Autoantibody profiles in patients with immune checkpoint inhibitor-induced neurological immune related adverse events

Background Neurological immune-related adverse events (irAE-n) are severe and potentially fatal toxicities of immune checkpoint inhibitors (ICI). To date, the clinical significance of neuronal autoantibodies in irAE-n is poorly understood. Here, we characterize neuronal autoantibody profiles in patients with irAE-n and compare these with ICI-treated cancer patients without irAE-n. Methods In this cohort study (DRKS00012668), we consecutively collected clinical data and serum samples of 29 cancer patients with irAE-n (n = 2 pre-ICI, n = 29 post-ICI) and 44 cancer control patients without irAE-n (n = 44 pre- and post-ICI). Using indirect immunofluorescence and immunoblot assays, serum samples were tested for a large panel of neuromuscular and brain-reactive autoantibodies. Results IrAE-n patients and controls received ICI treatment targeting programmed death protein (PD-)1 (61% and 62%), programmed death ligand (PD-L)1 (18% and 33%) or PD-1 and cytotoxic T-lymphocyte-associated protein (CTLA-)4 (21% and 5%). Most common malignancies were melanoma (both 55%) and lung cancer (11% and 14%). IrAE-n affected the peripheral nervous system (59%), the central nervous system (21%), or both (21%). Prevalence of neuromuscular autoantibodies was 63% in irAE-n patients, which was higher compared to ICI-treated cancer patients without irAE-n (7%, p <.0001). Brain-reactive autoantibodies targeting surface (anti-GABABR, -NMDAR, -myelin), intracellular (anti-GFAP, -Zic4, -septin complex), or unknown antigens were detected in 13 irAE-n patients (45%). In contrast, only 9 of 44 controls (20%) presented brain-reactive autoantibodies before ICI administration. However, seven controls developed de novo brain-reactive autoantibodies after ICI initiation, therefore, prevalence of brain-reactive autoantibodies was comparable between ICI-treated patients with and without irAE-n (p = .36). While there was no clear association between specific brain-reactive autoantibodies and clinical presentation, presence of at least one of six selected neuromuscular autoantibodies (anti-titin, anti-skeletal muscle, anti-heart muscle, anti-LRP4, anti-RyR, anti-AchR) had a sensitivity of 80% (95% CI 0.52-0.96) and a specificity of 88% (95% CI 0.76-0.95) for the diagnosis of myositis, myocarditis, or myasthenia gravis. Conclusion Neuromuscular autoantibodies may serve as a feasible marker to diagnose and potentially predict life-threatening ICI-induced neuromuscular disease. However, brain-reactive autoantibodies are common in both ICI-treated patients with and without irAE-n, hence, their pathogenic significance remains unclear.

[1]  S. Mallal,et al.  T cells specific for α-myosin drive immunotherapy-related myocarditis , 2022, Nature.

[2]  A. Gesierich,et al.  Characteristics of immune checkpoint inhibitor-induced encephalitis and comparison with HSV-1 and anti-LGI1 encephalitis: A retrospective multicentre cohort study. , 2022, European journal of cancer.

[3]  A. Gesierich,et al.  Dataset of a retrospective multicenter cohort study on characteristics of immune checkpoint inhibitor-induced encephalitis and comparison with HSV-1 and anti-LGI1 encephalitis , 2022, Data in brief.

[4]  A. Herrera,et al.  Prediction of Immune-Related Adverse Events Induced by Immune Checkpoint Inhibitors With a Panel of Autoantibodies: Protocol of a Multicenter, Prospective, Observational Cohort Study , 2022, Frontiers in Pharmacology.

[5]  R. Danesi,et al.  Neurological Manifestations Related to Immune Checkpoint Inhibitors: Reverse Translational Research by Using the European Real-World Safety Data , 2022, Frontiers in Oncology.

[6]  Douglas B. Johnson,et al.  Immune-checkpoint inhibitors: long-term implications of toxicity , 2022, Nature Reviews Clinical Oncology.

[7]  M. Suarez‐Almazor,et al.  Management of Immune-Related Adverse Events in Patients Treated With Immune Checkpoint Inhibitor Therapy: ASCO Guideline Update , 2021, Journal of clinical oncology : official journal of the American Society of Clinical Oncology.

[8]  A. Mammen,et al.  Consensus disease definitions for neurologic immune-related adverse events of immune checkpoint inhibitors , 2021, Journal for ImmunoTherapy of Cancer.

[9]  C. Grohé,et al.  Association Between Neuronal Autoantibodies and Cognitive Impairment in Patients With Lung Cancer. , 2021, JAMA oncology.

[10]  R. Sullivan,et al.  Chronic Immune-Related Adverse Events Following Adjuvant Anti-PD-1 Therapy for High-risk Resected Melanoma. , 2021, JAMA oncology.

[11]  W. Gerritsen,et al.  Immune Checkpoint Inhibitor–related Guillain-Barré Syndrome: A Case Series and Review of the Literature , 2021, Journal of immunotherapy.

[12]  M. Simó,et al.  Encephalitis Induced by Immune Checkpoint Inhibitors: A Systematic Review. , 2021, JAMA neurology.

[13]  G. Gigli,et al.  Neurologic Adverse Events of Immune Checkpoint Inhibitors , 2021, Neurology.

[14]  M. Levy,et al.  Neuroimmunological adverse events associated with immune checkpoint inhibitor: a retrospective, pharmacovigilance study using FAERS database , 2021, Journal of Neuro-Oncology.

[15]  D. Hamann,et al.  Biomarkers of Checkpoint Inhibitor Induced Immune-Related Adverse Events—A Comprehensive Review , 2021, Frontiers in Oncology.

[16]  P. Tassone,et al.  HLA Expression Correlates to the Risk of Immune Checkpoint Inhibitor-Induced Pneumonitis , 2020, Cells.

[17]  C. Klein,et al.  Neurologic autoimmunity and immune checkpoint inhibitors , 2020, Neurology.

[18]  M. Milone,et al.  Immune checkpoint inhibitor-associated myopathy: a clinicoseropathologically distinct myopathy , 2020, Brain communications.

[19]  K. O’Connor,et al.  Autoimmune Pathology in Myasthenia Gravis Disease Subtypes Is Governed by Divergent Mechanisms of Immunopathology , 2020, Frontiers in Immunology.

[20]  J. Honnorat,et al.  Value of Onconeural Antibodies in Checkpoint Inhibitor‐Related Toxicities , 2020, Annals of neurology.

[21]  R. Garje,et al.  Review of Indications of FDA-Approved Immune Checkpoint Inhibitors per NCCN Guidelines with the Level of Evidence , 2020, Cancers.

[22]  R. Sullivan,et al.  Severe Neurological Toxicity of Immune Checkpoint Inhibitors: Growing Spectrum , 2020, Annals of neurology.

[23]  M. Suarez‐Almazor,et al.  Immune checkpoint inhibitor related myasthenia gravis: single center experience and systematic review of the literature , 2019, Journal of Immunotherapy for Cancer.

[24]  F. Ducray,et al.  Increased frequency of anti-Ma2 encephalitis associated with immune checkpoint inhibitors , 2019, Neurology: Neuroimmunology & Neuroinflammation.

[25]  Y. Shimo,et al.  Pembrolizumab-related systemic myositis involving ocular and hindneck muscles resembling myasthenic gravis: a case report , 2019, BMC Neurology.

[26]  P. Jedlowski,et al.  Severe Myositis, Myocarditis, and Myasthenia Gravis with Elevated Anti-Striated Muscle Antibody following Single Dose of Ipilimumab-Nivolumab Therapy in a Patient with Metastatic Melanoma , 2019, Case reports in immunology.

[27]  D. Scheie,et al.  Neuromuscular adverse events associated with anti-PD-1 monoclonal antibodies , 2018, Neurology.

[28]  I. Nishino,et al.  Pembrolizumab-induced Ocular Myasthenia Gravis with Anti-titin Antibody and Necrotizing Myopathy , 2019, Internal medicine.

[29]  A. Mammen,et al.  Pre-existing antiacetylcholine receptor autoantibodies and B cell lymphopaenia are associated with the development of myositis in patients with thymoma treated with avelumab, an immune checkpoint inhibitor targeting programmed death-ligand 1 , 2018, Annals of the rheumatic diseases.

[30]  J. Sugisaka,et al.  Profiling Preexisting Antibodies in Patients Treated With Anti–PD-1 Therapy for Advanced Non–Small Cell Lung Cancer , 2019, JAMA oncology.

[31]  N. Weiss,et al.  Immune checkpoint inhibitor-related myositis and myocarditis in patients with cancer , 2018, Neurology.

[32]  M. Rosenfeld,et al.  Clinical and pathogenic significance of IgG, IgA, and IgM antibodies against the NMDA receptor , 2018, Neurology.

[33]  Matthew D. Hellmann,et al.  Immune‐Related Adverse Events Associated with Immune Checkpoint Blockade , 2018, The New England journal of medicine.

[34]  N. Staff,et al.  Neurological Complications Associated With Anti–Programmed Death 1 (PD-1) Antibodies , 2017, JAMA neurology.

[35]  Shigeaki Suzuki,et al.  Nivolumab-related myasthenia gravis with myositis and myocarditis in Japan , 2017, Neurology.

[36]  H. Prüss,et al.  High prevalence of neuronal surface autoantibodies associated with cognitive deficits in cancer patients , 2017, Journal of Neurology.

[37]  D. Schadendorf,et al.  Safety Profile of Nivolumab Monotherapy: A Pooled Analysis of Patients With Advanced Melanoma. , 2017, Journal of clinical oncology : official journal of the American Society of Clinical Oncology.

[38]  S. Cuzzubbo,et al.  Neurological adverse events associated with immune checkpoint inhibitors: Review of the literature. , 2017, European journal of cancer.

[39]  J. Seidman,et al.  Fulminant Myocarditis with Combination Immune Checkpoint Blockade. , 2016, The New England journal of medicine.

[40]  R. Liblau,et al.  CTLA4 blockade elicits paraneoplastic neurological disease in a mouse model. , 2016, Brain : a journal of neurology.

[41]  P. Sharma,et al.  Acute rhabdomyolysis with severe polymyositis following ipilimumab-nivolumab treatment in a cancer patient with elevated anti-striated muscle antibody , 2016, Journal of Immunotherapy for Cancer.

[42]  J. Utikal,et al.  Neurological, respiratory, musculoskeletal, cardiac and ocular side-effects of anti-PD-1 therapy. , 2016, European journal of cancer.

[43]  A. Ravaud,et al.  Nivolumab versus Everolimus in Advanced Renal-Cell Carcinoma. , 2015, The New England journal of medicine.

[44]  A. Ciabattini,et al.  CD4+ T Cell Priming as Biomarker to Study Immune Response to Preventive Vaccines , 2013, Front. Immunol..

[45]  C. Horak,et al.  Nivolumab plus ipilimumab in advanced melanoma. , 2013, The New England journal of medicine.

[46]  Virginia Pascual,et al.  Induction of ICOS+CXCR3+CXCR5+ TH Cells Correlates with Antibody Responses to Influenza Vaccination , 2013, Science Translational Medicine.

[47]  R. Buchert,et al.  IgA NMDA receptor antibodies are markers of synaptic immunity in slow cognitive impairment , 2012, Neurology.

[48]  E. Mohammadi,et al.  Barriers and facilitators related to the implementation of a physiological track and trigger system: A systematic review of the qualitative evidence , 2017, International journal for quality in health care : journal of the International Society for Quality in Health Care.

[49]  S. Sungkanuparph,et al.  A CASE SERIES AND REVIEW OF THE LITERATURE , 2011 .

[50]  M. Rosenfeld,et al.  Paraneoplastic syndromes of the CNS , 2008, The Lancet Neurology.

[51]  A. R.,et al.  Review of literature , 1951, American Potato Journal.

[52]  D. C. Henckel,et al.  Case report. , 1995, Journal.

[53]  V. Lennon,et al.  Thymic B lymphocyte clones from patients with myasthenia gravis secrete monoclonal striational autoantibodies reacting with myosin, alpha actinin, or actin , 1986, The Journal of experimental medicine.

[54]  J. Michelson,et al.  Myasthenic antibodies cross-link acetylcholine receptors to accelerate degradation. , 1978, The New England journal of medicine.

[55]  J. Patrick,et al.  Autoimmune Response to Acetylcholine Receptor , 1973, Science.