Mayumi Machida

Basolateral amygdala and the regulation of fear-conditioned changes in sleep: role of corticotropin-releasing factor.

STUDY OBJECTIVE To determine whether corticotropin-releasing factor (CRF) in the basolateral amygdala (BLA) modulated sleep and fear-conditioned alterations in sleep. DESIGN After 2 days of habituation to recording procedures, baseline sleep recordings were obtained. The animals were then habituated to the handling procedure necessary for microinjections over 2 consecutive days. In experiment 1, rats received microinjections of 0.5 μL antalarmin (1.61 or 4.82 mM), a CRF receptor 1 antagonist, or distilled water once a week for 3 wk. In experiment 2, rats received a microinjection of either antalarmin or vehicle prior to inescapable shock training (ST; 20 shocks; 0.8 mA, 0.5 sec; 1 min interstimulus interval). The animals were placed back in the context 7 days later for 30 min without shock (CR; context re-exposure). Sleep was recorded for 8 h after each manipulation. SETTING NA. SUBJECTS Outbred Wistar rats. INTERVENTIONS The rats were surgically implanted with electrodes for recording the electroencephalogram and electromyogram for determining arousal state and with bilateral guide cannulae directed at BLA. MEASUREMENTS AND RESULTS Antalarmin microinjected into BLA did not significantly alter sleep under undisturbed conditions. However, antalarmin microinjected bilaterally into BLA prior to ST blocked reductions in rapid eye movement sleep that ST normally produces. Further, the single microinjection prior to ST blocked the reduction in rapid eye movement typically seen after subsequent CR. Behavioral freezing, an indicator of fear memory, was not altered. CONCLUSIONS CRF in BLA is involved in regulating stress-induced alterations in sleep and it plays a role in modulating how stressful memories influence sleep.

Exposure to Mission Relevant Doses of 1 GeV/Nucleon 56Fe Particles Leads to Impairment of Attentional Set-Shifting Performance in Socially Mature Rats

Previous ground-based experiments have shown that cranial irradiation with mission relevant (20 cGy) doses of 1 GeV/nucleon 56Fe particles leads to a significant impairment in Attentional Set Shifting (ATSET) performance, a measure of executive function, in juvenile Wistar rats. However, the use of head only radiation exposure and the biological age of the rats used in that study may not be pertinent to determine the likelihood that ATSET will be impaired in Astronauts on deep space flights. In this study we have determined the impact that whole-body exposure to 10, 15 and 20 cGy of 1 GeV/nucleon 56Fe particles had on the ability (at three months post exposure) of socially mature (retired breeder) Wistar rats to conduct the attentional set-shifting paradigm. The current study has established that whole-body exposures to 15 and 20 (but not 10) cGy of 1 GeV/nucleon 56Fe particles results in the impairment of ATSET in both juvenile and socially mature rats. However, the exact nature of the impaired ATSET performance varied depending upon the age of the rats, whether whole-body versus cranial irradiation was used and the dose of 1 GeV/u 56Fe received. Exposure of juvenile rats to 20 cGy of 1 GeV/nucleon 56Fe particles led to a decreased ability to perform intra-dimensional shifting (IDS) irrespective of whether the rats received head only or whole-body exposures. Juvenile rats that received whole-body exposure also had a reduced ability to habituate to the assay and to complete intra-dimensional shifting reversal (IDR), whereas juvenile rats that received head only exposure had a reduced ability to complete compound discrimination reversal (CDR). Socially mature rats that received whole-body exposures to 10 cGy of 1 GeV/nucleon 56Fe particles exhibited no obvious decline in set-shifting performance; however those exposed to 15 and 20 cGy had a reduced ability to perform simple discrimination (SD) and compound discrimination (CD). Exposure to 20 cGy of 1 GeV/nucleon 56Fe particles also led to a decreased performance in IDR and to ∼25% of rats failing to habituate to the task. Most of these rats started to dig for the food reward but rapidly (within 15 s) gave up digging, suggesting that they had developed appropriate procedural memories about food retrieval, but had an inability to maintain attention on the task. Our preliminary data suggests that whole-body exposure to 20 cGy of 1 GeV/nucleon 56Fe particles reduced the cholinergic (but not the GABAergic) readily releasable pool (RRP) in nerve terminals of the basal forebrain from socially-mature rats. This perturbation of the cholinergic RRP could directly lead to the loss of CDR and IDR performance, and indirectly [through the metabolic changes in the medial prefrontal cortex (mPFC)] to the loss of SD and CD performance. These findings provide the first evidence that attentional set-shifting performance in socially mature rats is impaired after whole-body exposure to mission relevant doses (15 and 20 cGy) of 1 GeV/nucleon 56Fe particles, and importantly that a dose reduction down to 10 cGy prevents that impairment. The ability to conduct Discrimination tasks (SD and CD) and reversal learning (CDR) is reduced after exposure to 15 and 20 cGy of 1 GeV/nucleon 56Fe particles, but at 20 cGy there is an additional decrement, ∼ 25% of rats are unable to maintain attention to task. These behavioral decrements are associated with a reduction in the cholinergic RRP within basal forebrain, which has been shown to play a major role in regulating the activity of the PFC.

Effects of stressor predictability on escape learning and sleep in mice.

STUDY OBJECTIVES Controllable stress, modeled by escapable shock (ES), can produce significant alterations in post-stress sleep, including increased rapid eye movement (REM) sleep. Recent work has demonstrated that post-stress sleep may be influenced by stressor predictability, modeled by predictive auditory cues. In this study, we trained mice with ES, either signaled (SES) or unsignaled (UES) by auditory cues, and investigated the effects of predictability on escape learning and sleep associated with ES. DESIGN Adult male BALB/cJ mice were implanted for recording electroencephalography and activity via telemetry. After the mice recovered from surgery, baseline sleep recordings were obtained. The mice were then randomly assigned to SES and UES conditions. Both groups had control over the duration of footshocks (0.5 mA; 5.0 sec maximum duration) by moving to the non-occupied chamber in a shuttlebox. SES mice were presented tones (90 dB, 2 kHz, 10 sec maximum duration) that started 5.0 sec prior to and co-terminated with footshocks. UES mice were presented identical tones that were not synchronized to shock presentation. ES training continued for 2 consecutive days (EST1 and EST2) with 20 footshock presentations (1 min inter-stimulus intervals). Seven days after EST2, the animals were re-exposed to the training chamber (context) alone for 30 min. MEASUREMENTS AND RESULTS Escape latency was used to determine successful or unsuccessful escape learning. Sleep was scored for 20 h for baseline and on each treatment day. Freezing in the training context was scored as a behavioral index of fear. Nine of 14 SES mice successfully learned escape (SESl), and 5 failed to learn escape (SESf). Compared with baseline, SESl mice, but not SESf mice, showed significantly increased post-shock REM. All UES mice learned escape and showed enhanced post-shock REM. Freezing and sleep did not differ among groups on the context re-exposure day. CONCLUSIONS The results indicate that information available in a stressful situation can affect an animals ability to learn an appropriate response and post-stress sleep. CITATION Machida M; Yang L; Wellman LL; Sanford LD. Effects of stressor predictability on escape learning and sleep in mice. SLEEP 2013;36(3):421-430.

The role of active zone protein Rab3 interacting molecule 1 alpha in the regulation of norepinephrine release, response to novelty, and sleep

Sleep mechanisms and synaptic plasticity are thought to interact to regulate homeostasis and memory formation. However, the influences of molecules that mediate synaptic plasticity on sleep are not well understood. In this study we demonstrate that mice lacking Rab3 interacting molecule 1 alpha (RIM1 alpha) (Rim1 alpha KO), a protein of the synaptic active zone required for certain types of synaptic plasticity and learning, had 53+/-5% less baseline rapid eye movement (REM) sleep compared with their wild type littermates. Also, compared with wild type littermates, exposure of the mice to an open field or to a novel object induced more robust and longer lasting locomotion suggesting altered habituation. This difference in exploratory behavior correlated with genotype specific changes in REM and deregulated release of norepinephrine in the cortex and basal amygdala of the Rim1 alpha KO mice. Also, moderate sleep deprivation (4 h), a test of the homeostatic sleep response, induced REM sleep rebound with different time course in Rim1 alpha KO and their wild type littermates. As norepinephrine plays an important role in regulating arousal and REM sleep, our data suggest that noradrenergic deficiency in Rim1 alpha KO animals impacts exploratory behavior and sleep regulation and contributes to impairments in learning.

Sleep and behavior during vesicular stomatitis virus induced encephalitis in BALB/cJ and C57BL/6J mice.

Intranasal application of vesicular stomatitis virus (VSV) produces a well-characterized model of viral encephalitis in mice. Within one day post-infection (PI), VSV travels to the olfactory bulb and, over the course of 7 days, it infects regions and tracts extending into the brainstem followed by clearance and recovery in most mice by PI day 14 (PI 14). Infectious diseases are commonly accompanied by excessive sleepiness; thus, sleep is considered a component of the acute phase response to infection. In this project, we studied the relationship between sleep and VSV infection using C57BL/6 (B6) and BALB/c mice. Mice were implanted with transmitters for recording EEG, activity and temperature by telemetry. After uninterrupted baseline recordings were collected for 2 days, each animal was infected intranasally with a single low dose of VSV (5×10(4) PFU). Sleep was recorded for 15 consecutive days and analyzed on PI 0, 1, 3, 5, 7, 10, and 14. Compared to baseline, amounts of non-rapid eye movement sleep (NREM) were increased in B6 mice during the dark period of PI 1-5, whereas rapid eye movement sleep (REM) was significantly reduced during the light periods of PI 0-14. In contrast, BALB/c mice showed significantly fewer changes in NREM and REM. These data demonstrate sleep architecture is differentially altered in these mouse strains and suggests that, in B6 mice, VSV can alter sleep before virus progresses into brain regions that control sleep.

Antagonism of corticotropin releasing factor in the basolateral amygdala of resilient and vulnerable rats: Effects on fear-conditioned sleep, temperature and freezing

ABSTRACT The basolateral nucleus of the amygdala (BLA) plays a significant role in mediating individual differences in the effects of fear memory on sleep. Here, we assessed the effects of antagonizing corticotropin releasing factor receptor 1 (CRFR1) after shock training (ST) on fear‐conditioned behaviors and sleep. Outbred Wistar rats were surgically implanted with electrodes for recording EEG and EMG and with bilateral guide cannulae directed at BLA. Data loggers were placed intraperitoneally to record core body temperature. The CRFR1 antagonist, antalarmin (ANT; 4.82 mM) was microinjected into BLA after shock training (ST: 20 footshocks, 0.8 mA, 0.5 s duration, 60 s interstimulus interval), and the effects on sleep, freezing and the stress response (stress‐induced hyperthermia, SIH) were examined after ST and fearful context re‐exposure alone at 7 days (CTX1) and 21 days (CTX2) post‐ST. EEG and EMG recordings were scored for non‐rapid eye movement sleep (NREM), rapid eye movement sleep (REM) and wakefulness. The rats were separated into 4 groups: Vehicle‐vulnerable (Veh‐Vul; n = 10), Veh‐resilient (Veh‐Res; n = 11), ANT‐vulnerable (ANT‐Vul; n = 8) and ANT‐resilient (ANT‐Res; n = 8) based on whether, compared to baseline, the rats showed a decrease or no change/increase in REM during the first 4 h following ST. Post‐ST ANT microinjected into BLA attenuated the fear‐conditioned reduction in REM in ANT‐Vul rats on CTX1, but did not significantly alter REM in ANT‐Res rats. However, compared to Veh treated rats, REM was reduced in ANT treated rats on CTX2. There were no group differences in freezing or SIH across conditions. Therefore, CRFR1 in BLA plays a role in mediating individual differences in sleep responses to stress and in the extinction of fear conditioned changes in sleep. HIGHLIGHTSREM sleep can be increased or decreased by fear conditioning.Post‐training CRFR1 antagonism in BLA blocks fear conditioned decreases in REM sleep.Post‐training CRFR1 antagonism does not block conditioned fear behavior.Post‐training CRFR1 antagonism does not block fear conditioned temperature increases.

Early gene activation initiates neuroinflammation prior to VSV neuroinvasion: Impact on antiviral responses and sleep

Rapid eye movement (REM) sleep is rapidly and persistently suppressed during vesicular stomatitis virus (VSV) encephalitis in C57Bl/6J (B6) mice. REM sleep suppression was associated with a complex global brain chemokine/cytokine response with bimodal kinetics although regionally distinct cytokine profiles were readily identified. Cytokine mRNA was translated either immediately or suppressed until the pathogen was cleared from the CNS. Innate signaling pathway (TLRs, RIG-I) activation occurred rapidly and sequentially prior to VSV neuroinvasion suggesting that antiviral states are quickly established in the CNS in advance of viral pathogen penetration. Il1β suppressed REM sleep mimicking aspects of VSV-induced sleep alterations whereas some robustly induced chemokines may be protective of REM. Thus, multiple brain chemokines may mediate sleep across VSV encephalitis via differential somnogenic effects.

Controllable and uncontrollable stress differentially impact pathogenicity and survival in a mouse model of viral encephalitis

Intranasal instillation of vesicular stomatitis virus (VSV) into mice given controllable stress (modeled by escapable foot shock, ES) resulted in enhanced pathogenicity and decreased survival relative to infected mice given uncontrollable stress (modeled by inescapable foot shock, IS) and non-shocked control mice. Survival likely reflected differential cytokine gene expression that may have been regulated by miR146a, a predicted stress-responsive upstream regulator. Controllability also enhanced the accumulation of brain T resident memory cells that persisted long after viral clearance. The unexpected facilitatory effect of ES on antiviral neuroimmune responses and pathogenicity may arise from differential immunoactivating and immunosuppressive effects of uncontrollable and controllable stress.

Effects of Optogenetic inhibition of BLA on Sleep Brief Optogenetic Inhibition of the Basolateral Amygdala in Mice Alters Effects of Stressful Experiences on Rapid Eye Movement Sleep

Study Objectives Stressful events can directly produce significant alterations in subsequent sleep, in particular rapid eye movement sleep (REM); however, the neural mechanisms underlying the process are not fully known. Here, we investigated the role of the basolateral nuclei of the amygdala (BLA) in regulating the effects of stressful experience on sleep. Methods We used optogenetics to briefly inhibit glutamatergic cells in BLA during the presentation of inescapable footshock (IS) and assessed effects on sleep, the acute stress response, and fear memory. c-Fos expression was also assessed in the amygdala and the medial prefrontal cortex (mPFC), both regions involved in coping with stress, and in brain stem regions implicated in the regulation of REM. Results Compared to control mice, peri-shock inhibition of BLA attenuated an immediate reduction in REM after IS and produced a significant overall increase in REM. Moreover, upon exposure to the shock context alone, mice receiving peri-shock inhibition of BLA during training showed increased REM without altered freezing (an index of fear memory) or stress-induced hyperthermia (an index of acute stress response). Inhibition of BLA during REM under freely sleeping conditions enhanced REM only when body temperature was high, suggesting the effect was influenced by stress. Peri-shock inhibition of BLA also led to elevated c-Fos expression in the central nucleus of the amygdala and mPFC and differentially altered c-Fos activity in the selected brain stem regions. Conclusions Glutamatergic cells in BLA can modulate the effects of stress on REM and can mediate effects of fear memory on sleep that can be independent of behavioral fear.