Your search keyword '"Nosil, Patrik"' showing total 35 results

1. Natural Selection in Populations Subject to a Migration Load

Author

Bolnick, Daniel I. and Nosil, Patrik

Published

2007

2. Reproductive Isolation Caused by Visual Predation on Migrants between Divergent Environments

Author

Nosil, Patrik

Published

2004

3. Evolution repeats itself in replicate long-term studies in the wild.

Author

Nosil, Patrik, de Carvalho, Clarissa F., Villoutreix, Romain, Zamorano, Laura S., Sinclair-Waters, Marion, Planidin, Nicholas P., Parchman, Thomas L., Feder, Jeffrey, and Gompert, Zach

Subjects

*NATURAL selection, *PHASMIDA, *GENETIC variation, *FIELD research, *GENETIC mutation

Abstract

The extent to which evolution is repeatable remains debated. Here, we study changes over time in the frequency of cryptic color-pattern morphs in 10 replicate long-term field studies of a stick insect, each spanning at least a decade (across 30 years of total data). We find predictable "up-and-down" fluctuations in stripe frequency in all populations, representing repeatable evolutionary dynamics based on standing genetic variation. A field experiment demonstrates that these fluctuations involve negative frequency-dependent natural selection (NFDS). These fluctuations rely on demographic and selective variability that pushes populations away from equilibrium, such that they can reliably move back toward it via NFDS. Last, we show that the origin of new cryptic forms is associated with multiple structural genomic variants such that which mutations arise affects evolution at larger temporal scales. Thus, evolution from existing variation is predictable and repeatable, but mutation adds complexity even for traits evolving deterministically under natural selection. [ABSTRACT FROM AUTHOR]

Published

2024

4. Genome-Wide Association Mapping of Phenotypic Traits Subject to a Range of Intensities of Natural Selection in Timema cristinae *

Author

Comeault, Aaron A., Soria-Carrasco, Víctor, Gompert, Zach, Farkas, Timothy E., Buerkle, C. Alex, Parchman, Thomas L., and Nosil, Patrik

Published

2014

5. Complex evolutionary processes maintain an ancient chromosomal inversion.

Author

Nosil, Patrik, Soria-Carrasco, Victor, Villoutreix, Romain, De-la-Mora, Marisol, de Carvalho, Clarissa F., Parchman, Thomas, Feder, Jeffrey L., and Gompert, Zachariah

Subjects

*CHROMOSOME inversions, *NATURAL selection, *GENE flow, *GENETIC variation, *PHASMIDA

Abstract

Genome re-arrangements such as chromosomal inversions are often involved in adaptation. As such, they experience natural selection, which can erode genetic variation. Thus, whether and how inversions can remain polymorphic for extended periods of time remains debated. Here we combine genomics, experiments, and evolutionary modeling to elucidate the processes maintaining an inversion polymorphism associated with the use of a challenging host plant (Redwood trees) in Timema stick insects. We show that the inversion is maintained by a combination of processes, finding roles for life-history trade-offs, heterozygote advantage, local adaptation to different hosts, and gene flow. We use models to show how such multi-layered regimes of balancing selection and gene flow provide resilience to help buffer populations against the loss of genetic variation, maintaining the potential for future evolution. We further show that the inversion polymorphism has persisted for millions of years and is not a result of recent introgression. We thus find that rather than being a nuisance, the complex interplay of evolutionary processes provides a mechanism for the long-term maintenance of genetic variation. [ABSTRACT FROM AUTHOR]

Published

2023

6. Predicting and anticipating rapid evolution.

Author

Nosil, Patrik

Subjects

*DEFORESTATION, *ECOLOGICAL disturbances, *PHASMIDA, *NATURAL selection, *COLOR variation (Biology), *CYANIDES

Abstract

The article explores rapid evolution induced by human activities, highlighting a study by Ni et al. that demonstrates how deforestation alters species interactions and leads to color changes in the Batesian mimic, Zelandoperla. Topics include the mechanisms of evolution through altered predation dynamics, the implications of predicting evolutionary responses to environmental changes, and the integration of ecological and genetic data to enhance understanding of evolutionary processes.

Published

2024

7. Heterogeneous Genomic Differentiation between Walking-Stick Ecotypes: "Isolation by Adaptation" and Multiple Roles for Divergent Selection

Author

Nosil, Patrik, Egan, Scott P., and Funk, Daniel J.

Published

2008

8. Experimental Evidence That Predation Promotes Divergence in Adaptive Radiation

Author

Nosil, Patrik and Crespi, Bernard J.

Published

2006

9. Ecological Divergence Promotes the Evolution of Cryptic Reproductive Isolation

Author

Nosil, Patrik and Crespi, Bernard J.

Published

2006

10. The short‐term, genome‐wide effects of indirect selection deserve study: A response to Charlesworth and Jensen (2022).

Author

Gompert, Zachariah, Feder, Jeffrey L., and Nosil, Patrik

Subjects

LINKAGE disequilibrium, NATURAL selection, HITCHHIKING

Abstract

We recently published a paper quantifying the genome‐wide consequences of natural selection, including the effects of indirect selection due to the correlation of genetic regions (neutral or selected) with directly selected regions (Gompert et al., 2022). In their critique of our paper, Charlesworth and Jensen (2022) make two main points: (i) indirect selection is equivalent to hitchhiking and thus well documented (i.e., our results are not novel) and (ii) that we do not demonstrate the source of linkage disequilibrium (LD) between SNPs and the Mel‐Stripe locus in the Timema cristinae experiment we analyse. As we discuss in detail below, neither of these are substantial criticisms of our work. This is a reply to the commentary by Charlesworth and Jensen (2022); [ABSTRACT FROM AUTHOR]

Published

2022

11. Natural selection drives genome‐wide evolution via chance genetic associations.

Author

Gompert, Zachariah, Feder, Jeffrey L., and Nosil, Patrik

Subjects

NATURAL selection, APPLIED sciences, PHASMIDA, STATISTICAL association, GENOME-wide association studies

Abstract

Understanding selection's impact on the genome is a major theme in biology. Functionally neutral genetic regions can be affected indirectly by natural selection, via their statistical association with genes under direct selection. The genomic extent of such indirect selection, particularly across loci not physically linked to those under direct selection, remains poorly understood, as does the time scale at which indirect selection occurs. Here, we use field experiments and genomic data in stick insects, deer mice and stickleback fish to show that widespread statistical associations with genes known to affect fitness cause many genetic loci across the genome to be impacted indirectly by selection. This includes regions physically distant from those directly under selection. Then, focusing on the stick insect system, we show that statistical associations between SNPs and other unknown, causal variants result in additional indirect selection in general and specifically within genomic regions of physically linked loci. This widespread indirect selection necessarily makes aspects of evolution more predictable. Thus, natural selection combines with chance genetic associations to affect genome‐wide evolution across linked and unlinked loci and even in modest‐sized populations. This process has implications for the application of evolutionary principles in basic and applied science. [ABSTRACT FROM AUTHOR]

Published

2022

12. Comparative Analyses of Ecological Speciation

Author

Funk, Daniel J., author and Nosil, Patrik, author

Published

2008

13. Can the genomics of ecological speciation be predicted across the divergence continuum from host races to species? A case study in Rhagoletis.

Author

Meyers, Peter J., Doellman, Meredith M., Ragland, Gregory J., Hood, Glen R., Egan, Scott P., Powell, Thomas H. Q., Nosil, Patrik, and Feder, Jeffrey L.

Subjects

NATURAL selection, GENETIC speciation, BLUEBERRIES, CHROMOSOME inversions, GENOMICS, SINGLE nucleotide polymorphisms

Abstract

Studies assessing the predictability of evolution typically focus on short-term adaptation within populations or the repeatability of change among lineages. A missing consideration in speciation research is to determinewhether natural selection predictably transforms standing genetic variation within populations into differences between species. Here, we test whether and how host-related selection on diapause timing associates with genome-wide differentiation during ecological speciation by comparing ancestral hawthorn and newly formed apple-infesting host races of Rhagoletis pomonella to their sibling species Rhagoletis mendax that attacks blueberries. The associations of 57 857 single nucleotide polymorphisms in a diapause genome-wide-association study (GWAS) on the hawthorn race strongly predicted the direction and magnitude of genomic divergence among the three fly populations at a field site in Fennville, MI, USA. The apple race and R. mendax show parallel changes in the frequencies of putative inversions on three chromosomes associated with the earlier fruiting times of apples and blueberries compared to hawthorns. A diapause GWAS on R. mendax revealed compensatory changes throughout the genome accounting for the earlier eclosion of blueberry, but not apple flies. Thus, a degree of predictability, although not complete, exists in the genomics of diapause across the ecological speciation continuum in Rhagoletis. The generality of this result is placed in the context of other similar systems. This article is part of the theme issue 'Towards the completion of speciation: the evolution of reproductive isolation beyond the first barriers'. [ABSTRACT FROM AUTHOR]

Published

2020

14. Natural selection and the predictability of evolution in Timema stick insects.

Author

Nosil, Patrik, Villoutreix, Romain, de Carvalho, Clarissa F., Farkas, Timothy E., Soria-Carrasco, Víctor, Feder, Jeffrey L., Crespi, Bernard J., and Gompert, Zach

Subjects

*PHASMIDA, *NATURAL selection, *BIOLOGICAL evolution, *COLOR of insects, *POLYMORPHISM (Zoology)

Abstract

Predicting evolution remains difficult. We studied the evolution of cryptic body coloration and pattern in a stick insect using 25 years of field data, experiments, and genomics. We found that evolution is more difficult to predict when it involves a balance between multiple selective factors and uncertainty in environmental conditions than when it involves feedback loops that cause consistent back-and-forth fluctuations. Specifically, changes in color-morph frequencies are modestly predictable through time (r2 = 0.14) and driven by complex selective regimes and yearly fluctuations in climate. In contrast, temporal changes in pattern-morph frequencies are highly predictable due to negative frequency-dependent selection (r2 = 0.86). For both traits, however, natural selection drives evolution around a dynamic equilibrium, providing some predictability to the process. [ABSTRACT FROM AUTHOR]

Published

2018

15. Multilocus approaches for the measurement of selection on correlated genetic loci.

Author

Gompert, Zachariah, Egan, Scott P., Barrett, Rowan D. H., Feder, Jeffrey L., and Nosil, Patrik

Subjects

BIOLOGICAL adaptation, NATURAL selection, SURVIVAL behavior (Animals), GENOMES, REGRESSION analysis

Abstract

The study of ecological speciation is inherently linked to the study of selection. Methods for estimating phenotypic selection within a generation based on associations between trait values and fitness (e.g. survival) of individuals are established. These methods attempt to disentangle selection acting directly on a trait from indirect selection caused by correlations with other traits via multivariate statistical approaches (i.e. inference of selection gradients). The estimation of selection on genotypic or genomic variation could also benefit from disentangling direct and indirect selection on genetic loci. However, achieving this goal is difficult with genomic data because the number of potentially correlated genetic loci ( p) is very large relative to the number of individuals sampled ( n). In other words, the number of model parameters exceeds the number of observations ( p ≫ n). We present simulations examining the utility of whole-genome regression approaches (i.e. Bayesian sparse linear mixed models) for quantifying direct selection in cases where p ≫ n. Such models have been used for genome-wide association mapping and are common in artificial breeding. Our results show they hold promise for studies of natural selection in the wild and thus of ecological speciation. But we also demonstrate important limitations to the approach and discuss study designs required for more robust inferences. [ABSTRACT FROM AUTHOR]

Published

2017

16. Extremophile Poeciliidae: multivariate insights into the complexity of speciation along replicated ecological gradients.

Author

Riesch, Rüdiger, Tobler, Michael, Lerp, Hannes, Jourdan, Jonas, Doumas, Tess, Nosil, Patrik, Langerhans, R. Brian, and Plath, Martin

Subjects

MICROBIOLOGY of extreme environments, POECILIIDAE, REPRODUCTIVE isolation, GAMBUSIA, HYDROGEN sulfide, NATURAL selection

Abstract

Background: Replicate population pairs that diverge in response to similar selective regimes allow for an investigation of (a) whether phenotypic traits diverge in a similar and predictable fashion, (b) whether there is gradual variation in phenotypic divergence reflecting variation in the strength of natural selection among populations, (c) whether the extent of this divergence is correlated between multiple character suites (i.e., concerted evolution), and (d) whether gradual variation in phenotypic divergence predicts the degree of reproductive isolation, pointing towards a role for adaptation as a driver of (ecological) speciation. Here, we use poeciliid fishes of the genera Gambusia and Poecilia that have repeatedly evolved extremophile lineages able to tolerate high and sustained levels of toxic hydrogen sulfide (H2S) to answer these questions. Results: We investigated evolutionary divergence in response to H2S in Gambusia spp. (and to a lesser extent Poecilia spp.) using a multivariate approach considering the interplay of life history, body shape, and population genetics (nuclear miscrosatellites to infer population genetic differentiation as a proxy for reproductive isolation). We uncovered both shared and unique patterns of evolution: most extremophile Gambusia predictably evolved larger heads and offspring size, matching a priori predictions for adaptation to sulfidic waters, while variation in adult life histories was idiosyncratic. When investigating patterns for both genera (Gambusia and Poecilia), we found that divergence in offspring-related life histories and body shape were positively correlated across populations, but evidence for individual-level associations between the two character suites was limited, suggesting that genetic linkage, developmental interdependencies, or pleiotropic effects do not explain patterns of concerted evolution. We further found that phenotypic divergence was positively correlated with both environmental H2S-concentration and neutral genetic differentiation (a proxy for gene flow). Conclusions: Our results suggest that higher toxicity exerts stronger selection, and that divergent selection appears to constrain gene flow, supporting a scenario of ecological speciation. Nonetheless, progress toward ecological speciation was variable, partially reflecting variation in the strength of divergent selection, highlighting the complexity of selective regimes even in natural systems that are seemingly governed by a single, strong selective agent. [ABSTRACT FROM AUTHOR]

Published

2016

17. Color phenotypes are under similar genetic control in two distantly related species of Timema stick insect.

Author

Comeault, Aaron A., Carvalho, Clarissa F., Dennis, Stuart, Soria-Carrasco, Víctor, and Nosil, Patrik

Subjects

ECOLOGY, GENETIC polymorphisms, PHENOTYPES, ALLELES, HUMAN genetic variation

Abstract

Ecology and genetics are both of general interest to evolutionary biologists as they can influence the phenotypic and genetic response to selection. The stick insects Timema podura and Timema cristinae exhibit a green/melanistic body color polymorphism that is subject to different ecologically based selective regimes in the two species. Here, we describe aspects of the genetics of this color polymorphism in T. podura, and compare this to previous results in T. cristinae. We first show that similar color phenotypes of the two species cluster in phenotypic space. We then use genome-wide association mapping to show that in both species, color is controlled by few loci, dominance relationships between color alleles are the same, and SNPs associated with color phenotypes colocalize to the same linkage group. Regions within this linkage group that harbor genetic variants associated with color exhibit elevated linkage disequilibrium relative to genome wide expectations, but more strongly so in T. cristinae. We use these results to discuss predictions regarding how the genetics of color could influence levels of phenotypic and genetic variation that segregate within and between populations of T. podura and T. cristinae, drawing parallels with other organisms. [ABSTRACT FROM AUTHOR]

Published

2016

18. Chapter I.18: Ecological Speciation: Natural Selection and the Formation of New Species.

Author

Nosil, Patrik and Rundle, Howard

Subjects

SPECIES, NATURAL selection, BIOLOGICAL invasions, BIOLOGICAL evolution

Abstract

Understanding how new species arise is a central goal of evolutionary biology. Recent years have seen renewed interest in the classic idea that adaptive evolution within species and the origin of new species are intimately linked. More specifically, barriers to genetic exchange between populations (termed reproductive isolation) are the hallmark of species, and evolutionary biologists have been asking whether ecologically based divergent natural selection, the process that is responsible for adaptive divergence between populations, may cause such reproductive barriers to evolve. Convincing examples of this process, termed ecological speciation, are accumulating in the literature, and comparative approaches suggest that it may be a widespread phenomenon taxonomically. Attention is now being given to understanding details of the process and uncovering generalities in its operation. Three main components of ecological speciation can be recognized: a source of ecologically based divergent selection, a form of reproductive isolation, and a genetic mechanism linking the two. Current research is focused on understanding these components during the various stages of ecological speciation from initiation to completion. [ABSTRACT FROM PUBLISHER]

Published

2009

19. Experimental evidence for ecological selection on genome variation in the wild.

Author

Gompert, Zachariah, Comeault, Aaron A., Farkas, Timothy E., Feder, Jeffrey L., Parchman, Thomas L., Buerkle, C. Alex, and Nosil, Patrik

Subjects

BIOLOGICAL variation, NATURAL selection, GENETIC drift, LOCUS (Genetics), HOST plants, PHENOTYPES

Abstract

Understanding natural selection's effect on genetic variation is a major goal in biology, but the genome-scale consequences of contemporary selection are not well known. In a release and recapture field experiment we transplanted stick insects to native and novel host plants and directly measured allele frequency changes within a generation at 186 576 genetic loci. We observed substantial, genome-wide allele frequency changes during the experiment, most of which could be attributed to random mortality (genetic drift). However, we also documented that selection affected multiple genetic loci distributed across the genome, particularly in transplants to the novel host. Host-associated selection affecting the genome acted on both a known colour-pattern trait as well as other (unmeasured) phenotypes. We also found evidence that selection associated with elevation affected genome variation, although our experiment was not designed to test this. Our results illustrate how genomic data can identify previously underappreciated ecological sources and phenotypic targets of selection. [ABSTRACT FROM AUTHOR]

Published

2014

20. Genomic divergence during speciation: causes and consequences.

Author

Nosil, Patrik and Feder, Jeffrey L.

Subjects

*BIOLOGICAL divergence, *GENETIC speciation, *ORGANISMS, *NATURAL selection, *GENE flow, REPRODUCTIVE isolation

Abstract

Speciation is a fundamental process responsible for the diversity of life. Progress has been made in detecting individual 'speciation genes' that cause reproductive isolation. In contrast, until recently, less attention has been given to genome-wide patterns of divergence during speciation. Thus, major questions remain concerning how individual speciation genes are arrayed within the genome, and how this affects speciation. This theme issue is dedicated to exploring this genomic perspective of speciation. Given recent sequencing and computational advances that now allow genomic analyses in most organisms, the goal is to help move the field towards a more integrative approach. This issue draws upon empirical studies in plants and animals, and theoretical work, to review and further document patterns of genomic divergence. In turn, these studies begin to disentangle the role that different processes, such as natural selection, gene flow and recombination rate, play in generating observed patterns. These factors are considered in the context of how genomes diverge as speciation unfolds, from beginning to end. The collective results point to how experimental work is now required, in conjunction with theory and sequencing studies, to move the field from descriptive studies of patterns of divergence towards a predictive framework that tackles the causes and consequences of genome-wide patterns. [ABSTRACT FROM AUTHOR]

Published

2012

21. ADAPTIVE CHROMOSOMAL DIVERGENCE DRIVEN BY MIXED GEOGRAPHIC MODE OF EVOLUTION.

Author

Feder, Jeffrey L., Gejji, Richard, Powell, Thomas H. Q., and Nosil, Patrik

Subjects

CHROMOSOMES, BIOLOGICAL divergence, BIOLOGICAL evolution, BIOMARKERS, COMPUTER simulation, VICARIANCE, BIOLOGICAL variation, NATURAL selection

Abstract

Chromosomal inversions are ubiquitous in nature and of great significance for understanding adaptation and speciation. Inversions were the first markers used to investigate the genetic structure of natural populations, leading to the concept of coadapted gene complexes and theories concerning founder effects and genetic drift in small populations. However, we still lack elements of a general theory accounting for the origins and distribution of inversions in nature. Here, we use computer simulations to show that a 'mixed geographic mode' of evolution involving allopatric separation of populations followed by secondary contact and gene flow generates chromosomal divergence by natural selection under wider conditions than previous hypotheses. This occurs because inversions arising in allopatry contain a full complement of locally adapted genes. Once gene flow ensues, reduced recombination within inversions keeps these favorable genotypic combinations intact, resulting in inverted genomic regions being favored over collinear regions. This process allows inversions to establish to high frequencies. Our model can account for several classic patterns in the geographic distribution of inversions and highlights how selection on standing genetic variation allows rapid chromosomal evolution without the waiting time for new mutations. As inversion differences often separate closely related taxa, mixed modes of divergence could be common. [ABSTRACT FROM AUTHOR]

Published

2011

22. The role of gene expression in ecological speciation.

Author

Pavey, Scott A., Collin, Helene, Nosil, Patrik, and Rogers, Sean M.

Subjects

GENE expression, NATURAL selection, GENE regulatory networks, GENETIC speciation, GENE flow, BASE isolation system, PHENOTYPIC plasticity

Abstract

Ecological speciation is the process by which barriers to gene flow between populations evolve due to adaptive divergence via natural selection. A relatively unexplored area in ecological speciation is the role of gene expression. Gene expression may be associated with ecologically important phenotypes not evident from morphology and play a role during colonization of new environments. Here we review two potential roles of gene expression in ecological speciation: (1) its indirect role in facilitating population persistence and (2) its direct role in contributing to genetically based reproductive isolation. We find indirect evidence that gene expression facilitates population persistence, but direct tests are lacking. We also find clear examples of gene expression having effects on phenotypic traits and adaptive genetic divergence, but links to the evolution of reproductive isolation itself remain indirect. Gene expression during adaptive divergence seems to often involve complex genetic architectures controlled by gene networks, regulatory regions, and "eQTL hotspots." Nonetheless, we review how approaches for isolating the functional mutations contributing to adaptive divergence are proving to be successful. The study of gene expression has promise for increasing our understanding ecological speciation, particularly when integrative approaches are applied. [ABSTRACT FROM AUTHOR]

Published

2010

23. Ecological speciation in phytophagous insects.

Author

Matsubayashi, Kei W., Ohshima, Issei, and Nosil, Patrik

Subjects

INSECTS, BIOLOGICAL adaptation, SPECIES, GENETICS, NATURAL selection, REPRODUCTIVE isolation

Abstract

Divergent natural selection has been shown to promote speciation in a wide range of taxa. For example, adaptation to different ecological environments, via divergent selection, can result in the evolution of reproductive incompatibility between populations. Phytophagous insects have been at the forefront of these investigations of ‘ecological speciation’ and it is clear that adaptation to different host plants can promote insect speciation. However, much remains unknown. For example, there is abundant variability in the extent to which divergent selection promotes speciation, the sources of divergent selection, the types of reproductive barriers involved, and the genetic basis of divergent adaptation. We review these factors here. Several findings emerge, including the observation that although numerous different sources of divergent selection and reproductive isolation can be involved in insect speciation, their order of evolution and relative importance are poorly understood. Another finding is that the genetic basis of host preference and performance can involve loci of major effect and opposing dominance, factors which might facilitate speciation in the face of gene flow. In addition, we raise a number of other recent issues relating to phytophagous insect speciation, such as alternatives to ecological speciation, the geography of speciation, and the molecular signatures of speciation. Throughout, we aim to both synthesize what is known, as well as highlight areas where future work is especially needed. [ABSTRACT FROM AUTHOR]

Published

2010

24. The Genetics and Ecology of Reinforcement.

Author

Ortiz‐Barrientos, Daniel, Grealy, Alicia, and Nosil, Patrik

Subjects

GENETICS, SPECIES hybridization, REPRODUCTION, SPECIES, ECOLOGY, ZYGOTES

Abstract

Reinforcement, the evolution of prezygotic reproductive barriers by natural selection in response to maladaptive hybridization, is one of the most debated processes in speciation. Critics point to “fatal” conceptual flaws for sympatric evolution of prezygotic isolation, but recent theoretical and empirical work on genetics and ecology of reinforcement suggests that such criticisms can be overcome. New studies provide evidence for reinforcement in frogs, fish, insects, birds, and plants. While such evidence lays to rest the argument over reinforcement's existence, our understanding remains incomplete. We lack data on (1) the genetic basis of female preferences and the links between genetics of pre- and postzygotic isolation, (2) the ecological basis of reproductive isolation, (3) connections between prezygotic isolation between species and within-species sexual selection (potentially leading to a “cascade” of effects on reproductive isolation), (4) the role of habitat versus mate preference in reinforcement, and (5) additional detailed comparative studies. Here, we review data on these issues and highlight why they are important for understanding speciation. [ABSTRACT FROM AUTHOR]

Published

2009

25. Ecological explanations for (incomplete) speciation

Author

Nosil, Patrik, Harmon, Luke J., and Seehausen, Ole

Subjects

*SPECIES, *BIOLOGICAL invasions, *NATURAL selection, *REASONING

Abstract

Divergent natural selection has been shown to promote speciation in many taxa. However, although divergent selection often initiates the process of speciation, it often fails to complete it. Several time-based, geographic and genetic factors have been recognized to explain this variability in how far speciation proceeds. We review here recent evidence indicating that variability in the completeness of speciation can also be associated with the nature of divergent selection itself, with speciation being greatly promoted by (i) stronger selection on a given, single trait (the ‘stronger selection’ hypothesis) and (ii) selection on a greater number of traits (the ‘multifarious selection’ hypothesis). However, evidence for each selective hypothesis is still scarce, and further work is required to determine their relative importance. [Copyright &y& Elsevier]

Published

2009

26. Ernst Mayr and the integration of geographic and ecological factors in speciation.

Author

NOSIL, PATRIK

Subjects

*BIOLOGICAL divergence, *NATURAL selection, *ECOLOGICAL niche, REPRODUCTIVE isolation

Abstract

Mayr's best recognized scientific contributions include the biological species concept and the theory of geographic speciation. In the latter, reproductive isolation evolves as an incidental by-product of genetic divergence between allopatric populations. Mayr noted that divergent natural selection could accelerate speciation, but also argued that gene flow so strongly retards divergence that, even with selection, non-allopatric speciation is unlikely. However, current theory and data demonstrate that substantial divergence, and even speciation, in the face of gene flow is possible. Here, I attempt to connect some opposing views about speciation by integrating Mayr's ideas about the roles of ecology and geography in speciation with current data and theory. My central premise is that the speciation process (i.e. divergence) is often continuous, and that the opposing processes of selection and gene flow interact to determine the degree of divergence (i.e. the degree of progress towards the completion of speciation). I first establish that, in the absence of gene flow, divergent selection often promotes speciation. I then discuss how population differentiation in the face of gene flow is common when divergent selection occurs. However, such population differentiation does not always lead to the evolution of discontinuities, strong reproductive isolation, and thus speciation per se. I therefore explore the genetic and ecological circumstances that facilitate speciation in the face of gene flow. For example, particular genetic architectures or ecological niches may tip the balance between selection and gene flow strongly in favour of selection. The circumstances allowing selection to overcome gene flow to the extent that a discontinuity develops, and how often these circumstances occur, are major remaining questions in speciation research. © 2008 The Linnean Society of London, Biological Journal of the Linnean Society, 2008, 95, 26–46. [ABSTRACT FROM AUTHOR]

Published

2008

27. SELECTION AND GENOMIC DIFFERENTIATION DURING ECOLOGICAL SPECIATION: ISOLATING THE CONTRIBUTIONS OF HOST ASSOCIATION VIA A COMPARATIVE GENOME SCAN OF NEOCHLAMISUS BEBBIANAE LEAF BEETLES.

Author

Egan, Scott P., Nosil, Patrik, and Funk, Daniel J.

Subjects

*GENOMES, *BEETLES, *GENETICS, *NATURAL selection, *HERBIVORES, *INSECTS

Abstract

This study uses a comparative genome scan to evaluate the contributions of host plant related divergent selection to genetic differentiation and ecological speciation in maple- and willow-associated populations of Neochlamisus bebbianae leaf beetles. For each of 15 pairwise population comparisons, we identified “outlier loci” whose strong differentiation putatively reflects divergent selection. Of 447 AFLP loci, 15% were outliers across multiple population comparisons, and low linkage disequilibrium indicated that these outliers derived from multiple regions of the genome. Outliers were further classified as “host-specific” if repeatedly observed in “different-host” population comparisons but never in “same-host” comparisons. Outliers exhibiting the opposite pattern were analogously classified as “host-independent.” Host-specific outliers represented 5% of all loci and were more frequent than host-independent outliers, thus revealing a large role for host-adaptation in population genomic differentiation. Evidence that host-related selection can promote divergence despite gene flow was provided by population trees. These were structured by host-association when datasets included host-specific outliers, but not when based on neutral loci, which united sympatric populations. Lastly, three host-specific outliers were highly differentiated in all nine different-host comparisons. Because host-adaptation promotes reproductive isolation in these beetles, these loci provide promising candidate gene regions for future molecular studies of ecological speciation. [ABSTRACT FROM AUTHOR]

Published

2008

28. Divergent Host Plant Adaptation and Reproductive Isolation between Ecotypes of Timema cristinae Walking Sticks.

Author

Nosil, Patrik

Subjects

*NATURAL selection, *HOST plants, *GEOGRAPHY, *BIOLOGICAL evolution, *BIOLOGICAL variation, *BIOLOGICAL divergence, *GENE expression, *GENETIC regulation, REPRODUCTIVE isolation

Abstract

Theoretical and empirical studies have demonstrated that divergent natural selection can promote the evolution of reproductive isolation. Three unresolved questions concern the types of reproductive barriers involved, the role of geography, and the factors determining the extent of progress toward complete speciation. Here I synthesize studies of Timema cristinae host plant ecotypes to address these issues. The approach is to compare the magnitude of multiple reproductive barriers among different ecological and geographic scenarios, where pairs of populations within each scenario are the unit of replication. Application of this approach to T. cristinae revealed that divergent host adaptation can promote the evolution of diverse reproductive barriers, including those that are not inherently ecological. Gene flow in parapatry tended to constrain divergence, with the notable exception of the reinforcement of sexual isolation. Thus, geography affected progress toward speciation but did not influence all reproductive barriers in the same way. Studies of any single pair of taxa often capture only certain stages of the speciation process. For example, reproductive isolation between T. cristinae ecotypes is incomplete, and so only the stages before the completion of speciation have been examined. Studies of more divergent taxa within the genus are required to determine the factors that complete speciation. [ABSTRACT FROM AUTHOR]

Published

2007

29. PERSPECTIVE: REPRODUCTIVE ISOLATION CAUSED BY NATURAL SELECTION AGAINST IMMIGRANTS FROM DIVERGENT HABITATS.

Author

Nosil, Patrik, Vines, Timothy H., and Funk, Daniel J.

Subjects

*BIOLOGICAL classification, *REPRODUCTION, *HABITATS, *BIODIVERSITY, *BIOLOGICAL evolution, *NATURAL selection

Abstract

The classification of reproductive isolating barriers laid out by Dobzhansky and Mayr has motivated and structured decades of research on speciation. We argue, however, that this classification is incomplete and that the unique contributions of a major source of reproductive isolation have often been overlooked. Here, we describe reproductive barriers that derive from the reduced survival of immigrants upon reaching foreign habitats that are ecologically divergent from their native habitat. This selection against immigrants reduces encounters and thus mating opportunities between individuals from divergently adapted populations. It also reduces the likelihood that successfully mated immigrant females will survive long enough to produce their hybrid offspring. Thus, natural selection against immigrants results in distinctive elements of premating and postmating reproductive isolation that we hereby dub "immigrant inviability." We quantify the contributions of immigrant inviability to total reproductive isolation by examining study systems where multiple components of reproductive isolation have been measured and demonstrate that these contributions are frequently greater than those of traditionally recognized reproductive barriers. The relevance of immigrant inviability is further illustrated by a consideration of population-genetic theory, a review of selection against immigrant alleles in hybrid zone studies, and an examination of its participation in feedback loops that influence the evolution of additional reproductive barriers. Because some degree of immigrant inviability will commonly exist between populations that exhibit adaptive ecological divergence, we emphasize that these barriers play critical roles in ecological modes of speciation. We hope that the formal recognition of immigrant inviability and our demonstration of its evolutionary importance will stimulate more explicit empirical studies of its contributions to speciation. [ABSTRACT FROM AUTHOR]

Published

2005

30. Ecological speciation.

Author

Rundle, Howard D. and Nosil, Patrik

Subjects

*NATURAL selection, *BIOLOGICAL variation, *BIOLOGICAL evolution, *SEXUAL selection, *SPECIES

Abstract

Ecological processes are central to the formation of new species when barriers to gene flow (reproductive isolation) evolve between populations as a result of ecologically-based divergent selection. Although laboratory and field studies provide evidence that‘ecological speciation’ can occur, our understanding of the details of the process is incomplete. Here we review ecological speciation by considering its constituent components: an ecological source of divergent selection, a form of reproductive isolation, and a genetic mechanism linking the two. Sources of divergent selection include differences in environment or niche, certain forms of sexual selection, and the ecological interaction of populations. We explore the evidence for the contribution of each to ecological speciation. Forms of reproductive isolation are diverse and we discuss the likelihood that each may be involved in ecological speciation. Divergent selection on genes affecting ecological traits can be transmitted directly (via pleiotropy) or indirectly (via linkage disequilibrium) to genes causing reproductive isolation and we explore the consequences of both. Along with these components, we also discuss the geography and the genetic basis of ecological speciation. Throughout, we provide examples from nature, critically evaluate their quality, and highlight areas where more work is required. [ABSTRACT FROM AUTHOR]

Published

2005

31. Increasing our ability to predict contemporary evolution.

Author

Nosil, Patrik, Flaxman, Samuel M., Feder, Jeffrey L., and Gompert, Zachariah

Subjects

NATURAL selection, ABILITY, SCIENTISTS

Abstract

Classic debates concerning the extent to which scientists can predict evolution have gained new urgency as environmental changes force species to adapt or risk extinction. We highlight how our ability to predict evolution can be constrained by data limitations that cause poor understanding of deterministic natural selection. We then emphasize how such data limits can be reduced with feasible empirical effort involving a combination of approaches. [ABSTRACT FROM AUTHOR]

Published

2020

32. Evolution: Sex Limits Adaptation.

Author

Nosil, Patrik

Subjects

*EVOLUTIONARY theories, *BIOLOGICAL adaptation, *SEXUAL selection, *NATURAL selection, *SURVIVAL behavior (Animals)

Abstract

Summary Evolution is affected by survival of individuals and by mate choice, but how sexual selection affects adaptation remains unclear. A new study finds that sexual selection can limit adaptation by causing male-induced harm to females and thus opposing natural selection. [ABSTRACT FROM AUTHOR]

Published

2015

33. How maladaptation can structure biodiversity: eco-evolutionary island biogeography.

Author

Farkas, Timothy E., Hendry, Andrew P., Nosil, Patrik, and Beckerman, Andrew P.

Subjects

*BIOLOGICAL adaptation, *BIODIVERSITY, *BIOGEOGRAPHY, *BIOLOGICAL evolution, *NATURAL selection, *GENE flow

Abstract

Current research on eco-evolutionary dynamics is mainly concerned with understanding the role of rapid (or ‘contemporary’) evolution in structuring ecological patterns. We argue that the current eco-evolutionary research program, which focuses largely on natural selection, should be expanded to more explicitly consider other evolutionary processes such as gene flow. Because multiple evolutionary processes interact to generate quantitative variation in the degree of local maladaptation, we focus on how studying the ecological effects of maladaptation will lead to a more comprehensive view of how evolution can influence ecology. We explore how maladaptation can influence ecology through the lens of island biogeography theory, which yields some novel predictions, such as patch isolation increasing species richness. [ABSTRACT FROM AUTHOR]

Published

2015

34. A stabilizing eco-evolutionary feedback loop in the wild.

Author

Zamorano, Laura S., Gompert, Zachariah, Fronhofer, Emanuel A., Feder, Jeffrey L., and Nosil, Patrik

Subjects

*PROTECTIVE coloration (Biology), *PHASMIDA, *ECOSYSTEM dynamics, *COMMUNITIES, *INSECT adaptation, *PREDATION

Abstract

There is increasing evidence that evolutionary and ecological processes can operate on the same timescale 1,2 (i.e., contemporary time). As such, evolution can be sufficiently rapid to affect ecological processes such as predation or competition. Thus, evolution can influence population, community, and ecosystem-level dynamics. Indeed, studies have now shown that evolutionary dynamics can alter community structure 3,4,5,6 and ecosystem function. 7,8,9,10 In turn, shifts in ecological dynamics driven by evolution might feed back to affect the evolutionary trajectory of individual species. 11 This feedback loop, where evolutionary and ecological changes reciprocally affect one another, is a central tenet of eco-evolutionary dynamics. 1,12 However, most work on such dynamics in natural populations has focused on one-way causal associations between ecology and evolution. 13 Hence, direct empirical evidence for eco-evolutionary feedback is rare and limited to laboratory or mesocosm experiments. 13,14,15,16 Here, we show in the wild that eco-evolutionary dynamics in a plant-feeding arthropod community involve a negative feedback loop. Specifically, adaptation in cryptic coloration in a stick-insect species mediates bird predation, with local maladaptation increasing predation. In turn, the abundance of arthropods is reduced by predation. Here, we experimentally manipulate arthropod abundance to show that these changes at the community level feed back to affect the stick-insect evolution. Specifically, low-arthropod abundance increases the strength of selection on crypsis, increasing local adaptation of stick insects in a negative feedback loop. Our results suggest that eco-evolutionary feedbacks are able to stabilize complex systems by preventing consistent directional change and therefore increasing resilience. [Display omitted] • Feedbacks between ecology and evolution are challenging to demonstrate in the wild • We provide experimental evidence of such eco-evolutionary feedback loops in the wild • Low-arthropod abundance leads to strong selection on crypsis in a stick insect • The feedback loop is negative and promotes stability by preventing directional change Reciprocal interactions between ecological and evolutionary processes are a central tenet of eco-evolutionary dynamics but have rarely been demonstrated. Zamorano et al. demonstrate that changes in the arthropod community, driven by stick-insect evolution, can feed back to affect further evolution in the stick insect. [ABSTRACT FROM AUTHOR]

Published

2023

35. Stick Insect Genomes Reveal Natural Selection's Role in Parallel Speciation.

Author

Soria-Carrasco, Víctor, Gompert, Zachariah, Comeault, Aaron A., Farkas, Timothy E., Parchman, Thomas L., Johnston, J. Spencer, Buerkle, C. Alex, Feder, Jeffrey L., Bast, Jens, Schwander, Tanja, Egan, Scott P., Crespi, Bernard J., and Nosil, Patrik

Subjects

*NATURAL selection, *PHASMIDA, *GENETIC speciation, *INSECT evolution, *INSECT genomes, *SPECIES diversity, *GENETICS

Abstract

Natural selection can drive the repeated evolution of reproductive isolation, but the genomic basis of parallel speciation remains poorly understood. We analyzed whole-genome divergence between replicate pairs of stick insect populations that are adapted to different host plants and undergoing parallel speciation. We found thousands of modest-sized genomic regions of accentuated divergence between populations, most of which are unique to individual population pairs. We also detected parallel genomic divergence across population pairs involving an excess of coding genes with specific molecular functions. Regions of parallel genomic divergence in nature exhibited exceptional allele frequency changes between hosts in a field transplant experiment. The results advance understanding of biological diversification by providing convergent observational and experimental evidence for selection's role in driving repeatable genomic divergence. [ABSTRACT FROM AUTHOR]

Published

2014