Martin William Battle, Scott Fraser Ewing, Cathryn Dickson, Joseph Obaje, Kristen N Edgeworth, Rebecca Bindbeutel, Rea L Antoniou-Kourounioti, Dmitri A Nusinow, Matthew Alan Jones
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引用次数: 0
摘要
植物利用表型可塑性使其生长和发育适应当前的环境条件。昼夜节律系统提供了时间背景,有助于解读光照和温度信号。表型可塑性在自然界中提供了选择性和竞争优势,但在大规模集约化农业实践中却会造成阻碍,因为经济上重要的性状(包括植株生长和开花时间)会因当地环境条件的不同而有很大差异。这妨碍了对收获时间的准确预测,并造成作物的多变性。我们试图通过控制植物对环境信号反应的信号系统来限制表型可塑性和昼夜节律调节。植物生长和发育的数学模型预测,当昼夜节律和光信号途径受到操纵时,植物对环境变化的反应会减弱。我们利用植物光感受器植物色素 B 的组成型活性等位基因,并通过突变早开花 3(EARLY FLOWERING3)来破坏昼夜节律系统,从而验证了这一假设。我们发现,通过这些操作培育出的植物对光照和温度线索的反应较弱,而且无法预知黎明的到来。这些经过改造的植物具有统一的无性生长和开花时间,证明了如何在保持植物生产力的同时限制表型的可塑性。这对未来露地和受控环境中的农业都有重大意义。
Manipulation of photosensory and circadian signaling restricts phenotypic plasticity in response to changing environmental conditions in Arabidopsis.
Plants exploit phenotypic plasticity to adapt their growth and development to prevailing environmental conditions. Interpretation of light and temperature signals is aided by the circadian system, which provides a temporal context. Phenotypic plasticity provides a selective and competitive advantage in nature but is obstructive during large-scale, intensive agricultural practices since economically important traits (including vegetative growth and flowering time) can vary widely depending on local environmental conditions. This prevents accurate prediction of harvesting times and produces a variable crop. In this study, we sought to restrict phenotypic plasticity and circadian regulation by manipulating signaling systems that govern plants' responses to environmental signals. Mathematical modeling of plant growth and development predicted reduced plant responses to changing environments when circadian and light signaling pathways were manipulated. We tested this prediction by utilizing a constitutively active allele of the plant photoreceptor phytochrome B, along with disruption of the circadian system via mutation of EARLY FLOWERING3. We found that these manipulations produced plants that are less responsive to light and temperature cues and thus fail to anticipate dawn. These engineered plants have uniform vegetative growth and flowering time, demonstrating how phenotypic plasticity can be limited while maintaining plant productivity. This has significant implications for future agriculture in both open fields and controlled environments.
期刊介绍:
Molecular Plant is dedicated to serving the plant science community by publishing novel and exciting findings with high significance in plant biology. The journal focuses broadly on cellular biology, physiology, biochemistry, molecular biology, genetics, development, plant-microbe interaction, genomics, bioinformatics, and molecular evolution.
Molecular Plant publishes original research articles, reviews, Correspondence, and Spotlights on the most important developments in plant biology.