Habitat Use and Movement Patterns for a Fluvial Species, the Arctic Grayling, in a Watershed Impacted by a Large Reservoir: Evidence from Otolith Microchemistry

1. Fluvial environments are lost following construction of dams and flooding of river valleys. Rivers flowing into newly created reservoirs are still connected, but whether fluvial species of fish use or migrate through the newly formed lacustrine habitat is not known. We determined chemical composi...

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Bibliographic Details
Published in:The Journal of applied ecology 2007-12, Vol.44 (6), p.1156-1165
Main Authors: CLARKE, ADRIAN D, TELMER, KEVIN H, SHRIMPTON, J. MARK
Format: Article
Language:English
Subjects:
Animal populations
Applied ecology
fish life history
Fish migration
fish movement
Freshwater fishes
habitat fragmentation
Habitats
laser ablation‐inductively coupled plasma mass spectrometry
Marine fishes
Natural reservoirs
otolith chemistry
Otolith organs
Parsnips
Reservoirs
Riverine habitats
Rivers
Signatures
Special Profile: Ecological Quality of Freshwater Ecosystems
Spectrum analysis
Thymallus arcticus
Tributaries
Watersheds
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Summary:1. Fluvial environments are lost following construction of dams and flooding of river valleys. Rivers flowing into newly created reservoirs are still connected, but whether fluvial species of fish use or migrate through the newly formed lacustrine habitat is not known. We determined chemical composition of otoliths using laser ablation inductively coupled plasma mass spectrometry to assess patterns of movement in Arctic grayling (Thymallus arcticus) from a fluvial system flooded by dam construction to assess the reservoir impact on fish populations. 2. Rivers examined within the upper Peace River watershed in British Columbia had considerable differences in water chemistry. Elemental signatures measured in grayling otoliths were highly correlated to the stream chemistries where the fish were captured. Shifts between chemically distinct environments could be detected for grayling; some fish experienced significant changes in water chemistry while others did not. 3. Discriminant function analyses for otolith chemistry suggested that Arctic grayling formed four main populations: Parsnip watershed, Nation watershed, Omineca watershed and Ingenika watershed. There also appeared to be groupings according to smaller watersheds (subpopulations) within these systems. 4. Synthesis and applications. Construction of the WAC Bennett hydroelectric dam and formation of the Williston Reservoir may have created a barrier for migration of fluvial Upper Peace River Arctic grayling. Populations that were thought to have remained healthy into the 1980s were likely impacted immediately but this was not obvious due to the presence of residual 'prereservoir' fish. Natural chemical markers in otoliths revealed that Arctic grayling in our study did not move into the reservoir and may now be restricted only to a number of tributary systems with no interconnectivity. Future management must take account of this new, fragmented distribution.
ISSN:0021-8901
1365-2664
DOI:10.1111/j.1365-2664.2007.01350.x