Fish assemblages respond to altered flow regimes via ecological filtering of life history strategies
Article first published online: 12 OCT 2012
© 2012 Blackwell Publishing Ltd
Volume 58, Issue 1, pages 50–62, January 2013
How to Cite
MIMS, M. C. and OLDEN, J. D. (2013), Fish assemblages respond to altered flow regimes via ecological filtering of life history strategies. Freshwater Biology, 58: 50–62. doi: 10.1111/fwb.12037
- Issue published online: 11 DEC 2012
- Article first published online: 12 OCT 2012
- (Manuscript accepted 15 September 2012)
- flow regulation;
- freshwater fishes;
- life histories;
- United States
1. In riverine ecosystems, streamflow determines the physical template upon which the life history strategies of biota are forged. Human freshwater needs and activities have resulted in widespread alteration of the variability, predictability and timing of streamflow, and anticipating the biotic consequences of anthropogenic streamflow alteration is critical for successful environmental flow management. In this study, we examined relationships between dam characteristics, metrics of flow alteration and fish functional community composition according to life history strategies by coupling stream flow records and fish survey data in paired flow-regulated and free-flowing rivers across the conterminous United States.
2. Dam operations have generally reduced flow variability and increased flow constancy based on a comparison of pre- and post-dam flow records (respective mean record lengths 26.2 and 43.1 years). In agreement with ecological theory, fish assemblages downstream of dams were characterised by a lower proportion of opportunistic species (a strategy favoured in environmental settings dominated by unpredictable environmental change) and a higher proportion of equilibrium species (a strategy favoured in more stable, predictable environments) compared to free-flowing, neighbouring locations.
3. Multiple linear regression models provided modest support for links between alteration of specific flow attributes and differential life history representation below dams, and they provided strong support for life history associations with dam attributes (age and release type). We also found support for a relationship of both reduced flow variability and dam age with higher representation of non-native species below dams.
4. Our study demonstrated that river regulation by large dams has significant hydrological and biological consequences across the United States. We showed that on ecological time scales (i.e. the order of years to decades), dams are effectively changing the functional composition of communities that have established over millennia. Furthermore, the changes are directional and indicate a filtering by dams for some life histories (equilibrium strategists) and against other life histories (opportunists). Finally, our study highlights that dependence upon long-term flow records and availability of biotic surveys extracted from national survey efforts limit our ability to guide environmental flow standards particularly in data-poor regions.