Your search keyword '"Carbone, Mary Anna"' showing total 5 results

1. Genetic mapping uncovers cis-regulatory landscape of RNA editing.

Author

Ramaswami, Gokul, Deng, Patricia, Zhang, Rui, Carbone, Mary Anna, Mackay, Trudy F. C., and Li, Jin Billy

Published

2015

2. The Drosophila melanogaster Genetic Reference Panel.

Author

Mackay, Trudy F. C., 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 R. H., Barrón, Maite, Bess, Crystal, Blankenburg, Kerstin Petra, Carbone, Mary Anna, Castellano, David, Chaboub, Lesley, Duncan, Laura, and Harris, Zeke

Subjects

DROSOPHILA melanogaster, GENETIC research, PHENOTYPES, GENOMICS, X chromosome, GENE mapping

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. [ABSTRACT FROM AUTHOR]

Published

2012

3. Co-regulated transcriptional networks contribute to natural genetic variation in Drosophila sleep.

Author

Harbison, Susan T., Carbone, Mary Anna, Ayroles, Julien F., Stone, Eric A., Lyman, Richard F., and Mackay, Trudy F. C.

Subjects

*SLEEP disorders, *TRANSCRIPTION factors, *GENETIC polymorphisms, *GENE expression, *CATECHOLAMINES, *DROSOPHILA

Abstract

Sleep disorders are common in humans, and sleep loss increases the risk of obesity and diabetes. Studies in Drosophila have revealed molecular pathways and neural tissues regulating sleep; however, genes that maintain genetic variation for sleep in natural populations are unknown. Here, we characterized sleep in 40 wild-derived Drosophila lines and observed abundant genetic variation in sleep architecture. We associated sleep with genome-wide variation in gene expression to identify candidate genes. We independently confirmed that molecular polymorphisms in Catsup (Catecholamines up) are associated with variation in sleep and that P-element mutations in four candidate genes affect sleep and gene expression. Transcripts associated with sleep grouped into biologically plausible genetically correlated transcriptional modules. We confirmed co-regulated gene expression using P-element mutants. Quantitative genetic analysis of natural phenotypic variation is an efficient method for revealing candidate genes and pathways. [ABSTRACT FROM AUTHOR]

Published

2009

4. Systems genetics of complex traits in Drosophila melanogaster.

Author

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

Subjects

*DROSOPHILA melanogaster, *TRANSCRIPTION factors, *BINDING sites, *PHENOTYPES, *GENETIC research

Abstract

Determining the genetic architecture of complex traits is challenging because phenotypic variation arises from interactions between multiple, environmentally sensitive alleles. We quantified genome-wide transcript abundance and phenotypes for six ecologically relevant traits in D. melanogaster wild-derived inbred lines. We observed 10,096 genetically variable transcripts and high heritabilities for all organismal phenotypes. The transcriptome is highly genetically intercorrelated, forming 241 transcriptional modules. Modules are enriched for transcripts in common pathways, gene ontology categories, tissue-specific expression and transcription factor binding sites. The high degree of transcriptional connectivity allows us to infer genetic networks and the function of predicted genes from annotations of other genes in the network. Regressions of organismal phenotypes on transcript abundance implicate several hundred candidate genes that form modules of biologically meaningful correlated transcripts affecting each phenotype. Overlapping transcripts in modules associated with different traits provide insight into the molecular basis of pleiotropy between complex traits. [ABSTRACT FROM AUTHOR]

Published

2009

5. Genotype by environment interaction for gene expression in Drosophila melanogaster.

Author

Huang, Wen, Carbone, Mary Anna, Lyman, Richard F., Anholt, Robert R. H., and Mackay, Trudy F. C.

Subjects

GENE expression, DROSOPHILA melanogaster, GENOTYPE-environment interaction, BINDING sites, GENE regulatory networks, QUANTITATIVE genetics, REGULATOR genes

Abstract

The genetics of phenotypic responses to changing environments remains elusive. Using whole-genome quantitative gene expression as a model, here we study how the genetic architecture of regulatory variation in gene expression changed in a population of fully sequenced inbred Drosophila melanogaster strains when flies developed in different environments (25 °C and 18 °C). We find a substantial fraction of the transcriptome exhibited genotype by environment interaction, implicating environmentally plastic genetic architecture of gene expression. Genetic variance in expression increases at 18 °C relative to 25 °C for most genes that have a change in genetic variance. Although the majority of expression quantitative trait loci (eQTLs) for the gene expression traits in the two environments are shared and have similar effects, analysis of the environment-specific eQTLs reveals enrichment of binding sites for two transcription factors. Finally, although genotype by environment interaction in gene expression could potentially disrupt genetic networks, the co-expression networks are highly conserved across environments. Genes with higher network connectivity are under stronger stabilizing selection, suggesting that stabilizing selection on expression plays an important role in promoting network robustness. Huang et al. show that developing under different temperatures changes the genetic architecture of regulatory variation in Drosophila melanogaster gene expression yet the co-expression network remains robust. Data suggest that stabilizing selection on gene expression may promote co-expression network robustness. [ABSTRACT FROM AUTHOR]

Published

2020