Exotic invasive species are considered one of the largest threat to biodiversity worldwide, and the impact is expected to further increase under global climate change. Moreover, ecosystem invasion by exotic plant species may cause marked changes in biogeochemical cycles and ecosystems functioning, thereby accelerating environmental change.
However, the processes and characteristics which turn an introduced exotic species into an aggressive invader allowing its dominance the invaded ecosystems is still an open question. Similarly, were little is known on the functional changes that these ecosystem engineers induce in the invaded systems.
These questions are explored in a case study of a non-native resource-demanding acacia: Acacia longifolia, native to Australia, successfully invades water-limited sand dune systems worldwide with large ecological and economic impact. This drought-susceptible N-fixer follows a water spender strategy and exhibit different functional traits compared to native Mediterranean species. In the invaded systems acacia markedly altered the ecosystem structure, water balance, carbon gain and N-cycle of the native vegetation (Rascher et al. 2011, 2012). Hence, exotic species can have significant impacts on hydrological cycle in resource-limited semi-arid ecosystems through a repartitioning of water resources between the native and invasive species. Moreover, the introduction of novel traits into a community like high resource use (water spender) and N-fixation can promote invasiveness through changes in the water and nutrient cycle of the invaded system, thereby potentially disrupting the co-evolved interactions within the native plant community. This may have broad implications for the sustainability of Mediterranean dune forests in the future, since water is predicted to be an increasingly limited resource under climate change scenarios.
Rascher et al. 2011, Understory invasion by Acacia longifolia alters the water balance and carbon gain of a Mediterranean pine forest. Ecosystems 14: 904–919 (doi:10.1007/s10021-011-9453-7)
Rascher et al. 2012, Community scale 15N isoscapes: tracing the spatial impact of an exotic N2-fixing invader. Ecology Letters, 15: 484–491, doi10.1111/j.1461-0248.2012.01761.x
Antrittsvorlesung von Juniorprofessorin Dr. Johanna Pausch (Agrarökologie)
How to tackle nonlinear and disequilibrium responses in ecology and environmental research
New aspects of microbial sulfur cycling: from novel sulfate reducers to pyrite-forming microorganisms
Microbial storage compounds in soil: a neglected dimension of the carbon cycle
High resolution mass spectrometry in environmental sciences and beyond.