Ernesto Gianoli, Cristian Salgado-Luarte, Víctor M. Escobedo, Gisela C. Stotz
{"title":"在温带常绿植物中,叶片韧性比单位面积叶片质量(LMA)更能预测草食性和植物表现","authors":"Ernesto Gianoli, Cristian Salgado-Luarte, Víctor M. Escobedo, Gisela C. Stotz","doi":"10.1007/s10682-024-10298-0","DOIUrl":null,"url":null,"abstract":"<p>The mechanical strengthening of leaves protects seedlings from herbivore damage, particularly in shade-tolerant evergreens. Interspecific studies have shown that leaf mass per area (LMA) and leaf toughness (force-to-punch) can play this role. Here we compared the influence of LMA and leaf toughness on herbivory and plant performance in a temperate rainforest. In seedlings of 14 evergreen species, we addressed the across-species relationship between LMA and force-to-punch, and compared the strength of their associations with herbivory and with species’ light requirements. Moreover, in four understory species we performed a multivariate analysis within-species, analogue to phenotypic selection analysis, evaluating the correlation between seedling performance, estimated as chlorophyll fluorescence (<i>F</i><sub>v</sub>/<i>F</i><sub>m</sub>), and force-to-punch, LMA, lamina density and lamina thickness. LMA and force-to-punch were positively associated across species. Herbivory was negatively correlated with both force-to-punch and LMA, but a stepwise multiple regression showed that force-to-punch was a better predictor of herbivory. Neither leaf lamina density nor thickness were associated with herbivore damage. Those species that were more shade-tolerant had leaves with higher force-to-punch and higher LMA, and less slender seedlings. In the within-species analyses in four shade-tolerant species, seedling performance was generally positively associated with force-to-punch, but not with LMA, lamina thickness, or lamina density. Both interspecific and within-species analyses showed that force-to-punch is more strongly related to herbivore damage and plant performance than LMA. This consistency between interspecific patterns of trait covariation and within-species trait-performance associations suggests that natural selection could have shaped the relationships between mechanical traits and ecological roles observed across species.</p>","PeriodicalId":55158,"journal":{"name":"Evolutionary Ecology","volume":"7 1","pages":""},"PeriodicalIF":1.8000,"publicationDate":"2024-04-17","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Leaf toughness is a better predictor of herbivory and plant performance than leaf mass per area (LMA) in temperate evergreens\",\"authors\":\"Ernesto Gianoli, Cristian Salgado-Luarte, Víctor M. Escobedo, Gisela C. Stotz\",\"doi\":\"10.1007/s10682-024-10298-0\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>The mechanical strengthening of leaves protects seedlings from herbivore damage, particularly in shade-tolerant evergreens. Interspecific studies have shown that leaf mass per area (LMA) and leaf toughness (force-to-punch) can play this role. Here we compared the influence of LMA and leaf toughness on herbivory and plant performance in a temperate rainforest. In seedlings of 14 evergreen species, we addressed the across-species relationship between LMA and force-to-punch, and compared the strength of their associations with herbivory and with species’ light requirements. Moreover, in four understory species we performed a multivariate analysis within-species, analogue to phenotypic selection analysis, evaluating the correlation between seedling performance, estimated as chlorophyll fluorescence (<i>F</i><sub>v</sub>/<i>F</i><sub>m</sub>), and force-to-punch, LMA, lamina density and lamina thickness. LMA and force-to-punch were positively associated across species. Herbivory was negatively correlated with both force-to-punch and LMA, but a stepwise multiple regression showed that force-to-punch was a better predictor of herbivory. Neither leaf lamina density nor thickness were associated with herbivore damage. Those species that were more shade-tolerant had leaves with higher force-to-punch and higher LMA, and less slender seedlings. In the within-species analyses in four shade-tolerant species, seedling performance was generally positively associated with force-to-punch, but not with LMA, lamina thickness, or lamina density. 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Leaf toughness is a better predictor of herbivory and plant performance than leaf mass per area (LMA) in temperate evergreens
The mechanical strengthening of leaves protects seedlings from herbivore damage, particularly in shade-tolerant evergreens. Interspecific studies have shown that leaf mass per area (LMA) and leaf toughness (force-to-punch) can play this role. Here we compared the influence of LMA and leaf toughness on herbivory and plant performance in a temperate rainforest. In seedlings of 14 evergreen species, we addressed the across-species relationship between LMA and force-to-punch, and compared the strength of their associations with herbivory and with species’ light requirements. Moreover, in four understory species we performed a multivariate analysis within-species, analogue to phenotypic selection analysis, evaluating the correlation between seedling performance, estimated as chlorophyll fluorescence (Fv/Fm), and force-to-punch, LMA, lamina density and lamina thickness. LMA and force-to-punch were positively associated across species. Herbivory was negatively correlated with both force-to-punch and LMA, but a stepwise multiple regression showed that force-to-punch was a better predictor of herbivory. Neither leaf lamina density nor thickness were associated with herbivore damage. Those species that were more shade-tolerant had leaves with higher force-to-punch and higher LMA, and less slender seedlings. In the within-species analyses in four shade-tolerant species, seedling performance was generally positively associated with force-to-punch, but not with LMA, lamina thickness, or lamina density. Both interspecific and within-species analyses showed that force-to-punch is more strongly related to herbivore damage and plant performance than LMA. This consistency between interspecific patterns of trait covariation and within-species trait-performance associations suggests that natural selection could have shaped the relationships between mechanical traits and ecological roles observed across species.
期刊介绍:
Evolutionary Ecology is a concept-oriented journal of biological research at the interface of ecology and evolution. We publish papers that therefore integrate both fields of research: research that seeks to explain the ecology of organisms in the context of evolution, or patterns of evolution as explained by ecological processes.
The journal publishes original research and discussion concerning the evolutionary ecology of organisms. These may include papers addressing evolutionary aspects of population ecology, organismal interactions and coevolution, behaviour, life histories, communication, morphology, host-parasite interactions and disease ecology, as well as ecological aspects of genetic processes. The objective is to promote the conceptual, theoretical and empirical development of ecology and evolutionary biology; the scope extends to any organism or system.
In additional to Original Research articles, we publish Review articles that survey recent developments in the field of evolutionary ecology; Ideas & Perspectives articles which present new points of view and novel hypotheses; and Comments on articles recently published in Evolutionary Ecology or elsewhere. We also welcome New Tests of Existing Ideas - testing well-established hypotheses but with broader data or more methodologically rigorous approaches; - and shorter Natural History Notes, which aim to present new observations of organismal biology in the wild that may provide inspiration for future research. As of 2018, we now also invite Methods papers, to present or review new theoretical, practical or analytical methods used in evolutionary ecology.
Students & Early Career Researchers: We particularly encourage, and offer incentives for, submission of Reviews, Ideas & Perspectives, and Methods papers by students and early-career researchers (defined as being within one year of award of a PhD degree) – see Students & Early Career Researchers
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