Induced kappa receptor editing shows no allelic preference in a mouse pre-B cell line

B cell Ag receptor editing is a process that can change kappa antigen recognition specificity of a B cell receptor through secondary gene rearrangements on the same allele. In this study we used a model mouse pre-B cell line (38B9) to examine factors that might affect allelic targeting of secondary rearrangements of the kappa locus. We isolated clones that showed both productive and nonproductive rearrangements of one kappa allele, while retaining the other kappa allele in the germline configuration (kappa(+)/kappa degrees or kappa(-)/kappa degrees ). In the absence of any selective pressures, subsequent rearrangement of the germline alleles occurred at the same frequency as secondary rearrangement of the productive or nonproductive rearranged alleles. Because 38B9 cells lack Ig heavy chains, we stably expressed mu heavy chain protein in 38B9 cells to determine whether heavy-light pairing might affect allelic targeting of secondary kappa rearrangements. Although the expression of heavy chain was found to both pair with and stabilize kappa protein in these cells, it had no effect on preferential targeting Vkappa-Jkappa receptor editing compared with rearrangement of a germline allele. These studies suggest that in the absence of selection to eliminate autoreactive Vkappa-Jkappa genes, there is no allelic preference for secondary rearrangement events in 38B9 cells.     

Isolation of scid pre-B cells that rearrange kappa light chain genes: formation of normal signal and abnormal coding joins.

Consistent with an ordered immunoglobulin (Ig) gene assembly process during precursor (pre-) B cell differentiation, we find that most Abelson murine leukemia virus (A-MuLV)-transformed pre-B cells derived from scid (severe combined immune deficient) mice actively form aberrant rearrangements of their Ig heavy chain locus but do not rearrange endogenous kappa light chain variable region gene segments. However, we have identified several scid A-MuLV transformants that transcribe the germline Ig kappa light chain constant region and actively rearrange the kappa variable region gene locus. In one case progression to the stage of kappa light chain gene rearrangement did not require expression of Ig mu heavy chains; furthermore, this progression could not be efficiently induced following expression of mu heavy chains from an introduced vector. As observed in pre-B cell lines from normal mice, attempted V kappa-to-J kappa rearrangements in scid transformants occur by inversion at least as frequently as by deletion. The inverted rearrangements result in retention of both products of the recombination event in the chromosome, thus allowing their examination. scid kappa coding sequence joins are aberrant and analogous in structure to previously described scid heavy chain coding joins. In contrast, the recognition signals that flank involved coding segments frequently are joined precisely back-to-back in normal fashion. The scid VDJ recombinase defect therefore does not significantly impair recognition of, site-specific cutting at, or juxtaposition and appropriate ligation of signal sequences. Our finding that the scid defect prevents formation of correct coding but not signal joins distinguishes these events mechanistically.     

Surface mu heavy chain expressed on pre-B lymphomas transduces Ca2+ signals but fails to cause growth arrest of pre-B lymphomas.

Little is known about the role of signals transduced by cell surface IgM (sIgM) expressed during early B cell development. A subclone (1.6) of the late pre-B cell lymphoma 70Z/3.12 was used to study signal transduction by surface mu heavy (H) chain before and after transition to the early immature B cell stage, and the functional consequences thereof. Although kappa L chain expression can be induced on 1.6 cells by LPS or cytokines, immunoprecipitations indicated that the non-induced 1.6 cells expressed mu H chain with an alternative protein(s) which may be a surrogate light chain(s). Consistent with this, anti-mu but not anti-kappa or anti-lambda antibodies caused transient Ca2+ mobilization in noninduced 1.6 cells. The Ca2+ signal was derived from both intracellular stores and Ca2+ influx in either noninduced cells or in cells that had been preinduced to express kappa L chain. Thus, the ability of mu H chain to mobilize Ca2+ as a second messenger does not depend upon the expression of mature L chains. The immature B lymphomas, WEHI-231 and CH1, express mature forms of IgM and undergo growth arrest when stimulated by anti-mu antibody. In contrast, signals generated by mu H chain on either noninduced or preinduced 1.6 cells or in the sIgM+ pre-B cell transfectant 300-19 mu lambda 36/8 did not cause growth arrest. These results suggest that mu H chain expressed on pre-B cells is capable of mobilizing Ca2+, but that this signal alone is insufficient to induce growth arrest in the pre-B cell.     

Differentiation of cloned populations of immature B cells after transformation with Abelson murine leukemia virus

The nature of the target cell for Abelson virus transformation and the effect of transformation on B cell differentiation were studied with six cloned lines of nontransformed immature B lymphocytes. Three clones were at the pre-B cell stage of maturation prior to A-MuLV infection; two were at the B cell stage, and one appeared to represent a stage prior to rearrangement of the mu heavy chain gene. All six cloned lines could be transformed by Abelson virus. Many of the transformants of the pre-B cell clones underwent kappa light chain gene rearrangement and expression following viral infection. Distinct light chain gene rearrangements were segregated by further subcloning these transformed lines. Abelson virus infection of one cloned cell line believed to represent a stage of maturation prior to the pre-B cell stage produced pre-B cell transformants with a variety of heavy chain gene rearrangements. Thus B lymphoid target cells for Abelson virus are not restricted to a single developmental stage, and some transformed subclones can undergo extensive immunoglobulin gene rearrangements shortly after viral infection.     

Immunoglobulin synthesis and gene rearrangements in lymphoid cells transformed by replication-competent Rauscher murine leukemia virus: transformation of B cells at various stages of differentiation

Lymphoid cells transformed by Rauscher murine leukemia virus (R-MuLV) belonged to the B cell lineages. One group of cells exhibited Fc receptors but completely lacked immunoglobulin mu heavy and kappa light chains. The majority of the cells resemble pre-B type. They displayed mu chains but kappa chains were completely absent. Very rarely certain cells synthesized both mu and kappa chains. Based on the presence of Fc receptors and IgM synthesis the cells transformed by R-MuLV belonged to three B cell developmental stages. These cells were tested for immunoglobulin gene rearrangements using JH and CK probes. DNA from cell lines without any detectable levels of IgM mu exhibited embryonic as well as rearranged JH genes, whereas cells expressing IgM possess, in addition, productive and non-productive light chain gene rearrangements. The most terminally differentiated cell possesses JH and CK rearrangement associated with the synthesis of mu and kappa chains. Presumably the cells with rearranged JH and CK genes without immunoglobulin synthesis represent a developmental transition. We conclude that cells transformed by R-MuLV belonged to five step-wise compartments of B cell development. Our findings implicate definite sequential events of immunoglobulin gene rearrangement and expression during B cell development.     

Immunoglobulin light chains dictate vesicular transport-dependent and -independent routes for IgM degradation by the ubiquitin-proteasome pathway

Degradation of IgM mu heavy chains in light chain-negative pre-B cells is independent of vesicular transport, as is evident by its insensitivity to brefeldin A or cell permeabilization. Conversely, by the same criteria, degradation of the secretory mu heavy chain in light chain-expressing B cells depends on vesicular transport. To investigate whether the presence of conventional light chains or the developmental stage of the B-lymphocytes dictates the degradative route taken by mu, we express in 70Z/3 pre-B cells either lambda ectopically or kappa by lipopolysaccharides-stimulated differentiation into B cells and show their assembly with mu heavy chains. The resulting sensitivity of mu degradation to brefeldin A and cell permeabilization demonstrates that conventional light chains, a hallmark of B cell differentiation, are necessary and sufficient to divert mu from a vesicular transport-independent to a vesicular transport-dependent degradative route. Although both routes converge at the ubiquitin-proteasome degradation pathway, only in light chain-expressing cells is vesicular transport a prerequisite for mu ubiquitination.     

Ig gene rearrangement and expression in the progeny of B-cell progenitors in the course of clonal expansion in bone marrow cultures.

In cultures of murine bone marrow cells colonies of 10(3)-10(4) cells were identified which consisted to a large part of pre-B and B cells. Cell mixing experiments with genetically marked cells indicated that each colony is derived from a single progenitor cell not yet committed to the expression of either IgH locus. A concanavalin-A-mediated electrofusion method allowed us to rescue and amplify individual cells from a given colony by hybridization with X63.Ag8.653 cells. The molecular analysis of 12 such hybridomas revealed that all IgH loci were rearranged into DJH or productive or nonproductive VHDJH complexes. Most kappa and all lambda light chain loci were in germline configuration. Kappa chain expression was only seen in heavy (mu) chain expressing hybridomas. Hybridomas from a given colony were heterogeneous in terms of DJH and VHDJH rearrangements and in no cell was more than one productive VHDJH complex detected. None of the productive VHDJH complexes contained a VH gene of group 1 (J558), the largest VH gene family with about half of the VH genes. This is in marked contrast to VH gene usage in splenic B cells.     

Temporal relationship of translation and glycosylation of immunoglobulin heavy and light chains.

The initial glycosylation of MPC 11 gamma 2b heavy chains occurs quantitatively in vivo when the nascent heavy chains reach a size of approximately 38 000 daltons. Nonglycosylated, completed MPC 11 heavy chains cannot be glycosylated in these cells. Other classes of mouse heavy chains (i.e., mu, alpha, and gamma 1) also appear to be glycosylated as nascent chains; nonglycosylated, completed heavy chains cannot be glycosylated by the cell in any of these cases. In contrast, variant MPC 11 cells synthesizing a heavy chain with a carboxy-terminal deletion appear to glycosylate some heavy chains prior to chain completion and some heavy chains after chain completion and release from the polysomes. Similar to the variant MPC 11 cells, MOPC 46B cells (which synthesize a kappa light chain containing an oligosaccharide attached to an asparagine located 28 residues from the amino terminus) glycosylate the majority of light chains after prior to chain completion but also some light chains after chain completion and release from the polysomes. In addition, it appears that, although completed MOPC 46B light chains can be glycosylated if they are present in a monomeric form, they cannot be glycosylated if they are present in a covalent dimeric form.     

Immunoglobulin synthesis by lymphoid cells transformed in vitro by Abelson murine leukemia virus.

The majority of cell lines derived by infection of murine bone marrow cells with Abelson murine leukemia virus (A-MuLV) synthesize a mu chain but no detectable light chain. Aside from this mu-only phenotype, lines that make only light chain, both chains or no immunoglobulin-related polypeptides have also been found. Two lines have been studied in detail: one that makes only mu chain and one that makes only kappa light chain. Synthesis of both polypeptides can be increased by modifying the culture conditions so as to decrease the growth rate of the cells. Although some kappa chain secretion was observed, neither secreted nor surface mu was detected. We suggest that the mu- only phenotype may be an early normal step in the pathway of B lymphocyte maturation.     

Mouse pre-B cells synthesize and secrete mu heavy chains but not light chains

The immunoglobulins produced by the earliest recognizable B cell precursors (pre-B cells) were characterized in the mouse and human. Immunofluorescent analysis revealed no evidence of surface IgM components, and only mu heavy chains could be detected intracytoplasmically in pre-B cells. Surface IgM components could not be isolated from intact fetal liver cells that lacked sIgM+ B lymphocytes but possessed pre-B cells. Pre-B cells were shown to synthesize and secrete mu heavy chains but not light chains by immunochemical analysis. These mu chains constituted less than 0.01% of TCA precipitable protein synthesized and secreted by fetal liver cells during an 8 hr labelling period. Migration of both intracellular and secreted mu chains on SDS-PAGE suggested that they were smaller than mu chains secreted by mouse and human plasmacytomas. These data indicate that mu chain synthesis precedes light chain expression during B cell ontogeny and suggest a new role for pre-B cells in the generation and expression of a diverse immunoglobulin repertoire.     

Cloning and expression of human anti-tumor necrosis factor-alpha monoclonal antibodies from Epstein-Barr virus transformed oligoclonal libraries

Peripheral blood was obtained from a healthy human volunteer and transformed with Epstein-Barr virus (EBV). This produced an oligoclonal cell library in culture medium that was screened by ELISA for anti-human tumor necrosis factor-alpha (TNFalpha) activity. RNA from two positive clones was applied to RT-PCR using antibody-specific primers, and the light (kappa and lambda) and heavy chain genes (gamma and mu) were cloned into the plasmid vector pFab1-His2. The antibodies produced in Escherichia coli as Fab fragments were assayed for anti-TNFalpha activity utilizing ELISA. Two IgG1/kappa anti-TNFalpha antibodies and two IgM/kappa anti-TNFalpha antibodies were isolated. DNA sequence analysis showed that the VL and VH gene families of IgM and IgG were the same. Both the antibodies showed almost the same activity on ELISA-testing. Ten clones randomly selected from light (kappa and lambda) and heavy (gamma and mu) chain genes in the oligoclonal cell library 1D5 were sequenced, and each gene (kappa, lambda, gamma, and mu) was found to be composed of one to three different genes. These data support the conclusion that the cell clone is oligoclonal at the molecular level.     

Ly1+ PRO-B lymphocyte clones. Phenotype, growth requirements and differentiation in vitro and in vivo.

Several clones obtained from the bone marrow of a BALB/c mouse were found to contain the heavy and light chain Ig genes in the germline configuration, to express Ly1 and to carry the B cell lineage markers B-220, Lyb8 and BP-1; these clones are Pgp-1+, LFA-1+, J11d+, Mac-1+ and Thy1-, Lyt2-, L3T4-, GM1.2- and Ia-. Three clones analyzed in detail (Lyd9, LyH7 and Lyb9) have receptors for interleukin (IL) 2 and IL3 as assessed with the 7D4 and CC11 monoclonal antibodies respectively. They grow in rIL3 but not in rIL2 or rIL1; both rIL4 and rIL5 also promote their proliferation, albeit to a much lesser extent than rIL3. None of the interleukins tested alone or in various combinations promoted the clones to differentiate in vitro along the B cell pathway. Treatment with 5-Azacytidine (5-Aza) induced cell surface Ia expression but not rearrangement or expression of Ig genes. However, 5-Aza-treated Lyd9, LyH7 and Lyb9 cells co-cultured with X-ray irradiated accessory cells and LPS gave rise to Ly1+, IgM+ B lymphocytes (range 14-51%) including mu + kappa + (78-93%), and mu + lambda + (9-25%) B lymphocytes. In vivo, the Lyd9, LyH7 and Lyb9 clones gave rise to IgM+ B lymphocytes (8.5-17%) including mu + kappa +, and mu + lambda +, but not to Lyt2+ or L3T4+ T lymphocytes after 4-6 weeks of transfer into Scid mice. Our results indicate that Ly1+ IgM+ cells comprise a subpopulation of B lymphocytes that is derived from IL3-responsive Ly1+ PRO-B lymphocytes.     

Molecular requirements for the mu-induced light chain gene rearrangement in pre-B cells.

During B cell differentiation rearrangement of immunoglobulin (Ig) genes is partially regulated by the Ig proteins. Rearrangement of heavy (H) chain genes is inhibited, whilst that of light (L) chain genes is induced by the membrane form of the mu H chain. In order to analyse additional structural requirements of mu induced L chain gene rearrangement we transfected wild-type mu and mutant mu constructs lacking functional exons encoding the first or second constant domains into Abelson murine leukemia virus (AMuLV) transformed pre-B cells. All mu chains are expressed on the surface of the pre-B cell and all associate with omega and iota, two proteins forming a surrogate light chain, necessary for mu membrane expression. Nevertheless, only wild-type mu and not the mutant mu proteins promote L gene rearrangement. A heterodimer of proteins with Mr of 33 kd and 36 kd was found associated with wild-type but not with the mutant mu proteins. Continuous presence of mu is required for L chain gene recombination since loss of mu stopped and readdition of mu started L gene rearrangement. We propose that the protein complex composed of mu and the 33 kd/36 kd protein heterodimer is responsible for the activation of the L chain gene locus and its rearrangement.     

Two types of mu chain complexes are expressed during differentiation from pre-B to mature B cells.

Immunoglobulin mu chains synthesized in murine pre-B cells are known to be associated with surrogate light chains designated as omega (omega), iota (iota) and B34. In addition to these molecules, we identified the complexes of polypeptides (50, 40, 27 and 15.5 kd) associated with surface or intracellular mu chains of pre-B cell lines. Most of these polypeptides were continuously synthesized and associated with mu chains in virgin B cells lines, although some of them scarcely bound to the mu kappa dimer or mu 2 kappa 2 tetramer concomitantly present in the same clone or population. However, in mature B cells they were no longer detectable except B34. Cross-linking of micron chains on the surface of pre-B cells resulted in an increase in intracellular free Ca2+, indicating that the micron chain complex on the surface of pre-B cell lines acted as a signal transduction molecule. However, the receptor cross-linkage of pre-B cell lines did not induce the increased inositol phospholipid metabolism usually observed in virgin and mature B cell lines. These results suggest that, during the differentiation from pre-B to mature B cells, the cells express two types of mu chain complexes which exhibit different structures as a whole and possess different signal transducing capacities.