Investigating mechanisms of regulatory T cell function in inflammatory disease

Mair, Iris

January 2017

Regulatory T cells (Treg) play a crucial role in controlling immune homeostasis. Several inflammatory diseases including multiple sclerosis and inflammatory bowel disease have been associated with dysfunctional and/or reduced numbers of Treg. While several mechanisms of action have been discovered by which Treg can exert their function, disease-specific Treg requirements remain unknown. The Treg pool consists of highly diverse subpopulations, indicating that there is a potential to optimise Treg-targeted therapies if disease-relevant mechanisms can be established. Microarray data from our lab suggests a marked upregulation of the integrin αv as well as the IL-33 receptor ST2 in Treg retrieved from the inflamed central nervous system (CNS) during experimental autoimmune encephalomyelitis compared to peripheral lymphoid organs. These two molecules were further investigated within this PhD project with the aim to understand their role in Treg function during chronic inflammatory disease. αvβ integrins have been reported to be needed for effector T cell migration to inflamed sites through binding of extracellular matrix components and are involved in TGF-β activation by a variety of cell types. Conditional knockout mice lacking the integrin αv specifically in Foxpγ+ Treg were generated to address the role of αv integrins on regulatory T cells in inflammatory disease. αv-/- Treg showed a deficiency in activating latent TGF-β, but were able to suppress responder T cell proliferation in vitro as well as in vivo. αv-/- Treg were also able to migrate to the inflamed CNS during EAE and resolve disease. However, αv-/- Treg were detected at significantly lower numbers and proportions in the inflamed gut during a curative T cell transfer model of colitis; this led to a quantitative impairment in the ability of αv-/- Treg to cure colitis when compared to wild-type (WT) Treg. Whether this is a deficit in migration, survival, proliferation, or Foxp3 stability, remains to be investigated. IL-33 acts as an alarmin and is best studied as a cytokine released upon tissue damage that induces a potent type 2 immune response by acting on a multitude of immune cells. Expression of the IL-33 receptor ST2 on Treg has recently been associated with positive metabolic parameters in visceral adipose tissue, protection from gut inflammation, and tissue-restorative function in other inflamed tissues such as injured muscle or lung. This project showed that in steady state, ST2+ Treg expressed high levels of several markers which have been associated with potent regulatory function. When stimulated in vitro, ST2+ Treg showed a better survival and expansion rate compared to their ST2- counterparts, even more so in the presence of IL-33. T-bet deficiency in Treg resulted in an increased ST2+ Treg pool, and T-bet-associated cytokine IFN-γ was found to antagonise IL-33-induced expansion of the ST2+ Treg pool in a T-bet-independent manner. When ST2+ and ST2- Treg were tested for their respective suppressive capacity in vivo, ST2+ Treg were able to suppress responder T cell expansion despite being found only at low numbers in secondary lymphoid organs compared to ST2- Treg. However, in a curative model of T cell transfer colitis, ST2+ Treg were less capable of controlling the ongoing immune response than ST2- Treg. A possible explanation for the superiority of ST2- Treg in this setting can be found in the fact that injected ST2- Treg acquired a distribution of ST2 expression reminiscent of WT Treg over the course of disease. On the other hand, an increased starting pool of ST2+ Treg as occurs in T-bet-/- Treg significantly enhanced the capacity of Treg to control colitis compared to WT Treg. In conclusion, both ST2- and ST2+ Treg are likely to have a distinct, non-redundant role in suppressing T cell activation in secondary lymphoid organs and controlling ongoing inflammation in peripheral tissue, respectively.

Modulation of immune responses by UV irradiation

Yu, Cunjing

January 2016

Atopic dermatitis (AD) is a common, chronic relapsing inflammatory skin disease associated with cutaneous hyper-reactivity to environmental triggers that are innocuous to normal nonatopic individuals. AD affects 10% to 15% of children and 2% to 10% of adults in industrialized countries. There has been increasing interest in this disease triggered by its increasing prevalence in western societies and its contribution to the increasing health care costs. Yet, the underlying pathophysiologic and genetic mechanisms leading to the manifestation of AD are not clear. AD results from a complex interplay between environmental triggers, susceptibility genes including mutations in the keratinocyte protein filaggrin and altered immune responses resulting in allergic CD4+ T cell (Th2) immunity to epidermally encountered antigens. Regulatory T cells (Tregs) play an important role in controlling responsiveness to self-antigens and preventing autoimmune diseases, as well as in limiting inflammatory responses during inflammation and infection. Currently, studies investigating the number and function of Tregs in patients with AD have shown controversial results. It has been long established that symptoms of AD improve on exposure to sunlight. Narrowband UVB (NB-UVB) phototherapy is a common treatment modality for a variety of skin diseases. Considering the adverse effects for systemic treatment for severe adult AD, phototherapy, especially NB-UVB phototherapy may be a more practical long-term treatment. However, approximately 50% of patients over an 8-week treatment course do not improve after NB-UVB phototherapy. Therefore, it is important to identify characteristics of AD patients to determine whether they will respond to phototherapy and to avoid adverse effects for unresponsive patients. UVB exposure has also been associated with induction of Tregs in mice and increasing their numbers and/or functional capacity may offer benefit to patients with chronic AD. Active vitamin D (1,25(OH)2D3), one of the factors induced by UV-B radiation induces Tregs and is suggested to contribute to the suppressive effect of NB-UVB phototherapy. However, UV radiation could also have beneficial effects through other pathways known to affect immunoregulation. UVB exposure upregulates production of nitric oxide (NO) in the skin which also affects immune cell function. The protein filaggrin is broken down in differentiating keratinocytes to form the natural moisturizer of the skin. The gene encoding filaggrin (FLG) has been shown to be a major predisposing factor for AD. A key breakdown product is urocanic acid (UCA) which also acts as a natural sunscreen and undergoes trans-cis isomerisation on exposure to UV-B. Cis-UCA is known to modulate immune responses, however, the mechanisms of its action remain elusive. The production of all three compounds, vitamin D, cis-UCA and NO might all increase in the circulation of patients undergoing UVB phototherapy. While the immunomodulatory effect of Vitamin D is well described, cis-UCA and NO may also affect the behaviour of T lymphocytes systemically. Therefore, I investigated the effect of NO and cis-UCA on the phenotype and function of CD4+T cells and monocyte-derived dendritic cells (Mo-DCs) derived from peripheral blood mononuclear cells (PBMCs) from healthy volunteers. I also investigated the correlation between plasma concentration of 25(OH) vitamin D and nitrate, FLG genotype, circulating Tregs and clinical efficacy of NB-UVB phototherapy. My results showed that NO did not affect the phenotype of human mo-DCs and directly affected peripheral CD4+ T cells by inducing functional CD25+Foxp3+CD127-Tregs from CD4+CD25lo/- effector T cells. Moreover, NO increased expression of the of skin homing marker CLA on these Tregs, suggesting an increased ability of NO-induced Tregs to migrate to the skin. These NO-induced CD25+Foxp3+CD127-Tregs had immunosuppressive functions and inhibited autologous CD4+ T cell proliferation. Cytokines, at least IL-10, secreted by NO-treated CD4+ T cells were not sufficient for the suppressive function of NOinduced Foxp3+Tregs. The immune regulatory function of NO-induced Fopx3+Tregs required cell-cell contact and was mediated by membrane bound TGFβ and PD-1/PD-L1 but not CTLA-4. Results also showed that cis-UCA might have both pro- and anti-inflammatory effects. Cis- UCA significantly decreased the proportion of CD25hi Foxp3+ cells from activated CD4+ T cells. It also decreased the expression of vitamin D receptor in CD4+ T cells which may interfere with the immune regulatory function of vitamin D. These results suggested that there might be a fine balance between UV-induced anti-inflammatory molecules’ effect on CD4+ T cells. However, Cis-UCA also modulated CD4+ T cell directly by decreasing CD4+ T cell proliferation, decreasing phosphorylation of ERK after TCR activation, enhancing immune suppressive cytokines secretion, and inhibiting the percentage of CLA+CD4+T cells suggesting a decreased ability to migrate to the skin, . Cis-UCA also affected the phenotype and function of antigen presenting cells by decreasing the expression of HLA-DR, CD86 and CD40 on immature mo-DCs, which led to increased proportion of CD25+Foxp3+CD127- T cells when co-cultured with allogenic CD4+ T cells. Results generated from the clinical study in which all 29 patients got better after phototherapy suggested although circulating 25 (OH) vitamin D concentration was significantly increased after NB-UVB phototherapy, the change of circulating 25 (OH) vitamin D concentration did not correlate with disease improvement. This suggests that vitamin D is not the only pathway involved and that other molecules contribute to UVB-induced immune-regulation. The data also show that of the levels of circulating nitrate and the FLG genotype did not correlate with improvement / change with phototherapy. However, the expression of CD69 and CLA on circulating CD4+ T cells was decreased after treatment suggesting that UVB affected T cell activation and migration to the skin, and their importance in determining clinical responses requires further investigation. Taken together, the results from my study provide evidence that vitamin D is not the only molecule responsible for the beneficial effect of NB-UVB phototherapy. NO and cis-UCA may down-regulate immune responses by affecting human peripheral CD4+ T cells and mo- DCs phenotype and function. A further understanding of the effect of NO and cis-UCA on skin resident immune cells will provide more insights for narrowing NB-UVB phototherapy which will help to select patients that most likely to benefit from a mechanism-based treatment.

616.5

MS-275 (ENTINOSTAT) PROMOTES SUSTAINED TUMOR REGRESSION IN THE CONTEXT OF BOOSTING ONCOLYTIC IMMUNOTHERAPY

Nguyen, Andrew

10 1900

<p>We showed previously that histone deacetylase (HDAC) inhibition with MS-275 in the context of boosting oncolytic immunotherapy can drive heightened antitumor responses, leading to increased survival in mouse intracranial melanoma models. However, it is currently unclear how the co-administration of MS-275 directly impacts tumor growth. Here, we investigated the role of MS-275 in preventing the outgrowth of antigen-deficient tumor variants as a result of suboptimal treatment protocols. By adoptively transferring tumor antigen-specific memory T cells (Tm) that were expanded <em>in vivo</em> with recombinant Vesicular Stomatitis Virus (VSV-gp33), we observed complete regression of 5-day old, intradermal B16-gp33 tumors (B16-F10 overexpressing the LCMV GP33-41 epitope); however, the tumors relapsed within a month of treatment. Relapsing tumor explants were able to grow in mice that were prophylactically immunized with recombinant Adenovirus (Ad-gp33), indicating that the tumor could no longer be recognized. Strikingly however, there was zero tumor recurrence if MS-275 was co-administered with Tm and VSV-gp33, suggesting that MS-275 may prevent the emergence and/or escape of antigen loss variants. Such a benefit is lost if the administration of the drug is delayed as little as five days post VSV treatment, suggesting that its synergistic effects coincide with early immune responses and oncolytic activity. Furthermore, transplantation studies of relapsing tumor explants showed that combination treatment was unable to provide tumor protection, confirming that the mechanisms by which MS-275 prevents tumor recurrence are unlikely through direct up-regulation of antigen presentation in low- or non-antigen-expressing variants <em>in vivo</em>. Indeed, CD4 depletion in the absence of MS-275 resulted in sustained tumor regression, implying that immunoregulatory cells such as CD4+ Treg play a prominent role in sustaining tumor regression. Moreover, MS-275 modulates the phenotypic status of tumor-infiltrating MDSCs toward the differentiation of inflammatory macrophages. Taken together, the data suggests that combination therapy with HDACi with oncolytic immunotherapy mediates a synergized immune attack against the tumor through subversion of immunomodulatory mechanisms.</p> / Master of Science in Medical Sciences (MSMS)

oncolytic immunotherapy

vesicular stomatitis virus (VSV)

adoptive transfer therapy

histone deacetylase inhibitor (MS-275)

regulatory T cells (Tregs)

myeloid-derived suppressor cells (MDSCs)

Medical Immunology

Medical Immunology