Impaired hippocampal plasticity and altered neurogenesis in adult Ube3a maternal deficient mouse model for Angelman syndrome.

Angelman syndrome (AS) is a severe neurodevelopmental disorder characterized by mental retardation, seizures and sleep disturbances. It results from lack of the functional maternal allele of UBE3A gene. Ube3a maternal-deficient mice (Ube3a m-/p+), animal models for AS, are impaired in hippocampal-dependent learning tasks as compared with control (Ube3a m+/p+) mice. We first examined the basal expression of immediate early genes which expression is required for synaptic plasticity and memory formation. We found that basal expression of c-fos and Arc genes is reduced in the DG of Ube3a maternal deficient mice compared to their non-transgenic littermates. We then examined whether adult hippocampal neurogenesis, which likely serves as a mechanism toward brain plasticity, is altered in these transgenic mice. Neurogenesis occurs throughout life in mammalian dentate gyrus (DG) and recent findings suggest that newborn granule cells are involved in some forms of learning and memory. Whether maternal Ube3a deletion is detrimental on hippocampal neurogenesis is unclear. Herein, we show, using the mitotic marker Ki67, the birthdating marker 5-bromo-2'-dexoyuridine (BrdU) and the marker doublecortin (DCX) to respectively label cell proliferation, cell survival or young neuron production, that the Ube3a maternal deletion does not affect the proliferation nor the survival of newborn cells in the hippocampus. In contrast, using the postmitotic neuronal marker (NeuN), we show that Ube3a maternal deletion is associated with a lower fraction of BrdU+/NeuN+ newborn neurons among the population of surviving new cells in the hippocampus. Collectively, these findings suggest that some aspects of adult neurogenesis and plasticity are affected by Ube3a deletion and may contribute to the hippocampal dysfunction observed in AS mice.

Regional age-related changes in neuronal nitric oxide synthase (nNOS), messenger RNA levels and activity in SAMP8 brain.

BACKGROUND: Nitric oxide (NO) is a multifunctional molecule synthesized by three isozymes of the NO synthase (NOSs) acting as a messenger/modulator and/or a potential neurotoxin. In rodents, the role of NOSs in sleep processes and throughout aging is now well established. For example, sleep parameters are highly deteriorated in senescence accelerated-prone 8 (SAMP8) mice, a useful animal model to study aging or age-associated disorders, while the inducible form of NOS (iNOS) is down-regulated within the cortex and the sleep-structures of the brainstem. Evidence is now increasing for a role of iNOS and resulting oxidative stress but not for the constitutive expressed isozyme (nNOS). To better understand the role of nNOS in the behavioural impairments observed in SAMP8 versus SAMR1 (control) animals, we evaluated age-related variations occurring in the nNOS expression and activity and nitrites/nitrates (NOx-) levels, in three brain areas (n = 7 animals in each group). Calibrated reverse transcriptase (RT) and real-time polymerase chain reaction (PCR) and biochemical procedures were used. RESULTS: We found that the levels of nNOS mRNA decreased in the cortex and the hippocampus of 8- vs 2-month-old animals followed by an increase in 12-vs 8-month-old animals in both strains. In the brainstem, levels of nNOS mRNA decreased in an age-dependent manner in SAMP8, but not in SAMR1. Regional age-related changes were also observed in nNOS activity. Moreover, nNOS activity in hippocampus was found lower in 8-month-old SAMP8 than in SAMR1, while in the cortex and the brainstem, nNOS activities increased at 8 months and afterward decreased with age in SAMP8 and SAMR1. NOx- levels showed profiles similar to nNOS activities in the cortex and the brainstem but were undetectable in the hippocampus of SAMP8 and SAMR1. Finally, NOx- levels were higher in the cortex of 8 month-old SAMP8 than in age-matched SAMR1. CONCLUSION: Concomitant variations occurring in NO levels derived from nNOS and iNOS at an early age constitute a major factor of risk for sleep and/or memory impairments in SAMP8.

REM sleep control during aging in SAM mice: a role for inducible nitric oxide synthase.

Evidence that nitric oxide (NO) is involved in the regulation of rapid-eye-movement sleep (REMS) is supported by recent studies. During aging, NO generation encounters marked changes mainly related to the activation of the inducible NO-synthase (iNOS). To investigate links existing between iNOS and REMS impairments related to aging, we examine the age-related variations occurring in: mRNA and activity of iNOS in brainstem and frontal cortex; sleep parameters under baseline and after treatment by a selective iNOS inhibitor (AMT) in Senescence Accelerated Mice (SAM). SAMR1 (control) mice are a model of aging while SAMP8 are adequate to study neurodegenerative processes. RT-PCR analysis does not reveal significant variation in iNOS mRNA expression in both strains. However, significant age-related increases in iNOS activity occur in SAMR1 but such variation is not observed in SAMP8. In baseline conditions, aging induces a slight increase in slow-wave sleep (SWS) amounts in both groups and deteriorates greatly REMS architecture in SAMP8 compared to SAMR1. AMT reduces REMS amounts for 4-6h after treatment in a dose and age-dependent manner in SAMR1. Almost no changes occur in SAMP8. Data reported suggest that NO derived from iNOS contributes to trigger and maintain REMS during aging.

Sleep disturbances in Ube3a maternal-deficient mice modeling Angelman syndrome.

BACKGROUND: Angelman syndrome (AS) is a severe neurodevelopmental disorder with electroencephalographic (EEG) abnormalities and sleep disturbances. It results from lack of the functional maternal allele of UBE3A, which encodes a ubiquitin-protein ligase. Different mechanisms of UBE3A inactivation correlate with clinical phenotypes of varying severity; the majority of cases of AS are due to a de novo maternal deletion of the 15q11-q13 region. METHODS: Ube3a maternal-deficient mice (Ube3a m-/p+) were generated in a C57Bl/6J background. This study compares cortical EEG and architecture of the sleep-waking cycle in adult Ube3a m-/p+ mice compared with those of age-matched WT (m+/p+) mice, under baseline conditions or after 4-h sleep deprivation (SD). RESULTS: Ube3a m-/p+ mice exhibited: reduced slow-wave sleep (SWS) amount with increase waking (W) at the dark/light transitions; increased SWS and W episode numbers; and deterioration of paradoxical sleep (PS) over 24 h [amount: -44%; episode duration: -46%; episode number: -40%; theta peak frequency (TPF) acceleration: 7.6 Hz vs. 7.0 Hz in WT mice]. Characteristic paroxysmal EEG discharges are observed during W and SWS associated with synchronous muscle bursting activity during hypoactive W. During the recovery period following SD, Ube3a m-/p+ mice exhibited no rebound either in slow-wave activity (+89% in WT) or in delta-power spectra but a slight rebound in PS amount (+20%). CONCLUSIONS: These data validate the mouse model produced by null mutation of the maternal Ube3a gene and provide useful results to investigate and better understand the molecular basis of sleep disturbances in AS patients.

Nitric oxide and sleep.

Nitric oxide (NO) is a biological messenger synthesized by three main isoforms of NO synthase (NOS): neuronal (nNOS, constitutive calcium dependent), endothelial (eNOS, constitutive, calcium dependent) and inducible (iNOS, calcium independent). NOS is distributed in the brain either in circumscribed neuronal sets or in sparse interneurons. Within the laterodorsal tegmentum (LDT), pedunculopontine tegmentum and dorsal raphe nucleus, NOS-containing neurons overlap neurons grouped according to their contribution to sleep mechanisms. The main target for NO is the soluble guanylate cyclase that triggers an overproduction of cyclic guanosine monophosphate. NO in neurons of the pontine tegmentum facilitates sleep (particularly rapid-eye-movement sleep), and NO contained within the LDT intervenes in modulating the discharge of the neurons through an auto-inhibitory process involving the co-synthesized neurotransmitters. Moreover, NO synthesized within cholinergic neurons of the basal forebrain, while under control of the LDT, may modulate the spectral components of the EEG instead of the amounts of different sleep states. Finally, impairment of NO production (e.g. neurodegeneration, iNOS induction) has identifiable effects, including ageing, neuropathologies and parasitaemia.

Sleep wake profile and EEG spectral power in young or old senescence accelerated mice.

Changes occurring with age in cortical EEG and sleep-wake states architecture were examined in senescence accelerated prone (SAMP8) or senescence resistant (SAMR1) mice (age: 2 and 12 months) under baseline conditions or after a 4 h sleep deprivation (SD). In baseline conditions, an increase in slow wave sleep (SWS) amount (21-24%) occurs at the expense of the wakefulness (W) in old SAMP8 and SAMR1 mice versus young animals. In these conditions, SWS latency is reduced (67-72%). Moreover, in SAMP8 and SAMR1 mice, aging deteriorates paradoxical sleep (PS) architecture with more pronounced changes in SAMP8 (amount: -63%; episode duration: -44%; latency: +286%; circadian component loss; and EEG theta (theta) peak frequency (TPF): -1 Hz). During the 4 h recovery subsequent to a 4 h sleep deprivation, old SAMP8 mice exhibit an enhanced sensitivity resulting in SWS (+62%) and PS (+120%) rebounds, a characteristic of this inbred strain. Results obtained are discussed in line with the age-related learning and memory impairments existing in SAMP8 animals. In particular, the reduced cognitive performances described in old SAMP8 might be linked to the TPF deterioration during PS.

Changes occurring in cortical NO release and brain NO-synthases during a paradoxical sleep deprivation and subsequent recovery in the rat.

Variations occurring in cortical nitric oxide (NO) release were analysed with a voltametric method in rats (i) placed in control conditions, (ii) while being paradoxical sleep deprived (PSD), or (iii) recovering from a PSD. Activities of neuronal (nNOS) and inducible (iNOS) NO-synthases as well as nNOS expression were also determined in several brain regions. In baseline conditions, circadian variations in nNOS expression and activity were maximal during the dark period and minimal during the light one for all the structures analysed (frontal cortex, pons and medulla). In the same way, cortical NO release occurred through a circadian rhythm exhibiting maxima and minima during dark and light periods, respectively. In the same experimental conditions, iNOS activity did not exhibit time-dependent changes. The correlative changes observed in baseline conditions between NO release, nNOS expression and activity within the frontal cortex were disrupted during PSD and subsequent recovery. Still again, iNOS activity remained unchanged. Results obtained point out that the tight coupling existing in control conditions between nNOS expression-activity and NO release is disrupted by a PSD and remains affected during the subsequent 24 h recovery. Their significance is discussed.

Sleep-wake architecture in mouse models for Down syndrome.

Sleep-wake homeostasis is crucial for behavioral performances and memory both in the general population and in patients with learning disability, among whom were Down syndrome (DS) patients. We investigated, in mouse models of DS, cortical EEG and sleep-wake architecture under baseline conditions and after a 4-h sleep deprivation (SD). Young hemizygous mice (hSODwt/+) transgenic for the human CuZn superoxide dismutase (hSOD1) or for the human amyloid precursor protein (HuAPP(695); hAPPwt/+) were obtained on the same FVB/N inbred background. Baseline records for slow wave sleep (SWS) and wake (W) parameters were unchanged, whereas paradoxical sleep (PS) episode numbers were decreased and PS latency increased after lights off in hSODwt/+ mice versus controls. hSODwt/+ mice did not experience SWS or PS rebounds after SD but EEG activity in the delta-SWS activity (SWA) was enhanced. hAPPwt/+ mice exhibited no change in PS but an increase in W and a decrease in SWS before light transition as well as an increase in theta-power in PS and W. After SD, hAPPwt/+ mice exhibited SWS and PS rebounds as well as enhancement of SWA. We investigated also the nitrite/nitrate levels in all mice and found an increase in the brainstem of hSODwt/+ mice only versus control ones. These preliminary data provide useful results to investigate other genetically manipulated mice and to better understand the biochemical basis of sleep disorders in DS patients.