ENVIRONMENTAL FACTORS AFFECTING RESISTANCE TO DESICCATION IN THE DIATOM STAURONEIS ANCEPS

Several environmental parameters influence the ability of Stauroneis anceps Ehr. to survive periods of dehydration to equilibrium with atmospheric humidity. Cells grown in soil-water are better able to survive desiccation than cells grown in defined medium and cells from older cultures survive better than those from young cultures. Since active culture growth and cell division do not hinder survival, the factor responsible for increased survival in older cultures may be the accumulation of secreted metabolites in the medium. There is no survival when drying occurs in artificial substrata with particles 50 microns or less in diameter. Survival occurs when the particulate matter is 100 microns or larger. Slow drying seems to enhance survival, perhaps by allowing cells to interact longer with environmental organic substances conferring some degree of protection. Desiccated cells are better able to withstand temperature extremes than are vegetative cells in an aqueous environment. Dry cells survived longer than 9 days at 60 C and longer than 8 hr at 80 C but normal cultures were unable to survive 1 hr at 60 C. Temperatures of —15 to —20 C were also sustained more consistently by desiccated cells. Cells stored at vapor pressure deficits of 11.9 mm Hg or higher survived longer than 16 months but storage at 5.9 mm Hg or lower reduced survival time.     

Effect of Cold Temperatures on the Viability of Chromobacterium violaceum

The effect of low, nonfreezing temperatures on the viability of five strains of Chromobacterium violaceum was studied. The viability of cultures grown at 30 C was determined after exposure to various diluents held at 0 to 2 C. A culture diluted at its growth temperature served as the control. Cells of strain N were most sensitive in the early part of the exponential phase of growth. Cells of strains 252 and 341 were most sensitive in the late exponential, early stationary phase of growth. Cells of strain 9 showed greatest loss of viability during the maximal stationary phase. Strain 69 was completely resistant throughout its growth cycle to cold injury. Cell viability was much greater in buffered salts solution than in distilled water, broth, or physiological saline, whether cultures were diluted at room temperature or in the cold. The proportion of cells surviving after exposure to cold, however, was the same regardless of the composition of the diluent. Loss of viability was progressive at 0 to 2 C and reached a maximum after 2 hr. There was no loss of viability of cells exposed to 20 C, but there was some loss at 12 C. Strain 341 cultivated at 15 C was much less sensitive to 0 to 2 C than when it was cultivated at 30 C. The composition of the growth medium seemed to have no effect on the survival of cells exposed to cold. The polyamines, spermine and trimethylenediamine, as well as erythritol and sucrose, exerted some protective action against the effects of cold but not uniformly for all strains studied.     

Population Dynamics of Brucella on Solid Media

An examination is presented of the growth characteristics on solid media of one strain each of Brucella abortus and B. neotomae. It was observed that, during the exponential growth phase, generation times of approximately 100 min were measured for both organisms under a variety of conditions. The logarithmic growth phase did not extend beyond 18 hr in most instances. It was noted that erythritol added to Trypticase Soy Agar did not enhance the growth rate or the total viable yield of either organism. Phosphate buffer failed to exert a significant effect upon pH changes during culture. B. neotomae cultures on solid media produced markedly acidic reactions in 48 hr. If cells in an active growth phase are desired, it is suggested that solid media cultures of laboratory strains be harvested before 24 hr.     

Clostridium cellulolyticum Viability and Sporulation under Cellobiose Starvation Conditions

Depending on the moment of cellobiose starvation, Clostridium cellulolyticum cells behave in different ways. Cells starved during the exponential phase of growth sporulate at 30%, whereas exhaustion of the carbon substrate at the beginning of growth does not provoke cell sporulation. Growth in the presence of excess cellobiose generates 3% spores. The response of C. cellulolyticum to carbon starvation involves changes in proteolytic activities; higher activities (20% protein degradation) corresponded to a higher level of sporulation; lower proteolysis (5%) was observed in cells starved during the beginning of exponential growth, when sporulation was not observed; with an excess of cellobiose, an intermediate value (10%), accompanied by a low level of sporulation, was observed in cells taken at the end of the exponential growth phase. The basal percentage of the protein breakdown in nonstarved culture was 4%. Cells lacking proteolytic activities failed to induce sporulation. High concentrations of cellobiose repressed proteolytic activities and sporulation. The onset of carbon starvation during the growth phase affected the survival response of C. cellulolyticum via the sporulation process and also via cell-cellulose interaction. Cells from the exponential growth phase were more adhesive to filter paper than cells from the stationary growth phase but less than cells from the late stationary growth phase.     

Effects on Growth and Toxin Production of Exposure of Spores of Clostridium botulinum Type F to Sublethal Doses of Gamma Irradiation

Spores of the Langeland strain of Clostridium botulinum type F were grown at 30 or 10 C after exposure to 0.0, 0.1, or 0.2 megarad of cesium-137 gamma irradiation. When incubated at 30 C, cultures irradiated at the 0.2-megarad level reached the stationary growth phase 15 hr earlier than the 0.0 or 0.1 megarad-irradiated cultures. This was not the result of earlier or more frequent germination of the irradiated spores, the formation of larger individual cells, filament formation, or cell clumping. It appeared to result from elimination of a lytic phenomenon noted in 0.0 and 0.1 megarad-irradiated cultures after 26 and 29 hr of incubation, respectively, which was followed by a second exponential-growth response 5 hr later in these cultures. The time of toxin appearance in culture supernatant fractions was independent of prior irradiation treatment and occurred after 36 hr of incubation. Toxin release was essentially logarithmic until maximal titers were reached and maximal toxin titers were higher in irradiated than in unirradiated cultures. The higher toxin level was sustained over a period of 23 days of 30 C. Toxin produced in the 30 C cultures could not be trypsin-activated. An incubation temperature of 10 C resulted in no outgrowth of spores subjected to 0.2 megarad of irradiation, although spore germination did occur. At 10 C, outgrowth of the 0.1-megarad culture was faster with slightly higher quantities of a more stable toxin than was seen in the unirradiated control. At 10 C, trypsinization was necessary to demonstrate the toxin present in the cultures.     

Coiling is Not Essential to Anhydrobiosis by Aphelenchus avenae on Agar Amended with Sucrose

The roles of preconditioning and coiling upon entrance into anhydrobiosis by Aphelenchus avenae were tested via video-assisted analysis at 25²°C. Fourth-stage juveniles or young adults of A. avenae were individually placed on 5% agar containing 0.8 M sucrose. Nematodes became quiescent within 3 hr, then gradually resumed a low level of activity and assumed a coiled posture. High desiccation survival rate was recorded when nematodes were incubated on agar for more than 6 hr; the survival rates were 0%, 3%, 73%, and 92% for 0, 2, 6, and 12 hr on agar, respectively. All nematodes placed on agar for 24 hr or more revived after rehydration following desiccation. Once nematodes were on agar for a sufficient time, no difference in desiccation survival was observed between nematodes taking a coiled posture and those uncoiled artificially. Based on these results, exposure to osmotic stress for 6 hr can prepare A. aveae physiologically for anhydrobiosis, but coiling does not appear to be a physiological requirement for desiccation in survival.     

Aedes novalbopictus: establishment and characterization of larval cell lines

Two diploid cell lines were established from larval tissues of the mosquito Aedes novalbopictus. Many morphologically different types of cells were detected in primary cultures. However, only three types of cells became established in the cell lines. They were: epithelial-like cells (80–90%), fibroblast-like cells (5–10%), and giant cells (5–10%). Cell number increased about 15-fold during the first 6 days of culture and the population doubling time during the period of active growth was 18 hr. Seventy to 80% of the cells were diploid (2n = 6) and the rest were tetra-or polyploids. Cells from these two cultures so far (December, (1971)) have been subcultured 36 and 34 times, respectively. The growth pattern and general morphologic features of the cells of A. novalbopictus cultures closely resembled those of A. albopictus cultures.     

The behaviour of log phase Escherichia coli at temperatures that fluctuate about the minimum for growth

AIMS: To investigate the behaviour of cold-adapted, log phase Escherichia coli exposed to temperatures that fluctuate below and above the minimum for growth. METHODS AND RESULTS: Log phase E. coli cultures were incubated at a constant temperature of 2, 4 or 6 degrees C or with temperatures allowed to increase from those temperatures for 35 min, to 10 degrees C, at 6-, 12- or 24-h intervals, as commonly occurs during retail display of chilled foods. At suitable intervals for each culture, the optical absorbance value was determined using a spectrophotometer, the forward angle light scatter was determined using a flow cytometer, and portions were spread on plate count agar for enumeration of colony forming units (CFU). Numbers of CFU decreased by 3 log units or increased by 1 log unit for cultures incubated at 6 degrees C for 17 days without or with temperatures fluctuations at < or =12-h intervals, respectively. Cells elongated when cultures were incubated at 4 or 2 degrees C with temperatures fluctuating at 6-h intervals, and at 6 degrees C at constant or fluctuating temperatures, but cells did not elongate in cultures incubated at a constant temperature of 2 or 4 degrees C. SIGNIFICANCE AND IMPACT OF THE STUDY: The minimum growth temperature of E. coli is assumed to be > or =7 degrees C. Elongated cells were able to divide when temperatures rose from 6 degrees C to above 7 degrees C for <45 min at < or =12-h intervals. Such temperature fluctuations may be experienced by chilled foods during defrosting cycles of retail display cases. The finding that cells behave differently under fluctuating than at constant temperatures may significantly affect understanding of appropriate temperatures for the safe storage of chilled foods and for predictive modelling of bacterial growth in such foods.     

Properties of the H-4-II-E tumor cell system. II. In vitro characteristics of an experimental tumor cell line.

The growth and cell proliferation characteristics of the H-4-II-E cell line, giving rise to hepatoma H-4-II-E when inoculated into male ACI rats, were studied in vitro. Following seedling of 2 x 10(5) cells into culture dishes, exponential cell growth occurs in cultures fed both at 24 hr and 48 hr intervals with a population doubling time of 18-4 hr. Plateau phase growth conditions are established on day 7 and day 5 for cultures fed at 24 hr and 48 hr intervals respectively. Both the plateau phase cell density and the maintenance of plateau phase appear dependent on the frequency of feeding. For cultures fed daily, the transition from exponetial growth to plateau phase results from both a reduction in the number of proliferating cells (99% v. 35%) as well as an elongation of the cell cycle (17-7 hr v. 128-4 hr). The cell proliferation characteristics of the culture are further discussed in reference to both cell growth and feeding schedules of other cell lines.     

Effect of growth phase on survival of bromegrass suspension cells following cryopreservation and abiotic stresses

BACKGROUND AND AIMS: Cryopreservation is a practical method of preserving plant cell cultures and their genetic integrity. It has long been believed that cryopreservation of plant cell cultures is best performed with cells at the late lag or early exponential growth phase. At these stages the cells are small and non-vacuolated. This belief was based on studies using conventional slow prefreezing protocols and survival determined with fluorescein diacetate staining or 2,3,5-triphenyltetrazolium chloride assays. This classical issue was revisited here to determine the optimum growth phase for cryopreserving a bromegrass (Bromus inermis) suspension culture using more recently developed protocols and regrowth assays for determination of survival. METHODS: Cells at different growth phases were cryopreserved using three protocols: slow prefreezing, rapid prefreezing and vitrification. Stage-dependent trends in cell osmolarity, water content and tolerance to freezing, heat and salt stresses were also determined. In all cases survival was assayed by regrowth of cells following the treatments. KEY RESULTS: Slow prefreezing and rapid prefreezing protocols resulted in higher cell survival compared with the vitrification method. For all the protocols used, the best regrowth was obtained using cells in the late exponential or early stationary phase, whereas lowest survival was obtained for cells in the late lag or early exponential phase. Cells at the late exponential phase were characterized by high water content and high osmolarity and were most tolerant to freezing, heat and salt stresses, whereas cells at the early exponential phase, characterized by low water content and low osmolarity, were least tolerant. CONCLUSIONS: The results are contrary to the classical concept which utilizes cells in the late lag or early exponential growth phase for cryopreservation. The optimal growth phase for cryopreservation may depend upon the species or cell culture being cryopreserved and requires re-investigation for each cell culture. Stage-dependent survival following cryopreservation was proportionally correlated with the levels of abiotic stress tolerance in bromegrass cells.     

CHANGES IN CELL PROLIFERATION KINETICS OCCURRING DURING THE LIFE HISTORY OF MONOLAYER CULTURES OF A MOUSE TUMOUR CELL LINE

Following inoculation of monolayer cultures of EMT6 mouse tumour cells at 10⁵ cells, a short lag is followed by 3 days of exponential growth with a population doubling time of 12 hr. A plateau cell number is reached between days 4 and 5 and is maintained for at least 8 days. During exponential growth, the pulse ³H-TdR labelling index is 55–60%, all cells are in cycle, and the median cycle time is 11–12 hr. For the first 3 days of plateau phase, the labelling index is about 25 % and there is considerable cell loss. The cell cycle is 32–40 hr, and S-phase is very long. Later in plateau phase, the labelling index falls to <2 % and there is little cell loss. The changes in kinetics occurring in EMT6 cultures are discussed with reference to reported changes occurring in other cell lines.     

Influence of Temperature of Incubation and Type of Growth Medium on Pigmentation in Serratia marcescens

Maximal amounts of prodigiosin were synthesized in either minimal or complete medium after incubation of cultures at 27 C for 7 days. Biosynthesis of prodigiosin began earlier and the range of temperature for formation was greater in complete medium. No prodigiosin was formed in either medium when cultures were incubated at 38 C; however, after a shift to 27 C, pigmentation ensued, provided the period of incubation at 38 C was not longer than 36 hr for minimal medium or 48 hr for complete medium. Washed, nonpigmented cells grown in either medium at 38 C for 72 hr could synthesize prodigiosin when suspended in saline at 27 C when casein hydrolysate was added. These suspensions produced less prodigiosin at a slower rate than did cultures growing in casein hydrolysate at 27 C without prior incubation at 38 C. Optimal concentration of casein hydrolysate for pigment formation by suspensions was 0.4%; optimal temperature was 27 C. Anaerobic incubation, shift back to 38 C, killing cells by heating, or chloramphenicol (25 mug/ml) inhibited pigmentation. Suspensions of washed cells forming pigment reached pH 8.0 to 8.3 rapidly and maintained this pH throughout incubation for 7 days. Measurements of viable count and of protein, plus other data, indicated that cellular multiplication did not occur in suspensions of washed cells during pigment formation. By this procedure utilizing a shift down in temperature, biosynthesis of prodigiosin by washed cells could be separated from multiplication of bacteria.     

Rich Medium Composition Affects Escherichia coli Survival,Glycation, and Mutation Frequency during Long-Term Batch Culture

Bacteria such as Escherichia coli are frequently grown to high density to produce biomolecules for study in the laboratory. To achieve this, cells can be incubated in extremely rich media that increase overall cell yield. In these various media, bacteria may have different metabolic profiles, leading to changes in the amounts of toxic metabolites produced. We have previously shown that stresses experienced during short-term growth can affect the survival of cells during the long-term stationary phase (LTSP). Here, we incubated cells in LB, 2× yeast extract-tryptone (YT), Terrific Broth, or Super Broth medium and monitored survival during the LTSP, as well as other reporters of genetic and physiological change. We observe differential cell yield and survival in all media studied. We propose that differences in long-term survival are the result of changes in the metabolism of components of the media that may lead to increased levels of protein and/or DNA damage. We also show that culture pH and levels of protein glycation, a covalent modification that causes protein damage, affect long-term survival. Further, we measured mutation frequency after overnight incubation and observed a correlation between high mutation frequencies at the end of the log phase and loss of viability after 4 days of LTSP incubation, indicating that mutation frequency is potentially predictive of long-term survival. Since glycation and mutation can be caused by oxidative stress, we measured expression of the oxyR oxidative stress regulator during log-phase growth and found that higher levels of oxyR expression during the log phase are consistent with high mutation frequency and lower cell density during the LTSP. Since these complex rich media are often used when producing large quantities of biomolecules in the laboratory, the observed increase in damage resulting in glycation or mutation may lead to production of a heterogeneous population of plasmids or proteins, which could affect the quality of the end products yielded in some laboratory experiments.     

Effect of phenotypic plasticity on epiphytic survival and colonization by Pseudomonas syringae.

The bacterial epiphyte Pseudomonas syringae MF714R was cultured on agar or in broth or collected from colonized leaves; it was then inoculated onto greenhouse-grown bean plants incubated in a growth chamber at low relative humidity or in the field or onto field-grown bean plants. Cells cultured in liquid medium survived the least well after inoculation of leaf surfaces under all conditions. Cells cultured in solid medium exhibited the highest percent survival and desiccation tolerance in the growth chamber but generally survived less well in the field than did cells harvested from plants. Cells harvested from plants and inoculated onto plants in the field usually exhibited the highest percent survival, started to increase in population earlier, and reached a higher number than did cells cultured in vitro. Differences in field survival were apparently not attributable to differential UV tolerance. The observed effects of phenotypic plasticity on epiphytic survival and colonization should be considered in risk assessment studies, in studies of bacterial epidemiology, and in the use of microbial antagonists for biological pest control.     

Effect of continuous heat stress on cell growth and protein synthesis in Aedes albopictus

Aedes albopictus (clone C6/36) cells, which normally grow at 28 degrees C, were maintained at a supraoptimal temperature of 37 degrees C. The effect of continuous heat stress (37 degrees C) on cell growth was analyzed as were the modifications occurring with protein synthesis during short- and long-term heat stress. We observed that cells in lag or exponential growth phase, present inhibition of cell growth, and cells in the lag phase showed more sensitivity to death than cells growing exponentially. During the first hour of exposing the cells to 37 degrees C, they synthesized two heat shock proteins (hsps) of 82 kd and 70 kd, respectively, concomitant with inhibition of normally produced proteins at control temperature (28 degrees C). However, for incubations longer than 2 hr at 37 degrees C, a shift to the normal pattern of protein synthesis occurred. During these transitions, two other hsps of 76 kd and 90 kd were synthesized. Pulse chase experiments showed that the 70-kd hsp is stable at least for 18 hr, when the cells are returned to 28 degrees C. However, if cells were incubated at 37 degrees C, the 70-kd hsp is stable for at least 48 hr. The 70-kd hsp was localized in the cytoplasmic and in the nuclear compartment. Our results indicate a possible role of hsp 70-kd protein in the regulation of cell proliferation.     

Changes in extracellular polysaccharide content and morphology of Microcystis aeruginosa at different specific growth rates

The cyanobacterium Microcystis mainly exists in colonies under natural conditions but as single cells in typical laboratory cultures. Understanding the mechanism by which single cells form small and large colonies can provide a deeper insight into the life history of Microcystis and the mechanisms of Microcystis bloom formation. In this paper, Microcystis aeruginosa cultured under varying light intensities and temperatures exhibited different specific growth rates. Correlations were found between the specific growth rate, extracellular polysaccharide (EPS) content, and morphology of M. aeruginosa. Under low light intensities and temperatures, M. aeruginosa formed small colonies (maximum colony size approximately 100 μm) and exhibited low specific growth rates. By contrast, standard culture conditions yielded single or paired cells with high specific growth rates. Moreover, the EPS content decreased dramatically with increasing specific growth rate. A significant positive linear relationship was observed between the EPS content per cell and colony size. High EPS content and colony formation were associated with low specific growth rates. The specific growth rate in laboratory cultures was higher than the in situ growth rate under natural conditions. This result may explain why Microcystis normally exists as single cells or (more rarely) as paired cells in axenic laboratory cultures after long-term cultivation, but forms colonies under natural conditions.     

Infection and development of Nosema bombycis (Microsporida: Protozoa) in a cell line of Antheraea eucalypti

Spores of Nosema bombycis derived from diseased insects were highly purified by Urografin density gradient centrifugation. Antheraea eucalypti cells were inoculated with the purified spores primed with 0.1 n KOH solution to start a continuous propagation of N. bombycis in cell culture. The first increase in the number of infected A. eucalypti cells was observed at 48 hr postinoculation, and it was caused by the secondary infective forms of N. bombycis. The secondary infective forms were produced during the course of sporoblast differentiation. The parasites in cell cultures divided synchronously until 36 hr postinoculation. Mature spores were observed initially 6 days postinoculation at 27°C. The infected cultures were subcultured extensively for more than 1 year with the addition of healthy A. eucalypti cells.     

Low-temperature pausing of cultivated mammalian cells

There are currently two methods for maintaining cultured mammalian cells, continuous passage at 37 degrees C and freezing in small batches. We investigated a third approach, the "pausing" of cells for days or weeks at temperatures below 37 degrees C in a variety of cultivation vessels. High cell viability and exponential growth were observed after pausing a recombinant Chinese hamster ovary cell line (CHO-Clone 161) in a temperature range of 6-24 degrees C in microcentrifuge tubes for up to 3 weeks. After pausing in T-flasks at 4 degrees C for 9 days, adherent cultures of CHO-DG44 and human embryonic kidney (HEK293 EBNA) cells resumed exponential growth when incubated at 37 degrees C. Adherent cultures of CHO-DG44 cells paused for 2 days at 4 degrees C in T-flasks and suspension cultures of HEK293 EBNA cells paused for 3 days at either 4 degrees C or 24 degrees C in spinner flasks were efficiently transfected by the calcium phosphate-DNA coprecipitation method, yielding reporter protein levels comparable to those from nonpaused cultures. Finally, cultures of a recombinant CHO cell line (CHO-YIgG3) paused for 3 days at 4 degrees C, 12 degrees C, or 24 degrees C in bioreactors achieved the same cell mass and recombinant protein productivity levels as nonpaused cultures. The success of this approach to cell storage with rodent and human cell lines points to a general biological phenomenon which may have a wide range of applications for cultivated mammalian cells.     

Enhanced Production of Virus-Inhibiting Factor (Interferon) in Human Diploid Cells by Ultraviolet Irradiation and Temperature Shift-Down after Stimulation with Newcastle Disease Virus

The production of the virus-inhibiting factor or interferon (IF) was highest in cells incubated at 37 C after inoculation with Newcastle disease (ND) virus and decreased as the incubation temperature was lowered. Shift-down of incubation temperature to 32 C or 34 C after incubation at 37 C for 4–7 hr enhanced IF production in cell cultures stimulated with ND virus, as compared with cultures incubated continuously at 37 C. Shift-down to 32 C after incubation at 37 C for 6 hr. was optimal for this enhancement of IF yield. Enhanced IF production was also observed in cell cultures irradiated by ultraviolet light 4–7 hr after stimulation with ND virus.     

Temperature ranges over which rainbow trout fibroblasts survive and synthesize heat-shock proteins

Cultures of the rainbow trout fibroblast cell line RTG-2 withstood temperatures from 0 degrees C to 28 degrees C. At 0 degrees C and 28 degrees C, no proliferation occurred, but cells persisted for at least 7 days. If the cultures were placed back at 22 degrees C, proliferation returned to normal in those that had been kept at 0 degrees C but was reduced in cultures that had been kept at 28 degrees C. Above 28 degrees C, cultures survived for only short periods. If RTG-2 cells that were grown routinely at 22 degrees C were shifted to 26, 28, and 30 degrees C, heat shock proteins (hsps) of 100, 87, 70, 68, 60, 39, 27, and 19 kilodaltons were synthesized. Synthesis was most pronounced at 28 degrees C, and at this temperature hsp synthesis was maximal by 2 hr and had returned to control levels by 36 hr. Individual hsps were synthesized maximally at slightly different times and temperatures, but under all conditions hsps 87 and 70 were most abundant. If cultures were shifted to 24 degrees C or 32 degrees C, hsp synthesis was not observed. Neither the placement of cultures at 5 degrees C nor the shift of cultures that had been maintained at 0 degrees C or 5 degrees C back to 22 degrees C induced the synthesis of hsps. However, cultures incubated at 5 degrees C for 24 hr did synthesize hsps at 26 degrees C, 28 degrees C, and 30 degrees C.