Your search keyword '"Burge, Dylan O"' showing total 7 results

1. Massive haplotypes underlie ecotypic differentiation in sunflowers

Author

Todesco, Marco, Owens, Gregory L, Bercovich, Natalia, Légaré, Jean-Sébastien, Soudi, Shaghayegh, Burge, Dylan O, Huang, Kaichi, Ostevik, Katherine L, Drummond, Emily BM, Imerovski, Ivana, Lande, Kathryn, Pascual-Robles, Mariana A, Nanavati, Mihir, Jahani, Mojtaba, Cheung, Winnie, Staton, S Evan, Muños, Stéphane, Nielsen, Rasmus, Donovan, Lisa A, Burke, John M, Yeaman, Sam, and Rieseberg, Loren H

Subjects

Genetics, Acclimatization, Alleles, Ecotype, Flowers, Haplotypes, Helianthus, Phylogeny, Seeds, General Science & Technology

Abstract

Species often include multiple ecotypes that are adapted to different environments1. However, it is unclear how ecotypes arise and how their distinctive combinations of adaptive alleles are maintained despite hybridization with non-adapted populations2-4. Here, by resequencing 1,506 wild sunflowers from 3 species (Helianthus annuus, Helianthus petiolaris and Helianthus argophyllus), we identify 37 large (1-100 Mbp in size), non-recombining haplotype blocks that are associated with numerous ecologically relevant traits, as well as soil and climate characteristics. Limited recombination in these haplotype blocks keeps adaptive alleles together, and these regions differentiate sunflower ecotypes. For example, haplotype blocks control a 77-day difference in flowering between ecotypes of the silverleaf sunflower H. argophyllus (probably through deletion of a homologue of FLOWERING LOCUS T (FT)), and are associated with seed size, flowering time and soil fertility in dune-adapted sunflowers. These haplotypes are highly divergent, frequently associated with structural variants and often appear to represent introgressions from other-possibly now-extinct-congeners. These results highlight a pervasive role of structural variation in ecotypic adaptation.

Published

2020

2. One thousand plant transcriptomes and the phylogenomics of green plants

Author

Leebens-Mack, James H, Barker, Michael S, Carpenter, Eric J, Deyholos, Michael K, Gitzendanner, Matthew A, Graham, Sean W, Grosse, Ivo, Li, Zheng, Melkonian, Michael, Mirarab, Siavash, Porsch, Martin, Quint, Marcel, Rensing, Stefan A, Soltis, Douglas E, Soltis, Pamela S, Stevenson, Dennis W, Ullrich, Kristian K, Wickett, Norman J, DeGironimo, Lisa, Edger, Patrick P, Jordon-Thaden, Ingrid E, Joya, Steve, Liu, Tao, Melkonian, Barbara, Miles, Nicholas W, Pokorny, Lisa, Quigley, Charlotte, Thomas, Philip, Villarreal, Juan Carlos, Augustin, Megan M, Barrett, Matthew D, Baucom, Regina S, Beerling, David J, Benstein, Ruben Maximilian, Biffin, Ed, Brockington, Samuel F, Burge, Dylan O, Burris, Jason N, Burris, Kellie P, Burtet-Sarramegna, Valerie, Caicedo, Ana L, Cannon, Steven B, Cebi, Zehra, Chang, Ying, Chater, Caspar, Cheeseman, John M, Chen, Tao, Clarke, Neil D, Clayton, Harmony, Covshoff, Sarah, Crandall-Stotler, Barbara J, Cross, Hugh, dePamphilis, Claude W, Der, Joshua P, Determann, Ron, Dickson, Rowan C, Di Stilio, Veronica S, Ellis, Shona, Fast, Eva, Feja, Nicole, Field, Katie J, Filatov, Dmitry A, Finnegan, Patrick M, Floyd, Sandra K, Fogliani, Bruno, Garcia, Nicolas, Gateble, Gildas, Godden, Grant T, Goh, Falicia Qi Yun, Greiner, Stephan, Harkess, Alex, Heaney, James Mike, Helliwell, Katherine E, Heyduk, Karolina, Hibberd, Julian M, Hodel, Richard GJ, Hollingsworth, Peter M, Johnson, Marc TJ, Jost, Ricarda, Joyce, Blake, Kapralov, Maxim V, Kazamia, Elena, Kellogg, Elizabeth A, Koch, Marcus A, Von Konrat, Matt, Konyves, Kalman, Kutchan, Toni M, Lam, Vivienne, Larsson, Anders, Leitch, Andrew R, Lentz, Roswitha, Li, Fay-Wei, Lowe, Andrew J, Ludwig, Martha, Manos, Paul S, Mavrodiev, Evgeny, McCormick, Melissa K, McKain, Michael, McLellan, Tracy, and McNeal, Joel R

Subjects

Biotechnology, Genetics, Human Genome, Biological Evolution, Databases, Genetic, Evolution, Molecular, Genome, Plant, Phylogeny, Transcriptome, Viridiplantae, One Thousand Plant Transcriptomes Initiative, General Science & Technology

Abstract

Green plants (Viridiplantae) include around 450,000-500,000 species1,2 of great diversity and have important roles in terrestrial and aquatic ecosystems. Here, as part of the One Thousand Plant Transcriptomes Initiative, we sequenced the vegetative transcriptomes of 1,124 species that span the diversity of plants in a broad sense (Archaeplastida), including green plants (Viridiplantae), glaucophytes (Glaucophyta) and red algae (Rhodophyta). Our analysis provides a robust phylogenomic framework for examining the evolution of green plants. Most inferred species relationships are well supported across multiple species tree and supermatrix analyses, but discordance among plastid and nuclear gene trees at a few important nodes highlights the complexity of plant genome evolution, including polyploidy, periods of rapid speciation, and extinction. Incomplete sorting of ancestral variation, polyploidization and massive expansions of gene families punctuate the evolutionary history of green plants. Notably, we find that large expansions of gene families preceded the origins of green plants, land plants and vascular plants, whereas whole-genome duplications are inferred to have occurred repeatedly throughout the evolution of flowering plants and ferns. The increasing availability of high-quality plant genome sequences and advances in functional genomics are enabling research on genome evolution across the green tree of life.

Published

2019

3. Transcriptome-mining for single-copy nuclear markers in ferns.

Author

Rothfels, Carl J, Larsson, Anders, Li, Fay-Wei, Sigel, Erin M, Huiet, Layne, Burge, Dylan O, Ruhsam, Markus, Graham, Sean W, Stevenson, Dennis W, Wong, Gane Ka-Shu, Korall, Petra, and Pryer, Kathleen M

Subjects

Cell Nucleus, Ferns, Plant Proteins, Gene Expression Profiling, Sequence Analysis, DNA, Evolution, Molecular, Phylogeny, Gene Expression Regulation, Plant, Gene Dosage, Genes, Plant, Molecular Sequence Data, Transcriptome, Sequence Analysis, DNA, Evolution, Molecular, Gene Expression Regulation, Plant, Genes, General Science & Technology

Abstract

BackgroundMolecular phylogenetic investigations have revolutionized our understanding of the evolutionary history of ferns-the second-most species-rich major group of vascular plants, and the sister clade to seed plants. The general absence of genomic resources available for this important group of plants, however, has resulted in the strong dependence of these studies on plastid data; nuclear or mitochondrial data have been rarely used. In this study, we utilize transcriptome data to design primers for nuclear markers for use in studies of fern evolutionary biology, and demonstrate the utility of these markers across the largest order of ferns, the Polypodiales.Principal findingsWe present 20 novel single-copy nuclear regions, across 10 distinct protein-coding genes: ApPEFP_C, cryptochrome 2, cryptochrome 4, DET1, gapCpSh, IBR3, pgiC, SQD1, TPLATE, and transducin. These loci, individually and in combination, show strong resolving power across the Polypodiales phylogeny, and are readily amplified and sequenced from our genomic DNA test set (from 15 diploid Polypodiales species). For each region, we also present transcriptome alignments of the focal locus and related paralogs-curated broadly across ferns-that will allow researchers to develop their own primer sets for fern taxa outside of the Polypodiales. Analyses of sequence data generated from our genomic DNA test set reveal strong effects of partitioning schemes on support levels and, to a much lesser extent, on topology. A model partitioned by codon position is strongly favored, and analyses of the combined data yield a Polypodiales phylogeny that is well-supported and consistent with earlier studies of this group.ConclusionsThe 20 single-copy regions presented here more than triple the single-copy nuclear regions available for use in ferns. They provide a much-needed opportunity to assess plastid-derived hypotheses of relationships within the ferns, and increase our capacity to explore aspects of fern evolution previously unavailable to scientific investigation.

Published

2013

4. Horizontal transfer of an adaptive chimeric photoreceptor from bryophytes to ferns

Author

Li, Fay-Wei, Villarreal, Juan Carlos, Kelly, Steven, Rothfels, Carl J., Melkonian, Michael, Frangedakis, Eftychios, Ruhsam, Markus, Sigel, Erin M., Der, Joshua P., Pittermann, Jarmila, Burge, Dylan O., Pokorny, Lisa, Larsson, Anders, Chen, Tao, Weststrand, Stina, Thomas, Philip, Carpenter, Eric, Zhang, Yong, Tian, Zhijian, Li Chen, Yan, Zhixiang, Zhu, Ying, Sun, Xiao, Wang, Jun, Stevenson, Dennis W., Crandall-Stotler, Barbara J., Shaw, A. Jonathan, Deyholos, Michael K., Soltis, Douglas E., Graham, Sean W., Windham, Michael D., Langdale, Jane A., Wong, Gane Ka-Shu, Mathews, Sarah, and Pryer, Kathleen M.

Published

2014

5. Diversification of Ceanothus (Rhamnaceae) in the California Floristic Province

Author

Burge, Dylan O., Erwin, Diane M., Islam, Melissa B., Kellermann, Jürgen, Kembel, Steven W., Wilken, Dieter H., and Manos, Paul S.

Published

2011

6. MOLECULAR PHYLOGENETICS OF GARRYA (GARRYACEAE)

Author

Burge, Dylan O.

Published

2011

7. Leaf adaptations and species boundaries in North American Cercis: implications for the evolution of dry floras.

Author

Fritsch, Peter W., Nowell, Camille F., Leatherman, Lila S. T., Gong, Wei, Cruz, Boni C., Burge, Dylan O., and Delgado‐Salinas, Alfonso

Subjects

LEGUMES, PHYLOGENY, MORPHOMETRICS

Abstract

Premise of the Study: The North American Cercis clade spans dry to mesic climates and exhibits complex morphological variation. We tested various proposed species classifications of this group and whether aspects of leaf morphology, particularly the “drip‐tip” in some regional populations, are adaptive and/or linked with phylogeny. Methods: We made measurements on over 1100 herbarium specimens from throughout North America and analyzed the data with univariate and multivariate approaches. We analyzed phylogenetically DNA sequence data from nuclear ITS and three plastid regions from 40 samples, and estimated divergence times with a relaxed‐clock Bayesian analysis. We used climate and geographic position data to predict the variation observed in leaf size and shape by using stepwise multiple linear regressions. Key Results: Morphometric analyses yielded a pattern of continuous and often clinal character variation across North America, without correlated gaps in character states. Conversely, phylogenetic and divergence time analyses yielded distinct clades from California, the interior west, and eastern North America separated by between ~12 and 16 million years. Multiple regressions yielded highly significant correlations between leaf apex shape and precipitation of the warmest quarter. Conclusions: Despite a pattern of continuous morphological character variation, the long period of geographic and presumably genetic isolation warrants the delimitation of three species. Predictive modeling supports the adaptive value of acuminate apices or “drip‐tips” in mesic habitats. This suggests that Cercis leaves change more rapidly than inferred from parsimony reconstruction, which has implications for the evolution of the dry floras of North America and Eurasia. [ABSTRACT FROM AUTHOR]

Published

2018