Strong population structure deduced from genetics, otolith chemistry and parasite abundances explains vulnerability to localized fishery collapse in a large Sciaenid fish, <i>Protonibea diacanthus</i>

Taillebois, Laura; Barton, Diane P.; Crook, David A.; Saunders, Thor; Taylor, Jonathan; Hearnden, Mark; Saunders, Richard; Newman, Stephen J.; Travers, Michael J.; Welch, David J.; Greig, Alan; Dudgeon, Christine L.; Maher, Safia; Ovenden, Jennifer R.

doi:10.1111/eva.12499

Cited by 39 publications

(30 citation statements)

References 54 publications

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“…Similar misclassifications in otolith chemical signatures among sites have been observed in studies of other fish species including black-spotted croaker Protonibea diacanthus(Taillebois et al, 2017), Black Rock fish, Sebastes melanops(Miller, Banks, Gomez-Uchida, & Shanks, 2005) and Common carp, Cyprinus carpio. Classification success was similar for core, near core and edge, suggesting similar patterns of dispersal and mixing of individuals across ontogeny.…”

supporting

confidence: 76%

“…Misclassifications of individuals are likely due to the high number of locations relative to the number of elements used in the discriminant function analysis. Similar misclassifications in otolith chemical signatures among sites have been observed in studies of other fish species including black-spotted croaker Protonibea diacanthus(Taillebois et al, 2017), Black Rock fish, Sebastes melanops(Miller, Banks, Gomez-Uchida, & Shanks, 2005) and Common carp, Cyprinus carpio. In the three cases where the edge signatures (reflecting recent growth) were distinct between paired sites (Brisbane, Logan and Nerang River), the core and near-core signatures were also significantly different.…”

supporting

confidence: 76%

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Non‐diadromous life history and limited movement in northern lineages of Australian smelt: Evidence from otolith chemistry analysis

Islam

Schmidt

Crook

et al. 2018

Ecology of Freshwater Fish

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A comprehensive knowledge of migratory behaviour is paramount for the effective management and conservation of fishes in coastal drainages. The Australian smelt (Retropinna semoni) is a common fish distributed throughout coastal and inland drainages in south-eastern Australia. Multiple life history patterns (potamodromy, facultative diadromy, estuarine residence) in the southern regions of its geographic distribution have been reported, and it is possible that some of these differences reflect characteristic behaviours of cryptic species within the group. To elucidate the life history patterns of smelt at the northern extent of their range and to identify any differences in migratory behaviour between two genetically distinct lineages ("SEQ-N", "SEQ-S") in this region, the movement patterns of Australian smelt were assessed using otolith chemistry. No evidence of marine residence was found based on otolith Sr:Ca and Ba:Ca transects for either group, suggesting that both are non-diadromous.Significant differences in multi-elemental otolith chemistry signatures were found among rivers and between paired sites within some rivers, suggesting no connectivity among drainages and limited dispersal of individuals over large spatial scales within rivers. These findings provide key insights into the migratory patterns of northern Australian smelt populations and, in combination with previous research, suggest that life history variation in the Australian smelt complex may occur primarily at the intra-population level rather than among genetically distinct lineages.Conservation and management strategies for Australian smelt should take limited dispersal and individual life history variation into consideration in order to protect the components of this important species complex. K E Y W O R D SAustralian smelt, cryptic species, life history, otolith chemistry

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supporting

confidence: 76%

supporting

confidence: 76%

Non‐diadromous life history and limited movement in northern lineages of Australian smelt: Evidence from otolith chemistry analysis

Islam

Schmidt

Crook

et al. 2018

Ecology of Freshwater Fish

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“…While allele frequency distributions highlight population processes on a multi-generational timescale and length distributions can indicate spatial structuring at the time of sampling, otolith chemistry records environmental and physiological influences over an individual's life history. Otolith chemistry, therefore, has the potential to resolve population structure where gene flow homogenizes genetic differences, and throw light on the mechanisms explaining spatial length distributions and genetic connectivity (Ashford et al 2006, Taillebois et al 2017.…”

Section: Testing Population Structure Along the Continental Shelfmentioning

confidence: 99%

Spatial structuring and life history connectivity of Antarctic silverfish along the southern continental shelf of the Weddell Sea

Caccavo¹,

Ashford²,

Ryan³

et al. 2019

Mar. Ecol. Prog. Ser.

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A multi-disciplinary approach was employed to examine a physical-biological population hypothesis for a critical forage species, the Antarctic silverfish Pleuragramma antarctica. Caccavo et al. (2018; Sci Rep 8: 17856) had shown strong gene flow along the westward Antarctic Slope Current, in addition to spatially recurring length modes that provided evidence for episodic connectivity. In this paper, otolith nucleus chemistry from a subset of fish collected in the southern Weddell Sea as part of a hydrographic survey of the Filchner Trough system was used to test between connectivity scenarios. Nucleus chemistry, which reflects environmental exposure during early life, showed significant spatial structuring despite homogeneity in microsatellite allele frequencies. Mg:Ca and Sr:Ca differentiated length modes, and Mg:Ca showed significant contrasts between Atka Bay, Halley Bay, and Filchner Trough. Physical-biological mechanisms may help reconcile structuring shown by otolith chemistry, length, and abundance data with prior evidence of gene flow. Such mechanisms include self-recruitment shaped by circulation associated with the Filchner Trough, fluctuations in mixing between immigrant and locally recruited fish, and feeding opportunities between inflowing Modified Warm Deep Water and outflowing Ice Shelf Water. The results illustrate how comparisons between multi-disciplinary techniques based on integrated sampling designs that incorporate hydrography can enhance understanding of population structure and connectivity around the Southern Ocean.

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“…Different stocks may possess specific genetic, physiological and behavioural traits that can influence life processes such as growth rates, fecundity, abundance and disease resistance (Stepien 1995), and thus different resilience to exploitation and environmental changes. As such, when stock structure is more complex than recognised, the sustainability of the resource and the profitability of the fishery can be jeopardised (Kerr et al 2017;Taillebois et al 2017).…”

Section: Introductionmentioning

confidence: 99%

Otolith microchemistry: a useful tool for investigating stock structure of yellowfin tuna (Thunnus albacares) in the Indian Ocean

Artetxe-Arrate

Fraile

Crook

et al. 2019

Mar. Freshwater Res.

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A better understanding of the stock structure of yellowfin tuna (Thunnus albacares) in the Indian Ocean is needed to ensure the sustainable management of the fishery. In this study, carbon and oxygen stable isotopes (δ13C and δ18O) and trace elements (138Ba, 55Mn, 25Mg and 88Sr) were measured in otoliths of young-of-the-year (YOY) and age-1 yellowfin tuna collected from the Mozambique Channel and north-west Indian Ocean regions. Elemental profiles showed variation in Ba, Mg and Mn in YOY otolith composition, but only Mn profiles differed between regions. Differences in YOY near-core chemistry were used for natal-origin investigation. Ba, Mg and Mn were sufficiently different to discriminate individuals from the two regions, in contrast with carbon and oxygen stable isotopes. A linear discriminant analysis resulted in 80% correct classification of yellowfin tuna to their natal origin. Classification success increased to 91% using a random forest algorithm. Finally, a unique larval source was detected among age-1 yellowfin tuna. The signal of these fish resembled that of YOY from a north-west Indian Ocean origin, highlighting the importance of local production. The present study supports the use of otolith chemistry as a promising approach to analyse yellowfin stock structure in the Indian Ocean.

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Strong population structure deduced from genetics, otolith chemistry and parasite abundances explains vulnerability to localized fishery collapse in a large Sciaenid fish, Protonibea diacanthus

Cited by 39 publications

References 54 publications

Non‐diadromous life history and limited movement in northern lineages of Australian smelt: Evidence from otolith chemistry analysis

Non‐diadromous life history and limited movement in northern lineages of Australian smelt: Evidence from otolith chemistry analysis

Spatial structuring and life history connectivity of Antarctic silverfish along the southern continental shelf of the Weddell Sea

Otolith microchemistry: a useful tool for investigating stock structure of yellowfin tuna (Thunnus albacares) in the Indian Ocean

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