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果蝇中枢神经系统中线细胞谱系的特化:背腹模式基因对单 minded 转录的直接调控

Specification of the Drosophila CNS midline cell lineage: direct control of single-minded transcription by dorsal/ventral patterning genes.

作者信息

Kasai Y, Stahl S, Crews S

机构信息

Department of Biochemistry and Biophysics, The University of North Carolina at Chapel Hill, 27599-7260, USA.

出版信息

Gene Expr. 1998;7(3):171-89.

PMID:9840810
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6151948/
Abstract

The Drosophila CNS consists of a bilaterally symmetric group of neurons separated by a discrete group of CNS midline cells. The specification of the CNS midline cell lineage requires transcription of the single-minded gene. Genetic evidence suggests that a group of transcription factors, including Dorsal, Snail, Twist, and Daughterless:: Scute, is required for initial single-minded transcription. Comparison of the DNA sequences of the single-minded gene regulatory regions between two Drosophila species reveals conserved sequence elements. Biochemical studies using purified proteins indicate that a number of these conserved sequences represent binding sites for Dorsal, Snail, and Twist. In vitro mutagenesis combined with germline transformation indicates that these binding sites are required in vivo for single-minded mesectodermal transcription. These results show that single-minded transcription and, thus, CNS midline specification is directly controlled by dorsal/ventral patterning transcription factors. They also suggest a model in which multiple transcriptional activators function in a cooperative, concentration-dependent mode in combination with a transcriptional repressor to restrict single-minded transcription to the CNS midline precursor cells.

摘要

果蝇中枢神经系统(CNS)由一组双侧对称的神经元组成,这些神经元被一组离散的中枢神经系统中线细胞分隔开。中枢神经系统中线细胞谱系的特化需要单-minded基因的转录。遗传学证据表明,包括背侧(Dorsal)、蜗牛(Snail)、扭曲(Twist)和无女儿:: 盾片(Daughterless::Scute)在内的一组转录因子是初始单-minded转录所必需的。对两种果蝇物种之间单-minded基因调控区域的DNA序列进行比较,发现了保守的序列元件。使用纯化蛋白进行的生化研究表明,这些保守序列中的许多代表了背侧、蜗牛和扭曲的结合位点。体外诱变结合种系转化表明,这些结合位点在体内对于单-minded中胚层转录是必需的。这些结果表明,单-minded转录以及中枢神经系统中线特化直接受背侧/腹侧模式转录因子的控制。它们还提出了一个模型,其中多种转录激活因子与转录抑制因子协同作用,以浓度依赖模式将单-minded转录限制在中枢神经系统中线前体细胞中。

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