kappa+lambda+ dual receptor B cells are present in the human peripheral repertoire

A novel L3-acute lymphoblastic leukemia cell line (BALM-27) carrying cytoplasmic immunoglobulin 8 chain but lacking expression of cell surface immunoglobulin chains

A human acute lymphoblastic leukemia (ALL) cell line, BALM-27, was established from the peripheral blood specimen of a patient with B-cell ALL L3 type (ALL-L3) at diagnosis. As with the original leukemia cells, the established line was negative for all cell surface immunoglobulin (Ig) chains, but carrying only cytoplasmic Ig delta heavy chain. Southern blot analysis of the various Ig chain genes demonstrated homozygous deletion of the Jkappa gene, germ line configuration of the Jlambda and rearrangement of IgJH genes. Cytogenetic analysis of both primary leukemic bone marrow and BALM-27 cells showed the der(8;15)(q10;q10) chromosomal alteration, in addition to the t(8;22)(q24;q11) abnormality which is highly associated with ALL-L3 and Burkitt's lymphoma. The established cell line BALM-27 represents a rich resource of abundant, accessible, and manipulable cell material for analyzing the unique expression of Ig chain and for investigating the pathogenesis of B-cell malignancy. The scientific significance of BALM-27 lies in (1) the rarity of this type of leukemia cell lines, and (2) its unique chromosomal aberrations.

Double light chain producing lymphocytes: an enigma of allelic exclusion

The infrequent double light chain producing lymphocyte (DLCPL) is discussed in the context of allelic exclusion. Principally allelic selection rather than allelic exclusion would suggest a role for the DLCPL in the normal B cell population rather than as an aberrance of B cell malignancy. Found primarily in the periphery, it is uncertain at what stage of B cell ontogeny the DLCPL might reside. Nevertheless, through the possible presentation of two functional surface receptors, the DLCPL could be capable of recognizing both self and nonself epitopes.

The occurrence and significance of V gene mutations in B cell-derived human malignancy

The classification of B cell tumors has relevance for refining and improving clinical strategies. However, consensus has been difficult to establish, and although a scheme is now available, objective criteria are desirable. Genetic technology will underpin and extend current knowledge, and it is certain to reveal further subdivisions of current tumor categories. The Ig variable region genes of B cell tumors present a considerable asset for this area of investigation. The unique sequences carried in neoplastic B cells are easily isolated and sequenced. In addition to acting as clone-specific markers of each tumor, they indicate where the cell has come from and track its history following transformation. There is emerging clinical value in knowing whether the cell of origin has encountered antigen and has moved from the naive compartment to the germinal center, where somatic mutation is activated. This is amply illustrated by the subdivision of chronic lymphocytic leukemia into two subsets, unmutated or mutated, each with very different prognosis. Other tumors may be subdivided in a similar way. Microarray technology is developing rapidly to probe gene expression and to further divide tumor categories. All these genetic analyses will provide objective data to enhance both our understanding of B cell tumors and our ability to treat them.

Autoreactive B cells in the marginal zone that express dual receptors

Allotype and isotype exclusion is a property of most lymphocytes. The reason for this property is not known but it guarantees a high concentration of a single receptor, and threshold numbers of receptors may be required for efficient positive and negative selection. Receptor editing compromises exclusion by sustaining recombination even after a functional receptor is formed. Consequently, B cells expressing multiple receptors arise. We have studied such B cells in which one of the two receptors is anti-self, and find that these partially autoreactive B cells accumulate in the marginal zone. The restriction of these cells in this location may help to prevent them from undergoing diversification and developing into fully autoreactive B cells.

Shift of immunoglobulin phenotypes in B-cell precursor cell lines

Rearrangement of immunoglobulin chain genes is a hallmark of mammalian B cell development and differential expression of immunoglobulin chains has aided in the diagnosis and prognostication of patients with ALL. Matsu et al. describe two novel precursor B-cell lines with shift of expression of immunoglobulin phenotypes at diagnosis and relapse. The impact of this observation on diagnosis and the elucidation of the biology of the neoplastic cells will be discussed.

Establishment of novel B-cell precursor leukemia sister cell lines NALM-36 and NALM-37: shift of immunoglobulin phenotype to double light chain positive B-cell

Two novel B-cell precursor (BCP) acute lymphoblastic leukemia (ALL) sister cell lines, designated NALM-36 and NALM-37, were established from the peripheral blood (at diagnosis) and bone marrow (at relapse) of a 37-year-old woman with ALL. Immunophenotyping showed BCP type III pre-B cell characteristics including TdT, CD10, CD19, CD22, CD79a and HLA class II. T cell and myeloid-associated antigens tested were negative except CD5 which was 100% positive for both cell lines. The surrogate light chains lambda5 and VpreB were positive for both cell lines. Cytogenetic analysis of NALM-36 revealed an abnormal karyotype with 46, XX, add(1)(q?42), -14, +mar. Southern blot analysis of the immunoglobulin (Ig) genes status of NALM-36 at 10 months after establishment showed germ line configuration of the kappa light chain gene, and rearrangement of the lambda light and mu heavy chain genes. At 16 months we detected a phenotypic shift of Ig chain protein expression from a BCP-III pre-B cell phenotype to a BCP-IV mature B cell phenotype, with kappa and lambda double Ig light chain and mu heavy chain expression, both on the cell surface and in the cytoplasm. We designated this subline as NALM-36KL. Authenticity of the NALM-36KL, NALM-36 and NALM-37 cell lines was demonstrated by DNA fingerprinting. The extensive characterization of the sister cell lines suggests that these three novel cell lines, derived from a single patient, may represent unique and relevant in vitro model systems for BCP-type leukemia cells. They may provide useful models and unprecedented opportunities for analyzing the multitude of biological aspects of normal and neoplastic B-lymphocytes and their precursors.

Receptor revision plays no major role in shaping the receptor repertoire of human memory B cells after the onset of somatic hypermutation

In order to determine whether V gene replacement accompanies somatic hypermutation in the germinal center (GC) reaction in the human, we analyzed V(kappa)J(kappa) and V(lambda)J(lambda) joints and the kappa-deleting element in single lambda(+) naive and post GC B cells for rearrangements at the kappa and lambda loci. Among 265 lambda(+) post GC B cells, not a single unequivocal and only two potential examples of a cell that switched to lambda light chain expression after accumulation of (unfavorable) mutations in its productive V(kappa) rearrangement were observed. Taking the PCR efficiency into account, the frequency of such cells is likely below 3 %. In addition, heavy and light chain gene rearrangements were amplified and sequenced from the oligoclonal population of IgD-only peripheral blood post GC B cells which display extensive intraclonal sequence diversity. Among 61 IgD-only B cells belonging to 15 clones with intraclonal diversity, no combination of V gene rearrangements indicating receptor revision during clonal expansion was observed. Moreover, among 124 and 49 V(H) genes amplified from IgD-only and class-switched B cells, respectively, not a single example of V(H) revision through V(H) hybrid generation was detected. These results suggest that in the human GC reaction V gene replacement either does not usually accompany somatic hypermutation or is mostly counterselected.

Ordered recombination of immunoglobulin light chain genes occurs at the IGK locus but seems less strict at the IGL locus

Regulation of allelic and isotypic exclusion of human immunoglobulin (Ig) light-chain genes was studied in 113 chronic B-cell leukemias as a "single-cell" model that allowed complete analysis of each light chain allele. Our data show that monospecific Ig light chain expression is in about 90% of cases determined by ordered recombination: Igkappa gene (IGK) rearrangements, followed by IGK deletions and Iglambda gene (IGL) rearrangements, resulting in the presence of only one functional Ig light chain rearrangement. In about 10% (10 cases), 2 functional Ig light chain rearrangements (IGK/IGL or IGL/IGL, but not IGK/IGK) were identified. This might be explained by the fact that regulation of the ordered recombination process is not fully strict, particularly when the IGL locus is involved. Unfavorable somatic mutations followed by receptor editing might have contributed to this finding. Eight of these 10 cases indeed contained somatic mutations. In cases with 2 functional Ig light chain rearrangements, both alleles were transcribed, but monospecific Ig expression was still maintained. This suggests that in these cases allelelic exclusion is not regulated at the messenger RNA level but either at the level of translation or protein stability or via preferential pairing of Ig light and Ig heavy chains. Nevertheless, ordered rearrangement processes are the main determinant for monospecific Ig light chain expression.

Antibody regulation of B cell development

Antibodies on the surface of B lymphocytes trigger adaptive immune responses and control a series of antigen-independent checkpoints during B cell development. These physiologic processes are regulated by a complex of membrane immunoglobulin and two signal transducing proteins known as Ig alpha and Ig beta. Here we focus on the role of antibodies in governing the maturation of B cells from early antigen-independent through the final antigen-dependent stages.

Sequence analysis of light chain genes from human intestinal plasma cells demonstrates that lambda genes are almost all in-frame and highly mutated and most kappa genes are highly mutated when in-frame and minimally mutated when out-of-frame

Around 80 % of immunoglobulin (Ig)-producing cells in man are located in the gut, with a preponderance of IgA- and IgM-producing cells that express heavily mutated IgVH genes. Here we describe the characteristics of Ig light chain genes isolated from human ileal and colonic lamina propria plasma cells. We focused on the properties of the two most commonly used light chain families, Vkappa1 and Vlambda2. Out-of-frame lambda rearrangements were very rare, suggesting that these lambda light chains may have undergone sequential rearrangements until successful conformation was achieved. This has not been observed in the human peripheral B cell population. The in-frame lambda gene rearrangements were highly mutated, with a frequency of mutation that was indistinguishable from that observed in many groups of heavy chain variable regions used by intestinal plasma cells. The in-frame kappac chain rearrangements were also highly mutated, but contained a subgroup of genes (27.3 %) that showed over 98 % homology with the germ-line gene. The majority of unused kappa chain genes were unmutated. A strong tendency for preferential mutation of G over C nucleotides was observed. Detailed analysis of the sequences in which the biases were observed suggested that this was likely to be due to selection, rather than a characteristic of the mechanism introducing the mutations.

Fates of human B-cell precursors

Development of mammalian B-lineage cells is characterized by progression through a series of checkpoints defined primarily by rearrangement and expression of immunoglobulin genes. Progression through these checkpoints is also influenced by stromal cells in the microenvironment of the primary tissues wherein B-cell development occurs, ie, fetal liver and bone marrow and adult bone marrow. This review focuses on the developmental biology of human bone marrow B-lineage cells, including perturbations that contribute to the origin and evolution of B-lineage acute lymphoblastic leukemia and primary immunodeficiency diseases characterized by agammaglobulinemia. Recently described in vitro and in vivo models that support development and expansion of human B-lineage cells through multiple checkpoints provide new tools for identifying the bone marrow stromal cell–derived molecules necessary for survival and proliferation. Mutations in genes encoding subunits of the pre-B cell receptor and molecules involved in pre-B cell receptor signaling culminate in X-linked and non–X-linked agammaglobulinemia. A cardinal feature of these immunodeficiencies is an apparent apoptotic sensitivity of B-lineage cells at the pro-B to pre-B transition. On the other end of the spectrum is the apoptotic resistance that accompanies the development of B-lineage acute lymphoblastic leukemia, potentially a reflection of genetic abnormalities that subvert normal apoptotic programs. The triad of laboratory models that mimic the bone marrow microenvironment, immunodeficiency diseases with specific defects in B-cell development, and B-lineage acute lymphoblastic leukemia can now be integrated to deepen our understanding of human B-cell development.

Fates of human B-cell precursors

Development of mammalian B-lineage cells is characterized by progression through a series of checkpoints defined primarily by rearrangement and expression of immunoglobulin genes. Progression through these checkpoints is also influenced by stromal cells in the microenvironment of the primary tissues wherein B-cell development occurs, ie, fetal liver and bone marrow and adult bone marrow. This review focuses on the developmental biology of human bone marrow B-lineage cells, including perturbations that contribute to the origin and evolution of B-lineage acute lymphoblastic leukemia and primary immunodeficiency diseases characterized by agammaglobulinemia. Recently described in vitro and in vivo models that support development and expansion of human B-lineage cells through multiple checkpoints provide new tools for identifying the bone marrow stromal cell–derived molecules necessary for survival and proliferation. Mutations in genes encoding subunits of the pre-B cell receptor and molecules involved in pre-B cell receptor signaling culminate in X-linked and non–X-linked agammaglobulinemia. A cardinal feature of these immunodeficiencies is an apparent apoptotic sensitivity of B-lineage cells at the pro-B to pre-B transition. On the other end of the spectrum is the apoptotic resistance that accompanies the development of B-lineage acute lymphoblastic leukemia, potentially a reflection of genetic abnormalities that subvert normal apoptotic programs. The triad of laboratory models that mimic the bone marrow microenvironment, immunodeficiency diseases with specific defects in B-cell development, and B-lineage acute lymphoblastic leukemia can now be integrated to deepen our understanding of human B-cell development.

Spontaneous reduction of leukemic lymphoma cells possibly by anti-tumor antibody-mediated phagocytosis; a kappa lambda-dual-positive B cell lymphoma

We have investigated the possible role of anti-tumor antibody detected in a case of follicular lymphoma which demonstrated the spontaneous reduction of leukemic tumor cells. The tumor cells genotypically had monoclonal rearrangements of the immunoglobulin J H and C kappa genes, but phenotypically exhibited surface IgG, A, kappa and lambda (kappa lambda dual positivity). The culture study revealed that IgGlambda, at least, was derived from the serum, and IgAkappa was expressed intrinsically. Furthermore, the positive correlation between the densities of both surface light chains on two-color flow cytometry, the rosette formation study and its inhibition test by the Fcgamma fragment suggested that the serum IgGlambda combined with some antigens on the tumor-cell surface via its Fab portion and with the Fcgamma receptor of macrophages via its Fc portion. From these findings, we regarded the present case as an anti-tumor antibody-coated lymphoma. In addition, the phagocytic study disclosed that the serum-derived IgGlambda, at least, might have induced the phagocytosis of circulating lymphoma cells by macrophages. In conclusion, the existence of the anti-tumor antibody-coated lymphoma may be helpful in clarifying the immunological mechanism of the spontaneous regression occasionally seen in lymphomas.

Frequency and characterization of phenotypic Ig heavy chain allelically included IgM-expressing B cells in mice

Ig H chain (IgH) allelic exclusion remains a puzzling topic. Here, we address the following question: Do phenotypic IgH allelically included cells exist in normal mice and, if so, at what frequency? Sorted cells from heterozygous mice were evaluated for the expression of both IgM allotypes by double intracytoplasmic stainings. Dual expressors were found at a frequency of 1 in 104 splenic B cells. These data were confirmed by direct sequencing of IgH-rearranged alleles obtained after single cell (or clone) PCR on dual expressors. Typically, these cells have one rearranged J558 VH whereas, in the other allele, a D-proximal VH gene is used. Interestingly, dual expressors have rearranged IgH alleles with similar CDR3 lengths. These results show that, in contrast to the kappa L chain and the TCR beta-chain, IgH allelic exclusion is the result of an extremely stringent mechanism. We discuss two non-mutually exclusive scenarios for the origin of IgH dual expressors: 1) IgH allelically included cells arise when the first allele to rearrange productively is unable to form a pre-BCR; dual expressors could be a subset of this population in which, upon conventional L chain rearrangement, both IgH are expressed at the surface; and 2) synchronous rearrangement of the IgH alleles.

Receptor selection in B and T lymphocytes

The process of clonal selection is a central feature of the immune system, but immune specificity is also regulated by receptor selection, in which the fate of a lymphocyte's antigen receptor is uncoupled from that of the cell itself. Whereas clonal selection controls cell death or survival in response to antigen receptor signaling, receptor selection regulates the process of V(D)J recombination, which can alter or fix antigen receptor specificity. Receptor selection is carried out in both T and B cells and can occur at different stages of lymphocyte differentiation, in which it plays a key role in allelic exclusion, positive selection, receptor editing, and the diversification of the antigen receptor repertoire. Thus, the immune system takes advantage of its control of V(D)J recombination to modify antigen receptors in such a way that self/non-self discrimination is enhanced. New information about receptor editing in T cells and B-1 B cells is also discussed.

Restricted immunoglobulin variable region (Ig V) gene expression accompanies secondary rearrangements of light chain Ig V genes in mouse plasmacytomas

The many binding studies of monoclonal immunoglobulin (Ig) produced by plasmacytomas have found no universally common binding properties, but instead, groups of plasmacytomas with specific antigen-binding activities to haptens such as phosphorylcholine, dextrans, fructofuranans, or dinitrophenyl. Subsequently, it was found that plasmacytomas with similar binding chain specificities not only expressed the same idiotype, but rearranged the same light (V(L)) and heavy (V(H)) variable region genes to express a characteristic monoclonal antibody. In this study, we have examined by enzyme-linked immunosorbent assay five antibodies secreted by silicone-induced mouse plasmacytomas using a broader panel of antigens including actin, myosin, tubulin, single-stranded DNA, and double-stranded DNA. We have determined the Ig heavy and light chain V gene usage in these same plasmacytomas at the DNA and RNA level. Our studies reveal: (a) antibodies secreted by plasmacytomas bind to different antigens in a manner similar to that observed for natural autoantibodies; (b) the expressed Ig heavy genes are restricted in V gene usage to the V(H)-J558 family; and (c) secondary rearrangements occur at the light chain level with at least three plasmacytomas expressing both kappa and lambda light chain genes. These results suggest that plasmacytomas use a restricted population of B cells that may still be undergoing rearrangement, thereby bypassing the allelic exclusion normally associated with expression of antibody genes.

The roles of preB and B cell receptors in the stepwise allelic exclusion of mouse IgH and L chain gene loci

Membrane-bound preBCR of wild-type mice, and probably also preBCR-like V(preB) muH chain complexes in lambda5-deficient mice, signal allelic exclusion so that < 0.1% of all preB-II cells and all subsequent B lineage cells express two muH chains on their surface. On the other hand a large number of muH chains which are originally generated at the transition of preB-I to preB-II cells cannot pair with surrogate L chains, cannot form a preBCR on the surface and, hence, allow two H chain alleles to be productively rearranged in one B-lineage cell. By contrast membrane-bound BCR on immature B cells does not signal allelic or isotypic exclusion Of Ig kappaL and lambdaL chain gene loci. This allows the rearrangement machinery to remain active, and secondary L chain rearrangements on one kappaL chain allele are frequently observed. Rapid selection of fitting H/L chain pairs, forming BCR on the surface, allows B-lineage cells to enter the mature B cell pool where the rearrangement machinery is shut off, securing allelic exclusion of L chain loci in most B cells.

Phenotypic and molecular characterization of human peripheral blood B-cell subsets with special reference to N-region addition and J kappa-usage in V kappa J kappa-joints and kappa/lambda-ratios in naive versus memory B-cell subsets to identify traces of receptor editing processes

We identified a population of IgM+IgD+ B-cells in the peripheral blood (PB) of humans that express somatically mutated V-region genes like classical class switched or IgM-only memory B-cells and comprise around 15% of PB B-cells in adults. Mutated IgM+IgD+ cells differ from unmutated naive IgM+IgD+ cells in that they express the CD27 cell surface antigen. In addition, a very small subset of IgD-only B-cells was identified in the PB that carried rearranged VH-genes with an extremely high load of somatic mutations (up to 60 mutations per gene). A common characteristic of the four somatically mutated subsets, which altogether comprise 40% of PB B-lymphocytes in adults, is the surface expression of CD27. This antigen may thus represent a general marker for memory B-cells in the human. Somatically mutated and unmutated PB B-cell subsets were analyzed for N-region addition and J kappa-usage in V kappa J kappa-joints, and in addition for the respective kappa/lambda-ratios: N-nucleotides could be identified in a large fraction of V kappa-regions of all B-cell subsets, indicating that N-region insertion already occurs in the pre-germinal center (GC) phase of B-cell development. Both the J kappa-usage in expressed V kappa J kappa-joints and the kappa/lambda-ratio from somatically mutated B-cells do not differ substantially from those of the unmutated cells, so that in terms of these parameters, a contribution of secondary V kappa J kappa-rearrangements in shaping the memory B-cell repertoire is not detectable.

Re-expression of RAG-1 and RAG-2 genes and evidence for secondary rearrangements in human germinal center B lymphocytes

V(D)J recombination occurs in immature B cells within primary lymphoid organs. However, recent evidence demonstrated that the recombination activating genes RAG-1 and RAG-2 can also be expressed in murine germinal centers (GC) where they can mediate secondary rearrangements. This finding raises a number of interesting questions, the most important of which is what is the physiological role, if any, of secondary immunoglobulin (Ig) gene rearrangements. In the present report, we provide evidence that human GC B cells that have lost surface immunoglobulin re-express RAG-1 and RAG-2, suggesting that they may be able to undergo Ig rearrangement. Furthermore, we describe two mature B cell clones in which secondary rearrangements have possibly occurred, resulting in light chain replacement. The two clones carry both kappa and lambda light chains productively rearranged, but fail to express the x chain on the cell surface due to a stop codon acquired by somatic mutation. Interestingly, the analysis of the extent of somatic mutations accumulated by the two light chains might suggest that the lambda chain could have been acquired through a secondary rearrangement. Taken together, these data suggest that secondary Ig gene rearrangements leading to replacement may occur in human GC and may contribute to the peripheral B cell repertoire.

Thymocyte selection in Vav and IRF-1 gene-deficient mice

T cells undergo a defined program of phenotypic and genetic changes during differentiation within the thymus. These changes define commitment of T-cell receptor (TCR) gamma delta and TCR alpha beta cells and lineage differentiation into CD4+ T helper and CD8+ cytotoxic T cells. T-cell differentiation and selection in the thymus constitute a tightly co-ordinated multistep journey through a network that can be envisaged as a three-dimensional informational highway made up of stromal cells and extracellular matrix molecules. This intrathymic journey is controlled by information exchange, with thymocytes depending on two-way cellular interactions with thymic stromal cells in order to receive essential signals for maturation and selection. Genetic inactivation of surface receptors, signal transduction molecules, and transcription factors using homologous recombination has provided novel insight into the signaling cascades that relay surface receptor engagement to gene transcription and subsequent progression of the developmental program. In this review we discuss molecular mechanisms of T lymphocyte development in mice that harbour genetic mutations in the guanine nucleotide exchange factor Vav and the interferon regulatory transcription factor 1 (IRF-1). We also propose a novel model of T-cell selection based on TCR alpha chain-directed signals for allelic exclusion and TCR alpha-based selection for single receptor usage.

Receptor-Specific Allelic Exclusion of TCRVα-Chains During Development

Expression of a single Ag receptor on lymphocytes is maintained via allelic exclusion that generates cells with a clonal receptor repertoire. We show in normal mice and mice expressing functionally rearranged TCRαβ transgenes that allelic exclusion at the TCRα locus is not operational in immature thymocytes, whereas most mature T cells express a single TCRVα-chain. TCRVα allelic exclusion in mature thymocytes is regulated through a CD45 tyrosine phosphatase-mediated signal during positive selection. Using functional and genetic systems for selection of immature double TCRVα+ thymocytes, we show that peptide-specific ligand recognition provides the signal for allelic exclusion, i.e., mature T cells maintain expression of the ligand-specific TCRVα-chain, but lose the nonfunctional receptor. Whereas activation of TCRVβ-chains or CD3ε leads to receptor internalization, TCRVα ligation promotes retention of the TCR on the cell surface. Although both TCRVα- and TCRVβ-chains trigger phosphotyrosine signaling, only the TCRVβ-chain mediates membrane recruitment of the GTPase dynamin. These data indicate that TCRVα-directed signals for positive selection control allelic exclusion in T cells, and that developmental signals can select for single receptor usage.

Expression level of a transgenic lambda2 chain results in isotype exclusion and commitment to B1 cells

Two new lambda2 chain-transgenic mouse lines were established, both of which showed stable transgene expression during aging of the mice. The line L23, which expressed the transgene at low levels, exhibited normal B cell development, antibody responses and serum Ig levels. Most of the B cells in this mouse line co-expressed the transgenic lambda2 chain together with an endogenous kappa chain, thus showing poor allelic exclusion of endogenous L chains. On the other hand, high expression of the transgenic lambda2 chain in the other mouse line, L2, resulted in nearly complete exclusion of endogenous L chain isotypes. In this line, the lambda2 transgene was already detectable in the cytoplasm of all preB-II cells and some pro/preB-I cells. Its expression during these early phases obviously inhibited development of conventional B2 cells, since the B cells in the periphery of these mice were almost exclusively of the B1 type. This finding was confirmed by adoptive transfer of transgenic bone marrow into lethally irradiated recipients. Very few B cells were present in the spleen of such recipients. The serum IgM levels of L2 mice were close to normal and the majority of these IgM were associated with the transgenic lambda2 chain. Antibody responses to thymus-dependent antigens in such mice were almost exclusively found to be of IgM class. Together, these findings indicate a developmental bias leading to a predominance of B1 cells in the L2 line.

Receptor editing and commitment in B lymphocytes

B cells that fail to pass a developmental checkpoint, either as immature or mature B cells, can be rescued by creating a new B cell antigen receptor through nested secondary immunoglobulin gene rearrangements, a process termed receptor editing. Tolerance-mediated receptor editing occurs in self-reactive immature bone marrow B cells, while peripheral receptor editing probably occurs in low-affinity B cells competing for antigen and for survival signals within the germinal center response.

Lack of allelic exclusion in B cell chronic lymphocytic leukemia

We determined the immunoglobulin (Ig) V(H) subgroup expressed by the leukemia cells of 108 patients with B cell chronic lymphocytic leukemia (CLL). Surprisingly, we found that six samples (5%) each expressed Ig of more than one V(H) subgroup. Southern blot analysis demonstrated that these samples each had rearrangements involving both Ig heavy chain alleles. Nucleic acid sequence analyses of the Ig cDNA revealed each to express two functional Ig V(H) genes: V(H)3-33 and V(H)4-39; V(H)3-7 and V(H)4-39; V(H)3-23 and V(H)4-61; V(H)2-70 and V(H)3-30.3; or V(H)3-30 and V(H)4-b (DP67). One sample expressed three Ig V(H) genes: V(H)2-70, V(H)3-7, and V(H)4-59. Despite having more than one Ig heavy chain transcript, each sample was found to express only one functional Ig light chain. From the primary sequence, we deduced that the Ig of some of these CLL samples should react with Lc1, a monoclonal antibody (mAb) reactive with a supratypic cross-reactive idiotype present on Ig encoded by a subgroup of Ig V(H)4 genes (namely, V(H)4-39, V(H)4-b [DP-67], V(H)4-59, or V(H)4-61), and B6, an mAb that reacts with Ig encoded by certain Ig V(H)3 genes (namely, V(H)3-23, V(H)3-30, or V(H)3-30.3), and/or modified staphylococcal protein A (SpA), a 45-kilodalton bacterial "superantigen" that reacts with most Ig of the V(H)3 subgroup. Flow cytometric analyses revealed that such samples did in fact react with Lc1 and B6 and/or SpA, but not with control mAbs of irrelevant specificity. This study demonstrates that a subset of CLL patients have leukemic B cells that express more than one functional Ig heavy chain.

Molecular mechanisms and selective influences that shape the kappa gene repertoire of IgM+ B cells

To analyze the human kappa chain repertoire and the influences that shape it, a single cell PCR technique was used that amplified Vkappa Jkappa rearrangements from genomic DNA of individual human B cells. More than 350 productive and 250 nonproductive Vkappa Jkappa rearrangements were sequenced. Nearly every functional Vkappa gene segment was used in rearrangements, although six Vkappa gene segments, A27, L2, L6, L12a, A17, and O12/O2 were used preferentially. Of these, A27, L2, L6, and L12a showed evidence of positive selection based on the variable region and not CDR3, whereas A17 was overrepresented because of a rearrangement bias based on molecular mechanisms. Utilization of Jkappa segments was also nonrandom, with Jkappa1 and Jkappa2 being overrepresented and Jkappa3 and Jkappa5 underrepresented in the nonproductive repertoire, implying a molecular basis for the bias. In B cells with two Vkappa Jkappa rearrangements, marked differences were noted in the Vkappa segments used for the initial and subsequent rearrangements, whereas Jkappa segments were used comparably. Junctional diversity was generated by n-nucleotide addition in 60% and by exonuclease trimming in 75% of the Vkappa Jkappa rearrangements analyzed. Despite this large degree of diversity, a strict CDR3 length was maintained in both productive and nonproductive rearrangements. More than 23% of the productive rearrangements, but only 7% of the nonproductive rearrangements contained somatic hypermutations. Mutations were significantly more frequent in Vkappa sequences derived from CD5- as compared with CD5+ B cells. These results document that the gene segment utilization within the Vkappa repertoire is biased by both intrinsic molecular processes as well as selection after light chain expression. Moreover, IgM+ memory cells with highly mutated kappa genes reside within the CD5- but not the CD5+ B cell compartment.

Neoteny in lymphocytes: Rag1 and Rag2 expression in germinal center B cells

The products of the Rag1 and Rag2 genes drive genomic V(D)J rearrangements that assemble functional immunoglobulin and T cell antigen receptor genes. Expression of the Rag genes has been thought to be limited to developmentally immature lymphocyte populations that in normal adult animals are primarily restricted to the bone marrow and thymus. Abundant RAG1 and RAG2 protein and messenger RNA was detected in the activated B cells that populate murine splenic and Peyer's patch germinal centers. Germinal center B cells thus share fundamental characteristics of immature lymphocytes, raising the possibility that antigen-dependent secondary V(D)J rearrangements modify the peripheral antibody repertoire.

Two kappa immunoglobulin light chains are secreted by an anti-DNA hybridoma: implications for isotypic exclusion

An anti-DNA hybridoma derived from an MRL/lpr mouse secretes two different kappa light chains in combination with a single heavy chain. Multiple single cell clones express and secrete immunoglobulin containing both kappa light chains. The N-terminal protein sequences of the light chains correspond to sequences predicted from functionally rearranged mRNAs subjected to reverse transcription and amplified by polymerase chain reaction (PCR). Karyotype analysis of the hybridoma indicates a clonal line derived from the fusion of two cells. By amino acid sequence comparison and PCR analysis, both functional kappa light chains are derived from the MRL/lpr spleen. The two functional light chain cDNAs were cloned and co-transfected into COS-7 cells with the heavy chain cDNA. Only one of the light chains in combination with mAb 3E10 heavy chain confers anti-DNA reactivity. The presence of two separate kappa light chains and, therefore, two separate antigen receptors on a single B cell may have ramifications for both polyclonal activation and toleration of lupus B cells.

Immature B cells from human and mouse bone marrow can change their surface light chain expression

The capacity of bone marrow-derived surface immunoglobulin-positive (sIg+) human and mouse immature B cells, generated either in vitro or in vivo, to change their light (L) chain expression, has been assayed by the number of cells which change in vitro from one type of L chain to the other type, or to no sIg at all. Immature sIg+ B cells were generated in vitro from sIg- precursor cells from human or mouse bone marrow. The immature sIg+ cells expressed RAG-1. Human sIg+ cells expressed kappa and lambda L chains in ratios between 1:1 and 3:1, whereas in mouse cells, this ratio ranged from 10:1 to 20:1. Upon reculture of the human and mouse kappa+ sIg+ cells, about half of them remained kappa+, a quarter became lambda+, and another quarter became sIg-. Between 1 and 3% expressed both kappa and lambda chains. Of the human lambda+ cells, about two-thirds remained lambda+, only 1 to 2% became kappa+, while the other third became sIg-. Again, between 1 and 3% expressed both kappa and lambda L chains. These results indicate that expression of sIgM in the B cell membrane does not terminate L chain gene rearrangement, and that some order exists in kappa versus lambda gene rearrangements. Hence, human and mouse kappa+ immature B cells can become lambda+, but very few of the lambda+ cells can become kappa+, and both can become sIg-. Further, human CD10+/sIg+ kappa+ and lambda+ cells and mouse B220low/sIglow kappa+ cells enriched from bone marrow, i.e. immature B cells differentiated in vivo, changed their Ig phenotype upon in vitro culture, but in lower frequencies. By contrast, human and mouse mature B cells did not change their L chain or Ig phenotype. Hence, at least a part of the sIg+ immature B cells in bone marrow retain the capacity to change their L chain and Ig phenotype, and this capacity is lost when they become mature, peripheral B cells.

Positive and negative selection events during B lymphopoiesis

Early in B-cell development, large numbers of cells have to be generated, each of which expresses only one type of B-cell receptor (i.e. Ig) on its surface. This is achieved by the surface expression of a pre-B cell receptor containing a mu heavy chain/surrogate light chain which differentially provides signals for two responses of precursor B cells at this stage of development. On the one hand, it signals inhibition of further rearrangements of variable heavy chain to diverse-joining heavy chain loci to achieve allelic exclusion at the heavy-chain locus. On the other hand, it signals proliferative expansion by factors between 20 and 100. Later in B-cell development, tolerance to autoantigens must be established and maintained. Tolerance is achieved by developmental arrest and induction of secondary light-chain gene rearrangements in those IgM+ immature B cells that are reactive to autoantigens presented in the primary B-cell generating organs. Even later in development, when mature surface (s)IgM+/sIgD+ B cells encounter autoantigens presented to them in the periphery, either deletion or anergy of the autoantigen-reactive cells occurs. Anergic cells have a sIg-dependent, sIg-proximal defect in signaling and are short-lived. Anergy can be broken in vitro by polyclonal activation via ligation of CD40 in the presence of IL-4. A small part of the remaining immature B cells not reactive to autoantigens are selected to become mature, antigen-reactive sIgM+/sIgD+ B cells. Molecules which might guide such positive selection of B cells still remain to be identified.