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1. Gene-rich UV sex chromosomes harbor conserved regulators of sexual development

Author

Carey, Sarah B, Jenkins, Jerry, Lovell, John T, Maumus, Florian, Sreedasyam, Avinash, Payton, Adam C, Shu, Shengqiang, Tiley, George P, Fernandez-Pozo, Noe, Healey, Adam, Barry, Kerrie, Chen, Cindy, Wang, Mei, Lipzen, Anna, Daum, Chris, Saski, Christopher A, McBreen, Jordan C, Conrad, Roth E, Kollar, Leslie M, Olsson, Sanna, Huttunen, Sanna, Landis, Jacob B, Burleigh, J Gordon, Wickett, Norman J, Johnson, Matthew G, Rensing, Stefan A, Grimwood, Jane, Schmutz, Jeremy, and McDaniel, Stuart F

Subjects
Biological Sciences, Genetics, Biotechnology, Human Genome, 1.1 Normal biological development and functioning, Animals, DNA Transposable Elements, Evolution, Molecular, Female, Male, Mammals, Sex Chromosomes, Sexual Development
Abstract

Nonrecombining sex chromosomes, like the mammalian Y, often lose genes and accumulate transposable elements, a process termed degeneration. The correlation between suppressed recombination and degeneration is clear in animal XY systems, but the absence of recombination is confounded with other asymmetries between the X and Y. In contrast, UV sex chromosomes, like those found in bryophytes, experience symmetrical population genetic conditions. Here, we generate nearly gapless female and male chromosome-scale reference genomes of the moss Ceratodon purpureus to test for degeneration in the bryophyte UV sex chromosomes. We show that the moss sex chromosomes evolved over 300 million years ago and expanded via two chromosomal fusions. Although the sex chromosomes exhibit weaker purifying selection than autosomes, we find that suppressed recombination alone is insufficient to drive degeneration. Instead, the U and V sex chromosomes harbor thousands of broadly expressed genes, including numerous key regulators of sexual development across land plants.

Published
2021

2. All tangled up: Unraveling phylogenetics and reticulate evolution in the vining ferns, Lygodium (Schizaeales).

Author

Pelosi, Jessie A., Zumwalde, Bethany A., Testo, Weston L., Kim, Emily H., Burleigh, J. Gordon, and Sessa, Emily B.

Subjects
POLYPLOIDY, KARYOTYPES, ANEUPLOIDY, PHYLOGENY, DATA analysis
Abstract

Premise: Reticulate evolution, often accompanied by polyploidy, is prevalent in plants, and particularly in the ferns. Resolving the resulting non‐bifurcating histories remains a major challenge for plant phylogenetics. Here, we present a phylogenomic investigation into the complex evolutionary history of the vining ferns, Lygodium (Lygodiaceae, Schizaeales). Methods: Using a targeted enrichment approach with the GoFlag 408 flagellate land plant probe set, we generated large nuclear and plastid sequence datasets for nearly all taxa in the genus and constructed the most comprehensive phylogeny of the family to date using concatenated maximum likelihood and coalescence approaches. We integrated this phylogeny with cytological and spore data to explore karyotype evolution and generate hypotheses about the origins of putative polyploids and hybrids. Results: Our data and analyses support the origins of several putative allopolyploids (e.g., L. cubense, L. heterodoxum) and hybrids (e.g., L. ×fayae) and also highlight the potential prevalence of autopolyploidy in this clade (e.g., L. articulatum, L. flexuosum, and L. longifolium). Conclusions: Our robust phylogenetic framework provides valuable insights into dynamic reticulate evolution in this clade and demonstrates the utility of target‐capture data for resolving these complex relationships. [ABSTRACT FROM AUTHOR]

Published
2024
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3. The uncharacterized gene EVE contributes to vessel element dimensions in Populus

Author

Ribeiro, Cíntia L., Conde, Daniel, Balmant, Kelly M., Dervinis, Christopher, Johnson, Matthew G., McGrath, Aaron P., Szewczyk, Paul, Unda, Faride, Finegan, Christina A., Schmidt, Henry W., Miles, Brianna, Drost, Derek R., Novaes, Evandro, Gonzalez-Benecke, Carlos A., Peter, Gary F., Burleigh, J. Gordon, Martin, Timothy A., Mansfield, Shawn D., Chang, Geoffrey, Wicketti, Norman J., and Kirst, Matias

Published
2020

4. Benefits and Limits of Phasing Alleles for Network Inference of Allopolyploid Complexes.

Author

Tiley, George P, Crowl, Andrew A, Manos, Paul S, Sessa, Emily B, Solís-Lemus, Claudia, Yoder, Anne D, and Burleigh, J Gordon

Subjects
HAPLOTYPES, PLANT evolution, TIME perception, GENE flow, ALLELES
Abstract

Accurately reconstructing the reticulate histories of polyploids remains a central challenge for understanding plant evolution. Although phylogenetic networks can provide insights into relationships among polyploid lineages, inferring networks may be hindered by the complexities of homology determination in polyploid taxa. We use simulations to show that phasing alleles from allopolyploid individuals can improve phylogenetic network inference under the multispecies coalescent by obtaining the true network with fewer loci compared with haplotype consensus sequences or sequences with heterozygous bases represented as ambiguity codes. Phased allelic data can also improve divergence time estimates for networks, which is helpful for evaluating allopolyploid speciation hypotheses and proposing mechanisms of speciation. To achieve these outcomes in empirical data, we present a novel pipeline that leverages a recently developed phasing algorithm to reliably phase alleles from polyploids. This pipeline is especially appropriate for target enrichment data, where the depth of coverage is typically high enough to phase entire loci. We provide an empirical example in the North American Dryopteris fern complex that demonstrates insights from phased data as well as the challenges of network inference. We establish that our pipeline (PATÉ: Phased Alleles from Target Enrichment data) is capable of recovering a high proportion of phased loci from both diploids and polyploids. These data may improve network estimates compared with using haplotype consensus assemblies by accurately inferring the direction of gene flow, but statistical nonidentifiability of phylogenetic networks poses a barrier to inferring the evolutionary history of reticulate complexes. [ABSTRACT FROM AUTHOR]

Published
2024
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6. Data access for the 1,000 Plants (1KP) project

Author

Matasci, Naim, Hung, Ling-Hong, Yan, Zhixiang, Carpenter, Eric J, Wickett, Norman J, Mirarab, Siavash, Nguyen, Nam, Warnow, Tandy, Ayyampalayam, Saravanaraj, Barker, Michael, Burleigh, J Gordon, Gitzendanner, Matthew A, Wafula, Eric, Der, Joshua P, dePamphilis, Claude W, Roure, Béatrice, Philippe, Hervé, Ruhfel, Brad R, Miles, Nicholas W, Graham, Sean W, Mathews, Sarah, Surek, Barbara, Melkonian, Michael, Soltis, Douglas E, Soltis, Pamela S, Rothfels, Carl, Pokorny, Lisa, Shaw, Jonathan A, DeGironimo, Lisa, Stevenson, Dennis W, Villarreal, Juan Carlos, Chen, Tao, Kutchan, Toni M, Rolf, Megan, Baucom, Regina S, Deyholos, Michael K, Samudrala, Ram, Tian, Zhijian, Wu, Xiaolei, Sun, Xiao, Zhang, Yong, Wang, Jun, Leebens-Mack, Jim, and Wong, Gane Ka-Shu

Subjects
Viridiplantae, Biodiversity, Transcriptomes, Phylogenomics, Interactions, Pathways
Abstract

The 1,000 plants (1KP) project is an international multi-disciplinary consortium that has generated transcriptome data from over 1,000 plant species, with exemplars for all of the major lineages across the Viridiplantae (green plants) clade. Here, we describe how to access the data used in a phylogenomics analysis of the first 85 species, and how to visualize our gene and species trees. Users can develop computational pipelines to analyse these data, in conjunction with data of their own that they can upload. Computationally estimated protein-protein interactions and biochemical pathways can be visualized at another site. Finally, we comment on our future plans and how they fit within this scalable system for the dissemination, visualization, and analysis of large multi-species data sets.

Published
2014

8. A roadmap for global synthesis of the plant tree of life

Author

Eiserhardt, Wolf L., Antonelli, Alexandre, Bennett, Dominic J., Botigué, Laura R., Burleigh, J. Gordon, Dodsworth, Steven, Enquist, Brian J., Forest, Félix, Kim, Jan T., Kozlov, Alexey M., Leitch, Ilia J., Maitner, Brian S., Mirarab, Siavash, Piel, William H., Pérez-Escobar, Oscar A., Pokorny, Lisa, Rahbek, Carsten, Sandel, Brody, Smith, Stephen A., Stamatakis, Alexandros, Vos, Rutger A., Warnow, Tandy, and Baker, William J.

Published
2018

19. Synthesis of phylogeny and taxonomy into a comprehensive tree of life

Author

Hinchliff, Cody E., Smith, Stephen A., Allman, James F., Burleigh, J. Gordon, Chaudhary, Ruchi, Coghill, Lyndon M., Crandall, Keith A., Deng, Jiabin, Drew, Bryan T., Gazis, Romina, Gude, Karl, Hibbett, David S., Katz, Laura A., Laughinghouse, H. Dail, McTavish, Emily Jane, Midford, Peter E., Owen, Christopher L., Ree, Richard H., Rees, Jonathan A., Soltis, Douglas E., Williams, Tiffani, and Cranston, Karen A.

Published
2015

22. Phylotranscriptomic analysis of the origin and early diversification of land plants

Author

Wickett, Norman J., Mirarab, Siavash, Nguyen, Nam, Warnow, Tandy, Carpenter, Eric, Matasci, Naim, Ayyampalayam, Saravanaraj, Barker, Michael S., Burleigh, J. Gordon, Gitzendanner, Matthew A., Ruhfel, Brad R., Wafula, Eric, Der, Joshua P., Graham, Sean W., Mathews, Sarah, Melkonian, Michael, Soltis, Douglas E., Soltis, Pamela S., Miles, Nicholas W., Rothfels, Carl J., Pokorny, Lisa, Shaw, A. Jonathan, DeGironimo, Lisa, Stevenson, Dennis W., Surek, Barbara, Villarreal, Juan Carlos, Roure, Béatrice, Philippe, Hervé, dePamphilis, Claude W., Chen, Tao, Deyholos, Michael K., Baucom, Regina S., Kutchan, Toni M., Augustin, Megan M., Wang, Jun, Zhang, Yong, Tian, Zhijian, Yan, Zhixiang, Wu, Xiaolei, Sun, Xiao, Wong, Gane Ka-Shu, and Leebens-Mack, James

Published
2014

24. Figure 6 from: Demeulenaere E, Schils T, Burleigh JG, Ringelberg JJ, Koenen EJM, Ickert-Bond SM (2022) Phylogenomic assessment prompts recognition of the Serianthes clade and confirms the monophyly of Serianthes and its relationship with Falcataria and Wallaceodendron in the wider ingoid clade (Leguminosae, Caesalpinioideae). In: Hughes CE, de Queiroz LP, Lewis GP (Eds) Advances in Legume Systematics 14. Classification of Caesalpinioideae Part 1: New generic delimitations. PhytoKeys 205: 335-361. https://doi.org/10.3897/phytokeys.205.79144

Author

Demeulenaere, Else, primary, Schils, Tom, additional, Burleigh, J. Gordon, additional, Ringelberg, Jens J., additional, Koenen, Erik J. M., additional, and Ickert-Bond, Stefanie M., additional

Published
2022
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25. Figure 2 from: Demeulenaere E, Schils T, Burleigh JG, Ringelberg JJ, Koenen EJM, Ickert-Bond SM (2022) Phylogenomic assessment prompts recognition of the Serianthes clade and confirms the monophyly of Serianthes and its relationship with Falcataria and Wallaceodendron in the wider ingoid clade (Leguminosae, Caesalpinioideae). In: Hughes CE, de Queiroz LP, Lewis GP (Eds) Advances in Legume Systematics 14. Classification of Caesalpinioideae Part 1: New generic delimitations. PhytoKeys 205: 335-361. https://doi.org/10.3897/phytokeys.205.79144

Author

Demeulenaere, Else, primary, Schils, Tom, additional, Burleigh, J. Gordon, additional, Ringelberg, Jens J., additional, Koenen, Erik J. M., additional, and Ickert-Bond, Stefanie M., additional

Published
2022
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26. Figure 4 from: Demeulenaere E, Schils T, Burleigh JG, Ringelberg JJ, Koenen EJM, Ickert-Bond SM (2022) Phylogenomic assessment prompts recognition of the Serianthes clade and confirms the monophyly of Serianthes and its relationship with Falcataria and Wallaceodendron in the wider ingoid clade (Leguminosae, Caesalpinioideae). In: Hughes CE, de Queiroz LP, Lewis GP (Eds) Advances in Legume Systematics 14. Classification of Caesalpinioideae Part 1: New generic delimitations. PhytoKeys 205: 335-361. https://doi.org/10.3897/phytokeys.205.79144

Author

Demeulenaere, Else, primary, Schils, Tom, additional, Burleigh, J. Gordon, additional, Ringelberg, Jens J., additional, Koenen, Erik J. M., additional, and Ickert-Bond, Stefanie M., additional

Published
2022
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27. Figure 8 from: Demeulenaere E, Schils T, Burleigh JG, Ringelberg JJ, Koenen EJM, Ickert-Bond SM (2022) Phylogenomic assessment prompts recognition of the Serianthes clade and confirms the monophyly of Serianthes and its relationship with Falcataria and Wallaceodendron in the wider ingoid clade (Leguminosae, Caesalpinioideae). In: Hughes CE, de Queiroz LP, Lewis GP (Eds) Advances in Legume Systematics 14. Classification of Caesalpinioideae Part 1: New generic delimitations. PhytoKeys 205: 335-361. https://doi.org/10.3897/phytokeys.205.79144

Author

Demeulenaere, Else, primary, Schils, Tom, additional, Burleigh, J. Gordon, additional, Ringelberg, Jens J., additional, Koenen, Erik J. M., additional, and Ickert-Bond, Stefanie M., additional

Published
2022
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28. Figure 1 from: Demeulenaere E, Schils T, Burleigh JG, Ringelberg JJ, Koenen EJM, Ickert-Bond SM (2022) Phylogenomic assessment prompts recognition of the Serianthes clade and confirms the monophyly of Serianthes and its relationship with Falcataria and Wallaceodendron in the wider ingoid clade (Leguminosae, Caesalpinioideae). In: Hughes CE, de Queiroz LP, Lewis GP (Eds) Advances in Legume Systematics 14. Classification of Caesalpinioideae Part 1: New generic delimitations. PhytoKeys 205: 335-361. https://doi.org/10.3897/phytokeys.205.79144

Author

Demeulenaere, Else, primary, Schils, Tom, additional, Burleigh, J. Gordon, additional, Ringelberg, Jens J., additional, Koenen, Erik J. M., additional, and Ickert-Bond, Stefanie M., additional

Published
2022
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29. Figure 7 from: Demeulenaere E, Schils T, Burleigh JG, Ringelberg JJ, Koenen EJM, Ickert-Bond SM (2022) Phylogenomic assessment prompts recognition of the Serianthes clade and confirms the monophyly of Serianthes and its relationship with Falcataria and Wallaceodendron in the wider ingoid clade (Leguminosae, Caesalpinioideae). In: Hughes CE, de Queiroz LP, Lewis GP (Eds) Advances in Legume Systematics 14. Classification of Caesalpinioideae Part 1: New generic delimitations. PhytoKeys 205: 335-361. https://doi.org/10.3897/phytokeys.205.79144

Author

Demeulenaere, Else, primary, Schils, Tom, additional, Burleigh, J. Gordon, additional, Ringelberg, Jens J., additional, Koenen, Erik J. M., additional, and Ickert-Bond, Stefanie M., additional

Published
2022
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30. Figure 5 from: Demeulenaere E, Schils T, Burleigh JG, Ringelberg JJ, Koenen EJM, Ickert-Bond SM (2022) Phylogenomic assessment prompts recognition of the Serianthes clade and confirms the monophyly of Serianthes and its relationship with Falcataria and Wallaceodendron in the wider ingoid clade (Leguminosae, Caesalpinioideae). In: Hughes CE, de Queiroz LP, Lewis GP (Eds) Advances in Legume Systematics 14. Classification of Caesalpinioideae Part 1: New generic delimitations. PhytoKeys 205: 335-361. https://doi.org/10.3897/phytokeys.205.79144

Author

Demeulenaere, Else, primary, Schils, Tom, additional, Burleigh, J. Gordon, additional, Ringelberg, Jens J., additional, Koenen, Erik J. M., additional, and Ickert-Bond, Stefanie M., additional

Published
2022
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31. Figure 3 from: Demeulenaere E, Schils T, Burleigh JG, Ringelberg JJ, Koenen EJM, Ickert-Bond SM (2022) Phylogenomic assessment prompts recognition of the Serianthes clade and confirms the monophyly of Serianthes and its relationship with Falcataria and Wallaceodendron in the wider ingoid clade (Leguminosae, Caesalpinioideae). In: Hughes CE, de Queiroz LP, Lewis GP (Eds) Advances in Legume Systematics 14. Classification of Caesalpinioideae Part 1: New generic delimitations. PhytoKeys 205: 335-361. https://doi.org/10.3897/phytokeys.205.79144

Author

Demeulenaere, Else, primary, Schils, Tom, additional, Burleigh, J. Gordon, additional, Ringelberg, Jens J., additional, Koenen, Erik J. M., additional, and Ickert-Bond, Stefanie M., additional

Published
2022
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35. Linking Ecological Specialization to Its Macroevolutionary Consequences: An Example with Passerine Nest Type.

Author

Zenil-Ferguson, Rosana, McEntee, Jay P, Burleigh, J Gordon, and Duckworth, Renée A

Subjects
BIOLOGICAL extinction, COMPETITION (Biology), NESTS, BIRD nests, COMPARATIVE method, PASSERIFORMES
Abstract

A long-standing hypothesis in evolutionary biology is that the evolution of resource specialization can lead to an evolutionary dead end, where specialists have low diversification rates and limited ability to evolve into generalists. In recent years, advances in comparative methods investigating trait-based differences associated with diversification have enabled more robust tests of this idea and have found mixed support. We test the evolutionary dead end hypothesis by estimating net diversification rate differences associated with nest-type specialization among 3224 species of passerine birds. In particular, we test whether the adoption of hole-nesting, a nest-type specialization that decreases predation, results in reduced diversification rates relative to nesting outside of holes. Further, we examine whether evolutionary transitions to the specialist hole-nesting state have been more frequent than transitions out of hole-nesting. Using diversification models that accounted for background rate heterogeneity and different extinction rate scenarios, we found that hole-nesting specialization was not associated with diversification rate differences. Furthermore, contrary to the assumption that specialists rarely evolve into generalists, we found that transitions out of hole-nesting occur more frequently than transitions into hole-nesting. These results suggest that interspecific competition may limit adoption of hole-nesting, but that such competition does not result in limited diversification of hole-nesters. In conjunction with other recent studies using robust comparative methods, our results add to growing evidence that evolutionary dead ends are not a typical outcome of resource specialization. [Cavity nesting; diversification; hidden-state models; passerines; resource specialization.] [ABSTRACT FROM AUTHOR]

Published
2023
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48. Target Capture Methods Offer Insight into the Evolution of Rapidly Diverged Taxa and Resolve Allopolyploid Homeologs in the Fern Genus Polypodium s.s.

Author

Mendez-Reneau, Jonas, Burleigh, J. Gordon, and Sigel, Erin M.

Subjects
*FERNS, *HAPLOTYPES, *POLYPLOIDY, *SPECIES, *CHLOROPLAST DNA, *GENES, *TREES, *MOLECULAR phylogeny
Abstract

Like many fern lineages comprising reticulate species complexes, Polypodium s.s. (Polypodiacaeae) has a history shaped by rapid diversification, hybridization, and polyploidy that poses substantial challenges for phylogenetic inference with plastid and single-locus nuclear markers. Using target capture probes for 408 nuclear loci developed by the GoFlag project and a custom bioinformatic pipeline, SORTER, we constructed multi-locus nuclear datasets for diploid temperate and Mesoamerican species of Polypodium and five allotetraploid species belonging to the well-studied Polypodium vulgare complex. SORTER employs a clustering approach to separate putatively paralogous copies of targeted loci into orthologous matrices and haplotype phasing to infer allopolyploid haplotypes across loci, resulting in datasets amenable to both concatenated maximum likelihood and multi-species coalescent phylogenetic analyses. By comparing phylogenies derived from maximum likelihood and multi-species coalescent analyses of unphased and phased datasets, as well as evaluating discordance among gene trees and species trees, we recover support for incomplete lineage sorting within Polypodium s.s., novel relationships among diploid taxa of the Polypodium vulgare complex and its Mesoamerican sister clade, and the placement of several Polypodium species within other genera. Additionally, we were able to infer well-supported phylogenies that identified the hypothesized progenitors of the allotetraploid species, indicating that SORTER is an effective and accurate tool for reconstructing homeolog haplotypes of allopolyploids in fern taxa and other non-model organisms from target capture data. [ABSTRACT FROM AUTHOR]

Published
2023
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50. Updating splits, lumps, and shuffles: Reconciling GenBank names with standardized avian taxonomies.

Author

Hosner, Peter A., Min Zhao, Kimball, Rebecca T., Braun, Edward L., and Burleigh, J. Gordon

Subjects
GENE libraries, BIRD ecology, DNA sequencing, NUCLEOTIDE sequence, BIG data
Abstract

Copyright of Ornithology (Oxford University Press) is the property of Oxford University Press / USA and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published
2022
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