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. Il1ß 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.

Photoperiod alters duration and intensity of non-rapid eye movement sleep following immune challenge in Siberian hamsters (Phodopus sungorus).

Sleep is regulated by circadian and homeostatic processes, but can be altered by infectious disease. During infection or exposure to inflammatory stimuli, such as bacterial lipopolysaccharide (LPS), the duration and intensity of non-rapid eye movement sleep (NREMS), as measured by electoencephalogram (EEG) delta waves (.5-4 Hz), increase. These sleep alterations are hypothesized to conserve or redirect energy for immune system activation. Many vertebrates exhibit seasonal changes in immune function and sleep-wake cycle, and photoperiod (day length) serves as a reliable environmental cue. For example, winter is energetically demanding for most animals, and Siberian hamsters (Phodopus sungorus) adapted to short winter day lengths display reduced fever after LPS administration to presumably conserve energy. We hypothesized that short days increase the duration and intensity of NREMS after LPS challenge to create additional energy savings, despite evidence to the contrary that high fever is associated with increased NREMS. Male hamsters were housed under long (16 h light (L):8 h dark (D)) or short (8L:16D) day lengths, and chronically implanted with transmitters that recorded EEG and electromyogram (EMG) biopotentials simultaneously or core body temperature. After >10 wks in photoperiod conditions, hamsters received an i.p. injection of LPS or saline (control), and vigilance states (duration and distribution of NREMS, rapid eye movement sleep (REMS), and wakefulness) and EEG delta power spectra (NREMS intensity) were assessed. As expected, LPS treatment increased the duration and intensity of NREMS compared to controls. Hamsters adapted to short photoperiods exhibited cumulatively larger increases in NREMS duration and EEG delta wave amplitude 0-8 h after LPS injection compared to long-day LPS-treated hamsters despite short-day attenuation of fever. These results suggest a seasonal decoupling of LPS-induced fever with sleep to promote energy conservation during predictable energy shortages. Ultimately, the combination of increased sleep and reduced fever could represent a suite of physiological adaptations that increase the probability of surviving winter.

Immune outcomes of paradoxical sleep deprivation on cellular distribution in naive and lipopolysaccharide-stimulated mice.

BACKGROUND/AIMS: Several lines of evidence indicate that sleep loss imposes significant consequences on the host defense system, including changes in cell number, activity and distribution. However, it is not clear whether cellular alterations after sleep deprivation are caused by redistribution to immune organs or by death of these cells or how the response to a nonspecific immune activator would be affected. Therefore, the aim of this study was to assess the leukocyte distribution after paradoxical sleep deprivation (PSD) in saline- and lipopolysaccharide-treated mice. METHODS: Adult inbred mice were paradoxical sleep deprived (72 h), whereas the controls were kept in their home cages. After PSD, both groups received an injection of either saline or lipopolysaccharide (LPS; 1 or 5 µg/animal, intraperitoneally), 2 h prior to the collection of blood, spleen, lymph nodes and peritoneal wash. Isolated cells were then designated to differential leukocyte count (blood) and flow cytometry analysis of immune cell subsets (immune sites). RESULTS: The data revealed that PSD caused a significant reduction of circulating lymphocytes and a general decrease in all cellular subsets of spleen, mainly T and B cells. However, no alteration in response of PSD was found on other immune sites, such as lymph nodes and peritoneum. Of note, immune cell distribution in response to in vivo LPS stimulation remained unchanged after PSD. CONCLUSIONS: Our study provided original evidence concerning the immune outcomes of PSD, indicating that cellular decrease caused by PSD is not restricted to circulation, but also to immune sites. Taken together, our results could help shed light on the physiological mechanisms of leukocyte trafficking.

Immune alterations after selective rapid eye movement or total sleep deprivation in healthy male volunteers.

We investigated the impact of two nights of total sleep deprivation (SD) or four nights of rapid eye movement (REM) SD on immunological parameters in healthy men. Thirty-two volunteers were randomly assigned to three protocols (control, total SD or REM SD). Both SD protocols were followed by three nights of sleep recovery. The control and REM SD groups had regular nights of sleep monitored by polysomnography. Circulating white blood cells (WBCs), T- (CD4/CD8) and B-lymphocytes, Ig classes, complement and cytokine levels were assessed daily. Two nights of total SD increased the numbers of leukocytes and neutrophils compared with baseline levels, and these levels returned to baseline after 24 h of sleep recovery. The CD4(+) T-cells increased during the total SD period (one and two nights) and IgA levels decreased during the entire period of REM SD. These levels did not return to baseline after three nights of sleep recovery. Levels of monocytes, eosinophils, basophils and cytokines (IL-1ß, IL-2, IL-4, IL-6, IL-10, TNF-α and IFN-γ) remained unchanged by both protocols of SD. Our findings suggest that both protocols affected the human immune profile, although in different parameters, and that CD4(+) T-cells and IgA levels were not re-established after sleep recovery.

Differential numbers of foci of lymphocytes within the brains of Lewis rats exposed to weak complex nocturnal magnetic fields during development of experimental allergic encephalomyelitis.

To discern if specific structures of the rat brain contained more foci of lymphocytes following induction of experimental allergic encephalomyelitis and exposures to weak, amplitude-modulated magnetic fields for 6 min once per hour during the scotophase, the residuals between the observed and predicted values for the numbers of foci for 320 structures were obtained. Compared to the brains of sham-field exposed rats, the brains of rats exposed to 7-Hz 50 nT (0.5 mG) amplitude-modulated fields showed more foci within hippocampal structures and the dorsal central grey of the midbrain while those exposed to 7-Hz 500 nT (5 mG) fields showed greater densities within the hypothalamus and optic chiasm. The brains of rats exposed to either the 50 nT or 500 nT amplitude-modulated 40-Hz fields displayed greater densities of foci within the midbrain structures related to rapid eye movement. Most of the enhancements of infiltrations within the magnetic field-exposed rats occurred in structures within periventricular or periaqueductal regions and were both frequency- and intensity-dependent. The specificity and complexity of the configurations of the residuals of the numbers of infiltrated foci following exposures to the different fields suggest that the brain itself may be a "sensory organ" for the detection of these stimuli.

Humoral regulation of physiological sleep: cytokines and GHRH.

Interleukin-1, tumour necrosis factor, and growth hormone releasing hormone form part of the humoral mechanisms regulating physiological sleep. Their injection enhances non-rapid-eye-movement sleep whereas their inhibition reduces spontaneous sleep and sleep rebound after sleep deprivation. Changes in their mRNA levels and changes in their protein levels in the brain are consistent within their proposed role in sleep regulation. Furthermore, results from transgenic and mutant animals also are suggestive of their role in sleep regulation. The sites responsible for the growth hormone releasing hormone somnogenic activity seem to reside in the anterior hypothalamus/basal forebrain. Somnogenic sites for interleukin-1 and tumour necrosis factor likely include the anterior hypothalamus, but also may extend beyond that area. These substances elicit non-rapid-eye-movement sleep via a biochemical cascade that includes other known sleep regulatory substances.

In vivo and in vitro immune variables in patients with narcolepsy and HLA-DR2 matched controls.

We investigated cytokine levels (interleukin [IL]-1beta, IL-1ra, IL-2, IL-6, tumor necrosis factor [TNF]-alpha, TNF-beta) in plasma and secreted by mitogen-stimulated blood monocytes and lymphocytes; T-cell subsets; and natural killer cell activity in patients with narcolepsy and in human leukocyte antigen (HLA)-DR2 matched controls. The only significant finding was higher IL-6 secretion by monocytes of patients than by those of the HLA-DR2-positive controls. In conclusion, we found no major abnormalities of T-cell function in patients with narcolepsy, but slight alterations of monocyte function deserving further investigation.

Sleep as a mediator of the stress-immune relationship.

OBJECTIVE: To evaluate the role of sleep in the relationship of intrusive thoughts/avoidance behaviors to natural killer cell (NKC) number and function. METHOD: Twenty-nine individuals seeking treatment for bereavement-related depression were studied in the sleep laboratory. Background and clinical variables, including the Impact of Event Scale (IES) and the Hamilton Rating Scale for Depression (HRSD), were administered during the week preceding a 3-night sleep study. Blood samples were collected upon awakening after the second or third night of sleep. RESULTS: Greater frequency of intrusive thoughts and avoidance behaviors was associated with more time spent awake during the first non-rapid eye movement period (NREM-1) and lower NKC number (p values < .01). Greater time spent awake during NREM-1 was associated with lower NKC numbers (p < .05). Regression analyses revealed that the significant relationship between symptoms of intrusion/avoidance and NKC number was no longer significant when time spent awake during NREM-1 was entered into the regression equation. Time spent awake during NREM-1 accounted for 12% of the variance in NKC number (p < .05), whereas intrusion/avoidance accounted for 7% of the variance in NKC number (NS). CONCLUSIONS: These results suggest that EEG-assessed sleep may be a significant correlate of the stress-immune relationship.

A controlled study of serum anti-locus ceruleus antibodies in REM sleep behavior disorder.

The newly identified association of human nonnarcoleptic rapid eye movement (REM) sleep behavior disorder (RBD) with human leukocyte antigen (HLA) DQw1 class II genes raises the possibility that RBD may arise from autoimmune mechanisms. Two recent case reports involving postmortem brain stem histochemical analyses in elderly males with RBD identified severe monoaminergic cell loss in the locus ceruleus (LC). Thus, we designed a study to detect anti-LC antibodies in RBD. Ten Caucasian males (mean age, 66 years) with polygraphically confirmed RBD (n = 5, idiopathic RBD: n = 5, RBD with Parkinson's disease), but without narcolepsy, idiopathic hypersomnia, or autoimmune disease, were recruited for this study, along with 10 Caucasian male controls (mean age, 63 years) without a history of sleep disorder or autoimmune disease. In a blinded design, sera from the RBD patients and their controls were tested against human LC and other brainstem neurons. Brainstem tissue was obtained from autopsies of neurologically normal individuals. The presence of anti-LC antibodies was examined using immunohistochemistry on brainstem sections. Sections incubated with sera from normal individuals and sera from patients with paraneoplastic antineuronal antibodies (anti-Hu and anti-Ri) were used as controls. No reactivity with LC or any other brainstem area was identified with sera from either RBD patients or their controls, or from the other group of normal individuals. In contrast, sera from patients with paraneoplastic anti-Hu and anti-Ri antibodies reacted strongly with nuclei of LC and other brainstem neurons, sparing the nucleoli, and reacted to a lesser extent with the cytoplasm of these neurons. Therefore, it is unlikely that human RBD is associated with anti-LC antibodies. However, an autoimmune process in RBD has not been excluded by this study.

Acute-phase immune response: lipopolysaccharide-induced fever and sleep alterations are not simultaneously conditionable in the rat during the inactive (light) phase.

Recent research has demonstrated that specific parameters of the immune system can be augmented by behavioral conditioning. These physiological alterations have been largely achieved by implementation of the conditioned taste aversion paradigm. Fever and sleep alterations are early occurrences within the acute-phase immune response to infection. The present study attempted to concurrently condition these two simultaneous, yet independent, responses. Lipopolysaccharide (LPS) was used as an unconditioned stimulus. When paired with a novel-tasting saccharin solution, a conditioned febrile response was observed. However, the somnogenic effects of LPS were not simultaneously conditionable. The conditioning of fever, as well as other interleukin-1-mediated responses, offers promise in both clinical and experimental applications.