Abstract
Rising river temperatures in western North America have increased the energetic costs of migration and the risk of premature mortality in many Pacific salmon (Oncorhynchus spp.) populations. Predicting and managing risks for these populations requires data on acute and cumulative thermal exposure, the spatio-temporal distribution of adverse conditions, and the potentially mitigating effects of cool-water refuges. In this study, we paired radiotelemetry with archival temperature loggers to construct continuous, spatially-explicit thermal histories for 212 adult Chinook salmon (O. tshawytscha) and 200 adult steelhead (O. mykiss). The fish amassed ~500,000 temperature records (30-min intervals) while migrating through 470 kilometers of the Columbia and Snake rivers en route to spawning sites in Idaho, Oregon, and Washington. Spring- and most summer-run Chinook salmon migrated before river temperatures reached annual highs; their body temperatures closely matched ambient temperatures and most had thermal maxima in the lower Snake River. In contrast, many individual fall-run Chinook salmon and most steelhead had maxima near thermal tolerance limits (20–22 °C) in the lower Columbia River. High temperatures elicited extensive use of thermal refuges near tributary confluences, where body temperatures were ~2–10 °C cooler than the adjacent migration corridor. Many steelhead used refuges for weeks or more whereas salmon use was typically hours to days, reflecting differences in spawn timing. Almost no refuge use was detected in a ~260-km reach where a thermal migration barrier may more frequently develop in future warmer years. Within population, cumulative thermal exposure was strongly positively correlated (0.88 ≤ r ≤ 0.98) with migration duration and inconsistently associated (-0.28 ≤ r ≤ 0.09) with migration date. All four populations have likely experienced historically high mean and maximum temperatures in recent years. Expected responses include population-specific shifts in migration phenology, increased reliance on patchily-distributed thermal refuges, and natural selection favoring temperature-tolerant phenotypes.
Highlights
Long-distance migrations are energetically demanding and risky, but they allow animals to exploit spatially-dispersed resources and satisfy life history needs that vary through time [1,2,3]
The Snake River spring, summer, and fall-run Chinook salmon and summer steelhead populations we studied are currently listed as threatened under the U.S Endangered Species Act [71]
To help characterize the diversity of individual Chinook salmon and steelhead thermal histories, we reviewed thermographs that were color-coded for river reach for every recovered radio data storage transmitter (RDST) (S1 and S2 Appendices)
Summary
Long-distance migrations are energetically demanding and risky, but they allow animals to exploit spatially-dispersed resources and satisfy life history needs that vary through time [1,2,3]. Migratory populations can be especially prone to decline and extirpation due to habitat loss and fragmentation affecting one or more life stages, to construction of obstacles (e.g., roads, dams) along historic migration routes, and to the ecological and phenological changes associated with climate warming [4,5]. These diverse risks have been well documented for the anadromous salmonids (Oncorhynchus, Salmo, and Salvelinus spp), a largely philopatric and entirely ectothermic group that includes some of the most iconic long-distance migrants. Plasticity is critically important for how animals respond to short-term (e.g., within-generation) environmental fluctuations, whereas genetic adaptation is likely necessary when environmental change is unidirectional, as appears to be the case with recent climate warming [20,24,25,26,27,28]
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