Characterization of the FtsZ-Interacting Septal Proteins SepF and Ftn6 in the Spherical-Celled Cyanobacterium Synechocystis Strain PCC 6803

Assembly of the tubulin-like cytoskeletal protein FtsZ into a ring structure at midcell establishes the location of the nascent division sites in prokaryotes. However, it is not yet known how the assembly and contraction of the Z ring are regulated, especially in cyanobacteria, the environmentally crucial organisms for which only one FtsZ partner protein, ZipN, has been described so far. Here, we characterized SepF and Ftn6, two novel septal proteins, in the spherical-celled strain Synechocystis PCC 6803. Both proteins were found to be indispensable to Synechocystis sp. strain PCC 6803. The depletion of both SepF and Ftn6 resulted in delayed cytokinesis and the generation of giant cells but did not prevent FtsZ polymerization, as shown by the visualization of green fluorescent protein (GFP)-tagged FtsZ polymers. These GFP-tagged Z-ring-like structures often appeared to be abnormal, because these reporter cells respond to the depletion of either SepF or Ftn6 with an increased abundance of total, natural, and GFP-tagged FtsZ proteins. In agreement with their septal localization, we found that both SepF and Ftn6 interact physically with FtsZ. Finally, we showed that SepF, but not Ftn6, stimulates the formation and/or stability of FtsZ polymers in vitro.Binary fission of a mother cell to form two daughter cells is a widely conserved cell proliferation mechanism. In nearly all bacteria, cell division is initiated by the polymerization into a ring-like structure at midcell of the tubulin homolog GTPase protein FtsZ, which is also found in some archae, as well as in plastids and some mitochondria (for reviews, see references 7, 21, and 33). The Z-ring is subsequently used as a scaffold for recruitment of downstream factors that execute the synthesis of the division septum. The assembly of this complex, also referred to as the divisome, has been thoroughly investigated in studies of the rod-shaped model organisms Escherichia coli and Bacillus subtilis) (for reviews, see references 3, 4, 7, 9, 11, 19, and 21). In E. coli, more than 10 different proteins are required for the progression and completion of cell division. They are designated Fts proteins because their depletion leads to filamentation of the bacteria, and they are recruited to the division site in the following sequential order: FtsZ→FtsA/ZipA/ZapB→FtsK→FtsQ and FtsL/FtsB→FtsW→FtsI and FtsN.The stability of the FtsZ protofilaments is thought to be important for assembly of the septal Z ring. Four FtsZ-interacting proteins have been shown to promote FtsZ polymerization and/or Z-ring stabilization, namely, ZapA and ZipA (found only in gammaproteobacteria), FtsA (an actin-like protein), and SepF (not found in gammaproteobacteria) (10, 31). Both FtsA and ZipA assemble at the Z-ring early and participate in its anchorage to the inner face of the cytoplasmic membrane of the cell. They also participate in the recruitment of the downstream cytokinetic factor FtsK. Subsequently, the recruitment of FtsQ and the FtsB/FtsL complex allow the progressive assembly of downstream factors (FtsW, FtsI, and FtsN) involved in synthesis of the septal cell wall (7).By contrast, the negative regulatory proteins MinCDE, DivIVA, EzrA, SulA, and Noc operate in the destabilization and positioning of the Z-ring at midcell (7, 21, 30), sometimes through a direct interaction with FtsZ (SulA, MinC, and ErzA).Little is known concerning cell division in cyanobacteria, in spite of their crucial importance to the biosphere (5, 27, 34) and their interest for biotechnologists (1, 6, 32). Cyanobacteria are also attractive because many species (such as E. coli and B. subtilis) exhibit a cylindrical morphology with a well-defined middle, whereas many others have a spherical shape (29) and thus possess an infinite number of potential division planes at the point of greatest cell diameter. Furthermore, as the progenitor of the chloroplasts (8), cyanobacteria can be of help for deciphering the stromal chloroplastic division machinery (33). Interestingly, several cell division factors occurring in E. coli and B. subtilis have been shown (FtsZ, MinCDE, and SulA) or proposed (FtsE, FtsI, FtsQ, and FtsW) to be conserved in cyanobacteria (23, 26) and chloroplasts (which lack MinC) (33). In contrast, ftsA, ftsB, zipA, ftsK, ftsL, ftsN, and zapA have not been detected in cyanobacteria.So far, cyanobacterial cytokinesis has mainly been investigated using the two unicellular species Synechococcus sp. strain PCC 7942 (rod shaped; hereafter S. elongatus) and Synechocystis sp. strain PCC 6803 (spherical-celled; hereafter Synechocystis sp.) and the filamentous strain Anabaena PCC 7120, all of which possess a fully sequenced genome (http://genome.kazusa.or.jp/cyanobase/) that is easily manipulated (16). Both FtsZ and ZipN/Ftn2/Arc6, a protein occurring only in cyanobacteria (ZipN alternative name, Ftn2]) and plant chloroplasts (Arc6), were found to be crucial for cytokinesis (17, 23, 26) and to physically interact with each other (20, 23). We also reported that the MinCDE system participates in determining the correct positioning of the septal Z ring at midcell (23). In addition, it has recently been shown in studies of Synechococcus sp. that inactivation of both the cdv2 gene (an orthologue of the gene encoding B.subtilis sepF) and the ftn6 gene (present in only some cyanobacteria) promotes filamentation, though their role in cell division has yet to be characterized (16, 26).In a continuous effort to characterize the divisome machine of Synechocystis sp., we have used a combination of in vivo and in vitro techniques for thorough analysis of the SepF and Ftn6 proteins. We report here that both SepF and Ftn6 are crucial cytokinetic proteins that localize at the division site at midcell and whose depletion leads to the formation of giant cells that remain spherical. In agreement with their septal localization, both SepF and Ftn6 were found to interact physically with FtsZ; also, SepF, but not Ftn6, was found to stimulate the formation and/or stability of FtsZ polymers.