Your search keyword '"genome-wide selection scans"' showing total 10 results

1. Joint Analysis of Phenotypic and Genomic Diversity Sheds Light on the Evolution of Xenobiotic Metabolism in Humans.

Author

Mouterde, Médéric, Daali, Youssef, Rollason, Victoria, Čížková, Martina, Mulugeta, Anwar, Balushi, Khalid A Al, Fakis, Giannoulis, Constantinidis, Theodoros C, Al-Thihli, Khalid, Černá, Marie, Makonnen, Eyasu, Boukouvala, Sotiria, Al-Yahyaee, Said, Yimer, Getnet, Černý, Viktor, Desmeules, Jules, and Poloni, Estella S

Subjects

*POPULATION differentiation, *GENETIC variation, *HUMAN genetic variation, *GENOMICS, *GENOME-wide association studies, *PHARMACOGENOMICS

Abstract

Variation in genes involved in the absorption, distribution, metabolism, and excretion of drugs (ADME) can influence individual response to a therapeutic treatment. The study of ADME genetic diversity in human populations has led to evolutionary hypotheses of adaptation to distinct chemical environments. Population differentiation in measured drug metabolism phenotypes is, however, scarcely documented, often indirectly estimated via genotype-predicted phenotypes. We administered seven probe compounds devised to target six cytochrome P450 enzymes and the P-glycoprotein (P-gp) activity to assess phenotypic variation in four populations along a latitudinal transect spanning over Africa, the Middle East, and Europe (349 healthy Ethiopian, Omani, Greek, and Czech volunteers). We demonstrate significant population differentiation for all phenotypes except the one measuring CYP2D6 activity. Genome-wide association studies (GWAS) evidenced that the variability of phenotypes measuring CYP2B6, CYP2C9, CYP2C19, and CYP2D6 activity was associated with genetic variants linked to the corresponding encoding genes, and additional genes for the latter three. Instead, GWAS did not indicate any association between genetic diversity and the phenotypes measuring CYP1A2, CYP3A4, and P-gp activity. Genome scans of selection highlighted multiple candidate regions, a few of which included ADME genes, but none overlapped with the GWAS candidates. Our results suggest that different mechanisms have been shaping the evolution of these phenotypes, including phenotypic plasticity, and possibly some form of balancing selection. We discuss how these contrasting results highlight the diverse evolutionary trajectories of ADME genes and proteins, consistent with the wide spectrum of both endogenous and exogenous molecules that are their substrates. [ABSTRACT FROM AUTHOR]

Published

2022

2. Positive Selection in Human Populations: Practical Aspects and Current Knowledge

Author

Luisi, Pierre, Pybus, Marc, Laayouni, Hafid, Bertranpetit, Jaume, and Saitou, Naruya, Series Editor

Published

2021

3. Modern Strategies to Assess and Breed Forest Tree Adaptation to Changing Climate

Author

Andrés J. Cortés, Manuela Restrepo-Montoya, and Larry E. Bedoya-Canas

Subjects

genomics of adaptation, genomic prediction, genome-wide association studies, genome-wide selection scans, assisted gene flow, machine learning, Plant culture, SB1-1110

Abstract

Studying the genetics of adaptation to new environments in ecologically and industrially important tree species is currently a major research line in the fields of plant science and genetic improvement for tolerance to abiotic stress. Specifically, exploring the genomic basis of local adaptation is imperative for assessing the conditions under which trees will successfully adapt in situ to global climate change. However, this knowledge has scarcely been used in conservation and forest tree improvement because woody perennials face major research limitations such as their outcrossing reproductive systems, long juvenile phase, and huge genome sizes. Therefore, in this review we discuss predictive genomic approaches that promise increasing adaptive selection accuracy and shortening generation intervals. They may also assist the detection of novel allelic variants from tree germplasm, and disclose the genomic potential of adaptation to different environments. For instance, natural populations of tree species invite using tools from the population genomics field to study the signatures of local adaptation. Conventional genetic markers and whole genome sequencing both help identifying genes and markers that diverge between local populations more than expected under neutrality, and that exhibit unique signatures of diversity indicative of “selective sweeps.” Ultimately, these efforts inform the conservation and breeding status capable of pivoting forest health, ecosystem services, and sustainable production. Key long-term perspectives include understanding how trees’ phylogeographic history may affect the adaptive relevant genetic variation available for adaptation to environmental change. Encouraging “big data” approaches (machine learning—ML) capable of comprehensively merging heterogeneous genomic and ecological datasets is becoming imperative, too.

Published

2020

4. Predicting Thermal Adaptation by Looking Into Populations’ Genomic Past

Author

Andrés J. Cortés, Felipe López-Hernández, and Daniela Osorio-Rodriguez

Subjects

coalescent theory, genome-wide association studies, genome-wide selection scans, genome–environment associations, phylogeography, breeder’s equation, Genetics, QH426-470

Abstract

Molecular evolution offers an insightful theory to interpret the genomic consequences of thermal adaptation to previous events of climate change beyond range shifts. However, disentangling often mixed footprints of selective and demographic processes from those due to lineage sorting, recombination rate variation, and genomic constrains is not trivial. Therefore, here we condense current and historical population genomic tools to study thermal adaptation and outline key developments (genomic prediction, machine learning) that might assist their utilization for improving forecasts of populations’ responses to thermal variation. We start by summarizing how recent thermal-driven selective and demographic responses can be inferred by coalescent methods and in turn how quantitative genetic theory offers suitable multi-trait predictions over a few generations via the breeder’s equation. We later assume that enough generations have passed as to display genomic signatures of divergent selection to thermal variation and describe how these footprints can be reconstructed using genome-wide association and selection scans or, alternatively, may be used for forward prediction over multiple generations under an infinitesimal genomic prediction model. Finally, we move deeper in time to comprehend the genomic consequences of thermal shifts at an evolutionary time scale by relying on phylogeographic approaches that allow for reticulate evolution and ecological parapatric speciation, and end by envisioning the potential of modern machine learning techniques to better inform long-term predictions. We conclude that foreseeing future thermal adaptive responses requires bridging the multiple spatial scales of historical and predictive environmental change research under modern cohesive approaches such as genomic prediction and machine learning frameworks.

Published

2020

5. Modern Strategies to Assess and Breed Forest Tree Adaptation to Changing Climate.

Author

Cortés, Andrés J., Restrepo-Montoya, Manuela, and Bedoya-Canas, Larry E.

Subjects

BOTANY, FOREST conservation, PHYLOGEOGRAPHY, ABIOTIC stress, TREE breeding, GENETIC markers, CLIMATE change, WOODY plants

Abstract

Studying the genetics of adaptation to new environments in ecologically and industrially important tree species is currently a major research line in the fields of plant science and genetic improvement for tolerance to abiotic stress. Specifically, exploring the genomic basis of local adaptation is imperative for assessing the conditions under which trees will successfully adapt in situ to global climate change. However, this knowledge has scarcely been used in conservation and forest tree improvement because woody perennials face major research limitations such as their outcrossing reproductive systems, long juvenile phase, and huge genome sizes. Therefore, in this review we discuss predictive genomic approaches that promise increasing adaptive selection accuracy and shortening generation intervals. They may also assist the detection of novel allelic variants from tree germplasm, and disclose the genomic potential of adaptation to different environments. For instance, natural populations of tree species invite using tools from the population genomics field to study the signatures of local adaptation. Conventional genetic markers and whole genome sequencing both help identifying genes and markers that diverge between local populations more than expected under neutrality, and that exhibit unique signatures of diversity indicative of "selective sweeps." Ultimately, these efforts inform the conservation and breeding status capable of pivoting forest health, ecosystem services, and sustainable production. Key long-term perspectives include understanding how trees' phylogeographic history may affect the adaptive relevant genetic variation available for adaptation to environmental change. Encouraging "big data" approaches (machine learning—ML) capable of comprehensively merging heterogeneous genomic and ecological datasets is becoming imperative, too. [ABSTRACT FROM AUTHOR]

Published

2020

6. Predicting Thermal Adaptation by Looking Into Populations' Genomic Past.

Author

Cortés, Andrés J., López-Hernández, Felipe, and Osorio-Rodriguez, Daniela

Subjects

THERMAL tolerance (Physiology), MOLECULAR evolution, FORECASTING, MACHINE learning, POPULATION forecasting, PHYSIOLOGICAL adaptation, GEOTHERMAL ecology, PREDICTION models

Abstract

Molecular evolution offers an insightful theory to interpret the genomic consequences of thermal adaptation to previous events of climate change beyond range shifts. However, disentangling often mixed footprints of selective and demographic processes from those due to lineage sorting, recombination rate variation, and genomic constrains is not trivial. Therefore, here we condense current and historical population genomic tools to study thermal adaptation and outline key developments (genomic prediction, machine learning) that might assist their utilization for improving forecasts of populations' responses to thermal variation. We start by summarizing how recent thermal-driven selective and demographic responses can be inferred by coalescent methods and in turn how quantitative genetic theory offers suitable multi-trait predictions over a few generations via the breeder's equation. We later assume that enough generations have passed as to display genomic signatures of divergent selection to thermal variation and describe how these footprints can be reconstructed using genome-wide association and selection scans or, alternatively, may be used for forward prediction over multiple generations under an infinitesimal genomic prediction model. Finally, we move deeper in time to comprehend the genomic consequences of thermal shifts at an evolutionary time scale by relying on phylogeographic approaches that allow for reticulate evolution and ecological parapatric speciation, and end by envisioning the potential of modern machine learning techniques to better inform long-term predictions. We conclude that foreseeing future thermal adaptive responses requires bridging the multiple spatial scales of historical and predictive environmental change research under modern cohesive approaches such as genomic prediction and machine learning frameworks. [ABSTRACT FROM AUTHOR]

Published

2020

7. Genome-Wide Detection of Genes Under Positive Selection in Worldwide Populations of the Barley Scald Pathogen.

Author

Mohd-Assaad, Norfarhan, McDonald, Bruce A, and Croll, Daniel

Subjects

*PHYTOPATHOGENIC microorganisms, *BARLEY, *PLANT genomes, *GENES, *PLANT evolution, *GENE clusters, *HAPLOTYPES

Abstract

Coevolution between hosts and pathogens generates strong selection pressures to maintain resistance and infectivity, respectively. Genomes of plant pathogens often encode major effect loci for the ability to successfully infect specific host genotypes. Hence, spatial heterogeneity in host genotypes coupled with abiotic factors could lead to locally adapted pathogen populations. However, the genetic basis of local adaptation is poorly understood. Rhynchosporium commune , the pathogen causing barley scald disease, interacts at least partially in a gene-for-gene manner with its host. We analyzed global field populations of 125 R. commune isolates to identify candidate genes for local adaptation. Whole genome sequencing data showed that the pathogen is subdivided into three genetic clusters associated with distinct geographic and climatic regions. Using haplotype-based selection scans applied independently to each genetic cluster, we found strong evidence for selective sweeps throughout the genome. Comparisons of loci under selection among clusters revealed little overlap, suggesting that ecological differences associated with each cluster led to variable selection regimes. The strongest signals of selection were found predominantly in the two clusters composed of isolates from Central Europe and Ethiopia. The strongest selective sweep regions encoded protein functions related to biotic and abiotic stress responses. Selective sweep regions were enriched in genes encoding functions in cellular localization, protein transport activity, and DNA damage responses. In contrast to the prevailing view that a small number of gene-for-gene interactions govern plant pathogen evolution, our analyses suggest that the evolutionary trajectory is largely determined by spatially heterogeneous biotic and abiotic selection pressures. [ABSTRACT FROM AUTHOR]

Published

2018

8. Genome-wide detection of genes under positive selection in worldwide populations of the barley scald pathogen

Author

Daniel Croll, Bruce A. McDonald, and Norfarhan Mohd-Assaad

Subjects

0301 basic medicine, Genotype, population genomics, Genes, Fungal, Genomics, Biology, Environment, Genome, Polymorphism, Single Nucleotide, genome-wide selection scans, Population genomics, 03 medical and health sciences, Ascomycota, Genetics, Selection, Genetic, Gene, Ecology, Evolution, Behavior and Systematics, Selection (genetic algorithm), Cellular localization, Local adaptation, Plant Diseases, Whole genome sequencing, Abiotic stress, Agriculture, Hordeum, plant pathogen, fungi, Adaptation, Physiological, Phylogeography, 030104 developmental biology, Metagenomics, Genome, Fungal, Selective sweep, Research Article

Abstract

Coevolution between hosts and pathogens generates strong selection pressures to maintain resistance and infectivity, respectively. Genomes of plant pathogens often encode major effect loci for the ability to successfully infect specific host genotypes. Hence, spatial heterogeneity in host genotypes coupled with abiotic factors could lead to locally adapted pathogen populations. However, the genetic basis of local adaptation is poorly understood. Rhynchosporium commune, the pathogen causing barley scald disease, interacts at least partially in a gene-for-gene manner with its host. We analyzed global field populations of 125 R. commune isolates to identify candidate genes for local adaptation. Whole genome sequencing data showed that the pathogen is subdivided into three genetic clusters associated with distinct geographic and climatic regions. Using haplotype-based selection scans applied independently to each genetic cluster, we found strong evidence for selective sweeps throughout the genome. Comparisons of loci under selection among clusters revealed little overlap, suggesting that ecological differences associated with each cluster led to variable selection regimes. The strongest signals of selection were found predominantly in the two clusters composed of isolates from Central Europe and Ethiopia. The strongest selective sweep regions encoded protein functions related to biotic and abiotic stress responses. Selective sweep regions were enriched in genes encoding functions in cellular localization, protein transport activity, and DNA damage responses. In contrast to the prevailing view that a small number of gene-for-gene interactions govern plant pathogen evolution, our analyses suggest that the evolutionary trajectory is largely determined by spatially heterogeneous biotic and abiotic selection pressures., Genome Biology and Evolution, 10 (5), ISSN:1759-6653

Published

2018

9. Genome-wide scans for footprints of natural selection

Author

Michael W. Smith, Taras K. Oleksyk, and Stephen J. O'Brien

Subjects

Candidate gene, Population, Phylogenetic footprinting, Biology, Genome, General Biochemistry, Genetics and Molecular Biology, genome-wide selection scans, Evolution, Molecular, vertebrate species, Animals, Humans, Selection, Genetic, education, Phylogeny, education.field_of_study, Natural selection, Base Sequence, Genome, Human, human populations, Genetic Variation, Genome project, Articles, Evolutionary biology, Human genome, whole genome sequences, General Agricultural and Biological Sciences, genomes, candidate genes, Imputation (genetics), Genome-Wide Association Study

Abstract

Detecting recent selected ‘genomic footprints’ applies directly to the discovery of disease genes and in the imputation of the formative events that molded modern population genetic structure. The imprints of historic selection/adaptation episodes left in human and animal genomes allow one to interpret modern and ancestral gene origins and modifications. Current approaches to reveal selected regions applied in genome-wide selection scans (GWSSs) fall into eight principal categories: (I) phylogenetic footprinting, (II) detecting increased rates of functional mutations, (III) evaluating divergence versus polymorphism, (IV) detecting extended segments of linkage disequilibrium, (V) evaluating local reduction in genetic variation, (VI) detecting changes in the shape of the frequency distribution (spectrum) of genetic variation, (VII) assessing differentiating between populations (FST), and (VIII) detecting excess or decrease in admixture contribution from one population. Here, we review and compare these approaches using available human genome-wide datasets to provide independent verification (or not) of regions found by different methods and using different populations. The lessons learned from GWSSs will be applied to identify genome signatures of historic selective pressures on genes and gene regions in other species with emerging genome sequences. This would offer considerable potential for genome annotation in functional, developmental and evolutionary contexts.

Published

2009

10. Genome-Wide Scans for Footprints of Natural Selection

Author

Oleksyk, Taras K., Smith, Michael W., and O'Brien, Stephen J.

Published

2010