IVIG regulates the survival of human but not mouse neutrophils.

Intravenous immunoglobulin (IVIG) are purified IgG preparations made from the pooled plasma from thousands of healthy donors and are being tested in preclinical mouse models. Inherent challenges, however, are the pluripotency of IVIG and its xenogeneicity in animals. IVIG can alter the viability of human neutrophils via agonistic antibodies to Fas and Siglec-9.

Exposure of IgG to an acidic environment results in molecular modifications and in enhanced protective activity in sepsis.

IgG molecules are exposed on a regular basis to acidic conditions during immunoaffinity purification procedures, as well as during the production of some therapeutic immunoglobulin preparations. This exposure is known to induce in them an antigen-binding polyreactivity. The molecular mechanisms and the possible biological significance of this phenomenon remain, however, poorly understood.

Protein destabilizing agents induce polyreactivity and enhanced immunomodulatory activity in IVIg preparations.

Normal pooled human IVIg are produced using various blood protein fractionation technologies and as a result they may well differ in their biological properties. We have demonstrated that exposure of IVIg, for a period as short as 15 min, to protein-destabilizing agents like acidic pH, ROS or pro-oxidative ferrous ions dramatically increases the panel of recognized Ag including pro-inflammatory cytokines. We now show that exposure of IVIg to ferrous ions modifies some IgG molecules without denaturating them and enhances the protective activity of the preparation in experimental septic shock.

Intravenous immunoglobulin up-regulates the expression of the inhibitory FcgammaIIB receptor on B cells.

Intravenous immunoglobulin (IVIg) preparations are known to modulate autoimmune/inflammatory diseases through several F(ab')(2)- and Fc-dependent mechanisms. In this study, we show that the in vitro and the in vivo exposure of B lymphocytes from lupus-prone and from healthy mice to IVIg results in an increased expression of their surface inhibitory FcgammaIIB receptors. Further, this exposure enhanced the ability of a chimeric antibody, cross-linking FcgammaRIIB and immunoglobulin receptors on DNA-specific B lymphocytes, to suppress IgG anti-DNA antibody production.