Once described as mere “bags of enzymes,” bacterial cells are in fact highly organized, with many macromolecules exhibiting nonuniform localization patterns. Yet the physical and biochemical mechanisms that govern this spatial heterogeneity remain largely unknown. Here, we identify liquid–liquid phase separation (LLPS) as a mechanism for organizing clusters of RNA polymerase (RNAP) in Escherichia coli. Using fluorescence imaging, we show that RNAP quickly transitions from a dispersed to clustered localization pattern as cells enter log phase in nutrient-rich media. RNAP clusters are sensitive to hexanediol, a chemical that dissolves liquid-like compartments in eukaryotic cells. In addition, we find that the transcription antitermination factor NusA forms droplets in vitro and in vivo, suggesting that it may nucleate RNAP clusters. Finally, we use single-molecule tracking to characterize the dynamics of cluster components. Our results indicate that RNAP and NusA molecules move inside clusters, with mobilities faster than a DNA locus but slower than bulk diffusion through the nucleoid. We conclude that RNAP clusters are biomolecular condensates that assemble through LLPS. This work provides direct evidence for LLPS in bacteria and demonstrates that this process can serve as a mechanism for intracellular organization in prokaryotes and eukaryotes alike.
Once described as mere "bags of enzymes", bacterial cells are in fact highly organized, with many macromolecules exhibiting non-uniform localization patterns. Yet the physical and biochemical mechanisms that govern this spatial heterogeneity remain largely unknown. Here, we identify liquid-liquid phase separation (LLPS) as a mechanism for organizing clusters of RNA polymerase (RNAP) in E. coli. Using fluorescence imaging, we show that RNAP quickly transitions from a dispersed to clustered localization pattern as cells enter log phase in nutrientrich media. RNAP clusters are sensitive to hexanediol, a chemical that dissolves liquid-like compartments in eukaryotic cells. In addition, we find that the transcription antitermination factor NusA forms droplets in vitro and in vivo, suggesting that it may nucleate RNAP clusters. Finally, we use single-molecule tracking to characterize the dynamics of cluster components.Our results indicate that RNAP and NusA molecules move inside clusters, with mobilities faster than a DNA locus but slower than bulk diffusion through the nucleoid. We conclude that RNAP clusters are biomolecular condensates that assemble through LLPS. This work provides direct evidence for LLPS in bacteria and suggests that this process serves as a universal mechanism for intracellular organization across the tree of life. SignificanceBacterial cells are small and were long thought to have little to no internal structure. However, advances in microscopy have revealed that bacteria do indeed contain subcellular compartments. But how these compartments form has remained a mystery. Recent progress in larger, more complex eukaryotic cells has identified a novel mechanism for intracellular organization known as liquid-liquid phase separation. This process causes certain types of molecules to concentrate within distinct compartments inside the cell. Here, we demonstrate that the same process also occurs in bacteria. This work, together with a growing body of literature, suggests that liquidliquid phase separation is a universal mechanism for intracellular organization that extends across the tree of life.
The replisome is a multiprotein machine that is responsible for replicating DNA. During active DNA synthesis, the replisome tightly associates with DNA. In contrast, after DNA damage, the replisome may disassemble, exposing DNA to breaks and threatening cell survival. Using live cell imaging, we studied the effect of UV light on the replisome of Escherichia coli. Surprisingly, our results showed an increase in Pol III holoenzyme (Pol III HE) foci post-UV that do not colocalize with the DnaB helicase. Formation of these foci is independent of active replication forks and dependent on the presence of the χ subunit of the clamp loader, suggesting recruitment of Pol III HE at sites of DNA repair. Our results also showed a decrease of DnaB helicase foci per cell after UV, consistent with the disassembly of a fraction of the replisomes. By labeling newly synthesized DNA, we demonstrated that a drop in the rate of synthesis is not explained by replisome disassembly alone. Instead, we show that most replisomes continue synthesizing DNA at a slower rate after UV. We propose that the slowdown in replisome activity is a strategy to prevent clashes with engaged DNA repair proteins and preserve the integrity of the replication fork.DNA replication | replisome | fluorescence microscopy | UV | Escherichia coli
Replisomes are protein complexes that catalyze high-fidelity DNA replication at speeds approaching 1,000 bp/sec in bacteria (Chandler et al., 1975; O'Donnell et al., 2013). During the replication process replisomes encounter numerous impediments to their progress including protein/DNA complexes, non-duplex nucleic acid structures, and chromosomal damage (Mirkin and Mirkin, 2007). To overcome these obstacles, cells have evolved several systems that support replication on imperfect genomic templates. These include enzymes that dissociate protein/DNA complexes and resolve unusual nucleic acid structures, repair pathways that mitigate damaged DNA, and proteins that restructure collapsed replication forks. RNA polymerase (RNAP) and transcription-dependent nucleic acid structures called R-loops are common barriers to replisome progress (Aguilera and Garcia-Muse, 2012; Helmrich et al., 2013). R-loops are structures that form when a nascent RNA hybridizes with the DNA template behind RNAP (Westover et al., 2004). Bacterial replisomes moves at rates that are ~10-20 times faster than RNAP and can encounter R-loops and/or RNAP in both head-on and co-directional
Proteins are major contributors to the composition and the functions in the cell. They often assemble into larger structures, macromolecular machines, to carry out intricate essential functions.
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