Allelic inclusion in a pre-B-cell line that generates immunoglobulin heavy chain genes in vitro

Long-Range Control of V(D)J Recombination & Allelic Exclusion: Modeling Views

Allelic exclusion of immunoglobulin (Ig) and T-cell receptor (TCR) genes ensures the development of B and T lymphocytes operating under the mode of clonal selection. This phenomenon associates asynchronous V(D)J recombination events at Ig or TCR alleles and inhibitory feedback control. Despite years of intense research, however, the mechanisms that sustain asymmetric choice in random Ig/TCR dual allele usage and the production of Ig/TCR monoallelic expressing B and T lymphocytes remain unclear and open for debate. In this chapter, we first recapitulate the biological evidence that almost from the start appeared to link V(D)J recombination and allelic exclusion. We review the theoretical models previously proposed to explain this connection. Finally, we introduce our own mathematical modeling views based on how the developmental dynamics of individual lymphoid cells combine to sustain allelic exclusion.

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.

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.

Activation and phosphatidylinositol 3-kinase-dependent phosphorylation of protein kinase C-epsilon by the B cell antigen receptor

Protein kinase C (PKC) enzymes play an important role in B cell antigen receptor (BCR) signaling, linking the BCR to the activation of mitogen-activated protein kinases as well as the NF-kappa B, and AP-1 transcription factors. There are eleven different PKC isoforms, each of which is likely to have a unique set of substrates and hence a unique role in signal transduction. Although PKC-alpha, PKC-beta, PKC-delta, and PKC-zeta have been shown to be targets of BCR signaling, the full spectrum of PKC enzymes that are activated by the BCR remains to be determined. In this report, we show that PKC-epsilon is a target of BCR signaling. We found that PKC-epsilon is highly expressed in B cells and that BCR engagement causes PKC-epsilon to translocate from the cytosol to cellular membranes. This presumably reflects the binding of PKC-epsilon to its membrane-associated lipid activator, diacylglycerol. We also found that BCR engagement resulted in the phosphatidylinositol 3-kinase-dependent phosphorylation of PKC-epsilon. This modification may promote the full activation of PKC-epsilon. Activation of PKC-epsilon could be a key event in BCR signaling since PKC-epsilon has been strongly linked to cell survival and proliferation in other cell types.

Characterization of a unique anti-DNA hybridoma

We have previously described the isolation and in vitro binding properties of eight anti-DNA monoclonal antibodies (MAbs) from an MRL-lpr mouse. In light of recent reports that have indicated it is possible to isolate multiple MAbs from a single hybridoma, our pathogenic hybridoma, 11F8, was examined for evidence of similar phenomena. Chromosome counting suggested that 11F8 cells are unusual and might indeed be expressing multiple heavy and/or light chains. PCR, cloning, and sequencing of immunoglobulin heavy and light chains indicate that 11F8 displays expression of both gamma 2a and gamma 3 heavy chains at the DNA level. Flow cytometry and amino acid sequencing reveals that expression of multiple isotypes also occurs at the protein level but only a single heavy- and light-chain sequence is able to bind DNA. Based on these results, we conclude that 11F8 is an unusual hybridoma that secretes two distinct heavy and at least one light chain from a single cell, and may represent a trioma, a stable three-cell fusion.

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.

Assembly of the truncated immunoglobulin heavy chain D mu into antigen receptor-like complexes in pre-B cells but not in B cells

Rearrangements of the IgH locus with JH joined to reading frame 2 of DH are greatly underrepresented in B cells. These rearrangements encode the truncated heavy chain D mu. In pre-B cells, we found D mu protein expressed on the cell surface and assembled into a complex with surrogate light chains, Ig alpha, and Ig beta. Cross-linking of either mu m- or D mu m- containing pre-B cell receptors triggered signal transduction reactions. In contrast, when expressed in mature B cell lines, D mu was not detected on the cell surface and did not efficiently bind kappa immunoglobulin light chains, but did associate with Ig alpha and Ig beta. These results characterize the interactions of D mu chain with other components of the B cell antigen receptor complex and suggest possible mechanisms by which D mu expression may interfere with B cell development.

Roles of heavy and light chains in IgM polymerization

IgM antibodies are secreted as multisubunit polymers that consist of as many as three discrete polypeptides: mu heavy chains, light (L) chains, and joining (J) chains. We wished to determine whether L chains that are required to confer secretory competence on immunoglobulin molecules must be present for IgM to polymerize--that is, for intersubunit disulfide bonds to form between mu chains. Using a L-chain-loss variant of an IgM-secreting hybridoma, we demonstrated that mu chains were efficiently polymerized independent of L chains, in a manner similar to that observed for conventional microL complexes, and that the mu polymers incorporated J chain. These mu polymers were not secreted but remained associated with the endoplasmic reticulum-resident chaperone BiP (GRP78). This finding is consistent with the endoplasmic reticulum being the subcellular site of IgM polymerization. We conclude that mu chain alone has the potential to direct the polymerization of secreted IgM, a process necessary but not sufficient for IgM to attain secretory competence.

Analysis of the B-cell progenitor compartment at the level of single cells

BACKGROUND

During B-cell development in the mouse, the VH, DH and JH elements of the immunoglobulin heavy chain (IgH) locus are rearranged, firstly by DH-JH joining, and then by VH-DHJH joining. In-frame ('productive') VHDHJH joints and DHJH joints in reading frame 2 (one of the three possible DH reading frames) allow the expression of mu and truncated mu chains (D mu proteins), respectively. The expression of such molecules from one of the two IgH loci of a cell is thought to interfere with VH-DHJH recombination on the other IgH locus, and to guide the cells through further development.

RESULTS

We have developed a gene amplification assay that permits the examination of rearranged immunoglobulin genes in single cells. Using this assay, we monitored cells bearing DHJH and/or VHDHJH joints at early stages of development: in CD43+ B-cell progenitors, subdivided into fractions A, B, C and C' by flow cytometry, and in CD43- pre-B cells (fraction D). Fraction C was enriched for cells with two non-productive VHDHJH joints. Cells containing both a DHJH joint in DH reading frame 2 and a VHDHJH joint were not seen in any fraction. All fraction D cells harbored an in-frame VHDHJH joint. Cells with two productive VHDHJH joints appear to be selected against throughout development.

CONCLUSIONS

Cells expressing D mu proteins appear to be arrested in development as a result of inhibited VH-DHJH joining. Expression of the mu chain is required for maturation into CD43- pre-B cells; accordingly, cells carrying two non-productive VHDHJH joints accumulate in the CD43+ compartment. Such a developmental arrest may also affect cells that express self-reactive VHDHJH antibody domains. Our results indicate further that allelic exclusion at the IgH locus is already established at the pre-B cell stage.

Stimulation of kappa light-chain gene rearrangement by the immunoglobulin mu heavy chain in a pre-B-cell line

B-lymphocyte development exhibits a characteristic order of immunoglobulin gene rearrangements. Previous work has led to the hypothesis that expression of the immunoglobulin mu heavy chain induces rearrangement activity at the kappa light-chain locus. To examine this issue in more detail, we isolated five matched pairs of mu- and endogenously rearranged mu+ cell lines from the Abelson murine leukemia virus-transformed pro-B-cell line K.40. In four of the five mu+ cell lines, substantial expression of mu protein on the cell surface was observed, and this correlated with an enhanced frequency of kappa immunoglobulin gene rearrangement compared with that in the matched mu- cell lines. This increased kappa gene rearrangement frequency was not due to a general increase in the amount of V(D)J recombinase activity in the mu+ cells. Consistently, introduction of a functionally rearranged mu gene into one of the mu- pre-B-cell lines resulted in a fivefold increase in kappa gene rearrangements. In three of the four clonally matched pairs with increased kappa gene rearrangements, the increase in rearrangement frequency was not accompanied by a significant increase in germ line transcripts from the C kappa locus. However, in the fourth pair, K.40D, we observed an increase in germ line transcription of the kappa locus after expression of mu protein encoded by either an endogenously rearranged or a transfected functional heavy-chain allele. In these cells, the amount of the germ line C kappa transcript correlated with the measured frequency of rearranged kappa genes. These results support a regulated model of B-cell development in which mu protein expression in some way targets the V(D)J recombinase to the kappa gene locus.

Stimulation of kappa light-chain gene rearrangement by the immunoglobulin mu heavy chain in a pre-B-cell line

B-lymphocyte development exhibits a characteristic order of immunoglobulin gene rearrangements. Previous work has led to the hypothesis that expression of the immunoglobulin mu heavy chain induces rearrangement activity at the kappa light-chain locus. To examine this issue in more detail, we isolated five matched pairs of mu- and endogenously rearranged mu+ cell lines from the Abelson murine leukemia virus-transformed pro-B-cell line K.40. In four of the five mu+ cell lines, substantial expression of mu protein on the cell surface was observed, and this correlated with an enhanced frequency of kappa immunoglobulin gene rearrangement compared with that in the matched mu- cell lines. This increased kappa gene rearrangement frequency was not due to a general increase in the amount of V(D)J recombinase activity in the mu+ cells. Consistently, introduction of a functionally rearranged mu gene into one of the mu- pre-B-cell lines resulted in a fivefold increase in kappa gene rearrangements. In three of the four clonally matched pairs with increased kappa gene rearrangements, the increase in rearrangement frequency was not accompanied by a significant increase in germ line transcripts from the C kappa locus. However, in the fourth pair, K.40D, we observed an increase in germ line transcription of the kappa locus after expression of mu protein encoded by either an endogenously rearranged or a transfected functional heavy-chain allele. In these cells, the amount of the germ line C kappa transcript correlated with the measured frequency of rearranged kappa genes. These results support a regulated model of B-cell development in which mu protein expression in some way targets the V(D)J recombinase to the kappa gene locus.

Biased usage of two restricted VH gene segments in VH replacement

AT8-1-12-5, an intracytoplasmic gamma 2b-producing (mu- gamma 2b+) pre-B cell line transformed with Abelson murine leukemia virus continuously generated intracytoplasmic mu, gamma 2b-producing (mu+ gamma 2b+) cells during propagation in culture. Southern blotting, DNA cloning and sequence analysis showed that these mu+ gamma 2b+ cells were generated from the mu- gamma 2b+ pre-B cells by VH replacement events. The gene segments involved in these replacement events were restricted to only two VH gene segments, VH7.1 (VH7183 family) and VH6.2 (VHQ52 family). Cell staining using the monoclonal anti-VH141 antibody 3-5-6f that specifically recognized the VH6.2 but not VH7.1 gene products indicated that half of the VH replacement events occurring in AT8-1-12-5 used the VH6.2 gene segment. Deletion mapping indicated that the incoming VH gene segments, VH7.1 and VH6.2 were proximal to the resident VH gene segment, VH12.5 (VH7183 family). These results provided direct evidence of the biased usage of VH gene segments in VH replacement and have several implications for the mechanisms of VH replacement.

Tumorigenesis mediated by an antigen receptor

The heavy chain variable region of the immunoglobulin receptors on cells of the B lymphoma NYC are almost identical to that of other independent B-cell tumors of B/W mice. NYC IgM binds a viral antigen produced by the tumor cells; and despite extensive screening, immunoglobulin-negative variants were never found in the NYC cells, suggesting that NYC loses the capacity to grow in culture when it does not synthesize surface immunoglobulin. These findings indicate that the interaction of endogenous antigen with surface IgM continuously stimulates growth and, thus, that the tumorigenesis of B lymphomas in B/W mice is mediated by antigen receptors.

Allelic exclusion of membrane but not secreted immunoglobulin in a mature B cell line

Although many B lymphocytes contain two completely rearranged immunoglobulin (Ig) heavy (H) chain genes, only one of the alleles specifies a protein product. This phenomenon is termed allelic exclusion and is controlled in part by the membrane portion of Ig H chains. We have identified a mature B cell line derived from murine bone marrow that expresses two H chain proteins, gamma 3 and gamma 2b. Proteins of appropriate size for the membrane and secreted forms of both H chains are produced and both IgG3 and IgG2b are secreted from the cells. However, only IgG3 is expressed on the membrane. Detailed restriction mapping of the H chain genes indicates that both are rearranged, one containing a VHJ558 gene linked to the gamma 3 constant region and the other a VHS107 gene linked to the gamma 2b constant region. Primer extension sequencing of the RNA reveals that the gamma 2b RNA is transcribed from the allele containing VHS107 sequences while the gamma 3 RNA is transcribed from the allele containing VHJ558 sequences. Thus, this mature B cell line secretes two distinct antibody molecules but is allelically excluded at the level of surface Ig expression. This cell line provides a model system to study factors, in addition to aberrant rearrangement, that influence allelic exclusion.

Development of the primary antibody repertoire

The ability to generate a diverse immune response depends on the somatic assembly of genes that encode the antigen-binding portions of immunoglobulin molecules. In this article, we discuss the mechanism and control of these genomic rearrangement events and how aspects of this process are involved in generating the primary antibody repertoire.

High rates of deletions in the constant region segment of the immunoglobulin mu gene

Spontaneous deletions at the immunoglobulin heavy-chain locus are frequently found in myelomas, hybridomas and pre-B-cell lines. We have measured the rates for large and small deletions within the constant-region gene segment for mu chain in a pre-B-cell lines. The large deletions, which include the entire first and second exons, occurred at a rate of 1.7 X 10(-5) per cell generation. The small deletions, which span a few base pairs, occurred at a rate of 1.4 X 10(-7) per cell generation. The rate for the reversion of a termination codon in the second exon is even less than that for the small deletions and is 1000 times lower than the reversion rate that had been determined for the variable-region gene segment. Therefore, the variable-region gene segment is likely to be the preferred target for hypermutation.