Induction of oral tolerance in splenocyte-reconstituted SCID mice

Breakdown of mucosal immunity in gut by 2,3,7,8-tetraclorodibenzo-p-dioxin (TCDD)

OBJECTIVES

Mucosal immunity plays a pivotal role for body defense against infection and allergy. The aim of this study was to clarify the effects of 2,3,7,8-tetraclorodibenzo-p-dioxin (TCDD) on mucosal immunity in the gut.

METHODS

Fecal IgA level and oral tolerance induction were examined in TCDD-treated mice. Flow cytometric and histological analyses were also performed.

RESULTS

Single oral administration of low dose 2,3,7,8-TCDD resulted in a marked decrease in IgA secretion in the gut without any effects on the cellular components of gut-associated lymphoid tissues (GALT) including Peyer's patches (PPs) and mesenteric lymph nodes (LNs). Decressed IgA secretion by TCDD was not observed in aryl hydrocarbon receptor (AhR)-deficient mice. Flow cytometric analysis revealed that IgA B cells in PPs and the mesenteric LNs remained unchanged in the TCDD-treated mice. An immunofluorescence study also demonstrated that a significant number of cytoplasmic IgA cells were present in the lamina propria of the gut in the TCDD-treated mice. Furthermore, oral tolerance induction by ovalbumin (OVA) was impaired in the TCDD-treated mice and OVA-specific T cell proliferation occurred in the peripheral lymphoid tissues including the spleen and LNs.

CONCLUSIONS

These results suggest that a relatively low dose of TCDD impairs mucosal immunity in the gut and induces systemic sensitization by oral antigens.

Suppression of Th1 and Th17, but not Th2, responses in a CD8(+) T cell-mediated model of oral tolerance

The role of CD8(+) T cells in oral tolerance remains unclear. To address this, we developed a model to induce CD8(+) Tregs by feeding the major histocompatibility complex class I immunodominant epitope of OVA, OVA((257-264)). OVA((257-264)) feeding induced tolerance similar to that observed in OVA protein-fed mice, capable of suppressing the production of Th1 and Th17 cytokines and inhibiting a Th1-driven delayed-type hypersensitivity response following immunization with whole OVA (wOVA) protein. OVA((257-264)) peptide-induced suppression could be transferred to naive mice with CD8(+) cells, but not CD8-depleted cells, isolated from mesenteric lymph nodes of peptide-fed mice. Interestingly, while capable of inhibiting Th1 and Th17 responses, OVA((257-264)) feeding could not suppress any feature of a Th2 inflammatory response, though OVA protein feeding could, suggesting that these cells function through a different mechanism than their CD4(+) counterparts generated in response to feeding with wOVA. Thus, CD8(+) T cells are functionally capable of mediating tolerance to Th1 and Th17 responses.

The "Microflora Hypothesis" of allergic disease

Predisposition to allergic disease is a complex function of an individual's genetic background and, as is the case with multi-gene traits, environmental factors have important phenotypic consequences. Over a span of decades, a dramatic increase in the prevalence of allergic disease in westernized populations suggests the occurrence of critical changes in environmental pressures. Recently, it has been shown that the microbiota (i.e. microflora) of allergic individuals differs from that of non-allergic ones and that differences are detectable prior to the onset of atopy, consistent with a possible causative role. Features of the westernized lifestyle that are known to alter the microbiota, such as antibiotics and diet, are also associated with allergy in humans. In this chapter, we discuss the "Microflora Hypothesis" for allergy which predicts that an "unhealthy" microbiota composition, now commonly found within westernized communities, contributes to the development of allergy and conversely, that restoring a "healthy" microbiota, perhaps through probiotic supplementation, may prevent the development of allergy or even treat existing disease. In testing this hypothesis, our laboratory has recently reported that mice can develop allergic airway responses if their microbiota is altered at the time of first allergen exposure.

Breakdown of mucosal immunity in the gut and resultant systemic sensitization by oral antigens in a murine model for systemic lupus erythematosus

Secreted IgA plays a pivotal role in the mucosal immunity to maintain the front line of body defense. We found that the level of fecal IgA was dramatically decreased in aged (NZB x NZW)F(1) (BWF(1)) mice developing lupus nephritis, whereas levels in similarly aged New Zealand Black (NZB) and New Zealand White (NZW) mice remained unchanged compared with young mice. The number of cells obtained from Peyer's patches was markedly decreased in aged BWF(1) mice. Aged BWF(1) mice showed increased susceptibility to pathogenic bacterial infection. Furthermore, oral administration of OVA failed to inhibit secondary IgG response induced by systemic immunization, suggesting defective oral tolerance in aged BWF(1) mice. A significant amount of orally administered OVA was incorporated directly into the intestinal lamina propria in aged BWF(1) mice whereas it was mainly localized in subepithelial domes and interfollicular region in Peyer's patches in young mice. T cells obtained from renal and pulmonary lymph nodes of aged BWF(1) mice that had been orally administered with OVA showed an Ag-specific T cell proliferation, whereas those from young BWF(1), aged NZB, and aged NZW mice did not. Interestingly, aerosol exposure to OVA of aged BWF(1) mice, which had been orally administered with the same Ag, provoked an eosinophil infiltration in the lung. These results demonstrate that mucosal immunity in the gut is impaired and oral Ags induce systemic sensitization instead of oral tolerance in the development of murine lupus.

Continuous nasal administration of antigen is critical to maintain tolerance in adoptively transferred autoimmune arthritis in SCID mice

Mucosal tolerance is a natural mechanism that prevents immunological reactions to antigens by altering the activity of immune cells of pathogenic clones without modulating the entire immune system. This 'natural immune suppression' can be exploited when antigen(s) of the target organ in an autoimmune disease is used for mucosal treatment. Being inspired by the experimental results in animal models, clinical trials using type II collagen for mucosal treatment have been conducted in rheumatoid arthritis. High-density proteoglycan (aggrecan) is another major macromolecular component in articular cartilage, and may be a candidate autoantigen for provoking immune reactions in patients with rheumatoid arthritis. Indeed, like type II collagen, systemic immunization of genetically susceptible mice with proteoglycan (PG) aggrecan induces progressive autoimmune polyarthritis. Here, we investigated whether intranasally applied PG can be effective in suppressing PG-induced arthritis (PGIA) in BALB/c mice. We found that nasal administration of 100 microg PG exerted a strong suppressive effect on both the incidence and severity of the disease, most probably by reducing responsiveness towards the immunizing PG antigen. When we transferred PGIA into genetically matched but immunodeficient SCID mice, we were able to establish a tolerized state, but only if the recipient SCID mice received lymphocytes from tolerized animals and intranasal treatment with PG was continued. Without nasally administered antigen, the transferred anergic cells recovered and arthritis rapidly developed in a severe form. Intranasal PG treatment of recipient SCID mice was ineffective when cells from non-tolerized arthritic donors were transferred, in which case the regular weekly 'tolerizing' dose of PG made the disease worse. Our results suggest that mucosal treatment in an already existing disease may result in paradoxical outcomes.

Basic mechanisms and clinical implications of oral tolerance

Oral tolerance is the physiologic mechanism that prevents hypersensitivity to food proteins and probably to commensal bacteria. It has also attracted attention as a means of administering therapy for autoimmune and inflammatory diseases. Although evidence indicates that both clonal inactivation and active regulatory mechanisms may play a role and that the induction of these may be determined selectively by the feeding regimen used to induce tolerance, the exact mechanisms of oral tolerance remain unclear. Here, we discuss recent evidence that fed antigens are presented to CD4(+) T cells by antigen-presenting cells (APCs) that lack costimulatory activity, resulting in partial activation of T cells followed by a state of unresponsiveness. This seems to occur in many tissues of the immune system but may be particularly important in the draining mesenteric lymph node. Resting dendritic cells may be the predominant population of APCs involved in oral tolerance, and conditions that activate dendritic cells allow the induction of productive immunity. Conventionally, presentation of antigen in the absence of costimulation is thought to induce T-cell anergy, but evidence now indicates that anergic T cells can also act as regulatory cells via the production of inhibitory mediators or via cognate interactions with APCs and other T cells. We discuss how an ability to deactivate APCs may explain bystander suppressor activity in oral tolerance, and we consider how the production of transforming growth factor-beta or interleukin-10 by Th3 or T regulatory 1 cells may contribute to tolerance in vivo. We speculate that both the production of inhibitory mediators and the delivery of suppression via cognate interactions may be properties of otherwise "anergic" T cells.

Autoreactive CD4+ T cells protect from autoimmune diabetes via bystander suppression using the IL-4/Stat6 pathway

Targeted immune regulation can be achieved by use of tissue-specific T cells and offers the potential for organ-specific suppression of destructive autoimmune processes. Here, we report the generation and characterization of insulin B chain-specific "autoreactive" CD4+ regulatory T cells that locally suppress diabetogenic T cell responses against an unrelated self-antigen (viral transgene) in a virus-induced model for type 1 diabetes. Interleukin 4 (IL-4) is essential for prevention of diabetes since regulatory T cells cannot be induced in the absence of IL-4 or stat6 (IL-4 signaling pathway). Our observations demonstrate that autoreactive regulatory T cells can suppress autoreactive destructive T cell activity of differential antigenic specificity locally in the pancreatic draining lymph node, probably via cytokine-mediated modulation of antigen-presenting cells.