Koester S E, O'Leary D D
Molecular Neurobiology Laboratory, Salk Institute, La Jolla, California 92037.
Dev Biol. 1993 Nov;160(1):1-14. doi: 10.1006/dbio.1993.1281.
In adult rats, layer 5 cortical neurons send axons through the corpus callosum to contralateral cortex or through the internal capsule to subcortical targets, but individual neurons reportedly do not have both connections. Here we confirm this adult separation and address whether it develops by extension of axon collaterals to both sets of targets with later elimination of one or the other (a phenomenon common in developing cortex) or by initially selective axon outgrowth. Retrograde tracers Fast Blue and Diamidino Yellow were injected in the subcortical path at the pyramidal decussation and in the contralateral cortex, respectively, of adult and newborn rats. In 16 adults, no cortical neurons were double-labeled, indicating that none project to both sites. In 17 neonates, hundreds of thousands of layer 5 neurons were single-labeled in each brain, but only one was double-labeled. In cases in which the injections to one of the two targets was delayed, again, no double-labeled cells were found. These results indicate that the connectional distinction found in adults is not achieved by the elimination of long transient callosal or subcortical collaterals. To determine if shorter transient collaterals are extended by callosal neurons into the internal capsule, i.e., the subcortical pathway, we injected DiI into one cortical hemisphere of aldehyde-fixed Embryonic Day (E)19 and E21 brains. Two types of axons are seen in the white matter of the cortex opposite the injection: those which turn and extend through the callosum and those which branch, sending collaterals to both ipsilateral and contralateral cortex. Rarely were collaterals seen to extend into or toward the internal capsule. [3H]Thymidine birthdating studies show that layer 5 callosal and subcortically projecting neurons are generated at the same stage of corticogenesis. Thus, from early stages of axon extension, callosal and subcortically projecting cells are distinct classes of neurons and, responding differentially to cues present in cortex, initiate growth toward class-specific and nonoverlapping sets of targets. We conclude that the distinction between the two projection classes in inherent to them and is likely to be determined at an early stage of cortical development, prior to neuronal migration from the neuroepithelium.
在成年大鼠中,第5层皮质神经元发出的轴突通过胼胝体到达对侧皮质,或通过内囊到达皮质下靶点,但据报道单个神经元并不具有这两种连接。在这里,我们证实了这种成年期的分离现象,并探讨其是通过轴突分支延伸至两组靶点随后消除其中一组(这是发育中的皮质常见的现象),还是通过最初的选择性轴突生长而形成的。分别将逆行示踪剂快蓝和双脒基黄注入成年和新生大鼠锥体交叉处的皮质下路径及对侧皮质。在16只成年大鼠中,没有皮质神经元被双重标记,这表明没有神经元同时投射到两个部位。在17只新生大鼠中,每只大脑中都有数十万个第5层神经元被单标记,但只有1个被双重标记。在对两个靶点之一的注射延迟的情况下,同样未发现双重标记的细胞。这些结果表明,成年大鼠中发现的连接差异并非通过消除长时存在的胼胝体或皮质下侧支来实现。为了确定胼胝体神经元是否会将较短的瞬时侧支延伸至内囊,即皮质下通路,我们将碘化丙啶注入醛固定的胚胎第19天(E19)和第21天(E21)大鼠的一个皮质半球。在注射对侧的皮质白质中可见两种类型的轴突:一种转向并通过胼胝体延伸,另一种分支并向同侧和对侧皮质发送侧支。很少见到侧支延伸至内囊或向内囊方向延伸。[³H]胸腺嘧啶核苷出生时间标记研究表明,第5层胼胝体投射神经元和皮质下投射神经元在皮质发生的同一阶段产生。因此,从轴突延伸的早期阶段起,胼胝体投射细胞和皮质下投射细胞就是不同类别的神经元,它们对皮质中存在的信号作出不同反应,朝着特定类别的、不重叠的靶点集开始生长。我们得出结论,这两种投射类别的差异是其固有的,很可能在神经元从神经上皮迁移之前的皮质发育早期就已确定。
