过度表达金属稳态基因的表型和分子后果。
Phenotypic and molecular consequences of overexpression of metal-homeostasis genes.
机构信息
Faculty of Biology, Institute of Experimental Plant Biology and Biotechnology, University of Warsaw Warszawa, Poland.
出版信息
Front Plant Sci. 2014 Mar 7;5:80. doi: 10.3389/fpls.2014.00080. eCollection 2014.
Abstract
Metal hyperaccumulating plants are able to store very large amounts of metals in their shoots. There are a number of reasons why it is important to be able to introduce metal hyperaccumulation traits into non-accumulating species (e.g., phytoremediation or biofortification in minerals) and to engineer a desired level of accumulation and distribution of metals. Metal homeostasis genes have therefore been used for these purposes. Engineered accumulation levels, however, have often been far from expected, and transgenic plants frequently display phenotypic features not related to the physiological function of the introduced gene. In this review, we focus on an aspect often neglected in research on plants expressing metal homeostasis genes: the specific regulation of endogenous metal homeostasis genes of the host plant in response to the transgene-induced imbalance of the metal status. These modifications constitute one of the major mechanisms involved in the generation of the plant's phenotype, including unexpected characteristics. Interestingly, activation of so-called "metal cross-homeostasis" has emerged as a factor of primary importance.
摘要
金属超积累植物能够在其茎叶中储存大量的金属。有许多原因使得能够将金属超积累特性引入非积累物种(例如,在矿物质中的植物修复或生物强化)并设计期望的金属积累和分布水平变得非常重要。因此,金属稳态基因被用于这些目的。然而,工程设计的积累水平往往远低于预期,并且转基因植物经常表现出与引入基因的生理功能无关的表型特征。在这篇综述中,我们关注的是在表达金属稳态基因的植物研究中经常被忽视的一个方面:宿主植物的内源性金属稳态基因在应对转基因诱导的金属状态失衡时的特异性调节。这些修饰构成了产生植物表型的主要机制之一,包括意外的特征。有趣的是,所谓的“金属交叉稳态”的激活已成为一个首要的重要因素。
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