夜间光线如何设定海洋蠓(Clunio marinus)的圆周时钟。

IF 2.9 3区 生物学 Q2 BIOLOGY
Carolina M Peralta, Eric Feunteun, Julien Guillaudeau, Dušica Briševac, Tobias S Kaiser
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引用次数: 0

摘要

许多栖息在海陆交界处的生物都进化出了与半月(14.77 天)或月(29.53 天)周期相对应的生物钟。由于潮汐振幅在整个月相周期中都是可调的,这些环月相或环月时钟不仅使生物能够适应月相周期,还能适应特定的潮汐情况。生物钟是通过被称为 "环境信号"(zeitgebers)的环境线索与外部周期同步的。在这里,我们探究了夜间光线如何设置海洋昆虫 Clunio marinus 的环月钟和环膜月钟,这种海洋昆虫依靠环月钟和环膜月钟来控制出现的时间。我们首先通过测量海牛自然栖息地的光照强度来确定月光强度是如何受潮汐调节的。然后,我们在实验室实验中探索了不同的月光处理如何设定两个海牛品系的时钟相位,其中一个具有月亮节律,另一个具有半月节律。光照强度本身不会影响月相节律的相位。在夜间不同的2小时或4小时窗口中呈现月光表明:(1)所需的月光持续时间是因品系而异的,(2)存在因品系而异的月光敏感窗口,(3)月光的时间可以改变月律的相位,使其与最低低潮保持同步。模拟自然月光模式的实验证实,月相是由月光时间设定的。以野外观测到的月光强度模拟自然月光可获得最佳同步效果。总之,我们的研究表明,夜间光照的强度、持续时间和时间是一个复杂的、针对特定菌株的整合过程,从而精确地控制月相和半月节律。在自然月光条件下观察到的节律微调为更好地从时间生物学和遗传学角度分析海牛的环月(半)时钟奠定了基础。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
How Light at Night Sets the Circalunar Clock in the Marine Midge Clunio marinus.

Many organisms inhabiting the interface between land and sea have evolved biological clocks corresponding to the period of the semilunar (14.77 days) or the lunar (29.53 days) cycle. Since tidal amplitude is modulated across the lunar cycle, these circasemilunar or circalunar clocks not only allow organisms to adapt to the lunar cycle, but also to specific tidal situations. Biological clocks are synchronized to external cycles via environmental cues called zeitgebers. Here, we explore how light at night sets the circalunar and circasemilunar clocks of Clunio marinus, a marine insect that relies on these clocks to control timing of emergence. We first characterized how moonlight intensity is modulated by the tides by measuring light intensity in the natural habitat of C. marinus. In laboratory experiments, we then explored how different moonlight treatments set the phase of the clocks of two C. marinus strains, one with a lunar rhythm and one with a semilunar rhythm. Light intensity alone does not affect the phase of the lunar rhythm. Presenting moonlight during different 2-h or 4-h windows during the night shows that (1) the required duration of moonlight is strain-specific, (2) there are strain-specific moonlight sensitivity windows and (3) timing of moonlight can shift the phase of the lunar rhythm to stay synchronized with the lowest low tides. Experiments simulating natural moonlight patterns confirm that the phase is set by the timing of moonlight. Simulating natural moonlight at field-observed intensities leads to the best synchronization. Taken together, we show that there is a complex and strain-specific integration of intensity, duration and timing of light at night to precisely entrain the lunar and semilunar rhythms. The observed fine-tuning of the rhythms under natural moonlight regimes lays the foundation for a better chronobiological and genetic dissection of the circa(semi)lunar clock in C. marinus.

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来源期刊
CiteScore
6.10
自引率
8.60%
发文量
48
审稿时长
>12 weeks
期刊介绍: Journal of Biological Rhythms is the official journal of the Society for Research on Biological Rhythms and offers peer-reviewed original research in all aspects of biological rhythms, using genetic, biochemical, physiological, behavioral, epidemiological & modeling approaches, as well as clinical trials. Emphasis is on circadian and seasonal rhythms, but timely reviews and research on other periodicities are also considered. The journal is a member of the Committee on Publication Ethics (COPE).
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