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.     

High-efficiency, temperature-sensitive suppression of amber mutations in Escherichia coli.

We have constructed a high-copy-number plasmid carrying an allele of the supD gene (supD43,74). The plasmid conferred temperature-sensitive suppression of amber mutations. Strains carrying the plasmid exhibited 50 to 60% suppression at 30 degrees C but little or no suppression at 42 degrees C. After a temperature shift from 30 to 42 degrees C the efficiency of suppression decreased gradually over a 60- to 90-min period before reaching the 42 degrees C steady-state level of suppression.     

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.     

Analysis of the Multiseptate Potential of Bacillus subtilis

Bacillus subtilis was grown at 30 C in 15 media which produced generation times of between 200 and 40 min. A correlation was observed between the growth rate and the number of septa per cell. The time between the production of a septum and its involvement in cell division was not related to the growth rate, but, for the 15 populations, had a mean value of 138 min. Multiseptate cells became progressively evident when the organism was grown at rates in excess of a 138-min generation time.     

Regulation of Bacterial Cell Division: Genetic and Phenotypic Analysis of Temperature-Sensitive, Multinucleate, Filament-Forming Mutants of Escherichia coli

Three mutants of Escherichia coli K-12 which form filaments during 42 C incubation have been characterized. The mutant strains AX621, AX629, and AX655 continued to grow and to synthesize deoxyribonucleic acid at 42 C for 150 to 180 min, after which time growth ceased. When cultures of the mutants were transferred from 42 to 28 C, septation of the filaments began after a 25- to 30-min period and continued at a greater than normal rate until no filaments remained. Addition of chloramphenicol at the time of transfer from 42 to 28 C prevented cell division in strain AX655 and caused lysis of strains AX621 and AX629. The temperature sensitivity mutation in each strain mapped near leu. For strain AX621, the mutation was specifically located between leu and nadC by P1 transduction. Properties of these strains are compared with those of other cell division mutants.     

Influence of cooling rates and plunging temperatures in an interrupted slow-freezing procedure for semen of the African catfish, Clarias gariepinus

The objective of this study was to optimize interrupted slow-freezing protocols for African catfish semen. Semen diluted with methanol and extender was frozen in 1-ml vials in a programmable freezer. The temperatures of the freezer (T(chamber)) and of the semen (T(semen)) were measured simultaneously. We first tested two-step freezing protocols with different cooling rates (-2, -5, and -10 degrees C/min) and different temperatures at plunging into liquid N2. The difference between T(semen) and T(chamber) increased with faster cooling rates. In all programs, survival of spermatozoa, expressed as hatching rates, increased from near zero when T(semen) at plunging was higher than -30 degrees C to values equal to those of control when T(semen) at plunging was equal to or lower than -38 degrees C. The inclusion of an isothermal holding period before plunging into liquid N2 (three-step freezing protocols) resulted in an equilibration between T(semen) and T(chamber) and improved semen survival. Semen could be plunged at temperatures as high as -36 degrees C when cooled at -5 or -10 degrees C/min, without compromising postthaw semen survival. Cooling at -2 degrees C/min in combination with a 5-min holding period reduced postthaw survival. We conclude that with slow cooling rates of -2 to -5 degrees C/min, hatching rates can be maximized by plunging as soon as T(semen) reaches -38 degrees C. The isothermal holding period is beneficial when faster rates are used. A simple and efficient protocol for freezing African catfish semen can be obtained by cooling at a rate of -5 to -10 degrees C/min combined with a 5-min holding period in the freezer, at -40 degrees C.     

Modification of the cutaneous vascular response to exercise by local skin temperature

This study examined how local forearm temperature (Tloc) affects the responsiveness of the cutaneous vasculature to a reflex drive for vasoconstriction. We observed responses in forearm blood flow (FBF) and arterial blood pressure to a 5-min bout of supine leg exercise of moderate intensity (125-175 W) after the forearm had been locally warmed to 36, 38, 40, or 42 degrees C for 48 min. With exercise, FBF fell by 1.82 +/- 0.23, 4.06 +/- 0.58, and 3.64 +/- 1.48 ml X 100 ml-1 X min-1 at 36, 38, and 40 degrees C, respectively, and rose by 2.16 +/- 0.57 ml X 100 ml X min-1 at a Tloc of 42 degrees C (mean +/- SE). Forearm vascular conductance (FVC) fell with the onset of exercise by averages of 2.77 +/- 0.57, 7.02 +/- 0.51, 5.36 +/- 0.85, and 4.17 +/- 0.79 ml X 100 ml-1 X min-1 X 100 mmHg-1 at 36, 38, 40, and 42 degrees C, respectively. Second-order polynomial regression analysis indicated that the reductions in FVC were greatest near a Tloc of 39 degrees C and that at a Tloc of 40 or 42 degrees C the cutaneous vasoconstrictor response to the onset of exercise is attenuated. Although elevated Tloc can be used to increase base-line FBF levels to make cutaneous vasoconstrictor responses more obvious, the direct effects of Tloc on this response must also be considered. We conclude that the optimum Tloc for observing reflex cutaneous vasoconstriction is near 39 degrees C.     

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.     

Alteration of the rate of cell division independent of the rate of DNA synthesis in a mutant of Salmonella typhimurium

Summary Salmonella typhimurium strain IIG has a temperature—sensitive DNA synthesis initiation apparatus and completes rounds of DNA replication when shifted to 38°. At this temperature there is a period of apparently normal division followed by a second phase in which DNA-less cells are produced. The rate of division in this second phase can be markedly increased if a culture growing in MM is shifted to nutrient broth at the time of the temperature shift. The extra divisions induced by the nutritional shift are not due to extra replication forks being introduced by this process nor to the rapid growth of ts ⁺ revertants. It is concluded that in this strain at 38°, the rate of division can be increased without altering the rate of DNA synthesis. The extra divisions induced by the shift-up do not take place for about 90 min. The possible occurrence of such a period between the triggering of division and the division event in normal cells is discussed.     

Flavonoids in the Flowers of Gnaphalium affine D. Don

Thermonsenstivie division mutants were derived from Bacillus subtilis Marburg 168 thy trp₂ by means of membrane filtration after nitrosoguanidine mutagenesis. Among them, ts42 requiring uracil for normal growth at 48°C was investigated.

In the absence of uracil, the mutant cells grew normally at 37°C and stopped dividing after temperature shift to 48°C resulting in filaments of two to four times length of normal rods. The total cell number after temperature shift from 37 to 48°C, increased two to three fold in 90 min and remained constant thereafter. The viable count after the temperature shift to 48°C, increased 1.5 to 2 fold in initial 60 min and then decreased exponentially. A rapid restoration of colony forming ability was shown when the mutant cells were shifted back to the permissive temperature after 120 to 180 min of incubation at 48°C or when uracil was introduced to the culture at 48°C. This recovery of viability was partly observed even in the presence of chloramphenicol. The synthesis of RNA of this mutant was shown to decline 20 min after the temperature shift to 48°C whereas the syntheses of DNA and protein proceeded for more than 80 min at that temperature.

No newly isolated uracil requiring mutants formed filaments in the medium lacking uracil or showed growth pattern like ts42.     

Control of cell size at division in fission yeast by a growth-modulated size control over nuclear division

In the fission yeast Schizosaccharomyces pombe, nutritional reduction of growth rate by supplying poor nitrogen, carbon or phosphate sources causes a decrease in cell size. The effect on cell division following three different nutritional shifts-up has been investigated. In all cases, about 20% of the cells divide at the original cell length, and then cell division stops for a period. Cell division then resumes at the new faster rate, cell length at division being characteristic of the new medium. Further investigation reveals that the first effect of the shift is to inhibit nuclear division rapidly and completely. These results are strongly suggestive of the operation of a cell size requirement for entry into nuclear division. The cell size necessary for nuclear division is set, or modulated, by the prevailing growth conditions. This model is confirmed by a nutritional shift-down, where nuclear division and cell division are stimulated after the shift. Cell length at division falls rapidly until the new shorter length is attained, when a new steady state is assumed at a slower growth rate. The control system is compared with that in bacteria, and its implications for various models proposed for the control of timing of mitosis are discussed.     

Analysis of initiation of sites of cell wall growth in Streptococcus faecium during a nutritional shift

Three-dimensional reconstruction methods were applied to electron micrographs of Streptococcus faecium to study the initiation of cell wall growth sites during a nutritional shift experiment. Upon lowering the mass doubling time from 76 to 33 min by the addition of excess glutamate, the formation of new cell wall growth sites accelerated above the old steady-state rate at about the same time (10 to 15 min) as did mass, RNA, protein, cell numbers, and autolytic capacity but considerably before DNA (30 min) and peptidoglycan (20 min) synthesis did. During the shift, the average range of cell volumes over which new wall growth sites were introduced did not change significantly. However, upon the shift there was an increase in the frequency of cells having new sites, which was due to the faster-growing cells initiating more new sites in peripheral locations before division. After a transition period, the number of new sites per milliliter of culture increased at a rate that paralleled that of the culture mass. These findings support a model in which new sites are introduced when cells grow to a relatively constant, growth rate-independent size, while the rate at which sites form and grow increases with the growth rate. In this model, chromosome synthesis does not regulate the formation of new sites of cell wall growth, but existing sites cannot be completed until rounds of chromosome synthesis are completed.     

Bacteriophage Release in a Lysogenic Strain of Agrobacterium tumefaciens

Bacteriophage release in a lysogenic strain of Agrobacterium tumefaciens V-1 is temperature-sensitive. At 25 C and 30 C, phage was released in a ratio of 1 plaque-forming unit per 100 bacteria; at 35 C, although bacterial growth was not inhibited, phage release was suppressed. Phage synthesis was induced by heat shock, 42 C for 30 min, ultraviolet irradiation, and mitomycin C. Induction by ultraviolet light was unusual-an immediate rise in phage titer followed irradiation. A large increase occurred after a 90-min latent period. The lysogenic strain was cured of the phage by incubation at 37 C, and the cured strain produced plant tumors.     

Volume growth, murein synthesis, and murein cross-linkage during the division cycle of Escherichia coli PA3092.

Cells of Escherichia coli PA3092 were synchronized by centrifugal elutriation. The synchronously growing cells were double labeled with -3H or DL-[meso-2,6-14C]diaminopimelic acid (DAP) at different times. Cells incorporated [3H]DAP at a continuously increasing rate during their cycle, with a maximum occurring at about 30 min before division for trichloroacetic acid-precipitated cells (whole cells) and about 10 min before division for sodium dodecyl sulfate-treated cells (sacculi). This was in good agreement with the observed kinetics of volume growth under these conditions. Furazlocillin, which preferentially interacts with penicillin-binding protein 3, modified the pattern of incorporation of [3H]DAP. Electron microscopy indicated that furazlocillin did not inhibit the initiation of division but rather its completion. In addition, we measured the cross-linking of the murein inserted at different times during synchronous growth. The highest percentages were found to occur around division. At this same time, the cross-linking of old peptidoglycan was found to be decreased.     

Catalatic capacities in heat-shocked Euglena cells

1. Various heat treatments were applied to the wild strain Z. Klebs. of Euglena gracilis. 2. Samples of cells were taken at day 1 of the culture at 26 degrees C in a 33 mM lactate medium, when the catalatic capacities of the catalase were highest. 3. They were either submitted to heat treatments (36 and 38 degrees C), or heat-shocks (40, 42 degrees C) or non-permissive heat stress (45 degrees C) for 15 min, 1 and 2 hr. 4. After a 2-hr 45 degrees C treatment the cells were unable to recover normal physiological functions. 5. Heat treatments between 36 and 38 degrees C decreased the catalatic capacities of cells, while heat-shocks at 40 and 42 degrees C strongly reinforced these capacities of hydrogen peroxide dismutation. 6. Having been heat-shocked at 42 degrees C for 2 hr, the cells became different from control cells: (a) after several months of culture, they displayed catalatic capacities increased by 65%; (b) they were able from now on to survive a 2 hr heat shock at 45 degrees C.     

New mutations fts-36, lts-33, and ftsW clustered in the mra region of the Escherichia coli chromosome induce thermosensitive cell growth and division.

Three new mutants of Escherichia coli showing thermosensitive cell growth and division were isolated, and the mutations were mapped to the mra region at 2 min on the E. coli chromosome map distal to leuA. Two mutations were mapped closely upstream of ftsI (also called pbpB), in a region of 600 bases; the fts-36 mutant showed thermosensitive growth and formed filamentous cells at 42 degrees C, whereas the lts-33 mutant lysed at 42 degrees C without forming filamentous cells. The mutation in the third new thermosensitive, filament-forming mutant, named ftsW, was mapped between murF and murG. By isolation of these three mutants, about 90% of the 17-kilobase region from fts-36-lts-33 to envA could be filled with genes for cell division and growth, and the genes could be aligned.     

Morphological analysis of the division cycle of two Escherichia coli substrains during slow growth.

Morphological parameters of the cell division cycle have been examined in Escherichia coli B/r A and K. Whereas the shape factor (length of newborn cell/width) of the two strains was the same at rapid growth (doubling time, tau, less than 60 min), with decreasing growth rate the dimensions of the two strains did change so that B/r A cells became more rounded and B/r K cells became more elongated. The process of visible cell constriction (T period) lasted longer in B/r A than in B/r K during slow growth, reaching at tau = 200 min values of 40 and 17 min, respectively. The time between termination of chromosome replication and cell division (D period) was found to be longer in B/r A than in B/r K. As a result, in either strain completion of chromosome replication seemed always to occur before initiation of cell constriction. Nucleoplasmic separation did not coincide with termination as during rapid growth but occurred in both strains within the T period, about 10 min before cell division.     

Anucleate cell production and surface extension in a temperature-sensitive chromosome initiation mutant of Bacillus subtilis.

At 45 C, in a temperature-sensitive initiation mutant (TsB134) of Bacillus subtilis 168 Thy- tryp-, growing in a glucose-arginine minimal medium, chromosome completion occurred over a period of 80 to 90 min, after which there was no further nuclear division. Normal symmetrical cell divisions continued for a generation afterwards, so that nuclei were segregated into separate cells. During this period asymmetric divisions started to occur. Septa appeared at 25 to 30% from one end of the cell, giving a small anucleate cell and a larger nucleate cell. During inhibition of deoxyribonucleic acid (DNA) synthesis by thymine starvation under the restrictive conditions, asymmetrical division also occurred until there was approximately one nucleus per cell (about one generation time). Asymmetric division, giving anucleate cells, then occurred. Similar results were obtained when DNA synthesis was inhibited by nalidixic acid. After 3 h at 45 C, the rate of anucleate cell production in the presence and absence of thymine was constant at one division per 85 min per chromosome terminus present when DNA synthesis stopped. In the absence of DNA synthesis (during thymine starvation) at 35 C, growth in cell length was linear (i.e., the rate was constant), but at 45 C during thymine starvation the rate gradually increased by more than twofold. It is suggested that this was due to the establishment of new sites of growth associated with anucleate cell production. In the presence of thymine at 45 C, the rate of length extension increased by more than fourfold, which it is suggested was caused by the appearance of new growth zones as a result of chromosome termination and a contribution associated with anucleate cell production. If the mutant was incubated at 45 C for 90 min, both in the presence and absence of thymine, then anucleate cell formation could continue on restoration to 35 C in the absence of thymine...     

Hyperthermia-induced heat shock response and thermotolerance in postimplantation rat embryos

Postimplantation stage rat embryos (6-10 somites) undergo abnormal development after exposure to a temperature of 43 degrees C for 30 min. A heat shock of 43 degrees C for 30 min also induces the synthesis of a set of eight heat shock proteins (hsps) with molecular masses ranging from 28,000 to 82,000 Da. The synthesis of these hsps is rapidly induced after the heat shock is applied and rapidly decays after embryos are returned to 37 degrees C. A heat shock of 42 degrees C for 30 min has no effect on rat embryo growth and development, but does induce the synthesis of three hsps. The most prominent of these three is believed to be the typical mammalian 70 kDa hsp. Furthermore, a 42 degrees C, 30-min heat shock followed by a 43 degrees C 30-min heat shock leads to partial protection from the embryotoxic effects of a single exposure at 43 degrees C, i.e., thermotolerance.     

Lag period for phototropism inPilobolus crystallinus sporangiophores

The lag period for the second positive curvature was examined inPilobolus crystallinus sporangiophores. The lag period for curvature development was 20–30 min at lower fluence rates than 6.32 nmol/m²s but greatly extended at higher fluence rates. When a 20-min symmetrical irradiation with blue light was applied before a 20-min unilateral blue light irradiation, sporangiophores bent as much as those unilaterally and continuously irradiated for 40 min. However, when a 20-min unilateral irradiation was followed by a 20-min symmetrical irradiation, sporangiophores did not show any curvature. That is, the reaction during the first 20 min of the lag period is independent of light direction. This light-direction-independent lag period is considered to be the duration required for adaptation. The lag period for phototropism was also extended when fluence rate was reduced after the start of irradiation. These results suggested that an adaptation process is involved in phototropism ofPilobolus.