Relationship between the rearrangement of immunoglobulin genes, the appearance of a B lymphocyte antigen, and immunoglobulin synthesis in murine pre-B cell lines

Eighteen Abelson virus-transformed immature B cell lines were established and immunoglobulin biosynthesis, expression of a B lymphocyte antigen detected by a monoclonal antibody, and rearrangement of immunoglobulin genes in these cell lines were studied. Only one cell line (A1) synthesized micro-chains but no light chains, and the other cell lines synthesized no detectable immunoglobulins. None of the cell lines established had detectable membrane-associated IgM. Fifteen cell lines expressed a B lymphocyte antigen on their cell surfaces. In three cell lines, however, the majority (greater than 99%) of cells did not express this antigen. Heavy chain genes were rearranged on both chromosomes in all the cell lines, although one heavy chain gene was deleted in three cell lines. In 12 of 18 cell lines, one or both kappa-chain genes were rearranged. In six cell lines, however, both kappa-chain genes remained in embryonic form; lambda-chain genes were in embryonic form in all the cell lines. These results suggested the hierarchy of Ig gene rearrangements, beginning with mu and proceeding to kappa and then to lambda. JH rearrangement was also shown to precede the appearance of a B lymphocyte antigen. In three cell lines (A1-A3), which were considered subclones derived from a single common precursor, it was suggested that one rearranged JH gene was functional, and the other was nonfunctional, indicating that allelic exclusion already operated in pre-B cells.     

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.     

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.     

Aberrant immunoglobulin gene rearrangement in scid mouse bone marrow cells

We have analyzed Ig gene rearrangement in the immunodeficient mutant mouse, CB-17 scid. Bone marrow stem cells from scid mice were cultured in the in vitro culture system of Whitlock and Witte. Ig gene rearrangement in the scid cells was studied by DNA cloning. Seven DNA clones of Ig H chain JH and DH regions were analyzed by DNA sequencing, and all the clones contained a failure in D-J joining. In the rearranged structure, both DH and JH coding sequences are either partly or completely deleted. Molecular mechanisms causing the aberrant DNA rearrangement are discussed.     

DNase I sensitivity of immunoglobulin light chain genes in Abelson murine leukemia virus transformed pre-B cell lines.

We have used Abelson murine leukemia virus (A-MuLV) transformed pre-B cell lines to test the hypothesis that the rearrangement potential of a developing B-lymphocyte is dependent on an "opening" of the chromatin structure surrounding immunoglobulin (Ig) genes, thus allowing accessibility to an Ig gene recombinase. The chromatin structures surrounding heavy (H), kappa (kappa), and lambda (lambda) chain constant-region genes were assessed by DNase I sensitivity in A-MuLV transformed cell lines capable of H, kappa or lambda gene rearrangement. Our results indicate that DNase I-sensitive chromatin structures of these Ig constant-region genes correlate closely with the ability of the genes to undergo recombination. We also find that the chromatin structure of an Ig constant-region locus becomes DNase I sensitive before any DNA rearrangement events occur.     

Altered repertoire of endogenous immunoglobulin gene expression in transgenic mice containing a rearranged mu heavy chain gene

C57BL/6 mice transgenic for a mu heavy chain gene, the VDJ region of which came from the BALB/c hybridoma 17.2.25, expressed high levels of antibody carrying determinants specific for the transgene (idiotypes). The individual antibodies made by hybridomas from transgenic mice, however, were generally encoded by endogenous genes; in most cases the transgene was present but not expressed. The endogenous, idiotype-positive antibodies had heavy chains that were notable for the high frequencies of JH4 (as in the transgene) and VH segments from the VH81X family (unrelated to the transgene). The expression of endogenous genes mimicking the idiotype of the transgene suggests that a rearranged gene introduced into the germ line can activate powerful cellular regulatory influences.     

Ordered rearrangement of immunoglobulin heavy chain variable region segments

The immunoglobulin heavy chain variable region is encoded as three separate libraries of elements in germ-line DNA: VH, D and JH. To examine the order and regulation of their joining, we have developed assays that distinguish their various combinations and have used the assays to study tumor cell analogs of B-lymphoid cells as well as normal B-lymphoid cells. Abelson murine leukemia virus (A-MuLV) transformed fetal liver cells - the most primitive B-lymphoid cell analog available for analysis - generally had DJH rearrangements at both JH loci. These lines continued DNA rearrangement in culture, in most cases by joining a VH gene segment to an existing DJH complex with the concomitant deletion of intervening DNA sequences. None of these lines or their progeny showed evidence of VHD or DD rearrangements. Heavy chain-producing tumor lines, representing more mature stages of the B-cell pathway, and normal B-lymphocytes had either two VHDJH rearrangements or a VHDJH plus a DJH rearrangement at their two heavy chain loci; they also showed no evidence of VHD or DD rearrangements. These results support an ordered mechanism of variable gene assembly during B-cell differentiation in which D-to-JH rearrangements generally occur first and on both chromosomes followed by VH-to-DJH rearrangements, with both types of joining processes occurring by intrachromosomal deletion. The high percentage of JH alleles remaining in the DJH configuration in heavy chain-producing lines and, especially, in normal B-lymphocytes supports a regulated mechanism of heavy chain allelic exclusion in which a VHDJH rearrangement, if productive, prevents an additional VH-to-DJH rearrangement.     

An enhancer at the 3'' end of the mouse immunoglobulin heavy chain locus.

A tissue-specific enhancer (E mu) lies between the joining (JH) and mu constant region (C mu) gene segments of the immunoglobulin heavy chain (IgH) locus. Since mouse endogenous IgH genes are efficiently transcribed in its absence, the normal function of this enhancer remains ill-defined. Recently, another lymphoid-specific enhancer of equal strength has been identified 3' of the rat IgH locus. We have isolated an analogous sequence from mouse and have mapped it 12.5 kb 3' of the 3'-most constant region gene (C alpha-membrane) of the BALB/c mouse locus. The mouse and rat sequences are 82% homologous and share with other enhancers several DNA sequence motifs capable of binding protein. However, in transient transfection assays, the mouse sequence behaves as a weaker enhancer. The role of this distant element in the expression of endogenous IgH genes, both in E mu-deficient, Ig-producing cell lines and during normal B cell development, is discussed.     

Precursors of both conventional and Ly-1 B cells can escape feedback inhibition of Ig gene rearrangement

Experiments with transgenic mice carrying rearranged Ig transgenes have shown that membrane bound Ig molecules cause feedback inhibition of endogenous Ig gene rearrangement. However, this inhibition is never complete. It has been postulated that escape from feedback may be a property of the Ly-1 B cell subset, whereas rearrangement of endogenous Ig genes may be completely inhibited in conventional B cells. This possibility was investigated in transgenic mice carrying a lambda transgene under the control of the H chain enhancer. It was found that kappa producing B cells in these lambda transgenic mice were for the most part, although not exclusively, of the conventional B cell phenotype. Examination of peritoneal exudate cells revealed that a large proportion of Ly-1 B cells also express kappa. Adoptive transfer of bone marrow from adult lambda transgenic mice, a source of conventional B cell precursors, resulted in the production of relatively high levels of serum kappa 2 to 3 mo after transfer into recipient SCID mice. A high proportion of donor B cells in the spleen produced endogenous kappa protein with or without co-production of lambda. It is concluded that precursors of both conventional and Ly-1 B cells can escape feedback inhibition of L chain gene rearrangement.     

The scid defect affects the final step of the immunoglobulin VDJ recombinase mechanism

Abelson murine leukemia virus-transformed precursor B lymphocytes from scid (severe combined immunodeficient) mice, like A-MuLV transformants from normal mice, actively rearrange segments of their Ig heavy chain variable region gene locus during growth in culture. Targeting of recombination to appropriate segments appears normal in these lines as evidenced by initial rearrangement of sequences from within the D and JH locus to form aberrant "DJH" rearrangements and secondary rearrangement of sequences from within the VH locus to the aberrant "DJH" intermediates. A detailed analysis of the joints in these rearrangements indicates that the VDJ recombinase in scid pre-B cells can correctly recognize heptamernonamer signal sequences and perform precise endonucleolytic scissions at these sequences. We propose that the scid defect involves the inability of scid precursor lymphocytes to join correctly the cleaved ends of the coding strands of variable region gene segments.     

Immunoglobulin kappa light chain gene promoter and enhancer are not responsible for B-cell restricted gene rearrangement.

We have produced transgenic mice which synthesize chimeric mouse-rabbit immunoglobulin (Ig) kappa light chains following in vivo recombination of an injected unrearranged kappa gene. The exogenous gene construct contained a mouse germ-line kappa variable (V kappa) gene segment, the mouse germ-line joining (J kappa) locus including the enhancer, and the rabbit b9 constant (C kappa) region. A high level of V-J recombination of the kappa transgene was observed in spleen of the transgenic mice. Surprisingly, a particularly high degree of variability in the exact site of recombination and the presence of non germ-line encoded nucleotides (N-regions) were found at the V-J junction of the rearranged kappa transgene. Furthermore, unlike endogenous kappa genes, rearrangement of the exogenous gene occurred in T-cells of the transgenic mice. These results show that additional sequences, other than the heptamer-nonamer signal sequences and the promoter and enhancer elements, are required to obtain stage- and lineage- specific regulation of Ig kappa light chain gene rearrangement in vivo.     

Retention and loss of immunoglobulin heavy chain alleles in helper T cell hybridoma clones

Retention or loss of immunoglobulin heavy chain genes was studied in 20 functional T cell hybridoma clones. DNA probes representing C mu, C alpha and JH genes, as well as VH subgroups II and III were hybridized with restriction enzyme fragments of hybridoma DNA by the Southern filter hybridization technique. Parental alleles of the hybridoma cells were distinguished on the basis of polymorphism of the lengths of restriction enzyme fragments. All clones retained the alleles of the lymphoma parent cell BW-5147 at all four loci. Thirteen clones lost both CH and VH alleles of the immune partner cell, whereas seven retained both VH alleles, and at least C alpha of the antigen-specific partner. Hence, T cell function in these cells is compatible with the loss of most immunoglobulin heavy chain alleles. This is interpreted to indicate either gene rearrangement and deletion, or chromosome loss. Accordingly, the T cell receptor is either controlled by two split gene loci in chromosome 12, at the two respective (5' and 3') ends of the mouse heavy chain gene family, or by a gene(s) outside chromosome 12.     

Allelic exclusion of a T cell receptor-beta minilocus.

A TCR-beta minilocus in germline configuration (beta M) has previously been shown to undergo rearrangement and expression in transgenic mice. To study allelic exclusion of TCR miniloci, several beta M transgenic mouse lines were generated and crossed with mice transgenic for a functionally rearranged TCR V beta 2 gene (beta R). PCR analysis of beta M beta R double transgenic mice revealed almost complete suppression of endogenous TCR V beta gene rearrangements, but blockage of minilocus V beta rearrangements was achieved with only one of five minilocus transgenic lines. This result cannot be explained by copy number or arrangement of the multiple miniloci integrated. It appears that the minilocus is not autonomously regulated which suggests that sequences flanking the integration sites influence accessibility of the minilocus for rearrangement and allelic exclusion. However, although productively rearranged genes were formed in double transgenic mice, surface expression of minilocus-encoded beta chains was not detected. This indicates that allelic exclusion may operate at a level after gene rearrangement.     

VHDJH formation and DJH replacement during pre-B differentiation: non-random usage of gene segments.

The Abelson murine leukemia virus (A-MuLV) transformed cell line 300-19 was derived from the bone marrow of an adult NIH/Swiss outbred mouse. The original 300-19 clonal isolate carried DHH rearrangements of both JH alleles, a molecular genotype characteristic of early pre-B cells. During propagation in culture, the 300-19 line frequently generates secondary rearrangements of its JH alleles including rearrangements which append VH segments to the pre-existing DJH complexes to form complete VHDJH variable region genes and secondary D to JH rearrangements which replace the pre-existing DJH rearrangement by joining an upstream D to a downstream JH. The two types of secondary rearrangement events occur at approximately equal frequency. Approximately 30% of the VH to DJH joins lead to the production of mu heavy chains providing support for a regulated model of allelic exclusion. Like pre-B cell lines from other origins, the 300-19 line preferentially utilized VH gene segments from the more JH-proximal (3') families to form VHDJH rearrangements. However, the VH segments preferentially employed by 300-19 were from a different family than those previously demonstrated to be utilized by pre-B lines of BALB/c origin; we relate these different utilization patterns to differences in the organization of the more 3' VH families between the two strains. The initial DJH rearrangements of the 300-19 line employed more 3' (JH-proximal) D segments; however, the DJH replacements preferentially employed the most 5' D segment. We discuss this phenomenon in the context of a mechanism which may target recombinase to regions of the chromosome more 5' to the D locus (VH-containing regions) once an initial DJH complex is formed.     

Ig lambda-producing B cells do not show feedback inhibition of gene rearrangement

In order to study the regulation of expression of Ig lambda genes we have analyzed lambda-producing hybridomas derived from transgenic mice which harbor a functionally rearranged kappa transgene. We also analyzed lambda-producing hybridomas from nontransgenic mice. Surprisingly, all but one of the transgenic lambda-hybridomas co-produce kappa L chains. Also, in contrast to transgenic kappa-hybridomas, most lambda-hybridomas have rearranged endogenous kappa genes despite the presence of transgenic kappa-chains and endogenous H chains. Analysis of spleen cells and hybridomas from nontransgenic mice shows that about 20% of lambda-producing B cells in the spleen co-produce kappa, and a similar proportion of lambda-hybridomas from normal spleens produce both kappa- and lambda-chains. The data argue strongly against the strictly sequential expression of kappa and lambda genes. We present a new model for the regulation of kappa and lambda gene expression, whose key feature is the distinction between a kappa cell lineage in which Ig gene rearrangement is susceptible to feedback by a complete antibody molecule at the pre-B cell stage, and a kappa lambda B cell lineage which does not show feedback inhibition during B cell development.     

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.     

Switch region content of hybridomas: the two spleen cell Igh loci tend to rearrange to the same isotype

We have examined the switch region content of 25 hybridomas that secret antibodies of various isotypes with specificity for phosphocholine or glycoproteins of herpes simplex virus. These Southern hybridization experiments included probes for the murine JH region as well as probes for the mu, gamma 3, gamma 1, gamma 2b, gamma 2a, and alpha switch regions. For 22 of the hybridomas, the deletion model of the heavy chain switch fits the data well--all switch regions upstream of the rearranged (and expressed) switch regions are deleted and all switch regions downstream remain in the germline configuration. As exceptions to a simple deletion model of the switch recombination, we have observed two, and perhaps three, examples of switch region rearrangements downstream of an expressed heavy chain gene. The 25 hybridoma DNA samples include 28 rearranged gamma switch regions; the sizes of at least 25 of these rearranged fragments are consistent with recombination in the tandemly repeated sequences associated with gamma genes. For those hybridomas with two spleen cell-derived Igh loci, including three mu-expressers, three gamma 3-expressers, four gamma 1-expressers, and one gamma 2b-expresser, the two loci tend to be rearranged to the same switch region, suggesting that the heavy chain switch rearrangement is an isotype-specific event. The exceptions within this group include three hybridomas in which the switch seems to be incomplete--on one chromosome the JH complex is rearranged to the S gamma 3 region, while on the other it remains associated with the S mu region. A second group of hybridomas, which includes four gamma 3-expressers, have both gamma 3 and gamma 1 switch rearrangements. Each of these four hybridomas includes three rearranged JH segments, suggesting that they may be the result of an unusual differentiative pathway or a technical artifact. These experiments suggest that the heavy chain switch rearrangement in normal spleen cells is a deletion event that occurs within tandemly repeated elements. The rearrangement is mediated by factors with partial, or perhaps complete, isotype specificity.