Affiliation:
1. Agronomy Department University of Florida Gainesville Florida USA
2. Departamento de Producción Animal y Pasturas, Facultad de Agronomía Universidad de la República Paysandú Uruguay
3. Departamento de Biometría, Estadística y Computación, Facultad de Agronomía Universidad de la República Paysandú Uruguay
Abstract
AbstractAimsChanges in species composition and intraspecific trait variation are recognized as potential drivers of population and community temporal dynamics but their independent and overlapping effects have not been distinguished conclusively. Our goal was to quantify the relevance of temporal vs spatial changes in species composition and intraspecific trait variations when assessing community responses to seasonality, grazing pressure and above‐ground biomass gradients.LocationCampos grassland in northeastern Uruguay.MethodsLeaf dry matter content, specific leaf area, leaf width and tensile strength of dominant grass species were assessed across summer–autumn, winter, and spring seasons, under two grazing pressures. Species composition and above‐ground biomass were estimated in 20 × 20‐cm permanent quadrats within each season. Species trait variability was decomposed across space and time using hierarchical linear mixed models, while the spatio‐temporal community functional variation was decomposed into species turnover (abundance and/or species identity shifts) and intraspecific trait variation. Additionally, we explored the relevance of including or not including temporal intraspecific trait variation on community responses to seasonality, above‐ground biomass and grazing pressure using linear mixed models.ResultsIntraspecific trait variation explained 22.4%–66.5% of total trait variability, and it was generally more important across time than space, which accounted for 12.2%–57.7% of total variability. The within‐species trait variability was generally more important than species turnover in explaining the community spatio‐temporal functional variation. In general, seasonality more strongly caused intraspecific changes while the above‐ground biomass gradient caused species turnover. Functional community responses to grazing pressure, above‐ground biomass and seasonality were affected by considering or not considering intraspecific trait variation.ConclusionsTrait variation within species across seasons is at least equally important as variation within species across space. Its influence in the functional changes of vegetation should not be considered only along environmental gradients but also through time.