DPAGT1 myasthenia and myopathy: Genetic, phenotypic, and expression studies

Duygu Selcen, Xin Ming Shen, Joan Brengman, Ying Li, Anthony A. Stans, Eric Wieben, Andrew G. Engel

Research output: Contribution to journalArticlepeer-review

35 Scopus citations


Objective: To investigate patients with DPAGT1 (UDP-N-acetylglucosamine- dolichyl-phosphate N-acetylglucosaminephosphotransferase 1)-associated myasthenic syndrome. Methods: We performed exome and Sanger sequencing, determined glycoprotein expression in patient muscles, assessed pathogenicity of the mutant proteins by examining their expression and enzymatic activity in transfected cells, evaluated structural changes in muscle and the neuromuscular junction, and examined electrophysiologic aspects of neuromuscular transmission in vitro. Results: Patients 1 and 2, 16 and 14 years of age, had progressive fatigable weakness since infancy and are intellectually disabled. Patient 3, a less severely affected brother of patient 1, also has autistic features. Each patient harbors 2 novel heteroallelic mutations in DPAGT1, an enzyme subserving protein N-glycosylation. Patients 1 and 3 harbor Met1Leu, which reduces protein expression, and His375Tyr, which decreases enzyme activity. Patient 2 carries Val264Met, which abolishes enzyme activity, and a synonymous Leu120Leu mutation that markedly augments exon skipping, resulting in some skipped and infrequent nonskipped alleles. Therefore, the nonskipped allele rescues the phenotype. Intracellular microelectrode studies indicate combined pre- and postsynaptic defects of neuromuscular transmission with evidence for somatic mosaicism in patient 2. Structural studies reveal hypoplastic endplates, fiber-type disproportion, tubular aggregates, and degeneration of muscle fiber organelles resulting in autophagocytosis. Conclusions: DPAGT1 myasthenia affects multiple parameters of neuromuscular transmission, causes fiber-type disproportion and an autophagic myopathy, and can be associated with intellectual disability. We speculate that hypoglycosylation of synapse-specific proteins causes defects in central as well as motor synapses.

Original languageEnglish (US)
Pages (from-to)1822-1830
Number of pages9
Issue number20
StatePublished - May 20 2014

ASJC Scopus subject areas

  • Clinical Neurology


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