The influence of culture temperature on in vitro maturation of bovine oocytes

Bovine oocytes removed from 2–6-mm follicles were matured in vitro for 20 h at 33, 35, 37, 38 and 39°C. Evaluation criteria of oocyte maturity included nuclear maturation and the fluorescein diacetate (FDA) viability test. The percentage of oocytes in metaphase II increased from 2.8% at 33°C to 56.1% at 35°C and approximately 73% at 37–39°C.All control ova (i.e. matured in vivo and collected just after ovulation) evaluated using the FDA test showed very bright and uniform fluorescence within cells. The highest accumulation of intracellular fluorescein in cultured oocytes was observed at 35°C; fluorescein accumulation decreased proportionally to increased culture temperatures.     

Redistribution and recycling of internalized membrane in seminal vesicle secretory cells

This study was performed to clarify the fate of membrane constituents internalized from the apical domain in secretory cells, in particular their possible recycling and the compartments involved in it. Glycoproteins of the apical membrane of seminal vesicle secretory cells from guinea-pig were covalently labeled in vitro (0°C, 20 min) with ³H-galactose and the epithelium incubated for 15 min (37°C, first incubation) to allow endocytosis. The label which was not internalized was then exposed to enzymatic hydrolysis (0°C, 30 min) and the epithelium re-incubated to allow membrane movement for 15 and 30 min (37°C, 2nd incubation). After each step of the protocol, tissue pieces were fixed and processed for electron microscope autoradiography and the results studied by morphometric analysis. Following labeling, 99% of the silver grains were associated with the apical domain of the cell membrane (AD). After the 1st incubation at 37°C, 30° of the grains were inside the cells in association with the cytoplasmic vesicles (Cyt ves), secretory vacuoles (SV), Golgi vesicles (GV), Golgi cisternae (GC), multivesicular bodies (MVB), lysosomes (LYS), and the cell membrane basolateral domain (BLD). About 58% of non-internalized radioactivity was removed by hydrolysis. During the 2nd incubation at 37°C the concentration of label increased in BLD and LYS, decreased in SV and MVB, and fluctuated in GC, GV and AD. The distribution of grains observed at 15 min, as compared using the χ-square test, was highly significantly different from that expected without recycling. The results show that cell membrane glycoproteins internalized at the cell apex recycle back to the membrane apical domain and are consistent with the involvement of GC and SV in the recycling pathway. Membrane shuttle between the apical and basolateral domains of the cell membrane is also suggested by these observations.     

Effects of cytochalasin D on fusion of cells by HVJ (Sendai virus).

Fusion of cells mediated by HVJ was inhibited completely with 5 μg/ml or more of cytochalasin D (CD). With cytochalasin, HVJ-cell interaction at 0 °C proceeded as well as without cytochalasin; HVJ was adsorbed to cell surfaces and the cells agglutinated together. Then the virus particles were enfolded with cell membranes, which resulted in the disappearance of hemadsorption activity on the cell surfaces. When the cell-virus complex was incubated at 37 °C, the early reactions proceeded as well as without cytochalasin; the hemadsorption activity reappeared on the cell surfaces, the viral envelopes fused with cell membranes at the same degree as without cytochalasin, and a stage sensitive to sodium azide appeared as in a control without cytochalasin. But cell-to-cell fusion did not occur in the presence of cytochalasin; cells were dissociated freely from the cell aggregates during incubation. This indicates that cell-to-cell fusion was inhibited but HVJ envelope to cell membrane interactions proceeded well on incubation at 37 °C. These findings suggest that viral envelope-cell membrane fusion and cell-cell fusion are separable, and participation of a cytoskeleton system including microfilaments in the cells is essential for cell-cell fusion.     

Cell-mediated mineralization in culture at low temperature associated with subtle thermogenic response

In both the growth plate and in marrow stromal cell cultures cell-mediated mineralization is preceded by characteristics of anaerobic and low efficiency energy metabolism. Reagents that increase mineralization like malonate and dexamethasone (DEX) also increase the mitochondrial membrane potential (MtMP) especially 1 week after DEX stimulation. Contrarily, levamisole, which decreases mineralization, also decreases MtMP. Modulation of MtMP and energy metabolism could be linked to regulation of mineralization by the uncoupling of oxidative phosphorylation. This uncoupling should be associated with thermogenesis in cells that induce mineralization. We examined whether cold temperature affects mineralization, and whether cellular thermogenesis takes place at cold temperature in parallel to changes in MtMP. Osteoprogenitor cells (OPC) induced, in DEX stimulated rat marrow stroma, higher mineralization at 33°C than at 37°C. Increased mineralization by cold temperature required long incubation since incubation in the cold during short intervals, 3–4 days, did not increase mineralization relative to (37°C) controls. Marrow stromal cells in the presence of valinomycin responded to incubation at 33°C by retaining all the vital dye after 4 h, unlike the cells at 37°C; however, after 24 h the level of dye retention at 33°C was the same as at 37°C. The delayed response of the temperature-dependent (> 37°C) K⁺ ionophor to incubation in the cold indicated that certain cells may respond to low temperature by local intracellular heating, and by heat conduction to the plasma membrane. DEX-stimulated stromal cells, unlike unstimulated cells, showed increased mitochondrial rhodamine 123 retention in the presence of valinomycin after 24 h in the cold, which corresponds to day 4 of OPC induction. This is consistent with the concept that valinomycin-induced cell damage is mediated by (cold-induced) local heating. The mechanism of this cell damage should selectively prefer non-thermogenic (rhodamine retaining) over thermogenic (rhodamine leaking) cells such as OPC. At cold temperature DEX-stimulated stromal cells showed the best anti-OPC selection under exposure to valinomycine between days 3–7, concurrent with the period of rhodamine leakage from the mitochondria. These results indicate that thermogenesis is enhanced during the period of low MtMP in mineralizing cells, and prolonged exposure to cold increases mineralization also due to induction of subtle thermogenesis. © 1996 Wiley-Liss, Inc.     

Subcellular action of Neocarzinostatin. Intracellular incorporation, DNA breakdown and cytotoxicity

The subcellular site of action of a proteinaceous antitumor antibiotic neocarzinostatin (NCS) was studied using normal human lymphocytes, Epstein-Barr virus transformed lymphoblastoid cells, osmotically burst lymphoblastoid cells, and colicin E1 plasmid DNA. The rate of DNA strand break in these different types of DNA was found to be in the following order: Colicin DNA > burst cell DNA > lymphoblastoid cell DNA > normal lymphocyte DNA. Furthermore, fluorescence microscopy revealed that lymphoblastoid cells incorporated more fluorescein isothiocyanate labeled NCS than normal cells. High uptake of NCS in lymphoblastoid cells coincided with a high killing rate; low uptake of NCS in lymphocytes resulted in very little cell killing. Uptake velocity using fluorescein diacetate (FDA) also showed that the lymphoblastoid cells exhibited a higher uptake of FDA coinciding with a higher killing rate. The cell killing activity of NCS appears to be closely associated with the rate of intracellular uptake of NCS and subsequent direct degradation of DNA by the drug. This notion is reinforced by the reported finding that the dose required for DNA strand scission is only about 1/100 of that for the inhibition of cap formation. Thus DNA strand scission, rather than the cell membrane, appears to be the primary target of NCS. Enhanced incorporation of many substances is commonly observed upon transformation of cells by viruses, and our present results may provide an important clue toward the explanation of the selective toxicity toward tumor cells of NCS.     

Morphological changes in Ehrlich ascites tumor cells during the cell fusion reaction with HVJ (Sendai virus): II. Cluster formation of intramembrane particles in the early stage of cell fusion

The morphological events in the cell membrane of Ehrlich ascites tumor (EAT) cells associated with cell fusion caused by HVJ were investigated with freeze-fracture technique. When cell fusion was carried out at 37 °C, the EATC fusion was too rapid to allow identification of the sequential steps of membrane fusion and no deleterious changes in the plasma membrane could be detected. However, on lowering the incubation temperature from 37 to 28 °C, the process of cell fusion was slower and there was a distinct alteration in the plasma membrane. On incubation of cell aggregates with HVJ at 28 °C, the fusion reaction proceeded very slowly. On incubation for 10 min, fusion was initiated in a few cells, but most of the cells remained agglutinated with their cell membranes close to those of neighboring cells and often in direct contact in small localized regions. When cells in this stage were chilled and fixed at 4 °C, large clusters of intramembrane particles (IMPs) were seen all over the P face. On further incubation of the cells at 37 °C, cell fusion proceeded rapidly and the IMPs became randomly redistributed, indicating that clustering is a reversible phenomenon occurring in the early stage of cell fusion. This clustering was temperature-dependent. It was seen in cell fixations at 4 °C, but not at 28 °C without chilling, and it was prevented by inhibitors of cell fusion, such as cytochalasin D (CD) or glucose at high concentration. These findings suggest that certain structural changes in the plasma membrane that may induce thermotropic aggregation of IMP are required to initiate cell fusion.     

Inactivation of Escherichia coli and Lactobacillus plantarum in relation to membrane permeabilization due to rapid chilling followed by cold storage

The relationship between membrane permeabilization and loss of viability by chilling depending on the chilling rate was investigated in two bacterial models: one Gram-positive bacterium, Lactobacillus plantarum, and one Gram-negative bacterium, Escherichia coli. Cells were cold shocked slowly (2°C/min) or rapidly (2,000°C/min) from physiological temperature to 0°C and maintained at this temperature for up to 1 week. Loss of membrane integrity was assessed by the uptake of the fluorescent dye propidium iodide (PI). Cell death was found to be strongly dependent on the rate of temperature downshift to 0°C. Prolonged incubation of cells after the chilling emphasized the effect of treatment on the cells, as the amount of cell death increased with the length of exposure to low temperature, particularly when cells were rapidly chilled. More than 5 and 3-log reductions in cell population were obtained with L. plantarum and E. coli after the rapid cold shock followed by 7-day storage, respectively. A correlation between cell inactivation and membrane permeabilization was demonstrated with both bacterial strains. Thus, loss of membrane integrity due to the chilling treatments was directly involved in the inactivation of vegetative bacterial cells.     

Manifestations of cell damage after freezing and thawing

The nature of the primary lesions suffered by cells during freezing and thawing is unclear, although the plasma membrane is often considered the primary site for freezing injury. This study was designed to investigate the nature of damage immediately after thawing, by monitoring several functional tests of the cell and the plasma membrane. Hamster fibroblasts, human lymphocytes, and human granulocytes were subjected to a graded freeze-thaw stress in the absence of cryoprotective compound by cooling at -1 degree C/min to a temperature between -10 and -40 degrees C, and then were either warmed directly in water at 37 degrees C or cooled rapidly to -196 degrees C before rapid warming. Mitochondrial function in the cells was then assessed using 3-[4,5-dimethylthiazol-2-yl]-2,5-diphenyl-tetrazolium bromide (MTT), fluorescein diacetate (FDA), colony growth, and osmometric response in a hypertonic solution. Cells behaved as osmometers after cooling at -1 degree C/min to low temperatures at which there were no responses measured by other assays, indicating that the plasma membrane is not a primary site for injury sustained during slow cooling. These results also indicate that the FDA test does not measure membrane integrity, but reflects the permeability of the channels through which fluorescein leaves the cells. Fewer cells could respond osmotically after cooling under conditions where intracellular freezing was likely, implying that the plasma membrane is directly damaged by the conditions leading to intracellular freezing. A general model of freezing injury to nucleated mammalian cells is proposed in which disruption of the lysosomes constitutes the primary lesion in cells cooled under conditions where the cells are dehydrated at low temperatures.     

Lateral mobility of class I histocompatibility antigens in B lymphoblastoid cell membranes: modulation by cross-linking and effect of cell density

We have studied the lateral mobility of class 1 major histocompatibility complex (MHC) proteins in the membranes of human Epstein-Barr virus-transformed B cells using fluorescence photobleaching recovery. Class I MHC antigens were labeled with either W6/32 monoclonal antibody or its Fab fragment directly conjugated to fluorescein isothiocyanate. The diffusion coefficient of class I antigens labeled with Fab fragments of W6/32 was identical to that of a lipid analogue, fluorescein phosphatidylethanolamine, and was 10-fold greater than that of antigens labeled with intact W6/32. Furthermore, antigens labeled with Fab fragments but not with intact W6/32 had fractional mobilities identical to that of the lipid probe. The lateral mobility of class I antigens was dependent on the time of incubation with fluorescent antibody and on the presence of antibody microaggregates. Finally, class I MHC proteins labeled with intact W6/32 but not with Fab fragments were immobilized in the membranes of most cells grown in suspension at high cell density. These results suggest that, in the unperturbed state, class I MHC antigens diffuse as rapidly as membrane lipid, i.e., without cytoskeletal constraint. Cross-linking with bivalent ligand and growth to high cell density may trigger membrane events leading to slowing and immobilization of these proteins.     

Potential problems with fluorescein diacetate assays of cell viability when testing natural products for antimicrobial activity.

There are two potential problems in the use of fluorescein diacetate (FDA) as a measure of cell viability. The first is the hydrolysis of FDA to fluorescein in the absence of live cells and the second is the quenching of fluorescence by assay solutions. We show that common media components such as tryptone, peptone and yeast extract all promote hydrolysis of FDA in the absence of live cells, as do Tris-HCl and sodium phosphate buffers. As a consequence, various microbiological media promote hydrolysis of FDA in the absence of live cells. Different media were also shown to reduce the amount of visible fluorescence of fluorescein. Diluting the medium decreases the background hydrolysis of FDA as well as increases the amount of visible fluorescence. Both problems should be considered when using FDA as an indicator of cell viability when testing natural products for antimicrobial activity.     

Applicability of the fluorescein diacetate method of detecting active bacteria in freshwater

Fluorescein diacetate (FDA) hydrolysis was evaluated as a means to detect actively metabolizing bacteria in freshwater. Fluorescein diacetate, a nonfluorescent derivative of fluorescein, can be transported across cell membranes and deacetylated by nonspecific esterases. Resultant fluorescein accumulates within cells and allows direct visualization by epifluorescent microscopy. Application of FDA to a variety of freshwater habitats yielded estimates of active cells ranging from 6–24% of the total population. These estimates were 49–61% lower than estimates of active cells obtained from measures of electron transport activity. The difference was attributed to low permeability of the fluorogen through the outer membrane of heterotrophic gram-negative cells. Data suggest that FDA hydrolysis as a means of detecting active bacteria may be limited to environments rich in eucaryotes and gram-positive cells.     

Quantification of the nonspecific intercellular transfer of fluorescent molecules between labeled and unlabeled rat thymocytes

Fluorescein isothiocyanate has been used to label normal or tumor cells in order to study their migration in vivo. This requires that any transfer of fluorescence to neighbouring cells be carefully ruled out. The aim of the present report is to demonstrate the possibility of a transfer of fluorescein or fluorescein-bound molecules between untreated and labeled cells. When normal rat thymocytes were co-incubated with labeled cells (about 5 X 10(6) fluorescein molecules/cell) under continuous agitation or exposed to supernatants of these labeled cells, they bound an average of 10(4) fluorescein molecules. When the incubation was done on cell pellets after centrifugation, this transfer was increased tenfold. Hence, intercellular molecular exchange may occur in the absence of any specific interaction.     

Use of fluorescein diacetate for research on macrophage activation

Kinetic of changes in the fluorescence intensity of macrophages in a medium containing fluorescein diacetate (FDA) has been analysed. It is shown that under certain conditions the intensity of macrophages retains a constant level for rather a long time. The addition of stimulants such as lipopolysaccharide or tuftsin to the incubation medium leads to characteristic changes in the cell fluorescence level related to the increase in the activity of FDA intracellular hydrolyses and fluorescein efflux from macrophages. It is concluded that the kinetic of changes in the macrophages fluorescence intensity in a medium with FDA may serves as a test for detecting early functional changes upon macrophage activation.     

Study of the transverse diffusion of spin labelled phospholipids in biological membranes. I. Human red blood cells

Spin labeled analogs of phosphatidylcholine were used to study the transverse diffusion (flip-flop) of phospholipids in the erythrocyte membrane. The nitroxide spin label was placed either on the β acyl chain or on the choline group. These labeled phosphatidylcholine molecules were incorporated into the membrane by incubation of the red cells at 22°C with sonicated spin-labeled phosphatidylcholine vesicles from which all traces of free fatty acids and lyso derivatives were carefully removed by bovine serum albumin treatment. This incorporation did not provide any change in the morphology of the cell as indicated by scanning electron microscopy. When spin-labeled phosphatidylcholine, having a nitroxide on the β chain but near the polar head-group, was incorporated into the erythrocyte membrane, ascorbate treatment at 0dgC allows selective reduction of the signal coming from the outer layer of the membrane. When the label was on the polar head-group, the inner content of the erythrocyte rapidly reduced the label facing the cytoplasm, thus creating a spontaneous anisotropy of the labeling. The anisotropic distribution of spin-labeled phosphatidylcholine in the erythrocyte membrane was found to be stable at 22 and 37°C for more than 4 h. It is therefore concluded that the rate of outside-inside and inside-outside transition is so slow that the anisotropic distribution of the phospholipids in the erythrocyte membrane can be maintained during cell life.     

Modification of cell membranes with viral envelopes during fusion of cells with HVJ (Sendai virus).

A large number of viral materials are associated with the surface of cells after cell fusion with HVJ at 37 °C for 30 min. This is due to fusion of viral envelopes with the cell membrane. Studies were made on the process from viral adsorption to cell-cell, or cell-viral envelope fusion. On incubation at low temperatures, such as 0–15 °C, no envelope fusion or cell fusion was observed, although there was some interaction between the virus and cells. This interaction resulted in loss of hemadsorption (HA) activity of the cells and partial damage of the ion barrier of the cell membrane. The viral particles seem to come close to the lipid layer of the cell membrane at the low temperatures and to distort the non-flexible membrane structure. On incubation of the cell-virus complex at 37 °C, the cells rapidly became HA-positive and the HA activity was maximal within 5 min. At this stage there was much leakage of ions through the cell membrane. On further incubation the damage to the ion barrier of the cell membrane was repaired completely with completion of cell fusion. This process may be correlated with fusion of viral envelopes with cell membranes and restoration of the cell membrane fused with them.     

Indium-111 oxine labeled erythrocytes: Cellular distribution and efflux kinetics of the label

Indium-111 oxine labeled erythrocytes are useful in scintigraphic studies of splenic function because of the high yield of γ-photons [172(90%) and 247(94%) keV] of indium-111. However, the effects of indium-111 oxine on the structural and functional integrity of erythrocytes which might influence their reticulo-endothelial (RE) sequestration are unknown. We examined the morphology of human and rat indium-111 labeled erythrocytes by SEM, the distribution of the label within the cell by analysis of the membrane and cytosol (hemoglobin solution) and the kinetics of efflux of indium-111 from erythrocytes incubated at 37 °C in plasma or physiological buffer. Indium-111 oxine labeled red cells retain their discocytic morphology and the cell indices, and density characteristics on phthalate ester are similar to those of the control cells. The efficiency of labeling may be as high as 97%. Human or rat erythrocyte membranes retain 33 and 41% of indium-111, and the cytosol contains 67 and 59%, respectively. About 98% of the indium-111 is bound to the membrane proteins and 1% to the lipid bilayer. Efflux of indium-111 from cells in autologous plasma showed a multiphasic release resulting in about 4–5% release of the label in 2 h and 11.5% in 20 h. Cells in PBS showed 1–5% release of the label during the incubation period. These findings suggest that indium-111 oxine labeling of erythrocytes does not grossly alter the structural and deformability integrity of the cells to induce selective RE sequestration, unless the cells have been damaged prior to or during the labeling procedure, or the spleen is hyperactive.     

Technical aspects of the use of 3′,6′-diacetyl fluorescein for vital fluorescent staining of bacteria

Viable bacteria of several species have the capability to incorporate 3′,6′-diacetyl fluorescein (FDA) and rapidly hydrolyze it to fluorescein, which is stored intracellularly. However, several strains of viableEscherichia coli andAlcaligenes faecalis do not evolve and accumulate significant amounts of fluorescein when incubated on glass slides in the presence of FDA. In the present study, 10⁵–10⁷ E. coli orA. faecalis bacteria (viability more than 95%) were accumulated in separate experiments on 0.45-μm membrane filters and then stained for 5–10 min with FDA diluted immediately before use in phosphate-buffered saline, freshly prepared nutrient broth, or nutrient broth preconditioned by overnight growth of the respective bacteria. It was shown that in all cases about 20% of the bacteria did evolve significant amounts of fluorescein, thus enabling a visual observation of these cells in the fluorescence microscope.Bacillus cereus bacteria—that evolved and accumulated fluorescein on glass slides—were shown to be fluorescent on membrane filters after FDA staining. 100%, 40%, or 70% of the bacteria were stained if the FDA solution used had been prepared in nutrient broth preconditioned by overnight growth of the same bacteria, fresh nutrient broth, or phosphate-buffered saline, respectively. This preliminary study indicates the necessity of determining the technical conditions required for FDA staining for each bacterial species under study.     

The effects of cell membrane alteration on glucocorticoid uptake by the AtT-20/D-1 target cell

The glucocorticoid-sensitive AtT-20/D-1 cell line was used to study cellular uptake of glucocorticoids. A previous observation that glucocorticoid uptake by these cells was temperature dependent had prompted us to postulate that glucocorticoids entered the cell by a temperature-sensitive transport process located in the cell membrane. Attempts were then made to perturb the membrane mechanism. In some of these experiments, intact cells were treated with neuraminidase or pronase. The release of sialic acid in the case of neuraminidase treatmentand of sialic acid and cell surface peptides in the case of pronase treatment demonstrated that the enzymes were effective. Approx. 60% of total cellular sialic acid was released by a 15 min incubation with 20 μg/ml neuraminidase at 25°C. The treated cells appeared to be viable, in that they continued to produce corticotropin at a normal rate, yet intact cell glucocorticoid binding at both 4 and 25°C was only 20–30% of that of untreated cells. Treatment with pronase also caused steroid uptake at 4 and 25°C to be reduced, although the extent of reduction was less than that seen following neuraminidase treatment.In other experiments, the effect of exposure of AtT-20/D-1 cells to ethanol or dimethyl sulfoxide was determined. The solvent concentrations used (0.5–10%) did not alter cell viability significantly, and the ability of the cytosol receptor to bind steroid in a cell-free preparation was unimpaired. However, incubation of intact cells with 10% (v/v) dimethyl sulfoxide or ethanol resulted in an 80–90% decrease in steroid uptake at 25°C.We conclude that steroid uptake by the intact cell can be perturbed by treatments which do not affect the cytosol receptor or alter cell viability. These results support the postulate that glucocorticoids enter the AtT-20/D-1 cell by a specific membrane-associated mechanism.     

Fluorescein diacetate used as a vital stain for labeling living pollen tubes

Snapdragon and tobacco pollen treated with fluorescein diacetate (FDA, 10 μg/ml) for 40 min could germinate and grew well in FDA-free medium. The pollen tubes showed bright fluorescence of the protoplasm when they were living. Thus the FDA method can be used, in addition to its previous usage for viability test of cells, also for vital staining of pollen tubes, and may be valuable to the study of other living cells as well.     

Effect of cell purity,cell concentration,and incubation conditions on rat testis leydig cell steroidogenesis

Summary This study examines the effects of cell purity and incubation conditions on testosterone production by rat testis Leydig cells in short-term primary culture. Both basal and luteinizing hormone (LH)-stimulated testosterone production were affected by the purity of the cell preparation, i.e. as the purity of the cell preparation was increased the amount of testosterone produced per Leydig cell was also found to increase. The stimulation ratio of testosterone production, calculated as the secretion of testosterone in the presence of LH (100 ng/ml) divided by the basal secretion of testosterone, increased with the increase in plating density (20 000 to 200 000 cells per well). This pattern of change was independent of the vessel and volume of incubation. In terms of the absolute amount of testosterone produced, increasing the plating density led to a decrease in the amount of steroid produced both basally and in response to LH. Composition of the incubation medium also had an effect on testosterone production; phenol red and sodium bicarbonate exerted negative effects. At all temperatures studied (4°, 24°, 34°, and 37° C), LH increased testosterone production and the degree of stimulation increased with temperature. We conclude that cell purity and incubation conditions markedly affect rat Leydig cell steroidogenesis in vitro. Furthermore, the manner in which the results are presented can affect their interpretation.