TY  - JOUR
AU  - Midolo, Gabriele
AU  - Herben, Tomáš
AU  - Axmanová, Irena
AU  - Marcenò, Corrado
AU  - Pätsch, Ricarda
AU  - Bruelheide, Helge
AU  - Karger, Dirk Nikolaus
AU  - Aćić, Svetlana
AU  - Bergamini, Ariel
AU  - Bergmeier, E.
AU  - Biurrun, Erwin
AU  - Bonari, Idoia
AU  - Čarni, Andraž
AU  - Chiarucci, Alessandro
AU  - De Sanctis, Michele
AU  - Demina, Olga
AU  - Dengler, Jürgen
AU  - Dziuba, Tetiana
AU  - Fanelli, Giuliano
AU  - Garbolino, Emmanuel
AU  - Giusso del Galdo, Gianpietro
AU  - Goral, Friedemann
AU  - Güler, Behlül
AU  - Hinojos-Mendoza, Guillermo
AU  - Jansen, Florian
AU  - Jiménez-Alfaro, Borja
AU  - Lengyel, Attila
AU  - Lenoir, Jonathan
AU  - Pérez-Haase, Aaron
AU  - Pielech, Remigiusz
AU  - Prokhorov, Vadim
AU  - Rašomavičius, Valerijus
AU  - Ruprecht, Eszter
AU  - Rūsiņa, Solvita
AU  - Šilc, Urban
AU  - Škvorc, Željko
AU  - Stančić, Zvezdana
AU  - Tatarenko, Irina
AU  - Chytrý, Milan
PY  - 2023
UR  - http://aspace.agrif.bg.ac.rs/handle/123456789/6241
AB  - Motivation: Indicator values are numerical values used to characterize the ecological niches of species and to estimate their occurrence along gradients. Indicator values on climatic and edaphic niches of plant species have received considerable attention in ecological research, whereas data on the optimal positioning of species along disturbance gradients are less developed. Here, we present a new data set of disturbance indicator values identifying optima along gradients of natural and anthropogenic disturbance for 6382 vascular plant species based on the analysis of 736,366 European vegetation plots and using expert-based characterization of disturbance regimes in 236 habitat types. The indicator values presented here are crucial for integrating disturbance niche optima into large-scale vegetation analyses and macroecological studies. Main types of variables contained: We set up five main continuous indicator values for European vascular plants: disturbance severity, disturbance frequency, mowing frequency, grazing pressure and soil disturbance. The first two indicators are provided separately for the whole community and for the herb layer. We calculated the values as the average of expert-based estimates of disturbance values in all habitat types where a species occurs, weighted by the number of plots in which the species occurs within a given habitat type. Spatial location and grain: Europe. Vegetation plots ranging in size from 1 to 1000 m2. Time period and grain: Vegetation plots mostly sampled between 1956 and 2013 (= 5th and 95th quantiles of the sampling year, respectively). Major taxa and level of measurement: Species-level indicator values for vascular plants. Software format: csv file. © 2022 John Wiley & Sons Ltd.
T2  - Global Ecology and Biogeography
T2  - Global Ecology and Biogeography
T1  - Disturbance indicator values for European plants
EP  - 34
IS  - 1
SP  - 24
VL  - 32
DO  - 10.1111/geb.13603
ER  - 

@article{
author = "Midolo, Gabriele and Herben, Tomáš and Axmanová, Irena and Marcenò, Corrado and Pätsch, Ricarda and Bruelheide, Helge and Karger, Dirk Nikolaus and Aćić, Svetlana and Bergamini, Ariel and Bergmeier, E. and Biurrun, Erwin and Bonari, Idoia and Čarni, Andraž and Chiarucci, Alessandro and De Sanctis, Michele and Demina, Olga and Dengler, Jürgen and Dziuba, Tetiana and Fanelli, Giuliano and Garbolino, Emmanuel and Giusso del Galdo, Gianpietro and Goral, Friedemann and Güler, Behlül and Hinojos-Mendoza, Guillermo and Jansen, Florian and Jiménez-Alfaro, Borja and Lengyel, Attila and Lenoir, Jonathan and Pérez-Haase, Aaron and Pielech, Remigiusz and Prokhorov, Vadim and Rašomavičius, Valerijus and Ruprecht, Eszter and Rūsiņa, Solvita and Šilc, Urban and Škvorc, Željko and Stančić, Zvezdana and Tatarenko, Irina and Chytrý, Milan",
year = "2023",
abstract = "Motivation: Indicator values are numerical values used to characterize the ecological niches of species and to estimate their occurrence along gradients. Indicator values on climatic and edaphic niches of plant species have received considerable attention in ecological research, whereas data on the optimal positioning of species along disturbance gradients are less developed. Here, we present a new data set of disturbance indicator values identifying optima along gradients of natural and anthropogenic disturbance for 6382 vascular plant species based on the analysis of 736,366 European vegetation plots and using expert-based characterization of disturbance regimes in 236 habitat types. The indicator values presented here are crucial for integrating disturbance niche optima into large-scale vegetation analyses and macroecological studies. Main types of variables contained: We set up five main continuous indicator values for European vascular plants: disturbance severity, disturbance frequency, mowing frequency, grazing pressure and soil disturbance. The first two indicators are provided separately for the whole community and for the herb layer. We calculated the values as the average of expert-based estimates of disturbance values in all habitat types where a species occurs, weighted by the number of plots in which the species occurs within a given habitat type. Spatial location and grain: Europe. Vegetation plots ranging in size from 1 to 1000 m2. Time period and grain: Vegetation plots mostly sampled between 1956 and 2013 (= 5th and 95th quantiles of the sampling year, respectively). Major taxa and level of measurement: Species-level indicator values for vascular plants. Software format: csv file. © 2022 John Wiley & Sons Ltd.",
journal = "Global Ecology and Biogeography, Global Ecology and Biogeography",
title = "Disturbance indicator values for European plants",
pages = "34-24",
number = "1",
volume = "32",
doi = "10.1111/geb.13603"
}

Midolo, G., Herben, T., Axmanová, I., Marcenò, C., Pätsch, R., Bruelheide, H., Karger, D. N., Aćić, S., Bergamini, A., Bergmeier, E., Biurrun, E., Bonari, I., Čarni, A., Chiarucci, A., De Sanctis, M., Demina, O., Dengler, J., Dziuba, T., Fanelli, G., Garbolino, E., Giusso del Galdo, G., Goral, F., Güler, B., Hinojos-Mendoza, G., Jansen, F., Jiménez-Alfaro, B., Lengyel, A., Lenoir, J., Pérez-Haase, A., Pielech, R., Prokhorov, V., Rašomavičius, V., Ruprecht, E., Rūsiņa, S., Šilc, U., Škvorc, Ž., Stančić, Z., Tatarenko, I.,& Chytrý, M.. (2023). Disturbance indicator values for European plants. in Global Ecology and Biogeography, 32(1), 24-34.
https://doi.org/10.1111/geb.13603

Midolo G, Herben T, Axmanová I, Marcenò C, Pätsch R, Bruelheide H, Karger DN, Aćić S, Bergamini A, Bergmeier E, Biurrun E, Bonari I, Čarni A, Chiarucci A, De Sanctis M, Demina O, Dengler J, Dziuba T, Fanelli G, Garbolino E, Giusso del Galdo G, Goral F, Güler B, Hinojos-Mendoza G, Jansen F, Jiménez-Alfaro B, Lengyel A, Lenoir J, Pérez-Haase A, Pielech R, Prokhorov V, Rašomavičius V, Ruprecht E, Rūsiņa S, Šilc U, Škvorc Ž, Stančić Z, Tatarenko I, Chytrý M. Disturbance indicator values for European plants. in Global Ecology and Biogeography. 2023;32(1):24-34.
doi:10.1111/geb.13603 .

Midolo, Gabriele, Herben, Tomáš, Axmanová, Irena, Marcenò, Corrado, Pätsch, Ricarda, Bruelheide, Helge, Karger, Dirk Nikolaus, Aćić, Svetlana, Bergamini, Ariel, Bergmeier, E., Biurrun, Erwin, Bonari, Idoia, Čarni, Andraž, Chiarucci, Alessandro, De Sanctis, Michele, Demina, Olga, Dengler, Jürgen, Dziuba, Tetiana, Fanelli, Giuliano, Garbolino, Emmanuel, Giusso del Galdo, Gianpietro, Goral, Friedemann, Güler, Behlül, Hinojos-Mendoza, Guillermo, Jansen, Florian, Jiménez-Alfaro, Borja, Lengyel, Attila, Lenoir, Jonathan, Pérez-Haase, Aaron, Pielech, Remigiusz, Prokhorov, Vadim, Rašomavičius, Valerijus, Ruprecht, Eszter, Rūsiņa, Solvita, Šilc, Urban, Škvorc, Željko, Stančić, Zvezdana, Tatarenko, Irina, Chytrý, Milan, "Disturbance indicator values for European plants" in Global Ecology and Biogeography, 32, no. 1 (2023):24-34,
https://doi.org/10.1111/geb.13603 . .

TY  - JOUR
AU  - Sporbert, Maria
AU  - Welk, Erik
AU  - Seidler, Gunnar
AU  - Jandt, Ute
AU  - Aćić, Svetlana
AU  - Biurrun, Idoia
AU  - Campos, Juan Antonio
AU  - Čarni, Andraž
AU  - Cerabolini, Bruno E. L.
AU  - Chytrý, Milan
AU  - Čušterevska, Renata
AU  - Dengler, Jürgen
AU  - De Sanctis, Michele
AU  - Dziuba, Tetiana
AU  - Fagúndez, Jaime
AU  - Field, Richard
AU  - Golub, Valentin
AU  - He, Tianhua
AU  - Jansen, Florian
AU  - Lenoir, Jonathan
AU  - Marcenò, Corrado
AU  - Martín- Forés, Irene
AU  - Erenskjold Moeslund, Jesper
AU  - Moretti, Marco
AU  - Niinemets, Ülo
AU  - Penuelas, Josep
AU  - Pérez- Haase, Aaron
AU  - Vandvik, Vigdis
AU  - Vassilev, Kiril
AU  - Vynokurov, Denys
AU  - Bruelheide, Helge
PY  - 2021
UR  - http://aspace.agrif.bg.ac.rs/handle/123456789/5845
AB  - Plant functional traits summarize the main variability in plant form and function across taxa and biomes. We assess whether geographic range size, climatic niche size, and local abundance of plants can be predicted by sets of traits (trait syndromes) or are driven by single traits. Location: Eurasia. Methods: Species distribution maps were extracted from the Chorological Database Halle to derive information on the geographic range size and climatic niche size for 456 herbaceous, dwarf shrub and shrub species. We estimated local species abundances based on 740,113 vegetation plots from the European Vegetation Archive, where abundances were available as plant species cover per plot. We compiled a complete species-by-trait matrix of 20 plant functional traits from trait databases (TRY, BiolFlor and CLO-PLA). The relationships of species’ geographic range size, climatic niche size and local abundance with single traits and trait syndromes were tested with multiple linear regression models. Results: Generally, traits were more strongly related to local abundances than to broad-scale species distribution patterns in geographic and climatic space (range and niche size), but both were better predicted by trait combinations than by single traits. Local abundance increased with leaf area and specific leaf area (SLA). Geographic range size and climatic niche size both increased with SLA. While range size increased with plant height, niche size decreased with leaf carbon content. Conclusion: Functional traits matter for species’ abundance and distribution at both local and broad geographic scale. Local abundances are associated with different combinations of traits as compared to broad-scale distributions, pointing to filtering by different environmental and ecological factors acting at distinct spatial scales. However, traits related to the leaf economics spectrum were important for species’ abundance and occurrence at both spatial scales. This finding emphasizes the general importance of resource acquisition strategies for the abundance and distribution of herbaceous, dwarf shrub and shrub species.
PB  - John Wiley and Sons Inc
T2  - Journal of Vegetation Science
T1  - Different sets of traits explain abundance and distribution patterns of European plants at different spatial scales
IS  - 2
SP  - e13016
VL  - 32
DO  - 10.1111/jvs.13016
ER  - 

@article{
author = "Sporbert, Maria and Welk, Erik and Seidler, Gunnar and Jandt, Ute and Aćić, Svetlana and Biurrun, Idoia and Campos, Juan Antonio and Čarni, Andraž and Cerabolini, Bruno E. L. and Chytrý, Milan and Čušterevska, Renata and Dengler, Jürgen and De Sanctis, Michele and Dziuba, Tetiana and Fagúndez, Jaime and Field, Richard and Golub, Valentin and He, Tianhua and Jansen, Florian and Lenoir, Jonathan and Marcenò, Corrado and Martín- Forés, Irene and Erenskjold Moeslund, Jesper and Moretti, Marco and Niinemets, Ülo and Penuelas, Josep and Pérez- Haase, Aaron and Vandvik, Vigdis and Vassilev, Kiril and Vynokurov, Denys and Bruelheide, Helge",
year = "2021",
abstract = "Plant functional traits summarize the main variability in plant form and function across taxa and biomes. We assess whether geographic range size, climatic niche size, and local abundance of plants can be predicted by sets of traits (trait syndromes) or are driven by single traits. Location: Eurasia. Methods: Species distribution maps were extracted from the Chorological Database Halle to derive information on the geographic range size and climatic niche size for 456 herbaceous, dwarf shrub and shrub species. We estimated local species abundances based on 740,113 vegetation plots from the European Vegetation Archive, where abundances were available as plant species cover per plot. We compiled a complete species-by-trait matrix of 20 plant functional traits from trait databases (TRY, BiolFlor and CLO-PLA). The relationships of species’ geographic range size, climatic niche size and local abundance with single traits and trait syndromes were tested with multiple linear regression models. Results: Generally, traits were more strongly related to local abundances than to broad-scale species distribution patterns in geographic and climatic space (range and niche size), but both were better predicted by trait combinations than by single traits. Local abundance increased with leaf area and specific leaf area (SLA). Geographic range size and climatic niche size both increased with SLA. While range size increased with plant height, niche size decreased with leaf carbon content. Conclusion: Functional traits matter for species’ abundance and distribution at both local and broad geographic scale. Local abundances are associated with different combinations of traits as compared to broad-scale distributions, pointing to filtering by different environmental and ecological factors acting at distinct spatial scales. However, traits related to the leaf economics spectrum were important for species’ abundance and occurrence at both spatial scales. This finding emphasizes the general importance of resource acquisition strategies for the abundance and distribution of herbaceous, dwarf shrub and shrub species.",
publisher = "John Wiley and Sons Inc",
journal = "Journal of Vegetation Science",
title = "Different sets of traits explain abundance and distribution patterns of European plants at different spatial scales",
number = "2",
pages = "e13016",
volume = "32",
doi = "10.1111/jvs.13016"
}

Sporbert, M., Welk, E., Seidler, G., Jandt, U., Aćić, S., Biurrun, I., Campos, J. A., Čarni, A., Cerabolini, B. E. L., Chytrý, M., Čušterevska, R., Dengler, J., De Sanctis, M., Dziuba, T., Fagúndez, J., Field, R., Golub, V., He, T., Jansen, F., Lenoir, J., Marcenò, C., Martín- Forés, I., Erenskjold Moeslund, J., Moretti, M., Niinemets, Ü., Penuelas, J., Pérez- Haase, A., Vandvik, V., Vassilev, K., Vynokurov, D.,& Bruelheide, H.. (2021). Different sets of traits explain abundance and distribution patterns of European plants at different spatial scales. in Journal of Vegetation Science
John Wiley and Sons Inc., 32(2), e13016.
https://doi.org/10.1111/jvs.13016

Sporbert M, Welk E, Seidler G, Jandt U, Aćić S, Biurrun I, Campos JA, Čarni A, Cerabolini BEL, Chytrý M, Čušterevska R, Dengler J, De Sanctis M, Dziuba T, Fagúndez J, Field R, Golub V, He T, Jansen F, Lenoir J, Marcenò C, Martín- Forés I, Erenskjold Moeslund J, Moretti M, Niinemets Ü, Penuelas J, Pérez- Haase A, Vandvik V, Vassilev K, Vynokurov D, Bruelheide H. Different sets of traits explain abundance and distribution patterns of European plants at different spatial scales. in Journal of Vegetation Science. 2021;32(2):e13016.
doi:10.1111/jvs.13016 .

Sporbert, Maria, Welk, Erik, Seidler, Gunnar, Jandt, Ute, Aćić, Svetlana, Biurrun, Idoia, Campos, Juan Antonio, Čarni, Andraž, Cerabolini, Bruno E. L., Chytrý, Milan, Čušterevska, Renata, Dengler, Jürgen, De Sanctis, Michele, Dziuba, Tetiana, Fagúndez, Jaime, Field, Richard, Golub, Valentin, He, Tianhua, Jansen, Florian, Lenoir, Jonathan, Marcenò, Corrado, Martín- Forés, Irene, Erenskjold Moeslund, Jesper, Moretti, Marco, Niinemets, Ülo, Penuelas, Josep, Pérez- Haase, Aaron, Vandvik, Vigdis, Vassilev, Kiril, Vynokurov, Denys, Bruelheide, Helge, "Different sets of traits explain abundance and distribution patterns of European plants at different spatial scales" in Journal of Vegetation Science, 32, no. 2 (2021):e13016,
https://doi.org/10.1111/jvs.13016 . .

TY  - JOUR
AU  - Pouteau, Robin
AU  - Thuiller, Wilfried
AU  - Hobohm, Carsten
AU  - Brunel, Caroline
AU  - Conn, Barry J.
AU  - Dawson, Wayne
AU  - de Sá Dechoum, Michele
AU  - Ebel, Aleksandr L.
AU  - Essl, Franz
AU  - Fragman-Sapir, Ori
AU  - Fristoe, Trevor
AU  - Jogan, Nejc
AU  - Kreft, Holger
AU  - Lenzner, Bernd
AU  - Meyer, Carsten
AU  - Pergl, Jan
AU  - Pyšek, Petr
AU  - Verkhozina, Alla
AU  - Weigelt, Patrick
AU  - Yang, Qiang
AU  - Zykova, Elena
AU  - Aćić, Svetlana
AU  - Agrillo, Emiliano
AU  - Attorre, Fabio
AU  - Bergamini, Ariel
AU  - Berg, Christian
AU  - Bergmeier, Erwin
AU  - Biurrun, Idoia
AU  - Boch, Steffen
AU  - Bonari, Gianmaria
AU  - Botta-Dukát, Zoltán
AU  - Bruelheide, Helge
AU  - Campos, Juan Antonio
AU  - Čarni, Andraž
AU  - Casella, Laura
AU  - Carranza, Maria Laura
AU  - Chytrý, Milan
AU  - Čušterevska, Renata
AU  - De Sanctis, Michele
AU  - Dengler, Jürgen
AU  - Dimopoulos, Panayotis
AU  - Ejrnæs, Rasmus
AU  - Ewald, Jörg
AU  - Fanelli, Giuliano
AU  - Fernández-González, Federico
AU  - Gavilán, Rosario G.
AU  - Gegout, Jean-Claude
AU  - Haveman, Rense
AU  - Isermann, Maike
AU  - Jandt, Ute
AU  - Jansen, Florian
AU  - Jiménez-Alfaro, Borja
AU  - Kavgaci, Ali
AU  - Khanina, Larisa
AU  - Knollová, Ilona
AU  - Kuzemko, Anna
AU  - Lebedeva, Maria
AU  - Lenoir, Jonathan
AU  - Lysenko, Tatiana
AU  - Marcenò, Corrado
AU  - Martynenko, Vasiliy
AU  - Erenskjold Moeslund, Jesper
AU  - Pätsch, Ricarda
AU  - Pielech, Remigiusz
AU  - Rašomavičius, Valerijus
AU  - de Ronde, Iris
AU  - Ruprecht, Eszter
AU  - Rusina, Solvita
AU  - Shirokikh, Pavel
AU  - Šibík, Jozef
AU  - Šilc, Urban
AU  - Stanisci, Angela
AU  - Stančić, Stančić
AU  - Svenning, Jens-Christian
AU  - Swacha, Grzegorz
AU  - Dan Turtureanu, Pavel
AU  - Valachovič, Milan
AU  - Vassilev, Kiril
AU  - Yamalov, Sergey
AU  - van Kleunen, Mark
PY  - 2021
UR  - http://aspace.agrif.bg.ac.rs/handle/123456789/5872
AB  - The number of naturalized (i.e. established) alien species has increased rapidly over recent centuries. Given the differences in environmental tolerances among species, little is known about what factors determine the extent to which the observed size of the naturalized range of a species and hence the extent to which the observed richness of naturalized species of a region approach their full potential. Here, we asked which region- and species-specific characteristics explain differences between observed and expected naturalizations. Location: Global. Time period: Present. Major taxa studied: Vascular plants. Methods: We determined the observed naturalized distribution outside Europe for 1,485 species endemic to Europe using the Global Naturalized Alien Flora (GloNAF) database and their expected distributions outside Europe using species distribution models. First, we investigated which of seven socio-economic factors related to introduction pathways, anthropogenic pressures and inventory effort best explained the differences between observed and expected naturalized European floras. Second, we examined whether distributional features, economic use and functional traits explain the extent to which species have filled their expected ranges outside Europe. Results: In terms of suitable area, more than 95% of expected naturalizations of European plants were not yet observed. Species were naturalized in only 4.2% of their suitable regions outside of Europe (range filling) and in 0.4% of their unsuitable regions (range expansion). Anthropogenic habitat disturbance primarily explained the difference between observed and expected naturalized European floras, as did the number of treaties relevant to invasive species. Species of ornamental and economic value and with large specific leaf area performed better at filling and expanding beyond their expected range. Main conclusions: The naturalization of alien plant species is explained by climate matching but also by the regional level of human development, the introduction pressure associated with the ornamental and economic values of the species and their adaptation to disturbed environments.
PB  - Blackwell Publishing Ltd
T2  - Global Ecology and Biogeography
T1  - Climate and socio- economic factors explain differences between observed and expected naturalization patterns of European plants around the world
EP  - 1531
IS  - 7
SP  - 1514
VL  - 30
DO  - 10.1111/geb.13316
ER  - 

@article{
author = "Pouteau, Robin and Thuiller, Wilfried and Hobohm, Carsten and Brunel, Caroline and Conn, Barry J. and Dawson, Wayne and de Sá Dechoum, Michele and Ebel, Aleksandr L. and Essl, Franz and Fragman-Sapir, Ori and Fristoe, Trevor and Jogan, Nejc and Kreft, Holger and Lenzner, Bernd and Meyer, Carsten and Pergl, Jan and Pyšek, Petr and Verkhozina, Alla and Weigelt, Patrick and Yang, Qiang and Zykova, Elena and Aćić, Svetlana and Agrillo, Emiliano and Attorre, Fabio and Bergamini, Ariel and Berg, Christian and Bergmeier, Erwin and Biurrun, Idoia and Boch, Steffen and Bonari, Gianmaria and Botta-Dukát, Zoltán and Bruelheide, Helge and Campos, Juan Antonio and Čarni, Andraž and Casella, Laura and Carranza, Maria Laura and Chytrý, Milan and Čušterevska, Renata and De Sanctis, Michele and Dengler, Jürgen and Dimopoulos, Panayotis and Ejrnæs, Rasmus and Ewald, Jörg and Fanelli, Giuliano and Fernández-González, Federico and Gavilán, Rosario G. and Gegout, Jean-Claude and Haveman, Rense and Isermann, Maike and Jandt, Ute and Jansen, Florian and Jiménez-Alfaro, Borja and Kavgaci, Ali and Khanina, Larisa and Knollová, Ilona and Kuzemko, Anna and Lebedeva, Maria and Lenoir, Jonathan and Lysenko, Tatiana and Marcenò, Corrado and Martynenko, Vasiliy and Erenskjold Moeslund, Jesper and Pätsch, Ricarda and Pielech, Remigiusz and Rašomavičius, Valerijus and de Ronde, Iris and Ruprecht, Eszter and Rusina, Solvita and Shirokikh, Pavel and Šibík, Jozef and Šilc, Urban and Stanisci, Angela and Stančić, Stančić and Svenning, Jens-Christian and Swacha, Grzegorz and Dan Turtureanu, Pavel and Valachovič, Milan and Vassilev, Kiril and Yamalov, Sergey and van Kleunen, Mark",
year = "2021",
abstract = "The number of naturalized (i.e. established) alien species has increased rapidly over recent centuries. Given the differences in environmental tolerances among species, little is known about what factors determine the extent to which the observed size of the naturalized range of a species and hence the extent to which the observed richness of naturalized species of a region approach their full potential. Here, we asked which region- and species-specific characteristics explain differences between observed and expected naturalizations. Location: Global. Time period: Present. Major taxa studied: Vascular plants. Methods: We determined the observed naturalized distribution outside Europe for 1,485 species endemic to Europe using the Global Naturalized Alien Flora (GloNAF) database and their expected distributions outside Europe using species distribution models. First, we investigated which of seven socio-economic factors related to introduction pathways, anthropogenic pressures and inventory effort best explained the differences between observed and expected naturalized European floras. Second, we examined whether distributional features, economic use and functional traits explain the extent to which species have filled their expected ranges outside Europe. Results: In terms of suitable area, more than 95% of expected naturalizations of European plants were not yet observed. Species were naturalized in only 4.2% of their suitable regions outside of Europe (range filling) and in 0.4% of their unsuitable regions (range expansion). Anthropogenic habitat disturbance primarily explained the difference between observed and expected naturalized European floras, as did the number of treaties relevant to invasive species. Species of ornamental and economic value and with large specific leaf area performed better at filling and expanding beyond their expected range. Main conclusions: The naturalization of alien plant species is explained by climate matching but also by the regional level of human development, the introduction pressure associated with the ornamental and economic values of the species and their adaptation to disturbed environments.",
publisher = "Blackwell Publishing Ltd",
journal = "Global Ecology and Biogeography",
title = "Climate and socio- economic factors explain differences between observed and expected naturalization patterns of European plants around the world",
pages = "1531-1514",
number = "7",
volume = "30",
doi = "10.1111/geb.13316"
}

Pouteau, R., Thuiller, W., Hobohm, C., Brunel, C., Conn, B. J., Dawson, W., de Sá Dechoum, M., Ebel, A. L., Essl, F., Fragman-Sapir, O., Fristoe, T., Jogan, N., Kreft, H., Lenzner, B., Meyer, C., Pergl, J., Pyšek, P., Verkhozina, A., Weigelt, P., Yang, Q., Zykova, E., Aćić, S., Agrillo, E., Attorre, F., Bergamini, A., Berg, C., Bergmeier, E., Biurrun, I., Boch, S., Bonari, G., Botta-Dukát, Z., Bruelheide, H., Campos, J. A., Čarni, A., Casella, L., Carranza, M. L., Chytrý, M., Čušterevska, R., De Sanctis, M., Dengler, J., Dimopoulos, P., Ejrnæs, R., Ewald, J., Fanelli, G., Fernández-González, F., Gavilán, R. G., Gegout, J., Haveman, R., Isermann, M., Jandt, U., Jansen, F., Jiménez-Alfaro, B., Kavgaci, A., Khanina, L., Knollová, I., Kuzemko, A., Lebedeva, M., Lenoir, J., Lysenko, T., Marcenò, C., Martynenko, V., Erenskjold Moeslund, J., Pätsch, R., Pielech, R., Rašomavičius, V., de Ronde, I., Ruprecht, E., Rusina, S., Shirokikh, P., Šibík, J., Šilc, U., Stanisci, A., Stančić, S., Svenning, J., Swacha, G., Dan Turtureanu, P., Valachovič, M., Vassilev, K., Yamalov, S.,& van Kleunen, M.. (2021). Climate and socio- economic factors explain differences between observed and expected naturalization patterns of European plants around the world. in Global Ecology and Biogeography
Blackwell Publishing Ltd., 30(7), 1514-1531.
https://doi.org/10.1111/geb.13316

Pouteau R, Thuiller W, Hobohm C, Brunel C, Conn BJ, Dawson W, de Sá Dechoum M, Ebel AL, Essl F, Fragman-Sapir O, Fristoe T, Jogan N, Kreft H, Lenzner B, Meyer C, Pergl J, Pyšek P, Verkhozina A, Weigelt P, Yang Q, Zykova E, Aćić S, Agrillo E, Attorre F, Bergamini A, Berg C, Bergmeier E, Biurrun I, Boch S, Bonari G, Botta-Dukát Z, Bruelheide H, Campos JA, Čarni A, Casella L, Carranza ML, Chytrý M, Čušterevska R, De Sanctis M, Dengler J, Dimopoulos P, Ejrnæs R, Ewald J, Fanelli G, Fernández-González F, Gavilán RG, Gegout J, Haveman R, Isermann M, Jandt U, Jansen F, Jiménez-Alfaro B, Kavgaci A, Khanina L, Knollová I, Kuzemko A, Lebedeva M, Lenoir J, Lysenko T, Marcenò C, Martynenko V, Erenskjold Moeslund J, Pätsch R, Pielech R, Rašomavičius V, de Ronde I, Ruprecht E, Rusina S, Shirokikh P, Šibík J, Šilc U, Stanisci A, Stančić S, Svenning J, Swacha G, Dan Turtureanu P, Valachovič M, Vassilev K, Yamalov S, van Kleunen M. Climate and socio- economic factors explain differences between observed and expected naturalization patterns of European plants around the world. in Global Ecology and Biogeography. 2021;30(7):1514-1531.
doi:10.1111/geb.13316 .

Pouteau, Robin, Thuiller, Wilfried, Hobohm, Carsten, Brunel, Caroline, Conn, Barry J., Dawson, Wayne, de Sá Dechoum, Michele, Ebel, Aleksandr L., Essl, Franz, Fragman-Sapir, Ori, Fristoe, Trevor, Jogan, Nejc, Kreft, Holger, Lenzner, Bernd, Meyer, Carsten, Pergl, Jan, Pyšek, Petr, Verkhozina, Alla, Weigelt, Patrick, Yang, Qiang, Zykova, Elena, Aćić, Svetlana, Agrillo, Emiliano, Attorre, Fabio, Bergamini, Ariel, Berg, Christian, Bergmeier, Erwin, Biurrun, Idoia, Boch, Steffen, Bonari, Gianmaria, Botta-Dukát, Zoltán, Bruelheide, Helge, Campos, Juan Antonio, Čarni, Andraž, Casella, Laura, Carranza, Maria Laura, Chytrý, Milan, Čušterevska, Renata, De Sanctis, Michele, Dengler, Jürgen, Dimopoulos, Panayotis, Ejrnæs, Rasmus, Ewald, Jörg, Fanelli, Giuliano, Fernández-González, Federico, Gavilán, Rosario G., Gegout, Jean-Claude, Haveman, Rense, Isermann, Maike, Jandt, Ute, Jansen, Florian, Jiménez-Alfaro, Borja, Kavgaci, Ali, Khanina, Larisa, Knollová, Ilona, Kuzemko, Anna, Lebedeva, Maria, Lenoir, Jonathan, Lysenko, Tatiana, Marcenò, Corrado, Martynenko, Vasiliy, Erenskjold Moeslund, Jesper, Pätsch, Ricarda, Pielech, Remigiusz, Rašomavičius, Valerijus, de Ronde, Iris, Ruprecht, Eszter, Rusina, Solvita, Shirokikh, Pavel, Šibík, Jozef, Šilc, Urban, Stanisci, Angela, Stančić, Stančić, Svenning, Jens-Christian, Swacha, Grzegorz, Dan Turtureanu, Pavel, Valachovič, Milan, Vassilev, Kiril, Yamalov, Sergey, van Kleunen, Mark, "Climate and socio- economic factors explain differences between observed and expected naturalization patterns of European plants around the world" in Global Ecology and Biogeography, 30, no. 7 (2021):1514-1531,
https://doi.org/10.1111/geb.13316 . .

TY  - JOUR
AU  - Večera, Martin
AU  - Axmanová, Irena
AU  - Padullés Cubino, Josep
AU  - Lososova, Zdenka
AU  - Divišek, Jan
AU  - Knollová, Ilona
AU  - Aćić, Svetlana
AU  - Biurrun, Idoia
AU  - Boch, Steffen
AU  - Bonari, Gianmaria
AU  - Campos, Juan Antonio
AU  - Čarni, Andraž
AU  - Carranza, Maria Laura
AU  - Casella, Laura
AU  - Chiarucci, Alessandro
AU  - Čušterevska, Renata
AU  - Delbosc, Pauline
AU  - Dengler, Jürgen
AU  - Fernández-González, Federico
AU  - Gégout, Jean-Claude
AU  - Jandt, Ute
AU  - Jansen, Florian
AU  - Jaškova, Anni
AU  - Jiménez-Alfaro, Borja
AU  - Kuzemko, Anna
AU  - Lebedeva, Maria
AU  - Lenoir, Jonathan
AU  - Lysenko, Tatiana
AU  - Erenskjold Moeslund, Jesper
AU  - Pielech, Remigiusz
AU  - Ruprecht, Eszter
AU  - Šibík, Jozef
AU  - Šilc, Urban
AU  - Škvorc, Željko
AU  - Swacha, Grzegorz
AU  - Tatarenko, Irina
AU  - Vassilev, Kiril
AU  - Wohlgemuth, Thomas
AU  - Yamalov, Sergey
AU  - Chytrý, Milan
PY  - 2021
UR  - http://aspace.agrif.bg.ac.rs/handle/123456789/5890
AB  - Biodiversity is traditionally studied mostly at the species level, but biogeographical and macroecological studies at higher taxonomic levels can provide valuable insights into the evolutionary processes at large spatial scales. Our aim was to assess the representation of vascular plant families within different vegetation formations across Europe. Location: Europe. Methods: We used a data set of 816,005 vegetation plots from the European Vegetation Archive (EVA). For each plot, we calculated the relative species richness of each plant family as the number of species belonging to that family divided by the total number of species. We mapped the relative species richness, averaged across all plots in 50 km × 50 km grid cells, for each family and broad habitat groups: forests, grasslands, scrub and wetlands. We also calculated the absolute species richness and the Shannon diversity index for each family. Results: We produced 522 maps of mean relative species richness for a total of 152 vascular plant families occurring in forests, grasslands, scrub and wetlands. We found distinct spatial patterns for many combinations of families and habitat groups. The resulting series of 522 maps is freely available, both as images and GIS layers. Conclusions: The distinct spatial patterns revealed in the maps suggest that the relative species richness of plant families at the community level reflects the evolutionary history of individual families. We believe that the maps and associated data can inspire further biogeographical and macroecological studies and strengthen the ongoing integration of phylogenetic, functional and taxonomic diversity concepts.
PB  - John Wiley and Sons Inc
T2  - Journal of Vegetation Science
T1  - Mapping species richness of plant families in European vegetation
IS  - 3
SP  - e13035
VL  - 32
DO  - 10.1111/jvs.13035
ER  - 

@article{
author = "Večera, Martin and Axmanová, Irena and Padullés Cubino, Josep and Lososova, Zdenka and Divišek, Jan and Knollová, Ilona and Aćić, Svetlana and Biurrun, Idoia and Boch, Steffen and Bonari, Gianmaria and Campos, Juan Antonio and Čarni, Andraž and Carranza, Maria Laura and Casella, Laura and Chiarucci, Alessandro and Čušterevska, Renata and Delbosc, Pauline and Dengler, Jürgen and Fernández-González, Federico and Gégout, Jean-Claude and Jandt, Ute and Jansen, Florian and Jaškova, Anni and Jiménez-Alfaro, Borja and Kuzemko, Anna and Lebedeva, Maria and Lenoir, Jonathan and Lysenko, Tatiana and Erenskjold Moeslund, Jesper and Pielech, Remigiusz and Ruprecht, Eszter and Šibík, Jozef and Šilc, Urban and Škvorc, Željko and Swacha, Grzegorz and Tatarenko, Irina and Vassilev, Kiril and Wohlgemuth, Thomas and Yamalov, Sergey and Chytrý, Milan",
year = "2021",
abstract = "Biodiversity is traditionally studied mostly at the species level, but biogeographical and macroecological studies at higher taxonomic levels can provide valuable insights into the evolutionary processes at large spatial scales. Our aim was to assess the representation of vascular plant families within different vegetation formations across Europe. Location: Europe. Methods: We used a data set of 816,005 vegetation plots from the European Vegetation Archive (EVA). For each plot, we calculated the relative species richness of each plant family as the number of species belonging to that family divided by the total number of species. We mapped the relative species richness, averaged across all plots in 50 km × 50 km grid cells, for each family and broad habitat groups: forests, grasslands, scrub and wetlands. We also calculated the absolute species richness and the Shannon diversity index for each family. Results: We produced 522 maps of mean relative species richness for a total of 152 vascular plant families occurring in forests, grasslands, scrub and wetlands. We found distinct spatial patterns for many combinations of families and habitat groups. The resulting series of 522 maps is freely available, both as images and GIS layers. Conclusions: The distinct spatial patterns revealed in the maps suggest that the relative species richness of plant families at the community level reflects the evolutionary history of individual families. We believe that the maps and associated data can inspire further biogeographical and macroecological studies and strengthen the ongoing integration of phylogenetic, functional and taxonomic diversity concepts.",
publisher = "John Wiley and Sons Inc",
journal = "Journal of Vegetation Science",
title = "Mapping species richness of plant families in European vegetation",
number = "3",
pages = "e13035",
volume = "32",
doi = "10.1111/jvs.13035"
}

Večera, M., Axmanová, I., Padullés Cubino, J., Lososova, Z., Divišek, J., Knollová, I., Aćić, S., Biurrun, I., Boch, S., Bonari, G., Campos, J. A., Čarni, A., Carranza, M. L., Casella, L., Chiarucci, A., Čušterevska, R., Delbosc, P., Dengler, J., Fernández-González, F., Gégout, J., Jandt, U., Jansen, F., Jaškova, A., Jiménez-Alfaro, B., Kuzemko, A., Lebedeva, M., Lenoir, J., Lysenko, T., Erenskjold Moeslund, J., Pielech, R., Ruprecht, E., Šibík, J., Šilc, U., Škvorc, Ž., Swacha, G., Tatarenko, I., Vassilev, K., Wohlgemuth, T., Yamalov, S.,& Chytrý, M.. (2021). Mapping species richness of plant families in European vegetation. in Journal of Vegetation Science
John Wiley and Sons Inc., 32(3), e13035.
https://doi.org/10.1111/jvs.13035

Večera M, Axmanová I, Padullés Cubino J, Lososova Z, Divišek J, Knollová I, Aćić S, Biurrun I, Boch S, Bonari G, Campos JA, Čarni A, Carranza ML, Casella L, Chiarucci A, Čušterevska R, Delbosc P, Dengler J, Fernández-González F, Gégout J, Jandt U, Jansen F, Jaškova A, Jiménez-Alfaro B, Kuzemko A, Lebedeva M, Lenoir J, Lysenko T, Erenskjold Moeslund J, Pielech R, Ruprecht E, Šibík J, Šilc U, Škvorc Ž, Swacha G, Tatarenko I, Vassilev K, Wohlgemuth T, Yamalov S, Chytrý M. Mapping species richness of plant families in European vegetation. in Journal of Vegetation Science. 2021;32(3):e13035.
doi:10.1111/jvs.13035 .

Večera, Martin, Axmanová, Irena, Padullés Cubino, Josep, Lososova, Zdenka, Divišek, Jan, Knollová, Ilona, Aćić, Svetlana, Biurrun, Idoia, Boch, Steffen, Bonari, Gianmaria, Campos, Juan Antonio, Čarni, Andraž, Carranza, Maria Laura, Casella, Laura, Chiarucci, Alessandro, Čušterevska, Renata, Delbosc, Pauline, Dengler, Jürgen, Fernández-González, Federico, Gégout, Jean-Claude, Jandt, Ute, Jansen, Florian, Jaškova, Anni, Jiménez-Alfaro, Borja, Kuzemko, Anna, Lebedeva, Maria, Lenoir, Jonathan, Lysenko, Tatiana, Erenskjold Moeslund, Jesper, Pielech, Remigiusz, Ruprecht, Eszter, Šibík, Jozef, Šilc, Urban, Škvorc, Željko, Swacha, Grzegorz, Tatarenko, Irina, Vassilev, Kiril, Wohlgemuth, Thomas, Yamalov, Sergey, Chytrý, Milan, "Mapping species richness of plant families in European vegetation" in Journal of Vegetation Science, 32, no. 3 (2021):e13035,
https://doi.org/10.1111/jvs.13035 . .