Human regulatory B cells control the TFH cell response.

BACKGROUND: Follicular helper T (TFH) cells support terminal B-cell differentiation. Human regulatory B (Breg) cells modulate cellular responses, but their control of TFH cell-dependent humoral immune responses is unknown. OBJECTIVE: We sought to assess the role of Breg cells on TFH cell development and function. METHODS: Human T cells were polyclonally stimulated in the presence of IL-12 and IL-21 to generate TFH cells. They were cocultured with B cells to induce their terminal differentiation. Breg cells were included in these cultures, and their effects were evaluated by using flow cytometry and ELISA. RESULTS: B-cell lymphoma 6, IL-21, inducible costimulator, CXCR5, and programmed cell death protein 1 (PD-1) expressions increased on stimulated human T cells, characterizing TFH cell maturation. In cocultures they differentiated B cells into CD138+ plasma and IgD-CD27+ memory cells and triggered immunoglobulin secretions. Breg cells obtained by Toll-like receptor 9 and CD40 activation of B cells prevented TFH cell development. Added to TFH cell and B-cell cocultures, they inhibited B-cell differentiation, impeded immunoglobulin secretions, and expanded Foxp3+CXCR5+PD-1+ follicular regulatory T cells. Breg cells modulated IL-21 receptor expressions on TFH cells and B cells, and their suppressive activities involved CD40, CD80, CD86, and intercellular adhesion molecule interactions and required production of IL-10 and TGF-ß. CONCLUSION: Human Breg cells control TFH cell maturation, expand follicular regulatory T cells, and inhibit the TFH cell-mediated antibody secretion. These novel observations demonstrate a role for the Breg cell in germinal center reactions and suggest that deficient activities might impair the TFH cell-dependent control of humoral immunity and might lead to the development of aberrant autoimmune responses.

Intravenous immunoglobulin induces a functional silencing program similar to anergy in human B cells.

BACKGROUND: Chronic inflammatory and autoimmune diseases are largely due to inappropriate response of hyperactive or autoreactive B cells. These autoreactive B cells can evade central tolerance checkpoints and migrate to the periphery, where they would be silenced by anergy. Such anergic cells are characterized by B-cell receptor (BCR) desensitization and altered downstream signaling. OBJECTIVE: We sought to determine whether intravenous immunoglobulin (IVIg) induces a nonresponsive state of B cells and to address the similarities of this mechanism to those described in anergy. METHODS: Human B cells were stimulated with anti-IgM antibody, and effects of IVIg on several parameters, such as calcium release, tyrosine phosphorylation, BCR aggregation, BCR internalization, or transcriptional activity, were studied by using flow cytometry, confocal microscopy, Western blotting, and a quantitative PCR array. RESULTS: IVIg-treated B cells show defects in activating coreceptor expression, calcium signaling, and BCR aggregation on engagement by antigen. IVIg also induces suppression of phosphoinositide 3-kinase signaling, which plays a central role in determining B-cell fate. All these events ultimately lead to profound modifications in gene expression, resulting in long-term functional but reversible silencing of IVIg-treated B cells. CONCLUSION: Our findings provide insights into the effectiveness of IVIg in treating autoimmune or inflammatory pathologies associated with the loss of B-cell tolerance. Furthermore, these data provide a model to explore the complexity of positive versus negative selection in B cells.

IVIg modulates BCR signaling through CD22 and promotes apoptosis in mature human B lymphocytes.

Among various mechanisms for interactions with B cells, intravenous immunoglobulin (IVIg) may operate through the insertion of its Fc part into the Fc-γ receptor, or the binding of its sialic acid (SA)-bearing glycans to the negatively regulating CD22 lectin. It appeared that IVIg reduces B lymphocyte viability in a dose- and time-dependent manner. Furthermore, we show by confocal microscopy that SA-positive IgG, but not SA-negative IgG bind to CD22. This interaction reduces the strength of B-cell receptor-mediated signaling trough down-regulating tyrosine phosphorylation of Lyn and the B-cell linker proteins, and up-regulating phospholipase Cγ2 activation. This cascade resulted in a sustained activation of Erk 1/2 and arrest of the cell cycle at the G(1) phase. These changes may be accounted for the efficacy of IVIg in autoimmune diseases.

TLR9 responses of B cells are repressed by intravenous immunoglobulin through the recruitment of phosphatase.

One way for intravenous Ig (IVIg) to affect responses of the B cells might be to operate through their TLR7 and TLR9. We confirm the ability of TLR agonists to induce CD25 expression in B cells. For this to occur, sialylated Fc-gamma of IgG included in the IVIg preparation are required. As a result, IVIg suppresses TLR-induced production of the proinflammatory IL-6, but not that of the anti-inflammatory IL-10. That is, IVIg mimics the effects of the MyD88 inhibitor. Finally, as we previously showed that IVIg induces CD22 to recruit the inhibitory SHP-1, we established that this enzyme was also involved in IVIg-induced inhibition of TLR9 signaling. This is the first report to demonstrate such a mechanism underlying the negative impact of IVIg on B lymphocytes.

What is the contents of the magic draft IVIg?

Intravenous immunoglobulins (IVIg) consist of IgG concentrated from pooled plasma of numerous donors. Their contents is variable, depending in part on the method of preparation. Natural antibodies and natural autoantibodies are prominent in these preparations and their function. Among these, are the idiotype (Id)/anti-Id dimers. Attention has recently been paid to Fc-gamma receptors and sialylation of the IgG from IVIg.