Ca2+-mediated GTP-dependent dynamic assembly of bacterial cell division protein FtsZ into asters and polymer networks invitro

Yu, Xuan; Margolin, William

doi:10.1093/emboj/16.17.5455

Cited by 240 publications

(266 citation statements)

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“…Secondly, we examined the well-characterized effects of calcium on FtsZ polymerization. Addition of calcium at 10 mM to FtsZ polymerization assays inhibits the GTPase activity and causes bundling of polymers, resulting in hugely increased light-scattering (Mukherjee & Lutkenhaus, 1999;Scheffers et al, 2000;Yu & Margolin, 1997). We demonstrate that calcium has the same effect on FtsZ polymers in the presence of the GTP-regeneration system (Fig.…”

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confidence: 52%

“…FtsZ is strongly related to a/b-tubulin in terms of threedimensional structure (Lowe & Amos, 1998), the possession of GTPase activity (de Boer et al, 1992;Mukherjee et al, 1993;RayChaudhuri & Park, 1992) and the ability to polymerize in a nucleotide-dependent manner in vitro (Erickson et al, 1996;. Indeed, FtsZ forms a variety of polymeric structures in vitro depending on experimental conditions (Erickson et al, 1996;Lowe & Amos, 1999, 2000Yu & Margolin, 1997); however, all of these represent different arrangements of linear protofilaments.There have been multiple studies of the dynamics of FtsZ polymerization in vitro. In the presence of GDP (Rivas et al, 2000(Rivas et al, , 2001 Sossong et al, 1999) or in the presence of GTP under particular conditions where only single protofilaments are formed (Romberg et al, 2001), polymerization is proposed to be isodesmic.…”

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confidence: 99%

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Dynamic FtsZ polymerization is sensitive to the GTP to GDP ratio and can be maintained at steady state using a GTP-regeneration system

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Addinall

2003

Microbiology

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In vitro polymerization of the essential bacterial cell division protein FtsZ, in the presence of GTP, is rapid and transient due to its efficient binding and hydrolysis of GTP. In contrast, the in vivo polymeric FtsZ structure which drives cell division -the Z-ring -is present in cells for extended periods of time whilst undergoing constant turnover of FtsZ. It is demonstrated that dynamic polymerization of Escherichia coli FtsZ in vitro is sensitive to the ratio of GTP to GDP concentration. Increase of GDP concentration in the presence of a constant GTP concentration reduces both the duration of FtsZ polymerization and the initial light-scattering maximum which occurs upon addition of GTP. It is also demonstrated that by use of a GTP-regeneration system, polymers of FtsZ can be maintained in a steady state for up to 85 min, while preserving their dynamic properties. The authors therefore present the use of a GTP-regeneration system for FtsZ polymerization as an assay more representative of the in vivo situation, where FtsZ polymers are subject to a constant, relatively high GTP to GDP ratio. INTRODUCTIONThe FtsZ protein has a fundamental role in bacterial cell division , is highly conserved throughout the eubacteria and appears to be required for division of chloroplasts, some archaea and some mitochondria (Beech et al., 2000;Vitha et al., 2001;Wang & Lutkenhaus, 1996). FtsZ is a cytoplasmic protein which, at a particular stage in the Escherichia coli cell cycle, locates to the cell centre, forming a polymeric ring (the Z-ring) around the inner circumference of the cytoplasmic membrane Bi & Lutkenhaus, 1991;Dai & Lutkenhaus, 1991; Den Blaauwen et al., 1999;Pla et al., 1991). Invagination of the division septum then follows the shape of the Z-ring as it reduces in diameter until septation is complete Bi & Lutkenhaus, 1991. FtsZ is strongly related to a/b-tubulin in terms of threedimensional structure (Lowe & Amos, 1998), the possession of GTPase activity (de Boer et al., 1992;Mukherjee et al., 1993;RayChaudhuri & Park, 1992) and the ability to polymerize in a nucleotide-dependent manner in vitro (Erickson et al., 1996;. Indeed, FtsZ forms a variety of polymeric structures in vitro depending on experimental conditions (Erickson et al., 1996;Lowe & Amos, 1999, 2000Yu & Margolin, 1997); however, all of these represent different arrangements of linear protofilaments.There have been multiple studies of the dynamics of FtsZ polymerization in vitro. In the presence of GDP (Rivas et al., 2000(Rivas et al., , 2001 Sossong et al., 1999) or in the presence of GTP under particular conditions where only single protofilaments are formed (Romberg et al., 2001), polymerization is proposed to be isodesmic. Under conditions where FtsZ forms more complex polymers, polymerization and the GTPase activity are co-operative (Caplan & Erickson, 2003;Mukherjee & Lutkenhaus, 1999;White et al., 2000).The technique of right-angled light-scattering has proved useful for real-time monitoring of FtsZ polymerization (Mingorance et al., 2001;...

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confidence: 52%

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confidence: 99%

Dynamic FtsZ polymerization is sensitive to the GTP to GDP ratio and can be maintained at steady state using a GTP-regeneration system

Small

Addinall

2003

Microbiology

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“…This bundling can be induced by several factors, such as Ca 2+ (REF. 21), macromolecular crowding 22 and the binding of partner proteins such as ZipA 23 (see FIG. 3).…”

Section: Structure and Assembly Of Ftszmentioning

confidence: 99%

FtsZ and the division of prokaryotic cells and organelles

Margolin

2005

Nat Rev Mol Cell Biol

558

484

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Binary fission of many prokaryotes as well as some eukaryotic organelles depends on the FtsZ protein, which self-assembles into a membrane-associated ring structure early in the division process. FtsZ is homologous to tubulin, the building block of the microtubule cytoskeleton in eukaryotes. Recent advances in genomics and cell-imaging techniques have paved the way for the remarkable progress in our understanding of fission in bacteria and organelles.Duplication of cells occurs by the division of a mother cell into two daughter cells. This process, known as cytokinesis, provides the force to split cells and is spatially regulated to faithfully partition the genetic material. The cytoskeleton has a crucial role in cytokinesis. In animal and fungal cells, a medial ring of actin and myosin, helped by other proteins, contracts to divide the cell. Plant cells use a cell plate, and are guided by actin filaments and microtubules. Prokaryotes, which include bacteria and archaea, possess homologues of eukaryotic cytoskeletal proteins. Most prokaryotes use a tubulin homologue, a protein known as FtsZ, to divide. Eukaryotic organelles such as chloroplasts and mitochondria evolved from bacteria, and all chloroplasts and some mitochondria use FtsZ to divide.FtsZ is thought to be the first protein to localize to the site of future division in bacteria 1 , and it assembles into what is known as the Z ring (FIG. 1). In Escherichia coli, the Z ring recruits at least ten other proteins, all of which are required for the progression and completion of cytokinesis 2 , as will be discussed below. Whereas the cytokinetic apparatus in eukaryotic cells and even organelles can be observed directly in stained thin sections by transmission electron microscopy, the Z ring and its associated factors are not detectable by these methods. This is probably because the protein machinery is largely membrane bound and resides in a densely populated cytoplasmic environment. However, the development of green fluorescent protein (GFP) fusion and improved immunofluorescence techniques over the past 10 years have been crucial in allowing the first direct visualization of many cellular components and their dynamics. For example, using GFP fusions, the dynamics of the Z ring and other components of the cell-division protein machinery can now be visualized in living bacterial cells. The combination of these new cytological tools with genomics and the Competing interests statementThe author declares no competing financial interests. HHS Public Access Author Manuscript Author ManuscriptAuthor ManuscriptAuthor Manuscript already powerful genetics of several model systems have spurred rapid progress in our understanding of the molecular cell biology of bacteria and eukaryotic organelles. This review will discuss how the recent revolutions in genomics and cell biology have provided new evolutionary and mechanistic insights into how bacterial cells and organelles divide. The FtsZ family of proteins Conservation of FtsZFtsZ is a highly conserved protein ...

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“…This is due to the small size of the septum and the high protein density near the septum. In the meantime, in vitro experiments have found a number of FtsZ polymers (Bramhill and Thompson, 1994;Mukherjee and Lutkenhaus, 1994;Erickson, 1995;Yu and Margolin, 1997;Lu et al, 1998;Mukherjee and Lutkenhaus, 1998;Trusca et al, 1998;Löwe and Amos, 1999) that may be related to the in vivo polymer, although it should be kept in mind that in vivo FtsZ polymerisation may be guided by additional factors. Single, curved filaments have been obtained by polymerising FtsZ in solution in the presence of GTP (Lu et al, 1998(Lu et al, , 2000Mukherjee and Lutkenhaus, 1998).…”

Section: Introductionmentioning

confidence: 99%

“…When performed on a lipid monolayer, FtsZ polymerisation yielded minirings . Sheets of laterally aligned filaments have been obtained under many conditions: in the presence of Ca ++ (Yu and Margolin, 1997;Löwe and Amos, 1999), DEAE dextran , and GTP alone. A low resolution three-dimensional reconstruction of Ca ++ -induced M. jannaschii FtsZ sheets revealed that they are composed of antiparallel double protofilaments (Löwe and Amos, 1999).…”

Section: Introductionmentioning

confidence: 99%

Helical Tubes of FtsZ from Methanococcus jannaschii

Löwe¹,

Amos²

2000

Biological Chemistry

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Bacterial cell division depends on the formation of a cytokinetic ring structure, the Z-ring. The bacterial tubulin homologue FtsZ is required for Z-ring formation. FtsZ assembles into various polymeric forms in vitro, indicating a structural role in the septum of bacteria. We have used recombinant FtsZ1 protein from M. jannaschii to produce helical tubes and sheets with high yield using the GTP analogue GMPCPP [guanylyl-(␣,␤)-methylene-diphosphate]. The sheets appear identical to the previously reported Ca ++ -induced sheets of FtsZ from M. jannaschii that were shown to consist of 'thick'-filaments in which two protofilaments run in parallel. Tubes assembled either in Ca ++ or in GMPCPP contain filaments whose dimensions indicate that they could be equivalent to the 'thick'-filaments in sheets. Some tubes are hollow but others are filled by additional protein density. Helical FtsZ tubes differ from eukaryotic microtubules in that the filaments curve around the filament axis with a pitch of ~ 430 Å for Ca ++ -induced tubes or 590 -620 Å for GMPCPP. However, their assembly in vitro as wellordered polymers over distances comparable to the inner circumference of a bacterium may indicate a role in vivo. Their size and stability make them suitable for use in motility assays.

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Ca2+-mediated GTP-dependent dynamic assembly of bacterial cell division protein FtsZ into asters and polymer networks invitro

Cited by 240 publications

References 43 publications

Dynamic FtsZ polymerization is sensitive to the GTP to GDP ratio and can be maintained at steady state using a GTP-regeneration system

Dynamic FtsZ polymerization is sensitive to the GTP to GDP ratio and can be maintained at steady state using a GTP-regeneration system

FtsZ and the division of prokaryotic cells and organelles

Helical Tubes of FtsZ from Methanococcus jannaschii

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