Electron Microscope Study of Septum Formation in Escherichia coli Strains B and B/r During Synchronous Growth

The formation of cell wall septa was monitored in Escherichia coli B and B/r during synchronous growth in glucose media at 37 C by means of electron microscopy. The visible events of septation comprised the following sequence, starting at about 30 min of incubation: (a) bleb formation of the outer membrane; (b) invagination of mucopeptide and cytoplasmic membrane (with associated mesosomes); the outer membrane is excluded from the septum; (c) formation of a cross-wall; (d) ingrowth of the outer membrane during cell separation. The septum is composed of a fold of cytoplasmic membrane plus mucopeptide, and the latter is a double structure, composed of two opposed lamellae separated by an electron-transparent gap. Experiments with chloramphenicol and nalidixic acid suggested that division could occur in the presence of these inhibitors once a round of deoxyribonucleic acid replication is completed. The initial stages of septation, as estimated by the potential of the cells to produce bulges in the presence of ampicillin, may involve the modification of mucopeptide by hydrolases at the end of the C period. Assembly of the septum may occur during the first half of the D period by means of precursors synthesized during the preceding C period.     

Strain-specific difference that affects the inhibition of division of Escherichia coli filaments by chloramphenicol.

The Escherichia coli mutations ts1882 and ts2158 cause temperature-sensitive septum formation and result in growth of cells as long, multinucleate, nonseptate filaments at 42 C. When filaments are transferred to 28 C, they divide into short cells. Chloramphenicol, when added to cultures of filaments at the time of temperature reduction. Inhibited division of filaments when these temperature-sensitive mutations were present in the K-12 strain AB1157. However, when the ts1882 and ts2158 mutations were present in another k-12 strain, UTH4113, filaments of these strains divided in the presence of chloramphenicol.     

Induction of cell division in a temperature-sensitive division mutant of Escherichia coli by inhibition of protein synthesis.

Synchronous cells of the thermosensitive division-defective Escherichia coli strain MACI (divA) divided at the restrictive temperature (42 degrees C) if they were allowed to grow at 42 degrees C for a certain period before protein synthesis was inhibited by adding chloramphenicol (CAP) or rifampicin. The completion of chromosome replication was not required for such divA-independent division. Synchronous cells of strain MACI divided in the presence of an inhibitor of DNA synthesis, nalidixic acid, if they were shifted to 42 degrees C and CAP or rifampicin was added after some time; cells of the parent strain MC6 (div A+) treated in the same way did not divide. These data suggest that coupling of cell division to DNA synthesis depends on the divA function. The ability to divide at 42 degrees C, whether or not chromosome termination was allowed, was directly proportional to the mean cell volume of cultures at the time of CAP addition, suggesting that cells have to be a certain size to divide under these conditions. The period of growth required for CAP-induced division had to be at the restrictive temperature; when cells were grown at 30 degrees C, in the presence of nalidixic acid to prevent normal division, they did not divide on subsequent transfer to 42 degrees C followed, after a period, by protein synthesis inhibition. A model is proposed in which the role of divA as a septation initiator gene is to differentiate surface growth sites by converting a primary unregulated structure, with the capacity to make both peripheral wall and septum, to a secondary structure committed to septum formation.     

Mutant of Escherichia coli with Thermosensitive Protein in the Process of Cellular Division

A new thermosensitive mutant of Escherichia coli deficient in cell division was isolated by means of membrane filtration after nitrosoguanidine mutagenesis. The mutant cells grow normally at 30 C but stop dividing immediately after shift to 42 C, resulting in multinucleated filaments lacking septa. The number of colony-forming units does not decrease for at least 6 hr at 42 C. The maximum length of the filaments is 10 to 16 times that of normal cells. Addition of a high concentration of NaCl fails to stimulate cell division at 42 C. The filaments formed at 42 C divide abruptly 30 min after shift to 30 C, and synchronous increase of cell number is shown for 3 hr. The macromolecular synthesis of protein and nucleic acids at 42 C is normal on the whole. The cell division shown after the shift from 42 to 30 C is observed in the absence of thymine, but not in the presence of chloramphenicol or in a medium deficient in amino acids. However, the filament can divide to some extent in the presence of chloramphenicol if some protein synthesis is allowed to proceed at 30 C before the addition of the antibiotic. The elongated cells divide at 42 C provided that they are exposed to 30 C before being shifted to high temperature.     

Ampicillin induced septum formation in Bacillus cereus

Cells of Bacillus cereus grown in the presence of subinhibitory concentrations of ampicillin at either 30 degrees or 45 degrees C exhibited an increase in the numbers of centres of septum formation per unit cell length. Under identical conditions of cultivation, cells of Escherichia coli grew as aseptate filaments. In general, untreated B. cereus cells grown at 45 degrees C were longer than those grown at 30 degrees C. The strain of E. coli used was unaffected in terms of filamentation by elevated growth temperature. Results are discussed in terms of the presence and availability of penicillin binding proteins and autolysins involved in cell growth, division and separation.     

Genetical and physiological studies on a thermosensitive mutant of Escherichia coli defective in cell division.

A new temperature-sensitive mutant of E. coli, defective in cell division, was isolated after selection for tolerance to colicin E2. The mutant strain, ASHI24, growing in either minimal or complex medium, commences filament formation immediately upon shift to high temperature. High densities of bacteria or the presence of 0-44 M-sucrose prevents filament formation at 42 degrees C and division continues. Filament formation in the mutant is reversible and upon return to 29 degrees C the multinucleate filaments divide up into normal-sized bacteria by a series of rapid but sequential divisions. In the presence of chloramphenicol at 29 degrees C, 25% of these division sites are still expressed. A genetic locus designated ftsH, apparently controlling both temperature sensitivity and filament formation, was provisionally mapped at minute 80 on the E. coli K12 map.     

Cell Division of Escherichia coli BUG-6: Effect of Varying the Temperature Used as the Nonpermissive Growth Condition

When Escherichia coli BUG-6 is shifted from 30 C to 36 or 38 C, division does not stop, but the rate of division of the cell population is initially decreased followed by a period of increased rate of division before the rates characteristic of growth at 36 and 38 C are obtained. After a shift from 30 to 40 C, the rate of cell division gradually decreases over a 10-min period and then stops. The inhibition continues for 25 min, and then the cells divide rapidly before the division rate characteristic of 40 C is obtained. If filaments produced by 45 min of growth at 42 C are temporarily replaced at 30 C and then returned to 42 C, division occurs at 42 C. The amount of division is dependent on the length of the period at 30 C and can be decreased by a 3-min pulse of chloramphenicol immediately before the 42 to 30 C shift.     

Cell growth and division in Escherichia coli: a common genetic control involved in cell division and minicell formation

Escherichia coli Div 124(ts) is a conditional-lethal cell division mutant formed from a cross between a mutant that produces polar anucleated minicells and a temperature-sensitive cell division mutant affected in a stage of cross-wall synthesis. Under permissive growth temperature (30 C), Div 124(ts) grows and produces normal progeny cells and anucleated minicells from its polar ends. When transferred to nonpermissive growth temperature (42 C), growth and macromolecular synthesis continue, but cell division and minicell formation are inhibited. Growth at 42 C results in formation of filamentous cells showing some constrictions along the length of the filaments. Return of the filaments from 42 to 30 C results in cell division and minicell formation in association with the constrictions and other areas along the length of the filaments. This gives rise to a "necklace-type" array of cells and minicells. Recovery of cell division is observed after a lag and is followed by a burst in cell division and finally by a return to the normal growth characteristic of 30 C cultures. Recovery of cell division takes place in the presence of chloramphenicol or nalidixic acid when these are added at the time of shift from 42 to 30 C, and indicates that a division potential for filament fragmentation is accumulated while the cells are at 42 C. This division potential is used for the production of both minicells and cells of normal length. The conditional-lethal temperature sensitive mutation controls a step(s) in cross-wall synthesis common to cell division and minicell formation.     

Formation of Filaments and Synthesis of Macromolecules at Temperatures Below the Minimum for Growth of Escherichia coli

When Escherichia coli ML30 was transferred during exponential growth at a temperature near the minimum for growth to temperatures just below the minimum for growth, optical density increased for a considerable period of time and considerable synthesis of ribonucleic acid, deoxyribonucleic acid, protein and mucopeptide also occurred. Synthesis of deoxyribonucleic acid was inhibited slightly before the cessation of synthesis of other macromolecules. At 6 C, filaments up to 300 mu in length were formed. Cross walls were not formed, but on transfer to 30 C the filaments rapidly fragmented into short, single cells. The filaments had abundant nuclear material distributed along their length, in contrast to filaments formed by E. coli 15T(-) in the absence of thymine. There was evidence for false division points and incomplete septum formation.     

Cell Division of Escherichia coli BUG-6: Effect of Varying the Length of Growth at the Nonpermissive Temperature

When Escherichia coli BUG-6 is grown at 42 C and then returned to 30 C, the division kinetics during the recovery at 30 C are dependent on the length of time the cells were grown at 42 C. If chloramphenicol is added when the cells are shifted from 42 to 30 C, no division occurs if the period at 42 C is less than 4 min or more than 110 min. Maximum division occurs when the period at 42 C is 50 min. A discussion of these results with reference to a previously proposed model is presented.     

Effects of some platinum IV complexes on cell division of Escherichia coli.

A comparison was made of the effects of cis-tetrachlorodiaminoplatinum (IV) (cis-TCDPt), rans-TCDPt), and hexachloroplatinum (HCP) on growth and cell division of Escherichia coli strains D21 and D22. At or below 40 microgram/mL, cis-TCDPt inhibited cell division but not growth, DNA, or protein synthesis, although areas of increased electron density could be demonstrated in treated cells. In contrast, 40 microgram/mL of trans-TCDPt or HCP inhibited growth. Trans-TCDPt-treated cells developed condensed nucleoids; HCP-treated cells showed no obvious cytological changes to correlate with growth inhibition. Combination of cis-TCDPt with nalidixic acid, both at one-half the lowest filament-forming concentrations, resulted in formation of filaments, suggesting an additive effect. Combination of cis-TCDPt followed by ampicillin on E. coli B/r resulted in single bulges near the center of the filaments. Cis-TCDPt could therefore inhibit an initial step in the septation sequence, possibly at the level of the regulation of the hydrolytic enzymes. Whether cis-TCDPt exerts its effect by interreaction with DNA or with a membrane target is still uncertain.     

Division behavior and shape changes in isogenic ftsZ, ftsQ, ftsA, pbpB, and ftsE cell division mutants of Escherichia coli during temperature shift experiments.

Isogenic ftsZ, ftsQ, ftsA, pbpB, and ftsE cell division mutants of Escherichia coli were compared with their parent strain in temperature shift experiments. To improve detection of phenotypic differences in division behavior and cell shape, the strains were grown in glucose-minimal medium with a decreased osmolality (about 100 mosM). Already at the premissive temperature, all mutants, particularly the pbpB and ftsQ mutants, showed an increased average cell length and cell mass. The pbpB and ftsQ mutants also exhibited a prolonged duration of the constriction period. All strains, except ftsZ, continued to initiate new constrictions at 42 degrees C, suggesting the involvement of FtsZ in an early step of the constriction process. The new constrictions were blunt in ftsQ and more pronounced in ftsA and pbpB filaments, which also had elongated median constrictions. Whereas the latter strains showed a slow recovery of cell division after a shift back to the permissive temperature, ftsZ and ftsQ filaments recovered quickly. Recovery of filaments occurred in all strains by the separation of newborn cells with an average length of two times LO, the length of newborn cells at the permissive temperature. The increased size of the newborn cells could indicate that the cell division machinery recovers too slowly to create normal-sized cells. Our results indicate a phenotypic resemblance between ftsA and pbpB mutants and suggest that the cell division gene products function in the order FtsZ-FtsQ-FtsA, PBP3. The ftsE mutant continued to constrict and divide at 42 degrees C, forming short filaments, which recovered quickly after a shift back to the permissive temperature. After prolonged growth at 42 degree C, chains of cells, which eventually swelled up, were formed. Although the ftsE mutant produced filaments in broth medium at the restrictive temperature, it cannot be considered a cell division mutant under the presently applied conditions.     

Enzyme-induced Formation of Spheres from Cells and Envelopes of Escherichia coli

Normal and filamentous whole cells and isolated envelopes of Escherichia coli B were exposed to various enzymatic treatments to remove surface layers and to characterize the component(s) conferring rigidity in this organism. Modification of cell rigidity was determined by sphere formation in both whole cells and isolated envelopes. Enzymes capable of converting trypsinized normal or untreated filamentous whole cells and untreated envelopes to spheres included: lysozyme plus ethylenediaminetetraacetic acid, clostridial phospholipase C, and phospholipase D from cabbage. These data suggest that there are at least two components essential for maintenance of cell rigidity in E. coli B. The first is the peptidoglycan (mucopeptide), which is susceptible to lysozyme. The second is a phospholipid which is either covalently linked to the mucopeptide or in close association with it. This phospholipase C-sensitive component is protected more completely in normal than in filamentous whole cells by a protein layer which is easily modified by trypsin treatment to allow enzymatically induced sphere formation to occur.     

Reversible filamentous growth in the psychrophile Bacillus psychrophilus

At the near-maximum growth temperature of 32.5 °C, the psychrophile Bacillus psychrophilus loses the ability to septate and divide, resulting in the formation of filaments, which are four to six times longer than cells grown at 20 °C. DNA synthesis relative to growth occurs at the same rate both in the filaments at 32.5 °C, (which actually become multi-nucleated) and in normal-size cells at 20 °C, showing that the inhibition of DNA synthesis by the elevated temperature is not the cause of the filamentous growth, as has been found for other microorganisms. Similarly, temperature-sensitive cell-wall mucopeptide synthesis does not appear to be responsible. Reversal of filament production occurs when preformed filaments are incubated at 20 °C. Such reversal, i.e., septation of preformed filaments, requires the de novo synthesis of protein, probably throughout the reversal period.Filamentous cells are more nutritionally demanding than cells at 20 °C, with at least one substrate becoming limiting within 8 hr at 32.5 °C but not at 20 °C. However, such variation in nutritional requirement is not the cause of filament formation. KCl and NaCl stimulate cell division in cells growing at 32.5 °C but not in preformed filaments. Other membrane-active agents such as lysolecithin, dimethyl sulfoxide, ethanol, sodium oleate, and pantoyl lactone do not stimulate septum formation in filaments.     

Influence of penicillin and nalidixic acid on growth and cell division of Escherichia coli K-12

Ultrastructure of E. coli K-12 cells and the synthesis of DNA in bacteria treated with low concentration of nalidixic acid and penicillin was investigated. In E. coli both drugs caused inhibition of cell division in period D of the life cycle although nalidixic acid inhibits division at an earlier stage of septum formation. The ability of cells to form filaments in the presence of nalidixic acid depends on their age, i.e. time at which cells are taken from synchronous culture.     

A GTP-binding protein (Era) has an essential role in growth rate and cell cycle control in Escherichia coli.

Era is a membrane-associated GTP-binding protein which is essential for cell growth in Escherichia coli. In order to examine the physiological role of Era, strains in which Era was expressed at 40 degrees C but completely repressed at 27 degrees C were constructed. The growth of these strains was inhibited at the nonpermissive temperature, and cells became elongated. Under such conditions, no constrictions or septum formation could be detected by phase-contrast microscopy, and DNA segregation was apparently normal as revealed by fluorescence staining. These data demonstrate that Era has an essential function in cell growth rate control in liquid media and that depletion of Era blocks cell division either directly or indirectly. Thus, the role of GTP-binding proteins as important regulators of cell growth and division may be ubiquitous in nature.     

Cell-cycle-specific inhibition by chloramphenicol of septum fromation and cell division in synchronized cells of Bacillus subtilis.

The relationship between protein synthesis and processes of cell division was studied by using synchronized cells of Bacillus subtilis 168. The addition of chloramphenicol at the beginning of synchronous growth prevented septum formation and cell division, suggesting the requirement of protein synthesis for the processes of cell division. Experiments in which the drug was added to the cells at different cell ages showed that the protein synthesis required for the initiation of septum formation was completed at about 15 min and that the protein synthesis required for cell division was completed at about 45 min. By interpreting the result from the concept of the transition point for protein synthesis, it was suggested that the processes of cell division in B. subtilis require at least two kinds of protein molecules which are synthesized at distinct stages in the cell cycle. This was supported by the result of an experiment in which starvation and the readdition of a required amino acid to exponentially growing cells induced two steps of synchronous cell division. Further, the two transition points are in agreement with the estimations obtained by residual division after the inhibition of protein synthesis in asynchronous cells. The relationship of the timing between the completion of chromosome replication and the two transition points was also studied.     

Requirement of Cyclic Adenosine 3′,5′-Monophosphate for the Thermosensitive Effects of Rts1 in a Cyclic Adenosine 3′,5′-Monophosphate-Less Mutant of Escherichia coli

Previous publications showed that a covalently closed circular (CCC) Rts1 plasmid deoxyribonucleic acid (DNA) that confers kanamycin resistance upon the host bacteria inhibits host growth at 42 degrees C but not at 32 degrees C. At 42 degrees C, the CCC Rts1 DNA is not formed, and cells without plasmids emerge. To investigate the possible role of cyclic adenosine 3',5'-monophosphate (cAMP) in the action of Rts1 on host bacteria, Rts1 was placed in an Escherichia coli mutant (CA7902) that lacks adenylate cyclase or in E. coli PP47 (a mutant lacking cAMP receptor protein). Rts1 did not exert the thermosensitive effect on these cells, and CCC Rts1 DNA was formed even at 42 degrees C. Upon addition of cAMP to E. coli CA7902(Rts1), cell growth and formation of CCC Rts1 DNA were inhibited at 42 degrees C. The addition of cAMP to E. coli PP47(Rts1) did not cause inhibitory effects on either cell growth or CCC Rts1 DNA formation at 42 degrees C. The inhibitory effect of cAMP on E. coli CA7902(Rts1) is specific to this cyclic nucleotide, and other cyclic nucleotides such as cyclic guanosine 3',5'-monophosphate did not have the effect. For this inhibitory effect, cells have to be preincubated with cAMP; the presence of cAMP at the time of CCC Rts1 DNA formation is not enough for the inhibitory effect. If the cells are preincubated with cAMP, one can remove cAMP during the [(3)H]thymidine pulse and still observe its inhibitory effect on the formation of CCC Rts1 DNA. The presence of chloramphenicol during this preincubation period abolished the inhibitory effect of cAMP. These observations suggest that cAMP is necessary to induce synthesis of a protein that inhibits CCC Rts1 DNA formation and cell growth at 42 degrees C.     

Linkages between deoxyribonucleic acid synthesis and cell division in Myxococcus xanthus.

Addition of chloramphenicol or 0.5 M glycerol to growing Myxococcus xanthus resulted in an immediate cessation of cell division and 40% net increase in deoxyribonucleic acid (DNA). Although the chloramphenicol-treated cells divided in the presence of nalidixic acid after chloramphenicol was removed, glycerol-induced myxospores required DNA synthesis for subsequent cell division. Myxospores prepared from chloramphenicol-treated cells lost this potential to divide in the presence of nalidixic acid. The "critical period" of DNA synthesis necessary for cell division after germination overlapped in time (3 to 5 h) with initiation of net DNA synthesis. The length of the critical period of DNA synthesis was estimated at 12 min, or 5% of the M. xanthus chromosome. The requirement for cell division during germination also involved ribonucleic acid and protein synthesis after DNA synthesis. The data suggest that replication at or near the origin of the chromosome triggers the formation of a protein product that is necessary but not sufficient for subsequent cell division; DNA termination is also required. During myxospore formation, the postulated protein is destroyed, thereby reestablishing and making apparent this linkage between early DNA synthesis and cell division.