FtsZ is a soluble, tubulin-like GTPase that forms a membrane-associated ring at the division site of bacterial cells. While this ring is thought to drive cell constriction, it is not well understood how it is assembled or how it affects cell wall invagination. Here we report that FtsZ binds directly to a novel integral inner membrane protein in E. coli that we call ZipA. We present genetic and morphological evidence indicating that this interaction is required for cell division, and show that a fluorescent ZipA-Gfp fusion protein is located in a ring structure at the division site, both before and during cell wall invagination. ZipA is an essential component of the division machinery, and, by binding to both FtsZ and the cytoplasmic membrane, is likely to be directly involved in the assembly and/or function of the FtsZ ring.
Of the known essential division proteins in Escherichia coli, FtsN is the last to join the septal ring organelle. FtsN is a bitopic membrane protein with a small cytoplasmic portion and a large periplasmic one. The latter is thought to form an ␣-helical juxtamembrane region, an unstructured linker, and a C-terminal, globular, murein-binding SPOR domain. We found that the essential function of FtsN is accomplished by a surprisingly small essential domain ( E FtsN) of at most 35 residues that is centered about helix H2 in the periplasm. Bacterial cytokinesis is mediated by a ring-shaped apparatus. Assembly of this septal ring (SR; also called the divisome or septasome) begins at the future site of fission, well before cell constriction initiates, and it remains associated with the leading edge of the invaginating cell envelope until fission is completed. The mature ring in Escherichia coli is made up of at least 10 essential division proteins
The bacterial MreB actin cytoskeleton is required for cell shape maintenance in most non-spherical organisms. In rod-shaped cells such as Escherichia coli, it typically assembles along the long axis in a spiral-like configuration just underneath the cytoplasmic membrane. How this configuration is controlled and how it helps dictate cell shape is unclear. In a new genetic screen for cell shape mutants, we identified RodZ (YfgA) as an important transmembrane component of the cytoskeleton. Loss of RodZ leads to misassembly of MreB into non-spiral structures, and a consequent loss of cell shape. A juxta-membrane domain of RodZ is essential to maintain rod shape, whereas other domains on either side of the membrane have critical, but partially redundant, functions. Though one of these domains resembles a DNA-binding motif, our evidence indicates that it is primarily responsible for association of RodZ with the cytoskeleton.
The MinC protein directs placement of the division septum to the middle of Escherichia coli cells by blocking assembly of the division apparatus at other sites. MinD and MinE regulate MinC activity by modulating its cellular location in a unique fashion. MinD recruits MinC to the membrane, and MinE induces MinC/MinD to oscillate rapidly between the membrane of opposite cell halves. Using ®xed cells, we previously found that a MinE±green¯uorescent protein fusion accumulated in an annular structure at or near the midcell, as well as along the membrane on only one side of the ring. Here we show that in living cells, MinE undergoes a rapid localization cycle that appears coupled to MinD oscillation. The results show that MinE is not a ®xed marker for septal ring assembly. Rather, they support a model in which MinE stimulates the removal of MinD from the membrane in a wave-like fashion. These waves run from a midcell position towards the poles in an alternating sequence such that the time-averaged concentration of division inhibitor is lowest at midcell.
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