T cells expressing variable elements of T-cell receptor beta 8 and beta 2 chain regulate murine IgE production

Decreased Expression and Function of Vß6+ and Vß14+ T Cells is Associated with Decreased Th1 Cytokine Production in Mice with Plasma Cell Tumors

Aims and background

We have found that polyclonally stimulated T cells from mice bearing ascitic plasma cell tumors demonstrate specific decreases in Th1 cytokine production. In this study we investigated whether loss of Th1 responses in the plasma cell tumor system was associated with alterations in the Vß T cell receptor repertoire.

Methods

We examined the cell surface expression of specific Vß expressing splenic CD4+ or CD8+ T cells from normal and tumor bearing mice using direct three-color flowcytometry. In order to determine the Th phenotype of Vß expressing T cells, we enriched for Vß6, Vß14 or Vß8.1,8.2 cells, polyclonally stimulated them and measured the levels of the cytokines interleukin-4 (IL-4), IL-2 and interferon-gamma (IFN-gamma).

Results

We find that there is a statistically significant decrease in the frequency of Vß6+ and Vß14+ CD8+ T cells in mice bearing a plasma cell tumor (B53) as compared to normals (p<0.05). Stimulated Vß6+ and Vß14+ T cells exhibit an exclusively Th1 phenotype. Stimulated Vß6+ and Vß14+ T cells from B53 mice are deficient in production of the Th1 cytokines. In contrast, stimulated Vß8.1,8.2+ T cells, which are not altered in B53 mice, reveal a Th2 phenotype.

Conclusions

The significance of this study is our demonstration that decreased expression and function of Vß6+ and Vß14+ T cells may be, at least in part, responsible for the decrease in the production of IL-2 and/or IFN-gamma observed in hosts with tumors.

Comparative evaluation of anti-inflammatory properties of thymoquinone and curcumin using an asthmatic murine model

This study was designed to compare the inhibitory effects of thymoquinone (TQ) and curcumin (CMN) on the biological changes associating asthma. TQ appeared to exhibit greater inhibitory effects on the aggregation of inflammatory cells in bronchoalveolar lavage (BAL) fluid and in lung tissues. We also measured the effects of the two agents on serum IgE and the changes in the mRNA levels of inducible nitric oxide synthase (iNOS), tumor necrosis factor-α (TNF-α) and transforming growth factor-β1 (TGF-β1). Serum IgE was significantly decreased by TQ and CMN with TQ being more potent. Also, TQ showed superior inhibitory effects on iNOS and TGF-β1. Meanwhile, CMN was more potent in inhibiting mRNA expression of TNF-α. These results suggest that TQ is more potent in inhibiting the inflammatory changes associating asthma. On the other hand, CMN was a less potent inhibitor of all measured parameters, despite its superior inhibitory effect on TNF-α mRNA levels.

Staphylococcal-derived superantigen enhances peanut induced Th2 responses in the skin

BACKGROUND

The allergen-induced activation and expansion of IL-4 producing T helper type 2 (Th2) cells is a key event in the initiation and progression of allergic disease. Intriguingly, concomitant early childhood staphylococcal skin infections are being increasingly implicated in the allergen-induced switch of primary T cell responses towards the Th2 phenotype.

OBJECTIVE

We sought to identify whether or not staphylococcal-derived superantigen can influence the primary T cell response in the skin to food allergens with a view to determining whether such exposures create the immune pathology that predisposes to the development of food allergy.

METHODS

Using a novel Th2 reporter model, we determined the ability of the staphylococcal superantigen (SEB) to influence priming in the skin of IL-4 expressing Th2 cells by peanut extract (PE). Factors including the effect of SEB on the magnitude of the Th2 response in the skin draining lymph nodes, T cell receptor V region usage and the influence of endotoxin were evaluated.

RESULTS

Primary exposure to PE and SEB lead to significantly enhanced PE specific Th2 responses when the mice were subsequently exposed to PE alone. The enhancement of the Th2 response was dependent on the Vβ-binding properties of the SEB, but was not affected by endotoxin-mediated TLR-4 effects or strain differences in the mice.

CONCLUSIONS AND CLINICAL RELEVANCE

These results identify that in the skin environment, the presence of SEB can significantly increase the numbers of allergen-induced Th2 cells which develop in response to subsequent allergen exposure. These data highlight the process by which individuals may become pathologically sensitized to food allergens in early life.

The effect of specific immunotherapy on T-cell receptor repertoire in patients with allergy to house-dust mite

BACKGROUND

The precise mechanism of specific immunotherapy (SIT), long used for treating allergic diseases, remains undefined. SIT was shown to act by modifying the immune response of T lymphocytes to antigens. We examined the effect of SIT on the expression and use V-alpha, -beta, -gamma and -delta chains of T-cell receptors (TCR) in patients allergic to house-dust mite.

METHODS

Peripheral venous blood was taken for lymphocyte TCR analysis from 10 house-dust mite (HDM) allergic adults before initiating SIT and 6 months after initiating the treatment. Twelve similarly allergic patients without SIT served as controls. TCR chains were identified by fluorescence-activated cell sorter (FACS) using the following monoclonal antibodies: CD3, CD14, CD8, pan alpha-beta, pan gamma-delta, V-alpha2, V-alpha12.1, V-beta5a, V-beta5b, V-beta5c, V-beta8a, V-beta8b, V-beta3.1, V-beta13, V-beta12, V-beta6.7, V-delta1, V-delta2, V-gamma9, and V-gamma4.

RESULTS

Analyzed before and 6 months after SIT initiation, lymphocyte TCR showed significantly increased V-beta5b, V-beta12 and V-alpha12.1 values compared to controls (without significant changes in other markers).

CONCLUSIONS

SIT caused selective expansion of certain V-beta- and V-alpha-expressing T cells in patients allergic to HDM. Our results support the notion that the effect of SIT in patients with allergic rhinitis may be achieved by modifying the T lymphocyte response through the modulation of TCR usage.

T cell receptor Vbeta expression in patients with allergic asthma before and after repeated low-dose allergen inhalation

The objective of this study was to identify disease-associated T cell subsets by characterizing the lung and blood T cell receptor (TCR) repertoires in allergic asthmatics before and after repeated low-dose allergen challenge. Peripheral blood lymphocyte (PBL) and bronchoalveolar lavage (BAL) samples were obtained from eight patients with allergic asthma before and after a period of repeated low-dose allergen inhalations. RT-PCR followed by Southern blot allowed the quantification of relative Vbeta gene segment usage. Thirteen healthy individuals served as controls at PBL level. PBL as well as BAL T cells of asthmatics displayed a higher usage of Vbeta3, Vbeta5.2, and Vbeta6.1-3 and a lower usage of Vbeta16, Vbeta18, and Vbeta19 compared to PBL of healthy controls. Interestingly, TCR Vbeta7 and Vbeta9 usage was significantly higher in BAL than in PBL in asthmatics before as well as after challenge. TCR repertoire alterations after allergen challenge differed between individuals, with relatively mild changes.

Neonatal dexamethasone treatment induces long-lasting changes in T-cell receptor vbeta repertoire in rats

Glucocorticoids are frequently administered for the prevention of chronic lung disease in infants with respiratory distress syndrome. However, neonatal treatment may have consequences for immune functioning in the long-term. Here we demonstrate that neonatal glucocorticoid treatment has long-lasting effects on mRNA expression of several Vbeta genes within the CD4 and CD8 T cell subset in rats. Changes in the peripheral T cell Vbeta repertoire may be a consequence of altered intrathymic selection events in which corticosterone plays an important role. Indeed, here we show that neonatal glucocorticoid treatment affects corticosterone production by thymic epithelial cells during neonatal life. In conclusion, changes in T cell Vbeta repertoire after neonatal glucocorticoid treatment may contribute to altered immune reactivity in later life.

Impact of V beta 8+/+ T cells on the development of increased airway reactivity and IgE production in SJL mice

SJL mice have been extensively characterized as "low-responder" animals in terms of IgE-dependent immediate-type hypersensitivity responses. Since these mice are genetically deficient in certain TCR Vbeta gene segments, we asked whether this might be the reason for the "low-responder" status. Specifically in H-2d mice the TCR-Vbeta8.2 gene element has been shown to play an important role in Th2 immune responses to ovalbumin (OVA). Utilizing a TCR Vbeta8. 2-transgenic SJL (SJL Vbeta8+/+) mouse, we examined whether the H-2s -bearing "low-responder" mouse could be converted into a "high-responder" animal. Remarkably, non-sensitized SJL Vbeta8+/+ mice demonstrated strongly elevated levels of total IgE antibody. Mitogen-stimulated T cells from these mice released high amounts of IL-4 as compared to SJL wild-type (wt) mice. In addition, sensitization to OVA via the airways resulted in the development of increased airway responsiveness in SJL Vbeta8+/+ mice, but not in SJL wt animals. The results indicate that the capacity to produce IgE and IL-4 and to develop increased airway responsiveness can be restored in SJL wt mice by introducing the Vbeta8.2 gene segment into the TCR repertoire.

Role of IgE in the development of allergic airway inflammation and airway hyperresponsiveness--a murine model

The importance of IgE in airway inflammation and development of AHR in allergen-sensitized mice has been compared and contrasted in different models of sensitization and challenge. Using different modes of sensitization in normal and genetically manipulated mice after anti-IgE treatment, we have been able to distinguish the role of IgE under these different conditions. Striking differences in the three sensitization protocols were delineated in terms of the role of allergen-specific IgE, extent of eosinophilic airway inflammation, and development of AHR (Table 1). The highest levels of IgE and eosinophil infiltration (approximately 20-fold increases) were achieved after systemic sensitization with allergen (plus adjuvant) followed by repeated airway challenge. Passive sensitization with allergen-specific IgE followed by limited airway challenge induced a modest eosinophilic inflammatory response in the airways despite high levels of serum IgE. Exposure to allergen exclusively via the airways also resulted in a modest serum IgE response and a limited eosinophilic inflammatory response (approximately fourfold increases). Under all of these conditions, inhibition of IL-5-mediated eosinophilic airway inflammation was associated with attenuation of AHR. In contrast, the differences in the responses to the different modes of allergen exposure were associated with differences in the requirements for IgE in the development of AHR (Table 1). In the two models associated with mild eosinophil infiltration (passive sensitization and exclusive airway exposure), IgE was required for the development of AHR but did not substantially enhance airway inflammation on its own. However, IgE-allergen interaction was able to enhance T-cell function in vitro and induce T-cell expansion in vivo. In mice systemically sensitized and challenged via the airways, IgE (or IgE-mediated mast-cell activation) was not required for T-cell activation, eosinophilic inflammation and activation in the airways, or development of AHR. This was most clearly seen in B-cell-deficient and mast-cell-deficient, low-IgE-responder mouse strains (B6, B10) and in anti-IgE-treated high-IgEresponder mice (BALB/c). At the same time, we confirmed the importance of IgE in the induction of immediate-type hypersensitivity (mast-cell activation, immediate cutaneous hypersensitivity, passive cutaneous and systemic anaphylaxis). These differences were also highlighted by the means used to detect altered airway function. Passive sensitization and limited airway challenge or exclusive airway exposure to allergen over 10 days elicited changes in airway function that could be detected only in tracheal smooth-muscle preparations exposed to EFS. In contrast, systemic sensitization followed by repeated airway challenge resulted not only in changes in the contractile response to EFS but also in increased responsiveness to inhaled MCh. Thus, these results distinguish not only the differential involvement of IgE and eosinophil numbers but also their contribution to the readouts used to monitor airway function. Based on these studies, we conclude that IgE plays an important role in the development of airway inflammation and AHR under conditions in which limited IL-5-mediated eosinophilic airway infiltration is induced. In conditions where a robust eosinophilic inflammation of the airways is elicited, IgE (and IgE-mediated mast-cell activation) does not appear to be essential for airway inflammation and the development of AHR, detected as increased responsiveness to inhaled MCh. These findings reveal the potential importance of differential targeting in the treatment of allergic diseases with a predominance of IgE-mediated symptoms, e.g., allergic rhinitis and conjunctivitis, where anti-IgE may be an effective therapy, compared to those diseases with a predominant inflammatory component, e.g., AHR in atopic bronchial asthma, where anti-inflammatory or anti-IL-5 therapy may be more beneficial.

Mouse models of airway responsiveness: physiological basis of observed outcomes and analysis of selected examples using these outcome indicators

The mouse is an ideal species for investigation at the interface of lung biology and lung function. As detailed in this review, there are well-developed methods for the quantitative study of lung function in mice. These methods can be applied to mice in both terminal and nonterminal experiments. Terminal experimental approaches provide more detailed physiological information, but nonterminal measurements provide adequate data for certain experiments. In this review, we provide two examples of how these models can be used to further understanding of the primary pathobiology of airway responsiveness in both the absence and the presence of induced airway inflammation. The first model is a dissection of chromosomal loci linked to the variance in airway responsiveness observed in the absence of any manipulation to induce airway inflammation. The second model explores the role of T-cell costimulatory signals in the induction of airway hyperresponsiveness. As the number of mice with targeted deletions of effector genes or insertion of informative transgenes grows, additional examples are likely to accrue.

Vbeta8+ T lymphocytes are essential in the regulation of airway hyperresponsiveness and bronchoalveolar eosinophilia but not in allergen-specific IgE in a murine model of allergic asthma

BACKGROUND

There is increasing evidence that in allergic asthma the inflammatory process is regulated by T lymphocytes. In BALB/c mice the majority of ovalbumin responsive T lymphocytes express the Vbeta8.1+ and Vbeta8.2+ T-cell receptor.

OBJECTIVE

We analysed the contribution of Vbeta8+ T lymphocytes during the sensitization and challenge phase in the regulation of antigen-specific IgE, airway hyperresponsiveness and cellular infiltration in the airways in a murine model of allergic asthma.

METHODS

Mice strains genetically lacking (SJL/J and SJA/9) and expressing (BALB/c) the Vbeta8+ T cell receptor were used. In addition, prior to the sensitization and prior to the challenge BALB/c mice were treated with antibodies to Vbeta8. Mice were sensitized with ovalbumin, followed by repeated challenge with ovalbumin or saline aerosols.

RESULTS

In ovalbumin challenged BALB/c mice treated with control antibody a significant increase in eosinophils in the bronchoalveolar lavage, airway hyperresponsiveness and increased serum levels of ovalbumin-specific IgE were observed compared to control mice. Treatment of BALB/c mice with antibodies to Vbeta8 prior to the sensitization or prior to the challenge period completely inhibited the ovalbumin induced infiltration of eosinophils and airway hyperresponsiveness, while ovalbumin-specific IgE was slightly decreased. In SJA/9 and SJL/J mice ovalbumin challenge did not induce eosinophilic infiltration and airway hyperresponsiveness. In SJL/J mice ovalbumin challenge induced an upregulation of ovalbumin-specific IgE, however, in SJA/9 mice no upregulation was observed.

CONCLUSION

It is demonstrated that Vbeta8+ T lymphocytes are essential for infiltration of eosinophils in the airways and development of airway hyperresponsiveness in a murine model of allergic asthma. In contrast, although Vbeta8+ T lymphocytes seem to be important for the extent of IgE levels, no essential role for Vbeta8+ T lymphocytes in the induction of antigen-specific IgE was observed.

T-cell receptor repertoires utilized in response to linear peptides representing an immunodominant MHC class II restricted T-cell epitope are far more diverse than that utilized in response to the same epitope in the nominal antigen

Previous analyses of the T-cell receptor (TCR) repertoire utilized in response to the 1-102 fragment of the lambda cI repressor protein and specific for the immunodominant amino acid 12-26 region in the context of I-Ek, have shown this repertoire to be extremely restricted. In contrast, here we show that the TCR repertoires utilized in two strains of I-Ek expressing mice in response to two linear peptides representing this immunodominant region are diverse. Despite their extensive diversity, these repertoires are somewhat overlapping. In addition, structural similarities were observed between the full lambda cI fragment (1-102) and peptide elicited TCR repertoires, including frequent use of the Valpha2 family of gene segments, particularly among peptide (12-26) elicited TCRs cross-reactive with 1-102/I-Ek. Nevertheless, these data indicate that it may be difficult to mimic the immune response to an immunodominant epitope of a protein antigen via immunization with linear peptides containing the amino acid sequence of that epitope. Possible explanations for differences in the levels of TCR diversity among T cells responding to an epitope present in a nominal antigen as compared to T cells responding to linear peptide antigens containing this same epitope are discussed.

Suppression of IgE production in mice treated with a traditional Chinese medicine, bu-zhong-yi-qi-tang (Japanese name: hochu-ekki-to)

The ability of a traditional herbal medicine, Bu-zhong-yi-qi-tang (Japanese name: Hochu-ekki-to, HOT), to suppress IgE production was investigated. BALB/c mice were intraperitoneally immunized with aluminium hydroxide adsorbed with DNP-KLH (DNP-KLH + alum). When oral administration of HOT was begun just after immunization, the serum level of antigen-specific IgE was significantly decreased, although those of antigen-specific IgG1 and IgG2a were not influenced. In the culture of spleen cells obtained 14 days after immunization with DNP-KLH, antigen-specific IgE and IgG1 production by the cells of the HOT-treated mice was significantly suppressed compared to that in immunized mice. Furthermore, in the combination culture with CD4+ T cells and B cells separated from spleen cells, IgE production by the cells from immunized mice was inhibited by replacement of their corresponding cell population with either CD4+ T cells or B cells of HOT-treated mice. Additionally, production of interleukin 2 (IL-2) and IL-4 was significantly suppressed in HOT-treated mice but not that of IFN-gamma in comparison to the immunized mice. These results suggested that HOT decreased the IgE level in serum by inhibiting the development of IL-4-producing CD4+ T cells.

The potential role of gastroesophageal reflux in the pathogenesis of food-induced wheezing

Severe reactive airways disease (RAD) in children is frequently associated with gastroesophageal reflux or food allergy. However a relationship between these two confounding factors has yet to be investigated. We postulate that, in certain patients with micro-aspiration of gastric contents into the airways, food allergens sensitize T cells in the peribronchial lymphoid tissue and induce the production of food-specific IgE antibodies that sensitize airway cells. Subsequent exposure to these food allergens might then induce IgE dependent mediator release from mast cells as well as T cell and eosinophil activation, thus contributing to airway inflammation and RAD. In the current report, we describe the case of a patient with severe asthma who had food allergy and gastroesophageal reflux whose clinical findings support this hypothesis. We also provide additional evidence for a high rate of food sensitization in patients with bronchopulmonary dysplasia (BPD), RAD and GER. We conclude that additional studies are warranted to examine the possibility that patients who have RAD and GER require an evaluation for food allergy.

The relevance of murine animal models to study the development of allergic bronchial asthma

Bronchial asthma (BA) develops on the basis of a genetic predisposition and involves a characteristic sequence of changes in immune functions. In the immunopathogenesis, several phases can be distinguished: the initial stage is defined as the development of allergic sensitization. This step is dependent on: (i) T cell activation; (ii) IL-4 production; (ii) IgE synthesis; and (iv) mediator release by effector cells. The second phase of allergic inflammation as a consequence of the T cell dependent sensitization is characterized by IL-5 production and eosinophil activation and recruitment. Airway mucosa remodelling is the consequence of chronic inflammatory processes and represents the final stage of BA. In this article animal models will be discussed with regard to their relevance for these different phases in development of chronic allergic BA.

Murine animal models to study the central role of T cells in immediate-type hypersensitivity responses

The development of allergic sensitization and inflammation is dependent on activation and stimulation of T cells that exhibit pro-allergic functions. A mouse model system was developed to study the role of T cells in allergic sensitization in more detail. Local sensitization of mice stimulates an allergen specific IgE/IgG1 response that is associated with the development of immediate type skin test responses and increased airway responsiveness (AR). Strains of mice are identified that are high or low responder animals for allergens including ovalbumin and house dust mite. Each allergen stimulates a different pattern of T-cell receptor V beta expressing T cells in local draining lymph nodes. To induce a state of increased AR, at least two separate events are required. The first event is the presence of allergen specific IgE/IgG1. The second event is characterized as a local allergen challenge at the site of the response. These T cells play a critical role in the regulation of the allergic immune response including IgE production and increased AR. Based on these results intervention strategies can be developed which specifically target the development and function of these allergen specific T-cell populations and modify their pro-allergic activities.

Modification of immediate hypersensitivity responses by staphylococcal enterotoxin B

The staphylococcal enterotoxins have been termed superantigens based on their ability to stimulate polyclonal proliferative responses of murine and human T lymphocytes expressing particular T-cell receptor V beta gene products. Certain of these toxins have been shown both to activate and to induce anergy in reactive T cells. Staphylococcal enterotoxin B is known to interact with murine T cells bearing V beta 3, -7, -8.1, -8.2, -8.3, and -17. In BALB/c mice V beta 3+ and V beta 17+ T cells are deleted; V beta 7+ T cells are low in frequency. BALB/c mice sensitized to ovalbumin via the skin and airways develop immediate hypersensitivity including IgE/IgG1 antiovalbumin antibodies, immediate cutaneous reactivity to ovalbumin and, increased airway responsiveness. In both in vitro and in vivo studies, the development of these responses has been associated with the V beta 8+ subset of T cells and controlled by V beta 2 + T cells. In view of the central role of V beta 8+ T cells in these responses, we tested the effects of staphylococcal enterotoxin B on the development of immediate hypersensitivity in this system. Intradermal injection of staphylococcal enterotoxin B prevented the development of these responses in the absence of a major deletion of V beta 8+ T cells. The data suggest that the administration of staphylococcal enterotoxin B prevented the antigen-induced expansion of V beta 8+ T cells resulting in a state of responsiveness or anergy, thus preventing the manifestations of immediate hypersensitivity. Bacterial toxins may provide a novel approach to intervention in allergic or autoimmune diseases.

T cell receptor genetics, autoimmunity and asthma

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The central rôle of T-cells in allergic sensitization and IgE regulation

The atopic phenotype develops on the basis of a genetic predisposition. Several candidate genes and chromosomal regions have been recently identified that may play a rôle in the development of allergic sensitization and total IgE production, including genes encoding MHC and T-cell receptor (TCR) molecules, cytokines and others. Genetic predisposition triggers and immunological dysregulation which is controlled by CD4+ T-cells. (Specialized) antigen presenting cells process and present allergenic peptides (T-cell epitopes) on MHC class II molecules to T-cells that recognize MHC plus peptide using the TCR. Cognate and non-cognate interaction results in T-cell activation. Selective stimulation of the allergen specific T-cells is the result of allergen-specific sensitization. These T-cells are characterized by (simultaneous) production of IL-3, IL-4, IL-5 (and may be IL-13). These cytokines control the production of IgE by B cells and play a critical rôle in the activation and differentiation of effector cells of the allergic response (such as eosinophils and mast cells). In addition to MHC-TCR interaction and cytokine production, ligation of CD40 and CD40L represents an additional requirement for the production of functional IgE molecules. Immediate hypersensitivity responses are characterized by an early phase response (triggered by many mediators released from effector cells following allergen exposure, IgE cross-linking and activation of signal transduction pathways) and a late phase response that is mediated to a large extend by the influx of T-cells and effector cells into the site of allergic inflammation. Deliniation of the immunological mechanisms that result in allergic sensitization will contribute to the development of specific immunomodulatory strategies aimed to prevent the development of allergies.

T cell receptor-V beta repertoire in allergen-specific sensitization and increased airway responsiveness

An animal model system was developed to study the mechanisms resulting in allergic sensitization. Local allergen exposure via the airways and the lung stimulated an allergen-specific immunoglobulin E (IgE) response that was paralleled by the development of increased airway responsiveness (AR). It was found that CD4+ T cells of local draining lymph nodes played an important role in the regulation of these events. Stimulation of allergen-specific T cells requires interaction between major histocompatibility complex (MHC) class II molecules (expressed on antigen-presenting cells), peptide (presented on MHC) and the T cell receptor. Allergen sensitization stimulated T cells that expressed a restricted T cell receptor V beta (TCR-V beta) elements. Each allergen stimulated different V beta elements, and sensitization to the same allergen resulted in a different pattern of TCR-V beta stimulation in different lymphoid tissues. Some of these T cells had pro-allergenic effects, whereas others were able to inhibit the development of the allergic response, including the development of increased AR. These data indicate that the local T cell response regulates the type of immune response that evolves following local allergen sensitization.

Inhibition of the development of immediate hypersensitivity by staphylococcal enterotoxin B

We investigated the ability of staphylococcal enterotoxin B (SEB) to modify the immediate hypersensitivity response induced in BALB/c mice following sensitization to ovalbumin (OVA), a response mediated by OVA-reactive V beta 8 T cells. Mice were sensitized by skin painting with OVA every second day over a period of 2 weeks. SEB, a potent activator of V beta 8+ T cells, was administered at the same site where OVA was applied (skin of the lower abdomen) following two different protocols. In protocol (A) SEB was injected intradermally 1 day before painting with OVA and on day 7; in protocol B, SEB was injected each time OVA was applied to the skin (eight times). SEB (but not SEA) altered the development of immediate hypersensitivity to OVA, as demonstrated by the reduction in allergen-specific IgE, decreased OVA-specific immediate skin test responsiveness, and prevented the development of increased airways responsiveness after bronchial challenge with OVA. Injections of SEB did not alter the proliferative responses of local draining lymph node cells or spleen mononuclear cells to OVA, indicating that administration of SEB did not inhibit the sensitization of OVA, but shifted the immune response away from an immediate type response (IgE/IgG1) to IgG2a, IgG2b and IgG3. Although both protocols of SEB treatment did not lead to a major deletion of the V beta 8 T cell population, they did reduce the proliferative response of V beta 8+ T cells to OVA. These data indicate that the bacterial toxin SEB is capable of modifying the immediate hypersensitivity response induced by OVA by altering the functional capacity of antigen-reactive V beta 8 T cells.

Flexibility of the T cell receptor repertoire

Alternative T cell receptor (TcR) gene usage between mice of different Mls alleles has been demonstrated in a number of T cell responses. A clear illustration of a flexible TcR V beta usage in the same strain of mice remains to be established. Using a model system in which I-Ek-restricted T cells recognizing lambda repressor cI protein (cI) 12-26 and pigeon cytochrome c (pcc) 81-104 predominantly use V beta 3 in B10.A and B10.BR mice, and V beta 1 in Mls-2a-bearing A/J and C3H mice, we have first demonstrated that the hierarchy of TcR V beta usage can not be inferred from one strain of mice to the other. The presumed flexibility of V beta 3 to V beta 1 did not exist in B10.BR mice in the given responses. Instead, a switch of dominant TcR from V beta 1/V beta 3 to V beta 8 was identified in C3H and B10.BR mice. In contrast, there was an absolute rigidity in TcR repertoire usage in some mouse strains such as A/J. The lack of flexibility was not due to slow generating kinetics of replacing T cells; since A/J mice treated with staphylococcal enterotoxin A from birth on still responded poorly to cI 12-26 and pcc 81-104. Therefore, whether TcR V beta usage in a T cell response would be flexible or rigid is highly dependent on each strain of mice. However, even the plasticity seen in B10.BR mice is very limited and further tolerance of the V beta 8+ population results in non-responsiveness toward the given antigens.

House dust mite allergy: from T-cell epitopes to immunotherapy

CD4+ T-lymphocytes induce and regulate allergic inflammatory responses to common environmental aeroallergens derived from Dermatophagoides spp. (house dust mite, HDM), which cause clinical symptoms in approximately 10% of the population. Definition of the molecular structure of HDM proteins combined with the ability to isolate monoclonal populations of human CD4+ T-cells representative of the 'interleukin-4 (IL-4) dominant' functional phenotype, which support immunoglobulin E (IgE) synthesis, has allowed T-cell recognition of HDM to be examined in detail. The results of these investigations demonstrated extensive heterogeneity in both the antigen and HLA class II restriction specificity of the HDM reactive T-cell repertoire. Furthermore, long-lived clones of T-cells with oligoclonality in T-cell antigen receptor (TcR) usage, driven by chronic stimulation with HDM, have been identified in human peripheral blood. The presentation of specific peptides and superantigens under conditions that induce T-cell non-responsiveness has provided an in vitro model for analysing the mechanisms of CD4+ T-cell targeted immunotherapy. It appears that the mechanisms underlying T-cell anergy are accompanied by a transient downregulation of TcR and CD28 and mediated by a shift in the cytokine profile from that of the 'IL-4 dominant' to the 'interferon-gamma (IFN-gamma) dominant' functional phenotype of CD4+ T-cells. In parallel, using a murine model, it has been demonstrated that administration of an immunodominant peptide via the mucosal surfaces of the respiratory and alimentary tracts may tolerize an established response to intact HDM proteins. The potential application of these models in the development of novel approaches to immunotherapy is discussed.

T cells expressing specific V beta elements regulate immunoglobulin E production and airways responsiveness in vivo

The role of T cells expressing specific V beta elements was examined in the regulation of allergen-specific immunoglobulin (Ig)E production and airways responsiveness (AR). In BALB/c mice, inhalation of the allergen ovalbumin (OVA) induced an IgE anti-OVA response, immediate cutaneous reactivity, and increased AR. These results were associated with an expansion of V beta 8.1/8.2 T cells in local draining lymph nodes of the airways and the lung. Transfer of V beta 8.1/8.2 T cells from sensitized mice stimulated an IgE anti-OVA response, immediate cutaneous hypersensitivity, and increased AR in naive syngeneic recipients. In contrast, OVA-reactive V beta 2 T cells inhibited these effects. These data demonstrate for the first time that T cells with different V beta specificities play a critical role in the in vivo regulation of allergen-specific IgE production and AR.