TY - JOUR
T1 - Invasion impacts and dynamics of a European-wide introduced species
AU - Haubrock, Phillip J.
AU - Ahmed, Danish A.
AU - Cuthbert, Ross N.
AU - Stubbington, Rachel
AU - Domisch, Sami
AU - Marquez, Jaime
AU - Beidas, Ayah
AU - Amatulli, Guiseppe
AU - Shen, Longzhu
AU - Soto, Ismael
AU - Angeler, David
AU - Bonada, Núria
AU - Cañedo-Argüelles, Miguel
AU - Csabai, Zoltán
AU - Datry, Thibault
AU - de Eyto, Elvira
AU - Dohet, Alain
AU - Drohan, Emma
AU - England, Judy
AU - Feio, Maria
AU - Forio, Marie
AU - Goethals, Peter
AU - Graf, Wolfram G
AU - Heino, Jani
AU - Hudgins, Emma
AU - Jähnig, Sonja
AU - Johnson, Richard
AU - Larrañaga, Aitor
AU - Leitner, Patrick
AU - L'Hoste, Lionel
AU - Lizee, Marie-Helene
AU - Maire, Anthony
AU - Rasmussen, Jes
AU - Schäfer, Ralf
AU - Schmidt-Kloiber, Astrid
AU - Vannevel, Rudy
AU - Várbíró, Gábor
AU - Wilberg-Larsen, Peter
AU - Haase, Peter
PY - 2022/5/15
Y1 - 2022/5/15
N2 - Globalization has led to the introduction of thousands of alien species worldwide. With growing impacts by invasive species, understanding the invasion process remains critical for predicting adverse effects and informing efficient management. Theoretically, invasion dynamics have been assumed to follow an “invasion curve” (S‐shaped curve of available area invaded over time), but this dynamic has lacked empirical testing using large‐scale data and neglects to consider invader abundances. We propose an “impact curve” describing the impacts generated by invasive species over time based on cumulative abundances. To test this curve's large‐scale applicability, we used the data‐rich New Zealand mud snail Potamopyrgus antipodarum, one of the most damaging freshwater invaders that has invaded almost all of Europe. Using long‐term (1979–2020) abundance and environmental data collected across 306 European sites, we observed that P. antipodarum abundance generally increased through time, with slower population growth at higher latitudes and with lower runoff depth. Fifty‐nine percent of these populations followed the impact curve, characterized by first occurrence, exponential growth, then long‐term saturation. This behaviour is consistent with boom‐bust dynamics, as saturation occurs due to a rapid decline in abundance over time. Across sites, we estimated that impact peaked approximately two decades after first detection, but the rate of progression along the invasion process was influenced by local abiotic conditions. The S‐shaped impact curve may be common among many invasive species that undergo complex invasion dynamics. This provides a potentially unifying approach to advance understanding of large‐scale invasion dynamics and could inform timely management actions to mitigate impacts on ecosystems and economies.
AB - Globalization has led to the introduction of thousands of alien species worldwide. With growing impacts by invasive species, understanding the invasion process remains critical for predicting adverse effects and informing efficient management. Theoretically, invasion dynamics have been assumed to follow an “invasion curve” (S‐shaped curve of available area invaded over time), but this dynamic has lacked empirical testing using large‐scale data and neglects to consider invader abundances. We propose an “impact curve” describing the impacts generated by invasive species over time based on cumulative abundances. To test this curve's large‐scale applicability, we used the data‐rich New Zealand mud snail Potamopyrgus antipodarum, one of the most damaging freshwater invaders that has invaded almost all of Europe. Using long‐term (1979–2020) abundance and environmental data collected across 306 European sites, we observed that P. antipodarum abundance generally increased through time, with slower population growth at higher latitudes and with lower runoff depth. Fifty‐nine percent of these populations followed the impact curve, characterized by first occurrence, exponential growth, then long‐term saturation. This behaviour is consistent with boom‐bust dynamics, as saturation occurs due to a rapid decline in abundance over time. Across sites, we estimated that impact peaked approximately two decades after first detection, but the rate of progression along the invasion process was influenced by local abiotic conditions. The S‐shaped impact curve may be common among many invasive species that undergo complex invasion dynamics. This provides a potentially unifying approach to advance understanding of large‐scale invasion dynamics and could inform timely management actions to mitigate impacts on ecosystems and economies.
KW - Potamopyrgus antipodarum
KW - RESEARCH ARTICLE
KW - RESEARCH ARTICLES
KW - biological invasion
KW - long‐term time series
KW - rapid response/early detection
KW - temporal modelling
U2 - 10.1111/gcb.16207
DO - 10.1111/gcb.16207
M3 - Article
SN - 1354-1013
JO - Global Change Biology
JF - Global Change Biology
ER -