B cell growth-promoting activity of recombinant human interleukin 4

Human interleukin 4 (IL-4), also known as B cell stimulatory factor 1, is a T cell-derived glycoprotein consisting of 129 amino acids for which a cDNA has been recently isolated. IL-4 displays little or no B cell growth factor (BCGF) activity in the standard anti-IgM costimulatory assay using suboptimal concentrations of soluble anti-IgM antibody whereas the low m.w. BCGF is very active. When insolubilized anti-IgM was used as the costimulating agent, both IL-4 and the low m.w. BCGF were found to promote B cell proliferation. Human IL-4 is able to induce the proliferation of B lymphocytes preactivated for either 1 day with insolubilized anti-IgM antibody or for 3 days with Staphylococcus aureus strain Cowan I. However, IL-4 is poorly mitogenic for B cells preactivated for 1 day with the Staphylococcus strain whereas the low m.w. BCGF strongly enhances the proliferation of these B cells. These two findings demonstrate that the preactivation signal necessary to induce human B cells to proliferate in response to IL-4 is critical. The increased tritiated thymidine ([3H]dThd) uptake in preactivated B cell cultures with IL-4 reflects cel proliferation because cell cycle analysis demonstrates that IL-4 induces activated B cells to enter the S and G2/M phases of the cell cycle and the addition of IL-4 to preactivated B cell cultures permits the recovery of three- to fourfold more B cells after 4 days of culture. IL-4 and the low m.w. BCGF act in concert to induce the proliferation of anti-IgM-preactivated B cells as demonstrated by [3H]dThd uptake and cell cycle analysis. In striking contrast to the demonstrated antagonistic effect of interferon-gamma on the IL-4-induced expression of the low affinity receptor for IgE (Fc epsilon RL/CD23), on B cells, it was found that interferon-gamma enhanced the IL-4-induced proliferation of anti-IgM-preactivated B cells. Finally, it was found that IL-4 had to be present continuously during the culture period to exert an optimal growth-promoting effect on B cell blasts. As a conclusion, IL-4 is able to induce the proliferation of an appropriately activated subpopulation of human B cells.     

B cell-derived BCGF functions as autocrine growth factor(s) in normal and transformed B lymphocytes

This paper demonstrates that B cell lines, as well as normal activated B cells generate and respond to B cell-specific growth factor(s) (BCGF). BCGF derived from B cells (B-BCGF) appears to be distinct from interleukin 1, interleukin 2 (IL 2), B cell stimulatory factor, BCGF-II, interferon-gamma, or transforming growth factor. It acts on activated B cells, but not on resting G0 phase B cells to induce proliferation. B cell lines, immortalized by Epstein-Barr virus, constitutively secrete 10-fold higher level of B-BCGF compared with normal activated B cells, suggesting that an activated autocrine loop might be operating in immortalized B cells. On the basis of our observations, we postulate that B cell clonal expansion may occur, at least in part, through a B-BCGF-dependent autocrine pathway similar to IL 2 effect on T cells.     

Characterization and growth factor requirements of SJL lymphomas. I. Development of a B cell growth factor-dependent in vitro cell line, cRCS-X

Reticulum cell sarcomas (RCS) of SJL mice are completely dependent on host cells for their growth and therefore fail to grow in vitro. RCS cells induce marked proliferation in SJL Ly-1+2- T cells accompanied by lymphokine production. In an attempt to fully understand the host-tumor cell interaction, an RCS cell line, cRCS-X, was established in vitro from a transplantable tumor by the addition, every 3 wk, of gamma-irradiated syngeneic lymph node (LN) cells to the culture. cRCS-X maintains all of the characteristics of the parent tumor, RCS-X, including cell surface phenotype (Ks and I-As positive, Ds negative and B cell marker 14.8 positive), ability to stimulate host T cells, and ability to grow in nonirradiated but not in gamma-irradiated SJL mice. The growth factor requirements of cRCS-X were examined. It was found that human BCGF can replace gamma-irradiated LN cells in the maintenance of long term in vitro growth of cRCS-X. cRCS-X cells respond to human B cell growth factor (BCGF) or to recombinant murine interleukin (IL)-5 in a short term proliferation assay [( 3H]thymidine incorporation) in a dose-dependent manner in the presence and absence of fetal calf serum. BCGF also promotes colony formation in soft agar by cRCS-X cells. Although both IL-1 and interferon-gamma can synergize with BCGF in the induction of cRCS-X proliferation, these lymphokines, as well as IL-2, IL-3, granulocyte-macrophage colony-stimulating factor, and IL-4 have no effect on cRCS-X growth when added alone. In addition, it was shown that SJL LN cells produce both IL-4 and BCGF II activities as assayed on murine B cells, after stimulation with gamma-irradiated cRCS-X cells. In light of these results it is postulated that IL-5, [corrected] produced by syngeneic T cells [corrected] after stimulation with RCS, is essential for RCS growth, both in vitro and in vivo.     

T cell-derived B cell growth factor(s) can induce stimulation of both resting and activated B cells

The effects of a preparation containing partially purified, EL4-derived B cell growth factor(s) (BCGF) on B cell growth and proliferation have been examined by using B lymphocyte subpopulations separated on the basis of size. BCGF was found to maintain and enhance proliferation of a significant proportion of large activated B cells. In contrast, small resting B cells required the presence of BCGF and a second stimulus such as anti-IgM antibody (anti-mu) to be induced to proliferate. This disparity was not due to a lack of an effect of BCGF on small resting B cells. A factor contained within the partially purified EL4 supernatant produced time-dependent increases in cell size and RNA content in all subpopulations. These effects were independent of possible effects due to contaminating lymphokines such as interleukin 2 (IL 2), concanavalin A (Con A), and phorbol myristate acetate (PMA). Nonmitogenic doses of lipopolysaccharide (LPS) failed to show similar effects. Our data suggest that B cells at all levels of in vivo activation are responsive to stimulation by a growth factor present in EL4 supernatant, as manifested by cell growth and RNA synthesis. This activity has not previously been described for BCGF preparations. However, because the partially purified, EL4-derived supernatant used as BCGF in these studies has not been purified to homogeneity, we cannot conclude whether the factors that induce resting B cells to increase in size are the same as the growth factors that synergize with anti-mu to induce B cell proliferation or that maintain the proliferation of activated B cells.     

Differential effects of interleukin 2 vs B cell growth factor on human B cells

The effects of recombinant interleukin 2 (IL-2) and high m.w. (HMW) B cell growth factor (BCGF) were examined on normal human peripheral blood B cells activated with Staphylococcus aureus Cowan I (SAC). When SAC-activated B cells were separated into Tac-antigen (Tac-Ag)+ and Tac-Ag- fractions by a cell sorter, recombinant IL-2 induced only the Tac-Ag+ cells to proliferate, whereas both Tac-Ag+ and Tac-Ag- cells responded to HMW-BCGF (m.w. 60,000). Alternatively, SAC-activated B cells were separated according to density into three fractions: low density (large) cells (82 +/- 15% Tac-Ag+), intermediate density (medium) cells (45 +/- 13% Tac-Ag+), and high density (small) cells (less than 5% Tac-Ag+). Recombinant IL-2 enhanced proliferation of low density cells the most, intermediate density cells less, and high density cells not at all. HMW-BCGF induced all three fractions to proliferate to approximately the same degree. Finally, the effects of IL-2 and BCGF on the DNA and RNA content of the various fractions of B cells was examined. RNA content was greater in IL-2-stimulated B cells than BCGF-stimulated B cells, whereas DNA content was the same in both cell populations. IL-2 and BCGF may preferentially interact with different subpopulations of B cells. The interaction of IL-2 or BCGF with normal activated B cells may induce both similar and different intracellular events.     

Development and characterization of a human B cell line that responds to B cell growth factor but not interleukin 2

The human lymphoblastoid cell line we present here proliferated in response to a 14,000 m.w. B cell growth factor (BCGF), and not to interleukin 2 (IL 2). This cell line, designated B-A3, was established by Epstein Barr virus (EBV) transformation of Staphylococcus aureus Cowan I (SAC)-activated spleen B cells, and has been maintained in RPMI 1640 medium complemented with 15% fetal calf serum (FCS) without the addition of other exogenous growth factors. A proliferative response, as measured by [3H]thymidine uptake of B-A3 cells was significantly induced by either commercial IL 2-free human BCGF preparations, or phytohemagglutinin-stimulated mixed lymphocyte culture supernatant at all FCS concentrations used in the assay. The most marked proliferation due to BCGF, however, was observed in the absence of FCS. This BCGF-induced proliferation was not influenced by IL 2 or interferon-gamma (IFN-gamma), because both recombinant IL 2 and IFN-gamma failed to induce proliferation. The response of B-A3 cells to a specific BCGF was additionally indicated by the responsiveness of this cell line to BCGF purified by a series of chromatographic steps. The BCGF to which B-A3 cells responded had a m.w. of 14,000 and was similar to low m.w. BCGF reported from other laboratories. Surface characterization of B-A3 cells, analyzed by flow cytometry with a panel of monoclonal antibodies, demonstrated that the majority of B-A3 cells were stained positively with Leu-12, HLA-DR, and surface IgG markers, whereas staining with surface IgM, IgD markers, pan T cell markers (Leu-4 and Leu-9), and IL 2 receptor (Tac) were consistently negative. Taken together, the human lymphoblastoid cell line we present here responded specifically to a low m.w. BCGF. This cell line may be of value in the purification of BCGF to homogeneity, in studies of the interactions of BCGF with human B cells, and in the identification of the BCGF receptor.     

Identification of a receptor for high molecular weight human B cell growth factor

Regulation of the proliferation of human B lymphocytes is under the control of several different signals. Various B cell growth factors (BCGF) have been described including a 60-kDa BCGF called high m.w. BCGF (HMW-BCGF). In this paper we describe a mAb BA5 that blocks the proliferation of normal activated human B lymphocytes in response to HMW-BCGF and does not affect the proliferation of T cells in response to PHA or IL-2. BA5 shows minimum binding to resting B cells, significantly enhanced binding to resting B cells, significantly enhanced binding to activated B cells and essentially no binding to resting or activated T cells. BA5 recognizes a 90-kDa protein from solubilized membranes of activated B cells. 125I-HMW-BCGF cross-linked to its binding site on activated B cells produces a 150-kDa R-protein complex. Unlabeled HMW-BCGF cross-linked to its binding site on activated B cells produces a 150-kDa band recognized by both BA5 and BCGF/1/C2 (a mAb to HMW-BCGF) using Western blotting. Thus, BA5 recognizes a molecule intimately associated with the receptor for HMW-BCGF which includes a binding site for HMW-BCGF. BA5 can be used to explore the role of HMW-BCGF and B cell proliferation in various aspects of human B cell physiology.     

Clonal analysis of B cell growth and differentiation activities induced from T lymphocytes upon triggering of T3-Ti and T11 pathways

The cellular origin of B cell growth factors (BCGF) and differentiation factors (BCDF) was investigated in the present study. For this purpose, T4+ and T8+ T cell clones were obtained from human peripheral blood, activated via stimulation of either the antigen/MHC receptor (T3-Ti molecular complex) or the antigen-independent alternative pathway (T11 molecule), and subsequently examined for their capacity to induce B cell proliferation and immunoglobulin production. The results showed that 1) BCGF is produced by both T4+ and T8+ T cells at the population level as well as at the clonal level; 2) BCDF activity, in contrast, is largely but not exclusively restricted to the T4+ subset; and 3) both the T3-Ti and T11 pathways activate individual clonal T cell populations to promote B cell growth and differentiation.     

Human B cell responsiveness to B cell growth factor after activation by phorbol ester and monoclonal anti-mu antibody

The effect of phorbol ester on human B cell activation was examined. Picomolar to nanomolar concentrations of phorbol ester induced a high level of proliferation in small IgM-positive B cells isolated from peripheral blood by fluorescence-activated cell sorting. The addition of optimal doses of anti-mu antibody resulted in enhanced proliferation of phorbol ester-activated B cells. The addition of B cell growth factor (BCGF) to phorbol ester-activated B cells also resulted in a dose-dependent synergistic effect and maximal enhancement on day 3. BCGF activity could be absorbed with either phorbol ester- or anti-mu-activated B cells, but not with resting B cells, thus confirming the induction of functional BCGF receptor expression. Cell proliferation was not necessary for the induction of functional BCGF receptors. Phorbol ester was a more efficient inducer of BCGF receptor expression than was anti-mu antibody; gamma-interferon treatment had no effect. BCGF enhanced transferrin receptor expression by phorbol ester-activated B cells. The results suggest that phorbol ester-activated small B cells can be used to monitor BCGF activity, and this synergistic combination may be useful in establishing BCGF-dependent B cell clones in culture.     

The Ba fragment of complement factor B inhibits human B lymphocyte proliferation

Normal human B lymphocyte function is finely regulated by both positive and negative signals at each stage of activation, proliferation, and differentiation. Activation signals include antigen and surface Ig cross-linking agents such as anti-mu or anti-delta. Signals inducing proliferation include IL-2, high m.w.-B cell growth factor (BCGF), and low m.w.-BCGF. IL-2 as well as IL-6 and other partially characterized B cell differentiation factors can induce terminal differentiation of proliferating B cells into Ig-secreting plasma cells. Various C components have been described to regulate B cell function including Bb that enhances proliferation, C5a that enhances Ig production, and C3a that inhibits Ig production. In our study, we examined the ability of the factor B cleavage fragment Ba to influence human B cell function. Ba did not affect the activation of resting B cells but inhibited the proliferation of activated B cells stimulated with either high m.w.-BCGF or low m.w.-BCGF. The inhibition occurred with doses of Ba as low as 1 microgram/ml (29 nM). Ba was found to bind to activated human B lymphocytes in a saturable manner with an apparent K of approximately 25 nM and an apparent Bmax of 56,000 sites/cell. A peptide made of the carboxy terminal 10 amino acids of Ba (GHGPGEQQKR), was also found to inhibit growth factor induced proliferation of activated B cells but at an ID50 of approximately 5 microM. Finally, Ba was found to inhibit the terminal differentiation of Staphylococcus aweus Cowan-activated B cells stimulated with B cell differentiation factors but not Ig secretion by the partially differentiated EBV-transformed cell line SKW.6. Thus, concentrations of Ba achievable in vivo at sites of active inflammation were found to act on human B lymphocytes by inhibiting their proliferation. This may act to limit the immune response to a specific antigenic challenge.     

Identification and characterization of a B cell growth inhibitory factor (BIF) on BCGF-dependent B cell proliferation

The culture supernatants of Con A-activated human peripheral blood mononuclear cells (PBM) contained at least two regulatory factors upon B cell proliferation. One was B cell growth factor (BCGF), which activated antigen-stimulated B cells to proliferation and clonal expansion, and the other was its inhibitory factor, arbitrarily named B cell growth inhibitory factor (BIF). This BIF inhibited the effect of BCGF on anti-mu-stimulated B cells or the monoclonal mature B cell line (CLL-T.H.) obtained from the peripheral blood lymphocytes of B cell-type chronic lymphocytic leukemia patients, which were activated only with BCGF and without adding other proliferating stimuli (e.g., anti-mu). BIF activity was detected in the 24 hr culture supernatants of Con A-activated human PBM in FCS containing medium and also in serum-free RPMI 1640 medium. This substance with BIF activity could not be derived from FCS. Con A-induced BIF (m.w. of 80,000 and an isoelectric point of pH 5.4) was analyzed by Sephadex G-200 gel filtration and chromatofocusing. BIF was stable at pH 2.0 and at 56 degrees C for 30 min. Partially purified BIF had no effect on cell viability and almost no interferon activity (less than 1 IU/ml). BIF with high titer had a slight but significant inhibition on TCGF-dependent T cell growth and on PHA or Con A responses, but the extent of these inhibitions was far less than that of BCGF-dependent B cell growth. Absorption of BIF with Con A blasts made its inhibition on T cell growth even less. On the other hand, BIF activity could not be absorbed with Con A blasts but was almost absorbed with large numbers of CLL-T.H. cells. BIF had almost no inhibitory effect on the proliferation of a mouse fibroblast cell line (NIH 3T3), a mouse myeloma cell line (NS-1), human lymphoid cell lines (MOLT-4, HSB-2, and Daudi), or a human myeloid cell line (K-562). BIF-producing cells were estimated to be T cells and were identified as T8+ T cells. On the other hand, Con A-induced BCGF was demonstrated to be produced predominantly by T4+ T cells. These results show that human B cell proliferation is regulated by interaction between T4+ and T8+ cells via soluble factors, namely BCGF and BIF, respectively.     

Identification of a major 50-kDa molecular weight human B-cell growth factor with Tac antigen-inducing activity on B cells

A bioassay was developed using human small B cells adherent to anti-human IgM (anti-mu)-coated wells. These B cells were stimulated to proliferate by culture supernatants of concanavalin A (Con A)-activated human peripheral blood lymphocytes (Con A Sup) even in the presence of high concentrations of anti-mu coated on assay wells. Human B-cell growth factor (BCGF) activities were partially purified from Con A Sup. Preparative chromatography (Sephacryl S-200 and isoelectrofocusing) yielded a major peak of BCGF activity for B cells adherent to anti-mu-coated wells with a molecular weight of 50,000 (50 kDa) and a pI 7.6. The 50-kDa BCGF was further purified by sequential chromatography using DEAE-Sephacel, CM-Sepharose, Sephacryl S-200, CM-high performance liquid chromatography (HPLC), and hydroxyapatite (HA)-HPLC. The HA-HPLC-purified 50-kDa BCGF was free of interleukin-1 (IL-1), interleukin-2 (IL-2), and interferon activities, but could support growth of BCL1 cells, similar to BCGF-II. Neither IL-1 nor interferon-gamma had any growth-stimulating effect in our B-cell proliferation assay with or without BCGF in Iscove's synthetic assay medium. BCGF-induced proliferation of B cells adherent to anti-mu-coated wells could be markedly augmented by the simultaneous or sequential addition of recombinant human IL-2 (rIL-2). When cultured for 3 days with 50-kDa BCGF, about 40% of B cells adherent to anti-mu-coated wells expressed Tac antigen, and monoclonal anti-Tac antibody inhibited rIL-2 enhancement of proliferation of 50-kDa BCGF-preactivated B cells. In addition, 50-kDa BCGF could induce Tac antigen on an Epstein-Barr virus-transformed B-cell line (ORSON) in the presence of a suboptimal dose of phorbol myristate acetate (PMA) and also on a natural killer-like cell line (YT cells). We have therefore identified a major 50-kDa BCGF activity with Tac antigen-inducing activity that also has a synergistic effect with IL-2 on normal B-cell proliferation.     

Identification of interleukin-6 as an autocrine growth factor for Epstein-Barr virus-immortalized B cells.

Autocrine growth factors are believed to be important for maintenance of an immortalized state by Epstein-Barr virus (EBV), because cell-free supernatants of EBV-immortalized cell lines promote the proliferation of autologous cells and permit their growth at low cell density. In this study, we provide evidence for the existence of two autocrine growth factor activities produced by EBV-immortalized lines distinguished by size and biological activities. Much of the autocrine growth factor activity in lymphoblastoid cell line supernatants resided in a low-molecular-weight (less than 5,000) fraction. However, up to 20 to 30% of the autocrine growth factor activity resided in the high-molecular-weight (greater than 5,000) fraction. While the nature of the low-molecular-weight growth factor activity remains undefined, the high-molecular-weight growth factor activity was identified as interleukin-6 (IL-6). Culture supernatants from six EBV-induced lymphoblastoid cell lines tested contained IL-6 activity, because they promoted proliferation in the IL-6-dependent hybridoma cell line B9. In addition, a rabbit antibody to human IL-6 neutralized the capacity of the high-molecular-weight (greater than 5,000) fraction of a lymphoblastoid cell line supernatant to promote growth both in autologous EBV-immortalized cells and in B9 cells. Similarly, this high-molecular-weight autocrine growth factor activity was neutralized by a monoclonal antibody to human IL-6. Furthermore, characteristic bands, attributable to IL-6, were visualized in supernatants of each of four EBV-induced lymphoblastoid cell lines after immunoprecipitation with a rabbit antiserum to human IL-6. Thus, in addition to its previously reported properties, IL-6 is an autocrine growth factor for EBV-immortalized B cells cultured under serum-free conditions.     

Stimulation of EBV-activated human B cells by monocytes and monocyte products. Role of IFN-beta 2/B cell stimulatory factor 2/IL-6

EBV infects human B lymphocytes and induces them to proliferate, to produce Ig, and to give rise to immortal cell lines. Although the mechanisms of B cell activation by EBV are largely unknown, the continuous proliferation of EBV-immortalized B cells is dependent, at least in part, upon autocrine growth factors produced by the same EBV-infected B cells. In the present studies we have examined the influence of monocytes on B cell activation by EBV and found that unlike peripheral blood T cells and B cells, monocytes enhance by as much as 30- to 50-fold virus-induced B cell proliferation and Ig production. Upon activation with LPS, monocytes secrete a growth factor activity that promotes both proliferation and Ig secretion in EBV-infected B cells and thus reproduces the effects of monocytes in these cultures. Unlike a number of other factors, rIFN-beta 2/B cell stimulatory factor 2 (BSF-2)/IL-6 stimulates the growth of human B cells activated by EBV in a manner similar to that induced by activated monocyte supernatants. In addition, an antiserum to IFN-beta that recognizes both IFN-beta 1 and IFN-beta 2 completely neutralizes the B cell growth factor activity of activated monocyte supernatants. These findings demonstrate that IFN-beta 2/BSF-2/IL-6 is a growth factor for human B cells activated by EBV and suggest that this molecule is responsible for B cell growth stimulation induced by activated monocyte supernatants. We have examined the possibility that IFN-beta 2/BSF-2/IL-6 might also be responsible for B cell growth stimulation by supernatants of EBV-immortalized B cells and thus may function as an autocrine growth factor. However, IFN-beta 2/BSF-2/IL-6 is not detectable in supernatants of EBV-immortalized B cells by immunoprecipitation. Also, an antiserum to IFN-beta that neutralizes IFN-beta 2/BSF-2/IL-6 fails to neutralize autocrine growth factor activity. This suggests that autocrine growth factors produced by EBV-immortalized B cells are distinct from IFN-beta 2/BSF-2/IL-6. Thus, the continuous proliferation of EBV-immortalized B cells is enhanced by either autocrine or paracrine growth factors. One of the mediators with paracrine growth factor activity is IFN-beta 2/BSF-2/IL-6.     

Hyperreactivity of activated B cells to B cell growth factor in patients with systemic lupus erythematosus

Inasmuch as B cell function is in large part determined by lymphokine-derived accessory signals, we studied the effects of recombinant IL-2 and low-molecular-weight B cell growth factor (BCGF) on peripheral blood B cells activated with Staphylococcus aureus Cowan I to explain the B cell hyperfunction in patients with SLE. When S. aureus Cowan I-activated normal B cells were separated into Tac-antigen (Tac-Ag)+ and Tac-Ag- cells by employing a rosette technique, IL-2 induced only the Tac-Ag+ cells to proliferate, whereas both the Tac-Ag+ and Tac-Ag- cells responded to BCGF. The Tac-Ag+ and Tac-Ag- fractions of activated SLE B cells behaved like respective fractions of activated normal B cells for the pattern of response to these growth factors. It should be pointed out, however, that although the Tac-Ag+ B cells of SLE patients and those of normal controls responded to IL-2 to almost the same degree, both the Tac-Ag+ and Tac-Ag- B cells of SLE patients exhibited markedly enhanced proliferative responses to BCGF. The selectively enhanced responsiveness of a broader range of activated SLE B cells may lead to B cell hyperactivity in this disease.     

Augmentation of normal and malignant B cell proliferation by monoclonal antibody to the B cell-specific antigen BP50 (CDW40)

We recently described a 50,000 dalton polypeptide Bp50 (CDw40) that is expressed on human B cells and plays a role in regulating B cell proliferation. Here we additionally characterize the functional signal given by antibody binding to Bp50 on both normal and malignant B cells. A monoclonal anti-Bp50 antibody could augment the proliferation of B cells activated by anti-IgM, anti-CD20, or 12-O-tetradecanoyl phorbol-13-acetate (TPA) stimulation, but was not co-stimulatory with B cell growth factor (BCGF), interleukin 1, or interleukin 2. The signal did not depend on the Fc portion of the antibody, because F(ab')2 fragments of anti-Bp50 were still functionally active. Both anti-Bp50 and a low m.w. BCGF preparation were similar in that both were co-stimulatory with the same agents and both anti-Bp50 and BCGF affected activated B cells but not resting B cells. However, a panel of B cell malignancies differed in their responsiveness to anti-Bp50 vs BCGF: some tumors proliferated in response to anti-Bp50 but not BCGF, whereas other tumors had the opposite pattern. Bp50 was found to have several properties in common with HLA class II molecules: both Bp50 and class II were expressed at lower levels on blood B cells than on tonsillar B cells; the expression of both Bp50 and class II was increased after activation of blood B cells with TPA or anti-IgM; and the expression of both Bp50 and class II was increased after activation of non T, non-B acute leukemias with BCGF. Thus class II and Bp50 expression may be under common regulatory control. The fact that BCGF modulated the expression of Bp50 on leukemic cells suggests that BCGF and Bp50-mediated signals may be coordinately regulated.     

Identification of a novel human B cell activation antigen involved in B cell growth factor-dependent proliferation

The B6.4 mAb we present here identifies a novel activation Ag of B cell lineage. The B6.4 mAb was generated by immunizing mice with B cell growth factor (BCGF)-responding BA3 cells, and selected by its capability to block BCGF-induced proliferation of BA3 cells. The inhibitory effect of this antibody on BCGF-dependent proliferation was further confirmed by using normal activated B cells in the presence of exogenous BCGF derived from T cells or B cells. Furthermore, it did not affect IL-2-dependent proliferation of B cells. The expression of the B6.4 Ag, as analyzed by FACS, is restricted to in vitro activated B cells, and remains undetectable on resting B or T cells, PHA-activated T cells, and monocytes. The B6.4 Ag is also expressed on some lymphoblastoid B cell lines and most of the lymphomas and CLL of B cell origin; however, it did not express on pre-B cell ALL and plasma cell leukemias. The B6.4 Ag has a Mr of 35,000 Da, as determined by SDS-PAGE of radiolabeled immunoprecipitates from activated B cells. The B6.4 Ag is detectable on B cells as early as 8 h after activation, and precedes that of the IL-2R or transferrin R. All of these results suggest that the B6.4 Ag is an early activation Ag of B cells and is functionally related to a receptor of BCGF, but not IL-2.     

Identification and characterization of a B cell activation factor (BCAF) produced by a human T cell line

A human T cell line, Peer, that expresses the T cell helper phenotype produces discrete activation and growth factors for tonsillar B cells. The B cell activation factor produced by Peer is biochemically and physiologically distinct from other lymphokines known to enhance B cell proliferation, namely, interleukin 1, interleukin 2, interferon, and previously characterized B cell growth factors (BCGF). The BCGF produced by Peer is functionally similar to previously described BCGF but has a m.w. of approximately 30,000 daltons. The identification and characterization of a T cell-derived activation factor that can induce apparently resting (Go phase) B cells to enter S phase in the absence of an exogenous first signal has important implications in the additional dissection of the complex steps in the human B cell cycle.     

The direct effects of interleukin 1, interleukin 2, interferon-alpha, interferon-gamma, B-cell growth factor, and a B-cell differentiation factor on resting and activated human B cells

A wide variety of cytokines have been demonstrated to affect B-cell function. However, it is unclear which of these mediators actually exert direct effects on the B cells themselves. In the present study, the direct role of interleukin (IL) 1, IL-2, Interferon-gamma, or Interferon-alpha in human B-cell activation, proliferation, or differentiation was examined and compared with the effects of a B-cell growth factor (BCGF) or a B-cell differentiation factor (BCDF). Highly purified human B lymphocytes were separated according to size into two nonoverlapping populations. The fraction of small B cells was incubated with IL-1, IL-2, Interferon-gamma, Interferon-alpha, BCGF, or BCDF, and cell size changes, RNA synthesis, DNA synthesis, or supernatant immunoglobulin (Ig) production were measured. Neither IL-1, IL-2, Interferon-alpha, Interferon-gamma, nor the BCGF induced substantial cell size changes, RNA synthesis, DNA synthesis, or Ig production by the small fraction of B lymphocytes; however, the BCDF could directly activate a proportion of resting B lymphocytes to secrete Ig. The fraction of large B cells was also incubated with these cytokines. While neither IL-1, Interferon-alpha, nor Interferon-gamma enhanced DNA synthesis or Ig production by the fraction of large B lymphocytes, DNA synthesis was augmented 23-fold by BCGF and IgG production was increased 7-fold by BCDF. Additionally, IL-2 slightly enhanced both proliferation and differentiation of large B cells but substantially less so than BCGF and BCDF; DNA synthesis was increased 4-fold, while Ig production in the presence of IL-2 was increased by approximately 50%. Thus, the most important lymphokines modulating the function of these two fractions of tonsillar lymphocytes were a BCGF and a BCDF.