果蝇视神经叶神经元中的细胞迁移受无眼/Pax6 控制。
Cell migration in Drosophila optic lobe neurons is controlled by eyeless/Pax6.
机构信息
Center for Developmental Genetics, Department of Biology, New York University, 100 Washington Square East, New York, NY 10003, USA.
出版信息
Development. 2011 Feb;138(4):687-93. doi: 10.1242/dev.056069. Epub 2011 Jan 5.
Abstract
In the developing Drosophila optic lobe, eyeless, apterous and distal-less, three genes that encode transcription factors with important functions during development, are expressed in broad subsets of medulla neurons. Medulla cortex cells follow two patterns of cell movements to acquire their final position: first, neurons are arranged in columns below each neuroblast. Then, during pupation, they migrate laterally, intermingling with each other to reach their retinotopic position in the adult optic lobe. eyeless, which encodes a Pax6 transcription factor, is expressed early in progenitors and controls aspects of this cell migration. Its loss in medulla neurons leads to overgrowth and a failure of lateral migration during pupation. These defects in cell migration among medulla cortex cells can be rescued by removing DE-Cadherin. Thus, eyeless links neurogenesis and neuronal migration.
摘要
在发育中的果蝇视神经叶中,eyeless、apterous 和 distal-less 这三个基因编码在发育过程中具有重要功能的转录因子,它们在广泛的 medulla 神经元亚群中表达。medulla 皮质细胞通过两种细胞运动模式来获得最终位置:首先,神经元在每个神经母细胞下方排列成柱形。然后,在蛹化期间,它们横向迁移,相互混合以到达成年视神经叶中的视网膜位置。编码 Pax6 转录因子的 eyeless 基因在祖细胞中早期表达,并控制着这种细胞迁移的某些方面。在 medulla 神经元中缺失 eyeless 会导致过度生长和蛹化期间横向迁移失败。通过去除 DE-Cadherin 可以挽救 medulla 皮质细胞之间的细胞迁移缺陷。因此,eyeless 将神经发生和神经元迁移联系起来。
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