Single-molecule DNA repair in live bacteria

Uphoff, Stephan; Reyes‐Lamothe, Rodrigo; Leon, Federico Garza de; Sherratt, David J.; Kapanidis, Achillefs N.

doi:10.1073/pnas.1301804110

Cited by 185 publications

(319 citation statements)

References 45 publications

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“…S4). Referring to other DNA-binding proteins of comparable sizes (33,34), the range of PolC-PAmCherry diffusion coefficients indicates that the slower moving PolC proteins are engaged in confined motion, and we interpret the slow moving PolCPAmCherry as a subpopulation actively engaged in DNA replication.…”

Section: In Vivo Localization and Diffusion Of Polcmentioning

confidence: 64%

Single-Molecule DNA Polymerase Dynamics at a Bacterial Replisome in Live Cells

Liao

Schroeder

et al. 2016

Biophysical Journal

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PolC is one of two essential replicative DNA polymerases found in the Gram-positive bacterium Bacillus subtilis. The B. subtilis replisome is eukaryotic-like in that it relies on a two DNA polymerase system for chromosomal replication. To quantitatively image how the replicative DNA polymerase PolC functions in B. subtilis, we applied photobleaching-assisted microscopy, three-dimensional superresolution imaging, and single-particle tracking to examine the in vivo behavior of PolC at single-molecule resolution. We report the stoichiometry of PolC proteins within each cell and within each replisome, we elucidate the diffusion characteristics of individual PolC molecules, and we quantify the exchange dynamics for PolC engaged in lagging strand synthesis. We show that PolC is highly dynamic: this DNA polymerase is constantly recruited to and released from a centrally located replisome, providing, to our knowledge, new insight into the organization and dynamics of the replisome in bacterial cells.

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Section: In Vivo Localization and Diffusion Of Polcmentioning

confidence: 64%

Single-Molecule DNA Polymerase Dynamics at a Bacterial Replisome in Live Cells

Liao

Schroeder

et al. 2016

Biophysical Journal

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“…In this technique, trajectories are constructed by determining and connecting the positions of individual particles from consecutive time-lapse images. Importantly, such trajectories can be used to determine whether an individual particle is bound or free if the free particle diffuses significantly faster than its binding targets and remains bound or free for a long time (8,9). Recent advances have made it possible to track hundreds of particles in each cell by labeling the particles of interest with photoactivatable or photoconvertible fluorescent proteins and tracking one or a few at a time (10,11).…”

mentioning

confidence: 99%

Single-particle tracking reveals that free ribosomal subunits are not excluded from the Escherichia coli nucleoid

Sanamrad

Persson

Fange

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

183

228

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Biochemical and genetic data show that ribosomes closely follow RNA polymerases that are transcribing protein-coding genes in bacteria. At the same time, electron and fluorescence microscopy have revealed that ribosomes are excluded from the Escherichia coli nucleoid, which seems to be inconsistent with fast translation initiation on nascent mRNA transcripts. The apparent paradox can be reconciled if translation of nascent mRNAs can start throughout the nucleoid before they relocate to the periphery. However, this mechanism requires that free ribosomal subunits are not excluded from the nucleoid. Here, we use single-particle tracking in living E. coli cells to determine the fractions of free ribosomal subunits, classify individual subunits as free or mRNA-bound, and quantify the degree of exclusion of bound and free subunits separately. We show that free subunits are not excluded from the nucleoid. This finding strongly suggests that translation of nascent mRNAs can start throughout the nucleoid, which reconciles the spatial separation of DNA and ribosomes with cotranscriptional translation. We also show that, after translation inhibition, free subunit precursors are partially excluded from the compacted nucleoid. This finding indicates that it is active translation that normally allows ribosomal subunits to assemble on nascent mRNAs throughout the nucleoid and that the effects of translation inhibitors are enhanced by the limited access of ribosomal subunits to nascent mRNAs in the compacted nucleoid.nucleoid exclusion | transcription-translation coupling | antibiotics | single-molecule tracking | single-molecule imaging I n bacteria, translation often starts soon after the ribosomebinding site emerges from the RNA exit channel of the RNA polymerase. The transcribing RNA polymerase is then closely followed by translating ribosomes in such a way that the overall transcription elongation rate is tightly controlled by the translation rate (1). This coupling between transcription and translation of nascent mRNAs is important for regulatory mechanisms that respond to the formation of gaps between the transcribing RNA polymerases and the trailing ribosomes. Such gaps may, for example, allow the formation of secondary structures that allow RNA polymerases to proceed through transcription termination sites (2). The gaps may also allow the transcription termination factor Rho to access the nascent mRNAs and terminate transcription (3).Bacterial 70S ribosomes are formed when large 50S subunits and small 30S subunits assemble on mRNAs. Electron and fluorescence microscopy have revealed that ribosomes are excluded from the Escherichia coli nucleoid (4-6), but this spatial separation of DNA and ribosomes has not yet been reconciled with cotranscriptional translation. The paradox can be resolved if translation of nascent mRNAs can start throughout the nucleoid before they relocate to the periphery (7). However, this mechanism requires that free ribosomal subunits are not excluded from the nucleoid.To determine whether free r...

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“…The resulting Pol1 localizations occupy the central area of the cell (Figure 6A), broadly recapitulating the spatial organization of the E. coli nucleoid 7 . The majority of Pol1 tracks in undamaged cells display diffusion as shown in Figure 6C.…”

Section: Representative Resultsmentioning

confidence: 58%

Visualizing Protein-DNA Interactions in Live Bacterial Cells Using Photoactivated Single-molecule Tracking

Uphoff

Sherratt

Kapanidis

2014

JoVE

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Protein-DNA interactions are at the heart of many fundamental cellular processes. For example, DNA replication, transcription, repair, and chromosome organization are governed by DNA-binding proteins that recognize specific DNA structures or sequences. In vitro experiments have helped to generate detailed models for the function of many types of DNA-binding proteins, yet, the exact mechanisms of these processes and their organization in the complex environment of the living cell remain far less understood. We recently introduced a method for quantifying DNA-repair activities in live Escherichia coli cells using Photoactivated Localization Microscopy (PALM) combined with single-molecule tracking. Our general approach identifies individual DNA-binding events by the change in the mobility of a single protein upon association with the chromosome. The fraction of bound molecules provides a direct quantitative measure for the protein activity and abundance of substrates or binding sites at the single-cell level. Here, we describe the concept of the method and demonstrate sample preparation, data acquisition, and data analysis procedures.

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Single-molecule DNA repair in live bacteria

Cited by 185 publications

References 45 publications

Single-Molecule DNA Polymerase Dynamics at a Bacterial Replisome in Live Cells

Single-Molecule DNA Polymerase Dynamics at a Bacterial Replisome in Live Cells

Single-particle tracking reveals that free ribosomal subunits are not excluded from the Escherichia coli nucleoid

Visualizing Protein-DNA Interactions in Live Bacterial Cells Using Photoactivated Single-molecule Tracking

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