Abstract
It is well known that human activities, such as harvesting, have had major direct effects on marine ecosystems. However, it is far less acknowledged that human activities in the surroundings might have important effects on marine systems. There is growing evidence suggesting that major reorganization (i.e., a regime shift) is a common feature in the temporal evolution of a marine system. Here we show, and quantify, the interaction of human activities (nutrient upload) with a favourable climate (run-off) and its contribution to the eutrophication of the Black Sea in the 1980s. Based on virtual analysis of the bottom-up (eutrophication) vs. top-down (trophic cascades) effects, we found that an earlier onset of eutrophication could have counteracted the restructuring of the trophic regulation at the base of the food web that resulted from the depletion of top predators in the 1970s. These enhanced bottom-up effects would, however, not propagate upwards in the food web beyond the zooplankton level. Our simulations identified the removal of apex predators as a key element in terms of loss of resilience that inevitably leads to a reorganization. Once the food web has been truncated, the type and magnitude of interventions on the group replacing the apex predator as the new upper trophic level have no effect in preventing the trophic cascade. By characterizing the tipping point at which increased bottom-up forcing exactly counteracts the top-down cascading effects, our results emphasize the importance of a comprehensive analysis that take into account all structuring forces at play (including those beyond the marine system) at a given time.
Highlights
The Black Sea is a deep, mostly land-locked, basin in Eastern Europe
Based on virtual analysis of the bottom-up vs. top-down effects, we found that an earlier onset of eutrophication could have counteracted the restructuring of the trophic regulation at the base of the food web that resulted from the depletion of top predators in the 1970s
The most appropriate model structure found for each trophic level is shown below [Eqns (1)–(4)], where siðÁ; ÁÞ denote nonparametric smooth functions with the first argument enclosed in the parentheses being the covariate and the second argument the estimated degrees of freedom of the splines
Summary
The Black Sea is a deep, mostly land-locked, basin in Eastern Europe. The surrounding land area entertains intensive human activities and has experienced profound economical and societal changes in the formerly communist countries. That the Black Sea has undergone dramatic environmental changes in recent decades underlies its importance as a ‘natural laboratory’ for studying marine ecosystem dynamics (Mee et al, 2005; Daskalov et al, 2007; Oguz & Gilbert, 2007). The Black Sea is the world’s largest meromictic basin consisting of a two-layer system separated by a permanent pycnocline (Sorokin, 2002). This density boundary effectively limits the vertical exchange between the oxygenated upper layer-influenced by the atmospheric and fluvial processes – and the almost completely isolated anoxic deep water. Despite its 42000 m depth, most of the biological activity (apart from bacteria) is hosted within the upper 100–150 m
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