Kling A, Cooler S, Manookin M B, Rhoades C, Brackbill N, Field G, Rieke F, Sher A, Litke A, Chichilnisky E J
bioRxiv. 2024 Nov 1:2024.10.31.621339. doi: 10.1101/2024.10.31.621339.
The visual image transmitted by the retina to the brain has long been understood in terms of spatial filtering by the center-surround receptive fields of retinal ganglion cells (RGCs). Recently, this textbook view has been challenged by the stunning functional diversity and specificity observed in ∼40 distinct RGC types in the mouse retina. However, it is unclear whether the ∼20 morphologically and molecularly identified RGC types in primates exhibit similar functional diversity, or instead exhibit center-surround organization at different spatial scales. Here, we reveal striking and surprising functional diversity in macaque and human RGC types using large-scale multi-electrode recordings from isolated macaque and human retinas. In addition to the five well-known primate RGC types, 18-27 types were distinguished by their functional properties, likely revealing several previously unknown types. Surprisingly, many of these cell types exhibited striking non-classical receptive field structure, including irregular spatial and chromatic properties not previously reported in any species. Qualitatively similar results were observed in recordings from the human retina. The receptive fields of less-understood RGC types formed uniform mosaics covering visual space, confirming their classification, and the morphological counterparts of two types were established using single-cell recording. The striking receptive field diversity was paralleled by distinctive responses to natural movies and complexity of visual computation. These findings suggest that diverse RGC types, rather than merely filtering the scene at different spatial scales, instead play specialized roles in human vision.
视网膜向大脑传输的视觉图像长期以来一直是根据视网膜神经节细胞(RGC)中心-周边感受野的空间滤波来理解的。最近,这种教科书式的观点受到了挑战,因为在小鼠视网膜中观察到约40种不同的RGC类型具有惊人的功能多样性和特异性。然而,尚不清楚灵长类动物中约20种在形态和分子上已确定的RGC类型是否表现出类似的功能多样性,或者是否在不同空间尺度上表现出中心-周边组织。在这里,我们使用来自分离的猕猴和人类视网膜的大规模多电极记录,揭示了猕猴和人类RGC类型中惊人的功能多样性。除了五种众所周知的灵长类RGC类型外,还有18 - 27种类型根据其功能特性得以区分,这可能揭示了几种先前未知的类型。令人惊讶的是,这些细胞类型中的许多都表现出惊人的非经典感受野结构,包括以前在任何物种中都未报道过的不规则空间和颜色特性。在人类视网膜记录中观察到了定性相似的结果。对了解较少的RGC类型的感受野形成了覆盖视觉空间的均匀镶嵌,证实了它们的分类,并使用单细胞记录确定了两种类型的形态对应物。显著的感受野多样性与对自然电影的独特反应以及视觉计算的复杂性并行。这些发现表明,多种RGC类型并非仅仅在不同空间尺度上对场景进行滤波,而是在人类视觉中发挥着特殊作用。