Current Search:  Research Repository (x) » * (x) » Citation (x) » Shukla, P. (x) » Department of Biological Science (x) » Lemmon, Alan R. (x)

Search results

  • CSV Spreadsheet
(1 - 4 of 4)
Phylogenomics Uncovers Early Hybridization And Adaptive Loci Shaping The Radiation Of Lake Tanganyika Cichlid Fishes
Title
Phylogenomics Uncovers Early Hybridization And Adaptive Loci Shaping The Radiation Of Lake Tanganyika Cichlid Fishes.
Creator
Irisarri, Iker, Singh, Pooja, Koblmuller, Stephan, Torres-Dowdall, Julian, Henning, Frederico, Franchini, Paolo, Fischer, Christoph, Lemmon, Alan R., Lemmon, Emily Moriarty,...
Show moreIrisarri, Iker, Singh, Pooja, Koblmuller, Stephan, Torres-Dowdall, Julian, Henning, Frederico, Franchini, Paolo, Fischer, Christoph, Lemmon, Alan R., Lemmon, Emily Moriarty, Thallinger, Gerhard G., Sturmbauer, Christian, Meyer, Axel
Show less
Abstract/Description
Lake Tanganyika is the oldest and phenotypically most diverse of the three East African cichlid fish adaptive radiations. It is also the cradle for the younger parallel haplochromine cichlid radiations in Lakes Malawi and Victoria. Despite its evolutionary significance, the relationships among the main Lake Tanganyika lineages remained unresolved, as did the general timescale of cichlid evolution. Here, we disentangle the deep phylogenetic structure of the Lake Tanganyika radiation using...
Show moreLake Tanganyika is the oldest and phenotypically most diverse of the three East African cichlid fish adaptive radiations. It is also the cradle for the younger parallel haplochromine cichlid radiations in Lakes Malawi and Victoria. Despite its evolutionary significance, the relationships among the main Lake Tanganyika lineages remained unresolved, as did the general timescale of cichlid evolution. Here, we disentangle the deep phylogenetic structure of the Lake Tanganyika radiation using anchored phylogenomics and uncover hybridization at its base, as well as early in the haplochromine radiation. This suggests that hybridization might have facilitated these speciation bursts. Time-calibrated trees support that the radiation of Tanganyika cichlids coincided with lake formation and that Gondwanan vicariance concurred with the earliest splits in the cichlid family tree. Genes linked to key innovations show signals of introgression or positive selection following colonization of lake habitats and species' dietary adaptations are revealed as major drivers of colour vision evolution. These findings shed light onto the processes shaping the evolution of adaptive radiations.
Show less
Date Issued
2018-08-08
Identifier
FSU_libsubv1_wos_000440982800001, 10.1038/s41467-018-05479-9
Format
Citation
Diversification in wild populations of the model organism Anolis carolinensis
Title
Diversification In Wild Populations Of The Model Organism Anolis Carolinensis: A Genome-wide Phylogeographic Investigation.
Creator
Manthey, Joseph D., Tollis, Marc, Lemmon, Alan R., Lemmon, Emily Moriarty, Boissinot, Stephane
Abstract/Description
The green anole (Anolis carolinensis) is a lizard widespread throughout the southeastern United States and is a model organism for the study of reproductive behavior, physiology, neural biology, and genomics. Previous phylogeographic studies of A. carolinensis using mitochondrial DNA and small numbers of nuclear loci identified conflicting and poorly supported relationships among geographically structured clades; these inconsistencies preclude confident use of A. carolinensis evolutionary...
Show moreThe green anole (Anolis carolinensis) is a lizard widespread throughout the southeastern United States and is a model organism for the study of reproductive behavior, physiology, neural biology, and genomics. Previous phylogeographic studies of A. carolinensis using mitochondrial DNA and small numbers of nuclear loci identified conflicting and poorly supported relationships among geographically structured clades; these inconsistencies preclude confident use of A. carolinensis evolutionary history in association with morphological, physiological, or reproductive biology studies among sampling localities and necessitate increased effort to resolve evolutionary relationships among natural populations. Here, we used anchored hybrid enrichment of hundreds of genetic markers across the genome of A. carolinensis and identified five strongly supported phylogeographic groups. Using multiple analyses, we produced a fully resolved species tree, investigated relative support for each lineage across all gene trees, and identified mito-nuclear discordance when comparing our results to previous studies. We found fixed differences in only one clade-southern Florida restricted to the Everglades region-while most polymorphisms were shared between lineages. The southern Florida group likely diverged from other populations during the Pliocene, with all other diversification during the Pleistocene. Multiple lines of support, including phylogenetic relationships, a latitudinal gradient in genetic diversity, and relatively more stable long-term population sizes in southern phylogeographic groups, indicate that diversification in A. carolinensis occurred northward from southern Florida.
Show less
Date Issued
2016-11
Identifier
FSU_libsubv1_wos_000387664500017, 10.1002/ece3.2547
Format
Citation
Anchored enrichment dataset for true flies (order Diptera) reveals insights into the phylogeny of flower flies (family Syrphidae)
Title
Anchored Enrichment Dataset For True Flies (order Diptera) Reveals Insights Into The Phylogeny Of Flower Flies (family Syrphidae).
Creator
Young, Andrew Donovan, Lemmon, Alan R., Skevington, Jeffrey H., Mengual, Ximo, Stahls, Gunilla, Reemer, Menno, Jordaens, Kurt, Kelso, Scott, Lemmon, Emily Moriarty, Hauser,...
Show moreYoung, Andrew Donovan, Lemmon, Alan R., Skevington, Jeffrey H., Mengual, Ximo, Stahls, Gunilla, Reemer, Menno, Jordaens, Kurt, Kelso, Scott, Lemmon, Emily Moriarty, Hauser, Martin, De Meyer, Marc, Misof, Bernhard, Wiegmann, Brian M.
Show less
Abstract/Description
Background: Anchored hybrid enrichment is a form of next-generation sequencing that uses oligonucleotide probes to target conserved regions of the genome flanked by less conserved regions in order to acquire data useful for phylogenetic inference from a broad range of taxa. Once a probe kit is developed, anchored hybrid enrichment is superior to traditional PCR-based Sanger sequencing in terms of both the amount of genomic data that can be recovered and effective cost. Due to their incredibly...
Show moreBackground: Anchored hybrid enrichment is a form of next-generation sequencing that uses oligonucleotide probes to target conserved regions of the genome flanked by less conserved regions in order to acquire data useful for phylogenetic inference from a broad range of taxa. Once a probe kit is developed, anchored hybrid enrichment is superior to traditional PCR-based Sanger sequencing in terms of both the amount of genomic data that can be recovered and effective cost. Due to their incredibly diverse nature, importance as pollinators, and historical instability with regard to subfamilial and tribal classification, Syrphidae (flower flies or hoverflies) are an ideal candidate for anchored hybrid enrichment-based phylogenetics, especially since recent molecular phylogenies of the syrphids using only a few markers have resulted in highly unresolved topologies. Over 6200 syrphids are currently known and uncovering their phylogeny will help us to understand how these species have diversified, providing insight into an array of ecological processes, from the development of adult mimicry, the origin of adult migration, to pollination patterns and the evolution of larval resource utilization. Results: We present the first use of anchored hybrid enrichment in insect phylogenetics on a dataset containing 30 flower fly species from across all four subfamilies and 11 tribes out of 15. To produce a phylogenetic hypothesis, 559 loci were sampled to produce a final dataset containing 217,702 sites. We recovered a well resolved topology with bootstrap support values that were almost universally >95 %. The subfamily Eristalinae is recovered as paraphyletic, with the strongest support for this hypothesis to date. The ant predators in the Microdontinae are sister to all other syrphids. Syrphinae and Pipizinae are monophyletic and sister to each other. Larval predation on soft-bodied hemipterans evolved only once in this family. Conclusions: Anchored hybrid enrichment was successful in producing a robustly supported phylogenetic hypothesis for the syrphids. Subfamilial reconstruction is concordant with recent phylogenetic hypotheses, but with much higher support values. With the newly designed probe kit this analysis could be rapidly expanded with further sampling, opening the door to more comprehensive analyses targeting problem areas in syrphid phylogenetics and ecology.
Show less
Date Issued
2016-06-29
Identifier
FSU_libsubv1_wos_000378675500003, 10.1186/s12862-016-0714-0
Format
Citation
Expanding anchored hybrid enrichment to resolve both deep and shallow relationships within the spider tree of life
Title
Expanding anchored hybrid enrichment to resolve both deep and shallow relationships within the spider tree of life.
Creator
Hamilton, Chris A., Lemmon, Alan R., Lemmon, Emily Moriarty, Bond, Jason E.
Abstract/Description
Background: Despite considerable effort, progress in spider molecular systematics has lagged behind many other comparable arthropod groups, thereby hindering family-level resolution, classification, and testing of important macroevolutionary hypotheses. Recently, alternative targeted sequence capture techniques have provided molecular systematics a powerful tool for resolving relationships across the Tree of Life. One of these approaches, Anchored Hybrid Enrichment (AHE), is designed to...
Show moreBackground: Despite considerable effort, progress in spider molecular systematics has lagged behind many other comparable arthropod groups, thereby hindering family-level resolution, classification, and testing of important macroevolutionary hypotheses. Recently, alternative targeted sequence capture techniques have provided molecular systematics a powerful tool for resolving relationships across the Tree of Life. One of these approaches, Anchored Hybrid Enrichment (AHE), is designed to recover hundreds of unique orthologous loci from across the genome, for resolving both shallow and deep-scale evolutionary relationships within non-model systems. Herein we present a modification of the AHE approach that expands its use for application in spiders, with a particular emphasis on the infraorder Mygalomorphae. Results: Our aim was to design a set of probes that effectively capture loci informative at a diversity of phylogenetic timescales. Following identification of putative arthropod-wide loci, we utilized homologous transcriptome sequences from 17 species across all spiders to identify exon boundaries. Conserved regions with variable flanking regions were then sought across the tick genome, three published araneomorph spider genomes, and raw genomic reads of two mygalomorph taxa. Following development of the 585 target loci in the Spider Probe Kit, we applied AHE across three taxonomic depths to evaluate performance: deep-level spider family relationships (33 taxa, 327 loci); family and generic relationships within the mygalomorph family Euctenizidae (25 taxa, 403 loci); and species relationships in the North American tarantula genus Aphonopelma (83 taxa, 581 loci). At the deepest level, all three major spider lineages (the Mesothelae, Mygalomorphae, and Araneomorphae) were supported with high bootstrap support. Strong support was also found throughout the Euctenizidae, including generic relationships within the family and species relationships within the genus Aptostichus. As in the Euctenizidae, virtually identical topologies were inferred with high support throughout Aphonopelma. Conclusions: The Spider Probe Kit, the first implementation of AHE methodology in Class Arachnida, holds great promise for gathering the types and quantities of molecular data needed to accelerate an understanding of the spider Tree of Life by providing a mechanism whereby different researchers can confidently and effectively use the same loci for independent projects, yet allowing synthesis of data across independent research groups.
Show less
Date Issued
2016-10-13
Identifier
FSU_libsubv1_wos_000386026100002, 10.1186/s12862-016-0769-y
Format
Citation