The timing and manner of disassembly of the apparatuses for chloroplast and mitochondrial division in the red alga Cyanidioschyzon merolae

The timing and manner of disassembly of the apparatuses for chloroplast division (the plastid-dividing ring; PD ring) and mitochondrial division (the mitochondrion-dividing ring; MD ring) were investigated in the red alga Cyanidioschyzon merolae De Luca, Taddei and Varano. To do this, we synchronized cells both at the final stage of and just after chloroplast and mitochondrial division, and observed the rings in three dimensions by transmission electron microscopy. The inner (beneath the stromal face of the inner envelope) and middle (in the inter-membrane space) PD rings disassembled completely, and disappeared just before completion of chloroplast division. In contrast, the outer PD and MD rings (on the cytoplasmic face of the outer envelope) remained in the cytosol between daughter organelles after chloroplast and mitochondrial division. The outer rings started to disassemble and disappear from their surface just after organelle division, initially clinging to the outer envelopes at both edges before detaching. The results suggest that the two rings inside the chloroplast disappear just before division, and that this does not interfere with completion of division, while the outer PD and MD rings function throughout and complete chloroplast and mitochondrial division. These results, together with previous studies of C. merolae, disclose the entire cycle of change of the PD and MD rings. Received: 19 May 2000 / Accepted: 3 August 2000     

The primitive red algae Cyanidium caldarium and Cyanidioschyzon merolae as model system for investigating the dividing apparatus of mitochondria and plastids

The Cyanidiophyceae species Cyanidium caldarium and Cyanidioschyzon merolae have played important roles in showing the division mechanisms of mitochondria and plastids. The apparatus regulating mitochondrial and plastid divisions was formerly unknown. We first identified the division apparatus of plastids, called the plastid-dividing ring (PD ring), in C. caldarium and the division apparatus of mitochondria, called the mitochondrion-dividing ring (MD ring), in C. merolae. Eukaryotic cell division is therefore controlled by at least three dividing apparati (rings)—a contractile ring, an MD ring, and a PD ring—while bacterial division is controlled by a single bacterial contractile FtsZ ring. BioEssays 20 :344-354, 1998.© 1998 John Wiley & Sons, Inc.     

A plant-specific dynamin-related protein forms a ring at the chloroplast division site

Chloroplasts have retained the bacterial FtsZ for division, whereas mitochondria lack FtsZ except in some lower eukaryotes. Instead, mitochondrial division involves a dynamin-related protein, suggesting that chloroplasts retained the bacterial division system, whereas a dynamin-based system replaced the bacterial system in mitochondria during evolution. In this study, we identified a novel plant-specific group of dynamins from the primitive red alga Cyanidioschyzon merolae. Synchronization of chloroplast division and immunoblot analyses showed that the protein (CmDnm2) associates with the chloroplast only during division. Immunocytochemical analyses showed that CmDnm2 appears in cytoplasmic patches just before chloroplast division and is recruited to the cytosolic side of the chloroplast division site to form a ring in the late stage of division. The ring constricts until division is complete, after which it disappears. These results show that a dynamin-related protein also participates in chloroplast division and that its behavior differs from that of FtsZ and plastid-dividing rings that form before constriction at the site of division. Combined with the results of a recent study of mitochondrial division in Cyanidioschyzon, our findings led us to hypothesize that when first established in lower eukaryotes, mitochondria and chloroplasts divided using a very similar system that included the FtsZ ring, the plastid-dividing/mitochondrion-dividing ring, and the dynamin ring.     

Chloroplast division machinery as revealed by immunofluorescence and electron microscopy

The division of chloroplasts (plastids) is critical for the viability of photosynthetic eukaryotes. Previously we reported on the chloroplast division apparatus, which consists of inner and outer double or triple rings (PD rings). Chloroplasts are assumed to arise from bacterial endosymbionts, while bacterial division is instigated by a bacterial cytokinesis Z-ring protein (FtsZ). Here we present immunofluorescence and electron-microscopic evidence of chloroplast division via complex machinery involving the FtsZ and PD rings in the higher plant Pelargonium zonale Ait. Prior to invagination, the FtsZ protein was attached to a ring at the stromal division site. Following formation of the FtsZ ring, the inner stromal and outer cytosolic PD rings appeared, signifying the initiation of invagination. The FtsZ ring and the PD rings were found at the leading edge of chloroplast constriction throughout division. During chloroplast division, neither the FtsZ nor the inner rings changed width, but the volume of the outer ring gradually increased. We suggest that the FtsZ ring determines the division region, after which the inner and outer PD rings are formed as a lining for the FtsZ ring. With the outer ring providing the motivating force, the FtsZ and inner PD rings ultimately decompose to their base components.     

Triple immunofluorescent labeling of FtsZ, dynamin, and EF-Tu reveals a loose association between the inner and outer membrane mitochondrial division machinery in the red alga Cyanidioschyzon merolae.

In the mitochondria of primitive eukaryotes, FtsZ and dynamin are part of the machinery involved in division of the inner and outer membranes, respectively. These genes also commonly function in the same manner during chloroplast division. In this study, a relationship between the localization of the inner and outer division machinery was directly shown for the first time. Triple immunofluorescent labeling was performed in the red alga Cyanidioschyzon merolae by a device using narrow bandpass filter sets and bright photostable dyes. FtsZ (CmFtsZ1) and dynamin (CmDnm1) localizations were examined simultaneously throughout the mitochondrial division cycle with an alternative mitochondrial marker protein, the mitochondrial translation elongation factor EF-Tu, whose localization was also shown to be identical to the mitochondrial matrix. FtsZ and dynamin did not necessarily co-localize when both were recruited to the mitochondrial constriction site, indicating that inner and outer dividing machineries are not in tight association during the late stage of division.     

Mitochondrial division by an electron-dense ring inCyanidioschyzon merolae

Summary The first identification of a mitochondria-dividing ring (MD-ring), which is located in the cytoplasm near the outer envelope membrane at the constricted isthmus of dividing mitochondria in the red algaCyanidioschyzon merolae, is reported. The MD-ring is about 50 nm wide and 10 nm thick at early stage of mitochondrial constriction and is a somewhat electron-dense circular bundle. The MD-ring is believed to be essential for the division of mitochondrion (mitochondriokinesis) since the ring appears at the equatorial region of the mitochondria just before the initiation of mitochondrial division and can be observed throughout mitochondrial division. The MD-ring has features comparable to that of the plastid-dividing (PD) ring.Abbreviations MD mitochondria-dividing - PD plastid-dividing     

An evolutionary puzzle: chloroplast and mitochondrial division rings

Consistent with their bacterial origin, chloroplasts and primitive mitochondria retain a FtsZ ring for division. However, chloroplasts and mitochondria have lost most of the proteins required for bacterial division other than FtsZ and certain homologues of the Min proteins, but they do contain plastid and mitochondrion dividing rings, which were recently shown to be distinct from the FtsZ ring. Moreover, recent studies have revealed that rings of the eukaryote-specific dynamin-related family of GTPases regulate the division of chloroplasts and mitochondria, and these proteins emerged early in eukaryotic evolution. These findings suggest that the division of chloroplasts and primitive mitochondria involve very similar systems, consisting of an amalgamation of rings from bacteria and eukaryotes.     

Plastid division is driven by a complex mechanism that involves differential transition of the bacterial and eukaryotic division rings

During plastid division, two structures have been detected at the division site in separate analyses. The plastid-dividing ring can be detected by transmission electron microscopy as two (or three) electron-dense rings: an outer ring on the cytosolic face of the outer envelope, occasionally a middle ring in the intermembrane space, and an inner ring on the stromal face of the inner envelope. The FtsZ ring, which plays a central role in bacterial division, also is involved in plastid division and is believed to have descended to plastids from cyanobacterial endosymbiosis. The relationship between the two structures is not known, although there is discussion regarding whether they are identical. Biochemical and immunocytochemical investigations, using synchronized chloroplasts of the red alga Cyanidioschyzon merolae, showed that the plastid FtsZ ring is distinct and separable from the plastid-dividing ring. The FtsZ ring localizes in stroma and faces the inner plastid-dividing ring at the far side from the inner envelope. The FtsZ ring and the inner and outer plastid-dividing rings form in that order before plastid division. The FtsZ ring disappears at the late stage of constriction before dissociation of the plastid-dividing ring, when the constriction is still in progress. Our results suggest that the FtsZ ring;-based system, which originated from a plastid ancestor, cyanobacteria, and the plastid-dividing ring;-based system, which probably originated from host eukaryotic cells, form a complex and are involved in plastid division by distinct modes.     

Real-time analyses of chloroplast and mitochondrial division and differences in the behavior of their dividing rings during contraction

The time courses of chloroplast and mitochondrial division and the morphological changes in the plastid-dividing ring (PD ring) and mitochondrion-dividing ring (MD ring) during chloroplast and mitochondrial division were studied in Cyanidioschyzon merolae De Luca, Taddei and Varano. To accomplish this, chloroplast and cell division of living cells were continuously video-recorded under light microscopy, and the morphological changes in the PD and MD rings were analyzed quantitatively and three-dimensionally by transmission electron microscopy (TEM). Under the light microscope, the diameters of the chloroplast and the cell decreased at uniform velocities, the speed depending on the temperature. To study in detail the sequential morphological change of the mitochondrion in M phase and the contractile mechanism in the divisional planes of the chloroplast and the mitochondrion, we observed the PD and MD rings, which are believed to promote contraction, under TEM, using the diameter of the chloroplast as an index of the time. Three PD rings (an outer PD ring on the cytoplasmic face of the outer envelope, a middle PD ring in the intermembrane space, and an inner PD ring on the stromal face of the inner envelope) were clearly observed, but only the outer MD ring could be observed. The PD ring started to contract soon after it formed, while the contraction of the MD ring did not occur immediately after formation, but was delayed until the contraction of the PD ring was almost complete. Once the MD ring began to contract, the rate of decrease of its circumference was 4 times as high as that of the PD ring. As the outer PD and MD rings contracted, they grew thicker and maintained a constant volume, while the thickness of the inner PD ring did not change and its volume decreased at a constant rate with contraction. In the early stage of contraction, the widths of the three PD rings increased in order, from the outer to the inner ring. With contraction, their widths changed at different rates until they came to have much the same width. In cross-section, the MD ring was wider where it was next to the chloroplast than at the opposite side, adjacent to the nucleus in the early stage of contraction. By the late stage, the widths of the two sides became equal. In our observations, the microbody elongated along the outer MD ring and touched the outer PD ring during contraction of the PD and MD rings. These results clearly revealed differences between the mode of contraction of the outer, middle, and inner PD rings, and between the PD and the MD rings. They also revealed the coordinated widening of the three PD rings, and suggested that the microbody plays a role in the contraction of the PD and MD rings. Received: 1 July 1998 / Accepted: 1 September 1998     

Origin and evolution of the chloroplast division machinery

Chloroplasts were originally established in eukaryotes by the endosymbiosis of a cyanobacterium; they then spread through diversification of the eukaryotic hosts and subsequent engulfment of eukaryotic algae by previously nonphotosynthetic eukaryotes. The continuity of chloroplasts is maintained by division of preexisting chloroplasts. Like their ancestors, chloroplasts use a bacterial division system based on the FtsZ ring and some associated factors, all of which are now encoded in the host nuclear genome. The majority of bacterial division factors are absent from chloroplasts and several new factors have been added by the eukaryotic host. For example, the ftsZ gene has been duplicated and modified, plastid-dividing (PD) rings were most likely added by the eukaryotic host, and a member of the dynamin family of proteins evolved to regulate chloroplast division. The identification of several additional proteins involved in the division process, along with data from diverse lineages of organisms, our current knowledge of mitochondrial division, and the mining of genomic sequence data have enabled us to begin to understand the universality and evolution of the division system. The principal features of the chloroplast division system thus far identified are conserved across several lineages, including those with secondary chloroplasts, and may reflect primeval features of mitochondrial division. Shin-ya Miyagishima is the recipient of the Botanical Society Award for Young Scientists, 2004.     

Organelle division: Self-assembling GTPase caught in the middle

Recent findings indicate that the dynamin GTPase helps to divide animal and fungal mitochondria, and that the tubulin-like FtsZ GTPase is involved in division of, not only most bacteria, but also chloroplasts and probably mitochondria of unicellular eukaryotes.     

Novel filaments 5 nm in diameter constitute the cytosolic ring of the plastid division apparatus

The plastid division apparatus (called the plastid-dividing ring) has been detected in several plant and algal species at the constricted region of plastids by transmission electron microscopy. The apparatus is composed of two or three rings: an outer ring in the cytosol, an inner ring in the stroma, and a middle ring in the intermembrane space. The components of these rings are not clear. FtsZ, which forms the bacterial cytokinetic ring, has been proposed as a component of both the inner and outer rings. Here, we present the ultrastructure of the outer ring at high resolution. To visualize the outer ring by negative staining, we isolated dividing chloroplasts from a synchronized culture of a red alga, Cyanidioschyzon merolae, and lysed them with nonionic detergent Nonidet P-40. Nonidet P-40 extracted primarily stroma, thylakoids, and the inner and middle rings, leaving the envelope and outer ring largely intact. Negative staining revealed that the outer ring consists of a bundle of 5-nm filaments in which globular proteins are spaced 4.8 nm apart. Immunoblotting using an FtsZ-specific antibody failed to show immunoreactivity in the fraction containing the filament. Moreover, the filament structure and properties are unlike those of known cytoskeletal filaments. The bundle of filaments forms a very rigid structure and does not disassemble in 2 M urea. We also identified a dividing phase-specific 56-kD protein of chloroplasts as a candidate component of the ring. Our results suggest that the main architecture of the outer ring did not descend from cyanobacteria during the course of endosymbiosis but was added by the host cell early in plant evolution.     

Two Dictyostelium orthologs of the prokaryotic cell division protein FtsZ localize to mitochondria and are required for the maintenance of normal mitochondrial morphology

In bacteria, the protein FtsZ is the principal component of a ring that constricts the cell at division. Though all mitochondria probably arose through a single, ancient bacterial endosymbiosis, the mitochondria of only certain protists appear to have retained FtsZ, and the protein is absent from the mitochondria of fungi, animals, and higher plants. We have investigated the role that FtsZ plays in mitochondrial division in the genetically tractable protist Dictyostelium discoideum, which has two nuclearly encoded FtsZs, FszA and FszB, that are targeted to the inside of mitochondria. In most wild-type amoebae, the mitochondria are spherical or rod-shaped, but in fsz-null mutants they become elongated into tubules, indicating that a decrease in mitochondrial division has occurred. In support of this role in organelle division, antibodies to FszA and FszA-green fluorescent protein (GFP) show belts and puncta at multiple places along the mitochondria, which may define future or recent sites of division. FszB-GFP, in contrast, locates to an electron-dense, submitochondrial body usually located at one end of the organelle, but how it functions during division is unclear. This is the first demonstration of two differentially localized FtsZs within the one organelle, and it points to a divergence in the roles of these two proteins.     

The division of pleomorphic plastids with multiple FtsZ rings in tobacco BY-2 cells

Plastids, an essential group of plant cellular organelles, proliferate by division to maintain continuity through cell lineages in plants. In recent years, it was revealed that the bacterial cell division protein FtsZ is encoded in the nuclear genome of plant cells, and plays a major role in the plastid division process forming a ring along the center of plastids. Although the best-characterized type of plastid division so far is the division with a single FtsZ ring at the plastid midpoint, it was recently reported that in some plant organs and tissues, plastids are pleomorphic and form multiple FtsZ rings. However, the pleomorphic plastid division mechanism, such as the formation of multiple FtsZ rings, the constriction of plastids and the behavior of plastid (pt) nucleoids, remains totally unclear. To elucidate these points, we used the cultured cell line, tobacco (Nicotiana tabacum L.) Bright Yellow-2, in which plastids are pleomorphic and show dynamic morphological changes during culture. As a result, it was revealed that as the plastid elongates from an ellipsoid shape to a string shape after medium renewal, FtsZ rings are multiplied almost orderly and perpendicularly to the long axis of plastids. Active DNA synthesis of pt nucleoids is induced by medium transfer, and the division and the distribution of pt nucleoids occur along with plastid elongation. Although it was thought that the plastid divides with simultaneous multiple constrictions at all the FtsZ ring sites, giving rise to many small plastids, we found that the plastids generally divide constricting at only one FtsZ ring site. Moreover, using electron microscopy, we revealed that plastid-dividing (PD) rings are observed only at the constriction site, and not at swollen regions. These results indicate that in the pleomorphic plastid division with multiple FtsZ rings, the formation of PD rings occurs at a limited FtsZ ring site for one division. Multiplied FtsZ rings seem to localize in advance at the expected sites of division, and the formation of a PD ring at each FtsZ ring site occurs in a certain order, not simultaneously. Based on these results, a novel model for the pleomorphic plastid division with multiple FtsZ rings is proposed.     

Orderly formation of the double ring structures for plastid and mitochondrial division in the unicellular red alga Cyanidioschyzon merolae

The formation of the plastid-dividing ring (PD ring) and mitochondrion-dividing ring (MD ring) was studied in a highly synchronous culture of the unicellular red alga Cyanidioschyzon merolae. The timing and the order of formation of the MD and PD rings were determined by observing organelles around the onset of their division, using transmission electron microscopy. In  C. merolae, there is one chloroplast and one mitochondrion per cell, and the shape of the chloroplast changes sequentially from acorn-like, to round, to trapezoidal, to peanut-shaped, in that order, during the early stage of chloroplast division. None of the cells with acorn-shaped or round chloroplasts contained organelles with PD rings or MD rings, while all of the cells with peanut-shaped chloroplasts contained organelles with both PD rings and MD rings. In cells with peanut-shaped chloroplasts, the PD and MD rings were double ring structures, with an outer ring located on the cytoplasmic face of the outer membrane of the organelle, and an inner ring located in the matrix beneath the inner membrane. These results suggested that the double ring structures of the PD ring and the MD ring form when chloroplasts are trapezoidal in shape. Detailed three-dimensional observation of cells with trapezoidal chloroplasts revealed the following steps in the formation of the double ring structures of the PD and MD rings: (i) the inner ring of the PD ring forms first, followed by the outer ring; (ii) then the MD ring forms and becomes visible; (iii) when the double ring structures of the two rings have formed, the microbody then moves from its remote location to the plane of division of the mitochondrion and contraction of the PD and MD rings commences. These steps were also confirmed by computer-aided three-dimensional reconstruction of the images from serial thin sections. This study reveals the order of formation of the double ring structures of the PD and MD rings, and the behavior of the microbody around the onset of division of plastids and mitochondria. The results also provide the first evidence that the inner PD ring is not a tension element formed by the contractile pressure but a definite structure, independent of the outer ring. Received: 31 March 1998 / Accepted: 14 May 1998     

Two Types of FtsZ Proteins in Mitochondria and Red-Lineage Chloroplasts: The Duplication of FtsZ Is Implicated in Endosymbiosis

The ancestors of plastids and mitochondria were once free-living bacteria that became organelles as a result of endosymbiosis. According to this theory, a key bacterial division protein, FtsZ, plays a role in plastid division in algae and plants as well as in mitochondrial division in lower eukaryotes. Recent studies have shown that organelle division is a process that combines features derived from the bacterial division system with features contributed by host eukaryotic cells. Two nonredundant versions of FtsZ, FtsZ1 and FtsZ2, have been identified in green-lineage plastids, whereas most bacteria have a single ftsZ gene. To examine whether there is also more than one type of FtsZ in red-lineage chloroplasts (red algal chloroplasts and chloroplasts that originated from the secondary endosymbiosis of red algae) and in mitochondria, we obtained FtsZ sequences from the complete sequence of the primitive red alga Cyanidioschyzon merolae and the draft sequence of the stramenopile (heterokont) Thalassiosira pseudonana. Phylogenetic analyses that included known FtsZ proteins identified two types of chloroplast FtsZ in red algae (FtsZA and FtsZB) and stramenopiles (FtsZA and FtsZC). These analyses also showed that FtsZB emerged after the red and green lineages diverged, while FtsZC arose by the duplication of an ftsZA gene that in turn descended from a red alga engulfed by the ancestor of stramenopiles. A comparison of the predicted proteins showed that like bacterial FtsZ and green-lineage FtsZ2, FtsZA has a short conserved C-termmal sequence (the C-terminal core domain), whereas FtsZB and FtsZC, like the green-lineage FtsZ1, lack this sequence. In addition, the Cyanidioschyzon and Dictyostelium genomes encode two types of mitochondrial FtsZ proteins, one of which lacks the C-terminal variable domain. These results suggest that the acquisition of an additional FtsZ protein with a modified C terminus was common to the primary and secondary endosymbioses that produced plastids and that this also occurred during the establishment of mitochondria, presumably to regulate the multiplication of these organelles.     

FtsZ ring: the eubacterial division apparatus conserved in archaebacteria

FtsZ is a tubulin-like protein that is essential for cell division in eubacteria. It functions by forming a ring at the division site that directs septation. The archaebacteria constitute a kingdom of life separate from eubacteria and eukaryotes. Like eubacteria, archaebacteria are prokaryotes, although they are phylogenetically closer to eukaryotes. Here it is shown that archaebacteria also possess FtsZ and that it is biochemically similar to eubacterial FtsZs. Significantly, FtsZ from the archaebacterium Haloferax volcanii is a GTPase that is localized to a ring that coincides with the division constriction. These results indicate that the FtsZ ring was part of the division apparatus of a common prokaryotic ancestor that was retained by both eubacteria and archaebacteria.     

Colocalization of Plastid Division Proteins in the Chloroplast Stromal Compartment Establishes a New Functional Relationship between FtsZ1 and FtsZ2 in Higher Plants

Chloroplast division is driven by a macromolecular complex containing components that are positioned on the cytosolic surface of the outer envelope, the stromal surface of the inner envelope, and in the intermembrane space. The only constituents of the division apparatus identified thus far are the tubulin-like proteins FtsZ1 and FtsZ2, which colocalize to rings at the plastid division site. However, the precise positioning of these rings relative to the envelope membranes and to each other has not been previously defined. Using newly isolated cDNAs with open reading frames longer than those reported previously, we demonstrate here that both FtsZ2 proteins in Arabidopsis, like FtsZ1 proteins, contain cleavable transit peptides that target them across the outer envelope membrane. To determine their topological arrangement, protease protection experiments designed to distinguish between stromal and intermembrane space localization were performed on both in vitro imported and endogenous forms of FtsZ1 and FtsZ2. Both proteins were shown to reside in the stromal compartment of the chloroplast, indicating that the FtsZ1- and FtsZ2-containing rings have similar topologies and may physically interact. Consistent with this hypothesis, double immunofluorescence labeling of various plastid division mutants revealed precise colocalization of FtsZ1 and FtsZ2, even when their levels and assembly patterns were perturbed. Overexpression of FtsZ2 in transgenic Arabidopsis inhibited plastid division in a dose-dependent manner, suggesting that the stoichiometry between FtsZ1 and FtsZ2 is an important aspect of their function. These studies raise new questions concerning the functional and evolutionary significance of two distinct but colocalized forms of FtsZ in plants and establish a revised framework within which to understand the molecular architecture of the plastid division apparatus in higher plants.     

Chemical inhibition of the mitochondrial division dynamin reveals its role in Bax/Bak-dependent mitochondrial outer membrane permeabilization

Mitochondrial fusion and division play important roles in the regulation of apoptosis. Mitochondrial fusion proteins attenuate apoptosis by inhibiting release of cytochrome c from mitochondria, in part by controlling cristae structures. Mitochondrial division promotes apoptosis by an unknown mechanism. We addressed how division proteins regulate apoptosis using inhibitors of mitochondrial division identified in a chemical screen. The most efficacious inhibitor, mdivi-1 (for mitochondrial division inhibitor) attenuates mitochondrial division in yeast and mammalian cells by selectively inhibiting the mitochondrial division dynamin. In cells, mdivi-1 retards apoptosis by inhibiting mitochondrial outer membrane permeabilization. In vitro, mdivi-1 potently blocks Bid-activated Bax/Bak-dependent cytochrome c release from mitochondria. These data indicate the mitochondrial division dynamin directly regulates mitochondrial outer membrane permeabilization independent of Drp1-mediated division. Our findings raise the interesting possibility that mdivi-1 represents a class of therapeutics for stroke, myocardial infarction, and neurodegenerative diseases.     

Investigation of regulation of FtsZ assembly by SulA and development of a model for FtsZ polymerization

In Escherichia coli FtsZ organizes into a cytoskeletal ring structure, the Z ring, which effects cell division. FtsZ is a GTPase, but the free energy of GTP hydrolysis does not appear to be used for generation of the constriction force, leaving open the question of the function of the GTPase activity of FtsZ. Here we study the mechanism by which SulA, an inhibitor of FtsZ induced during the SOS response, inhibits FtsZ function. We studied the effects of SulA on the in vitro activities of FtsZ, on Z rings in vivo, and on a kinetic model for FtsZ polymerization in silico. We found that the binding of SulA to FtsZ is necessary but not sufficient for inhibition of polymerization, since the assembly of FtsZ polymers in the absence of the GTPase activity was not inhibited by SulA. We developed a new model for FtsZ polymerization that accounts for the cooperativity of FtsZ and could account for cooperativity observed in other linear polymers. When SulA was included in the kinetic scheme, simulations revealed that SulA with strong affinity for FtsZ delayed, but did not prevent, the assembly of polymers when they were not hydrolyzing GTP. Furthermore, the simulations indicated that SulA controls the assembly of FtsZ by binding to a polymerization-competent form of the FtsZ molecule and preventing it from participating in assembly. In vivo stoichiometry of the disruption of Z rings by SulA suggests that FtsZ may undergo two cooperative transitions in forming the Z ring.