The role of TGF-β in growth, differentiation, and maturation of B lymphocytes

Transforming growth factor-β (TGF-β) affects B cells at all stages in development. It appears to be involved in lymphopoiesis and is required for the development of plasma cells secreting all secondary isotypes. Its ability to inhibit proliferation and stimulate apoptosis suggest that it may be involved both in germinal center development and regulation of B-cell proliferation at sites of high antigen load such as the gastrointestinal tract. Although TGF-β appears to be required for the generation of B cells secreting secondary isotypes, it inhibits secretion of IgM and IgA from cells expressing those isotypes. In this regard, TGF-β may alter the level of RNA processing factors either directly or indirectly by inhibiting progression through the cell cycle. One of the best characterized effects of TGF-β is its ability to stimulate isotype switching to IgA in both mouse and man. There is some controversy concerning its mechanism of action in this process, but its critical role is without question. The controversy may stem in part from an inability to separate the effects of endogenous and exogenous TGF-β in the multiple models of isotype switching. The influence of endogenous TGF-β is perhaps best exemplified by analysis of production of the different classes of IgG in mouse strains producing different levels of TGF-β.     

Macrophage-derived TGF-beta1 induces IgA isotype expression

TGF-beta1 is a potent IgA isotype switching factor. However the cell population that generates the TGF-beta is not known. In this study, we examined the origin of the TGF-beta1 that is secreted by LPS-activated murine total spleen cell cultures and that is responsible for IgA isotype switching. Treatment with anti-TGFbeta1 antibody decreased IgA secretion 2 fold in these cultures and caused a 5-fold decrease in the number of IgA secreting cells. In Mphi-depleted spleen cell populations, this IgA response was markedly reduced and anti-TGFbeta1 antibody had no additional effect on IgA production. The inference that Mphi-derived TGF-beta1 is responsible for the isotype switching is supported by observations with the macrophage line, P388D1. LPS, particularly in the presence of IFN-gamma, induced P388D1 cells to secrete active TGF-beta1. The supernatant from such an activated P388D1 culture, in combination of IL-2, stimulated IgA secretion and this effect was abolished by anti-TGFbeta1 antibody.     

IL-21-induced isotype switching to IgG and IgA by human naive B cells is differentially regulated by IL-4

Naive B cells can alter the effector function of their Ig molecule by isotype switching, thereby allowing them to secrete not only IgM, but also the switched isotypes IgG, IgA, and IgE. Different isotypes are elicited in response to specific pathogens. Similarly, dysregulated production of switched isotypes underlies the development of various diseases, such as autoimmunity and immunodeficiency. Thus, it is important to characterize mediators controlling isotype switching, as well as their contribution to the overall B cell response. Isotype switching in human naive B cells can be induced by CD40L together with IL-4, IL-10, IL-13, and/or TGF-beta. Recently, IL-21 was identified as a switch factor for IgG1 and IgG3. However, the effect of IL-21 on switching to IgA, as well as the interplay between IL-21 and other switch factors, remains unknown. We found that IL-4 and IL-21 individually induced CD40L-stimulated human naive B cells to undergo switching to IgG, with IL-4 predominantly inducing IgG1(+) cells and IL-21 inducing IgG3. Culture of naive B cells with CD40L and IL-21, but not IL-4, also yielded IgA(+) cells. Combining IL-4 and IL-21 had divergent effects on isotype switching. Specifically, while IL-4 and IL-21 synergistically increased the generation of IgG1(+) cells from CD40L-stimulated B cells, IL-4 concomitantly abolished IL-21-induced switching to IgA. Our findings demonstrate the dynamic interplay between IL-4 and IL-21 in regulating the production of IgG subclasses and IgA, and suggest temporal roles for these cytokines in humoral immune responses to specific pathogens.     

Ig isotype switching in B lymphocytes. Isolation and characterization of clonal variants of the murine Ly-1+ B cell lymphoma, CH12, expressing isotypes other than IgM

We have selected and cloned variant cells from the murine B cell lymphoma, CH12, that produce a variety of other Ig isotypes in addition to or in place of the original IgM and IgD. Variants were selected by flow cytometry and automated cloning and isotype production was analyzed by membrane immunofluorescence and ELISA of culture fluids. Variants have been isolated that produce the single isotypes IgA, IgG2b, and IgG3, as well as variants that produce more than one isotype simultaneously, i.e., IgM, IgD, and IgA; IgG2b and IgA; IgG3 and IgA. All isotypes have been seen as cell surface proteins and all except IgD have been found in culture supernatants. All isotypes display the same idiotype and Ag-binding specificity for phosphatidyl choline as the original IgM and all are translated from the same VDJH and VJ kappa gene assemblies. Production of more than one isotype by a variant clone is due to simultaneous production of all the isotypes by each cell within the clone. The finding that the variants producing more than one isotype are all tetraploid suggests the interesting possibility that each isotype is derived from an independently switching chromosome. All isotype variants can be stimulated by LPS to secrete the appropriate Ig isotype at an increased rate similar to the IgM expressing parent. The variants differ in stability; some have remained stable for more than 9 months in culture, whereas other have undergone further isotype switching. The facts that some isotypes have not been seen, that multistep switching has occurred, and that many variants produce IgA in addition to another isotype are discussed in relation to current notions of isotype switching mechanisms.     

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.     

Effect of transforming growth factor (TGF)-beta 1 on IgA isotype expression. TGF-beta 1 induces a small increase in sIgA+ B cells regardless of the method of B cell activation.

Transforming growth factor-beta (TGF-beta) has been reported to play an important role in IgA isotype expression when B cells are stimulated with LPS. The goal of the present study was to determine whether TGF-beta has similar effects on IgA isotype expression under more physiologic conditions utilizing a variety of B cell activation systems. As previously reported, in the LPS system TGF-beta caused a small, but significant, absolute increase in surface IgA (sIgA) expression and a very definite increase in IgA secretion; these effects were enhanced by IL-2 and IL-5. In the case of B cell stimulation with another B cell stimulant, the thymus-independent type II mitogen, anti-IgD-dextran, TGF-beta led to a similar small increase in sIgA expression, but caused suppression of IgA secretion. Using the Th2 cell clones CDC35 and D10 to stimulate resting B cells in a cognate and non-cognate T cell-dependent fashion, respectively, TGF-beta again increased sIgA expression to a similar small extent. TGF-beta at low doses (0.1 ng/ml) did not increase IgA secretion significantly and, at higher doses (1.0 ng/ml) caused significant suppression of IgA secretion. Addition of various cytokines (IL-2, -4, -5, D10sup) other than TGF-beta to stimulated B cells did not increase sIgA expression, but did give rise to increased amounts of IgA secretion, especially when activated D10 T cells were used as the B cell stimulant. Finally, the addition of an antibody against TGF-beta to cultures containing TGF-beta on day 2 led to partial or complete reversal of the inhibitory effects of TGF-beta on IgA secretion. In conclusion, TGF-beta causes a consistent, but small increase in sIgA+ B cells, in cultures of B cells stimulated by a variety of T cell-dependent or independent stimuli. In contrast, TGF-beta either promotes or inhibits B cell survival and IgA secretion, depending on the method of B cell activation. These results are most consistent with the view that TGF-beta provides only a partial or incomplete IgA switch signal but that additional factors are involved in IgA isotype switching and differentiation.     

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.     

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.     

The regulation of IgA class switching

IgA class switching is the process whereby B cells acquire the expression of IgA, the most abundant antibody isotype in mucosal secretions. IgA class switching occurs via both T-cell-dependent and T-cell-independent pathways, and the antibody targets both pathogenic and commensal microorganisms. This Review describes recent advances indicating that innate immune recognition of microbial signatures at the epithelial-cell barrier is central to the selective induction of mucosal IgA class switching. In addition, the mechanisms of IgA class switching at follicular and extrafollicular sites within the mucosal environment are summarized. A better understanding of these mechanisms may help in the development of more effective mucosal vaccines.     

Accumulation of secreted antibodies in plant cell cultures varies according to the isotype,host species and culture conditions

Nicotiana tabacum suspension cells have been widely used to produce monoclonal antibodies, but the yield of secreted antibodies is usually low probably because of proteolytic degradation. Most IgGs that have been expressed in suspension cells have been of the human IgG1 isotype. In this study, we examined whether other isotypes displayed the same sensitivity to proteolytic degradation and whether the choice of plant host species mattered. Human serum IgG displayed different degradation profiles when incubated in spent culture medium from N. tabacum, Nicotiana benthamiana or Arabidopsis thaliana suspension cells. Zymography showed that the protease profile was host species dependent. Three human isotypes, IgG1, IgG2 and IgG4, and a mouse IgG2a were provided with the same heavy‐ and light‐chain variable regions from an anti‐human IgM antibody and expressed in N. tabacum cv. BY‐2 and A. thaliana cv. Col‐0 cells. Although all tested isotypes were detected in the extracellular medium using SDS‐PAGE and a functional ELISA, up to 10‐fold differences in the level of intact antibody were found according to the isotype expressed, to the host species and to the culture conditions. In the best combination (BY‐2 cells secreting human IgG1), we reported accumulation of more than 30 mg/L of intact antibody in culture medium. The possibility of using IgG constant regions as a scaffold to allow stable accumulation of antibodies with different variable regions was demonstrated for human IgG2 and mouse IgG2a.     

Sequential expression of immunoglobulin on developing mouse B lymphocytes: a systematic survey that suggests a model for the generation of immunoglobulin isotype diversity.

Paired immunofluorescent staining with antibodies specific for the major isotypes of mouse immunoglobulin was used to study the ontogenetic expression of diversity of cell surface immunoglobulin. The first B lymphocytes to emerge, derived from cytoplasmic IgM+ precursors, express sIgM exclusively. Between birth and 3 days of age separate populations of sIgM+ B lymphocyte acquire a second isotype: sIgD, one of the subclasses of sIgG, or sIgA. At 3 days, all splenic B lymphocytes that bear sIg or sIgA also express sIgM, but virtually none stain for sIgD. By 7 days, a substantial porportion of sIgG+ or sIgA+ lymphocytes in spleen and most of those in lymph node express both sIgM ans sIgD. Anti-mu antibody treatment from birth prevented development of B lymphocytes expressing any isotype. These observations suggest that the immature sIgM+ B lymphocyte is the pivotal cell in the generation of the different sublines of B cells and that sIgD ig or IgA. The frequency of lymphocytes bearing only sIgG or sIgA is higher in old than in young mice, suggesting that sIgD and sIgM may be lost after stimulation by antigens. The occurrence of a nearly identical distribution of sIg isotypes on B lymphocytes from athymic, pathogen-free mice suggests that primary expression of isotype diversity does not require T cells.     

Gene conversion-like sequence transfers between transgenic antibody V genes are independent of RAD54

Homology-based Ig gene conversion is a major mechanism for Ab diversification in chickens and the Rad54 DNA repair protein plays an important role in this process. In mice, although gene conversion appears to be rare among endogenous Ig genes, Ab H chain transgenes undergo isotype switching and gene conversion-like sequence transfer processes that also appear to involve homologous recombination or gene conversion. Furthermore, homology-based DNA repair has been suggested to be important for somatic mutation of endogenous mouse Ig genes. To assess the role of Rad54 in these mouse B cell processes, we have analyzed H chain transgene isotype switching, sequence transfer, and somatic hypermutation in mice that lack RAD54. We find that Rad54 is not required for either transgene switching or transgene hypermutation. Furthermore, even transgene sequence transfers that are known to require homology-based recombinations are Rad54 independent. These results indicate that mouse B cells must use factors for promoting homologous recombination that are distinct from the Rad54 proteins important in homology-based chicken Ab gene recombinations. Our findings also suggest that mouse H chain transgene sequence transfers might be more closely related to an error-prone homology-based somatic hypermutational mechanism than to the hyperconversion mechanism that operates in chicken B cells.     

Development and distribution of B lineage cells in the domestic cat: analysis with monoclonal antibodies to cat mu-, gamma-, kappa-, and lambda-chains and heterologous anti-alpha antibodies

To trace the development and distribution of B lineage cells in the domestic cat (Felis catus), we have produced monoclonal antibodies against mu-, gamma-, kappa-, and lambda-chains of feline immunoglobulins (Ig). Goat antibodies against human mu-, alpha-, and lambda-chains, which are reactive with shared determinants on their feline counterparts, were used in conjunction with the panel of mouse monoclonal antibodies. Cytoplasmic mu+ pre-B cells and surface IgM+ B lymphocytes were observed in 42 day fetal liver in which pre-B cells were more abundant than IgM+ B cells. Pre-B cells also were found in bone marrow in young cats, and continued to be generated in the marrow throughout life. In the spleen, adult levels of B cells were attained by 12 wk of age, at which time the frequencies of surface IgM+, IgG+, and lambda+ cells were 49, 3, and 40%, respectively. The distributions of Ig isotypes also were determined among plasma cells as a function of age and tissue localization. IgM plasma cells were predominant in the bone marrow of 1-wk-old cats, whereas IgG plasma cells were the prevalent isotype in adult bone marrow. In the mesenteric lymph nodes of adult animals, the frequency distributions of IgM, IgG, and IgA plasma cells were similar to the frequency distributions of IgM, IgG, and IgA isotypes among bone marrow plasma cells. IgA+ plasma cells predominated in the intestinal lamina propria, in which IgG+ and IgM+ plasma cells were relatively infrequent. In the tissues of both young and adult animals, the ratio of lambda:kappa expression was approximately 3:1. We conclude that the pattern of B cell development in the cat resembles that found in other mammals, except that the kappa to lambda ratio is reversed.     

Specific induction of secreted proteins by transforming growth factor-beta and 12-O-tetradecanoylphorbol-13-acetate. Relationship with an inhibitor of plasminogen activator

To examine the mechanisms by which transforming growth factors (TGFs) regulate the proliferation of eukaryotic cells, five cell lines, from different species and tissues, were treated with three agents that inhibit DNA synthesis and proliferation: BSC-1 cell-derived growth inhibitor (GI/TGF-beta), platelet-derived transforming growth factor-beta (TGF-beta), and 12-O-tetradecanoylphorbol-13-acetate. The cell lines tested were mink lung CCL 64 epithelial cells, Maloney sarcoma virus-transformed CCL 64.1, monkey kidney BSC-1 epithelial cells, human epidermoid A431 cells, and mouse embryo AKR-2B (clone 84A) cells. All cell lines responded to one or more of these agents by synthesizing and secreting a 48 to 51-kDa protein (IIP48). The TGF-beta s and 12-O-tetradecanoylphorbol-13-acetate had little or no effect on the incorporation of [35S] methionine into other secreted proteins or on the pattern of [35S]methionine-labeled intracellular proteins analyzed by one-dimensional, sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The maximum increase in induction of IIP48 varied from 2-fold to greater than 800-fold compared with the controls and occurred within 6 h of adding GI/TGF-beta to CCL 64 cells. Actinomycin D, alpha-amanitin, or 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole selectively decreased both the control and induced levels of IIP48 even after as little as 6 h of incubation. Thus, it appears that IIP48 mRNA turns over rapidly. Induction of IIP48 was dissociated from the inhibition of DNA synthesis by GI/TGF-beta. However, we found that epidermal growth factor and GI/TGF-beta act synergistically to increase the secreted level of IIP48. Others have shown that epidermal growth factor and TGF-beta act synergistically to stimulate growth of cells in agar. IIP48 from CCL 64, BSC-1, and AKR-2B cells is specifically immunoprecipitated by antibody to bovine plasminogen activator inhibitor. We found previously that TGF-beta also inhibits the production of major excreted protein, a thiol protease. It is proposed that TGF-beta is able to promote anchorage-independent growth of untransformed cells because of its ability to inhibit the production of secreted proteases and to increase the production of protease inhibitors.