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攀援钩吻 Austrobaileya scandens 的筛管结构变异及其对藤本性的意义。

Sieve tube structural variation in Austrobaileya scandens and its significance for lianescence.

机构信息

Institute for Mediterranean and Subtropical Horticulture 'La Mayora'-CSIC-UMA, Avda. Dr. Wienberg s/n, Algarrobo-Costa, Málaga, 29750, Spain.

Department of Organismic and Evolutionary Biology, Harvard University, Cambridge, Massachusetts, USA.

出版信息

Plant Cell Environ. 2022 Aug;45(8):2460-2475. doi: 10.1111/pce.14361. Epub 2022 Jun 7.

DOI:10.1111/pce.14361
PMID:35606891
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9540405/
Abstract

Lianas combine large leaf areas with slender stems, features that require an efficient vascular system. The only extant member of the Austrobaileyaceae is an endemic twining liana of the tropical Australian forests with well-known xylem hydraulics, but the vascular phloem continuum aboveground remains understudied. Microscopy analysis across leaf vein orders and stems of Austrobaileya scandens revealed a low foliar xylem:phloem ratio, with isodiametric vascular elements along the midrib, but tapered across vein orders. Sieve plate pore radii increased from 0.08 µm in minor veins to 0.12 µm in the petiole, but only to 0.20 µm at the stem base, tens of metres away. In easily bent searcher branches, phloem conduits have pectin-rich walls and simple plates, whereas in twining stems, conduits were connected through highly angled and densely porated sieve plates. The hydraulic resistance of phloem conduits in the twisted and elongated stems of A. scandens is large compared with trees of similar stature; phloem hydraulic resistance decreases from leaves to stems, consistent with the efficient delivery of photoassimilates from sources under Münch predictions. Sink strength of a continuously growing canopy might be stronger than in self-supporting understory plants, favoring resource allocation to aerial organs and the attainment of vertical stature.

摘要

藤本植物结合了大片的叶子和细长的茎,这些特征需要一个高效的维管系统。Austrobaileyaceae 科唯一现存的成员是澳大利亚热带森林中的一种特有缠绕藤本植物,具有众所周知的木质部水力学特性,但地上部分的韧皮部维管束连续体仍未得到充分研究。对 Austrobaileya scandens 的叶脉序和茎进行显微镜分析表明,叶片木质部与韧皮部的比例较低,中脉处有等径维管束,但沿叶脉序逐渐变细。筛板孔半径从小叶脉中的 0.08 μm 增加到叶柄中的 0.12 μm,但在离茎基数十米远的地方仅增加到 0.20 μm。在易于弯曲的搜索枝中,韧皮部导管具有富含果胶的壁和简单的板,但在缠绕的茎中,导管通过高度成角和密集穿孔的筛板连接。与相似高度的树木相比,A. scandens 扭曲和伸长的茎中的韧皮部导管的水力阻力较大;韧皮部水力阻力从叶片到茎部逐渐降低,这与 Münch 预测的从源到汇的光合产物有效输送一致。不断生长的树冠的汇强度可能比自支撑的林下植物更强,有利于资源分配给空中器官,并达到垂直高度。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/454a/9540405/83a089403d15/PCE-45-2460-g004.jpg
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