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1. Population genomics of the Wolbachia endosymbiont in Drosophila melanogaster

Author

Richardson, Mark F., Weinert, Lucy A., Welch, John J., Linheiro, Raquel S., Magwire, Michael M., Jiggins, Francis M., and Bergman, Casey M.

Subjects
Quantitative Biology - Populations and Evolution, Quantitative Biology - Genomics
Abstract

Wolbachia are maternally-inherited symbiotic bacteria commonly found in arthropods, which are able to manipulate the reproduction of their host in order to maximise their transmission. Here we use whole genome resequencing data from 290 lines of Drosophila melanogaster from North America, Europe and Africa to predict Wolbachia infection status, estimate cytoplasmic genome copy number, and reconstruct Wolbachia and mtDNA genome sequences. Complete Wolbachia and mitochondrial genomes show congruent phylogenies, consistent with strict vertical transmission through the maternal cytoplasm and imperfect transmission of Wolbachia. Bayesian phylogenetic analysis reveals that the most recent common ancestor of all Wolbachia and mitochondrial genomes in D. melanogaster dates to around 8,000 years ago. We find evidence for a recent incomplete global replacement of ancestral Wolbachia and mtDNA lineages, which is likely to be one of several similar incomplete replacement events that have occurred since the out-of-Africa migration that allowed D. melanogaster to colonize worldwide habitats., Comment: 41 pages, 5 figures

Published
2012
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2. The Drosophila melanogaster Genetic Reference Panel.

Author

Mackay, Trudy FC, Richards, Stephen, Stone, Eric A, Barbadilla, Antonio, Ayroles, Julien F, Zhu, Dianhui, Casillas, Sònia, Han, Yi, Magwire, Michael M, Cridland, Julie M, Richardson, Mark F, Anholt, Robert RH, Barrón, Maite, Bess, Crystal, Blankenburg, Kerstin Petra, Carbone, Mary Anna, Castellano, David, Chaboub, Lesley, Duncan, Laura, Harris, Zeke, Javaid, Mehwish, Jayaseelan, Joy Christina, Jhangiani, Shalini N, Jordan, Katherine W, Lara, Fremiet, Lawrence, Faye, Lee, Sandra L, Librado, Pablo, Linheiro, Raquel S, Lyman, Richard F, Mackey, Aaron J, Munidasa, Mala, Muzny, Donna Marie, Nazareth, Lynne, Newsham, Irene, Perales, Lora, Pu, Ling-Ling, Qu, Carson, Ràmia, Miquel, Reid, Jeffrey G, Rollmann, Stephanie M, Rozas, Julio, Saada, Nehad, Turlapati, Lavanya, Worley, Kim C, Wu, Yuan-Qing, Yamamoto, Akihiko, Zhu, Yiming, Bergman, Casey M, Thornton, Kevin R, Mittelman, David, and Gibbs, Richard A

Subjects
X Chromosome, Centromere, Telomere, Animals, Drosophila melanogaster, Starvation, Genomics, Genotype, Phenotype, Polymorphism, Single Nucleotide, Alleles, Quantitative Trait Loci, Genome-Wide Association Study, Selection, Genetic, Chromosomes, Insect, Chromosomes, Insect, Polymorphism, Single Nucleotide, Selection, Genetic, General Science & Technology
Abstract

A major challenge of biology is understanding the relationship between molecular genetic variation and variation in quantitative traits, including fitness. This relationship determines our ability to predict phenotypes from genotypes and to understand how evolutionary forces shape variation within and between species. Previous efforts to dissect the genotype-phenotype map were based on incomplete genotypic information. Here, we describe the Drosophila melanogaster Genetic Reference Panel (DGRP), a community resource for analysis of population genomics and quantitative traits. The DGRP consists of fully sequenced inbred lines derived from a natural population. Population genomic analyses reveal reduced polymorphism in centromeric autosomal regions and the X chromosome, evidence for positive and negative selection, and rapid evolution of the X chromosome. Many variants in novel genes, most at low frequency, are associated with quantitative traits and explain a large fraction of the phenotypic variance. The DGRP facilitates genotype-phenotype mapping using the power of Drosophila genetics.

Published
2012

5. Epistasis dominates the genetic architecture of Drosophila quantitative traits

Author

Huang, Wen, Richards, Stephen, Carbone, Mary Anna, Zhu, Dianhui, Anholt, Robert R. H., Ayroles, Julien F., Duncan, Laura, Jordan, Katherine W., Lawrence, Faye, Magwire, Michael M., Warner, Crystal B., Blankenburg, Kerstin, Han, Yi, Javaid, Mehwish, Jayaseelan, Joy, Jhangiani, Shalini N., Muzny, Donna, Ongeri, Fiona, Perales, Lora, Wu, Yuan-Qing, Zhang, Yiqing, Zou, Xiaoyan, Stone, Eric A., Gibbs, Richard A., and Mackay, Trudy F. C.

Published
2012

8. Epistasis for head morphology in Drosophila melanogaster

Author

Özsoy, Ergi D, primary, Yılmaz, Murat, additional, Patlar, Bahar, additional, Emecen, Güzin, additional, Durmaz, Esra, additional, Magwire, Michael M, additional, Zhou, Shanshan, additional, Huang, Wen, additional, Anholt, Robert R H, additional, and Mackay, Trudy F C, additional

Published
2021
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22. Genome-wide analysis in Drosophila reveals age-specific effects of SNPs on fitness traits

Author

Durham, Mary F, Magwire, Michael M, Stone, Eric, Leips, Jeff, Durham, Mary F, Magwire, Michael M, Stone, Eric, and Leips, Jeff

Abstract

Most organisms exhibit senescence; a decline in physiological function with age. In nature, rates of senescence vary extensively among individuals and this variation has a significant genetic component; however, we know little about the genes underlying senescence. Here we show the first evidence that individual alleles influence fecundity in an age-specific manner and so the genetic basis of natural variation in fecundity changes dramatically with age. We complete a genome-wide association to identify single-nucleotide polymorphisms (SNPs) affecting lifespan and age-specific fecundity using the Drosophila melanogaster Genetic Reference Panel. We identify 1,031 SNPs affecting fecundity and 52 influencing lifespan. Only one SNP is associated with both early- and late-age fecundity. The age-specific effect of candidate genes on fecundity is validated using RNA interference. In addition, there is a dramatic increase in the number of SNPs influencing fecundity with age. This result provides support for the mutation accumulation theory of aging

Published
2014

24. Natural variation in genome architecture among 205 Drosophila melanogaster Genetic Reference Panel lines

Author

Huang, Wen, primary, Massouras, Andreas, additional, Inoue, Yutaka, additional, Peiffer, Jason, additional, Ràmia, Miquel, additional, Tarone, Aaron M., additional, Turlapati, Lavanya, additional, Zichner, Thomas, additional, Zhu, Dianhui, additional, Lyman, Richard F., additional, Magwire, Michael M., additional, Blankenburg, Kerstin, additional, Carbone, Mary Anna, additional, Chang, Kyle, additional, Ellis, Lisa L., additional, Fernandez, Sonia, additional, Han, Yi, additional, Highnam, Gareth, additional, Hjelmen, Carl E., additional, Jack, John R., additional, Javaid, Mehwish, additional, Jayaseelan, Joy, additional, Kalra, Divya, additional, Lee, Sandy, additional, Lewis, Lora, additional, Munidasa, Mala, additional, Ongeri, Fiona, additional, Patel, Shohba, additional, Perales, Lora, additional, Perez, Agapito, additional, Pu, LingLing, additional, Rollmann, Stephanie M., additional, Ruth, Robert, additional, Saada, Nehad, additional, Warner, Crystal, additional, Williams, Aneisa, additional, Wu, Yuan-Qing, additional, Yamamoto, Akihiko, additional, Zhang, Yiqing, additional, Zhu, Yiming, additional, Anholt, Robert R.H., additional, Korbel, Jan O., additional, Mittelman, David, additional, Muzny, Donna M., additional, Gibbs, Richard A., additional, Barbadilla, Antonio, additional, Johnston, J. Spencer, additional, Stone, Eric A., additional, Richards, Stephen, additional, Deplancke, Bart, additional, and Mackay, Trudy F.C., additional

Published
2014
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25. Population genomics of the Wolbachia endosymbiont in Drosophila melanogaster

Author

Richardson, Mark F, Weinert, Lucy A, Welch, John J, Linheiro, Raquel S, Magwire, Michael M, Jiggins, Francis M, Bergman, Casey M, Richardson, Mark F, Weinert, Lucy A, Welch, John J, Linheiro, Raquel S, Magwire, Michael M, Jiggins, Francis M, and Bergman, Casey M

Abstract

Wolbachia are maternally inherited symbiotic bacteria, commonly found in arthropods, which are able to manipulate the reproduction of their host in order to maximise their transmission. The evolutionary history of endosymbionts like Wolbachia can be revealed by integrating information on infection status in natural populations with patterns of sequence variation in Wolbachia and host mitochondrial genomes. Here we use whole-genome resequencing data from 290 lines of Drosophila melanogaster from North America, Europe, and Africa to predict Wolbachia infection status, estimate relative cytoplasmic genome copy number, and reconstruct Wolbachia and mitochondrial genome sequences. Overall, 63% of Drosophila strains were predicted to be infected with Wolbachia by our in silico analysis pipeline, which shows 99% concordance with infection status determined by diagnostic PCR. Complete Wolbachia and mitochondrial genomes show congruent phylogenies, consistent with strict vertical transmission through the maternal cytoplasm and imperfect transmission of Wolbachia. Bayesian phylogenetic analysis reveals that the most recent common ancestor of all Wolbachia and mitochondrial genomes in D. melanogaster dates to around 8,000 years ago. We find evidence for a recent global replacement of ancestral Wolbachia and mtDNA lineages, but our data suggest that the derived wMel lineage arose several thousand years ago, not in the 20th century as previously proposed. Our data also provide evidence that this global replacement event is incomplete and is likely to be one of several similar incomplete replacement events that have occurred since the out-of-Africa migration that allowed D. melanogaster to colonize worldwide habitats. This study provides a complete genomic analysis of the evolutionary mode and temporal dynamics of the D. melanogaster–Wolbachia symbiosis, as well as important resources for further analyses of the impact of Wolbachia on host biology.

Published
2012

34. Systems genetics of complex traits in Drosophila melanogaster

Author

Ayroles, Julien F, primary, Carbone, Mary Anna, additional, Stone, Eric A, additional, Jordan, Katherine W, additional, Lyman, Richard F, additional, Magwire, Michael M, additional, Rollmann, Stephanie M, additional, Duncan, Laura H, additional, Lawrence, Faye, additional, Anholt, Robert R H, additional, and Mackay, Trudy F C, additional

Published
2009
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36. Longevity GWAS Using the Drosophila Genetic Reference Panel.

Author

Ivanov, Dobril K., Escott-Price, Valentina, Ziehm, Matthias, Magwire, Michael M., Mackay, Trudy F. C., Partridge, Linda, and Thornton, Janet M.

Subjects
DROSOPHILA genetics, DROSOPHILA melanogaster, LIFE spans, SINGLE nucleotide polymorphisms, GENE ontology, RAPAMYCIN, GENE frequency, GENETIC mutation, INSECT physiology, ANIMAL experimentation, GENETIC polymorphisms, INSECTS, LONGEVITY, RESEARCH funding, SEQUENCE analysis, IMPACT of Event Scale
Abstract

We used 197 Drosophila melanogaster Genetic Reference Panel (DGRP) lines to perform a genome-wide association analysis for virgin female lifespan, using ~2M common single nucleotide polymorphisms (SNPs). We found considerable genetic variation in lifespan in the DGRP, with a broad-sense heritability of 0.413. There was little power to detect signals at a genome-wide level in single-SNP and gene-based analyses. Polygenic score analysis revealed that a small proportion of the variation in lifespan (~4.7%) was explicable in terms of additive effects of common SNPs (≥2% minor allele frequency). However, several of the top associated genes are involved in the processes previously shown to impact ageing (eg, carbohydrate-related metabolism, regulation of cell death, proteolysis). Other top-ranked genes are of unknown function and provide promising candidates for experimental examination. Genes in the target of rapamycin pathway (TOR; Chrb, slif, mipp2, dredd, RpS9, dm) contributed to the significant enrichment of this pathway among the top-ranked 100 genes (p = 4.79×10(-06)). Gene Ontology analysis suggested that genes involved in carbohydrate metabolism are important for lifespan; including the InterPro term DUF227, which has been previously associated with lifespan determination. This analysis suggests that our understanding of the genetic basis of natural variation in lifespan from induced mutations is incomplete. [ABSTRACT FROM AUTHOR]

Published
2015
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37. Genetic basis of transcriptome diversity in Drosophila melanogaster.

Author

Wen Huang, Carbone, Mary Anna, Magwire, Michael M., Peiffer, Jason A., Lyman, Richard F., Stone, Eric A., Anholt, Robert R. H., and Mackay, Trudy F. C.

Subjects
GENOMICS, NUCLEOTIDE sequence, PHENOTYPES, EVOLUTION research, GENE expression, DROSOPHILA genetics
Abstract

Understanding how DNA sequence variation is translated into variation for complex phenotypes has remained elusive but is essential for predicting adaptive evolution, for selecting agriculturally important animals and crops, and for personalized medicine. Gene expression may provide a link between variation in DNA sequence and organismal phenotypes, and its abundance can be measured efficiently and accurately. Here we quantified genome-wide variation in gene expression in the sequenced inbred lines of the Drosophila melanogaster Genetic Reference Panel (DGRP), increasing the annotated Drosophila transcriptome by 11%, including thousands of novel transcribed regions (NTRs). We found that 42% of the Drosophila transcriptome is genetically variable in males Drosophila and females, including the NTRs, and is organized into modules of genetically correlated transcripts. We found that NTRs often were negatively correlated with the expression of protein-coding genes, which we exploited to annotate NTRs functionally. We identified regulatory variants for the mean and variance of gene expression, which have largely independent genetic control. Expression quantitative trait loci (eQTLs) for the mean, but not for the variance, of gene expression were concentrated near genes. Notably, the variance eQTLs often interacted epistatically with local variants in these genes to regulate gene expression. This comprehensive characterization of population-scale diversity of transcriptomes and its genetic basis in the DGRP is critically important for a systems understanding of quantitative trait variation. [ABSTRACT FROM AUTHOR]

Published
2015
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39. Epistasis dominates the genetic architecture of Drosophila quantitative traits.

Author

Wen Huang, Richards, Stephen, Carbone, Mary Anna, Zhu, Dianhui, Anholt, Robert R. H., Ayroles, Julien F., Duncan, Laura, Jordan, Katherine W., Lawrence, Faye, Magwire, Michael M., Warner, Crystal B., Blankenburg, Kerstin, Han, Yi, Javaid, Mehwish, Jayaseelan, Joy, Jhangianl, Shalini N., Muzny, Donna, Ongeri, Fiona, Perales, Lora, and Yuan-Qing Wu

Subjects
DROSOPHILA genetics, EPISTASIS (Genetics), QUANTITATIVE research, GENETIC polymorphisms, STARTLE reaction, NUCLEOTIDE sequence
Abstract

Epistasis-nonlinear genetic interactions between polymorphic loci-is the genetic basis of canalization and speciation, and epistatic interactions can be used to infer genetic networks affecting quantitative traits. However, the role that epistasis plays in the genetic architecture of quantitative traits is controversial. Here, we compared the genetic architecture of three Drosophila life history traits in the sequenced inbred lines of the Drosophila melanogaster Genetic Reference Panel (DGRP) and a large outbred, advanced intercross population derived from 40 DGRP lines (Flyland). We assessed allele frequency changes between pools of individuals at the extremes of the distribution for each trait in the Flyland population by deep DNA sequencing. The genetic architecture of all traits was highly polygenic in both analyses. Surprisingly, none of the SNPs associated with the traits in Flyland replicated in the DGRP and vice versa. However, the majority of these SNPs participated in at least one epistatic interaction in the DGRP. Despite apparent additive effects at largely distinct loci in the two populations, the epistatic interactions perturbed common, biologically plausible, and highly connected genetic networks. Our analysis underscores the importance of epistasis as a principal factor that determines variation for quantitative traits and provides a means to uncover genetic networks affecting these traits. Knowledge of epistatic networks will contribute to our understanding of the genetic basis of evolutionarily and clinically important traits and enhance predictive ability at an individualized level in medicine and agriculture. [ABSTRACT FROM AUTHOR]

Published
2012
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40. Mutations Increasing Drosophila melanogaster Life Span

Author

Magwire, Michael M

Subjects
longevity
Abstract

I have assessed longevity in a collection of 1332 co-isogenic gene-trap P-element insertion lines and determined changes in life span of each insert line relative to a corresponding control line. After a secondary screen to validate an effect on phenotype, 58 insert lines were significant for an increase in life span. Starvation resistance, chill coma recovery time and climbing activity were measured on these lines to identify pleiotropic effects. A positive correlation was found for males between life span and starvation resistance as well as between life span and chill coma recovery. Females only displayed a correlation between life span and chill coma recovery, which was negative. None of the lines indicated increased fitness for all phenotypes, indicating there may be some type of trade-off. There also appears to be a lot of pleiotropic variation depending on background and sex. Ten of the lines, all with the same parental background, were chosen for a half-diallel cross to identify epistasis between the mutants. There were substantial epistatic interactions between all ten lines. Furthermore, males and females displayed vastly different patterns of epistasis, again indicating major differences in life span regulation between the sexes. Finally, a subset of seven of the lines used in the epistatic study, in addition to the corresponding parental control, were chosen for microarray analysis to look for possible pathways and novel genes involved in increasing life span. 1,996 probe sets were significant at a false discovery rate q-value threshold of q ≤ 0.0001. Tukeys tests were carried out for these probe sets to determine how each of the seven mutant backgrounds differed compared to the control and each other. In addition, each mutant background was compared individually with the control to identify any changes in expression. Gene ontologies were determined for each of the lines to identify over-represented biological functions which would indicate possible longevity pathways. Dozens of pathways were suggested, including several novel pathways.

Published
2007

41. Epistasis for head morphology in Drosophila melanogaster.

Author

Özsoy ED, Yılmaz M, Patlar B, Emecen G, Durmaz E, Magwire MM, Zhou S, Huang W, Anholt RRH, and Mackay TFC

Subjects
Alleles, Animals, Chromosome Mapping, Genome-Wide Association Study, Drosophila melanogaster genetics, Epistasis, Genetic
Abstract

Epistasis-gene-gene interaction-is common for mutations with large phenotypic effects in humans and model organisms. Epistasis impacts quantitative genetic models of speciation, response to natural and artificial selection, genetic mapping, and personalized medicine. However, the existence and magnitude of epistasis between alleles with small quantitative phenotypic effects are controversial and difficult to assess. Here, we use the Drosophila melanogaster Genetic Reference Panel of sequenced inbred lines to evaluate the magnitude of naturally occurring epistasis modifying the effects of mutations in jing and inv, two transcription factors that have subtle quantitative effects on head morphology as homozygotes. We find significant epistasis for both mutations and performed single marker genome-wide association analyses to map candidate modifier variants and loci affecting head morphology. A subset of these loci was significantly enriched for a known genetic interaction network, and mutations of the candidate epistatic modifier loci also affect head morphology., (© The Author(s) 2021. Published by Oxford University Press on behalf of Genetics Society of America.)

Published
2021
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