Abstract
Traditionally, resistance and resilience are associated with good ecological health, often underpinning restoration goals. However, degraded ecosystems can also be highly resistant and resilient, making restoration difficult: degraded communities often become dominated by hyper-tolerant species, preventing recolonization and resulting in low biodiversity and poor ecosystem function. Using streams as a model, we undertook a mesocosm experiment to test if degraded community presence hindered biological recovery. We established 12 mesocosms, simulating physically healthy streams. Degraded invertebrate communities were established in half, mimicking the post-restoration scenario of physical recovery without biological recovery. We then introduced a healthy colonist community to all mesocosms, testing if degraded community presence influenced healthy community establishment. Colonists established less readily in degraded community mesocosms, with larger decreases in abundance of sensitive taxa, likely driven by biotic interactions rather than abiotic constraints. Resource depletion by the degraded community likely increased competition, driving priority effects. Colonists left by drifting, but also by accelerating development, reducing time to emergence but sacrificing larger body size. Since degraded community presence prevented colonist establishment, our experiment suggests successful restoration must address both abiotic and biotic factors, especially those that reinforce the ‘negative’ resistance and resilience which perpetuate degraded communities and are typically overlooked.
Highlights
Given widespread human impacts, restoration of degraded ecosystems is essential [1,2]
Freshwater restoration efforts can succeed in improving abiotic conditions [41,42], but there is often a lack of biological recovery and communities associated with degraded conditions
Our results suggest the presence of these degraded communities can contribute to the lack of community recovery, likely inhibiting the establishment of sensitive taxa
Summary
Restoration of degraded ecosystems is essential [1,2]. Other impediments include incomplete physical recovery [7,13] or lack of colonization [14], typically associated with catchment-wide issues reducing the efficacy of reach-scale restoration [8,13]. Amelioration of these factors is essential, but unlike in terrestrial systems, the importance of biotic interactions in aquatic community recovery has been largely ignored and is challenging to assess empirically [15,16]. We present a mesocosm experiment simulating a post-restoration scenario in an aquatic system to investigate the mechanisms behind biotic recovery failure
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