{"title":"一种脂质合成酶可维持茉莉酸合成的代谢通量,从而调节根系生长和磷酸盐平衡。","authors":"Mandavi Pandey, Lokesh Verma, Pawandeep Singh Kohli, Bhagat Singh, Abhijith Kochi, Jitender Giri","doi":"10.1093/plphys/kiae453","DOIUrl":null,"url":null,"abstract":"<p><p>Plants require phosphate (Pi) for proper growth and development but often face scarcity of this vital nutrient in the soil. Pi-starvation triggers membrane lipid remodeling to utilize the membrane phospholipid-bound Pi in plants. In this process, phospholipids are replaced by non-Pi-containing galactolipids (MGDG, DGDG) and sulfolipids. The galactolipids ratio (MGDG:DGDG) is suggested to influence jasmonic acid (JA) biosynthesis. However, how the MGDG:DGDG ratio, JA levels, and root growth are coordinated under Pi deficiency in rice (Oryza sativa) remains unknown. Here, we characterized DGDG synthase 1 (OsDGD1) for its role in regulating root development by maintaining metabolic flux for JA biosynthesis. We showed that OsDGD1 is responsive under low Pi and is under the direct control of Phosphate Starvation Response 2 (OsPHR2), the master regulator of low Pi adaptations. Further, OsDGD1 knockout (KO) lines showed marked phenotypic differences compared to the wild type (WT), including a significant reduction in root length and biomass, leading to reduced Pi uptake. Further, lipidome analyses revealed reduced DGDG levels in the KO line, leading to reduced membrane remodeling, thus affecting P utilization efficiency. We also observed an increase in the MGDG: DGDG ratio in KO lines, which enhanced the endogenous JA levels and signaling. This imbalance of JA in KO plants led to changes in auxin levels, causing drastic root growth inhibition. These findings indicate the critical role of OsDGD1 in maintaining optimum levels of JA during Pi deficiency for conducive root growth. Besides acting as signaling molecules and structural components, our study widens the role of lipids as metabolic flux controllers for phytohormone biosynthesis.</p>","PeriodicalId":20101,"journal":{"name":"Plant Physiology","volume":null,"pages":null},"PeriodicalIF":6.5000,"publicationDate":"2024-08-27","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"A lipid synthase maintains metabolic flux for jasmonate synthesis to regulate root growth and phosphate homeostasis.\",\"authors\":\"Mandavi Pandey, Lokesh Verma, Pawandeep Singh Kohli, Bhagat Singh, Abhijith Kochi, Jitender Giri\",\"doi\":\"10.1093/plphys/kiae453\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>Plants require phosphate (Pi) for proper growth and development but often face scarcity of this vital nutrient in the soil. Pi-starvation triggers membrane lipid remodeling to utilize the membrane phospholipid-bound Pi in plants. 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引用次数: 0
摘要
植物的正常生长和发育需要磷酸盐(Pi),但土壤中往往缺乏这种重要的营养物质。缺磷会引发膜脂重塑,以利用植物体内与膜磷脂结合的 Pi。在此过程中,磷脂被不含π的半乳糖脂(MGDG、DGDG)和硫脂取代。半乳糖脂比率(MGDG:DGDG)被认为会影响茉莉酸(JA)的生物合成。然而,在水稻(Oryza sativa)缺π的情况下,MGDG:DGDG 比率、JA 水平和根系生长是如何协调的仍是未知数。在这里,我们对 DGDG 合酶 1(OsDGD1)进行了表征,研究其通过维持 JA 生物合成的代谢通量来调节根系发育的作用。我们发现,OsDGD1 在低 Pi 条件下具有响应性,并受磷酸盐饥饿响应 2(OsPHR2)的直接控制,而磷酸盐饥饿响应 2 是低 Pi 适应性的主调控因子。此外,与野生型(WT)相比,OsDGD1基因敲除(KO)株表现出明显的表型差异,包括根长和生物量显著减少,导致π吸收减少。此外,脂质体分析显示,KO 株系中的 DGDG 水平降低,导致膜重塑减少,从而影响了钾的利用效率。我们还观察到,KO 株系中的 MGDG: DGDG 比率增加,从而提高了内源 JA 水平和信号转导。KO 株系中 JA 的失衡导致了辅素水平的变化,从而导致根系生长受到严重抑制。这些发现表明,OsDGD1 在 Pi 缺乏期间维持最佳 JA 水平以促进根系生长方面起着关键作用。除了作为信号分子和结构成分外,我们的研究还拓宽了脂质作为植物激素生物合成代谢通量控制器的作用。
A lipid synthase maintains metabolic flux for jasmonate synthesis to regulate root growth and phosphate homeostasis.
Plants require phosphate (Pi) for proper growth and development but often face scarcity of this vital nutrient in the soil. Pi-starvation triggers membrane lipid remodeling to utilize the membrane phospholipid-bound Pi in plants. In this process, phospholipids are replaced by non-Pi-containing galactolipids (MGDG, DGDG) and sulfolipids. The galactolipids ratio (MGDG:DGDG) is suggested to influence jasmonic acid (JA) biosynthesis. However, how the MGDG:DGDG ratio, JA levels, and root growth are coordinated under Pi deficiency in rice (Oryza sativa) remains unknown. Here, we characterized DGDG synthase 1 (OsDGD1) for its role in regulating root development by maintaining metabolic flux for JA biosynthesis. We showed that OsDGD1 is responsive under low Pi and is under the direct control of Phosphate Starvation Response 2 (OsPHR2), the master regulator of low Pi adaptations. Further, OsDGD1 knockout (KO) lines showed marked phenotypic differences compared to the wild type (WT), including a significant reduction in root length and biomass, leading to reduced Pi uptake. Further, lipidome analyses revealed reduced DGDG levels in the KO line, leading to reduced membrane remodeling, thus affecting P utilization efficiency. We also observed an increase in the MGDG: DGDG ratio in KO lines, which enhanced the endogenous JA levels and signaling. This imbalance of JA in KO plants led to changes in auxin levels, causing drastic root growth inhibition. These findings indicate the critical role of OsDGD1 in maintaining optimum levels of JA during Pi deficiency for conducive root growth. Besides acting as signaling molecules and structural components, our study widens the role of lipids as metabolic flux controllers for phytohormone biosynthesis.
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.