Enhancements in squid retinal responses to change of polarizations in a caustic shallow water

Jing Cai, Sergei Nikonov, Alison M Sweeney
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Abstract

Marine animals with polarization vision are able to effectively detect moving objects in shallow waters, which are illuminated by dynamic fluctuations of downwelling light known as caustics. While behavioral studies across different animal species have demonstrated the support of polarization vision in moving object detection within this noisy environment, little is known about how their retinal photoreceptors, absorbing polarized photons, respond to moving objects, or how each photoreceptor contributes to the collective retinal reaction to changes in polarization. In this study, we employed multi-electrode array recordings to examine the retinal neural response of squid to polarized light stimuli that were designed to simulate caustics environment. Extracellular retinal recordings not only exhibit neural activities selective to the direction of polarization but also demonstrate a significant enhancement in response to stimuli with changing polarization compared to constant polarization. This enhancement is robust in almost all recording channels, but absent in a random permutation of the recordings from different trial types. These results suggest that the retinal photoreceptors directly encode the change of polarization stimuli, thereby contributing to signal detections with polarization vision. Together, our research represents a novel neural exploration of cephalopod polarization vision in a caustic environment, and advances our understanding of how nature parses scenes with salient, dynamic polarization in animal vision.
乌贼视网膜对腐蚀性浅水中偏振变化的反应增强
具有偏振视觉的海洋动物能够有效地探测浅水中的移动物体,因为浅水中的下沉光被称为 "苛色",会产生动态波动。对不同动物物种的行为研究表明,偏振视觉支持在这种嘈杂环境中探测移动物体,但对于吸收偏振光子的视网膜光感受器如何对移动物体做出反应,以及每个光感受器如何对视网膜对偏振变化的集体反应做出贡献,我们却知之甚少。在这项研究中,我们利用多电极阵列记录来研究乌贼视网膜神经对偏振光刺激的反应。细胞外视网膜记录不仅显示出神经活动对偏振方向的选择性,而且还显示出与恒定偏振相比,对变化偏振刺激的反应明显增强。这种增强在几乎所有记录通道中都是稳健的,但在不同试验类型的随机排列记录中却不存在。这些结果表明,视网膜光感受器直接对偏振刺激的变化进行编码,从而有助于偏振视觉的信号检测。总之,我们的研究代表了对腐蚀性环境中头足类动物偏振视觉的一种新的神经探索,并推进了我们对自然界如何通过动物视觉中显著的动态偏振来解析场景的理解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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