The VpreB protein of the surrogate light-chain can pair with some mu heavy-chains in the absence of the lambda 5 protein

Nineteen different mu heavy-chains, seven of them not capable of forming a pre B cell receptor were expressed in Drosophila melanogaster Schneider cells together with either VpreB1, VpreB2, lambda5, or the complete surrogate light-chain to study their interactions in the formation of the pre B cell receptor. The lambda5 protein alone was unable to bind properly to any of the mu heavy-chains, while the VpreB proteins alone formed complexes with five of the mu heavy-chains. All mu heavy-chains incapable of forming a pre B cell receptor with surrogate light-chain were also incapable of complex formation with VpreB. The possible role of the VpreB/mu heavy-chain in allelic exclusion of the heavy-chain locus during B cell development is discussed.

Cutting edge: lack of peripheral B cells and severe agammaglobulinemia in mice simultaneously lacking Bruton's tyrosine kinase and the B cell-specific transcriptional coactivator OBF-1

OBF-1 is a B cell-restricted transcriptional coactivator that is recruited to octamer-containing promoters by interacting with the POU domain of Oct-1 or Oct-2. We have shown earlier that mice lacking OBF-1 were dramatically impaired in their ability to mount humoral immune responses and did not develop germinal centers in the spleen; however, they had a largely normal B cell development in the bone marrow. In this study, we demonstrate that OBF-1-deficient mice also have an early defect in B cell development and show that OBF-1-/- immature B cells are greatly impaired at the transition from the bone marrow to the spleen. In addition, when the OBF-1 mutation is combined to a mutation in the gene encoding Bruton's tyrosine kinase, a striking phenotype is observed. These double-deficient animals lack peripheral B cells and have virtually no serum Igs, thus closely resembling human X chromosome-linked agammaglobulinemia.

The roles of preB and B cell receptors in the stepwise allelic exclusion of mouse IgH and L chain gene loci

Membrane-bound preBCR of wild-type mice, and probably also preBCR-like V(preB) muH chain complexes in lambda5-deficient mice, signal allelic exclusion so that < 0.1% of all preB-II cells and all subsequent B lineage cells express two muH chains on their surface. On the other hand a large number of muH chains which are originally generated at the transition of preB-I to preB-II cells cannot pair with surrogate L chains, cannot form a preBCR on the surface and, hence, allow two H chain alleles to be productively rearranged in one B-lineage cell. By contrast membrane-bound BCR on immature B cells does not signal allelic or isotypic exclusion Of Ig kappaL and lambdaL chain gene loci. This allows the rearrangement machinery to remain active, and secondary L chain rearrangements on one kappaL chain allele are frequently observed. Rapid selection of fitting H/L chain pairs, forming BCR on the surface, allows B-lineage cells to enter the mature B cell pool where the rearrangement machinery is shut off, securing allelic exclusion of L chain loci in most B cells.

Frequencies of multiple IgL chain gene rearrangements in single normal or kappaL chain-deficient B lineage cells

PCR analyses of the kappaL chain locus in single B-lineage cells of wild-type, Ckappa-, or JCkappa-deficient homozygous or heterozygous mice often detect multiple in- and out-of-frame rearrangements at the kappaL and lambdaL loci. They are most frequent in small pre-BII cells and equally so in wild-type and kappaL chain-deficient cells. Hence, kappaL chain production appears not to inhibit secondary rearrangements. Around 20% of all small preBII cells express IgL chains in their cytoplasm. Cells with a first productive rearrangement on one allele are favored to enter the immature B cell compartment. Thus, allelic exclusion might be secured by control of accessibility of IgL chain loci for rearrangement and by rapid selection of cells with a fitting over those with a nonfitting IgL chain.

Effect of deregulated IL-7 transgene expression on B lymphocyte development in mice expressing mutated pre-B cell receptors

Deregulated overexpression of IL-7 under the control of the promoter of the Ealpha gene of MHC class II in IL-7-transgenic mice changes B cell development in wild-type mice and in mutants which limit B cell development at various cellular stages. While the introduction of deregulated IL-7 production does not change the size of the pro-B and pre-B I compartments in the bone marrow of wild-type and lambda5-/- mice, it increases these compartments 2.5- to fivefold in mice which cannot make immature and mature B cells, i. e. in RAG-2-/-, tmmuH-/-, and RAG-2-/- mice expressing a transgenic muH chain. Excessive IL-7 production also increases four- to fivefold the pre-B II compartment in all those mouse strains where it can be formed (i. e. in wild-type, lambda5-/- and muH chain-transgenic RAG-2-/- mice), while no pre-B- II-like cells appear in excessively IL-7-stimulated bone marrow of mice devoid of pre-B II cells (i. e. in tmmuH-/- and RAG-2-/- mice). In the spleen of all IL-7-transgenic mice significant numbers of both pro-B and pre-B I cells are detectable and increased numbers of pre-B II and immature B cells appear in the spleen of mouse strains which are capable of making them. The capacity of the spleen to accommodate expanded numbers of these B-lineage cells as well as mature B cells is much larger than that of the bone marrow of the IL-7-transgenic mice probably because the bone limits cellular expansion and provokes spillover into the peripheral lymphoid organs.

Four of five RAG-expressing JCkappa-/- small pre-BII cells have no L chain gene rearrangements: detection by high-efficiency single cell PCR

Single cell PCR assays have been further developed that detect over 80% of all VkappaJkappa, VkappaRS, and VlambdaJlambda rearrangements at efficiencies between 70% and 90%. These IgL chain gene rearrangement assays were used with small pre-BII cells that develop in comparably high numbers in the bone marrow of wild-type, Ckappa-deficient, and JCkappa-deficient homozygous and heterozygous mice. In all of these mice, only 15%-25% of all small pre-BII cells carry VlambdaJlambda rearrangements. These results confirm that lambdaL chain gene rearrangements occur independently of kappaL chain gene rearrangement and expression. They also show that a large part of the small pre-BII cells that express the rearrangement machinery can develop without IgL chain gene rearrangements.

Continued RAG expression in late stages of B cell development and no apparent re-induction after immunization

Models of B-cell development in the immune system suggest that only those immature B cells in the bone marrow that undergo receptor editing express V(D)J-recombination-activating genes (RAGs). Here we investigate the regulation of RAG expression in transgenic mice carrying a bacterial artificial chromosome that encodes a green fluorescent protein reporter instead of RAG2. We find that the reporter is expressed in all immature B cells in the bone marrow and spleen. Endogenous RAG messenger RNA is expressed in immature B cells in bone marrow and spleen and decreases by two orders of magnitude as they acquire higher levels of surface immunoglobulin M (IgM). Once RAG expression is stopped it is not re-induced during immune responses. Our findings may help to reconcile a series of apparently contradictory observations, and suggest a new model for the mechanisms that regulate allelic exclusion, receptor editing and tolerance.

B cells are programmed to activate kappa and lambda for rearrangement at consecutive developmental stages

Kappa and lambda, the two types of immunoglobulin light (L) chains present in mammals, contribute differently to the L chain pool of each species. Here we show that the extreme preponderance of kappa in the mouse results from programmed sequential activation of the kappa and lambda loci. Activation--a prerequisite of rearrangement--was monitored by analyzing transcription of unrearranged J-C clusters. Upon in vitro differentiation of a rearrangement-deficient pro/pre-B line, germ-line transcripts of the lambda J-C clusters, that are newly described here, became detectable 2 days later than their counterparts of J-C kappa. Clear differences could also be observed in vivo: germ-line transcripts of kappa were already present in large B220+ CD25+ pre B-II cells whereas germ-line lambda transcripts first became detectable at the consecutive developmental stage of small B220+ CD25+ pre-B-II cells. This activation pattern was found to be identical in mice which can not rearrange kappa due to a targeted deletion or inactivation of kappa. This suggests that pre-B-II cells follow a hit-and-run mechanism of development which includes programmed transitions and differential activation of the L chain loci, i.e. kappa first, then lambda. Thus, privileged activation of kappa might be the decisive factor in setting the 10:1 ratio of kappa to lambda present in the mouse.

Independent regulation of the two Pax5 alleles during B-cell development

The developmental control genes of the Pax family are frequently associated with mouse mutants and human disease syndromes. The function of these transcription factors is sensitive to gene dosage, as mutation of one allele or a modest increase in gene number results in phenotypic abnormalities. Pax5 has an important role in B-cell and midbrain development. By following the expression of individual Pax5 alleles at the single-cell level, we demonstrate here that Pax5 is subject to allele-specific regulation during B-lymphopoiesis. Pax5 is predominantly transcribed from only one allele in early progenitors and mature B cells, whereas it switches to a biallelic transcription mode in immature B cells. The allele-specific regulation of Pax5 is stochastic, reversible, independent of parental origin and correlates with synchronous replication, in contrast with imprinted and other monoallelically expressed genes. As a consequence, B-lymphoid tissues are mosaics with respect to the transcribed Pax5 allele, and thus mutation of one allele in heterozygous mice results in deletion of the cell population expressing the mutant allele due to loss of Pax5 function at the single-cell level. Similar allele-specific regulation may be a common mechanism causing the haploinsufficiency and frequent association of other Pax genes with human disease.

The transcription factor early growth response 1 (Egr-1) advances differentiation of pre-B and immature B cells

In mature B lymphocytes, the zinc finger transcription factor early growth response 1 (Egr-1) is one of the many immediate-early genes induced upon B cell antigen receptor engagement. However, its role during earlier stages of lymphopoiesis has remained unclear. By examining bone marrow B cell subsets, we found Egr-1 transcripts in pro/pre-B and immature B lymphocytes, and Egr-1 protein in pro/pre-B-I cells cultivated on stroma cells in the presence of interleukin (IL)-7. In recombinase-activating gene (RAG)-2-deficient mice overexpressing an Egr-1 transgene in the B lymphocyte lineage, pro/pre-B-I cells could differentiate past a developmental block at the B220(low) BP-1(-) stage to the stage of B220(low) BP-1(+) pre-B-I cells, but not further to the B220(low) BP-1(+) CD25(+) stage of pre-B-II cells. Therefore, during early B lymphopoiesis progression from the B220(low) BP-1(-) IL-2R- pro/pre-B-I stage to the B220(low) BP-1(+) IL-2R+ pre-B-II stage seems to occur in at least two distinct steps, and the first step to the stage of B220(low) BP-1(+) pre-B-I cells can be promoted by the overexpression of Egr-1 alone. Wild-type mice expressing an Egr-1 transgene had increased proportions of mature immunoglobulin (Ig)M+ B220(high) and decreased proportions of immature IgM+ B220(low) bone marrow B cells. Since transgenic and control precursor B cells show comparable proliferation patterns, overexpression of Egr-1 seems also to promote entry into the mature B cell stage. Analysis of changes in the expression pattern of potential Egr-1 target genes revealed that Egr-1 enhances the expression of the aminopeptidase BP-1/6C3 in pre-B and immature B cells and upregulates expression of the orphan nuclear receptor nur77 in IgM+ B cells.

Expression level of a transgenic lambda2 chain results in isotype exclusion and commitment to B1 cells

Two new lambda2 chain-transgenic mouse lines were established, both of which showed stable transgene expression during aging of the mice. The line L23, which expressed the transgene at low levels, exhibited normal B cell development, antibody responses and serum Ig levels. Most of the B cells in this mouse line co-expressed the transgenic lambda2 chain together with an endogenous kappa chain, thus showing poor allelic exclusion of endogenous L chains. On the other hand, high expression of the transgenic lambda2 chain in the other mouse line, L2, resulted in nearly complete exclusion of endogenous L chain isotypes. In this line, the lambda2 transgene was already detectable in the cytoplasm of all preB-II cells and some pro/preB-I cells. Its expression during these early phases obviously inhibited development of conventional B2 cells, since the B cells in the periphery of these mice were almost exclusively of the B1 type. This finding was confirmed by adoptive transfer of transgenic bone marrow into lethally irradiated recipients. Very few B cells were present in the spleen of such recipients. The serum IgM levels of L2 mice were close to normal and the majority of these IgM were associated with the transgenic lambda2 chain. Antibody responses to thymus-dependent antigens in such mice were almost exclusively found to be of IgM class. Together, these findings indicate a developmental bias leading to a predominance of B1 cells in the L2 line.

Identification of BSAP (Pax-5) target genes in early B-cell development by loss- and gain-of-function experiments

The Pax-5 gene codes for the transcription factor BSAP which is essential for the progression of adult B lymphopoiesis beyond an early progenitor (pre-BI) cell stage. Although several genes have been proposed to be regulated by BSAP, CD19 is to date the only target gene which has been genetically confirmed to depend on this transcription factor for its expression. We have now taken advantage of cultured pre-BI cells of wild-type and Pax-5 mutant bone marrow to screen a large panel of B lymphoid genes for additional BSAP target genes. Four differentially expressed genes were shown to be under the direct control of BSAP, as their expression was rapidly regulated in Pax-5-deficient pre-BI cells by a hormone-inducible BSAP-estrogen receptor fusion protein. The genes coding for the B-cell receptor component Ig-alpha (mb-1) and the transcription factors N-myc and LEF-1 are positively regulated by BSAP, while the gene coding for the cell surface protein PD-1 is efficiently repressed. Distinct regulatory mechanisms of BSAP were revealed by reconstituting Pax-5-deficient pre-BI cells with full-length BSAP or a truncated form containing only the paired domain. IL-7 signalling was able to efficiently induce the N-myc gene only in the presence of full-length BSAP, while complete restoration of CD19 synthesis was critically dependent on the BSAP protein concentration. In contrast, the expression of the mb-1 and LEF-1 genes was already reconstituted by the paired domain polypeptide lacking any transactivation function, suggesting that the DNA-binding domain of BSAP is sufficient to recruit other transcription factors to the regulatory regions of these two genes. In conclusion, these loss- and gain-of-function experiments demonstrate that BSAP regulates four newly identified target genes as a transcriptional activator, repressor or docking protein depending on the specific regulatory sequence context.

Loss- and gain-of-function mutations reveal an important role of BSAP (Pax-5) at the start and end of B cell differentiation

Pax-5 codes for the transcription factor BSAP which is expressed throughout B cell development except in terminally differentiated plasma cells. Gene targeting experiments in the mouse revealed a differential dependency of fetal and adult B-lymphopoiesis on this transcription factor. BSAP is required for B-lineage commitment in the fetal liver and for progression beyond an early pro-B cell stage in adult bone marrow. The characterization of Pax-5-deficient pro-B cells demonstrated an important role of BSAP in the regulation of the CD19, mb-1 (Ig alpha) and N-myc genes as well as in the developmental pathway controlling VH-to-DHJH recombination at the immunoglobulin heavy-chain (IgH) locus. The human PAX-5 gene was recently shown to participate together with the IgH locus in the chromosomal translocation t(9;14)(p13;q32). This translocation is characteristic of a small subset of non-Hodgkin lymphomas exhibiting plasmacytoid differentiation. The translocated PAX-5 gene is deregulated by the insertion of IgH regulatory elements into its 5' region, which may contribute to tumorigenesis by interfering with the shut-down of PAX-5 transcription and thus with the completion of plasma cell differentiation.

Human myelomonocytic cells express an inhibitory receptor for classical and nonclassical MHC class I molecules

Leukocyte activation can be negatively regulated by inhibitory receptors specific for MHC class I molecules. While one inhibitory receptor, Ig-like transcript 2 (ILT2), is expressed by all lymphoid and myelomonocytic cell types, other receptors display a more selective tissue distribution. Here we characterize an inhibitory receptor, termed ILT4, which is selectively expressed in monocytes, macrophages, and dendritic cells (DCs), binds classical class I molecules and the nonclassical class I molecules HLA-G, and transduces negative signals that can inhibit early signaling events triggered by stimulatory receptors. ILT4 may control inflammatory responses and cytotoxicity mediated by myelomonocytic cells and may modulate their Ag-presenting functions, focusing immune responses to microbial challenges and avoiding autoreactivity.

Induction of nuclear factor-kappa B during primary B cell differentiation

We have investigated activation of nuclear factor-kappa B (NF-kappa B) in the process of primary B cell differentiation in vitro. In this system, NF-kappa B is strongly induced when B cells develop from the pre-B cell to the immature B cell stage. Unlike the typical NF-kappa B activation in response to exogenous stimuli, induction proceeds with a slow time course. NF-kappa B induction is only observed in B cells that undergo differentiation, not in Rag2-deficient cells. Nuclear DNA binding complexes predominantly comprise p50/RelA heterodimers and, to a lesser extent, c-Rel-containing dimers. The increase in NF-kappa B binding activity is accompanied by a slow and steady decrease in I kappa B beta protein levels. Interestingly, absolute RelA protein levels remain unaffected, whereas RelB and c-Rel synthesis is induced. The reason for preferential nuclear translocation of RelA complexes appears to be selective inhibition by the I kappa B beta protein. I kappa B beta can efficiently inhibit p50/RelA complexes, but has a much reduced ability to interfere with p50/c-Rel DNA binding both in vitro and in vivo. Interestingly, p50/RelB complexes are not at all targeted by I kappa B beta, and coimmunoprecipitation experiments show no evidence for an association of I kappa B beta and RelB in vivo. Consistent with these observations, I kappa B beta cotransfection can inhibit p50/RelA-mediated trans-activation, but barely affects p50/RelB mediated trans-activation.

Fetal liver organ cultures allow the proliferative expansion of pre-B receptor-expressing pre-B-II cells and the differentiation of immature and mature B cells in vitro

We describe the phenotypic and functional properties of B lineage cells developing in fetal liver organ cultures (FLOC) of mouse embryos at day 14 or 15 of gestation which contain pro/pre-B-I cells. FLOC B cell development proceeds to mature IgM+, IgD+ and CD23+ lipopolysaccharide-reactive B cells within a culture period of 5-6 days. The phenotypes and relative proportions of pro/pre-B-I, pre-B-II, immature and mature B cells from FLOC were similar to that seen in livers freshly isolated from age-matched, i.e. newborn, mice. More importantly, the numbers of cells recovered in the different B lineage subpopulations from FLOC were close to those developed in vivo. Hence, in contrast to single-cell suspension cultures of fetal liver, FLOC allow the proliferative expansion of pre-B cell receptor-expressing pre-B-II cells. FLOC from embryos of mice with targeted mutations in the RAG-2 and lambda5 genes, which cannot expand by proliferative expansion of their pre-B-II compartment in vivo because they cannot express a pre-B cell receptor on their surface, show this same defect in vitro. FLOC are accessible to the action of mAb and cytokines. Thus, addition of anti-IL-7 receptor mAb to FLOC of normal mice inhibits B cell development at the transition of pro/pre-B-I to pre-B-II cells. This inhibition is reversed by addition of excess rIL-7. Addition of IL-7 alone stimulates the proliferation of pro/pre-B-I cells and inhibits their differentiation to pre-B-II and immature B cells, as it does in single-cell suspension cultures. FLOC should be useful to study the effects of other mAb, cytokines, ligands and other molecules on early B cell development.

Structure and expression of the c-Myc/Pvt 1 megagene locus

A chromosomal translocation (Tx) that interrupts the transcription of either c-Myc or Pvt 1 is the principal lesion in many B cell malignancies including Burkitt's Lymphoma (BL), AIDs-NHL, mouse plasmacytoma (Pct) and possibly multiple myeloma (MM). There is a restriction associated with this Tx such that only the immunoglobulin (Ig) heavy chain gene is found juxtaposed to c-Myc and only the Ig light chain gene is found juxtaposed to Pvt 1. Over the past several years, our laboratory has been instrumental in the elucidation of the structure of the mouse Pvt 1 locus as a means of understanding the relationship between these two divergent Txs which, nevertheless, produce indistinguishable disease phenotypes. In the mouse, we have identified a uniform Pvt1/Ig Ck fusion product which is consistently found in all tumors harboring Pvt 1 associated Txs. We have recently constructed transgenic mice harboring a translocated Pvt 1/Ck segment in order to determine whether 1). these mice produce the Pvt 1/Ck fusion product 2). these mice are immunocompromised and 3). these mice develop tumors of a B cell origin.

A functional B cell receptor transgene allows efficient IL-7-independent maturation of B cell precursors

IL-7 supports the proliferation of B cell precursors, but inhibits their maturation to mature surface IgM+ (sIgM+) B cells. This inhibition is thought to occur by direct or indirect down-regulation of recombinase genes, preventing the B cells from undergoing Ig light chain rearrangements. To directly analyze the IL-7 inhibitory effects, we studied B cell development and maturation in B cells bearing a transgenic (Tg) B cell receptor (BCR). We show here that proliferation of Tg B cell precursors is IL-7 dependent both in vivo and in vitro and is comparable to that of non-Tg B cell precursors. Tg B cell precursors grown on stroma and IL-7 expressed sIgM on >90% of the cells, and a large proportion of these cells coexpressed additional maturation markers such as IgD, CD23, CD21, and L-selectin, indicating that IL-7 does not inhibit maturation of Tg B cell precursors. The presence of the Tg inhibited V(D)J recombination in the cultured cells, as very low levels of recombination activating genes 2 (RAG-2) expression and endogenous V-Jkappa DNA rearrangements were found. Expression levels of RAG mRNAs were not significantly changed after removal of IL-7 from the in vitro Tg B cell cultures. In contrast, we found that IL-7 inhibited maturation of non-Tg B cell precursors and that removal of IL-7 resulted in a significant increase in RAG-2 expression and kappa rearrangements, thus allowing the B cells to express sIgM and to mature. These results suggest that IL-7-mediated inhibition of Ig gene rearrangement blocks maturation of B cell precursors and that the presence of Tg BCR efficiently circumvents this inhibition.

A functional B cell receptor transgene allows efficient IL-7-independent maturation of B cell precursors

IL-7 supports the proliferation of B cell precursors, but inhibits their maturation to mature surface IgM+ (sIgM+) B cells. This inhibition is thought to occur by direct or indirect down-regulation of recombinase genes, preventing the B cells from undergoing Ig light chain rearrangements. To directly analyze the IL-7 inhibitory effects, we studied B cell development and maturation in B cells bearing a transgenic (Tg) B cell receptor (BCR). We show here that proliferation of Tg B cell precursors is IL-7 dependent both in vivo and in vitro and is comparable to that of non-Tg B cell precursors. Tg B cell precursors grown on stroma and IL-7 expressed sIgM on &gt;90% of the cells, and a large proportion of these cells coexpressed additional maturation markers such as IgD, CD23, CD21, and L-selectin, indicating that IL-7 does not inhibit maturation of Tg B cell precursors. The presence of the Tg inhibited V(D)J recombination in the cultured cells, as very low levels of recombination activating genes 2 (RAG-2) expression and endogenous V-Jkappa DNA rearrangements were found. Expression levels of RAG mRNAs were not significantly changed after removal of IL-7 from the in vitro Tg B cell cultures. In contrast, we found that IL-7 inhibited maturation of non-Tg B cell precursors and that removal of IL-7 resulted in a significant increase in RAG-2 expression and kappa rearrangements, thus allowing the B cells to express sIgM and to mature. These results suggest that IL-7-mediated inhibition of Ig gene rearrangement blocks maturation of B cell precursors and that the presence of Tg BCR efficiently circumvents this inhibition.

The chemokine SDF-1, stromal cell-derived factor 1, attracts early stage B cell precursors via the chemokine receptor CXCR4

In the bone marrow, progenitor (pro-) and precursor (pre-) B cells depend on close contact with stromal cells for growth and maturation. Stromal cell-derived factor 1 (SDF-1), also known as pre-B cell growth-stimulating factor, is produced by bone marrow stromal cells and was reported to act together with interleukin-7 as co-mitogen for pre-B cells. SDF-1 was recently shown to be a chemokine which is chemotactic for different types of leukocytes and acts via the chemokine receptor CXCR4. Using sorted B220+ bone marrow cells and several B cell lines characteristic for different stages of B lymphopoiesis, we now show that SDF-1 is a potent attractant for pro- and pre-B cells, but is inactive on B cells at later stages of development. In early B cell precursors, SDF-1 induced intracellular Ca2+ mobilization and in vitro migration with a potency and efficacy similar to that observed for chemokines acting on blood leukocytes. These responses were mediated via CXCR4 as they could be inhibited by an antireceptor antibody. SDF-1 is the first chemokine shown to act on early-stage B cell precursors. Mice lacking SDF-1 die perinatally and show a severe deficiency in B lymphopoiesis. We propose that SDF-1 released from the stromal cells exerts its critical hematopoietic function by selectively attracting and confining early B cell precursors within the bone marrow microenvironment that provides the necessary factors for growth and differentiation.

B lineage-restricted rearrangement of a human Ig kappa transgene

To study the control of immunoglobulin kappa light chain gene rearrangement, we generated transgenic mice carrying a germ-line human kappa minilocus (HK) containing the J kappa-proximal V gene, V kappa IV, the V-J intergenic region, the five J kappa segments and the C kappa gene. This construct includes the intronic, but not the 3' kappa enhancer. Rearrangement of the HK transgene was found to be lymphoid specific and restricted to the B cell lineage. Quantification of kappa gene rearrangement in pre-B cell lines established from HK transgenic mice showed that, like endogenous kappa genes, rearrangement of the transgene is repressed in mu-negative early B cell precursors. These results indicate that rearrangement of the HK transgene is subjected to the same B/T cell and developmental regulation as V kappa-J kappa rearrangement at the endogenous locus. Comparison with an unrearranged kappa transgenic construct lacking the V-J intergenic region, suggests that this region, or elements associated with the proximal V gene, may act to restrict kappa gene rearrangement to the B cell lineage.

Essential functions of Pax5 (BSAP) in pro-B cell development: difference between fetal and adult B lymphopoiesis and reduced V-to-DJ recombination at the IgH locus

The Pax5 gene coding for the transcription factor BSAP has an essential role in B lymphopoiesis and midbrain development. Here we present a detailed analysis of the B-cell phenotype of Pax5 mutant mice that revealed a differential dependency of fetal and adult B lymphopoiesis on this transcriptional regulator. B-cell development is arrested in the bone marrow at the early pro-B (pre-BI) cell stage, which is characterized by expression of the early markers c-kit, CD43, lambda5, VpreB, and HSA and the absence of the later markers CD25 and BP-1. These pre-BI cells fail to express the BSAP target gene CD19 and are capable of long-term proliferation in vitro in the presence of stromal cells and IL-7. B-lymphoid progenitors could not be detected in the fetal liver of Pax5 mutant embryos. However, Pax5-deficient fetal liver cells gave rise to the development of pre-BI cells in bone marrow on transplantation into lethally irradiated mice. These data indicate different functions of Pax5 in the distinctive microenvironments of fetal liver and adult bone marrow. As shown by PCR analyses, the pre-BI cells in Pax5-deficient bone marrow have undergone D(H)-to-J(H) rearrangement of the immunoglobulin heavy-chain locus at normal frequency. In contrast, V(H)-to-D(H)J(H) rearrangements were reduced approximately 50-fold in Pax5-deficient pre-BI cells, suggesting a role for Pax5 in the developmental pathway controlling V-to-DJ recombination.

Ordering of human bone marrow B lymphocyte precursors by single-cell polymerase chain reaction analyses of the rearrangement status of the immunoglobulin H and L chain gene loci

CD19+CD10+ human B lineage bone marrow cells were separated into cycling or resting cells, which differ in their expression of CD34, VpreB, recombination activating gene (RAG-1), and terminal deoxynucleotidyl transferase (TdT). Polymerase chain reaction analyses developed for DHJH and VkJk, VkJkK(de) and VkK(de) rearrangements with DNA of single cells and a comparison with B lineage cell development in mouse bone marrow, allow to delineate the human B lymphocyte pathway of development as follows: CD34+VpreB+RAG-1+TdT+, DHJH-rearranged, kL germline cycling pre-B I cells-->CD34-VpreB+microH chain+ (pre-B receptor+) RAG-1-TdT-, VHDHJH-rearranged, kL germline, cycling pre-B II cells-->CD34-VpreB-, intracytoplasmic microH chain+ (pre-B receptor-) RAG-1+/-TdT-, VHDHJH-rearranged, mainly kL germline cycling pre-B II cells-->CD34-VpreB-intracytoplasmic microH chain+, RAG-1+TdT-, VHDHJH-rearranged, VkJk-rearranged, IgM-, resting pre-B II cells CD34+VpreB-, sIgM+, RAG-1+TdT-, VHDHJH- and VkJk-rearranged IgM+ immature B cells-->CD34-, CD10-, sIgM+/sIgD+ mature B cells. This order, for the first time established for human B lineage cells, shows striking similarities with that established for mouse B lineage cells in bone marrow.

B-cell-specific coactivator OBF-1/OCA-B/Bob1 required for immune response and germinal centre formation

The B-lymphocyte-specific transcriptional factor called Oct binding factor (OBF)-1, OCA-B or Bob1 (refs 1-3) is thought to be involved in the transcription of immunoglobulin genes through recruitment to the highly conserved octamer site of immunoglobulin promoters, mediated by either Oct-1 or Oct-2. To define the in vivo role of OBF-1 we have used gene targeting in embryonic stem cells to generate mice lacking the coactivator OBF-1. Such OBF-1-/- mice are born normally, are fertile and seem healthy, and surprisingly, rearrangement and transcription of immunoglobulin genes are largely unaffected. However, mice deficient in OBF-1 have reduced numbers of mature B cells and a severe reduction in the number of recirculating B cells, but otherwise show normal B-cell differentiation. Serum IgA and particularly IgG levels are greatly reduced. If mutant mice are immunized with either a thymus-independent or a thymus-dependent antigen, their immune responses are dramatically weakened. Strikingly, germinal centres completely fail to develop after immunization with thymus-dependent antigen. Our results demonstrate that in vivo OBF-1 is not required for initial transcription of immunoglobulin genes or for B cell development, but instead is essential for the response of B cells to antigens, and is required for the formation of germinal centres.

The SCID but not the RAG-2 gene product is required for S mu-S epsilon heavy chain class switching

We have investigated the capacity of precursor B cells from normal (BDF1) and V(D)J recombinase-deficient (RAG-27) or defective (SCID) mice to be induced by a CD40-specific monoclonal antibody and IL-4 to epsilon H chain gene transcription and to S mu-S epsilon switch recombination. In differentiating precursor B cells from all three strains of mice, the development of similar numbers of CD19+, CD23+, CD40+, and MHC class II+ expressing B lineage cells and similar levels of epsilon H chain gene transcription were induced. Efficient S mu-S epsilon switching occurred in normal and RAG-2-deficient, but not in SCID, precursor B cells. Thus, the transcription of the epsilon H chain is independent of the RAG-2 and the SCID gene product, while the S mu-S epsilon switch recombination requires the SCID gene-encoded DNA-dependent protein kinase, but not the RAG-2 protein.

The half-life of RAG-1 protein in precursor B cells is increased in the absence of RAG-2 expression

Site-specific recombination of immunoglobulin and T cell receptor gene segments in B and T lymphocytes is dependent on the expression of two recombinant activation genes, Rag-1 and Rag-2. Here, we show that RAG-1 protein turnover in pre-B cells depends on the expression of RAG-2. The apparent half-life of RAG-1 protein is increased when RAG-2 is not expressed in differentiating pre-B cells.

A subpopulation of B220+ cells in murine bone marrow does not express CD19 and contains natural killer cell progenitors

Bone marrow of both normal and rearrangement-deficient mice contains a small population of B220(CD45R)+ cells, which do not express the B lineage marker CD19. Instead, part of this population coexpresses the surface marker CD43 and lacks or expresses very low levels of heat stable antigen (HSA) and BP-1, thus representing a part of Hardy's fraction A (B220(+)-CD43+HSA-, BP-1-) of B lineage development. However, some 20-40% of these B220(+)-CD19- cells also coexpress the NK1.1 surface molecule and do not express genes like VpreB or B29 restricted to the B cell lineage. These cells respond to recombinant interleukin 2 in vitro, and develop into killer cells that can lyse the prototypic NK target tumor cell, YAC-1, as well as syngeneic normal lipopolysaccharide or concanavalin A blasts, providing they lack the surface expression of major histocompatibility complex class I molecules. The implications of these findings for studies on B lymphopoiesis are discussed. It is suggested that the CD19-specific monoclonal antibody is more reliable, as in humans, than B220(CD45R) to detect B lineage cells in mice.

Induction of sterile transcription from the kappa L chain gene locus in V(D)J recombinase-deficient progenitor B cells

B cell development in RAG-2-deficient (RAG-2T) mice is impeded at an early stage, due to the inability of these animals to rearrange their endogenous ig gene loci. Expression of an E mu-bcl-2 transgene in these mice did not change this phenotype. However, stromal cell/IL-7-reactive B cell progenitors (pro-B cells) were found in fetal live and bone marrow of RAG-2T and RAG-2T/E mu-bcl-2 transgenic mice in numbers comparable to normal mice. Like cells from normal mice they are c-kit+, surrogate L chain+ and CD25-, and can proliferate in vitro for long periods of time. Upon IL-7 deprivation, they can be induced to differentiate into c-kit-, surrogate L chain- and CD25+ cells that are no longer clonable on stromal cells and IL-7. Furthermore, sterile transcription from the kappa L chain gene loci is induced. The latter was also observed with pro-B cells directly isolated ex vivo from the bone marrow of RAG-2-deficient animals. The results suggest that progenitor B cell differentiation can occur in cells from V(D)J recombinase-deficient mice to the stage where kL chain gene rearrangements would normally be initiated. It further indicates that some molecular programs of early B cell differentiation can take place in the absence of Ig gene rearrangements.

Intra- and extra-thymic expression of the pre-T cell receptor alpha gene

We have analyzed pre-T cell receptor alpha (pT alpha) gene expression in cells from various anatomical sites to investigate the lineage specificity of pT alpha RNA as well as its presence in pro-T cells and in sites of extrathymic T cell development. pT alpha RNA is found in precursors of alpha beta T cells but is absent from mature alpha beta T cells as well as T cells that express the gamma delta T cell receptor on the cell surface. pT alpha expression is exquisitely T lineage specific in that mature and immature B cells, myeloid cells, NK cells and pluripotent stem cells are pT alpha negative. On the other hand, pT alpha expression is found in pro-T cells outside the thymus as well as in intra- and extra-thymic sites of T cell development. The latter finding is consistent with the notion that early steps of T cell development within and outside the thymus may be similar.

Stimulation by T cell independent antigens can relieve the arrest of differentiation of immature auto-reactive B cells in the bone marrow

The pair of microH-chain and kappa L-chain transgenes encoding the Sp6 TNP/DNA-specific IgM was bred onto the rearrangement-deficient genetic background of RAG-2T mice, and onto the kappa L-chain expression-deficient background of iE kappa T mice. Bone marrow of Sp6 transgenic RAG-2T mice contained normal numbers of B220(CD45R)+c-kit+ pro/preB-I-like cells and normal numbers of B220(CD45R)+TAC+ preB-II-like cells. Most strikingly, the numbers of immature sIgM+ B cells in the bone marrow were at least five-fold lower than normal, while mature B cells were almost undetectable in bone marrow as well as spleen. Hence, B cell development in these mice appears to be arrested at the transition from preB-II to immature B cells. The contents of bone marrow and spleen of the different precursors, immature and mature B cell compartments in Sp6iE kappa T mice were found to be similar to those of normal mice except that all sIg+ cells expressed lambda L-chains, of which 40% coexpressed the transgenic kappa L-chain. It indicates that the repertoire of lambda L-chain rearrangements and the lambda L-chains expressed from it suffices to relieve the arrest of differentiation seen in Sp6RAG-2T mice. The T cell-independent antigen TNP-Ficoll elicited within 5 days a response of the Sp6RAG-2T mice to develop to IgM-secreting cells and to fill the serum pool with the Sp6 transgenic IgM to 100 micrograms/ml, i.e. to normal serum levels of IgM in normal mice. TNP-Ficoll appears to interfere with the arrest of differentiation. Two scenarios for this arrest of differentiation and its relief by the T-independent antigen TNP-Ficoll are discussed.

The status of Ig loci rearrangements in single cells from different stages of B cell development

Differential expression of c-kit, CD25 (TAC), surrogate L chain and cytoplasmic muH chain, and surface expression of IgM and IgD allows the separation of B220 (CD45+) B cell subpopulations. PCR analyses with DNA of single cells developed by others and by us have been used to monitor the conformation of the Ig H and L chain gene loci in these different B lineage subpopulations. The results of these analyses indicate that B220+/c-kit+/CD25- cells are the precursors of large B220+/CD25+/sIgM- which, in turn, are the precursors of small B220+/CD25+/sIgM- cells. The majority of B220+/c-kit+/CD25- cells are DHJH-rearranged, with L chain loci in germline configuration and are thus pre-B I cells. More than 90% of all large B220+/CD25+/sIgM- cells have at least one H chain locus VHDHJH rearranged; half of them have also the second locus VHDHJH rearranged and are thus large pre-B II cells. Rearrangements of at least one allele of the kappa L chain loci become detectable in 65% of the small B220+/CD25+/sIgM- cells, 67% of the immature B and > 75% of the mature B cells. The ratio of kappa L to lambda L gene rearrangements in all three subpopulations is approximately 10:1, indicating that the kappa L/lambda L ratio is established as soon as rearrangements are made.

In-vitro analyses of mechanisms of B-cell development

B-cell lymphopoiesis in vivo is very complex due to the influences of cooperating cells, cytokines and other receptor-ligand interactions which appear to occur developmentally at different cellular stages. Therefore in-vitro models will help to unravel this complex situation. Here, we review our and others' work on in-vitro models of B-cell development. The role of stromal cells, cytokines, surrogate light chain and products of rearranged Ig-loci in the developmentally different cellular stages will be discussed.

Positive and negative selection events during B lymphopoiesis

Early in B-cell development, large numbers of cells have to be generated, each of which expresses only one type of B-cell receptor (i.e. Ig) on its surface. This is achieved by the surface expression of a pre-B cell receptor containing a mu heavy chain/surrogate light chain which differentially provides signals for two responses of precursor B cells at this stage of development. On the one hand, it signals inhibition of further rearrangements of variable heavy chain to diverse-joining heavy chain loci to achieve allelic exclusion at the heavy-chain locus. On the other hand, it signals proliferative expansion by factors between 20 and 100. Later in B-cell development, tolerance to autoantigens must be established and maintained. Tolerance is achieved by developmental arrest and induction of secondary light-chain gene rearrangements in those IgM+ immature B cells that are reactive to autoantigens presented in the primary B-cell generating organs. Even later in development, when mature surface (s)IgM+/sIgD+ B cells encounter autoantigens presented to them in the periphery, either deletion or anergy of the autoantigen-reactive cells occurs. Anergic cells have a sIg-dependent, sIg-proximal defect in signaling and are short-lived. Anergy can be broken in vitro by polyclonal activation via ligation of CD40 in the presence of IL-4. A small part of the remaining immature B cells not reactive to autoantigens are selected to become mature, antigen-reactive sIgM+/sIgD+ B cells. Molecules which might guide such positive selection of B cells still remain to be identified.

Stimulation of defective DNA transfer activity in recombination deficient SCID cell extracts by a 72-kDa protein from wild-type thymocytes

The SCID (Severe Combined Immune Deficiency) mutation causes two DNA recombination deficiencies: an aberrant joining of V(D)J immunoglobulin gene elements and a failure to perform efficient repair of DNA double-strand breaks. A recently established cell-free assay for DNA transfer (DTA) was applied to study nuclear extracts from normal and SCID-derived cells. The recombination deficiency was reflected in the cell-free system: SCID lymphocyte and fibroblast extracts showed reduced levels of DTA activity on a variety of DNA substrates. Analysis of nuclear extracts prepared from wild-type thymocytes and B cells representing different stages in lymphocyte ontogeny revealed the highest activities at the most immature stages. With progression of development, DTA activity decreased. Corresponding to their early developmental arrest, V(D)J rearrangement-incompetent RAG-2-/- lymphocyte extracts show high DTA activity. In contrast, extracts from SCID early lymphocytes express very low DNA transfer activity. Induction of V(D)J rearrangement in vivo in a normal preB cell line lead to a co-induction of the cell-free recombination activity. This indicates a development stage specificity of cell-free DNA recombination, which temporally parallels V(D)J recombination. A protein could be purified to near-homogeneity from wild-type thymocytes which stimulates the recombination activity specifically in SCID thymocyte and proB cell extracts. This protein, SRSP (SCID Recombination Stimulatory Protein), migrates as a single band of approximately 72 kDa in SDS-polyacrylamide gel electrophoresis.

Precursor B cells of mouse bone marrow express two different complexes with the surrogate light chain on the surface

Two monoclonal antibodies raised against the complex of mu heavy (H) chain and Vpre-B/lambda 5 surrogate light (L) chains recognize surrogate L chain in different conformations on normal pre-B cells. One, LM34 recognizes free lambda 5 protein and free lambda 5/Vpre-B surrogate L chains and binds to surrogate L chains on the surface of early, pro-B and pre-B-I cells where the surrogate L chain is associated with a gp130/gp35-65 complex of proteins. It also recognizes the surrogate L chain associated with the mu H chain on pre-B-II cells. The other monoclonal antibody, SL156, does not recognize free surrogate L chain or its components, nor its complex with gp130/gp35-65 on pro-B and pre-B-I cells. However, it does bind to a conformational epitope on the surrogate light chain/mu H chain complex on a subpopulation of pre-B-II cells and on mu H chain-positive pre-B cell lines. On mouse precursor B cells prepared ex vivo on ice, expression of the surrogate L chain is very low and almost undetectable. Incubation of the precursor cells for 1 h at 37 degrees C up-regulates the surface expression of surrogate L chain associated with gp130/gp35-65 (early complex) as well as the mu H chain/surrogate L chain complex. These results reconcile some of the apparently discrepant results on surface expression of the surrogate L chain obtained with human and mouse bone marrow pre-B cells, and show that a surrogate L chain/mu H chain-containing pre-B cell receptor can be expressed also on the surface of mouse pre-B-II cells.

IL-2 receptor alpha chain (CD25, TAC) expression defines a crucial stage in pre-B cell development

The analysis of the expression of the alpha chain of the IL-2 receptor (CD25, TAC) on the surface of B lineage cells in mouse bone marrow reveals that it is a useful marker to distinguish pre-B-I from pre-B-II cells. CD25 is not expressed on CD45R(B220)+ c-kit+ CD43+ TdT+ lambda 5+ c mu- sIg-IgH chain locus DJH-rearranged pre-B-I cells of mouse bone marrow. It is expressed on large cycling CD45R(B220)+ c-kit- CD43+ TdT- lambda 5+ c mu+ sIg- and on small resting CD45R(B220)+ c-kit- CD43- TdT- lambda 5- c mu- sIg- IgH chain locus VHDJH-rearranged pre-B-II cells. Therefore, the transition from pre-B-I to large pre-B-II cells is marked by the downregulation of c-kit and terminal deoxynucleotidyl transferase (TdT), and by the upregulation of CD25. SCID, RAG-2T, microMT and lambda 5T mutant mice do have normal, if not elevated numbers of pre-B-I cells but lack all CD25+ pre-B-II cells in their bone marrow. The expression of a transgenic H chain under control of the microH chain enhancer in RAG-2T bone marrow B lineage precursors allows the development of large and small CD25+ pre-B-II cells. The results suggest that the differentiation of pre-B-I to pre-B-II cells in mouse bone marrow requires the expression of microH chains and surrogate L chains in membranes, probably on the surface of precursor B cells.

Thymic selection of CD8+ single positive cells with a class II major histocompatibility complex-restricted receptor

We describe mice that express a transgenic T cell receptor alpha/beta (TCR-alpha/beta) specific for peptide 111-119 from influenza hemagglutinin presented by I-Ed class II major histocompatibility complex (MHC) molecules. The transgenic TCR is expressed on CD4+8- as well as CD4-8+ mature T cells even in mice that are deficient in rearrangement or do not express endogenous TCR-alpha genes. The CD4-8+ T cells require I-Ed class II MHC molecules for positive selection and can be activated to proliferate and to kill by I-Ed molecules presenting the relevant peptide. Full maturation of these cells, however, also requires the presence of class I MHC molecules. The results are compatible with the notion that T cell maturation requires multiple receptor-ligand interactions and establish an exception to the rule that class II-restricted TCRs are exclusively expressed by mature CD4+8- cells.

Influence of immunoglobulin heavy- and light-chain expression on B-cell differentiation

To study the influence of immunoglobulin heavy-chain (HC) and light-chain (LC) expression in promoting B-cell differentiation, we have introduced functional immunoglobulin HC and/or LC transgenes into the recombinase activating gene-2-deficient background (RAG-2-/-). RAG-2-/- mice do not undergo endogenous V(D)J rearrangement events and, therefore, are blocked in B- and T-cell development at the early pro-B- and pro-T-cell stages. Introduction of immunoglobulin HC transgenes into the RAG-2-/- background promotes the development of a B-lineage cell population that phenotypically has the characteristics of pre-B cells. We have shown further that this population has altered growth characteristics as measured by interleukin-7 responsiveness in culture. Bone marrow cells from immunoglobulin HC transgenic RAG-2-/- mice have up-regulated expression of germ-line kappa LC gene transcripts and down-regulated expression of lambda 5 surrogate LCs (SLCs). Although mu HC/SLC complexes are detectable intracellularly in HC/RAG-2-/- pre-B-cell populations, HC expression is not readily detectable on the surface of these cells. lambda LC RAG-2-/- mice had a bone marrow B-lineage cell phenotype indistinguishable from that of RAG-2-/- littermates, indicating that LC expression by itself has no influence on pro-B cell differentiation. Strikingly, simultaneous introduction of mu HC and lambda LC transgenes into RAG-2-/- mice led to the generation of a substantial population of "monoclonal" peripheral B-cells that were functional with regard to immunoglobulin secretion, indicating that T cells or diverse immunoglobulin repertoires are not necessary for peripheral B-cell development.

The expression of Vpre-B/lambda 5 surrogate light chain in early bone marrow precursor B cells of normal and B cell-deficient mutant mice

Precursor B (pre-B) cells in bone marrow of normal and B cell-deficient mutant mice were analyzed for the expression of Vpre-B/lambda 5 surrogate light chain (SL). The surface expression of SL is confined to the early stages (pro-B and pre-B-I) of pre-B cell development and becomes undetectable once mu heavy chain (microH) is produced. The cell-cycle analysis revealed that cytoplasmic microH+ large cells (large pre-B-II), approximately 30% of which coexpressed SL in the cytoplasm, were most actively cycling, whereas cytoplasmic microH+ small cells (small pre-B-II) were SL- and not in cycle. The analysis of pre-B cells in B cell-deficient mice suggests that the large pre-B-II stage is a critical step for the selection and amplification of cells carrying functionally rearranged microH genes.

Influence of surrogate L chain on DHJH-reading frame 2 suppression in mouse precursor B cells

DHJH rearrangements start in progenitor and precursor B cells and occur in three reading frames (rf). A strong bias for rf I has been noticed in murine and chicken antibodies, while the representation of rf II has been found suppressed both in peripheral as well as in precursor B cells. H chain gene loci DHJH rearranged in rf II are potentially capable of expressing a truncated DHJHC mu protein on the cell surface. Mice incapable of expressing this protein on the surface have previously been shown to have all reading frames represented in near equal frequency, suggesting that membrane-bound DHJHC mu protein is involved in the suppression of rf II. In this paper we show that suppression of rf II is not yet established in c-kit+ CD43+ IL-7/stromal cell-reactive pre-B I cells of fetal liver at day 15 of gestation, but becomes established when such precursor cell populations are expanded in vitro on stromal cells in the presence of IL-7. H chain gene loci using the DQ52 segment for rearrangements (which contains a stop codon in rf II, thus being unable to make DHJHC mu protein) do not show rf II suppression under these conditions. The same type of fetal liver-derived pre B-I cells from lambda 5 deficient mice also do not show rf II suppression after in vitro expansion. Bone marrow-derived pre B-I cells from normal mice assayed ex vivo and expanded in vivo show rf II suppression, while the corresponding pre-B I cells from lambda 5T mice do not. Collectively these experiments suggest that surrogate L chain is involved in rf II suppression. This may happen by inhibition of proliferation of pre-B cells expressing a complex of DHJHC mu protein and surrogate L chain.

Rearrangement and expression of kappa light chain genes can occur without mu heavy chain expression during differentiation of pre-B cells

The kinetics of kappa light (kappa L) chain gene rearrangement and expression on mRNA and protein level has been studied with four stromal cell/IL-7 reactive, long-term in vitro proliferating pre-B cell lines and clones, two from fetal liver of normal mice and two from fetal liver of E microH-bcl-2 transgenic (bcl-2-tg) mice. These pre-B cell lines and clones are DJH-rearranged on both H chain alleles. Two of the clones harbor H chain rearrangements which do not allow the expression of VHDJH rearranged H chain genes as microH chain proteins. Upon removal of IL-7 from the pre-B cell cultures all four cell lines rearrange VH-DJH and VL-JL gene segments, loose the surface expression of c-kit, CD43, and surrogate light chain, as well as the capacity to be clonable on stromal cells in the presence of IL-7. Pre-B cells from normal mice die by apoptosis during differentiation, while those from bcl-2-tg mice do not. All four lines and clones express comparable levels of mRNA for microH and kappa L chains with the same time kinetics during 3 days of differentiation. However, only two of the four pre-B cell lines and clones express microH chain protein, whereas all four pre-B cell lines and clones express kappa L chain protein at comparable levels between 2 x 10(5) and 1.4 x 10(6) kappa L chain molecules per cell. These results suggest that microH chain expression is not mandatory for rearrangement and normal expression of kappa L chain genes when pre-B cells differentiate to B cells.