Abstract
Congenital myasthenic syndromes (CMS) are genetic disorders characterised by impaired neuromuscular transmission. This review provides an overview on CMS and highlights recent advances in the field, including novel CMS causative genes and improved therapeutic strategies. CMS due to mutations in SLC5A7 and SLC18A3, impairing the synthesis and recycling of acetylcholine, have recently been described. In addition, a novel group of CMS due to mutations in SNAP25B, SYT2, VAMP1, and UNC13A1 encoding molecules implicated in synaptic vesicles exocytosis has been characterised. The increasing number of presynaptic CMS exhibiting CNS manifestations along with neuromuscular weakness demonstrate that the myasthenia can be only a small part of a much more extensive disease phenotype. Moreover, the spectrum of glycosylation abnormalities has been increased with the report that GMPPB mutations can cause CMS, thus bridging myasthenic disorders with dystroglycanopathies. Finally, the discovery of COL13A1 mutations and laminin α5 deficiency has helped to draw attention to the role of extracellular matrix proteins for the formation and maintenance of muscle endplates. The benefit of β2-adrenergic agonists alone or combined with pyridostigmine or 3,4-Dyaminopiridine is increasingly being reported for different subtypes of CMS including AChR-deficiency and glycosylation abnormalities, thus expanding the therapeutic repertoire available.
Highlights
Congenital myasthenic syndromes (CMS) are genetic disorders characterised by impaired neuromuscular transmission [1]
Testing for antibodies against the acetylcholine receptor (AChR) and the muscle-specific kinase (MuSK) is useful to rule out myasthenia gravis (MG)
Glycosylation of AChR subunits is required for the correct assembly of AChR pentamers and for efficient export to the cell surface [119] and abnormal glycosylation results in reduced AChRs at the muscle endplates, which is most likely the primary mechanisms leading to impaired neuromuscular transmission [120]
Summary
Congenital myasthenic syndromes (CMS) are genetic disorders characterised by impaired neuromuscular transmission [1]. All subtypes of CMS share the clinical feature of fatigable muscle weakness, but age at onset, presenting symptoms, distribution of weakness, and response to treatment vary, depending on the molecular mechanism that results from the underlying genetic defect. The clinical diagnosis of CMS is based on the presence of fatigable muscle weakness (usually from an early age) in conjunction with abnormal findings on neurophysiological studies, in particular decreTmheenctlailnriecaspl odniasegngoresaisteorfthCaMnS10is%boanserdepoentittihvee pnreervseenscteimouflfaattioigna(bRleNmS)uosrclaebnwoeramkanlejsitste(ruasundal/loyr fbrloomckainngeaornly asgineg)lien-fcibornejuenlcetcitornomwyitohgarabpnhoyrm(aSlFfiEnMdGin)g, saonndnepuorsoitpivheysiroelsopgoincasel sttuodipehs,airnmpaacortliocguilcaarl dtreecartemmeennt.tIatlisreimsppoonrsteangtrteoautenrdtehrsatnan1d0%thaotnalrthepouetgihtivmeonsteprvaetiesntitms hualavteiosynm(RpNtoSm)sofrroambnboirrtmh aolr jeiattrelyr acnhdil/dohroboldo,cskoinmgeodnosipnrgelsee-finbt rleateelrecitnrolmifeyodgurraipnghyte(SenFEagMeGy)e,aarnsdoproasdituivltehroeosdp.oTnsheetoclapshsaicrmmaycaoslothgeicnaicl tprehaetnmoetynpt.eItexishiimbiptsorwtaenatktnoeussndofertshteanodcuthlaart aanltdhofuacgihalmmoustscplaetsi,ebnutsthcaevrteasinymsupbtotympsesfrcoamn bpirrethseonrtewariltyh cahpinldoheiocoedp,issoodmees doroipsorelasteendtlliamtebr-ginirdlilfeewduearkinngestse,etnhaugseinyceraerassionrgatdhueldthiaogondo.sTtihcechclaalslesnicgme. Testing for antibodies against the acetylcholine receptor (AChR) and the muscle-specific kinase (MuSK) is useful to rule out myasthenia gravis (MG). TThhee ggeenneettiicc ddiiaaggnnoossiiss ooff CCMMSS iiss ccoommpplleexx dduuee ttoo tthhee eexxiisstteennccee ooff mmoorree tthhaann 3300 CCMMSS ccaauussaattiivvee ggeenneess iiddeennttiiffiieedd ttoo ddaattee ((TTaabbllee 11)). ALG2, α-1,3/1,6-mannosyltransferase; ALG14, UDP-N-acetylglucosaminyltransferase subunit; DOK7, docking protein 7; DPAGT1, dolichyl-phosphate N-acetylglucosaminephosphotransferase 1; GFPT1, glutamine-fructose-6-phosphate transaminase 1; GMPPB, GDP-mannose pyrophosphorylase B; LRP4, LDL receptor related protein 4; MuSK, Muscle specific kinase; PREPL, prolyl endopeptidase-like gene; SLC25A1, solute carrier family 25 member 1
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