In vitro reconstitution of a trimeric complex of DivIB, DivIC and FtsL, and their transient co-localization at the division site in Streptococcus pneumoniae

DivIB, DivIC and FtsL are bacterial proteins essential for cell division, which show interdependencies for their stabilities and localization. We have reconstituted in vitro a trimeric complex consisting of the recombinant extracellular domains of the three proteins from Streptococcus pneumoniae. The extracellular domain of DivIB was found to associate with a heterodimer of those of DivIC and FtsL. The heterodimerization of DivIC and FtsL was artificially constrained by fusion with interacting coiled-coils. Immunofluorescence experiments showed that DivIC is always localized at mid-cell, in contrast to DivIB and FtsL, which are co-localized with DivIC only during septation. Taken together, our data suggest that assembly of the trimeric complex DivIB/DivIC/FtsL is regulated during the cell cycle through controlled formation of the DivIC/FtsL heterodimer.     

Characterization of the essential cell division gene ftsL (yllD ) of Bacillus subtilis and its role in the assembly of the division apparatus

We have identified the Bacillus subtilis homologue of the essential cell division gene, ftsL , of Escherichia coli . Repression of ftsL in a strain engineered to carry a conditional promoter results in cell filamentation, with a near immediate arrest of cell division. The filaments show no sign of invagination, indicating that division is blocked at an early stage. FtsL is also shown to be required for septation during sporulation, and depletion of FtsL blocks the activation but not the synthesis of the prespore-specific sigma factor, σ^F. Immunofluorescence microscopy shows that depletion of FtsL has little or no effect on FtsZ ring formation, but the assembly of other division proteins, DivIB and DivIC, at the site of division is prevented. Repression of FtsL also results in a rapid loss of DivIC protein, indicating that DivIC stability is dependent on the presence of FtsL, in turn suggesting that FtsL is intrinsically unstable. The instability of one or more components of the division apparatus may be important for the cyclic assembly/disassembly of the division apparatus.     

The Bacillus subtilis cell division proteins FtsL and DivIC are intrinsically unstable and do not interact with one another in the absence of other septasomal components

The bacterial septum appears to comprise a macromolecular assembly of essential cell division proteins (the 'septasome') that are responsible for physically dividing the cell during cytokinesis. FtsL and DivIC are essential components of this division machinery in Bacillus subtilis. We used yeast two-hybrid analysis as well as a variety of biochemical and biophysical methods to examine the proposed interaction between Bacillus subtilis FtsL and DivIC. We show that FtsL and DivIC are thermodynamically unstable proteins that are likely to be unfolded and therefore targeted for degradation unless stabilized by interactions with other components of the septasome. However, we show that this stabilization does not result from a direct interaction between FtsL and DivIC. We propose that the observed interdependence of DivIC and FtsL stability is a result of indirect interactions that are mediated by other septasomal proteins.     

Intrinsic instability of the essential cell division protein FtsL of Bacillus subtilis and a role for DivIB protein in FtsL turnover

Cell division in most eubacteria is driven by an assembly of about eight conserved division proteins. These proteins form a ring structure that constricts in parallel with the formation of the division septum. Here, we show that one of the division proteins, FtsL, is highly unstable. We also show that the protein is targeted to the ring structure and that targeting occurs in concert with the recruitment of several other membrane-associated division proteins. FtsL stability is further reduced in the absence of DivIB protein (probably homologous to E. coli FtsQ) at high temperature, suggesting that DivIB is involved in the control of FtsL turnover. The reduced stability of FtsL may explain the temperature dependence of divIB mutants, because their phenotype can be suppressed by overexpression of FtsL. The results provide new insights into the roles of the FtsL and DivIB proteins in bacterial cell division.     

Septal localization of the membrane-bound division proteins of Bacillus subtilis DivIB and DivIC is codependent only at high temperatures and requires FtsZ

Using immunofluorescence microscopy, we have examined the dependency of localization among three Bacillus subtilis division proteins, FtsZ, DivIB, and DivIC, to the division site. DivIC is required for DivIB localization. However, DivIC localization is dependent on DivIB only at high growth temperatures, at which DivIB is essential for division. FtsZ localization is required for septal recruitment of DivIB and DivIC, but FtsZ can be recruited independently of DivIB. These localization studies suggest a more specific role for DivIB in division, involving interaction with DivIC.     

Central Domain of DivIB Caps the C-terminal Regions of the FtsL/DivIC Coiled-coil Rod

DivIB(FtsQ), FtsL, and DivIC(FtsB) are enigmatic membrane proteins that are central to the process of bacterial cell division. DivIB(FtsQ) is dispensable in specific conditions in some species, and appears to be absent in other bacterial species. The presence of FtsL and DivIC(FtsB) appears to be conserved despite very low sequence conservation. The three proteins form a complex at the division site, FtsL and DivIC(FtsB) being associated through their extracellular coiled-coil region. We report here structural investigations by NMR, small-angle neutron and x-ray scattering, and interaction studies by surface plasmon resonance, of the complex of DivIB, FtsL, and DivIC from Streptococcus pneumoniae, using soluble truncated forms of the proteins. We found that one side of the “bean”-shaped central β-domain of DivIB interacts with the C-terminal regions of the dimer of FtsL and DivIC. This finding is corroborated by sequence comparisons across bacterial genomes. Indeed, DivIB is absent from species with shorter FtsL and DivIC proteins that have an extracellular domain consisting only of the coiled-coil segment without C-terminal conserved regions (Campylobacterales). We propose that the main role of the interaction of DivIB with FtsL and DivIC is to help the formation, or to stabilize, the coiled-coil of the latter proteins. The coiled-coil of FtsL and DivIC, itself or with transmembrane regions, could be free to interact with other partners.Cell division is one of the defining features of life. Understanding the division of bacteria is also required to find novel antibiotic strategies. Numerous studies, carried out mostly with the model organisms Escherichia coli and Bacillus subtilis have uncovered several components of the divisome, which can be defined as the ensemble of proteins localized at the division site and participating in the process. Comparison of genomes and deletion studies indicate that the core of the divisome comprises eight conserved, mostly essential proteins: FtsZ, FtsA, FtsK, FtsQ(DivIB), FtsL, FtsB(DivIC), FtsW, and FtsI. Fts nomenclature applies to Gram-negative organisms, whereas Div nomenclature applies to Gram-positive bacteria. These proteins are listed here in the conditional order of their recruitment to the division site of E. coli (1–4).Processes in which they participate have been attributed to several division proteins. FtsZ forms polymers with an annular distribution on the cytoplasmic side of the membrane and governs the recruitment of the other proteins. FtsA may mediate the interaction of FtsZ with the membrane. FtsK participates to the resolution of chromosome dimers, and possibly to the membrane fission. FtsI, and likely FtsW, participate to septal cell wall formation (1–4). In contrast, the roles of FtsQ(DivIB), FtsL, and FtsB(DivIC) have not been firmly linked to any particular process.FtsQ(DivIB), FtsL, and FtsB(DivIC) are positioned in the middle of the conditional order of recruitment in E. coli and B. subtilis. When the temporality of the recruitment was examined, FtsQ(DivIB) was found to belong to the late recruits, together with the proteins involved in cell wall assembly (5). In E. coli, the presence of FtsL and FtsB at the division site is mutually dependent, and their localization depends on that of FtsQ (6, 7). In B. subtilis, the presence of FtsL and DivIC at mid-cell depends on that of DivIB, at the temperature at which DivIB is essential, and reciprocally (8, 9). A complex comprising FtsQ, FtsL, and FtsB was isolated from E. coli by co-immunoprecipitation (10), and reconstituted in vitro with recombinant soluble forms of pneumococcal DivIB, FtsL, and DivIC (11). The interaction of the three proteins was also confirmed by yeast and bacterial triple hybrid (12, 13).The genes ftsL and ftsB(divIC) are essential in E. coli and B. subtilis (6, 14–16) and presumably in Streptococcus pneumoniae (17). The essentiality of ftsQ(divIB) in laboratory conditions varies between species. The gene ftsQ is essential in E. coli (18), but divIB is essential only at high temperatures in B. subtilis (9, 19), or in a chemically defined medium in S. pneumoniae (17). Under these conditions, the essentiality of DivIB appears to be a consequence of the protection from proteolysis that it provides to FtsL (8, 17).FtsQ(DivIB), FtsL, and FtsB(DivIC) are bitopic membrane proteins with an N-terminal cytoplasmic region, a single transmembrane segment, and an extracytoplasmic region. The extracellular part is necessary and sufficient for the localization and function of FtsQ(DivIB), provided that it is anchored to the membrane (e.g. Refs. 20 and 21)), although the transmembrane segment also contributes to the localization (22, 23). The extracellular part is organized in three regions termed α, β, and γ. The crystal structure of a region consisting of the α- and β-domains was solved for FtsQ from E. coli and Yersinia enterocolitica (24). The α-domain, comprising about 70 amino acids proximal to the cytoplasmic membrane, corresponds to the POTRA (for polypeptide transport-associated) domain first identified by sequence analysis and proposed to function as a molecular chaperone (25). The α- and β-domains form the conserved region of the FtsQ(DivIB) protein. The γ-region constitutes a C-terminal tail. It is highly variable in length and sequence and predicted to be unfolded. The γ-region was not observed in the structures from E. coli and Y. entercolitica, thus confirming its flexible nature (24).The α-domain in the recombinant soluble form of the extracellular part of DivIB from Geobacillus stearothermophilus was digested by trypsin and therefore considered to be largely unfolded (26). The γ-region was also removed by trypsin digestion, together with a C-terminal fragment of the β-domain. The structure of the resulting shorter β-domain from G. stearothermophilus was solved by NMR (26) and lacks the two C-terminal β-strands.Localization epitopes have been identified in the transmembrane segment, the α-domain, and a region encompassing the C-terminal part of the β-domain and γ-tail of DivIB from B. subtilis (23). Likewise in E. coli, a region in the α-domain is required for localization of FtsQ, whereas the C-terminal region of the β-domain and the last α-helix are required for recruitment of FtsL and FtsB (24). In S. pneumoniae, the essentiality of DivIB in defined medium was found to reside in the C-terminal region of the β-domain (17).No experimental structure is known for FtsL or FtsB(DivIC). Both are small proteins comprising between 90 and 140 amino acids. The number of residues is sometimes larger, as in Mycobacterium tuberculosis (384 for FtsL and 228 for FtsB), due to N- and/or C-terminal extensions consisting of mostly charged and polar amino acids or proline-rich sequences. The major part of FtsL or FtsB(DivIC) is extracellular and contains a region proximal to the transmembrane segment, predicted to form a coiled-coil of about five heptads. Coiled-coil helices associate longitudinally to mediate protein association. It is possible that the coiled-coil helices are continuations of the transmembrane helices, although a proline (known to break helices) is present in some species between the two segments. Following the coiled-coil region is a 25–35-residue long C-terminal region in both FtsL and DivIC(FtsB). This region was recently shown in FtsB to be required for interaction with FtsQ in E. coli (27).We report here the results of structural studies in solution of a ternary complex consisting of the β- and γ-segments of DivIB, and a constrained dimer of the extracellular parts of FtsL and DivIC from S. pneumoniae. Despite the coiled-coil predictions, the recombinant extracellular domains of FtsL and DivIC did not interact in vitro (11, 28). Forced dimerization was obtained by fusion with artificial coiled-coil peptides k5 and e5 (35 residues long), which are known to form a heterodimer due to their complementarity of charge, with a nanomolar dissociation constant (29). The k5- and e5-coils were fused to the extracellular domain of FtsL and DivIC, to give rise to KL and EC fusion proteins, respectively. The constrained dimer (KL/EC) was shown to interact with the extracellular part of DivIB (DivIB_ext), yielding a soluble complex amenable to structural studies (11).The overall shape of the complex and its constituents was probed using small-angle x-ray scattering (SAXS)² and small-angle neutron scattering (SANS). NMR was used to investigate the interface between the proteins by chemical shift mapping. The interaction was further investigated using surface plasmon resonance with truncated forms of the proteins. The complex of DivIB, FtsL, and DivIC is formed by the interaction of one face of the β-domain of DivIB with the C-terminal regions of FtsL and DivIC, at the tip of an elongated rod formed by the coiled-coil segments. The α-domain of DivIB and the coiled-coil regions of FtsL and DivIC remain free to interact with other proteins of the division apparatus.     

Roles of pneumococcal DivIB in cell division

DivIB, also known as FtsQ in gram-negative organisms, is a division protein that is conserved in most eubacteria. DivIB is localized at the division site and forms a complex with two other division proteins, FtsL and DivIC/FtsB. The precise function of these three bitopic membrane proteins, which are central to the division process, remains unknown. We report here the characterization of a divIB deletion mutant of Streptococcus pneumoniae, which is a coccus that divides with parallel planes. Unlike its homologue FtsQ in Escherichia coli, pneumococcal DivIB is not required for growth in rich medium, but the Delta divIB mutant forms chains of diplococci and a small fraction of enlarged cells with defective septa. However, the deletion mutant does not grow in a chemically defined medium. In the absence of DivIB and protein synthesis, the partner FtsL is rapidly degraded, whereas other division proteins are not affected, pointing to a role of DivIB in stabilizing FtsL. This is further supported by the finding that an additional copy of ftsL restores growth of the Delta divIB mutant in defined medium. Functional mapping of the three distinct alpha, beta, and gamma domains of the extracellular region of DivIB revealed that a complete beta domain is required to fully rescue the deletion mutant. DivIB with a truncated beta domain reverts only the chaining phenotype, indicating that DivIB has distinct roles early and late in the division process. Most importantly, the deletion of divIB increases the susceptibility to beta-lactams, more evidently in a resistant strain, suggesting a function in cell wall synthesis.     

The Bacillus subtilis cell division protein FtsL localizes to sites of septation and interacts with DivIC

FtsL is a small bitopic membrane protein required for vegetative cell division and sporulation in Bacillus subtilis. We investigated its localization by fluorescence microscopy using a green fluorescent protein (GFP) fusion. GFP-FtsL was localized at mid-cell in vegetative cells and at the asymmetric septum in sporulating cells. We also show that FtsL forms a ring-like structure at the division site and that it remains localized at mid-cell during the whole septation process. By yeast two-hybrid analysis and non-denaturing polyacrylamide gel electrophoresis (PAGE) with purified proteins, FtsL was found to interact with another membrane-bound division protein, the FtsL-like DivIC protein.     

Membrane-bound division proteins DivIB and DivIC of Bacillus subtilis function solely through their external domains in both vegetative and sporulation division

The Bacillus subtilis membrane-bound division proteins, DivIB and DivIC, each contain a single transmembrane segment flanked by a short cytoplasmic N-terminal domain and a larger external C-terminal domain. Both proteins become localized at the division site prior to septation. Mutagenesis of both divIB and divIC was performed whereby the sequences encoding the cytoplasmic domains were replaced by the corresponding sequence of the other gene. Finally, the cytoplasmic-plus-transmembrane-encoding domain of each protein was replaced by a totally foreign sequence not involved in division, that encodes the N-terminal-plus-transmembrane domains of the Escherichia coli TolR protein. B. subtilis strains expressing the divIB and divIC hybrids, in the absence of the wild-type gene, were viable when grown under conditions in which the wild-type genes were found previously to be essential. Furthermore, these strains were able to sporulate to near normal levels. Thus, the cytoplasmic and transmembrane segments of DivIB and DivIC do not appear to have any specific functions other than to anchor these proteins correctly in the membrane. The implications of these findings are discussed.     

The Bacillus subtilis division protein DivIC is a highly abundant membrane-bound protein that localizes to the division site

The Bacillus subtilis divIC gene is involved in the initiation of cell division. It encodes a 14.7 kDa protein, with a potential transmembrane region near the N-terminus. In this paper, we show that DivIC is associated with the cell membrane and, in conjunction with previously published sequence data, conclude that it is oriented such that its small N-terminus is within the cytoplasm and its larger C-terminus is external to the cytoplasm. DivIC is shown to be a highly abundant division protein, present at approximately 50 000 molecules per cell. Using immunofluorescence microscopy, DivIC was seen to localize at the division site of rapidly dividing cells between well-segregated nucleoids. Various DivIC immunostaining patterns were observed, and these correlated with different cell lengths, suggesting that the DivIC localization takes on various forms during the cell cycle. The DivIC immunolocalization patterns are very similar to those of another membrane-bound B . subtilis division protein, DivIB.     

Evidence from Artificial Septal Targeting and Site-Directed Mutagenesis that Residues in the Extracytoplasmic β Domain of DivIB Mediate Its Interaction with the Divisomal Transpeptidase PBP 2B

Bacterial cytokinesis is achieved through the coordinated action of a multiprotein complex known as the divisome. The Escherichia coli divisome is comprised of at least 10 essential proteins whose individual functions are mostly unknown. Most divisomal proteins have multiple binding partners, making it difficult to pinpoint epitopes that mediate pairwise interactions between these proteins. We recently introduced an artificial septal targeting approach that allows the interaction between pairs of proteins to be studied in vivo without the complications introduced by other interacting proteins (C. Robichon, G. F. King, N. W. Goehring, and J. Beckwith, J. Bacteriol. 190:6048-6059, 2008). We have used this approach to perform a molecular dissection of the interaction between Bacillus subtilis DivIB and the divisomal transpeptidase PBP 2B, and we demonstrate that this interaction is mediated exclusively through the extracytoplasmic domains of these proteins. Artificial septal targeting in combination with mutagenesis experiments revealed that the C-terminal region of the β domain of DivIB is critical for its interaction with PBP 2B. These findings are consistent with previously defined loss-of-function point mutations in DivIB as well as the recent demonstration that the β domain of DivIB mediates its interaction with the FtsL-DivIC heterodimer. These new results have allowed us to construct a model of the DivIB/PBP 2B/FtsL/DivIC quaternary complex that strongly implicates DivIB, FtsL, and DivIC in modulating the transpeptidase activity of PBP 2B.Bacterial cytokinesis is a highly coordinated process that is carried out by a multiprotein complex known as the divisome (9, 11, 37, 39). In Escherichia coli, there are at least 10 essential divisomal proteins that carry out the division process. Divisome formation is initiated at the incipient division site by the recruitment of the FtsZ ring (1) which provides a molecular scaffold onto which the other divisional proteins are subsequently loaded (24, 33) (Fig. ​(Fig.1).1). In E. coli, the first proteins to load after FtsZ are a group of predominantly cytoplasmic proteins (FtsA, ZapA, and ZipA) that stabilize nascent FtsZ protofilaments and tether them to the membrane. The stabilized Z-ring then acts as a platform for recruitment of the remaining essential divisomal proteins, which are all single- or multipass membrane proteins (i.e., FtsE/FtsX, FtsK, FtsQ, FtsB, FtsL, FtsW, FtsI, and FtsN). With the exception of FtsI, a transpeptidase that cross-links septal murein, the biochemical function of these proteins is unknown.Open in a separate windowFIG. 1.Schema showing the hierarchical pathway of divisome assembly in E. coli and B. subtilis (adapted from reference 30). For a protein to be recruited to the divisome, all of the proteins upstream from it in the hierarchical recruitment pathway must already be present at the septum. Groups of proteins that form a subcomplex independent of other divisomal proteins, such as the ternary complex formed between E. coli FtsQ, FtsB, and FtsL, are highlighted by gray boxes. Red lines denote pairwise protein-protein interactions that have been experimentally demonstrated using genetic and/or biochemical approaches. The question mark indicates that the precise location of FtsW in the divisome assembly pathway in B. subtilis is currently unknown. (C) Possible outcomes of a heterologous septal targeting experiment in E. coli in which ZapA-DivIB is employed as the bait and GFP-PBP 2B is the prey. A direct interaction between DivIB and PBP 2B should result in a fluorescent ring at midcell (or a pair of dots when viewed in cross-section) due the recruitment of GFP-PBP 2B to the divisome (left panel). In contrast, a halo of fluorescence should be visible around the cell periphery due to the membrane-bound GFP-PBP 2B if there is no interaction between these two proteins (right panel).Divisomal protein recruitment in both Bacillus subtilis and E. coli occurs in a stepwise manner. For example, for FtsQ to be recruited to the E. coli divisome, all of the proteins upstream from it in the hierarchical recruitment pathway shown in Fig. ​Fig.1A1A must already be present at the septum. However, this pathway is not completely linear; some proteins appear to form subcomplexes prior to their recruitment to the divisome, such as the ternary complex formed between E. coli FtsQ, FtsB, and FtsL (2, 12, 14, 15). The situation in B. subtilis is more complex and less well understood. For example, B. subtilis DivIB, DivIC, FtsL, and PBP 2B appear to be recruited to the septum as an interdependent group late in the cell cycle (10) (Fig. ​(Fig.1B).1B). To further complicate matters, once these individual proteins or subcomplexes have been recruited to the divisome, they engage in a complex network of protein-protein interactions with other divisomal proteins (7, 8, 18, 23).The plethora of protein-protein interactions at the bacterial divisome makes it difficult to decipher which molecular epitopes on individual proteins mediate their interaction with other divisomal proteins. Thus, we recently introduced an artificial septal targeting (AST) technique that allowed us to examine interactions between pairs of interacting B. subtilis divisomal proteins in E. coli (30). This technique involves artificially targeting one of the B. subtilis proteins (the “bait”) to the E. coli divisome by fusing it to E. coli ZapA and then using fluorescence microscopy to determine whether it can recruit to the septum a green fluorescent protein (GFP) fusion to a putative interacting partner (the “prey”) (Fig. ​(Fig.1C).1C). The primary advantage of the AST technique is that it allows direct assessment of the interaction between two B. subtilis divisomal proteins without interference from other members of the divisome.We previously used AST to demonstrate a direct interaction between B. subtilis FtsL and DivIC and between DivIB and PBP 2B (30). The latter finding is consistent with the observation from bacterial two-hybrid studies that B. subtilis DivIB interacts directly with both PBP 2B and FtsL (5) and that the E. coli orthologs of these proteins (FtsI and FtsQ, respectively) also interact strongly (18). The extracellular domain of DivIB is divided into three subdomains, termed α, β, and γ (31). It was recently shown using a combination of nuclear magnetic resonance (NMR) spectroscopy and small-angle X-ray scattering (SAXS) that the concave face of the DivIB β domain makes direct contact with the C-terminal head of the FtsL-DivIC heterodimeric coiled coil (25), forming a stabilizing “cap” for these two intrinsically unstable proteins (32). In contrast, the α and γ regions of DivIB are not critical for formation of the DivIB/FtsL/DivIC ternary complex (25).The FtsQ/DivIB-FtsI/PBP 2B interaction appears to be widely conserved in both Gram-negative and Gram-positive bacteria, and therefore we decided to investigate the molecular details of this evolutionarily conserved interaction. By using a combination of AST and site-directed mutagenesis, we show that DivIB and PBP 2B interact exclusively through their extracytoplasmic regions and that this interaction is mediated by residues near the C terminus of DivIB. In combination with the results of previous studies, these new data have allowed us to construct a working model of the DivIB/PBP 2B/FtsL/DivIC complex.     

Analysis of the essential cell division gene ftsL of Bacillus subtilis by mutagenesis and heterologous complementation

The ftsL gene is required for the initiation of cell division in a broad range of bacteria. Bacillus subtilis ftsL encodes a 13-kDa protein with a membrane-spanning domain near its N terminus. The external C-terminal domain has features of an alpha-helical leucine zipper, which is likely to be involved in the heterodimerization with another division protein, DivIC. To determine what residues are important for FtsL function, we used both random and site-directed mutagenesis. Unexpectedly, all chemically induced mutations fell into two clear classes, those either weakening the ribosome-binding site or producing a stop codon. It appears that the random mutagenesis was efficient, so many missense mutations must have been generated but with no phenotypic effect. Substitutions affecting hydrophobic residues in the putative coiled-coil domain, introduced by site-directed mutagenesis, also gave no observable phenotype except for insertion of a helix-breaking proline residue, which destroyed FtsL function. ftsL homologues cloned from three diverse Bacillus species, Bacillus licheniformis, Bacillus badius, and Bacillus circulans, could complement an ftsL null mutation in B. subtilis, even though up to 66% of the amino acid residues of the predicted proteins were different from B. subtilis FtsL. However, the ftsL gene from Staphylococcus aureus (whose product has 73% of its amino acids different from those of the B. subtilis ftsL product) was not functional. We conclude that FtsL is a highly malleable protein that can accommodate a large number of sequence changes without loss of function.     

Artificial septal targeting of Bacillus subtilis cell division proteins in Escherichia coli: an interspecies approach to the study of protein-protein interactions in multiprotein complexes

Bacterial cell division is mediated by a set of proteins that assemble to form a large multiprotein complex called the divisome. Recent studies in Bacillus subtilis and Escherichia coli indicate that cell division proteins are involved in multiple cooperative binding interactions, thus presenting a technical challenge to the analysis of these interactions. We report here the use of an E. coli artificial septal targeting system for examining the interactions between the B. subtilis cell division proteins DivIB, FtsL, DivIC, and PBP 2B. This technique involves the fusion of one of the proteins (the “bait”) to ZapA, an E. coli protein targeted to mid-cell, and the fusion of a second potentially interacting partner (the “prey”) to green fluorescent protein (GFP). A positive interaction between two test proteins in E. coli leads to septal localization of the GFP fusion construct, which can be detected by fluorescence microscopy. Using this system, we present evidence for two sets of strong protein-protein interactions between B. subtilis divisomal proteins in E. coli, namely, DivIC with FtsL and DivIB with PBP 2B, that are independent of other B. subtilis cell division proteins and that do not disturb the cytokinesis process in the host cell. Our studies based on the coexpression of three or four of these B. subtilis cell division proteins suggest that interactions among these four proteins are not strong enough to allow the formation of a stable four-protein complex in E. coli in contrast to previous suggestions. Finally, our results demonstrate that E. coli artificial septal targeting is an efficient and alternative approach for detecting and characterizing stable protein-protein interactions within multiprotein complexes from other microorganisms. A salient feature of our approach is that it probably only detects the strongest interactions, thus giving an indication of whether some interactions suggested by other techniques may either be considerably weaker or due to false positives.     

Localization of FtsL to the Escherichia coli septal ring

In Escherichia coli, nine gene products are known to be essential for assembly of the division septum. One of these, FtsL, is a bitopic membrane protein whose precise function is not understood. Here we use fluorescence microscopy to study the subcellular localization of FtsL, both in a wild-type strain and in a merodiploid strain that expresses a GFP-FtsL fusion protein. We show that FtsL localizes to the cell septum where it forms a ring analogous to the cytoplasmic FtsZ ring. FtsL localization is dependent upon the function of FtsZ, FtsA and FtsQ, but not FtsI. In a reverse approach, we use fusions of green fluorescent protein (GFP) to FtsZ, FtsA and ZipA to show that these proteins localize to the division site in an FtsL-independent fashion. We propose that FtsL is a relatively late recruit to the ring structure that mediates septation.     

DivIC Stabilizes FtsL against RasP Cleavage

The essential cell division protein FtsL is a substrate of the intramembrane protease RasP. Using heterologous coexpression experiments, we show here that the division protein DivIC stabilizes FtsL against RasP cleavage. Degradation seems to be initiated upon accessibility of a cytosolic substrate recognition motif.Cell division in bacteria is a highly regulated process (1). The division site selection as well as assembly and disassembly of the divisome have to be strictly controlled (1, 4). Although the spatial control of the divisome is relatively well understood (2, 4, 14, 17), mechanisms governing the temporal control of division are still mainly elusive. Regulatory proteolysis was thought to be a potential modulatory mechanism (8, 9). The highly unstable division protein FtsL was shown to be rate limiting for division and would make an ideal candidate for a regulatory factor in the timing of bacterial cell division (7, 9). In Bacillus subtilis, FtsL is an essential protein of the membrane part of the divisome (5, 7, 8). It is necessary for the assembly of the membrane-spanning division proteins, and a knockout is lethal (8, 9, 12). We have previously reported that FtsL is a substrate of the intramembrane protease RasP (5).These findings raised the question of whether RasP can regulate cell division by cleaving FtsL from the division complex. In order to mimic the situation in which FtsL is bound to at least one of its interaction partners, we used a heterologous coexpression system in which we synthesized FtsL and DivIC. It has been reported before that DivIC and FtsL are intimate binding partners in various organisms (6, 9, 15, 21, 22, 26) and that FtsL and DivIC (together with DivIB) can form complexes even in the absence of the other divisome components (6, 21). We therefore asked whether RasP is able to cleave FtsL in the presence of its major interaction partner DivIC, which would argue for the possibility that RasP could cleave FtsL within a mature divisome. In contrast, if interaction with DivIC could stabilize FtsL against RasP cleavage, this result would bring such a model into question. An alternative option for the role of RasP might be the removal of FtsL from the membrane. It has been shown that divisome disassembly and prevention of reassembly are crucial to prevent minicell formation close to the new cell poles (3, 16).     

The use of flash photolysis for a high-resolution temporal and spatial analysis of bacterial chemotactic behaviour: CheZ is not always necessary for chemotaxis

The Bacillus subtilis cell-division protein DivIB is shown to be present at an ≈100-fold higher abundance (≈5000 molecules per cell) than its Escherichia coli FtsQ homologue. B. subtilis contains much more DivIB (at least 60-fold) than is needed to maintain the normal rate of cell division at moderate temperatures (up to 37°C). However, a high level of DivIB is needed to achieve the normal rate of division at high temperature (47°C). It is proposed that membrane-bound DivIB is involved in stabilizing or promoting the assembly of the division complex (which is intrinsically temperature sensitive) in a manner that requires more of the protein at higher temperatures. The (at least) 60-fold accumulation of DivIB and FtsZ from an undetectable level, following germination and outgrowth of spores up until the stage of the first cell division, was unaffected by blocking of initiation of the first round of replication. It is concluded that there is no major synthesis of either of these 'division initiation' proteins linked to initiation, progression or completion of the first round of replication accompanying spore outgrowth.     

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.     

Regulated intramembrane proteolysis of FtsL protein and the control of cell division in Bacillus subtilis

The small bitopic division protein FtsL is an essential part of the division machinery (divisome) in most eubacteria. In Bacillus subtilis FtsL is a highly unstable protein and the turnover has been implicated in regulation of division in response to DNA damage. N-terminal deletions and a domain swap experiment identified the short cytoplasmic domain of FtsL as being required for instability. We then identified a zinc metalloprotease, YluC, required for turnover, and likely sequence motifs involved in substrate recognition. YluC belongs to the site-2-protease (S2P) family of proteases involved in regulated intramembrane proteolysis (RIP), which plays a role in diverse regulatory phenomena from bacteria to man. The yluC mutant, and strains with N-terminal truncations of ftsL have a short cell phenotype, indicating that that FtsL is normally rate-limiting for division. Coexpression experiments of FtsL and YluC in Escherichia coli corroborated a model in which FtsL is directly cleaved by the membrane metalloprotease. The results shed new light on the regulation of cell division in B. subtilis and identify a novel class of targets for RIP.     

The divisomal protein DivIB contains multiple epitopes that mediate its recruitment to incipient division sites

Bacterial cytokinesis is orchestrated by an assembly of essential cell division proteins that form a supramolecular structure known as the divisome. DivIB and its orthologue FtsQ are essential members of the divisome in Gram-positive and Gram-negative bacteria respectively. DivIB is a bitopic membrane protein composed of an N-terminal cytoplasmic domain, a single-pass transmembrane domain, and a C-terminal extracytoplasmic region comprised of three separate protein domains. A molecular dissection approach was used to determine which of these domains are essential for recruitment of DivIB to incipient division sites and for its cell division functions. We show that DivIB has three molecular epitopes that mediate its localization to division septa; two epitopes are encoded within the extracytoplasmic region while the third is located in the transmembrane domain. It is proposed that these epitopes represent sites of interaction with other divisomal proteins, and we have used this information to develop a model of the way in which DivIB and FtsQ are integrated into the divisome. Remarkably, two of the three DivIB localization epitopes are dispensable for vegetative cell division; this suggests that the divisome is assembled using a complex network of protein–protein interactions, many of which are redundant and likely to be individually non-essential.