Germ-free condition and the susceptibility of BALB/c mice to post-thymectomy autoimmune gastritis

Induction of autoimmune gastritis by neonatal thymectomy requires autoantibodies and is prevented by anti-FcγR antibodies

The autoantibodies (auto-Abs) that are a hallmark of neonatally thymectomized (NTx) mice with autoimmune gastritis (AIG) have been poorly explored. We investigated their immune significance using B cell-deficient (B(-)) mice and found that B(-) mice are totally resistant to AIG but become susceptible to AIG after receiving bone marrow cells from B(+) mice. This susceptibility is most likely caused by the production of auto-Abs by B cells because B(-) pups also became susceptible to AIG when nourished by an AIG dam producing auto-Abs of the IgG class during the suckling period. NTx B(-) mice receiving purified IgG auto-Abs at this developmental stage similarly developed AIG. Auto-Abs probably act on antigen handling for antigen presentation because the treatment of NTx B(+) mice with anti-FcγR Abs prevented the development of AIG. Auto-Abs are indispensable for AIG development but are not sufficient because auto-Ab treatment did not increase AIG incidence in NTx B(+) mice above the baseline.

Genetic Control of Susceptibility to Autoimmune Gastritis

A familial component to the tendency to develop autoimmune gastritis has long been recognized. Although linkage to certain HLA alleles and an association with the endocrine autoimmune diseases thyroiditis and type 1 diabetes have been reported, little further progress has been achieved in clinical studies. In contrast, the mouse model of gastritis induced in the BALB/c strain by thymectomy in the third day of life has identified four linkage regions; two on distal chromosome 4 (Gasa1 and Gasa2), one on chromosome 6 (Gasa3) and one in the H2 (Gasa4). Three of these four genes colocalize with NOD mouse diabetes susceptibility genes--the strongest concordance identified to date between any two autoimmune diseases--reflecting the association between autoimmune diabetes and type 1 gastritis in humans.

CD4+CD45RBHi interleukin-4 defective T cells elicit antral gastritis and duodenitis

We have analyzed the gastrointestinal inflammation which develops following adoptive transfer of IL-4 gene knockout (IL-4(-/-)) CD4(+)CD45RB(Hi) (RB(Hi)) T cells to severe combined immunodeficient (SCID) or to T cell-deficient, T cell receptor beta and delta double knockout (TCR(-/-)) mice. Transfer of IL-4(-/-) RB(Hi) T cells induced a similar type of colitis to that seen in SCID or TCR(-/-) recipients of wild-type (wt) RB(Hi) T cells as reported previously. Interestingly, transfer of both wt and IL-4(-/-) RB(Hi) T cells to TCR(-/-) but not to SCID mice induced inflammation in the gastric mucosa. Notably, TCR(-/-) recipients of IL-4(-/-) RB(Hi) T cells developed a more severe gastritis with erosion, apoptosis of the antral epithelium, and massive infiltration of macrophages. This gastritis was partially dependent on the indigenous microflora. Recipients of both wt and IL-4(-/-) RB(Hi) T cells developed duodenitis with multinuclear giant cells, expansion of mucosal macrophages, and dendritic cells. Full B cell responses were reconstituted in TCR(-/-) recipients of RB(Hi) T cells; however, anti-gastric autoantibodies were not detected. We have now developed and characterized a novel model of chronic gastroduodenitis in mice, which will help in our understanding of the mechanisms involved in chronic inflammation in the upper gastrointestinal tract of humans.

A novel and effective approach of developing aggressive experimental autoimmune gastritis in neonatal thymectomized BALB/c mouse by polyinosinic:polycytidylic acid

Neonatal thymectomy induces autoimmune gastritis (AIG) in 40-70% of BALB/c mice. We presumed that induction of autoimmunity by polyinosinic:polycytidylic acid (poly I:C) might allow development of a more aggressive model of AIG. A group of BALB/c mice were thymectomized on day 3 after birth. Neonatal thymectomized mice were either injected with poly I:C or phosphate-buffered saline (PBS). Non thymectomized neonatal BALB/c mice were injected with only poly I:C. All neonatal thymectomized mice injected with poly I:C developed 3 cardinal features of AIG: (1) moderate to severe degree gastritis (2) presence of autoantibody to H(+)/K(+) ATPase and (3) loss of parietal cells. However, only 70% of the PBS-treated neonatal thymectomized BALB/c mice developed some, but not, all features of AIG. A mild degree of AIG was seen in 12 of 31 nonthymectomized BALB/c mice administered with only poly I:C. Administration of poly I:C in neonatal thymectomized BALB/c mice in the first and second week appeared to be the most effective for induction of aggressive AIG. The levels of interleukin (IL)-6, IL-12p70, interferon-gamma and tumour necrosis factor-alpha were significantly higher in poly I:C-injected thymectomized mice compared to PBS-injected neonatal thymectomized mice (P < 0.05). The frequencies of CD4(+)CD25(+) regulatory T cells in the spleen were significantly decreased in neonatal thymectomized mice administered with poly I:C compared to PBS-treated neonatal thymectomized mice (P < 0.01). Taken together, these results suggest that induction of inflammatory cytokines and reduction of regulatory T cells by poly I:C might contribute to the development of an aggressive model of AIG in neonatal thymectomized BALB/c mice.

Control of autoimmunity by naturally arising regulatory CD4+ T cells

Naturally acquired immunological self-tolerance is not entirely accounted for by clonal deletion, anergy, and ignorance. It is now well established that the T cell-repertoire of healthy individuals harbors self-reactive lymphocytes with a potential to cause autoimmune disease and these lymphocytes are under dominant control by a unique subpopulation of CD4+ T cells now called regulatory T cells. Efforts to delineate these Treg cells naturally present in normal individuals have revealed that they are enriched in the CD25+ CD4+ population. The identification of the CD25 molecule as a useful marker for naturally arising CD4+ regulatory T cells has made it possible to investigate many key aspects of their immunobiology, including their antigen specificities and the cellular/molecular pathways involved in their development and their mechanisms of action. Furthermore, reduction or dysfunction of the CD25+ CD4+ regulatory T cell population can be responsible for certain autoimmune diseases in humans.

The role of natural killer cells in the induction of autoimmune gastritis

A number of experimental models of organ-specific autoimmunity involve a period of peripheral T cell lymphopenia prior to disease onset. In particular, experimental autoimmune gastritis, induced in susceptible mouse strains by neonatal thymectomy, is a CD4+ T cell mediated autoimmune disease. We have previously demonstrated that this disease displays the hallmarks of a Th1-mediated DTH inflammatory response with an essential role for IFN-gamma very early in the pathogenesis of disease. Given the interplay between the innate and adaptive immune responses, a potential source of early IFN-gamma production in these lymphopenic mice is the innate immune response. Here we have assessed the contribution of innate immunity to the induction of experimental autoimmune gastritis, in particular, the role of natural killer (NK) cells in production of IFN-gamma. Analysis of NK cells and macrophages revealed no difference in either the number or activation status between euthymic and neonatally thymectomised mice. Furthermore, in vivo depletion of NK cells immediately after neonatal thymectomy of (BALB/cCrSlcxC57BL/6) F1 mice demonstrated no reduction in disease incidence compared to control groups of neonatally thymectomised mice. Therefore, we conclude that NK cells are not the primary source of IFN-gamma required for the pathogenesis of autoimmune gastritis following neonatal thymectomy but rather the small cohort of T cells in the periphery of lymphopenic mice are likely to be responsible for the IFN-gamma production.

Differential cytokine requirements for regulation of autoimmune gastritis and colitis by CD4(+)CD25(+) T cells

Murine autoimmune gastritis, induced by neonatal thymectomy or the injection of CD25-depleted lymphocytes into nu/nu recipients, is characterized by an inflammatory infiltrate into the gastric mucosa, parietal cell destruction and circulating anti-parietal cell antibodies. Using RAG-2(-/-)mice as recipients, we determined that the induction of disease relies on CD4(+)CD25(-)effector cells and prevention relies on CD4(+)CD25(+)regulatory cells; neither requires participation of CD8 cells or B cells. The severity of gastritis was dependent on the cytokine repertoire of CD4(+)CD25(-)effector T cells. Recipients of IL-4(-/-)T cells developed more severe gastritis and recipients of INF-gamma(-/-)T cells developed milder disease than recipients of wildtype or IL-10(-/-)effector T cells. Gastritis did not develop in the absence of IL-12. Protection from gastritis does not require either IL-4 or IL-10 because CD4(+)CD25(+)cells from IL-4(-/-)or IL-10(-/-)mice completely abrogated the disease process. CD4(+)CD25(+)cells also protected RAG-2(-/-)recipients from colitis and inhibitory activity was partially dependent on IL-10 expression. These findings highlight the critical role of CD4(+)CD25(+)regulatory T cells in protection from several autoimmune syndromes and delineate the differential contribution of IL-10 to CD4(+)CD25(+)Treg activity in the settings of gastritis and colitis.

Localization and characterization of antigen-presenting dendritic cells in the gastric mucosa of murine and human autoimmune gastritis

BACKGROUND

Activated CD4+ T cells and inflammatory cytokines are implicated in the pathogenesis of experimental autoimmune gastritis. However, there is a paucity of information about the cells that induce them. Antigen-presenting dendritic cells (DCs) play a cardinal role in the formation and survival of activated lymphocytes.

MATERIALS AND METHODS

Autoimmune gastritis was induced in neonatal BALB/c mice by thymectomy. DCs were detected in situ in the gastric mucosa from thymectomized mice and in patients with autoimmune gastritis, by immunohistochemistry and immunoelectron microscopy. The expression of MHC class II and CD86 antigens on DCs in the gastric mucosa and spleen was evaluated in dual-colour flow cytometry.

RESULTS

DCs were detected in the gastric mucosa of mice with autoimmune gastritis, and the number of DCs increased as the levels of gastritis became more severe as time passed following thymectomy. Flow cytometric analyses revealed that more than 60% of the DCs in the gastric mucosa had a mature phenotype (expressed MHC class II and/or CD86 antigens) both at 4 and 16 weeks after thymectomy. Activated and mature DCs were localized in the gastric mucosa from patients with autoimmune gastritis.

CONCLUSIONS

This is the first report on the localization and phenotypes of DCs in the gastric mucosa of autoimmune gastritis. The presence of mature DCs in the gastric mucosa of murine and human autoimmune gastritis, in spite of their absence in the gastric mucosa of normal mice, suggests that mature DCs play a role in the pathogenesis of autoimmune gastritis.

The Role of Environmental Antigens in the Spontaneous Development of Autoimmunity in MRL-lpr Mice

It has been proposed that the “normal” stimulation of the immune system that occurs from interactions with environmental stimuli, whether infectious or dietary, is necessary for the initiation and/or continuation of autoimmunity. We tested this hypothesis by deriving a group of MRL-lpr mice into a germfree (GF) environment. At 5 mo of age, no differences between GF and conventional MRL-lpr mice were noted in lymphoproliferation, flow cytometric analysis of lymph node cells (LN), or histologic analysis of the kidneys. Autoantibody levels were comparably elevated in both groups. A second experiment tested the role of residual environmental stimuli by contrasting GF mice fed either a low m.w., ultrafiltered Ag-free (GF-AF) diet or an autoclaved natural ingredient diet (GF-NI). At 4 mo of age, both groups showed extensive lymphoproliferation and aberrant T cell formation, although the GF-AF mice had ∼50% smaller LNs compared with sex-matched GF-NI controls. Autoantibody formation was present in both groups. Histologic analysis of the kidneys revealed that GF-AF mice had much lower levels of nephritis, while immunofluorescence analysis demonstrated no difference in Ig deposits but did reveal a paucity of C3 deposition in the kidneys of GF-AF mice.

These data do not support a role for infectious agents in the induction of lymphoproliferation and B cell autoimmunity in MRL-lpr mice. Furthermore, they suggest that autoantibodies do not originate from B cells that were initially committed to exogenous Ags. They do suggest a possible contributory role for dietary exposure in the extent of lymphoproliferation and development of nephritis in this strain.

Virus and Autoimmunity: Induction of Autoimmune Disease in Mice by Mouse T Lymphotropic Virus (MTLV) Destroying CD4+ T Cells

Neonatal infection of the mouse T lymphotropic virus (MTLV), a member of herpes viridae, causes various organ-specific autoimmune diseases, such as autoimmune gastritis, in selected strains of normal mice. The infection selectively depletes CD4+ T cells in the thymus and periphery for 2–3 wk from 1 wk after infection. Thymectomy 3 wk after neonatal MTLV infection enhances the autoimmune responses and produces autoimmune diseases at higher incidences and in a wider spectrum of organs than MTLV infection alone. On the other hand, inoculation of peripheral CD4+ cells from syngeneic noninfected adult mice prevents the autoimmune development. These autoimmune diseases can be adoptively transferred to syngeneic athymic nude mice by CD4+ T cells. The virus is not detected by bioassay in the organs/tissues damaged by the autoimmune responses. Furthermore, similar autoimmune diseases can be induced in normal mice by manipulating the neonatal thymus/T cells (e.g., by neonatal thymectomy) without virus infection. These results taken together indicate that neonatal MTLV infection elicits autoimmune disease by primarily affecting thymocytes/T cells, not self Ags. It may provoke or enhance thymic production of CD4+ pathogenic self-reactive T cells by altering the thymic clonal deletion mechanism, or reduce the production of CD4+ regulatory T cells controlling self-reactive T cells, or both. The possibility is discussed that other T cell-tropic viruses may cause autoimmunity in humans and animals by affecting the T cell immune system, not the self Ags to be targeted by the autoimmunity.

T lymphocyte-mediated control of autoimmunity

Autoreactive T cells can be readily identified in the peripheral lymphocyte pool of both humans and experimental animals. Peripheral tolerance may be maintained by regulatory/suppressor T cells which prevent the activation of autoantigen-specific cells. Mice thymectomized on day 3 of life (d3Tx) develop a wide spectrum of organ-specific autoimmune diseases. Reconstitution of d3Tx mice with CD4+ CD25+ T cells from normal mice prevents the development of disease. Similarly, CD4+ CD25+ T cells prevent the transfer of disease by autoantigen-specific cloned T cells derived from d3Tx mice. Thus, regulatory T cells can prevent both the induction and effector function of autoreactive T cells. In vitro, the CD4+ CD25+ population is anergic to stimulation through the T cell receptor (TCR) and suppresses the proliferative responses of normal CD4+ CD25- cells by a contract-dependent mechanism. Suppression is not MHC-dependent, but requires activation of the CD4+ CD25+ population. The mechanism of suppression in vivo and the target antigen(s) of this unique regulatory population remain to be characterized.

Effects of breeding environments on generation and activation of autoreactive B-1 cells in anti-red blood cell autoantibody transgenic mice

In anti-red blood cell autoantibody transgenic (autoAb Tg) mice almost all B cells are deleted except for B-1 cells in the peritoneal cavity and the gut. About one-half of the auto Ab Tg mice suffer from autoimmune hemolytic anemia (AIHA) in the conventional condition. Oral administration of lipopolysaccharides activates B-1 cells and induces autoimmune symptoms in the Tg mice, suggesting that the autoimmune disease in anti-RBC autoAb Tg mice is triggered by infections. To examine the association of bacterial infections with the generation of B-1 cells and the occurrence of the autoimmune disease, we analyzed anti-RBC autoAb Tg mice bred in germ-free and specific pathogen-free conditions. In germ-free conditions, few peritoneal B-1 cells were detected, while a significant number of peritoneal B-1 cells existed in specific pathogen-free conditions. In both conditions, no mice suffered from AIHA. However, when these Tg mice were transferred to the conventional condition or injected with lipopolysaccharide, peritoneal B-1 cells expanded and some of these mice suffered from AIHA. These results clearly showed that bacterial infections are responsible for both the expansion of B-1 cells and the onset of the autoimmune disease in these Tg mice.

Autoimmune disease as a consequence of developmental abnormality of a T cell subpopulation

Neonatal thymectomy (NTx), especially around day 3 after birth, causes various organ-specific autoimmune diseases in mice. This report shows that: (a) T cells expressing the interleukin 2 receptor alpha chains (CD25) ontogenically begin to appear in the normal periphery immediately after day 3, rapidly increasing within 2 wk to nearly adult levels (approximately 10% of CD3+ cells, especially of CD4+ cells); (b) NTx on day 3 eliminates CD25+ T cells from the periphery for several days; inoculation immediately after NTx of CD25+ splenic T cells from syngeneic non-Tx adult mice prevents autoimmune development, whereas inoculation of CD25- T cells even at a larger dose does not; and furthermore, (c) similar autoimmune diseases can be produced in adult athymic nu/nu mice by inoculating either spleen cell suspensions from 3-d-old euthymic nu/+ mice or CD25+ cell-depleted spleen cell suspensions from older, even 1-yr-old, nu/+ mice. The CD25- populations from neonates or adults are also similar in the profile of cytokine formation. These results, taken together, indicate that one aspect of peripheral self-tolerance is maintained by CD25+ T cells that sustain potentially pathogenic self-reactive T cells in a CD25- dormant state; the thymic production of the former is developmentally programmed to begin on day 3 after birth in mice. Thus, NTx on day 3 can, at least transiently, eliminate/reduce the autoimmune-preventive CD25+ T cells, thereby leading to activation of the self-reactive T cells that have been produced before NTx.

Organ-specific autoimmunity induced by adult thymectomy and cyclophosphamide-induced lymphopenia

Autoimmune gastritis, a CD4+ T cell-mediated organ-specific autoimmune disease, can be induced by thymectomy of neonatal, but not of older, BALB/c mice. Here we have shown that autoimmune gastritis can also be induced in 6-8-week-old BALB/c mice by thymectomy combined with a single dose of cyclophosphamide (300 mg/kg). This treatment reduced the numbers of splenic T and B cells approximately 25-fold. However, by 8 days after treatment, the number of splenic lymphocytes had returned to normal adult levels. Approximately 50% of treated mice developed autoimmune gastritis after 10-12 weeks. These mice had mononuclear cellular infiltrates within the gastric mucosa and serum autoantibodies to the alpha and beta subunits of the gastric H+/K+ ATPase. Transgenic mice, expressing the gastric H+/K+ ATPase beta-subunit in the thymus (Alderuccio, F., Toh, B. H., Tan, S. S., Gleeson, P. A. and van Driel, I. R., J. Exp. Med. 1993. 178: 419), did not develop autoimmune gastritis after the adult thymectomy/cyclophosphamide treatment. Thus a T cell response to the H+/K+ ATPase beta-subunit is likely to be required for the onset of gastritis. These observations suggest that pathogenic autoreactive T cells exist in the periphery of normal adult mice and that autoimmunity can be induced by the activation of these autoreactive T cells following transient lymphopenia. Cyclophosphamide-treatment of adult mice without thymectomy did not induce autoimmune gastritis, suggesting thymic regulation of these pathogenic T cells.

Oral administration of lipopolysaccharides activates B-1 cells in the peritoneal cavity and lamina propria of the gut and induces autoimmune symptoms in an autoantibody transgenic mouse

About a half of the antierythrocyte autoantibody transgenic (autoAb Tg) mice, in which almost all B cells are detected in the spleen, lymph nodes, and Peyer's patches, but not in the peritoneal cavity, suffer from autoimmune hemolytic anemia. The occurrence of this disease is strongly linked to production of autoAb by activated peritoneal B-1 cells in the Tg mice. In this study, we have shown that oral administration of lipopolysaccharides (LPS) activated B-1 cells in the lamina propria of the gut as well as the peritoneal cavity in the healthy Tg mice and induced the autoimmune symptoms in all the Tg mice. The activation of peritoneal and lamina propria B-1 cells by enteric LPS is found not only in the anti-RBC autoAb Tg mice and normal mice but also in the aly mice which congenitally lack lymph nodes and Peyer's patches. These results suggest that B-1 cells in the two locations may form a common pool independent of Peyer's patches and lymph nodes, and can be activated by enteric thymus-independent antigens or polyclonal activators such as LPS. The induction of autoimmune hemolytic anemia in the Tg mice by enteric LPS through the activation of B-1 cells in the lamina propria of gut and in the peritoneal cavity suggests that B-1 cells and bacterial infection may play a pathogenic role in the onset of autoimmune diseases.