Using Native and Synthetic Genes to Disrupt Inositol Pyrophosphates and Phosphate Accumulation in Plants.

IF 6.5 1区 生物学 Q1 PLANT SCIENCES
Catherine Freed, Branch Craige, Janet Donahue, Caitlin Cridland, Sarah Phoebe Williams, Chris Pereira, Jiwoo Kim, Hannah Blice, James Owen, Glenda Gillaspy
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Abstract

Inositol pyrophosphates are eukaryotic signaling molecules that have been recently identified as key regulators of plant phosphate sensing and homeostasis. Given the importance of phosphate to current and future agronomic practices, we sought to design plants which could be used to sequester phosphate, as a step in a phytoremediation strategy. To achieve this, we expressed Diadenosine and Diphosphoinositol Polyphosphate Phosphohydrolase (DDP1), a yeast (Saccharomyces cerevisiae) enzyme demonstrated to hydrolyze inositol pyrophosphates, in Arabidopsis thaliana and pennycress (Thlaspi arvense), a spring annual cover crop with emerging importance as a biofuel crop. DDP1 expression in Arabidopsis decreased inositol pyrophosphates, activated Phosphate Starvation Response marker genes, and increased phosphate accumulation. These changes corresponded with alterations in plant growth and sensitivity to exogenously applied phosphate. Pennycress plants expressing DDP1 displayed increases in phosphate accumulation, suggesting that these plants could potentially serve to reclaim phosphate from phosphate-polluted soils. We also identified a native Arabidopsis gene, Nucleoside diphosphate-linked moiety X 13 (NUDIX13), which we show encodes an enzyme homologous to DDP1 with similar substrate specificity. Arabidopsis transgenics overexpressing NUDIX13 had lower inositol pyrophosphate levels and displayed phenotypes similar to DDP1-overexpressing transgenics, while nudix13-1 mutants had increased levels of inositol pyrophosphates. Taken together, our data demonstrates that DDP1 and NUDIX13 can be used in strategies to regulate plant inositol pyrophosphates and could serve as potential targets for engineering plants to reclaim phosphate from polluted environments.

利用原生基因和合成基因破坏植物体内的肌醇焦磷酸盐和磷酸盐积累。
肌醇焦磷酸盐是真核生物的信号分子,最近被确认为植物磷酸盐感应和平衡的关键调节因子。鉴于磷酸盐对当前和未来农艺实践的重要性,我们试图设计出可用于螯合磷酸盐的植物,作为植物修复战略的一个步骤。为此,我们在拟南芥和菥蓂(Thlaspi arvense)中表达了二腺苷和二磷酸肌醇多磷酸酯磷酸水解酶(DDP1),这是一种酵母(Saccharomyces cerevisiae)酶,被证明能水解肌醇焦磷酸盐。拟南芥中 DDP1 的表达减少了肌醇焦磷酸盐,激活了磷酸盐饥饿反应标记基因,增加了磷酸盐积累。这些变化与植物生长和对外源磷酸盐敏感性的改变相对应。表达 DDP1 的竹篙草植物显示出磷酸盐积累的增加,这表明这些植物有可能从磷酸盐污染的土壤中回收磷酸盐。我们还发现了拟南芥的一个本地基因--核苷二磷酸连接分子 X 13(NUDIX13),该基因编码一种与 DDP1 同源的酶,具有类似的底物特异性。过表达 NUDIX13 的拟南芥转基因植物的肌醇焦磷酸水平较低,表现出与过表达 DDP1 的转基因植物相似的表型,而 nudix13-1 突变体的肌醇焦磷酸水平则有所提高。综上所述,我们的数据表明,DDP1和NUDIX13可用于植物肌醇焦磷酸盐的调控策略,并可作为工程植物从污染环境中回收磷酸盐的潜在靶标。
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来源期刊
Plant Physiology
Plant Physiology 生物-植物科学
CiteScore
12.20
自引率
5.40%
发文量
535
审稿时长
2.3 months
期刊介绍: Plant Physiology® is a distinguished and highly respected journal with a rich history dating back to its establishment in 1926. It stands as a leading international publication in the field of plant biology, covering a comprehensive range of topics from the molecular and structural aspects of plant life to systems biology and ecophysiology. Recognized as the most highly cited journal in plant sciences, Plant Physiology® is a testament to its commitment to excellence and the dissemination of groundbreaking research. As the official publication of the American Society of Plant Biologists, Plant Physiology® upholds rigorous peer-review standards, ensuring that the scientific community receives the highest quality research. The journal releases 12 issues annually, providing a steady stream of new findings and insights to its readership.
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