Genetic Stock Identification of Steelhead in the Columbia River Basin: An Evaluation of Different Molecular Markers

Winans, Gary A.; Paquin, Melanie M.; Doornik, Donald M. Van; Baker, Bruce M.; Thornton, Perry J.; Rawding, Dan; Marshall, Anne R.; Moran, Paul; Kalinowski, Steven T.

doi:10.1577/m03-052.1

Cited by 44 publications

(47 citation statements)

References 29 publications

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“…All individuals were genotyped at 11 microsatellite loci: Ots3 (Banks et al 1999), Ots104 (Nelson & Beacham 1999), Ots201b, 211 and 213 (Greig et al 2003, Ots2M and10M (Greig & Banks 1999)), Ots519NWFSC (Naish and Park 2002), Oke4 (Olsen et al 1998), Ogo4 (Olsen et al 1998), and Ssa408 (Cairney et al 2000. Microsatellite loci were amplified by Polymerase Chain Reaction (PCR), allele sizes were electrophoreticly resolved and scored according to the method of Winans et al (2004 Ogo4,Ots2M,201b,and 211,Ssa408).…”

Section: Methodsmentioning

confidence: 99%

Monitoring the Reproductive Success of Naturally Spawning Hatchery and Natural Spring Chinook Salmon in the Wenatchee River, 2008-2009 Progress Report.

Ford¹,

Williamson

2009

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Executive SummaryWe investigated differences in the statistical power to assign parentage between an artificially propagated and wild salmon population. The propagated fish were derived from the wild population, and are used to supplement its abundance. Levels of genetic variation were similar between the propagated and wild groups at 11 microsatellite loci, and exclusion probabilities were >0.999999 for both groups. The ability to unambiguously identify a pair of parents for each sampled progeny was much lower than expected, however. Simulations demonstrated that the proportion of cases the most likely pair of parents were the true parents was lower for propagated parents than for wild parents. There was a clear relationship between parentage assignment ability and the degree of linkage disequilibrium, the estimated effective number of breeders that produced the parents, and the size of the largest family within the potential parents. If a stringent threshold for parentage assignment was used, estimates of relative fitness were biased downward for the propagated fish. The bias appeared to be largely eliminated by either fractionally assigning progeny among parents in proportion to their likelihood of parentage, or by assigning progeny to the most likely set of parents without using a statistical threshold.We used a DNA-based parentage analysis to measure the relative reproductive success of hatchery-and natural-origin spring Chinook salmon in the natural environment. Both male and female hatchery-origin fish produced far fewer juvenile progeny per parent when spawning naturally than did natural origin fish. Differences in age structure, spawning location, weight and run timing were responsible for some of the difference in fitness. Male size and age had a large influence on fitness, with larger and older males producing more offspring than smaller or younger individuals. Female size had a significant effect on fitness, but the effect was much smaller than the effect of size on male fitness. For both sexes, run time had a smaller but still significant effect on fitness, with earlier returning fish favored. Spawning location within the river had a significant effect on fitness for both males and females, and for females explained most of the reduced fitness observed for hatchery fish in this population.While differences have been reported in the relative reproductive success of hatchery and naturally produced salmonids Oncorhynchus spp., factors explaining the differences are often confounded. We examined the spawning site habitat and redd structure variables of hatchery and naturally produced spring Chinook salmon O. tshawytscha of known size that spawned in two tributaries of the Wenatchee River. We controlled for variability in spawning habitat by limiting our analysis to redds found within four selected reaches. No difference in the instantaneous spawner density or location of the redd in the stream channel was detected between reaches. Within each reach, no difference in the fork length or weight of hatchery...

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Section: Methodsmentioning

confidence: 99%

Monitoring the Reproductive Success of Naturally Spawning Hatchery and Natural Spring Chinook Salmon in the Wenatchee River, 2008-2009 Progress Report.

Ford¹,

Williamson

2009

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“…Highly polymorphic microsatellite loci have been shown to provide considerable power for GSI (Kalinowski 2004;Winans et al 2004). Declining costs of genotyping and the recent completion of a cross-laboratory, standardized, microsatellite DNA baseline for over 150 populations throughout the range of Chinook salmon ) have led to microsatellites replacing allozymes for many GSI applications.…”

Section: Introductionmentioning

confidence: 99%

An improved method for predicting the accuracy of genetic stock identification

Anderson

Waples

Kalinowski

2008

Can. J. Fish. Aquat. Sci.

221

277

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Estimating the accuracy of genetic stock identification (GSI) that can be expected given a previously collected baseline requires simulation. The conventional method involves repeatedly simulating mixtures by resampling from the baseline, simulating new baselines by resampling from the baseline, and analyzing the simulated mixtures with the simulated baselines. We show that this overestimates the predicted accuracy of GSI. The bias is profound for closely related populations and increases as more genetic data (loci and (or) alleles) are added to the analysis. We develop a new method based on leave-one-out cross validation and show that it yields essentially unbiased estimates of GSI accuracy. Applying both our method and the conventional method to a coastwide baseline of 166 Chinook salmon (Oncorhynchus tshawytscha) populations shows that the conventional method provides severely biased predictions of accuracy for some individual populations. The bias for reporting units (aggregations of closely related populations) is moderate, but still present.Résumé : L'estimation de la précision de l'identification du stock génétique (« GSI ») qu'on peut espérer, étant donné une banque de données de base récoltée antérieurement, nécessite des simulations. La méthode courante comprend des simulations répétées de mélanges par ré-échantillonnage de la banque de données de base, des simulations de nouvelles banques de données de base en ré-échantillonnant la banque de données et l'analyse des mélanges ainsi simulés à l'aide des banques de données de base simulées. Nous montrons que cette méthode surestime la précision prédite de GSI. L'erreur est importante dans les populations fortement apparentées et elle augmente à mesure que de nouvelles données génétiques (locus et (ou) allèles) sont ajoutées à l'analyse. Nous mettons au point une nouvelle méthode basée sur une validation croisée de type « leave-one-out » (avec retrait d'un élément) et nous montrons qu'elle produit essentiellement des estimations non erronées de la précision de GSI. L'application de notre méthode et de la méthode courante à une banque de données de base provenant de 166 populations de saumons chinook (Oncorhynchus tshawytscha) réparties sur toute la côte montre que la méthode courante fournit des prédictions de la précision qui sont grandement faussées pour certaines populations individuelles. L'erreur dans le cas des unités d'évaluation (des rassemblements de populations fortement apparentées) est peu importante, mais réelle.[Traduit par la Rédaction]

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“…1). However, in comparison with the Columbia River to the north (Kostow 2003, Brannon et al 2004, Winans et al 2004, relatively little is known about the relationships among steelhead populations within the Klamath River system (Israel et al 2003, Papa et al in press), or between them and other populations in the KMP-ESU (Riesenbichler et al 1992, Busby et al 1994). In addition, non-native stocks of O. mykiss have been widely planted in the basin, and large hatcheries exist on both the Klamath (Iron Gate Hatchery) and Trinity (Trinity River Hatchery) rivers.…”

Section: Introductionmentioning

confidence: 99%

Population genetics of steelhead (Oncorhynchus mykiss) in the Klamath River

2006

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An analysis of population structure and genetic diversity was conducted on samples of Oncorhynchus mykiss (steelhead/rainbow trout) from 33 sites in the Klamath-Trinity River basin. Genotype data from 16 microsatellite loci in almost 1,700 fish revealed genetic differentiation between most sampled locations. Two pairs of samples from the same sites in different years were not significantly different, indicating stability of population structure, at least on a short time scale. Most sampling sites were genetically distinct from all other sampling sites, and there was an evidence of geographic structure within the Klamath-Trinity River basin, although populations from tributaries within the watershed (e.g. Salmon River, Scott River, Clear Creek) did not always constitute distinct genetic lineages. Population structure was evident using phylogeographic trees, isolation by distance analyses and individual assignment tests, which all found a relationship between geographic and genetic distance. Populations in the lower Klamath region, below the confluence with the Trinity River, consistently clustered together in phylogeographic analyses and had patterns of genetic diversity that suggest reduced gene flow between these sites and sites above the confluence. Finally, in an analysis that included data from other coastal California rivers, the populations closest to the mouth of the Klamath River appeared intermediate between populations from adjacent watersheds and the lineage formed by the other populations in the Klamath-Trinity basin.

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Genetic Stock Identification of Steelhead in the Columbia River Basin: An Evaluation of Different Molecular Markers

Cited by 44 publications

References 29 publications

Monitoring the Reproductive Success of Naturally Spawning Hatchery and Natural Spring Chinook Salmon in the Wenatchee River, 2008-2009 Progress Report.

Monitoring the Reproductive Success of Naturally Spawning Hatchery and Natural Spring Chinook Salmon in the Wenatchee River, 2008-2009 Progress Report.

An improved method for predicting the accuracy of genetic stock identification

Population genetics of steelhead (Oncorhynchus mykiss) in the Klamath River

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