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.     

Comparative activation requirements of human peripheral blood, spleen, and lymph node B cells

Human peripheral blood, spleen, and lymph node B cells were stimulated with Cowan I Staphylococcus aureus (SA) or F(ab')2 fragments of anti-mu antibody (anti-mu) and various lymphokines and were analyzed for proliferation and generation of Ig-secreting cells (ISC). SA alone but not anti-mu stimulated minimal proliferation of each population. Recombinant IL 2 (r-IL 2) effectively promoted proliferation of SA-stimulated blood and spleen B cells, but supported less vigorous responses of lymph node B cells. By contrast, r-IL 2 enhanced DNA synthesis of all anti-mu-stimulated B cells early in culture, but did not promote sustained proliferation of anti-mu-stimulated lymph node B cells and only promoted ongoing DNA synthesis of some anti-mu-activated blood (eight out of 17) and spleen (five out of 14) B cell preparations. Recombinant interferon-gamma (r-IFN-gamma) and a commercial preparation of B cell growth factor (BCGF) also augmented DNA synthesis of all three B cell populations stimulated with SA or anti-mu early in culture, but neither alone was able to sustain maximal proliferation. Markedly enhanced sustained proliferation of all three anti-mu- and SA-stimulated B cell populations was noted when cultures were supported by the combination of r-IL 2 and BCGF, or to a lesser extent by r-IL 2 and r-IFN-gamma. The generation of ISC from SA-stimulated blood or spleen but not lymph node B cells was effectively supported by r-IL 2 alone. Differentiation of lymph node B cells required the combination of r-IL 2 and BCGF. These studies emphasize the importance of both the activation stimulus and the origin of the B cells in determining the lymphokine requirements of human B cell responsiveness.     

Synergistic effect of recombinant IL 2 and interferon-gamma on the proliferation of human monoclonal lymphocytes

We studied the effect of interferon-gamma (IFN-gamma) on the proliferation of lymphocytes from 10 B-type chronic lymphocytic leukemia (B-CLL) patients. In no instance did IFN-gamma induce a proliferative response whether used alone or in combination with anti-mu antibody (Ab). This was observed regardless of the responsiveness of a given patient's cells to interleukin 2 (IL 2) and to B cell growth factor (BCGF). In contrast IFN-gamma strongly and reproducibly synergized with IL 2 (but not with BCGF) to support B-CLL proliferation in five of the 10 patients. The effect of IFN-gamma was dose related and could be inhibited by an anti-IFN-gamma monoclonal Ab. A monoclonal Ab toward the IL 2 receptor molecule was also inhibitory. Preincubation with IFN-gamma potentiated the responsiveness of B-CLL to IL 2 in secondary cultures, showing that IFN-gamma exerts its effect before that of IL 2.     

The effects of interleukin 1 on human B cell activation and proliferation

The precise role of B cell surface immunoglobulin (slg) in the activation of B cells is unclear at present. In particular, it is uncertain whether ligands interacting with the B cell slg suffice to induce proliferation, or simply induce a state of activation in which the B cell becomes responsive to growth factors made by accessory cells. We have examined the effects of two ligands, Staphylococcus aureus Cowan strain I (SAC) and antihuman mu chain (anti-mu), which interact with B cell slg on highly purified human peripheral blood and tonsillar B cells cultured at low cell concentrations. The effects on B cell proliferation of these ligands alone or in combination with highly purified interleukin 1 (IL 1) or a supernatant of a human T-T hybridoma containing a B cell growth factor (BCGF) were studied. SAC with its high cell wall content of protein A triggered maximal B cell proliferation which was not increased further by IL 1 or BCGF. High concentrations of soluble F(ab')2 fragments of goat anti-mu chain also induced significant B cell proliferation. Lower concentrations of anti-mu resulted in little or no B cell proliferation but activated the B cell to a state of responsiveness to both IL 1 and BCGF. IL 1 by itself had no effect on the proliferation of unstimulated B cells or on the proliferation of in vivo-activated B cells which responded to BCGF in vitro, but demonstrated clear synergy with low concentrations of anti-mu antibody. BCGF alone augmented the proliferation of unstimulated B cells, presumably by acting on B cells which had undergone some degree of activation in vivo. In addition, it showed marked synergy with anti-mu antibody, which resulted in proliferation similar in magnitude to that induced by SAC. This synergy was far greater than that seen between anti-mu antibody and IL 1, and the resulting proliferative response was only slightly increased by the presence of IL 1. We conclude that the importance of accessory cell factors for the initial rounds of B cell proliferation depends on the strength of the initial slg-mediated activation signal. When this is strong, the response is maximal and independent of accessory cells or accessory cell factors. When it is suboptimal, a moderate synergy is seen with IL 1 and a dramatic synergy with BCGF.     

Sequential effect of a high molecular weight B cell growth factor and of interleukin 2 on activated human B cells

A high m.w. B cell growth factor (50,000 BCGF) prepared from lectin-activated human peripheral blood lymphocyte culture supernatants acts only on B cells preactivated by a first signal. This first signal can be delivered in vitro (with anti-mu antibody (Ab)) or in vivo. Upon costimulation with anti-mu Ab the 50,000 BCGF induces an early and transient proliferative response, whereas the response to interleukin 2 (IL-2) develops more progressively. To determine the respective targets of the 50,000 BCGF and of IL-2, B cells were activated with anti-mu Ab and separated according to the expression of the IL-2 receptor (cluster designation (CD)25 antigen). CD25+ B cells do not respond to the 50,000 BCGF and do not acquire this responsiveness after an additional culture with IL-2. CD25- B cells respond to the 50,000 BCGF and not to IL-2. However, when CD25- B cells are cultured for 3 days with the 50,000 BCGF they become responsive to IL-2. These results demonstrate a pathway of B cell activation based on the ordered and sequential action of anti-mu Ab, the 50,000 BCGF, and IL-2.     

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.     

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.     

The modulation of membrane Ia on human B lymphocytes

Using flow cytometry techniques, changes in surface Ia (DR and DS) expression on human B lymphocytes were correlated with changes in the cell cycle following stimulation with anti-mu. The effect of interleukin (IL)-1, IL-2, B-cell growth factor (BCGF), and interferons on Ia expression on resting B cells was also examined. A population of resting B lymphocytes was cultured in vitro with 100 micrograms/ml of anti-mu and immunofluorescently stained for DR and DS at various times following stimulation. Detectable increases in DR and DS expression were found within 8 hr, and the major increases (twofold and fourfold) in DR and DS expression occurred over the next 48 hr. Using cell cycle inhibitors and propidium iodide staining, it was demonstrated that the enhanced DR and DS expression following anti-mu stimulation began during G0 to G1 transition and increased as the cells progressed through G1 phase. During S and G2/M phases, there were minimal further increases in surface Ia. Although prolonged exposure of B cells to anti-mu was required for cellular activation, cell size enlargement, and progression into S phase, a brief exposure to anti-mu, insufficient for cellular activation, markedly enhanced Ia expression. Thus anti-mu-stimulated resting human B lymphocytes rapidly increase their surface Ia expression. This increase occurs predominantly prior to entrance into S phase and can occur in the absence of significant cellular activation. Interferons have been reported to modulate surface Ia expression on a human lymphoid cell line and on monocytes and supernatants with BCGF activity to enhance surface Ia expression on murine B cells; however, neither alpha-interferon, gamma-interferon, IL-1, IL-2, nor BCGF modified surface DR expression on normal resting human B cells.     

Selective suppressive effects of glucocorticoids on the early events in the human B cell activation process

The effect of hydrocortisone on the induction of human B cell activation and proliferation has been described. Hydrocortisone prevents the anti-mu-induced cell enlargement of small tonsillar B cells, blocks expression of the activation markers 4F2 and 5E9 induced by anti-mu, inhibits RNA synthesis of small B cells stimulated by anti-mu with or without BCGF, and suppresses B cell proliferation in response to anti-mu and BCGF or to Staphylococcus aureus Cowan I. In contrast, hydrocortisone does not affect the proliferative response of in vitro or in vivo preactivated B cells. Therefore, hydrocortisone has a selective inhibitory effect on early events in the human B cell cycle that subsequently leads to inhibition of total RNA and DNA synthesis. Possible mechanisms of this action are discussed. These studies further define the nature of glucocorticoid-induced modulation of human B cell activation and proliferation.     

Activation of human B cells: alternate options for initial triggering and effects of nonmitogenic concentrations of anti-IgM antibodies on resting and activated cells

The monoclonal antibody 1F5, which is reactive with the CD20 (Bp 35) pan-B cell antigen, was shown to activate resting human peripheral blood B cells into the middle to late G1 phase of the cell cycle. However, in contrast to F(ab')2 fragments of polyclonal anti-mu, 1F5 synergized only weakly with B cell growth factor (BCGF) for DNA synthesis in these cells. We provide evidence that the CD20 molecule and surface immunoglobulin represent two alternative activation pathways in resting B cells. We also show that anti-immunoglobulins, during co-stimulation with BCGF, may play an important role in G1 as well as for the initial cell triggering. Thus, anti-mu in nonmitogenic concentrations was shown to provoke distinct effects on 1F5-pretreated G1 cells, as monitored by increases in cellular volumes as well as in cytoplasmic Ca2+ levels. Moreover, anti-mu could increase c-myc mRNA levels in 1F5-primed cells, implying that c-myc expression can be regulated in G1 as well as during the initial G0 to G1 transition. Partially purified human BCGF neither induced G1 entry in resting peripheral blood cells nor primed the cells for DNA synthesis. The finding that BCGF did not influence c-myc mRNA levels in resting or in activated B cells suggests that its mitogenic action does not involve the c-myc function.     

Reactivity of Leu-1+ tonsillar B cells to a high molecular weight B cell growth factor

This work was focused on the responsiveness of B cells from blood and tonsils to typical B cell growth factors (BCGF) in the absence of anti-mu antibody. This direct responsiveness was not observed with small dense B cells from either organ. Large tonsillar B cells but not large blood B cells did respond directly to a high m.w. BCGF (m.w. 50,000 BCGF), whereas large B cells from both organs responded directly to the low m.w. BCGF (m.w. 20,000 BCGF). The tonsillar B cells directly responsive to the m.w. 50,000 BCGF express the 4F2 marker and thus belong to a population of in vivo-preactivated B cells. Moreover, this direct responsiveness to the m.w. 50,000 BCGF is localized in Leu-1+ tonsillar B cells. The Leu-1+ and Leu-1- tonsillar B cell subsets do not differ in their responsiveness to the m.w. 50,000 BCGF upon costimulation with anti-mu antibody and to the m.w. 20,000 BCGF regardless of the presence of anti-mu antibody. Thus, the Leu-1+ subset present in tonsils shows a particular reactivity to a high m.w. BCGF.     

Activity of a partially purified human BCGF on murine assays for B-cell stimulatory factors. I. BCGF II-like activity of human BCGF

To further characterize a human B-cell growth factor (BCGF) produced by phytohemagglutinin (PHA) P-stimulated peripheral blood T cells, a partially purified preparation of this material was tested in a number of murine assays for B-cell stimulatory factors (BSF). Human BCGF lacked murine BSF-1 activity as assessed via the induction of polyclonal proliferation of anti-IgM-stimulated murine B cells; however, this material consistently augmented the proliferative response of murine B cells to anti-IgM and a saturating dose of murine BSF-1. Human BCGF also induced proliferation in unstimulated murine B cells, and augmented the proliferative response of dextran sulfate activated murine B cells. Human BCGF is therefore capable of causing proliferation of unstimulated and activated murine B cells, and by these criteria closely resembles murine BCGF II. In contrast to murine BCGF II, however, human BCGF failed to stimulate proliferation or immunoglobulin (Ig) secretion by murine BCL1 B lymphoma cells. A murine analog of this human BCGF showing the same pattern of biological responses was found in concanavalin A-stimulated supernatants of the murine MB2.1 T-cell line and D9-Cl T-cell hybridoma. The active component of the human BCGF preparation was not due to contaminating PHA, interleukin 1, interleukin 2; interferon-gamma, or endotoxin. Comparison between the above human BCGF and a commonly used source of murine BCGF II, i.e., supernatant from antigen-stimulated D10.G4.1 T cells, provided information suggestive of BCGF II heterogeneity. Both human BCGF and D10.G4.1 supernatant caused proliferation of unstimulated and dextran sulfate-stimulated murine B cells; however, only the human BCGF preparation augmented the proliferative response of murine B cells to anti-IgM and a saturating dose of murine BSF-1, and only the D10.G4.1 supernatant stimulated BCL1 cell proliferation and immunoglobulin secretion. The data therefore indicate that the different assays for BCGF II used in this study respond to different factors, and suggest the existence of two BCGF II-like activities.     

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.     

Noncytotoxic functions of natural killer (NK) cells: large granular lymphocytes (LGL) produce a B cell growth factor (BCGF)

Highly purified human large granular (LGL), depleted of any detectable contaminant T and B cells or monocytes, were found to be potent producers in vitro of a soluble B cell growth factor (BCGF) able to sustain proliferation of B cells activated by anti-mu. Activation by lectins (phytohemagglutinin, PHA, concanavalin A, Con A; and pokeweed mitogen, PWM) was required to induce the production of high levels of this BCGF from cultured LGL. Production of BCGF was also detected after the binding of LGL with natural killer (NK)-sensitive (K562) but not with NK-resistant (RL male 1) target cells. In contrast to T cells, LGL did not need the additional presence of accessory cells to reach optimal production of BCGF by 72 hr of culture. The subpopulation of LGL responsible for the production of BCGF had phenotypic characteristics associated with NK cells (3G8+, HNK1+/OKT11+, DR-, OKT3-, Leu-M1-), and separated cells with these markers exerted high levels of NK activity. Selective production of BCGF also was obtained from cytotoxic clones derived from LGL. A partial characterization of the LGL-derived BCGF was performed by gel filtration. BCGF activity was detected in fractions with estimated m.w. of 20,000 and 45,000. The LGL-derived BCGF activity was resistant to reduction with 2-mercaptoethanol and was stable at -20 degrees C for months. Conversely, heating (56 degrees C for 1 hr) or digestion with trypsin greatly reduced the LGL-derived BCGF activity. These findings strongly suggest that LGL including those with NK activity can play an important positive role in the early events of the B cell-mediated immune response.     

A B cell growth factor-like activity is secreted by cloned, neoplastic B cells

Supernatants from synchronized clones of neoplastic B cells (BCL1) were found to contain a B cell growth factor (BCGFI)-like activity. The BCGF activity in the BCL1 supernatants (SN) could synergize with EL-4 SN in the late phases of an IL 1-dependent BCGF I assay (days 5 through 8). These SN did not contain any detectable BCGF II, IL, 1, or IL 2 activity. In contrast to EL-4-derived BCGF I, which has a m.w. of approximately 18,000, the BCL1-BCGF activity has a m.w. of approximately 4500. Because the BCGF activity in BCL1 SN fluctuates with cell cycle in synchronized cultures, this BCL1-BCGF may play an auto-stimulatory role in B cell proliferation.     

Structural and functional characterization of IL 2 receptors on activated human B cells

After activation, B cells express the IL 2 receptor as determined by their reactivity with monoclonal anti-IL 2 receptor antibodies. In this report we show that anti-IL 2 receptor antibodies precipitated comparable 60,000 to 65,000 dalton proteins from highly purified B and T cells. Limited peptide mapping suggested that the receptors on B and T cells were identical. Moreover, activated B cells could be induced to proliferate by IL 2, but not to secrete Ig. Anti-IL 2R antibody blocked the effect of IL 2 but not the proliferative response induced by B cell growth factor (BCGF), suggesting independent growth factor receptors. Investigation of the kinetics of the B cell response to growth factor indicated that BCGF acts within 24 hr, whereas IL 2 was virtually devoid of activity for 48 hr. Nevertheless, after 72 to 96 hr, the effect of IL 2 was equal to or greater than that obtained with BCGF. These studies suggest that the initial stages of B cell proliferation involves a sequential interaction of BCGF and IL 2 with their respective receptors.     

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.     

Production of B cell growth factor by a Leu-7+, OKM1+ non-T cell with the features of large granular lymphocytes (LGL)

The present study reports the characterization of a non-T cell from human peripheral blood which is capable of releasing BCGF. This BCGF-producing non-T cell had a T3-, T8-, Leu-7+, OKM1+, HLA-DR-, Leu-11- surface phenotype and was likely to belong to the so-called large granular lymphocyte (LGL) subset because: after fractionation of non-T cells according to the expression of Leu-7 or HLA-DR markers, it was found in the Leu-7+, HLA-DR- fractions that were particularly enriched in LGL; it co-purified with LGL on Percoll density gradients; and it expressed Leu-7 and OKM1 markers that are shared by a large fraction of LGL. Although co-purified with cells with potent NK capacities, the BCGF-producing cell was not cytotoxic, because treatment of Leu-7+ cells with Leu-11 monoclonal antibody and complement abolished the NK activity but left the BCGF activity unaltered. The factor released by this LGL subset was not IL 1 or IL 2 mistakenly interpreted as BCGF, because: a) cell supernatants particularly rich in BCGF activity contained very little or no IL 1 or IL 2; b) BCGF-induced B cell proliferation was not inhibitable by anti-Tac antibodies (this in spite of the expression of IL 2 receptor by a proportion of activated B cells); and c) BCGF activity was absorbed by B but not T blasts.     

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.