Your search keyword '"Meirmans, Patrick G."' showing total 4 results

1. Correcting for Replicated Genotypes May Introduce More Problems Than it Solves.

Author

Meirmans, Patrick G.

Subjects

*POPULATION differentiation, *GENETIC variation, *ASEXUAL reproduction, *MOLECULAR cloning, *GENE flow

Abstract

ABSTRACT Across the tree of life, many organisms are able to reproduce clonally, via vegetative spread, budding or parthenogenesis. In population genetic analyses of clonally reproducing organisms, it is common practice to retain only a single representative per multilocus genotype. Though this practice of clone correction is widespread, the theoretical justification behind it has been very little studied. Here, I use individual‐based simulations to study the effect of clone correction on the estimation of the genetic summary statistics HO, HS, FIS, FST, F′′ST and Dest. The simulations follow the standard finite island model, consisting of a set of populations connected by gene flow, but with a variable rate of sexual versus asexual reproduction. The results of the simulations show that by itself, the inclusion of replicated genotypes does not lead to a deviation in the values of the summary statistics, except when the rate of sexual reproduction is less than about one in thousand. However, clone correction can introduce a strong deviation in the values of most of the statistics, when compared to a scenario of full sexual reproduction. For HS and FIS, this deviation can be informative about the process of asexual reproduction, but for FST, F′′ST and Dest, clone correction can lead to incorrect conclusions. I therefore argue that clone correction is not strictly necessary, but can in some cases be insightful. However, when clone correction is applied, it is imperative that results for both the corrected and uncorrected data are presented. [ABSTRACT FROM AUTHOR]

Published

2024

2. Natural selection on feralization genes contributed to the invasive spread of wild pigs throughout the United States

Author

Barmentlo, Niek W. G., primary, Meirmans, Patrick G., additional, Stiver, William H., additional, Yarkovich, Joseph G., additional, McCann, Blake E., additional, Piaggio, Antoinette J., additional, Wright, Dominic, additional, Smyser, Timothy J., additional, and Bosse, Mirte, additional

Published

2024

3. Natural selection on feralization genes contributed to the invasive spread of wild pigs throughout the United States

Author

Barmentlo, Niek W.G., Meirmans, Patrick G., Stiver, William H., Yarkovich, Joseph G., McCann, Blake E., Piaggio, Antoinette J., Wright, Dominic, Smyser, Timothy J., Bosse, Mirte, Barmentlo, Niek W.G., Meirmans, Patrick G., Stiver, William H., Yarkovich, Joseph G., McCann, Blake E., Piaggio, Antoinette J., Wright, Dominic, Smyser, Timothy J., and Bosse, Mirte

Abstract

Despite a long presence in the contiguous United States (US), the distribution of invasive wild pigs (Sus scrofa × domesticus) has expanded rapidly since the 1980s, suggesting a more recent evolutionary shift towards greater invasiveness. Contemporary populations of wild pigs represent exoferal hybrid descendants of domestic pigs and European wild boar, with such hybridization expected to enrich genetic diversity and increase the adaptive potential of populations. Our objective was to characterize how genetic enrichment through hybridization increases the invasiveness of populations by identifying signals of selection and the ancestral origins of selected loci. Our study focused on invasive wild pigs within Great Smoky Mountains National Park, which represents a hybrid population descendent from the admixture of established populations of feral pigs and an introduction of European wild boar to North America. Accordingly, we genotyped 881 wild pigs with multiple high-density single-nucleotide polymorphism (SNP) arrays. We found 233 markers under putative selection spread over 79 regions across 16 out of 18 autosomes, which contained genes involved in traits affecting feralization. Among these, genes were found to be related to skull formation and neurogenesis, with two genes, TYRP1 and TYR, also encoding for crucial melanogenesis enzymes. The most common haplotypes associated with regions under selection for the Great Smoky Mountains population were also common among other populations throughout the region, indicating a key role of putatively selective variants in the fitness of invasive populations. Interestingly, many of these haplotypes were absent among European wild boar reference genotypes, indicating feralization through genetic adaptation.

Published

2024

4. Natural selection on feralization genes contributed to the invasive spread of wild pigs throughout the United States

Author

Barmentlo, Niek W. G., Meirmans, Patrick G., Stiver, William H., Yarkovich, Joseph G., McCann, Blake E., Piaggio, Antoinette J., Wright, Dominic, Smyser, Timothy J., Bosse, Mirte, Barmentlo, Niek W. G., Meirmans, Patrick G., Stiver, William H., Yarkovich, Joseph G., McCann, Blake E., Piaggio, Antoinette J., Wright, Dominic, Smyser, Timothy J., and Bosse, Mirte

Abstract

Despite a long presence in the contiguous United States (US), the distribution of invasive wild pigs (Sus scrofa x domesticus) has expanded rapidly since the 1980s, suggesting a more recent evolutionary shift towards greater invasiveness. Contemporary populations of wild pigs represent exoferal hybrid descendants of domestic pigs and European wild boar, with such hybridization expected to enrich genetic diversity and increase the adaptive potential of populations. Our objective was to characterize how genetic enrichment through hybridization increases the invasiveness of populations by identifying signals of selection and the ancestral origins of selected loci. Our study focused on invasive wild pigs within Great Smoky Mountains National Park, which represents a hybrid population descendent from the admixture of established populations of feral pigs and an introduction of European wild boar to North America. Accordingly, we genotyped 881 wild pigs with multiple high-density single-nucleotide polymorphism (SNP) arrays. We found 233 markers under putative selection spread over 79 regions across 16 out of 18 autosomes, which contained genes involved in traits affecting feralization. Among these, genes were found to be related to skull formation and neurogenesis, with two genes, TYRP1 and TYR, also encoding for crucial melanogenesis enzymes. The most common haplotypes associated with regions under selection for the Great Smoky Mountains population were also common among other populations throughout the region, indicating a key role of putatively selective variants in the fitness of invasive populations. Interestingly, many of these haplotypes were absent among European wild boar reference genotypes, indicating feralization through genetic adaptation., Funding Agencies|USDA APHIS National Feral Swine Damage Management Program; USDA APHIS WS National Feral Swine Damage Management Program

Published

2024