Fingolimod induces neuroprotective factors in human astrocytes

We observed that FTY-P induces LIF, IL11, and HBEGF gene expressions and LIF and IL11 protein secretions in human astrocytes, both in absence and presence of the inflammatory cytokine TNF. Neuroprotective effects have been attributed to these proteins: LIF protects neuronal precursor cells in the substantia nigra in a murine Parkinson’s disease model in vivo [36]. Ischemic preconditioning in the retina is mediated via LIF receptor in vivo [37]. While high LIF concentrations increase the number of MBP+ cells in spinal cord explants, but not myelination/differentiation [38], myelination is enhanced in vitro by LIF with an optimum at low concentrations [39] in the order of magnitude as observed in our model after 1 week of continuous stimulation, suggesting that the amount of LIF produced by FTY-P stimulation is biologically effective. IL11, which belongs to the IL6 family like LIF and CNTF [40], promotes survival and maturation of oligodendrocytes and myelin formation in rodent CNS cultures [41, 42] and enhances survival of oligodendrocytes and neurons in an EAE model [42]. In addition, IL11 exerts immunoregulatory effects in rodent EAE [42]. HBEGF has been shown to restore neurogenesis in neuronal degenerative disorders and in ischemia induced brain injury [43]. Furthermore, it can enhance the survival of dopaminergic neurons [44]. Hence, a neurotrophic capacity of these proteins has been established previously and their induction by FTY-P reported in this study suggests a potential role of FTY-P in neuroprotection. We observed that the endogenous ligand S1P has principally similar effects inducing neuroprotective mediators in astrocytes. Thus, one may speculate that the pharmacological agent may enhance an already existing endogenous feature of the S1P system in human astrocytes.

In addition, FTY-P suppressed TNF-induced expression of inflammatory cytokines (BAFF, CXCL10), which could likely contribute to its beneficial effect on inflammation. BAFF and CXCL10 are key mediators in neuroinflammation: BAFF expression is elevated in MS lesions to levels observed in lymphatic organs [18]. Staining localized BAFF to astrocytes and activated astrocytes can produce greater amounts of bioactive BAFF per cell than activated macrophages, suggesting that BAFF derived from astrocytes is quantitatively meaningful [18]. Therefore, BAFF is thought to be a relevant part of the B-cell fostering environment and to perpetuate the immune response observed in the CNS of patients with MS [45]. In addition, BAFF was reported to bind to rodent neurons via BAFF-R [46] and NOGO-R [47]. Functional consequences in humans deserve further elaboration. CXCL10 binds to CXCR3 expressed i.a. on many mononuclear immune cell types. When present in the CNS, it recruits inflammatory mononuclear cells to the CNS and contributes to EAE pathogenesis [48]. TNF is a prototypic inflammatory cytokine produced by immune cells and CNS resident cells in the context of inflammation. TNF is present in active MS lesions [49], and TNF CSF concentrations correlate with disease progression in MS [50]. Soluble TNF can exert toxic effects directly via death-domain containing TNFR1 on oligodendrocytes and neurons [51, 52] and indirectly via astrocytes, which might then amplify inflammatory signals. Plain TNF antagonists, however, abolish also protective signaling for neurons and oligodendrocytes via TNFR2 and provoke or exacerbate MS [53, 54]. Suppressing proinflammatory cytokines produced by astrocytes downstream of TNF circumvents the risks associated with total TNF blockade [53]. Therefore, this is a perspective to limit further inflammation without the risk of reducing TNFR2-mediated protective signals. This constitutes a complementary approach to inhibitors selective for TNFR1 or soluble TNF [55, 56]. In contrast to the inhibition of TNF-induced CXCL10 demonstrated here, a recent study did not observe inhibition of CXCL10 induced by IL1β in astrocytes, but FTY-P was applied only at a much lower concentration of 0.1 μM [57].

Adverse events in fingolimod treated patients include upper respiratory tract infections. Neurotropic herpes virus infection and reactivation occurred more frequently in the fingolimod-treated patients [22]. MX1 and OAS2 are antiviral proteins that play an important role in the type I interferon-mediated response against a broad range of viral infections [58‐60]. Blocking of the antiviral mediators MX1 and OAS2 might extend the spectrum of immunosuppressive effects of FTY-P beyond impaired CCR7+ lymphocyte egress from secondary lymphatic organs and impaired antigen shuttling in the spleen marginal zone [61].

Since the main mode of action of FTY-P known in lymphocytes is receptor downmodulation and functional antagonism, we elaborated whether our findings are detectable also during continuous stimulation for up to 1 week. Albeit at a lower level, all effects persisted. Furthermore, there was no fundamental difference between S1P and FTY-P stimulation, as would be expected in the case of functional antagonistic effects by FTY-P as opposed to agonistic effects by S1P. This suggests that receptor agonistic signaling is present in long term, possibly because receptor downmodulation may be incomplete and partially compensated by persistent signaling after internalization [7, 9]. In line with this concept, also repeated application of FTY-P for 3 days results in sustained inhibition of intracellular calcium release by IL1β in human astrocytes. In fact, profound differences regarding S1PR1 expression, regulation, and signaling between lymphocytes and other cell types have been described: lymphocyte recirculation was suggested to be “exquisitely sensitive” [10] to receptor downmodulation as opposed to other cell types. Reasons might include lower surface expression of S1P1R [10] and a higher threshold of occupancy needed for cellular activation [11] in lymphocytes. In addition, e.g., endothelial cells, but not lymphocytes, have a substantial intracellular reserve of S1P1R, allowing for more continuous signaling [11]. Taken together, the sustained induction of neurotrophic factors and suppression of inflammatory genes in astrocytes by repeated application of FTY-P is in line with different signaling and receptor kinetics in different cell types.

Using a ligand that cannot cross the cell membrane (DH-S1P) [34], we excluded the possibility that induction of neurotrophic factors and reduction of inflammatory cytokines is mediated primarily by direct intracellular effects [4, 11], which would not be subjected to receptor downmodulation.

However, we demonstrated an involvement of surface S1PR3 and to a lesser extent S1PR1. The involvement of the S1PR1 is in line with an EAE model utilizing several knockout approaches, where the therapeutic effect of FTY720 was reported to be linked to S1P1R on astrocytes [23]. The important role of S1PR1 in EAE was further strengthened by the finding that defective phosphorylation of S1PR1 exacerbated TH17-mediated autoimmune neuroinflammation [62]. Our data indicate that also S1PR3 contributes to induction of neurotrophic factors by FTY-P.

Taken together, we observed that FTY-P induced neurotrophic factors and blocked inflammatory cytokines in astrocytes. These findings open the possibility that a part of the beneficial effects of FTY720 could be mediated via astrocytes.