Strain variations in cone wavelength peaks in situ during zebrafish development

IF 1.1 4区医学 Q4 NEUROSCIENCES Visual Neuroscience Pub Date : 2019-07-30 DOI:10.1017/S0952523819000075

R. Nelson, Annika Balraj, Tara Suresh, M. Torvund, Sara S. Patterson

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引用次数: 6

Abstract

Abstract There are four cone morphologies in zebrafish, corresponding to UV (U), blue (B), green (G), and red (R)-sensing types; yet genetically, eight cone opsins are expressed. How eight opsins are physiologically siloed in four cone types is not well understood, and in larvae, cone physiological spectral peaks are unstudied. We use a spectral model to infer cone wavelength peaks, semisaturation irradiances, and saturation amplitudes from electroretinogram (ERG) datasets composed of multi-wavelength, multi-irradiance, aspartate-isolated, cone-PIII signals, as compiled from many 5- to 12-day larvae and 8- to 18-month-old adult eyes isolated from wild-type (WT) or roy orbison (roy) strains. Analysis suggests (in nm) a seven-cone, U-360/B1-427/B2-440/G1-460/G3-476/R1-575/R2-556, spectral physiology in WT larvae but a six-cone, U-349/B1-414/G3-483/G4-495/R1-572/R2-556, structure in WT adults. In roy larvae, there is a five-cone structure: U-373/B2-440/G1-460/R1-575/R2-556; in roy adults, there is a four-cone structure, B1-410/G3-482/R1-571/R2-556. Existence of multiple B, G, and R types is inferred from shifts in peaks with red or blue backgrounds. Cones were either high or low semisaturation types. The more sensitive, low semisaturation types included U, B1, and G1 cones [3.0–3.6 log(quanta·μm−2·s−1)]. The less sensitive, high semisaturation types were B2, G3, G4, R1, and R2 types [4.3-4.7 log(quanta·μm−2·s−1)]. In both WT and roy, U- and B- cone saturation amplitudes were greater in larvae than in adults, while G-cone saturation levels were greater in adults. R-cone saturation amplitudes were the largest (50–60% of maximal dataset amplitudes) and constant throughout development. WT and roy larvae differed in cone signal levels, with lesser UV- and greater G-cone amplitudes occurring in roy, indicating strain variation in physiological development of cone signals. These physiological measures of cone types suggest chromatic processing in zebrafish involves at least four to seven spectral signal processing pools.

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斑马鱼发育过程中锥体波长峰值的应变变化

斑马鱼有四种视锥细胞形态，分别为紫外(U)、蓝色(B)、绿色(G)和红色(R)感应类型;然而基因上，8种视锥蛋白被表达。八种视蛋白在四种视锥类型中是如何在生理上隔离的尚不清楚，而在幼虫中，视锥生理光谱峰也未被研究。我们使用光谱模型从视网膜电图(ERG)数据集中推断出锥体波长峰值、半饱和辐照度和饱和振幅，这些数据集由多波长、多辐照度、天冬氨酸分离、锥体piii信号组成，这些数据集来自野生型(WT)或罗伊氏(roy)菌株分离的5至12天的幼虫和8至18个月大的成人眼睛。分析表明，WT幼虫的光谱生理结构为7锥体U-360/B1-427/B2-440/G1-460/G3-476/R1-575/R2-556，成虫的光谱生理结构为6锥体U-349/B1-414/G3-483/G4-495/R1-572/R2-556。幼虫呈五锥体结构:U-373/B2-440/G1-460/R1-575/R2-556;成虫有四锥体结构，B1-410/G3-482/R1-571/R2-556。多个B、G和R类型的存在是由红色或蓝色背景的峰的移位推断出来的。球果有高半饱和型和低半饱和型。较敏感、半饱和度较低的类型包括U、B1和G1锥[3.0-3.6 log(量子·μm−2·s−1)]。敏感度较低、半饱和度较高的类型为B2、G3、G4、R1和R2 [4.3-4.7 log(量子·μm−2·s−1)]。幼鱼的U-和B-锥体饱和度高于成虫，而g -锥体饱和度高于成虫。r -锥饱和度振幅是最大的(最大数据集振幅的50-60%)，并且在整个开发过程中保持不变。褐家蚕和黄家蚕幼虫在锥体信号水平上存在差异，黄家蚕的UV-振幅较小，g -锥体振幅较大，说明不同品系在锥体信号生理发育上存在差异。这些视锥类型的生理测量表明，斑马鱼的色彩处理至少涉及4到7个光谱信号处理池。

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来源期刊

Visual Neuroscience 医学-神经科学

CiteScore

2.20

自引率

5.30%

发文量

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.