In vivo quantitative high-throughput screening for drug discovery and comparative toxicology.
Patricia K DranchakErin OliphantBryan QuemeLaurence LamyYuhong WangRuili HuangMenghang XiaDingyin TaoJames InglesePublished in: Disease models & mechanisms (2023)
Quantitative high-throughput screening (qHTS) pharmacologically evaluates chemical libraries for therapeutic uses, toxicological risk and, increasingly, for academic probe discovery. Phenotypic high-throughput screening assays interrogate molecular pathways, often relying on cell culture systems, historically less focused on multicellular organisms. Caenorhabditis elegans has served as a eukaryotic model organism for human biology by virtue of genetic conservation and experimental tractability. Here, a paradigm enabling C. elegans qHTS using 384-well microtiter plate laser-scanning cytometry is described, in which GFP-expressing organisms revealing phenotype-modifying structure-activity relationships guide subsequent life-stage and proteomic analyses, and Escherichia coli bacterial ghosts, a non-replicating nutrient source, allow compound exposures over two life cycles, mitigating bacterial overgrowth complications. We demonstrate the method with libraries of anti-infective agents, or substances of toxicological concern. Each was tested in seven-point titration to assess the feasibility of nematode-based in vivo qHTS, and examples of follow-up strategies were provided to study organism-based chemotype selectivity and subsequent network perturbations with a physiological impact. We anticipate that this qHTS approach will enable analysis of C. elegans orthologous phenotypes of human pathologies to facilitate drug library profiling for a range of therapeutic indications.
Keyphrases
- drug discovery
- endothelial cells
- escherichia coli
- high resolution
- induced pluripotent stem cells
- single cell
- high throughput
- pluripotent stem cells
- gram negative
- emergency department
- risk factors
- small molecule
- drinking water
- gene expression
- multidrug resistant
- dna methylation
- staphylococcus aureus
- cystic fibrosis
- candida albicans
- single molecule