Temporal Dynamics of Migration-linked Genetic Variation Are Driven by Streamflows and Riverscape Permeability

Overview

Journal Mol Ecol

Specialties Environmental Health
Molecular Biology

Date 2020 Feb 4

PMID 32012393

Citations 5

Authors

Suzanne J Kelson

Michael R Miller

Tasha Q Thompson

Sean M ORourke

Stephanie M Carlson

Affiliations

Soon will be listed here.

Abstract

Landscape permeability is often explored spatially, but may also vary temporally. Landscape permeability, including partial barriers, influences migratory animals that move across the landscape. Partial barriers are common in rivers where barrier passage varies with streamflow. We explore the influence of partial barriers on the spatial and temporal distribution of migration-linked genotypes of Oncorhynchus mykiss, a salmonid fish with co-occurring resident and migratory forms, in tributaries to the South Fork Eel River, California, USA, Elder and Fox Creeks. We genotyped >4,000 individuals using RAD-capture and classified individuals as resident, heterozygous or migratory genotypes using life history-associated loci. Across four years of study (2014-2017), the permeability of partial barriers varied across dry and wet years. In Elder Creek, the largest waterfall was passable for adults migrating up-river 4-39 days each year. In this stream, the overall spatial pattern, with fewer migratory genotypes above the waterfall, remained true across dry and wet years (67%-76% of migratory alleles were downstream of the waterfall). We also observed a strong relationship between distance upstream and proportion of migratory alleles. In Fox Creek, the primary barrier is at the mouth, and we found that the migratory allele frequency varied with the annual timing of high flow events. In years when rain events occurred during the peak breeding season, migratory allele frequency was high (60%-68%), but otherwise it was low (30% in two years). We highlight that partial barriers and landscape permeability can be temporally dynamic, and this effect can be observed through changing genotype frequencies in migratory animals.

Citing Articles

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The Impacts of Dam Construction and Removal on the Genetics of Recovering Steelhead () Populations across the Elwha River Watershed.

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Rapture facilitates inexpensive and high-throughput parent-based tagging in salmonids.

Pepping M, ORourke S, Huang C, Katz J, Jeffres C, Miller M PLoS One. 2020; 15(11):e0239221.

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Indirect genetic control of migration in a salmonid fish.

Kelson S, Carlson S, Miller M Biol Lett. 2020; 16(8):20200299.

PMID: 32810431 PMC: 7480158. DOI: 10.1098/rsbl.2020.0299.

Temporal dynamics of migration-linked genetic variation are driven by streamflows and riverscape permeability.

Kelson S, Miller M, Thompson T, ORourke S, Carlson S Mol Ecol. 2020; 29(5):870-885.

PMID: 32012393 PMC: 7078995. DOI: 10.1111/mec.15367.

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