The immunoregulatory influence of transforming growth factor beta in thyroid autoimmunity: TGF beta inhibits autoreactivity in Graves' disease.

The immunoregulatory influence of transforming growth factor beta (TGF beta) was studied in patients with Graves' disease and in normal controls. Special attention was given to determine how TGF beta affects the interaction between thyroid epithelial cells and T lymphocytes. Human recombinant TGF beta 1 (rTGF beta 1) was immunosuppressive in patients with Graves' disease and in controls. In both groups it inhibited the proliferation of peripheral blood mononuclear cells and of peripheral and thyroid derived T cell lines and clones in response to non-specific stimuli. It also decreased the number of serine esterases expressing cytotoxic T cells and suppressed the recognition of thyroid epithelial cells by thyroid autoantigen specific T cell clones. Inhibition of autoantigen recognition was not only observed when rTGF beta 1 was added to the thyroid epithelial cell/lymphocyte co-culture, but was also found when thyroid epithelial cells were preincubated with rTGF beta 1, which was then removed before the initiation of co-culture. This was probably as a result of a decrease in the antigenicity of the target cells, as rTGF beta 1 also suppressed thyroid peroxidase as well as HLA class II autoantigen expression, in cultured thyroid epithelial cells. These results demonstrate that TGF beta may exert a variety of down-regulatory influences in Graves' disease. It may be of importance for the suppression of autoaggression in persons predisposed to autoimmunity; may be quantitatively overrun by immunostimulatory influences in the acute phase of the disease; and may be important for the induction of remission in patients with Graves' disease.     

Parasites and immunoregulatory T cells

Surviving a parasitic infection requires the generation of a controlled immune response. Failure to establish or to maintain homeostatic conditions usually causes disease. Investigation of the immunoregulatory network as the response to the parasitic process or induced by the parasite promises enormous therapeutic benefits for the control of parasitic diseases. Recent findings implicate various populations of regulatory T cells in this homeostatic regulation.     

Heterogeneity of M-cell-associated B and T cells in human Peyer's patches.

Reactive nitrogen intermediates (RNI) have been implicated in the interferon-gamma (IFN-gamma)-induced anti-microbial action of macrophages against a wide variety of pathogens. We have been studying the production of NO2- by macrophage lines derived from the bone marrow of either B10.A (Bcgs) strain mice (B10S cell lines), or their congenic BCG-resistant partners of the B10A.Bcgr (Bcgr) strain (B10R cell lines). We have discovered that there is a significant difference in the production of NO2- of B10S compared with B10R macrophages in response to IFN-gamma. By 48 hr following treatment with 10 U/ml IFN-gamma, B10R macrophages had produced an approximately threefold higher level of NO2- than B10S macrophages. Similar results were obtained when experiments were performed with total splenic cells harvested from the spleens of B10.A.Bcgr and B10.A strain mice. The bacteriostatic activity, as assessed by the [3H]uracil incorporation by Mycobacterium bovis BCG, was higher in B10R macrophages compared to B10S macrophages. The bacteriostatic activity of B10R and B10S macrophages correlated with the amount of nitric oxide produced by the macrophages. The anti-mycobacterial activity was inhibited by NgMMLA, a specific inhibitor of nitrite and nitrate synthesis from L-arginine. Addition of L-arginine to IFN-gamma-stimulated macrophages in the presence of NgMMLA restored nitrite production and bacteriostatic activity of macrophages. Northern blot analysis of macrophage nitric oxide synthase (iNOS) revealed that the difference in NO2- production by IFN-gamma-treated B10S and B10R lines was reflective of the difference in iNOS mRNA expression.     

Immunoregulatory T cells in autoimmunity

The aim of this work was to discuss the current knowledge concerning regulatory T cells in the pathogenesis of autoimmune diseases. CD4(+) T cells that constitutively express CD25 exhibit powerful suppressive properties. Such cells have been denominated regulatory T cells (T(R)). Alterations in T(R) cells are known to cause organ-specific autoimmune disease in animal models. These cells are anergic when stimulated via their TCR but proliferate when co-stimulated with IL-2. A particular characteristic is that CD4(+)CD25(+) T cells inhibit the proliferative responses of CD4(+)CD25(-) T cells by suppressing the capacity of the responders to transcribe IL-2. The survival and/or expansion of this regulatory subset in the periphery appears to need the availability of IL-2, the components of the IL-2R, as well as cell surface costimulatory molecules. Cytokine participation has been shown in many of the in vivo models of autoimmunity where regulatory cells participate, providing evidence in favour of a role for IL-10, transforming growth factor-beta and IL-4. The behavior and possible participation of regulatory T cells in human disease is still a poorly explored topic but their pathogenic role is warranted.     

The genetics of immunoregulatory T cells

The immune repertoire of normal, healthy individuals contains autoreactive T cells and natural antibodies that, under normal conditions, are controlled, either through central tolerance or by the activity of immunoregulatory T cells to prevent the onset of autoimmune diseases. Over the years, several types of immunoregulatory T cells have been identified. These include natural CD4+CD25+Foxp3+T (Treg) cells and type 1 NKT cells, which develop in the thymus, as well as acquired immunoregulatory T cells, such as type 1 cells (Tr1), Th3 cells, Ts cells and anergic CD4 T cells, which all appear to be products of peripheral immune activation. While little is understood about the genetics of most types of immunoregulatory T cell, detailed information on the genetic control of NKT and Treg cells is now available and may contribute significantly to our understanding of the aetiology of autoimmune disease.     

Abnormalities of immunoregulatory T cells in disorders of immune function.

We studied a five-year-old girl with several autoimmune disorders and a 16-year-old boy with acquired agammaglobulinemia to determine whether aberrations of immunoregulatory T cells could explain some instances of immunodeficiency or autoimmunity. The normal peripheral blood T-cell population, as defined by specific heteroantiserums, is 20 per cent TH2+ and 80 per cent TH2-. Human suppressor cells are TH2+, whereas helper cells are TH2-. In addition, each subset expresses Ia antigens upon activation. Our patient with autoimmune disease had no demonstrable TH2+ cells, and her lymphocytes could not be induced to suppress. Her circulating T cells were of an activated-helper phenotype, i.e., TH2-,Ia+. In contrast, in the boy with agammaglobulinemia, the T-cell population was predominantly of an activated-suppressor phenotype, i.e., TH2+,Ia+. This patient's T cells abrogated both his own and his histoidentical brother's B-cell secretion of immunoglobulins. We conclude that the characterization of T cells may provide insight into the causes of a number of abnormal immune states in man.     

gamma delta T cells in autoimmunity

Conclusions  γδ T cells likely play a critical role in the host defenses, and recent evidence has indicated they are important in regulation of the immune response after pathogen challenge. Data are also accumulating that they play a part in autoimmunity and immune regulation. Evidence indicates that γδ T cells mediate these effects through cytokine production, via direct effects on cells of the adaptive immune response, or through interactions with innate immune components or barriers. Nevertheless, the biological function of γδ T cells in immune responses, especially in autoimmunity, largely remains unresolved. Further studies are needed to gain more knowledge about the immunobiology of these cells, asking why precisely they bear an activated phenotype in vivo, how their cytokine production is regulated, and how they interact with other cells of the innate and adaptive immune responses.     

Natural regulatory T cells in autoimmunity

The suppressive/immunomodulatory function of CD4(+)CD25(+)FOXP3(+) regulatory T (Treg) cells is crucial for the maintenance of immune homeostasis, which helps to prevent autoimmunity and reduce the inflammation induced by pathogens and environmental insults. This review summarizes the current knowledge on the types and mechanisms of action of Treg cells and their role in the immune tolerance to self-antigens, with a particular focus on naturally occurring Treg cells.     

The SCID-hu mouse and thyroid autoimmunity: characterization of human thyroid autoantibody secretion

Severe combined immunodeficient (SCID) mice were injected with peripheral blood mononuclear cells (PBMC) from normal individuals and 14 out of 18 had detectable serum human (h) IgG (maximum levels providing a mean +/- SEM 934 +/- 213 micrograms/ml) and IgM (253 +/- 93 micrograms/ml) at 3-6 weeks after transplantation. Serum human immunoglobulin levels were maximum 6-12 weeks after transplantation and declined to low levels over the subsequent 5 months. Human B cells constituted up to 10% and human T cells up to 40% of cells in the peripheral circulation and spleens of these animals 2-3 weeks after transplantation, PBMC, or intrathyroidal (IT) lymphocytes, from 6 patients with Graves' disease and high serum levels of thyroid autoantibodies were transplanted into 30 SCID mice (Graves' SCID-hu). Although serum human immunoglobulins were observed in only low amounts in the animals receiving IT lymphocytes (n = 4), increased levels of hIgG or hIgM were more easily detectable in 19 Graves' SCID-hu mice that received PBMC. The Graves' SCID-hu mice had significantly lower mean levels of hIgG and hIgM than those observed following transplantation of normal PBMC (mean maximum 328 +/- 113 and 32 +/- 21 micrograms/ml, respectively). Six of these 19 mice had detectable human autoantibody to thyroid peroxidase (TPO, as microsomal antigen) between 3 and 8 weeks after transplantation, with titers ranging from 0.05 to 0.39 (normal SCID-hu serum less than 0.02 ELISA Index). No abnormal thyroid hormone (T4 and T3) levels or thyroiditis was seen when compared to normal SCID-hu mice. Immunization of reconstituted SCID mice with recombinant immunoactive human TPO antigen failed to initiate anti-TPO in normal PBMC-treated mice nor did it increase the titer of human anti-TPO in the anti-TPO positive animals. In conclusion we successfully established human thyroid autoantibody secretion in the SCID-hu mouse and characterized the transient nature of the model. Further studies will be required to achieve successful antigen presentation in this system.     

调节性T细胞免疫效应的调节机制

调节性T细胞(regulatory T cell, Treg)在器官移植、过敏性疾病、肿瘤免疫、感染免疫等病理过程中具有重要作用。Treg通过复杂的作用机制维持外周免疫耐受,限制效应细胞的应答程度,从而防止过度免疫反应所致组织损伤。机体对Treg细胞免疫活性的调节作用及其机制主要包括细胞因子、树突状细胞及共刺激分子、Toll样受体调节机制。     

CD8+ T cells in autoimmunity

Mounting evidence shows that CD8(+) T cells contribute to the initiation, progression and regulation of several pathogenic autoimmune responses in which these cells were not previously thought to play a major role. CD8(+) T cells can kill target cells directly, by recognizing peptide-MHC complexes on target cells, or indirectly, by secreting cytokines capable of signaling through death receptors expressed on the target cell surface. Autoreactive CD8(+) T cells can also contribute to autoimmunity by releasing cytokines capable of increasing the susceptibility of target cells to cytotoxicity, or by secreting chemokines that attract other immune cells to the site of autoimmunity. Autoreactive CD8(+) T cells can also downregulate autoimmune responses. Recent important advances include a mechanistic understanding of events leading to the activation and recruitment of autoreactive CD8(+) T cells in certain autoimmune responses and a greater appreciation of the diverse roles that these T cells play in autoimmunity.     

Control of immune responses by immunoregulatory T cells

Immunoregulatory T cells play a key role in modifying the immune responses to self antigens, tumor antigens, and pathogenic organisms. This review summarizes recent data on naturally occurring CD4⁺ regulatory T cells that constitutively express CD25 (CD25⁺T_reg). We examine the markers that can be used to differentiate these cells from effector T cells, what is known about their mode of action in controlling the activity of effector T cells, the antigenic specificity of CD25⁺T_reg, and their ability to survive and to be selected in vivo. We also summarize specific information on the role of CD25⁺T_reg in controlling anti-tumor responses, an area were manipulation of this subset holds particular clinical promise.     

Human regulatory T cells and autoimmunity

CD4+CD25+ regulatory T cells (Treg) appear to be critical in regulating immune responses to self-antigens. Treg deficiency is associated with several human autoimmune diseases. Although substantial progress has been made in the study of murine and human Treg, their fundamental mechanism of action remains unknown. In this review, we discuss the phenotype of human natural Treg, their functional mechanism, and their role in autoimmune disease.     

CD4+CD25+ T cells as immunoregulatory T cells in vitro

We have further characterized the in vitro phenotype and function of anergic and suppressive CD4(+)25(+) T cells. Following TCR ligation, DO.11.10 CD4(+)25(+) T cells suppress the activation of OT-1 CD8(+)25(-) T cells in an antigen nonspecific manner. Although suppression was seen when using a mixture of APC from both parental strains, it was very much more marked when using F1 APC. APC pretreated with, and then separated from CD4(+)25(+) T cells did not have diminished T cell costimulatory function, suggesting that APC are not the direct targets of CD4(+)25(+) T cell regulation. CTLA-4 blockade failed to abrogate suppression by CD4(+)25(+) T cells in mixing experiments. Although CD4(+)25(+) T cells failed to respond following cross-linking of TCR, they could be induced to proliferate following the addition of exogenous IL-2, allowing the generation of a T cell line from CD4(+)25(+) T cells. After the first in vitro restimulation, CD4(+)25(+) T cells were still anergic and suppressive following TCR engagement. However, after three rounds of restimulation, their anergic and suppressive status was abrogated.     

The leptin connection: regulatory T cells and autoimmunity

Leptin is a cytokine-like hormone with proinflammatory properties linked to autoimmune diseases. In this issue of Immunity, De Rosa et al. (2007) elucidate an important new role for leptin in the anergy and hyporesponsiveness of regulatory T cells.