Membrane assembly of aquaporin-4 autoantibodies regulates classical complement activation in neuromyelitis optica
John Soltys, Yiting Liu, Alanna Ritchie, Scott Wemlinger, Kristin Schaller, Hannah Schumann, Gregory P. Owens, Jeffrey L. Bennett
John Soltys, Yiting Liu, Alanna Ritchie, Scott Wemlinger, Kristin Schaller, Hannah Schumann, Gregory P. Owens, Jeffrey L. Bennett
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Research Article Inflammation Neuroscience

Membrane assembly of aquaporin-4 autoantibodies regulates classical complement activation in neuromyelitis optica

Abstract

Neuromyelitis optica (NMO) is an autoimmune CNS disorder mediated by pathogenic aquaporin-4 (AQP4) water channel autoantibodies (AQP4-IgG). Although AQP4-IgG–driven complement-dependent cytotoxicity (CDC) is critical for the formation of NMO lesions, the molecular mechanisms governing optimal classical pathway activation are unknown. We investigated the molecular determinants driving CDC in NMO using recombinant AQP4–specific autoantibodies (AQP4 rAbs) derived from affected patients. We identified a group of AQP4 rAbs targeting a distinct extracellular loop C epitope that demonstrated enhanced CDC on target cells. Targeted mutations of AQP4 rAb Fc domains that enhance or diminish C1q binding or antibody Fc-Fc interactions showed that optimal CDC was driven by the assembly of multimeric rAb platforms that increase multivalent C1q binding and facilitate C1q activation. A peptide that blocks antibody Fc-Fc interaction inhibited CDC induced by AQP4 rAbs and polyclonal NMO patient sera. Super-resolution microscopy revealed that AQP4 rAbs with enhanced CDC preferentially formed organized clusters on supramolecular AQP4 orthogonal arrays, linking epitope-dependent multimeric assembly with enhanced C1q binding and activation. The resulting model of AQP4-IgG CDC provides a framework for understanding classical complement activation in human autoantibody–mediated disorders and identifies a potential new therapeutic avenue for treating NMO.

Authors

John Soltys, Yiting Liu, Alanna Ritchie, Scott Wemlinger, Kristin Schaller, Hannah Schumann, Gregory P. Owens, Jeffrey L. Bennett

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Figure 2

Impact of CH2-C1q affinity and CH3 Fc-Fc interactions on AQP4-IgG–mediated CDC.

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Impact of CH2-C1q affinity and CH3 Fc-Fc interactions on AQP4-IgG–mediat...
(A) Space-filling and ribbon models of C1q, AQP4 rAb, and M23-AQP4 OAPs illustrating potential interactions driving C1q–AQP4 rAb–M23-AQP4 multivalent complex assembly. C1q globular heads bind to the CH2 domain of AQP4 rAb (green), while neighboring AQP4 rAbs interact via CH3 hydrophobic patches (blue). Fab variable regions and AQP4 extracellular loops are colored brown. (B) Space-filling model of the Fc region of a divalent AQP4 rAb (boxed area from A) denoting residues with engineered mutations to promote (green, blue) or limit (orange, red) C1q-CH2 or CH3-CH3 interactions. AEFTE denotes the combination G236A/S267E/H268F/S324T/I332E Fc domain mutations. CDC (left graphs; mean ± SEM; n = 4) and C1q binding (right graphs; mean ± SD; n = 3) were measured for His151/Leu154-independent (CE) and His151/Leu154-dependent (FI) AQP4 rAbs. rAb binding affinity on M23-AQP4 (KM23) is displayed in the top left corner of each CDC graph. The CDC and C1q binding curves for rAb ON 07-5 no. 186 (dotted brown line) is displayed in each graph for comparison. The K322A, AEFTE/I253D, and AEFTE/E345R mutations were introduced into select rAbs as indicated in the key.