The 1000 Genomes Toxicity Screening Project: Utilizing the power of human genome variation for population-scale in vitro testing
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Abdo, Nour. The 1000 Genomes Toxicity Screening Project: Utilizing the Power of Human Genome Variation for Population-scale In Vitro Testing. Chapel Hill, NC: University of North Carolina at Chapel Hill Graduate School, 2014. https://doi.org/10.17615/a5xs-p904APA
Abdo, N. (2014). The 1000 Genomes Toxicity Screening Project: Utilizing the power of human genome variation for population-scale in vitro testing. Chapel Hill, NC: University of North Carolina at Chapel Hill Graduate School. https://doi.org/10.17615/a5xs-p904Chicago
Abdo, Nour. 2014. The 1000 Genomes Toxicity Screening Project: Utilizing the Power of Human Genome Variation for Population-Scale In Vitro Testing. Chapel Hill, NC: University of North Carolina at Chapel Hill Graduate School. https://doi.org/10.17615/a5xs-p904- Last Modified
- March 19, 2019
- Creator
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Abdo, Nour
- Affiliation: Gillings School of Global Public Health, Department of Environmental Sciences and Engineering
- Abstract
- Incorporation of novel toxicity screening approaches is a crucial tool for tackling the complex contemporary challenges in evaluating the human health hazards of exposure to chemicals. A shift in toxicity testing from in vivo to in vitro methods may efficiently prioritize compounds, reveal new mechanisms, and enable predictive modeling. Quantitative high-throughput screening (qHTS) is a major source of data for computational toxicology. However, current in vitro testing paradigms such as Tox21 or NexGen still have major gaps that need addressing, such as population-based in vitro approaches to qHTS screening. This study evaluated the hypothesis that comparative population genomics with efficient in vitro experimental design can be used for the evaluation of the potential hazard, mode of action, and the extent of population variability in response to chemicals. In Aim 1, we evaluated and assessed the validity of in vitro genetically-anchored population human model system in assessing chemical toxicity and identifying candidate genetic susceptibility. We screened 81 human lymphoblast cell lines with 240 chemicals at 12 different concentrations and assessed the toxic response using different endpoints (cell death and caspase production). We evaluated the toxic responses to a panel of chemicals observed in lymphoblast cell lines, and compared them to other toxic responses seen with different cell lines that originate from different sources. In Aim 2, we expanded our model to include more than one population, to increase statistical power to detect genetic variants associated with toxicological response. The goals were to(1) quantitatively assess population-based toxicological hazard to environmental contaminants, (2) determine the extent of human inter-individual variability in chemical toxicity, identify susceptible sub-populations or races, (3) understand the genetic determinants of the inter-individual variability, (4) generate testable hypotheses about toxicity pathways by leveraging genetic and genomic data from 1000 Genomes and HapMap Projects, and (5) use the data obtained from this research to build predictive in silico models. In Aim 3, we addressed some of the remaining challenges in our model, such as the ability to screen chemical mixtures. We explored the potential and efficiency of our model in assessing new challenges such as the evaluation of environmental chemical mixtures in a population in vitro screening, and the extrapolation of the in vitro hazard to an oral equivalent dose. In summary, this research not only will use novel tools to investigate population genetically anchored variability, but it will also offer exceptional methodology for incorporating scientifically-based estimates of uncertainty in risk assessment.
- Date of publication
- August 2014
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- In Copyright
- Advisor
- Wright, Fred A.
- Fry, Rebecca
- Gold, Avram
- Rusyn, Ivan
- North, Kari
- Degree
- Doctor of Philosophy
- Degree granting institution
- University of North Carolina at Chapel Hill Graduate School
- Graduation year
- 2014
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- Place of publication
- Chapel Hill, NC
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- There are no restrictions to this item.
- Date uploaded
- April 23, 2015
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