Dove Abigail E, Cook Brianne L, Irgebay Zhazira, Vecsey Christopher G
Biology Department, Swarthmore College, 500 College Avenue, Swarthmore, PA 19081, United States.
Neuroscience Program, Skidmore College, 815 N. Broadway, Saratoga Springs, NY 12866, United States.
Physiol Behav. 2017 Oct 15;180:146-158. doi: 10.1016/j.physbeh.2017.08.020. Epub 2017 Aug 26.
Sleep can be altered by an organism's previous experience. For instance, female Drosophila melanogaster experience a post-mating reduction in daytime sleep that is purportedly mediated by sex peptide (SP), one of many seminal fluid proteins (SFPs) transferred from male to female during mating. In the present study, we first characterized this mating effect on sleep more fully, as it had previously only been tested in young flies under 12h light/12h dark conditions. We found that mating reduced sleep equivalently in 3-day-old or 14-day-old females, and could even occur in females who had been mated previously, suggesting that there is not a developmental critical period for the suppression of sleep by mating. In conditions of constant darkness, circadian rhythms were not affected by prior mating. In either constant darkness or constant light, the sleep reduction due to mating was no longer confined to the subjective day but could be observed throughout the 24-hour period. This suggests that the endogenous clock may dictate the timing of when the mating effect on sleep is expressed. We recently reported that genetic elimination of SP only partially blocked the post-mating female siesta sleep reduction, suggesting that the effect was unlikely to be governed solely by SP. We found here that the daytime sleep reduction was also reduced but not eliminated in females mated to mutant males lacking the vast majority of SFPs. This suggested that SFPs other than SP play a minimal role in the mating effect on sleep, and that additional non-SFP signals from the male might be involved. Males lacking sperm were able to induce a normal initial mating effect on female sleep, although the effect declined more rapidly in these females. This result indicated that neither the presence of sperm within the female reproductive tract nor female impregnation are required for the initial mating effect on sleep to occur, although sperm may serve to prolong the effect. Finally, we tested for contributions from other aspects of the mating experience. NorpA and eya2 mutants with disrupted vision showed normal mating effects on sleep. By separating males from females with a mesh, we found that visual and olfactory stimuli from male exposure, in the absence of physical contact, could not replicate the mating effect. Further, in ken/barbie male flies lacking external genitalia, courtship and physical contact without ejaculation were also unable to replicate the mating effect. These findings confirmed that the influence of mating on sleep does in fact require male/female contact including copulation, but may not be mediated exclusively by SP transfer.
睡眠可因生物体先前的经历而改变。例如,雌性黑腹果蝇在交配后白天睡眠时间减少,据称这是由性肽(SP)介导的,性肽是交配过程中雄性传递给雌性的众多精液蛋白(SFP)之一。在本研究中,我们首先更全面地描述了这种交配对睡眠的影响,因为此前仅在12小时光照/12小时黑暗条件下的年轻果蝇中进行过测试。我们发现,交配使3日龄或14日龄雌性果蝇的睡眠时间同等减少,甚至在先前已交配过的雌性果蝇中也会出现这种情况,这表明交配抑制睡眠不存在发育关键期。在持续黑暗的条件下,昼夜节律不受先前交配的影响。在持续黑暗或持续光照条件下,交配导致的睡眠减少不再局限于主观白天,而是在整个24小时期间都可观察到。这表明内源性时钟可能决定了交配影响睡眠的时间。我们最近报道,基因敲除SP仅部分阻断了交配后雌性果蝇午睡时间的减少,这表明该效应不太可能仅由SP控制。我们在此发现,与缺乏绝大多数SFP的突变雄性果蝇交配的雌性果蝇,其白天睡眠时间减少也有所减轻但并未消除。这表明除SP外的其他SFP在交配影响睡眠方面作用极小,且可能涉及来自雄性的其他非SFP信号。缺乏精子的雄性能够对雌性睡眠诱导出正常的初始交配效应,尽管这种效应在这些雌性果蝇中下降得更快。这一结果表明,雌性生殖道内精子的存在或雌性受孕都不是交配对睡眠产生初始效应所必需的,尽管精子可能有助于延长这种效应。最后,我们测试了交配经历其他方面的作用。视觉受损的NorpA和eya2突变体对睡眠表现出正常的交配效应。通过用网将雄性和雌性分开,我们发现,在没有身体接触的情况下,来自雄性的视觉和嗅觉刺激无法复制交配效应。此外,在缺乏外生殖器的ken/barbie雄性果蝇中,求偶和无射精的身体接触也无法复制交配效应。这些发现证实,交配对睡眠的影响实际上确实需要雌雄接触,包括交配,但可能并非仅由SP传递介导。
