Abstract
OBJECTIVE: Gamma-aminobutyric acid (GABA), the major inhibitory neurotransmitter in the adult central nervous system, plays an important role during embryonic neural network formation. GAD67 is the rate-limiting enzyme in GABA synthesis, and its deficiency leads to developmental and epileptic encephalopathy 89 (DEE 89). Patients who suffered from this syndrome generally manifested severe to profound neurodevelopmental delay, seizures, and often congenital anomalies such as the cleft palate or/and omphalocele. Up to now, only three papers on this syndrome have been published, and our knowledge about the disease's clinical course and pathophysiology is in its infancy. METHODS: We used whole-exome sequencing (WES) and multiple in-silico tools to detect a potential causative variant in a patient with severe neurodevelopmental delay and refractory epilepsy. Moreover, by molecular docking and molecular dynamics simulation, we investigate the effect of the candidate variant on the GAD67 function and structure. RESULTS: WES data analysis revealed a novel deleterious variant (NM_000817.3: c.850C>T; p.Leu284Phe) in the GAD1 gene, which encodes the GAD67 enzyme. Molecular docking and molecular dynamics simulation showed that this variant has deleterious effects on the structure and function of the GAD67. This study's patient, in addition to typical symptoms of the DEE89, showed microcephaly and clonus in the toe, which were novel clinical findings. SIGNIFICANCE: Our findings expand the mutational and clinical spectrum of DEE 89. Also, by gathering clinical symptoms and genetic findings of previously reported cases, moreover providing a comprehensive clinical picture of the disease, we found that there was no common drug therapy among patients whose epilepsy was controlled. Furthermore, the comparison of clinical symptoms between patients with missense and truncating mutations did not show any significant clinical difference, except that patients with missense mutations did not show cleft palates or omphaloceles.