Multiplexed optical barcoding and sequencing for spatial omics

Abstract

AbstractSpatial omics has brought a fundamental change in the way that we study cell and tissue biology in health and disease. Among various spatial omics methods, genome-scale imaging allows transcriptomic, 3D-genomic, and epigenomic profiling of individual cells with high spatial (subcellular) resolution but often requires a preselection of targeted genes or genomic loci. On the other hand, spatially dependent barcoding of molecules followed by sequencing provides untargeted, genome-wide profiling but typically lacks single-cell resolution. Here, we report a spatial omics method that could potentially combine the power of the two approaches by optically controlled spatial barcoding followed by sequencing. Specifically, we utilize patterned light to encode the locations of cells in tissues using oligonucleotide-based barcodes and then identify the barcoded molecular content, such as mRNAs, by sequencing. This optical barcoding method is designed with multiplexing and error-correction capacity and achieved by a light-directed ligation chemistry that attaches distinct nucleic-acid sequences to the reverse transcribed cDNA products at different locations. As a proof of principle for this method, we demonstrated high-efficiency in situ light-directed ligation, spatially dependent barcoding with multiplexed light-controlled ligations, and high-accuracy detection of spatially barcoded mRNAs in cells.