Osmotic and Metabolic-Induced Changes in Light Scattering of Leishmania donovani as Measured by Flow Cytometry

Leishmania donovani promastigotes were collected from cultures in log and stationary phases of growth and resuspended in Hank's Balanced Salt Solution containing 1 mM sodium acetate. Changes in the forward and side scattering of the cells were measured by flow cytometry in response to acute changes in osmolality and to the addition of several different substrates. Forward and side scattering of cells from log phase cultures decreased when the osmolality was decreased by the addition of H₂O and increased when the osmolality was increased by the addition of NaCl. Cells from stationary phase cultures had about the same forward scatter as cells from log phase cultures, but almost a four-fold lower side scatter, and their side scatter values did not change significantly in response to a reduction in osmolality. Microscopic observation showed that both log and stationary cells got longer and thinner, on average, in response to hyperosmolality. The light scattering properties of log (but not of stationary) cells changed in a reproducible manner when substrates were added to the buffer. The ratio of forward to side scatter increased in the following order: controls in balanced salt solution >aspartate >glutamate, glucose or 2-deoxyglucose >alanine >proline. Thus the light scattering properties of L. donovani promastigotes change with culture age, in response to changes in osmolality, and, in log phase cells, in response to the presence of several substrates.     

HearNPV在生长对数期与平台期宿主细胞中的复制差异分析

使用实时荧光定量PCR技术对HearNPV在生长对数期和平台期HzAM1细胞的复制差异进行分析。结果表明,HzAM1细胞生长对数期的倍增时间为22 h,生长对数期的细胞以S期细胞为主(48.6%),而平台期细胞中以G2/M期细胞为主(72.6%)。在这两种不同状态的细胞中,病毒的复制主要在感染后60 h内完成,在感染后14~20 h,病毒复制倍增时间分别为1.8 h和1.9 h,几乎没有差别。但是感染生长对数期细胞时,吸附侵入细胞内的BV数量、BV释放的数量、最终的病毒产量以及病毒表达的蛋白产量明显高于被病毒感染的生长平台期细胞。如生长对数期细胞内复制合成的病毒DNA总量的25%装配形成BV病毒粒子出芽释放到细胞外,而对于平台期细胞,病毒DNA仅有13%装配形成BV病毒粒子出芽释放到细胞外。病毒感染两种生长状态的细胞,病毒DNA均从感染后7~8 h开始复制,没有明显差别;而生长对数期细胞从被感染后18~20 h释放子代病毒BV,生长平台期细胞则在感染后22~25 h开始释放病毒BV。在感染后30~60 h,在生长对数期被感染的细胞释放BV的速度约为483 copies/cell/h,而平台期细胞约为100 copies/cell/h。最初吸附侵入到生长对数期细胞内的BV粒子数量明显多于侵入到生长平台期细胞内的BV数量。实验证实,生长对数期与平台期的细胞膜的流动性有很大差别,推测健康细胞表面有活性的病毒受体数量可能决定了侵入细胞内的BV的数量。     

Effects of cell surface damage on surface properties and adhesion of Pseudomonas aeruginosa

Bacterial cell surfaces play a crucial role in their adhesion to surfaces. In the present study, physico-chemical cell surface properties of Pseudomonas aeruginosa, isolated from a case of contact lens associated keratitis, are determined for mid-exponential and early stationary phase cells and for cells after exposure to a lens care solution or after mechanical damage by sonication. Exposure to a lens care solution and mechanical cell surface damage reduced the cell surface hydrophobicity and water contact angles decreased from 129 degrees to 96 degrees and 83 degrees, respectively. Zeta potentials in saline (-9 mV) were hardly affected after mechanical damage, but tri-modal zeta potential distributions, with subpopulation zeta potentials at -11, -28 and -41 mV, were observed after exposure of bacteria to a lens care solution. X-ray photoelectron spectroscopy indicated changes in the amounts of oxygen-, nitrogen- and phosphorus-rich cell surface components. Mid-exponential phase cells had more nitrogen-rich cell surface components than early stationary phase cells, but water contact angles and zeta potentials were not very different. In addition, mid-exponential phase cells adhered better than early stationary phase cells to hydrophobic and hydrophilic substrata in a parallel plate flow chamber. The capacity of P. aeruginosa to adhere was decreased after inflicting cell surface damage. Exposure to a lens care solution yielded a larger reduction in adhesion capacity than sonication, likely because sonication left most of the cells in a viable state, in contrast to exposure to a lens care solution. It is argued that for clinically relevant experiments, it may be preferable to work with surface damaged cells rather than with gently harvested organisms.     

Senescence of cultured human fibroblasts: mitotic versus metabolic time

To explore the relative importance of mitotic versus non-mitotic (metabolic) factors in determining the finite lifespan of human fibroblasts, mass cultures and 5 clones from 2 normal adults were followed as cohort pairs monitoring calendar time, mean population doublings (MPD), plating efficiency and expression of HL-A antigens. One member of each pair was split serially while the other was held in relative stationary phase with weekly refeeding using standard medium and culture conditions throughout. First cohorts became senescent after 52–62 MPD and 105–170 days while plating efficiencies declined and some HL-A antigens lost reactivity with specific antisera. At this time second cohorts were released from stationary phase and split serially. After initial loss of viability they generally showed higher plating efficiencies and normal reactivity of HL-A antigens till cell death within a calendar time of 195–240 days. The total MPD were reduced only marginally if allowance was made for low grade mitosis occurring during prolonged stationary phase. The results indicate that continuously replicating cells lose viability significantly before mitotically inhibited but actively metabolizing cohorts and suggest that factors which increase cellular turnover accelerate senescence and its pathological sequelae.     

CELL CYCLE COMPARTMENT ANALYSIS OF CHINESE HAMSTER CELLS IN STATIONARY PHASE CULTURES

The distribution of Chinese hamster cells with respect to the compartments of the cell generation cycle was studied in cultures in the stationary phase of growth in two different media. A measure of the state of depletion of the nutrient medium was formulated by defining a quantity termed the nutritive capacity of the medium. This quantity was used to verify that the cessation of cell proliferation is due to nutrient deficiencies and not to density dependent growth inhibition. Cell cultures in stationary phase were diluted into fresh medium and as growth resumed, mitotic index, cumulative mitotic index, label index and viability were measured as a function of time. The distribution of cells with respect to compartments of the cell generation cycle in stationary phase populations was reconstructed from these data. Stationary phase populations of Chinese hamster cells that retained the capacity for renewed growth when diluted into fresh medium were found to be arrested in the G₁ and G₂ portions of the cycle; the relative proportion of these cells in G₁ increased with time in the stationary phase, but the sequence differs in the two media. In early stationary phase, in the less rich medium, more cells are in G₂ than in G₁. Also in this medium a fraction of the population was observed to be synthesizing DNA during stationary phase, but this fraction was not stimulated to renewed growth by dilution into fresh medium.     

Transformation in Tetrahymena pyriformis: description of an inducible phenotype.

Transformation of Tetrahymena pyriformis to a rapid-swimming (presumably dispersal) form can be induced by washing cells and suspending them in distilled H2O, Dryl's solution or 10 mM Tris. Transformation is possible with high efficiency in mass cultures of axenically grown cells within approximately 5 h at 30 C. The radically different phenotype produced during transformation is characterized by a more elongate body form, increased numbers of somatic basal bodies and cilia, a long caudal cilium and oral membranelles positioned beneath the cell surface. DNA quantities characteristic of G1, S, and G2 cells are found in these transformed ciliates, suggesting that achievement of a particular stage in the DNA-division cycle is not a prerequisite for transformation. Preliminary observations on cells belonging to syngens 2-12 indicate that they also have a capacity to form a caudal cilium, but that the amicronucleate strain GL-C does not. Possible relevance of the transformed phenotype for taxonomy of Tetrahymena is discussed.     

Surface electrokinetic properties of two strains of Staphylococcus aureus during their cell growth cycle

Two strains of Staphylococcus aureus were investigated: S. aureus H, a normal wild-type strain, and 52A5, a mutant strain whose cell wall contains no teichoic acid but is made up entirely of mucopeptide. S. aureus H cells in the lag or stationary phase of growth had an electrophoretic mobility of ?1.10 μm/s/V/cm while those in the logarithmic phase had a mobility of ?0.80 μm/s/V/cm in saline at pH 7.2, 0.6 mM NaHCO₃, 25°C (I = 0.145 g-ions/l). S. aureus 52A5 cells in the same solution had a mobility of ?0.87 μm/s/V/cm in lag and stationary growth phases but a mobility of ?1.30 μm/s/V/cm in the logarithmic growth phase. The S. aureus H cell surfaces at lag phase had pKs of 3.2 and 9.5; at logarithmic phase, 4.2 and 9.0; and at stationary phase, 3.0 and 9.5. The 52A5 cell surfaces at lag phase had pKs of 2.3 and 10.3; at logarithmic phase, 1.7 and 8.5; at stationary phase, 2.6 and 10.2.     

Physiological and morphological characteristics of stationary phase vibrio cells able to support phase growth

Growth of phase alpha 3a on stationary phase Vibrio cultures requires micro-aerophilic conditions and is inhibited by aeration. Since pre-conditioning of the bacteria by allowing them to stand for 24 h after shaking for 3 d is an important aspect of the stationary phase phage growth system, various physiological and morphological characteristics of the stationary phase cells during the transition from shaking to standing were investigated. Shaken stationary phase cells were less viable and more sensitive to ultraviolet irradiation and heat than standing stationary phase cells. During pre-conditioning the small, non-flagellated cells present in shaken stationary phase cultures underwent morphological changes and became large, flagellated rods which resembled exponential phase cells. The transition of stationary phase cells from shaking to standing was associated with a marked increase in total RNA synthesis but a rapid and large decrease in total protein synthesis. Intracellular concentrations of ATP in shaken stationary phase cells were 53% lower than those in standing stationary phase cells. Studies on leucine uptake indicated that its transport was inhibited by isoleucine and that the major part (90%) of the total leucine uptake was due to a shared system for uptake of both amino acids. Shaken stationary phase cells transported less leucine than standing stationary phase cells. Inhibition of phage growth in aerated stationary phase cultures was not due to the prevention of phase absorption by shaking. It is suggested that the observed differences between shaken and standing stationary phase cells could be due to aeration affecting the template specificity of the Vibrio RNA polymerase.     

Synthesis and characteristics of the human serum albumin-triazine chiral stationary phase

Human serum albumin (HSA) was successfully bonded to silica with s-triazine as activator. The coupling reaction by this method was rapid and effective. The triazine-activated silica is relatively stable and can be installed for at least 1 month without obvious loss of reactivity when stored below 30 degrees C, pH below 7. It was observed that the amount of bound HSA reached 120 mg/g silica calculated from the UV absorbance difference of the HSA solution. d, l-tryptophan was selected as the probe solute to characterize the properties of HSA bonded s-triazine chiral stationary phase, and separation factor of 9.4 was obtained for d,l-tryptophan. Furthermore, the amount of effective HSA on silica was measured by high-performance frontal analysis, and only 16.8 mg/g silica was responsible for the resolution of d,l-tryptophan. These results indicate that the amount of both the bound and effective HSA on silica with triazine as activator was much higher than those by the Schiff base coupling method. Different kinds of enantiomers were resolved successfully on the aminopropylsilica-bonded HSA s-triazine chiral stationary phase.     

A peptidoglycan hydrolase similar to bacteriophage endolysins acts as an autolysin in Neisseria gonorrhoeae

We have identified a gene encoding an autolysin (atlA) from Neisseria gonorrhoeae . The deduced amino acid sequence of AtlA shows significant similarity to the peptidoglycan degrading transglycosylases (endolysins) of bacteriophages lambda and P2, suggesting that the encoded protein also functions in peptidoglycan hydrolysis. An atlA mutant was identical to the wild-type strain in exponential growth rate, but demonstrated reduced lysis and peptidoglycan turnover in the stationary phase of growth. When transferred into a buffer solution, at a pH non-permissive for other gonococcal autolysins, an autolytic activity was detectable in the wild-type strain that was not present in the mutant. The most dramatic phenotype of the mutant occurred after extended time in stationary phase. After approximately 16 h in stationary phase, both strains underwent an apparent replication event, after which the wild-type strain died rapidly whereas the atlA mutant survived considerably longer. Even after both the wild-type and mutant cells were dead, many of the mutant cells maintained intact morphology, whereas the wild-type cells were lysed. These results suggest that AtlA is a peptidoglycan transglycosylase related to bacteriophage endolysins and acts as an autolysin in the stationary phase.     

Protein turnover in exponential and stationary phase Vibrio cells

Vibrio strain 14 supports phage alpha 3a growth in standing stationary phase cells but not in shaking (aerated) stationary phase cells. In exponential cells, protein was turned over at 1.8% h-1, and the rate was increased by starvation or inhibition of protein synthesis. In shaking stationary phase cells the rate of protein turnover was low (1.0% h-1) for proteins synthesised during growth but high (20% h-1) for recently synthesised proteins. In contrast recently synthesised proteins in standing stationary phase cells were stable over 60 min and proteins synthesised during growth were turned over at 2.9% h-1. ppGpp and pppGpp were detected in exponential cells, but were not detected in stationary phase cells.     

Changes in Membrane Fatty Acid Composition and Δ12-Desaturase Activity during Growth of Acanthamoeba castellanii in Batch Culture

ABSTRACT. Growth of Acanthamoeba castellanii in batch culture at 30° C was associated with marked changes in cellular fatty acid composition. The largest change occurred in the linoleate to oleate ratio, which was maximal in early- to mid-exponential phase cultures but decreased approximately 10-fold as cells approached stationary phase. The higher degree of lipid unsaturation in young cultures was accentuated by a greater proportion of 20-carbon polyunsaturated fatty acids than in stationary phase cultures. The unsaturation index (average number of double bonds per fatty acid) was maximal in mid-exponential phase cultures after 24 hours growth. Incorporation of [1-¹⁴C]acetate into polyunsaturated fatty acids in short-term (2 hour) experiments was high in 12 and 24 hour old cultures, where linoleate and eicosadienoate accounted for up to 26% of total labelled fatty acids. Incorporation of [1-¹⁴CJacetate into these fatty acids was negligible in stationary phase cultures. These results were correlated with changes in the specific activity of the Δ12-desaturase. Δ12-Desaturase activity was greatest in microsomal membranes isolated from early- to mid-exponential phase cells, but declined by approximately 50% as cultures progressed towards stationary phase. Membrane fractionation studies revealed that although some differences in fatty acid composition between plasma-membrane, mitochondrial (enriched), and microsomal membrane fractions were evident, the large changes in lipid unsaturation in whole cells of A. castellanii could not be accounted for by differential development of particular subcellular membranes.     

Melanin content and hydroperoxide metabolism in human melanoma cells

Human melanoma cells were grown to exponential and stationary phases showing melanin contents of 4.2 +/- 0.3 and 11.3 +/- 0.6 micrograms/10(6) cells, respectively. The cells were separated in four subpopulations by a Percoll gradient; the subpopulation of density 1.07 (g/ml) was the most enriched in pigmented cells and produced 28 and 58% of the cells in exponential and stationary phases, respectively. Melanoma cells had similar superoxide dismutase and glutathione peroxidase activities in exponential and stationary phases. Moreover melanoma cells exhibited a higher catalase activity in the stationary phase: whole homogenate and cytosol activities were 7.0 +/- 0.3 and 10.8 +/- 0.6 U/mg protein, whereas in exponential phase the activities were 4.9 +/- 0.1 and 7.6 +/- 0.3 U/mg protein for whole homogenate and cytosol, respectively. The intracellular H2O2 steady-state concentration was 3.3 +/- 0.2 and 2.1 +/- 0.2 microM H2O2 for exponential and stationary phases, respectively. The spontaneous chemiluminescence of the two culture phases was 169 +/- 27 cps/10(6) cells (exponential) and 78 +/- 24 cps/10(6) cells (stationary). The cytotoxicity of H2O2 generated extracellularly by glucose oxidase was determined after 60 min of exposure. IC50 values for exponential and stationary cell cultures were 0.9 and 2.4 mU/ml of glucose oxidase, respectively. The increased catalase activities in the stationary phase as compared with the exponential phase are consistent with the decreased intracellular H2O2, with the decreased spontaneous chemiluminescence, and with the increased resistance to exogenous H2O2.     

Rate and extent of interconversion of tetrahydrofolate cofactors to dihydrofolate after cessation of dihydrofolate reductase activity in stationary versus log phase L1210 leukemia cells.

Previous studies from this laboratory established that the rapid but partial interconversion of tetrahydrofolate cofactors to dihydrofolate after exposure of L1210 leukemia cells to antifolates cannot be due to direct feedback inhibition of thymidylate synthase by dihydrofolate or any other endogenous folylpolyglutamates when dihydrofolate reductase activity is abolished by antifolates. Rather, the data suggested this preservation of tetrahydrofolate cofactor pools is likely due to a fraction of cellular folates unavailable for oxidation to dihydrofolate. This paper explores the role of cell cycle phase in L1210 leukemia cells in logarithmic versus stationary phase growth as a factor in the rate and extent of tetrahydrofolate cofactor interconversion to dihydrofolate after exposure of cells to the dihydrofolate reductase inhibitor trimetrexate. The S phase fraction was reduced by inoculating L1210 leukemia cells at high density to achieve a stationary state. Flow cytometric analysis of DNA content indicated that log phase cultures were 53.0% S phase; this decreased to 42.1% at 24 h and 24.1% at 48 h in stationary phase cultures. 5-Bromo-2'-deoxyuridine incorporation into DNA decreased 80 and 96%, while [3H]dUrd incorporation into DNA declined 70 and 95% for stationary cultures at 24 and 48 h, respectively, as compared with the log phase rates. Log phase cells interconverted 28.0% of the total pool of radiolabeled folates to dihydrofolate with a half-time of approximately 30 s. Stationary cells at 24 h interconverted 20.4% of the total folate pool with a t1/2 of approximately 3 min, and at 48 h, net interconversion to dihydrofolate decreased further to 12.1% with a t1/2 of approximately 6 min. The decrease in the extent of tetrahydrofolate cofactor interconversion to dihydrofolate in stationary phase cells was directly proportional to the decrease in the S phase fraction determined by total DNA content. This suggests that tetrahydrofolate cofactor depletion occurs only in S phase cells. The much larger drop in [3H]dUrd and 5-bromo-2'-deoxyuridine incorporation into DNA in comparison with the decline in the S phase fraction measured by DNA content along with the reduced rate of tetrahydrofolate cofactor interconversion to dihydrofolate indicates that the rate of DNA synthesis is decreased in S phase cells in stationary cultures. Network thermodynamic simulations suggest that a reduction in the number of S phase cells and their thymidylate synthase catalytic activity would account for the observed decrease in the rate and extent of interconversion of tetrahydrofolate cofactors to dihydrofolate after trimetrexate in stationary phase cultures.(ABSTRACT TRUNCATED AT 400 WORDS)     

A soluble acyl-coenzyme A oxidase from the yeast Candida utilis.

trans-2-Enoyl-CoA and two unidentified polar compounds were synthesized from the corresponding long-chain acyl-CoA by a particle-free supernatant fraction obtained from Candida utilis. The enzyme was unreactive toward free fatty acids but desaturated all long-chain acyl CoAs tested (14:0, 16:0, 18:1, 18:2). Molecular oxygen was the only required cofactor. Phenazine methosulfate and 2,6-dichloroindophenol did not replace the requirement for oxygen. The activity was inhibited specifically by NADPH and stimulated by linoleic acid or linolenic acid. The enzyme was not active in log phase cultures, but was detected only in stationary phase cells. Introduction of the trans-2-double bond was confirmed by gas-liquid chromatography, thin-layer chromatography, mass spectrometry, catalytic hydrogenation, oxidative cleavage, and chemical reactivity of the product toward nucleophilic addition.     

The destruction of Salmonella typhimurium in chicken exudate by different freeze-thaw treatments

Antibacterial treatments for frozen poultry, including holding at -5 degrees C and slow thawing at 4 degrees C to which exponential phase cells of Salmonella typhimurium were susceptible, were found to be relatively ineffective against stationary phase cells. Exposure of the latter, however, to a pre-freezing triple stress treatment of cold-shock exposure at 5 degrees C to a solution containing 5 mg/l of free available chlorine in 1% succinic acid (pH 2.5) for 20 min substantially lowered the resistance of the cells to subsequent freezing, storage and thawing in poultry flesh exudate. Cell survival was further decreased by storage of exudate at -18 degrees C for 28 d and this reduced the proportion of stationary phase cells to less than 1% of initial numbers, with a concomitant increase in sensitivity to deoxycholate. Such a combined pre-treatment may have practical potential for salmonella decontamination in the production of frozen poultry.     

Damaging effect of 3H-uridine on tissue culture cells during the logarithmic and stationary phases of growth]

The Chinese hamster fibroblasts entered the stationary phase of growth after 5.5 days of cultivation. The induction of the culture proliferation occurred within the first 4 hrs of cultivation in the fresh nutrient medium. After addition of 3H-uridine in high concentration and with high specific activity (75 micron Cu/M and 23 Cu/mM), in the stationary phase a lesser number of cells with aberrations and a higher mitotic index were noted than in the logarithmic phase. 3H-uridine injured the cells in the stationary phase of growth but to a lesser extent than those in the logarithmic phase, i. e. during the intensive RNA synthesis in cells.     

The bactericidal activity of a methyl and propyl parabens combination: isothermal and non-isothermal studies.

The effect of temperature on the kill rate of Escherichia coli by methyl and propyl parabens was studied. The kill kinetics was first order. It was shown that the Arrhenius equation provided a good model for describing the relationship between the first order rate constant and the temperature. The activation energy was found to be 274 kJ/mol for exponential phase cells and 168 kJ/mol for stationary phase cells. Exponential phase cells were much more susceptible to the lethal effects of the parabens than were the stationary phase cells. For example, at 34 degrees C stationary phase cells, in chemically defined media, had a kill rate constant of 0.072/h while the corresponding value for exponential phase cells was 0.238/h. In water the rate of kill for exponential phase cells was even faster giving a rate constant of 5.25/h at 34 degrees C. Non-isothermal kinetic testing was not found to be useful for modelling bacterial kill kinetics because we could not achieve the precision required in bacterial enumeration.     

Radiation resistance of Deinococcus radiodurans R1 with respect to growth phase

Deinococcus species exhibit an extraordinary ability to withstand ionizing radiation (IR). Most of the studies on radiation resistance have been carried out with exponential phase cells. The studies on radiation resistance of Deinococcus radiodurans R1 with respect to different phases of growth showed that late stationary phase cells of D. radiodurans R1 were fourfold more sensitive to IR and heat as compared with exponential or early stationary phase cells. The increased sensitivity of D. radiodurans R1 to IR in the late stationary phase was not due to a decrease in the intracellular Mn/Fe ratio or an increase in the level of oxidative protein damage. The resistance to IR was restored when late stationary phase cells were incubated for 15 min in fresh medium before irradiation, indicating that replenishment of exhausted nutrients restored the metabolic capability of the cells to repair DNA damage. These observations suggest that stress tolerance mechanisms in D. radiodurans R1 differ from established paradigms.     

Two-dimensional gel electrophoretic profile of rat basophilic leukemia (RBL) and mast cells.

RBL cells are not differentiated, but resemble mucosal mast cells (MMC). Two-dimensional (2-D) gel electrophoresis following isoelectric focusing (IEF) was performed using purified rat peritoneal mast cells and RBL cells. Certain similarities were identified with silver staining between mast cells and stationary phase (72 hr) RBL cells. RBL cells were also labelled with [35S]-cysteine in order to study the specific expression of proteins during logarithmic or stationary growth phases. Only stationary phase RBL cells appeared to specifically express three proteins of 42, 55 and 93 kD and were still capable of secreting histamine in response to immunoglobulin E (IgE) and specific antigen. These results suggest that specific RBL cell proteins may be used as markers for further analysis of their maturation/differentiation.