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ABSTRACT: Naturally arising CD25+CD4+ regulatory T cells, which express the transcription factor Foxp3, play key roles in the maintenance of immunologic self-tolerance and negative control of a variety of physiological and pathological immune responses. The majority of them are produced by the normal thymus as a functionally mature T cell subpopulation specialized for suppressive function. Their generation is in part genetically and developmentally controlled. Genetically determined or environmentally induced abnormality in CD25+CD4+ regulatory T cell development, maintenance, and function can be a cause of autoimmune disease in humans.
Current topics in microbiology and immunology 02/2006; 305:51-66. · 4.93 Impact Factor
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ABSTRACT: Naturally arising regulatory T (TR) cells, represented by CD25+CD4+ TR cells, play an essential role in maintaining immunological self-tolerance. This T cell-mediated dominant control of the immune response not only inhibits the development of autoimmune disease, but also impedes effective immunosurveillance against autologous tumor cells. Attenuation of TR cell-mediated immune suppression can therefore evoke effective tumor immunity in otherwise nonresponsive animals. This common regulatory mechanism for autoimmunity and tumor immunity can be exploited when devising a novel immunotherapy for cancer.
Current topics in microbiology and immunology 02/2005; 293:287-302. · 4.93 Impact Factor
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ABSTRACT: T-cell-mediated dominant control of self-reactive T cells is one mechanism for maintaining immunologic self tolerance. It also hampers the generation of immunity to autologous tumor cells. Abrogation of the control can evoke potent tumor immunity as well as autoimmunity in normal animals. This common regulatory mechanism for autoimmunity and tumor immunity can be exploited to devise a novel immunotherapy against cancer.
Microbes and Infection 10/2001; 3(11):911-8. · 3.10 Impact Factor
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ABSTRACT: There is accumulating evidence that T-cell-mediated dominant control of self-reactive T-cells contributes to the maintenance of immunologic self-tolerance and its alteration can cause autoimmune disease. Efforts to delineate such a regulatory T-cell population have revealed that CD25+ cells in the CD4+ population in normal naive animals bear the ability to prevent autoimmune disease in vivo and, upon antigenic stimulation, suppress the activation/proliferation of other T cells in vitro. The CD25+ CD4+ regulatory T cells, which are naturally anergic and suppressive, appear to be produced by the normal thymus as a functionally distinct subpopulation of T cells. They play critical roles not only in preventing autoimmunity but also in controlling tumor immunity and transplantation tolerance.
Immunological Reviews 09/2001; 182:18-32. · 11.15 Impact Factor
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A Kumanogoh,
X Wang,
I Lee,
C Watanabe,
M Kamanaka,
W Shi,
K Yoshida,
T Sato,
S Habu,
M Itoh,
N Sakaguchi, S Sakaguchi,
H Kikutani
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ABSTRACT: Mutations in the CD40 ligand (CD40L) gene lead to X-linked immunodeficiency with hyper-IgM, which is often associated with autoimmune diseases. To determine the contribution of defective CD40-CD40L interactions to T cell autoreactivity, we reconstituted CD40-CD40L interactions by transferring T cells from CD40-deficient mice to syngenic athymic nude mice and assessed autoimmunity. T cells from CD40-deficient mice triggered autoimmune diseases accompanied with elevations of various autoantibodies, while those from wild-type mice did not. In CD40-deficient mice, the CD25(+) CD45RB(low) CD4(+) subpopulation which regulates T cell autoreactivity was markedly reduced. CD40-deficient APCs failed to induce T regulatory cells 1 producing high levels of an inhibitory cytokine, IL-10 in vitro. Furthermore, autoimmune development was inhibited when T cells from CD40-deficient mice were cotransferred with CD45RB(low) CD4(+) T cells from wild-type mice or with T regulatory cells 1 induced on CD40-expressing APCs. Collectively, our results indicate that CD40-CD40L interactions contribute to negative regulation of T cell autoreactivity and that defective interactions can lead to autoimmunity.
The Journal of Immunology 02/2001; 166(1):353-60. · 5.79 Impact Factor
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S Sakaguchi
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ABSTRACT: T cells mediate various autoimmune diseases. Pathologic autoimmunity can be induced by manipulating thymic or peripheral control of self-reactive T cells. There is, for example, accumulating evidence that elimination or dysfunction of regulatory T cells can elicit T cell mediated, destructive autoimmune disease in otherwise normal animals and enhance autoimmunity in spontaneous models.
Current Opinion in Immunology 01/2001; 12(6):684-90. · 9.52 Impact Factor
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ABSTRACT: A CD4(+) T cell subpopulation defined by the expression levels of a particular cell surface molecule (e.g. CD5, CD45RB, CD25, CD62L or CD38) bears an autoimmune-preventive activity in various animal models. Here we show that the expression of CD25 is highly specific, when compared with other molecules, in delineating the autoimmune-preventive immunoregulatory CD4(+) T cell population. Furthermore, although CD25 is an activation marker for T cells, the following findings indicate that immunoregulatory CD25(+)CD4(+) T cells are functionally distinct from activated or anergy-induced T cells derived from CD25(-)CD4(+) T cells. First, the former are autoimmune-preventive in vivo, naturally unresponsive (anergic) to TCR stimulation in vitro and, upon TCR stimulation, able to suppress the activation/proliferation of other T cells, whereas the latter scarcely exhibit the in vivo autoimmune-preventive activity or the in vitro suppressive activity. Second, such activated or anergy-induced CD25(-) spleen cells produce various autoimmune diseases when transferred to syngeneic athymic nude mice, whereas similarly treated normal spleen cells, which include CD25(+)CD4(+) T cells, do not. Third, upon polyclonal T cell stimulation, CD25(+)CD4(+) T cells express CD25 at higher levels and more persistently than CD25(-)CD4(+) T cell-derived activated T cells; moreover, when the stimulation is ceased, the former revert to the original levels of CD25 expression, whereas the latter lose the expression. These results collectively indicate that naturally anergic and suppressive CD25(+)CD4(+) T cells present in normal naive mice are functionally and phenotypically stable, distinct from other T cells, and play a key role in maintaining immunologic self-tolerance.
International Immunology 09/2000; 12(8):1145-55. · 3.41 Impact Factor
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S Sakaguchi
Cell 06/2000; 101(5):455-8. · 32.40 Impact Factor
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ABSTRACT: There are accumulating demonstrations that manipulation of the T-cell immune system, such as elimination of a particular T-cell subpopulation from the periphery or removal of the thymus during a critical neonatal period, can elicit activation/expansion of pathogenic self-reactive T cells from the remaining T cells and produce a wide spectrum of organ-specific autoimmune diseases in otherwise normal mice or rats. The genetic makeup of the hosts appears to play a key role in determining which self-reactive T-cell clones are prone to be activated under such circumstances, since a comparable degree of the immunologic abnormality elicits autoimmune disease in different spectrums of organs, with different incidences and severities, depending on the mouse or rat strains used. These findings indicate that one aspect of natural immunologic self-tolerance is maintained by a T cell-mediated control of potentially pathogenic self-reactive T cells in the periphery, and that defective control, caused by environmental insults or genetic abnormalities, suffices to cause autoimmune disease; furthermore, in the presence of such a T-cell abnormality, host genetic factors including MHC and non-MHC genes may determine the specificity and intensity of the autoimmune responses, and consequently the phenotype of the autoimmune disease.
Reviews in immunogenetics 02/2000; 2(1):147-53.
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ABSTRACT: This study shows that removal of a T cell subpopulation can evoke effective tumor immunity in otherwise nonresponding animals. Elimination of CD25-expressing T cells, which constitute 5-10% of peripheral CD4+ T cells in normal naive mice, elicited potent immune responses to syngeneic tumors in vivo and eradicated them. The responses were mediated by tumor-specific CD8+ CTLs and tumor-nonspecific CD4-8- cytotoxic cells akin to NK cells. Furthermore, in vitro culture of CD25+4+ T cell-depleted splenic cell suspensions prepared from tumor-unsensitized normal mice led to spontaneous generation of similar CD4-8- cytotoxic cells capable of killing a broad spectrum of tumors; reconstitution of CD25+4+ T cells inhibited the generation. In this culture, self-reactive CD25-4+ T cells responding to self peptides/class II MHC complexes on APCs spontaneously proliferated upon removal of CD25+4+ T cells, secreting large amounts of IL-2. The IL-2 thus produced appeared to be responsible for the generation of CD4-8- NK cells as lymphokine-activated killer cells, because direct addition of an equivalent amount of IL-2 to the culture of CD4-8- cells generated similar lymphokine-activated killer/NK cells, whereas coculture of normal CD4-8- cells with CD25-4+ T cells from IL-2-deficient mice did not. Thus, removal of immunoregulatory CD25+4+ T cells can abrogate immunological unresponsiveness to syngeneic tumors in vivo and in vitro, leading to spontaneous development of tumor-specific effector cells as well as tumor-nonspecific ones. This novel way of evoking tumor immunity would help to devise effective immunotherapy for cancer in humans.
The Journal of Immunology 12/1999; 163(10):5211-8. · 5.79 Impact Factor
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ABSTRACT: 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.
The Journal of Immunology 06/1999; 162(9):5309-16. · 5.79 Impact Factor
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ABSTRACT: This study shows that the normal thymus produces immunoregulatory CD25+4+8- thymocytes capable of controlling self-reactive T cells. Transfer of thymocyte suspensions depleted of CD25+4+8- thymocytes, which constitute approximately 5% of steroid-resistant mature CD4+8- thymocytes in normal naive mice, produces various autoimmune diseases in syngeneic athymic nude mice. These CD25+4+8- thymocytes are nonproliferative (anergic) to TCR stimulation in vitro, but potently suppress the proliferation of other CD4+8- or CD4-8+ thymocytes; breakage of their anergic state in vitro by high doses of IL-2 or anti-CD28 Ab simultaneously abrogates their suppressive activity; and transfer of such suppression-abrogated thymocyte suspensions produces autoimmune disease in nude mice. These immunoregulatory CD25+4+8- thymocytes/T cells are functionally distinct from activated CD25+4+ T cells derived from CD25-4+ thymocytes/T cells in that the latter scarcely exhibits suppressive activity in vitro, although both CD25+4+ populations express a similar profile of cell surface markers. Furthermore, the CD25+4+8- thymocytes appear to acquire their anergic and suppressive property through the thymic selection process, since TCR transgenic mice develop similar anergic/suppressive CD25+4+8- thymocytes and CD25+4+ T cells that predominantly express TCRs utilizing endogenous alpha-chains, but RAG-2-deficient TCR transgenic mice do not. These results taken together indicate that anergic/suppressive CD25+4+8- thymocytes and peripheral T cells in normal naive mice may constitute a common T cell lineage functionally and developmentally distinct from other T cells, and that production of this unique immunoregulatory T cell population can be another key function of the thymus in maintaining immunologic self-tolerance.
The Journal of Immunology 06/1999; 162(9):5317-26. · 5.79 Impact Factor
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ABSTRACT: Elimination of CD25+ T cells, which constitute 5-10% of peripheral CD4+ T cells in normal naive mice, leads to spontaneous development of various autoimmune diseases. These immunoregulatory CD25+CD4+ T cells are naturally unresponsive (anergic) in vitro to TCR stimulation, and, upon stimulation, suppress proliferation of CD25-CD4+ T cells and CD8+ T cells. The antigen concentration required for stimulating CD25+CD4+ T cells to exert suppression is much lower than that required for stimulating CD25-CD4+ T cells to proliferate. The suppression, which results in reduced IL-2 production by CD25-CD4+ T cells, is dependent on cellular interactions on antigen-presenting cells (and not mediated by far-reaching or long-lasting humoral factors or apoptosis-inducing signals) and antigen non-specific in its effector phase. Addition of high doses of IL-2 or anti-CD28 antibody to the in vitro T cell stimulation culture not only breaks the anergic state of CD25+CD4+ T cells, but also abrogates their suppressive activity simultaneously. Importantly, the anergic/suppressive state of CD25+CD4+ T cells appeared to be their basal default condition, since removal of IL-2 or anti-CD28 antibody from the culture milieu allows them to revert to the original anergic/suppressive state. Furthermore, transfer of such anergy/suppression-broken T cells from normal mice produces various autoimmune diseases in syngeneic athymic nude mice. These results taken together indicate that one aspect of immunologic self-tolerance is maintained by this unique CD25+CD4+ naturally anergic/suppressive T cell population and its functional abnormality directly leads to the development of autoimmune disease.
International Immunology 01/1999; 10(12):1969-80. · 3.41 Impact Factor
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S Sakaguchi
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ABSTRACT: Various autoimmune diseases can be induced in normal animals by simply manipulating the thymus/T cells. For example, elimination of CD25+CD4+ T cells, which constitute about 10% of peripheral CD4+ T cells of normal mice, leads to the development of various organ-specific autoimmune diseases, such as thyroiditis, gastritis, adrenalitis, insulitis, sialoadenitis, oophoritis, or orchitis. Reconstitution of CD25+CD4+ T cells prevents the autoimmune development. Elimination/reduction of CD25+CD4+ T cells induced by genetical manipulation of T-cell ontogeny or caused by environmental agents, such as virus infection, also causes similar autoimmune diseases in normal mice. These newly developed animal models of autoimmune disease will be useful for elucidating the mechanism of immunologic self-tolerance and pathogenetic mechanism of autoimmune disease.
Nippon rinsho. Japanese journal of clinical medicine 07/1997; 55(6):1377-83.
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ABSTRACT: 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.
Journal of Experimental Medicine 09/1996; 184(2):387-96. · 13.85 Impact Factor
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ABSTRACT: This paper shows that elimination of a small subpopulation of peripheral T cells can elicit activation/expansion of self-reactive T cells from the remaining T cells and produce a wide spectrum of organ-specific and systemic autoimmune diseases in normal mice; reconstitution of the eliminated T-cell population prevents autoimmune development. This regulatory T-cell population expresses the CD25 molecule, apparently includes 'activated' T cells, and suppresses immune responses to non-self as well as self antigens in an antigen-nonspecific manner. Although the degree of abnormality in the T-cell regulation significantly influences the spectrum, incidence, and severity of autoimmune disease, the T-cell abnormality itself cannot determine the specificities of the elicited autoimmune responses since a comparable degree of abnormality causes different autoimmune diseases depending on the mouse strains used. Host genetic elements thus significantly contribute to determining the specificities. These findings taken together indicate that one aspect of natural self-tolerance is maintained by a T cell-mediated or -dependent control of potentially pathogenic self-reactive T cells in the periphery, and that defective control, caused by environmental insults or genetic abnormalities, suffices to activate self-reactive T cells, eliciting various autoimmune diseases depending on the genetic makeup of the host.
Journal of Autoimmunity 05/1996; 9(2):211-20. · 7.37 Impact Factor
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ABSTRACT: Approximately 10% of peripheral CD4+ cells and less than 1% of CD8+ cells in normal unimmunized adult mice express the IL-2 receptor alpha-chain (CD25) molecules. When CD4+ cell suspensions prepared from BALB/c nu/+ mice lymph nodes and spleens were depleted of CD25+ cells by specific mAb and C, and then inoculated into BALB/c athymic nude (nu/nu) mice, all recipients spontaneously developed histologically and serologically evident autoimmune diseases (such as thyroiditis, gastritis, insulitis, sialoadenitis, adrenalitis, oophoritis, glomerulonephritis, and polyarthritis); some mice also developed graft-vs-host-like wasting disease. Reconstitution of CD4+CD25+ cells within a limited period after transfer of CD4+CD25- cells prevented these autoimmune developments in a dose-dependent fashion, whereas the reconstitution several days later, or inoculation of an equivalent dose of CD8+ cells, was far less efficient for the prevention. When nu/nu mice were transplanted with allogeneic skins or immunized with xenogeneic proteins at the time of CD25- cell inoculation, they showed significantly heightened immune responses to the skins or proteins, and reconstitution of CD4+CD25+ cells normalized the responses. Taken together, these results indicate that CD4+CD25+ cells contribute to maintaining self-tolerance by down-regulating immune response to self and non-self Ags in an Ag-nonspecific manner, presumably at the T cell activation stage; elimination/reduction of CD4+CD25+ cells relieves this general suppression, thereby not only enhancing immune responses to non-self Ags, but also eliciting autoimmune responses to certain self-Ags. Abnormality of this T cell-mediated mechanism of peripheral tolerance can be a possible cause of various autoimmune diseases.
The Journal of Immunology 09/1995; 155(3):1151-64. · 5.79 Impact Factor
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ABSTRACT: Ionizing radiation can functionally alter the immune system and break self-tolerance. High dose (42.5 Gy), fractionated (2.5 Gy 17 times) total lymphoid irradiation (TLI) on mice caused various organ-specific autoimmune diseases, such as gastritis, thyroiditis, and orchitis, depending on the radiation dosages, the extent of lymphoid irradiation, and the genetic background of the mouse strains. Radiation-induced tissue damage is not the primary cause of the autoimmune disease because irradiation of the target organs alone failed to elicit the autoimmunity and shielding of the organs from irradiation was unable to prevent it. In contrast, irradiation of both the thymus and the peripheral lymphoid organs/tissues was required for efficient induction of autoimmune disease by TLI. TLI eliminated the majority of mature thymocytes and the peripheral T cells for 1 mo, and inoculation of spleen cell, thymocyte, or bone marrow cell suspensions (prepared from syngeneic nonirradiated mice) within 2 wk after TLI effectively prevented the autoimmune development. Depletion of T cells from the inocula abrogated the preventive activity. CD4+ T cells mediated the autoimmune prevention but CD8+ T cells did not. CD4+ T cells also appeared to mediate the TLI-induced autoimmune disease because CD4+ T cells from disease-bearing TLI mice adoptively transferred the autoimmune disease to syngeneic naive mice. Taken together, these results indicate that high dose, fractionated ionizing radiation on the lymphoid organs/tissues can cause autoimmune disease by affecting the T cell immune system, rather than the target self-Ags, presumably by altering T cell-dependent control of self-reactive T cells.
The Journal of Immunology 04/1994; 152(5):2586-95. · 5.79 Impact Factor
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ABSTRACT: Germline expression of rearranged TCR alpha-chain transgenes with the Ig H chain enhancer reproducibly elicits T cell-mediated autoimmune disease in the thyroid gland, gastric mucosa, Langerhans islets, salivary gland, ovaries, and testes in selected strains of normal mice. Multiple organs are destroyed in a single transgenic mouse and the same organ in transgenic strains with different MHC background, suggesting the transgene expression can elicit self-reactive T cell clones having different Ag specificities and MHC restrictions. Construction of this autoimmune-inducing TCR alpha EH transgene does not require particular V alpha J alpha gene segments or Ag specificities. Moreover, the autoimmune disease can be adoptively transferred to syngeneic normal mice by T cells expressing endogenous TCR alpha-chains. Taken together, these results indicate that the TCR alpha EH transgene expression does not suppress endogenous alpha-chain gene rearrangement and may trigger the expansion/activation of various self-reactive T cells expressing endogenous TCR alpha- and beta-chains. Furthermore, it appears that the transgene-induced autoimmune T cells are not deleted in the normal thymus or rendered anergic upon contact with the normal target self Ag, but can be controlled by a T cell-dependent mechanism, since transfer of the transgenic bone marrow cells to histocompatible SCID mice produces the same autoimmune disease as in the donors, and the autoimmune development in the SCID mice is effectively prevented by co-transfer of syngeneic nontransgenic T cells. This novel autoimmune model produced by genetic manipulation of the T cell lineage, not the target self Ag or the environment of T cell differentiation/selection, should be useful for elucidating the immunologic and genetic basis of autoimmune disease.
The Journal of Immunology 03/1994; 152(3):1471-84. · 5.79 Impact Factor
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ABSTRACT: Cyclosporin A (CsA), a potent immunosuppressive drug, caused organ-specific autoimmune disease, such as gastritis with anti-parietal cell autoantibodies or oophoritis with anti-oocyte autoantibodies, in BALB/c mice when the drug was administered daily for 1 wk to newborns. Administration to adult mice did not. CsA abrogated the production of L3T4+ T cells and Lyt-2+ T cells in the thymus. Consequently, these T cells were substantially depleted from the peripheral lymphoid organs, especially when the drug was administered from the day of birth. Autoimmune disease was prevented when CsA-treated newborn mice were inoculated with splenic T cells from normal syngeneic mice. However, removal of the thymus immediately after neonatal CsA treatment produced autoimmune disease with a higher incidence and in a wider spectrum of organs, i.e., thyroiditis, sialoadenitis of the salivary gland, gastritis, insulitis of the endocrine pancreas, adrenalitis, oophoritis, or orchitis. Each autoimmune disease was accompanied by the development of circulating autoantibodies specific for the corresponding organ Ag. Immunopathology of these autoimmune diseases was quite similar to that of human organ-specific autoimmune diseases.
The Journal of Immunology 02/1989; 142(2):471-80. · 5.79 Impact Factor
