The retinal pigments of the whale shark (Rhincodon typus) and their role in visual foraging ecology

IF 1.1 4区 医学 Q4 NEUROSCIENCES Visual Neuroscience Pub Date : 2019-11-13 DOI:10.1017/S0952523819000105
Jeffry I Fasick, H. Algrain, Katherine M. Serba, P. Robinson
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引用次数: 9

Abstract

Abstract The spectral tuning properties of the whale shark (Rhincodon typus) rod (rhodopsin or Rh1) and long-wavelength-sensitive (LWS) cone visual pigments were examined to determine whether these retinal pigments have adapted to the broadband light spectrum available for surface foraging or to the narrowband blue-shifted light spectrum available at depth. Recently published whale shark genomes have identified orthologous genes for both the whale shark Rh1 and LWS cone opsins suggesting a duplex retina. Here, the whale shark Rh1 and LWS cone opsin sequences were examined to identify amino acid residues critical for spectral tuning. Surprisingly, the predicted absorbance maximum (λmax) for both the whale shark Rh1 and LWS visual pigments is near 500 nm. Although Rh1 λmax values near 500 nm are typical of terrestrial vertebrates, as well as surface foraging fish, it is uncommon for a vertebrate LWS cone pigment to be so greatly blue-shifted. We propose that the spectral tuning properties of both the whale shark Rh1 and LWS cone pigments are most likely adaptations to the broadband light spectrum available at the surface. Whale shark melanopsin (Opn4) deactivation kinetics was examined to better understand the underlying molecular mechanisms of the pupillary light reflex. Results show that the deactivation rate of whale shark Opn4 is similar to the Opn4 deactivation rate from vertebrates possessing duplex retinae and is significantly faster than the Opn4 deactivation rate from an aquatic rod monochromat lacking functional cone photoreceptors. The rapid deactivation rate of whale shark Opn4 is consistent with a functional cone class and would provide the animal with an exponential increase in the number of photons required for photoreceptor signaling when transitioning from photopic to scotopic light conditions, as is the case when diving.
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鲸鲨(Rhincodon typus)视网膜色素及其在视觉觅食生态学中的作用
摘要研究了鲸鲨视杆(rhodopsin或Rh1)和长波长敏感(LWS)视锥色素的光谱调谐特性,以确定这些视网膜色素是适应可用于表面觅食的宽带光谱还是可用于深度的窄带蓝移光谱。最近发表的鲸鲨基因组已经确定了鲸鲨Rh1和LWS视锥蛋白的同源基因,这表明鲸鲨的视网膜是双工的。在这里,研究人员检测了鲸鲨Rh1和LWS视锥蛋白序列,以确定对光谱调谐至关重要的氨基酸残基。令人惊讶的是,鲸鲨Rh1和LWS视觉色素的预测吸光度最大值(λmax)都接近500 nm。虽然在500 nm附近的Rh1 λmax值在陆生脊椎动物和水面觅食的鱼类中是典型的,但脊椎动物LWS锥色素的蓝移如此之大是不常见的。我们提出,鲸鲨Rh1和LWS锥色素的光谱调谐特性很可能是对表面可用的宽带光谱的适应。研究了鲸鲨黑视素(Opn4)失活动力学,以更好地了解瞳孔光反射的潜在分子机制。结果表明,鲸鲨的Opn4失活率与具有双视网膜的脊椎动物的Opn4失活率相似,明显快于缺乏功能性视锥光感受器的水生杆状单色体的Opn4失活率。鲸鲨Opn4的快速失活率与功能性锥体类别一致,并且在从光向暗光条件过渡时(如潜水时),将为动物提供光感受器信号所需的光子数量的指数增长。
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来源期刊
Visual Neuroscience
Visual Neuroscience 医学-神经科学
CiteScore
2.20
自引率
5.30%
发文量
8
审稿时长
>12 weeks
期刊介绍: Visual Neuroscience is an international journal devoted to the publication of experimental and theoretical research on biological mechanisms of vision. A major goal of publication is to bring together in one journal a broad range of studies that reflect the diversity and originality of all aspects of neuroscience research relating to the visual system. Contributions may address molecular, cellular or systems-level processes in either vertebrate or invertebrate species. The journal publishes work based on a wide range of technical approaches, including molecular genetics, anatomy, physiology, psychophysics and imaging, and utilizing comparative, developmental, theoretical or computational approaches to understand the biology of vision and visuo-motor control. The journal also publishes research seeking to understand disorders of the visual system and strategies for restoring vision. Studies based exclusively on clinical, psychophysiological or behavioral data are welcomed, provided that they address questions concerning neural mechanisms of vision or provide insight into visual dysfunction.
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