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丛猴P和M视网膜神经节细胞的形态学

Morphology of P and M retinal ganglion cells of the bush baby.

作者信息

Yamada E S, Marshak D W, Silveira L C, Casagrande V A

机构信息

Department of Neurobiology and Anatomy, University of Texas Medical School, Houston 77225, USA.

出版信息

Vision Res. 1998 Nov;38(21):3345-52. doi: 10.1016/s0042-6989(97)00412-4.

DOI:10.1016/s0042-6989(97)00412-4
PMID:9893847
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3341668/
Abstract

P/midget ganglion cells mediate red-green color opponency in anthropoids. It has been proposed that these cells evolved as a specialization to subserve color vision in primates. If that is correct, they must have evolved about the same time as the long-wavelength ('red') and medium-wavelength ('green') pigment genes diverged, thirty million years ago. Strepsirhines are another group of primates that diverged from the ancestor of the anthropoids at least 55 million years ago. If P/midget ganglion cells evolved to subserve color vision, they should be absent in strepsirhines. We tested this hypothesis in a nocturnal strepsirhine, the greater bush baby Otolemur. The retinal ganglion cells were labeled with the lipophilic tracer Dil and the results show that bush babies have P/midget and M/parasol cells similar to those found in the peripheral retinas of anthropoids. A number of studies have shown that the P and M pathways of bush babies share many similarities with those of anthropoids, and our results show that the same is true for their retinal ganglion cells. These results support the hypothesis that the P system evolved prior to the emergence of red-green color opponency.

摘要

P/侏儒神经节细胞介导类人猿的红绿色拮抗。有人提出,这些细胞是作为一种特化进化而来,以服务于灵长类动物的色觉。如果这是正确的,它们一定是在三千万年前长波长(“红色”)和中波长(“绿色”)色素基因分化的同时进化而来的。原猴亚目动物是另一类灵长类动物,它们至少在五千五百万年前就从类人猿的祖先中分化出来了。如果P/侏儒神经节细胞进化是为了服务于色觉,那么在原猴亚目动物中应该不存在。我们在一种夜行性原猴亚目动物——大林跳鼠(Otolemur)身上检验了这一假设。视网膜神经节细胞用亲脂性示踪剂Dil进行标记,结果表明大林跳鼠具有与类人猿外周视网膜中发现的类似的P/侏儒细胞和M/伞状细胞。许多研究表明,大林跳鼠的P和M通路与类人猿的有许多相似之处,我们的结果表明它们的视网膜神经节细胞也是如此。这些结果支持了P系统在红绿色拮抗出现之前就已进化的假设。

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