Enhancer of trithorax/polycomb, Corto, regulates timing of hunchback gene relocation and competence in Drosophila neuroblasts.

IF 2.5 3区生物学 Q1 DEVELOPMENTAL BIOLOGY

Neural Development Pub Date : 2022-02-17 DOI:10.1186/s13064-022-00159-3

Terry L Hafer, Sofiya Patra, Daiki Tagami, Minoree Kohwi

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引用次数: 1

Abstract

Background: Neural progenitors produce diverse cells in a stereotyped birth order, but can specify each cell type for only a limited duration. In the Drosophila embryo, neuroblasts (neural progenitors) specify multiple, distinct neurons by sequentially expressing a series of temporal identity transcription factors with each division. Hunchback (Hb), the first of the series, specifies early-born neuronal identity. Neuroblast competence to generate early-born neurons is terminated when the hb gene relocates to the neuroblast nuclear lamina, rendering it refractory to activation in descendent neurons. Mechanisms and trans-acting factors underlying this process are poorly understood. Here we identify Corto, an enhancer of Trithorax/Polycomb (ETP) protein, as a new regulator of neuroblast competence.

Methods: We used the GAL4/UAS system to drive persistent misexpression of Hb in neuroblast 7-1 (NB7-1), a model lineage for which the early competence window has been well characterized, to examine the role of Corto in neuroblast competence. We used immuno-DNA Fluorescence in situ hybridization (DNA FISH) in whole embryos to track the position of the hb gene locus specifically in neuroblasts across developmental time, comparing corto mutants to control embryos. Finally, we used immunostaining in whole embryos to examine Corto's role in repression of Hb and a known target gene, Abdominal B (Abd-B).

Results: We found that in corto mutants, the hb gene relocation to the neuroblast nuclear lamina is delayed and the early competence window is extended. The delay in gene relocation occurs after hb transcription is already terminated in the neuroblast and is not due to prolonged transcriptional activity. Further, we find that Corto genetically interacts with Posterior Sex Combs (Psc), a core subunit of polycomb group complex 1 (PRC1), to terminate early competence. Loss of Corto does not result in derepression of Hb or its Hox target, Abd-B, specifically in neuroblasts.

Conclusions: These results show that in neuroblasts, Corto genetically interacts with PRC1 to regulate timing of nuclear architecture reorganization and support the model that distinct mechanisms of silencing are implemented in a step-wise fashion during development to regulate cell fate gene expression in neuronal progeny.

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三胸/多梳增强子Corto调节果蝇神经母细胞驼背基因重新定位的时间和能力。

背景:神经祖细胞以刻板的出生顺序产生多种细胞，但只能在有限的时间内指定每种细胞类型。在果蝇胚胎中，神经母细胞(神经祖细胞)通过在每次分裂中依次表达一系列时间同一性转录因子来指定多个不同的神经元。驼背(Hb)是该系列的第一个，说明了早期出生的神经元身份。当hb基因迁移到成神经细胞核层时，神经母细胞产生早期神经元的能力被终止，使其难以在后代神经元中激活。这一过程背后的机制和作用因素尚不清楚。在这里，我们发现Corto是一种Trithorax/Polycomb (ETP)蛋白的增强剂，是一种新的神经母细胞能力调节剂。方法:我们使用GAL4/UAS系统驱动Hb在神经母细胞7-1 (NB7-1)中的持续错误表达，这是一个早期能力窗口已被很好地表征的模型谱系，以研究Corto在神经母细胞能力中的作用。我们在全胚胎中使用免疫-DNA荧光原位杂交(DNA FISH)来追踪hb基因位点在整个发育时间内特异性在神经母细胞中的位置，并将corto突变体与对照胚胎进行比较。最后，我们在全胚胎中使用免疫染色来检测Corto在抑制Hb和已知靶基因腹部B (Abd-B)中的作用。结果:我们发现在corto突变体中，hb基因向神经母细胞核层的迁移延迟，早期能力窗口延长。基因重新定位的延迟发生在hb转录在神经母细胞中已经终止之后，而不是由于转录活性的延长。此外，我们发现Corto基因与polycomb group complex 1 (PRC1)的核心亚基后性梳(Psc)相互作用，以终止早期能力。Corto的缺失不会导致Hb或其Hox靶点Abd-B的抑制，特别是在神经母细胞中。结论:这些结果表明，在神经母细胞中，Corto基因与PRC1基因相互作用以调节核结构重组的时间，并支持在发育过程中以分步方式实施不同的沉默机制以调节神经元后代细胞命运基因表达的模型。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Neural Development 生物-发育生物学

CiteScore

6.60

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Neural Development is a peer-reviewed open access, online journal, which features studies that use molecular, cellular, physiological or behavioral methods to provide novel insights into the mechanisms that underlie the formation of the nervous system. Neural Development aims to discover how the nervous system arises and acquires the abilities to sense the world and control adaptive motor output. The field includes analysis of how progenitor cells form a nervous system during embryogenesis, and how the initially formed neural circuits are shaped by experience during early postnatal life. Some studies use well-established, genetically accessible model systems, but valuable insights are also obtained from less traditional models that provide behavioral or evolutionary insights.