Morphogenesis of Drosophila melanogaster macrochaetes: cell fate determination for bristle organ.

Q4 Biochemistry, Genetics and Molecular Biology
Journal of Stem Cells Pub Date : 2012-01-01
D P Furman, T A Bukharina
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引用次数: 0

Abstract

Formation of specialized spatial structures comprising various cell types is most important in the ontogenesis of multicellular organisms. An example is the D. melanogaster bristle organs. Bristles (micro- and macrochaetes) are external sensory organs, elements of the peripheral nervous system, playing the role of mechanoreceptors. Their comparatively simple organization comprising only four specialized cells and a common origin of these cells make macrochaetes a convenient model for studying cell differentiation. The four cells forming bristle organ result from two successive divisions of a single cell, sensory organ precursor (SOP) cell. The number of macrochaetes on drosophila body corresponds to the number of SOP cells. The morphogenesis of macrochaetes comprises three stages, the first two determining a neural fate of the cells. The third stage is cell specialization into components of the bristle organ-neuron, thecogen, tormogen, and trichogen. Development of each bristle commences from segregation of proneural clusters, of 20-30 cells, from the massif of undifferentiated cells of the wing imaginal disc. At this stage, each cluster cell can potentially become a SOP cell. At the second stage, the only SOP cell and its position are determined within each cluster. Finally, two asymmetric divisions of the SOP cell with subsequent differentiation of the daughter cells gives the bristle organ. Several dozens genes are involved in the control of macrochaete morphogenesis. The main component of this system is the proneural genes of achaete-scute complex (AS-C). An increased content of proneural proteins fundamentally distinguished the cells that will follow the neural developmental pathway from the disc epidermal cells. A local AS-C expression, initiated at specified disc sites by specific transcription factors, determines the number and topology of proneural clusters. The expression of AS-C genes, continuing in the cells of the cluster, increases the difference in proneural protein content, first, between the cluster cells and then, between the cluster cells and the single SOP cell, where it reaches the maximum level. This process is provided by both the intracellular regulation of AS-C gene activity and intercellular events mediated via the EGFR and Notch signaling pathways. The third stage in macrochaete morphogenesis comprises two successive asymmetric SOP cell divisions, determining the final specialization. The selector genes, in particular, numb, neuralized, tramtrack, and musashi, play the key role in cell type specification. This review systematizes the data on molecular genetic system controlling drosophila bristle morphogenesis and proposes an integral scheme of its functioning.

黑腹大毛果蝇的形态发生:刚毛器官细胞命运的决定。
在多细胞生物的个体发生过程中,由各种细胞类型组成的特殊空间结构的形成是最重要的。一个例子是黑腹龙的刚毛器官。鬃毛(微毛和大毛)是外感觉器官,是外周神经系统的组成部分,起机械感受器的作用。它们相对简单的组织结构仅由四个特化细胞组成,并且这些细胞的共同起源使巨毛藻成为研究细胞分化的方便模型。形成刚毛器官的四个细胞是由一个感觉器官前体细胞(SOP)连续两次分裂而成的。果蝇体内巨毛藻的数量与SOP细胞的数量相对应。巨毛藻的形态发生包括三个阶段,前两个阶段决定细胞的神经命运。第三阶段是细胞分化为刚毛器官的组成部分——神经元、原体、原体和毛原。每根刚毛的发育开始于由20-30个细胞组成的前毛簇从翼象盘的未分化细胞团中分离出来。在这个阶段,每个集群单元都可能成为一个SOP单元。在第二阶段,在每个集群中确定唯一的SOP单元及其位置。最后,SOP细胞的两次不对称分裂和随后的子细胞分化形成刚毛器官。数十个基因参与了巨毛藻形态发生的控制。该系统的主要组成部分是无毛鳞片复合体(AS-C)的原基因。原膜蛋白含量的增加从根本上区分了将遵循神经发育途径的细胞与椎间盘表皮细胞。由特定转录因子在特定的盘状位点启动的局部AS-C表达决定了原膜簇的数量和拓扑结构。AS-C基因的表达,在集群细胞中持续,增加了细胞前蛋白含量的差异,首先是集群细胞之间的差异,然后是集群细胞与单个SOP细胞之间的差异,达到最大水平。这一过程由AS-C基因活性的细胞内调控和通过EGFR和Notch信号通路介导的细胞间事件提供。大毛纲形态发生的第三阶段包括两个连续的不对称SOP细胞分裂,决定了最终的特化。选择基因,特别是麻木基因、神经化基因、tramtrack基因和武藏基因,在细胞类型规范中起着关键作用。本文对控制果蝇刚毛形态发生的分子遗传系统进行了系统的综述,并提出了其功能的整体方案。
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
Journal of Stem Cells
Journal of Stem Cells Medicine-Transplantation
CiteScore
0.10
自引率
0.00%
发文量
1
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