ABSTRACT
Background: Epilepsy-associated dysbiosis in gut microbiota has been previously described, but the mechanistic roles of the gut microbiome in epileptogenesis among children with cerebral palsy (CP) have yet to be illustrated. Methods: Using shotgun metagenomic sequencing coupled with untargeted metabolomics analysis, this observational study compared the gut microbiome and metabolome of eight children with non-epileptic cerebral palsy (NECP) to those of 13 children with cerebral palsy with epilepsy (CPE). Among children with CPE, 8 had drug-sensitive epilepsy (DSE) and five had drug-resistant epilepsy (DRE). Characteristics at enrollment, medication history, and 7-day dietary intake were compared between groups. Results: At the species level, CPE subjects had significantly lower abundances of Bacteroides fragilis and Dialister invisus but higher abundances of Phascolarctobacterium faecium and Eubacterium limosum. By contrast, DRE subjects had a significantly higher colonization of Veillonella parvula. Regarding microbial functional pathways, CPE subjects had decreased abundances of pathways for serine degradation, quinolinic acid degradation, glutamate degradation I, glycerol degradation, sulfate reduction, and nitrate reduction but increased abundances of pathways related to ethanol production. As for metabolites, CPE subjects had higher concentrations of kynurenic acid, 2-oxindole, dopamine, 2-hydroxyphenyalanine, 3,4-dihydroxyphenylglycol, L-tartaric acid, and D-saccharic acid; DRE subjects had increased concentrations of indole and homovanilic acid. Conclusions: In this study, we found evidence of gut dysbiosis amongst children with cerebral palsy and epilepsy in terms of gut microbiota species, functional pathways, and metabolites. The combined metagenomic and metabolomic analyses have shed insights on the potential roles of B. fragilis and D. invisus in neuroprotection. The combined analyses have also provided evidence for the involvement of GMBA in the epilepsy-related dysbiosis of kynurenine, serotonin, and dopamine pathways and their complex interplay with neuroimmune and neuroendocrinological pathways.
ABSTRACT
We report a severe case of congenital myasthenia gravis in a Chinese newborn who presented with complete ptosis, severe hypotonia, dysphagia and respiratory insufficiency with recurrent apnea that required mechanical ventilatory support since birth. Routine neurophysiologic studies, including the 3-Hz repetitive stimulation test and electromyogram were normal. Neostigmine and edrophonium tests were also negative. However, decremental response to 3-Hz stimulation became apparent after depleting the muscles with trains of 10-Hz stimuli for 10 min. The infant was subsequently confirmed to have heterozygous mutations in the choline acetyltransferase genes, p.T553N and p.S704P. Both missense mutations are novel mutations. The child remained on positive pressure ventilation at 3 years of age despite treatment with high-dose anticholinesterase. This case highlights the difficulty of making an early diagnosis based on clinical presentation and routine electrophysiologic tests, especially when neonatologists are not familiar with this condition. Further, as there are different genetic defects causing different types of congenital myasthenia gravis, anticholinesterase therapy may be beneficial to some but detrimental to others. Therefore, the exact molecular diagnosis is an important guide to therapy. A high index of suspicion coupled with extended electrodiagnostic tests in clinically suspected patients will ensure the selection of appropriate genetic molecular study for confirming the diagnosis.