Biophysical characterization of the C-terminal region of FliG, an essential rotor component of the Na+-driven flagellar motor. Gohara, M., Kobayashi, S., Abe-Yoshizumi, R., Nonoyama, N., Kojima, S., Asami, Y., & Homma, M. Journal of Biochemistry, 155(2):83--89, February, 2014.
doi  abstract   bibtex   
The bacterial flagellar motor generates a rotational force by the flow of ions through the membrane. The rotational force is generated by the interaction between the cytoplasmic regions of the rotor and the stator. FliG is directly involved in the torque generation of the rotor protein by its interaction. FliG is composed of three domains: the N-terminal, Middle and C-terminal domains, based on its structure. The C-terminal domain of FliG is assumed to be important for the interaction with the stator that generates torque. In this study, using CD spectra, gel filtration chromatography and DSC (differential scanning calorimetry), we characterized the physical properties of the C-terminal domain (G214-Stop) of wild-type (WT) FliG and its non-motile phenotype mutant derivatives (L259Q, L270R and L271P), which were derived from the sodium-driven motor of Vibrio. The CD spectra and gel filtration chromatography revealed a slight difference between the WT and the mutant FliG proteins, but the DSC results suggested a large difference in their stabilities. That structural difference was confirmed by differences in protease sensitivity. Based on these results, we conclude that mutations which confer the non-motile phenotype destabilize the C-terminal domain of FliG.
@article{gohara_biophysical_2014,
	title = {Biophysical characterization of the {C}-terminal region of {FliG}, an essential rotor component of the {Na}+-driven flagellar motor},
	volume = {155},
	issn = {1756-2651},
	doi = {10.1093/jb/mvt100},
	abstract = {The bacterial flagellar motor generates a rotational force by the flow of ions through the membrane. The rotational force is generated by the interaction between the cytoplasmic regions of the rotor and the stator. FliG is directly involved in the torque generation of the rotor protein by its interaction. FliG is composed of three domains: the N-terminal, Middle and C-terminal domains, based on its structure. The C-terminal domain of FliG is assumed to be important for the interaction with the stator that generates torque. In this study, using CD spectra, gel filtration chromatography and DSC (differential scanning calorimetry), we characterized the physical properties of the C-terminal domain (G214-Stop) of wild-type (WT) FliG and its non-motile phenotype mutant derivatives (L259Q, L270R and L271P), which were derived from the sodium-driven motor of Vibrio. The CD spectra and gel filtration chromatography revealed a slight difference between the WT and the mutant FliG proteins, but the DSC results suggested a large difference in their stabilities. That structural difference was confirmed by differences in protease sensitivity. Based on these results, we conclude that mutations which confer the non-motile phenotype destabilize the C-terminal domain of FliG.},
	language = {eng},
	number = {2},
	journal = {Journal of Biochemistry},
	author = {Gohara, Mizuki and Kobayashi, Shiori and Abe-Yoshizumi, Rei and Nonoyama, Natsumi and Kojima, Seiji and Asami, Yasuo and Homma, Michio},
	month = feb,
	year = {2014},
	pmid = {24174548},
	keywords = {Amino Acid Sequence, Bacterial Proteins, Blotting, Western, Circular Dichroism, Electrophoresis, Polyacrylamide Gel, Flagella, Models, Molecular, Vibrio},
	pages = {83--89}
}
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