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.     

Functional and biochemical characterization of B-cell differentiation factor (BCDF) produced by an HTLV-I-transformed human T-cell clone and demonstration of specific binding of the factor to a BCDF responsive cell line

We have previously described YA2, a human T-cell clone that secretes B-cell differentiation factor (BCDF) but not B-cell growth factor (BCGF). The BCDFs secreted by YA2 and HTLV-I-transformed YA2 (TYA2) were functionally similar in their ability to stimulate Ig secretion by Staphylococcus aureus Cowan strain I-activated B cells and IgM secretion by SKW6.4 cells. In addition, they were biochemically similar with a MW of 30 kDa by high-performance liquid chromatography (HPLC) sieving, and a pI of 6.0-6.8 by isoelectric focusing. The BCDF activity was not blocked by antibodies to interleukin 2 and BCGF. BCDF was purified from TYA2 supernatant by sequential media protein immunoadsorption, flat bed isoelectric focusing, HPLC TSK 2000 sieving, and repeated immunoadsorption and was then iodinated. The iodinated material had functional BCDF activity and migrated to a single band at MW 30 kDa by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and at pI of 6.8 by polyacrylamide gel isoelectric focusing. 125I-BCDF purified in this manner bound specifically to a BCDF-responsive cell line and not to phytohemagglutinin-activated T cells. 125I binding to the BCDF-responsive cell line was competitively inhibitable by the addition of cold BCDF. Thus we have purified and characterized a factor with BCDF activity and demonstrated that this factor binds specifically to a BCDF-responsive cell line.     

Somatic cell hybrids of mouse myeloma cells and B lymphocytes from a patient with agammaglobulinemia: failure to secrete human immunoglobulin.

Somatic cell hybrid clones were isolated from the fusion of RPC5.4 mouse myeloma cells and B lymphocytes from a patient with common varied agammaglobuinemia. The patient has B lymphocytes that synthesize immunoglobulin but fail to secrete immunoglobulin. The hybrid character of the six clones was established by examination of metaphase chromosome spreads. Most of the hybrid clones expressed mouse and human surface immunoglobulin. All of the clones synthesized immunoglobulin of mouse and human parental origin. Mouse parental immunoglobulin was secreted, whereas the human parental immunoglobulin was not secreted. Human light chain molecules were secreted as part of hybrid H2L2 molecules formed with mouse heavy chains. Human heavy chains had a reduced m.w. in comparison to the mouse heavy chains. Kinetic experiments indicated that human Ig was synthesized in amounts that were comparable to the mouse Ig. Pulse-chase experiments showed that that the intracellular human Ig was removed from the cytoplasm, probably by degradation. These experiments demonstrate that the hybrid cells are an in vitro model of naturally occurring failure of immunoglobulin secretion from agammaglobulinemia. The failure of fusion with mouse myeloma cells to complement the secretion defect suggests that these B cells produce an altered immunoglobulin molecule that is not programmed for secretion.     

Cell cycle-related expression of the receptor for a B cell differentiation factor

Cloned, neoplastic B cells (BCL1) have been used to evaluate the expression of the receptor for the B cell differentiation factor, BCDF mu. These cells do not secrete IgM before stimulation with BCDF mu-containing T cell supernatants (SN). By inducing cell cycle synchrony in this homogeneous population, the expression of the BCDF mu receptor could be evaluated as a function of the cell cycle. Responsiveness to BCDF mu-containing SN is maximal when the cells are in S and G2 phases of the cell cycle, and a 2-hr exposure of cells to BCDF mu-containing SN during S/G2 results in optimal IgM secretion 5 days later. Cells in S/G2 are also maximally effective in absorbing BCDF mu activity from SN. These data support the hypothesis that B cells do not respond to differentiative signals until after they are committed to at least one round of cell division.     

Human helper T cell factor(s). IV. Demonstration of a human late-acting B cell differentiation factor acting on Staphylococcus aureus Cowan I-stimulated B cells

At least two distinct B cell stimulatory factors (BSF) were found to be involved in the differentiation of Staphylococcus aureus Cowan I (SAC)-stimulated human B cells to IgG-producing cells. A factor tentatively called B cell differentiation factor I (BCDF I) was found in one fraction, and a second factor, BCDF II was found in another fraction. The BCDF I fraction alone induces IgG-production in SAC-stimulated B cells, but the BCDF II fraction does not. The BCDF II fraction enhances IgG production in SAC-stimulated B cells in the presence of the BCDF I fraction. Studies concerning the time-course of the action of the BCDF II fraction revealed that it contains a late-acting differentiation factor that acts on B cells most effectively when it is added to the SAC-stimulated B cell culture after the addition of BCDF I fraction; it induces IgG plaque-forming cells within 1 day. The pI value of a late-acting BCDF was in the range of 5 to 6; this pI range is different from that of BCDF I but similar to that of BCDF II, which was shown in our previous studies to be able to induce IgG production in Epstein Barr Virus-transformed B lymphoblastoid cell lines. In addition, the m.w. of a late-acting BCDF were about 35,000 and 20,000, which are the same as those of BCDF II, and thus its identity with BCDF II was suggested.     

Complement subcomponent C1q stimulates Ig production by human B lymphocytes

The regulation of Ig production by human B lymphocytes is a complex process involving interactions among B cells, APC, T lymphocytes and soluble factors including activation, growth, and differentiation factors. Components of the complement system, including C3a, C3b, C3d, and C5a, have been shown to influence various stages in this process. In this study, we demonstrate that the C1q subcomponent of complement binds to both small resting and large activated B cells and stimulates immunoglobulin production by Staphylococcus aureus Cowan-activated tonsillar B lymphocytes. This effect is present whether C1q is added to the B cells either at the beginning or near the end of a 7-day culture period and is not associated with enhancement of proliferation. The C1q stimulation of Ig production is, however, associated with increased steady state levels of mRNA for the mu Ig H chain. Furthermore, C1q stimulated IgM production by the human B cell line SKW 6.4, which is capable of secreting IgM in response to B cell differentiation factors (BCDF). SLE is a disorder frequently associated with polyclonal activation of B lymphocytes. We studied the effect of C1q on B cells from two patients with this disorder and one with an SLE-like illness, all selected for the predominance of either IgM or IgG in serum. Spontaneous or BCDF-stimulated Ig secretion was of the isotype predominant in vivo, whereas C1q selectively stimulated B cells to produce the other isotype (IgG vs IgM). Thus, C1q interacts with B lymphocytes in a manner distinct from that of BCDF found in mixed lymphocyte supernatants. C1q may be an important factor influencing the production of Ig by B lymphocytes in normal individuals and in patients with abnormalities of B cell activity.     

Characterization of lymphokines mediating B cell growth and differentiation from monoclonal anti-CD3 antibody-stimulated T cells

Addition of anti-CD3 mAb 147 (IgG1), 446 (IgG1), or 454 (IgG2a) to cultures of T plus non-T cells can result in both B cell growth and differentiation. To determine whether lymphokines mediating these activities were similar to those described from conventional mitogen-induced T cell activation, normal peripheral blood T cells were stimulated with anti-CD3 mAb for 48 h. The supernatants were assayed for factors inducing B cell growth or differentiation (BCDF). A marked increase in Ig secretion was observed when either EBV-transformed B cell lines or normal B cells, pre-activated with Staphylococcus aureus Cowan I strain, were cultured in the presence of mAb 446 (anti-CD3) stimulated T cell supernatant whereas no significant increase in Ig secretion was noted with either mAb 454- or 147-induced T cell supernatant despite equivalent T cell proliferative responses to these antibodies. In contrast, IL-2 secretion was detectable in T cell supernatants from T cells stimulated with either mAb 454 or 147 but not 446. Factors promoting B cell proliferation were detected in all antibody-stimulated T cell supernatants but, contrary to BCDF, appear to act only on non-activated B cells. To determine whether these effector activities were due to distinct lymphokines, supernatants were pooled and concentrated by ammonium sulfate precipitation. Superose 12 permeation chromatography revealed BCDF activity with an apparent Mr of approximately 30,000 Da. The growth factor activity eluted over a wider and higher molecular weight range which overlapped the differentiation factor activity. Fractions containing BCDF activity were pooled, dialyzed, applied to a Mono Q anion-exchange column, and eluted with a linear NaCl gradient. The growth factor activity came off in a single-peak while BCDF was found divided into two major areas. The growth factor eluted at an ionic strength between the two BCDF activities. BCDF has an apparent isoelectric point (pI) of 6, in contrast to the reported pI 5 for IL-6 and more acidic than the documented basic pI of IFN-gamma. Lastly, peaks with BCDF activity were not active in assays for either IL-2 or IL-4. In addition, a rabbit anti-IL-6 heteroantiserum failed to inhibit the pI 6 BCDF, suggesting non-identity between IL-6 and anti-CD3 induced BCDF. Thus, anti-CD3 activated T cells generate both growth factor activity and BCDF as separate molecular entities distinct from IFN-gamma, IL-2, IL-4, and conventional IL-6.     

Patterns of isotype commitment in human B cells: limiting dilution analysis of Epstein Barr virus-infected cells

The frequency of Epstein Barr virus- (EBV) inducible IgM, IgG, and IgA-secreting cells in human peripheral blood and tonsil was determined by performing limiting dilution experiments in suspension culture. We devised a method of propagating small numbers of EBV-infected B cells with irradiated umbilical cord blood cells as a feeder layer. Precursor cell frequencies can be derived from these experiments; we have shown by statistical analysis that they conform to the single hit model of the Poisson distribution. By using this technique, a significant percentage of surface immunoglobulin-bearing lymphocytes are activated to secrete immunoglobulin in vitro. On the average, 8 to 38% of B cells in peripheral blood and tonsil can be propagated and the secreted immunoglobulin from the clonal progeny can be analyzed. Neither the EBV immune status of the donor nor the source of the umbilical cord blood feeder layer could account for the variations in cloning efficiency observed among donors. A surprisingly high frequency of B cells secreted IgA in vitro and we have shown that a small proportion of B cell clones in tonsil and peripheral blood secrete both IgM and IgA during the 4-wk culture period. Other B cells, including all those that produce IgG, appear to be committed to the secretion of a single isotype. Thus, these studies establish methodology for the analysis of the secreted products of human B cells at the single cell level and demonstrate that the progeny of at least some clones can secrete more than one isotype in vitro.     

Isolation and characterization of B cell differentiation factor (BCDF) secreted from a human B lymphoblastoid cell line

A subclone of a human B lymphoblastoid cell line, CESS-2, spontaneously secreted a kind of BCDF (B-BCDF) in their culture supernatant without any stimulation. B-BCDF induced IgG and IgM secretions in human B lymphoblastoid cell lines, CESS cells and CL-4 cells, respectively. BCDF-responsive CESS cells expressed IgG on their surface, whereas CESS-2, which were able to secrete B-BCDF, did not express surface IgG. B-BCDF could induce Ig-secretion in SAC-stimulated low density peripheral B cells, but did not induce Ig secretion in nonstimulated B cells. B-BCDF did not show any IL 2, BCGF, or gamma-interferon activities. B-BCDF was highly purified by gel filtration on an AcA-34 column, by chromatofocusing and ion exchange chromatography on an HPLC system, and by gel filtration on an HPLC column. Highly purified preparations showed a single protein band in SDS-PAGE analysis. The m.w. and isoelectric points of the factor were 20,000 and pH 5.1 to 5.2, respectively. The minimum protein amount required for Ig induction in B cell lines was 16 ng/ml.     

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.     

Polyclonal activation of rat B cells. I. A single mitogenic signal can stimulate proliferation, but three signals are required for differentiation

A water-soluble, proteinaceous preparation derived from the cell walls of Salmonella typhimurium Re mutants has recently been tested in our laboratory for its ability to act as a mitogen for rat lymphocytes. We have found this preparation (STM) to be a potent stimulator of B lymphocyte proliferation, as measured both by 3H-TdR incorporation and by cell cycle analysis performed with flow cytofluorometry. STM stimulates approximately 50% of rat B cells to enter cycle. Previous investigations by others have shown that at least two sets of signals are required for B cell differentiation; a) proliferation signals that may consist of both a stimulator of B cell conversion from G0 to G1 and growth factors, and b) differentiation signals that probably include at least two B cell differentiation factors (BCDF). When STM was tested in a differentiation system it did not drive purified B cells to differentiate to PFC, either alone or when supplemented with a supernatant from concanavalin A-stimulated spleen cells (CAS). However, when both CAS and dextran sulfate (DXS) were supplied to the STM-stimulated cells, a large number of PFC resulted. DXS does not act by stimulating an additional, CAS-responsive B cell subset, since it has only a marginal effect upon 3H-TdR uptake and does not increase the number of B cells in cycle when used together with STM. We postulate that the two agents may be acting sequentially: STM stimulates the B cells to proliferate, and DXS drives the proliferating cells to become responsive to CAS. This suggests that the signals for B cell differentiation must consist of at least three activities: a trigger to stimulate the cells to proliferate, a factor to drive the cells to a BCDF-responsive state, and a BCDF that can drive the cells to secrete antibody.     

Immortalization of BGDF (BCGF II)- and BCDF-producing T cells by human T cell leukemia virus (HTLV) and characterization of human BGDF (BCGF II)

Human peripheral T cells were transformed by human T cell leukemia virus (HTLV), and T cell lines producing BGDF (BCGF II) and BCDF were established. Among these cell lines, a cell line, TCL-Na1, secreted the highest level of both BGDF and BCDF, and the amount of BCDF secreted by TCL-Na1 cells was 900-fold more than that produced by PHA-stimulated T cells. Within the limits of our examination, none of the HTLV-transformed T cell lines produced IL 2 or BSF-p1 (BCGF I). BCDF produced by TCL-Na1 cells had a m.w. of 35,000 and a pI value of 5.5, being separated from BGDF, which was eluted in the fractions corresponding to m.w. of more than 60,000 and pI values of 5 to 6. BGDF induced both proliferation and IgM secretion in a mouse leukemic B cell line, BCL1, and these activities were not separated by either isoelectric focusing or gel filtration in the presence or absence of 0.1% Triton X-100, suggesting that the molecule designated BGDF exerted both growth and differentiation activities. BGDF acted on normal mouse B cells to induce proliferation as well as IgM secretion. The target cells of BGDF were in vivo activated B blast cells. BGDF acted on DXS-activated murine B cells to induce both proliferation and IgM secretion but not anti-Ig-activated B cells, indicating that BGDF and BSF-p1 were different molecules.     

Immunoglobulin production by a human-mouse somatic cell hybrid

The fusion of human lymphocytes and TEPC-15 mouse myeloma cells, which had not been adapted to culture, resulted in the establishment of in vitro hybrid cell cultures. Ten clones of this somatic cell hybrid were examined. There was preferential exclusion of human chromosomes: between two and five human chromosomes were identified in the hybrid clones by Giemsa banding. All of the clones had the mouse parental histocompatibility antigens, but only four clones also retained the human parental histocompatibility antigens. Secretion of parental immunoglobulin was determined by SDS-gel electrophoresis of species-specific immune precipitates. Synthesis of parental immunoglobulin by individual hybrid cells was determined by double label fluorescent antibody staining. Individual cells from six of the clones secreted and synthesized both human and mouse parental immunoglobulins. Three clones secreted only one parental immunoglobulin. Cells from one of these clones secreted and synthesized only human immunoglobulin. Cells from the remaining two clones secreted only one parental species of immunoglobulin but synthesized both human and mouse immunoglobulins. Finally, one clone did not secrete immunoglobulin, yet the individual cells synthesized both human and mouse parental species of immunoglobulin.     

Regulation of lymphocyte blastogenesis and antibody production by soluble factor released by a human B-lymphoblastoid cell line

Yam 1B, a human B lymphoblastoid cell line, spontaneously produced an immunoregulatory factor, which suppresses blastogenesis and antibody formation by human lymphocytes. The Yam 1B cells, which were derived from the peripheral blood of an adult T-cell leukemia patient, have been established and maintained in our laboratory since 1985. This cell line expressed mature B-cell surface antigens including surface immunoglobulin M (IgM), CD23, and HLA-DR; had cytoplasmic IgM; and secreted small amounts of IgM in the culture supernatants. Yam 1B was positive for Epstein-Barr virus-associated antigen (EBNA) but negative for adult T-cell-associated antigen (ATLA). The serum-free Yam 1B culture supernatants (SN) inhibited the expression of transferrin R, but neither the expression of interleukin 2 (IL-2) R(CD25) nor the production of IL-2 in the lymphocytes stimulated with phytohemagglutin. Yam 1B SN also inhibited DNA synthesis by human T and B lymphocytes and immunoglobulin generation by normal B cells as well as by Epstein-Barr virus-transformed human B lymphoblastoid cell lines. The inhibitory activity of Yam 1B SN was inactivated at 56 degrees C and at pH 10 but was relatively stable at pH 2. It was abrogated by digestion with pronase and was partially stable by digestion with trypsin. Fractions collected from a Sephacryl S-300 gel filtration column (Pharmacia Fine Chemicals, Uppsala, Sweden) were found to have a peak of inhibitory activity of cell proliferation associated with molecules of apparent MWr of 43,000 to 67,000. The inhibitory activity of Yam 1B SN was not blocked by the anti-transforming growth factor beta antibody.(ABSTRACT TRUNCATED AT 250 WORDS)     

Autologous mixes lymphocyte reaction in human cord blood lymphocytes: decreased generation of helper and cytotoxic T-cell functions and increased proliferative response and induction of suppressor T cells

T lymphocytes from neonates proliferated significantly more than peripheral blood T lymphocytes from adults in autologous mixed lymphocyte reactions (AMLR). AMLR-activated cord, as compared to adult T lymphocytes, exerted significantly less nonspecific cytotoxic activity on PHA-stimulated adult mononuclear cells and Epstein-Barr virus-transformed target cells. The impaired generation of cytotoxicity of cord T cells was not corrected by Interleukin-2. Blood T lymphocytes from adults activated in AMLR synthesized a helper factor that supported PWM-induced proliferation and immunoglobulin production in both adult and cord B lymphocytes. In contrast, cord blood T lymphocytes failed to produce the helper factor for B lymphocytes. T cells from AMLR cultures established with neonatal lymphocytes showed suppressor activity, as assessed in PWM-stimulated immunoglobulin synthesis of adult peripheral-blood mononuclear cells, significantly higher than that exhibited by T cells from AMLR cultures performed with lymphocytes from adults. Finally, neonatal B lymphocytes could be activated to the production of IgM but not IgG by either adult AMLR-derived helper factor plus PWM or by Epstein-Barr virus, whereas adult B cells secreted both IgM and IgG under the same type of stimulation.     

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.     

Lymphokines regulate immunoglobulin isotype expression in an antigen-specific immune response

The control of immunoglobulin class switching appears to involve T cell-derived lymphokines. Such lymphokines have been shown to affect isotype expression in polyclonally activated B cells. We show in this paper that the same lymphokines similarly control isotype expression in an antigen-specific response acting in concert with a "T cell independent" antigen. In this situation, B cell growth factor II (BCGF II) enhances the production of antigen-specific IgM antibodies, whereas the production of antigen-specific IgG1 antibodies is only observed in the presence of B cell differentiation factor gamma (BCDF gamma). These results suggest that these lymphokines (and perhaps additional ones) are involved in the control of isotype expression in antigen-specific responses.     

Transforming growth factor beta is an important immunomodulatory protein for human B lymphocytes

The growth and differentiation of B cells to immunoglobulin (Ig)-secreting cells is regulated by a variety of soluble factors. This study presents data that support a role for transforming growth factor (TGF)-beta in this regulatory process. B lymphocytes were shown to have high-affinity receptors for TGF-beta that were increased fivefold to sixfold after in vitro activation. The addition of picogram quantities of TGF-beta to B cell cultures suppressed factor-dependent, interleukin 2 (IL 2) B cell proliferation and markedly suppressed factor-dependent (IL 2 or B cell differentiation factor) B cell Ig secretion. In contrast, the constitutive IgG production by an Epstein Barr virus-transformed B cell line was not modified by the presence of TGF-beta in culture. This cell line was found to lack high-affinity TGF-beta receptors. The degree of inhibition of B cell proliferation observed in in vitro cultures was found to be dependent not only on the concentration of TGF-beta added but also on the concentration of the growth stimulatory substance (IL 2) present. By increasing the IL 2 concentrations in culture, the inhibition of proliferation induced by TGF-beta could be partially overcome. In contrast, the inhibition of Ig secretion induced by TGF-beta could not be overcome by a higher concentration of stimulatory factor, demonstrating that the suppression of B cell differentiation by TGF-beta is not due solely to its effects on proliferation. Furthermore, it was demonstrated that B lymphocytes secrete TGF-beta. Unactivated tonsillar B cells had detectable amounts of TGF-beta mRNA on Northern blot analysis, and B cell activation with Staphylococcus aureus Cowan (SAC) resulted in a twofold to threefold increase in TGF-beta mRNA. Supernatants conditioned by unactivated B cells had small amounts of TGF-beta, SAC activation of the B cells resulted in a sixfold to sevenfold increase in the amount of TGF-beta present in the supernatants. Thus, B lymphocytes synthesize and secrete TGF-beta and express receptors for TGF-beta. The addition of exogenous TGF-beta to cultures of stimulated B cells inhibits subsequent proliferation and Ig secretion. TGF-beta may function as an autocrine growth inhibitor that limits B lymphocyte proliferation and ultimate differentiation.     

Proteins associated with B lymphocyte hyperactivity in New Zealand black mice

New Zealand Black (NZB) mice exhibit polyclonal B cell activation and elevated immunoglobulin production, an abnormality associated with the spontaneous autoimmune disease that affects this strain. To further our understanding of this abnormality of B cell differentiation and maturation, we have employed two-dimensional polyacrylamide gel electrophoresis to analyze the proteins synthesized by lymphocytes of several strains. Two proteins were produced by lymphocytes from NZB mice but not those from normal strains. One was a 16 kd protein with a pI of 5.1, and the other was a 27.5 kd protein with a pI of 4.5. The presence of the xid gene on the NZB background suppressed production of both proteins. They were synthesized by spleen cells but not by bone marrow or lymph node cells, and production was restricted to enlarged B lymphocytes. p16 was synthesized by normal mouse strain B cells upon stimulation with LPS. The 27.5 kd protein was shown to be secreted. On the basis of partial amino acid sequence determination of proteins eluted from gels, p27.5 was identified as J chain and p16 as the C terminal fragment of mu-chain. The synthesis of two other proteins, 13 kd and 18 kd in size, was elevated in NZB spleen lymphocytes. The 18 kd protein was identified as translation initiation factor eIf-4D. The increased level of this protein may be related to the upregulation of immunoglobulin synthesis.     

Synergy between B cell differentiation factors and interleukin 2, using a monoclonal system

By using monoclonal B cell targets, cells derived from patients with chronic lymphocytic leukemia, and B cell differentiation factors (BCDF) derived from monoclonal human T cell hybridomas, we have demonstrated marked synergy for differentiation between interleukin 2 (IL 2) and BCDF. IL 2 alone had no effect on the proliferation of differentiation to immunoglobulin secretion in these cell populations; however, in conjunction with a variety of BCDF, differentiation to plaque-forming cells (PFC) was augmented 10- to 100-fold. There was no increase in proliferation as measured by [3H]thymidine incorporation. These effects could be demonstrated with concentrations of IL 2 as low as 5 U/culture, well within the physiologic range, by using either commercially available or recombinant IL 2. The addition of IL 2 to the B cell and BCDF cultures resulted in almost 100% expression of the IL 2 receptor, Tac, on the surface of these cells, and the augmented PFC response could be inhibited 70 to 80% by the addition of anti-Tac to the culture. Kinetic studies revealed that the addition of IL 2 to the B cell cultures could be delayed for up to 72 hr without a change in the PFC response, suggesting that IL 2 was acting as a secondary or synergistic signal for differentiation. Thus, it appears that IL 2 does have a role in B cell maturation mediated, in part, by IL 2 binding to the IL 2 receptor present on certain B cells.