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Exploring the Evolutionary History of North American Prairie Grouse (Genus: Tympanuchus) Using Multi-locus Coalescent AnalysesGalla, Stephanie J. 05 1900 (has links)
Conservation biologists are increasingly using phylogenetics as a tool to understand evolutionary relationships and taxonomic classification. The taxonomy of North American prairie grouse (sharp-tailed grouse, T. phasianellus; lesser prairie-chicken, T. pallidicinctus; greater prairie-chicken, T. cupido; including multiple subspecies) has been designated based on physical characteristics, geography, and behavior. However, previous studies have been inconclusive in determining the evolutionary history of prairie grouse based on genetic data. Therefore, additional research investigating the evolutionary history of prairie grouse is warranted. In this study, ten loci (including mitochondrial, autosomal, and Z-linked markers) were sequenced across multiple populations of prairie grouse, and both traditional and coalescent-based phylogenetic analyses were used to address the evolutionary history of this genus. Results from this study indicate that North American prairie grouse diverged in the last 200,000 years, with species-level taxa forming well-supported monophyletic clades in species tree analyses. With these results, managers of the critically endangered Attwater's prairie-chicken (T. c. attwateri) can better evaluate whether outcrossing Attwater's with greater prairie-chickens would be a viable management tool for Attwater's conservation.
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Discord between morphological and phylogenetic species boundaries: incomplete lineage sorting and recombination results in fuzzy species boundaries in an asexual fungal pathogenStewart, Jane, Timmer, Lavern, Lawrence, Christopher, Pryor, Barry, Peever, Tobin January 2014 (has links)
BACKGROUND:Traditional morphological and biological species concepts are difficult to apply to closely related, asexual taxa because of the lack of an active sexual phase and paucity of morphological characters. Phylogenetic species concepts such as genealogical concordance phylogenetic species recognition (GCPSR) have been extensively used / however, methods that incorporate gene tree uncertainty into species recognition may more accurately and objectively delineate species. Using a worldwide sample of Alternaria alternata sensu lato, causal agent of citrus brown spot, the evolutionary histories of four nuclear loci including an endo-polygalacturonase gene, two anonymous loci, and one microsatellite flanking region were estimated using the coalescent. Species boundaries were estimated using several approaches including those that incorporate uncertainty in gene genealogies when lineage sorting and non-reciprocal monophyly of gene trees is common.RESULTS:Coalescent analyses revealed three phylogenetic lineages strongly influenced by incomplete lineage sorting and recombination. Divergence of the citrus 2 lineage from the citrus 1 and citrus 3 lineages was supported at most loci. A consensus of species tree estimation methods supported two species of Alternaria causing citrus brown spot worldwide. Based on substitution rates at the endo-polygalacturonase locus, divergence of the citrus 2 and the 1 and 3 lineages was estimated to have occurred at least 5, 400 years before present, predating the human-mediated movement of citrus and associated pathogens out of SE Asia.CONCLUSIONS:The number of Alternaria species identified as causing brown spot of citrus worldwide using morphological criteria has been overestimated. Little support was found for most of these morphospecies using quantitative species recognition approaches. Correct species delimitation of plant-pathogenic fungi is critical for understanding the evolution of pathogenicity, introductions of pathogens to new areas, and for regulating the movement of pathogens to enforce quarantines. This research shows that multilocus phylogenetic methods that allow for recombination and incomplete lineage sorting can be useful for the quantitative delimitation of asexual species that are morphologically indistinguishable. Two phylogenetic species of Alternaria were identified as causing citrus brown spot worldwide. Further research is needed to determine how these species were introduced worldwide, how they differ phenotypically and how these species are maintained.
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WHEN MOLECULES AND MORPHOLOGY CLASH: REVISITING SPECIES TREE RECONSTRUCTION OF AMBYSTOMATID SALAMANDERS USING MULTIPLE NUCLEAR LOCIWilliams, Joshua Steven 01 January 2012 (has links)
The analysis of diverse data sets can yield different phylogenetic estimates that challenge systematists to explain the source of discordance. The Ambystomatidae are a classic example of this phylogenetic conflict. Previous attempts to resolve the ambystomatid species tree using allozymic, morphological, and mitochondrial sequence data have yielded different estimates, making it unclear which data source best approximates ambystomatid phylogeny. We present the first multi-locus DNA sequencebased phylogenetic study of the Ambystomatidae. Because independent loci can contain discordant gene tree histories, concatenating unlinked loci into a single data matrix can lead to strongly supported and erroneous results. Therefore, we utilized a range of analyses, including coalescent-based methods of phylogenetic estimation that account for incomplete lineage sorting and concordance-based methods that estimate the proportion of sampled loci that support a particular clade. We repeated these analyses with the removal of individual loci to determine if any locus has a disproportionate effect on our phylogenetic results. Many deep and relatively shallow clades within Ambystoma were robustly resolved. Analyses that excluded loci produced overlapping posterior distributions, suggesting no disproportionate influence of any particular locus. Our estimates differ from previous hypotheses, although there was greater similarity with previous molecular estimates, relative to morphological estimates.
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Species Tree Likelihood Computation Given SNP Data Using Ancestral ConfigurationsFan, Hang January 2013 (has links)
No description available.
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DNA-based Species Delimitation of the Agriculturally Important Genus, Ravinia (Diptera: Sarcophagidae)Wong, Evan S. 12 October 2015 (has links)
No description available.
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Topics in Phylogenetic Species Tree Inference under the Coalescent ModelTian, Yuan January 2016 (has links)
No description available.
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Species trees from gene trees: reconstructing Bayesian posterior distributions of a species phylogeny using estimated gene tree distributionsLiu, Liang 14 September 2006 (has links)
No description available.
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Estimation of Species Tree Using Approximate Bayesian ComputationFan, Hang 25 October 2010 (has links)
No description available.
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Novel scalable approaches for multiple sequence alignment and phylogenomic reconstructionMir arabbaygi, Siavash 18 September 2015 (has links)
The amount of biological sequence data is increasing rapidly, a promising development that would transform biology if we can develop methods that can analyze large-scale data efficiently and accurately. A fundamental question in evolutionary biology is building the tree of life: a reconstruction of relationships between organisms in evolutionary time. Reconstructing phylogenetic trees from molecular data is an optimization problem that involves many steps. In this dissertation, we argue that to answer long-standing phylogenetic questions with large-scale data, several challenges need to be addressed in various steps of the pipeline. One challenges is aligning large number of sequences so that evolutionarily related positions in all sequences are put in the same column. Constructing alignments is necessary for phylogenetic reconstruction, but also for many other types of evolutionary analyses. In response to this challenge, we introduce PASTA, a scalable and accurate algorithm that can align datasets with up to a million sequences. A second challenge is related to the interesting fact that various parts of the genome can have different evolutionary histories. Reconstructing a species tree from genome-scale data needs to account for these differences. A main approach for species tree reconstruction is to first reconstruct a set of ``gene trees'' from different parts of the genome, and to then summarize these gene trees into a single species tree. We argue that this approach can suffer from two challenges: reconstruction of individual gene trees from limited data can be plagued by estimation error, which translates to errors in the species tree, and also, methods that summarize gene trees are not scalable or accurate enough under some conditions. To address the first challenge, we introduce statistical binning, a method that re-estimates gene trees by grouping them into bins. We show that binning improves gene tree accuracy, and consequently the species tree accuracy. To address the second challenge, we introduce ASTRAL, a new summary method that can run on a thousand genes and a thousand species in a day and has outstanding accuracy. We show that the development of these methods has enabled biological analyses that were otherwise not possible.
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Impact of Rates of Gene Duplication and Domain Shuffling on Species Tree Inference with Gene Tree ParsimonyShi, Tao January 2013 (has links)
Genome sequencing technologies are providing huge quantities of data for phylogenetic inference. However, most phylogenomic studies exclude gene families, because many have a complicated history of gene duplication/loss and structural change by domain shuffling, especially in deep phylogenies. Gene tree parsimony (GTP) methods, which seek the species tree that minimizes the cost of gene duplication, have been successfully applied to gene families with frequent duplication history. Their utility and performance in the context of gene families with complex histories of gene duplication and domain reshuffling remains unclear. In this study, we analyzed 4389 gene families from six angiosperm genomes encompassing a wide range of duplication rates, and a broad diversity of domain architecture. Overall species tree inference accuracy increased monotonically with the inclusion of more gene trees, and high accuracy was achieved with 50-100 gene trees. The rate of gene duplication strongly influences species tree inference accuracy, with the highest accuracy at either very low or very high rates of duplication and lowest accuracy centered around one duplication per branch in the unrooted species tree. This is the opposite of the relationship between substitution rates on tree construction accuracy, in which intermediate rates have highest accuracy. Accuracy is generally higher in gene families with high domain architecture diversity but has high variance in families with relatively low domain architecture diversity. The latter is probably due to the high variation of gene duplication number for those gene families. We close with some discussion of potential impacts of domain evolution on phylogenomic reconstruction protocols in general, including its effect on alignment.
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