Key Laboratory of Crop Physiology Ecology and Production Management of Ministry of Agriculture, Nanjing Agricultural University, Nanjing, Jiangsu Province, 210095, People's Republic of China.
Plant Physiol Biochem. 2023 Aug;201:107880. doi: 10.1016/j.plaphy.2023.107880. Epub 2023 Jul 7.
Phosphorus (P) deficit limits high wheat (Triticum aestivum L.) yields. Breeding low-P-tolerant cultivars is vital for sustainable agriculture and food security, but the low-P adaptation mechanisms are largely not understood. Two wheat cultivars, ND2419 (low-P-tolerant) and ZM366 (low-P-sensitive) were used in this study. They were grown under hydroponic conditions with low-P (0.015 mM) or normal-P (1 mM). Low-P suppressed biomass accumulation and net photosynthetic rate (A) in both cultivars, whereas ND2419 was relatively less suppressed. Intercellular CO concentration did not decrease with the decline of stomatal conductance. Additionally, maximum electron transfer rate (J) decreased sooner than maximum carboxylation rate (V). Results indicate that impeded electron transfer is directly responsible for decreased A. Under low-P, ND2419 exhibited greater PSII functionality (potential activity (F/F), maximum quantum efficiency (F/F), photochemical quenching (qL) and non-photochemical quenching (NPQ) required for electron transfer than ZM366, resulting more ATP for Rubisco activation. Furthermore, ND2419 maintained higher chloroplast Pi concentrations by enhancing chloroplast Pi allocation, compared with ZM366. Overall, the low-P-tolerant cultivar sustained electron transfer under low-P by enhancing chloroplast Pi allocation, allowing more ATP synthesis for Rubisco activation, ultimately presenting stronger photosynthesis capacities. The improved chloroplasts Pi allocation may provide new insights into improve low-P tolerance.
磷(P)亏缺限制了小麦(Triticum aestivum L.)的高产。培育低 P 耐性品种对于可持续农业和粮食安全至关重要,但低 P 适应机制在很大程度上尚不清楚。本研究使用了两个小麦品种,ND2419(低 P 耐性)和 ZM366(低 P 敏感)。它们在低 P(0.015 mM)或正常 P(1 mM)的水培条件下生长。低 P 抑制了两个品种的生物量积累和净光合速率(A),而 ND2419 的抑制程度相对较小。胞间 CO 浓度不会随着气孔导度的下降而降低。此外,最大电子传递速率(J)比最大羧化速率(V)下降得更早。结果表明,电子传递受阻是 A 降低的直接原因。在低 P 下,ND2419 表现出更高的 PSII 功能(潜在活性(F/F)、最大量子效率(F/F)、光化学猝灭(qL)和非光化学猝灭(NPQ),这些都需要电子传递,从而为 Rubisco 激活提供更多的 ATP。此外,ND2419 通过增强叶绿体 Pi 分配,维持较高的叶绿体 Pi 浓度,而 ZM366 则相反。总体而言,低 P 耐性品种通过增强叶绿体 Pi 分配来维持低 P 下的电子传递,从而为 Rubisco 激活提供更多的 ATP 合成,最终表现出更强的光合作用能力。改善的叶绿体 Pi 分配可能为提高低 P 耐性提供新的思路。
