Voluntary muscle contraction is triggered by the neurotransmitter acetylcholine binding its receptors on the postsynaptic membrane of the neuromuscular junction, opening ion channels that allow cation influx and initiate depolarization1–3. Mutations in muscle acetylcholine receptors disrupt this process by either impairing (fast-channel) or prolonging (slow-channel) channel openings1,4. These defects cause congenital myasthenic syndromes (CMS), characterized by severe muscle weakness that is often present at birth and, in some cases, progresses to paralysis and death5,6. The structural mechanisms underlying these pathogenic defects and their pharmacological correction remain unknown. Here, using cryogenic electron microscopy, chemical biology and electrophysiology, we determined the structures and functional consequences of representative CMS mutant receptors with and without drugs. In fast-channel disease-associated mutants, we discovered a cryptic allosteric site targeted by positive modulators that restore gating in a mutation-specific manner. In receptor mutants associated with slow-channel disease, quinidine, fluoxetine and reboxetine act as pore blockers; notably, the antidepressant reboxetine selectively blocks desensitized receptors in a mutation-independent fashion, suggesting repurposing potential. Mechanistically, fast-channel mutations uncouple agonist binding from gating, whereas slow-channel mutations stabilize an abnormally widened, desensitized-like pore. These findings reveal unifying principles of CMS pathogenesis and provide a framework for precision therapies.