Platinum-Induced Filamentous Growth in Escherichia coli

Certain group VIIIB transition metal compounds were found to inhibit cell division in Escherichia coli, causing marked filamentous growth. Gram-negative bacilli were the most sensitive to this effect, whereas gram-positive bacilli responded only at near-toxic levels of the metal. None of the cocci tested showed any apparent effect. Cytokinesis (cross-septation) can be initiated by removal or decrease of platinum, but not by treatment with pantoyl lactone, divalent cations, or a temperature of 42 C.     

Repair of radiation-induced damage to the cell division mechanism of Escherichia coli

Adler, Howard I. (Oak Ridge National Laboratory, Oak Ridge, Tenn.), William D. Fisher, Alice A. Hardigree, and George E. Stapleton. Repair of radiation-induced damage to the cell division mechanism of Escherichia coli. J. Bacteriol. 91:737-742. 1966.-Microscopic observations of irradiated populations of filamentous Escherichia coli cells indicated that filaments can be induced to divide by a substance donated by neighboring cells. We have made this observation the basis for a quantitative technique in which filaments are incubated in the presence of nongrowing donor cells. The presence of "donor" organisms promotes division and subsequent colony formation in filaments. "Donor" bacteria do not affect nonfilamentous cells. An extract of "donor" cells retains the division-promoting activity. The extract has been partially fractionated, and consists of a heat-stable and a heat-labile component. The heat-stable component is inactive in promoting cell division, but enhances the activity of the heat-labile component. The division-promoting system is discussed as a radiation repair mechanism and as a normal component of the cell division system in E. coli.     

Isolation and Characterization of an Escherichia coli ruv Mutant Which Forms Nonseptate Filaments After Low Doses of Ultraviolet Light Irradiation

Two ultraviolet light (UV)-sensitive mutants have been isolated from Escherichia coli K-12. These mutants, designated RuvA(-) and RuvB(-), were controlled by a gene located close to the his gene on the chromosome map. They were sensitive to UV (10- to 20-fold increase) and slightly sensitive to gamma rays (3-fold increase). Host cell reactivation, UV reactivation and genetic recombination were normal in these mutants. Irradiation of the mutants with UV resulted in the production of single-strand breaks in deoxyribonucleic acid, which was repaired upon incubation in a growth medium. After UV irradiation, these mutants resumed deoxyribonucleic acid synthesis at a normal rate, as did the parent wild-type bacteria, and formed nonseptate, multinucleate filaments. From these results we concluded that the mutants have some defect in cell division after low doses of UV irradiation, similar to the lon(-) or fil(+) mutant of E. coli. The ruv locus was divided further into ruvA and ruvB with respect to nalidixic acid sensitivity and the effect of minimal agar or pantoyl lactone on survival of the UV-irradiated cell. The ruvB(-)mutant was more sensitive to nalidixic acid than were ruvA(-) and the parent strain. There was a great increase in the surviving fraction of the UV-irradiated ruvB(-) mutant when it was plated on minimal agar or L agar containing pantoyl lactone. No such increase in survival was observed in the ruvA(-) mutant.     

Generation of buds, swellings, and branches instead of filaments after blocking the cell cycle of Rhizobium meliloti.

Inhibition of cell division in rod-shaped bacteria such as Escherichia coli and Bacillus subtilis results in elongation into long filaments many times the length of dividing cells. As a first step in characterizing the Rhizobium meliloti cell division machinery, we tested whether R. meliloti cells could also form long filaments after cell division was blocked. Unexpectedly, DNA-damaging agents, such as mitomycin C and nalidixic acid, caused only limited elongation. Instead, mitomycin C in particular induced a significant proportion of the cells to branch at the poles. Moreover, methods used to inhibit septation, such as FtsZ overproduction and cephalexin treatment, induced growing cells to swell, bud, or branch while increasing in mass, whereas filamentation was not observed. Overproduction of E. coli FtsZ in R. meliloti resulted in the same branched morphology, as did overproduction of R. meliloti FtsZ in Agrobacterium tumefaciens. These results suggest that in these normally rod-shaped species and perhaps others, branching and swelling are default pathways for increasing mass when cell division is blocked.     

Expression of the SOS response following simultaneous treatment with methyl-nitrosoguanidine and mitomycin C in Escherichia coli

Simultaneous treatment of Escherichia coli cultures with methyl-nitrosoguanidine and mitomycin C induces recA-dependent inhibition of respiration but not inhibition of cell division. This pattern of SOS functions expression is the same as that is found following treatment with methyl-nitrosoguanidine alone and contrary to the pattern induced after mitomycin C addition. The same result is obtained when a culture of E. coli RecA441 (formerly tif) is shifted to 42 degrees C and treated simultaneously with methyl-nitrosoguanidine. The suppressor effect of this compound over the pattern of SOS functions expression induced by mitomycin C or high temperature in recA441 mutants is directly related to the increase in its dose. Moreover, the division temperature-sensitive mutant ftsA treated with methyl-nitrosoguanidine and high temperature does not show any decrease in its normal filamentous growth when cultured at 42 degrees C. This indicates that the effect of methyl-nitrosoguanidine on the recA-independent inhibition of cell division is not due to any indiscriminate effect of this compound over the division process. These results suggest that the specific kind of lesion caused in DNA is very important in determining which SOS function is induced.     

Ketopantoic acid and ketopantoyl lactone reductases. Stereospecificity of transfer of hydrogen from reduced nicotinamide adenine dinucleotide phosphate.

The stereospecificity of hydrogen transfer from NADPH to the appropriate carbonyl substrate catalyzed by ketopantoic acid and ketopantoyl acid and ketopantoyl lactone reductases of yeast (Saccharomyces cerevisiae) and Escherichia coli has been determined. Yeast and E. coli ketopantoic acid reductases are B-specific enzymes which transfer hydrogen from [4B-3H]-NADPH to ketopantoic acid to form [3H]pantoic acid. In contrast to the usual observations on the stereospecificity of functionally similar dehydrogenases from different species, yeast and E. coli ketopantoyl lactone reductases exhibit opposite stereospecificities. Both of two forms of yeast ketopantoyl lactone reductases are A-specific enzymes which form [3H]pantoyl lactone from ketopantoyl lactone and [4A-3H]NADPH, whereas, two forms of E. coli ketopantoyl lactone reductases are B-specific enzymes.     

Cell Division and Prophage Induction in Escherichia coli: Effects of Pantoyl Lactone and Various Furan Derivatives

Strain T-44 is a thermosensitive mutant of Escherichia coli in which both cell division and prophage repression are altered at elevated temperatures. The effects of various ribosides, pantoyl lactone, and the furfural derivatives nitrofurazone and 5-methyl furfural suggest that some low-molecular-weight compound is important in the control of cell division and prophage repression in this strain. This low-molecular-weight compound may have a five-membered oxygen-containing ring as part of its structure.     

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.     

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.     

Filamentous Cells of Escherichia coli Formed in the Presence of Mitomycin

The effects of mitomycin C on cell elongation of Escherichia coli B were studied. Filament formation was most marked in cultures treated with a moderate level (1 mug/ml) of the antibiotic, becoming less obvious at higher levels (10 mug/ml). Cells treated with a bacteriostatic concentration (0.1 mug/ml or less) of mitomycin C were also significantly elongated. The filamentous or elongated cells appeared to lack septa, since their spheroplasts were considerably larger than those formed from normal cells. The appearance of empty spheres also indicated some defects in the surfaces of the filamentous cells. Electron micrographs of the filaments revealed a characteristic difference in the arrangement of the nuclei in the filaments formed in the presence of low (0.1 mug/ml) and high (5 mug/ml) concentrations of mitomycin C. The filaments formed by the low level of mitomycin C had normal well-defined nuclear bodies distributed along the long axis, whereas those formed by the elevated level of the antibiotic contained smaller nuclei. The latter were characteristically confined to the center of the cells and did not extend out to the tips of the filaments.     

Temperature-Sensitive Cell Division Mutants of Escherichia coli with Thermolabile Penicillin-Binding Proteins

The thermostability of the penicillin-binding proteins (PBPs) of 31 temperature-sensitive cell division mutants of Escherichia coli has been examined. Two independent cell division mutants have been found that have highly thermolabile PBP3. Binding of [(14)C]benzylpenicillin to PBP3 (measured in envelopes prepared from cells grown at the permissive temperature) was about 30% of the normal level at 30 degrees C, and the ability to bind [(14)C]benzylpenicillin was rapidly lost on incubation at 42 degrees C. The other PBPs were normal in both mutants. At 30 degrees C both mutants were slightly longer than their parents and on shifting to 42 degrees C they ceased dividing, but cell mass and deoxyribonucleic acid synthesis continued and long filaments were formed. At 42 degrees C division slowly recommenced, but at 44 degrees C this did not occur. The inhibition of division at 42 degrees C was suppressed by 0.35 M sucrose, and in one of the mutants it was partially suppressed by 10 mM MgCl(2). PBP3 was not stabilized in vitro at 42 degrees C by these concentrations of sucrose or MgCl(2). Revertants that grew as normal rods at 42 degrees C regained both the normal level and the normal thermostability of PBP3. The results provide extremely strong evidence that the inactivation of PBP3 at 42 degrees C in the mutants is the cause of the inhibition of cell division at this temperature and identify PBP3 as an essential component of the process of cell division in E. coli. It is the inactivation of this protein by penicillins and cephalosporins that results in the inhibition of division characteristic of low concentrations of many of these antibiotics.     

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.     

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.     

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.     

Regulation of Cell Division in Escherichia coli: Characterization of Temperature-Sensitive Division Mutants

A temperature-sensitive division mutant of Escherichia coli was isolated by using differential filtration to select for filaments at 42 C and normal cells at 30 C. Cells shifted from 30 to 42 C stop dividing almost immediately, suggesting the temperature-sensitive element is required for cell division late in the cell cycle. Cells returned to 30 from 42 C divide abruptly, suggesting accumulation of division potential at 42 C. Inhibitors of protein, deoxyribonucleic acid, and ribonucleic acid synthesis do not block division during the recovery period at 30 C. Cycloserine does not stop cell division, vancomycin shows some effect on cell division, whereas penicillin completely stops cell division during this period. The addition of high concentrations of NaCl to filaments at 42 C results in a burst of cell division. The final cell number is equivalent to the control which is grown at 30 C if sufficient salt is added (11 g/liter, final concentration). After the original burst, cell division ceases at the nonpermissive temperature even at increased osmolality. Chloramphenicol, puromycin, vancomycin, and penicillin prevent division during the recovery in the presence of NaCl. Kinetic data indicate division potential decays to a reversible inactive intermediate which rapidly decays to an irreversible inactive form. Conversion of division potential to the inactive form is correlated with a 100- to 1,000-fold derepression of the synthesis of division potential. The mutation appears to involve a stage in cross-wall synthesis which is required during the terminal stages of division.     

Expression of the genome of Mu-like phage D3112 specific for Pseudomonas aeruginosa in Escherichia coli and Pseudomonas putida cells

The behavior of Escherichia coli cells carrying RP4 plasmid which contains the genome of a Mu-like D3112 phage specific for Pseudomonas aeruginosa was studied. Two different types of D3112 genome expression were revealed in E. coli. The first is BP4-dependent expression. In this case, expression of certain D3112 genes designated as "kil" only takes place when RP4 is present. As a result, cell division stops at 30 degrees C and cells form filaments. Cell division is not blocked at 42 degrees C. The second type of D3112 genome expression is RP4-independent. A small number of phage is produced independently of RP4 plasmid but this does not take place at 42 degrees C. No detectable quantity of the functionally active repressor of the phage was determined in E. coli (D3112). It is possible that the only cause for cell stability of E. coli (D3112) or E. coli (RP4::D3112) at 42 degrees C in the absence of the repressor is the fact of an extremely poor expression of D3112. In another heterologous system, P. putida both ways of phage development (lytic and lysogenic) are observed. This special state of D3112 genome in E. coli cells is proposed to be named "conditionally expressible prophage" or, in short, "conex-phage", to distinguish it from a classical lysogenic state when stability is determined by repressor activity. Specific blockade of cell division, due to D3112 expression, was also found in P. putida cells. It is evident that the kil function of D3112 is not specific to recognize the difference between division machinery of bacteria belonging to distinct species or genera. Protein synthesis is needed to stop cell division and during a short time period this process could be reversible. Isolation of E. coli (D3112) which lost RP4 plasmid may be regarded as an evidence for D3112 transposition in E. coli. Some possibilities for using the system to look for E. coli mutants with modified expression of foreign genes are considered.     

Sodium dodecyl sulfate-sensitive septation in a mitomycin C-sensitive, mtc, mutant of Escherichia coli.

A mitomycin C-sensitive, mtc, mutant of Escherichia coli has an altered cell surface and is sensitive to sodium dodecyl sulfate (SDS). The mutant, M27, formed multinucleate nonseptated filaments in the presence of a low concentration of SDS (50 microgram/ml). When the culture grown at that concentration of SDS was diluted with an SDS-free medium, the filaments began to divide at a very rapid rate after a lag of about 20 min. Chloramphenicol inhibited this recovery division when added within 10 min after SDS dilution but did not inhibit the division when added 20 min after dilution. Penicillin G at a low concentration, which is enough to cause filamentation, had virtually no effect on the recovery division of SDS-induced filaments. The division of penicillin G-induced filaments was inhibited by SDS.     

One-Step Microbial Conversion of a Racemic Mixture of Pantoyl Lactone to Optically Active d-(-)-Pantoyl Lactone

Washed cells of Rhodococcus erythropolis IFO 12540 were found to convert only the l-(+)-isomer of pantoyl lactone to the d-(-)-isomer in a racemic mixture of pantoyl lactone. Under suitable reaction conditions, the amount of d-(-)-pantoyl lactone synthesized was 18.2 mg/ml (94.4% enantiomer excess; molar yield, 90.5%). This conversion was suggested to proceed through the following successive reactions: first, the enzymatic oxidation of l-(+)-pantoyl lactone to ketopantoyl lactone; second, the rapid and spontaneous hydrolysis of the ketopantoyl lactone to ketopantoic acid; and then, the enzymatic reduction of the ketopantoic acid to d-(-)-pantoic acid. After the reaction d-(-)-pantoic acid could be lactonized by means of acid treatment. During the conversion, the d-(-)-isomer, which was initially present in the reaction mixture, did not undergo any modification.