College of Horticulture Science and Engineering, Shandong Apple Technology Innovation Center, Shandong Collaborative Innovation Center for High-quality and Efficient Production of Fruits and Vegetables, Shandong Agricultural University, Tai'an, Shandong, 271018, China.
Apple Industry Research Institute of Zhaotong,Zhaotong, Yunnan, 657000, China.
Plant Physiol Biochem. 2024 Sep;214:108875. doi: 10.1016/j.plaphy.2024.108875. Epub 2024 Jul 2.
Potassium (K) and magnesium (Mg) play analogous roles in regulating plant photosynthesis and carbon and nitrogen (C-N) metabolism. Based on this consensus, we hypothesize that appropriate Mg supplementation may alleviate growth inhibition under low K stress. We monitored morphological, physiological, and molecular changes in G935 apple plants under different K (0.1 and 6 mmol L) and Mg supply (3 and 6 mmol L) conditions. Low K stress caused changes in root and leaf structure, inhibited photosynthesis, and limited the root growth of the apple rootstock. Further study on Mg supplementation showed that it could promote the uptake of K and NO by upregulating the expression of K transporter proteins such as Arabidopsis K transporter 1 (MdAKT1), high-affinity K transporter 1 (MdHKT1), and potassium transporter 5 (MdPT5) and nitrate transporters such as nitrate transporter 1.1/1.2/2.1/2.4 (MdNRT 1.1/1.2/2.1/2.4). Mg promoted the translocation of N from roots to leaves and enhanced photosynthetic N utilization efficiency (PNUE) by increasing the proportion of photosynthetic N and alleviating photosynthetic restrictions. Furthermore, Mg supplementation improved the synthesis of photosynthates by enhancing the activities of sugar-metabolizing enzymes (Rubisco, SS, SPS, S6PDH). Mg also facilitated the transport of sucrose and sorbitol from leaves to roots by upregulating the expression of sucrose transporter 1.1/1.2/4.1/4.2 (MdSUT 1.1/1.2/4.1/4.2) and sorbitol transporter 1.1/1.2 (MdSOT 1.1/1.2). Overall, Mg effectively alleviated growth inhibition in apple rootstock plants under low K stress by facilitating the uptake of N and K uptake, optimizing nitrogen partitioning, enhancing nitrogen use efficiency (NUE) and PNUE, and promoting the photosynthate synthesis and translocation.
钾(K)和镁(Mg)在调节植物光合作用和碳氮(C-N)代谢方面发挥着类似的作用。基于这一共识,我们假设适当的镁补充可能会缓解低钾胁迫下的生长抑制。我们监测了不同钾(0.1 和 6 mmol L)和镁供应(3 和 6 mmol L)条件下 G935 苹果植株的形态、生理和分子变化。低钾胁迫导致根和叶结构发生变化,抑制光合作用,并限制苹果砧木的根系生长。进一步研究镁补充表明,它可以通过上调 K 转运蛋白(如拟南芥 K 转运蛋白 1(MdAKT1)、高亲和力 K 转运蛋白 1(MdHKT1)和钾转运蛋白 5(MdPT5)和硝酸盐转运蛋白(如硝酸盐转运蛋白 1.1/1.2/2.1/2.4(MdNRT 1.1/1.2/2.1/2.4)来促进 K 和 NO 的吸收。镁促进 N 从根部向叶片的转运,并通过增加光合 N 的比例和缓解光合作用限制来提高光合 N 利用效率(PNUE)。此外,镁补充通过增强糖代谢酶(Rubisco、SS、SPS、S6PDH)的活性来提高光合产物的合成。镁还通过上调蔗糖转运蛋白 1.1/1.2/4.1/4.2(MdSUT 1.1/1.2/4.1/4.2)和山梨醇转运蛋白 1.1/1.2(MdSOT 1.1/1.2)来促进蔗糖和山梨醇从叶片向根部的运输。总的来说,镁通过促进 N 和 K 的吸收、优化氮分配、提高氮利用效率(NUE)和 PNUE、促进光合产物的合成和转运,有效地缓解了低钾胁迫下苹果砧木的生长抑制。
