Regulation of IgA differentiation in CH12LX B cells by lymphokines. IL-4 induces membrane IgM-positive CH12LX cells to express membrane IgA and IL-5 induces membrane IgA-positive CH12LX cells to secrete IgA

In these studies we utilized the Ag (SRBC)-reactive B cell line CH12LX to study isotype switching. CH12LX cells are a stable population of B cells mainly bearing membrane IgM (mIgM) (98 to 99%) with a small population of B cells bearing membrane IgA (mIgA) (1 to 2%). LPS induced a 5- to 10-fold increase in the secretion of both Ig, whereas a lymphokine-rich supernatant of D10 T cells induced a greater increase in the secretion of IgA than IgM. Analysis of the latter effect with recombinant lymphokines disclosed that rIL-4 induced an increase in the number of mIgA+ cells (6 to 15%) with minimal effect on IgA secretion, whereas IL-5 induced increased IgA secretion but had no effect on mIgA expression. The addition of both lymphokines induced increased mIgA expression and IgA secretion. No effect on mIgA expression or IgA secretion was seen with other lymphokines, including IL-1, IL-2, IL-3, IL-6, GM-CSF, and IFN-gamma. The rIL-4 effect on CH12LX cells represents true differentiation rather than selective proliferation for the following reasons: first, subclones of CH12LX cells respond to IL-4-containing T cell supernatant in the same fashion as the original cell line; second, culture of CH12LX cells with IL-4 causes the appearance of large numbers of dual-bearing mIgM/mIgA cells as well as mIgA+ cells and a dual-bearing mIgM/mIgA line was obtained by cloning CH12LX after stimulation with an IL-4-containing supernatant; third, sorted mIgA+ and mIgA- CH12LX cells had similar rates of proliferation in the presence or absence of IL-4. In further studies, it was found that IL-5 causes IgA secretion by mIgA+ but not mIgA- CH12LX cells indicating that it is acting as a post-isotype switch differentiation factor. These studies are consistent with the view that IL-4 and IL-5 act in a sequential fashion to induce IgA expression and secretion in CH12LX cells, IL-4 inducing differentiation of mIgM+ cells to mIgA+ cells and IL-5 enhancing the IgA secretion by the resulting mIgA-bearing cells.     

Cholera toxin promotes B cell isotype differentiation

Cholera toxin (CT) is a powerful oral immunogen and adjuvant that elicits strong IgG and IgA antibody responses. In our study we investigated whether this property of CT was associated with an effect on B cell isotype differentiation. Initially, we determined the effect of CT on normal LPS-induced Peyer's patch B cells and found that whereas CT is strongly inhibitory of IgM production, it increases by approximately three-fold the number and frequency of IgG- and IgA-producing cells. Subsequently, using cell sorting technology, we demonstrated that CT acts on membrane (m)IgM+, mIgG/mIgA- B cells rather than mIgG/mIgA+ B cells. In addition, we showed that CT does not cause selective inhibition of mIgM, or enhancement of mIgG/mIgA B cell proliferation. In parallel studies we determined the effect of CT on the differentiation of a clonal B cell population, CH12.LX cells, i.e., a population comprised mainly of mIgM+ cells (98%) admixed with a small subpopulation of mIgA+ cells (2%). Here we found that CT (in the absence of LPS) causes a rapid decrease (24 h) in the intensity of mIgM expression as well as a marked increase in the size of the subpopulation expressing mIgA. In addition, we found that CT (in the presence of LPS), inhibits CH12.LX IgM production while increasing the absolute number and frequency of IgA-producing cells. In contrast, CT inhibits IgA production by CH12.LX.A2 cells, a subclone of CH12.LX cells that bears only IgA. Finally, we demonstrated that CT is equally inhibitory of the proliferation of CH12.LX cells and CH12.LX.A2 cells. Taken together, these effects of CT on normal B cells and a clonal B cell line indicate that CT induces substantial numbers of mIgM+ cells to undergo isotype differentiation into mIgG+ or mIgA+ B cells. In a final series of studies we showed that the effect of CT on isotype differentiation was mimicked by the B subunit of CT, i.e., the subunit that does not activate intracellular adenylate cyclase; thus the induction of isotype differentiation by CT is not mediated by a perturbation in cAMP level.     

Substance P acts directly upon cloned B lymphoma cells to enhance IgA and IgM production.

The IgA producing murine B lymphoma, CH12.LX.C4.4F10 (4F10) and the IgM producing murine lymphoma, CH12.LX.C4.5F5 (5F5) were found to express substantial numbers of substance P (SP) receptors having dissociation constants equal to 0.69 nM. Binding of SP by these B lymphoma cells was via the tachykinin-specific C-terminus sequence, Phe-X-Gly-Leu-Met-NH2, because SP, SP antagonist (D-Pro2-D-Phe7-D-Trp9-SP), eledoisin, and substance K could effectively inhibit radiolabeled SP binding, whereas the SP N-terminus fragment, SP (1-4), could not. The functionality of these receptors could be demonstrated by the ability of subnanomolar concentrations of SP to induce Ig secretion in a dose-dependent fashion. However, the presence of a second stimulus in these cultures was required to obtain maximal increases. IgA secretion by 4F10 cells was elevated only 25 to 37%, and IgM secretion by 5F5 cells was not significantly increased in cultures in which nanomolar concentrations of SP were present. Conversely, coculturing 5F5 cells with a suboptimal concentration of LPS (50 ng/ml) and 10(-10)M SP resulted in an approximate threefold increase in supernatant IgM when compared to control cultures stimulated with LPS alone. While not as dramatic, 10(-10) M SP also enhanced IgA secretion of LPS-stimulated 4F10 cells by approximately 45%. This enhancement of Ig secretion was SP-specific, as evidenced by the ability of 1000-fold excess of SP antagonist to block SP-induced, but not LPS-induced, Ig production. Clearly, SP could act synergistically with LPS to enhance Ig secretion; therefore, we questioned whether this augmentation was also reflected at the level of H chain mRNA expression. 10(-9)M SP induced modest increases (50 to 60%) in mu-chain mRNA expression by LPS-stimulated 5F5 cells when compared with cells stimulated with LPS alone. The 4F10 cells did not display this magnitude of difference for alpha-chain mRNA expression. Thus, although SP-induced increases of mu-chain mRNA by 5F5 cells may contribute to the increased Ig secretion observed by these LPS-activated lymphocytes, it is unlikely that increased mRNA expression can totally account for the threefold increases in secretion that were observed.     

The roles of IL-4, TGF-beta and LPS in IgA switching.

CH12.LX B cells have been used as a lymphoma model of MHC restricted, antigen-dependent B cell differentiation. These B cells express surface IgM and secrete IgM. Most recently we have demonstrated that CH12.LX is a model of cytokine driven IgA differentiation. Recently, transforming growth factor beta (TGF-beta) has been shown to be a probable switch factor for IgA in LPS-stimulated mouse lymphocytes, therefore we chose CH12.LX B cells to study the effect of IL-4, TGF-beta and LPS in IgA isotype switching. Adding TGF-beta to the monoclonal cell line CH12.LX results in induction of mIgA expression but no enhancement of IgA secretion similar to the effect of IL-4. The addition of LPS serves as a non-specific stimulus to enhance the secretion of the expressed immunoglobulin, but has no IgA specific activity of its own. IL-4 and TGF-beta together are synergistic for mIgA expression. Pretreatment studies show that TGF-beta added after IL-4 is the same as TGF-beta alone whereas the converse is the same as adding both cytokines together. TGF-beta acts by increasing the steady state levels of alpha message, whereas northern analysis indicates that IL-4 does not induce alpha message the way TGF-beta does. These data confirm that TGF-beta by itself is an isotype switch factor for IgA. In addition, IL-4 and TGF-beta cause mIgA expression through different mechanisms. CH12.LX B cells serve as a valuable model to study the role of multiple signals required for mIgA expression and IgA secretion.     

Role of the interleukin 2 receptor in differentiation of a clone of Ly-1+ B cells

CH12.LX, an in vitro subclone of a murine B cell lymphoma that makes IgM reactive with sheep erythrocytes (SRBC), has cell surface receptors for the lymphokine interleukin 2 (IL 2). The binding of recombinant murine IL 2 to these receptors did not stimulate CH12.LX cells to differentiate and secrete antibody. However, the binding of either of two monoclonal antibodies (Mab) specific for the IL 2 receptor increased the proportion of CH12.LX cells that secrete hemolytic IgM. The effect did not require the presence of antigen. One of the Mab, 3C7, is known to block the binding of IL2 to its receptor on T cells, whereas the other, 7D4, which also reacts with the IL 2 receptor, does not block the binding of IL 2. The differentiation of CH12.LX induced by 3C7, but not that induced by 7D4, was inhibited by recombinant IL 2. Neither IL 2 (up to 200 U/ml) nor 3C7 (up to 10 micrograms/ml) had any significant influence on incorporation of [3H]thymidine; 7D4 at 10 micrograms/ml decreased thymidine incorporation by about 60%. Mitomycin C and hydroxyurea, which both inhibit the incorporation of [3H]thymidine into CH12.LX cells, also both induce antibody secretion. In both cases, the concentration necessary to cause differentiation is substantially lower than that needed to cause detectable inhibition of thymidine uptake. We conclude that the IL 2 receptor on CH12.LX cells is a functional signal transducing molecule, and we discuss the possible inverse relationship between proliferation and differentiation.     

Differential glycosylation of two glycoproteins synthesized by murine B cells in response to IL-4 plus IL-5

We sought to determine whether selected cytokines, known to stimulate profoundly B-cell activation and differentiation, also have as yet unrecognized effects upon the glycosylation of secreted Ig and/or membrane-associated proteins. The glycosylation of both secreted IgM and membrane-bound MHC Class-I synthesized by CH12LX cells was detected by enzyme-lectin conjugates in immunoabsorption assays. Stimulation of B cells with IL-4 plus IL-5 significantly decreases the terminal glycosylation of secreted IgM, whereas LPS has a minor effect, despite the fact that both stimuli are equipotent for IgM secretion. Neither LPS nor IL-4 plus IL-5 affect MHC Class-I expression. However, IL-4 plus IL-5 substantially increases the terminal glycosylation of MHC Class-I produced from both mIgM(+)and mIgA(+)CH12LX cells. LPS has no or a modest effect on the terminal glycosylation of MHC Class-I produced from CH12LX cells. These results suggest that Th(2)-derived cytokines differentially influence the glycosylation of secreted and membrane-associated glycoproteins of B cells. In turn, this might elucidate the basis of aberrant glycosylation reported in conditions such as IgA nephropathy, cancer and rheumatoid arthritis.     

Cytotoxic and immunotoxic effects of Fusarium mycotoxins using a rapid colorimetric bioassay

A colorimetric MTT (tetrazolium salt) cleavage test was used to evaluate cytotoxicity of twenty-three Fusarium mycotoxins on two cultured human cell lines (K-562 and MIN-GL1) as well as their inhibitory effect on proliferation of phytohemagglutinin-stimulated human peripheral blood lymphocytes. The values of 50% inhibition of lymphocyte blastogenesis were very close to the 50% cytotoxic doses observed with the more sensitive cell line (MIN-GL1). T-2 toxin was the most cytotoxic with CD₅₀ and ID₅₀ values less than 1 ng/ml. Type A trichothecenes were the most cytotoxic followed by the type B trichothecenes; the non-trichothecenes were the least cytotoxic. The MTT cleavage test, in conjunction with cell culture, is a simple and rapid bioassay to evaluate cytotoxicity and immunotoxicity of Fusarium mycotoxins.Abbreviations Ac acetyl - ACU acuminatin - DAS diacetoxyscirpenol - DON deoxynivalenol - FUS fusarenon-X - HT-2 HT-2 toxin - MC mononuclear cell - MTT 3-(4,5-dimethylthiazol-2-yl)2,5-diphenyltetrazolium bromide - NEO neosolaniol - NIV nivalenol - NT-1 4,8-diacetoxy T-2 tetraol - PBS phosphate buffered saline - TAT-2T tetraacetoxy T-2 tetraol - T-2 T-2 toxin     

Modulation of IgM secretion and H chain mRNA expression in CH12.LX.C4.5F5 B cells by adrenocorticotropic hormone

The murine B cell line CH12.LX.C4.5F5 (CH12 (5F5) expresses adrenocorticotropin (ACTH) receptors, which can modulate IgM secretion by these cells. Interestingly, the response to ACTH was concentration dependent, inducing IgM secretion at subnanomolar amounts and suppressing secretion at micromolar amounts. With the use of an enzyme-linking immunospot assay it was possible to demonstrate that the ACTH-induced increase in IgM secretion by CH12 (5F5) cells was caused at least in part by an increase in the number of cells secreting IgM. CH12 (5F5) cells activated with suboptimal concentrations of LPS demonstrated a similar biphasic response. ACTH at concentrations of 10(-13) to 10(-9) M augmented IgM secretion in LPS-activated cells as much as sixfold, whereas 10(-6) M ACTH slightly decreased LPS-induced IgM secretion. At the mRNA level, subnanomolar concentrations of ACTH increased microH chain mRNA expression up to twofold in unstimulated or LPS-stimulated CH12 (5F5) cells. Taken together, these studies show that physiologically relevant concentrations of ACTH can interact directly with receptors on these B lymphocytes to enhance IgM secretion and microH chain mRNA expression. Although ACTH does increase intracellular cAMP levels in CH12 (5F5) B cells, it is unlikely that the induction of this second messenger pathway is by itself responsible for the ACTH induced B cell differentiation. The concentration of ACTH necessary to stimulate significant intracellular cAMP increases was 10- to 100-fold higher than that required to increase IgM secretion. Furthermore, CH12 (5F5) cells treated with varying concentrations of 8-bromo cAMP or cholera toxin were inhibited in their ability to secrete IgM. These results strongly suggest that the enhancing effects of ACTH on CH12 (5F5) IgM secretion are via mechanisms independent of those mediated by cAMP.     

Human low molecular weight B cell growth factor induces surface IgM+/A- B cells to express and secrete IgA.

The regulation of Ig class expression has been a controversial area of research. It is well established that T cells, and/or their products, influence which Ig isotype is produced during an immune response. In this study the regulation of Ig secretion of activated human IgM+/A- B cells was examined. Human T cell supernatants induced PWM-activated IgM+/A- B cells to switch to IgA secretion. Purification of the lymphokine mediating this effect involved hydroxylapatite, ion exchange, and gel filtration chromatography. The purified lymphokine could induce switch of IgM+/A- B cells, and it was also capable of inducing proliferation of Staphylococcus aureus Cowan 1 strain (SAC)-activated IgM+/A- B cells. SDS-PAGE and isoelectric focusing indicated the protein mediating this activity had a molecular mass of approximately 14 kDa and a pI of 6.8. These results suggested that the observed activity might be due to low m.w. B cell growth factor (LMW-BCGF), a lymphokine which is capable of inducing proliferation of SAC-activated B cells and has a molecular weight and pI value in the range of the purified protein. Indeed, rLMW-BCGF was able to switch IgM+/A- B-cells to IgA expression and secretion as well as induce the proliferation of SAC-activated IgM+/A- B cells. These results demonstrate that LMW-BCGF is capable of inducing PWM-activated IgM+/A- B-cells to switch to IgA possibly by providing a proliferation signal which induces clonal expansion of IgM+/A- B cells, the progeny of which express a range of isotypes including IgA. This study also demonstrates that lymphokine induced isotype switching involves an intermediate stage of B cell development where human B cells coexpress IgM and a downstream isotype on their surface.     

Stimulation of immunoglobulin biosynthesis in human B cells by wheat germ agglutinin. I. Evidence that WGA can produce both a positive and negative signal for activation of human lymphocytes

Wheat germ agglutinin (WGA), previously regarded strictly as a nonmitogenic or anti-mitogenic lectin, can under appropriate conditions markedly stimulate in vitro synthesis and secretion of immunoglobulin (Ig) by human B lymphocytes. Stimulation of Ig production by WGA is 1) confined to a narrow lectin dose range (2 to 10 micrograms/ml; 2) abrogated by the simple sugar N-acetyl-D-glucosamine but not by a variety of other monosaccharides; 3) effective only after early additions of WGA within the initial 72 hr of 12-day cultures; 4) detected in the presence of B and T cells but not B cells alone; and 5) polyisotypic in nature, as indicated by augmented synthetic rates of Ig in each of 3 major classes (IgG, IgA, and IgM). With few exceptions, WGA produces equivalent or greater rates of Ig production as obtained in cultures activated with pokeweed mitogen (PWM), a well-recognized T-dependent polyclonal activator of human B cells. Furthermore, periperal blood lymphocytes from select individuals that respond weakly to PWM are markedly stimulated with WGA. In contrast to these stimulatory effects of WGA on Ig production by lymphocytes exposed to low lectin concentrations, addition of WGA in amounts greater than 15 micrograms/ml to PWM-stimulated human lymphocyte cultures produces marked suppression of the expected level of Ig synthesis. These data indicate that varying doses of WGA can produce contrasting stimulatory and inhibitory effects on human B cell metabolism.     

Synthetic Fc peptide-mediated regulation of the immune response. II. Analysis of secreted immunoglobulin classes, accessory cell contribution, and lymphocyte proliferation in p23-stimulated spleen cell cultures

The synthetic peptide p23 representing residues 335 to 357 in the CH3 domain of human IgG1 was able to increase levels of secreted Ig in murine spleen cell cultures. This in vitro response was optimal in the presence of between 10(-4) and 10(-3) micron p23/ml and the levels of secreted Ig reached a maximum on day 4 or day 5 of culture. Supernatants from p23-treated cell cultures generally contained more IgM than IgG and undetectable levels of IgA. Induction of Ig secretion by p23 was macrophage-independent but T cell-dependent and, with respect to the latter case, removal of T cells from spleen cells reduced the levels of both IgM and IgG. Although maintaining the B cell differentiation-inducing quality of its progenitor molecule, the Fc gamma fragment, p23 appeared to have lost the ability to induce B cell proliferation. Evidence is presented that a sequence functionally similar to p23 is extant in mouse IgG by showing that murine Fc gamma fragments were also able to induce increases in Ig-secreting cells in murine spleen cell cultures.     

In vitro stimulation of human lymphocytes by alpha, beta and delta toxins and toxoids of Staphylococcus aureus.

Alpha, beta and delta toxins of Staphylococcus aureus stimulate human peripheral blood lymphocytes to blastic transformation and formation of IgM, IgG and IgA. The toxins are efficient at concentrations that are not toxic for the cells in culture. A dose of a toxin suitable for stimulation is 100 ng/ml but a stimulation can be observed also at 10 ng/ml, in the case of Ig formation even at a concentration of 1 ng/ml. Toxoids are approximately as effective to elicit blastic transformation as the toxins themselves, their efficiency to stimulate Ig formation being somewhat lower but significant. Alpha and delta toxins and toxoids at the appropriate concentration appear to act as medium-strength polyclonal activators of lymphocytes. Beta toxin and its toxoid are weak polyclonal activators.     

Effects of aplysiatoxin and debromoaplysiatoxin on growth and differentiation of normal human bronchial epithelial cells

The effects of aplysiatoxin and debromoaplysiatoxin on the clonal growth rate, cross-linked envelope formation and plasminogen activator secretion of normal human bronchial epithelial cells were studied. Neither compound was mitogenic over a wide range of concentrations (10^–13 to 10^–7M). Both aplysiatoxin and debromoaplysiatoxin inhibited clonal growth rate with 50% inhibitory concentrations of 3 × 10^–11M and 10^–10M, respectively. Both compounds induced the formation of cross-linked envelopes and increased plasminogen activator secretion with equal potency. These data are similar to those previously obtained with 12-0-tetradecanoylphorbol-13-acetate and teleocidin B and suggest that aplysiatoxin and debromoaplysiatoxin induce terminal squamous differentiation in normal human bronchial epithelial cells.Abbreviations TPA 12-0-tetradecanoylphorbol-13-acetate - NHBE Normal Human bronchial epithelial - ID₅₀ 50% inhibitory concentration (dose) - PA Plasminogen activator - CLE Cross-linked envelope - LHC Laboratory of Human Carcinogenesis     

B cell response to T helper cell subsets. II. Both the stage of T cell differentiation and the cytokines secreted determine the extent and nature of helper activity.

Helper activity of several murine CD4+ T cell subsets was examined. Effector Th, derived from naive cells after 4 days of in vitro stimulation with alloantigen, when generated in the presence of IL-4, secreted high levels of IL-4, IL-5, and IL-6, and low levels of IL-2 and IFN-gamma, and induced the secretion of all Ig isotypes particularly IgM, IgG1, IgA, and IgE from resting allogeneic B cells. Effectors generated with IL-6 secreted IL-2, IL-4, IL-5, IL-6, and IFN-gamma, and induced similar levels of total Ig, 25 to 35 micrograms/ml, but with IgM, IgG3, IgG1, and IgG2a isotypes predominating. Helper activity of these Th was significantly greater than that of effectors generated with IL-2 (10-15 micrograms/ml Ig) and of 24-h-activated naive and memory cells (2-4 micrograms/ml), both of which induced mainly IgM. Unlike other isotypes, IgE was induced only by effector Th generated with IL-4. Blocking studies showed that secretion of all isotypes in response to IL-6-primed effectors was dependent on IL-2, IL-5, and IL-6. IL-4 was required for optimal IgM, IgG1, and IgA secretion, but limited secretion of IgG2a, whereas IFN-gamma was required for optimal IgG2a secretion, and limited IgM, IgG1, and IgA. In contrast, secretion of all isotypes in response to IL-4-primed effectors was dependent on IL-5, although IL-4 and IFN-gamma were also essential for IgE and IgG2a, respectively. Addition of exogenous IL-5 to B cell cultures driven by IL-6-primed effectors did not obviate the requirement for IL-2, IL-4, and IL-6, suggesting that interaction of IL-4-primed effectors with B cells was qualitatively different from that of IL-6-primed effectors, driving B cells to a stage requiring only IL-5 for differentiation. Addition of exogenous factors to IL-2-primed effector Th, particularly IL-4 in the presence of anti-IFN-gamma, resulted in levels of Ig, including IgE, comparable to those induced with other effectors. These results show that functionally distinct Th cell subsets can be generated rapidly in vitro, under the influence of distinct cytokines, which vary dramatically in their levels of help for resting B cells. The cytokines involved in responses to distinct Th cells differ depending on the quality of interaction with the B cell, and the extent of help is strongly determined by the quantity and nature of cytokines secreted by the T cells.     

Polyclonal immunoglobulin response of thymic,hepatic and splenic lymphocytes from fetal,germ-free and conventionally reared pigs to different B-cell activators

Immunoglobulin (Ig) response to different polyclonal B-cell activators was measured by ELISA in cell culture media of thymocytes, splenocytes and liver cells isolated from pig fetuses, 8-d-old germ-free piglets and conventionally reared pigs. Both in fetal and in postnatal life polyclonally stimulated lymphocytes were found to produce predominantly the IgM isotype; the first IgM formation was detected in 50-d-old fetal liver (gestation in pigs lasts 114 d). Surprisingly, 73-d-old fetal thymic cells were shown to be induced to Ig synthesis and secretion. In contrast to splenocytes of the same age, which secreted exclusively IgM, fetal thymocytes produced IgM, IgG and IgA. Polyclonally stimulated splenic cells as compared with thymic cells started to produce IgA later in fetal ontogeny, whereas the IgG response was not detectable in splenic cell culture media during the whole embryonal development and appeared only after birth. The earliest and the highest Ig stimulation was found after cultivation of lymphocytes withNocardia delipidated cell mitogen. Interestingly, the moderate stimulatory effect of 65-kDa heat shock protein (Hsp-65) in polyclonal IgM response of fetal splenocytes was observed. We showed that thymic B lymphocytes represent probably the first maturing B cell population detectable in fetal life, which is able to differentiate after polyclonal stimulation into IgM as well as IgA and IgG producing cells. Dedicated to Professor J. Šterzl on the occasion of his 70th birthday     

IL-4-dependent IgE switch in membrane IgA-positive human B cells

IgE responses by human B cells, separated according to membrane Ig classes, were analyzed in a clonal assay using EL-4 thymoma cells as helper cells, T cell supernatant, and rIL-4. In cultures seeded by means of the autoclone apparatus of the FACS, IgE responses were generated frequently by either IgM (mu+/gamma-alpha-) or IgA (alpha +/mu-)-positive B cells (16 and 14% of the Ig producing wells, respectively), but rarely by IgG (gamma +/mu-)-positive B cells (1.3% of Ig producing wells). The total amounts of Ig secreted by IgM-, IgG-, or IgA-positive cells and the total proportions of responding autoclone wells (23-27%) were comparable. All IgE secretion was IL-4 dependent. When the Ig secretion patterns from alpha +/mu- vs alpha +/mu-epsilon- B cells were compared, most autoclone wells from both types of cells produced IgA only, and similar proportions of IgA producing wells (6.2 and 6.0%) also secreted IgE. In addition, IgE restricted responses occurred 6 times more frequently with alpha +/mu- than with alpha +/mu-epsilon- cells, which suggests that membrane IgA+E double-positive, IgE committed B cells occur in vivo. The isotype pattern generated by alpha +/mu-epsilon- B cells cannot be explained by a chance assortment of separate IgA and IgE precursors or by cytophilic antibody. Thus, IL-4 dependent switch to IgE occurred frequently in IgM- or IgA-positive, but rarely among total IgG-positive, B cells. This could be relevant to IgE production in mucosal tissues rich in IgA expressing B cells.     

Stimulation of Immunoglobulin Production from Human B Lymphocytes by Staphylococcus aureus: Effects of Monocytes and Con A-Induced Suppressor Cells

Significant immunoglobulin (Ig) production by human peripheral blood lymphocytes was induced in vitro by stimulating the cells with pokeweed mitogen (PWM) and Staphylococcus aureus Cowan I (SpA CoI). IgG, IgM, and IgA were determined by a combination of the latex fixation test and radioimmunoassay. High levels (1,000 to 5,000 μg/ml) of IgG and IgM and a lesser amount of IgA were constantly produced during 7 to 8 days of incubation with both stimulants. Ig production induced by SpA Col stimulation was independent of the presence of T cells, while Ig production induced by PWM required T cells exclusively. Depletion of monocytes in the culture caused but a slight decrease in Ig production (particularly in the case of IgG). While the addition of a small number of monocytes enhanced IgG induction by both stimulants, coculture with an excess number of monocytes inhibited Ig induction (particularly IgG) by PWM stimulation but not by SpA CoI stimulation. Marked suppression of Ig production (IgG, IgM, and IgA) was observed in cocultures with Con A-activated T cells. The phenomena of suppression were observed in both the SpA Col-stimulated and PWM-stimulated lymphocytes. These data indicate that Ig production from B cells stimulated with a polyclonal B cell activator, SpA CoI, was independent of T cells and relatively of independent of monocytes, but could be subjected to the regulation of the Con A-induced suppressor T cells.     

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.