Systematic Cys mutagenesis of FlgI, the flagellar P-ring component of Escherichia coli

doi:10.1099/mic.0.2007/013854-0

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Systematic Cys mutagenesis of FlgI, the flagellar P-ring component of Escherichia coli

Yohei Hizukuri, Seiji Kojima, Toshiharu Yakushi, Ikuro Kawagishi and Michio Homma

Division of Biological Science, Graduate School of Science, Nagoya University, Furo-Cho, Chikusa-Ku, Nagoya 464-8602, Japan

Correspondence
Michio Homma
g44416a{at}cc.nagoya-u.ac.jp

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

The bacterial flagellar motor is embedded in the cytoplasmicmembrane, and penetrates the peptidoglycan layer and the outermembrane. A ring structure of the basal body called the P ring,which is located in the peptidoglycan layer, is thought to berequired for smooth rotation and to function as a bushing. Inthis work, we characterized 32 cysteine-substituted Escherichiacoli P-ring protein FlgI variants which were designed to substituteevery 10th residue in the 346 aa mature form of FlgI. Immunoblotanalysis against FlgI protein revealed that the cellular amountsof five FlgI variants were significantly decreased. Swarm assaysshowed that almost all of the variants had nearly wild-typefunction, but five variants significantly reduced the motilityof the cells, and one of them in particular, FlgI G21C, completelydisrupted FlgI function. The five residues that impaired motilityof the cells were localized in the N terminus of FlgI. To demonstratewhich residue(s) of FlgI is exposed to solvent on the surfaceof the protein, we examined cysteine modification by using thethiol-specific reagent methoxypolyethylene glycol 5000 maleimide,and classified the FlgI Cys variants into three groups: well-,moderately and less-labelled. Interestingly, the well- and moderatelylabelled residues of FlgI never overlapped with the residuesknown to be important for protein amount or motility. From theseresults and multiple alignments of amino acid sequences of variousFlgI proteins, the highly conserved region in the N terminus,residues 1–120, of FlgI is speculated to play importantroles in the stabilization of FlgI structure and the formationof the P ring by interacting with FlgI molecules and/or otherflagellar components.

Abbreviations: mPEG-maleimide, methoxypolyethylene glycol 5000 maleimide

${dagger}$ Present address: Department of Bioscience and Biotechnology,Faculty of Agriculture, Shinshu University, 8304 Minamiminowa,Nagano 399-4598, Japan.

${ddagger}$ Present address: Department of Frontier Bioscience, Facultyof Engineering, Hosei University, 3-7-2 Kajino-Cho, Koganei,Tokyo 184-8584, Japan.

A supplementary figure showing multiple alignments of FlgI aminoacid sequences derived from various bacteria is available withthe online version of this paper.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Bacteria swim by the rotation of flagella in a screw-like manner.The flagellar motor is embedded in the cytoplasmic membraneand the rotational power generated by the motor is transmittedto the helical flagellar filament through the hook. The flagellarmotor, which is composed of numerous proteins, is divided intotwo parts, the rotor and the stator that surrounds the rotor.The rotor is mainly composed of the MS ring and the C ring,which is located on the cytoplasmic side of the MS ring. Thestator is composed of the MotA/MotB complex, which containsat least four molecules of MotA and two molecules of MotB (Kojima& Blair, 2004), and functions as a proton channel (Blair& Berg, 1990; Stolz & Berg, 1991). About 10 of thesestator units surround the rotor, and interactions between thestator and rotor are believed to generate the driving forcefor rotation (Reid et al., 2006). The MotA/MotB stators assemblearound the flagellar basal body, and the functional flagellarmotor is established. It is thought that the peptidoglycan bindingmotif of MotB is involved in the assembly. A recent study hasrevealed that in Escherichia coli, the stator complexes incorporatedinto the motor are exchanged frequently with the one that floatson the cytoplasmic membrane near the motor (Leake et al., 2006),suggesting that the interaction between the rotor and the statoris weak and/or temporary.

The P ring is one of the components of the basal body. In Gram-negativebacteria, it assembles around a proximal part of the basal body,and is thought to be attached to the peptidoglycan layer; itforms a stiff cylindrical structure to hold the central rodwith the L ring, which assembles at the LPS (outer membrane)layer (Akiba et al., 1991). The P ring is a part of the basalbody, but is believed to be a non-rotating component to holdthe rod as a bushing. The P ring is thought to consist of 26copies of a single protein, FlgI (Jones et al., 1990; Sosinskyet al., 1992), which is expressed as a precursor form with acleavable N-terminal 19 aa leader sequence, and exportedto the periplasmic space via the Sec apparatus (Homma et al.,1987; Jones et al., 1989), where it assembles into the P ringsurrounding the rod (Kubori et al., 1992). The flagellar structureis constructed by a highly ordered process. First the MS ringis assembled at the cytoplasmic membrane as a base plate, thenthe C ring, the transport apparatus and the rod structure areassembled in turn. Next, the P- and L-ring structures are assembledaround the rod, followed by the hook and the filament. Disruptionof any flagellar component causes the assembly of flagellarstructure to arrest; a disruption in FlgI causes a motilitydefect because the flagellar construction terminates at therod structure. Recently, we revealed that the intramoleculardisulfide bond formation in FlgI is not necessary for P-ringassembly but is important to protect against degradation ofthe protein (Hizukuri et al., 2006).

Various interactions have been speculated for the P-ring proteinFlgI in the flagellar basal body (Fig. 1). To expand ourknowledge of the P-ring structure and to understand the spatialarrangement around the rod in the periplasmic space, we constructedand characterized a series of systematically Cys-substitutedE. coli FlgI variants. Among 32 FlgI Cys variants constructed,the protein amounts of five FlgI variants were significantlydecreased, and cells carrying five of the variants showed reducedmotility. We further characterized the variants using a thiol-specificreagent to investigate which residue of the protein was exposedto solvent on the protein surface. Interestingly, this workshowed that the residues of FlgI that can be labelled neveroverlap with the residues found to be important for proteinstability or motility.

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Fig. 1. Information about the P-ring protein FlgI; possible interactions between the P-ring protein FlgI and other components. In the left-hand image, cylindrically averaged flagellar structure reported by DeRosier (1998)

is outlined. The estimated P-ring region is shaded. The drawing of the FlgI monomer displayed in the right-hand box is an estimated shape. PG, peptidoglycan.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Bacterial strains, growth conditions, and media.
The E. coli strains used in this work are listed in Table 1

.To delete the cat gene cassette of the ${Delta}$ flgI : : cat strain YZ1(Hizukuri et al., 2006

), we used the method described by Datsenko& Wanner (2000)

, and the constructed strain was named YZ11.The ${Delta}$ motAB : : cat strain YS5 was kindly provided by YoshiyukiSowa (Oxford University). To construct a ${Delta}$ flgI ${Delta}$ motAB : : cattriple deletion strain, the ${Delta}$ motAB : : cat region of YS5 wastransferred into strain YZ11 by using P1 phage (Silhavy et al.,1984

), and the resultant strain was named YZ12-1. E. coli cellswere cultured at 37 °C in LB medium (1 % Bacto tryptone,0.5 % yeast extract, 0.5 % NaCl) or at 30 °C in TGmedium (1 % Bacto tryptone, 0.5 % NaCl, 0.5 %, w/v, glycerol).When necessary, ampicillin and kanamycin were added to a finalconcentration of 50 µg ml^–1.

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Table 1. Strains and plasmids

Construction of plasmids.
Routine DNA manipulations were carried out according to standardprocedures (Sambrook et al., 1989

). The plasmids used in thiswork are listed in Table 1

. To construct the pYZ301 plasmid,a 1.4 kb KpnI–SphI fragment containing the E. coliflgI gene was cut out of pYZ201 (Hizukuri et al., 2006

) andinserted into the corresponding sites of the vector pSU38. Toobtain a series of plasmids expressing FlgI Cys variants, weperformed site-directed mutagenesis on pYZ301 by which a fulllength of plasmid DNA was amplified by PfuUltra High-FidelityDNA Polymerase (Stratagene) using a pair of complementary primerscarrying a mutagenized codon, and was then digested by DpnI.To construct the pJN726 plasmid, a 2.4 kb SalI–SalIfragment containing the motAB genes was cut out of pYA6022 (Asaiet al., 2003

) and inserted into the vector pBAD24.

Motility assays.
Swarming motility was assayed as follows. Overnight culture(2 µl) (grown on LB medium at 37 °C) wasdropped on a soft agar T broth plate (1 % Bacto tryptone, 0.5% NaCl, 0.27 % Bacto agar) containing 50 µg ml^–1each of ampicillin and kanamycin and 0.04 % L-arabinose. Ifnecessary, 5 mM DTT was added to agar plates. The plateswere incubated at 30 °C for the time indicated foreach experiment. Relative swarm size of the FlgI Cys mutantwas calculated by normalizing to the diameter of the swarm ringof the wild-type FlgI-expressing cells after subtracting thediameter of the swarm ring of the vector-containing cells.

Detection of FlgI.
Immunoblot analysis using anti-E. coli FlgI antibodies (FlgI346)was performed as described previously (Hizukuri et al., 2006).

Cysteine modification by methoxypolyethylene glycol 5000 maleimide (mPEG-maleimide).
An overnight culture (grown on LB medium at 37 °C)was inoculated at a 50-fold dilution into TG medium containing50 µg ml^–1 ampicillin and kanamycin and0.04 % L-arabinose, and cultured at 30 °C. At the exponentialgrowth phase, 300 µl of cultured cells (OD₆₆₀=1.0)was harvested by centrifugation (9500 g, 5 min). Thecells were suspended in 1 ml Wash Buffer (10 mM potassiumphosphate buffer, pH 7.0, containing 0.1 mM EDTA-K),centrifuged again and resuspended in 25 µl MLM Buffer(Wash Buffer containing 10 mM DL-lactate/KOH and 0.1 mML-methionine). The thiol-specific reagent mPEG-maleimide (Fluka)was suspended in DMSO as a 40 mM stock solution and storedat –20 °C in the dark. Twenty-five microlitresof mPEG-maleimide reaction buffer (MLM Buffer containing 4 mMmPEG-maleimide, prepared freshly before each experiment) wasadded to cell suspensions and mixed well, then incubated withshaking at 37 °C for 30 min. To terminate thereaction, 5 µl β-mercaptoethanol was added andthen 5 µl 10 % SDS. The sample solution was boiledat 100 °C for 5 min and mixed with 15 µl5x SDS loading buffer containing β-mercaptoethanol. Analiquot of 5 µl was used for SDS-PAGE.

RESULTS

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Protein amounts and cross-linked products of FlgI Cys variants
We constructed the E. coli ${Delta}$ flgI ${Delta}$ motAB : : cat triple deletionstrain YZ12-1. The constructed strain showed no motility ineither liquid or soft agar medium, and no flagella were observedby electron microscopy (data not shown). When transformed withtwo plasmids, one harbouring the flgI gene and the other themotAB genes, YZ12-1 cell motility was almost the same as thatof wild-type cells in liquid medium (data not shown). Hereafter,we refer to this complemented strain as the wild-type FlgI-expressingstrain. In the future we plan to investigate the interactionbetween the P ring and the MotA/MotB stator complex; however,we focused our current investigation on the P-ring structureand its function.

We systematically constructed a series of FlgI Cys variants.We designed cysteine substitutions every 10th residue in themature form of FlgI (the numbers correspond to the positionsof the amino acid residues in the mature form of FlgI). Twoadditional mutants were also designed in which Ile³ and Ile³⁴⁶were substituted with cysteine (Fig. 6). FlgI protein hastwo native cysteine residues, at positions 254 and 338, andthey remained intact in our Cys-substituted variants. From the37 candidates designed, we obtained 32 FlgI Cys variants, butwere unable to generate D41C, Q61C, A131C, Q221C or L261C. Weexamined the protein amounts of the FlgI Cys variants by immunoblotanalysis using anti-FlgI antibodies (Fig. 2). Most of theFlgI variants showed slightly decreased amounts of product comparedto wild-type FlgI. However, the protein amounts of five variants,I3C, D111C, I181C, G241C and L251C, were significantly decreasedcompared to the other variants (Fig. 2, β-ME +, filledtriangles). We have reported that FlgI C254A, FlgI C338A andthe double mutant seem to be more susceptible to degradation(Hizukuri et al., 2006), so we speculate that FlgI Gly²⁴¹ andLeu²⁵¹ (which is located near Cys²⁵⁴) affect the susceptibilityof the protein to degradation when replaced with Cys. In FlgIE1C, an additional band that was larger (by $~$ 2 kDa) thanthe estimated monomer band was detected. The larger proteinmay be a precursor form (38 kDa) of the mature form ofFlgI (36 kDa) because replacement of the residue next toa signal cleavage site probably affects the cleavage efficiency.In the absence of the reductant β-mercaptoethanol, disulfidecross-linked products were detected in most of the FlgI Cysvariants (Fig. 2, β-ME -). The apparent molecularmasses of the cross-linked products showed a wave-like patternwith a peak at residues $~$ 160–190. The variants with Cysreplacements at the N- or C-terminal regions had the approximateestimated size of dimers (72 kDa). On the other hand, replacementsnear the central region caused decreased mobility of the bands,probably because the cross-linked dimers at the middle positionsformed aberrant shapes. It is worth noting that FlgI Y191C showeda large number of cross-linked products, whereas FlgI N171Cand FlgI A321C showed almost no cross-linked products.

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Fig. 6. Profiles of the FlgI Cys mutants. The grey bar at the N terminus indicates the leader peptide, which is cleaved when the protein is exported to the periplasm. The white vertical bands indicate the residues substituted with Cys in this study, while the grey vertical bands indicate the substitutions that we were unable to generate. C²⁵⁴ and C³³⁸ are shown above to indicate the positions of the native cysteine residues in FlgI. Profiles are shown under the name of each variant: Amount, the residues for which the protein amount was decreased when substituted with Cys; Motility, the residues that caused decreased ( $bullet$ ) or completely disrupted ( ${circ}$ ) motility of the cells; Modified, the residues that were well- ( ${square}$ ) or moderately ( ${blacksquare}$ ) labelled by mPEG-maleimide. The residues well- or moderately labelled by mPEG-maleimide (rectangles) never overlap with the residues that affect their protein amount (triangles) or the motility of cells (circles).

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Fig. 2. Detection of products of systematically substituted FlgI Cys variants. The FlgI proteins from YZ12-1 ( ${Delta}$ flgI ${Delta}$ motAB : : cat) cells harbouring pJN726 (MotAB) and pYZ301 (wt FlgI), pSU38 (vec.) or the pYZ301 derivatives containing a series of FlgI Cys variants were detected by immunoblotting using anti-FlgI antibodies. Upper panel, without β-mercaptoethanol (β-ME -); lower panel, with β-mercaptoethanol (β-ME +). The arrowheads on the right-hand side indicate the monomer of the mature form of FlgI (36 kDa). Filled triangles below the lower panel indicate the FlgI Cys variants for which the amount of protein was significantly lower than that of the wild-type.

Effects of the FlgI Cys variants on motility
Defects in FlgI cause a failure of P-ring assembly and resultin the termination of flagellar formation after rod construction.To assess the effects of the Cys replacements in FlgI on P-ringassembly, we first examined swarming ability in soft agar plates.We measured swarm ring sizes after sufficient incubation andcalculated the relative swarm rates for each FlgI Cys mutantagainst that of wild-type FlgI (Fig. 3

). Most of the FlgICys mutants retained swarming ability, but five mutants, FlgII3C, G21C, G51C, G81C and D111C, had significantly decreasedswarm rates (see also Fig. 4a

, upper panel). When we observedswimming ability in liquid medium using dark-field microscopy,cells carrying each of these five mutations except G21C weremotile, although the fractions of motile cells were extremelylow (<5 %); cells carrying the G21C mutation completely lostswimming ability. When we observed the cells by electron microscopy,the mutant cells expressing FlgI G21C were shown to be completelynon-flagellate (data not shown), implying that the Gly²¹ residueof FlgI is critical for P-ring assembly.

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Fig. 3. Motility of the FlgI Cys variant-expressing cells. The relative swarm size is shown of YZ12-1 ( ${Delta}$ flgI ${Delta}$ motAB : : cat) cells harbouring pJN726 (MotAB) and pYZ301 (wt FlgI), pSU38 (vec.) or pYZ301 derivatives containing a series of FlgI Cys variants. A drop (2 µl) of overnight culture was inoculated on 0.27 % soft agar T broth plates, which were incubated at 30 °C for an appropriate period of time. The swarm assays were repeated three times independently and the relative swarm sizes calculated in each experiment were averaged. $bullet$ , Weakly motile mutant; ${circ}$ , non-motile mutant.

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Fig. 4. Effect of DTT on motility of the FlgI Cys mutants. (a) Swarms of YZ12-1 ( ${Delta}$ flgI ${Delta}$ motAB : : cat) cells harbouring pJN726 (MotAB) and pYZ301 (wt FlgI), pSU38 (vec.) or pYZ301 derivatives containing the FlgI Cys variants I3C, G21C, G51C, G81C and D111C. A drop (2 µl) of overnight culture was inoculated on 0.27 % soft agar T broth plates without (upper panel) or with (lower panel) 5 mM DTT and plates were incubated at 30 °C for 8 h. (b) Relative swarm sizes from (a). Grey bars, without DTT; black bars, with 5 mM DTT. The swarm size of cells producing wild-type FlgI was used for normalization of the mutants under the equivalent conditions.

We investigated the effects of reducing agents such as DTT onthe motility of the weakly motile mutants FlgI I3C, G51C, G81Cand D11C, and the non-motile mutant G21C (Fig. 4

). In theabsence of DTT, these five mutants showed poor or no motility,as described above. On the other hand, when 5 mM DTT wasadded to the motility agar, the swarm ring size of the wild-typecells was slightly decreased, but the four weakly motile mutantshad significantly restored swarming abilities. The non-motilemutant G21C remained completely non-motile. These results suggestthat the motility defects of the four weakly motile mutantswere caused by the formation of an incorrect disulfide bondby the replacement Cys either within FlgI itself or with anotherCys-containing protein(s).

Thiol modification of the FlgI Cys variants by mPEG-maleimide
To obtain structural information about FlgI, we examined thecysteine modification of the FlgI Cys variants using mPEG-maleimide,which is a membrane-impermeable thiol-specific reagent thatcarries an attached polyethylene glycol and has a high molecularmass of $~$ 5000 Da (Akiyama et al., 2004). We detected thereaction by mobility shifts of the bands on SDS-PAGE gels (Fig. 5a).The band of wild-type FlgI did not shift in mobility, suggestingthat the two native Cys residues of FlgI were not accessed bymPEG-maleimide, probably because they formed an intramoleculardisulfide bond. On the other hand, some of the FlgI Cys variantsshowed $~$ 5 kDa shift of the monomer band (36 kDa), indicatingthat the additional Cys residue was accessible to mPEG-maleimide,which means that the additional Cys residues are likely to beexposed to solvent on the surface of the protein. To analyseaccessibility further, we quantified the labelling efficienciesof each FlgI Cys variant, which are given relative to the totalamount of FlgI present (Fig. 5b). Based on this analysis,we could classify these variants into three groups: the highlabelling efficiency group (>30 %, open rectangles), FlgIG11C, G161C, Y191C and S211C; the moderate labelling efficiencygroup (>15 %, closed rectangles), FlgI D31C, T71C, T101C,N121C, Q301C, N311C and Q331C; and the low labelling efficiencyand non-labelling group (<15 %), which contains the othermutants.

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Fig. 5. Cysteine modification of the FlgI Cys variants by mPEG-maleimide. (a) mPEG-maleimide-labelled FlgI proteins derived from YZ12-1 ( ${Delta}$ flgI ${Delta}$ motAB : : cat) cells harbouring pJN726 (MotAB) and pYZ301 (wt FlgI), pSU38 (vec.) or pYZ301 derivatives containing the FlgI Cys variants were detected by immunoblotting using anti-FlgI antibodies. For the mPEG-maleimide modification, cultures in the exponential growth phase were harvested, washed and incubated with 2 mM mPEG-maleimide at 37 °C for 30 min. After terminating the reaction, the samples were mixed with SDS loading buffer containing β-mercaptoethanol. The arrowhead on the right-hand side indicates the mature form of the FlgI monomer (36 kDa) and the asterisk indicates mPEG-maleimide-labelled FlgI, as judged by the $~$ 5 kDa shift of the monomer band. (b) mPEG-maleimide labelling efficiency was obtained by dividing the intensity of the shifted band by the total band intensity of FlgI. ${blacksquare}$ , Well-labelled (>30 % labelling efficiency); ${square}$ , moderately labelled (>15 % labelling efficiency).

Alignment of the amino acid sequences of the P-ring protein FlgI from various species
The replaced residues that impaired cell motility in this workwere localized around the N terminus of FlgI (Ile³, Gly²¹, Gly⁵¹,Gly⁸¹ and Asp¹¹¹; Fig. 3

). To assess the importance ofthe N terminus of FlgI, we aligned the amino acid sequencesof FlgI obtained from various flagellated bacteria (SupplementaryFig. S1). Multiple alignments revealed that the amino acid sequencesof FlgI were well conserved among various bacteria, except theN-terminal leader sequence, and in particular, the sequencesof the N-terminal region of FlgI (Arg²–Asp³¹ and Lys⁶³–Gly¹²⁰)were extremely well conserved. Replacement of Gly²¹ with Cys,which is in the most highly conserved region, caused the mostsevere phenotype, non-motility. The five residues whose mutationimpaired cell motility were all positioned around this N-terminalhighly conserved region. From this alignment analysis and ourexperimental results, the N-terminal highly conserved regionof FlgI is suggested to play important roles in various functions,such as maintenance of the structure of FlgI and formation ofan interface with other flagellar proteins or with itself.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

In this study, we characterized a series of FlgI Cys-substitutedmutants with respect to protein amount, motility of the cells,and modification by a thiol-specific reagent. The results ofthis work are summarized in Fig. 6. Among the mutations,the well- or moderately labelled residues (rectangles) neveroverlapped with the residues that affected their protein amount(triangles) or the motility of cells (circles). This may suggestthat the important residues for protein folding or P-ring assemblyare not exposed to solvent on the surface of the protein. Thisseems to be reasonable, because residues important for proteinfolding or assembly are likely to be located inside the protein(i.e. forming the core) or at the protein–protein interface.FlgI is secreted to the periplasmic space and then assembledaround the rod of the flagellar basal body to form the P-ringstructure. FlgI interacts with other FlgI molecules to formthe P ring, with the L-ring protein that is located above theP ring, with rod proteins, with peptidoglycan (PG), and possiblywith the MotA/B stator complex or other components in the periplasmicspace. Speculative interactions of FlgI are illustrated in Fig. 1.FlgI is predicted to form strong interactions with FlgI itselfor FlgH, the L-ring protein. In Salmonella enterica serovarTyphimurium, the P and L rings form an extremely stiff cylindricalstructure. Only the L–P ring complex remains after 7.5 Murea treatment, during which all of the other flagellar componentsdissociate (Akiba et al., 1991). Based on this evidence, ithas been inferred that the interactions of FlgI–FlgI andFlgI–FlgH are probably very strong.

FlgI may also interact with FlgG, a distal rod protein. In theprocess of P-ring assembly, secreted FlgI is predicted to recognizethe rod structure in the periplasm and associate with the rod.The rod is a part of the rotor structure, but the P ring isbelieved to be a part of the stator that supports the rod asa bushing and allows the rotor to run smoothly. Therefore, ithas been predicted that the FlgI–FlgG interaction is temporaryand/or very weak. The P ring is located in the peptidoglycanlayer (and so is named the P ring), and it may interact withthe peptidoglycan layer. Considering the role of the P ring,it is very likely that the P ring is fixed in the peptidoglycanlayer to stabilize rotation of the motor.

The highly conserved region in the N terminus, residues 1–120,of FlgI is suggested to play an important role, such as in stabilizingthe structure of FlgI or forming an interface with other FlgIproteins or other flagellar components, i.e. FlgH. The roleof the conserved region is not known, but it may be importantto maintain FlgI structure, because there are many Gly and Proresidues in this region. The G161C variant was the most accessibleto the cysteine modification reagent. When the hook basal bodies(HBBs) isolated from cells expressing FlgI G161C were treatedwith mPEG-maleimide, FlgI was labelled and showed band shifting(data not shown). In addition, FlgI Y191C showed numerous cross-linkedproducts compared to other variants (Fig. 2). These resultsmay suggest that the central region of FlgI is exposed to theouter surface of the P ring. In our previous work, we reportedthat the replacement of the native Cys residues of FlgI (Cys²⁵⁴and/or Cys³³⁸) with Ala has little effect on motility but resultsin a significantly decreased amount of protein (Hizukuri etal., 2006). We concluded that the intramolecular disulfide bondformed between Cys²⁵⁴ and Cys³³⁸ is required to prevent thedegradation of protein. Here, we showed that the amount of FlgIprotein is decreased for FlgI G241C or L251C, but is not changedin FlgI Q331C or A341C. The FlgI C254A mutation has a more severeeffect on both flagellar motility and protein amount than theFlgI C338A mutation (Hizukuri et al., 2006). These results maysuggest that the amino acids around Cys²⁵⁴ are more importantfor protein folding or protection against degradation than thosearound Cys³³⁸.

Recently, a novel structure, named the T ring, was discoveredin the flagellar basal body of Vibrio alginolyticus (Terashimaet al., 2006). The T ring is located on the periplasmic sideof the P ring and is composed of MotX and MotY, which are essentialproteins for motor function. The T ring is proposed to interactwith the PomA/PomB stator complex, which is homologous to theMotA/MotB complex, by the interaction between MotX and PomB.The T ring has an important role in the incorporation and stabilizationof the stator (Okabe et al., 2005; Terashima et al., 2006).E. coli and Salmonella species do not have a T ring or proteinhomologues of MotX or MotY. We think that the P ring of E. colimight have a similar role to that of the T ring for incorporationor stabilization of the MotA/MotB stator in the motor. The C-terminalpeptidoglycan binding (PGB) motif of MotB is believed to anchorto the peptidoglycan layer via the central flexible linker regionof MotB and to stabilize the stator complex during rotation.The P ring is also located in the peptidoglycan layer; thus,the stator complex may be associated with the P ring via thePGB motif of MotB when it assembles and functions around themotor. In future studies, we will assess the possible interactionsbetween the P ring and MotB.

ACKNOWLEDGEMENTS

We thank Yoshinori Akiyama and Kayo Koide for invaluable adviceabout the cysteine modification experiment. This work was supportedin part by grants-in-aid for scientific research from the Ministryof Education, Science, and Culture of Japan (to M. H., S. K,I. K and T. Y.), the Japan Science and Technology Corporation(to M. H. and T. Y.), the Soft Nano-Machine Project of the JapanScience and Technology Agency (to T. Y. and M. H.), and theJapan Society for the Promotion of Science (to Y. H.).

Edited by: J. G. Shaw

REFERENCES

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

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Received 8 October 2007; revised 24 November 2007; accepted 26 November 2007.

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