Improved Therapeutic Efficacy of a Bifunctional Anti-C5 MAb-FH SCR1-5 Fusion Protein over Anti-C5 MAb in an Accelerated Mouse Model of C3 Glomerulopathy

Overview

Journal Immunohorizons

Date 2025 Jan 27

PMID 39865974

Authors

Sayaka Sato

Takashi Miwa

Damodar Gullipalli

Madhu Golla

Eshagh Mohammadyari

Lin Zhou

Matthew Palmer

Wen-Chao Song

Affiliations

Soon will be listed here.

Abstract

C3 glomerulopathy (C3G), a rare kidney disease caused by dysregulation of alternative pathway complement activation, is characterized by glomerular C3 deposition, proteinuria, crescentic glomerulonephritis, and renal failure. The anti-C5 monoclonal antibody (mAb) drug eculizumab has shown therapeutic effects in some but not all patients with C3G, and no approved therapy is currently available. Here, we developed and used a triple transgenic mouse model of fast progressing lethal C3G (FHm/mP-/-hFDKI/KI) to compare the therapeutic efficacy of a bifunctional anti-C5 mAb fused to a functional factor H (FH) fragment (short consensus repeat 1-5 [SCR1-5]) and the anti-C5 mAb itself. The new C3G mouse model is derived by humanizing factor D (hFDKI/KI) in a previously described FHm/mP-/- mouse that developed lethal C3G. We tested the effectiveness of these 2 complement inhibitors in triple transgenic mice with established C3G and glomerular disease. No FHm/mP-/-hFDKI/KI mice treated with vehicle survived the 30-d study period. All FHm/mP-/-hFDKI/KI mice treated with the C5 mAb-FH SCR1-5 fusion protein and 50% of mice treated with the anti-C5 mAb survived the 30-d treatment period. Moreover, mice treated with the C5 mAb-FH SCR1-5 fusion protein, but not those treated with the anti-C5 mAb, showed restored plasma alternative pathway complement control. The C5 mAb-FH SCR1-5 fusion protein reversed glomerular disease to a greater degree than the anti-C5 mAb. These data suggest that simultaneously inhibiting the terminal and proximal complement pathways, by anti-C5 mAb and FH SCR1-5, respectively, can reverse established C3G and is more efficacious than inhibiting the terminal pathway alone. A similar approach may be effective in treating human C3G.

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