多性状相互作用而非系统发育,微调了随着海拔升高叶片面积减小的程度。
Multi-trait interactions, not phylogeny, fine-tune leaf size reduction with increasing altitude.
机构信息
Área de Biodiversidad y Conservación, Universidad Rey Juan Carlos, c/Tulipán s/n, Móstoles, Madrid, Spain.
出版信息
Ann Bot. 2011 Mar;107(3):455-65. doi: 10.1093/aob/mcq261. Epub 2011 Jan 3.
BACKGROUND AND AIMS
Despite long-held interest, knowledge on why leaf size varies widely among species is still incomplete. This study was conducted to assess whether abiotic factors, phylogenetic histories and multi-trait interactions act together to shape leaf size.
METHODS
Fifty-seven pairs of altitudinal vicariant species were selected in northern Spain, and leaf area and a number of functionally related leaf, shoot and whole plant traits were measured for each pair. Structural equation modelling helped unravel trait interactions affecting leaf size, and Mantel tests weighed the relative relevance of phylogeny, environment and trait interactions to explain leaf size reduction with altitude.
KEY RESULTS
Leaves of highland vicariants were generally smaller than those of lowlands. However, the extent of leaf size reduction with increasing altitude was widely variable among genera: from approx. 700 cm(2) reduction (96 % in Polystichum) to approx. 30 cm(2) increase (37 % in Sorbus). This was partially explained by shifts in leaf, shoot and whole plant traits (35-64 % of explained variance, depending on models), with size/number trade-offs more influential than shifts in leaf form and leaf economics. Shifts in traits were more important than phylogenetic distances or site-specific environmental variation in explaining the degree of leaf size reduction with altitude.
CONCLUSIONS
Ecological filters, constraints due to phylogenetic history (albeit modest in the study system), and phenotypic integration contribute jointly to shape single-trait evolution. Here, it was found that phenotypic change was far more important than shared ancestry to explain leaf size differences of closely related species segregated along altitudes.
背景与目的
尽管人们一直很感兴趣,但对于物种间叶片大小差异广泛存在的原因,我们的了解仍然不完整。本研究旨在评估非生物因素、系统发育历史和多性状相互作用是否共同作用来塑造叶片大小。
方法
在西班牙北部选择了 57 对海拔分异的物种,并为每一对物种测量了叶片面积和一些与功能相关的叶片、茎和整个植物性状。结构方程模型有助于揭示影响叶片大小的性状相互作用,而 Mantel 检验则衡量了系统发育、环境和性状相互作用相对于解释随海拔升高叶片大小减小的相对重要性。
主要结果
高山分异物种的叶片通常比低地的小。然而,叶片大小随海拔升高而减小的程度在属间差异很大:从大约减少 700cm²(96%在 Polystichum 中)到大约增加 30cm²(37%在 Sorbus 中)。这部分是由叶片、茎和整个植物性状的变化(取决于模型,解释方差的 35-64%)解释的,大小/数量权衡比叶片形态和叶片经济的变化更有影响力。性状的变化比系统发育距离或特定地点的环境变化更重要,解释了随海拔升高叶片大小减小的程度。
结论
生态过滤器、系统发育历史的约束(尽管在研究系统中是适度的)和表型整合共同作用来塑造单个性状的进化。在这里,我们发现表型变化比共同祖先对解释沿着海拔高度隔离的近缘物种的叶片大小差异更为重要。
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