FtsQ, FtsL and FtsI require FtsK, but not FtsN, for co-localization with FtsZ during Escherichia coli cell division

During cell division in Gram-negative bacteria, the cell envelope invaginates and constricts at the septum, eventually severing the cell into two compartments, and separating the replicated genetic materials. In Escherichia coli, at least nine essential gene products participate directly in septum formation: FtsA, FtsI, FtsL, FtsK, FtsN, FtsQ, FtsW, FtsZ and ZipA. All nine proteins have been localized to the septal ring, an equatorial ring structure at the division site. We used translational fusions to green fluorescent protein (GFP) to demonstrate that FtsQ, FtsL and FtsI localize to potential division sites in filamentous cells depleted of FtsN, but not in those depleted of FtsK. We also constructed translational fusions of FtsZ, FtsA, FtsQ, FtsL and FtsI to enhanced cyan or yellow fluorescent protein (ECFP or EYFP respectively), GFP variants with different fluorescence spectra. Examination of cells expressing different combinations of the fusions indicated that FtsA, FtsQ, FtsL and FtsI co-localize with FtsZ in filaments depleted of FtsN. These localization results support the model that E. coli cell division proteins assemble sequentially as a multimeric complex at the division site: first FtsZ, then FtsA and ZipA independently of each other, followed successively by FtsK, FtsQ, FtsL, FtsW, FtsI and FtsN.     

Evidence for functional overlap among multiple bacterial cell division proteins: compensating for the loss of FtsK

In Escherichia coli, at least 12 proteins colocalize to the cell midpoint, assembling into a membrane-associated protein machine that forms the division septum. Many of these proteins, including FtsK, are essential for viability but their functions in cell division are unknown. Here we show that the essential function of FtsK in cell division can be partially bypassed. Cells containing either the ftsA R286W mutation or a plasmid carrying the ftsQAZ genes suppressed a ftsK44(ts) allele efficiently. Moreover, ftsA R286W or multicopy ftsQAZ, which can largely bypass the requirement for the essential cell division gene zipA, allowed cells with a complete deletion of ftsK to survive and divide, although many of these ftsK null cells formed multiseptate chains. Green fluorescent protein (GFP) fusions to FtsI and FtsN, which normally depend on FtsK to localize to division sites, localized to division sites in the absence of FtsK, indicating that FtsK is not directly involved in their recruitment. Cells expressing additional ftsQ, and to a lesser extent ftsB and ftsN, were able to survive and divide in the absence of ftsK, although cell chains were often formed. Surprisingly, the cytoplasmic and transmembrane domains of FtsQ, while not sufficient to complement an ftsQ null mutant, conferred viability and septum formation in the absence of ftsK. These findings suggest that the N-terminal domain of FtsK is normally involved in stability of the division protein machine and shares functional overlap with FtsQ, FtsB, FtsA, ZipA and FtsN.     

Maturation of the Escherichia coli divisome occurs in two steps

Cell division proteins FtsZ (FtsA, ZipA, ZapA), FtsE/X, FtsK, FtsQ, FtsL/B, FtsW, PBP3, FtsN and AmiC localize at mid cell in Escherichia coli in an interdependent order as listed. To investigate whether this reflects a time dependent maturation of the divisome, the average cell age at which FtsZ, FtsQ, FtsW, PBP3 and FtsN arrive at their destination was determined by immuno- and GFP-fluorescence microscopy of steady state grown cells at a variety of growth rates. Consistently, a time delay of 14-21 min, depending on the growth rate, between Z-ring formation and the mid cell recruitment of proteins down stream of FtsK was found. We suggest a two-step model for bacterial division in which the Z-ring is involved in the switch from cylindrical to polar peptidoglycan synthesis, whereas the much later localizing cell division proteins are responsible for the modification of the envelope shape into that of two new poles.     

ZipA is required for recruitment of FtsK, FtsQ, FtsL, and FtsN to the septal ring in Escherichia coli

The septal ring in Escherichia coli consists of at least nine essential gene products whose order of assembly resembles a mostly linear dependency pathway: FtsA and ZipA directly bind FtsZ polymers at the prospective division site, followed by the sequential addition of FtsK, FtsQ, FtsL, FtsW, FtsI, and FtsN. Recruitment of FtsK and all downstream components requires the prior localization of FtsA. Here we show that recruitment of FtsK, FtsQ, FtsL, and FtsN equally requires ZipA. The results imply that association of both FtsA and ZipA with FtsZ polymers is needed for further maturation of the nascent organelle.     

FtsN-like proteins are conserved components of the cell division machinery in proteobacteria

In bacteria, cytokinesis is mediated by a ring-shaped multiprotein complex, called divisome. While some of its components are widely conserved, others are restricted to certain bacterial lineages. FtsN is the last essential cell division protein to localize to the division septum in Escherichia coli and is poorly conserved outside the enteric bacteria. We have identified a homologue of FtsN in the α-proteobacterium Caulobacter crescentus and show that it is essential for cell division. C. crescentus FtsN is recruited to the divisome significantly after cell division initiates and remains associated with the new cell poles after cytokinesis is finished. All determinants necessary for localization and function are located in a largely unstructured periplasmic segment of the protein. Its conserved SPOR-domain, by contrast, is dispensable for cytokinesis, although it supports targeting of FtsN to the division site. Interestingly, the SPOR-domain is recruited to the division plane when produced in isolated form and retains its localization potential in a heterologous host background. Searching for proteins that share the characteristic features of FtsN from E. coli and C. crescentus , we identified FtsN-like cell division proteins in β- and δ-proteobacteria, suggesting that FtsN is widespread among bacteria, albeit highly variable at the sequence level.     

The early divisome protein FtsA interacts directly through its 1c subdomain with the cytoplasmic domain of the late divisome protein FtsN

In Escherichia coli, FtsN localizes late to the cell division machinery, only after a number of additional essential proteins are recruited to the early FtsZ-FtsA-ZipA complex. FtsN has a short, positively charged cytoplasmic domain (FtsN(Cyto)), a single transmembrane domain (FtsN(TM)), and a periplasmic domain that is essential for FtsN function. Here we show that FtsA and FtsN interact directly in vitro. FtsN(Cyto) is sufficient to bind to FtsA, but only when it is tethered to FtsN(TM) or to a leucine zipper. Mutation of a conserved patch of positive charges in FtsN(Cyto) to negative charges abolishes the interaction with FtsA. We also show that subdomain 1c of FtsA is sufficient to mediate this interaction with FtsN. Finally, although FtsN(Cyto-TM) is not essential for FtsN function, its overproduction causes a modest dominant-negative effect on cell division. These results suggest that basic residues within a dimerized FtsN(Cyto) protein interact directly with residues in subdomain 1c of FtsA. Since FtsA binds directly to FtsZ and FtsN interacts with enzymes involved in septum synthesis and splitting, this interaction between early and late divisome proteins may be one of several feedback controls for Z ring constriction.     

Role of FtsEX in cell division of Escherichia coli: viability of ftsEX mutants is dependent on functional SufI or high osmotic strength

In Escherichia coli, at least 12 proteins, FtsZ, ZipA, FtsA, FtsE/X, FtsK, FtsQ, FtsL, FtsB, FtsW, FtsI, FtsN, and AmiC, are known to localize to the septal ring in an interdependent and sequential pathway to coordinate the septum formation at the midcell. The FtsEX complex is the latest recruit of this pathway, and unlike other division proteins, it is shown to be essential only on low-salt media. In this study, it is shown that ftsEX null mutations are not only salt remedial but also osmoremedial, which suggests that FtsEX may not be involved in salt transport as previously thought. Increased coexpression of cell division proteins FtsQ-FtsA-FtsZ or FtsN alone restored the growth defects of ftsEX mutants. ftsEX deletion exacerbated the defects of most of the mutants affected in Z ring localization and septal assembly; however, the ftsZ84 allele was a weak suppressor of ftsEX. The viability of ftsEX mutants in high-osmolarity conditions was shown to be dependent on the presence of a periplasmic protein, SufI, a substrate of twin-arginine translocase. In addition, SufI in multiple copies could substitute for the functions of FtsEX. Taken together, these results suggest that FtsE and FtsX are absolutely required for the process of cell division in conditions of low osmotic strength for the stability of the septal ring assembly and that, during high-osmolarity conditions, the FtsEX and SufI functions are redundant for this essential process.     

Murein (peptidoglycan) binding property of the essential cell division protein FtsN from Escherichia coli

The binding of the essential cell division protein FtsN of Escherichia coli to the murein (peptidoglycan) sacculus was studied. Soluble truncated variants of FtsN, including the complete periplasmic part of the protein as well as a variant containing only the C-terminal 77 amino acids, did bind to purified murein sacculi isolated from wild-type cells. FtsN variants lacking this C-terminal region showed reduced or no binding to murein. Binding of FtsN was severely reduced when tested against sacculi isolated either from filamentous cells with blocked cell division or from chain-forming cells of a triple amidase mutant. Binding experiments with radioactively labeled murein digestion products revealed that the longer murein glycan strands (>25 disaccharide units) showed a specific affinity to FtsN, but neither muropeptides, peptides, nor short glycan fragments bound to FtsN. In vivo FtsN could be cross-linked to murein with the soluble disulfide bridge containing cross-linker DTSSP. Less FtsN, but similar amounts of OmpA, was cross-linked to murein of filamentous or of chain-forming cells compared to levels in wild-type cells. Expression of truncated FtsN variants in cells depleted in full-length FtsN revealed that the presence of the C-terminal murein-binding domain was not required for cell division under laboratory conditions. FtsN was present in 3,000 to 6,000 copies per cell in exponentially growing wild-type E. coli MC1061. We discuss the possibilities that the binding of FtsN to murein during cell division might either stabilize the septal region or might have a function unrelated to cell division.     

A predicted ABC transporter, FtsEX, is needed for cell division in Escherichia coli

FtsE and FtsX have homology to the ABC transporter superfamily of proteins and appear to be widely conserved among bacteria. Early work implicated FtsEX in cell division in Escherichia coli, but this was subsequently challenged, in part because the division defects in ftsEX mutants are often salt remedial. Strain RG60 has an ftsE::kan null mutation that is polar onto ftsX. RG60 is mildly filamentous when grown in standard Luria-Bertani medium (LB), which contains 1% NaCl, but upon shift to LB with no NaCl growth and division stop. We found that FtsN localizes to potential division sites, albeit poorly, in RG60 grown in LB with 1% NaCl. We also found that in wild-type E. coli both FtsE and FtsX localize to the division site. Localization of FtsX was studied in detail and appeared to require FtsZ, FtsA, and ZipA, but not the downstream division proteins FtsK, FtsQ, FtsL, and FtsI. Consistent with this, in media lacking salt, FtsA and ZipA localized independently of FtsEX, but the downstream proteins did not. Finally, in the absence of salt, cells depleted of FtsEX stopped dividing before any change in growth rate (mass increase) was apparent. We conclude that FtsEX participates directly in the process of cell division and is important for assembly or stability of the septal ring, especially in salt-free media.     

A role for FtsA in SPOR‐independent localization of the essential Escherichia coli cell division protein FtsN

FtsN is a bitopic membrane protein and the last essential component to localize to the Escherichia coli cell division machinery, or divisome. The periplasmic SPOR domain of FtsN was previously shown to localize to the divisome in a self‐enhancing manner, relying on the essential activity of FtsN and the peptidoglycan synthesis and degradation activities of FtsI and amidases respectively. Because FtsN has a known role in recruiting amidases and is predicted to stimulate the activity of FtsI, it follows that FtsN initially localizes to division sites in a SPOR‐independent manner. Here, we show that the cytoplasmic and transmembrane domains of FtsN (FtsN_Cyto‐TM) facilitated localization of FtsN independently of its SPOR domain but dependent on the early cell division protein FtsA. In addition, SPOR‐independent localization preceded SPOR‐dependent localization, providing a mechanism for the initial localization of FtsN. In support of the role of FtsN_Cyto‐TM in FtsN function, a variant of FtsN lacking the cytoplasmic domain localized to the divisome but failed to complement an ftsN deletion unless it was overproduced. Simultaneous removal of the cytoplasmic and SPOR domains abolished localization and complementation. These data support a model in which FtsA–FtsN interaction recruits FtsN to the divisome, where it can then stimulate the peptidoglycan remodelling activities required for SPOR‐dependent localization.     

The bifunctional FtsK protein mediates chromosome partitioning and cell division in Caulobacter

Bacterial chromosome partitioning and cell division are tightly connected cellular processes. We show here that the Caulobacter crescentus FtsK protein localizes to the division plane, where it mediates multiple functions involved in chromosome segregation and cytokinesis. The first 258 amino acids of the N terminus are necessary and sufficient for targeting the protein to the division plane. Furthermore, the FtsK N terminus is required to either assemble or maintain FtsZ rings at the division plane. The FtsK C terminus is essential in Caulobacter and is involved in maintaining accurate chromosome partitioning. In addition, the C-terminal region of FtsK is required for the localization of the topoisomerase IV ParC subunit to the replisome to facilitate chromosomal decatenation prior to cell division. These results suggest that the interdependence between chromosome partitioning and cell division in Caulobacter is mediated, in part, by the FtsK protein.     

Multiple regions along the Escherichia coli FtsK protein are implicated in cell division

Escherichia coli FtsK is a large 1329 aa integral membrane protein, which links cell division and chromosome segregation through the respective activities of its 200 aa amino-terminal domain, FtsK(N), and its 500 aa carboxy-terminal domain, FtsK(C). A long 600 aa linker, FtsK(L), connects these two domains. Only FtsK(N) is essential for cell division. However, previous observations suggested that the cytoplasmic part of FtsK also participates in the process of septation. Here, we identify two distinct regions within FtsK(L), FtsK(179-331) and FtsK(332-641), which together with FtsK(N), are required for normal septation. We discuss how the implication of multiple regions along the FtsK protein in cell division could participate in the co-ordination of this process with the last stages of chromosome segregation.     

A role for the FtsQLB complex in cytokinetic ring activation revealed by an ftsL allele that accelerates division

The cytokinetic apparatus of bacteria is initially formed by the polymerization of the tubulin‐like FtsZ protein into a ring structure at midcell. This so‐called Z‐ring facilitates the recruitment of many additional proteins to the division site to form the mature divisome machine. Although the assembly pathway leading to divisome formation has been well characterized, the mechanisms that trigger cell constriction remain unclear. In this report, we study a ‘forgotten’ allele of ftsL from Escherichia coli, which encodes a conserved division gene of unknown function. We discovered that this allele promotes the premature initiation of cell division. Further analysis also revealed that the mutant bypasses the requirement for the essential division proteins ZipA, FtsK and FtsN, and partially bypasses the need for FtsA. These findings suggest that rather than serving simply as a protein scaffold within the divisome, FtsL may play a more active role in the activation of the machine. Our results support a model in which FtsL, along with its partners FtsB and FtsQ, function as part of a sensing mechanism that promotes the onset of cell wall remodeling processes needed for the initiation of cell constriction once assembly of the divisome complex is deemed complete.     

Double-stranded DNA translocation: structure and mechanism of hexameric FtsK

FtsK is a DNA translocase that coordinates chromosome segregation and cell division in bacteria. In addition to its role as activator of XerCD site-specific recombination, FtsK can translocate double-stranded DNA (dsDNA) rapidly and directionally and reverse direction. We present crystal structures of the FtsK motor domain monomer, showing that it has a RecA-like core, the FtsK hexamer, and also showing that it is a ring with a large central annulus and a dodecamer consisting of two hexamers, head to head. Electron microscopy (EM) demonstrates the DNA-dependent existence of hexamers in solution and shows that duplex DNA passes through the middle of each ring. Comparison of FtsK monomer structures from two different crystal forms highlights a conformational change that we propose is the structural basis for a rotary inchworm mechanism of DNA translocation.     

The essential cell division protein FtsN contains a critical disulfide bond in a non‐essential domain

Disulfide bonds are found in many proteins associated with the cell wall of Escherichia coli, and for some of these proteins the disulfide bond is critical to their stability and function. One protein found to contain a disulfide bond is the essential cell division protein FtsN, but the importance of this bond to the protein's structural integrity is unclear. While it evidently plays a role in the proper folding of the SPOR domain of FtsN, this domain is non‐essential, suggesting that the disulfide bond might also be dispensable. However, we find that FtsN mutants lacking cysteines give rise to filamentous growth. Furthermore, FtsN protein levels in strains expressing these mutants were significantly lower than in a strain expressing the wild‐type allele, as were FtsN levels in strains incapable of making disulfide bonds (dsb^‐) exposed to anaerobic conditions. These results strongly suggest that FtsN lacking a disulfide bond is unstable, thereby making this disulfide critical for function. We have previously found that dsb^‐ strains fail to grow anaerobically, and the results presented here suggest that this growth defect may be due in part to misfolded FtsN. Thus, proper cell division in E. coli is dependent upon disulfide bond formation.     

Staphylococcus aureus requires at least one FtsK/SpoIIIE protein for correct chromosome segregation

Faithful coordination between bacterial cell division and chromosome segregation in rod‐shaped bacteria, such as Escherichia coli and Bacillus subtilis, is dependent on the DNA translocase activity of FtsK/SpoIIIE proteins, which move DNA away from the division site before cytokinesis is completed. However, the role of these proteins in chromosome partitioning has not been well studied in spherical bacteria. Here, it was shown that the two Staphylococcus aureus FtsK/SpoIIIE homologues, SpoIIIE and FtsK, operate in independent pathways to ensure correct chromosome management during cell division. SpoIIIE forms foci at the centre of the closing septum in at least 50% of the cells that are close to complete septum synthesis. FtsK is a multifunctional septal protein with a C‐terminal DNA translocase domain that is not required for correct chromosome management in the presence of SpoIIIE. However, lack of both SpoIIIE and FtsK causes severe nucleoid segregation and morphological defects, showing that the two proteins have partially redundant roles in S. aureus.     

FtsK Is a DNA motor protein that activates chromosome dimer resolution by switching the catalytic state of the XerC and XerD recombinases

FtsK acts at the bacterial division septum to couple chromosome segregation with cell division. We demonstrate that a truncated FtsK derivative, FtsK(50C), uses ATP hydrolysis to translocate along duplex DNA as a multimer in vitro, consistent with FtsK having an in vivo role in pumping DNA through the closing division septum. FtsK(50C) also promotes a complete Xer recombination reaction between dif sites by switching the state of activity of the XerCD recombinases so that XerD makes the first pair of strand exchanges to form Holliday junctions that are then resolved by XerC. The reaction between directly repeated dif sites in circular DNA leads to the formation of uncatenated circles and is equivalent to the formation of chromosome monomers from dimers.     

The cytoplasmic domain of FtsK protein is required for resolution of chromosome dimers

Chromosome dimers, formed by homologous recombination between sister chromosomes, normally require cell division to be resolved into monomers by site-specific recombination at the dif locus of Escherichia coli. We report here that it is not in fact cell division per se that is required for dimer resolution but the action of the cytoplasmic domain of FtsK, which is a bifunctional protein required both for cell division and for chromosome partition.     

Last but not least: new insights into how FtsN triggers constriction during Escherichia coli cell division

The arrival of FtsN at the division site triggers synthesis of septal peptidoglycan and constriction of the cell envelope. New findings are changing our view of how this happens. Binding of FtsN's cytoplasmic domain to a protein named FtsA recruits a small amount of FtsN to the division site earlier than previously recognized. The ability of FtsA to interact with FtsN is regulated by the ZipA protein. The FtsN–FtsA interaction pushes FtsA into an ‘on’ conformation that activates the machinery for peptidoglycan synthesis. In addition, a small region of FtsN's periplasmic domain appears to interact with the FtsQLB complex, pushing it into an ‘on’ state that also triggers synthesis of peptidoglycan. Thus, FtsN allosterically activates peptidoglycan synthesis by two pathways, one in the cytoplasm and involving FtsA, and the other in the periplasm and involving FtsQLB.     

The bacterial cell division protein fragment EFtsN binds to and activates the major peptidoglycan synthase PBP1b

Peptidoglycan (PG) is an essential constituent of the bacterial cell wall. During cell division, the machinery responsible for PG synthesis localizes mid-cell, at the septum, under the control of a multiprotein complex called the divisome. In Escherichia coli, septal PG synthesis and cell constriction rely on the accumulation of FtsN at the division site. Interestingly, a short sequence of FtsN (Leu⁷⁵–Gln⁹³, known as ^EFtsN) was shown to be essential and sufficient for its functioning in vivo, but what exactly this sequence is doing remained unknown. Here, we show that ^EFtsN binds specifically to the major PG synthase PBP1b and is sufficient to stimulate its biosynthetic glycosyltransferase (GTase) activity. We also report the crystal structure of PBP1b in complex with ^EFtsN, which demonstrates that ^EFtsN binds at the junction between the GTase and UB2H domains of PBP1b. Interestingly, mutations to two residues (R141A/R397A) within the ^EFtsN-binding pocket reduced the activation of PBP1b by FtsN but not by the lipoprotein LpoB. This mutant was unable to rescue the ΔponB-ponA^ts strain, which lacks PBP1b and has a thermosensitive PBP1a, at nonpermissive temperature and induced a mild cell-chaining phenotype and cell lysis. Altogether, the results show that ^EFtsN interacts with PBP1b and that this interaction plays a role in the activation of its GTase activity by FtsN, which may contribute to the overall septal PG synthesis and regulation during cell division.