19 Translational Control in Development

B. Thompson, M. Wickens, J. Kimble
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引用次数: 17

Abstract

Development requires the coordinated expression of selected genes at specific times and in specific cells. Such regulated expression controls the establishment of embryonic axes, the existence of stem cells, and the specification of individual cell fates. Translational control has a key role in this regulation. It is particularly important during early embryogenesis and in the germ line, where transcription is typically quiescent; there, control of translation and mRNA stability are the primary ways to regulate patterns of protein synthesis. Yet, translational regulation continues throughout development and in somatic tissues. In this chapter, we view translational control from a developmental perspective. We discuss four major interfaces at which developmental biology meets molecular regulatory mechanisms: molecular switches, gradients, combinatorial control, and networks. These areas were chosen because they bear on fundamental processes of development. We emphasize instances in which sequence-specific regulatory factors control particular mRNAs, and we do not cover the role of general translation factors (e.g., eIF4E and eIF2α) on growth and differentiation (Chapter 4). MECHANISMS OF TRANSLATIONAL CONTROL: A PRIMER Translation is a multistep process and can be divided into three phases: initiation, elongation, and termination. In principle, translational control can be exerted in any of these phases. We focus in this chapter on initiation, which appears to be the most common point of control during development. Translational initiation involves more than 20 proteins, multiple biochemical complexes, and a series of separable steps (Chapter 4). A complex containing eukaryotic initiation factor 4E (eIF4E) (cap-binding protein) and eIF4G is crucial. At...
19开发中的转化控制
发育需要在特定的时间和特定的细胞中协调表达选定的基因。这种受调控的表达控制着胚胎轴的建立、干细胞的存在和单个细胞命运的规范。翻译控制在这一调控中起着关键作用。它在早期胚胎发生和种系中尤其重要,在那里转录通常是静止的;在那里,控制翻译和mRNA的稳定性是调节蛋白质合成模式的主要途径。然而,翻译调控在整个发育过程和体细胞组织中持续进行。在本章中,我们从发展的角度来看待翻译控制。我们讨论了发育生物学与分子调控机制的四个主要接口:分子开关、梯度、组合控制和网络。选择这些领域是因为它们关系到发展的基本进程。我们强调序列特异性调控因子控制特定mrna的实例,并且我们没有涵盖一般翻译因子(例如,eIF4E和eIF2α)在生长和分化中的作用(第4章)。翻译控制机制:引物翻译是一个多步骤过程,可分为三个阶段:起始,延伸和终止。原则上,可以在这些阶段中的任何阶段施加平移控制。我们在这一章集中讨论起始,这似乎是开发过程中最常见的控制点。翻译起始涉及20多种蛋白质,多种生化复合物和一系列可分离的步骤(第4章)。含有真核起始因子4E(帽结合蛋白)和eIF4G的复合物至关重要。在…
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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