Reviewing the consequences of genetic purging on the success of rescue programs

Pérez‐Pereira, Noelia; Caballero, Armando; García-Dorado, Aurora

doi:10.1007/s10592-021-01405-7

Cited by 27 publications

(46 citation statements)

References 94 publications

(129 reference statements)

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“…This result implies a de novo mutation rate of ∼0.003 recessive lethal mutations per diploid human (assuming a lethal mutation rate of 0.5%) and ∼0.001 recessive lethal mutations per diploid fly (assuming a lethal mutation rate of 1%). Notably, when assuming 4-5% of new nonsynonymous mutations to be recessive lethal, as recently suggested (Kardos et al 2021; Pérez-Pereira, Caballero, and García-Dorado 2022), these models predict levels of segregating recessive lethals that are well above those observed empirically ( Fig. 7 ).…”

Section: Discussionsupporting

confidence: 72%

“…Specifically, available evidence suggests that the average number of segregating recessive lethal mutations in humans is roughly in the range of 0.6 to 1.6 per diploid (Gao et al 2015;Narasimhan et al 2016), and analytical predictions with <~0.5% of new nonsynonymous mutations being recessive lethal appear to approximate this range, regardless of the assumed effective population size. By contrast, analytical predictions with ~5% of new mutations being recessive lethal, a value that has recently been proposed (Kardos et al 2021;Pérez-Pereira, Caballero, and García-Dorado 2022), suggest ~10-20 recessive lethal mutations per diploid, well outside of empirical observations.…”

Section: Table 3: Summary Of Parameters Used In Mutation-selection-dr...mentioning

confidence: 89%

“…For example, Kardos et al (2021) proposed a DFE where 5% of deleterious mutations are recessive lethal and ∼21% have s < -0.1. Similarly, Pérez-Pereira, Caballero, and García-Dorado (2022) proposed a DFE with that ∼4% of deleterious mutations are recessive lethal, and ∼41% have s < -0.1. Importantly, both of these DFEs were not directly estimated from data, but were instead designed largely to reflect results from mutation accumulation experiments (Kardos et al 2021; Pérez-Pereira, Caballero, and García-Dorado 2022).…”

Section: Introductionmentioning

confidence: 99%

“…Similarly, Pérez-Pereira, Caballero, and García-Dorado (2022) proposed a DFE with that ∼4% of deleterious mutations are recessive lethal, and ∼41% have s < -0.1. Importantly, both of these DFEs were not directly estimated from data, but were instead designed largely to reflect results from mutation accumulation experiments (Kardos et al 2021; Pérez-Pereira, Caballero, and García-Dorado 2022). Other recent studies have focused on “nearly lethal” mutations, or those mutations that are not expected to segregate in a sample of genetic variation.…”

Section: Introductionmentioning

confidence: 99%

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Quantifying the fraction of new mutations that are recessive lethal

Wade

Kyriazis

Cavassim

et al. 2022

Preprint

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The presence and impact of recessive lethal mutations has been widely documented in diploid outcrossing species. However, precise estimates in different species of the proportion of mutations that are recessive lethal remain limited. Here, we attempt to quantify the fraction of new mutations that are recessive lethal using Fit∂a∂i, a commonly-used method for inferring the distribution of fitness effects (DFE) using the site frequency spectrum. Using simulations, we demonstrate that Fit∂a∂i cannot accurately estimate the fraction of recessive lethal mutations, as expected given that Fit∂a∂i assumes that all mutations are additive by default. Consistent with the idea that mis-specification of the dominance model can explain this performance, we find that Fit∂a∂i can accurately infer the fraction of additive lethal mutations. Moreover, we demonstrate that in both additive and recessive cases, inference of the deleterious non-lethal portion of the DFE is minimally impacted by a small proportion (<10%) of lethal mutations. Finally, as an alternative approach to estimate the proportion of mutations that are recessive lethal, we employ models of mutation-selection-drift balance using existing genomic parameters and segregating recessive lethals estimates for humans and Drosophila melanogaster. In both species, we find that the segregating recessive lethal load can be explained by a very small fraction (<1%) of new nonsynonymous mutations being recessive lethal. Our results refute recent assertions of a much higher recessive lethal mutation fraction (4-5%), while highlighting the need for additional information on the joint distribution of selection and dominance coefficients.

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Section: Discussionsupporting

confidence: 72%

Section: Table 3: Summary Of Parameters Used In Mutation-selection-dr...mentioning

confidence: 89%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Quantifying the fraction of new mutations that are recessive lethal

Wade

Kyriazis

Cavassim

et al. 2022

Preprint

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“…Purging may be most effective in populations where inbreeding is gradual due to a moderate population size (4)(5)(6)(9)(10)(11). However, the extent to which purging is a relevant factor for the conservation of threatened populations, and more broadly, the degree to which populations can persist with low genome-wide diversity, is controversial (9,(12)(13)(14)(15)(16)(17)(18).…”

Section: Introductionmentioning

confidence: 99%

Genomic underpinnings of population persistence in Isle Royale moose

Kyriazis

Beichman

Brzeski

et al. 2022

Preprint

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Island ecosystems provide models to assess the impacts of isolation on population persistence. However, most studies of persistence have focused on a single species, without comparisons to other organisms they interact with in the ecosystem. The simple predator-prey system of moose and gray wolves on Isle Royale provides allows a direct contrast of genetic variation in a prey species with their natural predator. Wolves on Isle Royale exhibited signs of severe inbreeding depression, which nearly drove the population to extinction in 2019. In the relative absence of wolves, the moose population has thrived and exhibits no obvious signs of inbreeding depression despite being isolated for ~120 years and having low genetic diversity. Here, we examine the genomic underpinnings of population persistence in the Isle Royale moose population. We document high levels of inbreeding in the population, roughly as high as the wolf population at the time of its decline. However, inbreeding in the moose population manifests in the form of intermediate-length runs of homozygosity indicative of gradual inbreeding, contrasting with the severe recent inbreeding observed in the wolf population. Using simulations, we demonstrate that this more gradual inbreeding in the moose population has resulted in an estimated 50% purging of the inbreeding load, helping to explain the continued persistence of the population. However, we also document notable increases in genetic load, which could eventually threaten population viability over the long term. Finally, we document low diversity in mainland North American moose populations due to a severe founder event occurring near the end of the Holocene. Overall, our results demonstrate a complex relationship between inbreeding, genetic diversity, and population viability that highlights the importance of maintaining isolated populations at moderate size to avert extinction from genetic factors.

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Prediction of the minimum effective size of a population viable in the long term

et al. 2022

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The establishment of the minimum size for a viable population (MVP) has been used as a guidance in conservation practice to determine the extinction risks of populations and species. A consensus MVP rule of 50/500 individuals has been attained, according to which a minimum effective population size of Ne = 50 is needed to avoid extinction due to inbreeding depression in the short term, and of Ne = 500 to survive in the long term. However, the large inbreeding loads (B) usually found in nature, as well as the consideration of selection affecting genetic diversity, have led to a suggestion that those numbers should be doubled (100/1000). Purging of deleterious mutations can also be a main factor affecting the suggested rules. In a previous simulation study, the reduction of B by the action of purging pointed towards an MVP intermediate between the two rules for short term survival. Here, we focused on the consequences of purging in the establishment of MVPs for long term survival. We performed computer simulations of populations under the action of purging, drift, new mutation, and environmental effects on fitness to investigate the extinction times and the loss of genetic diversity for a range of effective population sizes. Our results indicate that purging can reduce the MVP needed for a population to persist in the long term, with estimates close to Ne = 500 for species with moderately large reproductive rates. However, MVP values appear to be of at least Ne = 1000 when the species´ reproductive rates are low.

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Reviewing the consequences of genetic purging on the success of rescue programs

Cited by 27 publications

References 94 publications

Quantifying the fraction of new mutations that are recessive lethal

Quantifying the fraction of new mutations that are recessive lethal

Genomic underpinnings of population persistence in Isle Royale moose

Prediction of the minimum effective size of a population viable in the long term

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