Your search keyword '"Vasily Zaburdaev"' showing total 23 results

1. A DNA Segregation Module for Synthetic Cells

Author

Mai P. Tran, Rakesh Chatterjee, Yannik Dreher, Julius Fichtler, Kevin Jahnke, Lennart Hilbert, Vasily Zaburdaev, and Kerstin Göpfrich

Subjects

Biomaterials, Life sciences, biology, ddc:570, General Materials Science, General Chemistry, Biotechnology

Abstract

The bottom-up construction of an artificial cell requires the realization of synthetic cell division. Significant progress has been made towards reliable compartment division, yet mechanisms to segregate the DNA-encoded informational content are still in their infancy. Herein, droplets of DNA Y-motifs are formed by liquid-liquid phase separation (LLPS). Entropy-driven DNA droplet segregation is obtained by cleaving the linking component between two populations of DNA Y-motifs. In addition to enzymatic cleavage, photolabile sites are introduced for spatio-temporally controlled DNA segregation in bulk as well as in cell-sized water-in-oil droplets and giant unilamellar lipid vesicles (GUVs). Notably, the segregation process is slower in confinement than in bulk. The ionic strength of the solution and the nucleobase sequences are employed to regulate the segregation dynamics. The experimental results are corroborated in a lattice-based theoretical model which mimics the interactions between the DNA Y-motif populations. Altogether, engineered DNA droplets, reconstituted in GUVs, could represent a strategy towards an entropy-driven DNA segregation module within bottom-up assembled synthetic cells.Table of ContentsAn entropy-driven DNA segregation module for bottom-up assembled synthetic cells is realized. It is based on DNA droplets that are engineered to segregate upon enzymatic or photocleavage inside giant unilamellar lipid vesicles (GUVs). The segregation kinetics is altered by the confinement, as confirmed by lattice-based numerical simulations. DNA segregation is further controlled by temperature, ionic strengths and nucleobase sequence.

Published

2023

2. The hierarchical packing of euchromatin domains can be described as multiplicative cascades

Author

Amra Noa, Hui-Shun Kuan, Vera Aschmann, Vasily Zaburdaev, and Lennart Hilbert

Subjects

Life sciences, biology, Embryology, QH301-705.5, Gene Expression, Geometry, Research and Analysis Methods, Euchromatin, Model Organisms, Protein Domains, ddc:570, Genetics, Morphogenesis, Animals, Humans, Pattern Formation, Biology (General), Cytoplasmic Staining, Zebrafish, Staining, Chromosome Biology, Embryos, Organisms, Biology and Life Sciences, Eukaryota, Cell Biology, Animal Models, Zebrafish Proteins, Chromatin, Fish, Fractals, Experimental Organism Systems, Osteichthyes, Specimen Preparation and Treatment, Vertebrates, Physical Sciences, Animal Studies, Epigenetics, Zoology, Embryonic Pattern Formation, Mathematics, Research Article, Developmental Biology

Abstract

The genome is packed into the cell nucleus in the form of chromatin. Biochemical approaches have revealed that chromatin is packed within domains, which group into larger domains, and so forth. Such hierarchical packing is equally visible in super-resolution microscopy images of large-scale chromatin organization. While previous work has suggested that chromatin is partitioned into distinct domains via microphase separation, it is unclear how these domains organize into this hierarchical packing. A particular challenge is to find an image analysis approach that fully incorporates such hierarchical packing, so that hypothetical governing mechanisms of euchromatin packing can be compared against the results of such an analysis. Here, we obtain 3D STED super-resolution images from pluripotent zebrafish embryos labeled with improved DNA fluorescence stains, and demonstrate how the hierarchical packing of euchromatin in these images can be described as multiplicative cascades. Multiplicative cascades are an established theoretical concept to describe the placement of ever-smaller structures within bigger structures. Importantly, these cascades can generate artificial image data by applying a single rule again and again, and can be fully specified using only four parameters. Here, we show how the typical patterns of euchromatin organization are reflected in the values of these four parameters. Specifically, we can pinpoint the values required to mimic a microphase-separated state of euchromatin. We suggest that the concept of multiplicative cascades can also be applied to images of other types of chromatin. Here, cascade parameters could serve as test quantities to assess whether microphase separation or other theoretical models accurately reproduce the hierarchical packing of chromatin., Author summary DNA is stored inside the cell nucleus in the form of chromatin. Chromatin exhibits a striking three-dimensional organization, where small domains group into larger domains, which again group into larger domains, and so forth. While this hierarchical domain packing is obvious from microscopy images, it is still not entirely clear how it is established, or how it should be properly characterized. Here, we demonstrate that multiplicative cascades—a concept from theoretical physics used to characterize for example cloud patterns, galaxy locations, or soil patterns—are also ideally suited to describe the domain-within-domain organization of chromatin. This description is rather simple, using only four numbers, and can thus facilitate testing of competing theories for the packing of chromatin domains.

Published

2020

3. Exogenous ethanol induces a metabolic switch that prolongs the survival of Caenorhabditis elegans dauer larva and enhances its resistance to desiccation

Author

Roberta Galli, Andrej Shevchenko, Vasily Zaburdaev, Xingyu Zhang, Vamshidhar R. Gade, Edmund Koch, Teymuras V. Kurzchalia, Robert Haase, Damla Kaptan, Bharath Kumar Raghuraman, Julio L. Sampaio, and Sider Penkov

Subjects

0301 basic medicine, Dauer larva, Mitochondrion, Desiccation tolerance, 03 medical and health sciences, 0302 clinical medicine, Aging, Exogenous Ethanol, Metabolic Shift, Mitochondrial Health, Stress Resistance, ddc:570, Animals, Desiccation, Caenorhabditis elegans, stress resistance, biology, Ethanol, aging, fungi, Lipid metabolism, Cell Biology, Metabolism, Original Articles, mitochondrial health, biology.organism_classification, Lipid Metabolism, Cell biology, 030104 developmental biology, exogenous ethanol, Larva, Original Article, Energy source, 030217 neurology & neurosurgery, metabolic shift

Abstract

The dauer larva of Caenorhabditis elegans, destined to survive long periods of food scarcity and harsh environment, does not feed and has a very limited exchange of matter with the exterior. It was assumed that the survival time is determined by internal energy stores. Here, we show that ethanol can provide a potentially unlimited energy source for dauers by inducing a controlled metabolic shift that allows it to be metabolized into carbohydrates, amino acids, and lipids. Dauer larvae provided with ethanol survive much longer and have greater desiccation tolerance. On the cellular level, ethanol prevents the deterioration of mitochondria caused by energy depletion. By modeling the metabolism of dauers of wild‐type and mutant strains with and without ethanol, we suggest that the mitochondrial health and survival of an organism provided with an unlimited source of carbon depends on the balance between energy production and toxic product(s) of lipid metabolism., Exogenous ethanol supports the survival of Caenorhabditis elegans dauer larvae by inducing a metabolic shift that drives its conversion into sugars, amino acids, and storage lipids, thus promoting mitochondrial integrity and stress resistance. Excessive production of lipids out of ethanol, however, appears to limit the survival due to a buildup of toxic lipids, suggesting that the balance between energy production and lipid metabolism determines the survival in the presence of an unlimited source of carbon.

Published

2020

4. Author Correction: Transcription organizes euchromatin via microphase separation

Author

Ksenia Kuznetsova, Tommaso Bianucci, Alf Honigmann, Vasily Zaburdaev, Nadine L. Vastenhouw, Hiroshi Kimura, Frank Jülicher, Yuko Sato, and Lennart Hilbert

Subjects

Life sciences, biology, Cell biology, Multidisciplinary, Embryo, Nonmammalian, Euchromatin, Transcription, Genetic, Chemistry, RNA Stability, Science, Biophysics, General Physics and Astronomy, Mitosis, General Chemistry, Computational biology, General Biochemistry, Genetics and Molecular Biology, ddc:570, Animals, RNA, Computer Simulation, Emulsions, Transcription (software), Author Correction, Zebrafish

Abstract

In eukaryotes, DNA is packed inside the cell nucleus in the form of chromatin, which consists of DNA, proteins such as histones, and RNA. Euchromatin, which is permissive for transcription, is spatially organized into transcriptionally inactive domains interspersed with pockets of transcriptional activity. While transcription and RNA have been implicated in euchromatin organization, it remains unclear how their interplay forms and maintains transcription pockets. Here we combine theory and experiment to analyze the dynamics of euchromatin organization as pluripotent zebrafish cells exit mitosis and begin transcription. We show that accumulation of RNA induces formation of transcription pockets which displace transcriptionally inactive chromatin. We propose that the accumulating RNA recruits RNA-binding proteins that together tend to separate from transcriptionally inactive euchromatin. Full phase separation is prevented because RNA remains tethered to transcribed euchromatin through RNA polymerases. Instead, smaller scale microphases emerge that do not grow further and form the typical pattern of euchromatin organization.

Published

2021

5. Histone H3K27 acetylation precedes active transcription during zebrafish zygotic genome activation as revealed by live cell analysis

Author

Philipp J. Keller, Nadine L. Vastenhouw, Timothée Lionnet, Vasily Zaburdaev, Lennart Hilbert, Hiroshi Kimura, Haruka Oda, Yuko Sato, Yinan Wan, John M. Heddleston, and Teng-Leong Chew

Subjects

Life sciences, biology, Embryo, Nonmammalian, Morpholino, Transcription, Genetic, Zygote, RNA polymerase II, Zygotic genome activation, Histones, 03 medical and health sciences, 0302 clinical medicine, Techniques and Resources, Live-cell imaging, Transcription (biology), ddc:570, Gene expression, Animals, RNA, Messenger, Molecular Biology, Zebrafish, 030304 developmental biology, Alpha-Amanitin, Cell Nucleus, 0303 health sciences, Genome, Chromatin regulation, Lysine, Histone modifications, Gene Expression Regulation, Developmental, Acetylation, Zebrafish Proteins, biology.organism_classification, Cell biology, Histone Code, Histone, biology.protein, Maternal to zygotic transition, RNA Polymerase II, 030217 neurology & neurosurgery, Developmental Biology

Abstract

Histone post-translational modifications are key gene expression regulators, but their rapid dynamics during development remain difficult to capture. We applied a Fab-based live endogenous modification labeling technique to monitor the changes in histone modification levels during zygotic genome activation (ZGA) in living zebrafish embryos. Among various histone modifications, H3 Lys27 acetylation (H3K27ac) exhibited most drastic changes, accumulating in two nuclear foci in the 64- to 1k-cell-stage embryos. The elongating form of RNA polymerase II, which is phosphorylated at Ser2 in heptad repeats within the C-terminal domain (RNAP2 Ser2ph), and miR-430 transcripts were also concentrated in foci closely associated with H3K27ac. When treated with α-amanitin to inhibit transcription or JQ-1 to inhibit binding of acetyl-reader proteins, H3K27ac foci still appeared but RNAP2 Ser2ph and miR-430 morpholino were not concentrated in foci, suggesting that H3K27ac precedes active transcription during ZGA. We anticipate that the method presented here could be applied to a variety of developmental processes in any model and non-model organisms., Summary: FabLEM, an endogenous labeling technique that uses modification-specific antigen-binding fragments, is used to examine changes in histone modification levels and transcription during zygotic genome activation in live zebrafish embryos.

Published

2019

6. Quantitative measurements of chromatin modification dynamics during zygotic genome activation

Author

Lennart Hilbert, Timothée Lionnet, Teng-Leong Chew, Haruka Oda, Philipp J. Keller, Yinan Wan, Hiroshi Kimura, Nadine L. Vastenhouw, John M. Heddleston, Yuko Sato, and Vasily Zaburdaev

Subjects

Histone H3, Histone, biology, Transcription (biology), Acetylation, Gene expression, biology.protein, Maternal to zygotic transition, Locus (genetics), Genome, Cell biology

Abstract

Histone posttranslational modifications (PTMs) are key gene expression regulators, but their rapid dynamics during development remain difficult to capture. We describe an approach that images fluorescent antibody fragments to quantify PTM enrichment and active transcription at defined loci during zygotic genome activation in living zebrafish embryos. The technique reveals a drastic increase in histone H3 Lys27 acetylation (H3K27ac) before genome activation both at a specific locus and globally.

Published

2019

7. Intracellular Mass Density Increase Is Accompanying but Not Sufficient for Stiffening and Growth Arrest of Yeast Cells

Author

Shada Abuhattum, Kyoohyun Kim, Titus M. Franzmann, Anne Eßlinger, Daniel Midtvedt, Raimund Schlüßler, Stephanie Möllmert, Hui-Shun Kuan, Simon Alberti, Vasily Zaburdaev, and Jochen Guck

Subjects

0301 basic medicine, optical diffraction tomography, Materials Science (miscellaneous), Intracellular pH, Biophysics, General Physics and Astronomy, liquid solid transition, yeast, 01 natural sciences, 010309 optics, 03 medical and health sciences, stiffness, ddc:570, Growth arrest, 0103 physical sciences, Physical and Theoretical Chemistry, Mathematical Physics, 030304 developmental biology, 0303 health sciences, atomic force microscopy, refractive index, biology, Chemistry, Atomic force microscopy, Metabolism, Naturwissenschaftliche Fakultät, biology.organism_classification, Yeast, lcsh:QC1-999, Cell biology, Living matter, 030104 developmental biology, Cytoplasm, Reprogramming, Bacteria, Intracellular, lcsh:Physics

Abstract

Many organisms, including yeast cells, bacteria, nematodes and tardigrades, endure harsh environmental conditions, such as nutrient scarcity, or lack of water and energy for a remarkably long time. The rescue programs that these organisms launch upon encountering these adverse conditions include reprogramming their metabolism in order to enter a quiescent or dormant state in a controlled fashion. Reprogramming coincides with changes in the macromolecular architecture and changes in the physical and mechanical properties of the cells. However, the cellular mechanisms underlying the physical-mechanical changes remain enigmatic. Here, we induce metabolic arrest of yeast cells by lowering their intracellular pH. We then determine the differences in the intracellular mass density and stiffness of active and metabolically arrested cells using optical diffraction tomography and atomic force microscopy. We show that an increased intracellular mass density is associated with an increase in stiffness when the growth of yeast is arrested. However, increasing the intracellular mass density alone is not sufficient for maintenance of the growth-arrested state in yeast cells. Our data suggest that the cytoplasm of metabolically arrested yeast displays characteristics of solid. Our findings constitute a bridge between the mechanical behavior of the cytoplasm and the physical and chemical mechanisms of metabolically arrested cells with the ultimate aim of understanding dormant organisms.

Published

2018

8. Pili mediated intercellular forces shape heterogeneous bacterial microcolonies prior to multicellular differentiation

Author

Kelly B. Eckenrode, Vasily Zaburdaev, Hadi Nasrollahi, Wolfram Pönisch, Khaled Alzurqa, Nicolas Biais, and Christoph Weber

Subjects

0301 basic medicine, 030106 microbiology, Cell, FOS: Physical sciences, Motility, lcsh:Medicine, Pilus, Article, Physical Phenomena, 03 medical and health sciences, medicine, Physics - Biological Physics, ddc:610, lcsh:Science, Multidisciplinary, biology, Chemistry, lcsh:R, Biofilm, High cell, biology.organism_classification, Neisseria gonorrhoeae, Cell biology, Living matter, Multicellular organism, 030104 developmental biology, medicine.anatomical_structure, Biological Physics (physics.bio-ph), Cell Tracking, Fimbriae, Bacterial, Microscopy, Electron, Scanning, lcsh:Q, Single-Cell Analysis, Intracellular, Bacteria

Abstract

Microcolonies are aggregates of a few dozen to a few thousand cells exhibited by many bacteria. The formation of microcolonies is a crucial step towards the formation of more mature bacterial communities known as biofilms, but also marks a significant change in bacterial physiology. Within a microcolony, bacteria forgo a single cell lifestyle for a communal lifestyle hallmarked by high cell density and physical interactions between cells potentially altering their behaviour. It is thus crucial to understand how initially identical single cells start to behave differently while assembling in these tight communities. Here we show that cells in the microcolonies formed by the human pathogen Neisseria gonorrhoeae (Ng) present differential motility behaviors within an hour upon colony formation. Observation of merging microcolonies and tracking of single cells within microcolonies reveal a heterogeneous motility behavior: cells close to the surface of the microcolony exhibit a much higher motility compared to cells towards the center. Numerical simulations of a biophysical model for the microcolonies at the single cell level suggest that the emergence of differential behavior within a multicellular microcolony of otherwise identical cells is of mechanical origin. It could suggest a route toward further bacterial differentiation and ultimately mature biofilms., Comment: 29 pages, 5 figures, supplementary information attached

Published

2018

9. How bacterial cells and colonies move on solid substrates

Author

Christoph Weber, Wolfram Pönisch, and Vasily Zaburdaev

Subjects

Persistence length, Stochastic Processes, biology, Chemistry, Movement, Fimbria, Dynamics (mechanics), FOS: Physical sciences, Motility, medicine.disease_cause, Random walk, biology.organism_classification, Models, Biological, Pilus, Neisseria gonorrhoeae, Living matter, Biological Physics (physics.bio-ph), Fimbriae, Bacterial, medicine, Biophysics, Physics - Biological Physics, Bacteria

Abstract

Many bacteria rely on active cell appendages, such as type IV pili, to move over substrates and interact with neighboring cells. Here, we study the motion of individual cells and bacterial colonies, mediated by the collective interactions of multiple pili. It was shown experimentally that the substrate motility of Neisseria gonorrhoeae cells can be described as a persistent random walk with a persistence length that exceeds the mean pili length. Moreover, the persistence length increases for a higher number of pili per cell. With the help of a simple, tractable stochastic model, we test whether a tug-of-war without directional memory can explain the persistent motion of single Neisseria gonorrhoeae cells. While the persistent motion of single cells indeed emerges naturally in the model, a tug-of-war alone is not capable of explaining the motility of microcolonies, which becomes weaker with increasing colony size. We suggest sliding friction between the microcolonies and the substrate as the missing ingredient. While such friction almost does not affect the general mechanism of single cell motility, it has a strong effect on colony motility. We validate the theoretical predictions by using a three-dimensional computational model that includes explicit details of the pili dynamics, force generation and geometry of cells., Comment: 25 pages, 17 figures

Published

2018

10. Transcription organizes euchromatin similar to an active microemulsion

Author

Vasily Zaburdaev, Lennart Hilbert, Hiroshi Kimura, Alf Honigmann, Yuko Sato, Frank Jülicher, and Nadine L. Vastenhouw

Subjects

Euchromatin, Transcription (biology), Binding protein, RNA, Biology, biology.organism_classification, Gene, Genome, Zebrafish, Chromatin, Cell biology

Abstract

The three-dimensional organization of the genome is essential for development and health. Although the organization of euchromatin (transcriptionally permissive chromatin) dynamically adjusts to changes in transcription, the underlying mechanisms remain elusive. Here, we studied how transcription organizes euchromatin, using experiments in zebrafish embryonic cells and theory. We show that transcription establishes an interspersed pattern of chromatin domains and RNA-enriched microenvironments. Specifically, accumulation of RNA in the vicinity of transcription sites creates microenvironments that locally remodel chromatin by displacing not transcribed chromatin. Ongoing transcriptional activity stabilizes the interspersed pattern of chromatin domains and RNA-enriched microenvironments by establishing contacts between chromatin and RNA. We explain our observations with an active microemulsion model based on two macromolecular mechanisms: RNA/RNA-binding protein complexes generally segregate from chromatin, while transcribed chromatin is retained among RNA/RNA-binding protein accumulations. We propose that microenvironments might be central to genome architecture and serve as gene regulatory hubs.

Published

2017

11. Author response: Competition between histone and transcription factor binding regulates the onset of transcription in zebrafish embryos

Author

Jens Karschau, Vasily Zaburdaev, Máté Pálfy, Lennart Hilbert, Andrej Shevchenko, Nadine L. Vastenhouw, Mukesh Kumar, and Shai R. Joseph

Subjects

Histone, biology, Transcription (biology), biology.protein, Zebrafish embryo, Transcription factor, Cell biology

Published

2017

12. Competition between histone and transcription factor binding regulates the onset of transcription in zebrafish embryos

Author

Lennart Hilbert, Máté Pálfy, Shai R. Joseph, Andrej Shevchenko, Nadine L. Vastenhouw, Vasily Zaburdaev, Mukesh Kumar, and Jens Karschau

Subjects

0301 basic medicine, Histone-modifying enzymes, Transcription, Genetic, Response element, Transcription coregulator, Genome, chemistry.chemical_compound, Transcription (biology), Histone methylation, Biology (General), Zebrafish, Genetics, General transcription factor, General Neuroscience, Gene Expression Regulation, Developmental, Embryo, General Medicine, ZGA, Cell biology, Living matter, Histone, Genes and Chromosomes, Medicine, embryogenesis, transcription regulation, competition, Research Article, Protein Binding, QH301-705.5, Science, E-box, Biology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, histones, Animals, Nucleosome, Protein–DNA interaction, Transcription factor, General Immunology and Microbiology, Pioneer factor, DNA, Developmental Biology and Stem Cells, 030104 developmental biology, chemistry, biology.protein, Developmental biology, Transcription Factors

Abstract

Upon fertilization, the genome of animal embryos remains transcriptionally inactive until the maternal-to-zygotic transition. At this time, the embryo takes control of its development and transcription begins. How the onset of zygotic transcription is regulated remains unclear. Here, we show that a dynamic competition for DNA binding between nucleosome-forming histones and transcription factors regulates zebrafish genome activation. Taking a quantitative approach, we found that the concentration of non-DNA-bound core histones sets the time for the onset of transcription. The reduction in nuclear histone concentration that coincides with genome activation does not affect nucleosome density on DNA, but allows transcription factors to compete successfully for DNA binding. In agreement with this, transcription factor binding is sensitive to histone levels and the concentration of transcription factors also affects the time of transcription. Our results demonstrate that the relative levels of histones and transcription factors regulate the onset of transcription in the embryo. DOI: http://dx.doi.org/10.7554/eLife.23326.001, eLife digest The DNA in a fertilized egg contains all the information required to form an animal’s body. In order for the animal to develop properly, particular genes encoded in the DNA are only active at specific times. The DNA is wrapped around proteins called histones, which allows the DNA to be tightly packed inside the cell. However, histones can block other proteins called transcription factors from binding to the DNA to activate the genes. Young embryos initially develop with all of their genes switched off, relying on the nutrients and other molecules provided by their mother. After some time, the embryo starts to switch on its own genes to take control of its own development, but it was not clear how this happens. Joseph et al. investigated how genes are activated in zebrafish embryos, which are often used as models to study how animals develop. The experiments show that competition between histones and transcription factors for binding to DNA controls when genes are switched on. In young fish embryos, there are so many histones present that transcription factors have no opportunity to bind to DNA. Over time, however, the numbers of histones decrease, allowing transcription factors to bind to DNA and switch on genes. Histones and transcription factors regulate the activity of genes throughout the life of the animal. Therefore, competition between these two types of protein may also control gene activity in other situations. A better understanding of how gene activity is controlled could allow researchers to more easily grow different types of cell in the laboratory or to reprogram specific cells in the body. As such, these new findings may aid the development of therapies to regenerate organs or tissues that have been damaged by injury or disease. DOI: http://dx.doi.org/10.7554/eLife.23326.002

Published

2017

13. A Bacterial Swimmer with Two Alternating Speeds of Propagation

Author

Matthias Theves, Carsten Beta, Johannes Taktikos, Holger Stark, and Vasily Zaburdaev

Subjects

Systems Biophysics, Time Factors, Pseudomonas putida, Ecology, Movement, Autocorrelation, Biophysics, Institut für Physik und Astronomie, Rotational diffusion, Geometry, Biology, Models, Biological, Displacement (vector), Swimming speed, Extended model, Constant (mathematics)

Abstract

We recorded large data sets of swimming trajectories of the soil bacterium Pseudomonas putida. Like other prokaryotic swimmers, P. putida exhibits a motion pattern dominated by persistent runs that are interrupted by turning events. An in-depth analysis of their swimming trajectories revealed that the majority of the turning events is characterized by an angle of phi(1) = 180 degrees (reversals). To a lesser extent, turning angles of phi(2 Sigma Sigma Sigma Sigma) = 00 are also found. Remarkably, we observed that, upon a reversal, the swimming speed changes by a factor of two on average a prominent feature of the motion pattern that, to our knowledge, has not been reported before. A theoretical model, based on the experimental values for the average run time and the rotational diffusion, recovers the mean-square displacement of P. putida if the two distinct swimming speeds are taken into account. Compared to a swimmer that moves with a constant intermediate speed, the mean-square displacement is strongly enhanced. We furthermore observed a negative dip in the directional autocorrelation at intermediate times, a feature that is only recovered in an extended model, where the nonexponential shape of the run-time distribution is taken into account.

Published

2013

14. Nucleosomal arrangement affects single-molecule transcription dynamics

Author

Patrick Cramer, Veronika Fitz, Christoph Ehrlich, Jaeoh Shin, Stephan W. Grill, Lucas Farnung, and Vasily Zaburdaev

Subjects

0301 basic medicine, Genetics, Multidisciplinary, biology, RNA, RNA polymerase II, Biological Sciences, Chromatin, Living matter, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, 0302 clinical medicine, chemistry, Gene expression, biology.protein, Biophysics, Nucleosome, A-DNA, 030217 neurology & neurosurgery, Polymerase, DNA

Abstract

In eukaryotes, gene expression depends on chromatin organization. However, how chromatin affects the transcription dynamics of individual RNA polymerases has remained elusive. Here, we use dual trap optical tweezers to study single yeast RNA polymerase II (Pol II) molecules transcribing along a DNA template with two nucleosomes. The slowdown and the changes in pausing behavior within the nucleosomal region allow us to determine a drift coefficient,., which characterizes the ability of the enzyme to recover from a nucleosomal backtrack. Notably, chi can be used to predict the probability to pass the first nucleosome. Importantly, the presence of a second nucleosome changes chi in a manner that depends on the spacing between the two nucleosomes, as well as on their rotational arrangement on the helical DNA molecule. Our results indicate that the ability of Pol II to pass the first nucleosome is increased when the next nucleosome is turned away from the first one to face the opposite side of the DNA template. These findings help to rationalize how chromatin arrangement affects Pol II transcription dynamics.

Published

2016

15. A pH-driven transition of the cytoplasm from a fluid- to a solid-like state promotes entry into dormancy

Author

Titus M. Franzmann, Jochen Guck, Elke Ulbricht, Anna Taubenberger, Shovamayee Maharana, Matthias C. Munder, Oliver Otto, Simon Alberti, Maik Herbig, Paul Müller, Doris Richter, Vasily Zaburdaev, Elisabeth Nüske, Daniel Midtvedt, and Liliana Malinovska

Subjects

0301 basic medicine, Cytoplasm, dormancy, food.ingredient, QH301-705.5, Cell Survival, cytosolic pH, Science, Cell, Saccharomyces cerevisiae, Phase Transition, General Biochemistry, Genetics and Molecular Biology, Amoeba (genus), macromolecular assembly, S. cerevisiae, 03 medical and health sciences, 0302 clinical medicine, food, Stress, Physiological, medicine, Dictyostelium, Biology (General), General Immunology and Microbiology, biology, General Neuroscience, starvation, Cell Biology, General Medicine, Hydrogen-Ion Concentration, Biophysics and Structural Biology, biology.organism_classification, Yeast, Living matter, Cell biology, Macromolecular assembly, 030104 developmental biology, medicine.anatomical_structure, S. pombe, Structural biology, Biochemistry, Medicine, Dormancy, metabolism, 030217 neurology & neurosurgery, Research Article

Abstract

Cells can enter into a dormant state when faced with unfavorable conditions. However, how cells enter into and recover from this state is still poorly understood. Here, we study dormancy in different eukaryotic organisms and find it to be associated with a significant decrease in the mobility of organelles and foreign tracer particles. We show that this reduced mobility is caused by an influx of protons and a marked acidification of the cytoplasm, which leads to widespread macromolecular assembly of proteins and triggers a transition of the cytoplasm to a solid-like state with increased mechanical stability. We further demonstrate that this transition is required for cellular survival under conditions of starvation. Our findings have broad implications for understanding alternative physiological states, such as quiescence and dormancy, and create a new view of the cytoplasm as an adaptable fluid that can reversibly transition into a protective solid-like state. DOI: http://dx.doi.org/10.7554/eLife.09347.001, eLife digest Most organisms live in unpredictable environments, which can often lead to nutrient shortages and other conditions that limit their ability to grow. To survive in these harsh conditions, many organisms adopt a dormant state in which their metabolism slows down to conserve vital energy. When the environmental conditions improve, the organisms can return to their normal state and continue to grow. The interior of cells is known as the cytoplasm. It is very crowded and contains many molecules and compartments called organelles that carry out a variety of vital processes. The cytoplasm has long been considered to be fluid-like in nature, but recent evidence suggests that in bacterial cells it can solidify to resemble a soft glass-type material under certain conditions. When cells become dormant they stop dividing and reorganise their cytoplasm in several ways; for example, the water content drops and many essential proteins form storage compartments. However, it was not clear how cells regulate the structure of the cytoplasm to enter into or exit from dormancy. Now, Munder et al. analyse the changes that occur in the cytoplasm when baker’s yeast cells enter a dormant state. The experiments show that when yeast cells are deprived of energy – as happens during dormancy – the cytoplasm becomes more acidic than normal. This limits the ability of molecules and organelles to move around the cytoplasm. Similar results were also seen in other types of fungi and an amoeba. Munder et al. found that this increase in acidity during dormancy causes many proteins to interact with each other and form large clumps or filament structures that result in the cytoplasm becoming stiffer. A separate study by Joyner et al. found that when yeast cells are starved of sugar, two large molecules are less able to move around the cell interior. Together, the findings of the studies suggest that the interior of cells can undergo a transition from a fluid-like to a more solid-like state to protect the cells from damage when energy is in short supply. The next challenge is to understand the molecular mechanisms that cause the physical properties of the cytoplasm to change under different conditions. DOI: http://dx.doi.org/10.7554/eLife.09347.002

Published

2016

16. Liquid transport facilitated by channels in Bacillus subtilis biofilms

Author

Michael Brenner, Vasily Zaburdaev, David A. Weitz, Richard Losick, Michael De Volder, and James N. Wilking

Subjects

Diffusion, Biological Transport, Active, Bacillus subtilis, Aquaporins, Biophysical Phenomena, Permeability, law.invention, Biofouling, Bacterial Proteins, law, Botany, Pressure, Biofilm growth, Multidisciplinary, biology, Temperature, Biofilm, Water, biochemical phenomena, metabolism, and nutrition, biology.organism_classification, Agar, Biofilms, Physical Sciences, Biophysics, Flux (metabolism), Manifold (fluid mechanics), Bacteria

Abstract

Many bacteria on earth exist in surface-attached communities known as biofilms. These films are responsible for manifold problems, including hospital-acquired infections and biofouling, but they can also be beneficial. Biofilm growth depends on the transport of nutrients and waste, for which diffusion is thought to be the main source of transport. However, diffusion is ineffective for transport over large distances and thus should limit growth. Nevertheless, biofilms can grow to be very large. Here we report the presence of a remarkable network of well-defined channels that form in wild-type Bacillus subtilis biofilms and provide a system for enhanced transport. We observe that these channels have high permeability to liquid flow and facilitate the transport of liquid through the biofilm. In addition, we find that spatial variations in evaporative flux from the surface of these biofilms provide a driving force for the flow of liquid in the channels. These channels offer a remarkably simple system for liquid transport, and their discovery provides insight into the physiology and growth of biofilms.

Published

2012

17. Formation and Dissolution of Bacterial Colonies

Author

Vasily Zaburdaev, Yen Ting Lin, Nicolas Biais, and Christoph Weber

Subjects

biology, Chemistry, Biofilm, FOS: Physical sciences, Cell movement, Environmental pressure, Bacterial Physiological Phenomena, Condensed Matter - Soft Condensed Matter, biology.organism_classification, Models, Biological, Neisseria gonorrhoeae, Living matter, Kinetics, Chemical physics, Cell Movement, Cell Adhesion, Hydrodynamics, Soft Condensed Matter (cond-mat.soft), Autocatalytic reaction, Dissolution, Bacteria

Abstract

Many organisms form colonies for a transient period of time to withstand environmental pressure. Bacterial biofilms are a prototypical example of such behavior. Despite significant interest across disciplines, physical mechanisms governing the formation and dissolution of bacterial colonies are still poorly understood. Starting from a kinetic description of motile and interacting cells we derive a hydrodynamic equation for their density on a surface. We use it to describe formation of multiple colonies with sizes consistent with experimental data and to discuss their dissolution., Comment: 3 figures, 1 Supplementary Material

Published

2015

18. Subnuclear Spatial Structuring of Chromatin and Polymerase II during Transcription Activation of the Zebrafish Zygotic Genome

Author

Nadine L. Vastenhouw, Lennart Hilbert, and Vasily Zaburdaev

Subjects

0303 health sciences, Zygote, biology, Biophysics, RNA polymerase II, Cell cycle, biology.organism_classification, Molecular biology, Chromatin, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Histone, chemistry, biology.protein, Maternal to zygotic transition, Zebrafish, 030217 neurology & neurosurgery, DNA, 030304 developmental biology

Abstract

The relevance of spatial organization of chromatin to regulation of transcription is increasingly recognized [1]. Conversely, it was recently suggested that the level of general transcription activity affects subnuclear chromatin distribution [2]. Here, we ask how a general increase in transcription by polymerase II changes subnuclear chromatin distribution. Specifically, we used the transition of early zebrafish embryos from transcription quiescence to fully established transcription (Zygotic Genome Activation - ZGA) as a naturally occurring example of transcription level increase. General transcription activity occurs only following ZGA, i.e. 10 synchronous cell divisions after initial fertilization (three hours post fertilization). To make subnuclear distribution changes during ZGA accessible to super-resolution microscopy, we developed a dissociated cell culture protocol. Zebrafish embryos were dissociated at the 128-cell stage (three cell divisions before ZGA). Cultured cells developed transcription activity and morphological hallmarks of ZGA, confirming occurrence of native ZGA. We obtained preliminary results by wide-field fluorescence microscopy. Using fluorescently labeled histone proteins, which spontaneously bind DNA, we visualized a fine-grained chromatin structure in post-ZGA interphase nuclei in vivo. Utilizing antibody fragments (Fabs), we detected agglomerations of transcribing polymerase II in vivo. These agglomerations appeared as micron-sized, approximately spherical “transcription hot spots”. Few large transcription hot spots occurred at the 256-cell stage; in consecutive cell cycles more and smaller spots appeared. Any distinct signal of transcribing polymerase II disappeared during cell divisions, when no transcription occurs, thus confirming specificity of Fab-based detection of actively transcribing polymerase II. In the future, we will employ super-resolution microscopy to resolve the fine structure of chromatin and transcription hot spots in vivo throughout native zebrafish ZGA. [1] Gavrilov and Razin, Molecular Biology, 2015. [2] Popken et al., Nucleus, 2015.

Published

2016

19. How the motility pattern of bacteria affects their dispersal and chemotaxis

Author

Johannes Taktikos, Holger Stark, and Vasily Zaburdaev

Subjects

Movement, Biophysics, lcsh:Medicine, Bioengineering, Bacterial Physiological Phenomena, Mechanics, Models, Biological, Microbiology, Biophysics Theory, Engineering, Escherichia coli, Biological Systems Engineering, Cell Mechanics, Biomechanics, lcsh:Science, Biology, Vibrio alginolyticus, Stochastic Processes, Chemotaxis, Physics, lcsh:R, fungi, Classical Mechanics, Flagellar Motility, Probability Theory, Cell Motility, lcsh:Q, Mathematics, Research Article

Abstract

Most bacteria at certain stages of their life cycle are able to move actively; they can swim in a liquid or crawl on various surfaces. A typical path of the moving cell often resembles the trajectory of a random walk. However, bacteria are capable of modifying their apparently random motion in response to changing environmental conditions. As a result, bacteria can migrate towards the source of nutrients or away from harmful chemicals. Surprisingly, many bacterial species that were studied have several distinct motility patterns, which can be theoretically modeled by a unifying random walk approach. We use this approach to quantify the process of cell dispersal in a homogeneous environment and show how the bacterial drift velocity towards the source of attracting chemicals is affected by the motility pattern of the bacteria. Our results open up the possibility of accessing additional information about the intrinsic response of the cells using macroscopic observations of bacteria moving in inhomogeneous environments.

Published

2013

20. Langevin dynamics deciphers the motility pattern of swimming parasites

Author

Thomas Pfohl, Rudolf Friedrich, Holger Stark, Sravanti Uppaluri, Vasily Zaburdaev, and Markus Engstler

Subjects

Cell locomotion, Movement, Trypanosoma brucei brucei, General Physics and Astronomy, Rotational diffusion, Motility, Biology, Complex dynamics, Kinetics, Trajectory pattern, Biophysics, Animals, Humans, Statistical physics, Langevin dynamics, Swimming

Abstract

The parasite African trypanosome swims in the bloodstream of mammals and causes the highly dangerous human sleeping sickness. Cell motility is essential for the parasite’s survival within the mammalian host. We present an analysis of the random-walk pattern of a swimming trypanosome. From experimental time-autocorrelation functions for the direction of motion we identify two relaxation times that differ by an order of magnitude. They originate from the rapid deformations of the cell body and a slower rotational diffusion of the average swimming direction. Velocity fluctuations are athermal and increase for faster cells whose trajectories are also straighter. We demonstrate that such a complex dynamics is captured by two decoupled Langevin equations that decipher the complex trajectory pattern by referring it to the microscopic details of cell behavior.

Published

2010

21. Correction: How the Motility Pattern of Bacteria Affects Their Dispersal and Chemotaxis

Author

Johannes Taktikos, Vasily Zaburdaev, and Holger Stark

Subjects

Multidisciplinary, biology, Biological dispersal, Motility, Chemotaxis, biology.organism_classification, Bacteria, Cell biology

Published

2014

22. Live cell X-ray imaging of autophagic vacuoles formation and chromatin dynamics in fission yeast

Author

Manuel Guizar-Sicairos, Petrina Delivani, Natalja Strelnikova, Thomas Pfohl, Michael Göllner, Nora Sauter, Iva M. Tolić, Ana Diaz, Vasily Zaburdaev, and Mariola R. Chacón

Subjects

biological physics, nanoscale biophysics, X-rays, 0301 basic medicine, Programmed cell death, Fission, Cell, lcsh:Medicine, Vacuole, Article, Ionizing radiation, 03 medical and health sciences, Schizosaccharomyces, Autophagy, Image Processing, Computer-Assisted, medicine, lcsh:Science, Biology, Physics, Multidisciplinary, biology, Tomography, X-Ray, lcsh:R, biology.organism_classification, Chromatin, Yeast, Living matter, Cell biology, 030104 developmental biology, medicine.anatomical_structure, Vacuoles, Schizosaccharomyces pombe, lcsh:Q, Chromosomes, Fungal

Abstract

Seeing physiological processes at the nanoscale in living organisms without labeling is an ultimate goal in life sciences. Using X-ray ptychography, we explored in situ the dynamics of unstained, living fission yeast Schizosaccharomyces pombe cells in natural, aqueous environment at the nanoscale. In contrast to previous X-ray imaging studies on biological matter, in this work the eukaryotic cells were alive even after several ptychographic X-ray scans, which allowed us to visualize the chromatin motion as well as the autophagic cell death induced by the ionizing radiation. The accumulated radiation of the sequential scans allowed for the determination of a characteristic dose of autophagic vacuole formation and the lethal dose for fission yeast. The presented results demonstrate a practical method that opens another way of looking at living biological specimens and processes in a time-resolved label-free setting.

23. Transcription Locally Disperses Chromatin and Thereby Organizes the Global Architecture of Interphase Nuclei

Author

Vasily Zaburdaev, Lennart Hilbert, Hiroshi Kimura, Nadine L. Vastenhouw, Alf Honigmann, and Yuko Sato

Subjects

Cell division, Biophysics, RNA polymerase II, Cell cycle, Biology, Blastula, Molecular biology, Chromatin, Cell biology, chemistry.chemical_compound, chemistry, biology.protein, Interphase, Scaffold/matrix attachment region, DNA

Abstract

Interphase nuclei are segregated into chromatin domains, which are rich in DNA, and the interchromatin compartment1. Transcribing RNA polymerase II is found at chromatin domain margins1. It can be assumed that polymerase II is not just passively recruited to chromatin domain margins, but actively organizes chromatin and its interface with the interchromatin compartment. Here, we investigated how polymerase II activity impacts the bulk organization of chromatin in interphase nuclei. We used blastula stage zebrafish embryos as a model system. Blastula stage cell cycles last 1 hour or less, so we could readily follow the onset of transcription and chromatin organization after cell division. First, we imaged transcription and chromatin organization in vivo. To this end, we injected embryos with fluorescently labeled antibody fragments against transcribing polymerase II and the SiR-DNA live stain. We found that after cell division, no transcription occurred and chromatin was uniformly distributed throughout the nucleus. Within 2-3 minutes, individual foci of polymerase II activity occurred, which locally displaced chromatin from a surrounding pocket of 100-500 nm diameter. The number of polymerase II foci and chromatin-depleted pockets increased continuously and formed a nucleus-spanning network of transcription activity, which was embedded in a mirror image network of chromatin-dense domains. STED super-resolution microscopy of fixed embryonic cells showed the same intercalation of transcription and chromatin down to ∼50 nm length scales. To test the apparent requirement of transcription for this chromatin organization, we disrupted transcription with flavopiridol. This indeed abolished the intercalated nanostructure and led to precipitation of chromatin into compacted domains. Our findings suggest that foci of polymerase II activity locally manipulate bulk chromatin organization and integrate into a nucleus-spanning network required to maintain global nuclear architecture. 1Albiez et al. Chromosome Research 2006.