Novel Complement Inhibitor Limits Severity of Experimentally Myasthenia Gravis

Overview

Journal Ann Neurol

Specialty Neurology

Date 2009 Feb 6

PMID 19194881

Citations 35

Authors

Jindrich Soltys

Linda L Kusner

Andrew Young

Chelliah Richmonds

Denise Hatala

Bendi Gong

Vaithesh Shanmugavel

Henry J Kaminski

Affiliations

Soon will be listed here.

Abstract

Objective: Complement mediated injury of the neuromuscular junction is considered a primary disease mechanism in human myasthenia gravis and animal models of experimentally acquired myasthenia gravis (EAMG). We utilized active and passive models of EAMG to investigate the efficacy of a novel C5 complement inhibitor rEV576, recombinantly produced protein derived from tick saliva, in moderating disease severity.

Methods: Standardized disease severity assessment, serum complement hemolytic activity, serum cytotoxicity, acetylcholine receptor (AChR) antibody concentration, IgG subclassification, and C9 deposition at the neuromuscular junction were used to assess the effect of complement inhibition on EAMG induced by administration of AChR antibody or immunization with purified AChR.

Results: Administration of rEV576 in passive transfer EAMG limited disease severity as evidenced by 100% survival rate and a low disease severity score. In active EAMG, rats with severe and mild EAMG were protected from worsening of disease and had limited weight loss. Serum complement activity (CH(50)) in severe and mild EAMG was reduced to undetectable levels during treatment, and C9 deposition at the neuromuscular junction was reduced. Treatment with rEV576 resulted in reduction of toxicity of serum from severe and mild EAMG rats. Levels of total AChR IgG, and IgG(2a) antibodies were similar, but unexpectedly, the concentration of complement fixing IgG(1) antibodies was lower in a group of rEV576-treated animals, suggesting an effect of rEV576 on cellular immunity.

Interpretation: Inhibition of complement significantly reduced weakness in two models of EAMG. C5 inhibition could prove to be of significant therapeutic value in human myasthenia gravis.

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