Interspecific trait variability and local soil conditions modulate grassland model community responses to climate

Medium‐to‐high elevation grasslands provide critical services in agriculture and ecosystem stabilization, through high biodiversity and providing food for wildlife. However, these ecosystems face elevated risks of disruption due to predicted soil and climate changes. Separating the effects of soil and climate, however, is difficult in situ, with previous experiments focusing largely on monocultures instead of natural grassland communities. We experimentally exposed model grassland communities, comprised of three species grown on either local or reference soil, to varied climatic environments along an elevational gradient in the European Alps, measuring the effects on species and community traits. Although species‐specific biomass varied across soil and climate, species' proportional contributions to community‐level biomass production remained consistent. Where species experienced low survivorship, species‐level biomass production was maintained through increased productivity of surviving individuals; however, maximum species‐level biomass was obtained under high survivorship. Species responded directionally to climatic variation, spatially separating differentially by plant traits (including height, reproduction, biomass, survival, leaf dry weight, and leaf area) consistently across all climates. Local soil variation drove stochastic trait responses across all species, with high levels of interactions occurring between site and species. This soil variability obscured climate‐driven responses: we recorded no directional trait responses for soil‐corrected traits like observed for climate‐corrected traits. Our species‐based approach contributes to our understanding of grassland community stabilization and suggests that these communities show some stability under climatic variation

Effects of sea-level rise and climatic changes on mangroves from southwestern littoral of Puerto Rico during the middle and late Holocene

We evaluated the response to sea level rise and climatic changes of the northeastern Caribbean by establishing a palaeoenvironmental reconstruction of the Flamenco Lagoon, located in the coastal side of the Guanica Dry Forest, a MAB/UNESCO reserve in the semi-arid southwestern coast of Puerto Rico (17°57′10.31″N, 66°50′39.30″W). The reconstruction was based on pollen records, sediments analysis, δ13C, δ15N, C/N data and AMS 14C dating of one sediment core. The geology of the area is rocky calcareous karst with rocky outcrops and canyons, with intermittent streams that move water during periods of high run-off conditions. The present lagoon is surrounded by rocky outcrops where dry forest vegetation is present on the terrestrial sides, and sand dunes on the coastal side. We propose that the studied lagoon developed after the stabilization of sea level rise in the region following three main stages: (1) before ~ 5400 cal yr BP, sediments were accumulated according to small channels dynamics and trees, shrubs and herbs were present. The sedimentary organic matter was mainly sourced from terrestrial C3 and C4 plants. (2) Between ~ 5400 and ~ 4400 cal yr BP, tidal flats were established and mangroves, mainly represented by Rhizophora trees, migrated landward with sea level rise and established in the area, and the sedimentary organic matter was sourced from terrestrial C3 plants. (3) Around 4400 cal yr BP, sea level was near the stabilization, the endorheic minibasin was closed when a coastal sand dune was established as a result of drier climatic conditions. Mangroves were eliminated from the system as a result of the closure of the area by sand dunes and increased salinity in water due to high evaporative demand of the climate. The pollen dominance of herbaceous and shrubby vegetation prevails until present. Throughout the lagoon development, sedimentary organic matter was sourced from C3 and C4 plants, as well as phytoplankton organic matter. The closure of the lagoon and the drier conditions prevalent in the region during the late Holocene, which lasts until the present day, and increased the contribution of salinity tolerant phytoplankton that characterizes the current conditions of the Flamenco Lagoon.Fil: Cohen, Marcelo Cancela Lisboa. Universidade Federal do Pará; BrasilFil: Lara, Ruben Jose. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Bahía Blanca. Instituto Argentino de Oceanografía. Universidad Nacional del Sur. Instituto Argentino de Oceanografía; ArgentinaFil: Cuevas, Elvira. Universidad de Puerto Rico; Puerto RicoFil: Mulero Oliveras, Eneilis. Universidad de Puerto Rico; Puerto RicoFil: Da Silveira Sternberg, Leonel. University of Miami. Department of Biology; Estados Unido