Shen, P.; Wolfe, M. B.; Saba, J.; Mooney, R.; Bao, Y.; Ahmad, E.; Landick, R.; Cao, X.

Mechanistic dissection of gene transcription and its regulation in diverse organisms remains a central challenge for molecular biology. In vivo analyses using high-throughput DNA sequencing readouts (e.g., RNA-seq, Term-seq, and NET-seq) have revealed that transcriptional pausing by RNA polymerase (RNAP) underpins the regulation of gene transcription. However, these in vivo methods are difficult to apply in non-model organisms and lack the power of bottom-up biochemical analysis that can deconvolute the confounding effects of the cellular environment. Here we report a method for unbiased transcription of entire genomes in vitro called RNAP-seq, which is capable of defining pause, arrest, and termination sites with single-nucleotide resolution and of defining the regulatory contributions of cis-acting RNA and DNA sequences and dissociable transcription factors with complete control over transcription conditions. Using RNAP-seq to compare transcription by recombinant RNAPs from Clostridioides difficile (Cdf) and Escherichia coli (Eco), we discovered that CdfRNAP exhibits pausing signatures distinct from EcoRNAP. CdfRNAP pauses more frequently and more strongly at T-rich sequences, particularly on antisense regions of genes. We also defined the action of CdfNusG at genome scale, revealing its preferential action in riboswitch control regions. These findings demonstrate lineage-specific pausing features and suggest that genome composition and RNAP co-evolve to shape gene expression. RNAP-seq is broadly adaptable to diverse bacterial species and offers a powerful framework for uncovering fundamental principles of transcription that govern gene expression.