Biosynthesis of plasma membrane components by SV40-virus-transformed 3T3 mouse cells temperature sensitive for expression of some transformed cell properties

We have studied the plasma membranes of an SV40-transformed 3T3 cell line temperature sensitive for the transformed growth phenotype (ts H6-15 cells), and have found that they vary little as a function of temperature of cultivation. Analysis by polyacrylamide gel electrophoresis was performed on plasma membranes prepared from ts H6-15 cell cultured at the permissive (32 °C) and non-permissive (39 °C) temperatures and radioactively-labelled in several ways. No significant differences were seen when the electrophoretic patterns of polypeptides of the plasma membranes of ts H6-15 cells, grown through 3–4 generations in medium containing radioactive leucine (32 °C and 39 °C temperatures) were compared. Plasma membranes derived from cells similarly grown in medium with radioactive glucosamine indicated that extensive alterations in the intrinsic glycopeptides occurred in association with alteration in growth phenotype. A shift towards decreased synthesis of large molecular weight (? 100 000–160 000) glycopeptides occurred in cells grown at the temperature of non-transformed growtn (39 °C). A decrease in amount of a 1200 000 molecular weight glycopeptide at 39 °C was the most prominent of these alterations.We have studied the surface exposure of polypeptides and glycopeptides of intact cells grown at 32 and 39 °C, using lactoperoxidase-catalyzed iodination, NaBH₄ reduction of galactose oxidase-treated cells, and metabolic-labelling with glucosamine of trypsin-sensitive molecules. We found no major qualitative differences between whole cell extracts or between plasma membrane preparations of cells cultivated at the permissive and non-permissive temperatures. Of special interest was the observation that the formation and surface exposure of a trypsin-sensitive, 240 000 molecular weight polypeptide appeared not to be ts in ts H6-15 cells. The significance of these observations will be discussed.     

Discontinuous thermotropic response of Tetrahymena membrane lipids correlated with specific lipid compositional changes

Steady-state fluorescence polarization measurements of 1,6-diphenyl-1,3,5-hexatriene in microsomal lipids from Tetrahymena pyriformis cells grown at 39 or 15°C revealed discrete slope discontinuities in plots of polarization vs. temperature. Two well-defined ‘break points’ were present in the 0–40°C temperature range examined and their precise location was dependent upon the growth temperature of the cells. By mixing phospholipids from cells grown at different temperatures, the break points at 17.5 and 32°C in 39°C-lipid multilayer preparations were shown to correlate with the breaks at 12 and 27°C, respectively, in similar preparations from 15°C-grown cells. The discrete break points were also present, but at slightly different characteristic temperatures, in a phosphatidylcholine fraction and a phosphatidylethanolamine plus 2-aminoethylphosphonolipid fraction purified from the phospholipids and in total microsomal lipids (phospholipids plus the sterol-like triterpenoid, tetrahymanol). However, catalytic hydrogenation of the phospholipid fatty acids or mixing the non-hydrogenated phospholipids with increasing proportions of synthetic dipalmitoyl phosphatidylcholine eliminated the break points. We interpret this discontinuous thermotropic response in microsomal lipids as signalling a lipid phase separation of importance in regulating physiological events.     

Regulation of passive membrane permeability for potassium ions by cell density of 3T3 and SV40-3T3 cells.

The passive K⁺ permeability of 3T3 and SV40-3T3 cells was evaluated from experiments on passive K⁺ efflux and electrical transmembrane potential measurements at different cell growth densities, external calcium concentrations and temperatures. Passive K⁺ permeability was shown to decrease markedly with increasing cell growth density, to increase with the lowering of external calcium concentration, and at low cell densities to be higher at low temperature (25 °C) than at physiological temperature (37 °C). These and further results taken from the literature are fully consistent with the notion of regulation of proliferation being effected by control of intracellular K⁺ concentrations. The phenomenon of high temperature inactivation of passive K⁺ permeabilities observed at low cell densities is discussed in analogy to recent results on model systems from phospholipid/cholesterol doted with channel-forming antibiotics.     

Cell-substrate separation: effect of applied force and temperature

We measure the change in cell-substrate separation in response to an upward force by combining two relatively new techniques, Electric Cell-substrate Impedance Sensing (ECIS) to measure average cell-substrate separation, and collagen-coated magnetic beads to apply force to the top (dorsal) surface of cells. The collagen-coated ferric oxide beads attach to integrin receptors in the dorsal surfaces of osteoblastlike ROS 17/2.8 cells. Magnetic force is controlled by the position and the number of permanent magnets, applying an average 320 or 560 pN per cell. Comparing model calculations with experimental impedance data, the junctional resistivity of the cell layer and the average distance between the lower (ventral) cell surface and substrate can be determined. The ECIS analysis shows that these forces produce an increase in the distance between the ventral cell surface and the substrate that is in the range of 10 to 25%. At temperatures of 4°, 22° and 37 °C, the measured cell surface-substrate distances without magnetic beads are 84 ± 4, 45 ± 2 and 38 ± 2 nm. The force-induced changes at 22° are 11 ± 3 and 21 ± 3 nm for 320 and 560 pN, and at 37° they are 5 ± 2 and 9 ± 2 nm. The resulting cell-substrate spring constants at 22° and 37° are thus about 28 and 63 pN nm^–1 (dyne cm^–1). Using a reasonable range for the number for individual integrin-ligand adhesion bonds gives a range for the spring constant of the individual adhesion bond of from about 10^–3 to 10^–1 pN nm^–1. These data also provide evidence that the number of adhesion bonds per cell increases with temperature. Received: 20 June 1997 / Accepted: 24 August 1997     

A novel cell modification method used in biotransformation of glycerol to 3-HPA by Lactobacillus reuteri

The aim of the present study was to develop a new cell modification method to facilitate the cell separation from broth. In order to reduce the transfer limitation of substrate and product caused by general immobilization methods in the following biotransformation of glycerol, the carboxyl-functioned superparamagnetic nanoparticle (MNP) was directly attached to the surface of Lactobacillus reuteri for 3-hydroxypropionealdehyde producing. The modification process could be finished in several minutes by just adding MNP fluid into the bulk fermentation broth. The modified cells could be rapidly separated from the solution with the aid of magnetic field. The interaction between cell and MNP was shown by electron microscopy. The efficiency of the cells attached by MNPs for transformation of various concentrations of glycerol (100–400 mM) was studied at various temperatures (25–40 °C) and pH levels (5.8–7.5) with different cell concentrations (7.5–30 g/L). The 3- hydroxypropionealdehyde (HPA)/glycerol molar conversion under optimal condition (30 °C and pH 7) reached 70 %. The inactive modified cell could be reactivated easily by fresh medium and recovered the ability of glycerol conversion. MNPS distributing on cell surface had little adverse effect on cell activity. The modification method simplified the two-step production of 3-HPA by resting L. reuteri. The method of MNPs attached to cell surface is totally different from the traditional immobilization method in which the cell is attached to or entrapped in big carrier. The results obtained in this study showed that carboxyl-functioned MNP could be directly used as cell modification particle and realized cell recycle with the aid of magnetic field in bioprocess.     

The relationships between growth temperature,fatty acid composition and the physical state and fluidity of membrane lipids in Yersinia enterocolitica

The relationship between membrane lipid composition and membrane lipid phase transitions was investigated in Yersinia enterocolitica cells grown at 5, 22 and 37°C. The total phospholipid concentrations were 9.4, 7.3 and 6.3% of the cell dry weight for cells grown at 5, 22 and 37°C, respectively. The relative concentrations of the three major phospholipids, phosphatidylethanolamine (73–76%), phosphatidylglycerol (9–11%) and cardiolipin (11–13%) were essentially the same at all three growth temperatures. The ratios of unsaturated to saturated fatty acids were 2.2, 1.1 and 0.4 for cells grown at 5, 22 and 37°C, respectively. This change in the fatty acid composition in response to temperature changes is similar to the patterns reported for other organisms. Reversible thermotropic phase transitions were detected by calorimetric analysis in both pure lipid preparations and membrane preparations. The mid-points of the thermotropic phase transitions were at ?13, ?9 and 1°C for membranes from cells grown at 5, 22 and 37°C, respectively. The phase transitions of the membranes from cells grown at the three different temperatures occurred below the lowest growth temperature (5°C). The alternations in the fatty acid composition in Y. enterocolitica did not, therefore, appear to be required to adjust membrane fluidity but might rather be required for some other membrane function.     

Electric surface charge dynamics of chloroplast thylakoid membranes. Temperature dependence of electrokinetic potential and aminoacridine interaction

Electric surface charge dynamics of unstacked broken chloroplasts at low-ionic strength were studied by free-flow electrophoresis and aminoacridine fluorescence and binding changes over the temperature range 4–36°C. Both illumination and ATP hydrolysis in the dark cause a significant increase of net negative surface charge. The light and dark electrokinetic (ζ) potentials have a broad temperature optimum between 20 and 36°C. The decline at lower temperature shows a transition at about 18°C. The ATP-induced increase of the ζ potential requires preactivation of the ATPase and is dicyclohexylcarbodiimide sensitive. Aminoacridine binding shows a quite different temperature dependence. At lower temperatures there is an increased number of binding sites with a decreased affinity and the binding becomes positively cooperative. It is demonstrated that aminoacridines aggregate to dimers upon binding to the membranes. This phenomenon is stimulated by light and favoured at lower temperatures. The light-dependent extra binding increases sigmoidally with increasing temperature, similar to the increase of ζ potential, but with a less abrupt transition. The different effects of temperature on the electrokinetic and binding data are explained in terms of surface charge screening in the electric double-layer of the thylakoid membrane.     

Physical characteristics of hyaluronate binding to the surface of simian virus 40-transformed 3T3 cells

The binding of labeled hyaluronate to the surface of Simian virus 40-transformed 3T3 cells was studied as a function of 1) pH, 2) ionic strength, 3) temperature, and 4) molecular weight of the hyaluronate. Binding occurred over a wide range of pH values with optima at pH 7 and at less than pH 4. Binding at low pH was eliminated at high ionic strength whereas that at physiological pH was enhanced, with a maximum at 0.5 M NaCl. The enhancement of binding at pH 7 was reversible and independent of the particular salt used. Scatchard plot analysis showed that increasing the ionic strength resulted in both a decrease in the dissociation constant (Kd) and an increase in the amount bound at saturation (Bmax). Temperature also influenced the binding of hyaluronate to the cell surface. The amount bound at low temperatures (0 degrees C) was 3 to 5 times that bound at high temperatures (40 degrees C) with a sharp transition occurring at 18 degrees C, the temperature of phase transition of the plasma membrane. The temperature effect was primarily a change in the Bmax and was reversible. Finally the molecular weight of the ligand influenced the binding. High molecular weight preparations of hyaluronate had a higher binding affinity (lower Kd) and a lower Bmax than did smaller molecular weight preparations.     

Effects of temperature on parameters of root growth relevant to nutrient uptake: Measurements on oilseed rape and barley grown in flowing nutrient solution

Summary Effects of root temperature on the growth and morphology of roots were measured in oilseed rape (Brassica napus L.) and barley (Hordeum vulgare L.). Plants were grown in flowing solution culture and acclimatized over several weeks to a root temperature of 5°C prior to treatment at a range of root temperatures between 3 and 25°C, with common shoot temperature. Root temperature affected root extension, mean radius, root surface area, numbers and lengths of root hairs. Total root length of rape plants increased with temperature over the range 3–9°C, but was constant at higher temperatures. Root length of barley increased with temperature in the range 3–25°C, by a factor of 27 after 20 days. Root radii had a lognormal distribution and their means decreased with increasing temperature from 0.14 mm at 3°C to 0.08 mm at 25°C. The density of root hairs on the root surface increased by a factor of 4 in rape between 3 and 25°C, but in barley the highest density was at 9°C. The contribution of root hairs to total root surface area was relatively greater in rape than in barley. The changes in root system morphology may be interpreted as adaptive responses to temperature stress on nutrient uptake, providing greater surface area for absorption per unit root weight or length.     

Commitment to germ tube or bud formation during release from stationary phase in Candida albicans.

Cells of the pathogenic yeast Candida albicans accumulate as unbudded singlets at stationary phase in defined medium at 25 °C. When released into fresh medium at 37 °C and pH 6.5, these cells will synchronously form elongate pseudomycelia, and when released into fresh medium at either 25 °C, pH 6.5, or 37 °C, pH 4.5, they will synchronously form buds. Using pH and temperature shift experiments, we have examined when cells become committed to pseudomycelium formation and bud formation under conditions conducive to each growth form respectively. It is demonstrated that in either case commitment occurs long after release from stationary phase, at approximately the same time the first evagination is visible on the cell's surface. In addition, it is demonstrated that once a released cell has formed a bud, it and its progeny lose the capacity to form pseudomycelia until they re-enter stationary phase; on the other hand, elongating pseudomycelia retain the capacity to form buds. The possible relationships of the commitment events to septation and to the cell cycle are discussed.     

3T3 cell motility in the temperature range 33 degrees C to 39 degrees C

The phenomena of mammalian cell motility in tissue culture is an integrated function of many cellular components. As such, cell motility is very sensitive to external stimuli and perturbation. In this article we report the effect of temperature in the range 33 degrees C to 39 degrees C on cell motility. For this 3T3 cells were plated in plastic tissue culture flasks. A large number of individual cells (60 per experiment) were tracked as a function of time by means of an automated device, the Cell Analyzer. The data show a peak in the average cell speed in the range 36.5 degrees C to 38.5 degrees C, falling off sharply at lower and higher temperatures. The average rate of cell motility closely correlates to the average cell proliferation rate in the range 33 degrees C to 39 degrees C.     

Seasonal changes in entrainment cues for the circadian rhythm of the supratidal amphipod Talorchestia longicornis

The supratidal amphipod Talorchestia longicornis Say has a circadian rhythm in activity, in which it is active on the substrate surface at night and inactive in burrows during the day. The present study determined: (1) the circadian rhythms in individual versus groups of amphipods; (2) the range of temperature cycles that entrain the circadian rhythm; (3) entrainment by high-temperature cycles versus light?:?dark cycles, and (4) seasonal substrate temperature cycles. The circadian rhythm was determined by monitoring temporal changes in surface activity using a video system. Individual and groups of amphipods have similar circadian rhythms. Entrainment occurred only to temperature cycles that included temperatures below 20°C (10–20, 15–20, 17–19, 15–25°C) but not to temperatures above 20°C (20–25, 20–30°C), and required only a 2°C temperature cycle (17–19°C). Diel substrate temperatures were above 20°C in the summer and below 20°C during the winter. Upon simultaneous exposure to a diel high-temperature cycle (20–30°C) and a light?:?dark cycle phased differently, amphipods entrained to the light?:?dark cycle. Past studies found that a temperature cycle below 20°C overrode the light?:?dark cycle for entrainment. The functional significance of this change in entrainment cues may be that while buried during the winter, the activity rhythm remains in phase with the day?:?night cycle by the substrate temperature cycles. During the summer, T. longicornis switches to the light?:?dark cycle for entrainment, perhaps as a mechanism to phase activity precisely to the short summer nights.     

Hydrophobicity and surface electrostatic charge of conidia of the mycoparasitic <Emphasis Type="Italic">Trichoderma</Emphasis> species

The present investigation was done to understand the fungal-fungal interactions mechanisms based on level of nonspecific adhesion of a potential fungal mycoparasite (Trichoderma) to their fungal host (Macrophomina phaseolina). The relative cell surface hydrophobicity (CSH) and cell surface electrostatic charge (CSEC) of 29 isolates of Trichoderma species, analyzed by bacterial adhesion to hydrocarbon (BATH), hydrophobic interaction chromatography (HIC), microelectrophoresis and contact angle, revealed a large degree of variability. CSH and CSEC of conidia depended on culture age, pH and temperature. Maximum CSH and CSEC were recorded in 25–28 °C range, and both declined significantly with increasing temperature. Isolate Trichoderma hazianum (Th)-23/98 expressed surface hydrophobicity at 25–28 °C and hydrophilicity at 40 °C. Surface hydrophobicity of the isolate was susceptible to various proteases (trypsin, pepsin, proteinase k and a-chymotrypsin) and inhibitors (SDS, mercaptoethanol and Triton X-100) and a significant reduction in CSH was recorded in hydrophobic conidia. Hydrophilic conidia remained more or less unaffected by such treatments. SDS-PAGE analysis of the hydrophobic and hydrophilic conidia exhibited several protein bands in the 25 to 61 kDa range. However, each protein population contained one protein that was not observed in the other population. For hydrophobic conidia, the unique protein had an apparent molecular mass of 49 kDa, while the unique protein associated with hydrophilic conidia had a molecular mass of 61 kDa. Our findings suggest that CSH and CSEC of mycoparasitic Trichoderma may contribute to non-specific adhesion on to the sclerotial surfaces of Macrophomina phaseolina that may be influenced by growth and environmental conditions.     

Surface salt bridges contribute to the extreme thermal stability of an FN3-like domain from a thermophilic bacterium

This study uses differential scanning calorimetry, X-ray crystallography, and molecular dynamics simulations to investigate the structural basis for the high thermal stability (melting temperature 97.5°C) of a FN3-like protein domain from thermophilic bacteria Thermoanaerobacter tengcongensis (FN3tt). FN3tt adopts a typical FN3 fold with a three-stranded beta sheet packing against a four-stranded beta sheet. We identified three solvent exposed arginine residues (R23, R25, and R72), which stabilize the protein through salt bridge interactions with glutamic acid residues on adjacent strands. Alanine mutation of the three arginine residues reduced melting temperature by up to 22°C. Crystal structures of the wild type (WT) and a thermally destabilized (?Tm ?19.7°C) triple mutant (R23L/R25T/R72I) were found to be nearly identical, suggesting that the destabilization is due to interactions of the arginine residues. Molecular dynamics simulations showed that the salt bridge interactions in the WT were stable and provided a dynamical explanation for the cooperativity observed between R23 and R25 based on calorimetry measurements. In addition, folding free energy changes computed using free energy perturbation molecular dynamics simulations showed high correlation with melting temperature changes. This work is another example of surface salt bridges contributing to the enhanced thermal stability of thermophilic proteins. The molecular dynamics simulation methods employed in this study may be broadly useful for in silico surface charge engineering of proteins.     

Changes of cell surface configuration and regulation of cell proliferation.

The electric surface charge configuration of 3T3 and SV40-3T3 cells was characterized by determining the product of electrophoretic mobility of the cells times the viscosity of suspension medium. This quantity could be shown to change with temperature and/or treatment with calf serum or trypsin in close correlation with the effects of these agents on characteristics of cell proliferation. The present results, taken together with those of earlier studies on cell-electrophoresis and characterization of lipid constituents of the cells, support the hypothesis of a lateral phase separation in the plasmamembrane as triggering process in stimulation of proliferation of resting normal cells.     

Changes of cell surface configuration and regulation of cell proliferation

The electric surface charge configuration of 3T3 and SV40-3T3 cells was characterized by determining the product of electrophoretic mobility of the cells times the viscosity of suspension medium. This quantity could be shown to change with temperature and/or treatment with calf serum or trypsin in close correlation with the effects of these agents on characteristics of cell proliferation. The present results, taken together with those of earlier studies on cell-electrophoresis and characterization of lipid constituents of the cells, support the hypothesis of a lateral phase separation in the plasmamembrane as triggering process in stimulation of proliferation of resting normal cells.     

Cyclic AMP-dependent protein kinases from Balb 3T3 cells and other 3T3 derived lines

Cyclic AMP-dependent protein kinase and 3H-cAMP-binding activities were determined in normal Balb 3T3 cells and compared with the same preparations from SV40, chemical, and spontaneous transformants of 3T3 cells. The cytosolic protein kinase activities and protein kinase activity ratios were similar in all cell lines, although when the normal 3T3 cytosol was prepared by homogenization it contained less 3H-cAMP binding activity than the transformed 3T3 cytosols. The Triton X-100 treated particulate fractions from the normal and transformed 3T3 cells contained similar protein kinase and binding activities. The isozymic profile of cAMP-dependent protein kinases was examined by DEAE-chromatography. The 3T3 cells contained only type II isozyme in either cytosolic or membrane fractions. All transformants of the 3T3 cells contained both type I and type II isozymes. Other cell cultures, including chicken embryo fibroblasts, rat kidney cells, and human or calf endothelial cells contained type I and type II isozymes. Binding of the photoaffinity analogue of cAMP, 8-N3 cAMP, to the regulatory subunits of protein kinases in sonicates obtained from Balb 3T3 and SV 3T3 cells followed by separation on SDS polyacrylamide electrophoresis showed that the amount of RII subunit was approximately equal in the two cell lines. RI in Balb 3T3 cells was detectable but in a much lower quantity than in SV 3T3 cells. The cyclic AMP dependent-protein kinases from Balb 3T3 cells appears to be different from SV 3T3 cells by three criteria: 3H-cAMP binding in homogenates, DEAE chromatographic separation of isozymes, and 8-N3 cAMP binding.     

Separation of human lymphocyte subpopulations by density gradient electrophoresis. I. Different mobilities of T (T mu, T alpha) and B lymphocytes from human tonsils

T and B lymphocytes from human tonsils were separated by density gradient electrophoresis on the basis of their surface charge. The high-mobility cell fractions were found to be highly enriched in T lymphocytes with only very small proportions of B cells. In contrast, the low-mobility fractions were predominantly B lymphocytes, and had only 10 to 30% contamination of T cells. The intermediate-mobility fractions contained both T and B lymphocytes in approximately equal proportions. IgM-bearing lymphocytes, as well as cells with receptors for mouse erythrocytes, the Fc portion of IgG, and complement were found in the intermediate- and low-mobility fractions. T lymphocytes, prepared by E rosetting, were also electrophoresed by this method and found to be of higher mobility as compared with peripheral blood T lymphocytes. T cells with Fc receptors for IgM (Tμ) or IgA (Tα) were found to be considerably heterodisperse with regard to surface charge and were present in all fractions. The separated cell fractions were treated in vitro with various concentrations of concanavalin A and thereafter examined for Tμ, Tγ, and Tα phenotypes. Low concentrations of Con A (2.5 μg/ml) had no effect on cell surface phenotypes. However, higher concentrations of Con A (20μg/ml) significantly reduced the numbers of T cells having IgM receptors (Tμ), but failed to alter the expression of the Tγ phenotype. The latter finding contrasts to that observed with T cells from the peripheral blood where high concentrations of Con A increase the proportions of the Tγ cells. This study demonstrates that density gradient electrophoresis can be used for the separation and study of lymphocyte subpopulations from human tonsils.     

Effect of culture media, temperature and light on radial growth and pycnidium production of cowpea isolates of Phoma bakeriana

The effects of culture media, temperature and light on radial growth and pycnidium production of cowpea isolates (PB1, PB2, PB3) of Phoma bakeriana were investigated in vitro. There was no isolate effect on growth and pycnidium production but some evidence of a medium effect. Exceptionally high growth rate on two media corresponded with high pycnidium production; while low growth rates on other media were generally associated with high sporulation. There was a large temperature effect and an isolate effect on growth with a significant temperature by isolate interaction. Temperatures of 5°C, 10°C and 35°C inhibited pycnidium formation completely while the range 15–30°C had no effect on sporulation. Maximum growth and pycnidium production occurred at 25°C. Near-ultraviolet radiation seemed to have caused higher pycnidium counts than the other light sources.     

Sugar transport in fat cells: effects of mechanical agitation, cell-bound insulin, and temperature.

The effects of several factors that affect the sugar transport activity in rat epididymal fat cells were studied. The transport activity was assessed semiquantitatively by measuring the uptake of 3-O-methyl-d-glucose by the oil-flotation method. The transport activity was stimulated by mechanical agitation, such as centrifugation of cells. This effect was transient. When agitated cells were incubated at 37 °C with gentle shaking, their transport activity declined. The decline was often facilitated by the addition of glucose or pyruvate. Presumably some cell preparations were low in the source of metabolic energy that was required for this recovery process. When cells were exposed to a high concentration of insulin, washed, and suspended in fresh buffer, the effect of insulin (plus that of mechanical agitation) declined after a certain lag period. The length of this period was a function of the initial insulin concentration. The incubation temperature had different effects on the basal and plus-insulin activities. The basal activity at 25 °C was higher than that at 37 °C, while the plus-insulin activity was lower at 25 °C than at 37 °C.