Mehdi Tafti

Deficiency in short-chain fatty acid β-oxidation affects theta oscillations during sleep

In rodents, the electroencephalogram (EEG) during paradoxical sleep and exploratory behavior is characterized by theta oscillations. Here we show that a deficiency in short-chain acyl-coenzyme A dehydrogenase (encoded by Acads) in mice causes a marked slowing in theta frequency during paradoxical sleep only. We found Acads expression in brain regions involved in theta generation, notably the hippocampus. Microarray analysis of gene expression in mice with mutations in Acads indicates overexpression of Glo1 (encoding glyoxylase 1), a gene involved in the detoxification of metabolic by-products. Administration of acetyl-L-carnitine (ALCAR) to mutant mice significantly recovers slow theta and Glo1 overexpression. Thus, an underappreciated metabolic pathway involving fatty acid β-oxidation also regulates theta oscillations during sleep.

MAO-A and COMT polymorphisms and gene effects in narcolepsy.

Narcolepsy presents one of the tightest associations with a specific HLA antigen (DQB1*0602) but there is strong evidence that non-HLA genes also confer susceptibility. Recent observations have implicated the hypocretin/orexin system in narcolepsy in both humans and animals. In addition, the implication of monoaminergic systems in the pathophysiology of narcolepsy is well established and a significant association between the monoamine oxydase-A (MAO-A) gene and human narcolepsy has recently provided a possible genetic link. We investigated polymorphisms of MAO-A and catechol-O-methyltransferase (COMT) in 97 Caucasians with well-defined narcolepsy-cataplexy and sought for genotypic effects on disease symptoms. No evidence of association between genotype or allele frequencies of both MAO-A or COMT gene and narcolepsy was found. However, a sexual dimorphism and a strong effect of COMT genotype on disease severity were found. Women narcoleptics with high COMT activity fell asleep twice as fast as those with low COMT activity during the multiple sleep latency test (MSLT) while the opposite was true for men. COMT genotype also strongly affected the presence of sleep paralysis and the number of REM sleep onsets during the MSLT. In agreement with well-documented pharmacological results in canine narcolepsy, this study reports the first genetic evidence for the critical involvement of the dopaminergic and/or noradrenergic systems in human narcolepsy.

Sexual dimorphism of the catechol-O-methyltransferase gene in narcolepsy is associated with response to modafinil

The gene for catechol-O-methyltransferase (COMT) plays a key modulatory role in dopaminergic and noradrenergic neurotransmission. Recent evidence suggests that modafinil, like other stimulants, might act through the dopaminergic system. We have reported a sexual dimorphism and a strong effect of the COMT genotype on narcolepsy symptoms and hypothesized that response to modafinil treatment may be associated with the COMT genotype. Here we confirm that COMT genotype distribution between men and women narcoleptics is associated with response to modafinil. In addition, the optimal daily dose of modafinil is approximately 100u2009mg lower in women narcoleptics and lower in all narcoleptics with low activity COMT genotype. Our results suggest that a sexual dimorphism in COMT activity affects the response to modafinil and probably to other dopaminergic stimulants.

Molecular approaches towards the isolation of sleep-related genes

Behavioural genetics is one of the most enticing fields in modern biology. Owing to straightforward and semiautomated techniques that can be used to measure locomotor activity, circadian rhythmicity is perhaps the best studied behaviour in animals. Thus, during the past decade, five essential circadian clock genes have been isolated in Drosophila, and homologous counterparts for all of these genes have also been found in mammals. As the sleep–wake cycle is under the control of the circadian clock, these circadian master genes are expected to influence sleeping behaviour. However, different vigilance states are regulated by additional mechanisms that also have a genetic basis. In this article we discuss molecular approaches that may prove useful in the search for sleep‐related genes.

Magnesium involvement in sleep: genetic and nutritional models.

Alterations of peripheral magnesium (Mg) concentration have been reported in association with several behavioral disorders and sleep organization. Blood Mg regulation is under a strong genetic control, whereas brain Mg regulation does not seem to be affected. We have studied peripheral and central levels of Mg and analyzed sleep in two lines of mice selected for low (MGL) and high (MGH) red blood cell (RBC) Mg levels. The same variables were also studied in C57BL/6J mice before and after 3 weeks of Mg deficiency. Whereas blood Mg was highly affected by the selection, brain Mg exhibited only small differences between the two lines. In contrast, Mg deficiency strongly decreased both central and peripheral Mg levels. Sleep analysis indicated that in both models the amount of paradoxical sleep was lower in mice with higher Mg levels. The amplitude of daily variation in sleep and slow-wave sleep delta power was markedly decreased in MGH line. Quantitative electroencephalogram (EEG) analysis also revealed a faster theta peak frequency in MGH mice, irrespective of behavioral states. Central Mg showed significant correlations with the amount of paradoxical sleep and sleep consolidation. However, because the direction of these correlations was not consistent, it is concluded that optimal, (physiological) rather than high or low, Mg levels are needed for normal sleep regulation.