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果蝇在进行太阳定位时既需要绿光也需要 UV 光,但它们缺乏时间补偿的太阳罗盘。

Drosophila require both green and UV wavelengths for sun orientation but lack a time-compensated sun compass.

机构信息

Graduate Neuroscience Program, University of California, Riverside, Riverside, CA 92521, USA.

Department of Entomology, University of California, Riverside, Riverside, CA 92521, USA.

出版信息

J Exp Biol. 2024 Oct 1;227(19). doi: 10.1242/jeb.246817. Epub 2024 Oct 14.

DOI:10.1242/jeb.246817
PMID:39397575
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11529886/
Abstract

Celestial orientation and navigation are performed by many organisms in contexts as diverse as migration, nest finding and straight-line orientation. The vinegar fly, Drosophila melanogaster, performs menotaxis in response to celestial cues during tethered flight and can disperse more than 10 km under field conditions. However, we still do not understand how spectral components of celestial cues and pauses in flight impact heading direction in flies. To assess individual heading, we began by testing flies in a rotating tether arena using a single green LED as a stimulus. We found that flies robustly perform menotaxis and fly straight for at least 20 min. Flies maintain their preferred heading directions after experiencing a period of darkness or stopping flight, even up to 2 h, but reset their heading when the LED changes position, suggesting that flies do not treat this stimulus as the sun. Next, we assessed the flies' responses to a UV spot alone or a paired UV-green stimulus - two dots situated 180 deg apart to simulate the solar and antisolar hemispheres. We found that flies respond to UV much as they do to green light; however, when the stimuli are paired, flies adjust for sudden 90 deg movements, performing sun orientation. Lastly, we found no evidence of a time-compensated sun compass when we moved the paired stimuli at 15 deg h-1 for 6 h. This study demonstrates that wavelength influences how flies respond to visual cues during flight, shaping the interpretation of visual information to execute an appropriate behavioral response.

摘要

许多生物在迁徙、寻找巢穴和直线定向等不同情境下进行天向导航和导航。黑腹果蝇在系绳飞行中会对天体线索做出趋向反应,并在野外条件下可以分散超过 10 公里。然而,我们仍然不知道天体线索的光谱成分和飞行中的停顿如何影响果蝇的飞行方向。为了评估个体的飞行方向,我们首先在旋转系绳竞技场中使用单个绿光 LED 作为刺激来测试果蝇。我们发现,果蝇能够强烈地进行趋向反应并直线飞行至少 20 分钟。果蝇在经历黑暗或停止飞行后,甚至长达 2 小时,仍能保持其首选的飞行方向,但当 LED 位置改变时,它们会重置飞行方向,这表明果蝇不会将此刺激视为太阳。接下来,我们评估了果蝇对单独的 UV 点或配对的 UV-绿光刺激的反应——两个相距 180 度的点,模拟太阳和对跖半球。我们发现,果蝇对 UV 光的反应与绿光相似;然而,当刺激配对时,果蝇会对突然的 90 度运动做出调整,从而进行太阳定向。最后,当我们以 15 度/小时的速度移动配对刺激 6 小时时,我们没有发现时间补偿的太阳罗盘的证据。这项研究表明,波长会影响果蝇在飞行中对视觉线索的反应方式,从而塑造对视觉信息的解释,以执行适当的行为反应。

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The long-distance flight behavior of supports an agent-based model for wind-assisted dispersal in insects.[具体昆虫名称]的长途飞行行为支持了一种基于代理的昆虫风辅助扩散模型。 (由于原文中“supports”前缺具体主体,所以这里保留英文[具体昆虫名称],你可根据实际情况补充完整)
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