Ordered rearrangement of immunoglobulin heavy chain variable region segments

T cell receptor beta gene sequences in the circular DNA of thymocyte nuclei: direct evidence for intramolecular DNA deletion in V-D-J joining

We have identified circular DNA containing T cell receptor (TCR) beta gene sequences in mouse thymocytes, thereby providing direct evidence for the intramolecular DNA deletion model of V-D-J joining in TCR beta genes. Two types of excision products of V-D-J joining have been identified. Type I, a circular reciprocal recombinant of normal V-D or D-J joining, contains a 7mer-7mer head-to-head structure expected from an excised product of normal V-D or D-J joining. Type II contains a D beta 2-J beta 1 structure on the circular DNA; the recombination event producing this molecule occurs between an upstream J and a downstream D segment, probably leaving the reciprocal 7mer-7mer structure on the chromosome. Some type I molecules seem to represent excision products of secondary joining after formation of the first D-J or V-D-J structure. The recombination mechanism that generates the circular DNA is discussed.

Mammalian T-lymphocyte antigen receptor genes: genetic and nongenetic potential to generate variability

T lymphocytes of higher vertebrates are able to specifically recognize a seemingly unlimited number of foreign antigens via their receptors, the T cell antigen receptors (TCRs). T lymphocytes mature by passing through the thymus and acquire antigen specificity by expressing the TCR molecules on their cell surface. Genetic and somatic diversification mechanisms give rise to the enormous degree of TCR variability observed in mature T cells: germline and combinatorial diversity as well as junctional and the so-called N-region diversity. In contrast to the situation in immunoglobulin genes somatic hypermutation does not seem to play a significant role in TCR diversification. It is argued here that the enzyme terminal nucleotidyl-transferase is potentially a major factor in generating the immense diversity. We propose furthermore that this enzyme ensures the flexibility of T cell responses to novel antigens by random insertion of so-called N-region nucleotides. Apart from the physiological functions of TCR genes any involvement in the etiology of T cell neoplasia remains to be proven.

Differentiation in the murine B cell lymphoma I.29: individual mu + clones may be induced by lipopolysaccharide to both IgM secretion and isotype switching

Cells from the monoclonal B cell lymphoma I.29 expressing surface IgM (mu +) are capable of differentiating in vitro to IgM secretion and of switching to IgA or IgE production in response to lipopolysaccharide (LPS) stimulation. To determine whether a single mu + B cell is capable of undertaking both differentiative pathways (isotype switch and plasma cell differentiation) I.29 mu + cells were cloned by limiting dilution and a panel of clones were analyzed by immunofluorescence, endogenous labeling and Northern blotting. While 100% of the clones could differentiate toward IgM secretion, only a proportion of them (greater than 70%) also switched to IgA and/or IgE production. Certain clones switched preferentially to a specific isotype. Taken together with the observation that C gamma genes were never the target of switching in our experiments, these data suggest that individual mu + clones from the I.29 lymphoma are "precommitted" as for their switching potentials. The subclones that showed a high frequency of switching to IgA transcribed the germ line C alpha gene(s), suggesting a role for chromatin structure in determining the isotype switch specificity. Switch variant clones expressing either IgA or IgE on the cell surface were isolated and found capable of further differentiating toward Ig secretion in response to LPS. On the contrary, we could not induce switch to IgA in IgE-producing cells. Unlike mu + and alpha + cells, all the switch variant clones expressing IgE tested by endogenous labeling constitutively secreted large amounts of IgE in the supernatants even in the absence of LPS stimulation.

Bone marrow pre-B cells and the clonal anergy theory of immunologic tolerance

This review begins with a summary of a decade's research from the author's own laboratory which documents the fact that B lymphocytes can receive and store negative, down-regulatory signals from an encounter with antigen, and that the sensitivity to such negative signalling depends critically on maturational status, the most immature B cells being the most susceptible. The review then examines the relationship between these experimentally-induced models of immunologic tolerance, with the pre-B to B cell transition as the critical stage for examination, and the real-life phenomenon of self-tolerance. It makes the point that no repertoire-purging mechanism to ensure self-tolerance can afford to be too effective, for fear of purging too many useful cells, given the number and variability of self-antigens. The review then examines certain dilemmas posed by recent findings in cellular and molecular immunology. These include: 1) the preferential use of particular VH gene families by B cells at different stages of the differentiation process; 2) the apparent frequency of B lymphocytes with the potential for antiself-reactivity in the B cell repertoire; and 3) the existence of a new type of B cell, the Ly-1-positive B cell, with peculiar characteristics. These findings are considered within the particular contexts of pre-B-to-B cell transition and tolerance induction through clonal anergy mechanisms.

The arrangement of immunoglobulin and T cell receptor genes in human lymphoproliferative disorders

Immunoglobulin and T cell antigen receptor genes in their germ-line form are organized as discontinuous DNA elements that are joined by recombinations during lymphocyte development. The analysis of immunoglobulin gene structure and arrangement has been of great value in the study of human lymphoid neoplasms. The analysis of rearranged immunoglobulin and T cell receptor genes has been of value in defining the lineage (T or B cell) of neoplasms that were of controversial origin previously, determining the clonality of abnormal lymphocyte proliferations, diagnosing and monitoring the therapy of lymphoid malignancies, determining the state of maturation and the causes for failure of maturation of cells of the B cell series, and providing major insights into the cause of malignant transformation of B and T lymphoid cells. Thus, the application of this molecular genetic approach has great potential for complementing conventional marker analysis, cytogenetics, and histopathology, thus broadening the scientific basis for the classification, diagnosis, and monitoring of the therapy of lymphoid neoplasia.

Lambda 5, a new light-chain-related locus selectively expressed in pre-B lymphocytes

The development from stem cells to pre-B cells, B lymphocytes and, finally, plasma cells and memory cells proceeds through various stages which have been defined by the genomic context in which immunoglobulin (Ig) heavy (H) and light (L) chain gene segments are found, as well as by their state of expression. They have also been identified by surface marker analysis and susceptibility to various stimuli regulating growth and differentiation. We have searched for genes that are expressed at given stages in the B-lymphocyte development pathway and which might function to control this development at various stages. A complementary DNA sequence called pZ183 was found in a library constructed from messenger RNA of the murine pre-B lymphoma cell line 70Z/3 which is selectively expressed in pre-B cells. Here we report the nucleotide sequence of a cDNA clone (pZ183-1) containing 0.7 kilobases (kb) of the pZ183 gene. Part of this sequence shows strong homology to constant (C) and joining (J) region sequences of lambda 1 L chains. Our findings define a new immunoglobulin L-chain-related locus, which we call lambda 5, that is selectively transcribed in pre-B lymphocytes.

The T4 gene encodes the AIDS virus receptor and is expressed in the immune system and the brain

The isolation of clones encoding the human surface protein T4, and the expression of the T4 gene in new cellular environments, have enabled us to examine the role of this protein in the pathogenesis of AIDS. Our studies support a mechanism of AIDS virus infection that initially involves the specific interaction of the AIDS virus with T4 molecules on the cell surface. This association can be demonstrated on T4+ transformed T and B lymphocytes as well as epithelial cells. Furthermore, the presence of T4 on the surface of all human cells examined is sufficient to render these cells susceptible to AIDS virus infection. Our data suggest that the T4-AIDS virus complex is then internalized by receptor-mediated endocytosis. Finally, we find that the T4 gene is expressed in the brain as well as in lymphoid cells, providing an explanation for the dual neurotropic and lymphotropic character of the AIDS virus. In this manner, a T lymphocyte surface protein important in mediating effector cell-target cell interactions has been exploited by a human retrovirus to specifically target the AIDS virus to populations of T4+ cells.

Synchronized rearrangement of T-cell gamma and beta chain genes in fetal thymocyte development

Kinetics of mouse T-cell gamma gene rearrangements in ontogeny were determined as an approach to understanding the possible role of these genes in the development of fetal thymocytes. Two of these genes (C gamma 1 and C gamma 2) rearranged rapidly during days 14 to 17 of the gestational period in BALB/c mice. Moreover, these rearrangements seemed to be tightly synchronized with rearrangements of T-cell receptor beta chain genes in the same cells. It is suggested that the early transcriptional activity of gamma genes, which precedes that of beta chain genes, may not reflect the functional activation of these genes. Nevertheless, productive and therefore potentially functional gamma gene rearrangements precede surface expression of T-cell receptors in the thymus by 2 to 3 days, which is compatible with a role for gamma gene products in thymocyte development prior to antigen-specific stages.

Immunogenetics

The 1985 Catalog of Mapped Genes (Human Gene Mapping 8; 33) has been used to pick out the known, immunologically important genes; these are then discussed in the following order: genes controlling organs, tissues and cells of the immune apparatus, genes determining 'self' structures, genes determining the structures of immunological specificity, genes determining substances with immunoregulatory and effector properties. The symbols for the genes and the biological functions of their products are explained. The genetics of the ABO blood groups, of the HLA-system and of antibody formation are given in rather more detail.

Rearrangement of antigen receptor genes is defective in mice with severe combined immune deficiency

A process unique to lymphocyte differentiation is the rearrangement of genes encoding antigen-specific receptors on B and T cells. A mouse mutant (C.B-17scid) with severe combined immune deficiency, i.e., that lacks functional B and T cells, shows no evidence of such gene rearrangements. However, rearrangements were detected in Abelson murine leukemia virus-transformed bone marrow cells and in spontaneous thymic lymphomas from C.B-17scid mice. Most of these rearrangements were abnormal: approximately 80% of Igh rearrangements deleted the entire Jh region, and approximately 60% of TCR beta rearrangements deleted the entire J beta 2 region. The deletions appeared to result from faulty D-to-J recombination. No such abnormal rearrangements were detected in transformed tissues from control mice. The scid mutation may adversely affect the recombinase system catalyzing the assembly of antigen receptor genes in developing B and T lymphocytes.

A novel VH to VHDJH joining mechanism in heavy-chain-negative (null) pre-B cells results in heavy-chain production

During B-cell development, the VH genes of immunoglobulin heavy (H) chains are assembled from three different germline components: the variable (VH) segment, the diversity (D) segment and the joining (JH) segment. The joining between two segments involves the recognition of conserved nonamer-heptamer sequences bordering each segment, double-stranded cuts at the heptamer-segment border, and the re-ligation of the two segment ends which have frequently been modified by the deletion and addition of nucleotides. The flexibility of the joint increases VHDJH variability. However, it also results in many pre-B cells which do not produce immunoglobulin H chains and have non-functional VHDJH complexes carrying the VH and JH coding sequences in different reading frames. We show here that such 'null cells' are not dead-end products of the B-cell developmental pathway but can perform a novel VH to VHDJH joining using a 5' VH segment to replace the VH sequence of the VHDJ-H complex. This process can result in the generation of a VHDJ+H complex and the subsequent expression of an immunoglobulin heavy chain.

Immunoglobulin heavy chain gene rearrangements in X-linked agammaglobulinemia

X-linked agammaglobulinemia (XLA) appears to involve a defect in human B lymphocyte differentiation which is manifested at the pre-B cell stage. The defect segregates as an X-linked recessive trait but is not a single genetic entity. IgM-producing B cell clones were established by Epstein-Barr virus transformation of peripheral blood mononuclear cells of patients with the XLA defect linked to the DXS3 and DXS17 chromosomal loci. Individual XLA B cell clones were demonstrated to have rearrangements of the JH regions of both immunoglobulin VH region loci. The rearranged JH regions of the B cell clone ALA 19 were molecularly cloned and their nucleotide sequence was determined. Both JH-associated rearrangements (designated 191 and 192) resulted from the juxtaposition of variable (VH), diversity (D) and joining (JH) segments (VHDJH rearrangements). The 191 rearrangement employed a VH segment belonging to VH subgroup III and a JH4 segment. The 192 rearrangement employed a VHII and a JH6 segment. The D191 and D192 segments encompassed 21 and 28 nucleotides, respectively, and showed little homology to each other or to previously reported human D sequences. Surprisingly, both VHDJH complexes had open reading frames. However, in accord with principles of allelic exclusion, only the 191 allele was detectably expressed in the total RNA of the cell. A possible mechanism for the lack of expression of the 192 allele is discussed. We conclude that the DXS3-DXS17-linked XLA defect does not preclude VH to DJH rearrangements or the expression of VH containing heavy chain molecules.

Developmentally regulated rearrangement and expression of genes encoding the T cell receptor-T3 complex

Human leukemic cells corresponding to the earliest identifiable stages of intrathymic T cell differentiation lack cell surface expression of the T cell receptor(TCR alpha/beta)-T3 complex but transcribe TCR beta mRNA from either germ-line configuration (1/13) or partially (DJ) or fully (VDJ) rearranged (12/13) genes. These cells do not produce TCR alpha mRNA, but do contain T3 delta and T3 epsilon mRNA and accumulate T3 polypeptides, primarily in the perinuclear envelope. Equivalent normal T cells isolated from thymus have a predominantly germ-line configuration of TCR beta but contain intracellular T3 proteins. T3 gene expression is therefore a very early event in T cell differentiation. TCR alpha chain production appears to be the limiting maturation-linked event in the transport, assembly, and cell surface membrane insertion of the TCR alpha/beta-T3 complex.

Identification of the major immunoglobulin heavy chain poly A+ RNA in murine lymphoid tissue

Total cellular Poly A+ RNA from TEPC15 myeloma and murine lymphoid tissues was analyzed by denaturing agarose gel electrophoresis and Northern blot hybridization to specific heavy chain constant region cDNAs; mu, gamma 2b and alpha RNA species were identified in each of the tissues and in the IgA producing TEPC15 myeloma. In total Poly A+ RNA from TEPC15 myeloma, alpha-cDNA hybridized predominantly to a 2.3 kb RNA species; 11.5 and 4.1 kb RNA species were evident as well. Successive hybridization of the same RNA to mu- and gamma 2b-specific cDNAs demonstrated the presence of both mu and gamma 2b specific RNA species with electrophoretic mobilities apparently identical to the 11.5 and 2.3 kb RNA species identified by alpha-specific hybridization. These data establish the presence of Poly A+ RNA species containing alpha, mu, and gamma 2b sequences in TEPC15 cells and suggest the transcription of RNA from both CH-containing chromosomes in TEPC15 myeloma (one chromosome in the TEPC15 cell line contains all the CH genes while the other chromosome has deleted all CH genes except alpha). In total Poly A+ RNA from normal mouse tissues (Peyer's patch and spleen) all three cDNA probes hybridized predominantly to an 11.5 kb RNA species. Primer extension experiments demonstrated that alpha cDNA could prime for the synthesis by reverse transcriptase of gamma 2b DNA when Peyer's patch Poly A+ RNA was used as the template. This suggests the existence of a single transcript containing alpha and gamma 2b sequences. Murine lymphoid tissues contained putative mRNAs for mu, gamma 2b and alpha heavy chain proteins, whereas TEPC15 myeloma polysomal Poly A+ RNA contained only alpha mRNA.

Analysis of immunoglobulins expressing the V kappa 21E and V kappa 21D gene products. Evidence for multigenic control of the expression of VH-VL combinations

The aim of this work was to study the genetic control of VH-VL combined expression. To this end immunoglobulins expressing the V kappa 21E and V kappa 21D gene products were isolated from the normal sera of several inbred strains of mice using a monoclonal antibody that selectively reacts with V kappa 21E and V kappa 21D subgroups. Analysis of the isoelectric focusing (IEF) pattern of the IgG heavy chains of these immunoglobulins obtained from H-2-congeneic mice revealed as expected that Igh-linked loci strongly influence VH-VL combined expression. The IEF pattern of V kappa 21D and V kappa 21E-associated heavy chains isolated from recombinant inbred mouse strains, however, revealed different phenotypes from either parental strains in strains in which both H-2 and Igh loci segregated from the same parent. These data, therefore, strongly suggest that the expression of VH-VL combinations is controlled in part by genetic loci which segregate independently from those linked to H-2 and Igh.

The role of the VL- and VH-segments in the preferential reassociation of immunoglobulin subunits

Competitive reassociation experiments, in which equimolar amounts of two different L-chains were allowed to compete for a limiting amount of H-chain, were performed to assess the role of the V kappa- and J kappa-segments on the ability of an L-chain to compete. Using H- and L-chains from the murine anti-phosphorylcholine (PC) myelomas, TEPC15, MOPC167 and MCPC603, and a series of V kappa 21 L-chains, it was found that the V kappa 21 L-chains competed uniformly better than the anti-PC L-chains, when the anti-PC H-chains were used, despite any differences in the J-segments of the competing L-chains. In addition, when the anti-PC L-chains, which all employ identical J kappa-segments but very diverse V kappa-segments, were in competition against each other, a hierarchy of competitive ability existed which was independent of whether the chains were autologous or heterologous and independent of antigen binding activity. Competitive reassociation experiments between the V kappa 21 and anti-PC L-chains were also performed using the heterologous anti-lysozyme monoclonal HyHEL-10 H-chain or the anti-galactan J539 H-chain, and it was found that the relative competitive ability of the V kappa 21 L-chains with respect to the anti-PC L-chains was dependent on which H-chain was employed. The results suggested that the main factor favouring preferential reassociation by any particular L-chain was the V kappa-segment and that the effects of the J kappa-segment could not be observed where a high degree of diversity in the V-segments existed. Furthermore, while the results implied that specific pairs of VH- and VL-domains had a higher affinity for each other, this was not a necessary criterion in the formation of autologous pairs of H- and L-chains as demonstrated by the preferential heterologous reassociation of the V kappa 21 L-chains over the autologous anti-PC L-chains. These results were consistent with the independent, random rearrangement of immunoglobulin H- and L-chain V-domain gene segments and predict that the hypothetical repertoire of antibodies is not limited by the selection of specific pairs of high-affinity VH-VL domains.

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.

During B-cell differentiation enhancer activity and transcription rate of immunoglobulin heavy chain genes are high before mRNA accumulation

During differentiation of B lymphocytes, a low level of immunoglobulin heavy chain gene transcripts is apparent at the pre-B-cell stage, and a dramatic increase in immunoglobulin mRNA level is seen after stimulated B cells have matured into immunoglobulin-secreting plasma cells. We have measured the transcription rate of endogenous heavy chain genes using cell lines representative of various stages of murine B-lymphocyte differentiation. We observe a good correlation between RNA polymerase density, as determined by nuclear run-on transcription experiments, and the activity of the heavy chain gene enhancer, as assayed by transfection experiments. Both enhancer activity and heavy chain gene transcription are very high in pre-B-cell lines. Thus we conclude that the increased accumulation of immunoglobulin heavy chain mRNA in immunoglobulin-secreting plasma cells is regulated mainly by posttranscriptional processes.

Rearrangements of T cell receptor loci can be found only rarely in B lymphoid cells

We have studied the rearrangement status of the T cell receptor genes in 64 B lymphoid cell lines, and we found that, unlike the immunoglobulin heavy chain genes in T lymphocytes, T cell receptor beta and related gamma chain genes are almost always in germ-line configuration in B lymphoid cells. The only exception was a myeloma MOPC511 (IgA, chi) which contained all T cell receptor genes, beta 1, beta 2, gamma 1, gamma 2, gamma 3 and alpha, in rearranged configuration in both homologous chromosomes. This exception supports the concept that all immunoglobulin and T cell receptor genes exploit the same recombinase to build their complete variable regions. Obviously, in MOPC511 cells the regulation, which confers the tissue specificity i.e. T vs. B lymphocytes, has failed.

Regulation of genome rearrangement events during lymphocyte differentiation

Analyses of A-MuLV transformed cell lines have provided fundamental insights into the molecular mechanisms which control the rearrangement events leading to the expression of specific antigen receptor genes. These studies have clearly indicated that tissue-specific, developmental stage-specific, and allelically excluded assembly of Ig H and L chain and TCR variable region genes are very strictly regulated processes and, furthermore, that this regulation probably is effected at the level of the accessibility of the individual sets of V gene segments to a common recombinase. More preliminary studies have also suggested that accessibility targeting may be involved in the regulation of directed Ig H chain class-switch recombination events. Currently, we do not understand the nature of "accessible" DNA sequences and we have little understanding of the molecular mechanisms by which Ig (and potentially TCR) chains mediate the regulation of specific recombination events by signaling changes in the accessibility of the various loci. However, an ideal model system for the analysis of these questions is currently available in the form of A-MuLV transformed pre-B cell lines which, in a properly regulated fashion, undergo all of the various recombination events associated with the pre-B stage of B cell differentiation.

Introduced T cell receptor variable region gene segments recombine in pre-B cells: evidence that B and T cells use a common recombinase

We have recently proposed that a common recombinase performs all of the many variable region gene assembly events in B and T cells, and that the specificity of these joining events is mediated by regulating the "accessibility" of the involved gene segments. To test this possibility, we have introduced "accessible" T cell receptor (TCR) variable region gene segments into a pre-B cell line capable of recombining endogenous and transfected immunoglobulin (Ig) variable region gene segments. Although the corresponding "inaccessible" endogenous TCR gene segments do not rearrange in this line or in B cells in general, the introduced TCR gene segments join very frequently and, in fact, closely resemble introduced Ig gene segments in their recombination characteristics. These observations suggest a new role for conventional Ig transcriptional enhancers--recombinational enhancement. Our studies provide insight into additional aspects of the joining mechanism such as N region insertion, aberrant joining, and recombination-recognition sequence requirements for joining.

Direct evidence for chromosomal inversion during T-cell receptor beta-gene rearrangements

A germline T-cell receptor variable region (V beta) gene segment (V beta 14) has been mapped 10 kilobases to the 3' side of the constant region (C beta 2) gene. The V beta 14 gene segment is in an inverted transcriptional polarity relative to the diversity-region (D beta) and joining-region (J beta) gene segments and the C beta genes. Analyses of a T-cell clone (J 6.19), which has productively rearranged the V beta 14 gene segment, indicate that the productive V beta-D beta-J beta rearrangement and its reciprocal flank recombination product are linked and located at either border of a chromosomal inversion. These data demonstrate for the first time a linkage between mammalian V and C genes and verify that a functional T-cell receptor V beta gene can be constructed through a chromosomal inversion.

Analysis of promoter and enhancer cell type specificities and the regulation of immunoglobulin gene expression

We have analysed the properties of IgH promoter (VH) and enhancer (Ig) regions which were used to drive the expression of the chloramphenicol acetyl transferase (CAT) gene (cat) in recombinant plasmids. We observe little synergistic effect between the VH promoter and Ig enhancer on cat gene expression in our constructs. Replacing the VH promoter by the thymidine kinase (TK) promoter does not affect the enhancer-mediated B-cell-specific expression of the cat gene. However, replacement of the VH promoter by the mouse renin gene promoter, which is not normally expressed in B cells, completely abolishes cat gene expression in cells of this lineage. When the Ig enhancer is replaced by the SV40 enhancer (SV), CAT activity is restricted to B cells. The VH promoter is as efficient as the TK promoter in a preB cell line. Extending the size of the VH promoter fragment to include sequences between 126 to 639 bp upstream from the transcription start point results in an eight-fold decrease in CAT activity. In this situation, the tissue specificity of the promoter cat fusion is maintained. Among the various combinations tested here, the association of the TK promoter and the Ig enhancer expresses the cat gene most efficiently. The implications of these observations are discussed.

Characterization of immunoglobulin enhancer deletions in murine plasmacytomas

We have analyzed enhancer deletions found in murine plasmacytomas by DNA cloning. This analysis revealed that the deletions occurred between the JH region and the switch region, removing the Ig heavy chain enhancer. The loss of the enhancer did not significantly affect the level of heavy chain expression as determined by RNA blots. Nucleotide sequence analysis revealed that there are no characteristic or homologous sequences around the recombination site. Extra nucleotides were found at the recombination sites, in a manner analogous to Ig and T-cell receptor V-D-J joining. The germline JH and switch sequences involved in the deletion were analyzed by the in vitro DNA cleavage system with an endonucleolytic activity purified from mouse fetal liver nuclear extracts. It was found that the germline JH DNA was strongly cleaved at the deletion recombination site.

Isolation and characterization of Abelson murine leukemia virus-transformed mast cell lines from midgestation embryonic placenta

Abelson murine leukemia virus was used to transform cells of the midgestation embryonic placenta. The frequency of transformed foci in semisolid agarose was highest when cells were isolated at 10 days of gestation and cell lines could be established in liquid culture. The continuous cell lines express characteristics of cultured mast cells, including surface antigens which are shared with lymphocytes and mononuclear phagocytes. These results imply a relationship between the transforming gene product and the mast cell growth factor interleukin 3.

Regulated progression of a cultured pre-B-cell line to the B-cell stage

The variable (V) regions of heavy and light immunoglobulin chains are encoded by multiple germline DNA elements which are assembled into complete variable-region genes in precursor(pre-) B lymphocytes. The heavy-chain V region (VH) is assembled from three separate germline DNA elements, the variable (VH), diversity (D) and joining (JH) segments; whereas light-chain variable regions of either the kappa or lambda type are assembled from two elements, the VL and JL. Analysis of tumour cell lines or sorted cell populations which represent early and late pre-B cells has suggested that heavy-chain assembly and expression generally precedes that of light chains; but, primarily because of the lack of appropriate model systems to study the phenomenon, the mechanism and significance of this apparently orderly differentiation process are much debated. Here we describe for the first time a transformed cell line, 300-19, which sequentially undergoes all of the immunoglobulin gene rearrangement and expression events associated with the differentiation of pre-B cells to surface immunoglobulin-positive B lymphocytes. Analysis of the in vitro differentiation of 300-19 cells provides direct evidence for distinct differentiation phases of first VH and subsequently VL assembly during B-cell differentiation. Furthermore, these analyses suggest that the mu heavy chain, resulting from a productive VHDJH rearrangement, has both a positive and a negative regulatory role in mediating this ordered differentiation process, that is, signalling the cessation of VH gene assembly and simultaneously signalling the onset of VL assembly.

Cell-type specificity of immunoglobulin gene expression is regulated by at least three DNA sequence elements

The regulation of cell-type specificity of immunoglobulin (lg) mu heavy chain (H) gene expression was examined by introducing various hybrid genes containing lg gene sequences combined with portions of a tissue-nonspecific transcription unit into lymphoid and nonlymphoid cells. Replacing the lymphocyte-specific IgH enhancer with a viral enhancer did not affect tissue specificity of mu Ig gene expression. We identified two new regulatory regions that provide transcriptional tissue specificity. First, the V H promoter region between position -154 and +57 was shown to direct lymphocyte-specific transcription of a bacterial gpt gene, even in the presence of a viral enhancer. Second, mu intragenic sequences, lacking the IgH enhancer, were found to regulate the level of accumulated Ig transcripts in a tissue-specific fashion. These results demonstrate that tissue specificity of Ig gene expression is not solely regulated by the enhancer but that the promoter, and as yet undefined intragenic sequences, contain lymphoid-specific regulatory information.