Yumei Zhou, Shiyun Wu, Jingjing Jia, Huan Chen, Ying Zhang, Zejing Wu, Boya Chen, Can Liu, Ming Yang
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引用次数: 0
摘要
在容器内壁涂覆高浓度铜(Cu)可有效抑制容器栽培幼苗的根系缠绕。然而,在铜-根修剪过程中,根的保护和防御反应如何维持根的结构和功能仍不清楚。在此,将直立杜兰苗种植在涂有 40(T1)、80(T2)、100(T3)、120(T4)、140(T5)和 160(T6) g L-1 Cu(OH)2 的容器中,并以不涂 Cu(OH)2 的容器为对照。虽然 T5 和 T6 对根系缠绕的抑制效果最好,但根系解剖结构受到破坏。T1 和 T2 不仅不能完全控制根系缠绕,还会导致根系活性降低和生长受阻。Cu(OH)2 处理显著增加了根部的木质素浓度,其中 T3 和 T4 的木质素浓度值最高。与 T3 处理相比,T4 处理的幼苗高度、生物量和根系活性都更高,但根系缠绕现象并不明显。Cu(OH)2 处理中过多的铜积累改变了其他矿质营养元素的吸收及其在根、茎和叶中的分配。总的来说,钙减少了,而镁、锰、铁和钾增加了,尤其是钾和锰在 T4 处理中与防御能力有关。结果表明,在过量铜的条件下,容器栽培的直立花幼苗在根系缠结控制、防御能力和养分吸收功能之间存在一个铜阈值。
The balance between alleviating copper damage and maintaining root function during root pruning with excessive copper.
Coating high concentrations of copper (Cu) on the inner wall of containers can efficiently inhibit root entanglement of container-grown seedlings. However, how the protective and defensive responses of roots maintain root structure and function during Cu-root pruning is still unclear. Here, Duranta erecta L. seedlings were planted in the containers coated with 40 (T1), 80 (T2), 100 (T3), 120 (T4), 140 (T5) and 160 (T6) g L-1 Cu(OH)2 with containers without Cu(OH)2 as the control. Although T5 and T6 produced the best inhibitory effect on root entanglement, root anatomy structure was damaged. T1 and T2 not only failed to completely control root circling, but also led to decreased root activity and stunted growth. Cu(OH)2 treatments significantly increased lignin concentration of roots with the highest values at T3 and T4. Compared with T3, seedlings at T4 had higher height, biomass and root activity, and no significant root entanglement. Excessive Cu accumulation in Cu(OH)2 treatments changed the absorption of other mineral nutrients and their allocation in the roots, stems and leaves. Overall, Ca was decreased while Mg, Mn, Fe and K were increased, especially K and Mn at T4 which is related to defense capacity. The results indicate that there is a Cu threshold to balance root entanglement control, defense capacity and nutrient uptake function under excessive Cu for container-grown D. erecta seedlings.
期刊介绍:
Tree Physiology promotes research in a framework of hierarchically organized systems, measuring insight by the ability to link adjacent layers: thus, investigated tree physiology phenomenon should seek mechanistic explanation in finer-scale phenomena as well as seek significance in larger scale phenomena (Passioura 1979). A phenomenon not linked downscale is merely descriptive; an observation not linked upscale, might be trivial. Physiologists often refer qualitatively to processes at finer or coarser scale than the scale of their observation, and studies formally directed at three, or even two adjacent scales are rare. To emphasize the importance of relating mechanisms to coarser scale function, Tree Physiology will highlight papers doing so particularly well as feature papers.