Portal de Periódicos da CAPES

Dok‐7 myasthenia: Phenotypic and molecular genetic studies in 16 patients

2008; Wiley; Volume: 64; Issue: 1 Linguagem: Inglês

10.1002/ana.21408

1531-8249

Duygu Selcen, Margherita Milone, Xin‐Ming Shen, C. Michel Harper, Anthony A. Stans, Eric D. Wieben, Andrew G. Engel,

Genomics and Rare Diseases

Abstract Objective Detailed analysis of phenotypic and molecular genetic aspects of Dok‐7 myasthenia in 16 patients. Methods We assessed our patients by clinical and electromyographic studies, by intercostal muscle biopsies for in vitro microelectrode analysis of neuromuscular transmission and quantitative electron microscopy EM of 409 end plates (EPs), and by mutation analysis, and expression studies of the mutants. Results The clinical spectrum varied from mild static limb‐girdle weakness to severe generalized progressive disease. The synaptic contacts were single or multiple, and some, but not all, were small. In vitro microelectrode studies indicated variable decreases of the number of released quanta and of the synaptic response to acetylcholine; acetylcholine receptor (AChR) channel kinetics were normal. EM analysis demonstrated widespread and previously unrecognized destruction and remodeling of the EPs. Each patient carries 2 or more heteroallelic mutations: 11 in genomic DNA, 7 of which are novel; and 6 identifiable only in complementary DNA or cloned complementary DNA, 3 of which are novel. The pathogenicity of the mutations was confirmed by expression studies. Although the functions of Dok‐7 include AChR β‐subunit phosphorylation and maintaining AChR site density, patient EPs showed normal AChR β‐subunit phosphorylation, and the AChR density on the remaining junctional folds appeared normal. Interpretation First, the clinical features of Dok‐7 myasthenia are highly variable. Second, some mutations are complex and identifiable only in cloned complementary DNA. Third, Dok‐7 is essential for maintaining not only the size but also the structural integrity of the EP. Fourth, the profound structural alterations at the EPs likely contribute importantly to the reduced safety margin of neuromuscular transmission. Ann Neurol 2008