2A) In this experimental setting, we also observed a significant

2A). In this experimental setting, we also observed a significant increase selleck inhibitor in the expression of the activation marker CD38 on B-cell surface after IFN-β treatment (Supporting Information Fig. 2B). Given that this protein is notoriously type I IFN inducible

[20], this result clearly shows that B lymphocytes are target of the IFN-β therapy confirming previous study by Zula et al. [21] who described a rapid activation of IFN signal transduction pathways in B cells present in unseparated blood from RRMS patients soon after IFN-β injection. In the past, we dissected the regulation of TLR7 in maturing monocyte-derived DCs and observed that its transcription was dependent on the endogenous IFN-β release [22]. Thus, to evaluate whether IFN-β therapy would modulate TLR7 expression in MS patients, we first monitored by real-time RT-PCR TLR7 level of transcription, together with that of TLR9, in MS patients versus HDs. It was of great interest to find that PBMCs obtained from MS patients display a clear defect, as compared with those of HDs, in TLR7 expression that was statistically significant (25 HDs and 45 MS patients analyzed) (Fig. 2A). This difference was not observed in the transcription

of TLR9 gene (Fig. 2B), demonstrating that in MS patients, the defective TLR7 expression is specific. Furthermore, we observed that in PBMCs isolated from the same MS patients Roscovitine molecular weight following 1 month of IFN-β therapy, the level of TLR7 mRNA was restored to the level observed in HDs, while that of TLR9 was not modulated (Fig. 2A and B). In the attempt to investigate which TLR7-expressing cell types in the peripheral blood might be responsible for this defect in MS patients, B cells and monocytes were purified from both HDs and MS patients at baseline and 1 month after the beginning of IFN-β therapy, since these two leukocyte populations express TLR7. Data on TLR7 expression in B cells isolated from HDs or MS (7 and 13 individuals, respectively) did not mirror the impairment observed in the context of the

mixed cell population of PBMCs (Fig. 2C and D), although a slightly enhanced level of TLR7 transcription in response to IFN-β Orotidine 5′-phosphate decarboxylase occurred also in this experimental setting. As observed in unseparated PBMCs, TLR9 levels of B cells did not differ in HDs and MS patients irrespective of IFN-β treatment. Interestingly, when the expression of TLR7 was analyzed in monocytes of MS patients (13 individuals), a different picture appeared. Indeed, a lower TLR7 mRNA level was highlighted in monocytes from MS patients than that obtained from HD (8 individuals) and, moreover, also a robust induction was observed in response to IFN-β therapy (longitudinal analysis of 5 patients at baseline and 1 month after IFN-β treatment) (Fig. 2E). TLR9 expression was absent in monocytes (data not shown). These data for the first time indicated a defect in TLR7 signaling in monocytes of MS patients.

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