Abstract 4738

Introduction

IVIg is known to have immunosuppressive effects in a variety of inflammatory and autoimmune diseases, which may be caused by modulations of T cell functions in treated patients. The mechanisms responsible for these modulations have been mostly investigated using in vitro stimulated T cells. These studies revealed that IVIg inhibited the proliferation of activated T cells possibly by interfering with the secretion of cytokines important for T cell proliferation, such as IL-2. In the present study, we sought to determine the precise mechanism by which IVIg inhibited cytokine secretion by stimulated T cells.

Methods

Human PBMC and Jurkat T cells were stimulated with PHA. Human T cells purified from PBMC were stimulated with CD3/CD28 T cell expander beads. Cells were cultured in presence or not of 10 mg/ml of IVIg for 24 hours. IL-2 secretion was measured in the culture supernatants by ELISA. IVIg was depleted of PHA-reactive IgG by passage on a PHA-Sepharose column. The extent of depletion was evaluated by ELISA using PHA as capture antigen. The role of F(ab')2 fragments in the inhibitory effect of IVIg on IL-2 secretion was determined using pepsin-generated fragments.

Results

IVIg inhibited IL-2 secretion by PHA-stimulated T cells, as previously reported. However, the use of increasing concentrations of PHA for T cell stimulation led to a decreased ability of IVIg to inhibit IL-2 production, suggesting that IVIg acted by neutralizing PHA or by competition for receptor occupancy on the cell surface. Pre-incubation of T cells with IVIg followed by washing and addition of PHA did not result in inhibition of IL-2 secretion, indicating that competition for receptor was not involved in this IVIg-mediated inhibition. In contrast, inhibition of IL-2 production by IVIg was completely abrogated using IVIg depleted from PHA-reactive IgG, indicating that IVIg-mediated inhibition of IL-2 secretion was the consequence PHA neutralization. Testing of F(ab')2 fragments of IVIg showed that these fragments bound to PHA and inhibited IL-2 secretion as efficiently as IVIg. Using another activation strategy, we showed that IVIg could also decrease IL-2 secretion by purified human T cells following anti-CD3/CD28 stimulation. Preliminary data using light microscopy indicated that IVIg interfered with the binding of CD3/CD28 beads on T cells, therefore reducing cell activation as evaluated by IL-2 secretion.

Conclusion

Altogether, our results suggest that the inhibition of T cell responses by IVIg occurs during the cell activation step, by preventing the binding of mitogens or antibody-coated beads on the cell surface. These observations emphasize the importance of ruling out the possible interactions of IVIg with culture medium additives, mitogens or activating agents before deriving strong conclusions on the mechanisms of action of IVIg based on their apparent immunomodulatory effects observed in vitro assays.

Disclosures:

No relevant conflicts of interest to declare.

Author notes

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Asterisk with author names denotes non-ASH members.

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