Chinook Salmon Depth Distributions on the Continental Shelf Are Shaped by Interactions Between Location, Season, and Individual Condition

Overview

Journal Mov Ecol

Publisher Biomed Central

Date 2024 Mar 16

PMID 38491373

Authors

Cameron Freshwater

Sean C Anderson

David D Huff

Joseph M Smith

Doug Jackson

Brian Hendriks

Scott G Hinch

Stephen Johnston

Andrew W Trites

Jackie King

Affiliations

Soon will be listed here.

Abstract

Background: Ecological and physical conditions vary with depth in aquatic ecosystems, resulting in gradients of habitat suitability. Although variation in vertical distributions among individuals provides evidence of habitat selection, it has been challenging to disentangle how processes at multiple spatio-temporal scales shape behaviour.

Methods: We collected thousands of observations of depth from acoustically tagged adult Chinook salmon Oncorhynchus tshawytscha, spanning multiple seasons and years. We used these data to parameterize a machine-learning model to disentangle the influence of spatial, temporal, and dynamic oceanographic variables while accounting for differences in individual condition and maturation stage.

Results: The top performing machine learning model used bathymetric depth ratio (i.e., individual depth relative to seafloor depth) as a response. We found that bathymetry, season, maturation stage, and spatial location most strongly influenced Chinook salmon depth. Chinook salmon bathymetric depth ratios were deepest in shallow water, during winter, and for immature individuals. We also identified non-linear interactions among covariates, resulting in spatially-varying effects of zooplankton concentration, lunar cycle, temperature and oxygen concentration.

Conclusions: Our results suggest Chinook salmon vertical habitat use is a function of ecological interactions, not physiological constraints. Temporal and spatial variation in depth distributions could be used to guide management decisions intended to reduce fishery impacts on Chinook salmon. More generally, our findings demonstrate how complex interactions among bathymetry, seasonality, location, and life history stage regulate vertical habitat selection.

Citing Articles

Prevalence of Chinook salmon is higher for southern than for northern resident killer whales in summer hot-spot feeding areas.

Saygili B, Trites A PLoS One. 2024; 19(10):e0311388.

PMID: 39388449 PMC: 11469597. DOI: 10.1371/journal.pone.0311388.

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