Transfer of Cell-Surface Antigens by Scavenger Receptor CD36 Promotes Thymic Regulatory T Cell Receptor Repertoire Development and Allo-tolerance

The development of T cell tolerance in the thymus requires the presentation of host proteins by multiple antigen-presenting cell (APC) types. However, the importance of transferring host antigens from transcription factor AIRE-dependent medullary thymic epithelial cells (mTECs) to bone marrow (BM) APCs is unknown. We report that antigen was primarily transferred from mTECs to CD8α⁺ dendritic cells (DCs) and showed that CD36, a scavenger receptor selectively expressed on CD8α⁺ DCs, mediated the transfer of cell-surface, but not cytoplasmic, antigens. The absence of CD8α⁺ DCs or CD36 altered thymic T cell selection, as evidenced by TCR repertoire analysis and the loss of allo-tolerance in murine allogeneic BM transplantation (allo-BMT) studies. Decreases in these DCs and CD36 expression in peripheral blood of human allo-BMT patients correlated with graft-versus-host disease. Our findings suggest that CD36 facilitates transfer of mTEC-derived cell-surface antigen on CD8α⁺ DCs to promote tolerance to host antigens during homeostasis and allo-BMT.

Exposure to microbial antigens during early life is required for the establishment of tolerance to commensal <a>bacteria</a>

Current pediatric guidelines recommend breastfeeding and avoidance of oral antibiotics in the first years of life to reduce the risk of development of allergies. Additionally, animal models have shown exposure to the microbiota prior to weaning is necessary for the prevention of asthma or inflammatory diseases later in life. These studies suggest exposure to commensal microbes prior to weaning supports the development of tolerogenic responses in the intestinal tract. This interval of life coincides with the development of regulatory T cells in the colon which can suppress inflammatory responses. We have recently described a critical window for the development of tolerance in mice and found exposure to microbial antigens between 10 and 21 days of life occurred via the colon and induced long lived antigen specific FoxP3+ regulatory T cell responses. This window of tolerance is defined and regulated by ligands found in breastmilk and in the microbial milieu, and exposure to the microbial antigens required goblet cell associated antigen passages. Regulatory T cells developing during early life were required to restrain inflammatory responses against commensals later in life in a model of colitis. Additionally, exposure to commensal antigens via the colon after day of life 21 resulted in robust antigen-specific T effector responses and exacerbated inflammation in a model of colitis, exhibiting the critical nature of regulating this window of tolerance. Thus, exposure to microbial antigens early in life is an imperative element to the development of tolerance, and is highly regulated to prevent inflammation against the commensal microbiota.

MARCH1 protects the lipid raft and tetraspanin web from MHCII proteotoxicity in dendritic cells

Dendritic cells (DCs) produce major histocompatibility complex II (MHCII) in large amounts to function as professional antigen presenting cells. Paradoxically, DCs also ubiquitinate and degrade MHCII in a constitutive manner. Mice deficient in the MHCII-ubiquitinating enzyme membrane-anchored RING-CH1, or the ubiquitin-acceptor lysine of MHCII, exhibit a substantial reduction in the number of regulatory T (Treg) cells, but the underlying mechanism was unclear. Here we report that ubiquitin-dependent MHCII turnover is critical to maintain homeostasis of lipid rafts and the tetraspanin web in DCs. Lack of MHCII ubiquitination results in the accumulation of excessive quantities of MHCII in the plasma membrane, and the resulting disruption to lipid rafts and the tetraspanin web leads to significant impairment in the ability of DCs to engage and activate thymocytes for Treg cell differentiation. Thus, ubiquitin-dependent MHCII turnover represents a novel quality-control mechanism by which DCs maintain homeostasis of membrane domains that support DC's Treg cell-selecting function.

Microbial antigen encounter during a preweaning interval is critical for tolerance to gut bacteria

We have a mutually beneficial relationship with the trillions of microorganisms inhabiting our gastrointestinal tract. However, maintaining this relationship requires recognizing these organisms as affable and restraining inflammatory responses to these organisms when encountered in hostile settings. How and when the immune system develops tolerance to our gut microbial members is not well understood. We identify a specific preweaning interval in which gut microbial antigens are encountered by the immune system to induce antigen-specific tolerance to gut bacteria. For some bacterial taxa, physiologic encounters with the immune system are restricted to this interval, despite abundance of these taxa in the gut lumen at later times outside this interval. Antigen-specific tolerance to gut bacteria induced during this preweaning interval is stable and maintained even if these taxa are encountered later in life in an inflammatory setting. However, inhibiting microbial antigen encounter during this interval or extending these encounters beyond the normal interval results in a failure to induce tolerance and robust antigen-specific effector responses to gut bacteria upon reencounter in an inflammatory setting. Thus, we have identified a defined preweaning interval critical for developing tolerance to gut bacteria and maintaining the mutually beneficial relationship with our gut microbiota.

Rapid and Efficient Generation of Regulatory T Cells to Commensal Antigens in the Periphery

Commensal bacteria shape the colonic regulatory T (Treg) cell population required for intestinal tolerance. However, little is known about this process. Here, we use the transfer of naive commensal-reactive transgenic T cells expressing colonic Treg T cell receptors (TCRs) to study peripheral Treg (pTreg) cell development in normal hosts. We found that T cells were activated primarily in the distal mesenteric lymph node. Treg cell induction was rapid, generating >40% Foxp3(+) cells 1 week after transfer. Contrary to prior reports, Foxp3(+) cells underwent the most cell divisions, demonstrating that pTreg cell generation can be the dominant outcome from naive T cell activation. Moreover, Notch2-dependent, but not Batf3-dependent, dendritic cells were involved in Treg cell selection. Finally, neither deletion of the conserved nucleotide sequence 1 (CNS1) region in Foxp3 nor blockade of TGF-β (transforming growth factor-β)-receptor signaling completely abrogated Foxp3 induction. Thus, these data show that pTreg cell selection to commensal bacteria is rapid, is robust, and may be specified by TGF-β-independent signals.

Sensory Neurons Co-opt Classical Immune Signaling Pathways to Mediate Chronic Itch

Mammals have evolved neurophysiologic reflexes, such as coughing and scratching, to expel invading pathogens and noxious environmental stimuli. It is well established that these responses are also associated with chronic inflammatory diseases, including asthma and atopic dermatitis. However, the mechanisms by which inflammatory pathways promote sensations such as itch remain poorly understood. Here, we show that type 2 cytokines directly activate sensory neurons in both mice and humans. Further, we demonstrate that chronic itch is dependent on neuronal IL-4Rα and JAK1 signaling. We also observe that patients with recalcitrant chronic itch that failed other immunosuppressive therapies markedly improve when treated with JAK inhibitors. Thus, signaling mechanisms previously ascribed to the immune system may represent novel therapeutic targets within the nervous system. Collectively, this study reveals an evolutionarily conserved paradigm in which the sensory nervous system employs classical immune signaling pathways to influence mammalian behavior.

Lactobacillus reuteri induces gut intraepithelial CD4+CD8αα+ T cells

The small intestine contains CD4⁺CD8αα⁺ double-positive intraepithelial lymphocytes (DP IELs), which originate from intestinal CD4⁺ T cells through down-regulation of the transcription factor Thpok and have regulatory functions. DP IELs are absent in germ-free mice, which suggests that their differentiation depends on microbial factors. We found that DP IEL numbers in mice varied in different vivaria, correlating with the presence of Lactobacillus reuteri This species induced DP IELs in germ-free mice and conventionally-raised mice lacking these cells. L. reuteri did not shape the DP-IEL-TCR (TCR, T cell receptor) repertoire but generated indole derivatives of tryptophan that activated the aryl-hydrocarbon receptor in CD4⁺ T cells, allowing Thpok down-regulation and differentiation into DP IELs. Thus, L. reuteri, together with a tryptophan-rich diet, can reprogram intraepithelial CD4⁺ T cells into immunoregulatory T cells.

Lactobacillus reuteri induces gut intraepithelial CD4+CD8αα+ T cells

The small intestine contains CD4⁺CD8αα⁺ double-positive intraepithelial lymphocytes (DP IELs), which originate from intestinal CD4⁺ T cells through down-regulation of the transcription factor Thpok and have regulatory functions. DP IELs are absent in germ-free mice, which suggests that their differentiation depends on microbial factors. We found that DP IEL numbers in mice varied in different vivaria, correlating with the presence of Lactobacillus reuteri This species induced DP IELs in germ-free mice and conventionally-raised mice lacking these cells. L. reuteri did not shape the DP-IEL-TCR (TCR, T cell receptor) repertoire but generated indole derivatives of tryptophan that activated the aryl-hydrocarbon receptor in CD4⁺ T cells, allowing Thpok down-regulation and differentiation into DP IELs. Thus, L. reuteri, together with a tryptophan-rich diet, can reprogram intraepithelial CD4⁺ T cells into immunoregulatory T cells.

Helicobacter species are potent drivers of colonic T cell responses in homeostasis and inflammation

Specific gut commensal bacteria improve host health by eliciting mutualistic regulatory T (T_reg) cell responses. However, the bacteria that induce effector T (T_eff) cells during inflammation are unclear. We addressed this by analyzing bacterial-reactive T cell receptor (TCR) transgenic cells and TCR repertoires in a murine colitis model. Unexpectedly, we found that mucosal-associated Helicobacter species triggered both T_reg cell responses during homeostasis and T_eff cell responses during colitis, as suggested by an increased overlap between the T_eff/T_reg TCR repertoires with colitis. Four of six T_reg TCRs tested recognized mucosal-associated Helicobacter species in vitro and in vivo. By contrast, the marked expansion of luminal Bacteroides species seen during colitis did not trigger a commensurate T_eff cell response. Unlike other T_reg cell-inducing bacteria, Helicobacter species are known pathobionts and cause disease in immunodeficient mice. Thus, our study suggests a model in which mucosal bacteria elicit context-dependent T_reg or T_eff cell responses to facilitate intestinal tolerance or inflammation.

Sensory neurons co-opt classical immune signaling pathways to mediate chronic itch

Mammals have evolved neurophysiologic reflexes such as scratching to expel invading pathogens and noxious environmental factors. It is also well established that these responses are associated with chronic inflammatory diseases such as atopic dermatitis. However, the mechanisms by which inflammatory pathways promote sensations such as itch remain poorly understood. Here, we show that the type 2 cytokines interleukin (IL)-4 and IL-13 directly stimulate sensory neurons and that chronic itch is dependent on neuronal IL-4Rα, the shared receptor subunit for IL-4 and IL-13. Based on our understanding of IL-4Rα signaling in immune cells, we hypothesized that downstream Janus kinase (JAK) signaling in sensory neurons would be a critical mediator of itch. Indeed, we find that both systemic JAK inhibition and interruption of JAK signaling in the nervous system can dramatically reduce itch. Further, sensory neuron-specific genetic deletion of JAK1 results in robust abatement of chronic itch in mice. Finally, in proof-of-concept translational studies, patients with recalcitrant chronic itch improved rapidly and dramatically in response to JAK inhibition. Thus, signaling mechanisms previously ascribed to the immune system may represent novel targets within the sensory nervous system for the treatment of pathologic sensory responses. Collectively, these studies reveal an evolutionarily conserved paradigm in which the sensory nervous system employs classical immune signaling pathways to influence mammalian behavior.

Abstract IA06: Role of TCR specificity in regulatory T cell selection

Regulatory T (Treg) cells play an important role in preserving self-tolerance and preventing autoimmunity. Because of this, Treg cells generate a natural barrier to immune mediated tumor rejection. Here, we will discuss the process of thymic education that generates a self-reactive Treg cell population which can suppress both autoimmune and anti-tumor responses. Treg cell selection in the thymus is primarily mediated by antigen-presenting cells (APCs) in the medulla, including medullary thymic epithelial cells (mTECs) that express the transcription factor Aire, as well as bone marrow (BM) APCs such as dendritic cells (DCs). Using TCR repertoire analysis of fixed TCRβ chain mice, we recently reported that BM APCs and mTECs make substantial contributions to negative and Treg cell selection. Interestingly, Aire-dependent TCRs were often dependent on BM APC antigen presentation, even though Aire expression itself is restricted to mTECs. Analysis of a selected set of Aire- and BM APC co-dependent TCRs suggests that Batf3-dependent CD8α+ DCs are the major BM APC subset responsible for co-operative antigen presentation. We will also discuss TCR repertoire analyses of Batf3/mice deficient in CD8α+ DCs, as well as potential mechanisms of antigen-transfer from mTECs to DCs and the implications on Treg cell recognition of self-antigens.

Citation Format: Chyi-Song Hsieh. Role of TCR specificity in regulatory T cell selection. [abstract]. In: Proceedings of the AACR Special Conference on Tumor Immunology and Immunotherapy; 2016 Oct 20-23; Boston, MA. Philadelphia (PA): AACR; Cancer Immunol Res 2017;5(3 Suppl):Abstract nr IA06.

Antigen-Specific Development of Mucosal Foxp3+RORγt+ T Cells from Regulatory T Cell Precursors

Foxp3⁺retinoic acid-related orphan receptor (ROR)γt⁺ T cells have recently been characterized as an immunoregulatory population highly enriched in the colon lamina propria. However, their developmental origin and relationship to RORγt^- regulatory T and Th17 cells remain unclear. In this study, we use a fixed TCRβ system to show that the TCR repertoire of the Foxp3⁺RORγt⁺ population is mostly distinct compared with other colonic T cell subsets. However, of these TCRs, a fraction is also found in the Th17 subset, suggesting that TCR repertoire overlap may contribute to the reported ability of Foxp3⁺RORγt⁺ cells to regulate Th17 immunity. Naive transgenic T cells expressing a Foxp3⁺RORγt⁺-restricted TCR first acquire a Foxp3⁺RORγt^- phenotype before coexpressing RORγt, suggesting that Foxp3⁺RORγt⁺ cell development can occur via an RORγt^- regulatory T cell intermediate.

Development of T-cell tolerance utilizes both cell-autonomous and cooperative presentation of self-antigen

The development of T-cell self-tolerance in the thymus is important for establishing immune homeostasis and preventing autoimmunity. Here, we review the components of T-cell tolerance, which includes T-cell receptor (TCR) self-reactivity, costimulation, cytokines, and antigen presentation by a variety of antigen-presenting cells (APCs) subsets. We discuss the current evidence on the process of regulatory T (Treg) cell and negative selection and the importance of TCR signaling. We then examine recent evidence showing unique roles for bone marrow (BM)-derived APCs and medullary thymic epithelial cells (mTECs) on the conventional and Treg TCR repertoire, as well as emerging data on the role of B cells in tolerance. Finally, we review the accumulating data that suggest that cooperative antigen presentation is a prominent component of T -ell tolerance. With the development of tools to interrogate the function of individual APC subsets in the medulla, we have gained greater understanding of the complex cellular and molecular events that determine T-cell tolerance.

Functional characterization of IgA-targeted bacterial taxa from undernourished Malawian children that produce diet-dependent enteropathy

To gain insights into the interrelationships among childhood undernutrition, the gut microbiota, and gut mucosal immune/barrier function, we purified bacterial strains targeted by immunoglobulin A (IgA) from the fecal microbiota of two cohorts of Malawian infants and children. IgA responses to several bacterial taxa, including Enterobacteriaceae, correlated with anthropometric measurements of nutritional status in longitudinal studies. The relationship between IgA responses and growth was further explained by enteropathogen burden. Gnotobiotic mouse recipients of an IgA(+) bacterial consortium purified from the gut microbiota of undernourished children exhibited a diet-dependent enteropathy characterized by rapid disruption of the small intestinal and colonic epithelial barrier, weight loss, and sepsis that could be prevented by administering two IgA-targeted bacterial species from a healthy microbiota. Dissection of a culture collection of 11 IgA-targeted strains from an undernourished donor, sufficient to transmit these phenotypes, disclosed that Enterobacteriaceae interacted with other consortium members to produce enteropathy. These findings indicate that bacterial targets of IgA responses have etiologic, diagnostic, and therapeutic implications for childhood undernutrition.

Characterizing regulatory T cell differentiation to bacterial antigens in the gut (MUC8P.727)

Regulatory T cells are an essential component of immune tolerance towards gut bacteria. Conversely, the microbiota shape the colonic Treg population. However, it is unclear if and how commensal bacteria direct naïve T cells to become peripheral Treg (pTreg) cells. Here, we define the process of pTreg development using transgenic T cells expressing commensal antigen reactive TCRs isolated from colonic Treg cells. We show that naïve TCR transgenic cells transferred into lymphoreplete mice are initially activated in a specific distal mesenteric lymph node. Treg cell differentiation is rapid, starting within 3 days, and efficient, with over 50% Foxp3+ cells arising 1 week after transfer. Contrary to prior observations, Foxp3+ cells are the most divided cells, suggesting that Treg cell differentiation is the primary cell fate upon commensal antigen encounter for these T cells. The most efficient period of Treg cell differentiation in TCR transgenic cells is around the age of weaning. Although T cells deficient in CNS1 showed a marked block in early Treg cell selection, dnTGFβRII cells were only partially deficient in Treg cell generation 1 week after transfer. By contrast, CNS1-deficient cells can upregulate Foxp3 at later time points. Thus, these data illustrate the kinetics, geography, and robustness of peripheral Treg cell selection to commensal bacteria, and suggests that CNS1 is an important region involved in early Foxp3 induction in a relatively TGFβ-independent fashion.

T-cell selection and intestinal homeostasis

Although intestinal bacteria live deep within the body, they are topographically on the exterior surface and thus outside the host. According to the classic notion that the immune system targets non-self rather than self, these intestinal bacteria should be considered foreign and therefore attacked and eliminated. While this appears to be true for some commensal bacterial species, recent data suggest that the immune system actively becomes tolerant to many bacterial organisms. The induction or activation of regulatory T (Treg) cells that inhibit, rather than promote, inflammatory responses to commensal bacteria appears to be a central component of mucosal tolerance. Loss of this mechanism can lead to inappropriate immune reactivity toward commensal organisms, perhaps contributing to mucosal inflammation characteristic of disorders such as inflammatory bowel disease.

Distinct contributions of Aire and antigen-presenting-cell subsets to the generation of self-tolerance in the thymus

The contribution of thymic antigen-presenting-cell (APC) subsets in selecting a self-tolerant T cell population remains unclear. We show that bone marrow (BM) APCs and medullary thymic epithelial cells (mTECs) played nonoverlapping roles in shaping the T cell receptor (TCR) repertoire by deletion and regulatory T (Treg) cell selection of distinct TCRs. Aire, which induces tissue-specific antigen expression in mTECs, affected the TCR repertoire in a manner distinct from mTEC presentation. Approximately half of Aire-dependent deletion or Treg cell selection utilized a pathway dependent on antigen presentation by BM APCs. Batf3-dependent CD8α⁺ dendritic cells (DCs) were the crucial BM APCs for Treg cell selection via this pathway, showing enhanced ability to present antigens from stromal cells. These results demonstrate the division of function between thymic APCs in shaping the self-tolerant TCR repertoire and reveal an unappreciated cooperation between mTECs and CD8α⁺ DCs for presentation of Aire-induced self-antigens to developing thymocytes.

The ability to rearrange dual TCRs enhances positive selection, leading to increased Allo- and Autoreactive T cell repertoires

Thymic selection is designed to ensure TCR reactivity to foreign Ags presented by self-MHC while minimizing reactivity to self-Ags. We hypothesized that the repertoire of T cells with unwanted specificities such as alloreactivity or autoreactivity are a consequence of simultaneous rearrangement of both TCRα loci. We hypothesized that this process helps maximize production of thymocytes capable of successfully completing thymic selection, but results in secondary TCRs that escape stringent selection. In T cells expressing two TCRs, one TCR can mediate positive selection and mask secondary TCR from negative selection. Examination of mice heterozygous for TRAC (TCRα(+/-)), capable of only one functional TCRα rearrangement, demonstrated a defect in generating mature T cells attributable to decreased positive selection. Elimination of secondary TCRs did not broadly alter the peripheral T cell compartment, though deep sequencing of TCRα repertoires of dual TCR T cells and TCRα(+/-) T cells demonstrated unique TCRs in the presence of secondary rearrangements. The functional impact of secondary TCRs on the naive peripheral repertoire was evidenced by reduced frequencies of T cells responding to autoantigen and alloantigen peptide-MHC tetramers in TCRα(+/-) mice. T cell populations with secondary TCRs had significantly increased ability to respond to altered peptide ligands related to their allogeneic ligand as compared with TCRα(+/-) cells, suggesting increased breadth in peptide recognition may be a mechanism for their reactivity. Our results imply that the role of secondary TCRs in forming the T cell repertoire is perhaps more significant than what has been assumed.

T cells and intestinal commensal bacteria--ignorance, rejection, and acceptance

Trillions of commensal bacteria cohabit our bodies to mutual benefit. In the past several years, it has become clear that the adaptive immune system is not ignorant of intestinal commensal bacteria, but is constantly interacting with them. For T cells, the response to commensal bacteria does not appear uniform, as certain commensal bacterial species appear to trigger effector T cells to reject and control them, whereas other species elicit Foxp3(+) regulatory T (Treg) cells to accept and be tolerant of them. Here, we review our current knowledge of T cell differentiation in response to commensal bacteria, and how this process leads to immune homeostasis in the intestine.

T cell immunodominance is dictated by the positively selecting self-peptide

Naive T cell precursor frequency determines the magnitude of immunodominance. While a broad T cell repertoire requires diverse positively selecting self-peptides, how a single positively selecting ligand influences naive T cell precursor frequency remains undefined. We generated a transgenic mouse expressing a naturally occurring self-peptide, gp250, that positively selects an MCC-specific TCR, AND, as the only MHC class II I-E(k) ligand to study the MCC highly organized immunodominance hierarchy. The single gp250/I-E(k) ligand greatly enhanced MCC-tetramer(+) CD4(+) T cells, and skewed MCC-tetramer(+) population toward V11α(+)Vβ3(+), a major TCR pair in MCC-specific immunodominance. The gp250-selected V11α(+)Vβ3(+) CD4(+) T cells had a significantly increased frequency of conserved MCC-preferred CDR3 features. Our studies establish a direct and causal relationship between a selecting self-peptide and the specificity of the selected TCRs. Thus, an immunodominant T cell response can be due to a dominant positively selecting self-peptide. DOI: http://dx.doi.org/10.7554/eLife.01457.001.

CTLA4Ig inhibits effector T cells through regulatory T cells and TGF-β

The CD28 costimulatory receptor is a critical regulator of T cell function, making it an attractive therapeutic target for the treatment of immune-mediated diseases. CTLA4Ig, now approved for use in humans, prevents naive T cell activation by binding to B7 proteins and blocking engagement of CD28. However, CTLA4Ig suppresses inflammation even if administered when disease is established, suggesting alternative mechanisms. We identified a novel, CD28-independent mechanism by which CTLA4Ig inhibits activated T cells. We show that in vitro, CTLA4Ig synergizes with NO from bone marrow-derived macrophages to inhibit T cell proliferation. Depletion of regulatory T cells (Tregs) or interference with TGF-β signaling abrogated the inhibitory effect of CTLA4Ig. Parallel in vivo experiments using an allergic airway inflammation model demonstrated that this novel mechanism required both macrophages and regulatory T cells. Furthermore, CTLA4Ig was ineffective in SMAD3-deficient mice, supporting a requirement for TGF-β signaling. Thus, in addition to preventing naive T cells from being fully activated, CTLA4Ig can turn off already activated effector T cells by an NO/regulatory T cell/TGF-β-dependent pathway. This mechanism is similar to cell-extrinsic effects of endogenous CTLA4 and may be particularly important in the ability of CTLA4Ig to treat chronic inflammatory disease.

Lack of adiponectin leads to increased lymphocyte activation and increased disease severity in a mouse model of multiple sclerosis

Multiple sclerosis (MS) is a presumed autoimmune disease directed against central nervous system (CNS) myelin, in which diet and obesity are implicated as risk factors. Immune responses can be influenced by molecules produced by fat cells, called adipokines. Adiponectin is an adipokine with anti-inflammatory effects. We tested the hypothesis that adiponectin has a protective role in the EAE model for MS, that can be induced by immunization with myelin antigens or transfer of myelin-specific T lymphocytes. Adiponectin deficient (ADPKO) mice developed worse EAE with greater CNS inflammation, demyelination, and axon injury. Lymphocytes from myelin-immunized ADPKO mice proliferated more, produced higher amounts of IFN-γ, IL-17, TNF-α, IL-6, and transferred more severe EAE than wild type (WT) lymphocytes. At EAE peak, the spleen and CNS of ADPKO had fewer regulatory T (Treg) cells than WT mice and during EAE recovery, Foxp3, IL-10 and TGF-β expression levels in the CNS were reduced in ADPKO compared with WT mice. Treatment with globular adiponectin in vivo ameliorated EAE, and was associated with an increase in Treg cells. These data indicate that adiponectin is an important regulator of T-cell functions during EAE, suggesting a new avenue of investigation for MS treatment.

A broad range of self-reactivity drives thymic regulatory T cell selection to limit responses to self

The degree of T cell self-reactivity considered dangerous by the immune system, thereby requiring thymic selection processes to prevent autoimmunity, is unknown. Here, we analyzed a panel of T cell receptors (TCRs) with a broad range of reactivity to ovalbumin (OVA(323-339)) in the rat insulin promoter (RIP)-mOVA self-antigen model for their ability to trigger thymic self-tolerance mechanisms. Thymic regulatory T (Treg) cell generation in vivo was directly correlated with in vitro TCR reactivity to OVA-peptide in a broad ~1,000-fold range. Interestingly, higher TCR affinity was associated with a larger Treg cell developmental "niche" size, even though the amount of antigen should remain constant. The TCR-reactivity threshold to elicit thymic negative selection and peripheral T cell responses was ~100-fold higher than that of Treg cell differentiation. Thus, these data suggest that the broad range of self-reactivity that elicits thymic Treg cell generation is tuned to secure peripheral tolerance to self.