Transcription of Ig Germline Genes in Single Human B Cells and the Role of Cytokines in Isotype Determination

We have developed a critical test of the chromatin accessibility model of Ig isotype determination in which local unfolding of chromatin higher order structure (chromatin accessibility) in the region of specific germline genes in the H chain locus determines the Ab class to be expressed in the B cell. We show that multiple germline genes are constitutively transcribed in the majority of naive human B cells in a population. Thus, because chromatin in its higher order structure cannot be transcribed, the entire Ig H chain locus must be unfolded in naive B cells. We have also established that IL-4 and anti-CD40 act by enhancing transcription in the majority of cells, rather than by activating transcription in more of the cells. Transcriptional activity in the human H chain locus rules out the perturbation of chromatin higher order structure as a factor in isotype determination. We have also found that the levels of germline gene transcription cannot fully account for the levels of secretion of the different Ig isotypes, and that secretion of IgE, in particular, is suppressed relative to that of IgG.

S epsilon S mu and S epsilon S gamma switch circles in human nasal mucosa following ex vivo allergen challenge: evidence for direct as well as sequential class switch recombination

B cells switch to IgE under the influence of IL-4, IL-13, and CD40 costimulation through a multistep process involving epsilon germline transcription and class switch recombination. Classically, switching has been considered an event restricted to lymphoid tissues; however, epsilon germline transcripts (I(initiator)epsilon RNA) have been observed within lung, sinus, and nasal tissue of individuals with asthma, sinusitis, and rhinitis. Furthermore, nasal mucosal tissue from allergic rhinitics produces epsilon germline transcripts following ex vivo allergen challenge. Collectively, these studies raised the possibility that switching to IgE may occur locally, at sites of allergic inflammation. Although epsilon germline transcripts are considered necessary to target the IgE locus, it is class switch recombination that ultimately leads to de novo IgE production. In this study, we demonstrate that S epsilon S mu DNA switch circles (products of class switch recombination) as well as I epsilon and C epsilon RNA are produced within nasal tissue from allergic individuals following ex vivo allergen challenge. epsilon germline transcription was inhibited when tissue was cultured with a combination of allergen and neutralizing Abs against IL-4 and IL-13, indicating that de novo cytokine production mediated the isotype switch. We also show allergen-induced appearance of S epsilon S gamma DNA switch circles and up-regulation of C gamma 4 mRNA, illustrating that sequential switching to IgE also occurred. This work strongly suggests that B cells residing within the nasal mucosa undergo switching to IgE in the context of a local immune response to allergen.

EBV-encoded latent membrane protein 1 cooperates with BAFF/BLyS and APRIL to induce T cell-independent Ig heavy chain class switching

By substituting the H chain C region of IgM with that of IgG, IgA, or IgE, class switching enables Abs to acquire new effector functions that are crucial for the neutralization of invading pathogens. Class switching occurs through class switch DNA recombination (CSR) and usually requires engagement of CD40 on B cells by CD40 ligand on Ag-activated CD4(+) T cells. CSR must be tightly regulated because abnormal IgG and IgA production favors the onset of autoimmunity, whereas increased switching to IgE leads to atopy. These inflammatory disorders can be triggered or exacerbated by EBV infection. In this study, we show that EBV induces CD40-independent CSR from C( micro ) to multiple downstream C(gamma), C(alpha), and C(epsilon) genes through latent membrane protein 1 (LMP1), a CD40-like viral protein that signals in a ligand-independent fashion. LMP1-induced CSR is associated with transcriptional activation of germline C(gamma), C(alpha), and C(epsilon) genes and triggers the up-regulation of activation-induced cytidine deaminase, a crucial component of the CSR machinery. In addition, LMP1 induces B cells to express B cell-activating factor of the TNF family and a proliferation-inducing ligand, two molecules that mediate B cell survival and T cell-independent Ab production. B cell-activating factor of the TNF family and a proliferation-inducing ligand cooperate with LMP1 to induce Ig class switching because their neutralization by appropriate soluble decoy receptors attenuates CSR in LMP1-expressing B cells. By showing that LMP1 triggers T cell-independent CSR, our findings suggest that EBV could play an important role in the pathogenesis of disorders with aberrant IgG, IgA, and/or IgE production.

Activation of the mouse Ig germline epsilon promoter by IL-4 is dependent on AP-1 transcription factors

Induction of germline (GL) epsilon transcripts, an essential step preceding Ig isotype switching to IgE, requires activation of transcription factors by IL-4 and a B cell activator, e.g., CD40 ligand or LPS. We demonstrate that AP-1 (Fos and Jun), induced transiently by CD40 ligand or LPS, binds a DNA element in the mouse GL epsilon promoter. AP-1 synergizes with Stat6 to activate both the intact GL epsilon promoter and a minimal heterologous promoter driven by the AP-1 and Stat6 sites of the mouse GL epsilon promoter. By contrast, C/EBP beta, which trans-activates the human GL epsilon promoter, inhibits IL-4 induction of the mouse promoter, probably by attenuating the synergistic interaction between AP-1 and Stat6. Furthermore, AP-1 does not trans-activate the human GL epsilon promoter. Thus, induction of GL epsilon transcripts in mice and humans may be regulated differently. In addition, although mouse GL epsilon transcripts have a half-life of approximately 100 min, the RNA level continues to increase for up to 24 h, and the promoter appears to be active for at least 2 days after B cell activation. Altogether, these data suggest that induction of AP-1 activity, although transient, is required for activation of the mouse GL epsilon promoter by IL-4-induced Stat6.

Inhibition of IgG1 and IgE production by stimulation of the B cell CTLA-4 receptor

Although a large amount of information is available on the activity of CTLA-4 in T cells, the role of this receptor in B cells has not been previously characterized. Our results show that CD40 or LPS stimulation in the presence of IL-4 induces CTLA-4 expression in purified B cells; the maximum level is reached in both membrane and intracellular compartments after 48-72 h. Engagement of the B cell CTLA-4 by immobilized mAb inhibits IgG1 and IgE production and reduces the frequency of IgG1- and IgE-expressing B cells. Cepsilon and Cgamma(1) germline mRNA expression as well as NF-kappaB and STAT6 activation, events required for isotype switching, are also inhibited by CTLA-4 engagement. Together these findings show the critical role of CTLA-4 in the control of IL-4-driven isotype switching and suggest new approaches for modulating immediate-type hypersensitivity responses.

Engagement of CD153 (CD30 ligand) by CD30+ T cells inhibits class switch DNA recombination and antibody production in human IgD+ IgM+ B cells

CD153 (CD30 ligand) is a member of the TNF ligand/cytokine family expressed on the surface of human B cells. Upon exposure to IL-4, a critical Ig class switch-inducing cytokine, Ag-activated T cells express CD30, the CD153 receptor. The observation that dysregulated IgG, IgA, and/or IgE production is often associated with up-regulation of T cell CD30 prompted us to test the hypothesis that engagement of B cell CD153 by T cell CD30 modulates Ig class switching. In this study, we show that IgD+ IgM+ B cells up-regulate CD153 in the presence of CD154 (CD40 ligand), IL-4, and B cell Ag receptor engagement. In these cells, CD153 engagement by an agonistic anti-CD153 mAb or T cell CD30 inhibits S mu-->Sgamma, Smu-->Salpha, and S mu-->Sepsilon class switch DNA recombination (CSR). This inhibition is associated with decreased TNFR-associated factor-2 binding to CD40, decreased NF-kappaB binding to the CD40-responsive element of the Cgamma3 promoter, decreased Igamma3-Cgamma3 germline gene transcription, and decreased expression of Ku70, Ku80, DNA protein kinase, switch-associated protein-70, and Msh2 CSR-associated transcripts. In addition, CD153 engagement inhibits IgG, IgA, and IgE production, and this effect is associated with reduced levels of B lymphocyte maturation protein-1 transcripts, and increased binding of B cell-specific activation protein to the Ig 3' enhancer. These findings suggest that CD30+ T cells modulate CSR as well as IgG, IgA, and IgE production by inducing reverse signaling through B cell CD153.

IL-4-dependent IgE class switching in an anti-trinitrophenyl B-cell hybridoma after engagement of antigen receptors

A B-cell hybridoma, TP67.21 that expresses surface anti-trinitrophenyl (TNP) IgM but does not secrete the antibody spontaneously has been reported to differentiate into anti-TNP IgM-secreting cells in response to lipopolysaccharide or engagement of surface IgM. Here, we report isolation and characterization of a subclone, TP67.21E (TP.E) that undergoes isotype switching to IgE in an interleukin (IL)-4-dependent manner. TP.E cells secreted anti-TNP IgE depending on exogenous IL-4 when they were cultured with an anti-IgM antibody for 6-8 days. 8-Mercaptoguanosine, which has been shown to enhance IgE class switching in murine splenic B-cells further augmented the IgE response in TP.E cells. Immunofluorescence microscopy revealed that approximately 1.2% of the cultured cells became positive for intracellular IgE after the stimulation culture. The germline epsilon transcripts were expressed transiently on days 2-4 of the culture, while expression of the productive epsilon transcripts was induced 5 days after the start of the culture, thus suggesting that IgE class switching occurred in TP.E cells under these conditions.

A highly sensitive and specific assay using a novel human growth hormone cDNA reporter gene regulated by the human interleukin-4 inducible germline epsilon transcript promoter

We have successfully developed a highly sensitive and specific assay system for human interleukin-4 (IL-4) regulated gene expression. It is based on a human Jijoye cell line with the germline epsilon transcript promoter joined to the human growth hormone (hGH) cDNA. The germline epsilon transcript promoter is responsive to IL-4 and involved in immunoglobulin heavy chain class switching. We cloned hGH complementary DNA (cDNA) as the reporter gene instead of using conventional hGH genomic DNA which failed to generate any IL-4 inducible clone in human Jijoye cells. The two IL-4 inducible cell lines with the hGH cDNA reporter show high signal/noise ratio for IL-4-mediated induction (60-90 fold). The response to IL-4 is dose-dependent with ED50 of 10 pM. As expected, there is no response to other human cytokines and growth factors, as well as mouse IL-4. The mutant hIL-4 antagonist hIL-4.Y124D inhibits the induction mediated by native hIL-4. These IL-4 inducible cell lines provide a sensitive, specific assay system to study IL-4-regulated gene expression, and in particular the regulation of the germline epsilon promoter.

Alpha-1 antitrypsin up-regulates human B cell differentiation selectively into IgE- and IgG4- secreting cells

Numerous allergens have proteolytic activities. It has been speculated that this property may contribute to their allergenicity. Therefore, we have evaluated the effect of different physiological protease inhibitors (PI) on the regulation of human IgE synthesis. Unexpectedly, the serine PI, alpha-1 antitrypsin, also called alpha-1 protease inhibitor (alpha1PI), induced a potent and selective dose-dependent increase of IgE and IgG4 production by human tonsillar B cells stimulated with the IgE and IgG4 switch factors, IL-4 and anti-CD40 mAb. The other serine PI tested were inefficient. Furthermore, this effect of alpha1PI was accompanied by an increase in (1) germ-line and mature sigma mRNA transcription, (2) proliferation and (3) membrane CD23 and CD21 expression, while the expression of other molecules involved in the regulation of IgE synthesis was unchanged. Since CD23-CD21 pairing plays a crucial role in the up-regulation of IgE synthesis, we have tested whether blocking this interaction affected alpha1PI-increased IgE production. The neutralizing anti-CD23 mAb, Mab 25, partly reversed the IgE increase caused by alpha1PI. Moreover, alpha1PI potentiation of IgE synthesis was prevented by elastase, a natural substrate of alpha1PI, thereby suggesting that alpha1PI may inhibit endogenous B cell enzyme(s) involved in the down-regulation of IgE synthesis. Alpha1PI also potentiated IgE and IgG4 production by IL-4-stimulated peripheral blood mononuclear cells but was not a switch factor for IgE and IgG4 as it was unable to replace IL-4 or anti-CD40 mAb in inducing IgE and IgG4 production. In conclusion, this study shows that alpha1PI acts as a potent co-stimulus for IgE and IgG4 synthesis and suggests that the equilibrium between protease/ protease inhibitor participates in the control of human IgE and IgG4 synthesis.

Expression of epsilon germ-line gene transcripts and mRNA for the epsilon heavy chain of IgE in nasal B cells and the effects of topical corticosteroid

We have studied the expression of the gene encoding the epsilon heavy chain of IgE in nasal B cells of hayfever patients. We developed probes to detect transcripts of the epsilon germ-line gene and the rearranged gene by in situ hybridization of biopsy sections from the nasal mucosa. We compared tissue from hayfever patients out of season with that of normal controls, and also of hayfever patients treated with topical corticosteroid (fluticasone propionate) or placebo for 6 weeks and then challenged with antigen. epsilon chain mRNA was expressed in an unexpectedly high proportion of nasal B cells of both hayfever patients and normal subjects. However, although similar numbers of B cells were found in both groups, the proportion of cells that express epsilon chain mRNA was several times higher in the hayfever patients. No transcripts of the epsilon germ-line gene were detected in either group before allergen challenge. When hayfever patients were administered antigen locally, early (10-30 min) and late (1-24 h) symptoms ensued. After 24 h, coincident with an increase in the number of cells expressing mRNA for IL-4 in the tissue, epsilon germ-line gene transcripts appeared in the nasal B cells. The induction by allergen of IL-4 mRNA and epsilon germ-line gene transcripts was suppressed by fluticasone propionate treatment. Our results suggest that local IgE synthesis and cytokine regulation of heavy chain switching to IgE occur in the nasal mucosa.

B cells genetically deficient in the c-Rel transactivation domain have selective defects in germline CH transcription and Ig class switching

The Ig heavy chain locus contains a number of binding sites for the transcriptional activator, c-Rel. In this study, we evaluated the capacity of B cells from mice made genetically deficient in the C-terminal, transactivation domain of the c-Rel protein (delta c-Rel) to undergo Ig class switching. Flow-cytometric and digestion circularization PCR analyses revealed that delta c-Rel B cells failed to switch to IgG3 in response to LPS alone, or to IgG1 or IgE in response to LPS + IL-4. This failure to switch to IgG3 or IgG1 was associated with a corresponding loss of germline CH gamma 3 or CH gamma 1 RNA. However, the defective switching to IgE in delta c-Rel B cells was associated with normal levels of germline CH epsilon RNA relative to control B cells. The ability of delta c-Rel B cells to switch to IgG1, in response to LPS + IL-4, could be restored through the action(s) of additional stimuli, and this was associated with induction of normal levels of germline CH gamma 1 RNA relative to controls. In contrast, LPS-activated B cells from delta c-Rel mice underwent normal switching to IgA in the presence of TGF-beta, relative to control B cells. This was associated with equivalent steady state levels of germline CH alpha RNA between the two B cell populations. These data are the first to demonstrate a key and selective role for c-Rel in the regulation of Ig class switching. Furthermore, distinct differences are revealed in the Ig isotype induction profiles of B cells lacking c-Rel activity vs those deficient in p50/nuclear factor-kappa B.

Combined diesel exhaust particulate and ragweed allergen challenge markedly enhances human in vivo nasal ragweed-specific IgE and skews cytokine production to a T helper cell 2-type pattern

We have previously shown that in vivo nasal challenge with diesel exhaust particles (DEP) induces both quantitative and qualitative changes in local IgE production and stimulates generalized local cytokine production. We have now investigated the combined effects of intranasal challenge with DEP plus ragweed allergen on local humoral immune responses. We collected nasal lavages from ragweed sensitized subjects at different times after nasal challenge. As compared with challenge with ragweed alone, challenge with both DEP and ragweed induced markedly higher ragweed-specific IgE but not total IgE levels or IgE-secreting cell numbers. Total and specific IgG4 levels also were enhanced, while total IgG levels were not. Synergy was also observed between the DEP and ragweed in altering the profile of epsilon mRNAs generated by alternative splicing, mRNAs that code for different expressed IgE proteins. Intranasal challenge with ragweed alone induced inconsistent and low levels of mucosal cytokine mRNAs. In contrast, challenge with both ragweed plus DEP resulted in decreased expression for Th1-type cytokines (IFN-gamma and IL-2) but elevated expression of mRNA for other cytokines (IL-4, -5, IL-6, IL-10, IL-13). This synergy between DEP and natural allergen exposure is suggested as a key feature in increasing allergen-induced respiratory allergic disease.

Identification of the high affinity receptor binding region in human immunoglobulin E

We have investigated the capacity of N- and C-terminally truncated and chimeric human (h) IgE-derived peptides to inhibit the binding of 125I-labeled hIgE, and to engage cell lines expressing high and low affinity receptors (Fc-epsilon-RI/II). The peptide sequence Pro343-Ser353 of the hC-epsilon-3 domain is common to all h-epsilon-chain peptides that recognize hFc-epsilon-RI. This region in IgE is homologous to the A loop in C-gamma-2 that engages the rat neonatal IgG receptor. Optimum Fc-epsilon-RI occupancy by hIgE occurs at pH 6.4, with a second peak at 7.4. N- or C-terminal truncation has little effect on the association rate of the ligands with this receptor. Dissociation markedly increases following C-terminal deletion, and hFc-epsilon-RI occupancy at pH 6.4 is diminished. His residue(s) in the C-terminal region of the epsilon-chain may thus contribute to the high affinity of interaction. Grafting the homologus rat epsilon-chain sequence into hIgE maintains hFc-epsilon-RI interaction without conferring binding to rat Fc-epsilon-RI. hFc-epsilon-RII interaction is lost, suggesting that these residues also contribute to hFc-epsilon RII binding. h-epsilon-chain peptides comprising only this sequence do not block hIgE/hFc-epsilon-RI interaction or engage the receptor. Therefore, sequences N- or C-terminal to this core peptide provide structures necessary for receptor recognition.

Prostaglandin E2 promotes B lymphocyte Ig isotype switching to IgE

The mechanism by which PG of the E series (PGE) promote murine B lymphocyte IgE production was investigated. We previously reported that PGE, and other agents that increase intracellular cAMP, synergize with IL-4 and LPS to induce IgE and IgG1 production while inhibiting IgM and IgG3 synthesis. These data suggested that PGE may promote IL-4-induced class switching, but the mechanism by which PGE increases IgE synthesis remained obscure. We report here that 1) PGE increases (up to 14-fold) the number of splenic B cells secreting IgE, even though PGE mildly inhibits proliferation. 2) PGE acts on sorted surface IgM positive B cells, consistent with PGE acting on uncommitted B cells to promote class switching to IgE. 3) PGE synergizes with IL-4 to induce germline epsilon transcripts, demonstrating that PGE acts at the level of transcription in cells that have not yet switched to IgE. 4) In the presence of PGE, rearranged mature V(D)J epsilon mRNA transcripts can be detected earlier and at higher levels than with IL-4 and LPS alone. Taken together, these data provide strong evidence that PGE synergizes with IL-4 and LPS to direct isotype switching to the epsilon heavy chain gene in purified B lymphocytes. PGE is a potentially important in vivo immunoregulator, particularly with regard to IgE production and the genesis of allergy. In support of this hypothesis, there are numerous clinical conditions (hyper-IgE, trauma, sepsis, Hodgkin's lymphoma, arthritis) in which overproduction of PGE is coincident with elevated IgE titers.

Interleukin 13 induces interleukin 4-independent IgG4 and IgE synthesis and CD23 expression by human B cells

Recently the cDNA encoding interleukin 13 (IL-13), a T-cell-derived cytokine, was cloned and expressed. The present study demonstrates that IL-13 induces IgG4 and IgE synthesis by human B cells. IL-13-induced IgG4 and IgE synthesis by unfractionated peripheral blood mononuclear cells and highly purified B cells cultured in the presence of activated CD4+ T cells or their membranes. IL-13-induced IgG4 and IgE synthesis is IL-4-independent, since it was not affected by neutralizing anti-IL-4 monoclonal antibody. Highly purified, surface IgD+ B cells could also be induced to produce IgG4 and IgE by IL-13, indicating that the production of these isotypes reflected IgG4 and IgE switching and not a selective outgrowth of committed B cells. IL-4 and IL-13 added together at optimal concentrations had no additive or synergistic effect, suggesting that common signaling pathways may be involved. This notion is supported by the observation that IL-13, like IL-4, induced CD23 expression on B cells and enhanced CD72, surface IgM, and class II major histocompatibility complex antigen expression. In addition, like IL-4, IL-13 induced germ-line IgE heavy-chain gene transcription in highly purified B cells. Collectively, our data indicate that IL-13 is another T-cell-derived cytokine that, in addition to IL-4, efficiently directs naive human B cells to switch to IgG4 and IgE production.

The expression and characterization of rat IgE produced by construction of the epsilon-heavy chain gene from exon modules

A system of exon "modules" was produced from the functionally rearranged epsilon-heavy gene isolated from the rat IgE-secreting immunocytoma IR162. The five individual exons, encoding the variable and constant region domains, were isolated and subcloned into the multiple cloning site of a pair of plasmid vectors with opposed orientation multiple cloning sites. The use of opposed orientation multiple cloning sites and the flanking restriction enzyme sites contained therein allows for the modular manipulation of the gene. These exon modules were initially used to reconstruct the epsilon-heavy chain gene into the native configuration to demonstrate the efficacy of the modular system for synthesis of IgE. Upon transfection into the rat myeloma cell line Y3, the reconstructed gene produced a polypeptide that associated with the endogenous light chain polypeptide and was secreted from the cell as tetrameric IgE. All physical and functional characterizations indicate that the IgE molecule produced is indistinguishable from native IR162 IgE. This modular system of exons will facilitate the manipulation of IgE structure through the systematic assembly of different epsilon-heavy chain mutant constructions. The resulting novel IgE proteins will be very useful to study the molecular nature of the interaction of IgE with its Fc receptor.

Modulation of IL-4 induced germline epsilon RNA synthesis in human B cells by tumor necrosis factor-alpha, anti-CD40 monoclonal antibodies or transforming growth factor-beta correlates with levels of IgE production

To determine the role of germline epsilon transcription in IgE synthesis, the effects of cytokines on germline epsilon RNA synthesis in IL-4 dependent epsilon switching in B cells was investigated. Induction of germline epsilon transcription in highly purified B cells seems to be a specific property of IL-4, since none of the other cytokines tested [IL-1 alpha, beta, IL-2, IL-3, IL-5, IL-6, IL-7, IL-9, IL-10, G-CSF, GM-CSF, M-CSF, IFN-gamma, IFN-alpha, tumor necrosis factor (TNF)-alpha, and transforming growth factor (TGF)-beta] were effective. TGF-beta, IFN-gamma, and IFN-alpha inhibit IL-4 dependent IgE synthesis, but only TGF-beta blocked germline epsilon RNA synthesis in purified B cells, indicating that this may be the mechanism by which TGF-beta inhibits IgE synthesis, and that IFN-gamma and IFN-alpha act on other stages of the regulatory process resulting in IgE production. IL-5, IL-6, and TNF-alpha enhance IL-4 dependent IgE synthesis, but only TNF-alpha enhanced IL-4 induced germline epsilon RNA synthesis. Finally, anti-CD40 mAbs and the non-IL-4 producing CD4+ T cell clone A3, which in the presence of IL-4 induce IgE synthesis by purified B cells, both strongly enhanced germline epsilon transcription. These data, together with the observation that epsilon switching in cultures initiated with single sIgM+, sIgE- B cells in all instances was preceded by germline epsilon RNA synthesis, indicate that there is a strong relationship between germline epsilon transcription and IgE synthesis.

Enhancer mediated suppression of epsilon heavy-chain gene expression in a murine IgE-producing hybridoma

In vitro co-culture of IgE-secreting hybridoma cells (B53) with spleen cells harvested from mice with established B53 tumours results in a specific, T cell-dependent suppression of epsilon-chain expression in the B53 cells. The role of immunoglobulin enhancers in the suppression of IgE synthesis in B53 cells was examined by transfecting B53 cells with CAT expression vectors containing the immunoglobulin heavy- or kappa light-chain intron enhancers or a Rous sarcoma virus (RSV) LTR. When epsilon-chain expression of transfected cells was suppressed in vitro. CAT expression was also suppressed in cells transfected with vectors containing the immunoglobulin heavy-chain gene enhancer, but not in cells transfected with vectors containing the kappa enhancer or RSV LTR. Thus, the T cell-dependent suppression of IgE synthesis in B53 cells correlates with a specific inactivation of the immunoglobulin heavy chain enhancer, strongly suggesting that T cell-mediated suppression of Ig synthesis can normally occur through specific repression of Ig enhancer function. This represents a new regulatory pathway involved in the control of IgE synthesis and is the first indication that the enhancer mediated expression of Ig genes in B cells can be modulated through T cell-dependent processes.

Immunoglobulin synthesis in the human myeloma cell line U-266; expression of two immunoglobulin heavy chain isotypes (epsilon and alpha) after long-term cultivation in vitro

A human IgE-producing myeloma has been cultivated in vitro as a continuous cell line (U-266) since 1968. Analysis of immunoglobulin production during early passages of the cell line demonstrated a high synthesis rate of monoclonal IgE. Analysis of late passages, cultivated after 1980, revealed a 3-6-fold lower rate of IgE secretion. This decrease was accompanied by the appearance of small amounts of IgA in the culture medium together with IgE. RNA was extracted from a late passage of U-266 and analyzed by Northern blotting, using epsilon and alpha-specific oligonucleotides as hybridization probes. The results showed the presence of epsilon as well as alpha-specific mRNA. Moreover the results demonstrated that the latter mRNA was derived from the alpha 2 locus and that the epsilon and the alpha 2-specific mRNA contained the same V region sequences. Southern blot analysis of DNA from the late passage of the U-266 cell line failed to reveal a recombinatory switch from the epsilon locus to the alpha 2 locus. The expression of alpha 2 is thus likely to be caused by differential splicing rather than by an isotype switch at the DNA level.

Thymus-dependent in vivo suppression of IgE synthesis in a murine IgE-secreting hybridoma

In previous studies we demonstrated that BALB/c mice bearing ascitic tumors of the IgE-secreting hybridoma B53 (epsilon, kappa, anti-dinitrophenyl) developed large numbers of Lyt-1-2+ Fc epsilon R(+) T lymphocytes (T cells with membrane Fc receptors) in response to the elevated serum IgE concentration. The development of Fc epsilon R(+) T lymphocytes was followed by a progressive decrease in the levels of serum IgE in spite of continued proliferation of the hybridoma cells. This sequence of events suggested that the IgE-secreting hybridoma triggered a suppressive immunoregulatory circuit of the host that inhibited IgE expression by the hybridoma cells. The present studies were undertaken to investigate the basis for the subsequent decline in serum IgE levels in mice with B53 tumors and to identify host factors that might be involved in this process. We observed that ascitic B53 cells recovered at increasing time points from BALB/c mice exhibited a selective decline in steady state levels and rates of synthesis of epsilon-heavy chain protein and mRNA. The expression of kappa-light chain protein and mRNA appeared relatively unchanged. The decrease in epsilon-heavy chain gene expression did not occur when B53 tumors were passaged in nu+/nu+ mice or in BALB/c mice depleted of Lyt-2+ cells (suppressor/cytotoxic cell lineage), but did occur in nu+/nu+ mice reconstituted with neonatal BALB/c thymus and in BALB/c mice depleted of L3T4+ cells (helper/inducer cell lineage). That Fc epsilon R(+) T lymphocytes were directly involved in the inhibition of IgE expression was supported by the earlier and more pronounced inhibition of B53 IgE in mice infused with Fc epsilon R(+) T lymphocytes. We conclude from these findings that: 1) the decline in serum IgE levels that occurs toward the end of each generation of in vivo passage of the B53 hybridoma is due to decreased production of IgE by the hybridoma cells, 2) the decreased production of IgE is due to a selective loss of epsilon mRNA expression, 3) the decrease production of IgE by B53 cells is dependent on the presence of Lyt-2+ cells, and 4) Fc epsilon R(+) T lymphocytes participate in the mechanism by which IgE production is suppressed.

Biosynthesis of membrane and secreted epsilon-chains during lipopolysaccharide-induced differentiation of an IgE+ murine B-lymphoma

A switch variant of the I.29 murine B-cell lymphoma expressing membrane IgE and inducible by lipopolysaccharide (LPS) to increase the rate of IgE secretion was characterized. The cells (I.29 epsilon +2) express membrane-bound IgE, and also secrete considerable amounts of IgE when grown in regular culture medium. Membrane and secreted IgE contain structurally different heavy chains. The former is constituted by a 93-kd molecule (epsilon m), while secretory chains (epsilon s) have an apparent mol. wt of 86,000. Both epsilon m and epsilon s are heavily glycosylated: in the presence of tunicamycin their apparent mol. wt is reduced by approx. 35% (61 kd for epsilon m and 56 kd for epsilon s). Glycosylation is necessary for membrane expression and for secretion of IgE molecules. Stimulation with LPS leads to the disappearance of IgE molecules from the cell surface (determined by radioiodination) although epsilon m-chains are still synthesized, suggesting a defective transport of membrane IgE in LPS-treated cells. The epsilon m:epsilon s ratio decreases upon LPS stimulation. A similar change can be observed in the messenger RNAs specific for epsilon m and epsilon s, possibly suggesting a major pretranslational control for epsilon m and epsilon s biosynthesis.

Inhibition of mast cell sensitization in vitro by a human immunoglobulin epsilon-chain fragment synthesized in Escherichia coli

An immunoglobulin epsilon-chain fragment was synthesized in E. coli by cloning and expression of the gene coding for the second, third and fourth constant domains of the human IgE heavy chain. The bacterial CH2-4 polypeptide product was assembled by oxidation into a covalently linked dimeric epsilon-chain molecule presumably analogous to the Fc region of native IgE. This bacterial Fc epsilon preparation, within the concentration range 0.01-10 micrograms/ml, inhibited sensitization of human lung mast cells, determined as histamine released upon challenge with specific antigen. Monomer CH2-4 epsilon-chain polypeptide, prepared by reduction and alkylation of the active bacterial Fc epsilon fragment, was inactive as an inhibitor of sensitization. The molar potency of the active bacterial Fc epsilon product was approximately one fourth of that of native IgE. Since the bacterial Fc epsilon is nonglycosylated, carbohydrate does not make an essential contribution to the Fc receptor binding activity of IgE. These results show that a functionally active immunoglobulin molecule can be synthesized by gene cloning and expression in E. coli.