为什么不随机建立树冠网络?

IF 2.2 4区 生物学 Q2 PLANT SCIENCES Theoretical and Experimental Plant Physiology Pub Date : 2024-05-27 DOI:10.1007/s40626-024-00340-5
Carlos Henrique Britto de Assis Prado
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摘要

我们比较了赛拉多(Cerrado)和卡廷加(Caatinga)植被中 58 个天然树冠网络(WCN)的分解、拓扑结构和特性,以及随机建立的相同数量、不同大小(从 10 节点到 248 节点)的树冠网络(分支区域)。节点的随机分布并没有破坏 WCN 特性之间的内在联系,而且所形成的树冠与 Caatinga 中的树冠相似,其水力相对安全,可应对严重的水压力和其他压力。然而,随机添加节点的生长方式缺乏灵活性,无法创造出类似于WCN的Cerrado树木。这些 Cerrado 树表现出的 WCN 侧向性和基部性较小,有可能达到更高的最大冠高,但其固有的水力结构风险较大,节点之间的通航能力较低。因此,在树木通常能达到相当高度的温和压力环境中,随机节点分布不适合建立 WCN。对节点数量(丰度)、节点插入位置(直线或横向)、节点沿木质轴的相对位置(离初始节点近或远)以及预期行为的感知,对于在各种变化的环境中构建合适且适应性强的 WCN 至关重要。除了显著的结构可塑性外,与认知相关的特征还可以通过WCN的一些宪法随机特征来实现,甚至通过胡乱增加节点来构建安全的水力结构,以及通过蓝图工程在一定范围内调节WCN的分解和拓扑结构。
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Why not be random to build a woody crown network?

We compared the decomposition, topology, and properties of 58 natural woody crown networks (WCN) from Cerrado and Caatinga vegetation with the same number of WCN built randomly at different sizes, from 10 to 248 nodes (the branching regions). The random distribution of nodes did not wrack the intrinsic relationships between WCN properties and created woody crowns similar to those found in Caatinga with relatively safe hydraulics to face severe water and other stresses. Nevertheless, growing by random node addition is an inflexible, unintentional procedure incapable of creating WCN-like Cerrado trees. These Cerrado trees showed WCN with less laterality and basitony, potentially achieving higher maximum crown height, but inherently had a riskier hydraulic architecture with lower navigability between nodes. Hence, random node distribution is unsuitable for building WCN in environments with mild stresses where trees typically attain considerable height. A sense of node numerosity (abundance), location of node insertion (rectilinear or lateral), node relative position (near or far from the initial node) along the woody axis, and anticipation behavior are essential to construct a suitable and adaptable WCN in each changing environment. Besides remarkable structural plasticity, the cognition-related features could be accomplished by some constitutional random traits of WCN, constructing safe hydraulic architecture even by haphazard node addition, and modulating the WCN decomposition and topology within limits through a blueprint project.

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来源期刊
CiteScore
4.20
自引率
7.70%
发文量
32
期刊介绍: The journal does not publish articles in taxonomy, anatomy, systematics and ecology unless they have a physiological approach related to the following sections: Biochemical Processes: primary and secondary metabolism, and biochemistry; Photobiology and Photosynthesis Processes; Cell Biology; Genes and Development; Plant Molecular Biology; Signaling and Response; Plant Nutrition; Growth and Differentiation: seed physiology, hormonal physiology and photomorphogenesis; Post-Harvest Physiology; Ecophysiology/Crop Physiology and Stress Physiology; Applied Plant Ecology; Plant-Microbe and Plant-Insect Interactions; Instrumentation in Plant Physiology; Education in Plant Physiology.
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