tauFisher predicts circadian time from a single sample of bulk and single-cell pseudobulk transcriptomic data.
Junyan DuanMichelle N NgoSatya Swaroop KarriLam C TsoiJohann E GudjonssonBabak ShahbabaJohn S LowengrubBogi AndersenPublished in: Nature communications (2024)
As the circadian clock regulates fundamental biological processes, disrupted clocks are often observed in patients and diseased tissues. Determining the circadian time of the patient or the tissue of focus is essential in circadian medicine and research. Here we present tauFisher, a computational pipeline that accurately predicts circadian time from a single transcriptomic sample by finding correlations between rhythmic genes within the sample. We demonstrate tauFisher's performance in adding timestamps to both bulk and single-cell transcriptomic samples collected from multiple tissue types and experimental settings. Application of tauFisher at a cell-type level in a single-cell RNAseq dataset collected from mouse dermal skin implies that greater circadian phase heterogeneity may explain the dampened rhythm of collective core clock gene expression in dermal immune cells compared to dermal fibroblasts. Given its robustness and generalizability across assay platforms, experimental setups, and tissue types, as well as its potential application in single-cell RNAseq data analysis, tauFisher is a promising tool that facilitates circadian medicine and research.
Keyphrases
- single cell
- rna seq
- high throughput
- gene expression
- data analysis
- end stage renal disease
- dna methylation
- newly diagnosed
- wound healing
- chronic kidney disease
- genome wide
- prognostic factors
- machine learning
- blood pressure
- big data
- patient reported outcomes
- artificial intelligence
- functional connectivity
- resting state