基于Strauss-Hardcore模型的紫花苜蓿导管空间构型与水力生态权衡：概念框架与研究展望

doi:10.17521/cjpe.2026.0063

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基于Strauss-Hardcore模型的紫花苜蓿导管空间构型与水力生态权衡：概念框架与研究展望

黄惠群, 陈晓娅, 刘西苑, 朱晓花, 李鑫, 曾和平

邵阳市草地资源保护中心, 422000
邵阳工业职业技术学院, 422000
昆明理工大学环境科学与工程学院, 650500

收稿日期:2026-02-09 修回日期:2026-04-06

The Spatial Architecture of Alfalfa Xylem and Its Hydraulic-Ecological Trade-off: A Conceptual Framework and Research Perspectives Based on the Strauss-Hardcore Model

huang huiqun

, 422000,
, 650500,

Received:2026-02-09 Revised:2026-04-06
Supported by:
Supported by the National Natural Science Foundation of China Joint Fund for Regional InnovationDevelopment Key Support Project(U21A20189); Hunan Provincial Natural Science Foundation Regional Joint Fund Project(2022JJ50032); and Shaoyang Municipal Natural Science Research Guidance Project(2025PT6148)

摘要/Abstract

摘要： 紫花苜蓿（Medicago sativa L.）是全球重要的多年生豆科牧草，其生产力与持久性在很大程度上受制于水分有效性。木质部导管作为植物体内水分长距离运输的关键结构，其解剖特征在水力输导效率与抗栓塞安全性之间形成经典的“效率–安全”权衡。传统研究多集中于导管直径、密度等单一性状，而对导管在组织尺度上的空间分布格局及其功能意义关注不足。近年来，空间点格局分析方法，尤其是Strauss–Hardcore点过程模型，被逐步应用于木质部导管二维空间分布的定量研究，为解析导管空间异质性提供了新的统计工具。该模型通过硬核距离（h）、局部相互作用距离（R）和点对交互作用强度（γ）等参数，刻画导管在物理排斥与局部聚集约束下的空间构型特征。已有研究表明，紫花苜蓿导管空间分布在不同基因型和环境条件下存在显著差异，且与水力安全性、水分利用效率及抗旱性等功能性状密切相关。本文系统综述了Strauss–Hardcore模型在紫花苜蓿导管空间分布研究中的应用进展，重点讨论不同空间构型对水力功能权衡的潜在影响机制，并从干旱、盐分及养分有效性等环境胁迫角度，总结导管空间格局的可塑性响应规律。在此基础上，结合近年来关于导管发育分子调控的研究进展，探讨环境信号—解剖结构—水力功能之间的可能关联路径，并展望三维结构表征、多组学整合及其在生态适应研究中的应用前景。

关键词: 紫花苜蓿, 木质部导管, 空间点格局, Strauss–Hardcore 模型, 水力权衡, 环境胁迫

Abstract: Alfalfa (Medicago sativa L.) is a globally important perennial legume forage whose productivity and persistence are strongly constrained by water availability. Xylem vessels serve as the primary pathway for long-distance water transport, and their anatomical characteristics underpin the classical trade-off between hydraulic efficiency and embolism resistance. Previous studies have mainly focused on single traits such as vessel diameter and density, whereas the spatial distribution of vessels at the tissue scale and its functional significance have received less attention. In recent years, spatial point pattern analysis, particularly the Strauss–Hardcore point process model, has been increasingly applied to quantify the two-dimensional spatiial arrangement of xylem vessels, providing new insights into vessel spatial heterogeneity. This model characterizes vessel spatial configurations under physical exclusion and local interaction constraints using key parameters, including hard-core distance (h), interaction distance (R), and pairwise interaction strength (γ). Accumulating evidence suggests that xylem vessel spatial patterns in Alfalfa (Medicago sativa L.) vary markedly among genotypes and environmental conditions and are closely associated with hydraulic safety, water-use efficiency, and drought tolerance. This review synthesizes recent advances in the application of the Strauss–Hardcore model to studies of xylem vessel spatial distribution in alfalfa, discusses the potential bet ween vessel spatial configurations and hydraulic trade-offs, and summarizes vessel network plasticity in response to drought, salinity, and nutrient availability. Furthermore, we highlight recent progress in the molecular regulation of vessel development and outline future directions integrating three-dimensional imaging and multi-omics approaches to better understand the ecological significance of xylem spatial organization.

Key words: Alfalfa (Medicago sativa L.), xylem vessel, spatial point pattern, Strauss–Hardcore model, hydraulic trade-off, environmental stress

黄惠群, 陈晓娅, 刘西苑, 朱晓花, 李鑫, 曾和平. 基于Strauss-Hardcore模型的紫花苜蓿导管空间构型与水力生态权衡：概念框架与研究展望. . DOI: 10.17521/cjpe.2026.0063

huang huiqun. The Spatial Architecture of Alfalfa Xylem and Its Hydraulic-Ecological Trade-off: A Conceptual Framework and Research Perspectives Based on the Strauss-Hardcore Model. Chinese Journal of Plant Ecology. DOI: 10.17521/cjpe.2026.0063

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链接本文: https://www.plant-ecology.com/CN/10.17521/cjpe.2026.0063

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