Positive supercoiling buildup is a trigger of E. coli's short-term response to cold shock

Adaptation to cold shock (CS) is a key survival skill of gut bacteria of warm-blooded animals. In E. coli, this skill emerges from a complex transcriptional program of multiple, timely-ordered shifts in gene expression. We identified short-term, cold shock repressed (CSR) genes by RNA-seq and provide evidence that their variability in evolutionary fitness is low and that their responsiveness to cold emanates from intrinsic features. Given that their single-cell variability in protein numbers increases after CS, we hypothesized that the responsiveness of a large portion of CSR genes is triggered by the high propensity for transcription locking due to positive supercoiling buildup (PSB). We then proposed a model of this phenomenon and, in support, show that nearly half of CSR genes are highly responsive to Gyrase inhibition. Also, their response strengths to CS and Gyrase inhibition correlate and most CSR genes increase their single-cell variability in protein numbers. Further, during CS, the cells' nucleoid density increases (in agreement with increased numbers of positive supercoils), their energy levels become depleted (while the resolving of positive supercoils is ATP dependent), and the colocalization of Gyrases and the nucleoid increases (in agreement with increased time length for resolving supercoils). We conclude that high sensitivity to PSB is at the core of the short-term, cold shock responsive transcriptional program of E. coli and propose that this gene feature may be useful for providing temperature sensitivity to chromosome-integrated synthetic circuits.

High-resolution, genome-wide mapping of positive supercoiling in chromosomes

Supercoiling impacts DNA replication, transcription, protein binding to DNA, and the three-dimensional organization of chromosomes. However, there are currently no methods to directly interrogate or map positive supercoils, so their distribution in genomes remains unknown. Here, we describe a method, GapR-seq, based on the chromatin immunoprecipitation of GapR, a bacterial protein that preferentially recognizes overtwisted DNA, for generating high-resolution maps of positive supercoiling. Applying this method to E. coli and S. cerevisiae, we find that positive supercoiling is widespread, associated with transcription, and particularly enriched between convergently-oriented genes, consistent with the 'twin-domain' model of supercoiling. In yeast, we also find positive supercoils associated with centromeres, cohesin binding sites, autonomously replicating sites, and the borders of R-loops (DNA-RNA hybrids). Our results suggest that GapR-seq is a powerful approach, likely applicable in any organism, to investigate aspects of chromosome structure and organization not accessible by Hi-C or other existing methods.

Cotranscriptional R-loop formation by Mfd involves topological partitioning of DNA

R-loops are nucleic acid hybrids which form when an RNA invades duplex DNA to pair with its template sequence. Although they are implicated in a growing number of gene regulatory processes, their mechanistic origins remain unclear. We here report real-time observations of cotranscriptional R-loop formation at single-molecule resolution and propose a mechanism for their formation. We show that the bacterial Mfd protein can simultaneously interact with both elongating RNA polymerase and upstream DNA, tethering the two together and partitioning the DNA into distinct supercoiled domains. A highly negatively supercoiled domain forms in between Mfd and RNA polymerase, and compensatory positive supercoiling appears in front of the RNA polymerase and behind Mfd. The nascent RNA invades the negatively supercoiled domain and forms a stable R-loop that can drive mutagenesis. This mechanism theoretically enables any protein that simultaneously binds an actively translocating RNA polymerase and upstream DNA to stimulate R-loop formation.

Transcription elongation through lac repressor-mediated DNA loops

During elongation, RNA polymerase (RNAP) must navigate through proteins that decorate genomic DNA. Several of these mediate long-distance interactions via structures, such as loops, that alter DNA topology and create torsional barriers. We used the tethered particle motion (TPM) technique and magnetic tweezers to monitor transcription of DNA templates in the presence of the lac repressor (LacI) protein which could bind at two sites, one proximal to, and one distal from, the promoter. The bivalent LacI tetramer binds recognition sites (operators) with up to nanomolar affinity depending on the sequence, and the concentration of LacI was adjusted to promote binding to either one or both operators, so as to produce unlooped or looped DNA. We observed that RNAP pausing before a LacI-securing loop was determined not by the affinity of LacI for the operator, but by the order in which the elongating RNAP encountered these operators. TPM experiments showed that, independent of affinity, LacI bound at the promoter-proximal operator became a stronger roadblock when securing a loop. In contrast, LacI bound to the distal operator was a weaker roadblock in a looped configuration suggesting that RNAP might more easily displace LacI obstacles within a torsion-constrained DNA loop. Since protein junctions can efficiently block the diffusion of DNA supercoiling, these data indicate that the positive supercoiling generated ahead of a transcribing RNAP may facilitate the dissociation of a roadblock. In support of this idea, magnetic tweezers measurements indicated that pauses are shorter when RNAP encounters obstacles on positively supercoiled than on relaxed DNA. Furthermore, at similar winding levels of the DNA template, RNAP pause duration decreased with tension. These findings are significant for our understanding of transcription within the crowded and tensed nucleoid.

High-resolution, genome-wide mapping of positive supercoiling in chromosomes

Supercoiling impacts DNA replication, transcription, protein binding to DNA, and the three-dimensional organization of chromosomes. However, there are currently no methods to directly interrogate or map positive supercoils, so their distribution in genomes remains unknown. Here, we describe a method, GapR-seq, based on the chromatin immunoprecipitation of GapR, a bacterial protein that preferentially recognizes overtwisted DNA, for generating high-resolution maps of positive supercoiling. Applying this method to E. coli and S. cerevisiae, we find that positive supercoiling is widespread, associated with transcription, and particularly enriched between convergently-oriented genes, consistent with the “twin-domain” model of supercoiling. In yeast, we also find positive supercoils associated with centromeres, cohesin binding sites, autonomously replicating sites, and the borders of R-loops (DNA-RNA hybrids). Our results suggest that GapR-seq is a powerful approach, likely applicable in any organism, to investigate aspects of chromosome structure and organization not accessible by Hi-C or other existing methods.

Direct observation of helicase–topoisomerase coupling within reverse gyrase

Reverse gyrases (RGs) are the only topoisomerases capable of generating positive supercoils in DNA. Members of the type IA family, they do so by generating a single-strand break in substrate DNA and then manipulating the two single strands to generate positive topology. Here, we use single-molecule experimentation to reveal the obligatory succession of steps that make up the catalytic cycle of RG. In the initial state, RG binds to DNA and unwinds ∼2 turns of the double helix in an ATP-independent fashion. Upon nucleotide binding, RG then rewinds ∼1 turn of DNA. Nucleotide hydrolysis and/or product release leads to an increase of 2 units of DNA writhe and resetting of the enzyme, for a net change of topology of +1 turn per cycle. Final dissociation of RG from DNA results in rewinding of the 2 turns of DNA that were initially disrupted. These results show how tight coupling of the helicase and topoisomerase activities allows for induction of positive supercoiling despite opposing torque.