Cell Size,Macromolecular Composition,and O2 Consumption During Agitated Cultivation of Naegleria gruberi*

SYNOPSIS. Cell size, macromolecular composition, carbohydrate utilization patterns, and O₂ concentrations were measured throughout the growth stages of Naegleria gruberi in agitated cultures in a complex medium. Biphasic logarithmic growth occurred during the initial 83 hr of growth and the mean generation time was 7.0 hr and 19 hr during initial and secondary log growth stages, respectively. The maximum yield was 5 × 10* amebaeJml. The pH rose rapidly (1 pH unit) during the secondary log growth phase (52-83 hr) and continued into the stationary growth phase (83-120 hr). Dry weight, total protein, carbohydrate, and RNA per ameba increased just before the secondary log growth phase. RNA increased 31% to 35% per ameba at the end of each phase of log growth. DNA increased ～ 2-fold throughout the different growth phases. Average cell size increased 90% during biphasic log growth then decreased during stationary phase. O₂ tension decreased from 100% to 18% of saturation during the biphasic growth phase, then increased during stationary growth to near 100% saturation. Glucose and total carbohydrate assays showed little utilization of those substrates throughout the growth stages. Naegleria gruberi presumably has a predominantly aerobic metabolism, also its metabolism may change during the different growth phases.     

Modification of low density lipoprotein metabolism by growth factors in cultured vascular cells and human skin fibroblasts. Dependence upon duration of exposure

Phospholipase A, sphingomyelinase and lysophospholipase activities were examined in cell homogenates and cell-free culture media of virulent and virulent-attenuated Naegleria fowleri and nonpathogenic Naegleria gruberi. Homogenates of virulent N. fowleri contained from 3 to 250 times the lipolytic activity of virulent-attenuated and non-pathogenic Naegleria spp. Similarly, the cell-free media of virulent N. fowleri cultures contained large quantities of phospholipase A, lysophospholipase and sphingomyelinase while comparable activities in the cell-free media of virulent-attenuated and nonpathogenic Naegleria spp. were only slightly, if at all, detectable. Lipolytic enzymes accumulated in the media of virulent N. fowleri cultures at various stages during growth but not in virulent-attenuated and nonpathogenic Naegleria cultures. In general, phospholipase A and sphingomyelinase accumulated during the log phase of growth while lysophospholipase appeared only in the late stationary phase. We conclude that pathogenic Naegleria contain potent lipolytic enzymes that are released selectively into the media during growth. These enzymes could contribute to the pathogenesis of Naegleria-induced primary amoebic meningoencephalitis.     

Biochemical Alterations of Dermatophytes during Growth

Alterations in the biochemical constituents of mycelia were studied during the growth, development, and starvation of Microsporum quinckeanum. On the basis of dry weight, growth of this dermatophyte could be divided into four phases: lag, log, stationary, and death. The percentage of total nitrogen, inorganic phosphorus, ribonucleic acid (RNA), and protein increased rapidly during the lag phase. The percentage of protein remained constant after the initial increase; however, inorganic phosphate and RNA decreased in older mycelia. Acid-soluble materials in the cells increased in concentration as the organism aged. Chitin was present in the spores at a much higher concentration than in the mycelia. The percentage of this compound decreased rapidly until the end of the lag phase. An increase and subsequent decrease in per cent chitin occurred during the log phase. Inorganic phosphorus in the mycelia increased from the value in the spore stage to a maximum in the early log phase, and then decreased rapidly during the remainder of the growth cycle. Compounds involved in protein synthesis increased rapidly during the lag phase of growth. Changes in chemical composition of the mold during starvation indicate that carbohydrate does not form the principal endogenous reserve of M. quinckeanum, whereas lipids may represent the primary reserve material.     

Cell Size,Macromolecule Composition,Nuclear Number,Oxygen Consumption and Cyst Formation During Two Growth Phases in Unagitated Cultures of Acanthamoeba castellanii1

SYNOPSIS. The size, composition and physiology of average cells have been studied in cultures of Acanthamoeba castellanii during the phases of logarithmic growth and population growth deceleration (PGD). Most of the features examined were relatively constant during log phase, but had significant changes during PGD. Average cell volume increased about 60% and total dry mass about 15–20% during the latter period. Total protein content remained constant thruout both growth phases, but cytochrome oxidase doubled during PGD. DNA, RNA and glycogen levels began to change during late log phase. DNA decreased about 50% and RNA increased about 75%. Glycogen decreased 50% during the RNA build-up and then increased to a plateau above the log phase level. A final decrease in glycogen followed an increase in the relative numbers of cysts in late PGD. It was found that PGD begins when O₂ becomes limiting and evidence that the subsequent changes in macromolecule composition are related to encystation is discussed.     

The Fate of RNA Degradation Products in Starved Cultures of Tetrahymena pyriformis W.*

The RNA content of a population of Tetrahymena pyriformis W was followed during the growth phases of the culture. The cellular RNA levels were found to reach a maximum in early log phase and to decrease throughout the remainder of the log and deceleration phases. There was a 25% decrease in RNA amount when cells in late stationary phase were compared to those in deceleration. This loss of RNA was mimicked when cells from the deceleration phase were suspended in a non-nutrient buffered medium. Procedures were established to determine RNA content and the intra- and extracellular distribution of RNA degradation products, namely purine and pyrimidine bases and orthophosphate. Balance sheets are presented to show that the decrease in RNA levels was accompanied by an equivalent increase in purine and pyrimidine bases and phosphorus derivatives. The validity of the procedures employed was demonstrated. The influence of magnesium, cholesterol and glucose on the cells suspended in a non-nutrient buffer was examined. Each was found to affect the ultimate distribution of RNA products in a characteristic fashion suggesting that each compound acts by a different mode of action.     

Carbohydrate Metabolism and Activity of Pyrophosphate: Fructose-6-Phosphate Phosphotransferase in Photosynthetic Soybean (Glycine max, Merr.) Suspension Cells

Activity of pyrophosphate:fructose-6-phosphate phosphotransferase (PFP) was investigated in relation to carbohydrate metabolism and physiological growth stage in mixotrophic soybean (Glycine max Merr.) suspension cells. In the presence of exogenous sugars, log phase growth occurred and the cells displayed mixotrophic metabolism. During this stage, photosynthetic oxygen evolution was depressed and sugars were assimilated from the medium. Upon depletion of medium sugar, oxygen evolution and chlorophyll content increased, and cells entered stationary phase. Activities of various enzymes of glycolysis and sucrose metabolism, including PFP, sucrose synthase, fructokinase, glucokinase, UDP-glucose pyrophosphorylase, and fructose-1,6-bisphosphatase, changed as the cells went from log to stationary phases of growth. The largest change occurred in the activity of PFP, which was three-fold higher in log phase cells. PFP activity increased in cells grown on media initially containing sucrose, glucose, or fructose and began to decline when sugar in the medium was depleted. Western blots probed with antibody specific to the -subunit of potato PFP revealed a single 56 kilodalton immunoreactive band that changed in intensity during the growth cycle in association with changes in total PFP activity. The level of fructose-2,6-bisphosphate, an activator of the soybean PFP, increased during the first 24 hours after cell transfer and returned to the stationary phase level prior to the increase in PFP activity. Throughout the growth cycle, the calculated in vivo cytosolic concentration of fructose-2,6-bisphosphate exceeded by more than two orders of magnitude the previously reported activation coefficient (K_a) for soybean PFP. These results indicate that metabolism of exogenously supplied sugars by these cells involves a PFP-dependent step that is not coupled directly to sucrose utilization. Activity of this pathway appears to be controlled by changes in the level of PFP, rather than changes in the total cytosolic level of fructose-2,6-bisphosphate.     

The Utilization of Glucose and Proline by Culture Forms of Trypanosoma brucei*

Exponentially dividing culture forms of Trypanosoma brucei did not utilize glucose provided in the culture medium. The inclusion of 2-deoxyglucose in the medium had no effect on the growth of the trypanosomes. Glucose could be replaced by proline in the liquid phase of biphasic medium without affecting the doubling time of the organisms. Proline added to the culture medium in this way disappeared during the log phase of growth. Glucose in the culture medium was used by the trypanosomes only when the stationary growth phase had been reached. Lipid accumulated in stationary phase trypanosomes grown in glucose-containing medium, but there was no lipid accumulation in log phase organisms or in those which had been grown in proline-containing medium. Bloodstream trypanosomes transferred to liquid medium rapidly utilized glucose over the first 12 hr of culture, and this was accompanied by an accumulation of free pyruvate in the medium. The rate of glucose utilization fell off over the next 36 hr; this was accompanied by a lowering of free pyruvate in the medium and a rise in the proline oxidase activity of the trypanosomes. The possible biologic significance of proline to trypanosomes developing in the midgut of the tsetse vector is discussed.     

Tetraether type polar lipids increase after logarithmic growth phase of Methanobacterium thermoautotrophicum in compensation for the decrease of diether lipids

Abstract The ratios of tetraether to diether type lipids in the total lipid during cell growth in batch cultures of Methanobacterium thermoautotrophicum ΔH (DSM 1053) were examined. The proportion of tetraether type lipids to the total lipid was about 80% during the log phase, and at the onset of the transient phase it began to rise up to about 93%. It was kept almost constant at that level throughout the stationary phase. The polar lipid composition changed with the age of the cell culture. The proportions of all the diether type polar lipids were lower and the levels of all tetraether type polar lipids were higher in the stationary phase than in the log phase. On the other hand, the composition of polar head groups, irrespective of the core lipids, was nearly constant in both growth phases measured so far despite the change in core lipid composition.     

Conditions for maximum enflagellation in Naegleria fowleri

Ameba to flagellate transformation in Naegleria fowleri (Lovell strain) was affected by growth temperature, phase of growth, strain of ameba, culture agitation, enflagellation temperature, enflagellation diluent, and cell concentration. Amebae transformed best when they were grown without agitation and enflagellated with agitation. Regardless of growth temperature (23 degrees, 30 degrees, 37 degrees, and 42 degrees C were tested), amebae transformed best at 37 degrees C. Enflagellation was greatest for cells harvested between 24 h (mid-exponential) and 84 h (late stationary) of growth.     

Conditions for Maximum Enflagellation in Naegleria fowleri1

ABSTRACT. Ameba to flagellate transformation in Naegleria fowleri (Lovell strain) was affected by growth temperature, phase of growth, strain of ameba, culture agitation, enflagellation temperature, enflagellation diluent, and cell concentration. Amebae transformed best when they were grown without agitation and enflagellated with agitation. Regardless of growth temperature (23°, 30°, 37°, and 42°C were tested), amebae transformed best at 37°C. Enflagellation was greatest for cells harvested between 24 h (mid-exponential) and 84 h (late stationary) of growth.     

Amebostomes of Naegleria fowleri

The strain of ameba, culture incubation temperature, and phase of ameba growth affected the number of amebostomes present on amebae of Naegleria fowleri. Serial passage of N. fowleri through mice decreased the average number of amebostomes. Amebostomes were shown to be functional by their ability to engulf yeast cells.     

Amebostomes of Naegleria fowleri1

The strain of ameba, culture incubation temperature, and phase of ameba growth affected the number of amebostomes present on amebae of Naegleria fowleri. Serial passage of N. fowleri through mice decreased the average number of amebostomes. Amebostomes were shown to be functional by their ability to engulf yeast cells.     

Regulation of RNA synthesis in plant cell culture: delayed synthesis of ribosomal RNA during transition from the stationary phase to active growth

Ribosomal RNA synthesis was studied during the early phases of growth activation in a cell suspension culture derived from peanut (Arachis hypogaea, L.) cotyledon. Upon dilution from stationary phase, these cells show a characteristic lag of 3 days before the commencement of cell division. An analysis of the nature of RNA synthesized during this early period of growth showed that the cells obtained immediately upon dilution from stationary phase synthesize primarily messenger RNA and essentially no ribosomal RNA. The synthesis of ribosomal RNA is delayed for about 24 hr after which it rises sharply resulting in a 2- to 3-fold accumulation of ribosomal RNA per cell during the subsequent 24-hr period. Both the messenger RNA and the ribosomal RNA were characterized by their cellular localization; by sucrose and CsCl gradient analyses, and by the determination of their base ratios.It would appear that a major facet of the lag phase in the cell growth is the diversion of a significant part of the RNA biosynthetic apparatus from the synthesis of messenger RNA to that of ribosomal RNA.     

Proline Uptake and Utilization by Chlorella pyrenoidosa

Conditions for proline uptake and utilization by Chlorella pyrenoidosa Chick are described. Proline is taken up by growing cultures during late log phase growth after depletion of glucose from the medium. However, proline uptake by stationary phase cultures requires the presence of glucose in the medium. The results are consistent with the interpretation that some carbohydrate is required for proline uptake but proline uptake is inhibited by the accumulation of intracellular carbohydrates.     

The production of extracellular carbohydrates by estuarine benthic diatoms: the effects of growth phase and light and dark treatment

Epipelic diatoms are important constituents of estuarine microphytobenthic biofilms. Field‐based investigations have shown that the production of carbohydrates by such taxa is ecologically important. However, limited information exists on the dynamics of carbohydrate production by individual species of epipelic diatoms. The production of low and high molecular weight extracellular carbohydrates in axenic cultures of five species of benthic estuarine diatoms, Cylindrotheca closterium (Ehrenberg), Navicula perminuta (Grun.) in Van Heurck, Nitzschia frustulum (Kütz.) Grunow, Nitzschia sigma (Kütz.) Grunow, and Surirella ovata (Kütz.) Grunow, were investigated. All species produced colloidal (water‐soluble) carbohydrates during growth, with maximal production occurring during stationary phase. During logarithmic growth, approximately 20% of extracellular carbohydrates consisted of polymeric material (extracellular polymeric substances [EPS]), but during stationary phase, EPS content increased to 34%–50%. Pyrolysis–mass spectrophotometry analysis showed differences in the composition of EPS produced during logarithmic and stationary phase. All species synthesized glucan as a storage carbohydrate, with maximum glucan accumulation during the transition from log to stationary phase. Short‐term labeling with ¹⁴C‐bicarbonate found that between 30 and 60% of photoassimilates were released as colloidal carbohydrate, with EPS consisting of approximately 16% of this colloidal fraction. When cells were placed in darkness, EPS production increased, and between 85 and 99% of extracellular carbohydrate produced was polymeric. Glucan reserves were utilized in dark conditions, with significant negative correlations between EPS and glucan for N. perminuta and S. ovata. Under dark conditions, cells continued to produce EPS for up to 3 days, although release of low molecular weight carbohydrates rapidly ceased when cells were dark treated. Three aspects of EPS production have been identified during this investigation: (1) production during rapid growth, which differs in composition from (2) EPS directly produced as a result of photosynthetic overflow during growth limiting conditions and (3) EPS produced for up to 3 days in the dark using intracellular storage reserves (glucans). The ecological implications of these patterns of production and utilization are discussed.     

A flow-cytometric analysis of hybridoma growth and monoclonal antibody production

A flow cytometric kinetic study of hybidoma growth and monoclonal antibody production is presented, along with the influence of glutamine on intracellular responses such as (relative) cell size, and cell RNA and total protein content. Specific findings are: (1) RNA content remained constant throughout the growth phase, then fell drastically as the cells entered the stationary phase. Also, in stationary phase, RNA content of antibody-producing cells was higher than for those not secreting antibody. (2) The cell size was constant and maximal throughout exponential phase, and diminished monotonically during later stages. (3) Average protein and antibody cellular content declined dramatically upon glutamine exhaustion. Thus, relative RNA levels and cell size provided quantitative determinants of both cell growth state and antibody secretion conditions. These results encourge consideration of structured kinetic studies which recognize the quality of the biophase.     

Growth Phase and the Number of Phosphorylation Sites in the Mitochondrial Electron Transport Chain of Acanthamoeba castellanii

SYNOPSIS. Mitochondria isolated from the soil ameba Acanthamoeba castellanii growing exponentially on complex medium have rotenone-insensitive oxygen uptake and ADP:O ratios which indicate the presence of only 2 phosphorylation sites in the electron transport chain. Stationary phase amebae yield mitochondria which are sensitive to inhibition by rotenone when respiring NAD⁺-Minked substrates and have 3 sites of phosphorylation. The levels of cytochromes (a + a ₃), b , and c are similar in mitochondria isolated from log or stationary phase amebae, and, with the exception of succinate, the respiratory rates obtained with different substrates do not change significantly from log to stationary growth phase.     

Transformation in Naegleria gruberi: patterns of RNA synthesis examined by polyacrylamide gel electrophoresis

Naegleria gruberi were grown on bacteria and methods were devised to free the cellular RNA from bacterial RNA contamination. Use of actinomycin D and cycloheximide showed that the transformation of Naegleria from amoeba to flagellate required RNA synthesis for 30 min and protein synthesis for 40 min after the initial stimulus of distilled water. Comparison of the patterns of RNA synthesized during transformation with those during growth indicated a considerable amount of new RNA produced during the phenotypic change. Most marked was the increase in RNA co-migrating on polyacrylamide gels with the small ribosomal sub-unit RNA, together with RNAs between the latter and transfer RNA. These results were compared with other published results using axenically-grown cells cells and sucrose density gradient centrifugation. Cells placed in 80 mM NaCl instead of distilled water fail to transform but the pattern of newly-synthesized RNAs was not significantly different from that seen in transforming cells. This suggested that high salt concentrations inhibit transformation by inhibiting synthesis and/or assembly of certain proteins rather than RNA synthesis. Eluted material from various regions of polyacrylamide gels containing RNA extracted from transforming cells was used in a cell-free system. Incorporation of 3H-glutamic acid but not 3H-tryptophan was stimulated by material extracted from the 18S regions of the gels.     

Polyhydric alcohol production and intracellular amino acid pool in relation to halotolerance of the yeast Debaryomyces hansenii

Changes in polyol production and the intracellular amino acid pool were followed during the growth cycle of Debaryomyces hansenii in 4 mM and 2.7 M NaCl media. The intracellular levels of polyols were markedly enhanced by high salinity, the dominant solutes being glycerol in log phase cells and arabinitol in stationary phase cells. At low salinity arabinitol was the most prominent intracellular solute throughout the growth cycle. There were no major changes in the composition of the total amino acid pool with changes in cultural salinity. The amount of total free amino acids related to cell dry weight was 15–50% lower in cells cultured in 2.7 M NaCl as compared to 4 mM NaCl media.After subtraction of contributions from intracellular polyols the calculated cellular C/N ratio was found to be unaffected by cultural age and salinity during the late log and early stationary phase. On prolonged incubation of stationary phase cells, this ratio decreased, particularly at high salinity. The sensitivity of cells towards exposure to high salinity was measured in terms of the length of the lag phase after transference to 2.7 M NaCl media. This lag phase decreased with increasing intracellular polyol concentrations. At a given polyol content, stationary phase cells were considerably less sensitive than were log phase cells.When cultured at high salinity the mutant strain, 26-2b, grew more slowly and retained less of the total polyol produced during the early growth stages than did the wildtype. Exogenously supplied mannitol, arabinitol, and glycerol stimulated the growth of the mutant in saline media. Erythritol was without effect.Abbreviations GLC gas-liquid chromatography - TCA trichloroacetic acid