Translational NeuroImmunology
In myasthenia gravis and Lambert-Eaton myasthenic syndrome muscle weakness is a direct consequence of autoantibodies binding to, and interfering with, the function of key neuromuscular junction proteins. A subgroup of patients have antibodies against muscle-specific kinase (MuSK). MuSK is essential for the formation and maintenance of neuromuscular synapses as it propagates a trophic signal to induce acetylcholine receptor clustering and supports presynaptic motor nerve terminal differentiation. We confirmed that MuSK autoantibodies are predominantly of the IgG4 subclass and can induce myasthenia gravis in immune-incompetent mice (Klooster & Plomp et al. 2012 Brain). From monoclonal antibodies isolated from these patients we learned that MuSK antibodies binding with one-arm (monovalent) are more pathogenic than MuSK antibodies that bind with both arms to MuSK (bivalent) (Figure 1). Monovalent MuSK antibodies inhibit MuSK signalling and obstruct neuromuscular junction functioning, while bivalent MuSK antibodies activate MuSK signalling (Huijbers & Zhang et al. 2013 PNAS, Vergoossen et al. 2021 bioRxiv, Huijbers et al. 2019 Neurol, Neuroimmunol & Neuroinflamm). IgG4 is the only antibody subclass that binds with one arm to a specific target, thus class switching to IgG4 is likely a critical step in development of MuSK myasthenia gravis.
…In myasthenia gravis and Lambert-Eaton myasthenic syndrome muscle weakness is a direct consequence of autoantibodies binding to, and interfering with, the function of key neuromuscular junction proteins. A subgroup of patients have antibodies against muscle-specific kinase (MuSK). MuSK is essential for the formation and maintenance of neuromuscular synapses as it propagates a trophic signal to induce acetylcholine receptor clustering and supports presynaptic motor nerve terminal differentiation. We confirmed that MuSK autoantibodies are predominantly of the IgG4 subclass and can induce myasthenia gravis in immune-incompetent mice (Klooster & Plomp et al. 2012 Brain). From monoclonal antibodies isolated from these patients we learned that MuSK antibodies binding with one-arm (monovalent) are more pathogenic than MuSK antibodies that bind with both arms to MuSK (bivalent) (Figure 1). Monovalent MuSK antibodies inhibit MuSK signalling and obstruct neuromuscular junction functioning, while bivalent MuSK antibodies activate MuSK signalling (Huijbers & Zhang et al. 2013 PNAS, Vergoossen et al. 2021 bioRxiv, Huijbers et al. 2019 Neurol, Neuroimmunol & Neuroinflamm). IgG4 is the only antibody subclass that binds with one arm to a specific target, thus class switching to IgG4 is likely a critical step in development of MuSK myasthenia gravis.
Interestingly, a niche of other autoimmune diseases has been identified that are associated with predominating IgG4 autoantibodies (Huijbers et al. 2018 Ann N Y Acad Sci, Huijbers et al. 2015 Eur J Neurol.). These diseases share many of the disease mechanism characteristics observed in MuSK MG. Why these diseases are hallmarked by IgG4 autoantibodies is not known.
These ambitious objectives are explored in close collaboration with the clinical research group Clinical Neuroimmunology (graag link naar groep Jan Verschuuren) of Prof. Dr. Jan Verschuuren (graag link naar profile Prof.dr. Jan Verschuuren) and electrophysiology expert Dr. Jaap Plomp (graag link naar profile Dr. Jaap Plomp) at the department of Neurology, which is part of the center of expertise for Neuromuscular diseases in the LUMC. This is one of the Health Care Providers of the EURO-NMD European Reference Network and part of NL-NMD (Dutch society for neuromuscular diseases).
Together with our broad network of collaborators, we aim to advance knowledge on healthy and diseased neuromuscular junction physiology, understand the aetiology of IgG4-mediated autoimmunity and develop new therapeutics for these disorders. We welcome all students and scientists interested in our work to contact us for any questions regarding positions or collaborations.
Our ambition
Together with our broad network of collaborators, we aim to advance knowledge on healthy and diseased neuromuscular junction physiology, understand the aetiology of IgG4-mediated autoimmunity and develop new therapeutics for these disorders. We welcome all students and scientists interested in our work to contact us for any questions regarding positions or collaborations.
…Together with our broad network of collaborators, we aim to advance knowledge on healthy and diseased neuromuscular junction physiology, understand the aetiology of IgG4-mediated autoimmunity and develop new therapeutics for these disorders. We welcome all students and scientists interested in our work to contact us for any questions regarding positions or collaborations.
M.G.M.Huijbers@lumc.nl or HG_NEURIMM@lumc.nl.
Our research focuses on the following objectives:
- Deciphering and targeting (pathogenic) IgG4 (auto)immune responses
- Therapeutic application of MuSK antibodies in neuromuscular diseases
- Understanding NMJ homeostasis and pathophysiology of myasthenia gravis
Our ambitious objectives are explored in close collaboration with the clinical research group Clinical Neuroimmunology (graag link naar groep Jan Verschuuren) of Prof. Dr. Jan Verschuuren (graag link naar profile Prof.dr. Jan Verschuuren) and electrophysiology expert Dr. Jaap Plomp (graag link naar profile Dr. Jaap Plomp) at the department of Neurology, which is part of the center of expertise for Neuromuscular diseases in the LUMC. This is one of the Health Care Providers of the EURO-NMD European Reference Network and part of NL-NMD (Dutch society for neuromuscular diseases).
Projects
Relevant websites
Key Publications
Our team
Dr. Maartje G. Huijbers
Principal Investigator / Assistant Professor
Olena Butenko
Researcher
Jamie L. Lim
Researcher
Laurent M. Paardekooper
Researcher
Oscar Dekker
PhD student
Dana L.E. Vergoossen
PhD student
Robyn L.K. Verpalen
PhD student
Yvonne E. Fillié-Grijpma
Research technician
Stine Jensen
Research technician