Regulation of murine IgE responses: induction of long-lived inhibition of allergen-specific responses is genetically restricted.

We previously reported that administration of high Mr glutaraldehyde-polymerized ovalbumin (OA-POL) 10 days prior to OA Al(OH)3 immunization results in 85 to 99% inhibition of primary and secondary anti-OA IgE responses and 10(2)- to 10(4)-fold increases in OA-specific IgG2a production in each of 14 inbred and 1 outbred murine strains tested. Administration of unmodified OA under the same conditions fails to inhibit IgE synthesis and yields only minor increases in IgG2a production. In the present report, the genetic restrictions placed on the capacity of this modified allergen to elicit long-lived reciprocal regulation of specific IgE and IgG2a responses were examined. Virtually permanent, antigen-specific inhibition of IgE production (greater than 90% for greater than 22 months) was elicited in C57B1/6 mice following administration of a single course of OA-POL. This inhibition was paralleled by substantial (250-fold) increases in specific IgG2a production and was dependent on the activity of extremely long-lived regulatory CD4 T cells. In contrast, BALB/c mice failed to maintain an IgE unresponsive state beyond 10-12 weeks and exhibited transient and less intense increases in IgG2a production. Examination of MHC and Igh congenic strains revealed that the induction of long-term split tolerance by these modified allergens is under multigenic control and is not solely attributable to MHC, Igh, or background genes.     

Induction of allergen-specific IgE and IgG responses by anti-idiotypic antibodies

In order to explore idiotypic, anti-idiotypic, and anti-anti-idiotypic responses to allergens, BALB/c mice were immunized with affinity-purified human idiotypic antibodies directed against a highly purified shrimp allergen. This resulted in the production of anti-idiotypic antibodies which were quantitated by using rabbit idiotypic antibodies raised against the same purified allergen. The mouse anti-idiotypic antibodies recognized shrimp-specific human idiotypic antibodies of the IgE isotype from 18 of 20 individuals, and IgG antibodies from 14 of 20 shrimp-sensitive patients. Immunization of BALB/c mice with affinity-purified, allergen-specific anti-idiotypic antibodies induced anti-allergen IgE and IgG responses in the absence of the allergen. This paper thus presents evidence that anti-idiotypic antibodies raised against allergen-specific idiotypic antibodies may substitute for the original allergen in the induction of allergen-specific idiotypic antibodies. The demonstration of shared idiotopes on IgG and IgE antibodies in the sera of shrimp-sensitive patients supports the use of allergen-specific anti-idiotypic antibodies as surrogate allergens.     

IL-4 is required to generate and sustain in vivo IgE responses

Antibodies of the IgE isotype play a predominant role in immediate hypersensitivity reactions. IL-4, a T cell-derived lymphokine that stimulates increased Ia expression by resting B cells and increased IgG1 secretion by LPS-activated B cells in vitro, has also been shown to regulate in vitro and in vivo polyclonal IgE responses. We report that large quantities of a purified anti-IL-4 mAb inhibit primary in vivo polyclonal IgE responses by 99% in mice infected with Nippostrongylus brasiliensis or injected with anti-IgD antibodies, and totally inhibit secondary Ag-specific IgE responses to TNP-keyhole limpet hemocyanin without effect on either IgG1 or IgG2a responses to these stimuli. The lack of effect of anti-IL-4 antibody on IgG1 secretion cannot be explained simply by inadequate neutralization of IL-4, inasmuch as the doses of anti-IL-4 antibody used blocked an N. brasiliensis-induced increase in B cell Ia expression by more than 85%, whereas in vitro studies indicate that enhancement of B cell Ia expression requires less IL-4 than induction of IgG1 secretion. In addition to demonstrating that IL-4 plays a necessary role in the generation of an in vivo IgE response, we show that IL-4 has an important role in sustaining established IgE responses, because anti-IL-4 antibody, when given at the peak of an N. brasiliensis- or TNP-keyhole limpet hemocyanin-induced IgE response, accelerates the declines in total serum IgE and in IgE anti-TNP antibody levels, respectively. These observations suggest that the effects of IL-4 on in vivo immune responses may be more specific than might have been predicted from in vitro observations, and that regulation of IL-4 production or action may be useful for the prevention or therapy of immediate hypersensitivity disorders.     

Prevention of allergen-specific, Th2-biased immune responses in vivo: role of increased IL-12 and IL-18 responsiveness

The factors that control development of adaptive responses to exogenous Ag remain incompletely understood. An ability to selectively direct immunity toward a specific phenotype would be of clinical benefit in numerous immunological disorders. Administration of chemically modified allergen glutaraldehyde-polymerized OVA (OA-POL) leads to >90% reductions in murine IgE and >500-fold increases in IgG2c responses that develop upon subsequent immunization with native Ag. In the present study, we examine the mechanisms underlying this reorientation of the type 2 dominant response that would normally develop. Lack of endogenous IL-12 or IFN-gamma results in markedly reduced induction of IgG2c responses following OA-POL treatment, but only IFN-gamma(-/-) mice demonstrate reduced capacity to prevent IgE induction. This indicates that while both IL-12 and IFN-gamma are critical promoters of type 1 immunity, only IFN-gamma is required to maximally inhibit development of type 2 immune responses. Compared with OVA-immunized mice, CD69(+) T cells from OA-POL-immunized mice demonstrate elevated IL-12Rbeta(2), IL-18Ralpha, and IL-18Rbeta mRNA levels, as well as increased IFN-gamma production in response to rIL-12 or rIL-18 stimulation. Collectively, these data indicate that preventing induction of type 2 immune responses is critically dependent on altered T cell responsiveness to these cytokines. The finding that targeted, Ag-specific manipulation of IL-12 and IL-18 responsiveness can be used to shape the phenotype of the dominant immune response that develops suggests that specifically targeting IL-12 and IL-18 receptor expression may offer clinical options for clinical prophylaxis or intervention.     

Dual mechanisms of potentiation of murine antigen-specific IgE production by cyclosporin A in vitro.

Concomitant administration of cyclosporin A (CsA) with Ag has been shown to augment the production of Ag-specific IgE in vivo. We demonstrate that addition of CsA also markedly potentiated Ag-specific IgE in vitro. Low doses of CsA (3 and 10 ng/ml) added at the time of culture initiation selectively enhanced Ag-specific IgE but not IgA or IgG1 production, whereas higher doses (30 ng/ml) suppressed production of all the isotypes. Augmented IgE production was found to correlate with enhanced production of IL-4 and diminished production of IFN-gamma. Delayed addition (after 2 days) of low doses of CsA to Ag-stimulated cultures did not potentiate IgE production, even though CsA differentially affected levels of IL-4 and IFN-gamma. CsA enhanced Ag-mediated cognate T/B interaction was not affected by neutralizing doses of anti-IL-4, suggesting Ag-mediated lymphocytic "synapses" may be inaccessible to anti-IL-4. The effect of CsA on Ag presentation was determined by pulsing peritoneal exudate cells, spleen cells, or primed B cells with Ag and low doses of CsA before incubation with primed splenocytes. Enhanced Ag-specific IgE responses were detected with no effect on IL-4 or IFN-gamma levels. Thus, our study indicates that CsA potentiation of Ag-specific IgE response is due to cumulative action of CsA on two independent pathways: first, CsA differentially modulates IL-4 and IFN-gamma levels during the early phase of cognate Th2/B cell interaction; and second, CsA directly affects APC and IgE isotype-specific amplifying cellular components without apparently affecting the secretory levels of IL-4 and IFN-gamma. Dual mechanisms of CsA-potentiated IgE production are consistent with the hypothesis of two-tiered T cell regulation of Ag-specific IgE responses.     

Induction of Th2 responses and IgE is largely due to carbohydrates functioning as adjuvants on Schistosoma mansoni egg antigens

Infection with the helminth parasite Schistosoma mansoni induces a pronounced Th2-type response that is associated with significant IgE production. To better understand how the parasite drives these responses, we investigated the relative roles of proteins and carbohydrates in driving Th2-type and/or IgE responses using a murine model of intranasal sensitization with soluble egg Ags (SEA) of Schistosoma mansoni. We found that repeated intranasal sensitization with soluble egg Ags led to the induction of both total and specific IgE production and nasal eosinophilia. By comparing the responses of mice sensitized with SEA or metaperiodate-treated SEA we were able to demonstrate that carbohydrates on SEA are the major inducers of IgE production and nasal recruitment of eosinophils. Mice sensitized with periodate-treated SEA displayed a significant decrease in both total and specific IgE levels in comparison to mice sensitized with native SEA. Furthermore, sensitization of mice with periodate-treated SEA significantly reduced levels of Ag-specific IgG1, but had no effect on IgG2a production. Nasal lymphocytes from mice sensitized with native SEA, but not with periodate-treated SEA, produced IL-4, IL-5, and IL-10 when restimulated with native SEA in vitro. On the other hand, lymphocytes from mice sensitized with periodate-treated SEA did not produce any of these same cytokines following in vitro restimulation, suggesting that carbohydrates were required for in vivo induction of Th2 response and for that of associated cytokine responses in this model. Lastly, competitive inhibition ELISA showed that although carbohydrates are required for SEA-specific IgE induction, they are not targets of the induced IgE response.     

Humoral immune functions in IL-4 transgenic mice

We have analyzed mice expressing IL-4 as a transgene, and found that expression of this lymphokine has profound effects on B cell function. B cells from transgenic mice exhibit phenotypic changes, including an increase in size and elevated expression of class II MHC. IL-4 increases the quantity of IgE produced by transgenic-derived B cells in response to LPS stimulation. In vivo, IL-4 markedly affects the serum Ig isotype repertoire. Serum levels of IgG1 and IgE are elevated, and levels of IgG2a, IgG2b, and IgG3 are depressed in IL-4 transgenic mice. Ag-specific antibody responses to immunization with hapten-carrier conjugates are also affected by IL-4. Transgenic mice show increased anti-hapten IgE and IgG1 and reduced anti-hapten IgG2a, IgG2b, and IgG3, compared with wild-type mice. Ag-specific IgE is substantially induced by T cell-dependent Ag, but not T cell-independent Ag, suggesting that cognate T-B interactions in addition to IL-4 are required for generating IgE responses in vivo. In vivo treatment with the anti-IL-4 mAb 11B11 reverses many of the isotype alterations in the transgenic mice, indicating that these changes arise as a direct consequence of IL-4 secretion.     

Initiation of delayed-type hypersensitivity by low doses of monoclonal IgE antibody. Mediation by serotonin and inhibition by histamine

Elicitation of delayed-type hypersensitivity (DTH) responses by DTH effector T cells requires a prior phase of DTH initiation. This consists of an immediate hypersensitivity-like response mediated by Ag-specific DTH-initiating factors that are analogous to IgE antibodies in that they sensitize tissue mast cells for release of the vasoactive amine serotonin (5-HT). Experiments were conducted to determine whether IgE mAb injected i.v., or 5-HT injected locally, could initiate DTH. It was found that small doses of IgE (1 microgram/mouse), or of 5-HT (50 to 500 ng locally), which mediated small immediate responses, were optimal for DTH initiation. Even lower doses of IgE (10 ng/mouse), or of 5-HT (5 ng locally), which did not mediate macroscopically measurable immediate responses, were capable of DTH initiation. Higher doses of IgE (10 to 100 micrograms/mouse), which mediated large immediate responses, were not able to initiate DTH. A similar dose response for DTH initiation was found with IgG1 mAb, which is another mast cell-sensitizing isotype of Ig. The inability of high doses of IgE or IgG1 to mediate DTH initiation was probably caused by local release of large inhibitory amounts of histamine, because systemic treatment with the histamine-2 receptor antagonist cimetidine allowed high doses of IgE to initiate DTH. Thus, IgE and IgG1 antibodies could initiate DTH via release of small amounts of 5-HT, but simultaneous release of large amounts of histamine were inhibitory, probably via an effect on histamine-2 receptors of recruited T cells. We concluded the following: 1) IgE or IgG1 antibodies can initiate DTH; 2) DTH initiation need not be associated with macroscopically detectable early responses; 3) mast cell release of 5-HT acts positively whereas release of histamine acts negatively in murine DTH; 4) Ag-specific factors are not the only mechanism of DTH initiation.     

Cyclosporin A is an adjuvant in murine IgE antibody responses

Cyclosporin A (CsA) is an undecapeptide fungal metabolite and is generally regarded as a new generation of immunosuppressive drugs. We uncovered a novel immunomodulatory property of CsA as a potent immunologic stimulator in the murine IgE antibody system. The enhancement of IgE responses was observed in mice receiving as few as three daily i.m. injections before Ag priming. Our studies demonstrate the three points listed below. First, CsA potentiates murine IgE responses regardless of Ag specificities in inbred mice. A hierarchy of immunopotentiation by CsA follows the order of low, intermediate, and high IgE responder mice. Second, CsA, when administered along with Ag, exerts a thorough and long lasting impact on the Ag-specific IgE antibody response, and leads to an Ag-specific breakthrough of IgE antibody synthesis in mice rendered tolerant in the IgE antibody system by soluble Ag pretreatment or neonatal IgE treatment. Third, IgE enhancer cells become sensitive to a low dose of irradiation. Two enhancer cellular components are identified, those of the Th cells and B cells, which appear to favor the induction of IgE responses. Understanding the cellular basis of the immunopotentiating effect of CsA will provide further insight into the murine IgE antibody system.     

Regulation of IgE production requires oligomerization of CD23.

Here we describe the production of a rabbit polyclonal Ab (RAS1) raised against the stalk of murine CD23. RAS1 inhibits release of CD23 from the surface of both M12 and B cells resulting in an increase of CD23 on the cell surface. Despite this increase, these cells are unable to bind IgE as determined by FACS. CD23 has previously been shown to bind IgE with both a high (4-10 x 10(7) M(-1)) and low (4-10 x 10(6) M(-1)) affinity. Closer examination by direct binding of (125)I-IgE revealed that RAS1 blocks high affinity binding while having no effect on low affinity binding. These data support the model proposing that oligomers of CD23 mediate high affinity IgE binding. These experiments suggest that RAS1 binding to cell surface CD23 results in a shift from oligomers to monomers, which, according to the model, only bind IgE with low affinity. These experiments also suggest that high affinity binding of IgE is required for IgE regulation by CD23 and is demonstrated by the fact that treatment of Ag/Alum-immunized mice treated with RAS1 results in a significant increase in IgE production similar to the levels seen in CD23-deficient mice. These mice also had significantly decreased levels of serum soluble CD23 and Ag-specific IgG1. RAS1 had no effect on IgE or Ag-specific IgG1 production in CD23-deficient mice.     

Hapten-specific IgE antibody responses in mice. VII. Conversion of IgE "non-responder" strains to IgE "responders" by elimination of suppressor T cell activity.

Mice of the inbred strains SJL (H-2s) and AKR (H-2k) are "non-responders" and "low-responders," respectively, in terms of their capacity to develop antibody responses of the IgE class when immunized with conventional proteins and hapten-protein conjugates under conditions optimal for eliciting IgE responses in "high-responder" mice, such as BALB/c (H-2d), to these same antigens. For example, BALB/c mice preimmunized with ASC and then challenged 7 days later with DNP-ASC develop peak augmented primary IgE anti-DNP antibody responses of 320 PCA units, whereas SJL and AKR mice develop responses which are 16-fold and 4-fold lower, respectively. However, pretreatment of the latter two strains with appropriate doses of either x-irradiation (150 R), cyclophosphamide (100 mg/kg) or ALS (150 mul) before carrier-preimmunization strikingly enhances the magnitude of IgE antibody responses in such mice to levels as high as 64-fold above those of untreated control mice of the same strains. Evidence obtained in these experiments indicates that the capacity of such maneuvers to to convert poor IgE responders to high responder status reflects elimination of nonantigen-specific suppressor T lymphocytes which are naturally present and normally function to suppress or "dampen" the IgE antibody response in a relatively selective manner. It appears that these cells modulate IgE responses by acting at least at two distinct points: 1) The most effective activity seems to be at the level of induction of carrier-specific helper T cells; 2) A second locus of inhibitory activity is more distal in the response, either impeding helper T cell-B cell cooperative interactions or suppressing B cell differentiation and/or function directly. Taken collectively, these observations demonstrate that the state of poor responsiveness of the SJL and AKR strains for the IgE antibody class is not a reflection of a genetic inability to develop IgE responses but rather a manifestation of a genetic capability to actively inhibit IgE antibody synthesis.     

IgE generation and mast cell effector function in mice deficient in IL-4 and IL-13

IL-4 and IL-13 are potent cytokines that drive production of IgE, which is critical to the development of atopic disease. In this study, we directly compared IgE generation and IgE-dependent mast cell effector function in mouse strains lacking IL-4, IL-13, IL-4 + IL-13, or their common receptor component, IL-4Ralpha. Although serum IgE was undetectable under resting conditions in most animals deficient in one or both cytokines, peritoneal mast cells from mice lacking IL-4 or IL-13 had only partial reductions in surface IgE level. In contrast, peritoneal mast cells from IL-4/13(-/-) and IL-4Ralpha(-/-) animals were severely deficient in surface IgE, and showed no detectable degranulation following treatment with anti-IgE in vitro. Surprisingly, however, intradermal challenge with high concentrations of anti-IgE Ab induced an ear-swelling response in these strains, implying some capacity for IgE-mediated effector function in tissue mast cells. Furthermore, upon specific immunization with OVA, both IL-4/IL-13(-/-) and IL-4Ralpha(-/-) mice produced detectable levels of serum IgE and Ag-specific IgG1, and generated strong ear-swelling responses to intradermal administration of anti-IgE. These findings suggest that a mechanism for IgE production exists in vivo that is independent of IL-4 or IL-13.     

IgE responses in human filariasis. IV. Parallel antigen recognition by IgE and IgG4 subclass antibodies

Immediate hypersensitivity responses are highly modulated in filariasis, and with few exceptions, the majority of infected individuals do not develop allergic manifestations. One possible mechanism for this modulated responsiveness could involve the high levels of IgG "blocking antibodies" shown to be present in filariasis and other chronic helminth infections. When immunoblot analyses were done to analyze the immunoglobulin (Ig) E and IgG antibody responses of patients simultaneously, remarkable similarity in the patterns of antigen binding was observed. In this study, the four IgG subclasses were analyzed in a similar manner in relation to IgE. The results clearly demonstrate that IgG4 was primarily responsible for this "parallel" recognition that was seen previously between IgG and IgE antibodies. These results lend additional support to the possibility that IgG4 may play an important role in modulating IgE-mediated allergic responses in vivo.     

Polyclonal activation of the murine immune system by a goat antibody to mouse IgD. IX. Induction of a polyclonal IgE response

The possibility that injection of mice with an affinity-purified goat antibody to mouse IgD (GaM delta) that stimulates polyclonal IgG1 secretion might also stimulate differentiation of B cells into IgE-secreting cells was suggested by the observation that such treatment induces T cells from those mice to secrete a lymphokine, B cell stimulatory factor 1 (BSF-1), that can stimulate both IgG1 and IgE secretion in vitro. Studies described in this paper show that injection of BALB/c mice with 200 to 3200 micrograms of GaM delta greatly increased the quantity of splenic epsilon chain-encoding mRNA, the number of spleen cells with cytoplasmic IgE, and the concentration of serum IgE 7 days after injection. Serum IgE levels obtained in these mice were approximately 100 times baseline levels and were comparable with those found in mice infected with the nematode parasite Nippostrongylus brasiliensis, but were approximately 2000-fold less than the peak serum IgG1 levels induced by GaM delta injection. Both IgE and IgG1 secretion in GaM delta injected mice were T dependent (blocked by anti-L3T4 antibody). These observations are consistent with the hypothesis that BSF-1 may play a role in the in vivo stimulation of IgE secretion and provide an easy to apply model for the investigation of in vivo regulation of IgE responses.     

IL-4 requirements for the generation of secondary in vivo IgE responses.

IL-4 has been shown to induce B lymphocytes to switch from the expression of membrane IgM to the expression of membrane IgE and to be required for the generation of primary polyclonal and secondary Ag-specific IgE responses in mice. To further define the role of IL-4 in the generation of memory IgE responses, we investigated the ability of a combination of anti-IL-4 and anti-IL-4R mAb to block the generation of secondary IgE responses induced by: 1) a second infection with the nematode parasites Nippostrongylus brasiliensis or Heligmosomoides polygyrus; or 2) injection of anti-IgD antibody-primed mice with anti-IgE antibody. The latter stimulus was designed to induce intrinsic membrane IgE-expressing B cells to differentiate into IgE-secreting cells. Although the IgE responses induced by a second nematode infection were completely inhibited by the combination of anti-IL-4 and anti-IL-4R mAb, anti-IgE antibody-induced IgE responses in anti-IgD primed mice were not inhibited by these antibodies to a large degree. Additional experiments demonstrated that the anti-IgE antibody-induced memory IgE response was dependent on CD4+ T cells but did not involve the low affinity B cell Fc epsilon RII. Taken together, these observations provide evidence that IL-4 is required for virgin B lymphocytes to develop into IgE-expressing cells, but is not required for B cells that express intrinsic membrane IgE to differentiate into IgE-secreting cells in a T-dependent response. Furthermore, these data suggest that secondary IgE responses in the parasite models that we have studied develop from B cells that had not previously switched to the expression of IgE.     

IgE antibody responses against Japanese cedar pollen in the mouse

IgE antibody responses against Japanese cedar pollen in the mouse were investigated to develop a mouse model of human allergy for combinations of factors including pollen administration routes, elicitation antigens and inbred mouse strains. Daily short term inhalation of native pollen or intratracheal administration of pollen suspended in saline induced IgE antibody responses in DBA/2, BDF1 and Balb/c mice, but failed to induce any detectable responses in C57BL/6 and C57BL/10 mice. Intraperitoneal injection of pollen suspension also induced IgE antibody responses in DBA/2, BDF1 and Balb/c mice but not in C57BL/6 mice. IgE antibody responses against pollen described above were detected by passive cutaneous anaphylaxis (PCA) reactions using crude extract of pollen as an elicitation antigen. On the other hand, IgE antibodies specific for antigen Sugi basic protein (AgSBP), which is a major allergen of pollen in humans (Yasueda, H., Yui, Shimizu, T., and Shida, T., 1983. Isolation and partial characterization of the major allergen from Japanese cedar (Cryptomeria japonica) pollen. J. Allergy Clin. Immunol. 71: 77-86), were also detected by PCA reactions using AgSBP in the sera from mice which received secondary or the tertiary stimulation by pollen. These results suggest that IgE antibody responses against Japanese cedar pollen in the mouse can be induced by airway sensitization and that the responses are genetically controlled by H-2-linked immune response genes. The results also suggest that not only IgE antibody responses specific for components other than AgSBP but also responses specific for AgSBP can be induced in the mouse by repeating appropriate sensitization by pollen.     

An essential role for IL-18 in CD8 T cell-mediated suppression of IgE responses

The ability of CD8 T cells to suppress IgE responses is well established. Previously, we demonstrated that CD8 T cells inhibit IgE responses via the induction of IL-12, which promotes Th1 and suppresses Th2 responses. In this study, we show that IL-18 also plays an essential role in IgE suppression. In vitro, IL-18 synergized with IL-12 to promote Th1/T cytotoxic 1 and inhibit Th2/T cytotoxic 2 differentiation. OVA-specific TCR transgenic (OT-I) CD8 cells induced both IL-12 and IL-18 when cultured with OVA(257-264) peptide-pulsed dendritic cells. In vivo, IL-18(-/-) mice exhibited higher IgE and IgG1 levels compared with wild-type mice after immunization with OVA/alum. Furthermore, adoptive transfer of CD8 T cells from OVA-primed mice suppressed IgE responses in OVA/alum-immunized mice, but not in IL-18(-/-) mice. IgE suppression in IL-18(-/-) mice was restored if CD8 T cells were coadoptively transferred with IL-18-competent wild-type bone marrow dendritic cell progenitors, demonstrating an essential role of IL-18 in CD8 T cell-mediated suppression of IgE responses. The data suggest that CD8 T cells induce IL-18 production during a cognate interaction with APCs that synergizes with IL-12 to promote immune deviation away from the allergic phenotype. Our data identify IL-18 induction as a potentially useful target in immunotherapy of allergic disease.     

Induction of pulmonary allergen-specific IgA responses or airway hyperresponsiveness in the absence of allergic lung disease following sensitization with limiting doses of ovalbumin-alum.

Respiratory allergies represent a failure to generate nonpathogenic responses to innocuous foreign materials. Herein we assessed the role of the sensitizing dose of allergen in this response/nonresponse paradigm, sensitizing BALB/c mice with 5 ng-2 microg of OVA-alum and assessing their responses to repeated OVA aerosol challenge. Mice sensitized with < or = 25 ng of OVA-alum did not develop atopic antibodies, airway hyperresponsiveness (AHR), eosinophilia, or pulmonary Th2 responses, but the 25-ng group animals did develop significant IgA responses. The mice sensitized with 100 ng of OVA-alum developed AHR in the absence of detectable allergic disease, while the mice sensitized with 250 ng-2 microg of OVA/alum developed full-spectrum allergic disease (i.e., eosinophilia, IgE, IgG1, pulmonary Th2 cytokine responses, and AHR). These data indicate that limiting doses of allergen can differentially induce IgA or AHR in the absence of atopic disease in mice.     

Hypoallergens for allergen-specific immunotherapy by directed molecular evolution of mite group 2 allergens

Allergen-specific immunotherapy is the only treatment that provides long lasting relief of allergic symptoms. Currently, it is based on repeated administration of allergen extracts. To improve the safety and efficacy of allergen extract-based immunotherapy, application of hypoallergens, i.e. modified allergens with reduced IgE binding capacity but retained T-cell reactivity, has been proposed. It may, however, be difficult to predict how to modify an allergen to create a hypoallergen. Directed molecular evolution by DNA shuffling and screening provides a means by which to evolve proteins having novel or improved functional properties without knowledge of structure-function relationships of the target molecules. With the aim to generate hypoallergens we applied multigene DNA shuffling on three group 2 dust mite allergen genes, two isoforms of Lep d 2 and Gly d 2. DNA shuffling yielded a library of genes from which encoded shuffled allergens were expressed and screened. A positive selection was made for full-length, high-expressing clones, and screening for low binding to IgE from mite allergic patients was performed using an IgE bead-based binding assay. Nine selected shuffled allergens revealed 80-fold reduced to completely abolished IgE binding compared with the parental allergens in IgE binding competition experiments. Two hypoallergen candidates stimulated allergen-specific T-cell proliferation and cytokine production at comparable levels as the wild-type allergens in patient peripheral blood mononuclear cell cultures. The two candidates also induced blocking Lep d 2-specific IgG antibodies in immunized mice. We conclude that directed molecular evolution is a powerful approach to generate hypoallergens for potential use in allergen-specific immunotherapy.     

Immunoregulatory role of Ig isotypes. II. Activation of cells that block induction of contact sensitivity responses by antibodies of IgG2a and IgG2b isotypes

The influence that the isotype of Ag-specific antibody has on the induction of contact hypersensitivity (CS) has been investigated. Injection (i.v.) of mice with haptenated peritoneal exudate cells (PEC) pretreated with anti-hapten mAb of the IgG2a and IgG2b isotypes results in the activation of Ag-specific afferent acting Ts cells (Ts-aff). These suppressor cells are not generated when animals are injected with anti-hapten antibodies of other isotypes. The Ts-aff cells function to inhibit the generation of CS responses when injected into naive animals. Suppression is due to the induction of both Lyt-1+,2- I-J+ and Lyt-1-,2+ I-J+ T cells, both of which adhere to the lectin Vicia villosa. Attachment of both TNP and 4-ethoxymethylene-2-phenyloxazolone haptens to the same PEC, followed by treatment with an IgG2a anti-TNP antibody, generates Ts-aff cells specific for both 4-ethoxymethylene-2-phenyloxazolone and TNP. The MHC haplotype of the PEC is irrelevant, as allogeneic PEC will also induce Ts-aff cells when injected by using an identical protocol. Ts-aff cells cannot be generated in B cell-depleted mice, nor does the Ts-aff cells generated in normal mice suppress CS responses in B cell-depleted mice. These results show that Ag-antibody complexes bound on the surface of a PEC can induce potent afferent suppression in vivo. A possible general role for antibody isotypes in directing regulatory activities is discussed.