The ALOXE3 gene variants from patients with Dravet syndrome decrease gene expression and enzyme activity.

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.

High fat suppresses SOD1 activity by reducing copper chaperone for SOD1 associated with neurodegeneration and memory decline.

High fat consumption leads to reactive oxygen species (ROS) which is associated with age-progressive neurological disorders. Cu/Zn superoxide dismutase (SOD1) is a critical enzyme against ROS. However, the relationship between SOD1 and the high-fat-induced ROS and neurodegeneration is poorly known. Here we showed that, upon treatment with a saturated fatty acid palmitic acid (PA), the SOD1 activity was decreased in mouse neuronal HT-22 cell line accompanied by elevation of ROS, but not in mouse microglial BV-2 cell line. We further showed that PA decreased the levels of copper chaperone for SOD1 (CCS) in HT-22 cells, which promoted the nuclear import of SOD1 and decreased its activity. We demonstrated that the reduction of CCS is involved in the PA-induced decrease of SOD1 activity and elevation of ROS. In addition, compared with the adult mice fed with a standard diet, the high-fat-diet adult mice presented an increase of plasma free fatty acids, reduction of hippocampal SOD1 activity and CCS, mitochondrial degeneration and long-term memory decline. Taken together, our findings suggest that the high-fat-induced lower CCS level is essential for SOD1 suppression which may be associated with neurodegeneration and cognitive decline.

FMRP-absence-induced up-regulation of hypothalamic MAP1B expression decreases AgRP level linking with reduces in food intake and body weight.

Fragile X mental retardation protein (FMRP), strongly associated with fragile X syndrome, plays important roles by regulating gene expression via interacting with other RNA binding proteins in the brain. However, the role of FMRP in hypothalamus, a central part responsible for metabolic control, is poorly known. Our study shows that FMRP is primarily located in the hypothalamic arcuate nucleus (ARC). Using proteomic analysis, we identified 56 up-regulated and 22 down-regulated proteins in the hypothalamus of Map1b KO mice, with microtubule-associated protein 1 B (MAP1B) being the most outstanding increased protein (more than 10 folds). Immunofluorescent assays showed that MAP1B significantly increased in the Map1b-KO ARC, in which the number of agouti-related peptide (AgRP)-staining neurons significantly reduced, but not altered for pro-opiomelanocortin (POMC) neurons. We further showed an age-dependent reduces in food intake and body weight of the KO mice, along with the decreases of MAP1B and AgRP at the same time points. In hypothalamic GT1-7 cells, the AgRP expression decreased upon knockdown of FMRP or overexpression of MAP1B, and increased in response to overexpression of FMRP or knockdown of MAP1B. Co-knockdown or co-overexpression of FMRP and MAP1B led to a reverse expression of AgRP compared to overexpression of knockdown of FMRP alone, demonstrating that MAP1B is essential for the regulatory effect of FMRP on AgRP expression. Taken together, these data suggest that FMRP-deficiency-induced increase of hypothalamic MAP1B and decrease of AgRP might be associated with reduces in food intake and body weight.