Sheardown, E.; Yan To Ling, J.; van der Burght, S. N.; Vaikkinen, H.; Gowing, B.; Ahringer, J.; Hamid, F.; Ch'ng, Q.

Quantifying transcript abundance at single-cell resolution is important for understanding gene regulation in intact multicellular organisms. In Caenorhabditis elegans, RNA fluorescence in situ hybridization has been widely used to visualize transcripts, but conventional smFISH approaches can be limited by low signal-to-noise, poor performance with short transcripts, and workflows that do not readily support absolute transcript counting in identified cells. Here, we present an integrated experimental and computational pipeline for quantitative transcript analysis in whole-mount C. elegans embryos, larvae, and adults. The pipeline combines Hybridization Chain Reaction (HCR), confocal microscopy, RS-FISH spot detection, manual cell annotation in FIJI, and custom MATLAB-based spot assignment to quantify individual transcripts within defined cells. We show that this approach enables sensitive, specific, and multiplexed detection of transcripts, including short insulin-like peptide mRNAs, with single-cell resolution. Known spatial expression patterns were resolved in embryos, larvae, and adults, and probe specificity was validated using deletion mutants that remove HCR probe-binding sites. Applying this pipeline to ins-4, ins-6, and daf-28 in ASI and ASJ sensory neurons revealed cell-specific and context-dependent regulatory relationships across multiple mutant backgrounds. This workflow provides an accessible method for absolute transcript counting in anatomically intact C. elegans and should support mechanistic studies of gene regulation, cellular heterogeneity, and transcriptional network function.