High-throughput toxicogenomic screening of chemicals in the environment using metabolically competent hepatic cell cultures.
Jill A FranzosaJessica A BonzoJohn JackNancy C BakerParth KothiyaRafal P WitekPatrick HurbanStephen SiferdSusan HesterImran ShahStephen S FergusonKeith A HouckJohn F WambaughPublished in: NPJ systems biology and applications (2021)
The ToxCast in vitro screening program has provided concentration-response bioactivity data across more than a thousand assay endpoints for thousands of chemicals found in our environment and commerce. However, most ToxCast screening assays have evaluated individual biological targets in cancer cell lines lacking integrated physiological functionality (such as receptor signaling, metabolism). We evaluated differentiated HepaRGTM cells, a human liver-derived cell model understood to effectively model physiologically relevant hepatic signaling. Expression of 93 gene transcripts was measured by quantitative polymerase chain reaction using Fluidigm 96.96 dynamic arrays in response to 1060 chemicals tested in eight-point concentration-response. A Bayesian framework quantitatively modeled chemical-induced changes in gene expression via six transcription factors including: aryl hydrocarbon receptor, constitutive androstane receptor, pregnane X receptor, farnesoid X receptor, androgen receptor, and peroxisome proliferator-activated receptor alpha. For these chemicals the network model translates transcriptomic data into Bayesian inferences about molecular targets known to activate toxicological adverse outcome pathways. These data also provide new insights into the molecular signaling network of HepaRGTM cell cultures.
Keyphrases
- high throughput
- single cell
- gene expression
- electronic health record
- cell therapy
- transcription factor
- rna seq
- emergency department
- mass spectrometry
- dna methylation
- young adults
- deep learning
- signaling pathway
- oxidative stress
- papillary thyroid
- lymph node metastasis
- network analysis
- long non coding rna
- data analysis
- single molecule
- childhood cancer