IL-4 regulates differentiation and proliferation of human precursor B cells

The mechanism by which precursor and pre-B cells undergo differentiation is unclear; however, it is known that growth factors play an important role in this maturation process. The lymphokine, IL-4 has been shown to increase expression of class II Ag on B cells and induce B cell proliferation. In the murine system, IL-4 induced differentiation of precursor B cells into pre-B cells. In order to analyze growth factors on B cell development we have established an in vitro culture system for human bone marrow cells. We found that in the presence of IL-4, normal human precursor and pre-B cells can be induced to differentiate in the absence of cell proliferation with four days of culture. Furthermore, IL-4 depressed proliferation induced by supernatant from a T cell line. The differentiation was measured by an increase in both the number of cytoplasmic mu and surface IgM-positive cells. The effect of IL-4 on precursor and pre-B cell differentiation was detected as soon as 14 h of exposure to the lymphokine in the absence of an adherent feeder layer. These data suggest that IL-4 directly affects the differentiation process of normal human precursor and pre-B cells, and may antagonistically affect cell proliferation.     

Cell surface antigens expressed by subsets of pre-B cells and B cells

A large number of monoclonal antibodies, produced by immunizing rats with mouse pre-B cell lines, have been analyzed for their ability to define cell surface antigens expressed by B cells at early stages of differentiation. Whereas many antibodies recognized antigens on pre-B cell lines, only two clones detected cell surface antigens that were distinguished by their restricted distribution among a panel of continuous cell lines and cells from various tissues. Monoclonal antibody clone AA4.1 recognized a cell surface antigen found on all pre-B lymphomas and on one of three B lymphomas tested. This antigen was found on cells at highest frequency in the bone marrow. Adult spleen and fetal liver also have detectable numbers of AA4.1+ cells. Cells that did not express this antigen include plasmacytomas, two of three B lymphomas, T lymphomas, a stem cell line, adult liver, brain, thymus, and lymph node cells. Clone GF1.2 detected an antigen on some pre-B cell lines, one of three B lymphomas tested, and a small fraction of cells from adult bone marrow, spleen, lymph node, and fetal liver. Plasmacytomas, some pre-B lymphomas, two B lymphomas, T lymphomas, adult liver, brain, and thymus cells were negative. In adult bone marrow, AA4.1 bound to all cytoplasmic IgM+ pre-B cells, whereas GF1.2 detected one-half of these cells. Both antibodies recognized approximately 50% of surface IgM+ (sIgM+) bone marrow cells. A small population of bone marrow cells lacking any detectable Ig (surface or cytoplasmic) also reacted with these antibodies. Depletion of AA4.1 or GF1.2 antigen-bearing cells from bone marrow reduced the ability of bone marrow B cells to respond to LPS by 50 to 65%. Experiments with a cloned pre-B lymphoma demonstrate that AA4.1+ pre-B cells become sIgM+ GF1.2+ B cells after activation with LPS. These antibodies recognize cell surface determinants with restricted distribution among the B lymphocyte lineage because they detect antigens displayed by normal and transformed immature B lymphocytes.     

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

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

Impaired precursor B cell differentiation in Bruton's tyrosine kinase-deficient mice

Bruton's tyrosine kinase (Btk) is a cytoplasmic signaling molecule that is crucial for precursor (pre-B) cell differentiation in humans. In this study, we show that during the transition of large cycling to small resting pre-B cells in the mouse, Btk-deficient cells failed to efficiently modulate the expression of CD43, surrogate L chain, CD2, and CD25. In an analysis of the kinetics of pre-B cell differentiation in vivo, Btk-deficient cells manifested a specific developmental delay within the small pre-B cell compartment of about 3 h, when compared with wild-type cells. Likewise, in in vitro bone marrow cultures, Btk-deficient large cycling pre-B cells showed increased IL-7 mediated expansion and reduced developmental progression into noncycling CD2(+)CD25(+) surrogate L chain-negative small pre-B cells and subsequently into Ig-positive B cells. Furthermore, the absence of Btk resulted in increased proliferative responses to IL-7 in recombination-activating gene-1-deficient pro-B cells. These findings identify a novel role for Btk in the regulation of the differentiation stage-specific modulation of IL-7 responsiveness in pro-B and pre-B cells. Moreover, our results show that Btk is critical for an efficient transit through the small pre-B cell compartment, thereby regulating cell surface phenotype changes during the developmental progression of cytoplasmic mu H chain expressing pre-B cells into immature IgM(+) B cells.     

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

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

B lymphocytes express and lose syndecan at specific stages of differentiation.

Lymphopoietic cells require interactions with bone marrow stroma for normal maturation and show changes in adhesion to matrix during their differentiation. Syndecan, a heparan sulfate-rich integral membrane proteoglycan, functions as a matrix receptor by binding cells to interstitial collagens, fibronectin, and thrombospondin. Therefore, we asked whether syndecan was present on the surface of lymphopoietic cells. In bone marrow, we find syndecan only on precursor B cells. Expression changes with pre-B cell maturation in the marrow and with B-lymphocyte differentiation to plasma cells in interstitial matrices. Syndecan on B cell precursors is more heterogeneous and slightly larger than on plasma cells. Syndecan 1) is lost immediately before maturation and release of B lymphocytes into the circulation, 2) is absent on circulating and peripheral B lymphocytes, and 3) is reexpressed upon their differentiation into immobilized plasma cells. Thus, syndecan is expressed only when and where B lymphocytes associate with extracellular matrix. These results indicate that B cells differentiating in vivo alter their matrix receptor expression and suggest a role for syndecan in B cell stage-specific adhesion.     

Bcl-2 reduces mutant rates in a transgenic lacZ reporter gene in mouse pre-B lymphocytes

To assess mutagenesis during early B-lymphocyte development in vitro, progenitor B cells (pre-B cells) were obtained from fetal livers of BALB/c mice and DBA/2N mice that harbored the transgenic shuttle vector, pUR288, with a lacZ reporter gene for the determination of mutant frequencies (MFs). Differentiation-arrested pre-B cells demonstrated a marked dose-dependent increase in lacZ mutant levels after exposure to gamma-irradiation with a peak MF of 250 x 10(-5) at 2.5 Gy. Without genotoxic treatment, pre-B cells undergoing spontaneous differentiation into surface IgM expressing immature B cells exhibited lacZ mutant levels of up to 95 x 10(-5). The mutational pattern was dominated in both experiments by illegitimate recombination mutations of lacZ, not point mutations. Likewise, in both experiments, the enforced expression of Bcl-2 resulted in a striking reduction of lacZ mutations. These findings indicated that mouse pre-B cells are prone to accumulate induced and self-inflicted mutations, particularly recombinations. Additionally, our studies revealed a heretofore unknown role of Bcl-2 in inhibiting mutagenesis during early B-cell development in mice.     

Differentiation of murine B cell precursors in agar culture. II. Response of precursor-enriched populations to growth stimuli and demonstration that the clonable pre-B cell assay is limiting for the B cell precursor

We established culture conditions under which fetal liver-derived B cell progenitors divide and differentiate in semisolid agar, forming colonies containing antibody-secreting cells. An important feature of this assay system is that, under certain conditions, it is limiting for only one component. This was revealed by determining the slope of the least-squares log-log regression line generated when the initial seeding density was varied. When support for the growth of the clonable pre-B cells was provided by fetal liver-derived adherent accessory cells, the slope of the regression line was 1, consistent with the interpretation that only one component, the pre-B cell, was limiting under these conditions. This interpretation was tested in the present report by positive selection for cells expressing B220, Lyb-2, or AA4.1, surface markers known to be present on cell lines of the B lineage. In all cases, an increased incidence of clonable pre-B cells was observed. Furthermore, regression analysis of titration experiments undertaken with these enriched populations revealed that the assay was still limiting for a single component. A second set of growth conditions have been defined in which the clonable pre-B assay appears to be limiting for more than one component. These conditions are obtained when the adherent accessory cells are replaced by one of three distinct hemopoietic growth factors, including CSF-1 (macrophage growth factor), GM-CSF (neutrophil/macrophage growth factor), or Multi-HGF (multi-lineage hemopoietic growth factor, also called BPA or IL 3). The most straightforward interpretation of these data is that a second cell type, distinct from the B cell precursor and dependent on the growth factors, was limiting under these conditions. In the present report, this hypothesis was confirmed because growth factor responsiveness was completely absent in B220 and Lyb-2-enriched populations. Factor responsiveness was found in unseparated fetal liver and in AA4-enriched populations. However, the AA4-enriched populations, in contrast to the B220- or Lyb-2-enriched populations, also contained a large number of factor-responsive neutrophil/macrophage colonies, raising the possibility that the effect of factors on AA4+ clonable pre-B cells was accessory cell-mediated.     

Immunoglobulin production by human peripheral lymphocytes induced by anti-C3 receptor antibodies

Human fetal liver was examined during various stages of gestation for the presence of B cells by using immunoglobulin isotype markers and monoclonal B cell antibodies. Frozen sections were studied with the use of single and double staining methods. The B cell monoclonal antibodies used were BA1, which defines both mature and immature B cells; B1, which identifies mature B cells; and B532, which binds to activated mature B cells. The data indicate that both BA1 and mu+ cells are present at 12 wk gestation, and increase in frequency with age. Delta and B1-bearing cells are detected only later in fetal life. Phenotypically identifiable T cells are present at low frequencies in the fetal liver throughout the time period examined (12 to 21 wk). At 12 to 13 wk gestation, the numbers of kappa- and lambda-chain-positive cells are two to three times greater than the number of mu+ cells. Based on morphology and staining with OKM1, these light chain-bearing cells appear to be non-lymphoid, most likely cells of macrophage origin that have phagocytosed maternal IgG. Our results show that the monoclonal antibodies reacting with subsets of B cells in adults can also be used to define distinct subsets of B and pre-B cells in the fetal liver.     

Pre-B cells in mouse bone marrow: in vitro maturation of peanut agglutinin binding B lymphocyte precursors separated from bone marrow by fluorescence-activated cell sorting

Peanut agglutinin (PNA) binding by mouse bone marrow cells and fractionation by the fluorescence-activated cell sorter have previously been shown to separate high concentrations of pre-B cells, as identified by cytoplasmic mu-chains (c mu). PNA+ and PNA- marrow cell fractions have now been assayed for the presence of functional pre-B cells able to generate mature B cells in culture, as defined by three criteria, the appearance of cell surface mu-chains (s mu), immunoglobulin secretion in response to bacterial lipopolysaccharides, and B cell colony formation. Small PNA+ cell fractions contained pre-B cells that developed into mature B lymphocytes in 1/2 to 1 day but did not sustain B cell production. Large PNA+ cells included pre-B cells that gave rise to mature B lymphocytes after an interval of 1 1/2 to 3 days and were able to sustain B cell genesis in vitro for at least 3 to 5 days thereafter. PNA- cell fractions contained mature B cells but lacked pre-B cell activity. The results demonstrate that PNA binding allows the separation of functional subsets of pre-B cells from bone marrow and that the three in vitro assays used in this study are closely comparable with one another as functional pre-B cell criteria. The findings suggest correlations between functional assays, c mu expression, PNA receptors, and cell size in characterizing stages of pre-B cell development.     

B cells in patients with X-linked agammaglobulinemia

X-linked agammaglobulinemia (XLA) has been described as a disorder in which pre-B cells fail to differentiate into B cells. However, a small number of B cells have been seen occasionally in patients with this disorder. Because the phenotype of these cells might be helpful in defining the site of the defect in XLA, immunofluorescent staining techniques were used to characterize the B cells that can be found in patients with XLA. Surface IgM-positive B cells could be detected in the peripheral circulation of all seven patients studied. These B cells constituted a very small percentage of the total lymphocytes (0.01 to 0.3% compared with 3.2 to 13.7% in controls) and differed in phenotype from control B cells. They were much more brightly stained for surface IgM (p less than 0.001) and less brightly stained for Ia (p less than 0.01). This phenotype is similar to that described for immature B cells in the mouse. Over 80% of the patients' B cells expressed surface IgD, and all expressed the B cell marker B1, but only 35% expressed the B cell marker B2. This B cell marker, which is the C3d receptor and the Epstein-Barr virus receptor, is expressed later in ontogeny than B1 and can be detected on over 80% of control B cells. All B cells expressed either kappa or lambda light chain. These findings indicate that the defect in differentiation of pre-B cells into B cells is not absolute in patients with XLA. The immature phenotype of the B cells additionally suggests that there may be a block in the maturation of B cells at more than one stage of differentiation in this disorder.     

Establishment of a leukemic cell model for studying human pre-B to B cell differentiation

Reproducible models for examining early stages of human B cell differentiation are poorly developed. We now describe the establishment and characterization of a novel human leukemic cell line that recapitulates the pre-B to B cell stage of differentiation. This cell line, designated BLIN-1, was initially established in tissue culture medium containing low m.w. B cell growth factor, and consistently shows a dependency on this cytokine for optimal growth at low density. BLIN-1 cells have a 9p chromosomal abnormality, identical to the abnormality present in the leukemic blasts from the patient's original bone marrow aspirate. The immunologic phenotype of BLIN-1 is consistent with a cell arrested at the pre-B cell stage of development. Analysis of Ig gene rearrangement and Ig expression in a series of BLIN-1 subclones show that the cells spontaneously rearrange kappa light chain genes, leading to the differentiation of surface kappa-negative pre-B cells into surface kappa-positive B cells. The BLIN-1 cell line is, to our knowledge, the first defined human model for examining this critical developmental stage in human B cell ontogeny. As such, it offers a unique resource for examining variables influencing onset of kappa L chain gene rearrangement and expression.     

Concerted generation of Ig isotype diversity in human fetal bone marrow

The human fetal bone marrow B cell compartment of 14- to 21-wk gestational age was examined phenotypically and with respect to Ig H chain commitment and diversity. A dramatic expansion of fetal marrow B cell pools at 16- to 18-wk gestational age characterizes a rapid and concerted chain of differentiation events. Transiently up to 1/4 of nucleated marrow cells are CD20+/CD21+ cells which begin to express surface Ig other than IgM. Limiting dilution analysis of EBV-infected marrow cells delineated a virtually exclusive commitment to IgM production until 15 wk and the absolute and relative number of these cells were small (approximately 5% of comparable adult values). In parallel to the rapid increase in total B cell pools size, cells committed and able to secrete any of the five Ig isotypes are generated by 16-wk gestational age and by 18 wk the frequencies of these cells rapidly reach levels typical for adult peripheral tissue such as blood or lymph node. Fetal L chain diversity always anticipated that observed in adult serum. In addition to rising pool sizes and diverse IgH expression, EBV transformability is a major variable during this period of B cell development with up to 2/3 of B lineage cells transformable, about half of which are pre-B cells. By 21-wk gestational age transformable pre-B cells have disappeared and (as in adult tissue) approximately 10 to 20% of CD20+ cells are transformable. The rapid, concerted expression of full H chain diversity during a narrow period in fetal development is unique to marrow and implies a lymphopoietic process in a privileged site rather than an immunologic differentiation event. During this event, the relative proportions between the different IgH classes expressed, resembled that found in adult tissue, perhaps suggesting that B cell inherent programming rather than only antigenic forces determine heavy chain choice. The staggered expression, early in postnatal life, of IgH regions 3' of the C mu locus may reflect regulatory functions rather than inherent immaturity of the B lineage.     

Differentiation of B lineage cells from liver of neonatal mice: generation of immunoglobulin isotype diversity in vitro

The development and differentiation of B cells expressing different immunoglobulin (Ig) isotypes was studied in cultures of murine neonatal liver cells. Before culture, 5 to 15% of the liver cells were mu + pre-B cells; 1 to 3% had surface IgM and less than 0.1% had slgG. During 4 days in culture the number of pre-B cells declined, whereas the number of IgM B cells increased greater than 20-fold; IgG B cells also increased in number. Of the four subclasses, IgG3+ and IgG2b+ cells predominated, each representing 3 to 10% of the total B cells at day 4. IgG1+ and IgG2a+ cells were present in lower numbers, representing 1 to 5% and 0.3 to 2.5% of B cells, respectively. Most IgG+ cells also expressed sIgM. Only a minority (less than 10%) of the sIgM+ cells were sIgD+, and most sIgG+ cells were sIgD-. Few T cells were present in these cultures (less than 0.5% in newborn liver), and sIgG+ cells were generated in normal frequencies in cultures of cells from nude mice. The numbers of B cells expressing each IgG subclass were similar in cultures from athymic nu/nu mice, nu/+ heterozygous littermates, and normal BALB/c mice. Plasmablasts and plasma cells appeared over a 14-day culture interval, and these expressed cytoplasmic IgM, IgG3, IgG1, IgG2b, IgG2a, and IgA. Measurable amounts of the first four isotypes were detected in the culture supernatants by radioimmunoassay. These results indicate that neonatal B cells can undergo isotype switching in the absence of T cell help, and that the expression of sIgD may not be a prerequisite for cells to switch Ig isotypes.     

Phenotypic and functional characterization of murine B lymphocyte precursors isolated from fetal and adult tissues

Murine fetal liver and adult bone marrow cells identified by monoclonal 14.8 antibody were enriched on antibody-coated polystyrene petri dishes. Cell surface immunoglobulin (sig)-bearing cells were depleted before this enrichment procedure, and the resulting preparations of 14.8+, slg- cells were characterized as to morphology, immunoglobulin gene expression, and functional potential in vivo and in vitro. All cells with detectable mu chains of IgM in the cytoplasm (cmu) were found to be included in the 14.8+ population. The enriched cells did not contain significant numbers of committed granulocyte-macrophage progenitor cells or putative hemopoietic stem cells. Selected cells from 16-day fetal liver were large, a majority of the cells had a lobulated rather than a spherical nuclear outline, and less than 1% had detectable cmu. Enriched cells from 19-day fetal liver were on the average smaller than those from 16-day-gestation liver and had a more typical lymphoid morphology; 30% were cmu+. Adult bone marrow 14.8+, slg- cells were similar to 19-day fetal liver cells in morphology, and approximately half were cmu+. These selected precursor cells retained the capacity to mature in vivo and in vitro. Fetal and adult 14.8+, slg- cells were efficient in generating newly formed B cells in vivo, and this maturation step appeared to be dependent on the presence of microenvironmental accessory cells. However, the ability of positively selected cells to mature in vitro was markedly decreased, and this potential was not rescued by providing known sources of accessory cells. Possible reasons for this difference are considered. This technique for positively selecting cells has allowed us to directly compare for the first time B cell precursors from fetal and adult tissues and will be invaluable for resolution of the cell compartments in the differentiation of B lymphocyte precursors, in the study of accessory cells known to facilitate this process, in the definition of humoral factors which may act on pre-B cells, in the study of immunoglobulin gene rearrangements which take place during normal differentiation, and for further comparative studies of fetal and adult lymphopoiesis.     

Redundancy in B cell developmental pathways: c-Cbl inactivation rescues early B cell development through a B cell linker protein-independent pathway

Deficiency in the adaptor protein B cell linker protein (BLNK) results in a substantial but incomplete block in B cell development, suggesting that alternative pathways exist for B lineage differentiation. Another adaptor protein, c-Cbl, plays a negative regulatory role in several BCR-signaling pathways. We therefore investigated the role of c-Cbl during B cell development and addressed the possibility that redundancies in pathways for B cell differentiation could be further revealed by eliminating negative effects mediated by c-Cbl. Strikingly, c-Cbl inactivation reversed a number of the critical defects in early B cell differentiation that are seen in BLNK-deficient mice. c-Cbl(-/-)BLNK(-/-) mice exhibited normalized down-regulation of pre-BCR and CD43, up-regulation of MHC class II, and augmented L chain rearrangement, resulting in a successful transition from pre-B cells to immature B cells. c-Cbl inactivation also reversed the potentially tumor-predisposing hyperproliferative response of BLNK(-/-) pre-B cells to IL-7. Pre-BCR cross-linking induced enhanced and prolonged tyrosine phosphorylation in c-Cbl(-/-)BLNK(-/-) pre-BCR(+) pre-B cells compared with c-Cbl(+/-)BLNK(-/-) cells, including elevated phosphorylation of Lyn, Syk, Btk, and phospholipase C-gamma2. Our studies suggest that some, but not all, pre-BCR-triggered developmental events can be mediated by BLNK-independent pathways that are negatively regulated by c-Cbl, and further suggest that different events during early B cell development require different strength or duration of pre-BCR signaling.     

BP-1/6C3 expression defines a differentiation stage of transformed pre-B cells and is not related to malignant potential

BP-1 antibody recognizes a cell surface molecule related to the zinc-dependent metallopeptidases that is expressed during a narrow window early in B cell differentiation. Expression of the same molecule, as originally recognized by the mAb 6C3, is widely accepted to be associated with the complete malignant transformation of pre-B lymphoid cells. We have examined BP-1/6C3 expression in a panel of established Abelson virus-transformed cells that includes both cells analogous to pre-B cells and to less differentiated B lineage cells that have not yet completed Ig H chain gene rearrangement. This analysis reveals that many of the less differentiated transformants do not express BP-1/6C3 for an extended culture period. In contrast, virtually all transformants that are analogous to normal pre-B cells express the determinant early in their culture history. The BP-1/6C3 negative transformants are fully tumorigenic in syngeneic mice, demonstrating that BP-1/6C3 expression is not required for complete malignant transformation. Our data thus suggest that the pattern of BP-1/6C3 expression in Abelson virus-transformed cells mimics that observed in normal cells and is indicative of a differentiation event unrelated to the malignant potential of the cells.     

Ontogeny and distribution of the murine B cell Fc gamma RII.

The distribution and expression of the IgG FcRII (Fc gamma RII) on normal murine B cells was examined. Using multicolor flow cytometry, spleens from neonatal mice of increasing age and adult bone marrow were analyzed for expression of the Fc gamma RII. In addition, B cells from peripheral lymphoid organs, as well as panel of B cell tumors, were tested. The results demonstrate that the Fc gamma RII is expressed on all pre-B cells and immature B cells in the neonatal spleen and adult bone marrow, on all mature B cells in peripheral lymphoid organs, and on switched B cells in Peyer's patches. Furthermore, the Fc gamma RII was found to be present on B cell tumors representative of all stages of B cell maturation and differentiation. Taken together, the results indicate that Fc gamma RII is expressed during the entire lifetime of the B cell. In addition, examination of spleen cells from neonatal mice revealed a large number of pre-B cells, phenotypically defined as B220+, IgM-. These pre-B cells were present at birth, peaked in number between 2 and 3 wk of age, and became a minor population by day 30. Further phenotypic analysis of these cells demonstrated the expression of the BLA-1 and BP-1 Ag, and the lack of T cell and NK cell markers, thus confirming their assignment to the B cell lineage. Finally, the Fc gamma RII present on these pre-B cells was shown to be functional, by virtue of its ability to bind aggregated IgG.