Your search keyword '"Kerssemakers, J.W.J. (author)"' showing total 31 results

1. Direct observation of a crescent-shape chromosome in expanded Bacillus subtilis cells

Author

Tišma, M. (author), Bock, Florian Patrick (author), Kerssemakers, J.W.J. (author), Antar, Hammam (author), Japaridze, A. (author), Gruber, Stephan (author), Dekker, C. (author), Tišma, M. (author), Bock, Florian Patrick (author), Kerssemakers, J.W.J. (author), Antar, Hammam (author), Japaridze, A. (author), Gruber, Stephan (author), and Dekker, C. (author)

Abstract

Bacterial chromosomes are folded into tightly regulated three-dimensional structures to ensure proper transcription, replication, and segregation of the genetic information. Direct visualization of chromosomal shape within bacterial cells is hampered by cell-wall confinement and the optical diffraction limit. Here, we combine cell-shape manipulation strategies, high-resolution fluorescence microscopy techniques, and genetic engineering to visualize the shape of unconfined bacterial chromosome in real-time in live Bacillus subtilis cells that are expanded in volume. We show that the chromosomes predominantly exhibit crescent shapes with a non-uniform DNA density that is increased near the origin of replication (oriC). Additionally, we localized ParB and BsSMC proteins – the key drivers of chromosomal organization – along the contour of the crescent chromosome, showing the highest density near oriC. Opening of the BsSMC ring complex disrupted the crescent chromosome shape and instead yielded a torus shape. These findings help to understand the threedimensional organization of the chromosome and the main protein complexes that underlie its structure., BN/Cees Dekker Lab, Dynamics of Micro and Nano Systems

Published

2024

2. Correction to: Direct observation of a crescent-shape chromosome in expanded Bacillus subtilis cells (Nature Communications, (2024), 15, 1, (2737), 10.1038/s41467-024-47094-x)

Author

Tišma, M. (author), Bock, Florian Patrick (author), Kerssemakers, J.W.J. (author), Antar, Hammam (author), Japaridze, A. (author), Gruber, Stephan (author), Dekker, C. (author), Tišma, M. (author), Bock, Florian Patrick (author), Kerssemakers, J.W.J. (author), Antar, Hammam (author), Japaridze, A. (author), Gruber, Stephan (author), and Dekker, C. (author)

Abstract

Correction to: Nature Communicationhttps://doi.org/10.1038/s41467-024-47094-x, published online 28 March 2024 The original version of this article contained an error in the “Acknowledgement “section. The original version read “We also acknowledge funding for the work in S.G. lab by the Swiss National Science Foundation (grant number: 310030L_170242).” This has been amended to “We also acknowledge funding for the work in S.G. lab by the Swiss National Science Foundation (grant number: 310030_197770).” This has now been corrected in both the PDF and HTML versions of the Article., correction to 1038/s41467-024-4709-x, BN/Cees Dekker Lab, Dynamics of Micro and Nano Systems

Published

2024

3. CTCF is a DNA-tension-dependent barrier to cohesin-mediated loop extrusion

Author

Davidson, Iain F. (author), Barth, R. (author), Zaczek, Maciej (author), van der Torre, J. (author), Tang, Wen (author), Nagasaka, Kota (author), Janissen, R. (author), Kerssemakers, J.W.J. (author), Wutz, Gordana (author), Dekker, C. (author), Peters, Jan Michael (author), Davidson, Iain F. (author), Barth, R. (author), Zaczek, Maciej (author), van der Torre, J. (author), Tang, Wen (author), Nagasaka, Kota (author), Janissen, R. (author), Kerssemakers, J.W.J. (author), Wutz, Gordana (author), Dekker, C. (author), and Peters, Jan Michael (author)

Abstract

In eukaryotes, genomic DNA is extruded into loops by cohesin1. By restraining this process, the DNA-binding protein CCCTC-binding factor (CTCF) generates topologically associating domains (TADs)2,3 that have important roles in gene regulation and recombination during development and disease1,4–7. How CTCF establishes TAD boundaries and to what extent these are permeable to cohesin is unclear8. Here, to address these questions, we visualize interactions of single CTCF and cohesin molecules on DNA in vitro. We show that CTCF is sufficient to block diffusing cohesin, possibly reflecting how cohesive cohesin accumulates at TAD boundaries, and is also sufficient to block loop-extruding cohesin, reflecting how CTCF establishes TAD boundaries. CTCF functions asymmetrically, as predicted; however, CTCF is dependent on DNA tension. Moreover, CTCF regulates cohesin’s loop-extrusion activity by changing its direction and by inducing loop shrinkage. Our data indicate that CTCF is not, as previously assumed, simply a barrier to cohesin-mediated loop extrusion but is an active regulator of this process, whereby the permeability of TAD boundaries can be modulated by DNA tension. These results reveal mechanistic principles of how CTCF controls loop extrusion and genome architecture., BN/Cees Dekker Lab, BN/Bionanoscience

Published

2023

4. MukBEF-dependent chromosomal organization in widened Escherichia coli

Author

Japaridze, A. (author), van Wee, R.G. (author), Gogou, C. (author), Kerssemakers, J.W.J. (author), van den Berg, D.F. (author), Dekker, C. (author), Japaridze, A. (author), van Wee, R.G. (author), Gogou, C. (author), Kerssemakers, J.W.J. (author), van den Berg, D.F. (author), and Dekker, C. (author)

Abstract

The bacterial chromosome is spatially organized through protein-mediated compaction, supercoiling, and cell-boundary confinement. Structural Maintenance of Chromosomes (SMC) complexes are a major class of chromosome-organizing proteins present throughout all domains of life. Here, we study the role of the Escherichia coli SMC complex MukBEF in chromosome architecture and segregation. Using quantitative live-cell imaging of shape-manipulated cells, we show that MukBEF is crucial to preserve the toroidal topology of the Escherichia coli chromosome and that it is non-uniformly distributed along the chromosome: it prefers locations toward the origin and away from the terminus of replication, and it is unevenly distributed over the origin of replication along the two chromosome arms. Using an ATP hydrolysis-deficient MukB mutant, we confirm that MukBEF translocation along the chromosome is ATP-dependent, in contrast to its loading onto DNA. MukBEF and MatP are furthermore found to be essential for sister chromosome decatenation. We propose a model that explains how MukBEF, MatP, and their interacting partners organize the chromosome and contribute to sister segregation. The combination of bacterial cell-shape modification and quantitative fluorescence microscopy paves way to investigating chromosome-organization factors in vivo., Dynamics of Micro and Nano Systems, BN/Bionanoscience, BN/Chirlmin Joo Lab, BN/Dimphna Meijer Lab, BN/Cees Dekker Lab, BN/Stan Brouns Lab

Published

2023

5. Directing Min protein patterns with advective bulk flow

Author

Meindlhumer, S. (author), Brauns, Fridtjof (author), Finžgar, Jernej Rudi (author), Kerssemakers, J.W.J. (author), Dekker, C. (author), Frey, Erwin (author), Meindlhumer, S. (author), Brauns, Fridtjof (author), Finžgar, Jernej Rudi (author), Kerssemakers, J.W.J. (author), Dekker, C. (author), and Frey, Erwin (author)

Abstract

The Min proteins constitute the best-studied model system for pattern formation in cell biology. We theoretically predict and experimentally show that the propagation direction of in vitro Min protein patterns can be controlled by a hydrodynamic flow of the bulk solution. We find downstream propagation of Min wave patterns for low MinE:MinD concentration ratios, upstream propagation for large ratios, but multistability of both propagation directions in between. Whereas downstream propagation can be described by a minimal model that disregards MinE conformational switching, upstream propagation can be reproduced by a reduced switch model, where increased MinD bulk concentrations on the upstream side promote protein attachment. Our study demonstrates that a differential flow, where bulk flow advects protein concentrations in the bulk, but not on the surface, can control surface-pattern propagation. This suggests that flow can be used to probe molecular features and to constrain mathematical models for pattern-forming systems., BN/Cees Dekker Lab

Published

2023

6. Condensin extrudes DNA loops in steps up to hundreds of base pairs that are generated by ATP binding events

Author

Ryu, J.K. (author), Rah, S.H. (author), Janissen, R. (author), Kerssemakers, J.W.J. (author), Bonato, Andrea (author), Michieletto, Davide (author), Dekker, C. (author), Ryu, J.K. (author), Rah, S.H. (author), Janissen, R. (author), Kerssemakers, J.W.J. (author), Bonato, Andrea (author), Michieletto, Davide (author), and Dekker, C. (author)

Abstract

The condensin SMC protein complex organizes chromosomal structure by extruding loops of DNA. Its ATP-dependent motor mechanism remains unclear but likely involves steps associated with large conformational changes within the ∼50 nm protein complex. Here, using high-resolution magnetic tweezers, we resolve single steps in the loop extrusion process by individual yeast condensins. The measured median step sizes range between 20-40 nm at forces of 1.0-0.2 pN, respectively, comparable with the holocomplex size. These large steps show that, strikingly, condensin typically reels in DNA in very sizeable amounts with ∼200 bp on average per single extrusion step at low force, and occasionally even much larger, exceeding 500 bp per step. Using Molecular Dynamics simulations, we demonstrate that this is due to the structural flexibility of the DNA polymer at these low forces. Using ATP-binding-impaired and ATP-hydrolysis-deficient mutants, we find that ATP binding is the primary step-generating stage underlying DNA loop extrusion. We discuss our findings in terms of a scrunching model where a stepwise DNA loop extrusion is generated by an ATP-binding-induced engagement of the hinge and the globular domain of the SMC complex., BN/Cees Dekker Lab

Published

2022

7. Quantitative analysis of surface wave patterns of Min proteins

Author

Meindlhumer, S. (author), Kerssemakers, J.W.J. (author), Dekker, C. (author), Meindlhumer, S. (author), Kerssemakers, J.W.J. (author), and Dekker, C. (author)

Abstract

The Min protein system is arguably the best-studied model system for biological pattern formation. It exhibits pole-to-pole oscillations in E. coli bacteria as well as a variety of surface wave patterns in in vitro reconstitutions. Such Min surface wave patterns pose particular challenges to quantification as they are typically only semi-periodic and non-stationary. Here, we present a methodology for quantitatively analysing such Min patterns, aiming for reproducibility, user-independence, and easy usage. After introducing pattern-feature definitions and image-processing concepts, we present an analysis pipeline where we use autocorrelation analysis to extract global parameters such as the average spatial wavelength and oscillation period. Subsequently, we describe a method that uses flow-field analysis to extract local properties such as the wave propagation velocity. We provide descriptions on how to practically implement these quantification tools and provide Python code that can directly be used to perform analysis of Min patterns., BN/Cees Dekker Lab

Published

2022

8. Bridging scales in a multiscale pattern-forming system

Author

Würthner, Laeschkir (author), Brauns, Fridtjof (author), Pawlik, G. (author), Halatek, Jacob (author), Kerssemakers, J.W.J. (author), Dekker, C. (author), Frey, Erwin (author), Würthner, Laeschkir (author), Brauns, Fridtjof (author), Pawlik, G. (author), Halatek, Jacob (author), Kerssemakers, J.W.J. (author), Dekker, C. (author), and Frey, Erwin (author)

Abstract

Self-organized pattern formation is vital for many biological processes. Reaction-diffusion models have advanced our understanding of how biological systems develop spatial structures, starting from homogeneity. However, biological processes inherently involve multiple spatial and temporal scales and transition from one pattern to another over time, rather than progressing from homogeneity to a pattern. To deal with such multiscale systems, coarse-graining methods are needed that allow the dynamics to be reduced to the relevant degrees of freedom at large scales, but without losing information about the patterns at small scales. Here, we present a semiphenomenological approach which exploits mass conservation in pattern formation, and enables reconstruction of information about patterns from the large-scale dynamics. The basic idea is to partition the domain into distinct regions (coarse grain) and determine instantaneous dispersion relations in each region, which ultimately inform about local pattern-forming instabilities. We illustrate our approach by studying the Min system, a paradigmatic model for protein pattern formation. By performing simulations, we first show that the Min system produces multiscale patterns in a spatially heterogeneous geometry. This prediction is confirmed experimentally by in vitro reconstitution of the Min system. Using a recently developed theoretical framework for mass-conserving reaction-diffusion systems, we show that the spatiotemporal evolution of the total protein densities on large scales reliably predicts the pattern-forming dynamics. Our approach provides an alternative and versatile theoretical framework for complex systems where analytical coarse-graining methods are not applicable, and can, in principle, be applied to a wide range of systems with an underlying conservation law., BN/Cees Dekker Lab

Published

2022

9. Quantitative analysis of surface wave patterns of Min proteins

Author

Meindlhumer, S. (author), Kerssemakers, J.W.J. (author), Dekker, C. (author), Meindlhumer, S. (author), Kerssemakers, J.W.J. (author), and Dekker, C. (author)

Abstract

The Min protein system is arguably the best-studied model system for biological pattern formation. It exhibits pole-to-pole oscillations in E. coli bacteria as well as a variety of surface wave patterns in in vitro reconstitutions. Such Min surface wave patterns pose particular challenges to quantification as they are typically only semi-periodic and non-stationary. Here, we present a methodology for quantitatively analysing such Min patterns, aiming for reproducibility, user-independence, and easy usage. After introducing pattern-feature definitions and image-processing concepts, we present an analysis pipeline where we use autocorrelation analysis to extract global parameters such as the average spatial wavelength and oscillation period. Subsequently, we describe a method that uses flow-field analysis to extract local properties such as the wave propagation velocity. We provide descriptions on how to practically implement these quantification tools and provide Python code that can directly be used to perform analysis of Min patterns., BN/Cees Dekker Lab

Published

2022

10. Condensin extrudes DNA loops in steps up to hundreds of base pairs that are generated by ATP binding events

Author

Ryu, J.K. (author), Rah, S.H. (author), Janissen, R. (author), Kerssemakers, J.W.J. (author), Bonato, Andrea (author), Michieletto, Davide (author), Dekker, C. (author), Ryu, J.K. (author), Rah, S.H. (author), Janissen, R. (author), Kerssemakers, J.W.J. (author), Bonato, Andrea (author), Michieletto, Davide (author), and Dekker, C. (author)

Abstract

The condensin SMC protein complex organizes chromosomal structure by extruding loops of DNA. Its ATP-dependent motor mechanism remains unclear but likely involves steps associated with large conformational changes within the ∼50 nm protein complex. Here, using high-resolution magnetic tweezers, we resolve single steps in the loop extrusion process by individual yeast condensins. The measured median step sizes range between 20-40 nm at forces of 1.0-0.2 pN, respectively, comparable with the holocomplex size. These large steps show that, strikingly, condensin typically reels in DNA in very sizeable amounts with ∼200 bp on average per single extrusion step at low force, and occasionally even much larger, exceeding 500 bp per step. Using Molecular Dynamics simulations, we demonstrate that this is due to the structural flexibility of the DNA polymer at these low forces. Using ATP-binding-impaired and ATP-hydrolysis-deficient mutants, we find that ATP binding is the primary step-generating stage underlying DNA loop extrusion. We discuss our findings in terms of a scrunching model where a stepwise DNA loop extrusion is generated by an ATP-binding-induced engagement of the hinge and the globular domain of the SMC complex., BN/Cees Dekker Lab

Published

2022

11. Bulk-surface coupling identifies the mechanistic connection between Min-protein patterns in vivo and in vitro

Author

Brauns, Fridtjof (author), Pawlik, G. (author), Halatek, Jacob (author), Kerssemakers, J.W.J. (author), Frey, Erwin (author), Dekker, C. (author), Brauns, Fridtjof (author), Pawlik, G. (author), Halatek, Jacob (author), Kerssemakers, J.W.J. (author), Frey, Erwin (author), and Dekker, C. (author)

Abstract

Self-organisation of Min proteins is responsible for the spatial control of cell division in Escherichia coli, and has been studied both in vivo and in vitro. Intriguingly, the protein patterns observed in these settings differ qualitatively and quantitatively. This puzzling dichotomy has not been resolved to date. Using reconstituted proteins in laterally wide microchambers with a well-controlled height, we experimentally show that the Min protein dynamics on the membrane crucially depend on the micro chamber height due to bulk concentration gradients orthogonal to the membrane. A theoretical analysis shows that in vitro patterns at low microchamber height are driven by the same lateral oscillation mode as pole-to-pole oscillations in vivo. At larger microchamber height, additional vertical oscillation modes set in, marking the transition to a qualitatively different in vitro regime. Our work reveals the qualitatively different mechanisms of mass transport that govern Min protein-patterns for different bulk heights and thus shows that Min patterns in cells are governed by a different mechanism than those in vitro., BN/Cees Dekker Lab, BN/Technici en Analisten

Published

2021

12. AutoStepfinder: A fast and automated step detection method for single-molecule analysis

Author

Loeff, L. (author), Kerssemakers, J.W.J. (author), Joo, C. (author), Dekker, C. (author), Loeff, L. (author), Kerssemakers, J.W.J. (author), Joo, C. (author), and Dekker, C. (author)

Abstract

Single-molecule techniques allow the visualization of the molecular dynamics of nucleic acids and proteins with high spatiotemporal resolution. Valuable kinetic information of biomolecules can be obtained when the discrete states within single-molecule time trajectories are determined. Here, we present a fast, automated, and bias-free step detection method, AutoStepfinder, that determines steps in large datasets without requiring prior knowledge on the noise contributions and location of steps. The analysis is based on a series of partition events that minimize the difference between the data and the fit. A dual-pass strategy determines the optimal fit and allows AutoStepfinder to detect steps of a wide variety of sizes. We demonstrate step detection for a broad variety of experimental traces. The user-friendly interface and the automated detection of AutoStepfinder provides a robust analysis procedure that enables anyone without programming knowledge to generate step fits and informative plots in less than an hour., BN/Chirlmin Joo Lab, BN/Technici en Analisten, BN/Cees Dekker Lab

Published

2021

13. Bulk-surface coupling identifies the mechanistic connection between Min-protein patterns in vivo and in vitro

Author

Brauns, Fridtjof (author), Pawlik, G. (author), Halatek, Jacob (author), Kerssemakers, J.W.J. (author), Frey, Erwin (author), Dekker, C. (author), Brauns, Fridtjof (author), Pawlik, G. (author), Halatek, Jacob (author), Kerssemakers, J.W.J. (author), Frey, Erwin (author), and Dekker, C. (author)

Abstract

Self-organisation of Min proteins is responsible for the spatial control of cell division in Escherichia coli, and has been studied both in vivo and in vitro. Intriguingly, the protein patterns observed in these settings differ qualitatively and quantitatively. This puzzling dichotomy has not been resolved to date. Using reconstituted proteins in laterally wide microchambers with a well-controlled height, we experimentally show that the Min protein dynamics on the membrane crucially depend on the micro chamber height due to bulk concentration gradients orthogonal to the membrane. A theoretical analysis shows that in vitro patterns at low microchamber height are driven by the same lateral oscillation mode as pole-to-pole oscillations in vivo. At larger microchamber height, additional vertical oscillation modes set in, marking the transition to a qualitatively different in vitro regime. Our work reveals the qualitatively different mechanisms of mass transport that govern Min protein-patterns for different bulk heights and thus shows that Min patterns in cells are governed by a different mechanism than those in vitro., BN/Cees Dekker Lab, BN/Technici en Analisten

Published

2021

14. AutoStepfinder: A fast and automated step detection method for single-molecule analysis

Author

Loeff, L. (author), Kerssemakers, J.W.J. (author), Joo, C. (author), Dekker, C. (author), Loeff, L. (author), Kerssemakers, J.W.J. (author), Joo, C. (author), and Dekker, C. (author)

Abstract

Single-molecule techniques allow the visualization of the molecular dynamics of nucleic acids and proteins with high spatiotemporal resolution. Valuable kinetic information of biomolecules can be obtained when the discrete states within single-molecule time trajectories are determined. Here, we present a fast, automated, and bias-free step detection method, AutoStepfinder, that determines steps in large datasets without requiring prior knowledge on the noise contributions and location of steps. The analysis is based on a series of partition events that minimize the difference between the data and the fit. A dual-pass strategy determines the optimal fit and allows AutoStepfinder to detect steps of a wide variety of sizes. We demonstrate step detection for a broad variety of experimental traces. The user-friendly interface and the automated detection of AutoStepfinder provides a robust analysis procedure that enables anyone without programming knowledge to generate step fits and informative plots in less than an hour., BN/Chirlmin Joo Lab, BN/Technici en Analisten, BN/Cees Dekker Lab

Published

2021

15. DNA-loop extruding condensin complexes can traverse one another

Author

Kim, E. (author), Kerssemakers, J.W.J. (author), Shaltiel, Indra A. (author), Haering, Christian H. (author), Dekker, C. (author), Kim, E. (author), Kerssemakers, J.W.J. (author), Shaltiel, Indra A. (author), Haering, Christian H. (author), and Dekker, C. (author)

Abstract

Condensin, a key component of the structure maintenance of chromosome (SMC) protein complexes, has recently been shown to be a motor that extrudes loops of DNA1. It remains unclear, however, how condensin complexes work together to collectively package DNA into chromosomes. Here we use time-lapse single-molecule visualization to study mutual interactions between two DNA-loop-extruding yeast condensins. We find that these motor proteins, which, individually, extrude DNA in one direction only are able to dynamically change each other’s DNA loop sizes, even when far apart. When they are in close proximity, condensin complexes are able to traverse each other and form a loop structure, which we term a Z-loop—three double-stranded DNA helices aligned in parallel with one condensin at each edge. Z-loops can fill gaps left by single loops and can form symmetric dimer motors that pull in DNA from both sides. These findings indicate that condensin may achieve chromosomal compaction using a variety of looping structures., Accepted Author Manuscript, BN/Cees Dekker Lab, BN/Technici en Analisten

Published

2020

16. Direct observation of independently moving replisomes in Escherichia coli

Author

Japaridze, A. (author), Gogou, C. (author), Kerssemakers, J.W.J. (author), Nguyen, Huyen My (author), Dekker, C. (author), Japaridze, A. (author), Gogou, C. (author), Kerssemakers, J.W.J. (author), Nguyen, Huyen My (author), and Dekker, C. (author)

Abstract

The replication and transfer of genomic material from a cell to its progeny are vital processes in all living systems. Here we visualize the process of chromosome replication in widened E. coli cells. Monitoring the replication of single chromosomes yields clear examples of replication bubbles that reveal that the two replisomes move independently from the origin to the terminus of replication along each of the two arms of the circular chromosome, providing direct support for the so-called train-track model, and against a factory model for replisomes. The origin of replication duplicates near midcell, initially splitting to random directions and subsequently towards the poles. The probability of successful segregation of chromosomes significantly decreases with increasing cell width, indicating that chromosome confinement by the cell boundary is an important driver of DNA segregation. Our findings resolve long standing questions in bacterial chromosome organization., BN/Cees Dekker Lab, BN/Technici en Analisten

Published

2020

17. DNA-loop extruding condensin complexes can traverse one another

Author

Kim, E. (author), Kerssemakers, J.W.J. (author), Shaltiel, Indra A. (author), Haering, Christian H. (author), Dekker, C. (author), Kim, E. (author), Kerssemakers, J.W.J. (author), Shaltiel, Indra A. (author), Haering, Christian H. (author), and Dekker, C. (author)

Abstract

Condensin, a key component of the structure maintenance of chromosome (SMC) protein complexes, has recently been shown to be a motor that extrudes loops of DNA1. It remains unclear, however, how condensin complexes work together to collectively package DNA into chromosomes. Here we use time-lapse single-molecule visualization to study mutual interactions between two DNA-loop-extruding yeast condensins. We find that these motor proteins, which, individually, extrude DNA in one direction only are able to dynamically change each other’s DNA loop sizes, even when far apart. When they are in close proximity, condensin complexes are able to traverse each other and form a loop structure, which we term a Z-loop—three double-stranded DNA helices aligned in parallel with one condensin at each edge. Z-loops can fill gaps left by single loops and can form symmetric dimer motors that pull in DNA from both sides. These findings indicate that condensin may achieve chromosomal compaction using a variety of looping structures., Accepted Author Manuscript, BN/Cees Dekker Lab, BN/Technici en Analisten

Published

2020

18. Direct observation of independently moving replisomes in Escherichia coli

Author

Japaridze, A. (author), Gogou, C. (author), Kerssemakers, J.W.J. (author), Nguyen, Huyen My (author), Dekker, C. (author), Japaridze, A. (author), Gogou, C. (author), Kerssemakers, J.W.J. (author), Nguyen, Huyen My (author), and Dekker, C. (author)

Abstract

The replication and transfer of genomic material from a cell to its progeny are vital processes in all living systems. Here we visualize the process of chromosome replication in widened E. coli cells. Monitoring the replication of single chromosomes yields clear examples of replication bubbles that reveal that the two replisomes move independently from the origin to the terminus of replication along each of the two arms of the circular chromosome, providing direct support for the so-called train-track model, and against a factory model for replisomes. The origin of replication duplicates near midcell, initially splitting to random directions and subsequently towards the poles. The probability of successful segregation of chromosomes significantly decreases with increasing cell width, indicating that chromosome confinement by the cell boundary is an important driver of DNA segregation. Our findings resolve long standing questions in bacterial chromosome organization., BN/Cees Dekker Lab, BN/Technici en Analisten

Published

2020

19. Direct imaging of the circular chromosome in a live bacterium

Author

Wu, Fabai (author), Japaridze, A. (author), Zheng, X.Z. (author), Wiktor, J.M. (author), Kerssemakers, J.W.J. (author), Dekker, C. (author), Wu, Fabai (author), Japaridze, A. (author), Zheng, X.Z. (author), Wiktor, J.M. (author), Kerssemakers, J.W.J. (author), and Dekker, C. (author)

Abstract

Although the physical properties of chromosomes, including their morphology, mechanics, and dynamics are crucial for their biological function, many basic questions remain unresolved. Here we directly image the circular chromosome in live E. coli with a broadened cell shape. We find that it exhibits a torus topology with, on average, a lower-density origin of replication and an ultrathin flexible string of DNA at the terminus of replication. At the single-cell level, the torus is strikingly heterogeneous, with blob-like Mbp-size domains that undergo major dynamic rearrangements, splitting and merging at a minute timescale. Our data show a domain organization underlying the chromosome structure of E. coli, where MatP proteins induce site-specific persistent domain boundaries at Ori/Ter, while transcription regulators HU and Fis induce weaker transient domain boundaries throughout the genome. These findings provide an architectural basis for the understanding of the dynamic spatial organization of bacterial genomes in live cells., BN/Cees Dekker Lab, BN/Sander Tans Lab, BN/Technici en Analisten

Published

2019

20. Direct imaging of the circular chromosome in a live bacterium

Author

Wu, Fabai (author), Japaridze, A. (author), Zheng, X.Z. (author), Wiktor, J.M. (author), Kerssemakers, J.W.J. (author), Dekker, C. (author), Wu, Fabai (author), Japaridze, A. (author), Zheng, X.Z. (author), Wiktor, J.M. (author), Kerssemakers, J.W.J. (author), and Dekker, C. (author)

Abstract

Although the physical properties of chromosomes, including their morphology, mechanics, and dynamics are crucial for their biological function, many basic questions remain unresolved. Here we directly image the circular chromosome in live E. coli with a broadened cell shape. We find that it exhibits a torus topology with, on average, a lower-density origin of replication and an ultrathin flexible string of DNA at the terminus of replication. At the single-cell level, the torus is strikingly heterogeneous, with blob-like Mbp-size domains that undergo major dynamic rearrangements, splitting and merging at a minute timescale. Our data show a domain organization underlying the chromosome structure of E. coli, where MatP proteins induce site-specific persistent domain boundaries at Ori/Ter, while transcription regulators HU and Fis induce weaker transient domain boundaries throughout the genome. These findings provide an architectural basis for the understanding of the dynamic spatial organization of bacterial genomes in live cells., BN/Cees Dekker Lab, BN/Sander Tans Lab, BN/Technici en Analisten

Published

2019

21. Mechanical Division of Cell-Sized Liposomes

Author

Deshpande, S.R. (author), Spoelstra, W.K. (author), van Doorn, M.C. (author), Kerssemakers, J.W.J. (author), Dekker, C. (author), Deshpande, S.R. (author), Spoelstra, W.K. (author), van Doorn, M.C. (author), Kerssemakers, J.W.J. (author), and Dekker, C. (author)

Abstract

Liposomes, self-assembled vesicles with a lipid-bilayer boundary similar to cell membranes, are extensively used in both fundamental and applied sciences. Manipulation of their physical properties, such as growth and division, may significantly expand their use as model systems in cellular and synthetic biology. Several approaches have been explored to controllably divide liposomes, such as shape transformation through temperature cycling, incorporation of additional lipids, and the encapsulation of protein division machinery. However, so far, these methods lacked control, exhibited low efficiency, and yielded asymmetric division in terms of volume or lipid composition. Here, we present a microfluidics-based strategy to realize mechanical division of cell-sized (∼6 μm) liposomes. We use octanol-assisted liposome assembly (OLA) to produce liposomes on chip, which are subsequently flowed against the sharp edge of a wedge-shaped splitter. Upon encountering such a Y-shaped bifurcation, the liposomes are deformed and, remarkably, are able to divide into two stable daughter liposomes in just a few milliseconds. The probability of successful division is found to critically depend on the surface area-to-volume ratio of the mother liposome, which can be tuned through osmotic pressure, and to strongly correlate to the mother liposome size for given microchannel dimensions. The division process is highly symmetric (∼3% size variation between the daughter liposomes) and is accompanied by a low leakage. This mechanical division of liposomes may constitute a valuable step to establish a growth-division cycle of synthetic cells., BN/Cees Dekker Lab, BN/Marileen Dogterom Lab, BN/Technici en Analisten

Published

2018

22. Real-time detection of condensin-driven DNA compaction reveals a multistep binding mechanism

Author

Eeftens, J.M. (author), Bisht, Shveta (author), Kerssemakers, J.W.J. (author), Kschonsak, Marc (author), Haering, Christian H. (author), Dekker, C. (author), Eeftens, J.M. (author), Bisht, Shveta (author), Kerssemakers, J.W.J. (author), Kschonsak, Marc (author), Haering, Christian H. (author), and Dekker, C. (author)

Abstract

Condensin, a conserved member of the SMC protein family of ring-shaped multi-subunit protein complexes, is essential for structuring and compacting chromosomes. Despite its key role, its molecular mechanism has remained largely unknown. Here, we employ single-molecule magnetic tweezers to measure, in real time, the compaction of individual DNA molecules by the budding yeast condensin complex. We show that compaction can proceed in large steps, driving DNA molecules into a fully condensed state against forces of up to 2 pN. Compaction can be reversed by applying high forces or adding buffer of high ionic strength. While condensin can stably bind DNA in the absence of ATP, ATP hydrolysis by the SMC subunits is required for rendering the association salt insensitive and for the subsequent compaction process. Our results indicate that the condensin reaction cycle involves two distinct steps, where condensin first binds DNA through electrostatic interactions before using ATP hydrolysis to encircle the DNA topologically within its ring structure, which initiates DNA compaction. The finding that both binding modes are essential for its DNA compaction activity has important implications for understanding the mechanism of chromosome compaction., BN/Cees Dekker Lab, BN/Technici en Analisten

Published

2017

23. Real-time detection of condensin-driven DNA compaction reveals a multistep binding mechanism

Author

Eeftens, J.M. (author), Bisht, Shveta (author), Kerssemakers, J.W.J. (author), Kschonsak, Marc (author), Haering, Christian H. (author), Dekker, C. (author), Eeftens, J.M. (author), Bisht, Shveta (author), Kerssemakers, J.W.J. (author), Kschonsak, Marc (author), Haering, Christian H. (author), and Dekker, C. (author)

Abstract

Condensin, a conserved member of the SMC protein family of ring-shaped multi-subunit protein complexes, is essential for structuring and compacting chromosomes. Despite its key role, its molecular mechanism has remained largely unknown. Here, we employ single-molecule magnetic tweezers to measure, in real time, the compaction of individual DNA molecules by the budding yeast condensin complex. We show that compaction can proceed in large steps, driving DNA molecules into a fully condensed state against forces of up to 2 pN. Compaction can be reversed by applying high forces or adding buffer of high ionic strength. While condensin can stably bind DNA in the absence of ATP, ATP hydrolysis by the SMC subunits is required for rendering the association salt insensitive and for the subsequent compaction process. Our results indicate that the condensin reaction cycle involves two distinct steps, where condensin first binds DNA through electrostatic interactions before using ATP hydrolysis to encircle the DNA topologically within its ring structure, which initiates DNA compaction. The finding that both binding modes are essential for its DNA compaction activity has important implications for understanding the mechanism of chromosome compaction., BN/Cees Dekker Lab, BN/Technici en Analisten

Published

2017

24. The progression of replication forks at natural replication barriers in live bacteria

Author

Moolman, M.C. (author), Tiruvadi Krishnan, S. (author), Kerssemakers, J.W.J. (author), de Leeuw, R. (author), Lorent, V.J.F. (author), Sherratt, David J. (author), Dekker, N.H. (author), Moolman, M.C. (author), Tiruvadi Krishnan, S. (author), Kerssemakers, J.W.J. (author), de Leeuw, R. (author), Lorent, V.J.F. (author), Sherratt, David J. (author), and Dekker, N.H. (author)

Abstract

Protein-DNA complexes are one of the principal barriers the replisome encounters during replication. One such barrier is the Tus-ter complex, which is a direction dependent barrier for replication fork progression. The details concerning the dynamics of the replisome when encountering these Tus-ter barriers in the cell are poorly understood. By performing quantitative fluorescence microscopy with microfuidics, we investigate the effect on the replisome when encountering these barriers in live Escherichia coli cells. We make use of an E. coli variant that includes only an ectopic origin of replication that is positioned such that one of the two replisomes encounters a Tus-ter barrier before the other replisome. This enables us to single out the effect of encountering a Tus-ter roadblock on an individual replisome. We demonstrate that the replisome remains stably bound after encountering a Tus-ter complex from the non-permissive direction. Furthermore, the replisome is only transiently blocked, and continues replication beyond the barrier. Additionally, we demonstrate that these barriers affect sister chromosome segregation by visualizing specific chromosomal loci in the presence and absence of the Tus protein. These observations demonstrate the resilience of the replication fork to natural barriers and the sensitivity of chromosome alignment to fork progression., BN/Nynke Dekker Lab, BN/Technici en Analisten

Published

2016

25. The progression of replication forks at natural replication barriers in live bacteria

Author

Moolman, M.C. (author), Tiruvadi Krishnan, S. (author), Kerssemakers, J.W.J. (author), de Leeuw, R. (author), Lorent, V.J.F. (author), Sherratt, David J. (author), Dekker, N.H. (author), Moolman, M.C. (author), Tiruvadi Krishnan, S. (author), Kerssemakers, J.W.J. (author), de Leeuw, R. (author), Lorent, V.J.F. (author), Sherratt, David J. (author), and Dekker, N.H. (author)

Abstract

Protein-DNA complexes are one of the principal barriers the replisome encounters during replication. One such barrier is the Tus-ter complex, which is a direction dependent barrier for replication fork progression. The details concerning the dynamics of the replisome when encountering these Tus-ter barriers in the cell are poorly understood. By performing quantitative fluorescence microscopy with microfuidics, we investigate the effect on the replisome when encountering these barriers in live Escherichia coli cells. We make use of an E. coli variant that includes only an ectopic origin of replication that is positioned such that one of the two replisomes encounters a Tus-ter barrier before the other replisome. This enables us to single out the effect of encountering a Tus-ter roadblock on an individual replisome. We demonstrate that the replisome remains stably bound after encountering a Tus-ter complex from the non-permissive direction. Furthermore, the replisome is only transiently blocked, and continues replication beyond the barrier. Additionally, we demonstrate that these barriers affect sister chromosome segregation by visualizing specific chromosomal loci in the presence and absence of the Tus protein. These observations demonstrate the resilience of the replication fork to natural barriers and the sensitivity of chromosome alignment to fork progression., BN/Nynke Dekker Lab, BN/Technici en Analisten

Published

2016

26. Slow unloading leads to DNA-bound ?2-sliding clamp accumulation in live Escherichia coli cells

Author

Moolman, M.C. (author), Tiruvadi Krishnan, S. (author), Kerssemakers, J.W.J. (author), Van den Berg, A. (author), Tulinski, P. (author), Depken, M. (author), Reyes-Lamothe, R. (author), Sherratt, D.J. (author), Dekker, N.H. (author), Moolman, M.C. (author), Tiruvadi Krishnan, S. (author), Kerssemakers, J.W.J. (author), Van den Berg, A. (author), Tulinski, P. (author), Depken, M. (author), Reyes-Lamothe, R. (author), Sherratt, D.J. (author), and Dekker, N.H. (author)

Abstract

The ubiquitous sliding clamp facilitates processivity of the replicative polymerase and acts as a platform to recruit proteins involved in replication, recombination and repair. While the dynamics of the E. coli ?2-sliding clamp have been characterized in vitro, its in vivo stoichiometry and dynamics remain unclear. To probe both ?2-clamp dynamics and stoichiometry in live E. coli cells, we use custom-built microfluidics in combination with single-molecule fluorescence microscopy and photoactivated fluorescence microscopy. We quantify the recruitment, binding and turnover of ?2-sliding clamps on DNA during replication. These quantitative in vivo results demonstrate that numerous ?2-clamps in E. coli remain on the DNA behind the replication fork for a protracted period of time, allowing them to form a docking platform for other enzymes involved in DNA metabolism., BN/Bionanoscience, Applied Sciences

Published

2014

27. Slow unloading leads to DNA-bound ?2-sliding clamp accumulation in live Escherichia coli cells

Author

Moolman, M.C. (author), Tiruvadi Krishnan, S. (author), Kerssemakers, J.W.J. (author), Van den Berg, A. (author), Tulinski, P. (author), Depken, M. (author), Reyes-Lamothe, R. (author), Sherratt, D.J. (author), Dekker, N.H. (author), Moolman, M.C. (author), Tiruvadi Krishnan, S. (author), Kerssemakers, J.W.J. (author), Van den Berg, A. (author), Tulinski, P. (author), Depken, M. (author), Reyes-Lamothe, R. (author), Sherratt, D.J. (author), and Dekker, N.H. (author)

Abstract

The ubiquitous sliding clamp facilitates processivity of the replicative polymerase and acts as a platform to recruit proteins involved in replication, recombination and repair. While the dynamics of the E. coli ?2-sliding clamp have been characterized in vitro, its in vivo stoichiometry and dynamics remain unclear. To probe both ?2-clamp dynamics and stoichiometry in live E. coli cells, we use custom-built microfluidics in combination with single-molecule fluorescence microscopy and photoactivated fluorescence microscopy. We quantify the recruitment, binding and turnover of ?2-sliding clamps on DNA during replication. These quantitative in vivo results demonstrate that numerous ?2-clamps in E. coli remain on the DNA behind the replication fork for a protracted period of time, allowing them to form a docking platform for other enzymes involved in DNA metabolism., BN/Bionanoscience, Applied Sciences

Published

2014

28. Electron beam fabrication of a microfluidic device for studying submicron-scale bacteria

Author

Moolman, M.C. (author), Huang, Z. (author), Krishnan, S.T. (author), Kerssemakers, J.W.J. (author), Dekker, N.H. (author), Moolman, M.C. (author), Huang, Z. (author), Krishnan, S.T. (author), Kerssemakers, J.W.J. (author), and Dekker, N.H. (author)

Abstract

Background: Controlled restriction of cellular movement using microfluidics allows one to study individual cells to gain insight into aspects of their physiology and behaviour. For example, the use of micron-sized growth channels that confine individual Escherichia coli has yielded novel insights into cell growth and death. To extend this approach to other species of bacteria, many of whom have dimensions in the sub-micron range, or to a larger range of growth conditions, a readily-fabricated device containing sub-micron features is required. Results: Here we detail the fabrication of a versatile device with growth channels whose widths range from 0.3 ?m to 0.8 ?m. The device is fabricated using electron beam lithography, which provides excellent control over the shape and size of different growth channels and facilitates the rapid-prototyping of new designs. Features are successfully transferred first into silicon, and subsequently into the polydimethylsiloxane that forms the basis of the working microfluidic device. We demonstrate that the growth of sub-micron scale bacteria such as Lactococcus lactis or Escherichia coli cultured in minimal medium can be followed in such a device over several generations. Conclusions: We have presented a detailed protocol based on electron beam fabrication together with specific dry etching procedures for the fabrication of a microfluidic device suited to study submicron-sized bacteria. We have demonstrated that both Gram-positive and Gram-negative bacteria can be successfully loaded and imaged over a number of generations in this device. Similar devices could potentially be used to study other submicron-sized organisms under conditions in which the height and shape of the growth channels are crucial to the experimental design., BN/Bionanoscience, Applied Sciences

Published

2013

29. Electron beam fabrication of a microfluidic device for studying submicron-scale bacteria

Author

Moolman, M.C. (author), Huang, Z. (author), Krishnan, S.T. (author), Kerssemakers, J.W.J. (author), Dekker, N.H. (author), Moolman, M.C. (author), Huang, Z. (author), Krishnan, S.T. (author), Kerssemakers, J.W.J. (author), and Dekker, N.H. (author)

Abstract

Background: Controlled restriction of cellular movement using microfluidics allows one to study individual cells to gain insight into aspects of their physiology and behaviour. For example, the use of micron-sized growth channels that confine individual Escherichia coli has yielded novel insights into cell growth and death. To extend this approach to other species of bacteria, many of whom have dimensions in the sub-micron range, or to a larger range of growth conditions, a readily-fabricated device containing sub-micron features is required. Results: Here we detail the fabrication of a versatile device with growth channels whose widths range from 0.3 ?m to 0.8 ?m. The device is fabricated using electron beam lithography, which provides excellent control over the shape and size of different growth channels and facilitates the rapid-prototyping of new designs. Features are successfully transferred first into silicon, and subsequently into the polydimethylsiloxane that forms the basis of the working microfluidic device. We demonstrate that the growth of sub-micron scale bacteria such as Lactococcus lactis or Escherichia coli cultured in minimal medium can be followed in such a device over several generations. Conclusions: We have presented a detailed protocol based on electron beam fabrication together with specific dry etching procedures for the fabrication of a microfluidic device suited to study submicron-sized bacteria. We have demonstrated that both Gram-positive and Gram-negative bacteria can be successfully loaded and imaged over a number of generations in this device. Similar devices could potentially be used to study other submicron-sized organisms under conditions in which the height and shape of the growth channels are crucial to the experimental design., BN/Bionanoscience, Applied Sciences

Published

2013

30. Non-Bias-Limited Tracking of Spherical Particles, Enabling Nanometer Resolution at Low Magnification

Author

Van Loenhout, M.T.J. (author), Kerssemakers, J.W.J. (author), De Vlaminck, I. (author), Dekker, C. (author), Van Loenhout, M.T.J. (author), Kerssemakers, J.W.J. (author), De Vlaminck, I. (author), and Dekker, C. (author)

Abstract

We present a three-dimensional tracking routine for nondiffraction-limited particles, which significantly reduces pixel bias. Our technique allows for increased resolution compared to that of previous methods, especially at low magnification or at high signal/noise ratio. This enables tracking with nanometer accuracy in a wide field of view and tracking of many particles. To reduce bias induced by pixelation, the tracking algorithm uses interpolation of the image on a circular grid to determine the x-, y-, and z-positions. We evaluate the proposed algorithm by tracking simulated images and compare it to well-known center-of-mass and cross-correlation methods. The final resolution of the described method improves up to an order of magnitude in three dimensions compared to conventional tracking methods. We show that errors in x,y-tracking can seriously affect z-tracking if interpolation is not used. We validate our results with experimental data obtained for conditions matching those used in the simulations. Finally, we show that the increased performance of the proposed algorithm uniquely enables it to extract accurate data for the persistence length and end-to-end distance of 107 DNA tethers in a single experiment, BN/Bionanoscience, Applied Sciences

Published

2012

31. Non-Bias-Limited Tracking of Spherical Particles, Enabling Nanometer Resolution at Low Magnification

Author

Van Loenhout, M.T.J. (author), Kerssemakers, J.W.J. (author), De Vlaminck, I. (author), Dekker, C. (author), Van Loenhout, M.T.J. (author), Kerssemakers, J.W.J. (author), De Vlaminck, I. (author), and Dekker, C. (author)

Abstract

We present a three-dimensional tracking routine for nondiffraction-limited particles, which significantly reduces pixel bias. Our technique allows for increased resolution compared to that of previous methods, especially at low magnification or at high signal/noise ratio. This enables tracking with nanometer accuracy in a wide field of view and tracking of many particles. To reduce bias induced by pixelation, the tracking algorithm uses interpolation of the image on a circular grid to determine the x-, y-, and z-positions. We evaluate the proposed algorithm by tracking simulated images and compare it to well-known center-of-mass and cross-correlation methods. The final resolution of the described method improves up to an order of magnitude in three dimensions compared to conventional tracking methods. We show that errors in x,y-tracking can seriously affect z-tracking if interpolation is not used. We validate our results with experimental data obtained for conditions matching those used in the simulations. Finally, we show that the increased performance of the proposed algorithm uniquely enables it to extract accurate data for the persistence length and end-to-end distance of 107 DNA tethers in a single experiment, BN/Bionanoscience, Applied Sciences

Published

2012