Notch signalling in the regulation of peripheral immunity.

Notch signalling plays a critical role in embryogenesis, influencing the differentiation and growth of a variety of cell types across the species. In the mammalian immune system, Notch signalling operates at various levels; it controls the differentiation of haematopoietic stem cells and directs the early development of the T and B-cell lineages. It is also involved in the maturation of both CD4+ and CD8+ T cells in the thymus. The biological activities of this pathway extend beyond lymphocyte ontogeny; recent evidence has shown that it also contributes to the regulation of the peripheral immune system through its ability to influence cell survival and growth. In fulfilling this function, Notch signalling appears to act in conjunction with defined immunological signals such as cytokines, T-cell antigen receptor and co-stimulatory receptor-mediated signalling. In this review we discuss the potential of the Notch signalling pathway in the maintenance of homeostasis within the immune system affecting both peripheral tolerance and the negative feedback controlling productive immunity. The therapeutic manipulation of this pathway is likely to have broad application in a range of immunologically based diseases.

Immunological tolerance to inhaled antigen.

Regulatory mechanisms exist in the immune system to limit the induction of pathogenic responses to antigens encountered within the respiratory tract. The development of allergic disease is thought to arise as a result of the breakdown in these regulatory processes. In this review we examine the nature of immune responses generated to inhaled protein antigens and the mechanisms used to establish tolerance to inhaled antigens.

T-cell regulation of peripheral tolerance and immunity: the potential role for Notch signalling.

Recognition of antigen by T cells in the periphery may lead either to the generation of productive immunity or the induction of tolerance. These two functional outcomes are a consequence of distinct pathways of T-cell differentiation. T cells are selected to become regulatory cells and their function is to maintain homeostasis with the immune system. In this review we discuss the cell-fate decisions that T cells might make allowing them to promote immunity or induce tolerance in the context of the role that Notch signalling may play in this process.

Serrate1-induced notch signalling regulates the decision between immunity and tolerance made by peripheral CD4(+) T cells.

Signals derived from antigen-presenting cells (APC) influence the functional differentiation of CD4(+) T cells. We report here that Serrate1 (Jagged1), a ligand for the Notch1 receptor, may contribute to the differentiation of peripheral CD4(+) T cells into either helper or regulatory cells. Our findings demonstrate that antigen presented by murine APC overexpressing human Serrate1 induces naive peripheral CD4(+) T cells to become regulatory cells. These cells can inhibit primary and secondary immune responses, and transfer antigen-specific tolerance to recipient mice. Our results show that Notch signalling may help explain 'linked' suppression in peripheral tolerance, whereby tolerance induced to one epitope encompasses all epitopes on that antigen during the course of an immune response.

Linked suppression in peripheral T cell tolerance to the house dust mite derived allergen Der p 1.

BACKGROUND: Peripheral tolerance is required to maintain balance within the immune system. A feature of peripheral tolerance is linked suppression, in which tolerance induced to a single T cell epitope inhibits the response to all epitopes in the same protein. It is suggested that this phenomenon is mediated by regulatory T cells through either the activity of immunopressive cytokines or direct cell contact. In previous experiments we failed to detect inhibitory cytokines when T cells from mice rendered tolerant by intranasal delivery of the immunodominant peptide of Der p 1 (p 1, 110-131) were restimulated with peptide in vitro. Therefore, the aim of this study was to determine if cognate interactions between T cells mediated by Notch/Delta signaling induce and maintain peripheral T cell tolerance. METHODS: Using in situ hybridization and viral mediated gene transfer, the expression and function of Delta1 were investigated in a murine model of T cell tolerance to Der p 1 in vivo. RESULTS: Delta1 expression is increased on peripheral T cells during the induction of tolerance with high-dose peptide delivered intranasally and when tolerant animals are rechallenged under immunogenic conditions. Peptide p 1, 110-131-specific CD4+ T cells transfected with Delta1 inhibited the response of antigen-primed T cells and induced linked suppression. CONCLUSIONS: High-dose peptide delivered intranasally induces transient expression of Delta 1 on inhibitory CD4+ T cells. Ligation of the Notch1 receptor on neighbouring T cells by Delta1+ regulatory T cells inhibits clonal expansion of the former and mediates linked suppression.

Induction of tolerance via the respiratory mucosa.

Immunological tolerance is defined as a state of specific non-responsiveness to a particular antigen induced by previous exposure to that same antigen. The mucosal surfaces comprise the upper and lower respiratory tracts, the gastrointestinal tract and the urogenitary tract, and are a major site of antigenic challenge. The immune system associated with the mucosa has the extraordinary potential to discriminate between antigens that are harmless (e.g. inhaled and dietary antigens) and those that are associated with pathogens. Normally soluble proteins delivered through the mucosal surfaces do not elicit a strong systemic immune response but instead induce a transient local immune response that is replaced by long-term peripheral unresponsiveness this is termed mucosal tolerance. The phenomenon of oral tolerance is well established and considerable attention has focussed on defining the underlying mechanisms. However, only comparatively recently was the induction of tolerance via the respiratory mucosa described, and it is this form of mucosal tolerance which forms the basis of this review.

The T cell surface protein, CD28.

The cluster of differentiation (CD) antigen CD28 is a 44-kDa, disulphide-bonded, homodimeric glycoprotein, which is constitutively expressed on the surface of all murine T cells and the majority of human T cells. Ligation of CD28 by its counter receptor, B7, expressed on the surface of antigen presenting cells, has been shown to induce signals that, in synergy with those derived from engagement of the T cell receptor by an antigen bound to a major histocompatibility complex, enhance proliferation and cytokine production. Manipulation of this interaction can have dramatic effects on the outcome of T cell activation. Blocking CD28/B7 interactions may be useful in preventing unwanted activation in allergy and autoimmune diseases, whereas enhancing this interaction can promote tumour rejection. Thus, CD28 and its signalling pathways may prove to be useful targets in the development of new therapeutic treatments.

Characterization of the specificity and duration of T cell tolerance to intranasally administered peptides in mice: a role for intramolecular epitope suppression.

Mucosal administration of antigens in experimental animals leads to the induction of peripheral T cell tolerance. We have previously reported that in H-2b mice, intranasal (i.n.) or oral administration of a peptide containing the immunodominant T cell epitope will down-regulate the function of CD4+ T cells reactive with Der P 1, a major target antigen in both B and T cell responses to house dust mite. In the present study we have investigated the tolerogenicity of peptides containing both dominant and subdominant determinants when given i.n. to nalve mice. Induction of tolerance by the nasally administered immunodominant peptide leads to a diminution in all T cell-derived cytokines and modulation of delayed-type hypersensitivity responses, but IgE production did not seem to be affected, furthermore the induction of T cell tolerance was stable, lasting beyond 6 months. We have also examined the specificity of intramolecular epitope suppression which is a feature of mucosal tolerance induced by nasally administered peptides and demonstrate that regulatory CD4+ T cells may exert their suppressive effect by linked recognition of epitopes on the same or neighbouring antigen-presenting cells.

Regulation of T cell function in mucosal tolerance.

Administering antigens through mucosal surfaces leads to the induction of antigen-specific T cell unresponsiveness. This property of the mucosal immune system is now beginning to be exploited in the design of immunotherapeutic strategies aimed at targeting disease-inducing T cell populations. The induction of high dose mucosal tolerance leads to the induction of T cell anergy. Recent studies have suggested that the induction of anergy in vivo may not necessarily be due to a lack of costimulation by APC. Instead, recognition of mucosal antigen leads to transient T cell activation which eventually gives rise to a population of regulatory T cells whose function is to modulate, rather than promote antigen-specific immune responses. These regulatory T cells mediate linked suppression in vivo thus enabling T cell responses directed to a multideterminant protein to be effectively controlled. The manner in which T cell responses to mucosally delivered antigens are regulated are examined herein.

Prediction of murine MHC class I epitopes in a major house dust mite allergen and induction of T1-type CD8+ T cell responses.

The group I (Der p 1) allergen of Dermatophagoides pteronyssinus (house dust mite, HDM) contains several T helper (Th) epitopes recognized by C57BL/6 mice, with the peptide (111-139) containing a dominant MHC class II-restricted epitope (113-127). Since CD8+ T cells are thought to play a role in the regulation of allergic disease, we examined the Der p 1 sequence for potential MHC class I-binding motifs and observed that residues 111-119 (FGISNYCQI) contain motifs for H-2Db and Kb. Furthermore, immunization of C57BL/6 mice with unadjuvanted Ty virus-like particles (VLP) carrying Der p 1 (111-139), a method known to induce murine cytotoxic T lymphocyte (CTL) responses, primed Der p 1 (111-119)-specific Db-restricted CTL which produce high levels of IFN-gamma and low levels of IL-5 and IL-6 in vitro (T1-type CTL). VLP carrying the minimal epitope (FGISNYCQI) also induced a CTL response following immunization without adjuvant by various routes. Der p 1 (111-139)-VLP adjuvanted with alum did not prime CTL in C57BL/6 mice but were found to prime Th1-type CD4+ T cells that recognize the overlapping peptide (113-127) and native protein. The ability to successfully predict allergen-specific CD8+ T cell epitopes and prime CD8+ and/or CD4+ T cell responses provides an opportunity to dissect the relative roles of these T cells in the regulation of allergic responses and may offer therapeutic potential for reprogramming Th2-type allergic responses.

Induction of T cell responses to the invariant chain derived peptide CLIP in mice immunized with the group 1 allergen of house dust mite.

In this study we demonstrate that immunization of H-2(b) mice with the allergen Der p 1 induces MHC class II restricted T cells that proliferate to residues 15-29 of Der p 1 (p15-29) and to the murine MHC class II-associated invariant chain derived peptide (CLIP). T cells from naive H-2(b) mice and those immunized with murine CLIP fail to respond to either CLIP or p15-29. T cell lines and clones reactive with p15-29 strongly proliferate in response to splenic antigen-presenting cells (APC) from normal H-2(b) mice but show reduced proliferation to APC from invariant chain deficient mice. Furthermore, T cells isolated from Der p 1 primed mice and expanded on H-2(b) spleen cells in the absence of the p15-29 epitope retained specificity for both p15-29 and CLIP, suggesting that naturally presented self components can act as mimetic peptides and may maintain T cell memory to foreign antigens.

Peptide-mediated regulation of the allergic immune response.

A major key to successful immunotherapy may depend on altering the qualitative nature of the immune response in allergic patients. In this review we examine how immune responses to environmental allergens are regulated, and the mechanisms used by the immune system to prevent allergic sensitization. We also discuss future prospects of using allergen-derived peptides in immunotherapy and the possibility of 'reprogramming' the immune responses by immunizing under conditions that promote Th1 responses instead of Th2 responses.

Regulation of house dust mite responses by intranasally administered peptide: transient activation of CD4+ T cells precedes the development of tolerance in vivo.

We have previously demonstrated that intranasal (i.n.) administration of an immunodominant peptide (p1-111-139) derived from the house dust mite (HDM) allergen Der p 1 inhibits antigen-specific CD4+ T cell responses in H-2b mice. Here we report that i.n. peptide induced a rapid but transient activation of MHC class II restricted CD4+ T cells that peaked 4 days after peptide treatment and was of similar magnitude to that induced by parenteral immunization with antigen in adjuvant. During the early phase of the response lymph node and splenic T cells secreted a range of lymphokines when re-stimulated in vitro with p1 111-139; however, by day 14 IL-2 and IFN-gamma secretion by T cells were down-regulated. Mice deficient in CD8+ T cells became tolerant by i.n. treatment with peptide, suggesting that CD8+ T cells are not involved in down-regulating the CD4+ T cell response. Rechallenging mice with a single dose of p1 111-139 21 days after the initial treatment elicited a further transient T cell response, which was subsequently down-regulated over time. Although the i.n. peptide induced a strong transient CD4+ T cell response, only low levels of peptide-specific antibodies were detected either after the initial or subsequent i.n. exposures to p1 111-139. Our findings address the mechanisms underlying peripheral T cell tolerance following i.n. administration of a high dose of immunogenic peptide and have implications for understanding the consequences of peptide immunothearapy.

Peptide modulation of allergen-specific immune responses.

In vitro peptide stimulation of allergen-reactive T-helper type 1 and type 0 cells, in the absence of costimulatory signals, induces anergy that is accompanied by the modulation of cell surface phenotype and changes in cytokine production. In experimental animal models, the administration of allergen-derived peptides may result in the downregulation of cytokine and antibody production, which is preceded by transient activation of CD4+ T cells, without the induction of effector immunity. Preliminary results of clinical trials using allergen-derived peptides for desensitization are becoming available and should provide some insight into the efficacy of peptide therapy in man.

Peptide-mediated immunoregulation.

Quantitative and qualitative characteristics of the signals received by a T cell determine whether receptor ligation results in cell activation, cell death, or the induction of antigen-specific non-responsiveness. Environmental factors such as the nature of costimulation, antigen-presenting cell type, peptide structure and cytokine levels also influence the differentiation of CD4+ helper T cells into functionally distinct subsets, which now appear pivotal in many immune-mediated disorders, including autoimmunity and allergy. Selective manipulation of the immune response, such as the functional inactivation or deviation of the cytokine secretion patterns of specific T cells, may be an effective strategy for immunotherapy.

T-cell responses to orally administered antigens. Study of the kinetics of lymphokine production after single and multiple feeding.

Mice fed a protein antigen develop a phenomenon called oral tolerance which is defined classically by the inability to respond to a parenteral challenge with the same antigen. In a recent report we showed that antigen-reactive T cells are not depleted following the development of oral tolerance to the soluble antigen ovalbumin (OVA). Instead mice remain highly sensitized so OVA-reactive T cells can be detected in the mesenteric lymph nodes (MLN), Peyer's patches and spleen. In the present study we show that OVA-specific T cells become sensitized in the MLN within 24 hr of feeding and that lymphokine responses peak 48-96 hr after feeding. T cells produced large amounts of granulocyte-macrophage colony-stimulating factor (GM-CSF) and interferon-gamma (IFN-gamma) but no interleukin-2 (IL-2) following activation in vitro. Responsiveness as measured by GM-CSF declined by days 8-11 while the ability to stimulate IFN-gamma secretion was more persistent. It was found in experiments with repeated feeding, 1 week apart, that the T-cell responsiveness was restimulated after each feed and that the magnitude and duration of the IFN-gamma or GM-CSF responses were almost identical to primary, even after 10 feeds.

Inhibition of T-cell responses by feeding peptides containing major and cryptic epitopes: studies with the Der p I allergen.

H-2b mice respond to the 222 residue allergen Der p I by producing T cells sensitized to the dominant epitopes encompassed in peptides 21-49, 78-100, 110-131 and 197-212. Immunization with the synthetic peptides 120-143 and 144-169, however, revealed cryptic epitopes which could sensitize T cells for responses to the respective peptides and, providing splenic adherent cells were added to lymph node cultures, to the whole allergen. It is shown that feeding recombinant fusion peptides can markedly inhibit the ability of the whole antigen to immunize mice, as measured by the in vitro interleukin-2 (IL-2) and granulocyte-macrophage colony-stimulating factor (GM-CSF)/IL-3 release on stimulation with protein or peptides, although inhibition measured by IL-2 release was more marked. The inhibition extended to epitopes other than those in the fusion peptides used for feeding. Thus feeding peptide 101-154 inhibited responses to 110-131 and 78-100. Fusion peptides 1-14 and 188-222 did not inhibit responses, although 188-222 did contain an epitope. Inhibition was also obtained when mice were fed a fusion containing the cryptic epitope 144-169. The ability of peptides containing the cryptic epitopes to inhibit responses has significant implications for peptide-based immunotherapy.

Differences in epitopes recognized by T cells during oral tolerance and priming.

Feeding protein antigens to mice normally leads to the development of oral tolerance but under some circumstances, feeding can lead to immunity, for example, following pretreatment of mice with cyclophosphamide (CY). In both cases, however, it is possible to detect sensitized T cells in the spleen and mesenteric lymph nodes (MLN) by in vitro lymphokine release for granulocyte-macrophage-CSF (GM-CSF) and IFN-gamma. This study examines the recognition of the immunodominant T cell epitope on ovalbumin (OVA) following intragastric priming and tolerance. T cells from CY/OVA treated mice and cells from mice injected subcutaneously with OVA in CFA responded well to both OVA and the H2d restricted peptide epitope pOVA323-339 releasing GM-CSF. On the other hand MLN or spleen T cells from tolerized mice which responded to the protein in vitro did not recognize the immunodominant determinant. The cells responding from tolerized mice were restricted by the class II MHC so these results show there can be differential recognition of T cell epitopes between oral priming and tolerance.