The ALOXE3 gene variants from patients with Dravet syndrome decrease gene expression and enzyme activity
•A total of 5 variants identified in the ALOXE3 gene from DS patients.•The c.-50C > G variant decreases gene expression by preventing the TFII-I’s binding.•The p.I647 V mutation decreases the activity of ALOXE3 protein. Aberrant expression or dysfunction of a number of genes in the brain contribu...
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Veröffentlicht in: | Brain research bulletin 2021-05, Vol.170, p.81-89 |
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Zusammenfassung: | •A total of 5 variants identified in the ALOXE3 gene from DS patients.•The c.-50C > G variant decreases gene expression by preventing the TFII-I’s binding.•The p.I647 V mutation decreases the activity of ALOXE3 protein.
Aberrant expression or dysfunction of a number of genes in the brain contributes to epilepsy, a common neurological disorder characterized by recurrent seizures. Local overexpression of arachidonate lipoxygenase 3 (ALOXE3), a key enzyme for arachidonic acid (AA) metabolic pathway, alleviates seizure severities. However, the relationship between the ALOXE3 gene mutation and epilepsy has not been reported until now. Here we firstly characterized the promoter of human ALOXE3 gene and found that the ALOXE3 promoter could drive luciferase gene expression in the human HEK-293 and SH-SY5Y cells. We then screened the ALOXE3 promoter region and all coding exons from those patients with Dravet syndrome and identified 5 variants c.−163T > C, c.−50C > G, c.−37G > A, c. + 228G > A and c. + 290G > T in the promoter region and one missense variant c.1939A > G (p.I647 V) in the exon. Of these variants in the promoter region, only -50C > G was a novel variant located on the transcriptional factor NFII-I binding element. Luciferase reporter gene analyses indicated that the c.-50C > G could decrease gene expression by preventing the TFII-I’s binding. In addition, the variant p.I647 V was conserved among all analyzed species and located within the ALOXE3 functional domain for catalyzing its substrate. In cultured cell lines, overexpression of ALOXE3 significantly decreased the cellular AA levels and overexpression of ALOXE3-I647 V could restore the AA levels, suggesting that the p.I647 V mutant led to a decrease in enzyme activity. Taken together, the present study proposes that the identified ALOXE3 variants potentially contribute to the AA-pathway-mediated epileptogenesis, which should provide a novel avenue for clinical diagnosis of epilepsy. |
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ISSN: | 0361-9230 1873-2747 |
DOI: | 10.1016/j.brainresbull.2021.02.010 |