Rosa Bacchetta

Demethylation analysis of the FOXP3 locus shows quantitative defects of regulatory T cells in IPEX-like syndrome

Immune dysregulation, Polyendocrinopathy, Enteropathy X-linked (IPEX) syndrome is a unique example of primary immunodeficiency characterized by autoimmune manifestations due to defective regulatory T (Treg) cells, in the presence of FOXP3 mutations. However, autoimmune symptoms phenotypically resembling IPEX often occur in the absence of detectable FOXP3 mutations. The cause of this “IPEX-like” syndrome presently remains unclear. To investigate whether a defect in Treg cells sustains the immunological dysregulation in IPEX-like patients, we measured the amount of peripheral Treg cells within the CD3+ T cells by analysing demethylation of the Treg cell-Specific-Demethylated-Region (TSDR) in the FOXP3 locus and demethylation of the T cell-Specific-Demethylated-Region (TLSDR) in the CD3 locus, highly specific markers for stable Treg cells and overall T cells, respectively. TSDR demethylation analysis, alone or normalized for the total T cells, showed that the amount of peripheral Treg cells in a cohort of IPEX-like patients was significantly reduced, as compared to both healthy subjects and unrelated disease controls. This reduction could not be displayed by flow cytometric analysis, showing highly variable percentages of FOXP3+ and CD25+FOXP3+ T cells. These data provide evidence that a quantitative defect of Treg cells could be considered a common biological hallmark of IPEX-like syndrome. Since Treg cell suppressive function was not impaired, we propose that this reduction per se could sustain autoimmunity.

Reappraisal of in utero Stem Cell Transplantation Based on Long-Term Results

The therapeutic field of in utero transplantation of stem cells, into human fetuses, has developed since 1988 with the hope of improved probability of engraftment and tolerance, due to immune immaturity of the host. Fifteen years later, it is possible to evaluate the results that we and others have obtained in the treatment of several fetal diseases. Seven fetal patients have been treated in Lyon: In 2 cases, pregnancy termination was induced by the in utero injection; in the 5 other cases, engraftment was obtained and repeatedly documented with presence of donor HLA antigens and/or Y chromosome in recipients. In the 2 patients with combined immunodeficiency disease, a sustained reconstitution of immunity was obtained as a result of the transplant but other complications occurred thereafter. In patients with thalassemia major, Niemann-Pick disease or hemophilia, a very partial and very transitory benefit was only obtained. Approximately 33 other patients with immunodeficiencies, hemoglobinopathies or inborn errors of metabolism have been treated worldwide, over the last 13 years, with a comparable method, using parental or fetal stem cells transplanted in utero. Successful treatment has usually been recorded in immunodeficiencies, and insufficient results have been obtained in the other cases. This form of treatment can therefore be recommended after prenatal diagnosis of combined immunodeficiency but additional research is required to improve the degree of engraftment, the lack of resistance of the host and the ‘space’ available for hematopoiesis in the other conditions.

Utilizing regulatory T cells to control alloreactivity

Effective resetting of the immune system cannot be achieved by non-specific immunosuppression. Instead, novel strategies aim at harnessing the bodys natural tolerance mechanisms to rectify an Ag-specific response without disturbing other immune functions. Fine-tuning of the balance between Ag-specific effector and regulatory T (Tr) cells is a promising strategy that requires detailed understanding of the differentiation and expansion pathways of the relevant Tr cell subsets. Here we review recent developments regarding the control of alloreactivity by induction and expansion of Tr cells. T-cell activation in the presence of tolerogenic APC and cytokines leads to the induction of Tr cells, which can mediate tolerance through cytokine-dependent and/or contact-dependent mechanisms. Better understanding of the mechanisms of immune regulation mediated by Tr cells may enable fine-tuning of specific immune responses and pave the way for novel therapeutic approaches.

IPEX Syndrome: Clinical Profile, Biological Features, and Current Treatment

Children carrying mutations in the forkhead box p3 (FOXP3) gene are affected by the syndrome known as Immune dysregulation, polyendocrinopathy, enteropathy, X-linked (IPEX). Early onset severe enteropathy, Type-1 diabetes (T1D) and eczema with elevated IgE serum levels are the hallmarks of the disease. Mortality is generally high within the first year of life, although some patients can partially respond to conventional immunosuppression showing clinical improvement. Progress in understanding the pathogenesis of IPEX have been made possible by the recognition that FOXP3 is the driving force for the function of naturally occurring regulatory T cells, a T-cell subset specialized in controlling immune responses. However, many open questions concerning the disease mechanisms, the indications for genetic screening and appropriate treatment of IPEX syndrome remain unanswered. In addition, several patients presenting IPEX-like symptoms do not carry mutations in the FOXP3 gene. In the present chapter, we will (1) summarize the latest findings on the biologic function of FOXP3 and its role in immune regulation, (2) highlight the most relevant signs for a correct diagnosis of IPEX syndrome, and (3) provide indications for the development of more targeted therapeutic strategies for the treatment of this devastating pediatric autoimmune disease.

Tolerance to Alloantigens and Recognition for “Allo + X” Induced in Humans by Fetal Stem Cell Transplantation

Transplantation of normal hemopoietic stem cells from the fetal liver can cure a number of diseases in experimental animals as well as in humans. Because of immune immaturity of the human fetus during the first trimester of gestation, fetal liver cells of 8–12 weeks post-fertilization are devoid of any T lymphocyte ; therefore they do not induce graft-versus-host disease (GvHD) after transplantation into an allogeneic host, despite full mismatch [1]. Prevention of rejection of these transplanted stem cells can be ensured by immunodeficiency disease of the host, by immunosuppressive treatment or by immune immaturity of the host when the transplant is performed into a fetal patient [2]. The stem cells from the fetal donor progressively differentiate into T lymphocytes within the environment of host antigens, and give rise to mature T cells exerting their functional activities and restoring immune defenses to the patient [3]. In most cases, the fetal donor and the patient host are fully mismatched at the class I and the class II loci of the major histocompatibility complex (MHC). T lymphocytes deriving from the donor stem cells are therefore confronted with HLA-different host cells (monocytes-macrophages, B lymphocytes, NK cells, target cells of various kinds, etc) after they have matured in this HLA-different host environment. This situation provides us with a unique model to study recognition of “self” and “allo” by helper and cytotoxic T cells, as well as the acquisition of tolerance during T cell ontogeny. Positive and negative selection processes are further demonstrated to be separate phenomena, likely to be induced by distinct cell categories.

INDUCTION OF TRANSPLANTATION TOLERANCE IN HUMANS USING FETAL CELL TRANSPLANTS

When engrafted with donor stem cells and lymphoid cells, patients develop transplantation tolerance to donor antigens. We analyzed the mechanism of tolerance induction in immunoincompetent recipients whose immunity has been reconstituted by transplantation of mismatched stem cells. Seven infants or human fetuses received fetal liver transplants as a treatment for severe combined immunodeficiency disease. After reconstitution of immunity by lymphocytes developed from donor stem cells, T-cell clones were produced and analyzed. Because donors and recipients were HLA mismatched, it was easy to demonstrate the donor origin of the T-cell clones. These clones were shown to have developed tolerance to histocompatibility antigens of the stem cell donor via a process of clonal deletion (probably as a result of contact with donor-derived macrophages and dendritic cells). They were also tolerant to histocompatibility antigens of the host but through a different mechanism: many clones recognized these antigens but had no detrimental effect on the target cells exhibiting host antigens, either in vitro or in vivo. Clonal anergy was therefore the cause of this tolerance to host determinants, resulting in a lack of graft-versus-host disease and of autoimmunity. The contact between developing T cells of donor origin and host epithelial cells within the host thymus may explain this colonal anergy. It should be noted that all patients had high serum levels of interleukin-10, which might have contributed to the persistent engraftment and tolerance.