Early expression of Ig mu chain from a transgene significantly reduces the duration of the pro-B stage but does not affect the small pre-B stage

During B cell development, V-J rearrangements at the Ig heavy mu chain (IgH mu chain) locus occur in early cycling precursors (pro-B stage). Subsequently, rearrangements at the Ig light (IgL) chain locus occur in late resting precursors (small pre-B stage). To study the effects of mu chain expression on the rate of B cell development, purified hematopoietic stem cells (HSC) bearing a mu chain transgene or wild-type HSC were transferred into immunodeficient RAG-2-/- mice and B cell development was followed over time. In addition, cycling B cell precursors were pulse-labeled by the injection of BrdU into transgenic and wild-type mice, and the production of BrdU-labeled kappa + and lambda + B cells was followed over time. These experiments suggested that early expression of the mu chain from the transgene significantly shortened the duration of the pro-B stage and immediately drove the precursors to differentiate into small pre-B cells. By contrast, the presence of the transgene did not affect the small pre-B stage, where IgL rearrangements occur. Thus, kappa and lambda rearrangements occurred only after the arrest of cell cycling as previously shown in wild-type mice, even when the mu chain is artificially expressed earlier in B cell development.     

Expression of integrins in squamous cell carcinoma of the oral cavity. Correlations with tumor invasion and metastasis

In mouse mutants incapable of expressing mu chains, VkappaJkappa joints are detected in the CD43(+) B cell progenitors. In agreement with these earlier results, we show by a molecular single cell analysis that 4-7% of CD43(+) B cell progenitors in wild-type mice rearrange immunoglobulin (Ig)kappa genes before the assembly of a productive VHDHJH joint. Thus, mu chain expression is not a prerequisite to Igkappa light chain gene rearrangements in normal development. Overall, approximately 15% of the total CD43(+) B cell progenitor population carry Igkappa gene rearrangements in wild-type mice. Together with the results obtained in the mouse mutants, these data fit a model in which CD43(+) progenitors rearrange IgH and Igkappa loci independently, with a seven times higher frequency in the former. In addition, we show that in B cell progenitors VkappaJkappa joining rapidly initiates kappa chain expression, irrespective of the presence of a mu chain.     

Receptor editing occurs frequently during normal B cell development

Allelic exclusion is established in development through a feedback mechanism in which the assembled immunoglobulin (Ig) suppresses further V(D)J rearrangement. But Ig expression sometimes fails to prevent further rearrangement. In autoantibody transgenic mice, reactivity of immature B cells with autoantigen can induce receptor editing, in which allelic exclusion is transiently prevented or reversed through nested light chain gene rearrangement, often resulting in altered B cell receptor specificity. To determine the extent of receptor editing in a normal, non-Ig transgenic immune system, we took advantage of the fact that lambda light chain genes usually rearrange after kappa genes. This allowed us to analyze kappa loci in IgMlambda+ cells to determine how frequently in-frame kappa genes fail to suppress lambda gene rearrangements. To do this, we analyzed recombined VkappaJkappa genes inactivated by subsequent recombining sequence (RS) rearrangement. RS rearrangements delete portions of the kappa locus by a V(D)J recombinase-dependent mechanism, suggesting that they play a role in receptor editing. We show that RS recombination is frequently induced by, and inactivates, functionally rearranged kappa loci, as nearly half (47%) of the RS-inactivated VkappaJkappa joins were in-frame. These findings suggest that receptor editing occurs at a surprisingly high frequency in normal B cells.     

Constitutive expression of terminal deoxynucleotidyl transferase in transgenic mice is sufficient for N region diversity to occur at any Ig locus throughout B cell differentiation

N region diversity in Ag receptors is a developmentally regulated process in B and T cells that correlates with the differential expression of terminal deoxynucleotidyl transferase (TdT). Absent in fetal and newborn mice, TdT expression is restricted to early T and pro-B cells in adults. To extend the TdT expression pattern throughout B cell ontogenesis, we generated transgenic mice carrying a TdT cDNA under the regulatory elements of the N-myc gene and the IgH enhancer. High expression was observed in secondary lymphoid organs consistent with TdT activity beyond the pre-B cell stage. This suggests that TdT transgene expression is not down-regulated as is the endogenous gene. Unlike normal mice, extensive N region diversity was found in rearranged lambda light chain genes of adult transgenic animals. Therefore, expression of TdT appears sufficient for N region diversity to occur at any Ig locus. More importantly, expression of the transgene takes place during fetal development. As a consequence, the potential fetal B cell repertoire is modified as both rearranged heavy and light chain genes now show N region additions. Constitutive expression of TdT throughout B cell differentiation does not therefore appear deleterious and suggests that TdT is recruited only to participate in the V(D)J recombination process.     

Transgenic expression of VpreB-3 under the control of the immunoglobulin heavy chain enhancer and SV40 promoter

Recently we isolated a novel gene, VpreB-3 gene from the cDNA library of a pre-B cell clone. This gene is selectively expressed in pre-B and bone marrow-derived B cell lines. Its products are associated with the immunoglobulin heavy (IgH) chain in pre-B cell line. In the present study, to address the role of VpreB-3 on B cell development, transgenic mice carrying the VpreB-3 gene under the control of the IgH enhancer and SV40 promoter were produced. The transgenic mice expressed the VpreB-3 gene in bone marrow and spleen at a high level compared with control mice. In the thymus, the expression of the transgene was also detected, although its level was low. Flow cytometry analysis revealed that the frequency of CD45R+ and mu+ B cells were reduced in the bone marrow of 2 of the 11 transgenic mice and also reduced in the spleen of 1 of the transgenic mice. Furthermore, the results of a stromal cell-dependent B cell culture assay suggested that early B cell development, the differentiation from CD45R- B progenitor cells to CD45R+ pro-B cells, was delayed in the bone marrow cultures of 3 of the 5 transgenic mice compared with the control mice. These results suggested that VpreB-3 products may play some role in early B cell development at the stage of CD45R- B progenitor cells before the expression of surface mu chains.     

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.     

Reciprocal homologous recombination in or near antibody VDJ genes

To determine if rearranged heavy chain variable (VDJ) genes can recombine with each other by crossing over of DNA strands, we constructed a transgene that contained a promoter, VDJ gene, reporter gene to detect crossover events, intron enhancer, matrix attachment region, and constant gene for IgM (C mu). Following immunization of transgenic mice, hybrid molecules were isolated from B cell DNA which contained the transgene recombined with the endogenous IgH locus. Reciprocal products of crossovers were detected by plasmid rescue and PCR amplification, and they were sequenced. Recombination occurred somewhere within 147 bp of homology that contained the JH4 gene segment and 3' flanking DNA. The recombined transgenes had a 20-fold increase in mutation in the VDJ region compared to nonrecombined transgenes, which indicates that DNA sequences 3' of the C mu gene in the endogenous IgH locus are necessary for full activity of the mutator mechanism. The recovery of recombinants between VDJ transgenes and endogenous VDJ genes raises the possibility that reciprocal recombination may somatically diversify rearranged genes between maternal and paternal alleles.     

Role of mu heavy chain in B cell development. I. Blocked B cell maturation but complete allelic exclusion in the absence of Ig alpha/beta

There is good evidence for a signaling role played by Ig heavy chain in the developmental transition through the pre-B cell stage. We have previously described signal-capable or signal-incapable mutants of mu heavy chain in which a signaling defect is caused by failure to associate with the Ig alpha/beta heterodimer. To further characterize the role of Ig heavy chain-mediated signaling in vivo, as well as in B cell development and allelic exclusion, we have created transgenic mice in which the B cells express these signal-capable and signal-incapable mutant mu chains. Failure of mu to signal via Ig alpha/beta results in a block in B cell development in mice expressing the signal-incapable mu. A small number of B cells in these animals do escape the developmental block and are expressed in the spleen and the periphery as B220+ transgenic IgM+ cells. These cells respond to LPS by proliferating but show no response to T-independent-specific Ag. In contrast, B cells expressing the signal-capable B cell receptor show a strong signaling response to Ag-specific stimulus. There is no Ig alpha seen in association with signal-deficient IgM. Thus, the B cell receptor complex is not assembled, and no signal can be delivered. Despite the block in developmental signaling, allelic exclusion is complete. There is no detectable coexpression of transgenic IgM and endogenous murine IgM, nor is there rearrangement of the endogenous heavy chain genes. This suggests that differing signaling mechanisms are responsible for the developmental transition and allelic exclusion and thus allows for separate examination of these signaling mechanisms.     

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.     

Rapid induction of B-cell lymphomas in mice carrying a human IgH/c-mycYAC

Activation of the c-myc proto-oncogene by one of the immunoglobulin (Ig) loci after chromosomal translocation is a consistent feature of Burkitt's lymphoma. Different subtypes of this tumor vary in the molecular architecture of the translocation region. In most cases there are no known regulatory elements of the Ig locus neighboring the oncogene and this considerably obscures the mechanism of its deregulation. In order to assess possible oncogene activation signals, we produced an experimental translocation region by insertion of a c-myc gene about 50 kb from the IgH intron enhancer in a yeast artificial chromosome (YAC) containing a 220 kb region of the human Ig heavy chain (IgH) locus. Single copy integration of this YAC into the genome of mouse embryonic stem (ES) cells was achieved by spheroplast fusion. Chimeric mice derived from these ES cells developed monoclonal B-cell lymphomas expressing surface IgM by 8-16 weeks of age. The IgH/c-myc translocus showed different V(h)DJ(H) rearrangement in almost all tumors without any alterations of the distance between c-myc and the IgH intron enhancer. This mouse model can be used for the in vivo analysis of c-myc deregulation and the tumor formation capacity of the IgH locus in aberrant rearrangements.     

Characterizing the target of acute stroke therapy

bcl-2/IgH fusion is considered a genetic error which occurs at the diversity (D) to joining (J(H)) stage of the gene rearrangement process in the immunoglobulin heavy chain (IgH) gene locus. Translocations of the bcl-2 protooncogene to the IgH locus at ontogenetically later IgH gene rearrangements are thought to represent exceptions. In the present study we analysed the junctional nucleotide sequence of 18 bcl-2/IgH fusion genes identifiable by polymerase chain reaction performed on DNA extracted from diagnostic lymph node tissue of 14 follicular lymphoma patients. In all clones studied, segments of variable length were found interposed between bcl-2 and J(H) gene sequences. Nucleotide sequence data analysis and comparisons performed with the corresponding germline sequences using the GenBank/EMBL database revealed the presence of D segments in most of the bcl-2/IgH fusion genes under study (13/18). By the same kind of computer-aided analysis, previously unrecognized D segments were identified in many published junctional sequences. These results suggest that bcl-2/IgH fusion events are very prevalent in rather more differentiated stages in B-cell ontogeny than previously recognized.     

Androgens and masculinization of genitalia in the spotted hyaena (Crocuta crocuta). 1. Urogenital morphology and placental androgen production during fetal life

The pre-T cell receptor (TCR) associates with CD3-transducing subunits and triggers the selective expansion and maturation of T cell precursors expressing a TCR-beta chain. Recent experiments in pre-Talpha chain-deficient mice have suggested that the pre-TCR may not be required for signaling allelic exclusion at the TCR-beta locus. Using CD3-epsilon- and CD3-zeta/eta-deficient mice harboring a productively rearranged TCR-beta transgene, we showed that the CD3-gammadeltaepsilon and CD3-zeta/eta modules, and by inference the pre-TCR/CD3 complex, are each essential for the establishment of allelic exclusion at the endogenous TCR-beta locus. Furthermore, using mutant mice lacking both the CD3-epsilon and CD3-zeta/eta genes, we established that the CD3 gene products are dispensable for the onset of V to (D)J recombination (V, variable; D, diversity; J, joining) at the TCR-beta, TCR-gamma, and TCR-delta loci. Thus, the CD3 components are differentially involved in the sequential events that make the TCR-beta locus first accessible to, and later insulated from, the action of the V(D)J recombinase.