Abstract
Marine populations are controlled by a series of drivers, pertaining to both the physical environment and the biological environment (trophic predator-prey interactions). There is heated debate over drivers, especially when trying to understand the causes of major ecosystem events termed regime shifts. In this work, we have researched and developed a novel methodology based on Genetic Programming (GP) for distinguishing which drivers can influence species abundance. This methodology benefits of having no a priori assumptions either on the ecological parameters used or on the underlying mathematical relationships among them. We have validated this methodology applying it to the North Sea pelagic ecosystem. We use the target species Calanus finmarchicus, a key copepod in temperate and subarctic ecosystems, along with 86 biological, hydrographical and climatic time series, ranging from local water nutrients and fish predation, to large scale climate pressure patterns. The chosen study area is the central North Sea, from 1972 to 2011, during which period there was an ecological regime shift. The GP based analysis identified 3 likely drivers of C. finmarchicus abundance, which highlights the importance of considering both physical and trophic drivers: temperature, North Sea circulation (net flow into the North Atlantic), and predation (herring). No large scale climate patterns were selected, suggesting that when there is availability of both data types, local drivers are more important. The results produced by the GP based procedure are consistent with the literature published to date, and validate the use of GP for interpreting species dynamics. We propose that this methodology holds promises for the highly non-linear field of ecology.
Highlights
Ecosystems dynamics are an integrated response of the ecosystem’s biological components to drivers, which act independently, synergistically or even antagonistically [1, 2]
We have used Genetic Programming (GP) to identify the variables that are relevant for approximating the abundance of Calanus finmarchicus in the North Sea, using 86 biological and physical variables, chosen because they are potential drivers of C. finmarchicus
This study has shown how the Genetic Programming based methodology can select a small number of variables from a large initial pool
Summary
Ecosystems dynamics are an integrated response of the ecosystem’s biological components (species/groups) to drivers, which act independently, synergistically or even antagonistically [1, 2]. These drivers are defined as any natural or human-induced factor that directly or indirectly causes a change in an ecosystem or population [3]. In this article we use Conversi et al [2] definitions of drivers: “physical drivers”, which are related to the physical environment, and “trophic” (or “biological”) drivers, which are related to predator-prey interactions. The latter are subdivided in bottom-up and top-down drivers
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