Conformational equilibrium of MinE regulates the allowable concentration ranges of a protein wave for cell division

Shunshi Kohyama; Kei Fujiwara; Natsuhiko Yoshinaga; Nobuhide Doi

doi:10.1039/d0nr00242a

The C-Terminal Domain of MinC Inhibits Assembly of the Z Ring in Escherichia coli

Journal of Bacteriology ◽

10.1128/jb.00666-06 ◽

2006 ◽

Vol 189 (1) ◽

pp. 236-243 ◽

Cited By ~ 43

Author(s):

Daisuke Shiomi ◽

William Margolin

Keyword(s):

Escherichia Coli ◽

Cell Division ◽

Fluorescent Protein ◽

Additional Function ◽

Ring Assembly ◽

C Terminus ◽

Min Proteins ◽

Z Ring ◽

Ftsz Assembly ◽

Green Fluorescent

ABSTRACT In Escherichia coli, the Min system, consisting of three proteins, MinC, MinD, and MinE, negatively regulates FtsZ assembly at the cell poles, helping to ensure that the Z ring will assemble only at midcell. Of the three Min proteins, MinC is sufficient to inhibit Z-ring assembly. By binding to MinD, which is mostly localized at the membrane near the cell poles, MinC is sequestered away from the cell midpoint, increasing the probability of Z-ring assembly there. Previously, it has been shown that the two halves of MinC have two distinct functions. The N-terminal half is sufficient for inhibition of FtsZ assembly, whereas the C-terminal half of the protein is required for binding to MinD as well as to a component of the division septum. In this study, we discovered that overproduction of the C-terminal half of MinC (MinC122-231) could also inhibit cell division and that this inhibition was at the level of Z-ring disassembly and dependent on MinD. We also found that fusing green fluorescent protein to either the N-terminal end of MinC122-231, the C terminus of full-length MinC, or the C terminus of MinC122-231 perturbed MinC function, which may explain why cell division inhibition by MinC122-231 was not detected previously. These results suggest that the C-terminal half of MinC has an additional function in the regulation of Z-ring assembly.

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Intrinsic characteristics of Min proteins on the cell division ofHelicobacter pylori

FEMS Microbiology Letters ◽

10.1093/femsle/fnw025 ◽

2016 ◽

Vol 363 (6) ◽

pp. fnw025 ◽

Cited By ~ 2

Author(s):

Yoshie Nishida ◽

Hiroaki Takeuchi ◽

Norihito Morimoto ◽

Akiko Umeda ◽

Yoshu Kadota ◽

...

Keyword(s):

Cell Division ◽

Min Proteins

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MinC Mutants Deficient in MinD- and DicB-Mediated Cell Division Inhibition Due to Loss of Interaction with MinD, DicB, or a Septal Component

Journal of Bacteriology ◽

10.1128/jb.187.8.2846-2857.2005 ◽

2005 ◽

Vol 187 (8) ◽

pp. 2846-2857 ◽

Cited By ~ 36

Author(s):

Huaijin Zhou ◽

Joe Lutkenhaus

Keyword(s):

Cell Division ◽

Regulatory System ◽

Ring Formation ◽

Cellular Location ◽

Terminal Domain ◽

Min Proteins ◽

Z Ring ◽

Cell Division Inhibition

ABSTRACT The min locus encodes a negative regulatory system that limits formation of the cytokinetic Z ring to midcell by preventing its formation near the poles. Of the three Min proteins, MinC is the inhibitor and prevents Z-ring formation by interacting directly with FtsZ. MinD activates MinC by recruiting it to the membrane and conferring a higher affinity on the MinCD complex for a septal component. MinE regulates the cellular location of MinCD by inducing MinD, and thereby MinC, to oscillate between the poles of the cell, resulting in a time-averaged concentration of MinCD on the membrane that is lowest at midcell. MinC can also be activated by the prophage-encoded protein DicB, which targets MinC to the septum without recruiting it first to the membrane. Previous studies have shown that the C-terminal domain of MinC is responsible for the interaction with MinD, DicB, and the septal component. In the present study, we isolated mutations in the C-terminal domain of MinC that affected its interaction with MinD, DicB, and the septal component. Among the mutations isolated, R133A and S134A are specifically deficient in the interaction with MinD, E156A is primarily affected in the interaction with DicB, and R172A is primarily deficient in the interaction with the septum. These mutations differentiate the interactions of MinC with its partners and further support the model of MinCD- and MinC-DicB-mediated cell division inhibition.

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Bacterial Min proteins beyond the cell division

Critical Reviews in Microbiology ◽

10.1080/1040841x.2018.1538932 ◽

2018 ◽

Vol 45 (1) ◽

pp. 22-32

Author(s):

Ashoka Chary Taviti ◽

Tushar Kant Beuria

Keyword(s):

Cell Division ◽

Min Proteins

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Cellular Architecture Mediates DivIVA Ultrastructure and Regulates Min Activity in Bacillus subtilis

mBio ◽

10.1128/mbio.00257-11 ◽

2011 ◽

Vol 2 (6) ◽

Cited By ~ 75

Author(s):

Prahathees Eswaramoorthy ◽

Marcella L. Erb ◽

James A. Gregory ◽

Jared Silverman ◽

Kit Pogliano ◽

...

Keyword(s):

Bacillus Subtilis ◽

Cell Division ◽

Spatial Organization ◽

Time Lapse ◽

Structured Illumination ◽

Structured Illumination Microscopy ◽

Content Type ◽

Temporal Regulation ◽

Min Proteins

ABSTRACTThe assembly of the cell division machinery at midcell is a critical step of cytokinesis. Many rod-shaped bacteria position septa using nucleoid occlusion, which prevents division over the chromosome, and the Min system, which prevents division near the poles. Here we examined thein vivoassembly of theBacillus subtilisMinCD targeting proteins DivIVA, a peripheral membrane protein that preferentially localizes to negatively curved membranes and resembles eukaryotic tropomyosins, and MinJ, which recruits MinCD to DivIVA. We used structured illumination microscopy to demonstrate that both DivIVA and MinJ localize as double rings that flank the septum and first appear early in septal biosynthesis. The subsequent recruitment of MinCD to these double rings would separate the Min proteins from their target, FtsZ, spatially regulating Min activity and allowing continued cell division. Curvature-based localization would also provide temporal regulation, since DivIVA and the Min proteins would localize to midcell after the onset of division. We use time-lapse microscopy and fluorescence recovery after photobleaching to demonstrate that DivIVA rings are highly stable and are constructed from newly synthesized DivIVA molecules. After cell division, DivIVA rings appear to collapse into patches at the rounded cell poles of separated cells, with little or no incorporation of newly synthesized subunits. Thus, changes in cell architecture mediate both the initial recruitment of DivIVA to sites of cell division and the subsequent collapse of these rings into patches (or rings of smaller diameter), while curvature-based localization of DivIVA spatially and temporally regulates Min activity.IMPORTANCEThe Min systems ofEscherichia coliandBacillus subtilisboth inhibit FtsZ assembly, but one key difference between these two species is that whereas theE. coliMin proteins localize to the poles, theB. subtilisproteins localize to nascent division sites by interaction with DivIVA and MinJ. It is unclear how MinC activity at midcell is regulated to prevent it from interfering with FtsZ engaged in medial cell division. We used superresolution microscopy to demonstrate that DivIVA and MinJ, which localize MinCD, assemble double rings that flank active division sites and septa. This curvature-based localization mechanism holds MinCD away from the FtsZ ring at midcell, and we propose that this spatial organization is the primary mechanism by which MinC activity is regulated to allow division at midcell. Curvature-based localization also conveys temporal regulation, since it ensures that MinC localizes after the onset of division.

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The Ultrastructure of the Nuclear Events of Binary Fission in Paramecium bursaria and the Effects of Colchicine on Cell Division

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100051396 ◽

1974 ◽

Vol 32 ◽

pp. 276-277

Author(s):

L. M. Lewis

Keyword(s):

Cell Division ◽

Nuclear Envelope ◽

Condensed Chromatin ◽

Binary Fission ◽

Paramecium Bursaria ◽

Nuclear Events ◽

Division Axis

The effects of colchicine on extranuclear microtubules associated with the macronucleus of Paramecium bursaria were studied to determine the possible role that these microtubules play in controlling the shape of the macronucleus. In the course of this study, the ultrastructure of the nuclear events of binary fission in control cells was also studied.During interphase in control cells, the micronucleus contains randomly distributed clumps of condensed chromatin and microtubular fragments. Throughout mitosis the nuclear envelope remains intact. During micronuclear prophase, cup-shaped microfilamentous structures appear that are filled with condensing chromatin. Microtubules are also present and are parallel to the division axis.

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Stimulated Virus Production in Vinblastine and Cytochalasin-Induced Multinucleate Cells

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100067923 ◽

1970 ◽

Vol 28 ◽

pp. 186-187

Author(s):

Krishan Awtar

Keyword(s):

Cell Division ◽

Normal Cell ◽

Virus Production ◽

Multinucleate Cells ◽

Daughter Cells ◽

Cell Divisions ◽

Nuclear Membranes ◽

Division 2 ◽

Vinblastine Sulfate

Exposure of cells to low sublethal but mitosis-arresting doses of vinblastine sulfate (Velban) results in the initial arrest of cells in mitosis followed by their subsequent return to an “interphase“-like stage. A large number of these cells reform their nuclear membranes and form large multimicronucleated cells, some containing as many as 25 or more micronuclei (1). Formation of large multinucleate cells is also caused by cytochalasin, by causing the fusion of daughter cells at the end of an otherwise .normal cell division (2). By the repetition of this process through subsequent cell divisions, large cells with 6 or more nuclei are formed.

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Confocal microscopy of the cytoskeleton in living plant cells following microinjection of fluorescent probes

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100146497 ◽

1993 ◽

Vol 51 ◽

pp. 130-131

Author(s):

Ann Cleary

Keyword(s):

Cell Division ◽

Fluorescent Probes ◽

Actin Filaments ◽

Intracellular Transport ◽

Cell Structure ◽

Plant Cells ◽

Cell Plate ◽

Cell Cortex ◽

Living Plant ◽

Rhodamine Phalloidin

Microinjection of fluorescent probes into living plant cells reveals new aspects of cell structure and function. Microtubules and actin filaments are dynamic components of the cytoskeleton and are involved in cell growth, division and intracellular transport. To date, cytoskeletal probes used in microinjection studies have included rhodamine-phalloidin for labelling actin filaments and fluorescently labelled animal tubulin for incorporation into microtubules. From a recent study of Tradescantia stamen hair cells it appears that actin may have a role in defining the plane of cell division. Unlike microtubules, actin is present in the cell cortex and delimits the division site throughout mitosis. Herein, I shall describe actin, its arrangement and putative role in cell plate placement, in another material, living cells of Tradescantia leaf epidermis.The epidermis is peeled from the abaxial surface of young leaves usually without disruption to cytoplasmic streaming or cell division. The peel is stuck to the base of a well slide using 0.1% polyethylenimine and bathed in a solution of 1% mannitol +/− 1 mM probenecid.

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Electronmicroscopic localization of ribonucleic acids in ciliate Bursaria truncatella during cell division

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100158200 ◽

1990 ◽

Vol 48 (3) ◽

pp. 132-133

Author(s):

Vladimir Popenko ◽

Natalya Cherny ◽

Maria Yakovleva

Keyword(s):

Cell Division ◽

High Specificity ◽

Longitudinal Axis ◽

Gold Complexes ◽

Somatic Nucleus ◽

Ribonucleic Acids ◽

Biological Meaning ◽

Bivalent Cations ◽

Lowicryl K4m ◽

Short Time

Highly polyploid somatic nucleus (macronucleus) of ciliate Bursaria truncatella under goes severe changes in morphology during cell division. At first, macronucleus (Ma) condences, diminishes in size and turns perpendicular to longitudinal axis of the cell. After short time, Ma turns again, elongates and only afterwards the process of division itself occurs. The biological meaning of these phenomena is not clear.Localization of RNA in the cells was performed on sections of ciliates B. truncatella, embedded in “Lowicryl K4M” at various stages: (1) before cell division (Figs. 2,3); (11) at the stage of macronucleus condensation; (111) during elongation of Ma (Fig.4); (1111) in young cells (0-5min. after division). For cytochemical labelling we used RNaseAcolloidal gold complexes (RNase-Au), which are known to bind to RNA containing cell ularstructures with high specificity. The influence of different parameters on the reliability and reproducibility of labelling was studied. In addition to the factors, discussed elsewhere, we found that the balance of mono- and bivalent cations is of great significance.

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Centromere assembly and non-random sister chromatid segregation in stem cells

Essays in Biochemistry ◽

10.1042/ebc20190066 ◽

2020 ◽

Vol 64 (2) ◽

pp. 223-232 ◽

Cited By ~ 1

Author(s):

Ben L. Carty ◽

Elaine M. Dunleavy

Keyword(s):

Stem Cells ◽

Cell Division ◽

Cell Fate ◽

Sister Chromatid ◽

Asymmetric Cell Division ◽

Protein A ◽

Germline Stem Cells ◽

Sister Chromatids ◽

Centromere Protein A ◽

Oocyte Meiosis

Abstract Asymmetric cell division (ACD) produces daughter cells with separate distinct cell fates and is critical for the development and regulation of multicellular organisms. Epigenetic mechanisms are key players in cell fate determination. Centromeres, epigenetically specified loci defined by the presence of the histone H3-variant, centromere protein A (CENP-A), are essential for chromosome segregation at cell division. ACDs in stem cells and in oocyte meiosis have been proposed to be reliant on centromere integrity for the regulation of the non-random segregation of chromosomes. It has recently been shown that CENP-A is asymmetrically distributed between the centromeres of sister chromatids in male and female Drosophila germline stem cells (GSCs), with more CENP-A on sister chromatids to be segregated to the GSC. This imbalance in centromere strength correlates with the temporal and asymmetric assembly of the mitotic spindle and potentially orientates the cell to allow for biased sister chromatid retention in stem cells. In this essay, we discuss the recent evidence for asymmetric sister centromeres in stem cells. Thereafter, we discuss mechanistic avenues to establish this sister centromere asymmetry and how it ultimately might influence cell fate.

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