2018
DOI: 10.1111/jbi.13171
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Spatial patterns and climate relationships of major plant traits in the New World differ between woody and herbaceous species

Abstract: Aim Despite several recent efforts to map plant traits and to identify their climatic drivers, there are still major gaps. Global trait patterns for major functional groups, in particular, the differences between woody and herbaceous plants, have yet to be identified. Here, we take advantage of big data efforts to compile plant species occurrence and trait data to analyse the spatial patterns of assemblage means and variances of key plant traits. We tested whether these patterns and their climatic drivers are … Show more

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Cited by 107 publications
(120 citation statements)
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References 73 publications
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“…Temperature‐related variables were correlated with all three plant traits, which is in line with recent findings (Moles et al., ; Reich & Oleksyn, ; Šímová et al., ). In particular, temperature seasonality was an important driver of changes in understorey mean values of H and SLA: forest stands characterized by high temperature variation across seasons (thermophilous deciduous and broadleaved evergreen forests located in the Mediterranean Region of Italy) were characterized by shorter understorey communities with high‐SLA values, while forest stands with low temperature variation across seasons (forests of the hilly and mountainous belt of northern and central Italy) were characterized by taller understorey communities with low SLA values.…”
Section: Discussionsupporting
confidence: 91%
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“…Temperature‐related variables were correlated with all three plant traits, which is in line with recent findings (Moles et al., ; Reich & Oleksyn, ; Šímová et al., ). In particular, temperature seasonality was an important driver of changes in understorey mean values of H and SLA: forest stands characterized by high temperature variation across seasons (thermophilous deciduous and broadleaved evergreen forests located in the Mediterranean Region of Italy) were characterized by shorter understorey communities with high‐SLA values, while forest stands with low temperature variation across seasons (forests of the hilly and mountainous belt of northern and central Italy) were characterized by taller understorey communities with low SLA values.…”
Section: Discussionsupporting
confidence: 91%
“…Numerous studies have assessed the relationships between the environment and key plant functional traits on a broad scale (Moles et al., , ; Šímová et al., ; Wright et al., , ) that reflect fundamental plant strategies [Leaf–Height–Seed traits (LHS); Westoby, ]. However, generalizable patterns have yet to emerge (Shipley et al., ): trait–environment correlations are often weak, and the strength and sign of these correlations vary across studies (Borgy et al, ; Moles et al., ; Šímová et al., ).…”
Section: Introductionmentioning
confidence: 99%
“…Biases in trait data coverage could spatially bias our maps of FMs and FD if botanical collecting effort in certain areas were focused on certain taxonomic or functional groups (Borgy, Violle, Choler, Garnier, et al, ). Because our maps of functional composition are broadly consistent with other estimates (Butler et al, ; Šímová et al, ; van Bodegom, Douma, & Verheijen, ), this is unlikely to be a major concern. Nevertheless, trait data and species occurrence are poor in some regions (e.g.…”
Section: Discussionsupporting
confidence: 88%
“…We derived gridded maps of contemporary FMs and FD (as convex hull volume (Cornwell, Schwilk, & Ackerly, )) across the Americas by merging species‐mean trait data with maps of species distributions. We used five plant functional traits that are representative of major ecological strategy axes (Díaz et al, ; Westoby & Wright, ), and predictive of species sorting along environmental gradients (Moles et al, ; Šímová et al, , ). We then coupled these estimates with contemporary and paleoclimate maps at timescales spanning the Last Interglacial (120 ka) to the present.…”
Section: Introductionmentioning
confidence: 99%
“…This suggests plant growth forms differ in their strategies to cope with environmental conditions. The lack of variation in the modulatory of non‐woody species across environments suggests they experience weaker environmental filtering compared to woody species (Šímová et al, ). Weaker environmental filtering in non‐woody species perhaps results from their shorter life span, dormancy (and other bet‐hedging) strategies and lack of long‐persisting, reinforced stems above ground, which in combination may allow them to avoid much environmental heterogeneity.…”
Section: Discussionmentioning
confidence: 99%