Historical and recent genetic bottlenecks in European grayling, Thymallus thymallus

While currently in a state of recovery in the United Kingdom (UK), the grayling (Thymallus thymallus) remains of conservation interest due to its historical decline, socio-economic value and the potential impact of hatchery-reared stock fish on the genetic structure and diversity of wild populations. However, little is known about the levels and distribution of genetic diversity among UK grayling populations. To this end, 27 UK populations of grayling were genotyped across 10 microsatellite loci and sequenced at the mtDNA D-Loop. All populations clustered into four higher-level groups: Northern England, Southern England, Wales, and group consisting of a mixture of native and introduced populations. Ten populations showed evidence of bottleneck or founder effects, and the effective population size (Ne) was low in all populations. In most cases, historical stocking records agreed with the genetic relationships revealed in the study. A D-Loop haplotype network supported the groupings observed in the nuclear data, while phylogenetic inference places the UK populations amongst Central European samples. The combined datasets demonstrate that many of the UK populations can be treated as separate Management Units and we recommend that to preserve population specific genetic diversity, that stocking should be an intervention of last resort. However, if stocking is deemed essential, brood stock should originate from the river to be stocked

Section: Population Bottlenecks and Effective Population Sizesupporting

confidence: 90%

Section: Population Bottlenecks and Effective Population Sizementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Substantial genetic structure among stocked and native populations of the European grayling (Thymallus thymallus, Salmonidae) in the United Kingdom

Dawnay

Hughes

et al. 2011

“…Our MSVAR analysis suggested that the contemporary common carp population size is roughly 3% of its historical size and that the population decline started 17000-49000 years ago, based on linear and/or exponential model. Similar values of strong ancient population decline were also reported for the African buffalo, 8% (Heller et al 2008) or the golden eagle, 3% (Bourke et al 2010) and even stronger for European grayling, 0.03-1.2% (Swatdipong et al 2010). Thus, an ancient genetic bottleneck that occurred thousands of years ago, could be the result of postglacial colonization of Europe from the Caspian basin refugia (Kohlmann et al 2003) or some ecological or climatic changes.…”

Section: Discussionsupporting

confidence: 72%

Genetic monitoring and effects of stocking practices on small Cyprinus carpio populations

Lappa

Kalomoiris

Oikonomidis³

et al. 2011

The ability to detect genetic differences both in space and time is crucial for conserving genetic variation. It can reveal genetic diversity and genetic composition changes of declining native populations that are supported through stocking with captive bred individuals. The present study was designed to analyse the temporal stability of a declining common carp (Cyprinus carpio) population from Lake Volvi (North Greece). Polymorphism was evaluated using seven microsatellite loci at two sampling time points (separated by 12 years). The genetic variability of four additional populations (from two rivers and two lakes) in Northern Greece was also investigated for comparison. Heterozygosity values (0.692-0.868) and allelic richness (8.530-11.148) were high for all studied populations and comparable to other European populations. However, the analysis of temporal common carp samples from Lake Volvi revealed a significant change in their genetic composition and admixture analysis demonstrated significant introgression of stocked individuals into the native population. Both temporal and point estimate methods revealed low effective size (Ne = 61-171.3) for this population, possibly a result of an ancient genetic bottleneck that led to population decline and/or recent anthropogenic interventions. This low Ne has rendered the native population vulnerable to alteration of its genetic composition. Our study demonstrates that enhancement programs should be applied cautiously, especially for small populations. Moreover, it underlines the need for temporal analyses, which may contribute to the evaluation of previous management policies and to future decision making.

“…The possibility of an increased probability of extinction because of decreased genetic variance is a significant concern of conservation biology as evidenced by the number of papers focused on this phenomenon in journals such as Conservation Genetics, Conservation Biology and Animal Conservation: a search using the term ''bottleneck*'' under the division of Biodiversity Conservation in web of science produced 402 papers, 342 of which were published in the last 10 years. Analysis of genetic variation using molecular markers in populations passing through such population bottlenecks has shown significant loss of genetic variation: examples include eutherian mammals (Bonnell and Selander 1974;Neumann et al 2004;Culver et al 2008;Durrant et al 2009;Haanes et al 2010;Corti et al 2011;Fenderson et al 2011;Ricanova et al 2011;Sastre et al 2011), marsupials (Sinclair et al 2002;Cardoso et al 2009), birds (Bellinger et al 2003;Munoz-Fuentes et al 2005;Funk et al 2010;Kuro-o et al 2010), amphibians (Schoville et al 2011), fish (Consuegra et al 2005;Earl et al 2010;Swatdipong et al 2010) and plants (Jacquemyn et al 2010). Despite the loss of molecular variation after passing through a bottleneck numerous species (but not all-see, for example, Heber and Briskie 2010) have shown few ill effects and their populations have expanded and persisted: for example, the Northern elephant seal (Hoelzel 1999;Weber et al 2000;Hoelzel et al 2002), the kakerori, an endemic bird of the Cook Islands (Chan et al 2011), the Seychelles kestrel (Groombridge et al 2009), the skink, Oligosoma suteri (Miller et al 2011), the butterfly, Parnassius apollo (Habel et al 2009) and the stingless bee Melipona scutellus (Alves et al 2011).…”

Section: Introductionmentioning

confidence: 99%

Do bottlenecks increase additive genetic variance?

Taft

Roff

2011

Because of anthropogenic factors many populations have been at least temporarily reduced to a very small population size. Such reductions could potentially decrease genetic variation and increase the probability of extinction. Analysis of molecular markers has shown a decrease in genetic variation but in many cases this has not reduced the ability of the population to recover from the bottleneck. This apparent paradox is resolved by a consideration of how population bottlenecks can affect additive genetic variance, the relevant measure of ability to respond to selective factors. A bottleneck has the potential to increase additive genetic variance in a population. This may result in an increase in fitness, particularly in populations of conservation concern that are small and lack genetic variation. Here we present a meta-analysis of experimental tests of this prediction using models designed to fit data that is strictly additive and data that has nonadditive components. This analysis shows that additive genetic variance in a dataset dominated by morphological traits increases, on average, after a bottleneck event when the inbreeding coefficient is less than 0.3, but neither of the theoretical models alone can adequately explain this result. Because of our inability at present to predict the results of a population bottleneck in a specific case and the probability of extinction associated with small population size we caution against using bottlenecks to increase genetic variance, and thus the fitness, of endangered populations.