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2. Gene content evolution in the arthropods

Author

Thomas, Gregg WC, Dohmen, Elias, Hughes, Daniel ST, Murali, Shwetha C, Poelchau, Monica, Glastad, Karl, Anstead, Clare A, Ayoub, Nadia A, Batterham, Phillip, Bellair, Michelle, Binford, Greta J, Chao, Hsu, Chen, Yolanda H, Childers, Christopher, Dinh, Huyen, Doddapaneni, Harsha Vardhan, Duan, Jian J, Dugan, Shannon, Esposito, Lauren A, Friedrich, Markus, Garb, Jessica, Gasser, Robin B, Goodisman, Michael AD, Gundersen-Rindal, Dawn E, Han, Yi, Handler, Alfred M, Hatakeyama, Masatsugu, Hering, Lars, Hunter, Wayne B, Ioannidis, Panagiotis, Jayaseelan, Joy C, Kalra, Divya, Khila, Abderrahman, Korhonen, Pasi K, Lee, Carol Eunmi, Lee, Sandra L, Li, Yiyuan, Lindsey, Amelia RI, Mayer, Georg, McGregor, Alistair P, McKenna, Duane D, Misof, Bernhard, Munidasa, Mala, Munoz-Torres, Monica, Muzny, Donna M, Niehuis, Oliver, Osuji-Lacy, Nkechinyere, Palli, Subba R, Panfilio, Kristen A, Pechmann, Matthias, Perry, Trent, Peters, Ralph S, Poynton, Helen C, Prpic, Nikola-Michael, Qu, Jiaxin, Rotenberg, Dorith, Schal, Coby, Schoville, Sean D, Scully, Erin D, Skinner, Evette, Sloan, Daniel B, Stouthamer, Richard, Strand, Michael R, Szucsich, Nikolaus U, Wijeratne, Asela, Young, Neil D, Zattara, Eduardo E, Benoit, Joshua B, Zdobnov, Evgeny M, Pfrender, Michael E, Hackett, Kevin J, Werren, John H, Worley, Kim C, Gibbs, Richard A, Chipman, Ariel D, Waterhouse, Robert M, Bornberg-Bauer, Erich, Hahn, Matthew W, and Richards, Stephen

Subjects
Human Genome, Genetics, Biotechnology, Generic health relevance, Animals, Arthropods, DNA Methylation, Evolution, Molecular, Genetic Speciation, Genetic Variation, Phylogeny, Genome assembly, Genomics, Protein domains, Gene content, Evolution, DNA methylation, Environmental Sciences, Biological Sciences, Information and Computing Sciences, Bioinformatics
Abstract

BackgroundArthropods comprise the largest and most diverse phylum on Earth and play vital roles in nearly every ecosystem. Their diversity stems in part from variations on a conserved body plan, resulting from and recorded in adaptive changes in the genome. Dissection of the genomic record of sequence change enables broad questions regarding genome evolution to be addressed, even across hyper-diverse taxa within arthropods.ResultsUsing 76 whole genome sequences representing 21 orders spanning more than 500 million years of arthropod evolution, we document changes in gene and protein domain content and provide temporal and phylogenetic context for interpreting these innovations. We identify many novel gene families that arose early in the evolution of arthropods and during the diversification of insects into modern orders. We reveal unexpected variation in patterns of DNA methylation across arthropods and examples of gene family and protein domain evolution coincident with the appearance of notable phenotypic and physiological adaptations such as flight, metamorphosis, sociality, and chemoperception.ConclusionsThese analyses demonstrate how large-scale comparative genomics can provide broad new insights into the genotype to phenotype map and generate testable hypotheses about the evolution of animal diversity.

Published
2020

4. Sperm competition intensity shapes divergence in both sperm morphology and reproductive genes across murine rodents.

Author

Kopania, Emily E K, Thomas, Gregg W C, Hutter, Carl R, Mortimer, Sebastian M E, Callahan, Colin M, Roycroft, Emily, Achmadi, Anang S, Breed, William G, Clark, Nathan L, Esselstyn, Jacob A, Rowe, Kevin C, and Good, Jeffrey M

Subjects
*MOLECULAR evolution, *SEXUAL selection, *MOLECULAR shapes, *MORPHOLOGY, *SPERMATOZOA, *SPERM competition, *SPERMATOGENESIS
Abstract

It remains unclear how variation in the intensity of sperm competition shapes phenotypic and molecular evolution across clades. Mice and rats in the subfamily Murinae are a rapid radiation exhibiting incredible diversity in sperm morphology and production. We combined phenotypic and genomic data to perform phylogenetic comparisons of male reproductive traits and genes across 78 murine species. We identified several shifts towards smaller relative testes mass (RTM), presumably reflecting reduced sperm competition. Several sperm traits were associated with RTM, suggesting that mating system evolution selects for convergent suites of traits related to sperm competitive ability. We predicted that sperm competition would also drive more rapid molecular divergence in species with large testes. Contrary to this, we found that many spermatogenesis genes evolved more rapidly in species with smaller RTM due to relaxed purifying selection. While some reproductive genes evolved rapidly under recurrent positive selection, relaxed selection played a greater role in underlying rapid evolution in small testes species. Our work demonstrates that postcopulatory sexual selection can impose strong purifying selection shaping the evolution of male reproduction and that broad patterns of molecular evolution may help identify genes that contribute to male fertility. [ABSTRACT FROM AUTHOR]

Published
2025
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5. Practical Guidance and Workflows for Identifying Fast Evolving Non-Coding Genomic Elements Using PhyloAcc.

Author

Thomas, Gregg W C, Gemmell, Patrick, Shakya, Subir B, Hu, Zhirui, Liu, Jun S, Sackton, Timothy B, and Edwards, Scott V

Subjects
*MOLECULAR evolution, *PHENOTYPES, *NUCLEOTIDE sequencing, *PHYLOGENY, *GENOMES, *PHYLOGENETIC models
Abstract

Comparative genomics provides ample ways to study genome evolution and its relationship to phenotypic traits. By developing and testing alternate models of evolution throughout a phylogeny, one can estimate rates of molecular evolution along different lineages in a phylogeny and link these rates with observations in extant species, such as convergent phenotypes. Pipelines for such work can help identify when and where genomic changes may be associated with, or possibly influence, phenotypic traits. We recently developed a set of models called PhyloAcc, using a Bayesian framework to estimate rates of nucleotide substitution on different branches of a phylogenetic tree and evaluate their association with pre-defined or estimated phenotypic traits. PhyloAcc-ST and PhyloAcc-GT both allow users to define a priori a set of target lineages and then compare different models to identify loci accelerating in one or more target lineages. Whereas ST considers only one species tree across all input loci, GT considers alternate topologies for every locus. PhyloAcc-C simultaneously models molecular rates and rates of continuous trait evolution, allowing the user to ask whether the two are associated. Here, we describe these models and provide tips and workflows on how to prepare the input data and run PhyloAcc. [ABSTRACT FROM AUTHOR]

Published
2024
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6. A model species for agricultural pest genomics: the genome of the Colorado potato beetle, Leptinotarsa decemlineata (Coleoptera: Chrysomelidae).

Author

Schoville, Sean D, Chen, Yolanda H, Andersson, Martin N, Benoit, Joshua B, Bhandari, Anita, Bowsher, Julia H, Brevik, Kristian, Cappelle, Kaat, Chen, Mei-Ju M, Childers, Anna K, Childers, Christopher, Christiaens, Olivier, Clements, Justin, Didion, Elise M, Elpidina, Elena N, Engsontia, Patamarerk, Friedrich, Markus, García-Robles, Inmaculada, Gibbs, Richard A, Goswami, Chandan, Grapputo, Alessandro, Gruden, Kristina, Grynberg, Marcin, Henrissat, Bernard, Jennings, Emily C, Jones, Jeffery W, Kalsi, Megha, Khan, Sher A, Kumar, Abhishek, Li, Fei, Lombard, Vincent, Ma, Xingzhou, Martynov, Alexander, Miller, Nicholas J, Mitchell, Robert F, Munoz-Torres, Monica, Muszewska, Anna, Oppert, Brenda, Palli, Subba Reddy, Panfilio, Kristen A, Pauchet, Yannick, Perkin, Lindsey C, Petek, Marko, Poelchau, Monica F, Record, Éric, Rinehart, Joseph P, Robertson, Hugh M, Rosendale, Andrew J, Ruiz-Arroyo, Victor M, Smagghe, Guy, Szendrei, Zsofia, Thomas, Gregg WC, Torson, Alex S, Vargas Jentzsch, Iris M, Weirauch, Matthew T, Yates, Ashley D, Yocum, George D, Yoon, June-Sun, and Richards, Stephen

Subjects
Animals, Insect Proteins, Transcription Factors, DNA Transposable Elements, Genetics, Population, Genomics, Pest Control, Biological, Evolution, Molecular, Phylogeny, Gene Expression Regulation, RNA Interference, Insecticide Resistance, Multigene Family, Agriculture, Female, Male, Solanum tuberosum, Genome, Insect, Host-Parasite Interactions, Genetic Variation, Molecular Sequence Annotation, Coleoptera, Genetics, Population, Pest Control, Biological, Evolution, Molecular, Genome, Insect, Biochemistry and Cell Biology, Other Physical Sciences
Abstract

The Colorado potato beetle is one of the most challenging agricultural pests to manage. It has shown a spectacular ability to adapt to a variety of solanaceaeous plants and variable climates during its global invasion, and, notably, to rapidly evolve insecticide resistance. To examine evidence of rapid evolutionary change, and to understand the genetic basis of herbivory and insecticide resistance, we tested for structural and functional genomic changes relative to other arthropod species using genome sequencing, transcriptomics, and community annotation. Two factors that might facilitate rapid evolutionary change include transposable elements, which comprise at least 17% of the genome and are rapidly evolving compared to other Coleoptera, and high levels of nucleotide diversity in rapidly growing pest populations. Adaptations to plant feeding are evident in gene expansions and differential expression of digestive enzymes in gut tissues, as well as expansions of gustatory receptors for bitter tasting. Surprisingly, the suite of genes involved in insecticide resistance is similar to other beetles. Finally, duplications in the RNAi pathway might explain why Leptinotarsa decemlineata has high sensitivity to dsRNA. The L. decemlineata genome provides opportunities to investigate a broad range of phenotypes and to develop sustainable methods to control this widely successful pest.

Published
2018

8. Genomics and conservation: Guidance from training to analyses and applications

Author

Schiebelhut, Lauren M., Guillaume, Annie Sandrine, Kuhn, Arianna, Schweizer, Rena M., Armstrong, Ellie E., Beaumont, Mark A., Byrne, Margaret, Cosart, Ted, Hand, Brian K., Howard, Leif, Mussmann, Steven M., Narum, Shawn R., Rasteiro, Rita, Rivera-Colon, Angel G., Saarman, Norah, Sethuraman, Arun, Taylor, Helen R., Thomas, Gregg W. C., Wellenreuther, Maren, Luikart, Gordon, Schiebelhut, Lauren M., Guillaume, Annie Sandrine, Kuhn, Arianna, Schweizer, Rena M., Armstrong, Ellie E., Beaumont, Mark A., Byrne, Margaret, Cosart, Ted, Hand, Brian K., Howard, Leif, Mussmann, Steven M., Narum, Shawn R., Rasteiro, Rita, Rivera-Colon, Angel G., Saarman, Norah, Sethuraman, Arun, Taylor, Helen R., Thomas, Gregg W. C., Wellenreuther, Maren, and Luikart, Gordon

Abstract

Environmental change is intensifying the biodiversity crisis and threatening species across the tree of life. Conservation genomics can help inform conservation actions and slow biodiversity loss. However, more training, appropriate use of novel genomic methods and communication with managers are needed. Here, we review practical guidance to improve applied conservation genomics. We share insights aimed at ensuring effectiveness of conservation actions around three themes: (1) improving pedagogy and training in conservation genomics including for online global audiences, (2) conducting rigorous population genomic analyses properly considering theory, marker types and data interpretation and (3) facilitating communication and collaboration between managers and researchers. We aim to update students and professionals and expand their conservation toolkit with genomic principles and recent approaches for conserving and managing biodiversity. The biodiversity crisis is a global problem and, as such, requires international involvement, training, collaboration and frequent reviews of the literature and workshops as we do here.

Published
2024
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9. The genome of the vervet (Chlorocebus aethiops sabaeus)

Author

Warren, Wesley C, Jasinska, Anna J, García-Pérez, Raquel, Svardal, Hannes, Tomlinson, Chad, Rocchi, Mariano, Archidiacono, Nicoletta, Capozzi, Oronzo, Minx, Patrick, Montague, Michael J, Kyung, Kim, Hillier, LaDeana W, Kremitzki, Milinn, Graves, Tina, Chiang, Colby, Hughes, Jennifer, Tran, Nam, Huang, Yu, Ramensky, Vasily, Choi, Oi-wa, Jung, Yoon J, Schmitt, Christopher A, Juretic, Nikoleta, Wasserscheid, Jessica, Turner, Trudy R, Wiseman, Roger W, Tuscher, Jennifer J, Karl, Julie A, Schmitz, Jörn E, Zahn, Roland, O'Connor, David H, Redmond, Eugene, Nisbett, Alex, Jacquelin, Béatrice, Müller-Trutwin, Michaela C, Brenchley, Jason M, Dione, Michel, Antonio, Martin, Schroth, Gary P, Kaplan, Jay R, Jorgensen, Matthew J, Thomas, Gregg WC, Hahn, Matthew W, Raney, Brian J, Aken, Bronwen, Nag, Rishi, Schmitz, Juergen, Churakov, Gennady, Noll, Angela, Stanyon, Roscoe, Webb, David, Thibaud-Nissen, Francoise, Nordborg, Magnus, Marques-Bonet, Tomas, Dewar, Ken, Weinstock, George M, Wilson, Richard K, and Freimer, Nelson B

Subjects
Human Genome, Biotechnology, Genetics, Infection, Animals, Chlorocebus aethiops, Chromosome Painting, Computational Biology, Evolution, Molecular, Gene Rearrangement, Genetic Variation, Genome, Genomics, Karyotype, Major Histocompatibility Complex, Molecular Sequence Annotation, Phylogeny, Phylogeography, Biological Sciences, Medical and Health Sciences, Bioinformatics
Abstract

We describe a genome reference of the African green monkey or vervet (Chlorocebus aethiops). This member of the Old World monkey (OWM) superfamily is uniquely valuable for genetic investigations of simian immunodeficiency virus (SIV), for which it is the most abundant natural host species, and of a wide range of health-related phenotypes assessed in Caribbean vervets (C. a. sabaeus), whose numbers have expanded dramatically since Europeans introduced small numbers of their ancestors from West Africa during the colonial era. We use the reference to characterize the genomic relationship between vervets and other primates, the intra-generic phylogeny of vervet subspecies, and genome-wide structural variations of a pedigreed C. a. sabaeus population. Through comparative analyses with human and rhesus macaque, we characterize at high resolution the unique chromosomal fission events that differentiate the vervets and their close relatives from most other catarrhine primates, in whom karyotype is highly conserved. We also provide a summary of transposable elements and contrast these with the rhesus macaque and human. Analysis of sequenced genomes representing each of the main vervet subspecies supports previously hypothesized relationships between these populations, which range across most of sub-Saharan Africa, while uncovering high levels of genetic diversity within each. Sequence-based analyses of major histocompatibility complex (MHC) polymorphisms reveal extremely low diversity in Caribbean C. a. sabaeus vervets, compared to vervets from putatively ancestral West African regions. In the C. a. sabaeus research population, we discover the first structural variations that are, in some cases, predicted to have a deleterious effect; future studies will determine the phenotypic impact of these variations.

Published
2015

10. Convergent evolution of the genomes of marine mammals

Author

Foote, Andrew D, Liu, Yue, Thomas, Gregg WC, Vinař, Tomáš, Alföldi, Jessica, Deng, Jixin, Dugan, Shannon, van Elk, Cornelis E, Hunter, Margaret E, Joshi, Vandita, Khan, Ziad, Kovar, Christie, Lee, Sandra L, Lindblad-Toh, Kerstin, Mancia, Annalaura, Nielsen, Rasmus, Qin, Xiang, Qu, Jiaxin, Raney, Brian J, Vijay, Nagarjun, Wolf, Jochen BW, Hahn, Matthew W, Muzny, Donna M, Worley, Kim C, Gilbert, M Thomas P, and Gibbs, Richard A

Subjects
Microbiology, Biological Sciences, Bioinformatics and Computational Biology, Genetics, Biotechnology, Human Genome, Adaptation, Physiological, Amino Acid Substitution, Animals, Evolution, Molecular, Genome, Humans, Mammals, Phenotype, Phylogeny, Selection, Genetic, Medical and Health Sciences, Developmental Biology, Agricultural biotechnology, Bioinformatics and computational biology
Abstract

Marine mammals from different mammalian orders share several phenotypic traits adapted to the aquatic environment and therefore represent a classic example of convergent evolution. To investigate convergent evolution at the genomic level, we sequenced and performed de novo assembly of the genomes of three species of marine mammals (the killer whale, walrus and manatee) from three mammalian orders that share independently evolved phenotypic adaptations to a marine existence. Our comparative genomic analyses found that convergent amino acid substitutions were widespread throughout the genome and that a subset of these substitutions were in genes evolving under positive selection and putatively associated with a marine phenotype. However, we found higher levels of convergent amino acid substitutions in a control set of terrestrial sister taxa to the marine mammals. Our results suggest that, whereas convergent molecular evolution is relatively common, adaptive molecular convergence linked to phenotypic convergence is comparatively rare.

Published
2015

11. Decoding Learning Gains: Measuring Outcomes and the Pivotal Role of the Major and Student Backgrounds. SERU Project and Consortium Research Paper. Research & Occasional Paper Series: CSHE.5.09

Author

University of California, Berkeley, Center for Studies in Higher Education, Thomas, Gregg, and Douglass, John Aubrey

Abstract

Throughout the world, interest in gauging learning outcomes at all levels of education has grown considerably over the past decade. In higher education, measuring "learning outcomes" is viewed by many stakeholders as a relatively new method to judge the "value added" of colleges and universities. The potential to accurately measure learning gains is also viewed as a diagnostic tool for institutional self-improvement. This essay compares the methodology and potential uses of three tools for measuring learning outcomes: the Collegiate Learning Assessment (CLA), the National Survey of Student Engagement (NSSE), and the University of California's Undergraduate Experience Survey (UCUES). In addition, we examine UCUES 2008 responses of seniors who entered as freshmen on six of the educational outcomes self-reports: analytical and critical thinking skills, writing skills, reading and comprehension skills, oral presentation skills, quantitative skills, and skills in a particular field of study. This initial analysis shows that campus-wide assessments of learning outcomes are generally not valid indicators of learning outcomes, and that self-reported gains at the level of the major are perhaps the best indicator we have, thus far, for assessing the value-added effects of a student's academic experience at a major research university. UCUES appears the better approach for assessing and reporting learning outcomes. This is because UCUES offers more extensive academic engagement data as well as a much wider range of demographic and institutional data, and therefore an unprecedented opportunity to advance our understanding of the nature of self-reported learning outcomes in higher education, and the extent to which these reports can contribute as indirect but valid measures of positive educational outcomes. At the same time, the apparent differences in learning outcomes across the undergraduate campuses of the University of California without controls for campus differences in composition illustrates some of the limitations of self-reported data. (Contains 5 notes and 6 tables.)

Published
2009

12. Highly evolvable malaria vectors: The genomes of 16 Anopheles mosquitoes

Author

Neafsey, Daniel E, Waterhouse, Robert M, Abai, Mohammad R, Aganezov, Sergey S, Alekseyev, Max A, Allen, James E, Amon, James, Arcà, Bruno, Arensburger, Peter, Artemov, Gleb, Assour, Lauren A, Basseri, Hamidreza, Berlin, Aaron, Birren, Bruce W, Blandin, Stephanie A, Brockman, Andrew I, Burkot, Thomas R, Burt, Austin, Chan, Clara S, Chauve, Cedric, Chiu, Joanna C, Christensen, Mikkel, Costantini, Carlo, Davidson, Victoria LM, Deligianni, Elena, Dottorini, Tania, Dritsou, Vicky, Gabriel, Stacey B, Guelbeogo, Wamdaogo M, Hall, Andrew B, Han, Mira V, Hlaing, Thaung, Hughes, Daniel ST, Jenkins, Adam M, Jiang, Xiaofang, Jungreis, Irwin, Kakani, Evdoxia G, Kamali, Maryam, Kemppainen, Petri, Kennedy, Ryan C, Kirmitzoglou, Ioannis K, Koekemoer, Lizette L, Laban, Njoroge, Langridge, Nicholas, Lawniczak, Mara KN, Lirakis, Manolis, Lobo, Neil F, Lowy, Ernesto, MacCallum, Robert M, Mao, Chunhong, Maslen, Gareth, Mbogo, Charles, McCarthy, Jenny, Michel, Kristin, Mitchell, Sara N, Moore, Wendy, Murphy, Katherine A, Naumenko, Anastasia N, Nolan, Tony, Novoa, Eva M, O'Loughlin, Samantha, Oringanje, Chioma, Oshaghi, Mohammad A, Pakpour, Nazzy, Papathanos, Philippos A, Peery, Ashley N, Povelones, Michael, Prakash, Anil, Price, David P, Rajaraman, Ashok, Reimer, Lisa J, Rinker, David C, Rokas, Antonis, Russell, Tanya L, Sagnon, N'Fale, Sharakhova, Maria V, Shea, Terrance, Simão, Felipe A, Simard, Frederic, Slotman, Michel A, Somboon, Pradya, Stegniy, Vladimir, Struchiner, Claudio J, Thomas, Gregg WC, Tojo, Marta, Topalis, Pantelis, Tubio, José MC, Unger, Maria F, Vontas, John, Walton, Catherine, Wilding, Craig S, Willis, Judith H, Wu, Yi-Chieh, Yan, Guiyun, Zdobnov, Evgeny M, Zhou, Xiaofan, Catteruccia, Flaminia, Christophides, George K, Collins, Frank H, and Cornman, Robert S

Subjects
Biological Sciences, Bioinformatics and Computational Biology, Biomedical and Clinical Sciences, Genetics, Medical Microbiology, Biotechnology, Rare Diseases, Vector-Borne Diseases, Malaria, Infectious Diseases, 2.2 Factors relating to the physical environment, Infection, Good Health and Well Being, Animals, Anopheles, Base Sequence, Chromosomes, Insect, Drosophila, Evolution, Molecular, Genome, Insect, Humans, Insect Vectors, Molecular Sequence Data, Phylogeny, Sequence Alignment, General Science & Technology
Abstract

Variation in vectorial capacity for human malaria among Anopheles mosquito species is determined by many factors, including behavior, immunity, and life history. To investigate the genomic basis of vectorial capacity and explore new avenues for vector control, we sequenced the genomes of 16 anopheline mosquito species from diverse locations spanning ~100 million years of evolution. Comparative analyses show faster rates of gene gain and loss, elevated gene shuffling on the X chromosome, and more intron losses, relative to Drosophila. Some determinants of vectorial capacity, such as chemosensory genes, do not show elevated turnover but instead diversify through protein-sequence changes. This dynamism of anopheline genes and genomes may contribute to their flexible capacity to take advantage of new ecological niches, including adapting to humans as primary hosts.

Published
2015

13. Mosquito genomics. Highly evolvable malaria vectors: the genomes of 16 Anopheles mosquitoes.

Author

Neafsey, Daniel E, Waterhouse, Robert M, Abai, Mohammad R, Aganezov, Sergey S, Alekseyev, Max A, Allen, James E, Amon, James, Arcà, Bruno, Arensburger, Peter, Artemov, Gleb, Assour, Lauren A, Basseri, Hamidreza, Berlin, Aaron, Birren, Bruce W, Blandin, Stephanie A, Brockman, Andrew I, Burkot, Thomas R, Burt, Austin, Chan, Clara S, Chauve, Cedric, Chiu, Joanna C, Christensen, Mikkel, Costantini, Carlo, Davidson, Victoria LM, Deligianni, Elena, Dottorini, Tania, Dritsou, Vicky, Gabriel, Stacey B, Guelbeogo, Wamdaogo M, Hall, Andrew B, Han, Mira V, Hlaing, Thaung, Hughes, Daniel ST, Jenkins, Adam M, Jiang, Xiaofang, Jungreis, Irwin, Kakani, Evdoxia G, Kamali, Maryam, Kemppainen, Petri, Kennedy, Ryan C, Kirmitzoglou, Ioannis K, Koekemoer, Lizette L, Laban, Njoroge, Langridge, Nicholas, Lawniczak, Mara KN, Lirakis, Manolis, Lobo, Neil F, Lowy, Ernesto, MacCallum, Robert M, Mao, Chunhong, Maslen, Gareth, Mbogo, Charles, McCarthy, Jenny, Michel, Kristin, Mitchell, Sara N, Moore, Wendy, Murphy, Katherine A, Naumenko, Anastasia N, Nolan, Tony, Novoa, Eva M, O'Loughlin, Samantha, Oringanje, Chioma, Oshaghi, Mohammad A, Pakpour, Nazzy, Papathanos, Philippos A, Peery, Ashley N, Povelones, Michael, Prakash, Anil, Price, David P, Rajaraman, Ashok, Reimer, Lisa J, Rinker, David C, Rokas, Antonis, Russell, Tanya L, Sagnon, N'Fale, Sharakhova, Maria V, Shea, Terrance, Simão, Felipe A, Simard, Frederic, Slotman, Michel A, Somboon, Pradya, Stegniy, Vladimir, Struchiner, Claudio J, Thomas, Gregg WC, Tojo, Marta, Topalis, Pantelis, Tubio, José MC, Unger, Maria F, Vontas, John, Walton, Catherine, Wilding, Craig S, Willis, Judith H, Wu, Yi-Chieh, Yan, Guiyun, Zdobnov, Evgeny M, Zhou, Xiaofan, Catteruccia, Flaminia, Christophides, George K, Collins, Frank H, and Cornman, Robert S

Subjects
Animals, Humans, Anopheles, Drosophila, Malaria, Sequence Alignment, Insect Vectors, Evolution, Molecular, Phylogeny, Base Sequence, Molecular Sequence Data, Genome, Insect, Chromosomes, Insect, Evolution, Molecular, Genome, Insect, Chromosomes, General Science & Technology
Abstract

Variation in vectorial capacity for human malaria among Anopheles mosquito species is determined by many factors, including behavior, immunity, and life history. To investigate the genomic basis of vectorial capacity and explore new avenues for vector control, we sequenced the genomes of 16 anopheline mosquito species from diverse locations spanning ~100 million years of evolution. Comparative analyses show faster rates of gene gain and loss, elevated gene shuffling on the X chromosome, and more intron losses, relative to Drosophila. Some determinants of vectorial capacity, such as chemosensory genes, do not show elevated turnover but instead diversify through protein-sequence changes. This dynamism of anopheline genes and genomes may contribute to their flexible capacity to take advantage of new ecological niches, including adapting to humans as primary hosts.

Published
2015

14. Comparative analysis of the domestic cat genome reveals genetic signatures underlying feline biology and domestication

Author

Montague, Michael J, Li, Gang, Gandolfi, Barbara, Khan, Razib, Aken, Bronwen L, Searle, Steven MJ, Minx, Patrick, Hillier, LaDeana W, Koboldt, Daniel C, Davis, Brian W, Driscoll, Carlos A, Barr, Christina S, Blackistone, Kevin, Quilez, Javier, Lorente-Galdos, Belen, Marques-Bonet, Tomas, Alkan, Can, Thomas, Gregg WC, Hahn, Matthew W, Menotti-Raymond, Marilyn, O'Brien, Stephen J, Wilson, Richard K, Lyons, Leslie A, Murphy, William J, and Warren, Wesley C

Subjects
Human Genome, Genetics, Biotechnology, Adaptation, Physiological, Amino Acid Sequence, Animals, Animals, Domestic, Animals, Wild, Carnivory, Cats, Chromosome Mapping, DNA Copy Number Variations, Dogs, Female, Gene Deletion, Gene Duplication, Genome, Genomics, Male, Membrane Transport Proteins, Molecular Sequence Data, Phylogeny, Selection, Genetic, Sequence Analysis, DNA, Sequence Homology, Amino Acid, Species Specificity, Felis catus, domestication, genome
Abstract

Little is known about the genetic changes that distinguish domestic cat populations from their wild progenitors. Here we describe a high-quality domestic cat reference genome assembly and comparative inferences made with other cat breeds, wildcats, and other mammals. Based upon these comparisons, we identified positively selected genes enriched for genes involved in lipid metabolism that underpin adaptations to a hypercarnivorous diet. We also found positive selection signals within genes underlying sensory processes, especially those affecting vision and hearing in the carnivore lineage. We observed an evolutionary tradeoff between functional olfactory and vomeronasal receptor gene repertoires in the cat and dog genomes, with an expansion of the feline chemosensory system for detecting pheromones at the expense of odorant detection. Genomic regions harboring signatures of natural selection that distinguish domestic cats from their wild congeners are enriched in neural crest-related genes associated with behavior and reward in mouse models, as predicted by the domestication syndrome hypothesis. Our description of a previously unidentified allele for the gloving pigmentation pattern found in the Birman breed supports the hypothesis that cat breeds experienced strong selection on specific mutations drawn from random bred populations. Collectively, these findings provide insight into how the process of domestication altered the ancestral wildcat genome and build a resource for future disease mapping and phylogenomic studies across all members of the Felidae.

Published
2014

16. Genomics and conservation: Guidance from training to analyses and applications

Author

Schiebelhut, Lauren M., primary, Guillaume, Annie S., additional, Kuhn, Arianna, additional, Schweizer, Rena M., additional, Armstrong, Ellie E., additional, Beaumont, Mark A., additional, Byrne, Margaret, additional, Cosart, Ted, additional, Hand, Brian K., additional, Howard, Leif, additional, Mussmann, Steven M., additional, Narum, Shawn R., additional, Rasteiro, Rita, additional, Rivera‐Colón, Angel G., additional, Saarman, Norah, additional, Sethuraman, Arun, additional, Taylor, Helen R., additional, Thomas, Gregg W. C., additional, Wellenreuther, Maren, additional, and Luikart, Gordon, additional

Published
2023
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19. Molecular evolution of male reproduction across species with highly divergent sperm morphology in diverse murine rodents

Author

Kopania, Emily E. K., primary, Thomas, Gregg W. C., additional, Hutter, Carl R., additional, Mortimer, Sebastian M. E., additional, Callahan, Colin M., additional, Roycroft, Emily, additional, Achmadi, Anang S., additional, Breed, William G., additional, Clark, Nathan L., additional, Esselstyn, Jacob A., additional, Rowe, Kevin C., additional, and Good, Jeffrey M., additional

Published
2023
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21. Clonal polymorphism and high heterozygosity in the celibate genome of the Amazon molly

Author

Warren, Wesley C., García-Pérez, Raquel, Xu, Sen, Lampert, Kathrin P., Chalopin, Domitille, Stöck, Matthias, Loewe, Laurence, Lu, Yuan, Kuderna, Lukas, Minx, Patrick, Montague, Michael J., Tomlinson, Chad, Hillier, LaDeana W., Murphy, Daniel N., Wang, John, Wang, Zhongwei, Garcia, Constantino Macias, Thomas, Gregg C. W., Volff, Jean-Nicolas, Farias, Fabiana, Aken, Bronwen, Walter, Ronald B., Pruitt, Kim D., Marques-Bonet, Tomas, Hahn, Matthew W., Kneitz, Susanne, Lynch, Michael, and Schartl, Manfred

Published
2018
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23. A Fast, Reproducible, High-throughput Variant Calling Workflow for Population Genomics.

Author

Mirchandani, Cade D, Shultz, Allison J, Thomas, Gregg W C, Smith, Sara J, Baylis, Mara, Arnold, Brian, Corbett-Detig, Russ, Enbody, Erik, and Sackton, Timothy B

Subjects
GENETIC variation, GENOMICS, WORKFLOW, COMPUTER workstation clusters, QUALITY control, GENOMES
Abstract

The increasing availability of genomic resequencing data sets and high-quality reference genomes across the tree of life present exciting opportunities for comparative population genomic studies. However, substantial challenges prevent the simple reuse of data across different studies and species, arising from variability in variant calling pipelines, data quality, and the need for computationally intensive reanalysis. Here, we present snpArcher, a flexible and highly efficient workflow designed for the analysis of genomic resequencing data in nonmodel organisms. snpArcher provides a standardized variant calling pipeline and includes modules for variant quality control, data visualization, variant filtering, and other downstream analyses. Implemented in Snakemake, snpArcher is user-friendly, reproducible, and designed to be compatible with high-performance computing clusters and cloud environments. To demonstrate the flexibility of this pipeline, we applied snpArcher to 26 public resequencing data sets from nonmammalian vertebrates. These variant data sets are hosted publicly to enable future comparative population genomic analyses. With its extensibility and the availability of public data sets, snpArcher will contribute to a broader understanding of genetic variation across species by facilitating the rapid use and reuse of large genomic data sets. [ABSTRACT FROM AUTHOR]

Published
2024
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24. Sooty mangabey genome sequence provides insight into AIDS resistance in a natural SIV host

Author

Palesch, David, Bosinger, Steven E., Tharp, Gregory K., Vanderford, Thomas H., Paiardini, Mirko, Chahroudi, Ann, Johnson, Zachary P., Kirchhoff, Frank, Hahn, Beatrice H., Norgren, Robert B., Patel, Nirav B., Sodora, Donald L., Dawoud, Reem A., Stewart, Caro-Beth, Seepo, Sara M., Harris, R. Alan, Liu, Yue, Raveendran, Muthuswamy, Han, Yi, English, Adam, Thomas, Gregg W. C., Hahn, Matthew W., Pipes, Lenore, Mason, Christopher E., Muzny, Donna M., Gibbs, Richard A., Sauter, Daniel, Worley, Kim, Rogers, Jeffrey, and Silvestri, Guido

Subjects
Immunity (Physiology) -- Genetic aspects, Sooty mangabey -- Genetic aspects -- Health aspects, Simian immunodeficiency virus -- Health aspects -- Genetic aspects, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Author(s): David Palesch [1]; Steven E. Bosinger [1, 2]; Gregory K. Tharp [1]; Thomas H. Vanderford [1]; Mirko Paiardini [1, 2]; Ann Chahroudi [1, 3]; Zachary P. Johnson [1]; Frank [...]

Published
2018
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28. Molecular Biology and Evolution

Author

Sun, Cheng, Huang, Jiaxing, Wang, Yun, Zhao, Xiaomeng, Su, Long, Thomas, Gregg W C, Zhao, Mengya, Zhang, Xingtan, Jungreis, Irwin, Kellis, Manolis, Vicario, Saverio, Sharakhov, Igor V, Bondarenko, Semen M, Hasselmann, Martin, Kim, Chang N, Paten, Benedict, Penso-Dolfin, Luca, Wang, Li, Chang, Yuxiao, Gao, Qiang, Ma, Ling, Ma, Lina, Zhang, Zhang, Zhang, Hongbo, Zhang, Huahao, Ruzzante, Livio, Robertson, Hugh M, Zhu, Yihui, Liu, Yanjie, Yang, Huipeng, Ding, Lele, Wang, Quangui, Ma, Dongna, Xu, Weilin, Liang, Cheng, Itgen, Michael W, Mee, Lauren, Cao, Gang, Zhang, Ze, Sadd, Ben M, Hahn, Matthew W, Schaack, Sarah, Barribeau, Seth M, Williams, Paul H, Waterhouse, Robert M, Mueller, Rachel Lockridge, and Entomology

Subjects
gene family evolution, Biochemistry & Molecular Biology, Adaptation, Biological/genetics, Animals, Bees/genetics, Biological Evolution, Codon Usage, DNA Transposable Elements, Diet, Feeding Behavior, Gene Components, Genome Size, Genome, Insect, Selection, Genetic, Bombus, genome assembly, genome evolution, insect diversity, Adaptation, Biological, 0601 Biochemistry and Cell Biology, AcademicSubjects/SCI01180, 0603 Evolutionary Biology, Discoveries, Genetics & Heredity, Evolutionary Biology, 0604 Genetics, Errata, AcademicSubjects/SCI01130, Bees, Life Sciences & Biomedicine
Abstract

Bumblebees are a diverse group of globally important pollinators in natural ecosystems and for agricultural food production. With both eusocial and solitary life-cycle phases, and some social parasite species, they are especially interesting models to understand social evolution, behavior, and ecology. Reports of many species in decline point to pathogen transmission, habitat loss, pesticide usage, and global climate change, as interconnected causes. These threats to bumblebee diversity make our reliance on a handful of well-studied species for agricultural pollination particularly precarious. To broadly sample bumblebee genomic and phenotypic diversity, we de novo sequenced and assembled the genomes of 17 species, representing all 15 subgenera, producing the first genus-wide quantification of genetic and genomic variation potentially underlying key ecological and behavioral traits. The species phylogeny resolves subgenera relationships, whereas incomplete lineage sorting likely drives high levels of gene tree discordance. Five chromosome-level assemblies show a stable 18-chromosome karyotype, with major rearrangements creating 25 chromosomes in social parasites. Differential transposable element activity drives changes in genome sizes, with putative domestications of repetitive sequences influencing gene coding and regulatory potential. Dynamically evolving gene families and signatures of positive selection point to genus-wide variation in processes linked to foraging, diet and metabolism, immunity and detoxification, as well as adaptations for life at high altitudes. Our study reveals how bumblebee genes and genomes have evolved across the Bombus phylogeny and identifies variations potentially linked to key ecological and behavioral traits of these important pollinators. Published version

Published
2020

29. Gibbon genome and the fast karyotype evolution of small apes

Author

Carbone, Lucia, Alan Harris, R., Gnerre, Sante, Veeramah, Krishna R., Lorente-Galdos, Belen, Huddleston, John, Meyer, Thomas J., Herrero, Javier, Roos, Christian, Aken, Bronwen, Anaclerio, Fabio, Archidiacono, Nicoletta, Baker, Carl, Barrell, Daniel, Batzer, Mark A., Beal, Kathryn, Blancher, Antoine, Bohrson, Craig L., Brameier, Markus, Campbell, Michael S., Capozzi, Oronzo, Casola, Claudio, Chiatante, Giorgia, Cree, Andrew, Damert, Annette, de Jong, Pieter J., Dumas, Laura, Fernandez-Callejo, Marcos, Flicek, Paul, Fuchs, Nina V., Gut, Ivo, Gut, Marta, Hahn, Matthew W., Hernandez-Rodriguez, Jessica, Hillier, LaDeana W., Hubley, Robert, Ianc, Bianca, Izsvák, Zsuzsanna, Jablonski, Nina G., Johnstone, Laurel M., Karimpour-Fard, Anis, Konkel, Miriam K., Kostka, Dennis, Lazar, Nathan H., Lee, Sandra L., Lewis, Lora R., Liu, Yue, Locke, Devin P., Mallick, Swapan, Mendez, Fernando L., Muffato, Matthieu, Nazareth, Lynne V., Nevonen, Kimberly A., O’Bleness, Majesta, Ochis, Cornelia, Odom, Duncan T., Pollard, Katherine S., Quilez, Javier, Reich, David, Rocchi, Mariano, Schumann, Gerald G., Searle, Stephen, Sikela, James M., Skollar, Gabriella, Smit, Arian, Sonmez, Kemal, Hallers, Boudewijn ten, Terhune, Elizabeth, Thomas, Gregg W. C., Ullmer, Brygg, Ventura, Mario, Walker, Jerilyn A., Wall, Jeffrey D., Walter, Lutz, Ward, Michelle C., Wheelan, Sarah J., Whelan, Christopher W., White, Simon, Wilhelm, Larry J., Woerner, August E., Yandell, Mark, Zhu, Baoli, Hammer, Michael F., Marques-Bonet, Tomas, Eichler, Evan E., Fulton, Lucinda, Fronick, Catrina, Muzny, Donna M., Warren, Wesley C., Worley, Kim C., Rogers, Jeffrey, Wilson, Richard K., and Gibbs, Richard A.

Published
2014
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34. Erratum to: Genus-wide characterization of bumblebee genomes provides insights into their evolution and variation in ecological and behavioral traits

Author

Sun, Cheng, primary, Huang, Jiaxing, additional, Wang, Yun, additional, Zhao, Xiaomeng, additional, Su, Long, additional, Thomas, Gregg W C, additional, Zhao, Mengya, additional, Zhang, Xingtan, additional, Jungreis, Irwin, additional, Kellis, Manolis, additional, Vicario, Saverio, additional, Sharakhov, Igor V, additional, Bondarenko, Semen M, additional, Hasselmann, Martin, additional, Kim, Chang N, additional, Paten, Benedict, additional, Penso-Dolfin, Luca, additional, Wang, Li, additional, Chang, Yuxiao, additional, Gao, Qiang, additional, Ma, Ling, additional, Ma, Lina, additional, Zhang, Zhang, additional, Zhang, Hongbo, additional, Zhang, Huahao, additional, Ruzzante, Livio, additional, Robertson, Hugh M, additional, Zhu, Yihui, additional, Liu, Yanjie, additional, Yang, Huipeng, additional, Ding, Lele, additional, Wang, Quangui, additional, Ma, Dongna, additional, Xu, Weilin, additional, Liang, Cheng, additional, Itgen, Michael W, additional, Mee, Lauren, additional, Cao, Gang, additional, Zhang, Ze, additional, Sadd, Ben M, additional, Hahn, Matthew W, additional, Schaack, Sarah, additional, Barribeau, Seth M, additional, Williams, Paul H, additional, Waterhouse, Robert M, additional, and Mueller, Rachel Lockridge, additional

Published
2021
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36. Genus-Wide Characterization of Bumblebee Genomes Provides Insights into Their Evolution and Variation in Ecological and Behavioral Traits

Author

Sun, Cheng, Huang, Jiaxing, Wang, Yun, Zhao, Xiaomeng, Su, Long, Thomas, Gregg W. C., Zhao, Mengya, Zhang, Xingtan, Jungreis, Irwin, Kellis, Manolis, Vicario, Saverio, Sharakhov, Igor V., Bondarenko, Semen M., Hasselmann, Martin, Kim, Chang N., Paten, Benedict, Penso-Dolfin, Luca, Wang, Li, Chang, Yuxiao, Gao, Qiang, Ma, Ling, Ma, Lina, Zhang, Zhang, Zhang, Hongbo, Zhang, Huahao, Ruzzante, Livio, Robertson, Hugh M., Zhu, Yihui, Liu, Yanjie, Yang, Huipeng, Ding, Lele, Wang, Quangui, Ma, Dongna, Xu, Weilin, Liang, Cheng, Itgen, Michael W., Mee, Lauren, Cao, Gang, Zhang, Ze, Sadd, Ben M., Hahn, Matthew W., Schaack, Sarah, Barribeau, Seth M., Williams, Paul H., Waterhouse, Robert M., Mueller, Rachel Lockridge, Sun, Cheng, Huang, Jiaxing, Wang, Yun, Zhao, Xiaomeng, Su, Long, Thomas, Gregg W. C., Zhao, Mengya, Zhang, Xingtan, Jungreis, Irwin, Kellis, Manolis, Vicario, Saverio, Sharakhov, Igor V., Bondarenko, Semen M., Hasselmann, Martin, Kim, Chang N., Paten, Benedict, Penso-Dolfin, Luca, Wang, Li, Chang, Yuxiao, Gao, Qiang, Ma, Ling, Ma, Lina, Zhang, Zhang, Zhang, Hongbo, Zhang, Huahao, Ruzzante, Livio, Robertson, Hugh M., Zhu, Yihui, Liu, Yanjie, Yang, Huipeng, Ding, Lele, Wang, Quangui, Ma, Dongna, Xu, Weilin, Liang, Cheng, Itgen, Michael W., Mee, Lauren, Cao, Gang, Zhang, Ze, Sadd, Ben M., Hahn, Matthew W., Schaack, Sarah, Barribeau, Seth M., Williams, Paul H., Waterhouse, Robert M., and Mueller, Rachel Lockridge

Abstract

Bumblebees are a diverse group of globally important pollinators in natural ecosystems and for agricultural food production. With both eusocial and solitary life-cycle phases, and some social parasite species, they are especially interesting models to understand social evolution, behavior, and ecology. Reports of many species in decline point to pathogen transmission, habitat loss, pesticide usage, and global climate change, as interconnected causes. These threats to bumblebee diversity make our reliance on a handful of well-studied species for agricultural pollination particularly precarious. To broadly sample bumblebee genomic and phenotypic diversity, we de novo sequenced and assembled the genomes of 17 species, representing all 15 subgenera, producing the first genus-wide quantification of genetic and genomic variation potentially underlying key ecological and behavioral traits. The species phylogeny resolves subgenera relationships, whereas incomplete lineage sorting likely drives high levels of gene tree discordance. Five chromosome-level assemblies show a stable 18-chromosome karyotype, with major rearrangements creating 25 chromosomes in social parasites. Differential transposable element activity drives changes in genome sizes, with putative domestications of repetitive sequences influencing gene coding and regulatory potential. Dynamically evolving gene families and signatures of positive selection point to genus-wide variation in processes linked to foraging, diet and metabolism, immunity and detoxification, as well as adaptations for life at high altitudes. Our study reveals how bumblebee genes and genomes have evolved across the Bombus phylogeny and identifies variations potentially linked to key ecological and behavioral traits of these important pollinators.

Published
2021
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37. Genus-Wide Characterization of Bumblebee Genomes Provides Insights into Their Evolution and Variation in Ecological and Behavioral Traits

Author

Entomology, Sun, Cheng, Huang, Jiaxing, Wang, Yun, Zhao, Xiaomeng, Su, Long, Thomas, Gregg W. C., Zhao, Mengya, Zhang, Xingtan, Jungreis, Irwin, Kellis, Manolis, Vicario, Saverio, Sharakhov, Igor V., Bondarenko, Semen M., Hasselmann, Martin, Kim, Chang N., Paten, Benedict, Penso-Dolfin, Luca, Wang, Li, Chang, Yuxiao, Gao, Qiang, Ma, Ling, Ma, Lina, Zhang, Zhang, Zhang, Hongbo, Zhang, Huahao, Ruzzante, Livio, Robertson, Hugh M., Zhu, Yihui, Liu, Yanjie, Yang, Huipeng, Ding, Lele, Wang, Quangui, Ma, Dongna, Xu, Weilin, Liang, Cheng, Itgen, Michael W., Mee, Lauren, Cao, Gang, Zhang, Ze, Sadd, Ben M., Hahn, Matthew W., Schaack, Sarah, Barribeau, Seth M., Williams, Paul H., Waterhouse, Robert M., Mueller, Rachel Lockridge, Entomology, Sun, Cheng, Huang, Jiaxing, Wang, Yun, Zhao, Xiaomeng, Su, Long, Thomas, Gregg W. C., Zhao, Mengya, Zhang, Xingtan, Jungreis, Irwin, Kellis, Manolis, Vicario, Saverio, Sharakhov, Igor V., Bondarenko, Semen M., Hasselmann, Martin, Kim, Chang N., Paten, Benedict, Penso-Dolfin, Luca, Wang, Li, Chang, Yuxiao, Gao, Qiang, Ma, Ling, Ma, Lina, Zhang, Zhang, Zhang, Hongbo, Zhang, Huahao, Ruzzante, Livio, Robertson, Hugh M., Zhu, Yihui, Liu, Yanjie, Yang, Huipeng, Ding, Lele, Wang, Quangui, Ma, Dongna, Xu, Weilin, Liang, Cheng, Itgen, Michael W., Mee, Lauren, Cao, Gang, Zhang, Ze, Sadd, Ben M., Hahn, Matthew W., Schaack, Sarah, Barribeau, Seth M., Williams, Paul H., Waterhouse, Robert M., and Mueller, Rachel Lockridge

Abstract

Bumblebees are a diverse group of globally important pollinators in natural ecosystems and for agricultural food production. With both eusocial and solitary life-cycle phases, and some social parasite species, they are especially interesting models to understand social evolution, behavior, and ecology. Reports of many species in decline point to pathogen transmission, habitat loss, pesticide usage, and global climate change, as interconnected causes. These threats to bumblebee diversity make our reliance on a handful of well-studied species for agricultural pollination particularly precarious. To broadly sample bumblebee genomic and phenotypic diversity, we de novo sequenced and assembled the genomes of 17 species, representing all 15 subgenera, producing the first genus-wide quantification of genetic and genomic variation potentially underlying key ecological and behavioral traits. The species phylogeny resolves subgenera relationships, whereas incomplete lineage sorting likely drives high levels of gene tree discordance. Five chromosome-level assemblies show a stable 18-chromosome karyotype, with major rearrangements creating 25 chromosomes in social parasites. Differential transposable element activity drives changes in genome sizes, with putative domestications of repetitive sequences influencing gene coding and regulatory potential. Dynamically evolving gene families and signatures of positive selection point to genus-wide variation in processes linked to foraging, diet and metabolism, immunity and detoxification, as well as adaptations for life at high altitudes. Our study reveals how bumblebee genes and genomes have evolved across the Bombus phylogeny and identifies variations potentially linked to key ecological and behavioral traits of these important pollinators.

Published
2021

38. Genus-wide characterization of bumblebee genomes provides insights into their evolution and variation in ecological and behavioral traits

Author

Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Sun, Cheng, Huang, Jiaxing, Wang, Yun, Zhao, Xiaomeng, Su, Long, Thomas, Gregg W C, Zhao, Mengya, Zhang, Xingtan, Jungreis, Irwin, Kellis, Manolis, Vicario, Saverio, Sharakhov, Igor V, Bondarenko, Semen M, Hasselmann, Martin, Kim, Chang N, Paten, Benedict, Penso-Dolfin, Luca, Wang, Li, Chang, Yuxiao, Gao, Qiang, Ma, Ling, Ma, Lina, Zhang, Zhang, Zhang, Hongbo, Zhang, Huahao, Ruzzante, Livio, Robertson, Hugh M, Zhu, Yihui, Liu, Yanjie, Yang, Huipeng, Ding, Lele, Wang, Quangui, Ma, Dongna, Xu, Weilin, Liang, Cheng, Itgen, Michael W, Mee, Lauren, Cao, Gang, Zhang, Ze, Sadd, Ben M, Hahn, Matthew, Schaack, Sarah, Barribeau, Seth M, Williams, Paul H, Waterhouse, Robert M, Mueller, Rachel Lockridge, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Sun, Cheng, Huang, Jiaxing, Wang, Yun, Zhao, Xiaomeng, Su, Long, Thomas, Gregg W C, Zhao, Mengya, Zhang, Xingtan, Jungreis, Irwin, Kellis, Manolis, Vicario, Saverio, Sharakhov, Igor V, Bondarenko, Semen M, Hasselmann, Martin, Kim, Chang N, Paten, Benedict, Penso-Dolfin, Luca, Wang, Li, Chang, Yuxiao, Gao, Qiang, Ma, Ling, Ma, Lina, Zhang, Zhang, Zhang, Hongbo, Zhang, Huahao, Ruzzante, Livio, Robertson, Hugh M, Zhu, Yihui, Liu, Yanjie, Yang, Huipeng, Ding, Lele, Wang, Quangui, Ma, Dongna, Xu, Weilin, Liang, Cheng, Itgen, Michael W, Mee, Lauren, Cao, Gang, Zhang, Ze, Sadd, Ben M, Hahn, Matthew, Schaack, Sarah, Barribeau, Seth M, Williams, Paul H, Waterhouse, Robert M, and Mueller, Rachel Lockridge

Abstract

Bumblebees are a diverse group of globally important pollinators in natural ecosystems and for agricultural food production. With both eusocial and solitary life-cycle phases, and some social parasite species, they are especially interesting models to understand social evolution, behavior, and ecology. Reports of many species in decline point to pathogen transmission, habitat loss, pesticide usage, and global climate change, as interconnected causes. These threats to bumblebee diversity make our reliance on a handful of well-studied species for agricultural pollination particularly precarious. To broadly sample bumblebee genomic and phenotypic diversity, we de novo sequenced and assembled the genomes of 17 species, representing all 15 subgenera, producing the first genus-wide quantification of genetic and genomic variation potentially underlying key ecological and behavioral traits. The species phylogeny resolves subgenera relationships while incomplete lineage sorting likely drives high levels of gene tree discordance. Five chromosome-level assemblies show a stable 18-chromosome karyotype, with major rearrangements creating 25 chromosomes in social parasites. Differential transposable element activity drives changes in genome sizes, with putative domestications of repetitive sequences influencing gene coding and regulatory potential. Dynamically evolving gene families and signatures of positive selection point to genus-wide variation in processes linked to foraging, diet and metabolism, immunity and detoxification, as well as adaptations for life at high altitudes. Our study reveals how bumblebee genes and genomes have evolved across the Bombus phylogeny and identifies variations potentially linked to key ecological and behavioral traits of these important pollinators., National Human Genome Research Institute (Grant U41HG007234), National Institutes of Health (Grant R01HG004037), Novartis Foundation (Grant 18B116), National Science Foundation (Grant DBI-1564611)

Published
2021

41. Evolution of Widespread Recombination Suppression on the Dwarf Hamster (Phodopus) X Chromosome.

Author

Moore, Emily C., Thomas, Gregg W. C., Mortimer, Sebastian, Kopania, Emily E. K., Hunnicutt, Kelsie E., Clare-Salzler, Zachary J., Larson, Erica L., and Good, Jeffrey M.

Subjects
*SEX chromosomes, *CHROMOSOME structure, *X chromosome, *MOLECULAR evolution, *HAMSTERS, *GENE mapping
Abstract

The X chromosome of therian mammals shows strong conservation among distantly related species, limiting insights into the distinct selective processes that have shaped sex chromosome evolution. We constructed a chromosome-scale de novo genome assembly for the Siberian dwarf hamster (Phodopus sungorus), a species reported to show extensive recombination suppression across an entire arm of the X chromosome. Combining a physical genome assembly based on shotgun and long-range proximity ligation sequencing with a dense genetic map, we detected widespread suppression of female recombination across ∼65% of the Phodopus X chromosome. This region of suppressed recombination likely corresponds to the Xp arm, which has previously been shown to be highly heterochromatic. Using additional sequencing data from two closely related species (P. campbelli and P. roborovskii), we show that recombination suppression on Xp appears to be independent of major structural rearrangements. The suppressed Xp arm was enriched for several transposable element families and de-enriched for genes primarily expressed in placenta, but otherwise showed similar gene densities, expression patterns, and rates of molecular evolution when compared to the recombinant Xq arm. Phodopus Xp gene content and order was also broadly conserved relative to the more distantly related rat X chromosome. These data suggest that widespread suppression of recombination has likely evolved through the transient induction of facultative heterochromatin on the Phodopus Xp arm without major changes in chromosome structure or genetic content. Thus, substantial changes in the recombination landscape have so far had relatively subtle influences on patterns of X-linked molecular evolution in these species. [ABSTRACT FROM AUTHOR]

Published
2022
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43. Genus-Wide Characterization of Bumblebee Genomes Provides Insights into Their Evolution and Variation in Ecological and Behavioral Traits

Author

Sun, Cheng, primary, Huang, Jiaxing, additional, Wang, Yun, additional, Zhao, Xiaomeng, additional, Su, Long, additional, Thomas, Gregg W C, additional, Zhao, Mengya, additional, Zhang, Xingtan, additional, Jungreis, Irwin, additional, Kellis, Manolis, additional, Vicario, Saverio, additional, Sharakhov, Igor V, additional, Bondarenko, Semen M, additional, Hasselmann, Martin, additional, Kim, Chang N, additional, Paten, Benedict, additional, Penso-Dolfin, Luca, additional, Wang, Li, additional, Chang, Yuxiao, additional, Gao, Qiang, additional, Ma, Ling, additional, Ma, Lina, additional, Zhang, Zhang, additional, Zhang, Hongbo, additional, Zhang, Huahao, additional, Ruzzante, Livio, additional, Robertson, Hugh M, additional, Zhu, Yihui, additional, Liu, Yanjie, additional, Yang, Huipeng, additional, Ding, Lele, additional, Wang, Quangui, additional, Ma, Dongna, additional, Xu, Weilin, additional, Liang, Cheng, additional, Itgen, Michael W, additional, Mee, Lauren, additional, Cao, Gang, additional, Zhang, Ze, additional, Sadd, Ben M, additional, Hahn, Matthew W, additional, Schaack, Sarah, additional, Barribeau, Seth M, additional, Williams, Paul H, additional, Waterhouse, Robert M, additional, and Mueller, Rachel Lockridge, additional

Published
2020
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44. Genus-wide characterization of bumblebee genomes reveals variation associated with key ecological and behavioral traits of pollinators

Author

Sun, Cheng, primary, Huang, Jiaxing, additional, Wang, Yun, additional, Zhao, Xiaomeng, additional, Su, Long, additional, Thomas, Gregg W.C., additional, Zhao, Mengya, additional, Zhang, Xingtan, additional, Jungreis, Irwin, additional, Kellis, Manolis, additional, Vicario, Saverio, additional, Sharakhov, Igor V., additional, Bondarenko, Semen M., additional, Hasselmann, Martin, additional, Kim, Chang N, additional, Paten, Benedict, additional, Penso-Dolfin, Luca, additional, Wang, Li, additional, Chang, Yuxiao, additional, Gao, Qiang, additional, Ma, Ling, additional, Ma, Lina, additional, Zhang, Zhang, additional, Zhang, Hongbo, additional, Zhang, Huahao, additional, Ruzzante, Livio, additional, Robertson, Hugh M., additional, Zhu, Yihui, additional, Liu, Yanjie, additional, Yang, Huipeng, additional, Ding, Lele, additional, Wang, Quangui, additional, Xu, Weilin, additional, Liang, Cheng, additional, Itgen, Michael W., additional, Mee, Lauren, additional, Sadd, Ben M., additional, Cao, Gang, additional, Zhang, Ze, additional, Hahn, Matthew, additional, Schaack, Sarah, additional, Barribeau, Seth M., additional, Williams, Paul H., additional, Waterhouse, Robert M., additional, and Mueller, Rachel Lockridge, additional

Published
2020
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45. Paternal age in rhesus macaques is positively associated with germline mutation accumulation but not with measures of offspring sociability

Author

Wang, Richard J., primary, Thomas, Gregg W.C., additional, Raveendran, Muthuswamy, additional, Harris, R. Alan, additional, Doddapaneni, Harshavardhan, additional, Muzny, Donna M., additional, Capitanio, John P., additional, Radivojac, Predrag, additional, Rogers, Jeffrey, additional, and Hahn, Matthew W., additional

Published
2020
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46. Additional file 3. of Gene content evolution in the arthropods

Author

Thomas, Gregg, Dohmen, Elias, Hughes, Daniel, Shwetha Murali, Poelchau, Monica, Glastad, Karl, Anstead, Clare, Ayoub, Nadia, Batterham, Phillip, Bellair, Michelle, Binford, Greta, Hsu Chao, Chen, Yolanda, Childers, Christopher, Dinh, Huyen, Harsha Doddapaneni, Duan, Jian, Dugan, Shannon, Esposito, Lauren, Friedrich, Markus, Garb, Jessica, Gasser, Robin, Goodisman, Michael, Gundersen-Rindal, Dawn, Han, Yi, Handler, Alfred, Masatsugu Hatakeyama, Hering, Lars, Hunter, Wayne, Ioannidis, Panagiotis, Jayaseelan, Joy, Kalra, Divya, Abderrahman Khila, Korhonen, Pasi, Lee, Carol, Lee, Sandra, Yiyuan Li, Lindsey, Amelia, Mayer, Georg, McGregor, Alistair, McKenna, Duane, Misof, Bernhard, Munidasa, Mala, Munoz-Torres, Monica, Muzny, Donna, Niehuis, Oliver, Nkechinyere Osuji-Lacy, Subba Palli, Panfilio, Kristen, Pechmann, Matthias, Perry, Trent, Peters, Ralph, Poynton, Helen, Nikola-Michael Prpic, Jiaxin Qu, Rotenberg, Dorith, Schal, Coby, Schoville, Sean, Scully, Erin, Skinner, Evette, Sloan, Daniel, Stouthamer, Richard, Strand, Michael, Szucsich, Nikolaus, Asela Wijeratne, Young, Neil, Zattara, Eduardo, Benoit, Joshua, Zdobnov, Evgeny, Pfrender, Michael, Hackett, Kevin, Werren, John, Worley, Kim, Gibbs, Richard, Chipman, Ariel, Waterhouse, Robert, Bornberg-Bauer, Erich, Hahn, Matthew, and Richards, Stephen

Abstract

Review history.

Published
2020
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47. Additional file 2. of Gene content evolution in the arthropods

Author

Thomas, Gregg, Dohmen, Elias, Hughes, Daniel, Shwetha Murali, Poelchau, Monica, Glastad, Karl, Anstead, Clare, Ayoub, Nadia, Batterham, Phillip, Bellair, Michelle, Binford, Greta, Hsu Chao, Chen, Yolanda, Childers, Christopher, Dinh, Huyen, Harsha Doddapaneni, Duan, Jian, Dugan, Shannon, Esposito, Lauren, Friedrich, Markus, Garb, Jessica, Gasser, Robin, Goodisman, Michael, Gundersen-Rindal, Dawn, Han, Yi, Handler, Alfred, Masatsugu Hatakeyama, Hering, Lars, Hunter, Wayne, Ioannidis, Panagiotis, Jayaseelan, Joy, Kalra, Divya, Abderrahman Khila, Korhonen, Pasi, Lee, Carol, Lee, Sandra, Yiyuan Li, Lindsey, Amelia, Mayer, Georg, McGregor, Alistair, McKenna, Duane, Misof, Bernhard, Munidasa, Mala, Munoz-Torres, Monica, Muzny, Donna, Niehuis, Oliver, Nkechinyere Osuji-Lacy, Subba Palli, Panfilio, Kristen, Pechmann, Matthias, Perry, Trent, Peters, Ralph, Poynton, Helen, Nikola-Michael Prpic, Jiaxin Qu, Rotenberg, Dorith, Schal, Coby, Schoville, Sean, Scully, Erin, Skinner, Evette, Sloan, Daniel, Stouthamer, Richard, Strand, Michael, Szucsich, Nikolaus, Asela Wijeratne, Young, Neil, Zattara, Eduardo, Benoit, Joshua, Zdobnov, Evgeny, Pfrender, Michael, Hackett, Kevin, Werren, John, Worley, Kim, Gibbs, Richard, Chipman, Ariel, Waterhouse, Robert, Bornberg-Bauer, Erich, Hahn, Matthew, and Richards, Stephen

Abstract

Supplementary Text and Supplementary Figures: Figures S1 – S34.

Published
2020
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48. Gene content evolution in the arthropods

Author

Thomas, Gregg W. C., Dohmen, Elias, Hughes, Daniel S. T., Murali, Shwetha C., Poelchau, Monica, Glastad, Karl, Anstead, Clare A., Ayoub, Nadia A., Batterham, Phillip, Bellair, Michelle, Binford, Greta J., Chao, Hsu, Chen, Yolanda H., Childers, Christopher, Dinh, Huyen, Doddapaneni, Harsha Vardhan, Duan, Jian J., Dugan, Shannon, Esposito, Lauren A., Friedrich, Markus, Garb, Jessica, Gasser, Robin B., Goodisman, Michael A. D., Gundersen-Rindal, Dawn E., Han, Yi, Handler, Alfred M., Hatakeyama, Masatsugu, Hering, Lars, Hunter, Wayne B., Ioannidis, Panagiotis, Jayaseelan, Joy C., Kalra, Divya, Khila, Abderrahman, Korhonen, Pasi K., Lee, Carol Eunmi, Lee, Sandra L., Li, Yiyuan, Lindsey, Amelia R. I., Mayer, Georg, McGregor, Alistair P., McKenna, Duane D., Misof, Bernhard, Munidasa, Mala, Munoz-Torres, Monica, Muzny, Donna M., Niehuis, Oliver, Osuji-Lacy, Nkechinyere, Palli, Subba R., Panfilio, Kristen A., Pechmann, Matthias, Perry, Trent, Peters, Ralph S., Poynton, Helen C., Prpic, Nikola-Michael, Qu, Jiaxin, Rotenberg, Dorith, Schal, Coby, Schoville, Sean D., Scully, Erin D., Skinner, Evette, Sloan, Daniel B., Stouthamer, Richard, Strand, Michael R., Szucsich, Nikolaus U., Wijeratne, Asela, Young, Neil D., Zattara, Eduardo E., Benoit, Joshua B., Zdobnov, Evgeny M., Pfrender, Michael E., Hackett, Kevin J., Werren, John H., Worley, Kim C., Gibbs, Richard A., Chipman, Ariel D., Waterhouse, Robert M., Bornberg-Bauer, Erich, Hahn, Matthew W., Richards, Stephen, Thomas, Gregg W. C., Dohmen, Elias, Hughes, Daniel S. T., Murali, Shwetha C., Poelchau, Monica, Glastad, Karl, Anstead, Clare A., Ayoub, Nadia A., Batterham, Phillip, Bellair, Michelle, Binford, Greta J., Chao, Hsu, Chen, Yolanda H., Childers, Christopher, Dinh, Huyen, Doddapaneni, Harsha Vardhan, Duan, Jian J., Dugan, Shannon, Esposito, Lauren A., Friedrich, Markus, Garb, Jessica, Gasser, Robin B., Goodisman, Michael A. D., Gundersen-Rindal, Dawn E., Han, Yi, Handler, Alfred M., Hatakeyama, Masatsugu, Hering, Lars, Hunter, Wayne B., Ioannidis, Panagiotis, Jayaseelan, Joy C., Kalra, Divya, Khila, Abderrahman, Korhonen, Pasi K., Lee, Carol Eunmi, Lee, Sandra L., Li, Yiyuan, Lindsey, Amelia R. I., Mayer, Georg, McGregor, Alistair P., McKenna, Duane D., Misof, Bernhard, Munidasa, Mala, Munoz-Torres, Monica, Muzny, Donna M., Niehuis, Oliver, Osuji-Lacy, Nkechinyere, Palli, Subba R., Panfilio, Kristen A., Pechmann, Matthias, Perry, Trent, Peters, Ralph S., Poynton, Helen C., Prpic, Nikola-Michael, Qu, Jiaxin, Rotenberg, Dorith, Schal, Coby, Schoville, Sean D., Scully, Erin D., Skinner, Evette, Sloan, Daniel B., Stouthamer, Richard, Strand, Michael R., Szucsich, Nikolaus U., Wijeratne, Asela, Young, Neil D., Zattara, Eduardo E., Benoit, Joshua B., Zdobnov, Evgeny M., Pfrender, Michael E., Hackett, Kevin J., Werren, John H., Worley, Kim C., Gibbs, Richard A., Chipman, Ariel D., Waterhouse, Robert M., Bornberg-Bauer, Erich, Hahn, Matthew W., and Richards, Stephen

Abstract

Background Arthropods comprise the largest and most diverse phylum on Earth and play vital roles in nearly every ecosystem. Their diversity stems in part from variations on a conserved body plan, resulting from and recorded in adaptive changes in the genome. Dissection of the genomic record of sequence change enables broad questions regarding genome evolution to be addressed, even across hyper-diverse taxa within arthropods. Results Using 76 whole genome sequences representing 21 orders spanning more than 500 million years of arthropod evolution, we document changes in gene and protein domain content and provide temporal and phylogenetic context for interpreting these innovations. We identify many novel gene families that arose early in the evolution of arthropods and during the diversification of insects into modern orders. We reveal unexpected variation in patterns of DNA methylation across arthropods and examples of gene family and protein domain evolution coincident with the appearance of notable phenotypic and physiological adaptations such as flight, metamorphosis, sociality, and chemoperception. Conclusions These analyses demonstrate how large-scale comparative genomics can provide broad new insights into the genotype to phenotype map and generate testable hypotheses about the evolution of animal diversity.

Published
2020

49. Reproductive Longevity Predicts Mutation Rates in Primates

Author

Thomas, Gregg W.C., Wang, Richard J., Puri, Arthi, Harris, R. Alan, Raveendran, Muthuswamy, Hughes, Daniel S.T., Murali, Shwetha C., Williams, Lawrence E., Doddapaneni, Harsha, Muzny, Donna M., Gibbs, Richard A., Abee, Christian R., Galinski, Mary R., Worley, Kim C., Rogers, Jeffrey, Radivojac, Predrag, and Hahn, Matthew W.

Published
2018
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50. A model species for agricultural pest genomics: the genome of the Colorado potato beetle, Leptinotarsa decemlineata (Coleoptera: Chrysomelidae)

Author

Ma, Sean, Chen, Yolanda, Ma, Martin, Benoit, Joshua, Bhandari, Anita, Bowsher, Julia, Brevik, Kristian, Cappelle, Kaat, Li, Mei-Ju, Childers, Anna, Li, Christopher, Christiaens, Olivier, Ma, Justin, Didion, Elise, Elpidina, Elena, Engsontia, Patamarerk, Ma, Markus, García-Robles, Inmaculada, Gibbs, Richard, Goswami, Chandan, Grapputo, Alessandro, Gruden, Kristina, Ma, Marcin, Ma, Bernard, Jennings, Emily, Jones, Jeffery, Kalsi, Megha, Khan, Sher, Kumar, Abhishek, Li, Fei, Ma, Vincent, Ma, Xingzhou, Martynov, Alex, Miller, Nicholas, Mitchell, Robert, Muñoz-Torres, Monica, Muszewska, Anna, Oppert, Brenda, Palli, Subba Reddy, Panfilio, Kristen, Pauchet, Yannick, Perkin, Lindsey, Petek, Marko, Poelchau, Monica, Record, Eric, Rinehart, Joseph, Robertson, Hugh, Rosendale, Andrew, Ruiz-Arroyo, Victor, Smagghe, Guy, Szendrei, Zsofia, Thomas, Gregg, Torson, Alex, Vargas Jentzsch, Iris, Weirauch, Matthew, Yates, Ashley, Yocum, George, Yoon, June-Sun, Richards, Stephen, Schoville, Sean, Andersson, Martin, Chen, Mei-Ju, Childers, Christopher, Clements, Justin, Friedrich, Markus, Grynberg, Marcin, Henrissat, Bernard, Lombard, Vincent, Ma, Alexander, Li, Lindsey, Ma, Marko, Robertson, Robert, Thomas, Gregg W.C., Ma, Matthew, Richards, Richard, Human Genome Sequencing Center [Houston] (HGSC), Baylor College of Medicine (BCM), Baylor University-Baylor University, Centre of Excellence in Biological interactions (CoE), University of Helsinki-Universität Zürich [Zürich] = University of Zurich (UZH)-University of Jyväskylä (JYU), National Institute of Biology, Max Planck Institute for Chemical Ecology, Max-Planck-Gesellschaft, Institut Pascal (IP), Université Blaise Pascal - Clermont-Ferrand 2 (UBP)-SIGMA Clermont (SIGMA Clermont)-Centre National de la Recherche Scientifique (CNRS), Ecole Polytechnique Fédérale de Lausanne (EPFL), Lawrence Berkeley National Laboratory [Berkeley] (LBNL), Department of Entomology, Michigan State University [East Lansing], Michigan State University System-Michigan State University System, Department of Biology, Georgetown University, Biodiversité et Biotechnologie Fongiques (BBF), Aix Marseille Université (AMU)-Institut National de la Recherche Agronomique (INRA)-École Centrale de Marseille (ECM), Faculty of Bioscience Engineering [Ghent], Universiteit Gent = Ghent University [Belgium] (UGENT), Indiana University [Bloomington], Indiana University System, Human Genome Sequencing Center, Institute of Modern Physics, Fudan University [Shanghai], Architecture et fonction des macromolécules biologiques (AFMB), Centre National de la Recherche Scientifique (CNRS)-Aix Marseille Université (AMU)-Institut National de la Recherche Agronomique (INRA), NIH NHGRI U54 HG003273 K12 GM000708, UVM Agricultural Experiment Station Hatch grant VT-H02010, Office of Science, Office of Basic Energy Sciences, of the U.S. Department of Energy DE-AC02-05CH11231, National Science Centre2012/07/D/NZ2/04286, NIH (NIGMS) 5R01GM080203, NIH (NHGRI)5R01HG004483, University of Helsinki-University of Zürich [Zürich] (UZH)-University of Jyväskylä, Université Blaise Pascal - Clermont-Ferrand 2 (UBP)-Sigma CLERMONT (Sigma CLERMONT)-Centre National de la Recherche Scientifique (CNRS), École Centrale de Marseille (ECM)-Aix Marseille Université (AMU)-Institut National de la Recherche Agronomique (INRA), Ghent University [Belgium] (UGENT), Institut National de la Recherche Agronomique (INRA)-Aix Marseille Université (AMU)-Centre National de la Recherche Scientifique (CNRS), Helsingin yliopisto = Helsingfors universitet = University of Helsinki-Universität Zürich [Zürich] = University of Zurich (UZH)-University of Jyväskylä (JYU), Georgetown University [Washington] (GU), Institut National de la Recherche Agronomique (INRA)-Aix Marseille Université (AMU)-École Centrale de Marseille (ECM), and Universiteit Gent = Ghent University (UGENT)

Subjects
Male, 0106 biological sciences, 0301 basic medicine, Genome, Insect, lcsh:Medicine, 01 natural sciences, Genome, Nucleotide diversity, Insecticide Resistance, pomme de terre, TRIBOLIUM-CASTANEUM, lcsh:Science, Leptinotarsa, CYSTEINE PROTEINASES, Phylogeny, 2. Zero hunger, education.field_of_study, Multidisciplinary, biology, insecte ravageur, Ecology, Genètica vegetal, Agriculture, leptinotarsa decemlineata, Genomics, S-TRANSFERASE GENES, lutte contre les ravageurs, Coleoptera, Other Physical Sciences, phénotype, espèce modèle, Multigene Family, Insect Proteins, RNA Interference, Female, Biotechnology, Autre (Sciences du Vivant), Genome evolution, doryphore, coleoptera, Evolution, Population, RNA-INTERFERENCE, GEOGRAPHIC POPULATIONS, Article, DNA sequencing, Host-Parasite Interactions, Evolution, Molecular, 03 medical and health sciences, [SDV.BBM.GTP]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Genomics [q-bio.GN], Genetics, Animals, analyse génomique, Pest Control, Biological, education, QH426, Gene, Solanum tuberosum, Comparative genomics, business.industry, chrysomelidae, lcsh:R, Human Genome, fungi, Colorado potato beetle, Pest control, Biology and Life Sciences, Molecular, Genetic Variation, Molecular Sequence Annotation, Biological, biology.organism_classification, 010602 entomology, Genòmica, Genetics, Population, 030104 developmental biology, Gene Expression Regulation, DROSOPHILA-MELANOGASTER, PROTEINASE-INHIBITORS, Evolutionary biology, TRANSPOSABLE ELEMENTS, DNA Transposable Elements, lcsh:Q, Pest Control, Biochemistry and Cell Biology, PEST analysis, CAENORHABDITIS-ELEGANS, business, Insect, Transcription Factors
Abstract

The Colorado potato beetle is one of the most challenging agricultural pests to manage. It has shown a spectacular ability to adapt to a variety of solanaceaeous plants and variable climates during its global invasion, and, notably, to rapidly evolve insecticide resistance. To examine evidence of rapid evolutionary change, and to understand the genetic basis of herbivory and insecticide resistance, we tested for structural and functional genomic changes relative to other arthropod species using genome sequencing, transcriptomics, and community annotation. Two factors that might facilitate rapid evolutionary change include transposable elements, which comprise at least 17% of the genome and are rapidly evolving compared to other Coleoptera, and high levels of nucleotide diversity in rapidly growing pest populations. Adaptations to plant feeding are evident in gene expansions and differential expression of digestive enzymes in gut tissues, as well as expansions of gustatory receptors for bitter tasting. Surprisingly, the suite of genes involved in insecticide resistance is similar to other beetles. Finally, duplications in the RNAi pathway might explain why Leptinotarsa decemlineata has high sensitivity to dsRNA. The L. decemlineata genome provides opportunities to investigate a broad range of phenotypes and to develop sustainable methods to control this widely successful pest.

Published
2017
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