Cold shock and fish |
| |
| Authors: | M. R. Donaldson S. J. Cooke D. A. Patterson J. S. Macdonald |
| |
| Affiliation: | * Fish Ecology and Conservation Physiology Laboratory, Ottawa‐Carleton Institute of Biology, Carleton University, Ottawa, ON K1S 5B6 Canada, ? Institute of Environmental Science, Carleton University, Ottawa, ON K1S 5B6 Canada, § Fisheries and Oceans Canada, Co‐operative Resource Management Institute, School of Resource and Environmental Management, Simon Fraser University, Burnaby, BC V5A 1S6 Canada and ‖ Fisheries and Oceans Canada, DFO/UBC Centre for Aquaculture and Environmental Research (CAER), West Vancouver, BC V7V 1N6 Canada |
| |
| Abstract: | Rapid decreases in water temperature may result in a number of physiological, behavioural and fitness consequences for fishes termed ‘cold shock’. Cold‐shock stress occurs when a fish has been acclimated to a specific water temperature or range of temperatures and is subsequently exposed to a rapid decrease in temperature, resulting in a cascade of physiological and behavioural responses and, in some cases, death. Rapid temperature decreases may occur from either natural (e.g. thermocline temperature variation, seiches and storm events) or anthropogenic sources (e.g. varied thermal effluents from power generation and production industries). The magnitude, duration and frequency of the temperature change as well as the initial acclimation temperatures of individuals can influence the extent of the consequences of cold shock on fishes. Early research on cold shock focused on documenting mortality events associated with cold shock. However, in recent years, a shift in research has occurred where the focus of cold‐shock studies now involves characterizing the sublethal effects of cold shock in terms of the stress response in fishes. This shift has revealed that cold shock can actually be used as a tool for fisheries science (e.g. to induce polyploidy). The cold‐shock stress response offers opportunities to develop many exciting research questions, yet to date, cold‐shock research has been largely unfocused. Few studies attempt to link laboratory physiology experiments with ecologically relevant field data on behaviour, growth, bioenergetics and fitness. Additional research will allow for the development of more focused and robust management policies and conservation initiatives. This review synthesizes the sublethal physiological and behavioural consequences of cold‐shock stress on fishes, identifies natural and anthropogenic sources of cold shock, discusses the benefits of cold shock to fisheries science and describes mitigation and management efforts. Existing knowledge gaps and opportunities for future cold‐shock research are presented. |
| |
| Keywords: | cold shock polyploidy stress response sublethal effects thermal effluents thermal shock |
|
|
