Sebastien Pichoff

Unique and overlapping roles for ZipA and FtsA in septal ring assembly in Escherichia coli

ZipA and FtsA are essential division proteins in Escherichia coli that are recruited to the division site by interaction with FtsZ. Utilizing a newly isolated temperature‐sensitive mutation in zipA we have more fully characterized the role of ZipA. We confirmed that ZipA is not required for Z ring formation; however, we found that ZipA, like FtsA, is required for recruitment of FtsK and therefore all downstream division proteins. In the absence of FtsA or ZipA Z rings formed; however, in the absence of both, new Z rings were unable to form and preformed Z rings were destabilized. Consistent with this, we found that an FtsZ mutant unable to interact with both ZipA and FtsA was unable to assemble into Z rings. These results demonstrate that ZipA and FtsA are both required for recruitment of additional division proteins to the Z ring, but either one is capable of supporting formation and stabilization of Z rings.

Tethering the Z ring to the membrane through a conserved membrane targeting sequence in FtsA.

The cytokinetic Z ring is required for bacterial cell division. It consists of polymers of FtsZ, the bacterial ancestor of eukaryotic tubulin, linked to the cytoplasmic membrane. Formation of a Z ring in Escherichia coli occurs as long as one of two proteins, ZipA or FtsA, is present. Both of these proteins bind FtsZ suggesting that they might function to tether FtsZ filaments to the membrane. Although ZipA has a transmembrane domain and therefore can function as a membrane anchor, interaction of FtsA with the membrane has not been explored. In this study we demonstrate that FtsA, which is structurally related to eukaryotic actin, has a conserved C‐terminal amphipathic helix that is essential for FtsA function. It is required to target FtsA to the membrane and subsequently to the Z ring. As FtsA is much more widely conserved in bacteria than ZipA, it is likely that FtsA serves as the principal membrane anchor for the Z ring.

Bacterial cytokinesis: From Z ring to divisome †

Ancestral homologues of the major eukaryotic cytoskeletal families, tubulin and actin, play critical roles in cytokinesis of bacterial cells. FtsZ is the ancestral homologue of tubulin and assembles into the Z ring that determines the division plane. FtsA, a member of the actin family, is involved in coordinating cell wall synthesis during cytokinesis. FtsA assists in the formation of the Z ring and also has a critical role in recruiting downstream division proteins to the Z ring to generate the divisome that divides the cell. Spatial regulation of cytokinesis occurs at the stage of Z ring assembly and regulation of cell size occurs at this stage or during Z ring maturation.

Escherichia coli Division Inhibitor MinCD Blocks Septation by Preventing Z-Ring Formation

The min system spatially regulates division through the topological regulation of MinCD, an inhibitor of cell division. MinCD was previously shown to inhibit division by preventing assembly of the Z ring (E. Bi and J. Lutkenhaus, J. Bacteriol. 175:1118-1125, 1993); however, this was questioned in a recent report (S. S. Justice, J. Garcia-Lara, and L. I. Rothfield, Mol. Microbiol. 37:410-423, 2000) which indicated that MinCD acted after Z-ring formation and prevented the recruitment of FtsA to the Z ring. This discrepancy was due in part to alternative fixation conditions. We have therefore reinvestigated the action of MinCD and avoided fixation by using green fluorescent protein (GFP) fusions to division proteins. MinCD prevented the localization of both FtsZ-GFP and ZipA-GFP, consistent with it preventing Z-ring assembly. Consistent with a direct interaction between FtsZ and the MinCD inhibitor, we find that increased FtsZ, but not FtsA, suppresses MinCD-induced lethality. Furthermore, strains carrying various alleles of ftsZ, selected on the basis of resistance to the inhibitor SulA, displayed variable resistance to MinCD. These results are consistent with FtsZ as the target of MinCD and confirm that this inhibitor prevents Z-ring assembly.

Cross-linking FtsZ polymers into coherent Z rings

A key event in bacterial cytokinesis is the formation of the Z ring, which serves as a mechanical scaffold that recruits other cytokinetic proteins to establish functional divisomes. This scaffolding function of Z rings is essential throughout cytokinesis, but the underlying molecular interactions are poorly understood. Here we report that a widely conserved FtsZ binding protein, ZapA, has cytological, biochemical and biophysical properties that argue for the importance of cross‐linking interactions between FtsZ polymers in the coherence of Z rings. Escherichia coli zapA null mutant cells have Z rings that are structurally looser and many helical precursors of Z rings fail to coalesce into coherent rings. Biophysical behaviour of FtsZ in the presence of ZapA reveals that ZapA not only bundles, but also cross‐links FtsZ polymers, which makes it the first cross‐linking protein of the bacterial cytoskeleton. Cross‐linking in vitro occurs at the stoichiometry of FtsZ–ZapA interaction at the Z rings in vivo, where nearly all intracellular ZapA is dynamically associated. ZapA also stabilizes longitudinal bonds between FtsZ monomers since it promotes the polymerization of FtsZ mutants with lesions at the polymerization interface and since it reverses the inhibitory effects of SulA, a known antagonist of FtsZ longitudinal interactions.

FtsA mutants impaired for self‐interaction bypass ZipA suggesting a model in which FtsA's self‐interaction competes with its ability to recruit downstream division proteins

Z‐ring assembly requires polymers of the tubulin homologue FtsZ to be tethered to the membrane. Although either ZipA or FtsA is sufficient to do this, both of these are required for recruitment of downstream proteins to form a functional cytokinetic ring. Gain of function mutations in ftsA, such as ftsA* (ftsA‐R286W), bypass the requirement for ZipA suggesting that this atypical, well‐conserved, actin homologue has a more critical role in Z‐ring function. FtsA forms multimers both in vitro and in vivo, but little is known about the role of FtsA polymerization. In this study we identify FtsA mutants impaired for self‐interaction. Such mutants are able to support Z‐ring assembly and are also able to bypass the requirement for ZipA. These mutants, including FtsA*, have reduced ability to self‐interact but interact normally with FtsZ and are less toxic if overexpressed. These results do not support a model in which FtsA monomers antagonize FtsZ polymers. Instead, we propose a new model in which FtsA self‐interaction competes with its ability to recruit downstream proteins. In this model FtsA self‐interaction at the Z ring is antagonized by ZipA, allowing unpolymerized FtsA to recruit downstream proteins such as FtsN.

Identification of a region of FtsA required for interaction with FtsZ.

The assembly of the Z ring is the earliest step in bacterial cell division. In Escherichia coli this assembly requires either FtsA or ZipA which bind to a conserved, C‐terminal 17 amino acid motif in FtsZ and to the membrane. The FtsZ–ZipA interaction is well characterized; however, nothing is known about the region of FtsA involved in the interaction with FtsZ even though the FtsA–FtsZ interaction is nearly ubiquitous in Eubacteria. FtsA is proposed to bind to the membrane through its conserved C‐terminal amphiphatic helix before efficiently interacting with FtsZ. Based upon this model we designed a genetic screen to identify mutants specifically impaired for the FtsA–FtsZ interaction. The mutants obtained retain the ability to be targeted to the membrane but fail to be recruited to the Z ring or interact with FtsZ in the yeast two‐hybrid system. These mutants do not complement an ftsA‐depletion strain. Through this approach we have identified a region of FtsA containing some invariant residues which is required for binding to FtsZ. The results support our model that FtsA is targeted to the membrane before it interacts with FtsZ and demonstrates that this interaction plays an essential role in E. coli cell division.

On the birth and fate of bacterial division sites

Thanks to genetics, to the study of protein–protein interactions and to direct viewing of subcellular structures by the use of immunofluorescence and green fluorescent protein (GFP) fusions, the organization of the constriction apparatus of walled bacteria is gradually coming to light. The tubulin‐like protein FtsZ assembles as a ring around the site of constriction and operates as an organizer and activator of septum‐shaping proteins. Much less is known about the factors specifying the location of FtsZ rings. Circumstantial evidence favours the presence at future ring positions of fixed elements, the potential division sites (PDS), before FtsZ assembles. FtsZ polymerization is initiated from a point on a PDS, the nucleation site, still to be identified, and proceeds bidirectionally around the cell. We hypothesize that new PDS are specified in a manner that depends on the functioning of an active chromosome partition apparatus. This view is supported by the fact that formation of mid‐cell PDS requires initiation of DNA replication, and by recent studies supporting the existence of a specialized partition apparatus in a variety of microorganisms. Although PDS may be specified directly by the partition apparatus, indirect localization linked to compartmentalized gene expression during chromosome segregation is also possible. Once created, PDS are used in a regulated manner, and several mechanisms normally operate to direct constriction to selected PDS at the correct time. One, dedicated to the permanent suppression of polar PDS, rests on the minicell suppression system and involves a protein that is able to discriminate between polar and non‐polar sites. Another is involved in asymmetric site selection at the early stages of sporulation in Bacillus subtilis. Finally, a mechanism observed only in certain multinucleated cells appears to favour division at non‐polar PDS related to the most ancient replication/DNA segregation events.

The bypass of ZipA by overexpression of FtsN requires a previously unknown conserved FtsN motif essential for FtsA-FtsN interaction supporting a model in which FtsA monomers recruit late cell division proteins to the Z ring

Assembly of the divisome in Escherichia coli occurs in two temporally distinct steps. First, FtsZ filaments attached to the membrane through interaction with FtsA and ZipA coalesce into a Z ring at midcell. Then, additional proteins are recruited to the Z ring in a hierarchical manner to form a complete divisome, activated by the arrival of FtsN. Recently, we proposed that the interaction of FtsA with itself competes with its ability to recruit downstream division proteins (both require the IC domain of FtsA) and ZipAs essential function is to promote the formation of FtsA monomers. Here, we tested whether overexpression of a downstream division protein could make ZipA dispensable, presumably by shifting the FtsA equilibrium to monomers. Only overexpression of FtsN bypassed ZipA and a conserved motif in the cytoplasmic domain of FtsN was required for both the bypass and interaction with FtsA. Also, this cytoplasmic motif had to be linked to the periplasmic E domain of FtsN to bypass ZipA, indicating that linkage of FtsA to periplasmic components of the divisome through FtsN was essential under these conditions. These results are used to further elaborate our model for the role of FtsA in recruiting downstream division proteins.

FtsEX acts on FtsA to regulate divisome assembly and activity

Significance Understanding divisome assembly and activation has become the focus of research on bacterial cytokinesis. However, very little is known about how this process is regulated. Here, we find that FtsEX (an ATP-binding cassette transporter-like complex) acts on the bacterial actin homolog FtsA to regulate divisome assembly and function in Escherichia coli. Our results suggest that FtsEX antagonizes FtsA polymerization to promote divisome assembly and continual ATP hydrolysis by FtsEX is needed for the divisome to synthesize septal peptidoglycan. Because FtsEX is also required for cell wall hydrolysis at the septum, our study indicates that FtsEX couples cell wall synthesis and hydrolysis at the septum by acting through FtsA. Our study also implies that unpolymerized FtsA is favored for division and FtsW plays a critical role in divisome activation. Bacterial cell division is driven by the divisome, a ring-shaped protein complex organized by the bacterial tubulin homolog FtsZ. Although most of the division proteins in Escherichia coli have been identified, how they assemble into the divisome and synthesize the septum remains poorly understood. Recent studies suggest that the bacterial actin homolog FtsA plays a critical role in divisome assembly and acts synergistically with the FtsQLB complex to regulate the activity of the divisome. FtsEX, an ATP-binding cassette transporter-like complex, is also necessary for divisome assembly and inhibits division when its ATPase activity is inactivated. However, its role in division is not clear. Here, we find that FtsEX acts on FtsA to regulate both divisome assembly and activity. FtsX interacts with FtsA and this interaction is required for divisome assembly and inhibition of divisome function by ATPase mutants of FtsEX. Our results suggest that FtsEX antagonizes FtsA polymerization to promote divisome assembly and the ATPase mutants of FtsEX block divisome activity by locking FtsA in the inactive form or preventing FtsA from communicating with other divisome proteins. Because FtsEX is known to govern cell wall hydrolysis at the septum, our findings indicate that FtsEX acts on FtsA to promote divisome assembly and to coordinate cell wall synthesis and hydrolysis at the septum. Furthermore, our study provides evidence that FtsA mutants impaired for self-interaction are favored for division, and FtsW plays a critical role in divisome activation in addition to the FtsQLB complex.