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ANRV322-MI61-27 ARI 6 August 2007 18:23 Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. Cytoskeletal Elements in Bacteria Peter L. Graumann Institute of Microbiology, Faculty for Biology, University of Freiburg, 179104 Freiburg, Germany; email: [email protected] Annu. Rev. Microbiol. 2007. 61:589–618 Key Words The Annual Review of Microbiology is online at micro.annualreviews.org cytoskeleton, MreB, FtsZ, intermediate filaments, cell morphology, cell cycle This article’s doi: 10.1146/annurev.micro.61.080706.093236 c 2007 by Annual Reviews. Copyright All rights reserved 0066-4227/07/1013-0589$20.00 Abstract All cytoskeletal elements known from eukaryotic cells are also present in bacteria, where they perform vital tasks in many aspects of the physiology of the cell. Bacterial tubulin (FtsZ), actin (MreB), and intermediate filament (IF) proteins are key elements in cell division, chromosome and plasmid segregation, and maintenance of proper cell shape, as well as in maintenance of cell polarity and assembly of intracellular organelle-like structures. Although similar tasks are performed by eukaryotic cytoskeletal elements, the individual functions of FtsZ, MreBs, and IFs are different from those performed by their eukaryotic orthologs, revealing a striking evolutional plasticity of cytoskeletal proteins. However, similar to the functions of their eukaryotic counterparts, the functions conferred by bacterial cytoskeletal proteins are driven by their ability to form dynamic filamentous structures. Therefore, the cytoskeleton was a prokaryotic invention, and additional bacteria-specific cytoskeletal elements, such as fibril and MinD-type ATPases, that confer various functions in cell morphology and during the cell cycle have been observed in prokaryotes. The investigation of these elements will give fundamental information for all types of cells and can reveal the molecular mode of action of cytoskeletal, filament-forming proteins. 589 ANRV322-MI61-27 ARI 6 August 2007 18:23 Contents Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. INTRODUCTION . . . . . . . . . . . . . . . . . TUBULIN-LIKE PROTEINS . . . . . . FtsZ Forms a Ring that Initiates Cell Division . . . . . . . . . . . . . . . . . . A Switch in the Localization of FtsZ During the Developmental Process of Sporulation . . . . . . . . . Proteins Regulating the Function of FtsZ . . . . . . . . . . . . . . . . . . . . . . . Positioning of the FtsZ Ring: MinD Filaments, Nucleoid Occlusion, and MipZ . . . . . . . . . . Bacterial Tubulins BtubA and BtubB . . . . . . . . . . . . . . . . . . . . . . . . ACTIN-LIKE PROTEINS . . . . . . . . . FtsA: A Crucial Component of the Division Machinery . . . . . . . . . . . MreB: A Filamentous Cytoskeletal Structure Performing an Essential Function in Many Bacteria with a Complex Cell Shape . . . . . . . . . . . . . . . . . . . . . . . . . Biochemical Properties of MreB Proteins . . . . . . . . . . . . . . . . . . . . . . Dynamic Localization of MreB Proteins . . . . . . . . . . . . . . . . . . . . . . Gene Multiplicity . . . . . . . . . . . . . . . . A Function in Control of Cell Morphology . . . . . . . . . . . . . . . . . . 590 592 592 594 595 595 596 596 596 597 598 599 600 IFs: intermediate filaments 590 Most if not all types of cells require factors that stabilize their cell membrane and provide some rigidity to the cell. Such factors are essential for the maintenance of cell morphology (the shape of an organism). Cellular life is also dependent on several dynamic processes such as physical segregation of chromosomes and division of the cell into two daughter cells, as well as movement of subcellular structures within the cell. Nature has evolved a class of proteins called cytoskeletal elements that are key factors in both asGraumann 602 602 604 605 607 607 607 608 609 609 609 610 610 611 600 INTRODUCTION Cell morphology: outward appearance (shape, structure, color, pattern) of an organism A Function During Bacterial Development . . . . . . . . . . . . . . . . . A Function in Chromosome Segregation . . . . . . . . . . . . . . . . . . . ParM and AlfA: A Function in Plasmid Partitioning . . . . . . . . . . . Cytoskeletal Elements in Magnetotactic Bacteria . . . . . . . . An Archaeal Actin-Like Protein . . . INTERMEDIATE FILAMENT-LIKE PROTEINS. . Crescentin Mediates Cell Curvature in C. crescentus . . . . . . . Cytoplasmic Filaments in Spirochetes: CfpA and Scc Proteins . . . . . . . . . . . . . . . . . . . . . . AglZ from Myxococcus xanthus . . . . . OTHER TYPES OF CYTOSKELETAL ELEMENTS Cytoskeletal Elements in Cell Wall–Less Bacteria: Fibril Protein and MreB-Like Filaments . . . . . . . . . . . . . . . . . . . . . ParA-Type Proteins form Plasmid-Segregating Filaments. Bacterial Dynamin . . . . . . . . . . . . . . . Cytoskeletal Elements of Unknown Composition . . . . . . . . pects, cell stability/morphology and cell dynamics. Cytoskeletal elements generally form filamentous structures that can be highly dynamic or static, depending on which task they confer. Three types of cytoskeletal elements in eukaryotic cells, tubulins, actins, and intermediate filaments (IFs), have been described and characterized. Tubulin forms microtubules consisting of straight protofilaments that assemble into hollow tubules through lateral contacts to both sides of the protofilaments (30) (Figure 1). Microtubules Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. ANRV322-MI61-27 ARI 6 August 2007 18:23 extend through association of GTP-bound α- and β-tubulin heterodimers onto the plus end, while the dimers are released from the minus end after hydrolysis, which destabilizes the intrafilament contacts. However, microtubules can rapidly release dimers from both ends and thus shrink, a stochastic event called catastrophic collapse, giving rise to dynamic instability of the filaments. Thus, tubulin filaments are highly dynamic elements within the cells. These tubules set up the tracks of the mitotic spindle apparatus that are used to segregate chromosomes during mitosis and meiosis through dedicated motor proteins. Tubulin filaments also serve as tracks for the transport of intracellular vesicles and other cargo, which are moved through cells by motor proteins that have a defined direction of movement on microtubules. Actin forms a two-stranded, right-handed helical filament with an axial rise of 5.4 nm per monomer that has a plus-/minus-end polarity and is also dynamic (44, 80) (Figure 1). Owing to filament asymmetry, ATP-bound actin adds to the plus end (also called barbed end) much faster than it does to the minus end (pointed end) when actin concentrations are high. ATPase activity leads to conversion to ADP-actin within the filament, and ADP-actin is released at the minus end. This process is called treadmilling and leads to a net polymerization at one end and depolymerization at the other end. Thus, while the center of the filament (and each subunit) remains stationary, the tip of the filament can push objects by limiting them in their diffusion such that they can diffuse only in the direction of the extended filament. Actin polymerization is required for cell movement via extension of pseudopods, in which additional proteins induce branching of actin filaments, generating a network that pushes against the leading edge of the membrane in a brush-like manner (44). Actin is also required for the movement of some types of vesicles through cells (44, 115). IFs are composed of extended coiledcoil proteins that assemble into rigid sheets GTP Tubulin GTP α-/β-tubulin - + GDP GDP GDP GTP - + FtsZ GTP GDP ATP ATP Actin ParM ADP ATP Strand 1 - ADP + ATP Strand 2 ATP MreB - + ADP IFs Figure 1 Schematic drawing of cytoskeletal elements in eukaryotes (tubulin, actin, and IFs) and in bacteria (FtsZ, with putative protofilament structure, ParA, MreB, and IFs). IFs, intermediate filaments. Both actin and MreB filaments (green and gray) are composed of identical subunits. (Figure 1). IFs form 8- to 10-nm-thick cytoskeletal elements that provide internal mechanical support for the cell and position different organelles, e.g., Golgi apparatus and mitochondria (107). For example, keratin provides mechanical strength in skin cells, even after the cells have died, as does vimentin in endothelial cells. IFs are much less conserved in sequence than are tubulins or actin, because different sequences can make up coiled-coil motifs. It has taken much longer to realize that similar cytoskeletal elements are also present in prokaryotic cells (43). Filamentous structures in bacteria have been described in many reports, in which electron microscopy www.annualreviews.org • Cytoskeletal Elements in Bacteria Dynamic instability: rapid depolymerization and shrinkage of filaments Filament: long chain of proteins Treadmilling: constant removal of the protein subunits from these filaments at one end while protein subunits are constantly added at the other end 591 ANRV322-MI61-27 ARI 6 August 2007 18:23 TUBULIN-LIKE PROTEINS b a FtsZ Forms a Ring that Initiates Cell Division FtsZ-CFP FtsZ-CFP Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. c d YFP-MreB Crescetin Figure 2 Fluorescence microscopy of cytoskeletal elements in bacteria. (a) FtsZ forms a ring at the middle of the cell (Bacillus subtilis cells expressing FtsZ-CFP), initiating division. (b) FtsZ switches its position during differentiation; B. subtilis cells express FtsZ-CFP at the onset of sporulation. White arrowheads indicate two polar Z rings. Note the spiral forms of FtsZ in several cells. (c) MreB forms helical filaments underneath the cell membrane (B. subtilis cells expressing YFP-MreB). (d ) Crescentin localizes to the concave side of the bent Caulobacter crescentus cells (immunofluorescence with anti-crescentin antibodies; cells are stained with the blue DNA stain DAPI). Panel d courtesy of C. Jacobs-Wagner, Yale University. White lines in panels a–c indicate septa between cells that grow in chains. White bars in panels a–c and white line in panel d are 2 μm. Polymerization: bonding of monomers or “single units” together from longer chains called polymers Differentiation: acquisition of a (new) cell type 592 was used. The first cytoskeletal element in a prokaryote was discovered in 1980 by Lutkenhaus et al. (72), and the second element was discovered in 1988 by Matsuhashi and coworkers (23). In spite of the power of bacterial genetics, the true function of FtsZ and MreB only became apparent with the investigation of the localization of the proteins within cells. Adaptation of cytological techniques developed for eukaryotic cells for the study of cellular organization of bacteria has shown that bacteria contain a multitude of specifically subcellularly localized proteins and possess proteins that confer highly dynamic and directional processes. Among these proteins, cytoskeletal elements play several crucial roles in bacterial physiology. Graumann FtsZ was the first protein described to form a cytoskeletal structure in prokaryotic cells. Using screens selecting for temperaturesensitive mutants that form filaments at high temperature (filamentation temperature sensitive), researchers have identified many genes involved in cell division, and ftsZ was first described in 1980 (72). Using immunoelectron microscopy, Bi & Lutkenhaus (9) showed that FtsZ is present primarily at the invaginating edge of the septum. The use of immunofluorescence microscopy revealed that FtsZ forms a ring (Z ring) at the middle of the cell, even if the membrane does not yet show any detectable invagination (2) (Figure 2a). Depletion of FtsZ leads to the formation of long aseptate cells, in which chromosomes are normally segregated and which ultimately lyse. FtsZ is the first protein of the division machinery that visibly localizes at midcell, and the localization of all division proteins is dependent on FtsZ (71). Formation of new FtsZ rings occurs rapidly (within 1 min) and can occur at future division sites even in the predivisional cell, before the midcell Z rings have almost completely closed (104). These experiments suggest that FtsZ is first to establish the division machinery, and in support of this, it is the most highly regulated and conserved division protein. Several reviews have summarized knowledge on FtsZ and cell division (3, 73); therefore, this review contains only a condensed account of the nature and function of FtsZ. An ftsZ gene is present in almost all bacterial and archaeal cells (round-, rod-, or more complex-shaped species) (Figure 3), except for Sulfolobus species, other Crenarchaeota, and some cell wall-less bacteria (belonging to the Mollicutes). Its essential function in cell division notwithstanding, FtsZ is dispensable for growth in Streptomyces coelicolor. Curiously, this organism can grow in the absence of Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. ANRV322-MI61-27 ARI 6 August 2007 18:23 FtsZ, during which one giant cell is formed that can produce a whole colony (78). In fact, Streptomyces cells divide rather irregularly and distribute their chromosomes sloppily. Thus, there is no apparent need to divide during growth in these organisms. However, S. coelicolor is unable to sporulate in the absence of FtsZ, because cell division is required to pinch off spores at the tips of aerial hyphae. FtsZ has two domains, one of which is a GTPase domain related to the GTPase domain of EF-Tu. The structure of FtsZ is highly similar to α- and β-tubulin (which are highly similar to each other) (70). GTP is bound between the two domains, and hydrolysis is thought to occur through contacts between the bottom of one FtsZ and the GTPase pocket of the following molecule within the filament, analogous to tubulin. During polymerization of tubulin, GTP in β-tubulin is immediately hydrolyzed, whereas hydrolysis in α- and β-tubulin is much slower. Conversely, GTP is hydrolyzed much more rapidly in FtsZ filaments (94), and hydrolysis may occur within each FtsZ monomer during polymerization. Because GDP-bound tubulin filaments are more unstable than the GDP/GTP-bound structures, FtsZ filaments are more unstable in vitro than the tubulin assemblies. The two domains of FtsZ can interact and polymerize when they are Pbps: penicillin-binding proteins −−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−−→ Figure 3 Scheme of cytoskeletal elements in bacteria. (a) FtsZ (and frequently also FtsA) forms a ring in the middle of coccal cells. In many cocci, division planes alternate in two or even three dimensions, giving rise to growth as tetrads or packets of cells, respectively. (b) FtsZ forms a midcell ring in rod-shaped cells and recruits cytosolic division proteins and (c) membrane-bound division proteins, such that the division septum is synthesized by penicillin-binding proteins (Pbps). MinD forms spiral structures that are enriched at the cell poles, preventing assembly of Z rings. Nucleoids (which contain the chromosomes) prevent formation of Z rings, such that only the middle of the cell is competent for FtsZ polymerization after nucleoids have separated. MreB forms dynamic helical filaments that move underneath the cell membrane and affect chromosome segregation and maintenance of cell morphology. (c) MreB proteins interact with membrane proteins (MreC) that affect cell morphology and in turn interact with Pbps. Cytoskeletal structures in (d ) C. crescentus and (e) in spiral formed bacteria. Spirochetes contain cytoskeletal filaments along the long side of the cells, and fibril forms a ribbon-like structure along the short axis of cell wall–less Spiroplasma cells. www.annualreviews.org • Cytoskeletal Elements in Bacteria 593 ANRV322-MI61-27 ARI 6 August 2007 Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. FRAP: fluorescence recovery after photobleaching 594 18:23 noncovalently linked, suggesting that polymerization of the ancestor evolved through fusion of the two domains (85). FtsZ protein forms different kinds of polymers in vitro, such as single protofilaments, sheets, and tubule-like structures, that are dependent on the presence of GTP (31). However, because FtsZ lacks loops that make lateral contacts between tubulin protofilaments, it is unlikely to form hollow microtubules like tubulin in vivo (Figure 1). Additionally, αand β-tubulin contain several inserts in their sequence that are absent in FtsZ and that are important for binding of additional factors that affect the formation of microtubules (3). However, FtsZ interacts with many other proteins that appear to affect its polymerization (see below). Using fluorescence recovery after photobleaching (FRAP), the Erickson group (102) has shown that the Z ring is highly dynamic in vivo. FRAP exploits the property of green fluorescent protein (GFP) to require an extensive time (in the range of up to 60 min) to regain excitability after an excitation/emission event. Thus, if a rigid structure of a GFPtagged protein is bleached within a subcellular area of the cell, recovery of fluorescence will depend on the time it takes for the bleached GFP molecules to regain fluorescence. However, if a structure is dynamic, exchange with molecules from a nonbleached area in the cell will speed up recovery of fluorescence. Using this technique, the Erickson group showed that upon bleaching of one half of an FtsZ ring, fluorescence is regained within a few seconds. Fluorescence recovery was markedly reduced in a mutant that possesses much slower GTPase activity, revealing that exchange of FtsZ monomers (and thus filament disassembly) depends on GTP hydrolysis. It has been proposed that the Z ring consists of many FtsZ filaments that constantly assemble and disassemble or that extend at one end and disassemble at the other end (called ratchet mechanism). This idea is supported by findings from the Margolin group (105), who found that in a subset of growing Escherichia coli cells, FtsZ Graumann forms spirals that dynamically extend away from the central Z ring or move underneath the cell membrane in young cells lacking a Z ring within a time frame of a few seconds. Oscillatory waves of FtsZ spirals were observed in elongated cells and were independent of MreB spirals (see below). Indeed, FtsZ can be captured in a spiral form as a specific mutant version that is shifted to nonpermissive temperature and resumes formation of normal rings and cell division after temperature shift-back (79). These data suggest that FtsZ forms long dynamic spirals that are reorganized into a ring structure at the onset of division, which possibly consists of shortpitched tightly stacked helices. A Switch in the Localization of FtsZ During the Developmental Process of Sporulation When B. subtilis cells are starved, or enter stationary phase, cells can differentiate into a spore that is dormant for a long period (spores can survive for 100 years in distilled water) and highly resistant to high temperature or a variety of chemical insults. The hallmark of sporulation is the generation of a septum close to one cell pole, rather than at midcell. This asymmetric division generates a small cell that differentiates into the spore and a large cell (called the mother cell) that lyses. Polar division is achieved owing to a change in the pattern of localization of FtsZ, which forms spiral structures at the onset of sporulation (Figure 2b) rather than a ring structure at midcell and finally localizes as two polar rings, both of which initiate divisome assembly (7). One septum matures faster than the other, and upon completion of one septum, a genetic program is initiated that leads to the activation of proteins that prevent the completion of the second (slower) polar septum and mediate disassembly of the second Z ring (29). The switch between midcell and bipolar assembly of Z rings is driven by overproduction of ftsZ transcription relative to exponentially growing cells (due to the Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. ANRV322-MI61-27 ARI 6 August 2007 18:23 induction of an additional promoter driven by a sporulation-specific sigma factor) and by the sporulation-specific synthesis of a membrane protein, SpoIIE, that stabilizes polar FtsZ rings (7). Artificial overproduction of FtsZ in growing cells indeed leads to the formation of spiral structures and, if accompanied by induction of SpoIIE synthesis, to the formation of stable bipolar Z rings. Therefore, inhibition of polar ring formation by the Min system is apparently overridden by high FtsZ levels and induction of SpoIIE, and formation of a Z ring at midcell may be prevented by a sporulation-specific structure of the nucleoid, called axial filaments, in which the nucleoid now extends from pole to pole but lacks a visible constriction at the cell center. Proteins Regulating the Function of FtsZ Just as tubulin assembly is regulated by a large array of proteins, several proteins that interact with FtsZ influence the stability of the Z ring. MinC inhibits polymerization of FtsZ close to the cell poles (see below), whereas FtsA and ZipA appear to stabilize Z rings in E. coli cells. Both FtsA and ZipA are essential for cell division but not for the formation of Z rings, and they interact with FtsZ independently (Figure 3c). However, in the absence of both FtsA and ZipA, formation of Z rings is abolished (86). That a single mutation in FtsA can bypass the requirement for ZipA during division supports the idea that FtsA and ZipA have overlapping functions in the establishment and/or maintenance of Z rings (38). Instead of possessing ZipA, B. subtilis possesses the unrelated ZapA, EzrA, and SepF/YlmA proteins, all of which bind to FtsZ, and of which ZapA and SepF/YlmA appear to stabilize Z rings and EzrA appears to destabilize FtsZ polymers in vivo (45, 47, 54). Consistent with these ideas, EzrA prevents FtsZ polymerization in vitro (46), and purified ZapA promotes bundling of FtsZ filaments (45). In addition, induction of DNA damage elicits the SOS response, causing transcription of genes that encode DNA repair, as well as of sulA in E. coli (or yneA in B. subtilis). SulA binds to FtsZ and prevents polymerization, effectively inhibiting division until DNA damage has been repaired (83). The battery of regulatory proteins shows that regulation of FtsZ polymerization is required to prevent unwanted and premature division and to elicit productive formation of a ring structure at the appropriate time in the cell cycle. Cell cycle: the series of events that take place in a cell between its formation and the moment it has duplicated itself Positioning of the FtsZ Ring: MinD Filaments, Nucleoid Occlusion, and MipZ FtsZ forms a ring relatively precisely at midcell in E. coli and B. subtilis, but not at any other position within the cell and only late during the cell cycle. Positioning of the Z ring is regulated by two additive systems. Noc (nucleoid occlusion; B. subtilis) and SlmA (synthetically lethal with a defective Min system) (E. coli) bind to the nucleoid and prevent the formation of a Z ring—SlmA does this directly by interfering with polymerization of FtsZ (8, 118). Thus, the nucleoid prevents the formation of the Z ring in its vicinity (occlusion), such that nonseparated chromosomes are not bisected by premature cell division. This leaves the cell center (as well as the cell poles, in which there is no DNA) competent for Z ring formation after nucleoids have separated (thus ensuring that Z ring formation follows late in the cell cycle after segregation of the chromosomes). Here, MinC prevents FtsZ polymerization (53). MinC is positioned at both cell poles in B. subtilis, or oscillates between the cell poles in E. coli, by MinD, a Walkertype ATPase with which MinC forms a complex (73, 90). MinD in turn is recruited to the poles in B. subtilis by DivIVa, a late component of the cell division machinery whose localization to the septum (which later becomes the new pole) depends on the FtsZ protein (74). In E. coli, MinD forms filamentous spirals as it moves from one pole to the other and back (Figure 3b) while MinC is carried piggyback (98). www.annualreviews.org • Cytoskeletal Elements in Bacteria 595 ARI 6 August 2007 18:23 It is possible that the MinD filaments assemble at one pole and extend to the other pole by addition of MinD to the growing tip of the filament(s), in a manner analogous to actin. MinD also forms short double-stranded filaments in vitro in the presence of ATP (103). The addition of phospholipid vesicles greatly enhances the formation of MinD filaments, which increase in length and selfassociate into bundles, supporting the notion that MinD self-assembles along the cell membrane (51). Membrane association is mediated by a short C-terminal sequence and requires ATP or a nonhydrolyzable analog. MinE disassembles MinD filaments in vitro, because it stimulates MinD ATPase activity (52, 103), and also localizes in an oscillatory manner (48). MinE forms a ring structure close to midcell that moves toward the MinD assembly at one pole. After MinD has disassembled from the pole, the MinE ring moves toward the other pole after MinD has assembled at this site, apparently “pushing” MinD away from one pole to the other and back. The net results of both systems in B. subtilis and in E. coli are a higher concentration of MinC close to the poles, masking these for FtsZ polymerization, and a low concentration at midcell. Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. ANRV322-MI61-27 Bacterial Tubulins BtubA and BtubB Verrucomicrobia are a phylum of bacteria of uncertain lineage that contains species that live in close association or as ectosymbionts of eukaryotic ciliates. Microtubule-like structures that serve as protection against predators have been observed in several species. Close tubulin homologs, termed BtubA and BtubB, have been found encoded in the genome of a free-living member of Verrucomicrobia, Prosthecobacter dejongeii, whereas ftsZ is absent from the genome (58). BtubA and BtubB form heterodimers that rapidly polymerize into double protofilaments or bundles of double filaments in the presence of GTP (101). Slow GTP hydrolysis results in depolymerization of filaments. The 3D structure of the 596 Graumann BtubA/B heterodimer closely resembles that of α-/β-tubulin, including the C-terminal domain of tubulin that forms the outside of microtubules, which is absent in FtsZ (96). The close resemblance of BtubA/BtubB to tubulin and their absence in any other known bacterial genome suggest that the genes have been transferred to P. dejongeii (and possibly also other Verrucomicrobia) via horizontal gene transfer to replace FtsZ. In any event, BtubA/B represent an intermediate step between FtsZ and tubulin, in terms of both structure and folding, because like FtsZ, BtubA/B do not require chaperones for folding, as tubulin does. It will be interesting to determine the distribution of BtubA/B in Verrucomicrobia and to elucidate their function in vivo. ACTIN-LIKE PROTEINS FtsA: A Crucial Component of the Division Machinery FtsA belongs to the family of actin-fold proteins (111). FtsA interacts directly with the extreme C terminus of FtsZ and localizes to the FtsZ ring (Figure 3c) invariably dependent on FtsZ but not on any other component of the division machinery, whereas most division proteins other than FtsZ are recruited to the FtsZ ring dependent on FtsA (32) (Figure 3c). These data show that FtsA is recruited to the FtsZ ring at an early time point. FtsA is essential in E. coli and many other bacteria including cocci (Streptococcus pneumoniae), whereas deletion of ftsA (which is usually upstream of ftsZ) in B. subtilis leads to a severe defect in division but allows for slow growth. The ration of FtsZ to FtsA is 5:1 in E. coli and B. subtilis and must be maintained to ensure proper division (16). In vitro, S. pneumoniae FtsA assembles into long curved polymers, apparently consisting of a 2+2 pair of paired filaments, in the presence of various nucleotide diphosphates and triphosphates (66). FtsA generally binds to ATP; however, ATPase activity could be detected only in B. subtilis FtsA but not in the ANRV322-MI61-27 ARI 6 August 2007 18:23 Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. S. pneumoniae ortholog. In the absence of FtsA, FtsZ forms abnormal rings in B. subtilis cells, and loss of FtsA and ZipA abolishes FtsZ ring-formation in E. coli, showing that FtsA is important for FtsZ polymerization (possibly in counteracting inhibition with MinC) or stability of FtsZ polymers at midcell. FtsA interacts directly with later-recruited division proteins (32) and thus plays an additional role in the assembly of the divisome. The exact function of FtsA remains to be uncovered. MreB: A Filamentous Cytoskeletal Structure Performing an Essential Function in Many Bacteria with a Complex Cell Shape In the late 1960s, screens designed to find genes whose product affects cell morphology in rod-shaped cells identified several loci in which mutations led to the formation of osmotically stable, round cells. One of these loci was the Mre (murein cluster E) operon, which contains three genes in E. coli, and in many other bacteria, called mreB, mreC, and mreD (23). Mutations in all three genes lead to formation of irregularly bulged or oval to round cells. MreB was first described in 1988, but its similarity to actin became apparent only in 1992. MreB contains five sequence motifs, called phosphate 1, phosphate 2, adenosine, connect 1, and connect 2, that are conserved in actin and other seemingly unrelated proteins. It was proposed in 1992 that MreB, together with several sugar kinases, FtsA, and plasmid-encoded StbA, belongs to the actinfold protein family (11). Actin consists of two domains of similar fold, domains I and II, and ATP is bound in the cleft between the two domains, triggering movement of the two domains. Domain movement in turn may mediate formation of filaments, but this is still under debate. Both domains are composed of four subdomains (two each), called Ia, Ib, IIa, and IIB. Subdomains Ia and IIa connect the two major domains and have a similar fold with identical topology, which most likely arose through gene duplication. Phosphate 1 and phosphate 2 motifs are situated on two β-hairpins on subdomains Ia and IIa and bind to the phosphate tail of ATP, critically influencing ATP binding and ATP hydrolysis (3). Compared with MreB, eukaryotic actin has several sequence insertions, all of which mediate either allosteric interactions within the actin monomer or binding to chaperones and cofactors. MreBCD genes are usually absent in round (coccoid) bacteria, although several round cyanobacteria and planctomycetes species contain an mreB ortholog. Mutation or deletion of mreB in E. coli results in formation of round slowly growing cells that are hypersensitive to antibiotics targeting cell wall synthesis enzymes (114). A similar phenotype is observed upon mutation of the downstream mreC and mreD genes (113). These experiments suggest that MreB is involved in cell wall synthesis. Because isolated peptidoglycan (PG) sacculi (called ghosts) retain a rod cell shape, or bent cell shape for sacculi from vibrios, it is clear that the structure of the cell wall determines the cell shape. MreB proteins may dictate the shape of the sacculus (see below). E. coli cells with a deletion of mreB, mreC, mreD, or all three genes are suppressor mutants, showing that cells are not viable in the absence of MreB/C/D but that their function can somehow be compensated for by extragenic mutations (63). MreB is also essential in B. subtilis, Caulobacter crescentus, and Rhodobacter sphaeroides (35, 59, 100), but not in S. coelicolor or Azospirillum brasilense (10, 77), showing that mreB is not essential in all bacteria with complex cell morphology. R. sphaeroides is an interesting case because the bacterium changes shape, from a rod to a coccobacillus, and undergoes extensive cytoplasmic membrane invagination when it switches from aerobic to anaerobic photosynthetic growth. MreB is essential for viability in both cell forms and was found only in the cytosolic fraction of lysed cells, indicating that it is only weakly membrane associated or not associated at all (100). Deletion of mreB www.annualreviews.org • Cytoskeletal Elements in Bacteria PG: peptidoglycan 597 ANRV322-MI61-27 ARI 6 August 2007 Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. Cytoskeleton: cellular scaffolding, dynamic structure that maintains cell shape and drives cellular division, enables some cell motion, and plays important roles in intracellular transport 598 18:23 in the nitrogen-fixing α-Proteobacterium A. brasilense results in a highly pleiotrophic phenotype in which cells are large and round, secrete modified exopolysaccharides, have an altered and larger capsule, aggregate more strongly, and are more resistant to osmotic stress than are wild-type cells (10). These phenotypes are similar to many changes observed in A. brasilense cells that undergo physiological conversion to cyst-like structures when cells colonize plant roots or other plant tissue. Apparently, the function of MreB in this bacterium is complex and includes control of cell permeability, cell surface structures, and, possibly, cell differentiation. Many proteins specifically localize to the cell poles in several bacteria. Deletion of mreB in C. crescentus and in E. coli leads to a loss of polar localization of several proteins (40, 84), showing that MreB is also involved in the establishment or maintenance of cell polarity. A second MreB paralog, Mbl (MreB-like), was found in B. subtilis and in B. cereus. Deletion of mbl is not lethal in B. subtilis but leads to the formation of highly irregularly shaped cells that grow much slower than wild-type cells (1). Using immunofluorescence microscopy, Errington and coworkers (59) showed that MreB and Mbl form distinct structures that had never before been observed in bacteria. Both proteins form dots and helical filamentous threads underneath the cell membrane (Figure 2c). Mbl filaments extend from pole to pole, and MreB filaments were predominantly found towards the cell center. Mbl filaments appeared to have a pitch (the distance from one point of a helix to the next point one helical turn away) different from that of MreB filaments and therefore to form independent structures. These experiments showed that a cytoskeletal structure that controls cell morphology exists in bacteria. On the basis of the different phenotypes of the depletion of MreB or deletion of mbl, which generates round or elongated and twisted cells, respectively, it was proposed that MreB controls the width of the cell and that Mbl controls longitudinal growth (59). Graumann A helical arrangement of MreB filaments was also found in E. coli and in the curved C. crescentus cells (35, 64, 98) (Figure 3d ). In the C. crescentus cells, helical MreB bands switch to a ring-like central localization around the time of cell division, which depends on the presence of FtsZ, showing that MreB has a cell cycle–dependent localization during C. crescentus growth and may be involved in cell division. However, in contrast to most cell cycle proteins, whose intracellular level changes dramatically during the C. crescentus cell cycle, MreB levels remain constant in synchronized cells (35). These findings suggest that the MreB cytoskeletal element is important to mediate complex cell morphology by providing an intracellular scaffold for cell wall synthesis and/or membrane structure. Curiously, loss of MreB can be suppressed by overproduction of FtsQ, FtsA, and FtsZ in E. coli (63). Round MreB-depleted cells have a much larger diameter than normal rod-shaped cells and thus require more FtsZ to form complete Z rings. Indeed, round MreB-depleted B. subtilis cells frequently have incomplete Z rings (59), and overproduction of FtsZ may therefore allow round cells to keep up cell division, allowing for their (slow) propagation in spite of an abnormal cell shape. Biochemical Properties of MreB Proteins When Löwe and coworkers (110) showed that the structure of MreB is similar to that of actin, and that MreB is thus the bacterial homolog of actin, it became clear that bacteria contain an actin-like cytoskeleton. The 3D structure of MreB from Thermotoga maritima can be superimposed onto actin over almost its entire length with only minor deviations. MreB is also similar to Hsp70; however, the Hsp70 contains a large insert within one subdomain and a large C-terminal domain, absent in both actin and MreB. MreB is less similar to hexokinase or FtsA, and thus most closely related to actin (110). With the Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. ANRV322-MI61-27 ARI 6 August 2007 18:23 use of electron microscopy (EM), Löwe and colleagues showed that MreB assembled into long filamentous structures, dependent on the presence of ATP or GTP (but not of magnesium), in which two MreB strands form a straight protofilament (110). In contrast to eukaryotic actin, this two-stranded filament is straight rather than helical. In vitro, polymerized MreB structures rarely consist of twostranded filaments; rather, they consist mostly of sheets or bundles of filaments that can be rather straight or highly curved. Further biochemical analysis of T. maritima MreB has shown that polymerization of MreB is influenced by Ca2+ and Mg2+ concentrations and that end-to-end annealing of filaments plays no detectable role in polymerization (33). ATP hydrolysis of MreB has kinetics similar to that of actin, but it occurs at a much lower critical concentration (about 2 orders of magnitude), as does polymerization of MreB. This suggests that the affinity of MreB monomers to each other is much higher than the affinity between actin monomers. Given that about 8000 molecules of MreB were determined to be present in B. subtilis, which corresponds to a concentration of 5.6 μM, a lower critical concentration for polymerization is required for the formation of filaments in vivo, in contrast to actin, which is much more abundant in eukaryotic cells (about 550 μM). Unlike actin, which favors ATP over GTP, MreB can use ATP and GTP equally well for the formation of filaments, which are much more rigid than those formed by actin (34). Further, MreB assembles into bundles of filaments, whereas actin assembles into single protofilaments. These experiments show that MreB filaments have the potential to provide mechanical rigidity to bacterial cells, which may contribute substantially to the maintenance of the rod shape or other complex types of shapes. Ultracentrifugation experiments have shown that MreB is largely present as a polymer in C. crescentus, and a high proportion of MreB is present in membrane preparations, in parallel with cytoplasmic MreB. Although MreB does not contain any motifs typical for membrane association or membrane integration, the protein remained in the membrane fraction after removal of peripheral membrane proteins by sodium carbonate, revealing a close association with the C. crescentus cell membrane (35). EM: electron microscopy Dynamic Localization of MreB Proteins MreB and Mbl filaments underneath the cell membrane were shown to be highly dynamic in vivo when functional GFP fusions became available. Time-lapse microscopy showed that GFP-Mbl filaments change their pitch and even orientation throughout the cell cycle (14). Using FRAP, Carballido-Lopez & Errington (14) further showed that GFP-Mbl filaments undergo rapid turnover. In these experiments, a longitudinal half-side of a cell (a half-cell cut along the long axis) was bleached with a laser light. After GFP is excited, it takes an extended period (up to 60 min) until the molecule can be excited again. Therefore, if a static structure containing GFP is bleached, fluorescence will be lost for a long time. GFPMbl fluorescence reappears after about 5 min in the bleached side of the cell, revealing that the structures must exchange GFP-Mbl from the nonbleached section of the cell (14). Importantly, concomitant with the recovery of fluorescence, the nonbleached GFP-Mbl filaments in the other cell part lost fluorescence, indicating that GFP-Mbl filaments turn over by movement of nonbleached GFP from one lateral side of the cell to the other. Rapid time-lapse microscopy studies confirmed that MreB-like filaments are highly dynamic structures. GFP-MreB and GFP-Mbl filaments change their localization within 10-s intervals, and filaments apparently move underneath the membrane along a helical patch with a speed of about 0.1 μm s−1 (19). This speed of movement corresponds to the lower end of extension of actin filaments measured in vivo (0.1–1 μm s−1 for actin). www.annualreviews.org • Cytoskeletal Elements in Bacteria 599 ARI 6 August 2007 18:23 In contrast to the structures of MreB in B. subtilis, time-lapse microscopy of E. coli MreB has suggested that these structures are static (105). However, experiments visualizing single MreB-YFP molecules in C. crescentus have recently shown that MreB also localizes dynamically in this bacterium. Using continuous illumination and capturing 65 frames s−1 , Kim et al. (60) observed fast-moving populations (most likely corresponding to unpolymerized MreB) and slowly moving—almost static—populations of MreB-YFP molecules. The slowly moving populations are expected to be polymerized MreB molecules within the helical filaments, suggesting that MreB treadmills by adding to the growing tip of a filament (and thus becoming static) and dissociating from the shrinking end. Because the slow population did show some slow movement, the authors argue that MreB forms many short (∼400 nm) filaments, i.e., treadmills within many short filaments. The fast-moving MreB population did not move as slowly as expected for freely diffusing 64-kDa (MreB + GFP) proteins. Rather, the polymerization rate was comparable to that of membrane proteins, suggesting that MreB may be membrane associated and thus diffuse along the membrane until it hits the tip of a growing filament (60). The dynamic localization of MreB in B. subtilis is highly important for the function of the protein. A mutation in the phosphate 2 motif is dominant-negative in E. coli and in B. subtilis, in that it leads to aberrant cell shape (21, 64). This MreB mutant forms helical elements; however, they are abnormal and static in B. subtilis, i.e., there is no extension of filaments in time-lapse experiments and no recovery of fluorescence in FRAP experiments (21). Although this mutant does form filaments, B. subtilis cells expressing the mutant version but not wild-type MreB grow poorly and show a strong cell shape and segregation defect (21). Thus, MreB dynamics are not essential for viability, but they are important for the proper function of MreB. Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. ANRV322-MI61-27 600 Graumann Gene Multiplicity In contrast to E. coli and relatives, which contain only one MreB ortholog, several other bacteria contain two (e.g., T. maritima, Fusobacterium nucleatum) or three orthologs (bacilli, many gram-positive bacteria, and some cyanobacteria, e.g., Gloeobacter violaceus). B. subtilis contains three mreB-like genes: mreB, mbl, and mreBH. The depletion of MreB, Mbl, or MreBH has different consequences for the morphology of the cell (15, 18), suggesting that the proteins perform different functions. However, it has recently become clear that the three MreB orthologs form one cytoskeletal element, because all three proteins extensively colocalize within the helical filaments, as revealed by functional CFP/YFP fusions (15, 21), and because they interact with each other, as shown by fluorescence resonance energy transfer (FRET) and bimolecular fluorescence complementation (BiFC) (21). Moreover, a dominantnegative allele of MreB that affects the localization of wild-type MreB also affects the dynamic localization of Mbl, whose filaments become static (21). Thus, the interaction of MreB and Mbl is physiologically relevant, and a defect in one MreB ortholog will translate into a defect in the other orthologs. MreB, Mbl, and MreBH may form mixed polymers, and/or MreB orthologs may be important for the structural integrity of each of the helical filaments. MreB filaments were highly abnormal in the absence of Mbl but showed only a mildly aberrant localization in the absence of MreBH (20). These data suggest that Mbl may be more important than MreBH for the putative mixed filaments. The idea of mixed polymers must be biochemically verified; nevertheless, MreB, Mbl, and MreBH can no longer be viewed as independent helical filamentous structures. A Function in Control of Cell Morphology How might an intracellular helical structure affect the formation of a cylindrical PG cell Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. ANRV322-MI61-27 ARI 6 August 2007 18:23 envelope across the cell membrane? Although this point is still unclear, a possible concept is the interaction of MreB with membranebound cell wall–synthesizing enzymes (called Pbps, penicillin-binding proteins) (Figure 3c) and/or with membrane proteins that would mediate a directed localization of Pbps. Indeed, Daniel & Errington (17) have shown by using the fluorescently labeled antibiotic vancomycin (Van-FL) that binds to the d-Alad-Ala moieties of cell wall precursors that the incorporation of cell wall precursors occurs in a helical arrangement within the cell wall in many rod-shaped cells. Helical arrangement of cell wall synthesis was supported by the use of another drug that binds to the reducing end of PG precursors (106). During cell extension, new cell wall material is thus inserted in a helical pattern along the lateral cell wall, while during cell division, a major proportion of Van-FL localizes as a ring to the site of division. Daniel & Errington (17) further showed that rod-shaped cells that lack MreB, such as gram-positive Corynebacterium and Streptomyces species, grow by inserting new cell wall material into polar zones, but not along the lateral wall, and at the division site, and that cocci synthesize new cell wall layers only at the division site. These experiments show that different patterns of cell wall growth exist in bacteria, and that the MreB cytoskeleton may direct the insertion of lateral cell wall material. Helical insertion of Van-FL was reported to be absent in mbl mutant cells (17), but this finding has recently been disputed (106). In support of the idea that MreB orthologs may influence the 3D organization of cell wall synthesis, C. crescentus Pbps localize in a bandlike pattern along the cell membrane, which are lost in the absence of MreB (35). Several Pbps were coimmunoprecipitated from membrane preparations, suggesting that they form a complex in vivo whose position may be directed via MreB (35). B. subtilis Pbps also appear to be localized in a helical arrangement within the cell membrane (95). Furthermore, the MreC protein localizes at discrete areas in a seemingly helical pattern in C. crescen- tus (where it is a periplasmic protein) (22, 26) and in B. subtilis (where MreC has one membrane span and thus is likely a membrane protein) (67). Depletion of MreC leads to loss of distinct localization of Pbps (22, 26), as well as loss of additional outer membrane proteins that also localize in helical band-like patterns (22). In E. coli, MreB interacts with MreC (membrane anchored), which in turn interacts with MreD (63) (Figure 3c). Likewise, Mbl and MreC colocalize and interact in B. subtilis (21), suggesting that the spatial information of MreB/Mbl filaments is transferred across the membrane via MreC, which has a small cytosolic domain and a large periplasmic domain. Indeed, depletion of MreC interferes with the formation of MreB filaments in both organisms (20, 63). Finally, C. crescentus MreC interacts with Pbps (22), suggesting that the link MreB-MreC-Pbps may direct cell wall synthesis. However, now the puzzle begins. B. subtilis Pbps maintain their specific (probably helical) localization in the absence of MreB or Mbl (95). Although the helical incorporation of cell wall precursors was reported to be lost in the absence of Mbl, this was recently disputed, and helical localization of Van-FL was maintained in mbl-null cells and MreB-depleted cells (106). Moreover, C. crescentus MreB and MreC do not colocalize (26), and disruption of MreB filaments by the specific inhibitor A22 retains the helical localization of MreC and of Pbps (in this case, cells stop to divide and grow but retain their proper cell morphology). Only in cells that lose their curved morphology during depletion of MreB do Pbps lose their specific localization pattern (22). Thus, MreB and MreC form two distinct subcellular structures in C. crescentus, both of which are required for proper localization of Pbps, whereas MreB and MreC in E. coli and Mbl and MreC in B. subtilis physically interact. R. sphaeroides MreB localizes at midcell in a transverse ring-like structure, but also in a helical pattern away from midcell, indicating that it may be involved in some aspect of cell division and/or control of cell wall extension (100). MreC and Pbps also www.annualreviews.org • Cytoskeletal Elements in Bacteria Van-FL: fluorescent vancomycin 601 ARI 6 August 2007 18:23 localize in a similar helical band-like pattern in R. sphaeroides and colocalize throughout the cell cycle (99). MreB colocalizes with Pbp2 only during the elongation phase of cell growth, and during septation, MreB remains at the septation site, whereas Pbp2 relocalizes to the one-quarter and three-quarter positions. Thus, Pbp2 and MreC are involved in PG synthesis during cell elongation, and MreB appears to be more restricted to cell wall synthesis occurring during cell division. Thus, although the concept of helical arrangement of cell wall synthesis through helical arrangement of the MreB cytoskeletal structures appears attractive, it is still unclear if and how the helical pattern of MreB orthologs affects helical incorporation of cell wall material. It is also unclear how MreBs obtain their helical arrangement within the cytosol. A variation of the MreB/cell wall concept appears to apply to the third MreB ortholog of B. subtilis, MreBH. Depletion of MreBH leads to the formation of bent and bulged cells (15, 18). MreBH interacts with LytE, a cell wall hydrolase. Because the murein sacculus is enlarged inside gram-positive bacteria and additional layers are laid down, the outer layers need to be loosened and ultimately released to make space for the enlargement of the inner rings. This crucial activity is mediated by hydrolases, and in fact, B. subtilis cells constantly give off cell wall material into the medium. LytE also localizes in a helical pattern within the cell wall and interacts with MreBH, as shown by yeast two-hybrid experiments (15). Loss of MreBH abolishes the specific localization of LytE (15), suggesting the MreBH directs the pattern of LytE localization and action, possibly by directing the secretion of LytE. Indeed, the Sec secretion system localizes in a spot-like pattern following a helical path within the membrane in B. subtilis (13). However, the puzzle comes back again: SecY maintains its helical pattern in the absence of MreB or of Mbl, so the complete story of MreBH-directed localization of LytE still remains to be unraveled. Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. ANRV322-MI61-27 602 Graumann A Function During Bacterial Development As outlined above, MreB might play a role during development in Azospirillum. In Streptomyces coelicolor, MreB is dispensable for growth (77), in agreement with the idea that incorporation of new cell wall material occurs at the tip of growing S. coelicolor chains of cells, but not at the lateral sides (17). S. coelicolor mreB mutants show a strong defect in the formation of spores (77), which are produced from aerial hyphae that extend away from the surface into the air. MreB mutant spores are highly enlarged, distorted, and strongly sensitive to stress conditions in which wild-type spores easily survive. MreB localizes to the septa of sporulating aerial hyphae (77). Thus, in Streptomyces the mreB gene is used for a differentiation process, influencing the formation of proper cell walls in spores, rather than for rod-shape maintenance during growth. In agreement with this notion, MreB (and a second mreB paralogous gene) is present only in actinomycetes that form spores (such as streptomycetes), but not in nonsporulating species, such as Corynebacterium glutamicum cells, which also grow by polar extension (17). Deletion of mreC results in slowly growing cells, suggesting that, in contrast to MreB, MreC plays an important role in vegetative S. coelicolor cells (77). A Function in Chromosome Segregation Three independent approaches have shown that MreB proteins also play an important role in chromosome segregation. After initiation of replication, and long before its termination, duplicated regions of the chromosome are separated toward opposite cell poles in rodshaped bacteria such as B. subtilis and E. coli. Origin regions of the chromosome are separated with an average speed of ∼0.2 μm min−1 over a distance of about 1.5 μm, even during inhibition of cell wall growth, followed by all other regions soon after these have been duplicated by the replication machinery Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. ANRV322-MI61-27 ARI 6 August 2007 18:23 located in the center of the cell (117). These data show that an active intracellular machinery must exist that pushes or pulls duplicated chromosome regions, one into each cell half. What drives chromosome segregation is still unclear, but the action of MreB is important or essential for this process. Depletion of MreB in B. subtilis leads to rapid decondensation of the nucleoid that contains the chromosome(s), and to the formation of anucleate cells, i.e., cells that lack DNA after cell division has occurred, even during continued synthesis of MreC and MreD (whose genes are driven by the same promoter as mreB) (18, 20). This defect in chromosome segregation arises even before a defect in cell morphology is apparent, ruling out a secondary effect via cell shape abnormalities. The segregation defect occurs at the stage of separation of origin regions; during depletion of MreB (and to a lesser extent of Mbl), origin regions frequently remain in the cell center or are moved into the same cell half. In E. coli, induction of a dominant-negative ATPase mutant allele of MreB leads to similar phenotypes and, although origin regions can still be separated (in contrast to terminus regions), one sister cell frequently receives both chromosomes (64). The most direct evidence for the involvement of MreB orthologs in chromosome partitioning comes from experiments in C. crescentus, in which the addition of the drug A22 rapidly and specifically interferes with the formation of MreB helical filaments and leads to disintegration of the cytoskeletal structures. Loss of MreB filaments is accompanied by the inability to separate origin regions, although termini separate when A22 is added after origins have moved apart (41). MreB is associated with DNA of the origin regions, but not of the terminus regions, showing that MreB is a crucial component in the process of early chromosome segregation (41). It has been speculated that extension of MreB filaments toward the poles could provide the force to separate origin regions, in agreement with an observed potential poleward movement of 0.24 μm min−1 for MreB (accounting for the pitch of MreB helices) (44). Because actin can propel whole bacteria (Listeria) through the cytosol in macrophages and can push beads through a viscous solution (80), it is possible that MreB pushes duplicated chromosome regions toward opposite cell poles. Indeed, such a mechanism operates during segregation of plasmids (see below), in which an MreB homolog forms a filament that drives plasmids toward opposite cell poles. If this scenario is true, an adaptor (or several) must exist that links extending MreB filaments to those regions on the chromosome that have been replicated. Alternatively, as proposed by Gerdes and coworkers (62), MreB could serve as an anchor for RNA polymerase (RNAP), on the basis of the finding that E. coli MreB interacts with RNAP in vivo. Intriguingly, it had been proposed before that RNAP may be the driving force for chromosome segregation, owing to the finding that inhibition of transcription prevents separation of origin regions, even of those that have been duplicated (inhibition of transcription also interferes with replication) (25). Most genes are oriented away from replication origins and may be moved toward opposite cell poles via tracking through many directionally MreBanchored RNAP molecules. An mreB in frame deletion can be generated in a special medium containing high sucrose and magnesium concentrations, which stabilize the cell wall and membrane (36). This finding reinforces the idea that MreB has an important influence on the composition and/or structure of the cell envelope. Exponentially growing mreB-null cells had a normal cell shape in the special medium and did not show any chromosome segregation defect, which suggests that MreB is not involved in chromosome segregation. An explanation for these puzzling findings might be that in the absence of MreB, Mbl is essential for viability, even in the special medium (21). Depletion of Mbl in mreB cells leads to cessation of growth, a complete loss of regular cell shape, and a defect in chromosome segregation. This observation suggests that Mbl www.annualreviews.org • Cytoskeletal Elements in Bacteria RNAP: RNA polymerase 603 ANRV322-MI61-27 ARI 6 August 2007 18:23 can partially assume MreB functions under special conditions, and it reinforces the idea that loss of one paralog weakens the mixed MreB/Mbl/MreBH polymer, which may be compensated for through stabilization by special media conditions. ParM and AlfA: A Function in Plasmid Partitioning Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. Beyond dispute, a bacterial actin homolog has been shown to be a critical element in the separation of a low-copy-number plasmid in E. coli (high-copy-number plasmids are separated randomly and do not need an active mechanism that ensures their propagation). R1 plasmid harbors the ParRMC, which consists of parR and parM genes, and a cis-acting partitioning locus ( parC ), which contains several ParR binding repeats. ParR binds cooperatively to these repeats and may pair parC sites of two replicated plasmids (81) (Figure 4c). ParM is an actin-like protein and forms Factin-like structures in vitro in the presence of ATP (112). In contrast to MreB filaments, and similar to actin, the two ParM strands coil a c around each other in a right-handed helical path. The crystal structure of ParM is similar to that of MreB and of actin. Upon binding of ADP (compared with the crystal structure of nucleotide-free ParM), the interdomain cleft closes as domains I and II approach each other, and the two domains of ParM undergo a large (25◦ ) movement. It is unclear if this movement is the basis for induction of polymerization. In vivo, ParM forms one or two helical filaments in E. coli cells carrying a ParRMC plasmid (and only if ParR and parC are present) (82). However, ParM filaments were found only in a subset of cells in a growing culture that contained two separated plasmids. Filaments were not present in cells containing one or two plasmids at the middle of the cell (82). Most importantly, plasmids were always present at the tip of the ParM filaments (81), suggesting that the filaments push plasmids away from the middle of the cell toward opposite cell poles (Figure 4a). A simple and elegant mechanism appears to regulate directed pushing of plasmid through ParM filaments. ParM strongly interacts with ParR bound to the parS site, which is dependent on ATP ATP-ParM ADP-ParM ParR bound to parS site ParM/plasmid d b e AlfA-GFP Figure 4 Plasmid-segregating actin homologs ParM and AlfA, which form filaments that probably push plasmids toward opposite cell poles. (a) Immunofluorescence microscopy of E. coli cells carrying LacI-GFP-labeled plasmid (red ) and ParM stained with antibodies ( green). Outlines of cells are captured by phase contrast. Image reproduced with permission of the publisher. (b) B. subtilis cells expressing AlfA-GFP; membranes are stained in red. Image courtesy of J. Pogliano. (c–e) Cartoon showing segregation of plasmids toward opposite cell poles through growing ParM and AlfA filaments. 604 Graumann Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. ANRV322-MI61-27 ARI 6 August 2007 18:23 binding to ParM. ParR in turn enhances the ATPase activity of ParM, and ATP hydrolysis leads to dissociation of the ParM/ParR interaction (81). ParR appears to pair two plasmids via their parC sites, which biorients the plasmids (Figure 4d ) and further triggers filament formation of ParM (Figure 4e ). ParM in turn interacts with ParR, ensuring a close but transient contact between motor and target. Thus, ATP-bound ParM molecules can add to the tip of the filament (or rather, at the tips of the bundles of filaments), in between the tip and the (ParR-bound) parC site, generating a treadmilling process that prevents backward diffusion of plasmids and drives replicated plasmids apart into both cell halves (Figure 4e). Transport appears to be rapid because filaments of intermediate length could not be detected, in which the plasmids would be halfway between midcell and cell pole (82). This mechanism is a simple but efficient way to separate two pieces of DNA by using (a) an attachment site and (b) an adaptor that interacts with (c) a polymer motor and that affects the state of nucleotide binding of the motor subunits. Strikingly, polymerization of ParM could be observed in vitro. Fluorescently labeled purified ParM polymerizes in an ATPdependent manner through addition of ATPbound ParM to both sides of the filament, supporting the finding that bidirectional symmetrical polymerization can push plasmids towards the cell poles (37). Like actin, a critical minimal concentration of ParM is required to induce polymerization and, similar to barbed ends of actin filaments, ParM filaments extended ∼2 μm s−1 at each end (5 μM−1 s−1 ). However, a recent report shows that ParM forms randomly oriented filament bundles in the presence of crowding agents (87); therefore the observed single filaments in vitro and in vivo could consist of bidirectionally oriented bundles of filaments. A nonhydrolyzable ATP analog stabilized ParM filaments, whereas ATP-bound filaments showed dynamic instability, that is, at some variable, critical point, growing ParM filaments rapidly disintegrated from one end and less often from both ends. Thus, ATP hydrolysis can trigger disassembly of the dynamic filaments. Dynamic instability is a hallmark of microtubules, and that tubulin and ParM bear no similarity at the protein level suggests that dynamic instability has arisen through convergent evolution, as has their similar role in the segregation of DNA molecules. AlfA has recently been identified as a plasmid-segregating actin-like protein in B. subtilis. It is encoded on a plasmid and, together with its downstream gene alfB, it is necessary and sufficient for plasmid segregation during growth and sporulation (6). AlfA forms long filaments that extend from pole to pole in cells (Figure 4b) and probably push the duplicated plasmids toward opposite poles, analogous to ParM. AlfA filaments have a high turnover rate, and a mutant version of AlfA that displays reduced turnover within the filaments is impaired in plasmid segregation, showing that also in this case filament dynamics are important for function in vivo (6). ParM and ActA form two phylogenetically discrete groups of actin-like proteins, each representing an evolutionary class distinct from MreB, actin, and FtsA. AlfA has so far been found in gram-positive organisms, whereas ParM has been detected in gram-negative bacteria. The evolution of these classes of actin-like proteins shows that early during evolution the actin-like precursor evolved into different classes that perform distinct functions, all of which are based on the ability to form polymers that extend and shrink in a highly dynamic manner. Cytoskeletal Elements in Magnetotactic Bacteria Magnetotactic species are a group of bacteria that have a specialized machinery (usually encoded on a chromosomal island) that sets up a linear array of 15 to 20 magnetosomes in a straight line along the short axis of the vibrio (or spiral-formed cell) (97) (Figure 5b). Magnetosomes are membranous structures www.annualreviews.org • Cytoskeletal Elements in Bacteria 605 ANRV322-MI61-27 ARI 6 August 2007 18:23 a b Magnetosome MamK/MamJ filament MamJ-GFP Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. c Basal bodies Cytoplasmic filament Periplasmic flagellar filament Figure 5 MamK (actin homolog) and MamJ form a cytoskeletal element that positions magnetosomes in a straight line. (a) Schematic drawing of the MamK/MamJ structure that assembles at the short axis of the cell, with MamK forming cytoskeletal filaments with which MamJ probably interacts. (b) MamJ-GFP fusion expressed in Magnetospirillum gryphiswaldense cells (image by A. Scheffel, H.J. Defeu Soufo & D. Schüler). (c) Electron micrograph of a spirochete cell, from which the outer membrane has been removed to reveal the periplasmic flagellar filament, basal bodies (where flagella are attached), and cytoplasmic filaments, which run along the long axis of the cells. Image from Reference 56 with permission from the publisher. Magnetotaxis: ability of certain motile, aquatic bacteria to sense a magnetic field and coordinate their movement in response 606 (usually 50 nm in diameter) filled with magnetite (Fe3 O4 ) that arise through invagination of the inner cell membrane and are used for orientation according to the magnetic field. Because most magnetotactic bacteria are microaerophilic and thus prefer to dwell in the rather small interface between oxic and anoxic zones within soil, it is believed that magnetotaxis provides spatial information for up and down movement within soil to find the optimal conditions for growth. Until recently, it had been unclear how magnetosomes are aligned in a straight line along the cell’s short axis. With the use of cryo-electron tomography, a network of up to seven filaments ∼4 nm thick that run parallel to the line of magnetosomes close to the cell Graumann membrane has been visualized in Magnetospirillum magneticum and in M. gryphiswaldense. This cytoskeletal structure could consist of two factors that have recently been identified to be essential for alignment of magnetosomes: an actin ortholog called MamK and a novel type of protein called MamJ. In the absence of MamK or MamJ, both of which are encoded from genes situated in the magnetosome island, magnetosomes still form but are mislocalized and frequently clustered in the middle of the cells (61, 93). Both proteins fused to GFP, showing filamentous structures along the short axis of the cell (Figure 5a), corresponding to the aligned magnetosome structure. However, although magnetosomes are aligned along the center of the helical Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. ANRV322-MI61-27 ARI 6 August 2007 18:23 cells, filamentous MamK-GFP and MamJGFP structures extend from pole to pole. In addition to MamK, M. magneticum contains an MreB paralog encoded on the chromosome, adjacent to genes encoding for other morphology factors. MamK, ParM, and MreB form three distinct phylogenetic groups, each of which arose early during evolution, a testament to their different functions. The filamentous structures detected in cryo-EM are ∼6 nm thick, indicating that they may derive from actin-like protofilaments composed of MamK (61). MamK forms a straight filamentous structure from pole to pole when expressed in E. coli cells (88), suggesting that it self-assembles into the cytoskeletal structure as seen in Magnetospirillum. Guiding the arrangement of intracellular organelle-like structures in a bacterium is a novel function for bacterial actin orthologs. After induction in E. coli MamK filaments slowly formed and became visible after ∼75 min, apparently nucleating at one of the few sites in the cell. When a MamK-GFP fusion and a MamKmCherry fusion were expressed sequentially, a mostly mosaic pattern with generally separated green and red sections arose within the filament (88). These experiments support the idea of nucleation and extension events and of extension of preexisting filaments. MamK filaments are dynamic structures, similar to those formed by MreB and ParM, but as evidenced by their diverse phylogenetic evolution, MamK and ParM form straight filaments rather than helical filaments, as formed by MreB orthologs. MamJ is a highly acidic 456-amino-acid protein and has a unique repetitive domain structure (93). In the absence of all other magnetosome genes, MamJ-GFP localizes throughout the cytosol, suggesting that MamJ does not form a cytoskeletal structure itself but is associated with such a structure and possibly connects magnetosomes with a cytoskeletal element, possibly MamK. Timecourse experiments showed that magnetosomes form at many different positions within the cell. In wild-type cells they assemble at the cell center in a straight line at a later time point, and in the absence of MamJ, they collapse into an agglomeration after their assembly (93). These experiments suggest that magnetosomes gather into a filament after they have formed through an invagination of the cell membrane around a magnetite crystal at many positions within the cell, through the combined action of MamK and MamJ. An Archaeal Actin-Like Protein A fifth phylogenetic type of prokaryotic actinlike proteins is present in several species within the Euryarchaeota. Notably, three strains of the order Thermoplasmatales contain a highly conserved copy of Ta0583, whose structure was determined from Thermoplasma acidophilum. Ta0583 is most similar to ParM (rather than to MreB or actin) in its overall structure (92), has ATPase activity, forms helices with a filament width of 5.5 nm and an axial repeating unit of 5.5 nm, both of which are comparable to eukaryotic actin, and forms crystalline sheets in vitro (49, 92). On the basis of the packaging of monomers within the crystal, Ta0583 can indeed form actin-like protofilaments that interact with each other to form sheet-like structures seen in EM images in vitro. Ta0583 is closer to actin in terms of its polymerization kinetics and phylogeny (49). In vivo, Ta0583 appears to be a low-abundance protein unlikely to form an extended cytoskeletal structure, although it may play an important role in cell morphology in Thermoplasmatales especially because these bacteria lack a rigid cell wall structure. The true function of Ta0583 remains to be elucidated. INTERMEDIATE FILAMENT-LIKE PROTEINS Crescentin Mediates Cell Curvature in C. crescentus IF-type proteins assemble into 8- to 10-nmthick reversible filamentous structures and www.annualreviews.org • Cytoskeletal Elements in Bacteria 607 ANRV322-MI61-27 ARI 6 August 2007 Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. Motility: ability to move spontaneously and independently, usually directed by chemotaxis 18:23 covalently cross-linked meshworks in many eukaryotic cells (Figure 1), wherein they frequently provide mechanical strength. The first bacterial IF-type protein was identified by Jacobs-Wagner and coworkers (4) in a screen for straight C. crescentus cells. A gene, creS, was identified whose deletion resulted in growing but completely straight cells. The encoded crescentin protein is predicted to contain a high content of coiled coils as well as characteristic stutters, which are positions at which coiled coils are clearly disrupted. Extended coiled coils containing stutters are characteristic of eukaryotic IF proteins. Through the use of immunofluorescence and GFP fusion it was vizualized that crescentin forms a filamentous structure along the short axis of the cell (Figure 2d ). Strikingly, in stationaryphase C. crescentus cells that are elongated and highly spiraled, crescentin localized at the short axis throughout the large cells (4). Thus, the curved cytoskeletal crescentin structure is essential for cell curvature by an unknown mechanism. Like eukaryotic IF proteins, crescentin assembles into 10-nm-thick filaments and sheets in vitro without any need for cofactors or energy (4). Owing to their high degree of coiled coils, IFs usually have a highly elongated structure. Because many different sequences can form coiled coils, sequence conservation between IF proteins is low, making it difficult to identify them solely in silico. However, IF-type proteins are predicted to be present in many other bacterial species. With the identification of crescentin, it has now been established that none of the three cytoskeletal elements within eukaryotic cells was a eukaryal invention. It will be interesting to investigate the detailed role and function of IF-type proteins in Caulobacter and other bacteria. Cytoplasmic Filaments in Spirochetes: CfpA and Scc Proteins Spirochaeta are a phylum (major genetic lineage) within the kingdom of Bacteria and in608 Graumann clude many human pathogens. Spirochetes are unusual in that they have a helical or flat-plane wave shape, are motile via flagella that run along the length of the cells within the periplasmic space, and are attached to both ends of the cells. These features enable spirochetes to move through viscous and dense media and to pass through cell layers during infection. EM and cryo-EM studies have revealed the presence of cytoplasmic filaments 5 to 7 nm in diameter, four to six of which run the length of the cells underneath the cell membrane (50, 55, 56). In contrast to crescentin, the filaments run in a helical path along the long axis of the cells (Figure 3e). Cross-bridging structures appear to cross-link filaments with each other on the cytosolic side of the filaments, which on the opposite side are connected to the membrane by different proteins (55). Apparently, the filaments are located underneath the corresponding group of periplasmic flagella and were originally suggested to be involved in motility. Gentle lysis of the cells preserves the cytoplasmic filaments that still exhibit the same helical periodicity of the formerly intact cell. The major constituent of the filaments was identified to be CfpA, a 79-kDa polypeptide unique to spirochetes that is predicted to contain several extended coiled-coil regions (120). This property suggests that CfpA may belong to the family of IF proteins. When expressed in E. coli, CfpA induces the formation of extended filamentous structures, indicating that CfpA may indeed form filaments by itself. Deletion of the cfpA gene has a pleiotrophic phenotype, including formation of chains of cells, reduction in motility, and, most strikingly, a defect in the intracellular arrangement of DNA (57). In contrast to wild-type cells in which the DNA is distributed throughout the cytoplasm, cfpA mutants contain compacted DNA at various subcellular positions and form anucleate cells (2% of the population). Thus, CfpA may affect the positioning of DNA within the cells (and/or cell division) and motility. Periplasmic Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. ANRV322-MI61-27 ARI 6 August 2007 18:23 flagella localize normally in the absence of CfpA, and vice versa, suggesting that both systems assemble independently of each other (56). Because lower mobility of the cfpA mutants could be due to the chaining morphology, it is unclear if CfpA has a direct or indirect effect on the function of flagella. Spirochetes have a highly unusual genome structure, including one large chromosome that is frequently linear and more than 20 additional minichromosomes and plasmids, each with different replicons, that are also frequently linear and have terminal hairpin telomeres. Possibly, this unusual genome requires a specialized IF-like filamentous structure for its propagation into daughter cells, which arise through FtsZ-dependent medial cell division (24) (Figure 3e). An additional protein containing an extended N-terminal coiled-coil region is present in Leptospira species. Scc protein forms helical structures 2 to 3 μm in length and also single filamentous structures 6 to 10 nm in diameter in vitro, independent of any cofactor, that are stable for days (76). When expressed in E. coli cells, Scc-GFP forms a single extended filament through the cell from pole to pole (highly reminiscent of ParM and AlfA) or underneath the cell membrane. Purified Scc binds to RNA and to DNA and forms striking rod-shaped nucleoprotein structures. Deletion of the Scc-encoding gene altered colony morphology, but not cell morphology or motility, indicating that Scc may be involved in chemotaxis during spreading of cells (76). It will be interesting to elucidate further the function of cytoplasmic filaments, CfpA, and Scc, as well as the mode of motility in spirochetes. AglZ from Myxococcus xanthus AglZ in involved in social motility in the bacterium Myxococcus xanthus and interacts with a small GTPase that is also involved in this process (119). The N terminus of AglZ shows similarity to the receiver domain of two-component response regulators, and the C terminus contains coiled-coil motifs. The purified coiled-coil part of AglZ forms filamentous structures in vitro. It will be interesting to determine the function of the protein, which may belong to the IF protein family. OTHER TYPES OF CYTOSKELETAL ELEMENTS Cytoskeletal Elements in Cell Wall–Less Bacteria: Fibril Protein and MreB-Like Filaments Mollicutes are a class of bacteria (e.g., Mycoplasma, Acholeplasma, and Spiroplasma) that do not contain a cell wall, although they phylogenetically belong to the grampositive phylum of bacteria. However, Mollicutes can have intricate cell morphologies, such as the long corkscrew-like Spiroplasma species. These bacteria can be as long as 10 μm but are only ∼300 nm in diameter. It has been unclear how Mollicutes can have a defined cell shape in the absence of a rigid wall. Thin specimens are ideal for a new technology called cryo-electron tomography. This technique uses subtle density differences in frozen cells, in which the formation of ice crystals has been suppressed through sudden freezing to –10◦ C (liquid methane) in milliseconds. Several images are taken from different angles, and 3D image reconstruction is computationally achieved from calculating actual density differences from all images. The Baumeister group (65) has resolved intracellular cytoskeletal elements in Spiroplasma melliferum that were previously unknown. Two types of sheets of filamentous structures lie underneath the membrane along the short axis of the cell (Figure 3e). A central sheet of nine thin filaments spaced ∼4 nm apart is flanked on both sides by a sheet of five thick filaments spaced 11 nm apart (65). The dimensions of the inner filaments are highly similar to those formed by actin or MreB and could thus be composed of an MreB ortholog. Indeed, Spiroplasma contains five mreB genes www.annualreviews.org • Cytoskeletal Elements in Bacteria 609 ARI 6 August 2007 18:23 in its genome. The outer sheets are composed of fibril, a protein unique to Spiroplasma. Fibril is a 59-kDa protein that is thought to form a dimer; these proteins appear to form tetramers that polymerize into extended helical structures with an axial repeat of 9 nm (108, 116). Given that each monomer is ∼5 nm in diameter, the 11-nm-wide filaments observed are most likely composed of fibril tetramers. Computer models predict that Spiroplasma can locally change its handedness, from rightto left-handed or vice versa (65, 109). Shortening one of the outer sheets relative to the other would generate such a change in handedness, and if such a change moved through the cell from one end to the other (like a wave), this would generate a propelling force suitable to propel Spiroplasma through a liquid. It remains to be seen if this is indeed a mechanism for swimming without a flagellum. Bacteria from the species Mycoplasma can have intricate cell shapes, ranging from pear-shaped cells to cells having stalk-like extension and bulged cell bodies. Using conventional EM, researchers (42, 75) have observed distinct subcellular structures in Mycoplasma genitalium that appeared to be fibrils or helically arranged blade-like structures. When membranes and cytosolic proteins are removed with Triton X100, an intriguing rod-like structure (apparently consisting of many parallel filaments) with a rounded tip that has the rough dimensions of 300 × 40 nm can be visualized (42). Although the composition of this Triton-insoluble fraction of Mycoplasma cells has been investigated (91), the defined components of the rod-like structure are still unclear, and the function of these structures remains to be elucidated. Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. ANRV322-MI61-27 ParA-Type Proteins form Plasmid-Segregating Filaments In addition to the ParR/ParM system (also called the type II segregation system), a sec610 Graumann ond type of segregation system exists (type I) that distributes low-copy-number plasmids to future bacterial daughter cells. The plasmidencoded system consists of a defined partitioning site ( par) and two genes in a bicistronic operon that encode for a Walker-box ATPase (ParA, which is similar to MinD) and for a DNA binding protein (ParB). ParB-type proteins bind to the par site (or in some cases sites) situated close to the par operon and interact with their ParA counterparts (39). ParA-type proteins form helical filaments that rapidly oscillate along the nucleoids (27). In vitro, ParA forms ATP-dependent filaments and bundles of filaments, in which the filaments appear to twist around each other (5, 28, 68). Consistent with the formation of higher-order filamentous structures, ParA ATPase activity is cooperative. Thus, formation of dynamic filaments appears to be a conserved function of MinDtype ATPases. The interaction between ParA and ParB suggests that ParA dynamics distribute plasmids along the nucleoids and thus ensure that sufficient copies are positioned within each cell half before cell division occurs. It is also clear that a helical pattern is a recurring scheme for the localization of many bacterial proteins that form highly dynamic filaments. Bacterial Dynamin Dynamins are a family of multidomain GTPases that perform a mechanochemical function in endocytosis, vesicle trafficking, and mitochondrial division and morphology in eukaryotic cells (89). For example, dynamin I forms a helical collar around the neck of clathrin-coated vesicles and pinches them off from the membrane. In vitro, dynamins form oligomeric rings and long helical structures that constrict upon binding of GTP. The pitch of dynamin spirals assembled on lipid vesicles increases upon GTP hydrolysis, suggesting that dynamins pinch off vesicles in a springlike manner (89). Recently, the structure of a cyanobacterial dynamin-like protein has been resolved, Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. ANRV322-MI61-27 ARI 6 August 2007 18:23 revealing striking conservation of the GTPase domain structure (69). The Nostoc punctiforme bacterial dynamin-like protein (BDLP) is a low-affinity GTPase that forms long tubules in the presence of GMP-PNP (a nonhydrolyzable analog of GTP) and of vesicles in vitro, and it tubulates vesicles in a compact helical coating with a 6-nm interfilament pitch repeat and a diameter of ∼45 nm. The helix has a pattern of a cartwheel with a 17-fold symmetry, when looked at from top or bottom, similar to that of eukaryotic dynamins. Lipids may be bound at the inside of the tubules, via the hydrophilic paddle region. N. punctiforme BDLP localizes to the cell membrane in the filamentous cyanobacterium in a punctate pattern (69). The B. subtilis BDLP ortholog also localizes in a similar pattern (M. Krishnamurthy & P.L. Graumann, unpublished results), indicating that BDLPs may play a role at the membrane in many bacterial species, because genes encoding dynamin-like proteins are also present in many other bacterial genomes. It will be exciting to determine which function BDLPs confer. Cytoskeletal Elements of Unknown Composition Using cryo-EM, Briegel et al. (12) observed apparently novel as yet uncharacterized cytoskeletal elements in C. crescentus cells. About one-fourth of the cells contained bundles of filaments adjacent to the membrane on the concave side of the cells, which were observed even in creS-deleted cells and in cells in which MreB filament formation was inhibited by A22. Thus, these elements that were much shorter than the long axis of the cell may present novel filament-forming proteins. Similarly, structures called cytoplasmic ribbons (bundles of three to five ribbons without an apparent connection to the membrane) were detected in about half of all cells analyzed, even in the absence of CreS and MreB. Two additional structures, polar ribbons and a ring-like structure, were detectable at low frequency, but nothing is known about their nature. Thus, at least four independent filamentous structures appear to exist in C. crescentus, suggesting that the bacterial cytoskeleton is even more intricate than recently believed (12). BDLP: bacterial dynamin-like protein SUMMARY POINTS 1. Cytoskeletal elements also exist in bacteria and thus arose early during evolution. 2. Bacterial tubulin-like protein FtsZ and actin-like MreB proteins form highly dynamic filaments and interact with proteins involved in cell division or cell shape maintenance, respectively. 3. FtsZ is the first protein known to form a ring at midcell and recruits further cell division proteins to form the divisome that ultimately drives formation of the division septum. 4. MreB proteins form helical filaments underneath the cell membrane and are involved in maintenance of cell shape, possibly directing locations of cell wall synthesis; MreB may also play a role in chromosome segregation. 5. Actin-like ParM, AlfA, and MamK proteins form straight filaments. ParM and AlfA drive plasmids toward opposite cell poles, and MamK positions magnetosomes (special organelles) in a straight line underneath the cell membrane. 6. ParA- and MinD-like Walker box ATPases form filaments within cells and mediate partitioning of certain plasmids or positioning of the FtsZ ring, respectively. www.annualreviews.org • Cytoskeletal Elements in Bacteria 611 ANRV322-MI61-27 ARI 6 August 2007 18:23 7. Crescentin, an intermediate filament-like protein, is essential for cell curvature in C. crescentus and forms a filamentous structure at the short axis of the cells. 8. Spirochetes and Spiroplasma cells have additional distinct filamentous cytoskeletal elements, the function of which is still unclear. DISCLOSURE STATEMENT Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. The author is not aware of any biases that might be perceived as affecting the objectivity of this review. ACKNOWLEDGMENTS I would like to thank Christine Jacobs-Wagner and Matt Cabeen (Yale University), Herve Joel Defeu Soufo (University of Freiburg), Joe Pogliano (UCSD), Andre Scheffel (Max Planck Institute, Bremen, Germany) and Dirk Schüler (University of Munich) for providing images. Work in my laboratory is supported by grants from the Deutsche Forschungsgemeinschaft. LITERATURE CITED 1. Abhayawardhane Y, Stewart GC. 1995. Bacillus subtilis possesses a second determinant with extensive sequence similarity to the Escherichia coli mreB morphogene. J. Bacteriol. 177:765–73 2. Addinall SG, Lutkenhaus J. 1996. FtsZ-spirals and -arcs determine the shape of the invaginating septa in some mutants of Escherichia coli. Mol. Microbiol. 22:231–37 3. Amos LA, van den Ent F, Löwe J. 2004. Structural/functional homology between the bacterial and eukaryotic cytoskeletons. Curr. Opin. 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ANRV322-MI61-27 618 Graumann AR322-FM ARI 9 July 2007 9:23 Annual Review of Microbiology Contents Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. Volume 61, 2007 Frontispiece Margarita Salas p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p xiv 40 Years with Bacteriophage Ø29 Margarita Salas p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 1 The Last Word: Books as a Statistical Metaphor for Microbial Communities Patrick D. Schloss and Jo Handelsman p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 23 The Mechanism of Isoniazid Killing: Clarity Through the Scope of Genetics Catherine Vilchèze and William R. Jacobs, Jr. p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 35 Development of a Combined Biological and Chemical Process for Production of Industrial Aromatics from Renewable Resources F. Sima Sariaslani p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 51 The RNA Degradosome of Escherichia coli: An mRNA-Degrading Machine Assembled on RNase E Agamemnon J. Carpousis p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 71 Protein Secretion in Gram-Negative Bacteria via the Autotransporter Pathway Nathalie Dautin and Harris D. Bernstein p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p 89 Chlorophyll Biosynthesis in Bacteria: The Origins of Structural and Functional Diversity Aline Gomez Maqueo Chew and Donald A. Bryant p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p113 Roles of Cyclic Diguanylate in the Regulation of Bacterial Pathogenesis Rita Tamayo, Jason T. Pratt, and Andrew Camilli p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p131 Aggresomes and Pericentriolar Sites of Virus Assembly: Cellular Defense or Viral Design? Thomas Wileman p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p149 As the Worm Turns: The Earthworm Gut as a Transient Habitat for Soil Microbial Biomes Harold L. Drake and Marcus A. Horn p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p169 vi AR322-FM ARI 9 July 2007 9:23 Biogenesis of the Gram-Negative Bacterial Outer Membrane Martine P. Bos, Viviane Robert, and Jan Tommassen p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p191 SigB-Dependent General Stress Response in Bacillus subtilis and Related Gram-Positive Bacteria Michael Hecker, Jan Pané-Farré, and Uwe Völker p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p215 Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. Ecology and Biotechnology of the Genus Shewanella Heidi H. Hau and Jeffrey A. Gralnick p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p237 Nonhomologous End-Joining in Bacteria: A Microbial Perspective Robert S. Pitcher, Nigel C. Brissett, and Aidan J. Doherty p p p p p p p p p p p p p p p p p p p p p p p p p p p p259 Postgenomic Adventures with Rhodobacter sphaeroides Chris Mackenzie, Jesus M. Eraso, Madhusudan Choudhary, Jung Hyeob Roh, Xiaohua Zeng, Patrice Bruscella, Ágnes Puskás, and Samuel Kaplan p p p p p p p p p p p p p p p p p283 Toward a Hyperstructure Taxonomy Vic Norris, Tanneke den Blaauwen, Roy H. Doi, Rasika M. Harshey, Laurent Janniere, Alfonso Jiménez-Sánchez, Ding Jun Jin, Petra Anne Levin, Eugenia Mileykovskaya, Abraham Minsky, Gradimir Misevic, Camille Ripoll, Milton Saier, Jr., Kirsten Skarstad, and Michel Thellier p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p309 Endolithic Microbial Ecosystems Jeffrey J. Walker and Norman R. Pace p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p331 Nitrogen Regulation in Bacteria and Archaea John A. Leigh and Jeremy A. Dodsworth p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p349 Microbial Metabolism of Reduced Phosphorus Compounds Andrea K. White and William W. Metcalf p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p379 Biofilm Formation by Plant-Associated Bacteria Thomas Danhorn and Clay Fuqua p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p401 Heterotrimeric G Protein Signaling in Filamentous Fungi Liande Li, Sara J. Wright, Svetlana Krystofova, Gyungsoon Park, and Katherine A. Borkovich p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p423 Comparative Genomics of Protists: New Insights into the Evolution of Eukaryotic Signal Transduction and Gene Regulation Vivek Anantharaman, Lakshminarayan M. Iyer, and L. Aravind p p p p p p p p p p p p p p p p p p p p453 Lantibiotics: Peptides of Diverse Structure and Function Joanne M. Willey and Wilfred A. van der Donk p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p477 The Impact of Genome Analyses on Our Understanding of Ammonia-Oxidizing Bacteria Daniel J. Arp, Patrick S.G. Chain, and Martin G. Klotz p p p p p p p p p p p p p p p p p p p p p p p p p p p p p503 Contents vii AR322-FM ARI 9 July 2007 9:23 Morphogenesis in Candida albicans Malcolm Whiteway and Catherine Bachewich p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p529 Structure, Assembly, and Function of the Spore Surface Layers Adriano O. Henriques and Charles P. Moran, Jr. p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p555 Cytoskeletal Elements in Bacteria Peter L. Graumann p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p589 Indexes Annu. Rev. Microbiol. 2007.61:589-618. Downloaded from arjournals.annualreviews.org by Universidad de Chile on 06/02/08. For personal use only. Cumulative Index of Contributing Authors, Volumes 57–61 p p p p p p p p p p p p p p p p p p p p p p p p619 Cumulative Index of Chapter Titles, Volumes 57–61 p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p p622 Errata An online log of corrections to Annual Review of Microbiology articles may be found at http://micro.annualreviews.org/ viii Contents
