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Modulation of Ligand-Gated Glycine Receptors Via Functional Monoclonal Antibodies.
Simard, Jeffrey R; Michelsen, Klaus; Wang, Yan; Yang, Chunhua; Youngblood, Beth; Grubinska, Barbara; Taborn, Kristin; Gillie, Daniel J; Cook, Kevin; Chung, Kyu; Long, Alexander M; Hall, Brian E; Shaffer, Paul L; Foti, Robert S; Gingras, Jacinthe.
Affiliation
  • Simard JR; Departments of Neuroscience (J.R.S., C.Y., B.Y. B.G., K.T., D.J.G., J.G.), Molecular Engineering (K.M., A.M.L., P.L.S.), Protein Technologies (Y.W., B.E.H.), and Pharmacokinetics and Drug Metabolism (R.S.F.), Amgen Research, Cambridge, Massachusetts; and Department of Pharmacokinetics and Drug Metab
  • Michelsen K; Departments of Neuroscience (J.R.S., C.Y., B.Y. B.G., K.T., D.J.G., J.G.), Molecular Engineering (K.M., A.M.L., P.L.S.), Protein Technologies (Y.W., B.E.H.), and Pharmacokinetics and Drug Metabolism (R.S.F.), Amgen Research, Cambridge, Massachusetts; and Department of Pharmacokinetics and Drug Metab
  • Wang Y; Departments of Neuroscience (J.R.S., C.Y., B.Y. B.G., K.T., D.J.G., J.G.), Molecular Engineering (K.M., A.M.L., P.L.S.), Protein Technologies (Y.W., B.E.H.), and Pharmacokinetics and Drug Metabolism (R.S.F.), Amgen Research, Cambridge, Massachusetts; and Department of Pharmacokinetics and Drug Metab
  • Yang C; Departments of Neuroscience (J.R.S., C.Y., B.Y. B.G., K.T., D.J.G., J.G.), Molecular Engineering (K.M., A.M.L., P.L.S.), Protein Technologies (Y.W., B.E.H.), and Pharmacokinetics and Drug Metabolism (R.S.F.), Amgen Research, Cambridge, Massachusetts; and Department of Pharmacokinetics and Drug Metab
  • Youngblood B; Departments of Neuroscience (J.R.S., C.Y., B.Y. B.G., K.T., D.J.G., J.G.), Molecular Engineering (K.M., A.M.L., P.L.S.), Protein Technologies (Y.W., B.E.H.), and Pharmacokinetics and Drug Metabolism (R.S.F.), Amgen Research, Cambridge, Massachusetts; and Department of Pharmacokinetics and Drug Metab
  • Grubinska B; Departments of Neuroscience (J.R.S., C.Y., B.Y. B.G., K.T., D.J.G., J.G.), Molecular Engineering (K.M., A.M.L., P.L.S.), Protein Technologies (Y.W., B.E.H.), and Pharmacokinetics and Drug Metabolism (R.S.F.), Amgen Research, Cambridge, Massachusetts; and Department of Pharmacokinetics and Drug Metab
  • Taborn K; Departments of Neuroscience (J.R.S., C.Y., B.Y. B.G., K.T., D.J.G., J.G.), Molecular Engineering (K.M., A.M.L., P.L.S.), Protein Technologies (Y.W., B.E.H.), and Pharmacokinetics and Drug Metabolism (R.S.F.), Amgen Research, Cambridge, Massachusetts; and Department of Pharmacokinetics and Drug Metab
  • Gillie DJ; Departments of Neuroscience (J.R.S., C.Y., B.Y. B.G., K.T., D.J.G., J.G.), Molecular Engineering (K.M., A.M.L., P.L.S.), Protein Technologies (Y.W., B.E.H.), and Pharmacokinetics and Drug Metabolism (R.S.F.), Amgen Research, Cambridge, Massachusetts; and Department of Pharmacokinetics and Drug Metab
  • Cook K; Departments of Neuroscience (J.R.S., C.Y., B.Y. B.G., K.T., D.J.G., J.G.), Molecular Engineering (K.M., A.M.L., P.L.S.), Protein Technologies (Y.W., B.E.H.), and Pharmacokinetics and Drug Metabolism (R.S.F.), Amgen Research, Cambridge, Massachusetts; and Department of Pharmacokinetics and Drug Metab
  • Chung K; Departments of Neuroscience (J.R.S., C.Y., B.Y. B.G., K.T., D.J.G., J.G.), Molecular Engineering (K.M., A.M.L., P.L.S.), Protein Technologies (Y.W., B.E.H.), and Pharmacokinetics and Drug Metabolism (R.S.F.), Amgen Research, Cambridge, Massachusetts; and Department of Pharmacokinetics and Drug Metab
  • Long AM; Departments of Neuroscience (J.R.S., C.Y., B.Y. B.G., K.T., D.J.G., J.G.), Molecular Engineering (K.M., A.M.L., P.L.S.), Protein Technologies (Y.W., B.E.H.), and Pharmacokinetics and Drug Metabolism (R.S.F.), Amgen Research, Cambridge, Massachusetts; and Department of Pharmacokinetics and Drug Metab
  • Hall BE; Departments of Neuroscience (J.R.S., C.Y., B.Y. B.G., K.T., D.J.G., J.G.), Molecular Engineering (K.M., A.M.L., P.L.S.), Protein Technologies (Y.W., B.E.H.), and Pharmacokinetics and Drug Metabolism (R.S.F.), Amgen Research, Cambridge, Massachusetts; and Department of Pharmacokinetics and Drug Metab
  • Shaffer PL; Departments of Neuroscience (J.R.S., C.Y., B.Y. B.G., K.T., D.J.G., J.G.), Molecular Engineering (K.M., A.M.L., P.L.S.), Protein Technologies (Y.W., B.E.H.), and Pharmacokinetics and Drug Metabolism (R.S.F.), Amgen Research, Cambridge, Massachusetts; and Department of Pharmacokinetics and Drug Metab
  • Foti RS; Departments of Neuroscience (J.R.S., C.Y., B.Y. B.G., K.T., D.J.G., J.G.), Molecular Engineering (K.M., A.M.L., P.L.S.), Protein Technologies (Y.W., B.E.H.), and Pharmacokinetics and Drug Metabolism (R.S.F.), Amgen Research, Cambridge, Massachusetts; and Department of Pharmacokinetics and Drug Metab
  • Gingras J; Departments of Neuroscience (J.R.S., C.Y., B.Y. B.G., K.T., D.J.G., J.G.), Molecular Engineering (K.M., A.M.L., P.L.S.), Protein Technologies (Y.W., B.E.H.), and Pharmacokinetics and Drug Metabolism (R.S.F.), Amgen Research, Cambridge, Massachusetts; and Department of Pharmacokinetics and Drug Metab
J Pharmacol Exp Ther ; 383(1): 56-69, 2022 10.
Article in En | MEDLINE | ID: mdl-35926871
Ion channels are targets of considerable therapeutic interest to address a wide variety of neurologic indications, including pain perception. Current pharmacological strategies have focused mostly on small molecule approaches that can be limited by selectivity requirements within members of a channel family or superfamily. Therapeutic antibodies have been proposed, designed, and characterized to alleviate this selectivity limitation; however, there are no Food and Drug Administration-approved therapeutic antibody-based drugs targeting ion channels on the market to date. Here, in an effort to identify novel classes of engineered ion channel modulators for potential neurologic therapeutic applications, we report the generation and characterization of six (EC50 < 25nM) Cys-loop receptor family monoclonal antibodies with modulatory function against rat and human glycine receptor alpha 1 (GlyRα1) and/or GlyRα3. These antibodies have activating (i.e., positive modulator) or inhibiting (i.e., negative modulator) profiles. Moreover, GlyRα3 selectivity was successfully achieved for two of the three positive modulators identified. When dosed intravenously, the antibodies achieved sufficient brain exposure to cover their calculated in vitro EC50 values. When compared head-to-head at identical exposures, the GlyRα3-selective antibody showed a more desirable safety profile over the nonselective antibody, thus demonstrating, for the first time, an advantage for GlyRα3-selectivity. Our data show that ligand-gated ion channels of the glycine receptor family within the central nervous system can be functionally modulated by engineered biologics in a dose-dependent manner and that, despite high protein homology between the alpha subunits, selectivity can be achieved within this receptor family, resulting in future therapeutic candidates with more desirable drug safety profiles. SIGNIFICANCE STATEMENT: This study presents immunization and multiplatform screening approaches to generate a diverse library of functional antibodies (agonist, potentiator, or inhibitory) raised against human glycine receptors (GlyRs). This study also demonstrates the feasibility of acquiring alpha subunit selectivity, a desirable therapeutic profile. When tested in vivo, these tool molecules demonstrated an increased safety profile in favor of GlyRα3-selectivity. These are the first reported functional GlyR antibodies that may open new avenues to treating central nervous system diseases with subunit selective biologics.
Subject(s)

Full text: 1 Database: MEDLINE Main subject: Receptors, Glycine / Antibodies, Monoclonal Limits: Animals / Humans Language: En Journal: J Pharmacol Exp Ther Year: 2022 Type: Article

Full text: 1 Database: MEDLINE Main subject: Receptors, Glycine / Antibodies, Monoclonal Limits: Animals / Humans Language: En Journal: J Pharmacol Exp Ther Year: 2022 Type: Article