Splitsville: structural and functional insights into the dynamic bacterial Z ring

Key Points All cells must divide to proliferate, and most bacteria divide by splitting themselves into two during cytokinesis. Many bacteria divide by splitting into approximately equal halves in a process called binary fission. Cytokinesis in bacteria is achieved by the divisome, a dedicated protei...

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Veröffentlicht in:	Nature reviews. Microbiology 2016-05, Vol.14 (5), p.305-319
Hauptverfasser:	Haeusser, Daniel P., Margolin, William
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Schlagworte:	631/326/41/1969 631/326/41/2536 631/326/88 631/80/641 631/80/641/2090 Bacteria - cytology Bacteria - metabolism Bacterial Proteins - chemistry Bacterial Proteins - genetics Bacterial Proteins - metabolism Cell Cycle - genetics Cell division Cell Membrane - metabolism Cell Membrane - ultrastructure Cell membranes Cytokinesis - genetics Cytokinesis - physiology Cytoskeletal Proteins - chemistry Cytoskeletal Proteins - genetics Cytoskeletal Proteins - metabolism Genetic aspects Infectious Diseases Life Sciences Medical Microbiology Membrane proteins Microbiology Parasitology Properties review-article Virology
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description	Key Points All cells must divide to proliferate, and most bacteria divide by splitting themselves into two during cytokinesis. Many bacteria divide by splitting into approximately equal halves in a process called binary fission. Cytokinesis in bacteria is achieved by the divisome, a dedicated protein machine that is located at the site of cell division. Recent advances in ultrastructural imaging, biochemistry and genetics of Escherichia coli and other model bacterial species have helped to refine models of divisome function and regulation. FtsZ, the bacterial homologue of tubulin, is the principal driver of bacterial cytokinesis. In vitro , FtsZ assembles into single protofilaments in the presence of GTP. In vivo , these protofilaments loosely assemble to encircle the cell at the site of division — called the Z ring — and are positioned there by species-specific spatial positioning proteins. As FtsZ is a soluble protein, FtsZ protofilaments must be tethered to the inner surface of the cytoplasmic membrane by additional proteins, including FtsA and ZipA in E. coli . This complex of FtsZ and membrane tethers is called the proto-ring and has highly dynamic behaviour. Although they do not form microtubules, FtsZ protofilaments self-associate to form bundles, either through interactions with other FtsZ subunits or with several FtsZ-binding proteins that enhance bundling, including ZipA and Zap proteins. These lateral interactions between FtsZ protofilaments may be important for the ability of FtsZ to divide a cell. FtsA, a bacterial homologue of actin, is a key connector between the Z ring and other proteins of the divisome, all of which span the membrane and some of which bind to the peptidoglycan layer. Once the divisome is completely assembled, it coordinates the inward constriction of the Z ring and cytoplasmic membrane with the synthesis of the cell division septum, which is composed of peptidoglycan. FtsA is a key player in this coordination, which probably involves feedback signalling between the peptidoglycan-binding divisome proteins and the Z ring. Biochemical characterization of FtsA remains a major challenge. In addition to signalling in the divisome during the process of cytokinesis, the divisome is regulated by mechanical, metabolic and stress inputs. FtsZ is a major target for these regulators, but other divisome proteins are also targets. Understanding how divisome proteins are inhibited or stimulated will be valuable in the future design of div
doi_str_mv	10.1038/nrmicro.2016.26
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Many bacteria divide by splitting into approximately equal halves in a process called binary fission. Cytokinesis in bacteria is achieved by the divisome, a dedicated protein machine that is located at the site of cell division. Recent advances in ultrastructural imaging, biochemistry and genetics of Escherichia coli and other model bacterial species have helped to refine models of divisome function and regulation. FtsZ, the bacterial homologue of tubulin, is the principal driver of bacterial cytokinesis. In vitro , FtsZ assembles into single protofilaments in the presence of GTP. In vivo , these protofilaments loosely assemble to encircle the cell at the site of division — called the Z ring — and are positioned there by species-specific spatial positioning proteins. As FtsZ is a soluble protein, FtsZ protofilaments must be tethered to the inner surface of the cytoplasmic membrane by additional proteins, including FtsA and ZipA in E. coli . This complex of FtsZ and membrane tethers is called the proto-ring and has highly dynamic behaviour. Although they do not form microtubules, FtsZ protofilaments self-associate to form bundles, either through interactions with other FtsZ subunits or with several FtsZ-binding proteins that enhance bundling, including ZipA and Zap proteins. These lateral interactions between FtsZ protofilaments may be important for the ability of FtsZ to divide a cell. FtsA, a bacterial homologue of actin, is a key connector between the Z ring and other proteins of the divisome, all of which span the membrane and some of which bind to the peptidoglycan layer. Once the divisome is completely assembled, it coordinates the inward constriction of the Z ring and cytoplasmic membrane with the synthesis of the cell division septum, which is composed of peptidoglycan. FtsA is a key player in this coordination, which probably involves feedback signalling between the peptidoglycan-binding divisome proteins and the Z ring. Biochemical characterization of FtsA remains a major challenge. In addition to signalling in the divisome during the process of cytokinesis, the divisome is regulated by mechanical, metabolic and stress inputs. FtsZ is a major target for these regulators, but other divisome proteins are also targets. Understanding how divisome proteins are inhibited or stimulated will be valuable in the future design of divisome-specific antimicrobial compounds. Bacterial cell division occurs under tight temporal and spatial regulation by the divisome. In this Review, Haeusser and Margolin review the structure and function of the divisome, highlighting insights into the assembly of this multicomponent machinery that were provided by recent technical advances. Bacteria must divide to increase in number and colonize their niche. Binary fission is the most widespread means of bacterial cell division, but even this relatively simple mechanism has many variations on a theme. In most bacteria, the tubulin homologue FtsZ assembles into a ring structure, termed the Z ring, at the site of cytokinesis and recruits additional proteins to form a large protein machine — the divisome — that spans the membrane. 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Microbiology</title><addtitle>Nat Rev Microbiol</addtitle><addtitle>Nat Rev Microbiol</addtitle><description>Key Points All cells must divide to proliferate, and most bacteria divide by splitting themselves into two during cytokinesis. Many bacteria divide by splitting into approximately equal halves in a process called binary fission. Cytokinesis in bacteria is achieved by the divisome, a dedicated protein machine that is located at the site of cell division. Recent advances in ultrastructural imaging, biochemistry and genetics of Escherichia coli and other model bacterial species have helped to refine models of divisome function and regulation. FtsZ, the bacterial homologue of tubulin, is the principal driver of bacterial cytokinesis. In vitro , FtsZ assembles into single protofilaments in the presence of GTP. 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FtsA, a bacterial homologue of actin, is a key connector between the Z ring and other proteins of the divisome, all of which span the membrane and some of which bind to the peptidoglycan layer. Once the divisome is completely assembled, it coordinates the inward constriction of the Z ring and cytoplasmic membrane with the synthesis of the cell division septum, which is composed of peptidoglycan. FtsA is a key player in this coordination, which probably involves feedback signalling between the peptidoglycan-binding divisome proteins and the Z ring. Biochemical characterization of FtsA remains a major challenge. In addition to signalling in the divisome during the process of cytokinesis, the divisome is regulated by mechanical, metabolic and stress inputs. FtsZ is a major target for these regulators, but other divisome proteins are also targets. Understanding how divisome proteins are inhibited or stimulated will be valuable in the future design of divisome-specific antimicrobial compounds. Bacterial cell division occurs under tight temporal and spatial regulation by the divisome. In this Review, Haeusser and Margolin review the structure and function of the divisome, highlighting insights into the assembly of this multicomponent machinery that were provided by recent technical advances. Bacteria must divide to increase in number and colonize their niche. Binary fission is the most widespread means of bacterial cell division, but even this relatively simple mechanism has many variations on a theme. In most bacteria, the tubulin homologue FtsZ assembles into a ring structure, termed the Z ring, at the site of cytokinesis and recruits additional proteins to form a large protein machine — the divisome — that spans the membrane. 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Microbiology</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Haeusser, Daniel P.</au><au>Margolin, William</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Splitsville: structural and functional insights into the dynamic bacterial Z ring</atitle><jtitle>Nature reviews. Microbiology</jtitle><stitle>Nat Rev Microbiol</stitle><addtitle>Nat Rev Microbiol</addtitle><date>2016-05-01</date><risdate>2016</risdate><volume>14</volume><issue>5</issue><spage>305</spage><epage>319</epage><pages>305-319</pages><issn>1740-1526</issn><eissn>1740-1534</eissn><abstract>Key Points All cells must divide to proliferate, and most bacteria divide by splitting themselves into two during cytokinesis. Many bacteria divide by splitting into approximately equal halves in a process called binary fission. Cytokinesis in bacteria is achieved by the divisome, a dedicated protein machine that is located at the site of cell division. Recent advances in ultrastructural imaging, biochemistry and genetics of Escherichia coli and other model bacterial species have helped to refine models of divisome function and regulation. FtsZ, the bacterial homologue of tubulin, is the principal driver of bacterial cytokinesis. In vitro , FtsZ assembles into single protofilaments in the presence of GTP. In vivo , these protofilaments loosely assemble to encircle the cell at the site of division — called the Z ring — and are positioned there by species-specific spatial positioning proteins. As FtsZ is a soluble protein, FtsZ protofilaments must be tethered to the inner surface of the cytoplasmic membrane by additional proteins, including FtsA and ZipA in E. coli . This complex of FtsZ and membrane tethers is called the proto-ring and has highly dynamic behaviour. Although they do not form microtubules, FtsZ protofilaments self-associate to form bundles, either through interactions with other FtsZ subunits or with several FtsZ-binding proteins that enhance bundling, including ZipA and Zap proteins. These lateral interactions between FtsZ protofilaments may be important for the ability of FtsZ to divide a cell. FtsA, a bacterial homologue of actin, is a key connector between the Z ring and other proteins of the divisome, all of which span the membrane and some of which bind to the peptidoglycan layer. Once the divisome is completely assembled, it coordinates the inward constriction of the Z ring and cytoplasmic membrane with the synthesis of the cell division septum, which is composed of peptidoglycan. FtsA is a key player in this coordination, which probably involves feedback signalling between the peptidoglycan-binding divisome proteins and the Z ring. Biochemical characterization of FtsA remains a major challenge. In addition to signalling in the divisome during the process of cytokinesis, the divisome is regulated by mechanical, metabolic and stress inputs. FtsZ is a major target for these regulators, but other divisome proteins are also targets. Understanding how divisome proteins are inhibited or stimulated will be valuable in the future design of divisome-specific antimicrobial compounds. Bacterial cell division occurs under tight temporal and spatial regulation by the divisome. In this Review, Haeusser and Margolin review the structure and function of the divisome, highlighting insights into the assembly of this multicomponent machinery that were provided by recent technical advances. Bacteria must divide to increase in number and colonize their niche. Binary fission is the most widespread means of bacterial cell division, but even this relatively simple mechanism has many variations on a theme. In most bacteria, the tubulin homologue FtsZ assembles into a ring structure, termed the Z ring, at the site of cytokinesis and recruits additional proteins to form a large protein machine — the divisome — that spans the membrane. In this Review, we discuss current insights into the regulation of the assembly of the Z ring and how the divisome drives membrane invagination and septal cell wall growth while flexibly responding to various cellular inputs.</abstract><cop>London</cop><pub>Nature Publishing Group UK</pub><pmid>27040757</pmid><doi>10.1038/nrmicro.2016.26</doi><tpages>15</tpages><oa>free_for_read</oa></addata></record>
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subjects	631/326/41/1969 631/326/41/2536 631/326/88 631/80/641 631/80/641/2090 Bacteria - cytology Bacteria - metabolism Bacterial Proteins - chemistry Bacterial Proteins - genetics Bacterial Proteins - metabolism Cell Cycle - genetics Cell division Cell Membrane - metabolism Cell Membrane - ultrastructure Cell membranes Cytokinesis - genetics Cytokinesis - physiology Cytoskeletal Proteins - chemistry Cytoskeletal Proteins - genetics Cytoskeletal Proteins - metabolism Genetic aspects Infectious Diseases Life Sciences Medical Microbiology Membrane proteins Microbiology Parasitology Properties review-article Virology
title	Splitsville: structural and functional insights into the dynamic bacterial Z ring
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