Department of Neurobiology and Anatomy, Neuroscience Graduate Program, and Center for Neuroscience, West Virginia University School of Medicine, Morgantown, West Virginia 26506, and.
Department of Pharmacology and Physiology, The George Washington University Medical Center, Washington, DC 20037.
J Neurosci. 2014 Jun 4;34(23):7787-801. doi: 10.1523/JNEUROSCI.4695-13.2014.
Proper assembly of cortical circuitry relies on the correct migration of cortical interneurons from their place of birth in the ganglionic eminences to their place of terminal differentiation in the cerebral cortex. Although molecular mechanisms mediating cortical interneuron migration have been well studied, intracellular signals directing their migration are largely unknown. Here we illustrate a novel and essential role for c-Jun N-terminal kinase (JNK) signaling in guiding the pioneering population of cortical interneurons into the mouse cerebral cortex. Migrating cortical interneurons express Jnk proteins at the entrance to the cortical rudiment and have enriched expression of Jnk1 relative to noninterneuronal cortical cells. Pharmacological blockade of JNK signaling in ex vivo slice cultures resulted in dose-dependent and highly specific disruption of interneuron migration into the nascent cortex. Time-lapse imaging revealed that JNK-inhibited cortical interneurons advanced slowly and assumed aberrant migratory trajectories while traversing the cortical entry zone. In vivo analyses of JNK-deficient embryos supported our ex vivo pharmacological data. Deficits in interneuron migration were observed in Jnk1 but not Jnk2 single nulls, and those migratory deficits were further exacerbated when homozygous loss of Jnk1 was combined with heterozygous reduction of Jnk2. Finally, genetic ablation of Jnk1 and Jnk2 from cortical interneurons significantly perturbed migration in vivo, but not in vitro, suggesting JNK activity functions to direct their guidance rather than enhance their motility. These data suggest JNK signaling, predominantly mediated by interneuron expressed Jnk1, is required for guiding migration of cortical interneurons into and within the developing cerebral cortex.
皮质回路的正确组装依赖于皮质中间神经元从它们在神经节隆起的出生地迁移到它们在大脑皮层的终末分化地。尽管调节皮质中间神经元迁移的分子机制已经得到了很好的研究,但指导它们迁移的细胞内信号在很大程度上是未知的。在这里,我们展示了 c-Jun N-末端激酶(JNK)信号在引导皮质中间神经元进入小鼠大脑皮层的先驱群体中的新的和基本作用。迁移的皮质中间神经元在皮质原基的入口处表达 Jnk 蛋白,并且相对于非中间神经元皮质细胞,Jnk1 的表达丰富。在离体切片培养物中,JNK 信号的药理学阻断导致中间神经元向新生皮质迁移的剂量依赖性和高度特异性破坏。延时成像显示,JNK 抑制的皮质中间神经元在穿过皮质进入区时缓慢前进,并呈现出异常的迁移轨迹。JNK 缺陷胚胎的体内分析支持了我们的离体药理学数据。在 Jnk1 但不是 Jnk2 单突变体中观察到中间神经元迁移缺陷,并且当 Jnk1 的纯合缺失与 Jnk2 的杂合减少相结合时,这些迁移缺陷进一步加剧。最后,从皮质中间神经元中遗传消融 Jnk1 和 Jnk2 显著扰乱了体内迁移,但在体外没有,这表明 JNK 活性的功能是指导它们的导向而不是增强它们的迁移性。这些数据表明,JNK 信号主要由中间神经元表达的 Jnk1 介导,是引导皮质中间神经元进入和在发育中的大脑皮层内迁移所必需的。