Can species climate niche predict canopy growth, functional traits and phenotypic plasticity in urban trees?

IF 6 2区环境科学与生态学 Q1 ENVIRONMENTAL STUDIES Urban Forestry & Urban Greening Pub Date : 2024-06-14 DOI:10.1016/j.ufug.2024.128417

Mohammad Golam Kibria , Mark G. Tjoelker , Renée M. Marchin , Stefan K. Arndt , Paul D. Rymer

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Abstract

There is much uncertainty in how climate change will impact the performance of urban trees. Climate niche modelling predicts that many urban tree species may become unsuitable in future climates, but this has rarely been tested in cities. Broad planting of diverse tree species in different cities provides the opportunity to test climate niche predictions. Here we investigated if the climate of origin of 14 urban tree species influenced tree growth, trait expression, and phenotypic plasticity. We determined climate niche limits for all species and measured canopy growth rates of individual trees from 2013 to 2021 in the two largest Australian cities: subtropical Sydney, and temperate Melbourne. Six functional traits including leaf water potential at turgor loss point (TLP), wood density (WD), leaf dry matter content (LDMC), specific leaf area (SLA), carbon isotope composition (δ¹³C) and Huber value (HV) were measured in both cities. Trees planted outside their climate niche limits had lower growth than trees planted inside their climate niche in the temperate but not subtropical city. Species with lower MAP of origin (i.e., drier) had faster canopy growth in both cities. Species with low MAP and high heat moisture index (HMI) at their origin had more negative TLP and greater WD, indicating species from drier environments maintain their high drought tolerance in cities. Trees planted in drier Melbourne had more negative TLP, higher WD and higher LDMC than in Sydney, demonstrating phenotypic plasticity in urban trees. Wetter origin species showed greater phenotypic plasticity in TLP, WD and δ¹³C. Canopy RGR was negatively related with δ¹³C reflecting a strong impact of stomatal behaviour on urban tree growth. Our study provides limited support that species climate niche limits reliably predict urban tree growth, so we caution against solely using climate niche matching and advocate for inclusion of functional traits when selecting urban tree species.

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物种的气候生态位能否预测城市树木的树冠生长、功能特征和表型可塑性？

气候变化将如何影响城市树木的表现还存在很多不确定性。气候生态位模型预测，许多城市树种可能会变得不适合未来的气候，但这一预测很少在城市中得到验证。在不同城市广泛种植不同树种为检验气候生态位预测提供了机会。在这里，我们研究了 14 种城市树种的原产地气候是否会影响树木的生长、性状表达和表型可塑性。我们确定了所有物种的气候生态位限制，并测量了2013年至2021年澳大利亚两个最大城市（亚热带城市悉尼和温带城市墨尔本）中单个树木的树冠生长率。我们在这两座城市测量了六种功能性特征，包括叶片失水点水势（TLP）、木材密度（WD）、叶片干物质含量（LDMC）、比叶面积（SLA）、碳同位素组成（δ13C）和胡伯值（HV）。在温带而非亚热带城市，种植在其气候生态位限制范围之外的树木比种植在其气候生态位之内的树木生长量低。在这两个城市中，原产地水分平均值较低（即较干燥）的树种树冠生长较快。原产地水分平均值低且热湿度指数（HMI）高的树种，TLP负值更大，WD也更大，这表明来自较干燥环境的树种在城市中仍能保持较高的耐旱性。与悉尼相比，在较干燥的墨尔本种植的树木具有更多的负TLP、更高的WD和更高的LDMC，这表明城市树木具有表型可塑性。原产地较湿的树种在 TLP、WD 和 δ13C 方面表现出更大的表型可塑性。树冠RGR与δ13C呈负相关，反映了气孔行为对城市树木生长的强烈影响。我们的研究为物种气候生态位限制可靠地预测城市树木生长提供了有限的支持，因此我们告诫不要仅使用气候生态位匹配，并主张在选择城市树木物种时纳入功能特征。

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来源期刊

Urban Forestry & Urban Greening FORESTRY-

CiteScore

11.70

自引率

12.50%

发文量

289

审稿时长

70 days

期刊介绍： Urban Forestry and Urban Greening is a refereed, international journal aimed at presenting high-quality research with urban and peri-urban woody and non-woody vegetation and its use, planning, design, establishment and management as its main topics. Urban Forestry and Urban Greening concentrates on all tree-dominated (as joint together in the urban forest) as well as other green resources in and around urban areas, such as woodlands, public and private urban parks and gardens, urban nature areas, street tree and square plantations, botanical gardens and cemeteries. The journal welcomes basic and applied research papers, as well as review papers and short communications. Contributions should focus on one or more of the following aspects: -Form and functions of urban forests and other vegetation, including aspects of urban ecology. -Policy-making, planning and design related to urban forests and other vegetation. -Selection and establishment of tree resources and other vegetation for urban environments. -Management of urban forests and other vegetation. Original contributions of a high academic standard are invited from a wide range of disciplines and fields, including forestry, biology, horticulture, arboriculture, landscape ecology, pathology, soil science, hydrology, landscape architecture, landscape planning, urban planning and design, economics, sociology, environmental psychology, public health, and education.