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Regulatory T cells (Treg) are critical immune cells to ensure immune homeostasis. Treg do so by establishing tolerance to self-antigens as well as food-derived antigens. Additionally, they fine-tune immune responses to limit the damage caused by inevitable inflammation during the resolution of an ongoing infection or anti-tumor response. Despite countless efforts to gain a detailed understanding of the mechanisms Treg utilize to regulate adaptive immune responses, in vivo evidence is rather limited. We were interested in the cell-cell interactions of Treg and their spatio-temporal dynamics during a viral infection. We sought to address Interleukin-2 (IL-2) competition as a viable mechanism to control anti-viral CD8 T cell responses. We used intra-vital 2-photon imaging to analyze the interactions between Treg and activated T cells during viral infection. Additionally, we performed multiple loss- and gain-of-function experiments, addressing the IL-2 active signaling of CD8, CD4, and regulatory T cells to understand the competitive sensing of IL-2. Finally, we performed single-cell RNA sequencing to understand the cell-intrinsic differences in Treg caused by infection. We found that IL-2 competition by Treg limits the CD8 T cell response and can alter the differentiation of CD8 T cells. Furthermore, we show that Treg do not arrest in proximity to CD8 T cells for prolonged periods and therefore are unlikely to regulate CD8 T cells via contact-dependent mechanisms previously proposed. Our data support an area control model in which Treg scavenge IL-2 while actively migrating through the LN, constantly limiting access to IL-2. Establishing CD4 T cells as the major source of IL-2 during the later phases of infection, we provide direct evidence that Treg compete with CD8 T cells for CD4-derived IL-2. Finally, we show that IL-2 limitation is in correlation with CD25 expression levels and has an impact on the differentiation of CD8 T cells. Altering the differentiation of CD8 T cells to increase effector or memory functions has huge implications in clinical treatments, e.g ’checkpoint immunotherapy’. Especially in scenarios like checkpoint immunotherapy, where an efficient expansion of CD8 T cells is vital to the success of the treatment, it is invaluable to understand the spatio-temporal dynamics of Treg. Not only can the expansion phase be optimized, but also side effects can be better controlled by ensuring the adequate timing of treatments and boosting the anti-inflammatory response after the initial establishment of CD8 T cells. On top of this, the gained understanding of the regulatory mechanism of Treg can help to enhance the efficacy of autoimmune disorder treatments. Overall, this study addressed highly relevant questions in the Treg field and answered aspects of Treg regulation, refining their mode of action and the spatio-temporal dynamics during viral infection, providing evidence for IL-2 competition as a major regulatory mechanism controlling antiviral CD8 T cell responses.
Lack of acid sphingomyelinase (ASM) activity, either through genetic deficiency or through pharmacological inhibition, is linked with increased activity and frequency of Foxp3+ regulatory T cells (Treg) among cluster of differentiation (CD) 4+ T cells in mice in vivo and in vitro1. Thus, pharmacological blockade of ASM activity, which catalyzes the cleavage of sphingomyelin to ceramide and phosphocholine, might be used as a new therapeutic mechanism to correct numeric and/ or functional Treg de-ficiencies in diseases like multiple sclerosis or major depression.
In the present study, the effect of pharmacological inhibition of ASM in humans, in vitro and in vivo, was analyzed. In the in vitro experiments, peripheral blood mono-nuclear cells (PBMC) of healthy human blood donors were treated with two widely prescribed antidepressants with high (sertraline, Ser) or low (citalopram, Cit) capaci-ty to inhibit ASM activity. Similar to the findings in mice an increase in the frequency of Treg among human CD4+ T cells upon inhibition of ASM activity was observed. For the analysis in vivo, a prospective study of the composition of the CD4+ T cell com-partment of patients treated for major depression was done. The data show that pharmacological inhibition of ASM activity was superior to antidepressants with little or no ASM-inhibitory activity in increasing CD45RA- CD25high effector Treg (efTreg) frequencies among CD4+ T cells to normal levels. Independently of ASM inhibition, correlating the data with the clinical response, i.e. improvement of the Hamilton rat-ing scale for depression (HAMD) by at least 50 per cent (%) after four weeks of treatment, it was found that an increase in efTreg frequencies among CD4+ cells dur-ing the first week of treatment identified patients with a clinical response.
Regarding the underlying mechanism, it could be found that the positive effect of ASM inhibition on Treg required CD28 co-stimulation suggesting that enhanced CD28 co-stimulation was the driver of the observed increase in the frequency of Treg among human CD4+ T cells. Inhibition of ASM activity was further associated with changes in the expression and shuttling of CTLA-4, a key inhibitory molecule ex-pressed by Treg, between cellular compartments but the suppressive activity of CTLA-4 through its transendocytosis activity was unaffected by the inhibition of ASM activity.
In summary, the frequency of (effector) Treg among CD4+ T cells in mice and in hu-mans is increased after inhibition of ASM activity suggesting that ASM blockade might beneficially modulate autoimmune diseases and depression-promoting in-flammation.
CD4+Foxp3+ Tregs can be induced in vitro by TGF-b stimulation. Here, CNS1 deficient CD4+ T cells were found to show compromised Foxp3 upregulation in vitro compared to CNS1 WT CD4+ T cells. Moreover, we could demonstrate that antigen-specific CD4+Foxp3+ Tregs can be induced in vivo by tolerogenic antigen stimulation. Parenteral application of agonist BDC2.5 mimetope induced Foxp3 expression in CD4+ BDC2.5 tg cells. We could show that induction of Foxp3 expression by tolerogenic peptide stimulation is impaired in CNS1 deficient CD4+ BDC2.5 tg cells compared to CNS1 WT CD4+ BDC2.5 tg controls. These results indeed indicate that in vivo induced Tregs share mechanistic characteristics with naturally occurring pTregs.
Additional in vivo experiments with blocking monoclonal anti-TGF-b demonstrated that high dosage TGF-b blockade abrogated peptide-induced Foxp3 expression in CNS1 WT BDC2.5 tg CD4+ cells, akin to what is seen for impaired Foxp3 upregulation in peptide-stimulated CNS1 KO BDC2.5 tg CD4+ cells without anti-TGF-b-treatment.
Adoptive transfer of CD4+CD25- T cells in T cell deficient recipients dramatically increased CD4+Foxp3+ Treg frequencies in both CNS1 WT CD4+ and CNS1 KO CD4+ donor cells. Despite an initially lower increase in Foxp3 expression in CNS1 KO donor cells compared to CNS1 WT donor cells early after transfer, in this setting impaired Treg induction in CNS1 deficient cells was not preserved over time. Consequently, diabetes onset and progression were indistinguishable between mice that received CNS1 WT or CNS1 KO donor cells. Additional Foxp3 induction by peptide stimulation of immunodeficient recipients after transfer of CNS1 WT BDC2.5. tg or CNS1 KO BDC2.5 tg donor cells was not detectable.
Einfluss der sauren Sphingomyelinase auf anti-virale T-Zellantworten im Masernvirus-Infektionsmodell
(2017)
Die saure Sphingomyelinase (Asm), ein Enzym des Sphingolipidmetabolismus,
spaltet Sphingomyelin zu Ceramid und Phosopocholin. Aktiviert wird die Asm unter
anderem durch Stimulation des CD28 Rezeptors. CD28 Signale werden auch für die
Aktivierung von konventionellen T-Zellen (Tconv) und für die Kostimulation benötigt
und sind essentiell für die Differenzierung von regulatorischen T-Zellen (Treg) im
Thymus und deren Erhalt in der Peripherie. Wir konnten zeigen, dass sich Tconv und
Treg Zellen hinsichtlich der Asm unterscheiden. Treg haben eine höhere "basale"
Asm Aktivität, widergespiegelt im höheren Ceramidgehalt und haben eine niedrigere
Lipidordnung als Tconv Zellen. Die Abwesenheit der Asm in defizienten Mäusen
bewirkt einen relativen Anstieg der Treg-Frequenz innerhalb der CD4+ T-Zellen.
Außerdem führt die Asm-Defizienz in Treg Zellen zu einer erhöhten Umsatzrate des
immunsupprimierenden Moleküls CTLA-4 und zu einer verstärkten Suppressivität
von Treg Zellen aus Asm-/- Mäusen gegenüber Wildtyp Zellen. Ein Anstieg in der
Treg-Frequenz, äquivalent zur genetischen Defizienz, kann auch durch Inhibition der
Asm, d. h. durch Wirkstoffe wie Amitriptylin und Desipramin erreicht werden. Es
konnte gezeigt werden, dass die Inhibitorbehandlung die absolute Anzahl der Tconv
Zellen selektiv verringert, da Treg Zellen gegenüber dem Asm Inhibitor-induzierten
Zelltod resistenter sind. Mechanistisch erklärbar sind die Unterschiede gegenüber
den proapoptotischen Inhibitoreffekten zwischen Tconv und Treg Zellen dadurch,
dass Treg Zellen durch die Anwesenheit von IL-2 geschützt sind. In Abwesenheit von
IL-2 sterben die Treg Zellen ebenfalls. Die gezielte Veränderung des Verhältnisses
von Treg zu Tconv durch den Einsatz von Asm-inhibitorischen Medikamenten kann
hilfreich bei der therapeutischen Behandlung von inflammatorischen- und
Autoimmunerkrankungen sein.
Inwiefern die Asm für die Funktion von T-Zellen in der anti-viralen Immunantwort
entscheidend ist, wurde im Masernvirus-Infektionsmodell näher untersucht. In Asm-/-
Mäusen und Amitriptylin-behandelten Mäusen konnte gezeigt werden, dass in
Abwesenheit der Asm die Kontrolle der Masernvirusinfektion verschlechtert ist. Treg
sind auch hier von entscheidender Bedeutung, da die Asm-abhängige, verstärkte
Masernvirusinfektion bei Fehlen der Asm nur in Gegenwart von Treg auftritt. In der
akuten Phase gibt es in Asm-/- Mäusen weniger masernvirusspezifische T-Zellen und dadurch eine verringerte Beseitigung der Viruslast. In der chronischen Phase ist die
Anzahl masernvirusspezifischer T-Zellen zwischen WT und Asm-/- Mäusen
vergleichbar. In Letzteren ist allerdings die Anzahl und Frequenz von T-Zellen im
Gehirn infizierter Mäuse noch deutlich erhöht, was die verstärkte Maserninfektion
widerspiegelt.
Zusammenfassend zeigt sich, dass die Asm die Funktion von Treg moduliert und
einen Einfluss auf das Verhältnis von Tconv und Treg zueinander hat. Im
Masernvirus-Infektionsmodell kann die Veränderung des Tconv zu Treg
Verhältnisses in Abwesenheit der Asm ursächlich für die verringerte Viruskontrolle
sein. Die Asm Inhibitor-induzierte Treg-Aktivierung und die Beeinflussung des Treg
zu Tconv Verhältnisses können wiederum für therapeutische Zwecke genutzt
werden, wie beispielsweise bei Multipler Sklerose und Rheumatoider Arthritis.