the synthesis of lambda 1 F only. DNA from the parental MOPC 315 cells and from the lambda 2 chain-producing cells contained discrete EcoRI restriction fragments coding for rearranged lambda 1 and lambda 23 chain genes and their respective germ-line V and J-C regions. DNA from the no-Ig-producing cells contained fragments coding for the rearranged lambda 1 chain gene and the germ-line V lambda 2 region, but it lacked the sequences coding for the rearranged lambda 2 chain gene and the germ-line V lambda 1 and J-C lambda 1 regions. These results suggest that rearrangements of the lambda 1 and lambda 2 chain genes occur on different chromosomes in MOPC 315 cells and imply that rearrangements of the lambda 1 and lambda 2 chain genes on the same chromosome may be mutually exclusive.     

Cloning and sequence analysis of an Ig lambda light chain mRNA expressed in the Burkitt''s lymphoma cell line EB4.

A cDNA library was constructed from the mRNA of the Ig lambda producing Burkitt's lymphoma cell line, EB4. Overlapping clones encompassing the coding sequence of the Ig lambda mRNA were isolated and sequenced. The predicted amino acid sequence shows a short hydrophobic leader peptide and a mature polypeptide of 217 residues in which V, J and C regions can be distinguished. The V region belongs to subgroup VI and has greatest homology (80%) with the Amyloid-AR protein. The constant region is the Kern- Oz+ isotype. Probing normal human DNA with the subcloned V lambda coding sequence detects one gene at high stringency and a family of 11 members at low stringency. To date, no restriction enzyme site polymorphisms have been detected. The V lambda VI gene is rearranged on both chromosomes of EB4 and is deleted on both chromosomes in the Burkitt's lymphoma cell line BL2.     

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.