A combination of genetic and phenotypic characterization of spring- and autumn-spawning herring suggests gene flow between populations

Berg, Florian; Østgaard, Hedda Dugstad; Slotte, Aril; Andersson, Leif; Folkvord, Arild

doi:10.1093/icesjms/fsaa046

Cited by 13 publications

(16 citation statements)

References 42 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Selection studies comparing otolith growth of larvae and survivors (adults) on for example strong and weak year classes might reveal new insights on the recruitment dynamics of herring. Further, this validation strengthens other studies where conclusions are drawn from microstructure analysis of adult otoliths which have management (Clausen et al, 2007) or ecological (Berg et al, 2020b) implications.…”

Section: Discussionsupporting

confidence: 81%

Comparison of Otolith Microstructure of Herring Larvae and Sibling Adults Reared Under Identical Early Life Conditions

et al. 2020

Self Cite

View full text Add to dashboard Cite

Atlantic herring (Clupea harengus) is a euryhaline species, occupying fully marine habitats (35 psu) in the North Atlantic, as well as brackish waters (<20 psu) such as in the adjacent Baltic Sea. We co-reared Atlantic purebreds and Atlantic/Baltic F1 hybrids in two salinity regimes (16 and 35 psu) in a common garden experiment for 3 years until their first maturity. This setup enabled for the first time a direct comparison between adults and their larval siblings at respective salinity regimes in terms of larval growth indicated by otolith microstructure. We validated that otolith microstructure analysis of adult otoliths is reflecting the experienced otolith growth during the larval stage. No major selection in terms of otolith growth had taken place during the juvenile stage, except for one experimental group. Surviving adult Atlantic purebreds reared at 16 psu had higher otolith growth compared to their larval stages. The validation that otolith microstructure analyses of adult herring can reliably be extracted and used to examine larval growth even after several years adds strong support for further use of such analyses. Among the parental generation, Baltic herring had a faster initial otolith growth than Atlantic herring. The growth of their laboratory-reared F1 progeny was intermediate compared to their parents. In general, larval growth of both Atlantic purebreds and Atlantic/Baltic hybrids reared in 16 psu was significantly larger than for those herring reared at 35 psu. There was no significant difference in larval growth between Atlantic purebreds and Atlantic/Baltic hybrids reared at 35 psu, but hybrid larval growth was significantly higher compared to larval growth of Atlantic purebreds at 16 psu. This was not reflected at the adult stage where purebreds were ultimately larger than hybrids (Berg et al., 2018). This indicates the influence and importance of environmental and genetic factors throughout the life of Atlantic herring, along with genetic contributions to phenotypic variability.

show abstract

Section: Discussionsupporting

confidence: 81%

Comparison of Otolith Microstructure of Herring Larvae and Sibling Adults Reared Under Identical Early Life Conditions

et al. 2020

Self Cite

View full text Add to dashboard Cite

show abstract

“…Interestingly, examinations of the otoliths from fish in this sample, using the method by Clausen et al (Clausen et al, 2007), showed that they hatched in spring. Thus, this must represent a group of herring that has switched spawning season from spring to autumn, maybe because their nutritional status was insufficient to support spawning (McQuinn, 1997), demonstrating that spawning time in herring is controlled by a combination of genetic and environmental factors (Bekkevold et al, 2007;Berg et al, 2020).…”

mentioning

confidence: 99%

Ecological adaptation in Atlantic herring is associated with large shifts in allele frequencies at hundreds of loci

Fan

Jamsandekar

Pettersson

et al. 2020

eLife

Self Cite

180

View full text Add to dashboard Cite

Atlantic herring is widespread in North Atlantic and adjacent waters and is one of the most abundant vertebrates on earth. This species is well suited to explore genetic adaptation due to minute genetic differentiation at selectively neutral loci. Here we report hundreds of loci underlying ecological adaptation to different geographic areas and spawning conditions. Four of these represent megabase inversions confirmed by long read sequencing. The genetic architecture underlying ecological adaptation in herring deviates from expectation under a classical infinitesimal model for complex traits because of large shifts in allele frequencies at hundreds of loci under selection.

show abstract

“…10 , showed that they hatched in spring. Thus, this must represent a group of herring that has switched spawning season from spring to autumn, maybe because their nutritional status was insufficient to support spawning 11 , demonstrating that spawning time in herring is controlled by a combination of genetic and environmental factors 12,13 .…”

Section: Resultsmentioning

confidence: 99%

The genetic architecture underlying ecological adaptation in Atlantic herring is not consistent with the infinitesimal model

Fan

Jamsandekar

Pettersson

et al. 2020

Preprint

Self Cite

View full text Add to dashboard Cite

Atlantic herring is widespread in North Atlantic and adjacent waters and is one of the most abundant vertebrates on earth. This species is well suited to explore genetic adaptation due to minute genetic differentiation at selectively neutral loci. Here we report hundreds of loci underlying ecological adaptation to different geographic areas and spawning conditions. Four of these represent megabase inversions confirmed by long read sequencing. The genetic architecture underlying ecological adaptation in the herring is in conflict with the infinitesimal model for complex traits because of the large shifts in allele frequencies at hundreds of loci under selection.

show abstract

A combination of genetic and phenotypic characterization of spring- and autumn-spawning herring suggests gene flow between populations

Cited by 13 publications

References 42 publications

Comparison of Otolith Microstructure of Herring Larvae and Sibling Adults Reared Under Identical Early Life Conditions

Comparison of Otolith Microstructure of Herring Larvae and Sibling Adults Reared Under Identical Early Life Conditions

Ecological adaptation in Atlantic herring is associated with large shifts in allele frequencies at hundreds of loci

The genetic architecture underlying ecological adaptation in Atlantic herring is not consistent with the infinitesimal model

Contact Info

Product

Resources

About