1. Academic Validation
  2. Complement inhibition prevents glial nodal membrane injury in a GM1 antibody-mediated mouse model

Complement inhibition prevents glial nodal membrane injury in a GM1 antibody-mediated mouse model

  • Brain Commun. 2022 Nov 23;4(6):fcac306. doi: 10.1093/braincomms/fcac306.
Clare I Campbell 1 Rhona McGonigal 1 Jennifer A Barrie 1 Jolien Delaere 2 Laura Bracke 2 Madeleine E Cunningham 1 Denggao Yao 1 Tim Delahaye 2 Inge Van de Walle 2 Hugh J Willison 1
Affiliations

Affiliations

  • 1 Institute of Infection, Immunity and Inflammation, University of Glasgow, Glasgow G12 8TA, UK.
  • 2 argenx BV, Zwijnaarde, 9052 Ghent, Belgium.
Abstract

The involvement of the complement pathway in Guillain-Barré syndrome pathogenesis has been demonstrated in both patient biosamples and animal models. One proposed mechanism is that anti-ganglioside Antibodies mediate neural membrane injury through the activation of complement and the formation of membrane attack complex pores, thereby allowing the uncontrolled influx of ions, including calcium, intracellularly. Calcium influx activates the calcium-dependent protease calpain, leading to the cleavage of neural cytoskeletal and transmembrane proteins and contributing to subsequent functional failure. Complement inhibition has been demonstrated to provide effective protection from injury in anti-ganglioside antibody-mediated mouse models of axonal variants of Guillain-Barré syndrome; however, the role of complement in the pathogenesis of demyelinating variants has yet to be established. Thus, it is currently unknown whether complement inhibition would be an effective therapeutic for Guillain-Barré syndrome patients with injuries to the Schwann cell membrane. To address this, we recently developed a mouse model whereby the Schwann cell membrane was selectively targeted with an anti-GM1 antibody resulting in significant disruption to the axo-glial junction and cytoplasmic paranodal loops, presenting as conduction block. Herein, we utilize this Schwann cell nodal membrane injury model to determine the relevance of inhibiting complement activation. We addressed the early complement component C2 as the therapeutic target within the complement cascade by using the anti-C2 humanized monoclonal antibody, ARGX-117. This anti-C2 antibody blocks the formation of C3 convertase, specifically inhibiting the classical and lectin complement pathways and preventing the production of downstream harmful anaphylatoxins (C3a and C5a) and membrane attack complexes. Here, we demonstrate that C2 inhibition significantly attenuates injury to paranodal proteins at the node of Ranvier and improves respiratory function in ex vivo and in vivo Schwann cell nodal membrane injury models. In parallel studies, C2 inhibition also protects axonal integrity in our well-established model of acute motor axonal neuropathy mediated by both mouse and human anti-GM1 Antibodies. These data demonstrate that complement inhibition prevents injury in a Schwann cell nodal membrane injury model, which is representative of neuropathies associated with anti-GM1 Antibodies, including Guillain-Barré syndrome and multifocal motor neuropathy. This outcome suggests that both the motor axonal and demyelinating variants of Guillain-Barré syndrome should be included in future complement inhibition clinical trials.

Keywords

Guillain–Barré syndrome; axo-glial junction; complement inhibition; glial membrane injury; paranodal loops.

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