Localization of the murine lambda 5 gene on chromosome 16

The study of B cells and antibodies in Japan: a historical perspective

Japanese scientists were involved in pioneering work on therapeutic antisera and have made huge contributions to the characterization of the antibody molecules that are responsible for this and many other biological activities, as well as working back to understand the B cells that produce these Igs. This review emphasizes the role of Japanese immunologists in this field, starting with their work in developing antisera and studying the structure of Igs. It describes the molecular mechanisms that generate the enormous antibody repertoire and regulate B-cell development and signaling. It also details the importance of the germinal center in generating B-cell memory and the terminal differentiation of B cells as antibody-secreting plasma cells.

Powered by pairing: The surrogate light chain amplifies immunoglobulin heavy chain signaling and pre-selects the antibody repertoire

Selective expansion of functional pre-B cells is accomplished by the assembly of a signaling-competent pre-B cell receptor (pre-BCR) consisting of immunoglobulin mu heavy chains (muHC), surrogate light chains (SLC) and Igalpha/Igbeta. Here, we review recent data showing that muHCs, in the absence of SLC, deliver autonomous differentiation signals. However, enhanced signaling necessary for pre-B cell expansion requires cross-linking of pre-BCRs via the non-immunoglobulin tail of SLC's subunit lambda5. We also discuss how SLC's ability to modulate the strength of pre-BCR signals is controlled by a muHC's idiotype and its affinity to the chaperone BiP. In this model, BiP in concert with SLC functions as a pre-selector of the antibody repertoire.

The pre-B-cell receptor: selector of fitting immunoglobulin heavy chains for the B-cell repertoire

In this Opinion article, I address the role of the pre-B-cell receptor (pre-BCR) in the development of antigen-specific B cells in terms of immunoglobulin heavy chain (IgH) variable-region repertoire selection, precursor B-cell differentiation and proliferation, and IgH allelic exclusion. Comparisons with the role of the pre-T-cell receptor (pre-TCR) in T-cell development raise provocative questions. Why do B- and T-cell lineages both use a surrogate chain - the surrogate light chain and the pre-TCR alpha-chain, respectively - as a step to develop their repertoires of antigen-recognizing cells? What are the functions of the pre-BCR and pre-TCR in lymphocyte differentiation and antigen-receptor allelic exclusion? This article, together with the accompanying article by Harald von Boehmer, hopes to answer some of these questions.

VpreB1/VpreB2/lambda 5 triple-deficient mice show impaired B cell development but functional allelic exclusion of the IgH locus

At the precursor B cell stage during bone marrow B cell development, Ig muH chain associates with surrogate L (SL) chain, which is encoded by the three genes VpreB1, VpreB2, and lambda 5, to form the pre-B cell receptor (pre-BCR). Surface expression of the pre-BCR is believed to signal both proliferation and allelic exclusion of the IgH locus. Mice which lack either VpreB1/VpreB2 or lambda 5 show a lack of precursor B cell expansion but normal IgH allelic exclusion. This would suggest that one of either lambda 5 or VpreB can make a pre-BCR-like complex which is still able to signal allelic exclusion but not proliferation. To investigate this, we established mice lacking all components of the SL chain. These mice showed severely impaired B cell development which was similar to that previously found in mice lacking either lambda 5 or VpreB1/VpreB2. Surprisingly, the IgH locus was still allelically excluded and thus the SL chain appears not to be involved in allelic exclusion.

Characterization of the rat A2a adenosine receptor gene

To understand the molecular basis for the regulation of rat A2a adenosine receptor (A2a-R) expression, we have characterized the rat A2a-R gene and defined its promoter regions. Through a combination of restriction mapping and sequence analysis, we have demonstrated that the rat A2a-R gene is composed of two exons interrupted by a 7.2-kb intron. Primer extension and RNase protection on RNA isolated from PC12 cells suggested that the A2a-R gene encoded two clusters of alternative transcripts. The most upstream transcription start site was designated as +1. The sequence of the proximal 1.5 kb of 5'-flanking region demonstrated no potential TATA box, CCAAT box, or initiator element in the appropriate location. Varying lengths of 5'-flanking regions were inserted into a transient expression vector (pGL2-basic), which contained bacterial luciferase as the reporter gene, to determine its promoter region(s) in PC12 cells, CHOP cells, and C6 cells. Consistent with two clusters of transcription start sites, two independent functional promoter regions (designated P1, -67/-1; and P2, +272/+304) for the rat A2a-R gene were identified. Although both promoters are in use in PC12 cells, only P2 is active in CHOP cells, indicating possible cell line-specific usage of these two promoters.

Physical location of the human immunoglobulin lambda-like genes, 14.1, 16.1, and 16.2

The human immunoglobulin lambda-like (IGLL) genes, which are homologous to the human immunoglobulin lambda (IGL) light chain genes, are expressed only in pre-B cells and are involved in B cell development. Three IGLL genes, 14.1, 16.1, and 16.2 are present in humans as opposed to one, lambda 5 (Igll), found in the mouse. To precisely map the location of the human IGLL genes in relation to each other and to the human IGL gene locus, at 22q11.1-2, a somatic cell hybrid panel and pulsed field gel electrophoresis (PFGE) were used. Hybridization with a lambda-like gene-specific DNA probe to somatic cell hybrids revealed that these genes reside on 22q11.2 between the breakpoint cluster region (BCR) and the Ewing sarcoma breakpoint at 22q12 and that gene 16.1 was located distal to genes 14.1 and 16.2. Gene 14.1 was found by PFGE to be proximal to 16.2 by at least 30 kilobases (kb). A 210 kb Not I fragment containing genes 14.1 and 16.2 is adjacent to a 400 kb Not I fragment containing the BCR locus, which is just distal to the IGL-C (IGL constant region) genes. We have determined that the IGLL genes 14.1 and 16.2 are approximately 670 kb and 690 to 830 kb distal, respectively, to the 3'-most IGL-C gene in the IGL gene locus, IGL-C7. We thus show the first physical linkage of the IGL and the IGLL genes, 14.1 and 16.2. We discuss the relevance of methylation patterns and CpG islands to expression, and the evolutionary significance of the IGLL gene duplications. Consistent with the GenBank nomenclature, these human IGLL genes will be referred to as IGLL1 (14.1), IGLL2 (16.2), and IGLL3 (16.1), reflecting their position on chromosome 22, as established by this report.

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.

Organization and expression of the pseudo-light chain genes in human B-cell ontogeny

In pre-B cells, the mu chain is expressed at the cell surface in association with a "light chain surrogate" encoded by the V pre-B and the lambda-like genes. This mu-psi-L complex presumably triggers early steps of the B cell differentiation, possibly by controlling the Ig gene rearrangements. In the humans, the lambda-like complex contains 3 genes, located in the 22q11.2-q12.3 band, telomeric to the IGCL locus, with which they share a similar organization, pointing to a common genetic origin. Only one lambda-like gene, 14.1, is functional and specifically expressed with V pre-B in pre-B cells. This expression starts in cells which still have the IGH locus in germline configuration (pro-B stage) and ceases as soon as the IGL loci rearrange. These pre-B specific transcripts provide useful markers of cells of the B lineage in both physiological and pathological situations.

Pre-B lymphocyte-specific transcriptional control of the mouse VpreB gene

The VpreB genes, which encode surrogate immunoglobulin light chain molecules, are expressed as RNA almost exclusively in pre-B cells. We have investigated the transcriptional control mechanisms which are responsible for the pre-B cell-specific RNA expression of the mouse VpreB1 and VpreB2 genes. Nuclear run-on analyses demonstrate that the pre-B cell-specific expression of both VpreB genes is controlled primarily at the level of initiation of transcription. S1 nuclease protection-mapping defined two or three major start sites of transcription for the VpreB genes. To find a promoter and other potential cis-acting regulatory elements, a 700-bp fragment 5' of the transcription start sites of the VpreB1 gene was used in gene transfer experiments and found to act as a promoter in pre-B lymphocytes. Deletion experiments showed that 191 bp upstream of the most 5' transcription start site is required for the pre-B cell promoter activity. DNA sequence analysis of the 5' region of the mouse VpreB1, VpreB2 and human VpreB genes reveal that this region of approximately 200 bp is strongly conserved. This 200-bp promoter region contains several conserved nucleotide sequence motifs which may act to mediate the pre-B cell-specific transcription of the VpreB genes.

The human pre-B-specific lambda-like cluster is located in the 22q11.2-22q12.3 region, distal to the IgC lambda locus

The chromosomal location of the lambda-like gene cluster, a gene family selectively expressed in human pre-B cells, was analyzed by in situ hybridization with a probe specific for the lambda-like genes. This cluster mapped in the q11.2-q12.3 region of chromosome 22. The use of Burkitt lymphoma and myelogenous leukemia cell lines with translocations in the 22q11 region led to a refinement in the location according to the following order: cen----BCRL2, VpreB, IgV lambda 1----BCRL4, IgV lambda----IgC lambda----BCR----BCRL3, lambda-like----tel. Unlike those of the mouse system, the pre-B-specific genes VpreB and lambda-like do not belong to the same transcriptional unit.

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.

Restriction fragment analysis of V preB and lambda 5 within the genus Mus

DNA from a panel of inbred strains of mice and colony bred mice, isolated from different geographical locations, was hybridized to mouse V preB and lambda 5 probes under stringent conditions, indicating sequence similarities greater than 80%. The probe for lambda 5 detects one gene and the probe for V preB detects two genes (V preB1 and V preB2) in the inbred strains of mice examined under the stringency used. No restriction endonuclease fragment length polymorphisms (RFLP) were detected with the V preB and lambda 5 DNA probes among the inbred strains of mice using Bam HI and Hind III. Very few RFLP were detected among Mus musculus subspecies, and the intensity of the hybridization did not differ significantly with either DNA probe. The number of RFLP increased slightly when different species and subgenera were examined, and the intensity of the hybridization signal began to decrease in samples from the different subgenera, suggesting a slight decrease in sequence similarity for both V preB genes with increased time of divergence. Fewer RFLP were detected with the lambda 5 DNA probe. DNA from 11 different Mus species representing 4 subgenera, genetically isolated from laboratory mice for approximately 1-12 million years, continued to hybridize under high stringency conditions using both DNA probes. A comigrating lambda 5 and V preB restriction endonuclease fragment was detected in most of the samples examined, suggesting the close physical linkage of V preB1 and lambda 5 is maintained within the genus Mus. These results suggest that V preB1, V preB2 and lambda 5 have been present for over 12 million years.

The human Vpre B gene is located on chromosome 22 near a cluster of V lambda gene segments

The chromosomal location of the human VpreB gene was determined by Southern blotting analysis of restriction enzyme-digested DNAs from a panel of 17 mouse-human somatic cell hybrids. The pattern of hybridization of a Vpre B-specific probe in conjunction with earlier analysis of several marker genes allowed the following conclusions: 1) Vpre B is on human chromosome 22 within band 22q11.2 distal to the bcr-like gene, bcr-2 and proximal to the bcr-like gene, bcr-4. 2) Vpre B has been localized relative to several constitutional and tumor-specific breakpoints within 22q11.2, segregates in hybrids retaining 22q- chromosomes with some but not with all members of the V lambda 1 subgroup of the V lambda genes, and is amplified with these genes in K562 cells. 3) The order of the loci on chromosome 22 is centromere----bcr-2, Vpre B, V lambda 1----bcr-4----C lambda----bcr-1----bcr-3----sis.