Encephalopsin (OPN3) is required for normal refractive development and the GO/GROW response to induced myopia.

IF 1.8 3区医学 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY

Molecular Vision Pub Date : 2023-05-14 eCollection Date: 2023-01-01

Courtney Linne, Khine Yin Mon, Shane D'Souza, Heonuk Jeong, Xiaoyan Jiang, Dillon M Brown, Kevin Zhang, Shruti Vemaraju, Kazuo Tsubota, Toshihide Kurihara, Machelle T Pardue, Richard A Lang

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引用次数: 0

Abstract

Purpose: Myopia, or nearsightedness, is the most common form of refractive error and is increasing in prevalence. While significant efforts have been made to identify genetic variants that predispose individuals to myopia, these variants are believed to account for only a small portion of the myopia prevalence, leading to a feedback theory of emmetropization, which depends on the active perception of environmental visual cues. Consequently, there has been renewed interest in studying myopia in the context of light perception, beginning with the opsin family of G-protein coupled receptors (GPCRs). Refractive phenotypes have been characterized in every opsin signaling pathway studied, leaving only Opsin 3 (OPN3), the most widely expressed and blue-light sensing noncanonical opsin, to be investigated for function in the eye and refraction.

Methods: Opn3 expression was assessed in various ocular tissues using an Opn3eGFP reporter. Weekly refractive development in Opn3 retinal and germline mutants from 3 to 9 weeks of age was measured using an infrared photorefractor and spectral domain optical coherence tomography (SD-OCT). Susceptibility to lens-induced myopia was then assessed using skull-mounted goggles with a -30 diopter experimental and a 0 diopter control lens. Mouse eye biometry was similarly tracked from 3 to 6 weeks. A myopia gene expression signature was assessed 24 h after lens induction for germline mutants to further assess myopia-induced changes.

Results: Opn3 was found to be expressed in a subset of retinal ganglion cells and a limited number of choroidal cells. Based on an assessment of Opn3 mutants, the OPN3 germline, but not retina conditional Opn3 knockout, exhibits a refractive myopia phenotype, which manifests in decreased lens thickness, shallower aqueous compartment depth, and shorter axial length, atypical of traditional axial myopias. Despite the short axial length, Opn3 null eyes demonstrate normal axial elongation in response to myopia induction and mild changes in choroidal thinning and myopic shift, suggesting that susceptibility to lens-induced myopia is largely unchanged. Additionally, the Opn3 null retinal gene expression signature in response to induced myopia after 24 h is distinct, with opposing Ctgf, Cx43, and Egr1 polarity compared to controls.

Conclusions: The data suggest that an OPN3 expression domain outside the retina can control lens shape and thus the refractive performance of the eye. Prior to this study, the role of Opn3 in the eye had not been investigated. This work adds OPN3 to the list of opsin family GPCRs that are implicated in emmetropization and myopia. Further, the work to exclude retinal OPN3 as the contributing domain in this refractive phenotype is unique and suggests a distinct mechanism when compared to other opsins.

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脑视磷脂(OPN3)是正常屈光发育和GO/GROW对诱发性近视的反应所必需的。

目的:近视是最常见的屈光不正，并且发病率正在上升。虽然人们已经做出了巨大的努力来确定易患近视的遗传变异，但这些变异被认为只占近视患病率的一小部分，这导致了一种视瞳化的反馈理论，视瞳化依赖于对环境视觉线索的主动感知。因此，从g蛋白偶联受体(gpcr)的视蛋白家族开始，人们对在光感知的背景下研究近视重新产生了兴趣。屈光表型已经在研究的每个视蛋白信号通路中被表征，只留下opsin 3 (OPN3)，最广泛表达和蓝光感应的非规范视蛋白，在眼睛和折射中的功能有待研究。方法:利用Opn3eGFP报告基因检测Opn3在不同眼组织中的表达。使用红外折射仪和光谱域光学相干断层扫描(SD-OCT)测量3 - 9周龄的Opn3视网膜和种系突变体的每周屈光发育情况。然后使用颅骨护目镜，使用-30屈光度实验镜和0屈光度控制镜来评估对晶状体诱发性近视的易感性。从3到6周，对小鼠的眼睛生物测量进行类似的跟踪。在晶状体诱导后24小时评估种系突变体的近视基因表达特征，以进一步评估近视引起的变化。结果:Opn3在一部分视网膜神经节细胞和有限数量的脉络膜细胞中表达。基于对Opn3突变体的评估，Opn3种系，而不是视网膜条件Opn3基因敲除，表现为屈光性近视表型，表现为晶状体厚度减少，水隔深度变浅，眼轴长度变短，不典型的传统轴性近视。尽管眼轴长度较短，但Opn3缺失眼在诱导近视时表现出正常的眼轴伸长，脉络膜变薄和近视移位发生轻微变化，表明对晶状体诱导近视的易感性基本不变。此外，24 h后诱发性近视的Opn3空视网膜基因表达特征是明显的，与对照组相比，具有相反的Ctgf, Cx43和Egr1极性。结论:这些数据表明，视网膜外的OPN3表达域可以控制晶状体形状，从而控制眼睛的屈光性能。在这项研究之前，没有研究Opn3在眼睛中的作用。这项工作将OPN3添加到与近视和近视有关的视蛋白家族gpcr列表中。此外，排除视网膜OPN3作为这种屈光表型的贡献域的工作是独特的，与其他视蛋白相比，它表明了一种独特的机制。

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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来源期刊

Molecular Vision 生物-生化与分子生物学

CiteScore

4.40

自引率

0.00%

发文量

审稿时长

1 months

期刊介绍： Molecular Vision is a peer-reviewed journal dedicated to the dissemination of research results in molecular biology, cell biology, and the genetics of the visual system (ocular and cortical). Molecular Vision publishes articles presenting original research that has not previously been published and comprehensive articles reviewing the current status of a particular field or topic. Submissions to Molecular Vision are subjected to rigorous peer review. Molecular Vision does NOT publish preprints. For authors, Molecular Vision provides a rapid means of communicating important results. Access to Molecular Vision is free and unrestricted, allowing the widest possible audience for your article. Digital publishing allows you to use color images freely (and without fees). Additionally, you may publish animations, sounds, or other supplementary information that clarifies or supports your article. Each of the authors of an article may also list an electronic mail address (which will be updated upon request) to give interested readers easy access to authors.