Department of Chemical Physiology & Biochemistry, Oregon Health & Science University, Portland, OR, 97239, USA.
Bachelor of Science in Neuroscience Program (Honours), University of Calgary , Canada.
Exp Eye Res. 2020 Jun;195:108026. doi: 10.1016/j.exer.2020.108026. Epub 2020 Apr 1.
Adaptation to changes in ambient light intensity, in retinal cells and circuits, optimizes visual functions. In the retina, light-adaptation results in changes in light-sensitivity and spatiotemporal tuning of ganglion cells. Under light-adapted conditions, contrast sensitivity (CS) of ganglion cells is a bandpass function of spatial frequency; in contrast, dark-adaptation reduces CS, especially at higher spatial frequencies. In this work, we aimed to understand intrinsic neuromodulatory mechanisms that underlie retinal adaptation to changes in ambient light level. Specifically, we investigated how CS is affected by dopamine (DA), nitric oxide (NO), and modifiers of electrical coupling through gap junctions, under different conditions of adapting illumination. Using the optokinetic response as a behavioral readout of direction-selective ganglion cell activity, we characterized the spatial CS of chicks under high- and low-photopic conditions and how it was regulated by DA, NO, and gap-junction uncouplers. We observed that: (1) DA D2R-family agonists and a donor of NO increased CS tested in low-photopic illumination, as if observed in the high-photopic light; whereas (2) removing their effects using either DA antagonists or NO- synthase inhibitors mimicked low-photopic CS; (3) simulation of high-photopic CS by DA agonists was abolished by NO-synthase inhibitors; and (4) selectively blocking coupling via connexin 35/36-containing gap junctions, using a "designer" mimetic peptide, increased CS, as does strong illumination. We conclude that, in the chicken retina: (1) DA and NO induce changes in spatiotemporal processing, similar to those driven by increasing illumination, (2) DA possibly acts through stimulating NO synthesis, and (3) blockade of coupling via gap junctions containing connexin 35/36 also drives a change in retinal CS functions. As a noninvasive method, the optokinetic response can provide rapid, conditional, and reversible assessment of retinal functions when pharmacological reagents are injected into the vitreous humor. Finally, the chick's large eyes, and the many similarities between their adaptational circuit functions and those in mammals such as the mouse, make them a promising model for future retinal research.
适应环境光强的变化,在视网膜细胞和回路中,优化了视觉功能。在视网膜中,光适应导致光敏感度和神经节细胞的时空调谐的变化。在光适应条件下,神经节细胞的对比敏感度 (CS) 是空间频率的带通函数;相比之下,暗适应降低 CS,尤其是在较高的空间频率下。在这项工作中,我们旨在了解内在的神经调制机制,这些机制是视网膜适应环境光水平变化的基础。具体来说,我们研究了多巴胺 (DA)、一氧化氮 (NO) 以及通过缝隙连接改变电耦合的调节剂在不同适应光照条件下如何影响 CS。我们使用光动反应作为方向选择性神经节细胞活动的行为读出,我们描述了小鸡在高光和低光条件下的空间 CS 以及 DA、NO 和缝隙连接解耦剂如何调节它。我们观察到:(1)DA D2R 家族激动剂和 NO 的供体增加了在低光条件下测试的 CS,就像在高光条件下观察到的那样;而 (2) 使用 DA 拮抗剂或 NO 合酶抑制剂去除它们的作用模拟了低光 CS;(3)NO 合酶抑制剂消除了 DA 激动剂模拟高光 CS 的作用;(4) 使用一种“设计”模拟肽选择性阻断通过含有连接蛋白 35/36 的缝隙连接的耦合,增加了 CS,就像强光照一样。我们得出结论,在鸡视网膜中:(1)DA 和 NO 诱导时空处理的变化,类似于由增加光照引起的变化;(2)DA 可能通过刺激 NO 合成起作用;(3)通过含有连接蛋白 35/36 的缝隙连接阻断耦合也会改变视网膜 CS 功能。作为一种非侵入性方法,光动反应可以在向玻璃体中注射药理试剂时提供快速、条件和可逆的视网膜功能评估。最后,小鸡的大眼睛,以及它们的适应电路功能与老鼠等哺乳动物之间的许多相似之处,使它们成为未来视网膜研究的有前途的模型。
