Nucleoid openness profiling links bacterial genome structure to phenotype

Abstract

ABSTRACTGene expression requires specific structural alternations in the nucleoid structure to enable the access of the transcription machinery into the genomic DNA. In prokaryotes, DNA binding proteins, including nucleoid-associated proteins (NAPs) and transcription factors (TFs), drive the change in structure and gene expression. Currently, studies of global NAP and TF binding are often hindered by the lack of appropriate epigenomic tools. Here, we present POP-seq, a method that provides in vivo genome-wide openness profiles of the bacterial nucleoid. We demonstrate that POP-seq can be used to map the global in vivo protein-DNA binding events. Our results highlight a negative correlation between genome openness, compaction and transcription, suggesting that regions that are not accessible to Tn5 transposase are either too compacted or occupied by RNA polymerase. Importantly, we also show that the least open regions are enriched in housekeeping genes, while the most open regions are significantly enriched in genes important for fast adaptation to changing environment. Finally, we demonstrated that the genome openness profile is growth condition specific. Together, those results suggest a model where one can distinguish two types of epigenetic control: one stable, long-term silencing of highly compacted regions, and a second, highly responsive regulation through the dynamic competition between NAPs and RNA polymerase binding. Overall, POP-seq captures structural changes in the prokaryotic chromatin and provides condition-specific maps of global protein-DNA binding events, thus linking overall transcriptional and epigenetic regulation directly to phenotype.