Opsin-based photoreception in Crinoids

Youri Nonclercq, Marjorie Lienard, Alexia Lourtie, Emilie Duthoo, Lise Vanespen, Igor Eeckhaut, Patrick Flammang, Jerome Delroisse
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Abstract

Opsin-mediated light perception has been investigated in many marine invertebrates including some clades of echinoderms such as sea stars, sea urchins and brittle stars. On the other hand, the understanding of potential light perception in crinoids, the basal lineage of the echinoderm phylum, remains largely unexplored. Only a few behavioural observations suggest that crinoids may be sensitive to light stimuli. This study investigates the behavioural and molecular basis of opsin-based photoreception in Antedon bifida, a European crinoid species belonging to the Comatulid order. In this context, the behavioural response to different light wavelengths, the characterisation of opsin genes in the recent chromosome-scale genome of this species and the opsin immunolocalisation within the crinoid tissues have been investigated. Behavioural tests pointed to a significant negative phototactic behaviour induced by a wide range of light wavelengths (463 to 630 nm) with maximum sensitivity to blue light (λmax = 463 nm). In silico genome analyses revealed the presence of only three rhabdomeric opsin genes located on chromosomes 4 and 6: Abif-opsins 4.1, 4.2 and 4.3. All crinoid opsins are phylogenetically clustered as a sister-group of all other echinoderm rhabdomeric opsins, supporting their evolution via duplication of an ancestral gene in the crinoid lineage. The low opsin diversity contrasts with other echinoderms which are generally characterised by up to eight bilaterian opsin groups. Interestingly, A. bifida opsin sequences present typical amino acid residues of rhabdomeric opsins of other bilaterians, including two conserved cysteines (C110, C187), the probable ancestral E181 counterion, a NPxxY(x)6F pattern, a highly conserved lysine potentially covalently bound to a chromophore, and the (D)RY motif, all supportive of photoreceptive functions. Finally, immunoreactivity to newly generated antibodies designed against sea star opsins was highlighted in several tissues associated with the ambulacral grooves of the calyx and the pinnules. Within these tissues, Abif-opsins (potentially the Abif-opsin 4.1) are expressed in the ectoneural basiepithelial nerve plexus and the hyponeural nerve plexus. On the other hand, a different opsin type (potentially the Abif-opsin 4.2) is also expressed in the sensory papillae of tube feet. The localization of at least two opsin types in different sensory structures suggests the presence of a complex extraocular photoreception system exclusively based on rhabdomeric opsins in this crinoid species.
甲壳动物基于光蛋白的光感受
许多海洋无脊椎动物(包括棘皮动物的一些支系,如海星、海胆和脆星)都对由光感知蛋白介导的光感知进行了研究。另一方面,人们对棘皮动物门的基系--棘皮动物的潜在光感知能力的了解在很大程度上仍处于空白状态。只有少数行为观察表明,棘皮动物可能对光刺激敏感。本研究调查了欧洲棘皮动物中的一个物种 Antedon bifida(属于 Comatulid 目)基于蛋白的光感受的行为和分子基础。在此背景下,研究人员调查了该物种对不同波长光线的行为反应、该物种最新染色体级基因组中眼动素基因的特征,以及眼动素在棘皮动物组织中的免疫定位。行为测试表明,在多种波长(463-630 nm)的光照下,该物种会出现明显的负趋光行为,对蓝光的敏感度最高(λmax = 463 nm)。硅基因组分析表明,在第 4 和第 6 染色体上只存在三个横纹肌蛋白基因:Abif-opsins 4.1、4.2 和 4.3。所有的棘皮动物蛋白在系统发育上都是所有其他棘皮动物横纹肌蛋白的姊妹群,这证明它们是通过复制棘皮动物的祖先基因进化而来的。这种蛋白多样性较低的情况与其他棘皮动物形成了鲜明对比,后者一般具有多达八个双子叶蛋白群。有趣的是,双鞭毛虫的视蛋白序列具有其他双脊类动物的横纹肌视蛋白的典型氨基酸残基,包括两个保守的半胱氨酸(C110、C187)、可能的祖先 E181 反离子、NPxxY(x)6F 模式、可能与发色团共价结合的高度保守的赖氨酸以及 (D)RY 模式,所有这些都支持光感受功能。最后,针对海星蛋白设计的新生成抗体的免疫反应在与花萼和羽片的伏沟相关的几个组织中得到了强调。在这些组织中,阿比夫蛋白(可能是阿比夫蛋白 4.1)在外骨骼基底神经丛和下骨神经丛中表达。另一方面,在管足的感觉乳头中也表达了一种不同类型的光学蛋白(可能是阿比夫光学蛋白 4.2)。在不同的感觉结构中至少存在两种类型的视蛋白,这表明该棘皮动物存在一个完全基于横纹肌视蛋白的复杂的眼外光感知系统。
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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