Gegear Robert J, Casselman Amy, Waddell Scott, Reppert Steven M
Department of Neurobiology, University of Massachusetts Medical School, Worcester, Massachusetts 01605, USA.
Nature. 2008 Aug 21;454(7207):1014-8. doi: 10.1038/nature07183. Epub 2008 Jul 20.
Although many animals use the Earth's magnetic field for orientation and navigation, the precise biophysical mechanisms underlying magnetic sensing have been elusive. One theoretical model proposes that geomagnetic fields are perceived by chemical reactions involving specialized photoreceptors. However, the specific photoreceptor involved in such magnetoreception has not been demonstrated conclusively in any animal. Here we show that the ultraviolet-A/blue-light photoreceptor cryptochrome (Cry) is necessary for light-dependent magnetosensitive responses in Drosophila melanogaster. In a binary-choice behavioural assay for magnetosensitivity, wild-type flies show significant naive and trained responses to a magnetic field under full-spectrum light ( approximately 300-700 nm) but do not respond to the field when wavelengths in the Cry-sensitive, ultraviolet-A/blue-light part of the spectrum (<420 nm) are blocked. Notably, Cry-deficient cry(0) and cry(b) flies do not show either naive or trained responses to a magnetic field under full-spectrum light. Moreover, Cry-dependent magnetosensitivity does not require a functioning circadian clock. Our work provides, to our knowledge, the first genetic evidence for a Cry-based magnetosensitive system in any animal.
尽管许多动物利用地球磁场进行定向和导航,但磁感觉背后精确的生物物理机制一直难以捉摸。一种理论模型提出,地磁场是通过涉及特殊光感受器的化学反应来感知的。然而,在任何动物中,尚未最终证实参与这种磁感受的具体光感受器。在此我们表明,紫外线A/蓝光光感受器隐花色素(Cry)对于黑腹果蝇中依赖光的磁敏感反应是必需的。在磁敏感性的二元选择行为测定中,野生型果蝇在全光谱光(约300 - 700纳米)下对磁场表现出显著的原始和训练后的反应,但当光谱中Cry敏感的紫外线A/蓝光部分(<420纳米)的波长被阻断时,它们对磁场没有反应。值得注意的是,缺乏Cry的cry(0)和cry(b)果蝇在全光谱光下对磁场既没有原始反应也没有训练后的反应。此外,依赖Cry的磁敏感性不需要正常运作的生物钟。据我们所知,我们的工作为任何动物中基于Cry的磁敏感系统提供了首个遗传学证据。