In vivo IgM depletion by anti-mu monoclonal antibody therapy. The role of IgM in hyperacute vascular rejection of discordant xenografts.

Xenoreactive natural antibodies (XNA) and complement activation are thought to be the 2 main factors responsible for the hyperacute vascular rejection (HVR) of discordant xenografts. The aim of this work was to study the role of IgM XNA in the HVR of guinea pig to rat cardiac xenografts, a discordant model. Adult LOU/C rats were depleted of circulating IgM and therefore of IgM XNA using an anti-mu mAb (mouse anti-rat IgM mAb 7 [MARM-7]). Rats were injected with 10 mg and 5 mg of MARM-7 at days -3 and -1, respectively, and guinea pig cardiac xenografts were performed on day 0. Control animals were injected on the same days with 10 mg and 5 mg of anti-alpha mAb (MARA-1) or equivalent volumes of PBS. Xenografts were performed on day 0. Guinea pig cardiac xenograft survival time was significantly prolonged in IgM-depleted animals (62 min, P < 0.01) compared with controls using PBS (18 min) or MARA-1 mAb (12 min). This prolongation was not due to a decrease in the complement activity in IgM-depleted rats, since no significant variation of the C1q, C4, C3, and C5 complement hemolytic activity was observed between control and treated animals before HVR. Prolongation of the xenograft survival time in the MARM-7-treated group was correlated with an undetectable serum level of IgM and IgM XNA and a lack of IgM XNA deposits on the rejected xenograft vascular endothelium. Contrarily, both IgM-depleted and control animals showed C3 deposits on the rejected xenograft vascular endothelium and myocardium, as well as diffuse deposits of IgG2a XNA. Although HVR was not abrogated by the depletion of IgM XNA, our data indicate that IgM is implicated in the HVR and that the anti-mu approach is a potential therapeutic treatment for discordant xenografts. Finally, we suggest that other factors such as IgM-independent activation of complement might be one of the mechanisms responsible for the pathogenesis of HVR in the guinea pig to rat xenograft model.