A linkage map of the mouse immunoglobulin lambda light chain locus

Contribution of Immunoglobulin Enhancers to B Cell Nuclear Organization

B cells undergo genetic rearrangements at immunoglobulin gene (Ig) loci during B cell maturation. First V(D)J recombination occurs during early B cell stages followed by class switch recombination (CSR) and somatic hypermutation (SHM) which occur during mature B cell stages. Given that RAG1/2 induces DNA double strand breaks (DSBs) during V(D)J recombination and AID (Activation-Induced Deaminase) leads to DNA modifications (mutations during SHM or DNA DSBs during CSR), it is mandatory that IgH rearrangements be tightly regulated to avoid any mutations or translocations within oncogenes. Ig loci contain various cis-regulatory elements that are involved in germline transcription, chromatin modifications or RAG/AID recruitment. Ig cis-regulatory elements are increasingly recognized as being involved in nuclear positioning, heterochromatin addressing and chromosome loop regulation. In this review, we examined multiple data showing the critical interest of studying Ig gene regulation at the whole nucleus scale. In this context, we highlighted the essential function of Ig gene regulatory elements that now have to be considered as nuclear organizers in B lymphocytes.

Central B-cell tolerance: where selection begins

The development of an adaptive immune system based on the random generation of antigen receptors requires a stringent selection process that sifts through receptor specificities to remove those reacting with self-antigens. In the B-cell lineage, this selection process is first applied to IgM(+) immature B cells. By using increasingly sophisticated mouse models, investigators have identified the central tolerance mechanisms that negatively select autoreactive immature B cells and prevent inclusion of their antigen receptors into the peripheral B-cell pool. Additional studies have uncovered mechanisms that promote the differentiation of nonautoreactive immature B cells and their positive selection into the peripheral B-cell population. These mechanisms of central selection are fundamental to the generation of a naïve B-cell repertoire that is largely devoid of self-reactivity while capable of reacting with any foreign insult.

Allelic exclusion of immunoglobulin genes: models and mechanisms

The allelic exclusion of immunoglobulin (Ig) genes is one of the most evolutionarily conserved features of the adaptive immune system and underlies the monospecificity of B cells. While much has been learned about how Ig allelic exclusion is established during B-cell development, the relevance of monospecificity to B-cell function remains enigmatic. Here, we review the theoretical models that have been proposed to explain the establishment of Ig allelic exclusion and focus on the molecular mechanisms utilized by developing B cells to ensure the monoallelic expression of Ig kappa and Ig lambda light chain genes. We also discuss the physiological consequences of Ig allelic exclusion and speculate on the importance of monospecificity of B cells for immune recognition.

Organization and genomic complexity of bovine lambda-light chain gene locus

Complete characterization and physical mapping of bovine lambda (lambda) light chain locus, spanning 412kbp, on chromosome 17, has revealed twenty-five V(lambda) genes, seventeen being functional, organized in three sub-clusters 23.7kbp 5' of the J(lambda)-C(lambda) units. Three V(lambda) sub-clusters are separated by two large introns of 126.8 and 138.3kbp. The predominantly expressed V(lambda)1 genes are present in the two 5' sub-clusters, while J(lambda)-proximal V(lambda) sub-cluster comprises rarely expressed V(lambda)2 and V(lambda)3 genes. The preferential expression of V(lambda)1 genes in the bovine immunoglobulin repertoire is influenced by the composition of recombination signal sequences (RSS). Of the J(lambda)-C(lambda) cluster, it is mainly J(lambda)3-C(lambda)3 unit that is expressed in reading frame 2, though J(lambda)2 and J(lambda)3 have identical RSS. The predominant expression of J(lambda)3-C(lambda)3 genes over J(lambda)2-C(lambda)2 is likely due to endogenous counter selection for J(lambda)2 encoded CDR3 and framework 4 regions. Differences in the genomic complexity of V(lambda) genes in Hereford and Holstein cattle are due to polymorphism at the lambda-light chain gene locus. Despite more potential germline encoded combinatorial diversity, restricted V(lambda)1-J(lambda)3-C(lambda)3 recombinations encode the most lambda-light chain repertoire in cattle.

Receptor selection in B and T lymphocytes

The process of clonal selection is a central feature of the immune system, but immune specificity is also regulated by receptor selection, in which the fate of a lymphocyte's antigen receptor is uncoupled from that of the cell itself. Whereas clonal selection controls cell death or survival in response to antigen receptor signaling, receptor selection regulates the process of V(D)J recombination, which can alter or fix antigen receptor specificity. Receptor selection is carried out in both T and B cells and can occur at different stages of lymphocyte differentiation, in which it plays a key role in allelic exclusion, positive selection, receptor editing, and the diversification of the antigen receptor repertoire. Thus, the immune system takes advantage of its control of V(D)J recombination to modify antigen receptors in such a way that self/non-self discrimination is enhanced. New information about receptor editing in T cells and B-1 B cells is also discussed.

The primary antibody repertoire of kappa-deficient mice is characterized by non-stochastic Vlamda1 + V(H) gene family pairings and a higher degree of self-reactivity

We have investigated the primary antibody repertoire of genetically manipulated 129/Sv kappa-deficient (JCkappaD) mice, in order to understand the contributions of the lambda-light chain, in the absence of an otherwise predominant kappa-light chain, to the development of humoral immunity. The expression of Vlambda1 gene (lambda1 and lambda3 subtypes) and the Vlambda1 + V(H) (J558, 36-60, V(H)11 and S107) gene family associations were studied in 7.43 x 10(3) mitogen-activated splenic B-lymphocyte clones of JCkappaD origin. Furthermore, the functional significance of the exclusive expression of the lambda-light chain, in the peripheral B-cell repertoire of JCkappaD mice, was analysed by determining natural autoantibody specificities in the circulating serum immunoglobulin and the frequency of autoreactive B-lymphocyte clones in the peripheral B-lymphocyte repertoire. These experiments revealed that: first, of the three available Vlambda genes at the lambda locus, the Vlambda1 gene is the one that is expressed most frequently (59.9%); second, non-random Vlambda1 + V(H) (J558, 36-60) gene family pairings occur in kappa-deficient mice; and third, a higher degree of self-reactivity is generated as a result of exclusive use of the lambda-light chain, as evidenced by higher levels of serum natural autoantibodies as well as a high frequency of autoreactive B-lymphocyte clones in kappa-deficient (129/Sv JCkappaD) mice. These observations suggest that the high murine kappa/lambda ratio in mice may, apart from high sequence diversity at the kappa-locus, be a result of endogenous selection against the lambda-light chain to restrict self-reactivity within the homeostatic threshold.

One-megabase sequence analysis of the human immunoglobulin lambda gene locus

A total of 1,025,415 bases of nucleotide sequence, including the entire human immunoglobulin lambda gene locus has been determined. This is the largest contiguous human DNA sequence ever published. The sequence data revealed the organization of 36 potentially active V lambda gene segments, 33 pseudogene segments, and seven J lambda-C lambda gene segments. Among these 69 functional or nonfunctional V lambda gene segments, 32 were newly discovered. These V lambda gene segments are located within five gene-rich clusters and are divided into five clans based on sequence identity. Five potentially active nonimmunoglobulin genes were also detected within the lambda gene locus, and two other genes were observed in the upstream region. Sequence organization suggests that large DNA duplications diversified the germ-line repertoire of the V lambda gene segments.

A quasi-monoclonal mouse

As a model for studying the generation of antibody diversity, a gene-targeted mouse was produced that is hemizygous for a rearranged V(D)J segment at the immunoglobulin (Ig) heavy chain locus, the other allele being nonfunctional. The mouse also has no functional kappa light chain allele. The heavy chain, when paired with any lambda light chain, is specific for the hapten (4-hydroxy-3-nitrophenyl) acetyl (NP). The primary repertoire of this quasi-monoclonal mouse is monospecific, but somatic hypermutation and secondary rearrangements change the specificity of 20 percent of the antigen receptors on B cells. The serum concentrations of the Ig isotypes are similar to those in nontransgenic littermates, but less than half of the serum IgM binds to NP, and none of the other isotypes do. Thus, neither network interactions nor random activation of a small fraction of the B cell population can account for serum Ig concentrations.

The primary antibody repertoire of normal, immunodeficient and autoimmune mice is characterized by differences in V gene expression

During the last decade, the structure and organization of the immunoglobulin heavy and light chain locis have been defined in mice and humans. Studies on VH gene expression at different stages of development, in different organs and disease states have provided useful insight into the construction of a primary antibody repertoire in mice. Clearly, 3'VH genes 7183, Q52 and Vh11, which are conserved during evolution, are preferentially expressed during early development of the B-lymphocyte repertoire. A preferential use for the V kappa 4 gene family is evident during early B-cell development. The initial development of the primary antibody repertoire is therefore influenced by a restricted set of VH and V kappa gene elements. The restricted B-cell repertoire is subsequently normalized in the periphery, as revealed by stochastic VH gene expression, as a result of exposure to environmental antigens. Obviously, the peripheral B-cell pool characterized by stochastic VH gene expression is selectively replenished by newly generated B cells in bone marrow that preferentially expresses 3'VH genes. The V kappa genes are, however, expressed in a non-random manner in the neonatal and adult B-lymphocyte repertoire that is probably related to VH and V kappa association dynamics and/or positive or negative selection. Interestingly, these characteristics of neonatal and adult primary repertoire are noted in both B1 and B2 lymphocytes. No remarkable age-related differences are evident for VH and V kappa gene expression. In healthy mice, both the mitogen responsive (available) and unstimulated (expressed) B-cell repertoire show similar VH gene expression. Interestingly, VH gene expression varies in different organs which may reflect, or occur as a result of, the specialized function of each organ. For example, J558 gene expression is higher in the peripheral LN where B cells continuously encounter exogenous antigens. The skewed VH and V kappa gene expression noted in immunodeficient and autoimmune lupus-prone mice reflects the impairment of the primary antibody repertoire associated with immunodeficiency and autoimmune disorders.

Formation and resolution of double-strand break intermediates in V(D)J rearrangement

A recently described pre-B cell line can be induced at high temperature to actively rearrange its immunoglobulin light-chain loci. We used this cell line to determine the fate of double-strand breaks generated by V(D)J rearrangement. After induction, 30%-40% of K loci had broken JK1 signal ends. JK1-coding ends were detectable, but 10- to 100-fold less frequent. Both covalently closed (hairpin) and open, blunt, processed coding ends were observed. Coding junctions involving JK1 accumulated with similar kinetics as JK1 signal ends, arguing that coding ends can be resolved quickly and efficiently to coding junctions, whereas signal ends remain mostly unjoined. Signal ends are then joined rapidly when cells are returned to the low temperature. These results support the model that broken signal ends and hairpin coding ends are authentic intermediates in V(D)J recombination. It appears that hairpin coding ends are rapidly opened, processed, and resolved to coding junctions, whereas joining of signal ends is clearly uncoupled from the joining of coding ends and can be much slower. Efficient formation of signal junctions may require cell cycle progression, or down-regulation of the recombination machinery.

Light chain editing in kappa-deficient animals: a potential mechanism of B cell tolerance

The genetic organization of the kappa and lambda light chain loci permits multiple, successive rearrangement attempts at each allele. Multiple rearrangements allow autoreactive B cells to escape clonal deletion by editing their surface receptors. Editing may also facilitate efficient B cell production by salvaging cells with nonproductive light chain (L chain) rearrangements. To study receptor editing of kappa L chains, we have characterized B cells from mice hemizygous for the targeted inactivation of kappa (JCkD/wt) which have an anti-DNA heavy chain transgene, 3H9. Hybridomas from JCkD/wt mice exhibited an increased frequency of rearrangements to downstream Jk segments (such as Jk5) compared with most surveys from normal mice, consistent with receptor editing by sequential kappa locus rearrangements in JCkD/wt. We observed an even higher frequency of rearrangements to Jk5 in 3H9 JCkD/wt animals compared with nontransgenic JCkD/wt, consistent with editing of autoreactive kappa in 3H9 JCkD/wt. We also recovered a large number of 3H9 JCkD/wt lines with Vk12/13-Jk5 rearrangements and could demonstrate by PCR and Southern analysis that up to three quarters of these lines underwent multiple kappa rearrangements. To investigate editing at the lambda locus, we used homozygous kappa-deficient animals (JCkD/JCkD and 3H9 JCkD/JCkD). The frequencies of V lambda 1 and V lambda 2 rearrangements among splenic hybridomas in 3H9 JCkD/JCkD were reduced by 75% whereas V lambda X was increased 5-10-fold, compared with nontransgenic JCkD/JCkD animals. This indicates that V lambda 1 and V lambda 2 are negatively regulated in 3H9 JCkD/JCkD, consistent with earlier studies that showed that the 3H9 heavy chain, in combination with lambda 1 binds DNA. As successive lambda rearrangements to V lambda X do not inactivate V lambda 1, the consequence of lambda editing in 3H9 JCkD/JCkD would be failed allelic exclusion at lambda. However, analysis of 18 3H9 JCkD/JCkD hybridomas with V lambda 1 and V lambda X DNA rearrangements revealed that most of these lines do not have productive lambda 1 rearrangements. In sum, both kappa and lambda loci undergo editing to recover from nonproductive rearrangement, but only kappa locus editing appears to play a substantial role in rescuing autoreactive B cells from deletion.

Far upstream regions of class II MHC Ea are necessary for position-independent, copy-dependent expression of Ea transgene

The chromatin upstream of the class II MHC Ea gene contains specific, DNase I hypersensitive (DH) sites (groups I-V), overlapping and extending the promoter proximal and distal control regions. To determine whether the Ea DH groups I-V define a functionally important chromatin domain or locus control region (LCR), we have used wild type Ead gene constructs to generate transgenic mouse lines from strains that do not express an endogenous Ea gene product. Constructs contained either DH groups I-V 'Longs' or DH groups I-II 'Shorts', of the hypersensitive sites defined within 20 kb 5' of Ea. We show that position-independent, copy number-dependent expression of the Ead gene occurs only with the Long construct (8/8 transgenic mouse lines, over a range of copy numbers, 1-30 copies); in contrast, the Short constructs are subject to position-dependent effects. This suggests that the region delineated by Ea DH groups I-II is necessary but not sufficient as an LCR, which requires the presence of the upstream regions containing DH III-V for complete position-independent, copy number-dependent expression. These results introduce an immunologically-important, putative LCR which can be used to target genes to cells of the B cell lineage, as well as to other class II MHC expressing cells, and highlight the importance of chromatin structure analysis as a means to locate DNA regions of regulatory interest which are dispersed over a large distance.

Receptor editing in self-reactive bone marrow B cells

A central paradigm of immunology is clonal selection: lymphocytes displaying clonally distributed antigen receptors are generated and subsequently selected by antigen for growth or elimination. Here we show that in mice transgenic for anti-H-2Kk,b antibody genes, in which a homogeneous clone of developing B cells can be analyzed for the outcome of autoantigen encounter, surface immunoglobulin M+/idiotype+ immature B cells binding to self-antigens in the bone marrow are induced to alter the specificity of their antigen receptors. Transgenic bone marrow B cells encountering membrane-bound Kb or Kk proteins modify their receptors by expressing the V(D)J recombinase activator genes and assembling endogenously encoded immunoglobulin light chain variable genes. This (auto)antigen-directed change in the specificity of newly generated lymphocytes is termed receptor editing.

The surrogate light chain in B-cell development

The proteins encoded by the VpreB and lambda 5 genes associate with each other to form a light (L) chain-like structure, the surrogate L chain. It can form Ig-like complexes with three partners-the classical heavy (H) chain, the DHJHC mu-protein, or the newly discovered p55 chain; these are expressed on the surface of pre-B cells at different stages of development. Here, Fritz Melchers and colleagues review the structures of the VpreB and lambda 5 genes in mouse and their relatives in humans, describe their pattern of expression, and speculate on their possible evolution and functions.

Molecular characterization of the human immunoglobulin V lambda I germline gene repertoire

To advance our understanding of the human immunoglobulin V lambda germline gene contribution to normal as well as autoimmune responses, we have isolated and sequenced six germline genes of the V lambda I subgroup. These genes can be divided into three sub-subgroups on the basis of greater than or equal to 93% nucleotide sequence homology and greater than or equal to 88% deduced amino acid sequence similarity. Examination of all cDNA and protein sequences available for expressed V lambda I genes supports the assignment of these three sub-subgroups. Sequence comparisons also suggest that germline gene members of two of these sub-subgroups, I-a and I-b, are preferentially utilized in the expressed V lambda I repertoire. This finding may be at least partially attributable to regulatory sequence abnormalities apparent in two of the other V lambda I germline genes (Humlv101 and Humlv104) which may interfere with their expression.

Two conserved essential motifs of the murine immunoglobulin lambda enhancers bind B-cell-specific factors

Two highly homologous enhancers associated with the two murine immunoglobulin lambda constant-region clusters were recently identified. In order to better understand the molecular basis for the developmental stage- and cell-type-restricted expression of lambda genes, we have undertaken an analysis of the putative regulatory domains of these enhancers. By using a combination of DNase I footprinting, electrophoretic mobility shift assay, and site-specific mutations, four candidate protein binding sites have been identified at analogous positions in both enhancers. A mutation of any of these sites decreases enhancer activity. Two of the sites, lambda A and lambda B, are essential for enhancer function, and both of these sites appear to bind both B-cell-specific and general factors. Nevertheless, isolated lambda A and lambda B sites show no evidence of inherent transactivating potential, alone or together, even when present in up to three copies. We suggest that the generation of transactivating signals from these enhancers may require the complex interaction of multiple B-cell-specific and nonspecific DNA-binding factors.

Two conserved essential motifs of the murine immunoglobulin lambda enhancers bind B-cell-specific factors

Two highly homologous enhancers associated with the two murine immunoglobulin lambda constant-region clusters were recently identified. In order to better understand the molecular basis for the developmental stage- and cell-type-restricted expression of lambda genes, we have undertaken an analysis of the putative regulatory domains of these enhancers. By using a combination of DNase I footprinting, electrophoretic mobility shift assay, and site-specific mutations, four candidate protein binding sites have been identified at analogous positions in both enhancers. A mutation of any of these sites decreases enhancer activity. Two of the sites, lambda A and lambda B, are essential for enhancer function, and both of these sites appear to bind both B-cell-specific and general factors. Nevertheless, isolated lambda A and lambda B sites show no evidence of inherent transactivating potential, alone or together, even when present in up to three copies. We suggest that the generation of transactivating signals from these enhancers may require the complex interaction of multiple B-cell-specific and nonspecific DNA-binding factors.

DNase I hypersensitive sites flank the mouse class II major histocompatibility complex during B cell development

The mouse class II major histocompatibility complex (MHC) encodes a polymorphic, multigene family important in the immune response, and is expressed mainly on mature B cells, on certain types of dendritic cells and is also inducible by gamma-interferon on antigen presenting cells. To study the regulatory elements which control this expression pattern, we have examined the chromatin structure flanking the class II MHC region, in particular during B cell differentiation. Using a panel of well-characterised mouse cell lines specific for different stages of B cell development (pre-B, B, plasma cell) as well as non-B cell lines, we have mapped the DNase I hypersensitive (DHS) sites adjacent to the mouse MHC class II region. The results presented show, for the first time that there are specific hypersensitive sites flanking the class II MHC locus during pre B cell, B cell and plasma cell stages of B cell differentiation, irrespective of the status of class II MHC expression. These hypersensitive sites are not found in T cell, fibroblast or uninduced myelomonocytic cell lines. This suggests that these DHS sites define a developmentally stable, chromatin structure, which can be used as a marker of B cell lineage commitment and may indicate that a combination of these hypersensitive sites reflect regulatory proteins involved in the immediate expression of a particular class II MHC gene or possibly control of the entire locus.

V lambda-J lambda rearrangements are restricted within a V-J-C recombination unit in the mouse

The murine lambda gene locus is organized as follows: V lambda 2-V lambda x-J lambda 2C lambda 2-psi J lambda 4C lambda 4-V lambda 1-J lambda 3C lambda 3-J lambda 1C lambda 1 where all segments have the same transcriptional orientation. The combinatorial process of gene recombination should allow the generation of eight distinct immunoglobulin light chains. We have therefore investigated the probability of obtaining such chains among the mature lambda B cell repertoire. We analyze serum lambda immunoglobulins and lambda B cell clones induced by treatment with rabbit anti-lambda antibodies coupled to LPS. Confirming previous data obtained by others, our results indicate that the rearrangements of lambda segments take place within each V lambda-J lambda-C lambda cluster, thereby defining a unit of recombination. Our results also provide no evidence for the use of undescribed segments as has been recently suggested by the finding of the V lambda x segment.

Interaction of a nuclear protein with a palindromic sequence of the mouse immunoglobulin lambda 2-chain gene promoter is important for its transcription

By using a gel mobility retardation assay, we detected the formation of three major complexes from the binding of nuclear proteins to the promoter of the immunoglobulin lambda 2-chain gene. Two of the complexes were generated by the presence of an unidentified nuclear factor(s) called herein NF-lambda 2. Although the sequences between lambda 2- and lambda 1-chain gene promoters are very similar, the lambda 1-chain promoter did not compete for the binding of NF-lambda 2 efficiently. The binding site of NF-lambda 2 was localized by DNase I footprinting to a 14-bp region which is about 30 bp upstream of the immunoglobulin octamer motif. This region, referred to as the NF-lambda 2 motif, is within an 18-bp region of twofold rotational symmetry. Experiments with oligomers containing either the NF-lambda 2 or the octamer motifs as competitors for binding and DNase I footprinting, showed that the third complex is the product of the simultaneous binding of an octamer-binding protein and NF-lambda 2. Changing the sequence of the NF-lambda 2 motif to that of the lambda 1-chain counterpart abolished the binding ability of NF-lambda 2. Concomitantly, the level of chloramphenicol acetyltransferase expression driven by the mutated lambda 2 promoter decreased by two- to fivefold when compared with that of the wild-type promoter. It is therefore concluded that the interaction of NF-lambda 2 with the NF-lambda 2 motif stimulates transcription of the lambda 2-chain gene.

cDNA clones encoding immunoglobulin lambda chains from rabbit expressing the phenotype c7

A cDNA library derived from spleen cells of an unimmunized rabbit expressing the c7 phenotype of Ig lambda chains (c7+, c21-) was screened with V lambda or C lambda probes of a lambda light chain bearing c21 epitopes. The nucleotide sequences of three hybridizing clones were found to be identical within the V lambda, J lambda and C lambda regions. The V lambda region was 97% similar to that of the functional germ-line gene V lambda 2, and the C lambda region was identical to that of gene C lambda 6, recently identified. Gene C lambda 6 exhibited four codon differences when compared with gene C lambda 5, the latter encoding c21 epitopes. The data presented here and in the accompanying report (Jaton, J.-C. et al., Eur. J. Immunol. 1990, 20:2713) support the view that gene C lambda 6 encodes the C region of c7 lambda chains and that c7 and c21 markers designate two distinct isotypic forms of lambda chains. On the basis of comparative Southern blotting analyses and restriction maps of cloned genomic regions containing V lambda and C lambda genes, a scheme is proposed to account for the c7- and c21- phenotypes.

Interaction of a nuclear protein with a palindromic sequence of the mouse immunoglobulin lambda 2-chain gene promoter is important for its transcription

By using a gel mobility retardation assay, we detected the formation of three major complexes from the binding of nuclear proteins to the promoter of the immunoglobulin lambda 2-chain gene. Two of the complexes were generated by the presence of an unidentified nuclear factor(s) called herein NF-lambda 2. Although the sequences between lambda 2- and lambda 1-chain gene promoters are very similar, the lambda 1-chain promoter did not compete for the binding of NF-lambda 2 efficiently. The binding site of NF-lambda 2 was localized by DNase I footprinting to a 14-bp region which is about 30 bp upstream of the immunoglobulin octamer motif. This region, referred to as the NF-lambda 2 motif, is within an 18-bp region of twofold rotational symmetry. Experiments with oligomers containing either the NF-lambda 2 or the octamer motifs as competitors for binding and DNase I footprinting, showed that the third complex is the product of the simultaneous binding of an octamer-binding protein and NF-lambda 2. Changing the sequence of the NF-lambda 2 motif to that of the lambda 1-chain counterpart abolished the binding ability of NF-lambda 2. Concomitantly, the level of chloramphenicol acetyltransferase expression driven by the mutated lambda 2 promoter decreased by two- to fivefold when compared with that of the wild-type promoter. It is therefore concluded that the interaction of NF-lambda 2 with the NF-lambda 2 motif stimulates transcription of the lambda 2-chain gene.

Immunoglobulin lambda light chain evolution: Igl and Igl-like sequences form three major groups

The nucleotide sequences, and the derived protein sequences, of immunoglobulin (Ig) Igl, Igl-like VpreB genes and the protein sequences of Igl-C regions were aligned and compared. A classification of the Igl and Igl-like VpreB sequences into three categories, designated groups I, II, and III, is proposed. Group I contains the human and mouse Igl-like VpreB genes. Group II contains Igl-V genes of the rabbit and the recently described mouse Igl-Vx gene. Group III includes the Igl-V genes, encoding all other known Igl-V region protein sequences, of mouse, rat, human, pig, sheep, and chicken. An evolutionary analysis of the three groups is presented, and suggests that the group III genes are evolving at a faster rate than those of the other groups and that within this group a further subdivision is possible: the V lambda-encoding genes of mouse, rat, and one human subgroup evolve faster than other group III genes. It is suggested that all mammalian species contain Igl-V genes of each group. A similar comparison between the protein sequences encoded by the known Igl-C genes indicates that the duplication of the Igl-J-C gene pairs occurred independently in each species, after mammalian speciation, and that the Igl-V-(J-C)(J-C) gene clusters of the mouse may not have their homologues in other species.

A novel enhancer in the immunoglobulin lambda locus is duplicated and functionally independent of NF kappa B

As a first step toward defining the elements necessary for lambda immunoglobulin gene regulation, DNase I hypersensitive sites were mapped in the mouse lambda locus. A hypersensitive site found 15.5 kb downstream of C lambda 4 was present in all the B-cell but not in the T-cell lines tested. This site coincided with a strong B-cell-specific transcriptional enhancer (E lambda 2-4). This novel enhancer is active in myeloma cells, regardless of the status of endogenous lambda genes, but is inactive in a T-cell line and in fibroblasts. The enhancer E lambda 2-4 functions in the absence of the transcription factor NF kappa B, which is necessary for kappa enhancer function. No evidence could be found for NF kappa B binding by this element. Rearrangement of V lambda 2 to JC lambda 3 or JC lambda genes deletes E lambda 2-4; however, a second strong enhancer was found 35 kb downstream of C lambda 1, which cannot be eliminated by lambda gene rearrangements. The second lambda enhancer (E lambda 3-1) is 90% homologous to the E lambda 2-4 sequence in the region determined to comprise the active enhancer and likewise lacks the consensus binding site for NF kappa B. The data support a model for the independent activation of kappa and lambda gene expression based on locus-specific regulation at the enhancer level.

Sequence and linkage of the V kappa 21A and G germ-line gene segments in the mouse

The germ-line V gene segments encoding the subgroups A and G of the BALB/c V kappa 21 family were cloned and assigned to the previously described 30-kb cluster of the V kappa 21 family. Sequence comparison revealed close homology between the two gene segments at the DNA and the predicted amino acid sequence level, indicating that V kappa 21A and V kappa 21G originated by a rather recent gene duplication.