Limiting dilution analysis of Epstein-Barr virus-induced immunoglobulin production

The major goal of this work is to establish a culture system for the growth of human B lymphocytes at the single-cell level so that the immunoglobulin secreted by the clonal progeny of that cell can be analyzed. A method which involves culturing small numbers (1–1000) of lymphocytes, which have been infected with Epstein-Barr virus (EBV) prior to plating, in round-bottom microtiter plates is described. A feeder layer of irradiated (2500 R) umbilical cord blood lymphocytes to which phytohemagglutinin has been added was found to be optimal. Culture supernatants collected from 3 to 6 weeks postinfection are assayed for the production of IgG and IgM by radioimmunoassay in order to determine the overall cloning efficiency of the system. We have shown that up to 33% of surface Ig-positive cells produce detectable clones in this system. Umbilical cord blood cells are superior to T-cell and macrophage cell lines as feeder layers. Furthermore, culture supernatants from phytohemagglutinin-stimulated umbilical cord lymphocytes do not adequately replace these cells. We also observed that while most IgM-secreting clones continued to produce immunoglobulin during the 7-week time period analyzed, the majority of IgG-secreting clones had a relatively short half-life in vitro. This culture system allows us to examine a significant proportion of the human B-cell population and carry out studies on the frequency of specific antibody- and isotype-producing clones.     

Ig isotypes produced by EBV-transformed B cells as a function of age and tissue distribution

EBV can transform human B cells giving rise to lymphoblastoid cell lines that produce and secrete Ig. Herein B cells from various tissues of newborns and adults were transformed by EBV and their Ig products were analyzed with isotype-specific mAb. Although IgG- and IgA-bearing B cells were present in the newborn, EBV transformed IgM-producing cells almost exclusively in both newborn blood and breast milk. IgM-secreting cells were derived from IgM+ B cells and IgM- pre-B cells present in neonatal blood, but only from IgM+ cells in adult blood. Whereas in adults most EBV-transformed cells produced IgM, producers of IgG and of IgA were present in frequencies that varied according to the tissue source. Precursors of IgG-producing cells were relatively abundant in blood, spleen, and tonsil, and relatively infrequent in bone marrow and appendix. EBV-inducible IgA producers were relatively concentrated in the appendix and to a lesser extent in tonsils and blood. Differences in the subclass composition of EBV-transformed populations of IgG- and IgA-producers were also observed for the various adult lymphoid tissues. IgG1-producing cells predominated in most tissues, and precursors of IgG2 were largely confined to the circulation. Whereas IgA1-producing cells were predominant in all tissues, a marked enrichment in IgA2-producers was observed in the appendix. These results indicate a remarkable heterogeneity in the isotype distribution pattern of EBV-transformable B cells that is determined both by developmental age and tissue localization. We propose that EBV selectively transforms primed B cells, the isotype commitment of which varies according to tissue origin and age.     

In vitro regulation of IgA subclass production. III. Selective transformation of IgA1 producing cells by Epstein-Barr virus

In past experiments, using limited dilution analysis, we have demonstrated that a high percentage of immunoglobulin-secreting clones derived from Epstein-Barr virus- (EBV) stimulated lymphocytes secrete IgA. To further characterize the IgA produced by these clones, the IgA subclass of supernatants from clones stimulated 4 to 6 wk previously with EBV was determined by radioimmunoassay. All of 17 IgA-producing clones secreted IgA1; none secreted IgA2. Because we have shown that surface IgM+ (sIgM+) B cells are an enriched source of IgA2 plasma cell precursors, panning techniques were used to purify sIgM+ B cells from tonsils. Of 103 clones derived from these sIgM+ B cells, 102 secreted IgA1 and only one secreted IgA2. The relative absence of IgA2-producing clones could not be attributed to an absence of EBV receptors on IgA2 cells. A mean of 84 +/- 4% of freshly isolated IgA2 B cells and 78 +/- 6% of IgA1 B cells could be stained with a monoclonal antibody binding the EBV receptor; and there was no failure of EBV to infect IgA2 plasma cells precursors. Of IgA2 plasma cells derived from peripheral blood lymphocytes stimulated 7 days previously with EBV, 54 +/- 7% were positive for the EBV nuclear antigen, compared with 54 +/- 18% of IgA1 plasma cells from the same cultures. Seven days after EBV stimulation, a mean of 25% of the total IgA plasma cells were positive for cytoplasmic IgA2, whereas by 21 days after stimulation only 7% were positive for IgA2. This shift in the proportions of IgA1 and IgA2 plasma cells could be attributed to a failure of the IgA2 plasma cell number to increase after 10 days in culture. There was no evidence for selective suppression of IgA2 production by T cells or selective lysis of IgA2 plasma cells by infectious EBV particles. These results demonstrate that although precursors for both IgA1- and IgA2-producing cells can be stimulated to differentiate in response to EBV, there is preferential transformation of IgA1-producing cells.     

Activated T lymphocytes resist the toxic effects of the adenosine deaminase inhibitor, 2-deoxycoformycin

Tonsil lymphocytes from three adults and three children were examined for immunoglobulin (Ig) production before and after Epstein-Barr virus (EBV) transformation. T-cell depletion was required to obtain cell lines from EBV-seropositive individuals. Cytoplasmic Ig was mainly IgG in adult lymphocytes before and after transformation; IgA and IgM were more prominent after than before. IgM and IgG predominated in lymphocytes of children before and after transformation; IgA was more prominent after than before. Cytoplasmic Ig of peripheral blood lymphocytes from these individuals was mainly IgM. Secreted Ig from tonsil lymphocytes was mainly IgA or IgG; after transformation IgM predominated with adult cell lines, and IgG or IgM with cell lines from children. IgE was consistently sparse in spite of ragweed and/or grass allergies of the adults.     

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.     

Analysis of T cell and B cell function in Peyer's patch and lamina propria of New Zealand Black and DBA/2 mice

We have analyzed gastrointestinal immune function in both DBA/2 and spontaneously autoimmune New Zealand Black (NZB) mice. We have studied both in vitro proliferation and differentiation of Peyer's patch cells and have measured immunoglobulin (Ig) secretion by cultured jejunal segments. Peyer's patch B cells and T cells from both DBA/2 and NZB mice showed similar proliferative responses to Con A and lipopolysaccharide (LPS), respectively. Unlike NZB splenic B cells, isolated Peyer's patch B cells from NZB mice did not spontaneously secrete Ig of any isotype. Seven-day cultures of equal numbers of Peyer's patch T cells and B cells resulted in similar patterns of secretion of IgA, IgG, and IgM in both strains. The addition of Con A to cultures of DBA/2 Peyer's patch cells consistently resulted in a onefold to threefold increase in IgA secretion after 7 days. Con A stimulation of NZB Peyer's patch cells did not produce any increment in IgA secretion. LPS stimulation of Peyer's patch cells from either strain resulted in a similar increase in IgG secretion with little effect on IgA secretion. The in vivo correlate of this finding was seen in the IgA to IgG ratio of Ig secreted by cultured jejunal fragments. In DBA/2 mice the rates of IgA/IgG varied from 2.36 to 4.85, whereas in NZB mice the ratio never exceeded 0.5. These experiments show that defects on the T cell compartment of NZB mice encompass gut-associated lymphoid tissue. The possible relationship of these findings and previously observed defects in oral tolerance is discussed.     

Pathophysiologic analysis of peripheral blood lymphocytes from patients with primary immunodeficiency. I. Ig synthesis by peripheral blood lymphocytes stimulated with either pokeweed mitogen or Epstein-Barr virus in vitro

In the present study 5 patients with common variable hypogammaglobulinemia (CVH) and 4 patients with selective IgA deficiency (IgA-D) were analyzed for the cellular defects responsible for impaired Ig synthesis with use of peripheral blood lymphocytes stimulated with either PWM or EBV in vitro. By the use of co-culture with PWM, all the patients examined had intrinsic B cell defects restricted to the synthesis of Ig class corresponding to the low or absent Ig class(es) in the sera. Two types of excessive suppressor T activity were found, which were abrogated by irradiation. One was isotype-nonspecific and the other was IgA-specific. Moreover, failure of IgA-specific helper T activity was demonstrated. The use of EBV as an agent that polyclonally activates B cells independently of T cells and monocytes should allow a clearer delineation of the level of the B cell defects. When co-cultured with EBV, B cells from 3 patients with CVH produced normal to subnormal quantities of IgM although they could produce no IgM upon co-culturing with normal T cells and PWM. B cells from 2 patients with CVH could produce IgM normally by stimulation with either PWM or EBV; however, there was no restoration to produce IgG or IgA in these patients. In addition, B cells from 2 patients with IgA-D produced not only IgG and IgM but also IgA almost normally at 4 days after in vitro stimulation with EBV.     

Characterization of a spontaneous murine B cell leukemia (BCL1). II. Tumor cell proliferation and IgM secretion after stimulation by LPS.

A spontaneous BALB/c B lymphocyte leukemia could be stimulated in vitro by the polyclonal B cell activator lipopolysaccharide (LPS) and the conditions for activation were studied. Spleen cells or peripheral blood lymphocytes from tumor-bearing animals responded by increased DNA synthesis and the peak of activation occurred earlier than with normal mouse spleen cells. Tumor cells harvested from the spleen, but not from the peripheral blood, could be induced by LPS to secrete IgM. Direct demonstration that the response was due to tumor cell activation and not that of contaminating normal B lymphocytes was provided by karyotype analysis and by immunoprecipitation, which showed the restriction of light chains on secreted IgM molecules to the lambda isotype.     

Jacalin, an IgA-binding lectin, inhibits differentiation of human B cells by both a direct effect and by activating T-suppressor cells

Jacalin, a lectin extracted from the seeds of Artocarpus intergifolia (jackfruit), has been reported to bind specifically to IgA while inducing B-cell polyclonal immunoglobulin secretion. We confirmed that jacalin only binds to IgA and not to IgG or IgM and extended these findings by showing that it does not bind to IgE. Addition of jacalin to either unfractioned peripheral blood lymphocytes or purified B cells failed to induce immunoglobulin synthesis; indeed immunoglobulin production was diminished in the presence of jacalin. We found that jacalin directly inhibited the induction of immunoglobulin synthesis from B cells in the presence of T-cell replacing factor. Cell lines making IgG, IgM, and IgA were inhibited by jacalin. Furthermore, T cells incubated with jacalin also inhibited immunoglobulin production by stimulated B cells. Under these conditions jacalin was found to be a potent mitogen for T cells but to induce little or no activation of B cells. Jacalin appears to be a potent T-cell mitogen which can induce suppressor T cells for Ig production. It also has a direct inhibitory effect on B-cell Ig production.     

IL-2 and a contact-mediated signal provided by TCR alpha beta + or TCR gamma delta + CD4+ T cells induce polyclonal Ig production by committed human B cells. Enhancement by IL-5, specific inhibition of IgA synthesis by IL-4.

To study the role of T cells in T-B cell interactions resulting in isotype production, autologous purified human splenic B and T cells were cocultured in the presence of IL-2 and Con A. Under these conditions high amounts of IgM, IgG, and IgA were secreted. B cell help was provided by autologous CD4+ T cells whereas autologous CD8+ T cells were ineffective. Moreover, CD8+ T cells suppressed Ig production when added to B cells cocultured with CD4+ T cells. Autologous CD4+ T cells could be replaced by allogeneic activated TCR gamma delta,CD4+ or TCR alpha beta,CD4+ T cell clones with nonrelevant specificities, indicating that the TCR is not involved in these T-B cell interactions. In contrast, resting CD4+ T cell clones, activated CD8+, or TCR gamma delta,CD4-,CD8- T cell clones failed to induce IL-2-dependent Ig synthesis. CD4+ T-B cell interaction required cell-cell contact. Separation of the CD4+ T and B cells by semiporous membranes or replacement of the CD4+ T cells by their culture supernatants did not result in Ig synthesis. However, intact activated TCR alpha beta or TCR gamma delta,CD4+ T cell clones could be replaced by plasma membrane preparations of these cells. Ig synthesis was blocked by mAb against class II MHC and CD4. These data indicate that in addition to CD4 and class II MHC Ag a membrane-associated determinant expressed on both TCR alpha beta or TCR gamma delta,CD4+ T cells after activation is required for productive T-B cell interactions resulting in Ig synthesis. Ig production was also blocked by mAb against IL-2 and the IL-2R molecules Tac and p75 but not by anti-IL-4 or anti-IL-5 mAb. The CD4+ T cell clones and IL-2 stimulated surface IgM-IgG+ and IgM-IgA+, but not IgM+IgG- or IgM+IgA- B cells to secrete IgG and IgA, respectively, indicating that they induced a selective expansion of IgG- and IgA-committed B cells rather than isotype switching in Ig noncommitted B cells. Induction of Ig production by CD4+ T cell clones and IL-2 was modulated by other cytokines. IL-5 and transforming growth factor-beta enhanced, or blocked, respectively, the production of all isotypes in a dose-dependent fashion. Interestingly, IL-4 specifically blocked IgA production in this culture system, indicating that IL-4 inhibits only antibody production by IgA-committed B cells.     

Relationship between immunoglobulin production and immortalization by Epstein Barr virus

After infection with Epstein Barr virus (EBV), human B lymphocytes actively secrete immunoglobulin (Ig) and are immortalized to become long-term cell lines. In these studies, we investigated the relationship between these virally induced processes utilizing limiting dilution culture techniques, and asked whether all B cells stimulated by EBV to secrete Ig are also immortalized. The activation of B cells by EBV resulting in Ig production and immortalization involved a single precursor cell, required live viral particles, and was independent of immunity to EBV by the lymphocyte donor. However, the precursor frequency of B cells activated to secrete Ig (mean 4.7%) was higher than the precursor frequency of B cells activated to long-term in vitro growth (mean 2.1%). When examined at a single cell level, it appeared that although the vast majority of the immortalized B cells also secrete Ig, only approximately 50% of the B cell precursors induced by EBV to secrete Ig go on to form long-term cell lines. In addition, although immortalized B cell clones producing all major classes of Ig were detected, IgM-committed precursors were more likely to become immortal than were precursors committed to IgG or IgA production. In contrast to these findings in B cells freshly infected with EBV, Ig production was almost always associated with evidence of long-term growth when B cells from previously established EBV-induced B cell lines were tested in identical limiting dilution cultures. Thus, after infection with EBV, human B cells can either become transiently activated to proliferate and to secrete Ig, or become transformed into long-term cell lines most of which produce Ig.     

Immunoglobulin M and immunoglobulin G secretion by human B cells exposed to RU 41.740, a glycoprotein extract from Klebsiella pneumoniae

RU 41.740, a glycoprotein extract from Klebsiella pneumoniae, was seen to activate human B cells to immunoglobulin secretion in vitro. The effects of RU 41.740 on human B cells were compared to those induced by pokeweed mitogen, a T-cell-dependent polyclonal B-cell activator, and Epstein-Barr virus, a T-cell-independent polyclonal B-cell activator. Exposure of human B cells to all of these agents resulted in increased immunoglobulin M (IgM) and immunoglobulin G (IgG) secretion. IgM and IgG secretion induced by RU 41.740 appeared to be T cell dependent when B cells were isolated from human peripheral blood. However, this activity may have been T cell independent when B cells were isolated from human spleen. RU 41.740-induced IgM secretion by peripheral blood B cells was seen to peak after 6 days in culture; IgG secretion peaked after 7 days in culture. The optimal concentration of RU 41.740 for the induction of IgM and IgG secretion by human B cells in vitro was seen to be 200 micrograms/ml.     

CD40 stimulation provides an IFN-gamma-independent and IL-4-dependent differentiation signal directly to human B cells for IgE production.

IgE induction from human cells has generally been considered to be T cell dependent and to require at least two signals: IL-4 stimulation and T cell/B cell interaction. In the present study we report a human system of T cell-independent IgE production from highly purified B cells. When human cells were co-stimulated with a mAb directed against CD40 (mAb G28-5), there was induction of IgE secretion from purified blood and tonsil B cells as well as unfractionated lymphocytes. Anti-CD40 alone failed to induce IgE from blood mononuclear cells or purified B cells. The effect of the combination of anti-CD40 and IL-4 on IgE production was very IgE isotype specific as IgG, IgM, and IgA were not increased. Furthermore, anti-CD40 with IL-5 or PWM did not co-stimulate IgG, IgM, or IgA and in fact strongly inhibited PWM-stimulated IgG, IgM and IgA production from blood or tonsil cells. IgE synthesis induced by anti-CD40 plus IL-4 was IFN-gamma independent as is the in vivo production of IgE in humans; the doses of IFN-gamma that profoundly suppressed IgG synthesis induced by IL-4, or IL-4 plus IL-6, had no inhibitory effect on anti-CD40-induced IgE production. Anti-CD23 and anti-IL-6 also could not block anti-CD40 plus IL-4-induced IgE production, but anti-IL-4 totally blocked their effect. IgE production via CD40 was not due to IL-5, IL-6 or nerve growth factor as none of these synergized with IL-4 to induce IgE synthesis by purified B cells. Finally, we observed that CD40 stimulation alone could enhance IgE production from in vivo-driven IgE-producing cells from patients with very high IgE levels; cells that did not increase IgE production in response to IL-4. Taken together, our data suggest that the signals delivered for IgE production by IL-4 and CD40 stimulation may mimic the pathway for IgE production seen in vivo in human allergic disease.     

T cell regulation of antibody responses: an I-A-specific, autoreactive T cell collaborates with antigen-specific helper T cells to promote IgG responses

In earlier studies we showed that hapten-specific inducer T cell clones specifically induce B cells from immunized donors to secrete IgM antibodies. However, IgG responses were not observed, suggesting that an additional signal(s) was required. In this report, we show that an autoreactive T cell clone produces a factor(s) that collaborates with antigen-specific inducer T cells to promote specific IgG responses. This factor is not restricted by antigen or MHC determinants and promotes IgG production both in vivo and in vitro. These findings suggest that autoreactive cells may play an important role in the regulation of isotype expression.     

Human peripheral blood B lymphocyte subpopulations: functional and phenotypic analysis of surface IgD positive and negative subsets

Highly purified human peripheral blood B cells stimulated with Cowan I Staphylococcus aureus (SA) and mitogen-activated T cell supernatants (T supt) generated large numbers of immunoglobulin (Ig)-secreting cells (ISC), whereas fewer ISC developed in cultures containing T supt in the absence of SA. To determine whether surface Ig isotype expression defined responsive B cell subsets, IgD+ and IgD- B cells were prepared with the fluorescence-activated cell sorter. Whereas both the IgD+ and IgD- B cells responded to SA + T supt, only the IgD- subset generated substantial numbers of ISC in response to T supt alone. Analysis of secreted Ig revealed that IgG and IgA were the predominant isotypes secreted by IgD- B cells in response to T supt or SA + T supt. By contrast, the IgD+ cells secreted predominantly IgM in response to SA + T supt but not to T supt alone. When responsiveness to pokeweed mitogen (PWM) was examined in the presence of supplemental T cells, the IgD- subset was found to be greatly enriched for responsive cells, and again, IgG and IgA were the predominant isotypes secreted, although these cells were also capable of secreting some IgM. The magnitude of the response induced by PWM from IgD- B cells was usually greater than that induced by SA + T supt. Although IgD+ B cells responded poorly to PWM, the differentiation of a small number of IgM-secreting cells was routinely stimulated by this polyclonal activator in the presence of T cells. The magnitude of the PWM response by IgD+ B cells was always greatly diminished compared with that stimulated by SA + T supt. Cell cycle analysis after acridine orange staining, cell volume measurement, and staining for expression of activation antigens (transferrin receptor and 4F2) indicated that the IgD- B cells were largely resting, but did contain a population of activated cells. Removal of activated 4F2+ cells from the IgD- subset diminished but did not abolish their capacity to generate ISC in response to SA + T supt or PWM in the presence of T cells. These results suggest that the IgD- population contains both an activated 4F2+ and a resting 4F2- subset. The data emphasize that multiple subpopulations of peripheral blood B cells contain precursors of ISC. Moreover, the responsiveness of the subsets to various stimuli and the Ig isotype subsequently secreted appear to be intrinsic features of each subset.     

Activation through CD3 molecule leads a number of human T cell clones to induce IgE synthesis in vitro by B cells from allergic and nonallergic individuals

Seventy-eight clones established from tonsillar T lymphocytes of two nonallergic children were tested under different experimental conditions for their ability to induce in vitro IgE synthesis by B cells from allergic or nonallergic donors. After 24 hr preactivation with phytohemagglutinin (PHA), 11 out of 32 CD4+ clones from the first and 17 out of 36 CD4+ clones from the second tonsil donor showed the ability to induce IgE synthesis in vitro by B cells from both allergic and nonallergic individuals, whereas none of 10 CD8+ clones nor T blasts of PHA-induced cell lines obtained from unfractionated T cell suspensions of the same tonsils had such an effect. Seven of the 11 T cell clones from the first tonsil donor active on IgE production after pre-activation with PHA also induced IgE synthesis in vitro by nonallergic and allergic B cells upon stimulation with anti-CD3 monoclonal antibody. Under the same experimental conditions, virtually all of the T cell clones able to induce IgE synthesis in vitro by target B cells showed the ability to stimulate IgG and IgM production as well. T cell clones were also established from the peripheral blood of a nonallergic donor and were tested for their ability to induce IgE synthesis in autologous B cells. After preactivation with PHA, seven out of 35 CD4+ clones induced the production of detectable amounts of both IgE and IgG in autologous B cells. The addition to the cultures of PHA-stimulated unfractionated T cells inhibited in a dose-dependent manner the IgE but not the IgG synthesis induced by an autologous helper T cell clone in autologous B cells. Taken together, these data indicate that a remarkable proportion of human T cell clones upon triggering of the CD3 molecular complex were able to provide help for the synthesis of IgE in B cells from both allergic and nonallergic individuals. The successful induction of IgE synthesis by single T cell clones was apparently related to the lack of concomitant suppressor activity to which IgE-producing cells appeared to be exquisitely sensitive.     

Suppression of polyclonal human B cell activation by IgG binding factors: interference with the maturation of Ig-containing cells into Ig-secreting cells

Human IgG binding factors (IgG BF) were prepared by immunopurification on IgG immunosorbents from cell-free supernatants of unstimulated peripheral blood mononuclear cells (PB MNC). The suppressive effects of IgG BF was studied using PB MNC stimulated by pokeweed mitogen or by nocardia delipidated cell mitogen. At the end of the culture three parameters of B cell activation were measured: (1) the numbers of IgM-, IgG-, or IgA-containing cells (CC) using direct immunofluorescence, (2) the numbers of IgM, IgG, or IgA plaque-forming cells (PFC) using a Protein A hemolytic plaque assay, and (3) the concentrations of IgM, IgG, or IgA in culture supernatants using an enzyme-linked immunosorbent assay. Addition of IgG BF at the third day of culture resulted in a selective decrease of IgG CC, while IgM CC and IgA CC were increased or unchanged. Conversely, IgG BF induced a nonselective diminution of the number of PFC and of the amount of secreted Ig of the three major Ig classes. Therefore the results demonstrate two distinct effects of IgG BF: (1) an isotype-specific suppression of cells producing IgG, demonstrated by the parallel decrease of IgG CC and IgG PFC, and (2) a blocking of the late stages of B cell maturation evidenced by the discrepancy between normal or elevated Ig CC and decreased Ig PFC of the IgM and IgA classes.     

Transforming growth factor beta 1 increases IgA isotype switching at the clonal level

Transforming growth factor beta 1 (TGF beta 1) has important effects on expression of the IgA isotype. TGF beta 1 alone, or in combination with IL-5 or IL-2 increases IgA secretion by populations of LPS-activated surface IgA negative (sIgA-) spleen B cells, while concurrently decreasing IgM and IgG secretion. The present study demonstrates the activity of TGF beta 1 as an IgA isotype switch factor at the clonal level. Stimulation of LPS-activated sIgA- spleen B cell populations with TGF beta 1, or a combination of TGF beta 1 and IL-2, resulted in a significant increase in total numbers of IgA secreting cells, and this increase ultimately was paralleled by an increase in total IgA secretion. Using limiting dilution analysis, TGF beta 1 was shown to increase the frequency of IgA secreting B cell clones, by approximately 20-fold. This was not accompanied by increased numbers of IgA secreting cells/clone. In contrast, IL-2 does not have activity as an IgA switch factor, but does increase IgA production by B cells already committed to secrete that isotype. Cell cycle inhibitors such as thymidine and hydroxyurea also selectively increased numbers of IgA secreting cells and total IgA secretion among populations of LPS-activated sIgA- spleen B cells. This suggests the IgA enhancing activity of TGF beta 1 may, in part, be related to its ability to inhibit cell growth.     

Regulation of IgA secretion by T cell clones derived from the human gastrointestinal tract

The role of T cells in Ig isotype regulation is still unclear. To address this question, we generated mitogen-stimulated T cell clones from normal human lymphoid follicles of the gut-associated lymphoid tissue (appendix). Both the T cell clones and clonal supernatants provided preferential help for IgA secretion by PWM-stimulated B cells. Many of these CD3+, CD4+, 4B4+, DR+ helper clones co-expressed Fc-gamma and Fc-alpha R, but there was poor correlation between the expression of Fc-alpha R and IgA help (p = 0.31). Most of the T cell clones helped both IgM+A- and IgM-A+ B cell populations to secrete IgA, suggesting that they mediate switch of isotype-uncommitted B cells as well as post-switch expansion of IgA-committed B cells; however, some of the T cell clones helped IgM+A- B cell populations much more than IgM-A+ B cell populations, suggesting that, in this case, the regulatory effect is predominantly at the level of B cell switch. In all, these results show that the mucosal immune system contains individual T cells which are capable of positively regulating IgA-specific isotype differentiation at two levels of B cell development, thus allowing for efficient generation of IgA-secreting B cells.