Spatial dissimilarity analysis in single-cell transcriptomics

We develop the spatial dissimilarity method to uncover complex bivariate relationships in single-cell and spatial transcriptomics data, addressing challenges such as alternative splicing and allele-specific gene expression. Applying this method to detect alternative splicing in neurons demonstrates improved accuracy and sensitivity compared to existing tools, notably identifying neuron subtypes. In tumor cells, spatial dissimilarity analysis reveals somatic variants that emerge during tumor progression, validated through whole-exome sequencing. These findings highlight how allele-specific genetic variants contribute to the subclone architecture of cancer cells, offering insights into cellular heterogeneity. Applied on a human cell atlas, we uncover numerous cases of allele-specific expression of genes in normal cells. We provide a software package for spatial dissimilarity analysis to enable enhanced understanding of cellular complexity and gene expression dynamics under homeostatic conditions and during states of transitions.