Your search keyword '"Homma, Michio"' showing total 127 results

1. Protein degradation by a component of the chaperonin‐linked protease ClpP.

Author

Ishikawa, Fumihiro, Homma, Michio, Tanabe, Genzoh, and Uchihashi, Takayuki

Abstract

In cells, proteins are synthesized, function, and degraded (dead). Protein synthesis (spring) is important for the life of proteins. However, how proteins die is equally important for organisms. Proteases are secreted from cells and used as nutrients to break down external proteins. Proteases degrade unwanted and harmful cellular proteins. In eukaryotes, a large enzyme complex called the proteasome is primarily responsible for cellular protein degradation. Prokaryotes, such as bacteria, have similar protein degradation systems. In this review, we describe the structure and function of the ClpXP complex in the degradation system, which is an ATP‐dependent protease in bacterial cells, with a particular focus on ClpP. [ABSTRACT FROM AUTHOR]

Published

2024

2. Interaction of FlhF, SRP-like GTPase with FliF, MS ring component assembling the initial structure of flagella in marine Vibrio.

Author

Fukushima, Yuria, Homma, Michio, and Kojima, Seiji

Subjects

*VIBRIO, *GUANOSINE triphosphatase, *CARRIER proteins, *ESCHERICHIA coli, *VIBRIO alginolyticus

Abstract

Vibrio alginolyticus forms a single flagellum at its cell pole. FlhF and FlhG are known to be the main proteins responsible for the polar formation of single flagellum. MS-ring formation in the flagellar basal body appears to be an initiation step for flagellar assembly. The MS-ring is formed by a single protein, FliF, which has two transmembrane (TM) segments and a large periplasmic region. We had shown that FlhF was required for the polar localization of Vibrio FliF, and FlhF facilitated MS-ring formation when FliF was overexpressed in Escherichia coli cells. These results suggest that FlhF interacts with FliF to facilitate MS-ring formation. Here, we attempted to detect this interaction using Vibrio FliF fragments fused to a tag of Glutathione S-transferase in E. coli. We found that the N-terminal 108 residues of FliF, including the first TM segment and the periplasmic region, could pull FlhF down. In the first step, signal recognition particle (SRP) and its receptor are involved in the transport of membrane proteins to target them, which delivers them to the translocon. FlhF may have a similar or enhanced function as SRP, which binds to a region rich in hydrophobic residues. [ABSTRACT FROM AUTHOR]

Published

2023

3. Formation of multiple flagella caused by a mutation of the flagellar rotor protein FliM in Vibrio alginolyticus.

Author

Homma, Michio, Takekawa, Norihiro, Fujiwara, Kazushi, Hao, Yuxi, Onoue, Yasuhiro, and Kojima, Seiji

Subjects

*VIBRIO alginolyticus, *FLAGELLA (Microbiology), *MARINE bacteria, *NUCLEOTIDE sequencing, *ADENOSINE triphosphatase, *ROTORS, *MISSENSE mutation, *GENETIC mutation

Abstract

Marine bacterium Vibrio alginolyticus forms a single flagellum at a cell pole. In Vibrio, two proteins (GTPase FlhF and ATPase FlhG) regulate the number of flagella. We previously isolated the NMB155 mutant that forms multiple flagella despite the absence of mutations in flhF and flhG. Whole‐genome sequencing of NMB155 identified an E9K mutation in FliM that is a component of C‐ring in the flagellar rotor. Mutations in FliM result in defects in flagellar formation (fla) and flagellar rotation (che or mot); however, there are a few reports indicating that FliM mutations increase the number of flagella. Here, we determined that the E9K mutation confers the multi‐flagellar phenotype and also the che phenotype. The co‐expression of wild‐type FliM and FliM‐E9K indicated that they were competitive in regard to determining the flagellar number. The ATPase activity of FlhG has been correlated with the number of flagella. We observed that the ATPase activity of FlhG was increased by the addition of FliM but not by the addition of FliM‐E9K in vitro. This indicates that FliM interacts with FlhG to increase its ATPase activity, and the E9K mutation may inhibit this interaction. FliM may control the ATPase activity of FlhG to properly regulate the number of the polar flagellum at the cell pole. [ABSTRACT FROM AUTHOR]

Published

2022

4. Functional analysis of the N-terminal region of Vibrio FlhG, a MinD-type ATPase in flagellar number control.

Author

Homma, Michio, Mizuno, Akira, Hao, Yuxi, and Kojima, Seiji

Subjects

*ADENOSINE triphosphatase, *MUTANT proteins, *VIBRIO alginolyticus, *VIBRIO, *FUNCTIONAL analysis, *GUANOSINE triphosphatase, *PROTEIN stability

Abstract

GTPase FlhF and ATPase FlhG are two key factors involved in regulating the flagellum number in Vibrio alginolyticus. FlhG is a paralogue of the Escherichia coli cell division regulator MinD and has a longer N -terminal region than MinD with a conserved DQAxxLR motif. The deletion of this N -terminal region or a Q9A mutation in the DQAxxLR motif prevents FlhG from activating the GTPase activity of FlhF in vitro and causes a multi-flagellation phenotype. The mutant FlhG proteins, especially the N -terminally deleted variant, were remarkably reduced compared to that of the wild-type protein in vivo. When the mutant FlhG was expressed at the same level as the wild-type FlhG, the number of flagella was restored to the wild-type level. Once synthesized in Vibrio cells, the N -terminal region mutation in FlhG seems not to affect the protein stability. We speculated that the flhG translation efficiency is decreased by N -terminal mutation. Our results suggest that the N -terminal region of FlhG controls the number of flagella by adjusting the FlhF activity and the amount of FlhG in vivo. We speculate that the regulation by FlhG, achieved through transcription by the master regulator FlaK, is affected by the mutations, resulting in reduced flagellar formation by FlhF. [ABSTRACT FROM AUTHOR]

Published

2022

5. Roles of the second messenger c‐di‐GMP in bacteria: Focusing on the topics of flagellar regulation and Vibrio spp.

Author

Homma, Michio and Kojima, Seiji

Subjects

*CYCLIC guanylic acid, *VIBRIO cholerae, *VIBRIO, *CYCLIC adenylic acid, *INOSITOL phosphates, *VIBRIO alginolyticus, *CELLULOSE synthase

Abstract

Typical second messengers include cyclic AMP (cAMP), cyclic GMP (cGMP), and inositol phosphate. In bacteria, cyclic diguanylate (c‐di‐GMP), which is not used in animals, is widely used as a second messenger for environmental responses. Initially found as a regulator of cellulose synthesis, this small molecule is known to be widely present in bacteria. A wide variety of synthesis and degradation enzymes for c‐di‐GMP exist, and the activities of effector proteins are regulated by changing the cellular c‐di‐GMP concentration in response to the environment. It has been shown well that c‐di‐GMP plays an essential role in pathogenic cycle and is involved in flagellar motility in Vibrio cholerae. In this review, we aim to explain the direct or indirect regulatory mechanisms of c‐di‐GMP in bacteria, focusing on the study of c‐di‐GMP in Vibrio spp. and in flagella, which are our research subjects. [ABSTRACT FROM AUTHOR]

Published

2022

6. Hybrid-fuel bacterial flagellar motors in Escherichia coli.

Author

Sowa, Yoshiyuki, Homma, Michio, Ishijima, Akihiko, and Berry, Richard M.

Subjects

*POLYSTYRENE, *CYTOPLASMIC filaments, *CYTOPLASM, *FLAGELLARIACEAE, *ELECTROCHEMICALS industry

Abstract

The bacterial flagellar motor rotates driven by an electrochemical ion gradient across the cytoplasmic membrane, either H+ or Na+ ions. The motor consists of a rotor ∼50 nm in diameter surrounded by multiple torque-generating ion-conducting stator units. Stator units exchange spontaneously between the motor and a pool in the cytoplasmic membrane on a timescale of minutes, and their stability in the motor is dependent upon the ion gradient. We report a genetically engineered hybrid-fuel flagellar motor in Escherichia coli that contains both H+- and Na+-driven stator components and runs on both types of ion gradient. We controlled the number of each type of stator unit in the motor by protein expression levels and Na+ concentration ([Na+]), using speed changes of single motors driving 1-μm polystyrene beads to determine stator unit numbers. De-energized motors changed from locked to freely rotating on a timescale similar to that of spontaneous stator unit exchange. Hybrid motor speed is simply the sum of speeds attributable to individual stator units of each type. With Na+ and H+ stator components expressed at high and medium levels, respectively, Na+ stator units dominate at high [Na+] and are replaced by H+ units when Na+ is removed. Thus, competition between stator units for spaces in a motor and sensitivity of each type to its own ion gradient combine to allow hybrid motors to adapt to the prevailing ion gradient. We speculate that a similar process may occur in species that naturally express both H+ and Na+ stator components sharing a common rotor. [ABSTRACT FROM AUTHOR]

Published

2014

7. Intragenic Suppressor of a Plug Deletion Nonmotiity Mutation in PotB, a Chimeric Stator Protein of Sodium-Driven Flagella.

Author

Zhu, Shiwei, Homma, Michio, and Kojima, Seiji

Subjects

*CHIMERIC proteins, *SUPPRESSOR mutation, *FLAGELLA (Microbiology), *SODIUM, *VIBRIO alginolyticus

Abstract

The torque of bacterial flagellar motors is generated by interactions between the rotor and the stator and is coupled to the influx of H+or Na+ through the stator. A chimeric protein, PotB, in which the N-terminal region of Vibrio alginolyticus PomB was fused to the C-terminal region of Escherichia coli MotB, can function with PomA as a Na~-driven stator in E. coli. Here, we constructed a deletion variant of PotB (with a deletion of residues 41 to 91 [~41-91], called PotBi&L), which lacks the periplasmic linker region including the segment that works as a "plug" to inhibit premature ion influx. This variant did not confer motile ability, but we isolated a Na+-driven, spontaneous suppressor mutant, which has a point mutation (R1O9P) in the MotB/PomB-specific a-helix that connects the transmembrane and peptidoglycan binding domains of PotB~L in the region of MotB. Overproduction of the PomA/PotB~L(R1O9P) stator inhibited the growth of E. coil cells, suggesting that this stator has high Na~-conducting activity. Mutational analyses of ArglO9 and nearby residues suggest that the structural alteration in this a-helix optimizes PotBi&L conformation and restores the proper arrangement of transmembrane helices to form a functional channel pore. We speculate that this a-helix plays a key role in assembly-coupled stator activation. [ABSTRACT FROM AUTHOR]

Published

2012

8. Only One of the Five CheY Homologs in Vibrio cholerae Directly Switches Flagellar Rotation.

Author

Hyakutake, Akihiro, Homma, Michio, Austin, Melissa J., Boin, Markus A., Hëse, Claudia C., and Kawagishi, Ikuro

Subjects

*CHEMOTAXIS, *VIBRIO cholerae, *FLAGELLARIACEAE, *ESCHERICHIA, *PROTEINS, *BACTERIOLOGY, *HOMOLOGY (Biology)

Abstract

Vibrio cholerae has three sets of chemotaxis (Che) proteins, including three histidine kinases (CheA) and four response regulators (CheY) that are encoded by three che gene clusters. We deleted the cheY genes individually or in combination and found that only the cheY3 deletion impaired chemotaxis, reinforcing the previous conclusion that che cluster II is involved in chemotaxis. However, this does not exclude the involvement of the other clusters in chemotaxis, in other bacteria, phospho-CheY binds directly to the flagellar motor to modulate its rotation, and CheY overexpression, even without CheA, causes extremely biased swimming behavior. We reasoned that a V. cholerae CheY homolog, if it directly controls flagellar rotation, should also induce extreme swimming behavior when overproduced. This was the case for CheY3 (che cluster II). However, no other CheY homolog, including the putative CheY (CheY0) protein encoded outside the che clusters, affected swimming, demonstrating that these CheY homologs cannot act directly on the flagellar motor. CheY4 very slightly enhanced the spreading of an Escherichia coli cheZ mutant in semisolid agar, raising the possibility that it can affect chemotaxis by removing a phosphoryl group from CheY3. We also found that V. cholerae CheY3 and E. coli CheY are only partially exchangeable. Mutagenic analyses suggested that this may come from coevolution of the interacting pair of proteins, CheY and the motor protein FliM. Taken together, it is likely that the principal roles of che clusters I and III as well as cheY0 are to control functions other than chemotaxis. [ABSTRACT FROM AUTHOR]

Published

2005

9. Flagellum-independent Trail Formation of Escherichia coli on Semi-solid Agar.

Author

Fukuoka, Hajime, Homma, Michio, and Ichihara, Shigeyuki

Subjects

*ESCHERICHIA coli, *AGAR, *CARBON

Abstract

Reports on Escherichia coli which can form linear trails and move in a flagellum-independent manner on semisolid agar containing carbon sources. Correlation of trail formation with the growth speed and/or carbon metabolism; Changes in cell morphology in linear trails into larger cell sizes.

Published

2003

10. Intragenic suppressors of a mutation in the aspartate chemoreceptor gene that abolishes binding of the receptor to methyltransferase.

Author

Shiomi, Daisuke, Homma, Michio, and Kawagishi, Ikuro

Subjects

*GENETIC mutation, *CHEMORECEPTORS

Abstract

Examines the intragenic suppressors of a mutation in the aspartate chemoreceptor gene. Isolation of intragenic suppressors of the mutation; Importance of class I suppressors on the signal bias of Tar-W5501; Reinforcement of the importance of the xWxxF motif.

Published

2002

11. Characterization of the flagellar hook length control protein...

Author

Kawagishi, Ikuro and Homma, Michio

Subjects

*SALMONELLA typhimurium, *ESCHERICHIA coli

Abstract

Presents a study on the flagellar hook length control protein FliK of Salmonella typhimurium and Escherichia coli. Distinct part of S. typhimurium and E. Coli; Contents of the basal body; Length of the hook of the bacterial flagellum; Name given to hooks of indeterminate length; Name of the gene which is responsible for the polyhood mutant phenotype; Biological structures which are believed to have their length determined by molecular-ruler mechanism.

Published

1996

12. Chemotactic responses to an attractant and a repellent by the polar and lateral flagellar systems...

Author

Homma, Michio and Oota, Hisashi

Subjects

*VIBRIO, *CHEMOTAXIS

Abstract

Investigates the chemotactic responses to an attractant and repellent by the polar and lateral flagellar systems of Vibrio alginolyticus. Chemotactic responses of YM4; Swarm-deficient mutants; Chemotaxis-deficient mutants; Phenol response in lateral flagella rotation.

Published

1996

13. ビブリオ菌べん毛モーターの超高速回転を支える超分子リング構造形成のしくみ

Author

Terashima Hiroyuki, Homma Michio, and Imada Katsumi

Published

2014

14. Roles of linker region flanked by transmembrane and peptidoglycan binding region of PomB in energy conversion of the Vibrio flagellar motor.

Author

Miyamura, Yusuke, Nishikino, Tatsuro, Koiwa, Hiroaki, Homma, Michio, and Kojima, Seiji

Subjects

*ENERGY conversion, *VIBRIO, *MEMBRANE proteins, *SODIUM ions, *AGAR plates

Abstract

The flagellar components of Vibrio spp., PomA and PomB, form a complex that transduces sodium ion and contributes to rotate flagella. The transmembrane protein PomB is attached to the basal body T‐ring by its periplasmic region and has a plug segment following the transmembrane helix to prevent ion flux. Previously we showed that PomB deleted from E41 to R120 (Δ41–120) was functionally comparable to the full‐length PomB. In this study, three deletions after the plug region, PomB (Δ61–120), PomB (Δ61–140), and PomB (Δ71–150), were generated. PomB (Δ61–120) conferred motility, whereas the other two mutants showed almost no motility in soft agar plate; however, we observed some swimming cells with speed comparable for the wild‐type cells. When the two PomB mutants were introduced into a wild‐type strain, the swimming ability was not affected by the mutant PomBs. Then, we purified the mutant PomAB complexes to confirm the stator formation. When plug mutations were introduced into the PomB mutants, the reduced motility by the deletion was rescued, suggesting that the stator was activated. Our results indicate that the deletions prevent the stator activation and the linker and plug regions, from E41 to S150, are not essential for the motor function of PomB but are important for its regulation. [ABSTRACT FROM AUTHOR]

Published

2024

15. Signaling by the Escherichia coli aspartate chemoreceptor Tar with a single cytoplasmic domain...

Author

Tatsuno, Ichiro and Homma, Michio

Subjects

*CHEMORECEPTORS

Abstract

Demonstrates the use of in vivo intersubunit suppression to show that certain combinations of full-length and truncated mutant Tar proteins complemented each other to restore attractant responses to aspartate. Tar being a bacterial aspartate chemoreceptor which forms a homodimer in the presence of absence of ligands; Details of the research.

Published

1996

16. Structure and Energy-Conversion Mechanism of the Bacterial Na+-Driven Flagellar Motor.

Author

Takekawa, Norihiro, Imada, Katsumi, and Homma, Michio

Subjects

*VIBRIO alginolyticus, *MEMBRANE proteins, *CELL membranes, *STATORS, *SODIUM channels

Abstract

Many bacteria swim by means of flagella that are rotated by a nanoscale motor embedded in the cell membrane. Torque is generated by the interaction between ion-conducting membrane proteins that comprise the stator and ring-shaped structures that form the rotor. Although the structure and function of the motor have been extensively studied, many mysteries remain, including the force-generation mechanism, the path of ion flow through the stator, the activation mechanism of the stator, and the mechanism of switching between clockwise (CW) and counterclockwise (CCW) rotation. We summarize recent knowledge of the Na+-driven flagellar motor, especially the Vibrio polar motor that rotates much faster than the H+-driven motor and provides a useful model system for examining comparative aspects of flagellar function. The rotation of the bacterial flagellar motor is generated by the interaction between two parts in the motor, the rotor and the stator. The rotor is composed of a central rod and surrounding rings, and the stator is a unit that works as an energy convertor to couple ion influx to rotation of the rotor. The Na+-driven flagellar motor in Vibrio alginolyticus , whose rotation speed is faster than that of any H+-driven motor, contains PomA/PomB as stator proteins and some additional ring-like structures, the T-, H-, and O-rings, that are not found in H+-driven motors. Assembly of the PomA/PomB stators into the motor depends on the environmental Na+ concentration. In the presence of sodium, the periplasmic region of the stator changes its conformation to an activated form that binds to peptidoglycan, and charged residues in the cytoplasmic region interact with charged residues in the rotor protein FliG to generate rotational force. FliG dynamically changes its conformation to switch the rotational direction of the motor in response to the chemotactic signal transferred from the other rotor component, FliM, that binds to the chemotaxis response regulator protein CheY. [ABSTRACT FROM AUTHOR]

Published

2020

17. Structure of MotA, a flagellar stator protein, from hyperthermophile.

Author

Nishikino, Tatsuro, Takekawa, Norihiro, Tran, Duy Phuoc, Kishikawa, Jun-ichi, Hirose, Mika, Onoe, Sakura, Kojima, Seiji, Homma, Michio, Kitao, Akio, Kato, Takayuki, and Imada, Katsumi

Subjects

*STATORS, *MEMBRANE proteins, *ELECTRIC torque motors, *X-ray crystallography, *FLAGELLA (Microbiology)

Abstract

Many motile bacteria swim and swarm toward favorable environments using the flagellum, which is rotated by a motor embedded in the inner membrane. The motor is composed of the rotor and the stator, and the motor torque is generated by the change of the interaction between the rotor and the stator induced by the ion flow through the stator. A stator unit consists of two types of membrane proteins termed A and B. Recent cryo-EM studies on the stators from mesophiles revealed that the stator consists of five A and two B subunits, whereas the low-resolution EM analysis showed that purified hyperthermophilic MotA forms a tetramer. To clarify the assembly formation and factors enhancing thermostability of the hyperthermophilic stator, we determined the cryo-EM structure of MotA from Aquifex aeolicus (Aa-MotA), a hyperthermophilic bacterium, at 3.42 Å resolution. Aa-MotA forms a pentamer with pseudo C5 symmetry. A simulated model of the Aa-MotA 5 MotB 2 stator complex resembles the structures of mesophilic stator complexes, suggesting that Aa-MotA can assemble into a pentamer equivalent to the stator complex without MotB. The distribution of hydrophobic residues of MotA pentamers suggests that the extremely hydrophobic nature in the subunit boundary and the transmembrane region is a key factor to stabilize hyperthermophilic Aa-MotA. • The Na-type stator of Aquifex aeolicus , a hyperhermophile, comprises MotA and MotB. • The structure of the hyperthermophilic Aa-MotA was determined at 3.42 Å. • Aa-MotA can form a pentameric ring assembly without MotB. • A simulated structure of Aa-stator is equivalent to known A 5 B 2 stator structures. • Extremely hydrophobic nature of Aa-MotA may be a key for its hyperthermostability. [ABSTRACT FROM AUTHOR]

Published

2022

18. Hoop-like role of the cytosolic interface helix in Vibrio PomA, an ion-conducting membrane protein, in the bacterial flagellar motor.

Author

Nishikino, Tatsuro, Sagara, Yugo, Terashima, Hiroyuki, Homma, Michio, and Kojima, Seiji

Subjects

*MEMBRANE proteins, *VIBRIO, *SODIUM ions, *MOLECULAR motor proteins, *STRUCTURAL stability, *COMPLEX ions

Abstract

Vibrio has a polar flagellum driven by sodium ions for swimming. The force-generating stator unit consists of PomA and PomB. PomA contains four transmembrane regions and a cytoplasmic domain of approximately 100 residues, which interacts with the rotor protein, FliG, to be important for the force generation of rotation. The 3D structure of the stator shows that the cytosolic interface (CI) helix of PomA is located parallel to the inner membrane. In this study, we investigated the function of CI helix and its role as stator. Systematic proline mutagenesis showed that residues K64, F66 and M67 were important for this function. The mutant stators did not assemble around the rotor. Moreover, the growth defect caused by PomB plug deletion was suppressed by these mutations. We speculate that the mutations affect the structure of the helices extending from TM3 and TM4 and reduce the structural stability of the stator complex. This study suggests that the helices parallel to the inner membrane play important roles in various processes, such as the hoop-like function in securing the stability of the stator complex and the ion conduction pathway, which may lead to the elucidation of the ion permeation and assembly mechanism of the stator. [ABSTRACT FROM AUTHOR]

Published

2022

19. Mutations in the stator protein PomA affect switching of rotational direction in bacterial flagellar motor.

Author

Terashima, Hiroyuki, Hori, Kiyoshiro, Ihara, Kunio, Homma, Michio, and Kojima, Seiji

Subjects

*STATORS, *PROTEINS, *CHEMOTAXIS, *ROTORS, *TORQUE

Abstract

The flagellar motor rotates bi-directionally in counter-clockwise (CCW) and clockwise (CW) directions. The motor consists of a stator and a rotor. Recent structural studies have revealed that the stator is composed of a pentameric ring of A subunits and a dimer axis of B subunits. Highly conserved charged and neighboring residues of the A subunit interacts with the rotor, generating torque through a gear-like mechanism. The rotational direction is controlled by chemotaxis signaling transmitted to the rotor, with less evidence for the stator being involved. In this study, we report novel mutations that affect the switching of the rotational direction at the putative interaction site of the stator to generate rotational force. Our results highlight an aspect of flagellar motor function that appropriate switching of the interaction states between the stator and rotor is critical for controlling the rotational direction. [ABSTRACT FROM AUTHOR]

Published

2022

20. ZomB is essential for chemotaxis of Vibrio alginolyticus by the rotational direction control of the polar flagellar motor.

Author

Takekawa, Norihiro, Nishikino, Tatsuro, Hori, Kiyoshiro, Kojima, Seiji, Imada, Katsumi, and Homma, Michio

Subjects

*VIBRIO alginolyticus, *CHEMOTAXIS, *VIBRIO parahaemolyticus, *SHEWANELLA putrefaciens, *MEMBRANE proteins, *SHEWANELLA

Abstract

Bacteria exhibit chemotaxis by controlling flagellar rotation to move toward preferred places or away from nonpreferred places. The change in rotation is triggered by the binding of the chemotaxis signaling protein CheY‐phosphate (CheY‐P) to the C‐ring in the flagellar motor. Some specific bacteria, including Vibrio spp. and Shewanella spp., have a single transmembrane protein called ZomB. ZomB is essential for controlling the flagellar rotational direction in Shewanella putrefaciens and Vibrio parahaemolyticus. In this study, we confirmed that the zomB deletion results only in the counterclockwise (CCW) rotation of the motor in Vibrio alginolyticus as previously reported in other bacteria. We found that ZomB is not required for a clockwise‐locked phenotype caused by mutations in fliG and fliM, and that ZomB is essential for CW rotation induced by overproduction of CheY‐P. Purified ZomB proteins form multimers, suggesting that ZomB may function as a homo‐oligomer. These observations imply that ZomB interacts with protein(s) involved in either flagellar motor rotation, chemotaxis, or both. We provide the evidence that ZomB is a new player in chemotaxis and is required for the rotational control in addition to CheY in Vibrio alginolyticus. [ABSTRACT FROM AUTHOR]

Published

2021

21. Investigation of the chromophore binding cavity in the 11-cis acceptable microbial rhodopsin MR.

Author

Mori, Arisa, Yagasaki, Jin, Homma, Michio, Reissig, Louisa, and Sudo, Yuki

Subjects

*CHROMOPHORES, *RETINAL (Visual pigment), *BINDING sites, *BACTERIORHODOPSIN, *SCHIFF bases, *CONVERTERS (Electronics)

Abstract

Abstract: Rhodopsins are photoactive molecules functioning as photo-energy or photo-signal converters with the chromophore retinal. Recently we characterized a unique microbial rhodopsin (middle rhodopsin, MR) which can also bind 11-cis retinal besides all-trans and 13-cis retinal at a particular ratio. In this study, we investigated the structural characteristics around the retinal binding cavity in MR. The results suggest that the space of the retinal binding site of MR is less restricted to the retinal chromophore and the presence of the 11-cis conformer is regulated by the residues located around the retinal. Furthermore, although the triple mutant of MR has identical residues with the well-studied microbial rhodopsin bacteriorhodopsin (BR) within 5Å from the retinal, the absorption maximum and retinal composition of MR did not reach those of BR, indicating that some long-range effect(s) (>5Å) is also important for the maintenance of the chemical properties of MR. [Copyright &y& Elsevier]

Published

2013

22. Fluorescence imaging of GFP-fused periplasmic components of Na+-driven flagellar motor using Tat pathway in Vibrio alginolyticus.

Author

Takekawa, Norihiro, Kojima, Seiji, and Homma, Michio

Subjects

*TWIN-arginine translocase complex, *CELL membranes, *SIGNAL peptides, *BACTERIAL genetics, *ESCHERICHIA coli, *VIBRIO alginolyticus, *GREEN fluorescent protein, *CHIMERIC proteins, *PHYSIOLOGICAL effects of sodium

Abstract

The twin-arginine translocation (Tat) system works to export folded proteins across the cytoplasmic membrane via specific signal peptides harbouring a twin-arginine motif. In Escherichia coli, a functional GFP is exported to the periplasm through the Tat pathway by fusion of the signal peptide of TorA, which is one of the periplasmic proteins exported by the Tat pathway. In this study, we fused the signal peptide of Vibrio alginolyticus TorA (TorASP) to GFP and demonstrate the export of functional GFP to the periplasm of V. alginolyticus. We also made fusions of TorASP–GFP with MotX, MotY and FlgT, which are periplasmic components of the Na+-driven flagellar motor. Those fusion proteins were localized to the flagellar motor independent of the Na+ concentration in the environment. [ABSTRACT FROM AUTHOR]

Published

2013

23. Sodium-driven motor of the polar flagellum in marine bacteria Vibrio.

Author

Li, Na, Kojima, Seiji, and Homma, Michio

Subjects

*MOTILITY of microorganisms, *FLAGELLA (Microbiology), *MARINE bacteria, *VIBRIO, *SODIUM channels, *CELL membranes, *PROTEINS, *GENETIC mutation

Abstract

The Na+-driven bacterial flagellar motor is a molecular machine powered by an electrochemical potential gradient of sodium ions across the cytoplasmic membrane. The marine bacterium Vibrio alginolyticus has a single polar flagellum that enables it to swim in liquid. The flagellar motor contains a basal body and a stator complexes, which are composed of several proteins. PomA, PomB, MotX, and MotY are thought to be essential components of the stator that are required to generate the torque of the rotation. Several mutations have been investigated to understand the characteristics and function of the ion channel in the stator and the mechanism of its assembly around the rotor to complete the motor. In this review, we summarize recent results of the Na+-driven motor in the polar flagellum of Vibrio. [ABSTRACT FROM AUTHOR]

Published

2011

24. Direct Observation of the Structural Change of Tyrl 74 in the Primary Reaction of Sensory Rhodopsin II.

Author

Mizuno, Misao, Sudo, Yuki, Homma, Michio, and Mizutani, Yasuhisa

Subjects

*RHODOPSIN, *PHOTOTAXIS, *PHOTOISOMERIZATION, *WAVELENGTHS, *TYROSINE, *TRYPTOPHAN

Abstract

Sensory rhodopsin II (SRII) is a negative phototaxis receptor containing retinal as its chromophore, which mediates the avoidance of blue light. The signal transduction is initiated by the photoisomerization of the retinal chromophore, resulting in conformational changes of the protein which are transmitted to a transducer protein. To gain insight into the SRII sensing mechanism, we employed time-resolved ultraviolet resonance Raman spectroscopy monitoring changes in the protein structure in the picosecond time range following photoisomerization. We used a 450 nm pump pulse to initiate the SRII photocycle and two kinds of probe pulses with wavelengths of 225 and 238 nm to detect spectral changes in the tryptophan and tyrosine bands, respectively. The observed spectral changes of the Raman bands are most likely due to tryptophan and tyrosine residues located in the vicinity of the retinal chromophore, i.e., Trp76, Trp171, Tyr51, or Tyr174. The 225 nm UVRR spectra exhibited bleaching of the intensity for all the tryptophan bands within the instrumental response time, followed by a partial recovery with a time constant of 30 ps and no further changes up to 1 ns. In the 238 nm UVRR spectra, a fast recovering component was observed in addition to the 30 ps time constant component. A comparison between the spectra of the WT and Y174F mutant of SRII indicates that Tyr174 changes its structure and/or environment upon chromophore photoisomerization. These data represent the first real-time observation of the structural change of Tyr174, of which functional importance was pointed out previously. [ABSTRACT FROM AUTHOR]

Published

2011

25. Disulphide cross-linking between the stator and the bearing components in the bacterial flagellar motor.

Author

Hizukuri, Yohei, Kojima, Seiji, and Homma, Michio

Subjects

*CROSSLINKING (Polymerization), *PROTEIN crosslinking, *FLAGELLA (Microbiology), *ESCHERICHIA coli, *CELL membranes

Abstract

The flagellar motor is composed of the stator and the rotor, and the interaction between the stator and the rotor at the cytoplasmic region is believed to produce mechanical force for the rotation of flagella. The periplasmic region of the stator has been proposed to play an important role in assembly around and incorporation into the motor. In this study, we provide evidence suggesting that the periplasmic region of the stator component MotB interacts with the P-ring component FlgI, which functions as a bearing for the rotor along with the L-ring protein FlgH, from a site-directed disulphide cross-linking approach. First, we prepared four FlgI and three MotB cysteine-substituted mutant proteins and co-expressed them in various combinations in Escherichia coli. We detected cross-linked combinations of FlgI G11C and MotB S248C when treated with the oxidant Cu-phenanthroline or bismaleimide cross-linkers. Furthermore, we performed Cys-scanning mutagenesis around these two residues and found additional combinations of cross-linked residues. Treatment with a protonophore CCCP significantly reduced the cross-linking efficiency between FlgI and MotB in flagellated cells, but not in non-flagellated cells. These results suggest a direct contact between MotB and FlgI upon assembly of the stator into a motor. [ABSTRACT FROM PUBLISHER]

Published

2010

26. Functional Transfer of an Essential Aspartate for the Ion-binding Site in the Stator Proteins of the Bacterial Flagellar Motor

Author

Terashima, Hiroyuki, Kojima, Seiji, and Homma, Michio

Subjects

*ASPARTIC acid, *PROTEINS, *PROTEIN binding, *IONS, *ELECTROCHEMISTRY, *BACTERIA, *HYDROGEN ions, *SODIUM ions

Abstract

Abstract: Rotation of the bacterial flagellar motor exploits the electrochemical potential of the coupling ion (H+ or Na+) as its energy source. In the marine bacterium Vibrio alginolyticus, the stator complex is composed of PomA and PomB, and conducts Na+ across the cytoplasmic membrane to generate rotation. The transmembrane (TM) region of PomB, which forms the Na+-conduction pathway together with TM3 and TM4 of PomA, has a highly conserved aspartate residue (Asp24) that is essential for flagellar rotation. This residue contributes to the Na+-binding site. However, it is not clear whether residues other than Asp24 are involved in binding the coupling ion. We examined the possibility that loss of the negative charge of Asp24 can be suppressed by introduction of negatively charged residues in TM3 or TM4 of PomA. The motility defect associated with the D24N substitution in PomB could be rescued only by a N194D substitution in PomA. This result suggests that there must be a negatively charged ion-binding pocket in the stator complex but that the presence of a negatively charged residue at position 24 of PomB is not essential. A tandemly fused PomA dimer containing the N194D mutation either in its N-terminal or C-terminal half with PomB-D24N was functional, suggesting that PomB-D24N can form an ion-binding pocket with either subunit of PomA dimer. The findings obtained in this study provide important clues to the mechanism of ion binding in the stator complex. [Copyright &y& Elsevier]

Published

2010

27. Phototactic and Chemotactic Signal Transduction by Transmembrane Receptors and Transducers in Microorganisms.

Author

Suzuki, Daisuke, Irieda, Hiroki, Homma, Michio, Kawagishi, Ikuro, and Sudo, Yuki

Subjects

*PHOTOTAXIS, *CHEMOTAXIS, *TRANSDUCERS, *RHODOPSIN, *PHOTORECEPTORS, *MICROORGANISMS, *CHEMICAL senses, *PHOTOISOMERIZATION, *ABSORPTION

Abstract

Microorganisms show attractant and repellent responses to survive in the various environments in which they live. Those phototaxic (to light) and chemotaxic (to chemicals) responses are regulated by membrane-embedded receptors and transducers. This article reviews the following: (1) the signal relay mechanisms by two photoreceptors, Sensory Rhodopsin I (SRI) and Sensory Rhodopsin II (SRII) and their transducers (HtrI and HtrII) responsible for phototaxis in microorganisms; and (2) the signal relay mechanism of a chemoreceptor/transducer protein, Tar, responsible for chemotaxis in E. coli. Based on results mainly obtained by our group together with other findings, the possible molecular mechanisms for phototaxis and chemotaxis are discussed. [ABSTRACT FROM AUTHOR]

Published

2010

28. Control of Chemotactic Signal Gain via Modulation of a Pre-formed Receptor Array.

Author

Irieda, Hiroki, Homm, Motohiro, Homma, Michio, and Kawagishi, Ikuro

Subjects

*ESCHERICHIA coli, *CELLULAR signal transduction, *BIOENERGETICS, *PHYSIOLOGICAL control systems, *CHEMORECEPTORS, *SENSORY receptors

Abstract

The remarkably wide dynamic range of the chemotactic pathway of Escherichia coli, a model signal transduction system, is achieved by methylation/amidation of the transmembrane chemoreceptors that regulate the histidine kinase CheA in response to extracellular stimuli. The chemoreceptors cluster at a cell pole together with CheA and the adaptor CheW. Several lines of evidence have led to models that assume high cooperativity and sensitivity via collaboration of receptor dimers within a cluster. Here, using in vivo disulfide cross-linking assays, we have demonstrated a well defined arrangement of the aspartate chemoreceptor (Tar). The differential effects of amidation on cross-linking at different positions indicate that amidation alters the relative orientation of Tar dimers to each other (presumably inducing rotational displacements) without much affecting the conformation of the periplasmic domains. Interestingly, the effect of aspartate on cross-linking at any position tested was roughly opposite to that of receptor amidation. Furthermore, amidation attenuated the effects of aspartate by several orders of magnitude. These results suggest that receptor covalent modification controls signal gain by altering the arrangement or packing of receptor dimers in a pre-formed cluster. [ABSTRACT FROM AUTHOR]

Published

2006

29. Helical distribution of the bacterial chemoreceptor via colocalization with the Sec protein translocation machinery.

Author

Shiomi, Daisuke, Yoshimoto, Masayuki, Homma, Michio, and Kawagishi, Ikuro

Subjects

*CHEMORECEPTORS, *SENSORY receptors, *BACTERIAL proteins, *CHROMOSOMAL translocation, *BACTERIAL genetics

Abstract

In Escherichia coli, chemoreceptor clustering at a cell pole seems critical for signal amplification and adaptation. However, little is known about the mechanism of localization itself. Here we examined whether the aspartate chemoreceptor (Tar) is inserted directly into the polar membrane by using its fusion to green fluorescent protein (GFP). After induction of Tar–GFP, fluorescent spots first appeared in lateral membrane regions, and later cell poles became predominantly fluorescent. Unexpectedly, Tar–GFP showed a helical arrangement in lateral regions, which was more apparent when a Tar–GFP derivative with two cysteine residues in the periplasmic domain was cross-linked to form higher oligomers. Moreover, similar distribution was observed even when the cytoplasmic domain of the double cysteine Tar–GFP mutant was replaced by that of the kinase EnvZ, which does not localize to a pole. Observation of GFP–SecE and a translocation-defective MalE–GFP mutant, as well as indirect immunofluorescence microscopy on SecG, suggested that the general protein translocation machinery (Sec) itself is arranged into a helical array, with which Tar is transiently associated. The Sec coil appeared distinct from the MreB coil, an actin-like cytoskeleton. These findings will shed new light on the mechanisms underlying spatial organization of membrane proteins in E. coli. [ABSTRACT FROM AUTHOR]

Published

2006

30. Stabilization of Polar Localization of a Chemoreceptor via Its Covalent Modifications and Its Communication with a Different Chemoreceptor.

Author

Shiomi, Daisuke, Banno, Satomi, Homma, Michio, and Kawagishi, Ikuro

Subjects

*ESCHERICHIA coli, *GREEN fluorescent protein, *SENSORY receptors, *CHEMICAL senses, *FLUORESCENT polymers, *AMINO acids

Abstract

In the chemotaxis of Escherichia coli, polar clustering of the chemoreceptors, the histidine kinase CheA, and the adaptor protein CheW is thought to be involved in signal amplification and adaptation. However, the mechanism that leads to the polar localization of the receptor is still largely unknown. In this study, we examined the effect of receptor covalent modification on the polar localization of the aspartate chemoreceptor Tar fused to green fluorescent protein (GFP). Amidation (and presumably methylation) of Tar-GFP enhanced its own polar localization, although the effect was small. The slight but significant effect of amidation on receptor localization was reinforced by the fact that localization of a noncatalytic mutant version of GFP-CheR that targets to the C-terminal pentapeptide sequence of Tar was similarly facilitated by receptor amidation. Polar localization of the demethylated version of Tar-GFP was also enhanced by increasing levels of the serine chemoreceptor Tar. The effect of covalent modification on receptor localization by itself may be too small to account for chemotactic adaptation, but receptor modification is suggested to contribute to the molecular assembly of the chemoreceptor/histidine kinase array at a cell pole, presumably by stabilizing the receptor dimer-to-dimer interaction. [ABSTRACT FROM AUTHOR]

Published

2005

31. Interactions of MotX with MotY and with the PomA/PomB Sodium Ion Channel Complex of the Vibrio alginolyticus Polar Flagellum.

Author

Okabe, Mayuko, Yakushi, Toshiharu, and Homma, Michio

Subjects

*VIBRIO, *GRAM-negative bacteria, *FLAGELLA (Microbiology), *MOTILITY of microorganisms, *CELL membranes, *SODIUM ions, *BIOCHEMISTRY

Abstract

Rotation of the sodium ion-driven polar flagellum of Vibrio alginolyticus requires the inner membrane sodium ion channel complex PomA/PomB and the outer membrane components MotX and MotY. None of the detergents used in this study were able to solubilize MotX when it was expressed alone. However, when co-expressed with MotY, MotX was solubilized by some detergents. The change in the solubility of MotX suggests that MotY interacts with MotX. In agreement with this, a pull-down assay showed the association of MotY with MotX. Solubilized MotX and MotY eluted in the void volume from a gel-filtration column, suggesting that MotX and MotY form a large oligomeric structure(s). In the absence of MotY, MotX affected membrane localization of the PomA/PomB complex and of PomB alone but not of PomA alone, suggesting an interaction between MotX and PomB. We propose that MotX exhibits multiple interactions with the other motor components, first with MotY for its localization to the outer membrane and then with the PomA/PomB complex through PomB for the motor rotation. [ABSTRACT FROM AUTHOR]

Published

2005

32. Concerted Effects of Amino Acid Substitutions in Conserved Charged Residues and Other Residues and Other Residues in the Cytoplasmic Domain of PomA, a Stator Component...

Author

Fukuoka, Hajime, Yakushi, Toshiharu, and Homma, Michio

Subjects

*AMINO acids, *ESCHERICHIA coli, *FLAGELLARIACEAE, *CELL membranes, *PHENOTYPES, *VIBRIO

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 coil 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 (RSSA, 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 L132M 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 mm 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. [ABSTRACT FROM AUTHOR]

Published

2004

33. Interaction of PomB with the Third Transmembrane Segment of PomA in the Na+-Driven Polar Flagellum of Vibrio alginolyticus.

Author

Yakushi, Toshiharu, Maki, Shingo, and Homma, Michio

Subjects

*GENETIC mutation, *MEMBRANE proteins, *BIOMOLECULES, *PROTEINS, *TERATOGENESIS, *VIBRIO infections

Abstract

The marine bacterium Vibrio alginolyticus has four motor components, PomA, PomB, MotX, and MotY, responsible for its Na+-driven flagellar rotation. PomA and PomB are integral inner membrane proteins having four and one transmembrane segments (TMs), respectively, which are thought to form an ion channel complex. First, site-directed Cys mutagenesis was systematically performed from Asp-24 to Glu-41 of PomB, and the resulting mutant proteins were examined for susceptibility to a sulfhydryl reagent. Secondly, the Cys substitutions at the periplasmic boundaries of the PomB TM (Ser-38) and PomA TMs (Gly-23, Ser-34, Asp-170, and Ala-178) were combined. Cross-linked products were detected for the combination of PomB-S38C and PomA-D170C mutant proteins. The Cys substitutions in the periplasmic boundaries of PomA TM3 (from Met-169 to Asp-171) and the PomB TM (from Leu-37 to Ser-40) were combined to construct a series of double mutants. Most double mutations reduced the motility, whereas each single Cys substitution slightly affected it. Although the motility of the strain carrying PomA-D170C and PomB-S38C was significantly inhibited, it was recovered by reducing reagent. The strain with this combination showed a lower affinity for Na+ than the wild-type combination. PomA-D148C and PomB-P16C, which are located at the cytoplasmic boundaries of PomA TM3 and the PomB TM, also formed the cross-linked product. From these lines of evidence, we infer that TM3 of PomA and the TM of PomB are in close proximity over their entire length and that cooperation between these two TMs is required for coupling of Na+ conduction to flagellar rotation. [ABSTRACT FROM AUTHOR]

Published

2004

34. Targeting of the chemotaxis methylesterase/deamidase CheB to the polar receptor–kinase cluster in an Escherichia coli cell.

Author

Banno, Satomi, Shiomi, Daisuke, Homma, Michio, and Kawagishi, Ikuro

Subjects

*ESCHERICHIA coli, *CHEMOTAXIS, *ESTERASES, *METHYLATION, *ENTEROBACTERIACEAE, *CHEMORECEPTORS

Abstract

Chemotactic adaptation to persisting stimulation involves reversible methylation of the chemoreceptors that form complexes with the histidine kinase CheA at a cell pole. The methyltransferase CheR targets to the C-terminal NWETF sequence of the chemoreceptor. In contrast, localization of the methylesterase CheB is largely unknown, although regulation of its activity via phosphorylation is central to adaptation. In this study, green fluorescent protein was fused to full-length CheB or its various parts: the N-terminal regulatory domain (N), the C-terminal catalytic domain (C) and the linker (L). The full-length and NL fusions and, to a lesser extent, the LC fusion localized to a pole. Deletion of the P2 domain from CheA abolished polar localization of the full-length and NL fusions, but did not affect that of the LC fusion. Pull-down assays demonstrated that the NL fragment, but not the LC fragment, binds to the P2 fragment of CheA. These results indicate that binding of the NL domain to the P2 domain targets CheB to the polar signalling complex. The LC fusion, like the chemoreceptor, partially localized in the absence of CheA, suggesting that the LC domain may interact with its substrate sites, either as part of the protein or as a proteolytic fragment. [ABSTRACT FROM AUTHOR]

Published

2004

35. Isolation of Vibrio alginolyticus sodium-driven flagellar motor complex composed of PomA and PomB solubilized by sucrose monocaprate.

Author

Yakushi, Toshiharu, Kojima, Masaru, and Homma, Michio

Subjects

*BACTERIA, *SODIUM, *SUCROSE, *MEMBRANE proteins, *PLASMIDS, *IMIDAZOLES

Abstract

The polar flagella of Vibrio alginolyticus have sodium-driven motors, and four membrane proteins, PomA, PomB, MotX and MotY, are essential for torque generation of the motor. Poma and PomB are believed to form a sodium-conducting channel. This paper reports the purification of the motor complex by using sucrose monocaprate, a non-ionic detergent, to solubilize the complex. Plasmid pKJ301, which encodes intact PomA, and PomB tagged with a C-terminal hexahistidine that does not interfere with PomB function, was constructed. The membrane fraction of cells transformed with pKJ301 was solubilized with sucrose monocaprate, and the solubilized materials were applied to a Ni-NTA column. The imidazole eluate contained both Poma and PomB, which were further purified by anion-exchange chromatography. Gel-filtration chromatography was used to investigate the apparent molecular size of the complex; the PomA/PomB complex was eluted as approx. 900 kDa and PomB alone was eluted as approx. 260 kDa. These findings suggest that the motor complex may have a larger structure than previously assumed. [ABSTRACT FROM AUTHOR]

Published

2004

36. slight bending of an α-helix in FliM creates a counterclockwise-locked structure of the flagellar motor in Vibrio.

Author

Takekawa, Norihiro, Nishikino, Tatsuro, Yamashita, Toshiki, Hori, Kiyoshiro, Onoue, Yasuhiro, Ihara, Kunio, Kojima, Seiji, Homma, Michio, and Imada, Katsumi

Subjects

*VIBRIO alginolyticus, *VIBRIO, *STRUCTURAL models, *CRYSTAL structure, *MOLECULAR motor proteins, *CHEMOTAXIS

Abstract

Many bacteria swim by rotating flagella. The chemotaxis system controls the direction of flagellar rotation. Vibrio alginolyticus , which has a single polar flagellum, swims smoothly by rotating the flagellar motor counterclockwise (CCW) in response to attractants. In response to repellents, the motor frequently switches its rotational direction between CCW and clockwise (CW). We isolated a mutant strain that swims with a CW-locked rotation of the flagellum, which pulls rather than pushes the cell. This CW phenotype arises from a R49P substitution in FliM, which is the component in the C-ring of the motor that binds the chemotaxis signalling protein, phosphorylated CheY. However, this phenotype is independent of CheY, indicating that the mutation produces a CW conformation of the C-ring in the absence of CheY. The crystal structure of FliM with the R49P substitution showed a conformational change in the N-terminal α-helix of the middle domain of FliM (FliMM). This helix should mediates FliM–FliM interaction. The structural models of wild type and mutant C-ring showed that the relatively small conformational change in FliMM induces a drastic rearrangement of the conformation of the FliMM domain that generates a CW conformation of the C-ring. [ABSTRACT FROM AUTHOR]

Published

2021

37. Torque–speed Relationship of the Na+-driven Flagellar Motor of Vibrio alginolyticus

Author

Sowa, Yoshiyuki, Hotta, Hiroyuki, Homma, Michio, and Ishijima, Akihiko

Subjects

*PROTONS, *NANOSTRUCTURES

Abstract

The torque–speed relationship of the Na+-driven flagellar motor of Vibrio alginolyticus was investigated. The rotation rate of the motor was measured by following the position of a bead, attached to a flagellar filament, using optical nanometry. In the presence of 50 mM NaCl, the generated torque was relatively constant (∼3800 pN nm) at lower speeds (speeds up to ∼300 Hz) and then decreased steeply, similar to the H+-driven flagellar motor of Escherichia coli. When the external NaCl concentration was varied, the generated torque of the flagellar motor was changed over a wide range of speeds. This result could be reproduced using a simple kinetic model, which takes into consideration the association and dissociation of Na+ onto the motor. These results imply that for a complete understanding of the mechanism of flagellar rotation it is essential to consider both the electrochemical gradient and the absolute concentration of the coupling ion. [Copyright &y& Elsevier]

Published

2003

38. The aspartate chemoreceptor Tar is effectively methylated by binding to the methltransferase mainly through hydrophobic interaction.

Author

shiomi, Daisuke, Okumura, Hisashi, Homma, Michio, and Kawagishi, Ikuro

Subjects

*TAR, *MUTAGENESIS, *AMINO acid sequence

Abstract

Examines the systematic mutagenesis of the pentapeptide sequence of Tar. Effect of alanine substitution of residue on the receptor methylation and adaptation; Production of CheR; Importance of hydrophobicity and the size of the residues on the interaction with CheR.

Published

2000

39. Live‐cell fluorescence imaging reveals dynamic production and loss of bacterial flagella.

Author

Zhuang, Xiang‐Yu, Guo, Shihao, Li, Zhuoran, Zhao, Ziyi, Kojima, Seiji, Homma, Michio, Wang, Pengyuan, Lo, Chien‐Jung, and Bai, Fan

Subjects

*BACTERIAL flagella, *VIBRIO alginolyticus, *FLUORESCENCE, *PROTEIN structure, *CELL division, *MOTILITY of bacteria

Abstract

Bacterial flagella are nanomachines that drive bacteria motility and taxis in response to environmental changes. Whether flagella are permanent cell structures and, if not, the circumstances and timing of their production and loss during the bacterial life cycle remain poorly understood. Here we used the single polar flagellum of Vibrio alginolyticus as our model and implementing in vivo fluorescence imaging revealed that the percentage of flagellated bacteria (PFB) in a population varies substantially across different growth phases. In the early‐exponential phase, the PFB increases rapidly through the widespread production of flagella. In the mid‐exponential phase, the PFB peaks at around 76% and the partitioning of flagella between the daughter cells are 1:1 and strictly at the old poles. After entering the stationary phase, the PFB starts to decline, mainly because daughter cells stop making new flagella after cell division. Interestingly, we observed that bacteria can actively abandon flagella after prolonged stationary culturing, though cell division has long been suspended. Further experimental investigations confirmed that flagella were ejected in V. alginolyticus, starting from breakage in the rod. Our results highlight the dynamic production and loss of flagella during the bacterial life cycle. Importance: Flagella motility is critical for many bacterial species. The bacterial flagellum is made up of about 20 different types of proteins in its final structure and can be self‐assembled. The current understanding of the lifetime and durability of bacterial flagella is very limited. In the present study, we monitored Vibrio alginolyticus flagellar assembly and loss by in vivo fluorescence labeling, and found that the percentage of flagellated bacteria varies substantially across different growth phases. The production of flagella was synchronized with cell growth but stopped when cells entered the stationary phase. Surprisingly, we observed that bacteria can actively abandon flagella after prolonged stationary culturing, as well as in the low glucose buffering medium. We then confirmed the ejection of flagella in V. alginolyticus started with breakage of the rod. Our results highlight the dynamic production and loss of flagella during the bacterial life cycle. [ABSTRACT FROM AUTHOR]

Published

2020

40. Regulation of the Single Polar Flagellar Biogenesis.

Author

Kojima, Seiji, Terashima, Hiroyuki, and Homma, Michio

Subjects

*GUANOSINE triphosphate, *VIBRIO alginolyticus, *ORGANELLE formation, *MARINE bacteria, *GENERATING functions

Abstract

Some bacterial species, such as the marine bacterium Vibrio alginolyticus, have a single polar flagellum that allows it to swim in liquid environments. Two regulators, FlhF and FlhG, function antagonistically to generate only one flagellum at the cell pole. FlhF, a signal recognition particle (SRP)-type guanosine triphosphate (GTP)ase, works as a positive regulator for flagellar biogenesis and determines the location of flagellar assembly at the pole, whereas FlhG, a MinD-type ATPase, works as a negative regulator that inhibits flagellar formation. FlhF intrinsically localizes at the cell pole, and guanosine triphosphate (GTP) binding to FlhF is critical for its polar localization and flagellation. FlhG also localizes at the cell pole via the polar landmark protein HubP to directly inhibit FlhF function at the cell pole, and this localization depends on ATP binding to FlhG. However, the detailed regulatory mechanisms involved, played by FlhF and FlhG as the major factors, remain largely unknown. This article reviews recent studies that highlight the post-translational regulation mechanism that allows the synthesis of only a single flagellum at the cell pole. [ABSTRACT FROM AUTHOR]

Published

2020

41. Characterization of PomA periplasmic loop and sodium ion entering in stator complex of sodium-driven flagellar motor.

Author

Nishikino, Tatsuro, Iwatsuki, Hiroto, Mino, Taira, Kojima, Seiji, and Homma, Michio

Subjects

*SODIUM ions, *STATORS, *ION channels, *VIBRIO, *BIOTIN

Abstract

The bacterial flagellar motor is a rotary nanomachine driven by ion flow. The flagellar stator complex, which is composed of two proteins, PomA and PomB, performs energy transduction in marine Vibrio. PomA is a four transmembrane (TM) protein and the cytoplasmic region between TM2 and TM3 (loop2–3) interacts with the rotor protein FliG to generate torque. The periplasmic regions between TM1 and TM2 (loop1–2) and TM3 and TM4 (loop3–4) are candidates to be at the entrance to the transmembrane ion channel of the stator. In this study, we purified the stator complex with cysteine replacements in the periplasmic loops and assessed the reactivity of the protein with biotin maleimide (BM). BM easily modified Cys residues in loop3–4 but hardly labelled Cys residues in loop1–2. We could not purify the plug deletion stator (ΔL stator) composed of PomBΔ41–120 and WT-PomA but could do the ΔL stator with PomA-D31C of loop1–2 or with PomB-D24N of TM. When the ion channel is closed, PomA and PomB interact strongly. When the ion channel opens, PomA interacts less tightly with PomB. The plug and loop1–2 region regulate this activation of the stator, which depends on the binding of sodium ion to the D24 residue of PomB. [ABSTRACT FROM AUTHOR]

Published

2020

42. Characterization of the MinD/ParA‐type ATPase FlhG in Vibrio alginolyticus and implications for function of its monomeric form.

Author

Kojima, Seiji, Imura, Yoshino, Hirata, Hikaru, and Homma, Michio

Subjects

*VIBRIO alginolyticus, *ADENOSINE triphosphatase, *GEL permeation chromatography, *VIBRIO, *ADENOSINE triphosphate

Abstract

FlhG is a MinD/ParA‐type ATPase that works as a negative regulator for flagellar biogenesis. In Vibrio alginolyticus, FlhG functions antagonistically with the positive regulator FlhF to generate a single polar flagellum. Here, we examined the effects of ADP and ATP on the aggregation and dimerization of Vibrio FlhG. Purified FlhG aggregated after exposure to low NaCl conditions, and its aggregation was suppressed in the presence of ADP or ATP. FlhG mutants at putative ATP‐binding (K31A) or catalytic (D60A) residues showed similar aggregation profiles to the wild type, but ATP caused strong aggregation of the ATPase‐stimulated D171A mutant although ADP significantly suppressed the aggregation. Results of size exclusion chromatography of purified FlhG or Vibrio cell lysates suggested that FlhG exists as a monomer in solution, and ATP does not induce FlhG dimerization. The K31A and D60A mutants eluted at monomer fractions regardless of nucleotides, but ATP shifted the elution peak of the D171A mutant to slightly earlier, presumably because of a subtle conformational change. Our results suggest that monomeric FlhG can function in vivo, whose active conformation aggregates easily. [ABSTRACT FROM AUTHOR]

Published

2020

43. Tree of motility – A proposed history of motility systems in the tree of life.

Author

Miyata, Makoto, Robinson, Robert C., Uyeda, Taro Q. P., Fukumori, Yoshihiro, Fukushima, Shun‐ichi, Haruta, Shin, Homma, Michio, Inaba, Kazuo, Ito, Masahiro, Kaito, Chikara, Kato, Kentaro, Kenri, Tsuyoshi, Kinosita, Yoshiaki, Kojima, Seiji, Minamino, Tohru, Mori, Hiroyuki, Nakamura, Shuichi, Nakane, Daisuke, Nakayama, Koji, and Nishiyama, Masayoshi

Subjects

*MOLECULAR motor proteins, *BACTERIAL flagella, *MOLECULAR biology, *MOTILITY of bacteria, *MYOSIN, *EUKARYOTES, *TREES

Abstract

Motility often plays a decisive role in the survival of species. Five systems of motility have been studied in depth: those propelled by bacterial flagella, eukaryotic actin polymerization and the eukaryotic motor proteins myosin, kinesin and dynein. However, many organisms exhibit surprisingly diverse motilities, and advances in genomics, molecular biology and imaging have showed that those motilities have inherently independent mechanisms. This makes defining the breadth of motility nontrivial, because novel motilities may be driven by unknown mechanisms. Here, we classify the known motilities based on the unique classes of movement‐producing protein architectures. Based on this criterion, the current total of independent motility systems stands at 18 types. In this perspective, we discuss these modes of motility relative to the latest phylogenetic Tree of Life and propose a history of motility. During the ~4 billion years since the emergence of life, motility arose in Bacteria with flagella and pili, and in Archaea with archaella. Newer modes of motility became possible in Eukarya with changes to the cell envelope. Presence or absence of a peptidoglycan layer, the acquisition of robust membrane dynamics, the enlargement of cells and environmental opportunities likely provided the context for the (co)evolution of novel types of motility. [ABSTRACT FROM AUTHOR]

Published

2020

44. Effect of sodium ions on conformations of the cytoplasmic loop of the PomA stator protein of Vibrio alginolyticus.

Author

Mino, Taira, Nishikino, Tatsuro, Iwatsuki, Hiroto, Kojima, Seiji, and Homma, Michio

Subjects

*SODIUM ions, *VIBRIO alginolyticus, *STATORS, *BIOLOGICAL membranes, *SODIUM channels, *ION channels, *CYSTEINE

Abstract

The sodium driven flagellar stator of Vibrio alginolyticus is a hetero-hexamer membrane complex composed of PomA and PomB, and acts as a sodium ion channel. The conformational change in the cytoplasmic region of PomA for the flagellar torque generation, which interacts directly with a rotor protein, FliG, remains a mystery. In this study, we introduced cysteine mutations into cytoplasmic charged residues of PomA, which are highly conserved and interact with FliG, to detect the conformational change by the reactivity of biotin maleimide. In vivo labelling experiments of the PomA mutants revealed that the accessibility of biotin maleimide at position of E96 was reduced with sodium ions. Such a reduction was also seen in the D24N and the plug deletion mutants of PomB, and the phenomenon was independent in the presence of FliG. This sodium ions specific reduction was also detected in Escherichia coli that produced PomA and PomB from a plasmid, but not in the purified stator complex. These results demonstrated that sodium ions cause a conformational change around the E96 residue of loop2–3 in the biological membrane. [ABSTRACT FROM AUTHOR]

Published

2019

45. Structure of the periplasmic domain of SflA involved in spatial regulation of the flagellar biogenesis of Vibrio reveals a TPR/SLR-like fold.

Author

Sakuma, Mayuko, Nishikawa, Shoji, Inaba, Satoshi, Nishigaki, Takehiko, Kojima, Seiji, Homma, Michio, and Imada, Katsumi

Subjects

*VIBRIO alginolyticus, *VIBRIO, *ORGANELLE formation, *SPATIAL arrangement, *PROTEIN-protein interactions, *CHLAMYDOMONAS

Abstract

Bacteria have evolved various types of flagellum, an organella for bacterial motility, to adapt to their habitat environments. The number and the spatial arrangement of the flagellum are precisely controlled to optimize performance of each type of the flagellar system. Vibrio alginolyticus has a single sheathed flagellum at the cell pole for swimming. SflA is a regulator protein to prevent peritrichous formation of the sheathed flagellum, and consists of an N-terminal periplasmic region, a transmembrane helix, and a C-terminal cytoplasmic region. Whereas the cytoplasmic region has been characterized to be essential for inhibition of the peritrichous growth, the role of the N-terminal region is still unclear. We here determined the structure of the N-terminal periplasmic region of SflA (SflAN) at 1.9-Å resolution. The core of SflAN forms a domain-swapped dimer with tetratricopeptide repeat (TPR)/Sel1-like repeat (SLR) motif, which is often found in the domains responsible for protein–protein interaction in various proteins. The structural similarity and the following mutational analysis based on the structure suggest that SflA binds to unknown partner protein by SflAN and the binding signal is important for the precise control of the SflA function. [ABSTRACT FROM AUTHOR]

Published

2019

46. Effect of PlzD, a YcgR homologue of c-di-GMP-binding protein, on polar flagellar motility in Vibrio alginolyticus.

Author

Kojima, Seiji, Yoneda, Takuro, Morimoto, Wakako, and Homma, Michio

Subjects

*VIBRIO alginolyticus, *SUBCELLULAR fractionation, *ESCHERICHIA coli, *PROTEINS, *CHLAMYDOMONAS

Abstract

YcgR, a cyclic diguanylate (c-di-GMP)-binding protein expressed in Escherichia coli , brakes flagellar rotation by binding to the motor in a c-di-GMP dependent manner and has been implicated in triggering biofilm formation. Vibrio alginolyticus has a single polar flagellum and encodes YcgR homologue, PlzD. When PlzD or PlzD-GFP was highly over-produced in nutrient-poor condition, the polar flagellar motility of V. alginolyticus was reduced. This inhibitory effect is c-di-GMP independent as mutants substituting putative c-di-GMP-binding residues retain the effect. Moderate over-expression of PlzD-GFP allowed its localization at the flagellated cell pole. Truncation of the N-terminal 12 or 35 residues of PlzD abolished the inhibitory effect and polar localization, and no inhibitory effect was observed by deleting plzD or expressing an endogenous level of PlzD-GFP. Subcellular fractionation showed that PlzD, but not its N-terminally truncated variants, was precipitated when over-produced. Moreover, immunoblotting and N-terminal sequencing revealed that endogenous PlzD is synthesized from Met33. These results suggest that an N-terminal extension allows PlzD to localize at the cell pole but causes aggregation and leads to inhibition of motility. In V. alginolyticus , PlzD has a potential property to associate with the polar flagellar motor but this interaction is too weak to inhibit rotation. [ABSTRACT FROM AUTHOR]

Published

2019

47. Rotational direction of flagellar motor from the conformation of FliG middle domain in marine Vibrio.

Author

Nishikino, Tatsuro, Hijikata, Atsushi, Miyanoiri, Yohei, Onoue, Yasuhiro, Kojima, Seiji, Shirai, Tsuyoshi, and Homma, Michio

Published

2018

48. FliL association with flagellar stator in the sodium-driven Vibrio motor characterized by the fluorescent microscopy.

Author

Lin, Tsai-Shun, Zhu, Shiwei, Kojima, Seiji, Homma, Michio, and Lo, Chien-Jung

Abstract

Bacterial flagellar motor (BFM) is a protein complex used for bacterial motility and chemotaxis that involves in energy transformation, torque generation and switching. FliL is a single-transmembrane protein associated with flagellar motor function. We performed biochemical and biophysical approaches to investigate the functional roles of FliL associated with stator-units. Firstly, we found the periplasmic region of FliL is crucial for its polar localization. Also, the plug mutation in stator-unit affected the polar localization of FliL implying the activation of stator-unit is important for FliL recruitment. Secondly, we applied single-molecule fluorescent microscopy to study the role of FliL in stator-unit assembly. Using molecular counting by photobleaching, we found the stoichiometry of stator-unit and FliL protein would be 1:1 in a functional motor. Moreover, the turnover time of stator-units are slightly increased in the absence of FliL. By further investigation of protein dynamics on membrane, we found the diffusions of stator-units and FliL are independent. Surprisingly, the FliL diffusion rate without stator-units is unexpectedly slow indicating a protein-complex forming event. Our results suggest that FliL plays a supporting role to the stator in the BFM. [ABSTRACT FROM AUTHOR]

Published

2018

49. Localization and domain characterization of the SflA regulator of flagellar formation in Vibrio alginolyticus.

Author

Inaba, Satoshi, Nishigaki, Takehiko, Takekawa, Norihiro, Kojima, Seiji, and Homma, Michio

Subjects

*VIBRIO alginolyticus, *BACTERIAL flagella, *BACTERIAL genetics, *BACTERIA classification, *FLUORESCENT proteins

Abstract

Many swimming bacteria use flagella as locomotive organelles. The spatial and numerical regulation of flagellar biosynthesis differs by bacterial species. The marine bacteria Vibrio alginolyticus use a single polar flagellum whose number is regulated positively by FlhF and negatively by FlhG. Cells lacking FlhF and FlhG have no flagellum. The motility defect in an flh FG deletion was suppressed by a mutation in the sflA gene that resulted in the production of multiple, peritrichous flagella. SflA is a Vibrio-specific protein. SlfA either facilitates flagellum growth at the cell pole or prevents flagellar formation on the cell body by an unknown mechanism. Fluorescent protein fusions to SflA localized to the cell pole in the presence of FlhF and FlhG, but exhibited both polar and lateral cell localization in Δ flh FG cells. Polar localization of SflA required the polar landmark protein HubP. Over-expression of the C-terminal region of SflA (Sfl AC) in Δ flh FG Δ sflA cells suppressed the lateral flagellar formation. Our results suggest that SflA localizes with the flagella and that Sfl AC represses the flagellar initiation in Δ flh FG strains. A model is presented where SflA inhibits lateral flagellar formation to facilitate single polar flagellum assembly in V. alginolyticus cells. [ABSTRACT FROM AUTHOR]

Published

2017

50. Serine suppresses the motor function of a periplasmic PomB mutation in the Vibrio flagella stator.

Author

Nishikino, Tatsuro, Zhu, Shiwei, Takekawa, Norihiro, Kojima, Seiji, Onoue, Yasuhiro, and Homma, Michio

Subjects

*VIBRIO alginolyticus, *SERINE, *PROTEIN-protein interactions, *PROTEIN crosslinking, *CHEMOTAXIS, *THERAPEUTICS, *BACTERIA

Abstract

The flagellar motor of Vibrio alginolyticus is made of two parts: a stator consisting of proteins PomA and PomB, and a rotor whose main component is FliG. The interaction between FliG and PomA generates torque for flagellar rotation. Based on cross-linking experiments of double-Cys mutants of PomB, we previously proposed that a conformational change in the periplasmic region of PomB caused stator activation. Double-Cys mutants lost their motility due to an intramolecular disulfide bridge. In this study, we found that the addition of serine, a chemotactic attractant, to a PomB(L160C/I186C) mutant restored motility without cleaving the disulfide bridge. We speculate that serine changed the rotor (FliG) conformation, affecting rotational direction. Combined with the counterclockwise ( CCW)-biased mutation FliG(G214S), motility of PomB(L160C/I186C) was restored without the addition of serine. Likewise, motility was restored without serine in Che− mutants, in either a CCW-locked or clockwise ( CW)-locked strain. In contrast, in a Δ cheY ( CCW-locked) strain, Vibrio (L160C/I186C) required serine to be rescued. We speculate that CheY affects stator conformation and motility restoration by serine is independent on the chemotaxis signaling pathway. [ABSTRACT FROM AUTHOR]

Published

2016