Your search keyword '"Anthony D. Long"' showing total 3 results

1. Adaptation in Outbred Sexual Yeast is Repeatable, Polygenic and Favors Rare Haplotypes

Author

Behzad Zabanavar, Hannah Chiao-Shyan Hoang, Arundhati Majumder, Vy Thoai La, Vanessa Genesaret Delgado, Robert A. Linder, Ryan Tran, Simon William Leemans, and Anthony D. Long

Subjects

Haplotype, Outcrossing, Saccharomyces cerevisiae, Biology, Genome, Effective population size, Pleiotropy, Evolutionary biology, Genetics, Allele, Adaptation, Molecular Biology, Selection (genetic algorithm), Ecology, Evolution, Behavior and Systematics

Abstract

We carried out a 200 generation Evolve and Resequence (E&R) experiment initiated from an outbred diploid recombined 18-way synthetic base population. Replicate populations were evolved at large effective population sizes (>105 individuals), exposed to several different chemical challenges over 12 weeks of evolution, and whole-genome resequenced. Weekly forced outcrossing resulted in an average between adjacent-gene per cell division recombination rate of ∼0.0008. Despite attempts to force weekly sex, roughly half of our populations evolved cheaters and appear to be evolving asexually. Focusing on seven chemical stressors and 55 total evolved populations that remained sexual we observed large fitness gains and highly repeatable patterns of genome-wide haplotype change within chemical challenges, with limited levels of repeatability across chemical treatments. Adaptation appears highly polygenic with almost the entire genome showing significant and consistent patterns of haplotype change with little evidence for long-range linkage disequilibrium in a subset of populations for which we sequenced haploid clones. That is, almost the entire genome is under selection or drafting with selected sites. At any given locus adaptation was almost always dominated by one of the 18 founder's alleles, with that allele varying spatially and between treatments, suggesting that selection acts primarily on rare variants private to a founder or haplotype blocks harboring multiple mutations.

Published

2022

2. The Power to Detect Quantitative Trait Loci Using Resequenced, Experimentally Evolved Populations of Diploid, Sexual Organisms

Author

Kevin R. Thornton, James G. Baldwin-Brown, and Anthony D. Long

Subjects

0106 biological sciences, evolve and resequence, Population genetics, Genes, Insect, 01 natural sciences, Gene Frequency, Effective population size, Models, Methods, Genetics, 0303 health sciences, Experimental evolution, adaptive evolution, Population size, Selection coefficient, Single Nucleotide, simulation, Drosophila melanogaster, Sequence Analysis, Biotechnology, Genetic Markers, Evolution, Quantitative Trait Loci, Locus (genetics), Biology, Polymorphism, Single Nucleotide, 010603 evolutionary biology, Evolution, Molecular, 03 medical and health sciences, Genetic, genomics, Animals, Computer Simulation, experimental evolution, Polymorphism, Molecular Biology, Allele frequency, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Evolutionary Biology, Models, Genetic, Genetic Drift, Human Genome, Haplotype, Molecular, Sequence Analysis, DNA, DNA, Diploidy, Genes, Biochemistry and Cell Biology, Lod Score, Insect, QTL detection

Abstract

A novel approach for dissecting complex traits is to experimentally evolve laboratory populations under a controlled environment shift, resequence the resulting populations, and identify single nucleotide polymorphisms (SNPs) and/or genomic regions highly diverged in allele frequency. To better understand the power and localization ability of such an evolve and resequence (E&R) approach, we carried out forward-in-time population genetics simulations of 1 Mb genomic regions under a large combination of experimental conditions, then attempted to detect significantly diverged SNPs. Our analysis indicates that the ability to detect differentiation between populations is primarily affected by selection coefficient, population size, number of replicate populations, and number of founding haplotypes. We estimate that E&R studies can detect and localize causative sites with 80% success or greater when the number of founder haplotypes is over 500, experimental populations are replicated at least 25-fold, population size is at least 1,000 diploid individuals, and the selection coefficient on the locus of interest is at least 0.1. More achievable experimental designs (less replicated, fewer founder haplotypes, smaller effective population size, and smaller selection coefficients) can have power of greater than 50% to identify a handful of SNPs of which one is likely causative. Similarly, in cases where s 0.2, less demanding experimental designs can yield high power. © 2014 The Author.

Published

2014

3. Abundance and Distribution of Transposable Elements in Two Drosophila QTL Mapping Resources

Author

Julie M. Cridland, Stuart J. Macdonald, Anthony D. Long, and Kevin R. Thornton

Subjects

Male, Population genetics, Genome, 0302 clinical medicine, Models, Genetics, 0303 health sciences, DSPR, food and beverages, Single Nucleotide, transposable element, Drosophila melanogaster, Multigene Family, Female, Biotechnology, Transposable element, X Chromosome, Evolution, 1.1 Normal biological development and functioning, Quantitative Trait Loci, Genomics, Quantitative trait locus, Biology, Polymorphism, Single Nucleotide, Evolution, Molecular, 03 medical and health sciences, Genetic, Gene mapping, genomics, Animals, Gene family, Selection, Genetic, Polymorphism, Selection, Molecular Biology, Gene, Discoveries, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Evolutionary Biology, Models, Genetic, Human Genome, Computational Biology, Molecular, population genetics, DNA Transposable Elements, Genetic Fitness, Generic health relevance, Biochemistry and Cell Biology, DGRP, 030217 neurology & neurosurgery

Abstract

Here we present computational machinery to efficiently and accurately identify transposable element (TE) insertions in 146 next-generation sequenced inbred strains of Drosophila melanogaster. The panel of lines we use in our study is composed of strains from a pair of genetic mapping resources: The Drosophila Genetic Reference Panel (DGRP) and the Drosophila Synthetic Population Resource (DSPR). We identified 23,087 TE insertions in these lines, of which 83.3% are found in only one line. There are marked differences in the distribution of elements over the genome, with TEs found at higher densities on the X chromosome, and in regions of low recombination. We also identified many more TEs per base pair of intronic sequence and fewer TEs per base pair of exonic sequence than expected if TEs are located at random locations in the euchromatic genome. There was substantial variation in TE load across genes. For example, the paralogs derailed and derailed-2 show a significant difference in the number of TE insertions, potentially reflecting differences in the selection acting on these loci. When considering TE families, we find a very weak effect of gene family size on TE insertions per gene, indicating that as gene family size increases the number of TE insertions in a given gene within that family also increases. TEs are known to be associated with certain phenotypes, and our data will allow investigators using the DGRP and DSPR to assess the functional role of TE insertions in complex trait variation more generally. Notably, because most TEs are very rare and often private to a single line, causative TEs resulting in phenotypic differences among individuals may typically fail to replicate across mapping panels since individual elements are unlikely to segregate in both panels. Our data suggest that "burden tests" that test for the effect of TEs as a class may be more fruitful. © The Author 2013. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution. All rights reserved.

Published

2013