The periseptal annulus: An organelle associated with cell division in Gram-negative bacteria

MacAlister, T J; MacDonald, Brian; Rothfield, Lawrence

doi:10.1073/pnas.80.5.1372

Cited by 56 publications

(53 citation statements)

References 9 publications

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“…6 and S2; Movies S2 and S3). These structures may be related to the periseptal annulus observed prior to the separation of the cytoplasmic cylinders in E. coli and Salmonella typhimurium (Macalister et al, 1983;Cook et al, 1987). More recently, slower diffusion of periplasmic proteins was observed at the constriction site at a late stage of C. crescentus cell division (Judd et al, 2005); consistent with a the transient occurrence of periplasmic periseptal structures.…”

Section: Novel Structures In Dividing Cellssupporting

confidence: 51%

Native cellular architecture of Treponema denticola revealed by cryo-electron tomography

Izard¹,

Hsieh²,

Limberger³

et al. 2008

Journal of Structural Biology

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Using cryo-electron tomography, we are developing a refined description of native cellular structures in the pathogenic spirochete Treponema denticola. Tightly organized bundles of periplasmic flagella were readily observed in intact plunge-frozen cells. The periplasmic space was measured in both wild-type and aflagellate strains, and found to widen by less than the diameter of flagella when the latter are present. This suggests that a structural change occurs in the peptidoglycan layer to accommodate the presence of the flagella. In dividing cells, the flagellar filaments were found to bridge the cytoplasmic cylinder constriction site. Cytoplasmic filaments, adjacent to the inner membrane, run parallel to the tightly organized flagellar filaments. The cytoplasmic filaments may be anchored by a narrow plate-like structure. The tapering of the cell ends was conserved between cells, with a patella-shaped structure observed in the periplasm at the tip of each cytoplasmic cylinder. Several incompletely characterized structures have been observed in the periplasm between dividing cells, including a cable-like structure linking two cytoplasmic cylinders and complex foil-shaped structures.

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Section: Novel Structures In Dividing Cellssupporting

confidence: 51%

Native cellular architecture of Treponema denticola revealed by cryo-electron tomography

Izard¹,

Hsieh²,

Limberger³

et al. 2008

Journal of Structural Biology

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“…1E and F). These circumferential junctions resemble the periseptal annuli described for several other eubacteria (32). The junctions separate the part of the periplasmic space between the outer membrane and the peptidoglycan of the single cells within the filaments.…”

Section: Morphology Of Cell Walls In Conventional Preparationsmentioning

confidence: 80%

Envelope structure of four gliding filamentous cyanobacteria

1995

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The cell walls of four gliding filamentous Oscillatoriaceae species comprising three different genera were studied by freeze substitution, freeze fracturing, and negative staining. In all species, the multilayered gramnegative cell wall is covered with a complex external double layer. The first layer is a tetragonal crystalline S-layer anchored on the outer membrane. The second array is formed by parallel, helically arranged surface fibrils with diameters of 8 to 12 nm. These fibrils have a serrated appearance in cross sections. In all cases, the orientation of the surface fibrils correlates with the sense of revolution of the filaments during gliding, i.e., clockwise in both Phormidium strains and counterclockwise in Oscillatoria princeps and Lyngbya aeruginosa. The lack of longitudinal corrugations or contractions of the surface fibrils and the identical appearances of motile and nonmotile filaments suggest that this structure plays a passive screw thread role in gliding. It is hypothesized that the necessary propulsive force is generated by shear forces between the surface fibrils and the continuing flow of secreted extracellular slime. Furthermore, the so-called junctional pores seem to be the extrusion sites of the slime. In motile cells, these pores exhibit a different staining behavior than that seen in nonmotile ones. In the former, the channels of the pores are filled with electron-dense material, whereas in the latter, the channels appear comparatively empty, highly contrasting the peptidoglycan. Finally, the presence of regular surface structures in other gliding prokaryotes is considered an indication that comparable structures are general features of the cell walls of gliding microbes.Many multicellular, filamentous cyanobacteria move on solid surfaces by a type of motility described as gliding. Gliding is not exclusive to cyanobacteria but rather is widespread among prokaryotes (for a review, see references 3 and 20). It is unknown whether gliding motility is in all cases based on a common mechanism.Gliding of the nonpolar, filamentous cyanobacteria appears as a slow uniform motion, occasionally interrupted by reversals (13). Neither wriggling nor contraction nor peristaltic alterations of the filamentous trichomes are detectable by light microscopy (38). Members of the Oscillatoriaceae translocate in a highly coordinated manner. Translational movements are accompanied in most species by revolution around the long axis of the filament (4). While moving, the trichomes secrete slime which is left behind as a twisted and collapsed thin tube (20). The sense of revolution is unique and species specific (46), as evinced by the handedness of the rotation.The lack of flagella or of other plausible locomotive organelles is puzzling. Electron microscopic studies have so far failed to identify motor structures common among gliders. A number of unusual structures have been described which may or may not be related to this peculiar type of motility. This list comprises spinning discs (37), fibrils within the ce...

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“…Because the doublet is first visible as a pair of closely apposed individual rings that then move apart, it is possible that the MreB ''singlet'' ring may be a tightly packed doublet. The only other known paired structures that flank the division site are the continuous zones of adhesion (periseptal annuli) between inner membrane and the murein-outer membrane layer that have been reported to extend partially or completely around the cell cylinder on either side of the division site (24,25). It is not known whether there is a relationship between these structures and the MreB doublet elements.…”

Section: Discussionmentioning

confidence: 99%

Duplication and segregation of the actin (MreB) cytoskeleton during the prokaryotic cell cycle

Vats

Rothfield

2007

Proc. Natl. Acad. Sci. U.S.A.

111

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The bacterial actin homolog MreB exists as a single-copy helical cytoskeletal structure that extends between the two poles of rod-shaped bacteria. In this study, we show that equipartition of the MreB cytoskeleton into daughter cells is accomplished by division and segregation of the helical MreB array into two equivalent structures located in opposite halves of the predivisional cell. This process ensures that each daughter cell inherits one copy of the MreB cytoskeleton. The process is triggered by the membrane association of the FtsZ cell division protein. The cytoskeletal division and segregation events occur before and independently of cytokinesis and involve specialized MreB structures that appear to be intermediates in this process.septasome ͉ FtsZ ͉ cell division

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The periseptal annulus: An organelle associated with cell division in Gram-negative bacteria

Cited by 56 publications

References 9 publications

Native cellular architecture of Treponema denticola revealed by cryo-electron tomography

Native cellular architecture of Treponema denticola revealed by cryo-electron tomography

Envelope structure of four gliding filamentous cyanobacteria

Duplication and segregation of the actin (MreB) cytoskeleton during the prokaryotic cell cycle

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