In T cells, as in all other cells of the body, sphingolipids form important structural components of membranes. Due to metabolic modifications, sphingolipids additionally play an active part in the signaling of cell surface receptors of T cells like the T cell receptor or the co-stimulatory molecule CD28. Moreover, the sphingolipid composition of their membranes crucially affects the integrity and function of subcellular compartments such as the lysosome. Previously, studying sphingolipid metabolism has been severely hampered by the limited number of analytical methods/model systems available. Besides well-established high resolution mass spectrometry new tools are now available like novel minimally modified sphingolipid subspecies for click chemistry as well as recently generated mouse mutants with deficiencies/overexpression of sphingolipid-modifying enzymes. Making use of these tools we and others discovered that the sphingolipid sphingomyelin is metabolized to ceramide to different degrees in distinct T cell subpopulations of mice and humans. This knowledge has already been translated into novel immunomodulatory approaches in mice and will in the future hopefully also be applicable to humans. In this paper we are, thus, summarizing the most recent findings on the impact of sphingolipid metabolism on T cell activation, differentiation, and effector functions. Moreover, we are discussing the therapeutic concepts arising from these insights and drugs or drug candidates which are already in clinical use or could be developed for clinical use in patients with diseases as distant as major depression and chronic viral infection.

As structural membrane components and signaling effector molecules sphingolipids influence a plethora of host cell functions, and by doing so also the replication of viruses. Investigating the effects of various inhibitors of sphingolipid metabolism in primary human peripheral blood lymphocytes (PBL) and the human B cell line BJAB we found that not only the sphingosine kinase (SphK) inhibitor SKI-II, but also the acid ceramidase inhibitor ceranib-2 efficiently inhibited measles virus (MV) replication. Virus uptake into the target cells was not grossly altered by the two inhibitors, while titers of newly synthesized MV were reduced by approximately 1 log (90%) in PBL and 70–80% in BJAB cells. Lipidomic analyses revealed that in PBL SKI-II led to increased ceramide levels, whereas in BJAB cells ceranib-2 increased ceramides. SKI-II treatment decreased sphingosine-1-phosphate (S1P) levels in PBL and BJAB cells. Furthermore, we found that MV infection of lymphocytes induced a transient (0.5–6 h) increase in S1P, which was prevented by SKI-II. Investigating the effect of the inhibitors on the metabolic (mTORC1) activity we found that ceranib-2 reduced the phosphorylation of p70 S6K in PBL, and that both inhibitors, ceranib-2 and SKI-II, reduced the phosphorylation of p70 S6K in BJAB cells. As mTORC1 activity is required for efficient MV replication, this effect of the inhibitors is one possible antiviral mechanism. In addition, reduced intracellular S1P levels affect a number of signaling pathways and functions including Hsp90 activity, which was reported to be required for MV replication. Accordingly, we found that pharmacological inhibition of Hsp90 with the inhibitor 17-AAG strongly impaired MV replication in primary PBL. Thus, our data suggest that treatment of lymphocytes with both, acid ceramidase and SphK inhibitors, impair MV replication by affecting a number of cellular activities including mTORC1 and Hsp90, which alter the metabolic state of the cells causing a hostile environment for the virus.

Die Reifung, Differenzierung und Funktion von Lymphozyten wird maßgeblich von aktivierenden und inhibitorischen Zelloberflächenrezeptoren reguliert. "Killer cell Lectin-like receptor G1" (KLRG1) ist ein Typ-II-Transmembranprotein, dessen Expression auf Subpopulationen von T-Lymphozyten und Natürlichen Killerzellen beschränkt ist. Die vorliegende Arbeit hatte zum Ziel, die differentielle Expression und mögliche Funktion von KLRG1 auf diesen Zellen im Maussystem zu charakterisieren. Mit Hilfe zellbiologischer Untersuchungsmethoden konnte gezeigt werden, dass die KLRG1-Expressionsfrequenz mit dem Reifegrad der Zellen korreliert. Frühere Beobachtungen, wonach KLRG1 durch Erkennung eigener Klasse-I-Moleküle des Haupthistokompatibilitätskomplexes (MHC) über inhibitorische Rezeptoren der Ly49-Familie induziert wird, konnten auf klassische Klasse-I-Moleküle und neue Ly49-Familienmitglieder ausgeweitet werden. Ferner belegen Daten dieser Arbeit, dass reife NK-Zellen die KLRG1-Expressionsfrequenz in verschiedenen lymphoiden Organen dem Klasse-I-Niveau der umgebenden Zellen anpassen können und dass T- und B-Lymphozyten möglicherweise eine zentrale Rolle hierbei spielen. Somit stellt KLRG1 einen NK-Zellrezeptor dar, dessen Expression durch Ly49-Rezeptorengagement dynamisch reguliert wird. Es ist möglich, dass KLRG1 kompensatorische (ko-)inhibitorische Eigenschaften besitzt, die für die Aufrechterhaltung der Selbsttoleranz von NK-Zellen von Bedeutung sind. Unter den CD8-T-Zellen identifiziert ein polyklonales abT-Zellrezeptorrepertoire und die Expression von CD8 als ab-Heterodimer den 2-3%igen Anteil an KLRG1+ Zellen als konventionelle T-Zellen thymischen Ursprungs. Umfangreiche phänotypische und funktionelle Analysen ergaben, dass KLRG1-exprimierende CD8-Zellen sich aus ca. 20% proinflammatorischer Effektorzellen und ca. 80% Gedächtniszellen zusammensetzen. Aufgrund von Daten der Arbeitsgruppe Pircher scheint das Zellteilungsvermögen letzterer ausgeschöpft zu sein. Demzufolge markiert KLRG1 eine neue Subpopulation von CD8-T-Zellen, der sowohl Effektorzellen, als auch "replikativ seneszente" Gedächtniszellen angehören. Abschließende Untersuchungen ergaben, dass KLRG1 interessanterweise auch von 1-2% der CD4+ T-Zellen exprimiert wird und dass die KLRG1+ CD4-T-Zellen zum Großteil CD25 koexprimieren. Funktionelle Anschlußexperimente zeigten, dass es sich bei diesen Zellen um regulatorische T-Zellen handelt. Zusammenfassend kennzeichnet KLRG1-Expression eine Subpopulationen von NK-Zellen, die körpereigene Zellen über Klasse-I erkennen können, eine Untergruppe von Effektor- und seneszenten CD8-T-Zellen sowie neuartige regulatorische CD4-T-Zellen.

Genetic deficiency for acid sphingomyelinase or its pharmacological inhibition has been shown to increase Foxp3\(^+\) regulatory T-cell frequencies among CD4\(^+\) T cells in mice. We now investigated whether pharmacological targeting of the acid sphingomyelinase, which catalyzes the cleavage of sphingomyelin to ceramide and phosphorylcholine, also allows to manipulate relative CD4\(^+\) Foxp3\(^+\) regulatory T-cell frequencies in humans. Pharmacological acid sphingomyelinase inhibition with antidepressants like sertraline, but not those without an inhibitory effect on acid sphingomyelinase activity like citalopram, increased the frequency of Foxp3\(^+\) regulatory T cell among human CD4\(^+\) T cells in vitro. In an observational prospective clinical study with patients suffering from major depression, we observed that acid sphingomyelinase-inhibiting antidepressants induced a stronger relative increase in the frequency of CD4\(^+\) Foxp3\(^+\) regulatory T cells in peripheral blood than acid sphingomyelinase-non- or weakly inhibiting antidepressants. This was particularly true for CD45RA\(^-\) CD25\(^{high}\) effector CD4\(^+\) Foxp3\(^+\) regulatory T cells. Mechanistically, our data indicate that the positive effect of acid sphingomyelinase inhibition on CD4\(^+\) Foxp3\(^+\) regulatory T cells required CD28 co-stimulation, suggesting that enhanced CD28 co-stimulation was the driver of the observed increase in the frequency of Foxp3+ regulatory T cells among human CD4\(^+\) T cells. In summary, the widely induced pharmacological inhibition of acid sphingomyelinase activity in patients leads to an increase in Foxp3+ regulatory T-cell frequencies among CD4\(^+\) T cells in humans both in vivo and in vitro.

Acute graft-versus-host disease (aGvHD) is a major cause of morbidity and mortality after allogeneic hematopoietic stem cell plus T cell transplantation (allo-HSCT). In this study, we investigated the requirement for CD28 co-stimulation of donor CD4\(^{+}\) conventional (CD4\(^{+}\)CD25\(^{-}\)Foxp3\(^{-}\), Tconv) and regulatory (CD4\(^{+}\)CD25\(^{+}\)Foxp3\(^{+}\), Treg) T cells in aGvHD using tamoxifen-inducible CD28 knockout (iCD28KO) or wild-type (wt) littermates as donors of CD4\(^{+}\) Tconv and Treg. In the highly inflammatory C57BL/6 into BALB/c allo-HSCT transplantation model, CD28 depletion on donor CD4\(^{+}\) Tconv reduced clinical signs of aGvHD, but did not significantly prolong survival of the recipient mice. Selective depletion of CD28 on donor Treg did not abrogate protection of recipient mice from aGvHD until about day 20 after allo-HSCT. Later, however, the pool of CD28-depleted Treg drastically declined as compared to wt Treg. Consequently, only wt, but not CD28-deficient, Treg were able to continuously suppress aGvHD and induce long-term survival of the recipient mice. To our knowledge, this is the first study that specifically evaluates the impact of CD28 expression on donor Treg in aGvHD. Moreover, the delayed kinetics of aGvHD lethality after transplantation of iCD28KO Treg provides a novel animal model for similar disease courses found in patients after allo-HSCT.