Your search keyword '"Sabatini FM"' showing total 3 results

1. Climate-trait relationships exhibit strong habitat specificity in plant communities across Europe.

Author

Kambach S, Sabatini FM, Attorre F, Biurrun I, Boenisch G, Bonari G, Čarni A, Carranza ML, Chiarucci A, Chytrý M, Dengler J, Garbolino E, Golub V, Güler B, Jandt U, Jansen J, Jašková A, Jiménez-Alfaro B, Karger DN, Kattge J, Knollová I, Midolo G, Moeslund JE, Pielech R, Rašomavičius V, Rūsiņa S, Šibík J, Stančić Z, Stanisci A, Svenning JC, Yamalov S, Zimmermann NE, and Bruelheide H

Subjects

Europe, Seeds, Ecosystem, Plants

Abstract

Ecological theory predicts close relationships between macroclimate and functional traits. Yet, global climatic gradients correlate only weakly with the trait composition of local plant communities, suggesting that important factors have been ignored. Here, we investigate the consistency of climate-trait relationships for plant communities in European habitats. Assuming that local factors are better accounted for in more narrowly defined habitats, we assigned > 300,000 vegetation plots to hierarchically classified habitats and modelled the effects of climate on the community-weighted means of four key functional traits using generalized additive models. We found that the predictive power of climate increased from broadly to narrowly defined habitats for specific leaf area and root length, but not for plant height and seed mass. Although macroclimate generally predicted the distribution of all traits, its effects varied, with habitat-specificity increasing toward more narrowly defined habitats. We conclude that macroclimate is an important determinant of terrestrial plant communities, but future predictions of climatic effects must consider how habitats are defined., (© 2023. The Author(s).)

Published

2023

2. Using historical spy satellite photographs and recent remote sensing data to identify high-conservation-value forests.

Author

Munteanu C, Senf C, Nita MD, Sabatini FM, Oeser J, Seidl R, and Kuemmerle T

Subjects

Biodiversity, Forests, Remote Sensing Technology, Conservation of Natural Resources methods, Ecosystem

Abstract

High-conservation-value forests (HCVFs) are critically important for biodiversity and ecosystem service provisioning, but they face many threats. Where systematic HCVF inventories are missing, such as in parts of Eastern Europe, these forests remain largely unacknowledged and therefore often unprotected. We devised a novel, transferable approach for detecting HCVFs based on integrating historical spy satellite images, contemporary remote sensing data (Landsat), and information on current potential anthropogenic pressures (e.g., road infrastructure, population density, demand for fire wood, terrain). We applied the method to the Romanian Carpathians, for which we mapped forest continuity (1955-2019), canopy structural complexity, and anthropogenic pressures. We identified 738,000 ha of HCVF. More than half of this area was identified as susceptible to current anthropogenic pressures and lacked formal protection. By providing a framework for broad-scale HCVF monitoring, our approach facilitates integration of HCVF into forest conservation and management. This is urgently needed to achieve the goals of the European Union's Biodiversity Strategy to maintain valuable forest ecosystems., (© 2021 The Authors. Conservation Biology published by Wiley Periodicals LLC on behalf of Society for Conservation Biology.)

Published

2022

3. An integrated framework of plant form and function: the belowground perspective.

Author

Weigelt A, Mommer L, Andraczek K, Iversen CM, Bergmann J, Bruelheide H, Fan Y, Freschet GT, Guerrero-Ramírez NR, Kattge J, Kuyper TW, Laughlin DC, Meier IC, van der Plas F, Poorter H, Roumet C, van Ruijven J, Sabatini FM, Semchenko M, Sweeney CJ, Valverde-Barrantes OJ, York LM, and McCormack ML

Subjects

Phenotype, Plant Leaves, Ecosystem, Plants

Abstract

Plant trait variation drives plant function, community composition and ecosystem processes. However, our current understanding of trait variation disproportionately relies on aboveground observations. Here we integrate root traits into the global framework of plant form and function. We developed and tested an overarching conceptual framework that integrates two recently identified root trait gradients with a well-established aboveground plant trait framework. We confronted our novel framework with published relationships between above- and belowground trait analogues and with multivariate analyses of above- and belowground traits of 2510 species. Our traits represent the leaf and root conservation gradients (specific leaf area, leaf and root nitrogen concentration, and root tissue density), the root collaboration gradient (root diameter and specific root length) and the plant size gradient (plant height and rooting depth). We found that an integrated, whole-plant trait space required as much as four axes. The two main axes represented the fast-slow 'conservation' gradient on which leaf and fine-root traits were well aligned, and the 'collaboration' gradient in roots. The two additional axes were separate, orthogonal plant size axes for height and rooting depth. This perspective on the multidimensional nature of plant trait variation better encompasses plant function and influence on the surrounding environment., (© 2021 The Authors. New Phytologist © 2021 New Phytologist Foundation.)

Published

2021