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1. Stator Dynamics Depending on Sodium Concentration in Sodium-Driven Bacterial Flagellar Motors

Author

Tsai-Shun Lin, Seiji Kojima, Hajime Fukuoka, Akihiko Ishijima, Michio Homma, and Chien-Jung Lo

Subjects
bacterial flagellar motor, sodium-motive force, stator exchange, membrane protein, perfusion, Microbiology, QR1-502
Abstract

Bacterial flagellar motor (BFM) is a large membrane-spanning molecular rotary machine for swimming motility. Torque is generated by the interaction between the rotor and multiple stator units powered by ion-motive force (IMF). The number of bound stator units is dynamically changed in response to the external load and the IMF. However, the detailed dynamics of stator unit exchange process remains unclear. Here, we directly measured the speed changes of sodium-driven chimeric BFMs under fast perfusion of different sodium concentration conditions using computer-controlled, high-throughput microfluidic devices. We found the sodium-driven chimeric BFMs maintained constant speed over a wide range of sodium concentrations by adjusting stator units in compensation to the sodium-motive force (SMF) changes. The BFM has the maximum number of stator units and is most stable at 5 mM sodium concentration rather than higher sodium concentration. Upon rapid exchange from high to low sodium concentration, the number of functional stator units shows a rapidly excessive reduction and then resurrection that is different from predictions of simple absorption model. This may imply the existence of a metastable hidden state of the stator unit during the sudden loss of sodium ions.

Published
2021
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2. Fluctuations in Intracellular CheY-P Concentration Coordinate Reversals of Flagellar Motors in E. coli

Author

Yong-Suk Che, Takashi Sagawa, Yuichi Inoue, Hiroto Takahashi, Tatsuki Hamamoto, Akihiko Ishijima, and Hajime Fukuoka

Subjects
chemotaxis, signal transduction, diffusion, response regulator, CheY, flagellar motor, Microbiology, QR1-502
Abstract

Signal transduction utilizing membrane-spanning receptors and cytoplasmic regulator proteins is a fundamental process for all living organisms, but quantitative studies of the behavior of signaling proteins, such as their diffusion within a cell, are limited. In this study, we show that fluctuations in the concentration of the signaling molecule, phosphorylated CheY, constitute the basis of chemotaxis signaling. To analyze the propagation of the CheY-P signal quantitatively, we measured the coordination of directional switching between flagellar motors on the same cell. We analyzed the time lags of the switching of two motors in both CCW-to-CW and CW-to-CCW switching (∆τCCW-CW and ∆τCW-CCW). In wild-type cells, both time lags increased as a function of the relative distance of two motors from the polar receptor array. The apparent diffusion coefficient estimated for ∆τ values was ~9 µm2/s. The distance-dependency of ∆τCW-CCW disappeared upon loss of polar localization of the CheY-P phosphatase, CheZ. The distance-dependency of the response time for an instantaneously applied serine attractant signal also disappeared with the loss of polar localization of CheZ. These results were modeled by calculating the diffusion of CheY and CheY-P in cells in which phosphorylation and dephosphorylation occur in different subcellular regions. We conclude that diffusion of signaling molecules and their production and destruction through spontaneous activity of the receptor array generates fluctuations in CheY-P concentration over timescales of several hundred milliseconds. Signal fluctuation coordinates rotation among flagella and regulates steady-state run-and-tumble swimming of cells to facilitate efficient responses to environmental chemical signals.

Published
2020
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3. CheB localizes to polar receptor arrays during repellent adaptation.

Author

Hajime Fukuoka, Keisuke Nishitani, Taiga Deguchi, Taketo Oshima, Yumiko Uchida, Tatsuki Hamamoto, Yong-Suk Che, and Akihiko Ishijima

Subjects
*ENZYME kinetics, *ESCHERICHIA coli, *BINDING sites, *REPELLENTS, *SERINE
Abstract

Adaptation of the response to stimuli is a fundamental process for all organisms. Here, we show that the adaptation enzyme CheB methylesterase of Escherichia coli assembles to the ON state receptor array after exposure to the repellent l-isoleucine and dissociates from the array after adaptation is complete. The duration of increased CheB localization and the time of highly clockwise-biased flagellar rotation were similar and depended on the strength of the stimulus. The increase in CheB at the receptor array and the decrease in cytoplasmic CheB were both ~100 molecules, which represents 15 to 20% of the total cellular content of CheB. We confirmed that the main binding site for CheB in the ON state array is the P2 domain of phosphorylated CheA, with a second minor site being the carboxyl-terminal pentapeptide of the serine chemoreceptor. Thus, we have been able to quantify the regulation of the signal output of the receptor array by the intracellular dynamics of an adaptation enzyme. [ABSTRACT FROM AUTHOR]

Published
2024
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4. The Chemoreceptor Sensory Adaptation System Produces Coordinated Reversals of the Flagellar Motors on an Escherichia coli Cell

Author

Yumiko Uchida, Tatsuki Hamamoto, Yong-Suk Che, Hiroto Takahashi, John S. Parkinson, Akihiko Ishijima, and Hajime Fukuoka

Subjects
Bacterial Proteins, Chemotaxis, Escherichia coli Proteins, Escherichia coli, Methyl-Accepting Chemotaxis Proteins, Molecular Biology, Microbiology, Chemoreceptor Cells, Research Article
Abstract

In isotropic environments, an Escherichia coli cell exhibits coordinated rotational switching of its flagellar motors, produced by fluctuations in the intracellular concentration of phosphorylated CheY (CheY-P) emanating from chemoreceptor signaling arrays. In this study, we show that these CheY-P fluctuations arise through modifications of chemoreceptors by two sensory adaptation enzymes: the methyltransferase CheR and the methylesterase CheB. A cell containing CheR, CheB, and the serine chemoreceptor Tsr exhibited motor synchrony, whereas a cell lacking CheR and CheB or containing enzymatically inactive forms did not. Tsr variants with different combinations of methylation-mimicking Q residues at the adaptation sites also failed to show coordinated motor switching in cells lacking CheR and CheB. Cells containing CheR, CheB, and Tsr [NDND], a variant in which the adaptation site residues are not substrates for CheR or CheB modifications, also lacked motor synchrony. TsrΔNWETF, which lacks a C-terminal pentapeptide-binding site for CheR and CheB, and the ribose-galactose receptor Trg, which natively lacks this motif, failed to produce coordinated motor switching, despite the presence of CheR and CheB. However, addition of the NWETF sequence to Trg enabled Trg-NWETF to produce motor synchrony, as the sole receptor type in cells containing CheR and CheB. Finally, CheBc, the catalytic domain of CheB, supported motor coordination in combination with CheR and Tsr. These results indicate that the coordination of motor switching requires CheR/CheB-mediated changes in receptor modification state. We conclude that the opposing receptor substrate-site preferences of CheR and CheB produce spontaneous blinking of the chemoreceptor array’s output activity. IMPORTANCE Under steady-state conditions with no external stimuli, an Escherichia coli cell coordinately switches the rotational direction of its flagellar motors. Here, we demonstrate that the CheR and CheB enzymes of the chemoreceptor sensory adaptation system mediate this coordination. Stochastic fluctuations in receptor adaptation states trigger changes in signal output from the receptor array, and this array blinking generates fluctuations in CheY-P concentration that coordinate directional switching of the flagellar motors. Thus, in the absence of chemoeffector gradients, the sensory adaptation system controls run-tumble swimming of the cell, its optimal foraging strategy.

Published
2022

5. Stator Dynamics Depending on Sodium Concentration in Sodium-Driven Bacterial Flagellar Motors

Author

Akihiko Ishijima, Michio Homma, Seiji Kojima, Chien-Jung Lo, Tsai-Shun Lin, and Hajime Fukuoka

Subjects
Microbiology (medical), bacterial flagellar motor, Materials science, Rotor (electric), Stator, Sodium, Dynamics (mechanics), chemistry.chemical_element, stator exchange, Mechanics, Microbiology, perfusion, QR1-502, Ion, law.invention, chemistry, law, sodium-motive force, Torque, membrane protein, Absorption (chemistry), Original Research, Low sodium
Abstract

Bacterial flagellar motor (BFM) is a large membrane-spanning molecular rotary machine for swimming motility. Torque is generated by the interaction between the rotor and multiple stator units powered by ion-motive force (IMF). The number of bound stator units is dynamically changed in response to the external load and the IMF. However, the detailed dynamics of stator unit exchange process remains unclear. Here, we directly measured the speed changes of sodium-driven chimeric BFMs under fast perfusion of different sodium concentration conditions using computer-controlled, high-throughput microfluidic devices. We found the sodium-driven chimeric BFMs maintained constant speed over a wide range of sodium concentrations by adjusting stator units in compensation to the sodium-motive force (SMF) changes. The BFM has the maximum number of stator units and is most stable at 5 mM sodium concentration rather than higher sodium concentration. Upon rapid exchange from high to low sodium concentration, the number of functional stator units shows a rapidly excessive reduction and then resurrection that is different from predictions of simple absorption model. This may imply the existence of a metastable hidden state of the stator unit during the sudden loss of sodium ions.

Published
2021

6. Fluctuations in Intracellular CheY-P Concentration Coordinate Reversals of Flagellar Motors in E. coli

Author

Takashi Sagawa, Akihiko Ishijima, Hajime Fukuoka, Yong-Suk Che, Tatsuki Hamamoto, Hiroto Takahashi, and Yuichi Inoue

Subjects
Cell signaling, Rotation, lcsh:QR1-502, Methyl-Accepting Chemotaxis Proteins, Signal transduction, Flagellum, E. coli, Biochemistry, Article, lcsh:Microbiology, Diffusion, CheY, Serine, 03 medical and health sciences, 0302 clinical medicine, Escherichia coli, Phosphorylation, Molecular Biology, 030304 developmental biology, 0303 health sciences, Chemistry, Escherichia coli Proteins, Chemotaxis, Flagellar motor, Response regulator, Flagella, Cytoplasm, Biophysics, 030217 neurology & neurosurgery
Abstract

Signal transduction utilizing membrane-spanning receptors and cytoplasmic regulator proteins is a fundamental process for all living organisms, but quantitative studies of the behavior of signaling proteins, such as their diffusion within a cell, are limited. In this study, we show that fluctuations in the concentration of the signaling molecule, phosphorylated CheY, constitute the basis of chemotaxis signaling. To analyze the propagation of the CheY-P signal quantitatively, we measured the coordination of directional switching between flagellar motors on the same cell. We analyzed the time lags of the switching of two motors in both CCW-to-CW and CW-to-CCW switching (∆tCCW-CW and ∆tCW-CCW). In wild-type cells, both time lags increased as a function of the relative distance of two motors from the polar receptor array. The apparent diffusion coefficient estimated for ∆t values was ~9 &micro, m2/s. The distance-dependency of ∆tCW-CCW disappeared upon loss of polar localization of the CheY-P phosphatase, CheZ. The distance-dependency of the response time for an instantaneously applied serine attractant signal also disappeared with the loss of polar localization of CheZ. These results were modeled by calculating the diffusion of CheY and CheY-P in cells in which phosphorylation and dephosphorylation occur in different subcellular regions. We conclude that diffusion of signaling molecules and their production and destruction through spontaneous activity of the receptor array generates fluctuations in CheY-P concentration over timescales of several hundred milliseconds. Signal fluctuation coordinates rotation among flagella and regulates steady-state run-and-tumble swimming of cells to facilitate efficient responses to environmental chemical signals.

Published
2020

7. Organisms that Function with Small Numbers of Molecules

Author

Akihiko Ishijima, Hajime Fukuoka, and Yong-Suk Che

Subjects
biology, Chemistry, Cell, Motility, Femtoliter, Chemotaxis, biology.organism_classification, medicine.disease_cause, Cell biology, medicine.anatomical_structure, medicine, Escherichia coli, Function (biology), Bacteria, Organism
Abstract

Escherichia coli and other bacteria are said to be the lowest forms of life in the biological world. Nevertheless, bacteria are magnificent organisms that can recognize the ambient environment, propagate ambient information into its body, and (in the case of most bacteria, at least…) possess the capacity to swim toward a more favorable environment; these are systems that no man-made machine could even hope to imitate. This complex machinery is constructed in an extremely small unit of space about a femtoliter. Because this organism is so small, its proteins function in far smaller numbers than seen in other organisms (on the order of about 100 protein molecules involving methylation and demethylation, and 1000 phosphorylated protein molecules work in a cell). Let us gain an understanding of the chemotaxis and motility of bacteria through the following conversation between a mother and her daughter.

Published
2018

8. Direct Imaging of Intracellular Signaling Molecule Responsible for the Bacterial Chemotaxis

Author

Hajime, Fukuoka

Subjects
Cytoplasm, Flagella, Chemotaxis, Escherichia coli Proteins, Green Fluorescent Proteins, Escherichia coli, Membrane Proteins, Phosphorylation, Protein Binding, Signal Transduction
Abstract

To elucidate the mechanisms by which cells respond to extracellular stimuli, the behavior of intracellular signaling proteins in a single cell should be directly examined, while simultaneously recording the cellular response. In Escherichia coli, an extracellular chemotactic stimulus is thought to induce a switch in the rotational direction of the flagellar motor, elicited by the binding and dissociation of the phosphorylated form of CheY (CheY-P) to and from the motor. We recently provided direct evidence for the binding of CheY-P to a functioning flagellar motor in live cells. Here, we describe the method for simultaneously measuring the fluorescent signal of the CheY-enhanced green fluorescent protein fusion protein (CheY-EGFP) and the rotational switching of the flagellar motor. By performing fluorescence and bright-field microscopy simultaneously, the rotational switch of the flagellar motor was shown to be induced by the binding and dissociation of CheY-P, and the number of CheY-P molecules bound to the motor was estimated.

Published
2017

9. Direct Imaging of Intracellular Signaling Molecule Responsible for the Bacterial Chemotaxis

Author

Hajime Fukuoka

Subjects
0301 basic medicine, Chemistry, Chemotaxis, Plasma protein binding, Fusion protein, Green fluorescent protein, Cell biology, 03 medical and health sciences, 030104 developmental biology, Cytoplasm, Extracellular, bacteria, biological phenomena, cell phenomena, and immunity, Signal transduction, Intracellular
Abstract

To elucidate the mechanisms by which cells respond to extracellular stimuli, the behavior of intracellular signaling proteins in a single cell should be directly examined, while simultaneously recording the cellular response. In Escherichia coli, an extracellular chemotactic stimulus is thought to induce a switch in the rotational direction of the flagellar motor, elicited by the binding and dissociation of the phosphorylated form of CheY (CheY-P) to and from the motor. We recently provided direct evidence for the binding of CheY-P to a functioning flagellar motor in live cells. Here, we describe the method for simultaneously measuring the fluorescent signal of the CheY-enhanced green fluorescent protein fusion protein (CheY-EGFP) and the rotational switching of the flagellar motor. By performing fluorescence and bright-field microscopy simultaneously, the rotational switch of the flagellar motor was shown to be induced by the binding and dissociation of CheY-P, and the number of CheY-P molecules bound to the motor was estimated.

Published
2017

10. Single-Cell E. coli Response to an Instantaneously Applied Chemotactic Signal

Author

Kazushi Kinbara, Hiroto Takahashi, Yuichi Inoue, Takahiro Muraoka, Akihiko Ishijima, Yu Kikuchi, Hajime Fukuoka, and Takashi Sagawa

Subjects
Systems Biophysics, Histidine Kinase, Methyl-accepting chemotaxis protein, Chemotaxis, Escherichia coli Proteins, Histidine kinase, Biophysics, Membrane Proteins, Methyl-Accepting Chemotaxis Proteins, Biology, Serine, Bacterial Proteins, Biochemistry, Single-cell analysis, Cytoplasm, Escherichia coli, Reaction Time, bacteria, Phosphorylation, Single-Cell Analysis, biological phenomena, cell phenomena, and immunity, Intracellular
Abstract

In response to an attractant or repellant, an Escherichia coli cell controls the rotational direction of its flagellar motor by a chemotaxis system. When an E. coli cell senses an attractant, a reduction in the intracellular concentration of a chemotaxis protein, phosphorylated CheY (CheY-P), induces counterclockwise (CCW) rotation of the flagellar motor, and this cellular response is thought to occur in several hundred milliseconds. Here, to measure the signaling process occurring inside a single E. coli cell, including the recognition of an attractant by a receptor cluster, the inactivation of histidine kinase CheA, and the diffusion of CheY and CheY-P molecules, we applied a serine stimulus by instantaneous photorelease from a caged compound and examined the cellular response at a temporal resolution of several hundred microseconds. We quantified the clockwise (CW) and CCW durations immediately after the photorelease of serine as the response time and the duration of the response, respectively. The results showed that the response time depended on the distance between the receptor and motor, indicating that the decreased CheY-P concentration induced by serine propagates through the cytoplasm from the receptor-kinase cluster toward the motor with a timing that is explained by the diffusion of CheY and CheY-P molecules. The response time included 240 ms for enzymatic reactions in addition to the time required for diffusion of the signaling molecule. The measured response time and duration of the response also revealed that the E. coli cell senses a similar serine concentration regardless of whether the serine concentration is increasing or decreasing. These detailed quantitative findings increase our understanding of the signal transduction process that occurs inside cells during bacterial chemotaxis.

Published
2014

11. Micrometer-Size Vesicle Formation Triggered by UV Light

Author

Takashi Yamashita, Tsutomu Hamada, Yuichi Inoue, Tatsuya Shima, Takahiro Muraoka, Masamune Morita, Akihiko Ishijima, Takashi Sagawa, Kazushi Kinbara, Masahiro Takagi, Hajime Fukuoka, and Yuki Omata

Subjects
Materials science, Ultraviolet Rays, Infrared, Vesicle, Phospholipid, Membranes, Artificial, Surfaces and Interfaces, Condensed Matter Physics, Micrometre, Crystallography, chemistry.chemical_compound, Membrane, chemistry, Amphiphile, Electrochemistry, Biophysics, General Materials Science, Lamellar structure, Irradiation, Phospholipids, Spectroscopy
Abstract

Vesicle formation is a fundamental kinetic process related to the vesicle budding and endocytosis in a cell. In the vesicle formation by artificial means, transformation of lamellar lipid aggregates into spherical architectures is a key process and known to be prompted by e.g. heat, infrared irradiation, and alternating electric field induction. Here we report UV-light-driven formation of vesicles from particles consisting of crumpled phospholipid multilayer membranes involving a photoactive amphiphilic compound composed of 1,4-bis(4-phenylethynyl)benzene (BPEB) units. The particles can readily be prepared from a mixture of these components, which is casted on the glass surface followed by addition of water under ultrasonic radiation. Interestingly, upon irradiation with UV light, micrometer-size vesicles were generated from the particles. Neither infrared light irradiation nor heating prompted the vesicle formation. Taking advantage of the benefits of light, we successfully demonstrated micrometer-scale spatiotemporal control of single vesicle formation. It is also revealed that the BPEB units in the amphiphile are essential for this phenomenon.

Published
2014

12. Torque-speed relationships of Na+-driven chimeric flagellar motors in Escherichia coli

Author

Hiroto Takahashi, Yuichi Inoue, Hajime Fukuoka, Richard M. Berry, Michio Homma, Chien-Jung Lo, Akihiko Ishijima, Teuta Pilizota, Yoshiyuki Sowa, and George H. Wadhams

Subjects
Physics, Kinetic model, Stator, Escherichia coli Proteins, Molecular Motor Proteins, Sodium, Stall (fluid mechanics), medicine.disease_cause, Rotary engine, Ion, law.invention, Torque, Structural Biology, law, Flagella, medicine, Biophysics, Escherichia coli, ATP-Binding Cassette Transporters, Cell envelope, Molecular Biology, Vibrio alginolyticus, Bacterial Outer Membrane Proteins
Abstract

The bacterial flagellar motor is a rotary motor in the cell envelope of bacteria that couples ion flow across the cytoplasmic membrane to torque generation by independent stators anchored to the cell wall. The recent observation of stepwise rotation of a Na(+)-driven chimeric motor in Escherichia coli promises to reveal the mechanism of the motor in unprecedented detail. We measured torque-speed relationships of this chimeric motor using back focal plane interferometry of polystyrene beads attached to flagellar filaments in the presence of high sodium-motive force (85 mM Na(+)). With full expression of stator proteins the torque-speed curve had the same shape as those of wild-type E. coli and Vibrio alginolyticus motors: the torque is approximately constant (at approximately 2200 pN nm) from stall up to a "knee" speed of approximately 420 Hz, and then falls linearly with speed, extrapolating to zero torque at approximately 910 Hz. Motors containing one to five stators generated approximately 200 pN nm per stator at speeds up to approximately 100 Hz/stator; the knee speed in 4- and 5-stator motors is not significantly slower than in the fully induced motor. This is consistent with the hypothesis that the absolute torque depends on stator number, but the speed dependence does not. In motors with point mutations in either of two critical conserved charged residues in the cytoplasmic domain of PomA, R88A and R232E, the zero-torque speed was reduced to approximately 400 Hz. The torque at low speed was unchanged by mutation R88A but was reduced to approximately 1500 pN nm by R232E. These results, interpreted using a simple kinetic model, indicate that the basic mechanism of torque generation is the same regardless of stator type and coupling ion and that the electrostatic interaction between stator and rotor proteins is related to the torque-speed relationship.

Published
2016

13. Coordinated regulation of multiple flagellar motors by the Escherichia coli chemotaxis system

Author

Hajime Fukuoka, Yuichi Inoue, and Akihiko Ishijima

Subjects
Cell signaling, Biophysics, Chemotaxis, Biology, medicine.disease_cause, Intracellular Signaling Process, Biochemistry, medicine, Extracellular, Phosphorylation, Signal transduction, Escherichia coli, Intracellular
Abstract

Escherichia coli cells swim toward a favorable environment by chemotaxis. The chemotaxis system regulates the swimming behavior of the bacteria by controlling the rotational direction of their flagellar motors. Extracellular stimuli sensed by chemoreceptors are transduced to an intracellular signal molecule, phosphorylated CheY (CheY-P), that switches the rotational direction of the flagellar motors from counterclockwise (CCW) to clockwise (CW) or from CW to CCW. Many studies have focused on identifying the proteins involved in the chemotaxis system, and findings on the structures and intracellular localizations of these proteins have largely elucidated the molecular pathway. On the other hand, quantitative evaluations of the chemotaxis system, including the process of intracellular signaling by the propagation of CheY-P and the rotational switching of flagellar motor by binding of CheY-P molecules, are still uncertain. For instance, scientific consensus has held that the flagellar motors of an E. coli cell switch rotational direction asynchronously. However, recent work shows that the rotational switching of any two different motors on a single E. coli cell is highly coordinated; a sub-second switching delay between motors is clearly correlated with the relative distance of each motor from the chemoreceptor patch located at one pole of the cell. In this review of previous studies and our recent findings, we discuss the regulatory mechanism of the multiple flagellar motors on an individual E. coli cell and the intracellular signaling process that can be inferred from this coordinated switching.

Published
2012

14. Mutations Targeting the C-Terminal Domain of FliG Can Disrupt Motor Assembly in the Na+-Driven Flagella of Vibrio alginolyticus

Author

Norihiro Takekawa, Michio Homma, Natsumi Nonoyama, Hajime Fukuoka, and Seiji Kojima

Subjects
Vibrio alginolyticus, biology, Rotor (electric), Stator, C-terminus, Point mutation, Sodium, Flagellum, biology.organism_classification, Sodium Channels, law.invention, Crystallography, Bacterial Proteins, Cell Movement, Flagella, Structural Biology, law, Vibrio Infections, Thermotoga maritima, Mutation, Mutagenesis, Site-Directed, Biophysics, Basal body, Molecular Biology
Abstract

The torque of the bacterial flagellar motor is generated by the rotor-stator interaction coupled with specific ion translocation through the stator channel. To produce a fully functional motor, multiple stator units must be properly incorporated around the rotor by an as yet unknown mechanism to engage the rotor-stator interactions. Here, we investigated stator assembly using a mutational approach of the Na(+)-driven polar flagellar motor of Vibrio alginolyticus, whose stator is localized at the flagellated cell pole. We mutated a rotor protein, FliG, which is located at the C ring of the basal body and closely participates in torque generation, and found that point mutation L259Q, L270R or L271P completely abolishes both motility and polar localization of the stator without affecting flagellation. Likewise, mutations V274E and L279P severely affected motility and stator assembly. Those residues are localized at the core of the globular C-terminal domain of FliG when mapped onto the crystal structure of FliG from Thermotoga maritima, which suggests that those mutations induce quite large structural alterations at the interface responsible for the rotor-stator interaction. These results show that the C-terminal domain of FliG is critical for the proper assembly of PomA/PomB stator complexes around the rotor and probably functions as the target of the stator at the rotor side.

Published
2011

15. Coordinated Reversal of Flagellar Motors on a Single Escherichia coli Cell

Author

Akihiko Ishijima, Hajime Fukuoka, Takashi Sagawa, Shun Terasawa, Hiroto Takahashi, and Yuichi Inoue

Subjects
Cell signaling, Chemoreceptor, Rotation, Phosphatase, Green Fluorescent Proteins, Intracellular Space, Biophysics, Methyl-Accepting Chemotaxis Proteins, Flagellum, Biology, Models, Biological, Dephosphorylation, Bacterial Proteins, Extracellular, Escherichia coli, Escherichia coli Proteins, Molecular Motor Proteins, Muscle, Molecular Motors, and Cell Motility, Membrane Proteins, Chemoreceptor Cells, Cell biology, Flagella, Phosphorylation, bacteria, Artificial Cells, Mutant Proteins, biological phenomena, cell phenomena, and immunity, Intracellular, Gene Deletion
Abstract

An Escherichia coli cell transduces extracellular stimuli sensed by chemoreceptors to the state of an intracellular signal molecule, which regulates the switching of the rotational direction of the flagellar motors from counterclockwise (CCW) to clockwise (CW) and from CW back to CCW. Here, we performed high-speed imaging of flagellar motor rotation and show that the switching of two different motors on a cell is controlled coordinatedly by an intracellular signal protein, phosphorylated CheY (CheY-P). The switching is highly coordinated with a subsecond delay between motors in clear correlation with the distance of each motor from the chemoreceptor patch localized at a cell pole, which would be explained by the diffusive motion of CheY-P molecules in the cell. The coordinated switching becomes disordered by the expression of a constitutively active CheY mutant that mimics the CW-rotation stimulating function. The coordinated switching requires CheZ, which is the phosphatase for CheY-P. Our results suggest that a transient increase and decrease in the concentration of CheY-P caused by a spontaneous burst of its production by the chemoreceptor patch followed by its dephosphorylation by CheZ, which is probably a wavelike propagation in a subsecond timescale, triggers and regulates the coordinated switching of flagellar motors.

Published
2011
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16. Verification of Single-Molecule Imaging and Single-Molecule Measurements

Author

Hajime Fukuoka, Akihiko Ishijima, and Yuichi Inoue

Subjects
Materials science, General Computer Science, Molecular motor, Molecule, Electrical and Electronic Engineering, Single Molecule Imaging, Molecular physics
Abstract

Single-molecule imaging and single-molecule measurements constitute an integral part of life science researches. The research method, which allows direct measurements of individual motions and events of biomolecules, has contributed much to the development of life science research by providing us with numerous findings. It is left up to the judgment of researchers, however, whether the measurements really represent single-molecule events, which make it harder for more researchers to enter into this field. This paper deals with how single-molecule measurements were presented in past research outcomes and illustrates statistical-mechanical methods as well.

Published
2010

17. Thermosensing Function of the Escherichia coli Redox Sensor Aer

Author

Akihiko Ishijima, Yuichi Inoue, Noriko Ohta, Ikuro Kawagishi, Shinji Ohno, Hajime Fukuoka, and So Ichiro Nishiyama

Subjects
medicine.disease_cause, Microbiology, Thermosensing, Escherichia coli, medicine, Thermotaxis, Molecular Biology, biology, Escherichia coli Proteins, fungi, Temperature, Gene Expression Regulation, Bacterial, Periplasmic space, biology.organism_classification, Enterobacteriaceae, Cell biology, Transmembrane domain, nervous system, Biochemistry, Cytoplasm, Intercellular Signaling Peptides and Proteins, Carrier Proteins, human activities, Function (biology), circulatory and respiratory physiology, Signal Transduction
Abstract

Escherichia coli chemoreceptors can sense changes in temperature for thermotaxis. Here we found that the aerotaxis transducer Aer, a homolog of chemoreceptors lacking a periplasmic domain, mediates thermoresponses. We propose that thermosensing by the chemoreceptors is a general attribute of their highly conserved cytoplasmic domain (or their less conserved transmembrane domain).

Published
2010

18. Exchange of rotor components in functioning bacterial flagellar motor

Author

Shun Terasawa, Akihiko Ishijima, Hiroto Takahashi, Yuichi Inoue, and Hajime Fukuoka

Subjects
Photobleaching, Total internal reflection fluorescence microscope, Rotation, Chemistry, Stator, Rotor (electric), Green Fluorescent Proteins, Biophysics, Fluorescence recovery after photobleaching, Cell Biology, Biochemistry, law.invention, Coupling (electronics), Nuclear magnetic resonance, Bacterial Proteins, Microscopy, Fluorescence, Flagella, law, Escherichia coli, Molecular motor, Torque, Molecular Biology
Abstract

The bacterial flagellar motor is a rotary motor driven by the electrochemical potential of a coupling ion. The interaction between a rotor and stator units is thought to generate torque. The overall structure of flagellar motor has been thought to be static, however, it was recently proved that stators are exchanged in a rotating motor. Understanding the dynamics of rotor components in functioning motor is important for the clarifying of working mechanism of bacterial flagellar motor. In this study, we focused on the dynamics and the turnover of rotor components in a functioning flagellar motor. Expression systems for GFP-FliN, FliM-GFP, and GFP-FliG were constructed, and each GFP-fusion was functionally incorporated into the flagellar motor. To investigate whether the rotor components are exchanged in a rotating motor, we performed fluorescence recovery after photobleaching experiments using total internal reflection fluorescence microscopy. After photobleaching, in a tethered cell producing GFP-FliN or FliM-GFP, the recovery of fluorescence at the rotational center was observed. However, in a cell producing GFP-FliG, no recovery of fluorescence was observed. The transition phase of fluorescence intensity after full or partially photobleaching allowed the turnover of FliN subunits to be calculated as 0.0007s(-1), meaning that FliN would be exchanged in tens of minutes. These novel findings indicate that a bacterial flagellar motor is not a static structure even in functioning state. This is the first report for the exchange of rotor components in a functioning bacterial flagellar motor.

Published
2010

19. Sodium-dependent dynamic assembly of membrane complexes in sodium-driven flagellar motors

Author

Michio Homma, Hajime Fukuoka, Tomoyuki Wada, Akihiko Ishijima, and Seiji Kojima

Subjects
Rotor (electric), Stator, Sodium, Ionophore, chemistry.chemical_element, Biology, Microbiology, law.invention, Ion, Coupling (electronics), Membrane, chemistry, Biochemistry, law, Biophysics, Binding site, Molecular Biology
Abstract

The bacterial flagellar motor is driven by the electrochemical potential of specific ions, H + or Na + . The motor consists of a rotor and stator, and their interaction generates rotation. The stator, which is composed of PomA and PomB in the Na + motor of Vibrio alginolyticus, is thought to be a torque generator converting the energy of ion flux into mechanical power. We found that specific mutations in PomB, including D24N, F33C and S248F, which caused motility defects, affected the assembly of stator complexes into the polar flagellar motor using green fluorescent protein-fused stator proteins. D24 of PomB is the predicted Na + -binding site. Furthermore, we demonstrated that the coupling ion, Na + , is required for stator assembly and that phenamil (an inhibitor of the Na + -driven motor) inhibited the assembly. Carbonyl cyanide m-chlorophenylhydrazone, which is a proton ionophore that collapses the sodium motive force in this organism at neutral pH, also inhibited the assembly. Thus we conclude that the process of Na + influx through the channel, including Na + binding, is essential for the assembly of the stator complex to the flagellar motor as well as for torque generation.

Published
2009

20. The Mechanism of the Ion-Driven Flagellar Motor Rotation: Where Is the Rotational Force Generated?

Author

Toshiharu Yakushi, Michio Homma, and Hajime Fukuoka

Subjects
Mechanism (engineering), Nuclear magnetic resonance, Rotor (electric), law, Chemical physics, Chemistry, Stator, Torque, Flagellum, Electrostatics, Rotation, Molecular machine, law.invention
Abstract

Bacterial flagellar motors are molecular machines powered by the electrochemical potential gradient of specific ions, H+ or Na+, across the membrane. The force is generated by the interaction between a stator and a rotor of the motor which is located at the base of flagellum. A mechanical model of the H+-driven motor rotation by electrostatic interactions between the stator protein, MotA, and the rotor protein, FliG, has been presented. In this review, we summarize recent studies of the Na+-driven motor and discuss the molecular mechanism of the rotation comparing with the H+-driven motor.

Published
2005

21. Direct Imaging of Intracellular Signaling Components That Regulate Bacterial Chemotaxis

Author

Hiroto Takahashi, Yuichi Inoue, Hajime Fukuoka, Akihiko Ishijima, and Takashi Sagawa

Subjects
Rotation, Green Fluorescent Proteins, Immunoblotting, Intracellular Space, Methyl-Accepting Chemotaxis Proteins, Direct imaging, Plasma protein binding, Molecular Dynamics Simulation, Biology, Time-Lapse Imaging, Biochemistry, Green fluorescent protein, Bacterial Proteins, Escherichia coli, Phosphorylation, Molecular Biology, Methyl-accepting chemotaxis protein, Chemotaxis, Escherichia coli Proteins, Molecular Motor Proteins, Membrane Proteins, Cell Biology, Cell biology, Microscopy, Fluorescence, Flagella, bacteria, biological phenomena, cell phenomena, and immunity, Signal transduction, Intracellular, Protein Binding, Signal Transduction
Abstract

The bacterial chemotaxis system regulates the rotational direction of flagellar motors through an intracellular signaling molecule, the phosphorylated form of CheY (CheY-P). The binding of CheY-P to a motor is believed to switch the motor's rotational direction from counterclockwise to clockwise. We demonstrated that the rotational switch of a motor was directly regulated by the binding and dissociation of CheY-P by simultaneously visualizing CheY tagged with green fluorescent protein and the rotational switching of a motor in live cells. The binding of 13 ± 7 CheY-P molecules was sufficient to induce clockwise rotation, and CheY-P molecules bound to and dissociated from a motor within ~100 ms during switching. Thus, we have directly measured the regulation of the output from a signal transduction pathway by intracellular signaling proteins.

Published
2014

22. Glucose-stimulated single pancreatic islets sustain increased cytosolic ATP levels during initial Ca2+ influx and subsequent Ca2+ oscillations

Author

Hajime Fukuoka, Kazuaki Nagashima, Seiji Takashima, Nobuya Inagaki, Hiromi Imamura, Takashi Tanaka, Hidetaka Kioka, Akira Kakizuka, and Hiroyuki Noji

Subjects
medicine.medical_specialty, medicine.medical_treatment, Glutamine, Pancreatic Islets, Mitochondrion, Biology, Biochemistry, Imaging, Membrane Potentials, chemistry.chemical_compound, Islets of Langerhans, Mice, Adenosine Triphosphate, Cytosol, Leucine, Internal medicine, Cell Line, Tumor, Pyruvic Acid, medicine, Insulin, Animals, Secretion, Calcium Signaling, Molecular Biology, Membrane potential, Pancreatic islets, Depolarization, Cell Biology, Mitochondria, ATP, stomatognathic diseases, Endocrinology, medicine.anatomical_structure, Glucose, Metabolism, chemistry, Sweetening Agents, Calcium, Energy Metabolism, Adenosine triphosphate, Intracellular
Abstract

In pancreatic islets, insulin secretion occurs via synchronous elevation of Ca(2+) levels throughout the islets during high glucose conditions. This Ca(2+) elevation has two phases: a quick increase, observed after the glucose stimulus, followed by prolonged oscillations. In these processes, the elevation of intracellular ATP levels generated from glucose is assumed to inhibit ATP-sensitive K(+) channels, leading to the depolarization of membranes, which in turn induces Ca(2+) elevation in the islets. However, little is known about the dynamics of intracellular ATP levels and their correlation with Ca(2+) levels in the islets in response to changing glucose levels. In this study, a genetically encoded fluorescent biosensor for ATP and a fluorescent Ca(2+) dye were employed to simultaneously monitor the dynamics of intracellular ATP and Ca(2+) levels, respectively, inside single isolated islets. We observed rapid increases in cytosolic and mitochondrial ATP levels after stimulation with glucose, as well as with methyl pyruvate or leucine/glutamine. High ATP levels were sustained as long as high glucose levels persisted. Inhibition of ATP production suppressed the initial Ca(2+) increase, suggesting that enhanced energy metabolism triggers the initial phase of Ca(2+) influx. On the other hand, cytosolic ATP levels did not fluctuate significantly with the Ca(2+) level in the subsequent oscillation phases. Importantly, Ca(2+) oscillations stopped immediately before ATP levels decreased significantly. These results might explain how food or glucose intake evokes insulin secretion and how the resulting decrease in plasma glucose levels leads to cessation of secretion., インスリン分泌における重要因子が変動する様子を可視化 -蛍光タンパク質センサーを用いたライブイメージング法で-. 京都大学プレスリリース. 2014-01-30.

Published
2013

23. Coordinated regulation of multiple flagellar motors by the

Author

Hajime, Fukuoka, Yuichi, Inoue, and Akihiko, Ishijima

Subjects
CheY, receptor, Review, rotary motor, bacteria, signal transduction
Abstract

Escherichia coli cells swim toward a favorable environment by chemotaxis. The chemotaxis system regulates the swimming behavior of the bacteria by controlling the rotational direction of their flagellar motors. Extracellular stimuli sensed by chemoreceptors are transduced to an intracellular signal molecule, phosphorylated CheY (CheY-P), that switches the rotational direction of the flagellar motors from counterclockwise (CCW) to clockwise (CW) or from CW to CCW. Many studies have focused on identifying the proteins involved in the chemotaxis system, and findings on the structures and intracellular localizations of these proteins have largely elucidated the molecular pathway. On the other hand, quantitative evaluations of the chemotaxis system, including the process of intracellular signaling by the propagation of CheY-P and the rotational switching of flagellar motor by binding of CheY-P molecules, are still uncertain. For instance, scientific consensus has held that the flagellar motors of an E. coli cell switch rotational direction asynchronously. However, recent work shows that the rotational switching of any two different motors on a single E. coli cell is highly coordinated; a sub-second switching delay between motors is clearly correlated with the relative distance of each motor from the chemoreceptor patch located at one pole of the cell. In this review of previous studies and our recent findings, we discuss the regulatory mechanism of the multiple flagellar motors on an individual E. coli cell and the intracellular signaling process that can be inferred from this coordinated switching.

Published
2011

25. The Vibrio motor proteins, MotX and MotY, are associated with the basal body of Na-driven flagella and required for stator formation

Author

Toshiharu Yakushi, Seiji Kojima, Hiroyuki Terashima, Hajime Fukuoka, and Michio Homma

Subjects
Vibrio alginolyticus, biology, Molecular Motor Proteins, Sodium, Membrane Proteins, Flagellum, biology.organism_classification, Microbiology, Vibrio, Sodium Channels, Cell biology, Motor protein, Bacterial Proteins, Flagella, Basal body, Molecular Biology, Bacterial Outer Membrane Proteins
Abstract

The four motor proteins PomA, PomB, MotX and MotY, which are believed to be stator proteins, are essential for motility by the Na(+)-driven flagella of Vibrio alginolyticus. When we purified the flagellar basal bodies, MotX and MotY were detected in the basal body, which is the supramolecular complex comprised of the rotor and the bushing, but PomA and PomB were not. By antibody labelling, MotX and MotY were detected around the LP ring. These results indicate that MotX and MotY associate with the basal body. The basal body had a new ring structure beneath the LP ring, which was named the T ring. This structure was changed or lost in the basal body from a DeltamotX or DeltamotY strain. The T ring probably comprises MotX and MotY. In the absence of MotX or MotY, we demonstrated that PomA and PomB were not localized to a cell pole. From the above results, we suggest that MotX and MotY of the T ring are involved in the incorporation and/or stabilization of the PomA/PomB complex in the motor.

Published
2006

26. Roles of Charged Residues of Rotor and Stator in Flagellar Rotation: Comparative Study using H+-Driven and Na+-Driven Motors in Escherichia coli

Author

Michio Homma, Hajime Fukuoka, Jung-Hoon Yang, David F. Blair, and Toshiharu Yakushi

Subjects
Stator, Mutant, Flagellum, Rotation, medicine.disease_cause, Microbiology, law.invention, Microbial Cell Biology, Bacterial Proteins, law, medicine, Escherichia coli, Molecular Biology, Vibrio alginolyticus, biology, Rotor (electric), Molecular Motor Proteins, Sodium, Membrane Proteins, biology.organism_classification, Membrane protein, Biochemistry, Flagella, Mutation, Biophysics, Protons, Locomotion, Hydrogen
Abstract

In Escherichia coli , rotation of the flagellar motor has been shown to depend upon electrostatic interactions between charged residues of the stator protein MotA and the rotor protein FliG. These charged residues are conserved in the Na + -driven polar flagellum of Vibrio alginolyticus , but mutational studies in V. alginolyticus suggested that they are relatively unimportant for motor rotation. The electrostatic interactions detected in E. coli therefore might not be a general feature of flagellar motors, or, alternatively, the V. alginolyticus motor might rely on similar interactions but incorporate additional features that make it more robust against mutation. Here, we have carried out a comparative study of chimeric motors that were resident in E. coli but engineered to use V. alginolyticus stator components, rotor components, or both. Charged residues in the V. alginolyticus rotor and stator proteins were found to be essential for motor rotation when the proteins functioned in the setting of the E. coli motor. Patterns of synergism and suppression in rotor/stator double mutants indicate that the V. alginolyticus proteins interact in essentially the same way as their counterparts in E. coli . The robustness of the rotor-stator interface in V. alginolyticus is in part due to the presence of additional charged residues in PomA but appears mainly due to other factors, because an E. coli motor using both rotor and stator components from V. alginolyticus remained sensitive to mutation. Motor function in V. alginolyticus may be enhanced by the proteins MotX and MotY.

Published
2006

27. Concerted effects of amino acid substitutions in conserved charged residues and other residues in the cytoplasmic domain of PomA, a stator component of Na+-driven flagella

Author

Toshiharu Yakushi, Hajime Fukuoka, and Michio Homma

Subjects
Cytoplasm, Movement, Mutant, Molecular Sequence Data, Flagellum, Biology, Microbiology, Conserved sequence, Microbial Cell Biology, Amino Acid Sequence, Molecular Biology, Peptide sequence, Conserved Sequence, Vibrio, chemistry.chemical_classification, Molecular Motor Proteins, Sodium, Temperature, Gene Expression Regulation, Bacterial, Transmembrane protein, Amino acid, Biochemistry, Membrane protein, chemistry, Amino Acid Substitution, Flagella, Biophysics, Mutagenesis, Site-Directed, Bacterial Outer Membrane Proteins
Abstract

PomA is a membrane protein that is one of the essential components of the sodium-driven flagellar motor in Vibrio species. The cytoplasmic charged residues of Escherichia coli MotA, which is a PomA homolog, are believed to be required for the interaction of MotA with the C-terminal region of FliG. It was previously shown that a PomA variant with neutral substitutions in the conserved charged residues (R88A, K89A, E96Q, E97Q, and E99Q; AAQQQ) was functional. In the present study, five other conserved charged residues were replaced with neutral amino acids in the AAQQQ PomA protein. These additional substitutions did not affect the function of PomA. However, strains expressing the AAQQQ PomA variant with either an L131F or a T132M substitution, neither of which affected motor function alone, exhibited a temperature-sensitive (TS) motility phenotype. The double substitutions R88A or E96Q together with L131F were sufficient for the TS phenotype. The motility of the PomA TS mutants immediately ceased upon a temperature shift from 20 to 42°C and was restored to the original level approximately 10 min after the temperature was returned to 20°C. It is believed that PomA forms a channel complex with PomB. The complex formation of TS PomA and PomB did not seem to be affected by temperature. Suppressor mutations of the TS phenotype were mapped in the cytoplasmic boundaries of the transmembrane segments of PomA. We suggest that the cytoplasmic surface of PomA is changed by the amino acid substitutions and that the interaction of this surface with the FliG C-terminal region is temperature sensitive.

Published
2004

28. Flagellum-independent trail formation of escherichia coli on semi-solid agar

Author

Michio Homma, Shigeyuki Ichihara, and Hajime Fukuoka

Subjects
food.ingredient, Flagellum, Cell morphology, medicine.disease_cause, Applied Microbiology and Biotechnology, Biochemistry, Analytical Chemistry, Microbiology, food, medicine, Escherichia coli, Agar, Molecular Biology, TRAIL formation, Microscopy, biology, Organic Chemistry, General Medicine, biology.organism_classification, Enterobacteriaceae, Flagella, Mutation, Biophysics, bacteria, Bacteria, Biotechnology, Semi solid
Abstract

Escherichia coli can form linear trails and move in a flagellum-independent manner on semisolid agar containing carbon sources. Trail formation seemed to correlate with the growth speed and/or carbon metabolism. Cell morphology in linear trails changed into larger cell sizes. We speculate that the flagellum-independent trail formation is a new mechanism for migration of E. coli cells.

Published
2003

45. 3N1546 Real-time video nanometry and controlled laser irradiation reveals a cellular response time of E. coli cell for chemoattractant(Cell biology6,The 49th Annual Meeting of the Biophysical Society of Japan)

Author

Yu Kikuchi, Takahiro Muraoka, Akihiko Ishijima, Kazushi Kinbara, Takashi Sagawa, Hajime Fukuoka, Hiroto Takahashi, and Yuichi Inoue

Subjects
Real time video, medicine.anatomical_structure, law, Cell, medicine, Response time, Chemotaxis, Nanotechnology, Irradiation, Biology, Laser, law.invention, Cell biology
Published
2011

46. 1P220 1YA1030 Synchronous regulation of multiple flagellar motors on a single Escherichia coli cell(Cell biology,Early Research in Biophysics Award Candidate Presentations,Early Research in Biophysics Award,The 48th Annual Meeting of the Biophysical Society of Japan)

Author

Shun Terasawa, Hajime Fukuoka, Akihiko Ishijima, Hiroto Takahashi, and Yuichi Inoue

Subjects
medicine.anatomical_structure, Cell, medicine, Biophysics, Biology, medicine.disease_cause, Escherichia coli, Cell biology
Published
2010

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