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1. The value of long-term ecological research for evolutionary insights

Author

Cocciardi, Jennifer M., Hoffman, Ava M., Alvarado-Serrano, Diego F., Anderson, Jill, Blumstein, Meghan, Boehm, Emma L., Bolin, Lana G., Borokini, Israel T., Bradburd, Gideon S., Branch, Haley A., Brudvig, Lars A., Chen, Yanni, Collins, Scott L., Des Marais, David L., Gamba, Diana, Hanan, Niall P., Howard, Mia M., Jaros, Joseph, Juenger, Thomas E., Kooyers, Nicholas J., Kottler, Ezra J., Lau, Jennifer A., Menon, Mitra, Moeller, David A., Mozdzer, Thomas J., Sheth, Seema N., Smith, Melinda, Toll, Katherine, Ungerer, Mark C., Vahsen, Megan L., Wadgymar, Susana M., Waananen, Amy, Whitney, Kenneth D., and Avolio, Meghan L.

Published
2024
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2. Poor data stewardship will hinder global genetic diversity surveillance

Author

Toczydlowski, Rachel H., Liggins, Libby, Gaither, Michelle R., Anderson, Tanner J., Barton, Randi L., Berg, Justin T., Beskid, Sofia G., Davis, Beth, Delgado, Alonso, Farrell, Emily, Ghoojaei, Maryam, Himmelsbach, Nan, Holmes, Ann E., Queeno, Samantha R., Trinh, Thienthanh, Weyand, Courtney A., Bradburd, Gideon S., Riginos, Cynthia, Toonen, Robert J., and Crandall, Eric D.

Published
2021

4. Pitfalls and windfalls of detecting demographic declines using population genetics in long‐lived species.

Author

Clark, Meaghan I., Fitzpatrick, Sarah W., and Bradburd, Gideon S.

Subjects
DEMOGRAPHIC change, WILDLIFE conservation, GENETIC variation, RESEARCH personnel, CENTENARIANS
Abstract

Detecting recent demographic changes is a crucial component of species conservation and management, as many natural populations face declines due to anthropogenic habitat alteration and climate change. Genetic methods allow researchers to detect changes in effective population size (Ne) from sampling at a single timepoint. However, in species with long lifespans, there is a lag between the start of a decline in a population and the resulting decrease in genetic diversity. This lag slows the rate at which diversity is lost, and therefore makes it difficult to detect recent declines using genetic data. However, the genomes of old individuals can provide a window into the past, and can be compared to those of younger individuals, a contrast that may help reveal recent demographic declines. To test whether comparing the genomes of young and old individuals can help infer recent demographic bottlenecks, we use forward‐time, individual‐based simulations with varying mean individual lifespans and extents of generational overlap. We find that age information can be used to aid in the detection of demographic declines when the decline has been severe. When average lifespan is long, comparing young and old individuals from a single timepoint has greater power to detect a recent (within the last 50 years) bottleneck event than comparing individuals sampled at different points in time. Our results demonstrate how longevity and generational overlap can be both a hindrance and a boon to detecting recent demographic declines from population genomic data. [ABSTRACT FROM AUTHOR]

Published
2024
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6. The era of the ARG: An introduction to ancestral recombination graphs and their significance in empirical evolutionary genomics.

Author

Lewanski, Alexander L., Grundler, Michael C., and Bradburd, Gideon S.

Subjects
GENOMICS, GENOMES, BIOLOGY, GENEALOGY, AWARENESS
Abstract

In the presence of recombination, the evolutionary relationships between a set of sampled genomes cannot be described by a single genealogical tree. Instead, the genomes are related by a complex, interwoven collection of genealogies formalized in a structure called an ancestral recombination graph (ARG). An ARG extensively encodes the ancestry of the genome(s) and thus is replete with valuable information for addressing diverse questions in evolutionary biology. Despite its potential utility, technological and methodological limitations, along with a lack of approachable literature, have severely restricted awareness and application of ARGs in evolution research. Excitingly, recent progress in ARG reconstruction and simulation have made ARG-based approaches feasible for many questions and systems. In this review, we provide an accessible introduction and exploration of ARGs, survey recent methodological breakthroughs, and describe the potential for ARGs to further existing goals and open avenues of inquiry that were previously inaccessible in evolutionary genomics. Through this discussion, we aim to more widely disseminate the promise of ARGs in evolutionary genomics and encourage the broader development and adoption of ARG-based inference. [ABSTRACT FROM AUTHOR]

Published
2024
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8. Functional genomic diversity is correlated with neutral genomic diversity in populations of an endangered rattlesnake.

Author

Mathur, Samarth, Mason, Andrew J., Bradburd, Gideon S., and Gibbs, H. Lisle

Subjects
RATTLESNAKES, GENETIC variation, ENDANGERED species, INBREEDING, GENOMICS
Abstract

Theory predicts that genetic erosion in small, isolated populations of endangered species can be assessed using estimates of neutral genetic variation, yet this widely used approach has recently been questioned in the genomics era. Here, we leverage a chromosome-level genome assembly of an endangered rattlesnake (Sistrurus catenatus) combined with whole genome resequencing data (N = 110 individuals) to evaluate the relationship between levels of genome-wide neutral and functional diversity over historical and future timescales. As predicted, we found positive correlations between genome-wide estimates of neutral genetic diversity (π) and inferred levels of adaptive variation and an estimate of inbreeding mutation load, and a negative relationship between neutral diversity and an estimate of drift mutation load. However, these correlations were half as strong for projected future levels of neutral diversity based on contemporary effective population sizes. Broadly, our results confirm that estimates of neutral genetic diversity provide an accurate measure of genetic erosion in populations of a threatened vertebrate. They also provide nuance to the neutral-functional diversity controversy by suggesting that while these correlations exist, anthropogenetic impacts may have weakened these associations in the recent past and into the future. [ABSTRACT FROM AUTHOR]

Published
2023
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11. Modeling the Evolution of Rates of Continuous Trait Evolution.

Author

Martin, Bruce S, Bradburd, Gideon S, Harmon, Luke J, and Weber, Marjorie G

Subjects
*BIOLOGICAL evolution, *BEAKED whales, *BODY size, *CETACEA, *COMPARATIVE method
Abstract

Rates of phenotypic evolution vary markedly across the tree of life, from the accelerated evolution apparent in adaptive radiations to the remarkable evolutionary stasis exhibited by so-called "living fossils." Such rate variation has important consequences for large-scale evolutionary dynamics, generating vast disparities in phenotypic diversity across space, time, and taxa. Despite this, most methods for estimating trait evolution rates assume rates vary deterministically with respect to some variable of interest or change infrequently during a clade's history. These assumptions may cause underfitting of trait evolution models and mislead hypothesis testing. Here, we develop a new trait evolution model that allows rates to vary gradually and stochastically across a clade. Further, we extend this model to accommodate generally decreasing or increasing rates over time, allowing for flexible modeling of "early/late bursts" of trait evolution. We implement a Bayesian method, termed "evolving rates" (evorates for short), to efficiently fit this model to comparative data. Through simulation, we demonstrate that evorates can reliably infer both how and in which lineages trait evolution rates varied during a clade's history. We apply this method to body size evolution in cetaceans, recovering substantial support for an overall slowdown in body size evolution over time with recent bursts among some oceanic dolphins and relative stasis among beaked whales of the genus Mesoplodon. These results unify and expand on previous research, demonstrating the empirical utility of evorates. [cetacea; macroevolution; comparative methods; phenotypic diversity; disparity; early burst; late burst] [ABSTRACT FROM AUTHOR]

Published
2023
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13. Genetic isolation by distance underlies colour pattern divergence in red‐eyed treefrogs (Agalychnis callidryas).

Author

Clark, Meaghan I., Bradburd, Gideon S., Akopyan, Maria, Vega, Andres, Rosenblum, Erica Bree, and Robertson, Jeanne M.

Subjects
*GENETIC distance, *HYLIDAE, *SINGLE nucleotide polymorphisms, *GENETIC variation, *RED, REPRODUCTIVE isolation
Abstract

Investigating the spatial distribution of genetic and phenotypic variation can provide insights into the evolutionary processes that shape diversity in natural systems. We characterized patterns of genetic and phenotypic diversity to learn about drivers of colour‐pattern diversification in red‐eyed treefrogs (Agalychnis callidryas) in Costa Rica. Along the Pacific coast, red‐eyed treefrogs have conspicuous leg colour patterning that transitions from orange in the north to purple in the south. We measured phenotypic variation of frogs, with increased sampling at sites where the orange‐to‐purple transition occurs. At the transition zone, we discovered the co‐occurrence of multiple colour‐pattern morphs. To explore possible causes of this variation, we generated a single nucleotide polymorphism data set to analyse population genetic structure, measure genetic diversity and infer the processes that mediate genotype–phenotype dynamics. We investigated how patterns of genetic relatedness correspond to individual measures of colour pattern along the coast, including testing for the role of hybridization in geographic regions where orange and purple phenotypic groups co‐occur. We found no evidence that colour‐pattern polymorphism in the transition zone arose through recent hybridization. Instead, a strong pattern of genetic isolation by distance indicates that colour‐pattern variation was either retained through other processes such as ancestral colour polymorphisms or ancient secondary contact, or else it was generated by novel mutations. We found that phenotype changes along the Pacific coast more than would be expected based on genetic divergence and geographic distance alone. Combined, our results suggest the possibility of selective pressures acting on colour pattern at a small geographic scale. [ABSTRACT FROM AUTHOR]

Published
2022
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14. Broad Concordance in the Spatial Distribution of Adaptive and Neutral Genetic Variation across an Elevational Gradient in Deer Mice.

Author

Schweizer, Rena M, Jones, Matthew R, Bradburd, Gideon S, Storz, Jay F, Senner, Nathan R, Wolf, Cole, and Cheviron, Zachary A

Subjects
GENETIC variation, PHENOTYPES, NUCLEOTIDES, MITOCHONDRIAL physiology, GENOTYPES, NEOVASCULARIZATION
Abstract

When species are continuously distributed across environmental gradients, the relative strength of selection and gene flow shape spatial patterns of genetic variation, potentially leading to variable levels of differentiation across loci. Determining whether adaptive genetic variation tends to be structured differently than neutral variation along environmental gradients is an open and important question in evolutionary genetics. We performed exome-wide population genomic analysis on deer mice sampled along an elevational gradient of nearly 4,000 m of vertical relief. Using a combination of selection scans, genotype−environment associations, and geographic cline analyses, we found that a large proportion of the exome has experienced a history of altitude-related selection. Elevational clines for nearly 30% of these putatively adaptive loci were shifted significantly up- or downslope of clines for loci that did not bear similar signatures of selection. Many of these selection targets can be plausibly linked to known phenotypic differences between highland and lowland deer mice, although the vast majority of these candidates have not been reported in other studies of highland taxa. Together, these results suggest new hypotheses about the genetic basis of physiological adaptation to high altitude, and the spatial distribution of adaptive genetic variation along environmental gradients. [ABSTRACT FROM AUTHOR]

Published
2021
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15. Stepping into the past to conserve the future: Archived skin swabs from extant and extirpated populations inform genetic management of an endangered amphibian.

Author

Rothstein, Andrew P., Knapp, Roland A., Bradburd, Gideon S., Boiano, Daniel M., Briggs, Cheryl J., and Rosenblum, Erica Bree

Subjects
WILDLIFE reintroduction, WILDLIFE recovery, WATERSHEDS, AMPHIBIAN declines, WILDLIFE conservation, AMPHIBIANS
Abstract

Moving animals on a landscape through translocations and reintroductions is an important management tool used in the recovery of endangered species, particularly for the maintenance of population genetic diversity and structure. Management of imperiled amphibian species rely heavily on translocations and reintroductions, especially for species that have been brought to the brink of extinction by habitat loss, introduced species, and disease. One striking example of amphibian declines and associated management efforts is in California's Sequoia and Kings Canyon National Parks with the mountain yellow‐legged frog species complex (Rana sierrae/muscosa). Mountain yellow‐legged frogs have been extirpated from more than 93% of their historic range, and limited knowledge of their population genetics has made long‐term conservation planning difficult. To address this, we used 598 archived skin swabs from both extant and extirpated populations across 48 lake basins to generate a robust Illumina‐based nuclear amplicon data set. We found that samples grouped into three main genetic clusters, concordant with watershed boundaries. We also found evidence for historical gene flow across watershed boundaries with a north‐to‐south axis of migration. Finally, our results indicate that genetic diversity is not significantly different between populations with different disease histories. Our study offers specific management recommendations for imperiled mountain yellow‐legged frogs and, more broadly, provides a population genetic framework for leveraging minimally invasive samples for the conservation of threatened species. [ABSTRACT FROM AUTHOR]

Published
2020
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16. A spatial approach to jointly estimate Wright's neighborhood size and long-term effective population size.

Author

Hancock, Zachary B, Toczydlowski, Rachel H, and Bradburd, Gideon S

Subjects
*STATISTICAL models, *COMPUTER simulation, *RESEARCH funding, *POPULATION density, *POPULATION geography, *ANIMAL experimentation, *SPACE perception, *GENETICS, *NEIGHBORHOOD characteristics, *SOCIAL isolation
Abstract

Spatially continuous patterns of genetic differentiation, which are common in nature, are often poorly described by existing population genetic theory or methods that assume either panmixia or discrete, clearly definable populations. There is therefore a need for statistical approaches in population genetics that can accommodate continuous geographic structure, and that ideally use georeferenced individuals as the unit of analysis, rather than populations or subpopulations. In addition, researchers are often interested in describing the diversity of a population distributed continuously in space; this diversity is intimately linked to both the dispersal potential and the population density of the organism. A statistical model that leverages information from patterns of isolation by distance to jointly infer parameters that control local demography (such as Wright's neighborhood size), and the long-term effective size (Ne) of a population would be useful. Here, we introduce such a model that uses individual-level pairwise genetic and geographic distances to infer Wright's neighborhood size and long-term Ne. We demonstrate the utility of our model by applying it to complex, forward-time demographic simulations as well as an empirical dataset of the two-form bumblebee (Bombus bifarius). The model performed well on simulated data relative to alternative approaches and produced reasonable empirical results given the natural history of bumblebees. The resulting inferences provide important insights into the population genetic dynamics of spatially structured populations. [ABSTRACT FROM AUTHOR]

Published
2024
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17. Physiological and genomic evidence that selection on the transcription factor Epas1 has altered cardiovascular function in high-altitude deer mice.

Author

Schweizer, Rena M., Velotta, Jonathan P., Ivy, Catherine M., Jones, Matthew R., Muir, Sarah M., Bradburd, Gideon S., Storz, Jay F., Scott, Graham R., and Cheviron, Zachary A.

Subjects
TRANSCRIPTION factors, HYPOXIA-inducible factors, BIOLOGICAL fitness, BIOLOGICAL adaptation, DEER, GENETIC regulation, NATURAL selection
Abstract

Evolutionary adaptation to extreme environments often requires coordinated changes in multiple intersecting physiological pathways, but how such multi-trait adaptation occurs remains unresolved. Transcription factors, which regulate the expression of many genes and can simultaneously alter multiple phenotypes, may be common targets of selection if the benefits of induced changes outweigh the costs of negative pleiotropic effects. We combined complimentary population genetic analyses and physiological experiments in North American deer mice (Peromyscus maniculatus) to examine links between genetic variation in transcription factors that coordinate physiological responses to hypoxia (hypoxia-inducible factors, HIFs) and multiple physiological traits that potentially contribute to high-altitude adaptation. First, we sequenced the exomes of 100 mice sampled from different elevations and discovered that several SNPs in the gene Epas1, which encodes the oxygen sensitive subunit of HIF-2α, exhibited extreme allele frequency differences between highland and lowland populations. Broader geographic sampling confirmed that Epas1 genotype varied predictably with altitude throughout the western US. We then discovered that Epas1 genotype influences heart rate in hypoxia, and the transcriptomic responses to hypoxia (including HIF targets and genes involved in catecholamine signaling) in the heart and adrenal gland. Finally, we used a demographically-informed selection scan to show that Epas1 variants have experienced a history of spatially varying selection, suggesting that differences in cardiovascular function and gene regulation contribute to high-altitude adaptation. Our results suggest a mechanism by which Epas1 may aid long-term survival of high-altitude deer mice and provide general insights into the role that highly pleiotropic transcription factors may play in the process of environmental adaptation. Author summary: Adaptation often requires coordinated evolutionary changes across multiple dynamic systems to maintain physiological function. For example, high-altitude habitats place a premium on tissue-oxygen delivery to cope with limited oxygen availability (hypoxia). Circulatory O2 transport is regulated dynamically, changing on the order of seconds, and results from several interacting physiological processes. The mechanisms of adaptation in such complex phenotypes are poorly understood. One promising candidate is the gene Epas1, which encodes a transcription factor that regulates physiological responses to hypoxia. We used population genomic analyses and physiological assays to explore the connections between Epas1 genetic variation and physiological function in high-altitude deer mice, which exhibit evolutionary adaptations to hypoxia. We identified a mutation in Epas1 that is associated with variation in cardiovascular function: the predominant variant at high altitude is associated with the maintenance of an elevated heart rate under hypoxia and with differences in the expression of genes that influence heart rate and are regulated by Epas1. Our population genomic analyses demonstrated that Epas1 exhibits a signature of natural selection at high altitude, suggesting that these phenotypic effects influence Darwinian fitness. Our results suggest that adaptation in complex and dynamic traits may be attributable to relatively simple genetic changes. [ABSTRACT FROM AUTHOR]

Published
2019
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18. Spatial Population Genetics: It's About Time.

Author

Bradburd, Gideon S. and Ralph, Peter L.

Abstract

Many important questions about the history and dynamics of organisms have a geographical component: How many are there, and where do they live? How do they move and interbreed across the landscape? How were they moving a thousand years ago, and where were the ancestors of a particular individual alive today? Answers to these questions can have profound consequences for our understanding of history, ecology, and the evolutionary process. In this review, we discuss how geographic aspects of the distribution, movement, and reproduction of organisms are reflected in their pedigree across space and time. Because the structure of the pedigree is what determines patterns of relatedness in modern genetic variation, our aim is to thus provide intuition for how these processes leave an imprint in genetic data. We also highlight some current methods and gaps in the statistical toolbox of spatial population genetics. [ABSTRACT FROM AUTHOR]

Published
2019
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19. Disentangling the effects of geographic and ecological isolation on genetic differentiation

Author

Bradburd, Gideon S, Ralph, Peter L, and Coop, Graham M

Subjects
Evolutionary Biology, Ecology, Models, Genetic, Isolation by distance, landscape genetics, Bayes Theorem, Environment, Zea mays, Article, Markov Chains, partial Mantel test, Phylogeography, Genetic, Gene Frequency, Models, Genetics, Humans, isolation by ecology, Monte Carlo Method
Abstract

Populations can be genetically isolated both by geographic distance and by differences in their ecology or environment that decrease the rate of successful migration. Empirical studies often seek to investigate the relationship between genetic differentiation and some ecological variable(s) while accounting for geographic distance, but common approaches to this problem (such as the partial Mantel test) have a number of drawbacks. In this article, we present a Bayesian method that enables users to quantify the relative contributions of geographic distance and ecological distance to genetic differentiation between sampled populations or individuals. We model the allele frequencies in a set of populations at a set of unlinked loci as spatially correlated Gaussian processes, in which the covariance structure is a decreasing function of both geographic and ecological distance. Parameters of the model are estimated using a Markov chain Monte Carlo algorithm. We call this method Bayesian Estimation of Differentiation in Alleles by Spatial Structure and Local Ecology (BEDASSLE), and have implemented it in a user-friendly format in the statistical platform R. We demonstrate its utility with a simulation study and empirical applications to human and teosinte data sets.

Published
2013

20. A Spatial Framework for Understanding Population Structure and Admixture.

Author

Bradburd, Gideon S., Ralph, Peter L., and Coop, Graham M.

Subjects
*HUMAN genetic variation, *GENETIC polymorphism research, *POPULATION research, *GREENISH warbler, *COLONIZATION
Abstract

Geographic patterns of genetic variation within modern populations, produced by complex histories of migration, can be difficult to infer and visually summarize. A general consequence of geographically limited dispersal is that samples from nearby locations tend to be more closely related than samples from distant locations, and so genetic covariance often recapitulates geographic proximity. We use genome-wide polymorphism data to build “geogenetic maps,” which, when applied to stationary populations, produces a map of the geographic positions of the populations, but with distances distorted to reflect historical rates of gene flow. In the underlying model, allele frequency covariance is a decreasing function of geogenetic distance, and nonlocal gene flow such as admixture can be identified as anomalously strong covariance over long distances. This admixture is explicitly co-estimated and depicted as arrows, from the source of admixture to the recipient, on the geogenetic map. We demonstrate the utility of this method on a circum-Tibetan sampling of the greenish warbler (Phylloscopus trochiloides), in which we find evidence for gene flow between the adjacent, terminal populations of the ring species. We also analyze a global sampling of human populations, for which we largely recover the geography of the sampling, with support for significant histories of admixture in many samples. This new tool for understanding and visualizing patterns of population structure is implemented in a Bayesian framework in the program SpaceMix. [ABSTRACT FROM AUTHOR]

Published
2016
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21. Isolation by environment.

Author

Wang, Ian J. and Bradburd, Gideon S.

Subjects
*ALGAE-cnidarian relationships, *HUMAN genetic variation, *GENETICS, *BIOLOGICAL divergence, REPRODUCTIVE isolation
Abstract

The interactions between organisms and their environments can shape distributions of spatial genetic variation, resulting in patterns of isolation by environment ( IBE) in which genetic and environmental distances are positively correlated, independent of geographic distance. IBE represents one of the most important patterns that results from the ways in which landscape heterogeneity influences gene flow and population connectivity, but it has only recently been examined in studies of ecological and landscape genetics. Nevertheless, the study of IBE presents valuable opportunities to investigate how spatial heterogeneity in ecological processes, agents of selection and environmental variables contributes to genetic divergence in nature. New and increasingly sophisticated studies of IBE in natural systems are poised to make significant contributions to our understanding of the role of ecology in genetic divergence and of modes of differentiation both within and between species. Here, we describe the underlying ecological processes that can generate patterns of IBE, examine its implications for a wide variety of disciplines and outline several areas of future research that can answer pressing questions about the ecological basis of genetic diversity. [ABSTRACT FROM AUTHOR]

Published
2014
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22. Genomic and Fitness Consequences of Genetic Rescue in Wild Populations.

Author

Fitzpatrick, Sarah W., Bradburd, Gideon S., Kremer, Colin T., Salerno, Patricia E., Angeloni, Lisa M., and Funk, W. Chris

Subjects
*GENE flow, *RESCUES, *GUPPIES
Abstract

Gene flow is an enigmatic evolutionary force because it can limit adaptation but may also rescue small populations from inbreeding depression [ 1–3 ]. Several iconic examples of genetic rescue—increased population growth caused by gene flow [ 4 , 5 ]—have reversed population declines [ 6 , 7 ]. However, concerns about outbreeding depression and maladaptive gene flow limit the use of human-mediated gene flow in conservation [ 8 , 9 ]. Rescue effects of immigration through demographic and/or genetic mechanisms have received theoretical and empirical support, but studies that monitor initial and long-term effects of gene flow on individuals and populations in the wild are lacking. Here, we used individual-based mark-recapture, multigenerational pedigrees, and genomics to test the demographic and evolutionary consequences of manipulating gene flow in two isolated, wild Trinidadian guppy populations. Recipient and source populations originated from environments with different predation, flow, and resource regimes [ 10 ]. We documented 10-fold increases in population size following gene flow and found that, on average, hybrids lived longer and reproduced more than residents and immigrants. Despite overall genomic homogenization, alleles potentially associated with local adaptation were not entirely swamped by gene flow. Our results suggest that genetic rescue was caused not just by increasing individual genetic diversity, rather new genomic variation from immigrants combined with alleles from the recipient population resulted in highly fit hybrids and subsequent increases in population size. Contrary to the classic view of maladaptive gene flow, our study reveals conditions under which immigration can produce long-term fitness benefits in small populations without entirely swamping adaptive variation. • New gene flow into small, isolated guppy populations led to increases in abundance • Mark-recapture and pedigree data show high hybrid survival and reproductive success • Candidate adaptive alleles resist introgression more than neutral expectations • Gene flow can rescue small populations without erasing adaptive variation Gene flow can limit adaptation but may also rescue small populations. Fitzpatrick et al. document genetic rescue in small populations of Trinidadian guppies. Wild pedigrees and mark-recapture data reveal high hybrid fitness and maintenance of putative adaptive alleles, suggesting assisted gene flow may be an effective conservation strategy. [ABSTRACT FROM AUTHOR]

Published
2020
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24. A geographic history of human genetic ancestry.

Author

Grundler MC, Terhorst J, and Bradburd GS

Abstract

Describing the distribution of genetic variation across individuals is a fundamental goal of population genetics. In humans, traditional approaches for describing population genetic variation often rely on discrete genetic ancestry labels, which, despite their utility, can obscure the complex, multi-faceted nature of human genetic history. These labels risk oversimplifying ancestry by ignoring its temporal depth and geographic continuity, and may therefore conflate notions of race, ethnicity, geography, and genetic ancestry. Here, we present a method that capitalizes on the rich genealogical information encoded in genomic tree sequences to infer the geographic locations of the shared ancestors of a sample of sequenced individuals. We use this method to infer the geographic history of genetic ancestry of a set of human genomes sampled from Europe, Asia, and Africa, accurately recovering major population movements on those continents. Our findings demonstrate the importance of defining the spatial-temporal context of genetic ancestry to describing human genetic variation and caution against the oversimplified interpretations of genetic data prevalent in contemporary discussions of race and ancestry.

Published
2024
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25. The Roles of Drift and Selection on Short Stamen Loss in Arabidopsis thaliana along an Elevational Gradient in the Spanish Pyrenees.

Author

Buysse SF, Pérez SG, Puzey JR, Garrison A, Bradburd GS, Oakley CG, Tonsor SJ, Picó FX, Josephs EB, and Conner JK

Abstract

Traits that have lost function sometimes persist through evolutionary time. These traits may be maintained by a lack of standing genetic variation for the trait, if selection against the trait is weak relative to drift, or if they have a residual function. To determine the evolutionary processes shaping whether nonfunctional traits are retained or lost, we investigated short stamens in 16 populations of Arabidopsis thaliana along an elevational cline in the Spanish Pyrenees. We found a cline in short stamen number from retention of short stamens in high elevation populations to incomplete loss in low elevation populations. We did not find evidence that limited genetic variation constrains the loss of short stamens at high elevations nor evidence for divergent selection on short stamens between high and low elevations. Finally, we identified loci associated with short stamens in the Spanish Pyrenees that are different from loci associated with variation in short stamen number across latitudes from a previous study. Overall, we did not identify the evolutionary mechanisms maintaining an elevational cline in short stamen number but did identify different genetic loci underlying the variation in short stamen along similar phenotypic clines., Competing Interests: Conflict of Interest: The authors declare no conflicts of interest.

Published
2024
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26. Pitfalls and windfalls of detecting demographic declines using population genetics in long-lived species.

Author

Clark MI, Fitzpatrick SW, and Bradburd GS

Abstract

Detecting recent demographic changes is a crucial component of species conservation and management, as many natural populations face declines due to anthropogenic habitat alteration and climate change. Genetic methods allow researchers to detect changes in effective population size (N e ) from sampling at a single timepoint. However, in species with long lifespans, there is a lag between the start of a decline in a population and the resulting decrease in genetic diversity. This lag slows the rate at which diversity is lost, and therefore makes it difficult to detect recent declines using genetic data. However, the genomes of old individuals can provide a window into the past, and can be compared to those of younger individuals, a contrast that may help reveal recent demographic declines. To test whether comparing the genomes of young and old individuals can help infer recent demographic bottlenecks, we use forward-time, individual-based simulations with varying mean individual lifespans and extents of generational overlap. We find that age information can be used to aid in the detection of demographic declines when the decline has been severe. When average lifespan is long, comparing young and old individuals from a single timepoint has greater power to detect a recent (within the last 50 years) bottleneck event than comparing individuals sampled at different points in time. Our results demonstrate how longevity and generational overlap can be both a hindrance and a boon to detecting recent demographic declines from population genomic data.

Published
2024
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27. The era of the ARG: an empiricist's guide to ancestral recombination graphs.

Author

Lewanski AL, Grundler MC, and Bradburd GS

Abstract

In the presence of recombination, the evolutionary relationships between a set of sampled genomes cannot be described by a single genealogical tree. Instead, the genomes are related by a complex, interwoven collection of genealogies formalized in a structure called an ancestral recombination graph (ARG). An ARG extensively encodes the ancestry of the genome(s) and thus is replete with valuable information for addressing diverse questions in evolutionary biology. Despite its potential utility, technological and methodological limitations, along with a lack of approachable literature, have severely restricted awareness and application of ARGs in empirical evolution research. Excitingly, recent progress in ARG reconstruction and simulation have made ARG-based approaches feasible for many questions and systems. In this review, we provide an accessible introduction and exploration of ARGs, survey recent methodological breakthroughs, and describe the potential for ARGs to further existing goals and open avenues of inquiry that were previously inaccessible in evolutionary genomics. Through this discussion, we aim to more widely disseminate the promise of ARGs in evolutionary genomics and encourage the broader development and adoption of ARG-based inference.

Published
2023

28. Importance of timely metadata curation to the global surveillance of genetic diversity.

Author

Crandall ED, Toczydlowski RH, Liggins L, Holmes AE, Ghoojaei M, Gaither MR, Wham BE, Pritt AL, Noble C, Anderson TJ, Barton RL, Berg JT, Beskid SG, Delgado A, Farrell E, Himmelsbach N, Queeno SR, Trinh T, Weyand C, Bentley A, Deck J, Riginos C, Bradburd GS, and Toonen RJ

Subjects
Humans, Biodiversity, Probability, Genetic Variation, Conservation of Natural Resources, Metadata
Abstract

Genetic diversity within species represents a fundamental yet underappreciated level of biodiversity. Because genetic diversity can indicate species resilience to changing climate, its measurement is relevant to many national and global conservation policy targets. Many studies produce large amounts of genome-scale genetic diversity data for wild populations, but most (87%) do not include the associated spatial and temporal metadata necessary for them to be reused in monitoring programs or for acknowledging the sovereignty of nations or Indigenous peoples. We undertook a distributed datathon to quantify the availability of these missing metadata and to test the hypothesis that their availability decays with time. We also worked to remediate missing metadata by extracting them from associated published papers, online repositories, and direct communication with authors. Starting with 848 candidate genomic data sets (reduced representation and whole genome) from the International Nucleotide Sequence Database Collaboration, we determined that 561 contained mostly samples from wild populations. We successfully restored spatiotemporal metadata for 78% of these 561 data sets (n = 440 data sets with data on 45,105 individuals from 762 species in 17 phyla). Examining papers and online repositories was much more fruitful than contacting 351 authors, who replied to our email requests 45% of the time. Overall, 23% of our email queries to authors unearthed useful metadata. The probability of retrieving spatiotemporal metadata declined significantly as age of the data set increased. There was a 13.5% yearly decrease in metadata associated with published papers or online repositories and up to a 22% yearly decrease in metadata that were only available from authors. This rapid decay in metadata availability, mirrored in studies of other types of biological data, should motivate swift updates to data-sharing policies and researcher practices to ensure that the valuable context provided by metadata is not lost to conservation science forever., (© 2023 The Authors. Conservation Biology published by Wiley Periodicals LLC on behalf of Society for Conservation Biology.)

Published
2023
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29. A spatial approach to jointly estimate Wright's neighborhood size and long-term effective population size.

Author

Hancock ZB, Toczydlowski RH, and Bradburd GS

Abstract

Spatially continuous patterns of genetic differentiation, which are common in nature, are often poorly described by existing population genetic theory or methods that assume panmixia or discrete, clearly definable populations. There is therefore a need for statistical approaches in population genetics that can accommodate continuous geographic structure, and that ideally use georeferenced individuals as the unit of analysis, rather than populations or subpopulations. In addition, researchers are often interested describing the diversity of a population distributed continuously in space, and this diversity is intimately linked to the dispersal potential of the organism. A statistical model that leverages information from patterns of isolation-by-distance to jointly infer parameters that control local demography (such as Wright's neighborhood size), and the long-term effective size ( N ) of a population would be useful. Here, we introduce such a model that uses individual-level pairwise genetic and geographic distances to infer Wright's neighborhood size and long-term e ) of a population would be useful. Here, we introduce such a model that uses individual-level pairwise genetic and geographic distances to infer Wright's neighborhood size and long-term N e . We demonstrate the utility of our model by applying it to complex, forward-time demographic simulations as well as an empirical dataset of the Red Sea clownfish ( Amphiprion bicinctus ). The model performed well on simulated data relative to alternative approaches and produced reasonable empirical results given the natural history of clownfish. The resulting inferences provide important insights into the population genetic dynamics of spatially structure populations.

Published
2023
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30. Inferring Continuous and Discrete Population Genetic Structure Across Space.

Author

Bradburd GS, Coop GM, and Ralph PL

Subjects
Animals, Cluster Analysis, Data Interpretation, Statistical, Gene Flow genetics, Genetic Variation genetics, Humans, Models, Genetic, North America, Population Groups genetics, Populus genetics, Ursidae genetics, Genetics, Population methods, Genetics, Population statistics & numerical data
Abstract

A classic problem in population genetics is the characterization of discrete population structure in the presence of continuous patterns of genetic differentiation. Especially when sampling is discontinuous, the use of clustering or assignment methods may incorrectly ascribe differentiation due to continuous processes ( e.g. , geographic isolation by distance) to discrete processes, such as geographic, ecological, or reproductive barriers between populations. This reflects a shortcoming of current methods for inferring and visualizing population structure when applied to genetic data deriving from geographically distributed populations. Here, we present a statistical framework for the simultaneous inference of continuous and discrete patterns of population structure. The method estimates ancestry proportions for each sample from a set of two-dimensional population layers, and, within each layer, estimates a rate at which relatedness decays with distance. This thereby explicitly addresses the "clines versus clusters" problem in modeling population genetic variation, and remedies some of the overfitting to which nonspatial models are prone. The method produces useful descriptions of structure in genetic relatedness in situations where separated, geographically distributed populations interact, as after a range expansion or secondary contact. We demonstrate the utility of this approach using simulations and by applying it to empirical datasets of poplars and black bears in North America., (Copyright © 2018 Bradburd et al.)

Published
2018
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