Naturally rare versus newly rare: demographic inferences on two timescales inform conservation of Galápagos giant tortoises

Garrick, Ryan C.; Kajdacsi, Brittney; Russello, Michael A.; Benavides, Edgar; Hyseni, Chaz; Gibbs, James P.; Tapia, Washington; Caccone, Adalgisa

doi:10.1002/ece3.1388

Cited by 30 publications

(43 citation statements)

References 119 publications

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“…Another cause of heterozygote deficit can be the mating of close relatives, leading to an increase in homozygosity. Here, we found the adult sample to have a significant F is value, which is consistent with other studies that have found the Pinzón population to have inbreeding coefficients higher than many of the other populations of Galá-pagos tortoise (Garrick et al 2015). Given the recent decrease in population size and its currently small size, inbreeding is also a plausible explanation for the observed heterozygote deficit.…”

Section: In Situ Diversitysupporting

confidence: 92%

“…Yet, simulation studies have shown that the M-ratio test may be more robust than heterozygosity-based approaches for detecting bottlenecks under a number of scenarios including when a population has made a demographic recovery, mutation rates are high, or pre-bottleneck sizes were large (Williamson-Natesan 2005). The latter case may be relevant for C. ephippium, as recent reconstructions based on slower-evolving mitochondrial DNA and a nuclear intron (PAX-P1) revealed that Pinzón tortoises had a very large historical effective population size that was increasing over the last 8000 generations (Garrick et al 2015). This work built upon an earlier study using mitochondrial DNA (Beheregaray et al 2003a) that likewise detected signatures of demographic expansion in Pinzón tortoises based on mismatch distributions.…”

Section: In Situ Diversitymentioning

confidence: 96%

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Genetics of a head-start program to guide conservation of an endangered Galápagos tortoise (Chelonoidis ephippium)

et al. 2015

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Critically endangered wildlife species typically require intensive management using a variety of in situ and ex situ approaches. Yet, despite broad application of ex situ conservation strategies, comparatively few programs incorporate genetic tools into management decisions and monitoring efforts. This is the case with the giant Galá-pagos tortoise endemic to Pinzón Island (Chelonoidis ephippium); a head-start program has been in place for 50 years without an evaluation of whether this conservation intervention has captured the breadth of diversity present in the wild population. Here we used microsatellite genotypic data to reconstruct patterns of within-and among-population genetic variation in the wild and captivity, and to assess the degree to which head-start cohorts and adult captive founders are representative of the gene pool in situ. We found that Pinzón giant tortoises maintain high levels of variation in situ despite their welldocumented decline and that the founders of the captive population are a reasonably diverse and representative group. However, we also found that the head-start cohorts are not representative of the wild population, as evidenced by significant genetic differentiation between the in situ and ex situ samples and by the private alleles detected in both. Future head-start activities should broaden the source locations of eggs and hatchlings to more comprehensively capture the extent and distribution of genetic variation in this critically endangered keystone herbivore. More broadly, this study further highlights the utility of integrating genetic information within ex situ conservation programs.

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Section: In Situ Diversitysupporting

confidence: 92%

Section: In Situ Diversitymentioning

confidence: 96%

Genetics of a head-start program to guide conservation of an endangered Galápagos tortoise (Chelonoidis ephippium)

et al. 2015

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“…In particular, genomescale variation data allows for inference of demographic factors such as population size changes, the timing and ordering of population splits, migration rates between populations, and the founding of admixed populations (Pool et al 2010;Pickrell and Pritchard 2012;Sousa and Hey 2013). Such efforts can refine our picture of demographic events inferred from the archaeological record (e.g., Fagundes et al 2007;Goebel et al 2008), or reveal such events in species where no archaeological data are available, and can aid conservation efforts by complementing census data (e.g., Hájková et al 2007;Garrick et al 2015).Population genomic data sets are well suited for this task simply because demographic changes leave their mark on patterns of genetic variation. Recent population growth, for example, will result in an excess of rare variation compared to equilibrium expectations (Fu 1997), while population contraction will result in an excess of intermediate frequency alleles (Maruyama and Fuerst 1985).…”

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confidence: 99%

Effects of Linked Selective Sweeps on Demographic Inference and Model Selection

2016

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The availability of large-scale population genomic sequence data has resulted in an explosion in efforts to infer the demographic histories of natural populations across a broad range of organisms. As demographic events alter coalescent genealogies, they leave detectable signatures in patterns of genetic variation within and between populations. Accordingly, a variety of approaches have been designed to leverage population genetic data to uncover the footprints of demographic change in the genome. The vast majority of these methods make the simplifying assumption that the measures of genetic variation used as their input are unaffected by natural selection. However, natural selection can dramatically skew patterns of variation not only at selected sites, but at linked, neutral loci as well. Here we assess the impact of recent positive selection on demographic inference by characterizing the performance of three popular methods through extensive simulation of data sets with varying numbers of linked selective sweeps. In particular, we examined three different demographic models relevant to a number of species, finding that positive selection can bias parameter estimates of each of these models-often severely. We find that selection can lead to incorrect inferences of population size changes when none have occurred. Moreover, we show that linked selection can lead to incorrect demographic model selection, when multiple demographic scenarios are compared. We argue that natural populations may experience the amount of recent positive selection required to skew inferences. These results suggest that demographic studies conducted in many species to date may have exaggerated the extent and frequency of population size changes.KEYWORDS population genetics; positive selection; demographic inference T HE widespread availability of population genomic data has spurred a new generation of studies aimed at understanding the histories of natural populations from a host of model and nonmodel organisms alike. In particular, genomescale variation data allows for inference of demographic factors such as population size changes, the timing and ordering of population splits, migration rates between populations, and the founding of admixed populations (Pool et al. 2010;Pickrell and Pritchard 2012;Sousa and Hey 2013). Such efforts can refine our picture of demographic events inferred from the archaeological record (e.g., Fagundes et al. 2007;Goebel et al. 2008), or reveal such events in species where no archaeological data are available, and can aid conservation efforts by complementing census data (e.g., Hájková et al. 2007;Garrick et al. 2015).Population genomic data sets are well suited for this task simply because demographic changes leave their mark on patterns of genetic variation. Recent population growth, for example, will result in an excess of rare variation compared to equilibrium expectations (Fu 1997), while population contraction will result in an excess of intermediate frequency alleles (Maruyama and Fuerst 198...

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“…Galápagos giant tortoises are endemic to the Galápagos Islands and are currently recognized as an endangered, multi-species complex including both extant and extinct taxa. Taxonomic definitions are based on morphology, geographic isolation and population genetic evidence based on short DNA sequences of the mitochondrial genome (mtDNA) and/or a dozen or so nuclear microsatellite loci [5][6][7][8]. The species complex enjoys maximal protection.…”

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confidence: 99%

A genomic perspective timely needed for re-evaluating the species delimitations, evolutionary trajectories, and conservation strategies of the Galapagos giant tortoises

Fontaine¹

2017

PCI Evol Biol

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Genome-wide data obtained from even a small number of individuals can provide unprecedented levels of detail about the evolutionary history of populations and species [1], determinants of genetic diversity [2], species boundaries and the process of speciation itself [3]. Loire and Galtier [4] present a clear example, using the emblematic Galápagos giant tortoise (Chelonoidis nigra), of how multi-species comparative population genomic approaches can provide valuable insights about population structure and species delimitation even when sample sizes are limited but the number of loci is large and distributed across the genome.

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Naturally rare versus newly rare: demographic inferences on two timescales inform conservation of Galápagos giant tortoises

Cited by 30 publications

References 119 publications

Genetics of a head-start program to guide conservation of an endangered Galápagos tortoise (Chelonoidis ephippium)

Genetics of a head-start program to guide conservation of an endangered Galápagos tortoise (Chelonoidis ephippium)

Effects of Linked Selective Sweeps on Demographic Inference and Model Selection

A genomic perspective timely needed for re-evaluating the species delimitations, evolutionary trajectories, and conservation strategies of the Galapagos giant tortoises

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