Your search keyword '"Sendell-Price AT"' showing total 9 results

1. Candidate gene polymorphisms are linked to dispersive and migratory behaviour: Searching for a mechanism behind the "paradox of the great speciators".

Author

Estandía A, Sendell-Price AT, Oatley G, Robertson F, Potvin D, Massaro M, Robertson BC, and Clegg SM

Subjects

Animals, Humans, Bayes Theorem, Polymorphism, Genetic, Biological Evolution, Animal Migration, Passeriformes genetics

Abstract

The "paradox of the great speciators" has puzzled evolutionary biologists for over half a century. A great speciator requires excellent dispersal propensity to explain its occurrence on multiple islands, but reduced dispersal ability to explain its high number of subspecies. A rapid reduction in dispersal ability is often invoked to solve this apparent paradox, but a proximate mechanism has not been identified yet. Here, we explored the role of six genes linked to migration and animal personality differences (CREB1, CLOCK, ADCYAP1, NPAS2, DRD4, and SERT) in 20 South Pacific populations of silvereye (Zosterops lateralis) that range from highly sedentary to partially migratory, to determine if genetic variation is associated with dispersal propensity and migration. We detected genetic associations in three of the six genes: (i) in a partial migrant population, migrant individuals had longer microsatellite alleles at the CLOCK gene compared to resident individuals from the same population; (ii) CREB1 displayed longer average microsatellite allele lengths in recently colonized island populations (<200 years), compared to evolutionarily older populations. Bayesian broken stick regression models supported a reduction in CREB1 length with time since colonization; and (iii) like CREB1, DRD4 showed differences in polymorphisms between recent and old colonizations but a larger sample is needed to confirm. ADCYAP1, SERT, and NPAS2 were variable but that variation was not associated with dispersal propensity. The association of genetic variants at three genes with migration and dispersal ability in silvereyes provides the impetus for further exploration of genetic mechanisms underlying dispersal shifts, and the prospect of resolving a long-running evolutionary paradox through a genetic lens., (© 2023 The Authors. Journal of Evolutionary Biology published by John Wiley & Sons Ltd on behalf of European Society for Evolutionary Biology.)

Published

2023

2. Rapid adaptive radiation of Darwin's finches depends on ancestral genetic modules.

Author

Rubin CJ, Enbody ED, Dobreva MP, Abzhanov A, Davis BW, Lamichhaney S, Pettersson M, Sendell-Price AT, Sprehn CG, Valle CA, Vasco K, Wallerman O, Grant BR, Grant PR, and Andersson L

Subjects

Animals, Beak, Genomics, Haplotypes, Finches genetics, Passeriformes

Abstract

Recent adaptive radiations are models for investigating mechanisms contributing to the evolution of biodiversity. An unresolved question is the relative importance of new mutations, ancestral variants, and introgressive hybridization for phenotypic evolution and speciation. Here, we address this issue using Darwin's finches and investigate the genomic architecture underlying their phenotypic diversity. Admixture mapping for beak and body size in the small, medium, and large ground finches revealed 28 loci showing strong genetic differentiation. These loci represent ancestral haplotype blocks with origins predating speciation events during the Darwin's finch radiation. Genes expressed in the developing beak are overrepresented in these genomic regions. Ancestral haplotypes constitute genetic modules for selection and act as key determinants of the unusual phenotypic diversity of Darwin's finches. Such ancestral haplotype blocks can be critical for how species adapt to environmental variability and change.

Published

2022

3. An island-hopping bird reveals how founder events shape genome-wide divergence.

Author

Sendell-Price AT, Ruegg KC, Robertson BC, and Clegg SM

Subjects

Animals, Founder Effect, Genetic Variation, Genome genetics, Phenotype, Selection, Genetic, Passeriformes genetics

Abstract

When populations colonize new areas, both strong selection and strong drift can be experienced due to novel environments and small founding populations, respectively. Empirical studies have predominantly focused on the phenotype when assessing the role of selection, and limited neutral-loci when assessing founder-induced loss of diversity. Consequently, the extent to which processes interact to influence evolutionary trajectories is difficult to assess. Genomic-level approaches provide the opportunity to simultaneously consider these processes. Here, we examine the roles of selection and drift in shaping genomic diversity and divergence in historically documented sequential island colonizations by the silvereye (Zosterops lateralis). We provide the first empirical demonstration of the rapid appearance of highly diverged genomic regions following population founding, the position of which are highly idiosyncratic. As these regions rarely contained loci putatively under selection, it is most likely that these differences arise via the stochastic nature of the founding process. However, selection is required to explain rapid evolution of larger body size in insular silvereyes. Reconciling our genomic data with these phenotypic patterns suggests there may be many genomic routes to the island phenotype, which vary across populations. Finally, we show that accelerated divergence associated with multiple founding steps is the product of genome-wide rather than localized differences, and that diversity erodes due to loss of rare alleles. However, even multiple founder events do not result in divergence and diversity levels seen in evolutionary older subspecies, and therefore do not provide a shortcut to speciation as proposed by founder-effect speciation models., (© 2021 The Authors. Molecular Ecology published by John Wiley & Sons Ltd.)

Published

2021

4. The Genomic Landscape of Divergence Across the Speciation Continuum in Island-Colonising Silvereyes ( Zosterops lateralis ).

Author

Sendell-Price AT, Ruegg KC, Anderson EC, Quilodrán CS, Van Doren BM, Underwood VL, Coulson T, and Clegg SM

Subjects

Animals, Gene Flow, Genome, Genomics, Selection, Genetic, Genetic Speciation, Passeriformes

Abstract

Inferring the evolutionary dynamics at play during the process of speciation by analyzing the genomic landscape of divergence is a major pursuit in population genomics. However, empirical assessments of genomic landscapes under varying evolutionary scenarios that are known a priori are few, thereby limiting our ability to achieve this goal. Here we combine RAD-sequencing and individual-based simulations to evaluate the genomic landscape of divergence in the silvereye ( Zosterops lateralis ). Using pairwise comparisons that differ in divergence timeframe and the presence or absence of gene flow, we document how genomic patterns accumulate along the speciation continuum. In contrast to previous predictions, our results provide limited support for the idea that divergence accumulates around loci under divergent selection or that genomic islands widen with time. While a small number of genomic islands were found in populations diverging with and without gene flow, in few cases were SNPs putatively under selection tightly associated with genomic islands. The transition from localized to genome-wide levels of divergence was captured using individual-based simulations that considered only neutral processes. Our results challenge the ubiquity of existing verbal models that explain the accumulation of genomic differences across the speciation continuum and instead support the idea that divergence both within and outside of genomic islands is important during the speciation process., (Copyright © 2020 Sendell-Price et al.)

Published

2020

5. Rapid morphological divergence following a human-mediated introduction: the role of drift and directional selection.

Author

Sendell-Price AT, Ruegg KC, and Clegg SM

Subjects

Animals, Genome, Introduced Species, New Zealand, Polymorphism, Single Nucleotide, Polynesia, Genetic Drift, Passeriformes anatomy & histology, Passeriformes genetics, Selection, Genetic

Abstract

Theory predicts that when populations are established by few individuals, random founder effects can facilitate rapid phenotypic divergence even in the absence of selective processes. However, empirical evidence from historically documented colonisations suggest that, in most cases, drift alone is not sufficient to explain the rate of morphological divergence. Here, using the human-mediated introduction of the silvereye (Zosterops lateralis) to French Polynesia, which represents a potentially extreme example of population founding, we reassess the potential for morphological shifts to arise via drift alone. Despite only 80 years of separation from their New Zealand ancestors, French Polynesian silvereyes displayed significant changes in body and bill size and shape, most of which could be accounted for by drift, without the need to invoke selection. However, signatures of selection at genes previously identified as candidates for bill size and body shape differences in a range of bird species, also suggests a role for selective processes in driving morphological shifts within this population. Twenty-four SNPs in our RAD-Seq dataset were also found to be strongly associated with phenotypic variation. Hence, even under population founding extremes, when it is difficult to reject drift as the sole mechanism based on rate tests of phenotypic shifts, the additional role of divergent natural selection in novel environments can be revealed at the level of the genome.

Published

2020

6. Rapid adaptive radiation of Darwin's finches depends on ancestral genetic modules

Author

Carl-Johan, Rubin, Erik D, Enbody, Mariya P, Dobreva, Arhat, Abzhanov, Brian W, Davis, Sangeet, Lamichhaney, Mats, Pettersson, Ashley T, Sendell-Price, C Grace, Sprehn, Carlos A, Valle, Karla, Vasco, Ola, Wallerman, B Rosemary, Grant, Peter R, Grant, and Leif, Andersson

Subjects

Haplotypes, Beak, Animals, Finches, Genomics, Passeriformes

Abstract

Recent adaptive radiations are models for investigating mechanisms contributing to the evolution of biodiversity. An unresolved question is the relative importance of new mutations, ancestral variants, and introgressive hybridization for phenotypic evolution and speciation. Here, we address this issue using Darwin's finches and investigate the genomic architecture underlying their phenotypic diversity. Admixture mapping for beak and body size in the small, medium, and large ground finches revealed 28 loci showing strong genetic differentiation. These loci represent ancestral haplotype blocks with origins predating speciation events during the Darwin's finch radiation. Genes expressed in the developing beak are overrepresented in these genomic regions. Ancestral haplotypes constitute genetic modules for selection and act as key determinants of the unusual phenotypic diversity of Darwin's finches. Such ancestral haplotype blocks can be critical for how species adapt to environmental variability and change.

Published

2022

7. The Genomic Landscape of Divergence Across the Speciation Continuum in Island-Colonising Silvereyes (Zosterops lateralis)

Author

Tim Coulson, Sonya M. Clegg, Ashley T. Sendell-Price, Benjamin M. Van Doren, Vinh Le Underwood, Kristen Ruegg, Eric C. Anderson, and Claudio S. Quilodrán

Subjects

0106 biological sciences, Zosterops lateralis, Genetic Speciation, Genomics, Context (language use), QH426-470, Investigations, RAD sequencing, Genomic landscape, 010603 evolutionary biology, 01 natural sciences, Gene flow, Divergence, Population genomics, Genomic heterogeneity, 03 medical and health sciences, Genetic algorithm, Genetics, Genomic valleys, Animals, Passeriformes, Selection, Genetic, Genomic islands, Evolutionary dynamics, Molecular Biology, Genetics (clinical), Selection (genetic algorithm), 030304 developmental biology, 0303 health sciences, Genome, biology, Small number, Simulated divergence, biology.organism_classification, Evolutionary biology, Corrigendum

Abstract

A goal of the genomic era is to infer the evolutionary dynamics at play during the process of speciation by analysing the genomic landscape of divergence. However, empirical assessments of genomic landscapes under varying evolutionary scenarios are few, limiting the ability to achieve this goal. Here we combine RAD-sequencing and individual-based simulations to evaluate the genomic landscape in the silvereye (Zosterops lateralis). Using comparisons matched for divergence timeframe and gene flow context, we document how genomic patterns accumulate along the speciation continuum. In contrast to previous predictions, our results provide limited support for the idea that divergence accumulates around loci under divergent selection or that genomic islands widen with time. While a small number of genomic islands were found in populations diverging with and without gene flow, in few cases were SNPs putatively under selection tightly associated with genomic islands. Furthermore, we modelled the transition from localised to genome-wide levels of divergence using individual-based simulations that considered only neutral processes. Our results challenge the ubiquity of existing verbal models that explain the accumulation of genomic differences across the speciation continuum and instead support the idea that divergence both within and outside of genomic islands is important during the speciation process.DATA ACCESSION NUMBERSResequencing data from this study have been submitted to the National Center for Biotechnology Information (NCBI; https://www.ncbi.nlm.nih.gov) under accession number PRJNA489169.

Published

2020

8. An island-hopping bird reveals how founder events shape genome-wide divergence

Author

Bruce C. Robertson, Sonya M. Clegg, Ashley T. Sendell-Price, and Kristen Ruegg

Subjects

0106 biological sciences, 0301 basic medicine, Zosterops lateralis, Population, Subspecies, 010603 evolutionary biology, 01 natural sciences, Divergence, 03 medical and health sciences, Genetic algorithm, Genetics, Animals, Passeriformes, Selection, Genetic, education, Ecology, Evolution, Behavior and Systematics, Selection (genetic algorithm), education.field_of_study, Genome, biology, Genetic Variation, Island hopping, biology.organism_classification, Founder Effect, Phenotype, 030104 developmental biology, Evolutionary biology, Founder effect

Abstract

When populations colonise new areas, both strong selection and strong drift can be experienced due to novel environments and small founding populations, respectively. Empirical studies have predominantly focused on the phenotype when assessing the role of selection, and limited neutral loci when assessing founder-induced loss of diversity. Consequently, the extent to which processes interact to influence evolutionary trajectories is difficult to assess. Genomic-level approaches provide the opportunity to simultaneously consider these processes. Here, we examine the roles of selection and drift in shaping genomic diversity and divergence in historically documented sequential island colonisations by the silvereye bird (Zosterops lateralis). We provide the first empirical demonstration of the rapid appearance of highly diverged genomic regions following population founding, the position of which are highly idiosyncratic. As these regions rarely contained loci putatively under selection, it is most likely that these differences arise via the stochastic nature of the founding process. However, selection is required to explain rapid evolution of larger body size in insular silvereyes. Reconciling our genomic data with these phenotypic patterns suggests there may be many genomic routes to the island phenotype, that vary across populations. Finally, we show that accelerated divergence associated with multiple founding steps is the product of genome-wide rather than localised differences, and that diversity erodes due to loss of rare alleles. However even multiple founder events do not result in divergence and diversity levels seen in evolutionary older subspecies, and therefore do not provide a shortcut to speciation as proposed by founder-effect speciation models.

Published

2021

9. Rapid morphological divergence following a human-mediated introduction: the role of drift and directional selection

Author

Sonya M. Clegg, Kristen C. Ruegg, and Ashley T. Sendell-Price

Subjects

0106 biological sciences, 0301 basic medicine, Population genetics, Range (biology), Zosterops lateralis, Population, Biology, Polymorphism, Single Nucleotide, 010603 evolutionary biology, 01 natural sciences, Article, Polynesia, Divergence, 03 medical and health sciences, Genetics, Animals, Passeriformes, Selection, Genetic, education, Genetics (clinical), Selection (genetic algorithm), Adaptive radiation, education.field_of_study, Genome, Natural selection, Directional selection, Genetic Drift, biology.organism_classification, 030104 developmental biology, Evolutionary biology, Introduced Species, New Zealand, Founder effect

Abstract

Theory predicts that when populations are established by few individuals, random founder effects can facilitate rapid phenotypic divergence even in the absence of selective processes. However, empirical evidence from historically documented colonisations suggest that, in most cases, drift alone is not sufficient to explain the rate of morphological divergence. Here, using the human-mediated introduction of the silvereye (Zosterops lateralis) to French Polynesia, which represents a potentially extreme example of population founding, we reassess the potential for morphological shifts to arise via drift alone. Despite only 80 years of separation from their New Zealand ancestors, French Polynesian silvereyes displayed significant changes in body and bill size and shape, most of which could be accounted for by drift, without the need to invoke selection. However, signatures of selection at genes previously identified as candidates for bill size and body shape differences in a range of bird species, also suggests a role for selective processes in driving morphological shifts within this population. Twenty-four SNPs in our RAD-Seq dataset were also found to be strongly associated with phenotypic variation. Hence, even under population founding extremes, when it is difficult to reject drift as the sole mechanism based on rate tests of phenotypic shifts, the additional role of divergent natural selection in novel environments can be revealed at the level of the genome.

Published

2020