Mapping and quantifying nascent transcript start sites using TT-TSS-seq

Transcription initiation is a highly dynamic and tightly regulated process involving the coordinated action of transcription factors, chromatin remodelers, and RNA polymerase which determine where and when transcription begins. Accurately mapping and quantifying transcription start sites (TSSs) from nascently transcribed RNAs remains a key area of interest, as it provides critical insights into transcription dynamics. Here, we combined transient transcriptome sequencing with transcription start site sequencing (TT-TSS-seq) to accurately map and quantify transcription initiation sites from nascent transcripts. Since transient metabolic labelling yields low-input RNA, we optimized the TSS-seq protocol to enhance sensitivity and accuracy. Specifically, we refined enzymatic reactions for decapping and RNA ligation and incorporated 5' oligonucleotides including unique molecular identifiers (UMIs) and barcodes to enable accurate quantification and sample multiplexing. The TT-TSS-seq approach detected transcription initiation of unstable transcripts, such as enhancer RNAs. Moreover, we identified that a large fraction of genes use multiple transcription initiation sites, yet often produce only a single stable transcript. Overall, TT-TSS-seq provides precise mapping and quantification of transcription initiation sites, offering new insights into transcriptional dynamics and expanding the toolkit for studying gene regulation. S288C S. cerevisea, and HM1 mESC cells.