Hajime Fukuoka scite author profile

Lactobacillus reuteri is a heterofermentative lactic acid bacterium that naturally inhabits the gut of humans and other animals. The probiotic effects of L. reuteri have been proposed to be largely associated with the production of the broad-spectrum antimicrobial compound reuterin during anaerobic metabolism of glycerol. We determined the complete genome sequences of the reuterin-producing L. reuteri JCM 1112T and its closely related species Lactobacillus fermentum IFO 3956. Both are in the same phylogenetic group within the genus Lactobacillus. Comparative genome analysis revealed that L. reuteri JCM 1112T has a unique cluster of 58 genes for the biosynthesis of reuterin and cobalamin (vitamin B12). The 58-gene cluster has a lower GC content and is apparently inserted into the conserved region, suggesting that the cluster represents a genomic island acquired from an anomalous source. Two-dimensional nuclear magnetic resonance (2D-NMR) with 13C3-glycerol demonstrated that L. reuteri JCM 1112T could convert glycerol to reuterin in vivo, substantiating the potential of L. reuteri JCM 1112T to produce reuterin in the intestine. Given that glycerol is shown to be naturally present in feces, the acquired ability to produce reuterin and cobalamin is an adaptive evolutionary response that likely contributes to the probiotic properties of L. reuteri.

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

Terashima

Fukuoka

Yakushi

et al. 2006

Molecular Microbiology

109

157

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Sodium‐dependent dynamic assembly of membrane complexes in sodium‐driven flagellar motors

Fukuoka

Wada

Kojima

et al. 2009

Molecular Microbiology

127

128

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SummaryThe 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 proteinfused 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.

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Coordinated Reversal of Flagellar Motors on a Single Escherichia coli Cell

Terasawa

Fukuoka

Inoue

et al. 2011

Biophysical Journal

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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.

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

et al. 2006

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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.

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Hajime Fukuoka

Comparative Genome Analysis of Lactobacillus reuteri and Lactobacillus fermentum Reveal a Genomic Island for Reuterin and Cobalamin Production

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

Sodium‐dependent dynamic assembly of membrane complexes in sodium‐driven flagellar motors

Coordinated Reversal of Flagellar Motors on a Single Escherichia coli Cell

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

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Hajime Fukuoka

Comparative Genome Analysis of Lactobacillus reuteri and Lactobacillus fermentum Reveal a Genomic Island for Reuterin and Cobalamin Production

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

Sodium‐dependent dynamic assembly of membrane complexes in sodium‐driven flagellar motors

Coordinated Reversal of Flagellar Motors on a Single Escherichia coli Cell

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

Contact Info

Product

Resources

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

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