Your search keyword '"Cyrille Billaudeau"' showing total 7 results

1. A high content microscopy screening identifies new genes involved in cell width control in Bacillus subtilis

Author

Charlène Cornilleau, Cyrille Billaudeau, Priscille Brodin, Dimitri Juillot, Véronique Léjard, Rut Carballido-López, Arnaud Chastanet, Parfait Evouna-Mengue, Nathalie Deboosere, and Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)

Subjects

0303 health sciences, biology, 030306 microbiology, [SDV]Life Sciences [q-bio], Cell, Morphogenesis, Bacillus subtilis, Cell cycle, biology.organism_classification, Bacterial cell structure, Cell biology, Cell wall, 03 medical and health sciences, chemistry.chemical_compound, medicine.anatomical_structure, chemistry, Extracellular, medicine, Peptidoglycan, 030304 developmental biology

Abstract

How cells control their shape and size is a fundamental question of biology. In most bacteria, cell shape is imposed by the peptidoglycan (PG) polymeric meshwork that surrounds the cell. Thus, bacterial cell morphogenesis results from the coordinated action of the proteins assembling and degrading the PG shell. Remarkably, during steady-state growth, most bacteria maintain a defined shape along generations, suggesting that error-proof mechanisms tightly control the process. In the rod-shaped model for Gram-positive bacteriaBacillus subtilis, the average cell length varies as a function of the growth rate but the cell diameter remains constant throughout the cell cycle and across growth conditions. Here, in an attempt to shed light on the cellular circuits controlling bacterial cell width, we developed a screen to identify genetic determinants of cell width inB. subtilis. Using high-content screening (HCS) fluorescence microscopy and semi-automated measurement of single-cell dimensions, we screened a library of ~ 4000 single knockout mutants. We identified 13 mutations significantly altering cell diameter, in genes that belong to several functional groups. In particular, our results indicate that metabolism plays a major role in cell width control inB. subtilis.

Published

2021

2. Temporal compartmentalization of viral infection in bacterial cells

Author

Paulo Tavares, Lina Jakutyte, Thorsten Mielke, Silvia Ayora, Cyrille Billaudeau, Rut Carballido-López, Audrey Labarde, Beatrix Fauler, Prishila Ponien, María López-Sanz, Eric Jacquet, Institut de Biologie Intégrative de la Cellule (I2BC), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), AgroParisTech, Institut de Chimie des Substances Naturelles (ICSN), and Institut de Chimie du CNRS (INC)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS)

Subjects

DNA Replication, Time Factors, viruses, DNA-Directed DNA Polymerase, Biology, Genome, Virus, Bacteriophage, 03 medical and health sciences, chemistry.chemical_compound, Capsid, Multienzyme Complexes, Compartment (development), Bacteriophages, 030304 developmental biology, bacteriophage, virus infection, phage DNA replication, virus assembly, bacterial cell compartmentalization, 0303 health sciences, Multidisciplinary, 030302 biochemistry & molecular biology, Virion, Biological Sciences, biology.organism_classification, Cell Compartmentation, Cell biology, Nucleoprotein, [SDV.MP]Life Sciences [q-bio]/Microbiology and Parasitology, chemistry, Virus Diseases, Cytoplasm, DNA, Viral, Host-Pathogen Interactions, Replisome, DNA, Bacillus subtilis

Abstract

International audience; Virus infection causes major rearrangements in the subcellular architecture of eukaryotes, but its impact in prokaryotic cells was much less characterized. Here, we show that infection of the bacterium Bacillus subtilis by bacteriophage SPP1 leads to a hijacking of host replication proteins to assemble hybrid viral–bacterial replisomes for SPP1 genome replication. Their biosynthetic activity doubles the cell total DNA content within 15 min. Replisomes operate at several independent locations within a single viral DNA focus positioned asymmetrically in the cell. This large nucleoprotein complex is a self-contained compartment whose boundaries are delimited neither by a membrane nor by a protein cage. Later during infection, SPP1 procapsids localize at the periphery of the viral DNA compartment for genome packaging. The resulting DNA-filled capsids do not remain associated to the DNA transactions compartment. They bind to phage tails to build infectious particles that are stored in warehouse compartments spatially independent from the viral DNA. Free SPP1 structural proteins are recruited to the dynamic phage-induced compartments following an order that recapitulates the viral particle assembly pathway. These findings show that bacteriophages restructure the crowded host cytoplasm to confine at different cellular locations the sequential processes that are essential for their multiplication.

Published

2021

3. Dynamic Membrane Localization of RNase Y in <named-content content-type='genus-species'>Bacillus subtilis</named-content>

Author

Cyrille Billaudeau, Lina Hamouche, Soumaya Laalami, Saravuth Ngo, Harald Putzer, Anna Rocca, Arnaud Chastanet, Inst Biol Physicochim, UPR9273, Centre National de la Recherche Scientifique (CNRS), MICrobiologie de l'ALImentation au Service de la Santé (MICALIS), AgroParisTech-Université Paris-Saclay-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), and Institut de biologie physico-chimique (IBPC (FR_550))

Subjects

Molecular Biology and Physiology, RNase P, RNA Stability, [SDV]Life Sciences [q-bio], membrane proteins, Bacillus subtilis, Microbiology, 03 medical and health sciences, Ribonucleases, Bacterial Proteins, RNA degradation, Transcription (biology), Virology, Gene expression, Endoribonucleases, Escherichia coli, RNA, Messenger, 030304 developmental biology, 0303 health sciences, Nuclease, Messenger RNA, biology, 030306 microbiology, Chemistry, MRNA cleavage, Cell Membrane, RNA, Gene Expression Regulation, Bacterial, biology.organism_classification, [SDV.MP.BAC]Life Sciences [q-bio]/Microbiology and Parasitology/Bacteriology, QR1-502, Cell biology, RNase Y, RNA, Bacterial, Microscopy, Fluorescence, RNA processing, biology.protein, Research Article

Abstract

All living organisms must degrade mRNA to adapt gene expression to changing environments. In bacteria, initiation of mRNA decay generally occurs through an endonucleolytic cleavage. In the Gram-positive model organism Bacillus subtilis and probably many other bacteria, the key enzyme for this task is RNase Y, which is anchored at the inner cell membrane. While this pseudocompartmentalization appears coherent with translation occurring primarily at the cell periphery, our knowledge on the distribution and dynamics of RNase Y in living cells is very scarce. Here, we show that RNase Y moves rapidly along the membrane in the form of dynamic short-lived foci. These foci become more abundant and increase in size following transcription arrest, suggesting that they do not constitute the most active form of the nuclease. This contrasts with RNase E, the major decay-initiating RNase in E. coli, where it was shown that formation of foci is dependent on the presence of RNA substrates. We also show that a protein complex (Y-complex) known to influence the specificity of RNase Y activity in vivo is capable of shifting the assembly status of RNase Y toward fewer and smaller complexes. This highlights fundamental differences between RNase E- and RNase Y-based degradation machineries., Metabolic turnover of mRNA is fundamental to the control of gene expression in all organisms, notably in fast-adapting prokaryotes. In many bacteria, RNase Y initiates global mRNA decay via an endonucleolytic cleavage, as shown in the Gram-positive model organism Bacillus subtilis. This enzyme is tethered to the inner cell membrane, a pseudocompartmentalization coherent with its task of initiating mRNA cleavage/maturation of mRNAs that are translated at the cell periphery. Here, we used total internal reflection fluorescence microscopy (TIRFm) and single-particle tracking (SPT) to visualize RNase Y and analyze its distribution and dynamics in living cells. We find that RNase Y diffuses rapidly at the membrane in the form of dynamic short-lived foci. Unlike RNase E, the major decay-initiating RNase in Escherichia coli, the formation of foci is not dependent on the presence of RNA substrates. On the contrary, RNase Y foci become more abundant and increase in size following transcription arrest, suggesting that they do not constitute the most active form of the nuclease. The Y-complex of three proteins (YaaT, YlbF, and YmcA) has previously been shown to play an important role for RNase Y activity in vivo. We demonstrate that Y-complex mutations have an effect similar to but much stronger than that of depletion of RNA in increasing the number and size of RNase Y foci at the membrane. Our data suggest that the Y-complex shifts the assembly status of RNase Y toward fewer and smaller complexes, thereby increasing cleavage efficiency of complex substrates like polycistronic mRNAs.

Published

2020

4. MreB Forms Subdiffraction Nanofilaments during Active Growth in Bacillus subtilis

Author

Arnaud Chastanet, Charlène Cornilleau, Rut Carballido-López, Cyrille Billaudeau, Zhizhong Yao, Carballido-Lopez, Rut, MICrobiologie de l'ALImentation au Service de la Santé (MICALIS), Institut National de la Recherche Agronomique (INRA)-AgroParisTech, Université Paris Saclay (COmUE), and Inovarion

Subjects

Molecular Biology and Physiology, helix, [SDV]Life Sciences [q-bio], polymer, Bacillus subtilis, protein localization, TIRF, MreB, Microbiology, Bacterial cell structure, cell shape, Protein filament, Cell wall, 03 medical and health sciences, chemistry.chemical_compound, Bacterial Proteins, Virology, Cytoskeleton, 030304 developmental biology, 0303 health sciences, biology, 030306 microbiology, cytoskeleton, SIM, biology.organism_classification, Protein subcellular localization prediction, QR1-502, Protein Transport, chemistry, filament, Biophysics, microscopy, cell wall, Peptidoglycan, Protein Multimerization, superresolution, Research Article

Abstract

The construction of the bacterial cell envelope is a fundamental topic, as it confers its integrity to bacteria and is consequently the target of numerous antibiotics. MreB is an essential protein suspected to regulate the cell wall synthetic machineries. Despite two decades of study, its localization remains the subject of controversies, its description ranging from helical filaments spanning the entire cell to small discrete entities. The true structure of these filaments is important because it impacts the model describing how the machineries building the cell wall are associated, how they are coordinated at the scale of the entire cell, and how MreB mediates this regulation. Our results shed light on this debate, revealing the size of native filaments in B. subtilis during growth. They argue against models where MreB filament size directly affects the speed of synthesis of the cell wall and where MreB would coordinate distant machineries along the side wall., The actin-like MreB protein is a key player of the machinery controlling the elongation and maintenance of the cell shape of most rod-shaped bacteria. This protein is known to be highly dynamic, moving along the short axis of cells, presumably reflecting the movement of cell wall synthetic machineries during the enzymatic assembly of the peptidoglycan mesh. The ability of MreB proteins to form polymers is not debated, but their structure, length, and conditions of establishment have remained unclear and the subject of conflicting reports. Here we analyze various strains of Bacillus subtilis, the model for Gram-positive bacteria, and we show that MreB forms subdiffraction-limited, less than 200 nm-long nanofilaments on average during active growth, while micron-long filaments are a consequence of artificial overaccumulation of the protein. Our results also show the absence of impact of the size of the filaments on their speed, orientation, and other dynamic properties conferring a large tolerance to B. subtilis toward the levels and consequently the lengths of MreB polymers. Our data indicate that the density of mobile filaments remains constant in various strains regardless of their MreB levels, suggesting that another factor determines this constant.

Published

2019

5. Spatial reorganization of telomeres in long-lived quiescent cells

Author

Angela Taddei, Antoine Hocher, Romain Koszul, Julien Mozziconacci, Martial Marbouty, Axel Cournac, Cyrille Billaudeau, Myriam Ruault, Micol Guidi, Isabelle Loïodice, Dynamique du noyau, Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut Curie [Paris]-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Génétique des génomes - Genetics of Genomes (UMR 3525), Institut Pasteur [Paris] (IP)-Centre National de la Recherche Scientifique (CNRS), Régulation spatiale des Génomes - Spatial Regulation of Genomes, Laboratoire de Physique Théorique de la Matière Condensée (LPTMC), Université Pierre et Marie Curie - Paris 6 (UPMC)-Centre National de la Recherche Scientifique (CNRS), HAL-UPMC, Gestionnaire, Centre National de la Recherche Scientifique (CNRS)-Institut Curie [Paris]-Institut National de la Santé et de la Recherche Médicale (INSERM)-Université Pierre et Marie Curie - Paris 6 (UPMC), Institut Pasteur [Paris]-Centre National de la Recherche Scientifique (CNRS), and Centre National de la Recherche Scientifique (CNRS)-Université Pierre et Marie Curie - Paris 6 (UPMC)

Subjects

Genetics, [SDV.GEN]Life Sciences [q-bio]/Genetics, Research, Centromere, Saccharomyces cerevisiae, [SDV.GEN] Life Sciences [q-bio]/Genetics, Telomere, Biology, biology.organism_classification, Resting Phase, Cell Cycle, Genome, Carbon, Chromatin, Chromosome conformation capture, [SDV.BBM] Life Sciences [q-bio]/Biochemistry, Molecular Biology, Gene silencing, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, Chromosomes, Fungal, Reactive Oxygen Species, Gene, Silent Information Regulator Proteins, Saccharomyces cerevisiae

Abstract

Background The spatiotemporal behavior of chromatin is an important control mechanism of genomic function. Studies in Saccharomyces cerevisiae have broadly contributed to demonstrate the functional importance of nuclear organization. Although in the wild yeast survival depends on their ability to withstand adverse conditions, most of these studies were conducted on cells undergoing exponential growth. In these conditions, as in most eukaryotic cells, silent chromatin that is mainly found at the 32 telomeres accumulates at the nuclear envelope, forming three to five foci. Results Here, combining live microscopy, DNA FISH and chromosome conformation capture (HiC) techniques, we report that chromosomes adopt distinct organizations according to the metabolic status of the cell. In particular, following carbon source exhaustion the genome of long-lived quiescent cells undergoes a major spatial re-organization driven by the grouping of telomeres into a unique focus or hypercluster localized in the center of the nucleus. This change in genome conformation is specific to quiescent cells able to sustain long-term viability. We further show that reactive oxygen species produced by mitochondrial activity during respiration commit the cell to form a hypercluster upon starvation. Importantly, deleting the gene encoding telomere associated silencing factor SIR3 abolishes telomere grouping and decreases longevity, a defect that is rescued by expressing a silencing defective SIR3 allele competent for hypercluster formation. Conclusions Our data show that mitochondrial activity primes cells to group their telomeres into a hypercluster upon starvation, reshaping the genome architecture into a conformation that may contribute to maintain longevity of quiescent cells. Electronic supplementary material The online version of this article (doi:10.1186/s13059-015-0766-2) contains supplementary material, which is available to authorized users.

Published

2015

6. A High-Content Microscopy Screening Identifies New Genes Involved in Cell Width Control in Bacillus subtilis

Author

Arnaud Chastanet, Cyrille Billaudeau, Parfait Evouna-Mengue, Rut Carballido-López, Nathalie Deboosere, Dimitri Juillot, Charlène Cornilleau, Priscille Brodin, Véronique Léjard, MICrobiologie de l'ALImentation au Service de la Santé (MICALIS), AgroParisTech-Université Paris-Saclay-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Centre d’Infection et d’Immunité de Lille - INSERM U 1019 - UMR 9017 - UMR 8204 (CIIL), Institut Pasteur de Lille, Réseau International des Instituts Pasteur (RIIP)-Réseau International des Instituts Pasteur (RIIP)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Université de Lille-Centre Hospitalier Régional Universitaire [Lille] (CHRU Lille)-Centre National de la Recherche Scientifique (CNRS), MetaGenoPolis (MGP (US 1367)), Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), MICrobiologie de l'ALImentation au Service de la Santé [MICALIS], Centre d’Infection et d’Immunité de Lille - INSERM U 1019 - UMR 9017 - UMR 8204 [CIIL], and MetaGenoPolis [MGP (US 1367)]

Subjects

cell division, carbon metabolism, Cell division, Physiology, Morphogenesis, cell width, Bacillus subtilis, Biochemistry, Microbiology, cell shape, Bacterial cell structure, chemistry.chemical_compound, Min System, Genetics, cell growth, Rod complex, Molecular Biology, HCS microscopy, Ecology, Evolution, Behavior and Systematics, biology, Cell growth, Cell cycle, biology.organism_classification, [SDV.MP.BAC]Life Sciences [q-bio]/Microbiology and Parasitology/Bacteriology, QR1-502, Min system, Computer Science Applications, Cell biology, chemistry, Modeling and Simulation, cell wall, Peptidoglycan, metabolism, Research Article

Abstract

How cells control their shape and size is a fundamental question of biology. In most bacteria, cell shape is imposed by the peptidoglycan (PG) polymeric meshwork that surrounds the cell. Thus, bacterial cell morphogenesis results from the coordinated action of the proteins assembling and degrading the PG shell. Remarkably, during steady-state growth, most bacteria maintain a defined shape along generations, suggesting that error-proof mechanisms tightly control the process. In the rod-shaped model for the Gram-positive bacterium Bacillus subtilis, the average cell length varies as a function of the growth rate, but the cell diameter remains constant throughout the cell cycle and across growth conditions. Here, in an attempt to shed light on the cellular circuits controlling bacterial cell width, we developed a screen to identify genetic determinants of cell width in B. subtilis. Using high-content screening (HCS) fluorescence microscopy and semiautomated measurement of single-cell dimensions, we screened a library of ∼4,000 single knockout mutants. We identified 13 mutations significantly altering cell diameter, in genes that belong to several functional groups. In particular, our results indicate that metabolism plays a major role in cell width control in B. subtilis. IMPORTANCE Bacterial shape is primarily dictated by the external cell wall, a vital structure that, as such, is the target of countless antibiotics. Our understanding of how bacteria synthesize and maintain this structure is therefore a cardinal question for both basic and applied research. Bacteria usually multiply from generation to generation while maintaining their progenies with rigorously identical shapes. This implies that the bacterial cells constantly monitor and maintain a set of parameters to ensure this perpetuation. Here, our study uses a large-scale microscopy approach to identify at the whole-genome level, in a model bacterium, the genes involved in the control of one of the most tightly controlled cellular parameters, the cell width.

7. Methods for Studying Membrane-Associated Bacterial Cytoskeleton Proteins In Vivo by TIRF Microscopy

Author

Arnaud Chastanet, Cyrille Billaudeau, Rut Carballido-López, Charlène Cornilleau, MICrobiologie de l'ALImentation au Service de la Santé (MICALIS), and AgroParisTech-Université Paris-Saclay-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE)

Subjects

0303 health sciences, Actin-like MreB proteins, Total internal reflection fluorescence microscope, biology, 030306 microbiology, Bacillus subtilis, [SDV.BC.BC]Life Sciences [q-bio]/Cellular Biology/Subcellular Processes [q-bio.SC], biology.organism_classification, Agarose pad, MreB, [SDV.MP.BAC]Life Sciences [q-bio]/Microbiology and Parasitology/Bacteriology, Prokaryotic cytoskeleton, 03 medical and health sciences, chemistry.chemical_compound, chemistry, In vivo, Microscopy, Biophysics, Bacterial cytoskeleton, Agarose, CellASIC ® microfluidic system, Actin, 030304 developmental biology, TIRF microscopy

Abstract

MreB proteins are actin homologs present in nonspherical bacteria. They assemble into membrane-associated discrete filamentous structures that exhibit different dynamic behaviors along the bacterial sidewalls. Total internal reflection fluorescence (TIRF) microscopy, a sensitive method for studying molecular events at cell surfaces with high contrast and temporal resolution, is a method of choice to characterize the localization and dynamics of cortical MreB assemblies in vivo. This chapter describes the methods for visualizing fluorescently tagged MreB proteins in live Bacillus subtilis cells. We detail how to (1) grow B. subtilis strains for reproducible TIRF observations, (2) immobilize cells on agarose pads and (3) in CellASIC ® microfluidic plates, and (4) acquire TIRF images and time lapses.