Shanks James A, Ito Shinya, Schaevitz Laura, Yamada Jena, Chen Bin, Litke Alan, Feldheim David A
Department of Molecular, Cell, and Developmental Biology, University of California, Santa Cruz, California 95064.
Santa Cruz Institute for Particle Physics, University of California, Santa Cruz, Santa Cruz, California 95064, and.
J Neurosci. 2016 May 11;36(19):5252-63. doi: 10.1523/JNEUROSCI.4599-15.2016.
Retinal ganglion cells (RGCs) relay information about the outside world to multiple subcortical targets within the brain. This information is either used to dictate reflexive behaviors or relayed to the visual cortex for further processing. Many subcortical visual nuclei also receive descending inputs from projection neurons in the visual cortex. Most areas receive inputs from layer 5 cortical neurons in the visual cortex but one exception is the dorsal lateral geniculate nucleus (dLGN), which receives layer 6 inputs and is also the only RGC target that sends direct projections to the cortex. Here we ask how visual system development and function changes in mice that develop without a cortex. We find that the development of a cortex is essential for RGC axons to terminate in the dLGN, but is not required for targeting RGC axons to other subcortical nuclei. RGC axons also fail to target to the dLGN in mice that specifically lack cortical layer 6 projections to the dLGN. Finally, we show that when mice develop without a cortex they can still perform a number of vision-dependent tasks.
The dorsal lateral geniculate nucleus (dLGN) is a sensory thalamic relay area that receives feedforward inputs from retinal ganglion cells (RGCs) in the retina, and feed back inputs from layer 6 neurons in the visual cortex. In this study we examined genetically manipulated mice that develop without a cortex or without cortical layer 6 axonal projections, and find that RGC axons fail to project to the dLGN. Other RGC recipient areas, such as the superior colliculus and suprachiasmatic nucleus, are targeted normally. These results provide support for a new mechanism of target selection that may be specific to the thalamus, whereby descending cortical axons provide an activity that promotes feedforward targeting of RGC axons to the dLGN.
视网膜神经节细胞(RGCs)将有关外界的信息传递至脑内多个皮质下靶点。这些信息要么用于支配反射行为,要么被传递至视觉皮层进行进一步处理。许多皮质下视觉核团还接收来自视觉皮层投射神经元的下行输入。大多数区域接收来自视觉皮层第5层皮质神经元的输入,但背外侧膝状体核(dLGN)是个例外,它接收第6层的输入,也是唯一向皮层发送直接投射的RGC靶点。在此,我们探究在没有皮层的情况下发育的小鼠,其视觉系统的发育和功能会如何变化。我们发现,皮层的发育对于RGC轴突在dLGN中终止至关重要,但对于将RGC轴突靶向其他皮质下核团并非必需。在特异性缺乏向dLGN投射的皮质第6层的小鼠中,RGC轴突也无法靶向dLGN。最后,我们表明,在没有皮层的情况下发育的小鼠仍然能够执行一些依赖视觉的任务。
背外侧膝状体核(dLGN)是一个感觉丘脑中继区域,接收来自视网膜中视网膜神经节细胞(RGCs)的前馈输入,以及来自视觉皮层第6层神经元的反馈输入。在本研究中,我们检查了在没有皮层或没有皮质第6层轴突投射的情况下发育的基因操作小鼠,发现RGC轴突无法投射到dLGN。其他RGC接受区域,如中脑上丘和视交叉上核,靶向正常。这些结果为一种可能特定于丘脑的新的靶点选择机制提供了支持,即下行皮质轴突提供一种促进RGC轴突向前馈靶向dLGN的活动。