Department of Chemistry, Life Sciences and Environmental Sustainability, University of Parma, Parma, Italy.
Department of Health Sciences, University of Milan Medical School, Milan, Italy.
Brain Behav Immun. 2019 Aug;80:300-307. doi: 10.1016/j.bbi.2019.04.007. Epub 2019 Apr 3.
Sleep is altered in response to an immune challenge: non-rapid eye movement (NREM) sleep is increased and fragmented, REM sleep is inhibited. Sleep and immune response are affected by stress: several stressors inhibit sleep and increase waking time; stress-induced cortisol secretion affects the immune response, with immunosuppressive effects. Different levels of trait aggressiveness are associated with specific patterns of neuroendocrine and autonomic stress responsiveness. Aim of this study was to test the hypothesis that trait aggressiveness, by affecting response to stressors, modifies sleep alterations induced by the activation of the immune response. To this aim, rats were selected on the basis of their latency time to attack a male intruder in the resident-intruder test. Animals were instrumented for chronic recordings of sleep-wake activity and injected, intraperitoneally, with an immune challenge (250 μg/kg lipopolysaccharide - LPS, a component of gram-negative bacterial cell wall). Here we report that high aggressive (HA) rats responded to an immune challenge with a 24-h long increase in cortical brain temperature. During the first 12 post-injection hours, HA rats also responded with a prolonged increase in NREM sleep amount, and a 5-h long and continuous inhibition of REM sleep. In HA rats, the LPS-induced increase in the amount of time spent in NREM sleep was due to an increase in the number of episodes of this sleep phase, without any change in the bout duration. The LPS-induced REM sleep inhibition observed in HA rats was due to a decrease in both the number and duration of REM sleep bouts. In HA rats, during REM sleep, LPS administration significantly reduced the power of the EEG theta band. In non-aggressive (NA) rats, in response to LPS administration, cortical brain temperature was increased only for two hours, NREM sleep was unaffected, and REM sleep inhibition was scattered along the first 8 post-injection hours. The LPS-induced changes in the number of NREM sleep bouts of NA rats were limited to few and scattered hours, with a change in bout duration only in a single hour. A combination of decreases, in few hours, in both REM sleep bouts and their duration contributed to the REM sleep inhibition observed in NA rats. In NA rats, the power of EEG theta band was not modified, during REM sleep, by LPS administration. Gross motor activity was inhibited in both HA and NA rats. Results of this study show that trait aggressiveness affects febrile and sleep responses to an immune challenge.
非快速眼动 (NREM) 睡眠增加且变得碎片化,快速眼动 (REM) 睡眠受到抑制。睡眠和免疫反应受压力影响:许多应激源会抑制睡眠并增加觉醒时间;应激诱导的皮质醇分泌会影响免疫反应,产生免疫抑制作用。不同程度的特质攻击性与特定的神经内分泌和自主应激反应模式相关。本研究的目的是验证以下假设:特质攻击性通过影响对应激源的反应,改变免疫反应激活引起的睡眠改变。为此,根据在驻留-入侵者测试中攻击雄性入侵者的潜伏期,选择大鼠。动物被植入用于慢性睡眠-觉醒活动记录的设备,并通过腹腔内注射免疫挑战物(250μg/kg 脂多糖 - LPS,革兰氏阴性细菌细胞壁的组成部分)。在这里,我们报告说,高攻击性 (HA) 大鼠对免疫挑战的反应是皮质脑温升高 24 小时。在注射后 12 小时内,HA 大鼠还表现出 NREM 睡眠量持续延长,以及 REM 睡眠持续 5 小时的抑制。在 HA 大鼠中,LPS 诱导的 NREM 睡眠时间增加是由于该睡眠阶段的发作次数增加,而阶段持续时间没有变化。在 HA 大鼠中,LPS 诱导的 REM 睡眠抑制是由于 REM 睡眠发作的数量和持续时间均减少所致。在 HA 大鼠中,在 REM 睡眠期间,给予 LPS 会显著降低 EEG θ波段的功率。在非攻击性 (NA) 大鼠中,给予 LPS 后皮质脑温仅升高两个小时,NREM 睡眠不受影响,REM 睡眠抑制沿注射后的前 8 小时分散。NA 大鼠 NREM 睡眠发作次数的 LPS 诱导变化仅限于少数几个分散的小时,并且仅在一个小时内改变了发作持续时间。在少数几个小时内 REM 睡眠发作和持续时间均减少,导致了在 NA 大鼠中观察到的 REM 睡眠抑制。在 NA 大鼠中,给予 LPS 不会改变 REM 睡眠期间 EEGθ波段的功率。HA 和 NA 大鼠的总体运动活动均受到抑制。本研究的结果表明,特质攻击性会影响发热和对免疫挑战的睡眠反应。
