Reiter Russel J, Tamura Hiroshi, Tan Dun Xian, Xu Xiao-Ying
Department of Cellular and Structural Biology, University of Texas Health Science Center, San Antonio, Texas.
Department of Cellular and Structural Biology, University of Texas Health Science Center, San Antonio, Texas.
Fertil Steril. 2014 Aug;102(2):321-8. doi: 10.1016/j.fertnstert.2014.06.014. Epub 2014 Jul 1.
To summarize the role of melatonin and circadian rhythms in determining optimal female reproductive physiology, especially at the peripheral level.
Databases were searched for the related English-language literature published up to March 1, 2014. Only papers in peer-reviewed journals are cited.
Not applicable.
PATIENT(S): Not applicable.
INTERVENTION(S): Melatonin treatment, alterations of the normal light:dark cycle and light exposure at night.
MAIN OUTCOME MEASURE(S): Melatonin levels in the blood and in the ovarian follicular fluid and melatonin synthesis, oxidative damage and circadian rhythm disturbances in peripheral reproductive organs.
RESULT(S): The central circadian regulatory system is located in the suprachiasmatic nucleus (SCN). The output of this master clock is synchronized to 24 hours by the prevailing light-dark cycle. The SCN regulates rhythms in peripheral cells via the autonomic nervous system and it sends a neural message to the pineal gland where it controls the cyclic production of melatonin; after its release, the melatonin rhythm strengthens peripheral oscillators. Melatonin is also produced in the peripheral reproductive organs, including granulosa cells, the cumulus oophorus, and the oocyte. These cells, along with the blood, may contribute melatonin to the follicular fluid, which has melatonin levels higher than those in the blood. Melatonin is a powerful free radical scavenger and protects the oocyte from oxidative stress, especially at the time of ovulation. The cyclic levels of melatonin in the blood pass through the placenta and aid in the organization of the fetal SCN. In the absence of this synchronizing effect, the offspring may exhibit neurobehavioral deficits. Also, melatonin protects the developing fetus from oxidative stress. Melatonin produced in the placenta likewise may preserve the optimal function of this organ.
CONCLUSION(S): Both stable circadian rhythms and cyclic melatonin availability are critical for optimal ovarian physiology and placental function. Because light exposure after darkness onset at night disrupts the master circadian clock and suppresses elevated nocturnal melatonin levels, light at night should be avoided.
总结褪黑素和昼夜节律在决定最佳女性生殖生理过程中的作用,尤其是在外周水平的作用。
检索数据库中截至2014年3月1日发表的相关英文文献。仅引用同行评审期刊上的论文。
不适用。
不适用。
褪黑素治疗、改变正常的明暗周期以及夜间光照。
血液和卵巢卵泡液中的褪黑素水平以及外周生殖器官中的褪黑素合成、氧化损伤和昼夜节律紊乱。
中枢昼夜调节系统位于视交叉上核(SCN)。这个主时钟的输出通过主要的明暗周期与24小时同步。SCN通过自主神经系统调节外周细胞的节律,并向松果体发送神经信息,在那里控制褪黑素的周期性分泌;释放后,褪黑素节律增强外周振荡器。外周生殖器官,包括颗粒细胞、卵丘和卵母细胞也能产生褪黑素。这些细胞以及血液可能会将褪黑素分泌到卵泡液中,卵泡液中的褪黑素水平高于血液中的水平。褪黑素是一种强大的自由基清除剂,可保护卵母细胞免受氧化应激,尤其是在排卵时。血液中褪黑素的周期性水平穿过胎盘,有助于胎儿SCN的组织形成。如果没有这种同步作用,后代可能会出现神经行为缺陷。此外,褪黑素可保护发育中的胎儿免受氧化应激。胎盘中产生的褪黑素同样可能维持该器官的最佳功能。
稳定的昼夜节律和周期性的褪黑素供应对于最佳的卵巢生理和胎盘功能至关重要。由于夜间黑暗开始后的光照会扰乱主昼夜节律时钟并抑制夜间升高的褪黑素水平,因此应避免夜间光照。
