PhyloVelo enhances transcriptomic velocity field mapping using monotonically expressed genes.
Kun WangLiangzhen HouXin WangXiangwei ZhaiZhaolian LuZhike ZiWeiwei ZhaiXiongLei HeChristina CurtisDa ZhouZheng HuPublished in: Nature biotechnology (2023)
Single-cell RNA sequencing (scRNA-seq) is a powerful approach for studying cellular differentiation, but accurately tracking cell fate transitions can be challenging, especially in disease conditions. Here we introduce PhyloVelo, a computational framework that estimates the velocity of transcriptomic dynamics by using monotonically expressed genes (MEGs) or genes with expression patterns that either increase or decrease, but do not cycle, through phylogenetic time. Through integration of scRNA-seq data with lineage information, PhyloVelo identifies MEGs and reconstructs a transcriptomic velocity field. We validate PhyloVelo using simulated data and Caenorhabditis elegans ground truth data, successfully recovering linear, bifurcated and convergent differentiations. Applying PhyloVelo to seven lineage-traced scRNA-seq datasets, generated using CRISPR-Cas9 editing, lentiviral barcoding or immune repertoire profiling, demonstrates its high accuracy and robustness in inferring complex lineage trajectories while outperforming RNA velocity. Additionally, we discovered that MEGs across tissues and organisms share similar functions in translation and ribosome biogenesis.
Keyphrases
- single cell
- rna seq
- crispr cas
- genome wide
- high throughput
- electronic health record
- blood flow
- cell fate
- genome editing
- big data
- bioinformatics analysis
- high resolution
- genome wide identification
- depressive symptoms
- poor prognosis
- dna methylation
- mass spectrometry
- healthcare
- genome wide analysis
- binding protein
- high density
- health information
- social media
- nucleic acid