Deletion of the min Operon Results in Increased Thermosensitivity of an ftsZ84 Mutant and Abnormal FtsZ Ring Assembly, Placement, and Disassembly

doi:10.1128/JB.182.21.6203-6213.2000

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Journal of Bacteriology, November 2000, p. 6203-6213, Vol. 182, No. 21
0021-9193/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Deletion of the min Operon Results in Increased Thermosensitivity of an ftsZ84 Mutant and Abnormal FtsZ Ring Assembly, Placement, and Disassembly

Xuan-Chuan Yu and William Margolin^*

Department of Microbiology and Molecular Genetics, University of Texas-Houston Medical School, Houston, Texas 77030

Received 22 May 2000/Accepted 28 July 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

To investigate the interaction between FtsZ and the Min system during cell division of Escherichia coli, we examined the effectsof combining a well-known thermosensitive mutation of ftsZ, ftsZ84,with $Delta$ minCDE, a deletion of the entire min locus. Because theMin system is thought to down-regulate Z-ring assembly, the predictionwas that removing minCDE might at least partially suppress thethermosensitivity of ftsZ84, which can form colonies below 42°Cbut not at or above 42°C. Contrary to expectations, the doublemutant was significantly more thermosensitive than the ftsZ84single mutant. When shifted to the new lower nonpermissive temperature,the double mutant formed long filaments mostly devoid of Z rings,suggesting a likely cause of the increased thermosensitivity.Interestingly, even at 22°C, many Z rings were missing in thedouble mutant, and the rings that were present were predominantlyat the cell poles. Of these, a large number were present onlyat one pole. These cells exhibited a higher than expected incidenceof polar divisions, with a bias toward the newest pole. Moreover,some cells exhibited dramatically elongated septa that stainedfor FtsZ, suggesting that the double mutant is defective in Z-ringdisassembly, and providing a possible mechanism for the polarbias. Thermoresistant suppressors of the double mutant arose thathad modestly increased levels of FtsZ84. These cells also exhibitedelongated septa and, in addition, produced a high frequency ofbranched cells. A thermoresistant suppressor of the ftsZ84 singlemutant also synthesized more FtsZ84 and produced branched cells.The evidence from this study indicates that removing the Min systemexposes and exacerbates the inherent defects of the FtsZ84 protein,resulting in clear septation phenotypes even at low growth temperatures.Increasing levels of FtsZ84 can suppress some, but not all, ofthesephenotypes.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Bacteria such as Escherichia coli normally divide by binary fission, producing two daughter cells of equal size, each containinga nucleoid. The division process starts with the localizationof FtsZ to the center of the mother cell and formation of a septalring structure, the Z ring. Other essential cell division proteinsare then recruited to the Z ring, and the ring contracts as theingrowing septum invaginates. Once the septum is fully formed,the Z ring disappears and the daughter cells separate. Littleis known about what regulates Z-ring assembly, contraction, anddisassembly.

FtsZ is essential for cell division and viability. Deletion or mutation of the ftsZ gene blocks cell division at an earlystage, causing the formation of long filamentous cells with multiplenucleoids. The thermosensitive ftsZ84 mutant grows normally at28°C but becomes filamentous at higher temperatures and failsto form colonies at 42°C. This mutant has been particularly well-studiedbecause it encodes a protein with an amino acid change in a domainimplicated in GTP binding. This domain is highly conserved amongFtsZ proteins throughout prokaryotes and organelles and is alsoconserved among eukaryotic tubulins (19, 23). As expected,purified FtsZ84 protein has reduced GTP binding, hydrolysis, andpolymerization activity (8, 30). The lethal phenotype ofthe ftsZ84 mutant at 42°C can be suppressed by (i) complementationby the wild-type FtsZ, indicating that the mutation is recessive;(ii) increasing levels of FtsZ84 itself, by expressing it ectopicallyor by increasing the NaCl concentration, which appears to increasetranscription of the ftsZ gene via ppGpp effects (24, 25);and (iii) moderate overexpression of another essential cell divisionprotein, ZipA, which appears to stabilize FtsZ polymers in vivoand in vitro (29). These results indicate that lower temperatures,increased concentrations of the defective FtsZ84 protein itself,or increased concentrations of ZipA are sufficient to overcomethe GTP binding defect, allowing a functional Z ring topolymerize.

The Min system is an important regulator of FtsZ assembly and Z-ring positioning in E. coli. Encoded by a three-gene operon,MinC and MinD together act as an FtsZ inhibitor, while MinE actsto suppress MinCD-mediated inhibition only at the central divisionsite (9, 10) MinE therefore confers topological specificityupon the MinCD inhibitor. Deletion of minCD or overexpressionof minE leads to polar division and produces anucleate minicells,while moderate overexpression of minCD, high-level overexpressionof minC, or deletion of minE inhibits cell division at all potentialsites and results in filament formation (7, 9, 10). Recentresults have shed new light on how the Min system might regulateZ-ring positioning. First, MinE forms a ring near midcell independentof FtsZ (26); this could explain how MinE can counteract theMinCD inhibitor at the division site, allowing the medial Z ringto form. Second, when the Min system is eliminated by deletion,seemingly random clusters of Z rings form in all nucleoid-freeregions of the cell but rarely on top of nucleoids, suggestingthat (i) the nucleoid inhibits ring formation and (ii) MinCD normallyinhibits ring formation throughout the cell except where the inhibitionhas been suppressed by MinE (41). Third, MinD and MinC oscillaterapidly together between the two cell poles, consistent with theidea that MinCD inhibits FtsZ throughout the cell (13, 27,28). The isolation of an FtsZ allele which resists MinCD inhibitionsuggests that FtsZ is the direct target of MinCD inhibition (5),although no interaction between FtsZ and MinC or MinD has beendetected in yeast two-hybrid assays (15). Recently, high levelsof purified MinC were shown to inhibit FtsZ polymerization invitro (14), suggesting that a direct interaction between MinCand FtsZ occurs in the cell. In vivo, MinCD-mediated inhibitioncan be overcome by a severalfold increase in the levels of FtsZand another key cell division protein, FtsA, which leads to polardivision and minicell production (4, 38). This Min phenocopy is presumably caused by titration of the MinCD inhibitorby the higher levels of FtsZ and FtsA. Despite these advances,it is not yet clear how MinC inhibits polymerization, nor howMinD helps MinC inhibit Z rings invivo.

To understand more about how the Min proteins and FtsZ interact, we chose to investigate how the activity of the defectiveFtsZ84 protein might be affected by removing the Min system. Thepromiscuity of Z-ring formation in $Delta$ minCDE mutants and the abilityof MinC to inhibit FtsZ polymer assembly suggested that FtsZ84might be more active in the absence of the Min proteins. In thispaper, we describe the phenotype of an ftsZ84 $Delta$ minCDE double mutantand report several unexpected findings. Instead of suppressingthe thermosensitivity of the ftsZ84 mutant, deletion of the Minsystem made the thermosensitive phenotype more severe. This phenotypecorrelated with a scarcity of Z rings and could be suppressedby higher levels of FtsZ84. Interestingly, FtsZ84 rings appearedto have a novel defect in disassembly and were strongly biasedtoward polar localization at the permissive temperature. A modelto explain these findings ispresented.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Bacterial strains and growth media. All strains were derivatives of the wild-type E. coli strain MG1655. TX3772 is an MG1655 derivative that contains $Delta$ lacU169(37). LB (Luria-Bertani) medium (31) containing 0.5% NaClwas used for most experiments. In cases where more stringent conditionsfor ftsZ84 were desired, LBNS (LB with no added NaCl) medium wasused. Minimal glucose medium for TX3772 derivatives containedM9 salts supplemented with 0.2% glucose (31).

Construction of mutant strains. To construct the $Delta$ minCDE ftsZ84 double mutant in the wild-type MG1655 background, an ftsZ84 allele linked to a leu::Tn10 markerfrom EC488 (39) was first transduced into the MG1655 derivativeTX3772 at 32°C with phage P1. Tet^r transductants were screened for thermosensitivity at 42°C, andone such transductant was purified and designated WM1109. To removethe Tet^r marker in order to facilitate future strain constructions, WM1109was transduced to leucine prototrophy by selection for colonygrowth on minimal glucose, and leu⁺ Tet^s transductants were then screened for thermosensitivity. One purifiedtransductant, WM1125, exhibited a phenotype typical of an ftsZ84mutant, growing normally at 32°C but forming filaments at 42°C.The presence of the ftsZ84 allele in WM1125 was further confirmedby PCR sequence analysis. The $Delta$ minCDE ftsZ84 double mutant wasthen constructed by transducing a $Delta$ minB::kan allele from PB114in which the entire minCDE operon was deleted and replaced witha Kan^r cassette (10) into strain WM1125 to make WM1147. WM947 is aderivative of MG1655 that also contains the same $Delta$ minB::kan marker(41).

Thermoresistant suppressors were isolated from WM1125 and WM1147 by selecting for colonies on LB plates at 42 and 37°C, respectively,and were named WM1175 and WM1151,respectively.

Indirect immunofluorescence staining. Cell fixation, immunofluorescence staining, staining of nucleoids with DAPI (4',6-diamidino-2-phenylindole), phase-contrastmicroscopy, and fluorescence microscopy were performed as describedpreviously (36, 42). Secondary antibodies conjugated to thegreen fluorophore Alexa 488 were obtained from Molecular Probes(Eugene, Oreg.). Images were captured with a DEI-750 RGB colorvideo camera and framegrabber (Optronics Engineering, Goleta,Calif.) and manipulated with Adobe Photoshop. As previously described,the blue and red channels of the RGB output from the camera wereswapped in order to have the blue DAPI stain appear red for greatercontrast. For time-lapse growth of cells on agar-coated microscopeslides, cells were treated essentially as described previously(35).

Quantitation of FtsZ protein levels. The level of FtsZ in different strains under different conditions was measured by immunoblotting. First, cells were grownin LB medium at different temperatures and harvested by centrifugation.Cell pellets were resuspended in 100 to 200 µl of 0.5% sodiumdodecyl sulfate (SDS) and incubated at 100°C for 10 min. Ten microlitersof this sample was diluted into 200 µl of distilled H₂O, and thetotal protein concentration of the cell lysate was measured bythe bicinchoninic acid assay (32) using bovine serum albumin(BSA) as a standard. SDS was added to the BSA standard to ensureall samples contained the same concentration of SDS. The proteinsin the samples were then separated by SDS-polyacrylamide gel electrophoresis,transferred to nitrocellulose membranes, and probed with affinity-purifiedpolyclonal anti-FtsZ antibody at a 1:2,000 dilution. Blots werethen incubated with goat anti-rabbit secondary antibody conjugatedto peroxidase (Sigma Chemical Co., St. Louis, Mo.), and antibodybinding was detected by chemiluminescence. The resulting bandson X-ray films were scanned, and their intensities were quantitatedwith NIH Image 1.60.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Synthetic thermosensitive phenotype of a $Delta$ minCDE ftsZ84 double mutant. To test the hypothesis that a min deletion might partially suppress the thermosensitive phenotype of an ftsZ84 mutant, a $Delta$ minCDEftsZ84 double mutant was constructed by sequential P1 transduction(WM1147). We examined the ability of WM1147 to form colonies atdifferent temperatures on LB agar. Surprisingly, this strain wassignificantly more thermosensitive than WM1125, its min⁺ ftsZ84 parent. WM1125 could form colonies at all temperaturestested below 42°C, although at 37°C the colonies contained a mixtureof filaments and short cells (Table 1). In contrast, WM1147 couldform colonies only at 22°C and 28 but not at 32°C or above (Table1 and data not shown). Expression of wild-type FtsZ from a plasmidin WM1147 allowed growth at all temperatures (data not shown),indicating that no additional mutations other than ftsZ84 and $Delta$ minCDE were responsible for the synthetic phenotype. These resultssuggest that removal of the MinCD division inhibitor, along withthe topological specificity factor MinE, further exacerbates theftsZ84 defects. This is contrary to the predicted suppressionof ftsZ84 by removal of the MinCD inhibitor.

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TABLE 1. Ability of ftsZ84, $Delta$ minCDE, and $Delta$ minCDE ftsZ84 double mutant strains to form colonies on LB agar at different growth temperatures

Many Z rings are missing in the $Delta$ minCDE ftsZ84 double mutant. Why would deleting minCDE make the ftsZ84 mutant more thermosensitive? One hypothesis is that the removal of MinCD inhibitionalso uncovers more sites at which FtsZ protein can localize, whichmight reduce the protein concentration at the normal potentialdivision site. The increase in such sites in $Delta$ minCDE cells doesnot prevent wild-type FtsZ from promiscuously forming clustersof Z rings at most of these sites (41). However, the low GTP-bindingactivity of FtsZ84 should result in a higher critical concentrationfor assembly. If a critical local protein concentration is necessaryfor multimerization and nucleation of the Z ring, the availabilityof more potential sites might dilute the FtsZ84 protein to a pointwhere little nucleation could occur. This should be manifestedby a scarcity of Z rings, even in nucleoid-free regions normallyable to support promiscuous ring formation by the wild-typeprotein.

To test this hypothesis, we examined FtsZ localization in the double mutant strain WM1147 by immunofluorescence microscopy(IFM) and compared this localization to that in the single mutants.In the min⁺ ftsZ84 mutant (WM1125), FtsZ84 formed a central ring in mostcells grown at the permissive temperature, in this case 22°C (Fig.1A to C). In the ftsZ⁺ $Delta$ minCDE mutant, Z rings were present in all nucleoid-free regionsof the cell including the poles (Fig. 1D to F), as observed previously(41). However, in the $Delta$ minCDE ftsZ84 double mutant, Z ringswere notably absent at many potential division sites between nucleoids(Fig. 1G to I). This occurred even at 22°C, a permissive temperaturefor colony formation.

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FIG. 1. Localization of FtsZ in ftsZ84, $Delta$ minCDE, and $Delta$ minCDE ftsZ84 mutants. Cells were grown by shaking in LB broth at 22°C to mid-exponential phase (optical density at 600 nm of approximately 0.2). Ten microliters of cells was loaded onto a 12-mm coverslip precoated with polylysine, fixed, and incubated with affinity-purified rabbit polyclonal anti-FtsZ antibody (1:500 dilution). The samples were subsequently incubated with Alexa 488-conjugated goat anti-rabbit secondary antibody (green) and 1 µg of DAPI per ml (pseudocolored red). (A to C) Strain WM1125 (ftsZ84); (D to F) strain WM947 ( $Delta$ minCDE); (G to I) strain WM1147 ( $Delta$ minCDE ftsZ84). (A, D, and G): FtsZ staining; (B, E, and H): DAPI staining; (C, F, and I): overlay of FtsZ and DAPI images. White arrows in panels G to I highlight apparent gaps between nucleoids; black arrows highlight polar FtsZ rings.

We next investigated the effects of raising the temperature to the nonpermissive range. Although the WM1147 double mutantcould not form colonies on LB agar at 37°C, it could be grownin LB broth at 37°C after prior growth at 22°C. At least 90% ofthe long filaments generated after several generations at 37°Cwere devoid of Z rings, as detected by IFM. However, a minorityof filaments contained clear Z rings and often had multiple ringsper filament. It is not clear if the latter class of filamentsrepresents an adaptation/suppression phenomenon (see below) orif some filaments were somehow better predisposed to form ringsprior to the temperatureinduction.

In the few WM1147 filaments containing Z rings, we measured the overall cell length per ring to be 22.8 µm. This compareswith average lengths per ring in the ftsZ84 mutant, wild-type,and $Delta$ minCDE mutant of 6.8, 3.1, and 1.8 µm, respectively, at 37°C.The higher frequency of Z rings per cell length in a $Delta$ minCDE mutantrelative to the wild type has been described previously (41).The data indicate that the ring density drops significantly inthe ftsZ84 mutant grown at 37°C and becomes much lower in the $Delta$ minCDE ftsZ84 double mutant WM1147. It should be emphasized thatthe 22.8-µm cell length per ring pertains to the 10% of WM1147cells with rings; the estimated cell length per ring in the overallWM1147 population grown at at 37°C is at least 100 µm.

FtsZ84 protein levels in the double mutant. To rule out the possibility that the decreased number of Z rings in the double mutant was caused by a significant decreasein FtsZ levels, we measured the total levels of FtsZ in the wildtype and single and double mutants by immunoblotting. As shownin Fig. 2A, at 37°C, the level of FtsZ in the ftsZ84 mutant WM1125and the double mutant WM1147 is about 70% of that in wild-typecells, while the level of FtsZ in the min mutant WM947 is essentiallythe same as in the wild type. This indicates that the FtsZ84 proteinmay be itself somewhat thermolabile in vivo, which might contributeto the increased thermosensitivity of strains containing the ftsZ84allele. At 22°C, on the other hand, the levels of FtsZ in theabove mutants are between 90 and 100% of the wild-type values.Because FtsZ84 levels in the min⁺ and $Delta$ minCDE mutants are essentially the same at both 22 and 37°C,it is unlikely that the increased thermosensitivity and drasticallylower ring frequency in the $Delta$ minCDE mutant results from differencesin FtsZ levels. Instead, we favor the idea that the absence ofmin exposes existing defects of FtsZ84, as discussed below.

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FIG. 2. FtsZ protein levels in the wild-type, ftsZ84, $Delta$ minCDE, $Delta$ minCDE ftsZ84, and $Delta$ minCDE ftsZ84 thermoresistant suppressor strains at different temperatures. Quantitation of FtsZ by immunoblotting with anti-FtsZ antibody was performed as described in Materials and Methods. The FtsZ level in wild-type (TX3772) cells was arbitrarily assigned a value of 100% (y axis). All values are the averages from three independent experiments. (A) Comparison of FtsZ levels in the different mutants at 22 and 37°C; (B) comparison at 28 and 42°C.

Preferential polar localization and activity of Z rings in the $Delta$ minCDE ftsZ84 double mutant. In short cells with newly segregated nucleoids, the absence of the Min system should result in three possible regions in whichZ rings can form: the two polar sites and the midcell (nonpolar)site. Assuming that rings can form at these sites with equal probability,the theoretical ratio of polar to nonpolar (internal) Z ringsin short $Delta$ minCDE cells should be 2:1 (35). However, in reality,many $Delta$ minCDE cells are multinucleate filaments because polar divisionsoccur at the expense of midcell divisions. Therefore, the ratioof polar to nonpolar rings is often less than 1:1 (41). Thedeficiency of Z rings in the $Delta$ minCDE ftsZ84 double mutant resultsin filaments that are significantly longer than those in a $Delta$ minCDEftsZ⁺ mutant. As a result, the expected polar/nonpolar ratio shouldbe lower still, given the large number of potential division sitespredicted to exist within the long filaments compared to the fixednumber of two polarsites.

After characterizing the positioning of the Z rings in the double mutant at the permissive temperature of 22°C, we were surprisedto find that the few Z rings that were present were localizedpredominantly at the cell poles (within 1 µm of the pole). In111 cells examined, 93 cells contained one or two polar Z ringseach, and the total number of polar rings was calculated to be111. However, only 23 of these 111 cells had one or two nonpolarrings, with a total number of 24 nonpolar rings (see Fig. 1G toI and Table 2). This resulted in a strikingly high polar/nonpolarring ratio of 4.58. In contrast, in the single $Delta$ minCDE mutantgrown at 22°C, we counted 110 rings in a typical cell sample;of these, 70 were nonpolar and 40 were polar, giving a polar/nonpolarring ratio of 0.57 (Table 2). Polar rings were never observedin the single ftsZ84 mutant at the permissive temperature. Theseresults indicate that the polar bias of Z-ring localization inthe $Delta$ minCDE ftsZ84 double mutant was significantly greater thanthat in the single $Delta$ minCDE mutant and must therefore be favoredin some way by the presence of the ftsZ84 mutation.

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TABLE 2. Polar Z-ring positioning bias in different mutants

To test whether the polar rings in the double mutant were active in cell division, we monitored cells growing on a thin layerof LB agar on glass slides at 22°C by phase-contrast microscopy.One example of several such experiments is shown in Fig. 3. Growthand division of two short filaments were followed over a courseof 225 min. During this time, we could clearly observe seven polardivision events (see arrows) but only one nonpolar division event(see arrow in the 66-min panel). As a result, three short filamentsand seven minicells were formed over the 225-min time frame. Thisresult and others from similar experiments (data not shown) areconsistent with the IFM evidence for preferential localizationof Z rings at the cell poles in the double mutant and stronglysuggest that these polar Z rings are functional for division.

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FIG. 3. Time-lapse monitoring of the polar bias of cell division during growth of individual $Delta$ minCDE ftsZ84 cells on agar. Strain WM1147 ( $Delta$ minCDE ftsZ84) was grown at 22°C to an optical density at 600 nm of 0.1 to 0.2. Then 5 µl of the cell culture was loaded onto a thin layer of LB agar on a glass slide and grown for several hours at approximately 22°C under a cover glass for time-lapse photomicrography. A 100× oil immersion phase-contrast objective was used to capture the images of the cells at the times indicated (in minutes). Each arrow highlights a division event. The arrow in the 66-min panel highlights initiation of a nonpolar septum. The other seven arrows highlight polar division events leading to the formation of minicells.

Consecutive division events at the new pole. In addition to the polar preference for division events, the time-lapse data in Fig. 3 reveal that the polar divisions appearto occur sequentially at one pole, suggesting that one pole ismore active than the other for cell division. For example, threeminicells each were produced from one pole of the two originalfilaments in Fig. 3, while the other poles remained quiescentover the period of the experiment. The seventh minicell becamevisible at the 198- and 225-min time points (see middle arrowin 198-min panel), and this minicell was formed near the polemost recently formed by the nonpolar division of thefilament.

One explanation for this result is that in the double mutant, poles generated by the most recent cell division events (newpoles) are the most active for Z-ring assembly and cell division,whereas potential division sites at nonpolar sites and old polesare much less active. If this hypothesis is correct, then nonpolarsites should be no more active than sites at old poles and Z ringsshould form at nonpolar sites and at old poles with equal probability.Because the long filaments of the double mutant contain many morepotential division sites between nucleoids than polar sites, itfollows that cells containing two polar rings should occur muchless frequently than cells with one polar ring or with nonpolarrings. Data from additional time-lapse experiments strongly supportedthis idea. Of a total of 36 cell division events that could beunambiguously attributed to a new or old pole based on prior division,3 occurred at an old pole, 26 occurred at a new pole, and 7 werenonpolar. This high percentage of division events at new polessuggests that new poles are by far the most active regions forcell division in the doublemutant.

Further examination of the polar ring distribution indicated that among the 111 cells counted previously, 72 cells containedone polar ring, 21 cells contained two polar rings, and 23 cellshad one or more nonpolar rings. The number of cells with two polarrings is clearly lower than that with just one polar ring, whichis consistent with our hypothesis. However, the number of cellswith nonpolar rings is surprisingly low given the number of nonpolarpotential division sites expected within these filaments. A closerexamination of nucleoid staining in the double mutant (Fig. 1Gto I) indicates that many nucleoids are not properly segregatedat the permissive temperature for colony formation by the ftsZ84mutant. Such segregation problems have been noted previously inmin mutants (2, 21) and in ftsZ mutants (16, 34). Ourrecently proposed integrated model for positioning of cell divisionsites (41) predicts that the presence of large unpartitionedchromosomes within the double mutant filaments might prevent Z-ringformation by nucleoid occlusion effects, except at nucleoid-freeareas at the cell poles. This would result in a bias towards formationof rings at polar sites. As can be seen in Fig. 1G to I, the cellpoles in these mutants are often nucleoid-free and such regionscontain Zrings.

It should be emphasized, however, that many nucleoids are well-segregated in cells of the double mutant (Fig. 1H and I, arrows).The resulting nucleoid-free spaces remain mostly devoid of Z rings(Fig. 1G to I, arrows, and data not shown), indicating that segregationproblems cannot be the sole cause of the polar bias of Z-ringpositioning. Furthermore, large nucleoid-free areas are presentat both poles in many of these filaments, which is a typical Min phenotype (2, 41), yet the majority of these cells havea single Z ring at only one pole (see also Fig. 1G to I). Thissuggests that the bias towards localization at a single pole isnot because nucleoids block the other pole. This evidence supportsour idea that rings have a preference for one pole, probably thenew pole, in these shortfilaments.

Elongated septa and persistence of FtsZ84 at newly formed poles. We have presented evidence for preferential Z-ring assembly at new poles over other potential division sites in the $Delta$ minCDEftsZ84 double mutant. Wild-type FtsZ does not have any obviouspolar preference in a $Delta$ minCDE mutant (Fig. 1D to F); instead,Z rings are formed at all nucleoid-free gaps (41). Therefore,we hypothesize that the polar bias in the double mutant stemsfrom defects inherent in the FtsZ84 protein. The major known defectsof FtsZ84 are its much lower GTP binding and hydrolysis activitiesas compared to the wild-type protein. The GTP binding defect correlateswith lower activity in self-assembly (29), and it is likelythat the GTPase defect inhibits polymer turnover, which is dependenton GTP hydrolysis (20). Because ftsZ84 mutants survive at temperaturesbelow 42°C, these defects obviously do not compromise the abilityof FtsZ84 to divide cells at these temperatures in the presenceof the Min system. As we have shown, the absence of the Min systemenhances the defective effects of the FtsZ84 protein. The mostobvious effects are the reduced ability to form stable Z ringsat a given temperature, probably as a result of the low GTP bindingactivity of FtsZ84. However, the other predicted defect in polymerturnover, caused by reduced GTP hydrolysis, might be manifestedin vivo by a delay in the constriction and/or disassembly of existingrings.

To address this possibility, we examined cells of the double mutant for evidence of defective septum disassembly. In manycases, we found that the septum was dramatically elongated whenthe two daughter cells were at the last stage of separation (Fig.4A to C). In this strain (data not shown) and a derivative ofthis strain (Fig. 4D to O, see below), the FtsZ septal ring structureoften appeared to be duplicated, with foci at each newly formeddaughter cell pole (arrows). This phenomenon is never observedin cells containing wild-type FtsZ, presumably because wild-typeZ rings have normal GTPase activity and can disassemble rapidlyupon septation (35). In a min⁺ ftsZ84 strain, rings also appear to disassemble rapidly uponthermoinduction (1), and we have only rarely observed the elongatedseptum phenotype in this strain background (data not shown). Weconclude that the absence of the Min system exacerbates both theassembly defect of FtsZ84 and the apparent disassembly defectof FtsZ84 as evidenced by these unusually persistent septal structures.

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FIG. 4. Persistence of FtsZ staining at elongated septa in the $Delta$ minCDE ftsZ84 double mutant and its thermoresistant derivative. Cells were treated as described in the legend to Fig. 1. (A to C) Strain WM1147 grown at 22°C; (D to O) strain WM1151 grown at 37°C. Three images were taken of each field of cells: FtsZ, FtsZ plus DAPI overlay, and DAPI only. These appear as the top, middle, and bottom images within each set of three. Panels A to C and J to L each show a filament with an elongated central septum with FtsZ staining (arrows). Panels D to F, G to I, and M to O show cases of apparent bisection of FtsZ staining by an elongated septum to yield two separate FtsZ foci at the newly formed poles (arrows).

Suppression of the thermosensitivity of the $Delta$ minCDE ftsZ84 double mutant by increased FtsZ84 levels. When cells of strain WM1147 were plated on LB agar and grown at the nonpermissive temperatures of 37°C or higher, survivingcolonies arose at frequencies as high as 10⁴. To investigate the mechanism behind this suppression, we characterizedone thermoresistant strain (WM1151). Although this strain formedcolonies at 37°C on LB agar, it grew very poorly at 42°C on LBagar. Like its parent WM1147, WM1151 did not form colonies onLBNS agar plates at 37°C, which is a more stringent test of thermosensitivityof the ftsZ84 mutation than growth on LB agar because the lackof NaCl causes reduced expression of ftsZ (25). Both of theseresults indicated that the thermoresistant phenotype was not aresult of a simple reversion of the original point mutation inftsZ84 back to the wildtype.

To determine if the thermoresistance of WM1151 correlated with an increase in Z-ring frequency, we examined Z rings in cellsgrown at 37°C by IFM. As shown in Fig. 4D to O, most cells containedpolar and nonpolar rings. The frequency of Z rings, while stillbelow wild-type levels, was much higher than that in WM1147 atthis temperature, with an average cell length per ring of 5.7µm. Of 117 rings counted, 46 (39%) were nonpolar, which is approximatelytwice the frequency of nonpolar rings in WM1147 grown at its permissivetemperature of 22°C (Table 2). Nevertheless, the ratio of polarto nonpolar rings is still significantly higher than that in the $Delta$ minCDE single mutant. These results indicate that WM1151 hasproperties midway between the single mutants and the WM1147 doublemutantparent.

We next determined, by immunoblotting, whether the increased frequency of Z rings in WM1151 correlated with increased levelsof FtsZ. As shown in Fig. 2A, FtsZ levels in WM1151 were 40 to50% higher than in wild-type cells and about twofold higher thanin the WM1147 double mutant or the ftsZ84 single mutant (WM1125)at 37°C, the nonpermissive temperature for the double mutant.The high frequency of thermoresistant suppressors, combined withthe higher FtsZ levels in the suppressor strain WM1151, suggestthat these modestly increased levels of FtsZ84 may be sufficientto promote assembly of more nonpolar rings and to suppress thethermosensitivity of the $Delta$ minCDE ftsZ84 doublemutant.

Abnormal septal morphology and cellular branching in the strain with higher FtsZ84 levels. Despite the higher Z-ring frequency in WM1151 relative to the double mutant parent, WM1147, WM1151 cells, like those of WM1147,often contained Z rings that appeared to be defective in disassembly.FtsZ staining was often found in dramatically elongated septa(Fig. 4G to L, arrows). As in WM1147, the FtsZ staining patternwas often bisected. This resulted in the appearance of two clearFtsZ foci, one at each of the two new poles that were juxtaposed(Fig. 4E, H, and K, arrows). The morphology of these foci suggestedthat they were no longer Z rings, but rather more amorphous aggregatesofFtsZ.

When grown at 37°C for more than 5 h, strain WM1151 routinely produced branched cells at a high frequency (Fig. 5A to C).The frequency ranged from 2 to 10%, depending on the temperatureand how long the cells were cultured. It was previously reportedthat min mutants can form branched cells at similarly high frequencies,but branching depended on specific strain backgrounds and specializeddefined slow-growth media (3). In the case described herein,branching occurs in an otherwise wild-type strain background instandard rich LB medium.

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FIG. 5. Branched cells and abnormal septal morphology in the thermoresistant derivatives of ftsZ84 or the $Delta$ minCDE ftsZ84 double mutant. Strains WM1151 (thermoresistant $Delta$ minCDE ftsZ84) (A to C) and WM1175 (thermoresistant ftsZ84) (D to F) were grown at 37 and 42°C, respectively, for 5 h to mid-exponential phase. Cells were then fixed and stained with anti-FtsZ/Alexa 488 to visualize Z rings (B and E) and DAPI to visualize nucleoids (C and F) as described in the legend to Fig. 1. Phase-contrast images of the fixed cells are shown in panels A and D. To visualize asymmetric constriction in live cells of a thermoresistant ftsZ84 mutant, strain WM1175 was grown in LB broth at 42°C for 6 h, and 5 µl of culture was loaded onto a glass slide and covered with a cover glass. (G and H) Phase-contrast images were taken at 1/60 sec with a video camera. Unseparated cells and filaments moving and tumbling together were easily distinguished from separated cells.

To examine whether branching of WM1151 cells was dependent on the $Delta$ minCDE mutation, the ftsZ84 mutation, or the increasedlevels of FtsZ84 protein, we decided to go back and isolate thermoresistantsuppressors of an ftsZ84 single mutant to determine if they alsogenerated large numbers of branched cells. Such suppressors aroseat high frequency at 42°C, similar to those of WM1147, and onewas chosen and designated strain WM1175. This thermoresistantstrain formed colonies at 42°C on LB agar but did not form colonieson LBNS, consistent with it not being a reversion of the originalftsZ84 mutant. Sequence analysis confirmed that the original ftsZ84mutation but no other mutations were present within the ftsZ gene.When grown at 42°C for more than 5 h, many cells of WM1175 formedbranches and exhibited elongated septa similar to those producedby strain WM1151 grown at 37°C. Examples of such cells are shownin Fig. 5D to F. In addition, WM1175 often formed abnormal, asymmetricsepta that appeared to be precursors of branches (Fig. 5G andH). Z-ring placement appeared between segregated nucleoids inthe branched cells and did not correlate with any particular locationwith respect to the branch points (Fig. 5B to C and E to F anddata notshown).

These results suggest that altered expression of the ftsZ84 allele is necessary to promote high-frequency branching in anotherwise wild-type strain and that the $Delta$ minCDE deletion is notnecessary for this effect. It follows that the modest increasein FtsZ84 levels in WM1151 may be the major factor responsiblefor branching. To test this idea, we investigated whether thethermoresistant suppressor in WM1175 also correlated with increasedlevels of FtsZ84 protein. Quantitative immunoblot analysis (Fig.2B) indeed showed that at 42°C, the level of FtsZ84 in WM1175was about 20% higher than the normal level of FtsZ in wild-typecells and almost twofold higher than the level of FtsZ84 in WM1125(ftsZ84) cells. The FtsZ levels in WM1175 at 28°C were equivalentto the levels at 42°C, suggesting that the increase in FtsZ expressionis constitutive. These results suggest that thermoresistant suppressionof the ftsZ84 single mutant, as with the $Delta$ minCDE ftsZ84 doublemutant, is caused by a modest increase in FtsZ84 levels and thatsuch an increase in the defective protein results in the formationof branches in a large number of cells. Increases of wild-typeFtsZ of this magnitude have not been reported to yield branchedcells.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

We have shown that removing the Min system increases the thermosensitivity of an ftsZ84 mutant, which encodes a defectiveFtsZ with lower GTP binding and hydrolysis activities. This syntheticeffect was unexpected, because Z rings form highly efficientlyin a $Delta$ minCDE strain and it was predicted that in the absence ofthe MinCD inhibitor, FtsZ84 might be able to nucleate Z ringsat a lower critical concentration. However, deleting minCDE appearsto have the opposite effect. While the single ftsZ84 mutant formscolonies on LB agar at all temperatures below 42°C, the $Delta$ minCDEftsZ84 double mutant cannot form colonies at or above 32°C. Cellsof the double mutant, even at 22°C, are filamentous and containnumerous potential division sites, defined as nucleoid-free gaps,with no Zrings.

Why is FtsZ84 worse at forming Z rings in the absence of the Min system? Immunoblotting analysis indicated that the levelsof FtsZ84, while somewhat lower than levels of FtsZ in a wild-typestrain, are no different with or without MinCDE. This rules outthe possibility that the lack of Z rings in the $Delta$ minCDE ftsZ84double mutant is simply a result of significantly lowered FtsZ84levels. While several alternative models are possible, we favorthe following model to explain the synthetic effect. The firstassumption of the model is that FtsZ84 is defective in formingZ rings because it requires a higher critical concentration, relativeto wild-type FtsZ, to assemble into the putative polymers thatmake up the rings. This might explain why a small increase inFtsZ84 concentration can suppress thermosensitivity. The secondassumption is that in a normal min⁺ cell, the nucleoid and the Min system block most of the cellsurface from assembling Z rings (41). According to this model,only the midcell region can support Z-ring assembly because (i)the MinE ring counteracts the inhibition of FtsZ by MinCD elsewherein the cell, such as the nucleoid-free cell poles, and (ii) initiationof chromosome segregation or some other effect of replicationcauses the nucleoid occlusion effect to be suppressed at the midpointof the two chromosome masses, which corresponds to the exact centerof thecell.

When the Min proteins are absent, the nucleoid-free poles now become potential sites for Z-ring assembly, increasing the overallnumber of potential assembly sites per cell length. This increasedavailability of sites causes FtsZ to distribute to more regionsof the cell, effectively decreasing its local concentration atany given potential division site. Wild-type FtsZ responds tothe lack of Min proteins by forming rings at all of these sites;this can be explained as its estimated concentration of 10 µMis at least five times higher than the critical concentrationfor GTP-mediated polymer assembly in vitro (18, 20, 40).Therefore, wild-type FtsZ is not limiting for the formation ofrings under these conditions. However, FtsZ84 is not only slightlyless concentrated, as found by our immunoblot analysis, but alsorequires a higher critical concentration for assembly than wild-typeFtsZ because of its GTP binding defect. We postulate that thedilution effect caused by the increased number of potential assemblysites results in the general failure of FtsZ84 to form rings inthe $Delta$ minCDE mutant and that modestly increasing FtsZ84 concentrationincreases the number of Z rings proportionately. The model predictsthat if nucleoid-free gaps were lengthened, for example in a DNAreplication mutant, then FtsZ84 would be even less able to formrings and a greater increase in FtsZ84 levels would be necessaryforviability.

The defect of FtsZ84 in GTP binding can explain the lower frequency of Z rings in the double mutant according to the abovemodel. The other known defect of FtsZ84, besides GTP binding,is in GTP hydrolysis, and this defect also can explain some ofthe phenotypes we observe. GTP hydrolysis appears to drive FtsZpolymer disassembly in vitro (20). Our results indicate thatin vivo, Z-ring disassembly is indeed defective in an ftsZ84 mutantand is observed most readily in the absence of the Minsystem.

A related and surprising result of our study is that the majority of Z rings within the short filaments of the $Delta$ minCDE ftsZ84double mutant at 22°C are located at the cell poles. Polar ringsare expected in a min mutant and form in addition to medial ringsin short cells (41). But the length of the double mutant filaments,largely resulting from the scarcity of prior septation events,means that many nucleoid-free gaps are present within the filamentsthat should be sites for Z-ring assembly. Nevertheless, most ofthese internal sites are not used, and instead most Z rings format a pole. This implies that the pole has a special ability toattract FtsZ84 in the absence of the Minsystem.

We can come up with two explanations for this polar bias. One is that nucleoid segregation in the double mutant is abnormal,with many filaments containing unsegregated nucleoids. Nucleoidocclusion would theoretically block Z rings from forming throughoutmost of the cell except at nucleoid-free areas at the poles. Weoften saw unsegregated nucleoids in these filaments by DAPI staining,consistent with previous reports linking segregation defects withdefects in the Min system (2, 21, 41). FtsZ-dependent latecell division proteins, which would not be localized in the absenceof Z rings, have also been implicated in segregation (16, 17,33, 43). However, most filaments of the double mutant, whiledisplaying some segregation defects, still contain multiple gapsbetween nucleoids as visualized by DAPI staining. The absenceof Z rings in virtually all of these gaps suggests a second hypothesis,which we favor: FtsZ84 is actively recruited to form rings nearthe most recently formed pole. This idea is entirely consistentwith (i) the prevalence of cells with a Z ring at only one poleof a short filament, (ii) our time-lapse data showing sequentialminicell formation from one pole at the expense of the rest ofthe cell, including the opposite pole, and (iii) the duplicationof FtsZ84 staining upon formation of two new poles, a result ofdelayed clearance of FtsZ84 from the newly formedseptum.

Overall, our results are consistent with the following general model: (i) FtsZ84 protein is defective in assembling into ringsand disassembling once the septum is formed; (ii) both of thesedefects are significantly enhanced in the absence of the Min system,resulting in increased thermosensitivity of the strain, many missingZ rings, and the persistence of FtsZ structures at new poles;and (iii) incompletely disassembled FtsZ84 structures at new polesremaining from the prior division event serve to nucleate newZ rings, resulting in a bias towards Z-ring formation at new polesand the production of sequential minicells in the absence of theMin system. The ring disassembly defect might also directly causethe deficiency in nonpolar rings: by sequestering FtsZ84 at theold poles, its dispersal throughout the cell would be prevented,leading to a lowering of the local FtsZ84 concentration at nonpolarsites and a failure to form nonpolarrings.

One additional hypothesis that arises from this model is that the Min system may have a role in FtsZ polymer turnover. Inmin⁺ cells, for example, even though FtsZ84 is normally defectivein disassembly, defects such as elongated septa are seldom detected.We speculate that this is because the MinCD inhibitor activelysweeps out any residual aggregated FtsZ84 at the new pole, whilein cells lacking the Min proteins this turnover occurs significantlymore slowly. Therefore, we propose that MinCD, in addition toinhibiting Z-ring formation (7), may also help to disassemblethe Z ring after cell division. This would be consistent withthe postulated role of the Min system in negatively regulatingFtsZ structures in order to prevent nonspecific Z-ring formation.This model should also prompt a revisiting of the idea that olddivision sites are used for polar rings in min mutants. Althoughour integrated division site placement model (41) argues againstthe existence of predetermined division sites, it could be thatunder special conditions, such as those described herein, remnantsof old sites play a role in polar ring assembly because the MinCDinhibitor is not around to remove them. Such an idea may be relevantto the understanding of how cell division is regulated in themany species, such as alpha-proteobacteria, that lack a discernibleMin system (19).

We found that thermoresistant suppressors of ftsZ84 mutants arose at frequencies considerably higher than expected for a singleallele-specific alteration. This fact, combined with the higherexpression of ftsZ84 in the suppressors that we tested, suggeststhat suppression occurs via several different pathways that resultin higher ftsZ84 expression. The number of promoters in the genecluster preceding ftsZ and the known effects of ppGpp on transcriptionof this region are consistent with this idea. We were not ableto successfully map the suppressor by linkage analysis, as thethermoresistant phenotype was unstable (X. C. Yu and N. Choudhary,unpublished results). However, the suppression was not a resultof a change in the ftsZ84 gene, as confirmed by sequencing. Ifupstream transcription is affected in these suppressor strains,it is important to emphasize that expression of upstream genes,such as ftsQ and/or ftsA, may also be increased in these strainsand may contribute to the phenotypesobserved.

The formation of branches correlates well with the increased synthesis of FtsZ84 protein and altered septal morphology inthe thermoresistant suppressor strains tested in this study. Branchinghas been found in other mutants, such as min, ftsL, and pbp mutants(3, 12, 22), and abnormal septal morphology has been observedwith ftsZ26 mutants that form spiral septa (6). Growth ratealso seems to play a role in other studies of branching (11).We found that branching frequency in the suppressor strains wasgreatest at higher growth temperatures. We speculate that thisoccurs because the defective FtsZ84 protein is less able to keepup with rapid wall growth at higher growth temperatures, resultingin abnormal septa. We also speculate that increased levels ofFtsZ84 are not sufficient to overcome these problems because theprotein is still defective in polymer turnover. Further work todetermine the nature of the thermoresistant suppression and sufficiencyof FtsZ84 levels for branching isunderway.

	ACKNOWLEDGMENTS

We thank N. Choudhary for help with some of the strain constructions and other members of the Margolin lab for comments andcriticisms. We also thank D. Weiss for strainEC488.

This work was supported by grants from the National Science Foundation (MCB-9513521) and the National Institutes of Health(1R01-6M61704-01).

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Microbiology and Molecular Genetics, University of Texas Medical School,6431 Fannin, Houston, TX 77030. Phone: (713) 500-5452. Fax: (713)500-5499. E-mail: William.Margolin{at}uth.tmc.edu-Houston.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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1.	Addinall, S. G., C. Cao, and J. Lutkenhaus. 1997. Temperature shift experiments with an ftsZ84(Ts) strain reveal rapid dynamics of FtsZ localization and indicate that the Z ring is required throughout septation and cannot reoccupy division sites once constriction has initiated. J. Bacteriol. 179:4277-4284[Abstract/Free Full Text].
2.	Åkerlund, T., R. Bernander, and K. Nordström. 1992. Cell division in Escherichia coli minB mutants. Mol. Microbiol. 6:2073-2083[CrossRef][Medline].
3.	Åkerlund, T., K. Nordström, and R. Bernander. 1993. Branched Escherichia coli cells. Mol. Microbiol. 10:849-858[Medline].
4.	Begg, K., Y. Nikolaichik, N. Crossland, and W. D. Donachie. 1998. Roles of FtsA and FtsZ in activation of division sites. J. Bacteriol. 180:881-884[Abstract/Free Full Text].
5.	Bi, E., and J. Lutkenhaus. 1990. Analysis of ftsZ mutations that confer resistance to the cell division inhibitor SulA (SfiA). J. Bacteriol. 172:5602-5609[Abstract/Free Full Text].
6.	Bi, E., and J. Lutkenhaus. 1992. Isolation and characterization of ftsZ alleles that affect septal morphology. J. Bacteriol. 174:5414-5423[Abstract/Free Full Text].
7.	Bi, E., and J. Lutkenhaus. 1993. Cell division inhibitors SulA and MinCD prevent formation of the FtsZ ring. J. Bacteriol. 175:1118-1125[Abstract/Free Full Text].
8.	de Boer, P., R. Crossley, and L. Rothfield. 1992. The essential bacterial cell-division protein FtsZ is a GTPase. Nature 359:254-256[CrossRef][Medline].
9.	de Boer, P. A., R. E. Crossley, and L. I. Rothfield. 1990. Central role for the Escherichia coli minC gene product in two different cell division-inhibition systems. Proc. Natl. Acad. Sci. USA 87:1129-1133[Abstract/Free Full Text].
10.	de Boer, P. A. J., R. E. Crossley, and L. I. Rothfield. 1989. A division inhibitor and a topological specificity factor coded for by the minicell locus determine the proper placement of the division site in Escherichia coli. Cell 56:641-649[CrossRef][Medline].
11.	Gullbrand, B., T. Åkerlund, and K. Nordström. 1999. On the origin of branches in Escherichia coli. J. Bacteriol. 181:6607-6614[Abstract/Free Full Text].
12.	Guzman, L.-M., J. J. Barondess, and J. Beckwith. 1992. FtsL, an essential cytoplasmic membrane protein involved in cell division in Escherichia coli. J. Bacteriol. 174:7716-7728.
13.	Hu, Z., and J. Lutkenhaus. 1999. Topological regulation of cell division in Escherichia coli involves rapid pole to pole oscillation of the division inhibitor MinC under the control of MinD and MinE. Mol. Microbiol. 34:82-90[CrossRef][Medline].
14.	Hu, Z., A. Mukherjee, S. Pichoff, and J. Lutkenhaus. 1999. The MinC component of the division site selection system in Escherichia coli interacts with FtsZ to prevent polymerization. Proc. Natl. Acad. Sci. USA 96:14819-14824[Abstract/Free Full Text].
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