A new role for excitation in the retinal direction-selective circuit

IF 4.7 2区 医学 Q1 NEUROSCIENCES
Lea Ankri, Serena Riccitelli, Michal Rivlin-Etzion
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引用次数: 0

Abstract

A key feature of the receptive field of neurons in the visual system is their centre–surround antagonism, whereby the centre and the surround exhibit responses of opposite polarity. This organization is thought to enhance visual acuity, but whether and how such antagonism plays a role in more complex processing remains poorly understood. Here, we investigate the role of centre and surround receptive fields in retinal direction selectivity by exposing posterior-preferring On–Off direction-selective ganglion cells (pDSGCs) to adaptive light and recording their response to globally moving objects. We reveal that light adaptation leads to surround expansion in pDSGCs. The pDSGCs maintain their original directional tuning in the centre receptive field, but present the oppositely tuned response in their surround. Notably, although inhibition is the main substrate for retinal direction selectivity, we found that following light adaptation, both the centre- and surround-mediated responses originate from directionally tuned excitatory inputs. Multi-electrode array recordings show similar oppositely tuned responses in other DSGC subtypes. Together, these data attribute a new role for excitation in the direction-selective circuit. This excitation carries an antagonistic centre–surround property, possibly designed to sharpen the detection of motion direction in the retina.

Key points

  • Receptive fields of direction-selective retinal ganglion cells expand asymmetrically following light adaptation.
  • The increase in the surround receptive field generates a delayed spiking phase that is tuned to the null direction and is mediated by excitation.
  • Following light adaptation, excitation rules the computation in the centre receptive field and is tuned to the preferred direction.
  • GABAergic and glycinergic inputs modulate the null-tuned delayed response differentially.
  • Null-tuned delayed spiking phases can be detected in all types of direction-selective retinal ganglion cells.
  • Light adaptation exposes a hidden directional excitation in the circuit, which is tuned to opposite directions in the centre and surround receptive fields.

Abstract Image

激发在视网膜方向选择电路中的新作用
视觉系统神经元感受野的一个主要特征是中心-周围拮抗,即中心和周围表现出极性相反的反应。这种组织结构被认为能提高视觉敏锐度,但这种拮抗作用是否以及如何在更复杂的处理过程中发挥作用,目前仍鲜为人知。在这里,我们通过将后向开-关方向选择性神经节细胞(pDSGCs)暴露于自适应光并记录它们对全局移动物体的反应,研究了中心和环绕感受野在视网膜方向选择性中的作用。我们发现,光适应会导致 pDSGCs 的环绕扩展。pDSGCs 在中心感受野中保持其原有的方向调谐,但在其周围却呈现出相反的调谐反应。值得注意的是,虽然抑制是视网膜方向选择性的主要基质,但我们发现在光适应后,中心和环绕介导的反应都源自方向调谐的兴奋输入。多电极阵列记录显示,其他 DSGC 亚型也有类似的相反调谐反应。这些数据共同表明,兴奋在方向选择电路中扮演着新的角色。这种兴奋具有中心-环绕拮抗特性,可能是为了增强视网膜对运动方向的检测。关键点:方向选择性视网膜神经节细胞的感受野在光照适应后不对称地扩大。环绕感受野的增加会产生一个延迟的尖峰阶段,该阶段被调谐到空方向,并由兴奋介导。光适应后,兴奋主导中心感受野的计算,并调谐到首选方向。GABA 能和甘氨酸能输入对空调谐延迟反应的调节是不同的。在所有类型的方向选择性视网膜神经节细胞中都能检测到空调谐延迟尖峰阶段。光适应暴露了电路中隐藏的方向性兴奋,它被调谐到中心和周围感受野的相反方向。
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
Journal of Physiology-London
Journal of Physiology-London 医学-神经科学
CiteScore
9.70
自引率
7.30%
发文量
817
审稿时长
2 months
期刊介绍: The Journal of Physiology publishes full-length original Research Papers and Techniques for Physiology, which are short papers aimed at disseminating new techniques for physiological research. Articles solicited by the Editorial Board include Perspectives, Symposium Reports and Topical Reviews, which highlight areas of special physiological interest. CrossTalk articles are short editorial-style invited articles framing a debate between experts in the field on controversial topics. Letters to the Editor and Journal Club articles are also published. All categories of papers are subjected to peer reivew. The Journal of Physiology welcomes submitted research papers in all areas of physiology. Authors should present original work that illustrates new physiological principles or mechanisms. Papers on work at the molecular level, at the level of the cell membrane, single cells, tissues or organs and on systems physiology are all acceptable. Theoretical papers and papers that use computational models to further our understanding of physiological processes will be considered if based on experimentally derived data and if the hypothesis advanced is directly amenable to experimental testing. While emphasis is on human and mammalian physiology, work on lower vertebrate or invertebrate preparations may be suitable if it furthers the understanding of the functioning of other organisms including mammals.
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