Reproduction vs. growth : indications for altered energy fluxes in Lake Constance whitefish through size-selective fishery

The five species of coregonids that inhabit the lower Mackenzie River, broad whitefish, Coregonus nasus, inconnu, Stenodus leucuicthys, lake whitefish, C. clupeaformis, Arctic cisco, C. autumnalis, and least cisco, C. sardinella, have unique life cycles wherein they undertake extensive migrations to...

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Bibliographic Details
Published in:Advances in Limnology
Main Authors: Thomas, Gregor, Eckmann, Reiner
Format: Article in Journal/Newspaper
Language:English
Published: 2012
Subjects:
fisheries-induced evolution
Coregonus
hatching
maternity effects
growth rate
life-history traits
ddc:570
Arctic
Northwest Territories
Mackenzie River
Canada
Arctic Red River
Arctic cisco
Mackenzie river
Online Access:http://nbn-resolving.de/urn:nbn:de:bsz:352-188431
https://doi.org/10.1127/advlim/63/2012/133
Description
Summary:The five species of coregonids that inhabit the lower Mackenzie River, broad whitefish, Coregonus nasus, inconnu, Stenodus leucuicthys, lake whitefish, C. clupeaformis, Arctic cisco, C. autumnalis, and least cisco, C. sardinella, have unique life cycles wherein they undertake extensive migrations to and from spawning grounds, overwintering areas and feeding areas. We present analysis of these migratory patterns based on a study in the Arctic Red River situated in the Northwest Territories, Canada. The time of upstream and downstream migration as part of the spawning cycle was observed to be species-specific. We correlate the timing of migration to the seasonal development of gonads to determine the relative timing of spawning. Common garden experiments comparing the two most seasonally distinct species, broad whitefish and inconnu, showed that there was a difference between these species in the number of degree-days to hatch to compensate for the timing of spawning. Emergence of all species is under a strong stabilizing selection corresponding to the spring ice break-up on the Lower Mackenzie River. Due to this environmental constraint shared among all coregonid species in the system, we suggest that spawning timing is under disruptive selection to reduce hybridization among species. The common garden experiments above support a genetic alteration of the rate of embryonic development to allow for separation in timing of spawning among coregonids and therefore reinforce reproductive isolation among species. published published

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