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6. Mitochondrial phylogenomics, the origin of swallowtail butterflies, and the impact of the number of clocks in Bayesian molecular dating.

Author

CONDAMINE, F. A. B. I. E. N. L., NABHOLZ, B. E. N. O. I. T., CLAMENS, ANNE‐LAURE, DUPUIS, J. U. L. I. A. N. R., and SPERLING, F. E. L. I. X. A. H.

Subjects
*PAPILIONIDAE, *LEPIDOPTERA, *PHYLOGENY, *GENOMES, *ORNITHOPTERA
Abstract

Abstract: Swallowtail butterflies (Lepidoptera: Papilionidae) have been instrumental in understanding many foundational concepts in biology; despite this, a resolved and robust phylogeny of the group has been a major impediment to elucidating patterns and processes of their ecological and evolutionary history. This study presents a mitogenomic, time‐calibrated phylogeny for all swallowtail genera. A shotgun sequencing approach was performed to obtain 32 complete mitogenomes that were added to available butterfly mitogenomes, resulting in a dataset including 142 butterfly taxa (and four outgroups) representing all butterfly families. Phylogenetic analyses were carried out under maximum likelihood (ML) and Bayesian inferences (BIs) with alternative partitioning strategies and the mixture (CAT) model. To test competing hypotheses about the systematics of Papilionidae, such as the enigmatic position of Baronia brevicornis or the status of the tribe Teinopalpini, we estimated the marginal likelihood of alternative topologies and computed Bayes factors. Estimates of divergence times were assessed using a Bayesian relaxed‐clock approach calibrated with six fossils while testing for the number of clocks. The results recovered a well‐resolved and supported phylogeny confirming that Baroniinae is sister to Parnassiinae + Papilioninae, both recovered as monophyletic. It also laid the foundations for classification at tribe and genus level, suggesting that the tribe Teinopalpini only contains the genus Teinopalpus (Meandrusa being sister to Papilio). The number of molecular clocks in dating analyses had a significant impact on divergence times. A single clock recovered an origin of butterflies in the Cretaceous (98, 66–188 Ma) and also for swallowtails (85, 55–163 Ma), while partitioning the clocks yielded an origin of Papilionoidea in the very Late Cretaceous (71, 64–86 Ma), and all butterfly families originated in the aftermath of the Cretaceous–Paleogene extinction. These results challenge previous studies suggesting that butterflies appeared in the Early Cretaceous, 110 Ma, concurrently with the rise of angiosperms. [ABSTRACT FROM AUTHOR]

Published
2018
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7. Whole-genome analyses resolve early branches in the tree of life of modern birds

Author

Jarvis, E., Mirarab, S., Aberer, A., Li, B., Houde, P., Li, C., Ho, S., Faircloth, B., Nabholz, B., Howard, J., Suh, A., Weber, C., da Fonseca, R., Li, J., Zhang, F., Li, H., Zhou, L., Narala, N., Liu, L., Ganapathy, G., boussau, B., Bayzid, M.S., Zavidovych, V., Subramanian, S., Gabaldon, T., Capella-Gutierrez, S., Huerta-Cepas, J., Rekepalli, B., Munch, K., Schierup, M., Lindow, B., Warren, W., Ray, D., Green, R., Bruford, M., Zhan, X., Dixon, A., Li, S., Li, N., Huang, Y., Derryberry, E., Bertelsen, M., Sheldon, F., Brumfield, R., Mello, C., Lovell, P., Wirthlin, M., Schneider, M., Prosdocimi, F., Samaniego, J.A., Velazquez, A., Alfaro-Nunez, A., Campos, P., Petersen, B., Sicheritz-Ponten, T., Pas, A., Bailey, T., Scofield, P., Bunce, Michael, Lambert, D., Zhou, Q., Perelman, P., Driskell, A., Shapiro, B., Xiong, Z., Zeng, Y., Liu, S., Li, Z., Liu, B., Wu, K., Xiao, J., Xiong, Y., Zheng, Q., Zhang, Y., Yang, H., Wang, J., Smeds, L., Rheindt, F., Braun, M., Fjeldsa, J., Oelando, L., Barker, K., Jonsson, K., Johnson, W., Koepfli, K., O'Brien, S., Haussler, D., Ryder, O., Rahbek, C., Willerslev, E., Graves, G., Glenn, T., McCormack, J., Burt, D., Ellegren, H., Alstrom, P., Edwards, S., Stamatakis, A., Mindell, D., Cracraft, J., Braun, E., Warnow, T., Wang, Jun, Gilbert, Thomas, Zhang, G., Jarvis, E., Mirarab, S., Aberer, A., Li, B., Houde, P., Li, C., Ho, S., Faircloth, B., Nabholz, B., Howard, J., Suh, A., Weber, C., da Fonseca, R., Li, J., Zhang, F., Li, H., Zhou, L., Narala, N., Liu, L., Ganapathy, G., boussau, B., Bayzid, M.S., Zavidovych, V., Subramanian, S., Gabaldon, T., Capella-Gutierrez, S., Huerta-Cepas, J., Rekepalli, B., Munch, K., Schierup, M., Lindow, B., Warren, W., Ray, D., Green, R., Bruford, M., Zhan, X., Dixon, A., Li, S., Li, N., Huang, Y., Derryberry, E., Bertelsen, M., Sheldon, F., Brumfield, R., Mello, C., Lovell, P., Wirthlin, M., Schneider, M., Prosdocimi, F., Samaniego, J.A., Velazquez, A., Alfaro-Nunez, A., Campos, P., Petersen, B., Sicheritz-Ponten, T., Pas, A., Bailey, T., Scofield, P., Bunce, Michael, Lambert, D., Zhou, Q., Perelman, P., Driskell, A., Shapiro, B., Xiong, Z., Zeng, Y., Liu, S., Li, Z., Liu, B., Wu, K., Xiao, J., Xiong, Y., Zheng, Q., Zhang, Y., Yang, H., Wang, J., Smeds, L., Rheindt, F., Braun, M., Fjeldsa, J., Oelando, L., Barker, K., Jonsson, K., Johnson, W., Koepfli, K., O'Brien, S., Haussler, D., Ryder, O., Rahbek, C., Willerslev, E., Graves, G., Glenn, T., McCormack, J., Burt, D., Ellegren, H., Alstrom, P., Edwards, S., Stamatakis, A., Mindell, D., Cracraft, J., Braun, E., Warnow, T., Wang, Jun, Gilbert, Thomas, and Zhang, G.

Abstract

To better determine the history of modern birds, we performed a genome-scale phylogenetic analysis of 48 species representing all orders of Neoaves using phylogenomic methods created to handle genome-scale data. We recovered a highly resolved tree that confirms previously controversial sister or close relationships. We identified the first divergence in Neoaves, two groups we named Passerea and Columbea, representing independent lineages of diverse and convergently evolved land and water bird species. Among Passerea, we infer the common ancestor of core landbirds to have been an apex predator and confirm independent gains of vocal learning. Among Columbea, we identify pigeons and flamingoes as belonging to sister clades. Even with whole genomes, some of the earliest branches in Neoaves proved challenging to resolve, which was best explained by massive protein-coding sequence convergence and high levels of incomplete lineage sorting that occurred during a rapid radiation after the Cretaceous-Paleogene mass extinction event about 66 million years ago.

Published
2014

16. The erratic mitochondrial clock: variations of mutation rate, not population size, affect mtDNA diversity across birds and mammals

Author

Galtier Nicolas, Glémin Sylvain, and Nabholz Benoit

Subjects
Evolution, QH359-425
Abstract

Abstract Background During the last ten years, major advances have been made in characterizing and understanding the evolution of mitochondrial DNA, the most popular marker of molecular biodiversity. Several important results were recently reported using mammals as model organisms, including (i) the absence of relationship between mitochondrial DNA diversity and life-history or ecological variables, (ii) the absence of prominent adaptive selection, contrary to what was found in invertebrates, and (iii) the unexpectedly large variation in neutral substitution rate among lineages, revealing a possible link with species maximal longevity. We propose to challenge these results thanks to the bird/mammal comparison. Direct estimates of population size are available in birds, and this group presents striking life-history trait differences with mammals (higher mass-specific metabolic rate and longevity). These properties make birds the ideal model to directly test for population size effects, and to discriminate between competing hypotheses about the causes of substitution rate variation. Results A phylogenetic analysis of cytochrome b third-codon position confirms that the mitochondrial DNA mutation rate is quite variable in birds, passerines being the fastest evolving order. On average, mitochondrial DNA evolves slower in birds than in mammals of similar body size. This result is in agreement with the longevity hypothesis, and contradicts the hypothesis of a metabolic rate-dependent mutation rate. Birds show no footprint of adaptive selection on cytochrome b evolutionary patterns, but no link between direct estimates of population size and cytochrome b diversity. The mutation rate is the best predictor we have of within-species mitochondrial diversity in birds. It partly explains the differences in mitochondrial DNA diversity patterns observed between mammals and birds, previously interpreted as reflecting Hill-Robertson interferences with the W chromosome. Conclusion Mitochondrial DNA diversity patterns in birds are strongly influenced by the wide, unexpected variation of mutation rate across species. From a fundamental point of view, these results are strongly consistent with a relationship between species maximal longevity and mitochondrial mutation rate, in agreement with the mitochondrial theory of ageing. Form an applied point of view, this study reinforces and extends the message of caution previously expressed for mammals: mitochondrial data tell nothing about species population sizes, and strongly depart the molecular clock assumption.

Published
2009
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17. A cautionary note on synonymization based on mitochondrial data in Orthoptera: a comment of Hochkirch et al. 2023.

Author

Nabholz B, Puissant S, and Defaut B

Subjects
Animals, DNA, Mitochondrial genetics, Phylogeny, Grasshoppers anatomy & histology, Grasshoppers classification
Abstract

Hochkirch et al. (2023) recently published a phylogeny of the band-winged grasshopper genus Oedipoda. Using three mitochondrial and one nuclear loci, they estimated the phylogeny of 177 specimens. This phylogeny offers insights into the evolutionary history and biogeography of the group and demonstrates the usefulness of molecular data to estimated populations and species histories. They also provide valid taxonomical changes, raising two former subspecies and one former synonymy to the species level. However, we believe that taxonomic changes regarding synonymization proposed by the authors are premature given the data utilized. Indeed, we will illustrate cases below where well-established species lack support from mitochondrial data, which is comparable to or even more extensive than that used by Hochkirch et al. (2023).

Published
2024
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18. Exon capture museomics deciphers the nine-banded armadillo species complex and identifies a new species endemic to the Guiana Shield.

Author

Barthe M, Rancilhac L, Arteaga MC, Feijó A, Tilak MK, Justy F, Loughry WJ, McDonough CM, de Thoisy B, Catzeflis F, Billet G, Hautier L, Nabholz B, and Delsuc F

Abstract

The nine-banded armadillo (Dasypus novemcinctus) is the most widespread xenarthran species across the Americas. Recent studies have suggested it is composed of four morphologically and genetically distinct lineages of uncertain taxonomic status. To address this issue, we used a museomic approach to sequence 80 complete mitogenomes and capture 997 nuclear loci for 71 Dasypus individuals sampled across the entire distribution. We carefully cleaned up potential genotyping errors and cross contaminations that could blur species boundaries by mimicking gene flow. Our results unambiguously support four distinct lineages within the D. novemcinctus complex. We found cases of mito-nuclear phylogenetic discordance but only limited contemporary gene flow confined to the margins of the lineage distributions. All available evidence including the restricted gene flow, phylogenetic reconstructions based on both mitogenomes and nuclear loci, and phylogenetic delimitation methods consistently supported the four lineages within D. novemcinctus as four distinct species. Comparable genetic differentiation values to other recognized Dasypus species further reinforced their status as valid species. Considering congruent morphological results from previous studies, we provide an integrative taxonomic view to recognise four species within the D. novemcinctus complex: D. novemcinctus, D. fenestratus, D. mexicanus, and D. guianensis sp. nov., a new species endemic of the Guiana Shield that we describe here. The two available individuals of D. mazzai and D. sabanicola were consistently nested within D. novemcinctus lineage and their status remains to be assessed. The present work offers a case study illustrating the power of museomics to reveal cryptic species diversity within a widely distributed and emblematic species of mammals., (© The Author(s) 2024. Published by Oxford University Press on behalf of the Society of Systematic Biologists.)

Published
2024
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19. Demographic responses of oceanic island birds to local and regional ecological disruptions revealed by whole-genome sequencing.

Author

Gabrielli M, Leroy T, Salmona J, Nabholz B, Milá B, and Thébaud C

Subjects
Oceans and Seas, Reunion, Mauritius, Population Dynamics
Abstract

Disentangling the effects of ecological disruptions operating at different spatial and temporal scales in shaping past species' demography is particularly important in the current context of rapid environmental changes driven by both local and regional factors. We argue that volcanic oceanic islands provide useful settings to study the influence of past ecological disruptions operating at local and regional scales on population demographic histories. We investigate potential drivers of past population dynamics for three closely related species of passerine birds from two volcanic oceanic islands, Reunion and Mauritius (Mascarene archipelago), with distinct volcanic history. Using ABC and PSMC inferences from complete genomes, we reconstructed the demographic history of the Reunion Grey White-eye (Zosterops borbonicus (Pennant, 1781)), the Reunion Olive White-eye (Z. olivaceus (Linnaeus, 1766)) and the Mauritius Grey White-eye (Z. mauritianus (Gmelin, 1789)) and searched for possible causes underlying similarities or differences between species living on the same or different islands. Both demographic inferences strongly support ancient and long-term expansions in all species. They also reveal different trajectories between species inhabiting different islands, but consistent demographic trajectories in species or populations from the same island. Species from Reunion appear to have experienced synchronous reductions in population size during the Last Glacial Maximum, a trend not seen in the Mauritian species. Overall, this study suggests that local events may have played a role in shaping population trajectories of these island species. It also highlights the potential of our conceptual framework to disentangle the effects of local and regional drivers on past species' demography and long-term population processes., (© 2024 The Authors. Molecular Ecology published by John Wiley & Sons Ltd.)

Published
2024
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20. Genomics of the relict species Baronia brevicornis sheds light on its demographic history and genome size evolution across swallowtail butterflies.

Author

Marino A, Reboud EL, Chevalier E, Tilak MK, Contreras-Garduño J, Nabholz B, and Condamine FL

Subjects
Animals, Genome Size, Phylogeny, DNA Transposable Elements genetics, Genomics, Demography, Butterflies genetics
Abstract

Relict species, like coelacanth, gingko, tuatara, are the remnants of formerly more ecologically and taxonomically diverse lineages. It raises the questions of why they are currently species-poor, have restrained ecology, and are often vulnerable to extinction. Estimating heterozygosity level and demographic history can guide our understanding of the evolutionary history and conservation status of relict species. However, few studies have focused on relict invertebrates compared to vertebrates. We sequenced the genome of Baronia brevicornis (Lepidoptera: Papilionidae), which is an endangered species, the sister species of all swallowtail butterflies, and is the oldest lineage of all extant butterflies. From a dried specimen, we were able to generate both long-read and short-read data and assembled a genome of 406 Mb for Baronia. We found a fairly high level of heterozygosity (0.58%) compared to other swallowtail butterflies, which contrasts with its endangered and relict status. Taking into account the high ratio of recombination over mutation, demographic analyses indicated a sharp decline of the effective population size initiated in the last million years. Moreover, the Baronia genome was used to study genome size variation in Papilionidae. Genome sizes are mostly explained by transposable elements activities, suggesting that large genomes appear to be a derived feature in swallowtail butterflies as transposable elements activity is recent and involves different transposable elements classes among species. This first Baronia genome provides a resource for assisting conservation in a flagship and relict insect species as well as for understanding swallowtail genome evolution., Competing Interests: Conflicts of interest statement The authors declare no conflict of interest., (© The Author(s) 2023. Published by Oxford University Press on behalf of The Genetics Society of America.)

Published
2023
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21. Adaptive phenotypic and genomic divergence in the common chaffinch (Fringilla coelebs) following niche expansion within a small oceanic island.

Author

Recuerda M, Palacios M, Frías O, Hobson K, Nabholz B, Blanco G, and Milá B

Subjects
Animals, Ecosystem, Genome-Wide Association Study, Gene Flow, Genomics, Genetics, Population, Finches
Abstract

According to models of ecological speciation, adaptation to adjacent, contrasting habitat types can lead to population divergence given strong enough environment-driven selection to counteract the homogenizing effect of gene flow. We tested this hypothesis in the common chaffinch (Fringilla coelebs) on the small island of La Palma, Canary Islands, where it occupies two markedly different habitats. Isotopic (δ 13 C, δ 15 N) analysis of feathers indicated that birds in the two habitats differed in ecosystem and/or diet, and analysis of phenotypic traits revealed significant differences in morphology and plumage colouration that are consistent with ecomorphological and ecogeographical predictions respectively. A genome-wide survey of single-nucleotide polymorphism revealed marked neutral structure that was consistent with geography and isolation by distance, suggesting low dispersal. In contrast, loci putatively under selection identified through genome-wide association and genotype-environment association analyses, revealed amarked adaptive divergence between birds in both habitats. Loci associated with phenotypic and environmental differences among habitats were distributed across the genome, as expected for polygenic traits involved in local adaptation. Our results suggest a strong role for habitat-driven local adaptation in population divergence in the chaffinches of La Palma, a process that appears to be facilitated by a strong reduction in effective dispersal distances despite the birds' high dispersal capacity., (© 2023 The Authors. Journal of Evolutionary Biology published by John Wiley & Sons Ltd on behalf of European Society for Evolutionary Biology.)

Published
2023
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22. Genomics, Population Divergence, and Historical Demography of the World's Largest and Endangered Butterfly, The Queen Alexandra's Birdwing.

Author

Reboud EL, Nabholz B, Chevalier E, Tilak MK, Bito D, and Condamine FL

Subjects
Animals, Metagenomics, Demography, Genomics, Genome, Butterflies genetics
Abstract

The world's largest butterfly is the microendemic Papua New Guinean Ornithoptera alexandrae. Despite years of conservation efforts to protect its habitat and breed this up-to-28-cm butterfly, this species still figures as endangered in the IUCN Red List and is only known from two allopatric populations occupying a total of only ∼140 km². Here we aim at assembling reference genomes for this species to investigate its genomic diversity, historical demography and determine whether the population is structured, which could provide guidance for conservation programs attempting to (inter)breed the two populations. Using a combination of long and short DNA reads and RNA sequencing, we assembled six reference genomes of the tribe Troidini, with four annotated genomes of O. alexandrae and two genomes of related species Ornithoptera priamus and Troides oblongomaculatus. We estimated the genomic diversity of the three species, and we proposed scenarios for the historical population demography using two polymorphism-based methods taking into account the characteristics of low-polymorphic invertebrates. Indeed, chromosome-scale assemblies reveal very low levels of nuclear heterozygosity across Troidini, which appears to be exceptionally low for O. alexandrae (lower than 0.01%). Demographic analyses demonstrate low and steadily declining Ne throughout O. alexandrae history, with a divergence into two distinct populations about 10,000 years ago. These results suggest that O. alexandrae distribution has been microendemic for a long time. It should also make local conservation programs aware of the genomic divergence of the two populations, which should not be ignored if any attempt is made to cross the two populations., (© The Author(s) 2023. Published by Oxford University Press on behalf of Society for Molecular Biology and Evolution.)

Published
2023
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23. Response to Kratochvíl and Rovatsos.

Author

Leroy T and Nabholz B

Abstract

Thibault Leroy and Benoit Nabholz respond to the letter by Lukáš Kratochvíl and Michail Rovatsos that comments on the original authors' study of island songbirds., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published
2022
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24. Island songbirds as windows into evolution in small populations.

Author

Leroy T, Rousselle M, Tilak MK, Caizergues AE, Scornavacca C, Recuerda M, Fuchs J, Illera JC, De Swardt DH, Blanco G, Thébaud C, Milá B, and Nabholz B

Subjects
Animals, Genetic Drift, Genetic Variation, Population Density, Selection, Genetic, Evolution, Molecular, Genetics, Population, Songbirds genetics
Abstract

Due to their limited ranges and inherent isolation, island species have long been recognized as crucial systems for tackling a range of evolutionary questions, including in the early study of speciation. 1 , 2 Such species have been less studied in the understanding of the evolutionary forces driving DNA sequence evolution. Island species usually have lower census population sizes (N) than continental species and, supposedly, lower effective population sizes (Ne). Given that both the rates of change caused by genetic drift and by selection are dependent upon Ne, island species are theoretically expected to exhibit (1) lower genetic diversity, (2) less effective natural selection against slightly deleterious mutations, 3 , 4 and (3) a lower rate of adaptive evolution. 5-8 Here, we have used a large set of newly sequenced and published whole-genome sequences of Passerida species (14 insular and 11 continental) to test these predictions. We confirm that island species exhibit lower census size and Ne, supporting the hypothesis that the smaller area available on islands constrains the upper bound of Ne. In the insular species, we find lower nucleotide diversity in coding regions, higher ratios of non-synonymous to synonymous polymorphisms, and lower adaptive substitution rates. Our results provide robust evidence that the lower Ne experienced by island species has affected both the ability of natural selection to efficiently remove weakly deleterious mutations and also the adaptive potential of island species, therefore providing considerable empirical support for the nearly neutral theory. We discuss the implications for both evolutionary and conservation biology., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published
2021
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25. High-quality carnivoran genomes from roadkill samples enable comparative species delineation in aardwolf and bat-eared fox.

Author

Allio R, Tilak MK, Scornavacca C, Avenant NL, Kitchener AC, Corre E, Nabholz B, and Delsuc F

Subjects
Animals, High-Throughput Nucleotide Sequencing veterinary, Nanopore Sequencing veterinary, Foxes classification, Foxes genetics, Genetic Variation, Genome, Hyaenidae classification, Hyaenidae genetics
Abstract

In a context of ongoing biodiversity erosion, obtaining genomic resources from wildlife is essential for conservation. The thousands of yearly mammalian roadkill provide a useful source material for genomic surveys. To illustrate the potential of this underexploited resource, we used roadkill samples to study the genomic diversity of the bat-eared fox ( Otocyon megalotis ) and the aardwolf ( Proteles cristatus ), both having subspecies with similar disjunct distributions in Eastern and Southern Africa. First, we obtained reference genomes with high contiguity and gene completeness by combining Nanopore long reads and Illumina short reads. Then, we showed that the two subspecies of aardwolf might warrant species status ( P. cristatus and P. septentrionalis ) by comparing their genome-wide genetic differentiation to pairs of well-defined species across Carnivora with a new Genetic Differentiation index (GDI) based on only a few resequenced individuals. Finally, we obtained a genome-scale Carnivora phylogeny including the new aardwolf species., Competing Interests: RA, MT, CS, NA, AK, EC, BN, FD No competing interests declared, (© 2021, Allio et al.)

Published
2021
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26. Genome-wide macroevolutionary signatures of key innovations in butterflies colonizing new host plants.

Author

Allio R, Nabholz B, Wanke S, Chomicki G, Pérez-Escobar OA, Cotton AM, Clamens AL, Kergoat GJ, Sperling FAH, and Condamine FL

Subjects
Animals, Butterflies classification, Butterflies physiology, Genome-Wide Association Study methods, Geography, Host-Parasite Interactions, Phylogeny, Plants classification, Plants parasitology, Species Specificity, Time Factors, Butterflies genetics, Ecosystem, Evolution, Molecular, Genome, Insect genetics
Abstract

The mega-diversity of herbivorous insects is attributed to their co-evolutionary associations with plants. Despite abundant studies on insect-plant interactions, we do not know whether host-plant shifts have impacted both genomic adaptation and species diversification over geological times. We show that the antagonistic insect-plant interaction between swallowtail butterflies and the highly toxic birthworts began 55 million years ago in Beringia, followed by several major ancient host-plant shifts. This evolutionary framework provides a valuable opportunity for repeated tests of genomic signatures of macroevolutionary changes and estimation of diversification rates across their phylogeny. We find that host-plant shifts in butterflies are associated with both genome-wide adaptive molecular evolution (more genes under positive selection) and repeated bursts of speciation rates, contributing to an increase in global diversification through time. Our study links ecological changes, genome-wide adaptations and macroevolutionary consequences, lending support to the importance of ecological interactions as evolutionary drivers over long time periods.

Published
2021
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27. MitoFinder: Efficient automated large-scale extraction of mitogenomic data in target enrichment phylogenomics.

Author

Allio R, Schomaker-Bastos A, Romiguier J, Prosdocimi F, Nabholz B, and Delsuc F

Subjects
Animals, Ants genetics, Biological Evolution, Conserved Sequence genetics, DNA, Mitochondrial genetics, Genome, Mitochondrial genetics, Phylogeny, Sequence Analysis, DNA methods, Software, Transcriptome genetics, Computational Biology methods, Genomics methods
Abstract

Thanks to the development of high-throughput sequencing technologies, target enrichment sequencing of nuclear ultraconserved DNA elements (UCEs) now allows routine inference of phylogenetic relationships from thousands of genomic markers. Recently, it has been shown that mitochondrial DNA (mtDNA) is frequently sequenced alongside the targeted loci in such capture experiments. Despite its broad evolutionary interest, mtDNA is rarely assembled and used in conjunction with nuclear markers in capture-based studies. Here, we developed MitoFinder, a user-friendly bioinformatic pipeline, to efficiently assemble and annotate mitogenomic data from hundreds of UCE libraries. As a case study, we used ants (Formicidae) for which 501 UCE libraries have been sequenced whereas only 29 mitogenomes are available. We compared the efficiency of four different assemblers (IDBA-UD, MEGAHIT, MetaSPAdes, and Trinity) for assembling both UCE and mtDNA loci. Using MitoFinder, we show that metagenomic assemblers, in particular MetaSPAdes, are well suited to assemble both UCEs and mtDNA. Mitogenomic signal was successfully extracted from all 501 UCE libraries, allowing us to confirm species identification using CO1 barcoding. Moreover, our automated procedure retrieved 296 cases in which the mitochondrial genome was assembled in a single contig, thus increasing the number of available ant mitogenomes by an order of magnitude. By utilizing the power of metagenomic assemblers, MitoFinder provides an efficient tool to extract complementary mitogenomic data from UCE libraries, allowing testing for potential mitonuclear discordance. Our approach is potentially applicable to other sequence capture methods, transcriptomic data and whole genome shotgun sequencing in diverse taxa. The MitoFinder software is available from GitHub (https://github.com/RemiAllio/MitoFinder)., (© 2020 The Authors. Molecular Ecology Resources published by John Wiley & Sons Ltd.)

Published
2020
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28. Is adaptation limited by mutation? A timescale-dependent effect of genetic diversity on the adaptive substitution rate in animals.

Author

Rousselle M, Simion P, Tilak MK, Figuet E, Nabholz B, and Galtier N

Subjects
Animals, Birds genetics, Insecta genetics, Mammals genetics, Models, Genetic, Mollusca genetics, Open Reading Frames, Time, Adaptation, Physiological, Mutation Rate, Polymorphism, Genetic
Abstract

Whether adaptation is limited by the beneficial mutation supply is a long-standing question of evolutionary genetics, which is more generally related to the determination of the adaptive substitution rate and its relationship with species effective population size (Ne) and genetic diversity. Empirical evidence reported so far is equivocal, with some but not all studies supporting a higher adaptive substitution rate in large-Ne than in small-Ne species. We gathered coding sequence polymorphism data and estimated the adaptive amino-acid substitution rate ωa, in 50 species from ten distant groups of animals with markedly different population mutation rate θ. We reveal the existence of a complex, timescale dependent relationship between species adaptive substitution rate and genetic diversity. We find a positive relationship between ωa and θ among closely related species, indicating that adaptation is indeed limited by the mutation supply, but this was only true in relatively low-θ taxa. In contrast, we uncover no significant correlation between ωa and θ at a larger taxonomic scale, suggesting that the proportion of beneficial mutations scales negatively with species' long-term Ne., Competing Interests: The authors have declared that no competing interests exist.

Published
2020
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29. Within-island diversification in a passerine bird.

Author

Gabrielli M, Nabholz B, Leroy T, Milá B, and Thébaud C

Subjects
Animals, Islands, Phylogeny, Biodiversity, Passeriformes
Abstract

The presence of congeneric taxa on the same island suggests the possibility of in situ divergence, but can also result from multiple colonizations of previously diverged lineages. Here, using genome-wide data from a large population sample, we test the hypothesis that intra-island divergence explains the occurrence of four geographical forms meeting at hybrid zones in the Reunion grey white-eye ( Zosterops borbonicus ), a species complex endemic to the small volcanic island of Reunion. Using population genomic and phylogenetic analyses, we reconstructed the population history of the different forms. We confirmed the monophyly of the complex and found that one of the lowland forms is paraphyletic and basal relative to others, a pattern highly consistent with in situ divergence. Our results suggest initial colonization of the island through the lowlands, followed by expansion into the highlands, which led to the evolution of a distinct geographical form, genetically and ecologically different from the lowland ones. Lowland forms seem to have experienced periods of geographical isolation, but they diverged from one another by sexual selection rather than niche change. Overall, low dispersal capabilities in this island bird combined with both geographical and ecological opportunities seem to explain how divergence occurred at such a small spatial scale.

Published
2020
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30. Whole Genome Shotgun Phylogenomics Resolves the Pattern and Timing of Swallowtail Butterfly Evolution.

Author

Allio R, Scornavacca C, Nabholz B, Clamens AL, Sperling FA, and Condamine FL

Subjects
Animals, Time, Biological Evolution, Butterflies classification, Butterflies genetics, Genome, Insect genetics, Phylogeny
Abstract

Evolutionary relationships have remained unresolved in many well-studied groups, even though advances in next-generation sequencing and analysis, using approaches such as transcriptomics, anchored hybrid enrichment, or ultraconserved elements, have brought systematics to the brink of whole genome phylogenomics. Recently, it has become possible to sequence the entire genomes of numerous nonbiological models in parallel at reasonable cost, particularly with shotgun sequencing. Here, we identify orthologous coding sequences from whole-genome shotgun sequences, which we then use to investigate the relevance and power of phylogenomic relationship inference and time-calibrated tree estimation. We study an iconic group of butterflies-swallowtails of the family Papilionidae-that has remained phylogenetically unresolved, with continued debate about the timing of their diversification. Low-coverage whole genomes were obtained using Illumina shotgun sequencing for all genera. Genome assembly coupled to BLAST-based orthology searches allowed extraction of 6621 orthologous protein-coding genes for 45 Papilionidae species and 16 outgroup species (with 32% missing data after cleaning phases). Supermatrix phylogenomic analyses were performed with both maximum-likelihood (IQ-TREE) and Bayesian mixture models (PhyloBayes) for amino acid sequences, which produced a fully resolved phylogeny providing new insights into controversial relationships. Species tree reconstruction from gene trees was performed with ASTRAL and SuperTriplets and recovered the same phylogeny. We estimated gene site concordant factors to complement traditional node-support measures, which strengthens the robustness of inferred phylogenies. Bayesian estimates of divergence times based on a reduced data set (760 orthologs and 12% missing data) indicate a mid-Cretaceous origin of Papilionoidea around 99.2 Ma (95% credibility interval: 68.6-142.7 Ma) and Papilionidae around 71.4 Ma (49.8-103.6 Ma), with subsequent diversification of modern lineages well after the Cretaceous-Paleogene event. These results show that shotgun sequencing of whole genomes, even when highly fragmented, represents a powerful approach to phylogenomics and molecular dating in a group that has previously been refractory to resolution., (© The Author(s) 2019. Published by Oxford University Press, on behalf of the Society of Systematic Biologists. All rights reserved. For permissions, please email: journals.permissions@oup.com.)

Published
2020
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31. Influence of Recombination and GC-biased Gene Conversion on the Adaptive and Nonadaptive Substitution Rate in Mammals versus Birds.

Author

Rousselle M, Laverré A, Figuet E, Nabholz B, and Galtier N

Subjects
Animals, Evolution, Molecular, Gene Conversion, Poultry genetics, Primates genetics
Abstract

Recombination is expected to affect functional sequence evolution in several ways. On the one hand, recombination is thought to improve the efficiency of multilocus selection by dissipating linkage disequilibrium. On the other hand, natural selection can be counteracted by recombination-associated transmission distorters such as GC-biased gene conversion (gBGC), which tends to promote G and C alleles irrespective of their fitness effect in high-recombining regions. It has been suggested that gBGC might impact coding sequence evolution in vertebrates, and particularly the ratio of nonsynonymous to synonymous substitution rates (dN/dS). However, distinctive gBGC patterns have been reported in mammals and birds, maybe reflecting the documented contrasts in evolutionary dynamics of recombination rate between these two taxa. Here, we explore how recombination and gBGC affect coding sequence evolution in mammals and birds by analyzing proteome-wide data in six species of Galloanserae (fowls) and six species of catarrhine primates. We estimated the dN/dS ratio and rates of adaptive and nonadaptive evolution in bins of genes of increasing recombination rate, separately analyzing AT → GC, GC → AT, and G ↔ C/A ↔ T mutations. We show that in both taxa, recombination and gBGC entail a decrease in dN/dS. Our analysis indicates that recombination enhances the efficiency of purifying selection by lowering Hill-Robertson effects, whereas gBGC leads to an overestimation of the adaptive rate of AT → GC mutations. Finally, we report a mutagenic effect of recombination, which is independent of gBGC., (© The Author(s) 2018. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published
2019
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32. Overestimation of the adaptive substitution rate in fluctuating populations.

Author

Rousselle M, Mollion M, Nabholz B, Bataillon T, and Galtier N

Subjects
Climate, Computer Simulation, Genome, Models, Genetic, Mutation Rate, Polymorphism, Genetic, Adaptation, Physiological genetics, Evolution, Molecular, Population Density
Abstract

Estimating the proportion of adaptive substitutions ( α ) is of primary importance to uncover the determinants of adaptation in comparative genomic studies. Several methods have been proposed to estimate α from patterns polymorphism and divergence in coding sequences. However, estimators of α can be biased when the underlying assumptions are not met. Here we focus on a potential source of bias, i.e. variation through time in the long-term population size ( N ) of the considered species. We show via simulations that ancient demographic fluctuations can generate severe overestimations of α , and this is irrespective of the recent population history., (© 2018 The Author(s).)

Published
2018
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33. Illumina Library Preparation for Sequencing the GC-Rich Fraction of Heterogeneous Genomic DNA.

Author

Tilak MK, Botero-Castro F, Galtier N, and Nabholz B

Subjects
Animals, Chickens genetics, DNA chemistry, DNA isolation & purification, Genomics economics, Genomics methods, High-Throughput Nucleotide Sequencing economics, High-Throughput Nucleotide Sequencing methods, Hot Temperature, Polymerase Chain Reaction economics, Polymerase Chain Reaction methods, Sequence Analysis, DNA economics, Sequence Analysis, DNA methods, DNA genetics, GC Rich Sequence, Gene Library
Abstract

Standard Illumina libraries are biased toward sequences of intermediate GC-content. This results in an underrepresentation of GC-rich regions in sequencing projects of genomes with heterogeneous base composition, such as mammals and birds. We developed a simple, cost-effective protocol to enrich sheared genomic DNA in its GC-rich fraction by subtracting AT-rich DNA. This was achieved by heating DNA up to 90 °C before applying Illumina library preparation. We tested the new approach on chicken DNA and found that heated DNA increased average coverage in the GC-richest chromosomes by a factor up to six. Using a Taq polymerase supposedly appropriate for PCR amplification of GC-rich sequences had a much weaker effect. Our protocol should greatly facilitate sequencing and resequencing of the GC-richest regions of heterogeneous genomes, in combination with standard short-read and long-read technologies., (© The Author(s) 2018. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published
2018
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34. Avian Genomes Revisited: Hidden Genes Uncovered and the Rates versus Traits Paradox in Birds.

Author

Botero-Castro F, Figuet E, Tilak MK, Nabholz B, and Galtier N

Subjects
Animals, Base Composition, Biological Evolution, Chickens genetics, Databases, Genetic, Evolution, Molecular, Gene Conversion, Genomics, Genotype, Mammals genetics, Phenotype, Phylogeny, Selection, Genetic genetics, Birds genetics, GC Rich Sequence genetics, Genome genetics
Abstract

According to current assemblies, avian genomes differ from those of the other lineages of amniotes in 1) containing a lower number of genes; 2) displaying a high stability of karyotype and recombination map; and 3) lacking any correlation between evolutionary rates (dN/dS) and life-history traits, unlike mammals and nonavian reptiles. We question the reality of the bird missing genes and investigate whether insufficient representation of bird gene content might have biased previous evolutionary analyses. Mining RNAseq data, we show that the vast majority of the genes missing from avian genome assemblies are actually present in most species of birds. These mainly correspond to the GC-rich fraction of the bird genome, which is the most difficult to sequence, assemble and annotate. With the inclusion of these genes in a phylogenomic analysis of high-quality alignments, we uncover a positive and significant correlation between the ratio of nonsynonymous to synonymous substitution rate (dN/dS) and life-history traits in Neoaves. We report a strong effect of GC-biased gene conversion on the dN/dS ratio in birds and a peculiar behavior of Palaeognathae (ostrich and allies) and Galloanserae (chickens, ducks and allies). Avian genomes do not contain fewer genes than mammals or nonavian reptiles. Previous analyses have overlooked ∼15% of the bird gene complement. GC-rich regions, which are the most difficult to access, are a key component of amniote genomes. They experience peculiar molecular processes and must be included for unbiased functional and comparative genomic analyses in birds., (© The Author 2017. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published
2017
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35. Large Variation in the Ratio of Mitochondrial to Nuclear Mutation Rate across Animals: Implications for Genetic Diversity and the Use of Mitochondrial DNA as a Molecular Marker.

Author

Allio R, Donega S, Galtier N, and Nabholz B

Subjects
Animals, Biological Evolution, Biomarkers, Cell Nucleus genetics, Databases, Nucleic Acid, Evolution, Molecular, Genetic Speciation, Genetic Variation genetics, Genetics, Population methods, Genome genetics, Mitochondria genetics, Mutation, Phylogeny, Polymorphism, Genetic genetics, Population Density, Selection, Genetic genetics, DNA, Mitochondrial genetics, Mutation Rate
Abstract

It is commonly assumed that mitochondrial DNA (mtDNA) evolves at a faster rate than nuclear DNA (nuDNA) in animals. This has contributed to the popularity of mtDNA as a molecular marker in evolutionary studies. Analyzing 121 multilocus data sets and four phylogenomic data sets encompassing 4,676 species of animals, we demonstrate that the ratio of mitochondrial over nuclear mutation rate is highly variable among animal taxa. In nonvertebrates, such as insects and arachnids, the ratio of mtDNA over nuDNA mutation rate varies between 2 and 6, whereas it is above 20, on average, in vertebrates such as scaled reptiles and birds. Interestingly, this variation is sufficient to explain the previous report of a similar level of mitochondrial polymorphism, on average, between vertebrates and nonvertebrates, which was originally interpreted as reflecting the effect of pervasive positive selection. Our analysis rather indicates that the among-phyla homogeneity in within-species mtDNA diversity is due to a negative correlation between mtDNA per-generation mutation rate and effective population size, irrespective of the action of natural selection. Finally, we explore the variation in the absolute per-year mutation rate of both mtDNA and nuDNA using a reduced data set for which fossil calibration is available, and discuss the potential determinants of mutation rate variation across genomes and taxa. This study has important implications regarding DNA-based identification methods in predicting that mtDNA barcoding should be less reliable in nonvertebrates than in vertebrates., (© The Author 2017. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published
2017
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36. Evolutionary forces affecting synonymous variations in plant genomes.

Author

Clément Y, Sarah G, Holtz Y, Homa F, Pointet S, Contreras S, Nabholz B, Sabot F, Sauné L, Ardisson M, Bacilieri R, Besnard G, Berger A, Cardi C, De Bellis F, Fouet O, Jourda C, Khadari B, Lanaud C, Leroy T, Pot D, Sauvage C, Scarcelli N, Tregear J, Vigouroux Y, Yahiaoui N, Ruiz M, Santoni S, Labouisse JP, Pham JL, David J, and Glémin S

Subjects
GC Rich Sequence, Gene Conversion, Selection, Genetic, Evolution, Molecular, Genome, Plant, Magnoliopsida genetics, Polymorphism, Genetic
Abstract

Base composition is highly variable among and within plant genomes, especially at third codon positions, ranging from GC-poor and homogeneous species to GC-rich and highly heterogeneous ones (particularly Monocots). Consequently, synonymous codon usage is biased in most species, even when base composition is relatively homogeneous. The causes of these variations are still under debate, with three main forces being possibly involved: mutational bias, selection and GC-biased gene conversion (gBGC). So far, both selection and gBGC have been detected in some species but how their relative strength varies among and within species remains unclear. Population genetics approaches allow to jointly estimating the intensity of selection, gBGC and mutational bias. We extended a recently developed method and applied it to a large population genomic dataset based on transcriptome sequencing of 11 angiosperm species spread across the phylogeny. We found that at synonymous positions, base composition is far from mutation-drift equilibrium in most genomes and that gBGC is a widespread and stronger process than selection. gBGC could strongly contribute to base composition variation among plant species, implying that it should be taken into account in plant genome analyses, especially for GC-rich ones.

Published
2017
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37. A large set of 26 new reference transcriptomes dedicated to comparative population genomics in crops and wild relatives.

Author

Sarah G, Homa F, Pointet S, Contreras S, Sabot F, Nabholz B, Santoni S, Sauné L, Ardisson M, Chantret N, Sauvage C, Tregear J, Jourda C, Pot D, Vigouroux Y, Chair H, Scarcelli N, Billot C, Yahiaoui N, Bacilieri R, Khadari B, Boccara M, Barnaud A, Péros JP, Labouisse JP, Pham JL, David J, Glémin S, and Ruiz M

Subjects
Biological Evolution, Contig Mapping, Crops, Agricultural genetics, Genome, Plant, Metagenomics, Transcriptome
Abstract

We produced a unique large data set of reference transcriptomes to obtain new knowledge about the evolution of plant genomes and crop domestication. For this purpose, we validated a RNA-Seq data assembly protocol to perform comparative population genomics. For the validation, we assessed and compared the quality of de novo Illumina short-read assemblies using data from two crops for which an annotated reference genome was available, namely grapevine and sorghum. We used the same protocol for the release of 26 new transcriptomes of crop plants and wild relatives, including still understudied crops such as yam, pearl millet and fonio. The species list has a wide taxonomic representation with the inclusion of 15 monocots and 11 eudicots. All contigs were annotated using BLAST, prot4EST and Blast2GO. A strong originality of the data set is that each crop is associated with close relative species, which will permit whole-genome comparative evolutionary studies between crops and their wild-related species. This large resource will thus serve research communities working on both crops and model organisms. All the data are available at http://arcad-bioinformatics.southgreen.fr/., (© 2016 John Wiley & Sons Ltd.)

Published
2017
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38. Hemizygosity Enhances Purifying Selection: Lack of Fast-Z Evolution in Two Satyrine Butterflies.

Author

Rousselle M, Faivre N, Ballenghien M, Galtier N, and Nabholz B

Subjects
Animals, Female, Male, Polymorphism, Genetic, Butterflies genetics, Chromosomes, Insect genetics, Evolution, Molecular, Hemizygote, Selection, Genetic, X Chromosome genetics, Y Chromosome genetics
Abstract

The fixation probability of a recessive beneficial mutation is increased on the X or Z chromosome, relative to autosomes, because recessive alleles carried by X or Z are exposed to selection in the heterogametic sex. This leads to an increased dN/dS ratio on sex chromosomes relative to autosomes, a pattern called the "fast-X" or "fast-Z" effect. Besides positive selection, the strength of genetic drift and the efficacy of purifying selection, which affect the rate of molecular evolution, might differ between sex chromosomes and autosomes. Disentangling the complex effects of these distinct forces requires the genome-wide analysis of polymorphism, divergence and gene expression data in a variety of taxa. Here we study the influence of hemizygosity of the Z chromosome in Maniola jurtina and Pyronia tithonus, two species of butterflies (Lepidoptera, Nymphalidae, Satyrinae). Using transcriptome data, we compare the strength of positive and negative selection between Z and autosomes accounting for sex-specific gene expression. We show that M. jurtina and P. tithonus do not experience a faster, but rather a slightly slower evolutionary rate on the Z than on autosomes. Our analysis failed to detect a significant difference in adaptive evolutionary rate between Z and autosomes, but comparison of male-biased, unbiased and female-biased Z-linked genes revealed an increased efficacy of purifying selection against recessive deleterious mutations in female-biased Z-linked genes. This probably contributes to the lack of fast-Z evolution of satyrines. We suggest that the effect of hemizygosity on the fate of recessive deleterious mutations should be taken into account when interpreting patterns of molecular evolution in sex chromosomes vs. autosomes., (© The Author 2016. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published
2016
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39. Body mass-corrected molecular rate for bird mitochondrial DNA.

Author

Nabholz B, Lanfear R, and Fuchs J

Subjects
Animals, Genome, Mitochondrial, Phylogeny, Birds genetics, DNA, Mitochondrial genetics, Evolution, Molecular, Mutation Rate
Abstract

Mitochondrial DNA remains one of the most widely used molecular markers to reconstruct the phylogeny and phylogeography of closely related birds. It has been proposed that bird mitochondrial genomes evolve at a constant rate of ~0.01 substitution per site per million years, that is that they evolve according to a strict molecular clock. This molecular clock is often used in studies of bird mitochondrial phylogeny and molecular dating. However, rates of mitochondrial genome evolution vary among bird species and correlate with life history traits such as body mass and generation time. These correlations could cause systematic biases in molecular dating studies that assume a strict molecular clock. In this study, we overcome this issue by estimating corrected molecular rates for birds. Using complete or nearly complete mitochondrial genomes of 475 species, we show that there are strong relationships between body mass and substitution rates across birds. We use this information to build models that use bird species' body mass to estimate their substitution rates across a wide range of common mitochondrial markers. We demonstrate the use of these corrected molecular rates on two recently published data sets. In one case, we obtained molecular dates that are twice as old as the estimates obtained using the strict molecular clock. We hope that this method to estimate molecular rates will increase the accuracy of future molecular dating studies in birds., (© 2016 John Wiley & Sons Ltd.)

Published
2016
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40. Life History Traits, Protein Evolution, and the Nearly Neutral Theory in Amniotes.

Author

Figuet E, Nabholz B, Bonneau M, Mas Carrio E, Nadachowska-Brzyska K, Ellegren H, and Galtier N

Subjects
Animals, Biological Evolution, Birds genetics, Databases, Nucleic Acid, Genome, Mammals genetics, Mutation Rate, Phylogeny, Polymorphism, Genetic, Population Density, Proteins genetics, Selection, Genetic, Evolution, Molecular, Life History Traits, Models, Genetic, Sequence Analysis, DNA methods
Abstract

The nearly neutral theory of molecular evolution predicts that small populations should accumulate deleterious mutations at a faster rate than large populations. The analysis of nonsynonymous (dN) versus synonymous (dS) substitution rates in birds versus mammals, however, has provided contradictory results, questioning the generality of the nearly neutral theory. Here we analyzed the impact of life history traits, taken as proxies of the effective population size, on molecular evolutionary and population genetic processes in amniotes, including the so far neglected reptiles. We report a strong effect of species body mass, longevity, and age of sexual maturity on genome-wide patterns of polymorphism and divergence across the major groups of amniotes, in agreement with the nearly neutral theory. Our results indicate that the rate of protein evolution in amniotes is determined in the first place by the efficiency of purifying selection against deleterious mutations-and this is true of both radical and conservative amino acid changes. Interestingly, the among-species distribution of dN/dS in birds did not follow this general trend: dN/dS was not higher in large, long-lived than in small, short-lived species of birds. We show that this unexpected pattern is not due to a more narrow range of life history traits, a lack of correlation between traits and Ne, or a peculiar distribution of fitness effects of mutations in birds. Our analysis therefore highlights the bird dN/dS ratio as a molecular evolutionary paradox and a challenge for future research., (© The Author 2016. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published
2016
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41. Phylogenomic analyses data of the avian phylogenomics project.

Author

Jarvis ED, Mirarab S, Aberer AJ, Li B, Houde P, Li C, Ho SY, Faircloth BC, Nabholz B, Howard JT, Suh A, Weber CC, da Fonseca RR, Alfaro-Núñez A, Narula N, Liu L, Burt D, Ellegren H, Edwards SV, Stamatakis A, Mindell DP, Cracraft J, Braun EL, Warnow T, Jun W, Gilbert MT, and Zhang G

Subjects
Animals, Birds classification, Classification methods, DNA chemistry, DNA Transposable Elements, Genome, Genomics, Sequence Alignment, Birds genetics, Phylogeny
Abstract

Background: Determining the evolutionary relationships among the major lineages of extant birds has been one of the biggest challenges in systematic biology. To address this challenge, we assembled or collected the genomes of 48 avian species spanning most orders of birds, including all Neognathae and two of the five Palaeognathae orders. We used these genomes to construct a genome-scale avian phylogenetic tree and perform comparative genomic analyses., Findings: Here we present the datasets associated with the phylogenomic analyses, which include sequence alignment files consisting of nucleotides, amino acids, indels, and transposable elements, as well as tree files containing gene trees and species trees. Inferring an accurate phylogeny required generating: 1) A well annotated data set across species based on genome synteny; 2) Alignments with unaligned or incorrectly overaligned sequences filtered out; and 3) Diverse data sets, including genes and their inferred trees, indels, and transposable elements. Our total evidence nucleotide tree (TENT) data set (consisting of exons, introns, and UCEs) gave what we consider our most reliable species tree when using the concatenation-based ExaML algorithm or when using statistical binning with the coalescence-based MP-EST algorithm (which we refer to as MP-EST*). Other data sets, such as the coding sequence of some exons, revealed other properties of genome evolution, namely convergence., Conclusions: The Avian Phylogenomics Project is the largest vertebrate phylogenomics project to date that we are aware of. The sequence, alignment, and tree data are expected to accelerate analyses in phylogenomics and other related areas.

Published
2015
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42. Gene expression, chromosome heterogeneity and the fast-X effect in mammals.

Author

Nguyen LP, Galtier N, and Nabholz B

Subjects
Animals, Evolution, Molecular, Hemizygote, Humans, Multivariate Analysis, Polymorphism, Genetic, Gene Expression, Mammals genetics, X Chromosome genetics
Abstract

The higher rate of non-synonymous over synonymous substitutions (dN/dS) of the X chromosome compared with autosomes is often interpreted as a consequence of X hemizygosity. However, other factors, such as gene expression, are also known to vary between X and autosomes. Analysing 4800 orthologues in six mammals, we found that gene expression levels, associated with GC content, fully account for the variation in dN/dS between X and autosomes with no detectable effect of hemizygosity. We also report an extensive variance in dN/dS and gene expression between autosomes., (© 2015 The Author(s) Published by the Royal Society. All rights reserved.)

Published
2015
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43. The bimodal distribution of genic GC content is ancestral to monocot species.

Author

Clément Y, Fustier MA, Nabholz B, and Glémin S

Subjects
Likelihood Functions, Oryza genetics, Poaceae genetics, Zea mays genetics, Base Composition genetics, Codon genetics, Evolution, Molecular, Genome, Plant
Abstract

In grasses such as rice or maize, the distribution of genic GC content is well known to be bimodal. It is mainly driven by GC content at third codon positions (GC3 for short). This feature is thought to be specific to grasses as closely related species like banana have a unimodal GC3 distribution. GC3 is associated with numerous genomics features and uncovering the origin of this peculiar distribution will help understanding the potential roles and consequences of GC3 variations within and between genomes. Until recently, the origin of the peculiar GC3 distribution in grasses has remained unknown. Thanks to the recent publication of several complete genomes and transcriptomes of nongrass monocots, we studied more than 1,000 groups of one-to-one orthologous genes in seven grasses and three outgroup species (banana, palm tree, and yam). Using a maximum likelihood-based method, we reconstructed GC3 at several ancestral nodes. We found that the bimodal GC3 distribution observed in extant grasses is ancestral to both grasses and most monocot species, and that other species studied here have lost this peculiar structure. We also found that GC3 in grass lineages is globally evolving very slowly and that the decreasing GC3 gradient observed from 5' to 3' along coding sequences is also conserved and ancestral to monocots. This result strongly challenges the previous views on the specificity of grass genomes and we discuss its implications for the possible causes of the evolution of GC content in monocots., (© The Author(s) 2014. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published
2014
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44. Whole-genome analyses resolve early branches in the tree of life of modern birds.

Author

Jarvis ED, Mirarab S, Aberer AJ, Li B, Houde P, Li C, Ho SY, Faircloth BC, Nabholz B, Howard JT, Suh A, Weber CC, da Fonseca RR, Li J, Zhang F, Li H, Zhou L, Narula N, Liu L, Ganapathy G, Boussau B, Bayzid MS, Zavidovych V, Subramanian S, Gabaldón T, Capella-Gutiérrez S, Huerta-Cepas J, Rekepalli B, Munch K, Schierup M, Lindow B, Warren WC, Ray D, Green RE, Bruford MW, Zhan X, Dixon A, Li S, Li N, Huang Y, Derryberry EP, Bertelsen MF, Sheldon FH, Brumfield RT, Mello CV, Lovell PV, Wirthlin M, Schneider MP, Prosdocimi F, Samaniego JA, Vargas Velazquez AM, Alfaro-Núñez A, Campos PF, Petersen B, Sicheritz-Ponten T, Pas A, Bailey T, Scofield P, Bunce M, Lambert DM, Zhou Q, Perelman P, Driskell AC, Shapiro B, Xiong Z, Zeng Y, Liu S, Li Z, Liu B, Wu K, Xiao J, Yinqi X, Zheng Q, Zhang Y, Yang H, Wang J, Smeds L, Rheindt FE, Braun M, Fjeldsa J, Orlando L, Barker FK, Jønsson KA, Johnson W, Koepfli KP, O'Brien S, Haussler D, Ryder OA, Rahbek C, Willerslev E, Graves GR, Glenn TC, McCormack J, Burt D, Ellegren H, Alström P, Edwards SV, Stamatakis A, Mindell DP, Cracraft J, Braun EL, Warnow T, Jun W, Gilbert MT, and Zhang G

Subjects
Animals, Avian Proteins genetics, Base Sequence, Biological Evolution, Birds classification, DNA Transposable Elements, Genes, Genetic Speciation, INDEL Mutation, Introns, Sequence Analysis, DNA, Birds genetics, Genome, Phylogeny
Abstract

To better determine the history of modern birds, we performed a genome-scale phylogenetic analysis of 48 species representing all orders of Neoaves using phylogenomic methods created to handle genome-scale data. We recovered a highly resolved tree that confirms previously controversial sister or close relationships. We identified the first divergence in Neoaves, two groups we named Passerea and Columbea, representing independent lineages of diverse and convergently evolved land and water bird species. Among Passerea, we infer the common ancestor of core landbirds to have been an apex predator and confirm independent gains of vocal learning. Among Columbea, we identify pigeons and flamingoes as belonging to sister clades. Even with whole genomes, some of the earliest branches in Neoaves proved challenging to resolve, which was best explained by massive protein-coding sequence convergence and high levels of incomplete lineage sorting that occurred during a rapid radiation after the Cretaceous-Paleogene mass extinction event about 66 million years ago., (Copyright © 2014, American Association for the Advancement of Science.)

Published
2014
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45. Transcriptome population genomics reveals severe bottleneck and domestication cost in the African rice (Oryza glaberrima).

Author

Nabholz B, Sarah G, Sabot F, Ruiz M, Adam H, Nidelet S, Ghesquière A, Santoni S, David J, and Glémin S

Subjects
Bayes Theorem, Chromosome Mapping, Crops, Agricultural genetics, DNA, Plant genetics, Genetic Variation, Polymorphism, Single Nucleotide, Sequence Analysis, DNA, Evolution, Molecular, Genetics, Population, Genome, Plant, Poaceae genetics, Transcriptome
Abstract

The African cultivated rice (Oryza glaberrima) was domesticated in West Africa 3000 years ago. Although less cultivated than the Asian rice (O. sativa), O. glaberrima landraces often display interesting adaptation to rustic environment (e.g. drought). Here, using RNA-seq technology, we were able to compare more than 12,000 transcripts between 9 O. glaberrima, 10 wild O. barthii and one O. meridionalis individuals. With a synonymous nucleotide diversity πs = 0.0006 per site, O. glaberrima appears as the least genetically diverse crop grass ever documented. Using approximate Bayesian computation, we estimated that O. glaberrima experienced a severe bottleneck during domestication. This demographic scenario almost fully accounts for the pattern of genetic diversity across O. glaberrima genome as we detected very few outliers regions where positive selection may have further impacted genetic diversity. Moreover, the large excess of derived nonsynonymous substitution that we detected suggests that the O. glaberrima population suffered from the 'cost of domestication'. In addition, we used this genome-scale data set to demonstrate that (i) O. barthii genetic diversity is positively correlated with recombination rate and negatively with gene density, (ii) expression level is negatively correlated with evolutionary constraint, and (iii) one region on chromosome 5 (position 4-6 Mb) exhibits a clear signature of introgression with a yet unidentified Oryza species. This work represents the first genome-wide survey of the African rice genetic diversity and paves the way for further comparison between the African and the Asian rice, notably regarding the genetics underlying domestication traits., (© 2014 John Wiley & Sons Ltd.)

Published
2014
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46. Kr/Kc but not dN/dS correlates positively with body mass in birds, raising implications for inferring lineage-specific selection.

Author

Weber CC, Nabholz B, Romiguier J, and Ellegren H

Subjects
Animals, Bayes Theorem, Birds classification, Birds physiology, Body Mass Index, Evolution, Molecular, Mutation Rate, Phylogeny, Quantitative Trait Loci, Selection, Genetic, Species Specificity, Amino Acid Substitution, Avian Proteins genetics, Birds genetics, Computational Biology methods
Abstract

Background: The ratio of the rates of non-synonymous and synonymous substitution (dN/dS) is commonly used to estimate selection in coding sequences. It is often suggested that, all else being equal, dN/dS should be lower in populations with large effective size (Ne) due to increased efficacy of purifying selection. As Ne is difficult to measure directly, life history traits such as body mass, which is typically negatively associated with population size, have commonly been used as proxies in empirical tests of this hypothesis. However, evidence of whether the expected positive correlation between body mass and dN/dS is consistently observed is conflicting., Results: Employing whole genome sequence data from 48 avian species, we assess the relationship between rates of molecular evolution and life history in birds. We find a negative correlation between dN/dS and body mass, contrary to nearly neutral expectation. This raises the question whether the correlation might be a method artefact. We therefore in turn consider non-stationary base composition, divergence time and saturation as possible explanations, but find no clear patterns. However, in striking contrast to dN/dS, the ratio of radical to conservative amino acid substitutions (Kr/Kc) correlates positively with body mass., Conclusions: Our results in principle accord with the notion that non-synonymous substitutions causing radical amino acid changes are more efficiently removed by selection in large populations, consistent with nearly neutral theory. These findings have implications for the use of dN/dS and suggest that caution is warranted when drawing conclusions about lineage-specific modes of protein evolution using this metric.

Published
2014
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47. Bio++: efficient extensible libraries and tools for computational molecular evolution.

Author

Guéguen L, Gaillard S, Boussau B, Gouy M, Groussin M, Rochette NC, Bigot T, Fournier D, Pouyet F, Cahais V, Bernard A, Scornavacca C, Nabholz B, Haudry A, Dachary L, Galtier N, Belkhir K, and Dutheil JY

Subjects
Algorithms, Genomics methods, Humans, Internet, Computational Biology methods, Evolution, Molecular, Software
Abstract

Efficient algorithms and programs for the analysis of the ever-growing amount of biological sequence data are strongly needed in the genomics era. The pace at which new data and methodologies are generated calls for the use of pre-existing, optimized-yet extensible-code, typically distributed as libraries or packages. This motivated the Bio++ project, aiming at developing a set of C++ libraries for sequence analysis, phylogenetics, population genetics, and molecular evolution. The main attractiveness of Bio++ is the extensibility and reusability of its components through its object-oriented design, without compromising the computer-efficiency of the underlying methods. We present here the second major release of the libraries, which provides an extended set of classes and methods. These extensions notably provide built-in access to sequence databases and new data structures for handling and manipulating sequences from the omics era, such as multiple genome alignments and sequencing reads libraries. More complex models of sequence evolution, such as mixture models and generic n-tuples alphabets, are also included.

Published
2013
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48. Genome-wide analysis in chicken reveals that local levels of genetic diversity are mainly governed by the rate of recombination.

Author

Mugal CF, Nabholz B, and Ellegren H

Subjects
Animals, Base Composition, Breeding, Female, Male, Regression Analysis, Chickens genetics, Genetic Variation genetics, Genomics, Recombination, Genetic genetics
Abstract

Background: Polymorphism is key to the evolutionary potential of populations. Understanding which factors shape levels of genetic diversity within genomes forms a central question in evolutionary genomics and is of importance for the possibility to infer episodes of adaptive evolution from signs of reduced diversity. There is an on-going debate on the relative role of mutation and selection in governing diversity levels. This question is also related to the role of recombination because recombination is expected to indirectly affect polymorphism via the efficacy of selection. Moreover, recombination might itself be mutagenic and thereby assert a direct effect on diversity levels., Results: We used whole-genome re-sequencing data from domestic chicken (broiler and layer breeds) and its wild ancestor (the red jungle fowl) to study the relationship between genetic diversity and several genomic parameters. We found that recombination rate had the largest effect on local levels of nucleotide diversity. The fact that divergence (a proxy for mutation rate) and recombination rate were negatively correlated argues against a mutagenic role of recombination. Furthermore, divergence had limited influence on polymorphism., Conclusions: Overall, our results are consistent with a selection model, in which regions within a short distance from loci under selection show reduced polymorphism levels. This conclusion lends further support from the observations of strong correlations between intergenic levels of diversity and diversity at synonymous as well as non-synonymous sites. Our results also demonstrate differences between the two domestic breeds and red jungle fowl, where the domestic breeds show a stronger relationship between intergenic diversity levels and diversity at synonymous and non-synonymous sites. This finding, together with overall lower diversity levels in domesticates compared to red jungle fowl, seem attributable to artificial selection during domestication.

Published
2013
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49. High levels of gene expression explain the strong evolutionary constraint of mitochondrial protein-coding genes.

Author

Nabholz B, Ellegren H, and Wolf JB

Subjects
Animals, Biological Evolution, Birds, DNA, Mitochondrial genetics, Insecta, Mammals, Mitochondria genetics, Mitochondria metabolism, Mitochondrial Proteins metabolism, Oxidative Phosphorylation, Selection, Genetic, Evolution, Molecular, Gene Expression, Mitochondrial Proteins genetics
Abstract

The nearly neutral theory of molecular evolution has been widely accepted as the guiding principle for understanding how selection affects gene sequence evolution. One of its central predictions is that the rate at which proteins evolve should negatively scale with effective population size (N(e)). In contrast to the expectation of reduced selective constraint in the mitochondrial genome following from its lower N(e), we observe what can be interpreted as the opposite: for a taxonomically diverse set of organisms (birds, mammals, insects, and nematodes), mitochondrially encoded protein-coding genes from the oxidative phosphorylation pathway (mtOXPHOS; n = 12-13) show markedly stronger signatures of purifying selection (illustrated by low d(N)/d(S)) than their nuclear counterparts interacting in the same pathway (nuOXPHOS; n: ∼75). To understand these unexpected evolutionary dynamics, we consider a number of structural and functional parameters including gene expression, hydrophobicity, transmembrane position, gene ontology, GC content, substitution rate, proportion of amino acids in transmembrane helices, and protein-protein interaction. Across all taxa, unexpectedly large differences in gene expression levels (RNA-seq) between nuclear and mitochondrially encoded genes, and to a lower extent hydrophobicity, explained most of the variation in d(N)/d(S). Similarly, differences in d(N)/d(S) between functional OXPHOS protein complexes could largely be explained by gene expression differences. Overall, by including gene expression and other functional parameters, the unexpected mitochondrial evolutionary dynamics can be understood. Our results not only reaffirm the link between gene expression and protein evolution but also open new questions about the functional role of expression level variation between mitochondrial genes.

Published
2013
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50. Reconstructing the phylogenetic history of long-term effective population size and life-history traits using patterns of amino acid replacement in mitochondrial genomes of mammals and birds.

Author

Nabholz B, Uwimana N, and Lartillot N

Subjects
Animals, Base Composition, Biological Evolution, Birds physiology, Body Size, Evolution, Molecular, Female, Fossils, Mammals physiology, Models, Statistical, Mutation, Placenta, Population Density, Pregnancy, Sequence Alignment, Amino Acid Substitution, Birds genetics, Genome, Mitochondrial, Longevity genetics, Mammals genetics, Phylogeny
Abstract

The nearly neutral theory, which proposes that most mutations are deleterious or close to neutral, predicts that the ratio of nonsynonymous over synonymous substitution rates (dN/dS), and potentially also the ratio of radical over conservative amino acid replacement rates (Kr/Kc), are negatively correlated with effective population size. Previous empirical tests, using life-history traits (LHT) such as body-size or generation-time as proxies for population size, have been consistent with these predictions. This suggests that large-scale phylogenetic reconstructions of dN/dS or Kr/Kc might reveal interesting macroevolutionary patterns in the variation in effective population size among lineages. In this work, we further develop an integrative probabilistic framework for phylogenetic covariance analysis introduced previously, so as to estimate the correlation patterns between dN/dS, Kr/Kc, and three LHT, in mitochondrial genomes of birds and mammals. Kr/Kc displays stronger and more stable correlations with LHT than does dN/dS, which we interpret as a greater robustness of Kr/Kc, compared with dN/dS, the latter being confounded by the high saturation of the synonymous substitution rate in mitochondrial genomes. The correlation of Kr/Kc with LHT was robust when controlling for the potentially confounding effects of nucleotide compositional variation between taxa. The positive correlation of the mitochondrial Kr/Kc with LHT is compatible with previous reports, and with a nearly neutral interpretation, although alternative explanations are also possible. The Kr/Kc model was finally used for reconstructing life-history evolution in birds and mammals. This analysis suggests a fairly large-bodied ancestor in both groups. In birds, life-history evolution seems to have occurred mainly through size reduction in Neoavian birds, whereas in placental mammals, body mass evolution shows disparate trends across subclades. Altogether, our work represents a further step toward a more comprehensive phylogenetic reconstruction of the evolution of life-history and of the population-genetics environment.

Published
2013
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