Translational efficiency of heat-induced messages in Drosophila melanogaster cells

When Drosophila cells are exposed to elevated temperatures, pre-existing polysomes are depleted and normal cellular protein synthesis is greatly reduced. Polysomes rapidly reform on newly synthesized messenger RNA as the so-called heat shock proteins become the major products of protein synthesis in the cell. These circumstances afford the opportunity to calculate rates of initiation and elongation of protein synthesis directly from measurements of the quantity of actively translated messenger RNA and the quantity of protein produced over a given period. Ribosomes were found to initiate on heat-induced messages in Drosophila with a frequency of between 9 and 14 initiations per minute at 37 °C. This rate is close to that reported for other eukaryotic systems at similar temperatures. Thus, although heat treatment causes a profound change in the patterns of protein synthesis, it does not deleteriously affect the capacity of cells to synthesize protein.     

A yeast lysis mutant: potential biotechnological applications

The conditional yeast lysis mutant cly8 was studied for potential biotechnological applications. The strain stops to grow immediately after a shift to elevated temperatures ( > 30°C). Cell viability (colony forming capacity) decreases at 37°C at a rate depending on the composition of the medium. However, at the elevated temperature cells still consume glucose and incorporate [¹⁴C]leucine into cell material. With decreasing viability the mutant cells become leaky for small, predominantly cytoplasmic components such as leucine or uridine but not for vacuolar storage products like arginine. No trichloroacetic acid-precipitable material could be detected in the medium after the shift to the elevated temperature indicating that leakiness was restricted to low molecular weight compounds. On acetate medium mutant cells became permeable only after prolonged incubation at 37°C but could be used for the oxidation of exogenous NADH. In comparison to the wild type the mutant also produced more glycerol. When the mutant cells were immobilized, glycerol production was in the same range at room temperature and at 28°C and could be maintained for several days.     

Defect in translation of poliovirus RNA at the restrictive temperature.

Translation of the RNA of LSc type 1 poliovirus was examined in vivo at the restrictive temperature (39 °C). During the first two hours of infection at 39 °C the levels of viral polyribosomes were 50% lower than at 35 °C (permissive temperature). During the third hour of infection at 39 °C, only 4 to 10% of the control levels of polyribosomes were observed. Three experiments indicate that the elongation of viral peptides was not occurring properly at 39 °C. First, cultures incubated at 39 °C during the third hour of infection with both [³⁵S]methionine and [³H]uridine exhibit a fourfold increase in the ratio of viral protein/viral RNA in the polyribosome region of sucrose gradients in comparison to controls kept at 35 °C. However, at both temperatures the relative size distribution of polyribosomes was similar. Second, the ratios of released protein/nascent protein after 90-second and 5-minute pulses with [³⁵S]methionine indicate that elongation of peptide chains was inhibited at 39 °C. Third, when initiation of synthesis of viral protein was blocked with 150 mM-NaCl, the polyribosomes disaggregated four to five times more rapidly at 35 °C than at 39 °C. The data indicate that translation of viral RNA is inhibited at the restrictive temperature because of a reduced rate of elongation of viral proteins. The reduced rate of peptide chain elongation at 39 °C was fully reversible when cultures were shifted to 35 °C in the presence of 150 mm-NaCl. The latter finding indicates a conformational change in viral protein at 39 °C.     

Regulation of translation in rabbit reticulocytes and mouse L-cells; comparison of the effects of temperature

Various parameters of protein synthesis were analyzed in rabbit reticulocytes exposed to various temperatures for up to five hours. Between 10°C and 40°C total protein synthesis exhibited two different apparent activation energies (36 kcal/mole, 10–24°C; 22 kcal/mole, 24–40°C), as did protein elongation and release (35 kcal/mole, 10–25°C; 12 kcal/mole, 25–40°C). However, the level of polysomes remained essentially unchanged between 0°C and 42°C which implies that the activation energy for polypeptide initiation is quite similar to that for elongation and is also biphasic. This situation is different from that in cultured mouse L-cells where the polysome level is dependent on temperatures. Nevertheless, reticulocytes and L-cells appear to be similar in their temperature dependence of initiation and in their rate of elongation (5–6 amino acids/second at 36°C).     

The effect of cessation of growth on protein synthesis in a mutant of Chinese hamster ovary cells with a temperature-sensitive leucyl-tRNA synthetase

A temperature-sensitive mutant of Chinese hamster ovary cells with an altered leucyl-tRNA synthetase fails to grow and to incorporate amino acids into protein properly at or near the non-permissive temperature. This mutant was used to determine whether cessation of growth at the elevated temperature affected elongation factor EF-1, since the activity of EF-1 is markedly lower in non-growing cells in stationary phase than in rapidly-growing cells in exponential phase. Cell-free extracts prepared from cells maintained at 39°C for 24 h showed a marked decrease in the ability to translate natural mRNAs, compared to cells incubated at 34°C. However, the ability to translate poly(U), which requires elongation factor EF-1 (and EF-2), was not affected. Analyses of activities involved in the initiation of protein synthesis and in the activation of amino acids revealed that, with the exception of leucyl-tRNA synthetase, the rest of the components required for translation also appeared to be relatively stable even after 24 h at the elevated temperature. The effects of elevated temperature on cell-free extracts were also investigated. The results were similar to those obtained with intact cells; that is, except for leucyl-tRNA synthetase which was rapidly inactivated in vitro at 39°C, other aminoacyl-tRNA synthetases and translational components involved in chain initiation and elongation were relatively stable. Thus, no change in EF-1 activity was detected as a result of arrested cell growth, an inherent lability of the elongation factor, or metabolic degradation as a consequence of a rapid turnover rate in the absence of protein synthesis.     

Use of low temperature for growth arrest and synchronization of human diploid fibroblasts

The growth kinetics of human diploid fibroblasts at two different temperatures were followed. Proliferation of exponentially growing cells is reduced and eventually stops upon incubation at low temperature (i.e. 30°C). The cells which are in S phase at the time of switching to low temperature complete their DNA synthesis and become arrested in the G₁ phase of the cell cycle. The arrested cells can be stimulated to proliferate by restoration of the optimal growth temperature (37°C). The kinetics of entry into S phase were investigated by measuring [³H]thymidine incorporation into TCA-precipitable material, by autoradiography and by flow cytofluorimetry. The synchronized cells initiate DNA synthesis at approximately 8 h and DNA synthesis peaks at 20.4±0.7 h after stimulation.In addition, the rates of UV-induced excision repair at 30°C and 37°C were compared. The results indicate that at 30°C the excision-repair process is operative but at a slightly reduced rate in comparison with repair at 37°C.This method will be useful for the study of S-phase-dependent processes, as well as for repair studies in the absence of cell division.     

Cytolytic T lymphocyte mediated chromium-51 release versus spontaneous release from blast and spleen cell targets at low temperatures

The rate of spontaneous ⁵¹Cr release from spleen cell and LPS blast target cells is strongly temperature dependent. Between 32 and 37 °C the rate of spontaneous release increases dramatically with temperature. Cytolytic T-lymphocyte-mediated lysis of these target cells is also temperature dependent, but lysis does not increase greatly above 32 °C. The ratio of specific ⁵¹Cr release to spontaneous release can be significantly improved by doing ⁵¹Cr-release assays at temperatures below 37 °C.     

The control of protein synthesis during heat shock in Drosophila cells involves altered polypeptide elongation rates

When Drosophila tissue culture cells are shifted from 25 to 36°C (heat shocked) the pre-existing mRNAs (25°C mRNAs) remain in the cytoplasm but their translation products are underrepresented relative to the induced heat shock proteins. Many of these undertranslated 25°C mRNAs are found in association with polysomes of similar size in heat-shocked and control cells. Furthermore, the messages encoding α-tubulin, β-tubulin, and actin are found associated with one-third to one-half as many total ribosomes in heat-shocked cells as in cells incubated at 25°C. Increased temperature should lead to increased output of protein per ribosome. However, the 25°C proteins are actually synthesized at less than 10% of 25°C levels in heat-shocked cells. Thus, the rates of both elongation and initiation of translation are significantly (15- to 30-fold) slower on 25°C mRNAs than they are on heat shock mRNAs in heat-shocked cells.     

The Influence of Temperature on Floral Initiation in the Olive

Floral initiation is completely inhibited when the olive is grown in a glasshouse at a minimum temperature of 16°C and a maximum temperature of 27°–30°C but occurs when it is grown at natural winter conditions in California. This study was undertaken to determine more specifically the temperature requirements for flowering and to show the relation of temperature treatment to hud development and floral initiation. Results of experiments performed with trees in containers grown at constant temperatures in controlled environment growth rooms show that the optimum temperature for flowering is 10°–13°C. Either higher (18°C) or lower (4°C) temperatures inhibit flowering completely. Morphological studies show that axis elongation and floral initiation occur in buds during temperature treatment at 10°C and 13°C but fail to occur during 4°C or 18°C treatments, or following these treatments when the temperature is raised to 21°C. When plants were exposed to 13°C for varying durations, it was found that no inflorescences formed after a 7.5 week exposure but that many formed after an 11-week exposure. A subsequent experiment showed that many more inflorescences formed after a 10-week exposure at 13°C than after 9 weeks exposure. Morphological changes in the bud seem to be associated with this increase in flowering affected by duration of treatment.     

Low-temperature-induced rate transitions in DNA synthesis of Escherichia coli 15T.

DNA synthesis rates were measured in Escherichia coli 15T^? (555-7) at each degree increment in the range of 8 to 37 °C. These measurements were made (a) by means of continuous incorporation of thymine into temperature-equilibrated cultures, (b) by incorporation of short pulses of thymidine into chilled, intact cells, or (c) by incorporation of deoxynucleotide triphosphate into chilled, toluenized cells. Measurements were made in wild type and in a fast-growing mutant, with each assayed at doubling times of less than 60 min (glucose-grown cells) and greater than 60 min (aspartic acid-grown cells). Rates of DNA synthesis from each experimental system were plotted according to the method of Arrhenius, and data points fitted to either one, two, or three lines.Using the slopes of the regression lines as a general index of temperature coefficients, it is possible to relate growth history, medium (or growth rate), and cell type to temperature coefficients. Only in temperature-equilibrated cells did DNA synthesis possibly have a single temperature coefficient across the entire 8 to 37 °C range; in cells grown at 37 °C and cooled to a lower temperature before DNA synthesis was measured, at least two temperature coefficients were observed. In addition to affecting the actual slopes of the regression lines, growth history, medium (or growth rate), and cell type appear to affect the temperatures at which slopes change. Collectively, these observations show that DNA synthesis rates measured at certain low temperatures cannot routinely be extrapolated to higher temperatures, to different growth conditions, or to other strains.     

Benzodiazepine receptors: temperature dependence of [3H]flunitrazepam binding.

The characteristics of [³H]flunitrazepam binding to brain specific benzodiazepine receptors were determined at varying temperatures. The rates at which [³H]flunitrazepam associated with and dissociated from benzodiazepine receptors increased with increasing temperatures. The dissociation constant (K_D) also increased with increases in temperature. The (K_D) determined by Scatchard analyses of saturation isotherms showed a similar change with changes in temperature. The maximal binding capacity (Bmax) did not change with changes in temperature. The inhibitory constants of several benzodiazepines to inhibit [³H]flunitrazepam binding to brain were also higher at 37°C than at 0°C, suggesting that the binding affinity of all benzodiazepines to brain benzodiazepine receptors is lower at 37°C than at 0°C. Van't Hoff analysis of [³H]flunitrazepam binding to brain at different temperatures reveals two linear components to this relationship.     

Influence of temperature on spatial fibrin clot formation process in thrombodynamics assay

Using thrombodynamics, a novel in vitro hemostasis assay, which imitates the process of hemostatic clot growth in vivo, we have investigated the process of spatial fibrin clot formation in non-steered platelet-free plasma of healthy volunteers at the temperatures ranged from 20 to 43°C. The temperature dependence of extrinsic and intrinsic tenase activities, which determine values of the initial and stationary clot growth rates, respectively, has been determined. Lowering the temperature from 37 to 24°C mainly extended the initiation phase of clot growth, while the stationary rate of clot growth remained basically unchanged. During the temperature decrease up to 24°C (acute hypothermia) none of the thrombodynamics parameters demonstrated any dramatic change of the plasma coagulation system. Thus, the thrombodynamics assay provided additional arguments supporting the viewpoint, that the temperature lowering itself insignificantly influences the state of the plasma hemostasis system.     

Effects of temperature on food ingestion rate and absorption,retention, and equilibrium burden of phosphorus in an aquatic snail,Goniobasis clavaeformis Lea *

The effects of sublethal temperatures on feeding rates and phosphorus dynamics of a freshwater snail, Goniobasis clavaeformis Lea, were determined and feeding rates were measured at four temperatures. The food source was aufwuchs labelled with radioactive phosphorus. A model was developed to elucidate the results of this type of study. Food ingestion rate increased with increasing temperature up to 14°C and then decreased at temperatures above 14°C. The elimination rate of absorbed phosphorus increased with increasing temperature throughout the entire range of experimental temperatures, 10-19.3°C. Mean retention times of absorbed phosphorus i n Goniobasis were estimated to be 34, 24, 10, and 6 days at 10, 13.8, 15, and 193°C, respectively. Mean retention time of unabsorbed ³²P in the gut of this species as a function of temperature followed the same temperature relationship as that of ingestion rate. The absorption efficiency of phosphorus was estimated to be constant at about 39% for ail experimental temperatures, although the data suggest that the absorption ePRciency may have been related inversely to the rate of gut clearance or directly to the residence time of food in the gut. The equilibrium body load of phosphorus at each experimental temperature was estimated based on concentrations of stable phosphorus in the food source and the kinetics of ³²P in Goniobasis. The equilibrium body burden of phosphorus in Goniobasis increased with increasing temperatures up to a maximum at 11–12°C and then decreased at temperatures above 12°C.     

Temperature effects on carbon and nitrogen metabolism in some Maritime Antarctic freshwater phototrophic communities

Biofilms growing on ice and benthic mats are among the most conspicuous biological communities in Antarctic landscapes and harbour a high diversity of organisms. These communities are consortia that make important contributions to carbon and nitrogen input in non-marine Antarctic ecosystems. Here, we study the effect of increasing temperatures on the carbon and nitrogen metabolism of two benthic communities on Byers Peninsula (Livingston Island, Maritime Antarctica): a biofilm dominated by green algae growing on seasonal ice, and a land-based microbial mat composed mainly of cyanobacteria. Inorganic carbon photoassimilation, urea and nitrate uptake and N₂-fixation (acetylene reduction activity) rates were determined in situ in parallel at five different temperatures (0, 5, 10, 15, 25°C) using thermostatic baths. The results for the cyanobacterial mat showed that photosynthesis and N₂-fixation responded positively to increased temperatures, but urea and NO₃⁻ uptake rates did not show a significant variation related to temperature. This microbial mat exhibits relatively low activity at 0°C whereas at higher temperatures (up to 15°C), N₂-fixation rate increased significantly. Similarly, the maximum photosynthetic activity increased in parallel with temperature and showed no saturation up to 25°C. In contrast, the ice biofilm displayed higher photosynthetic activity at 0°C than at the other temperatures assayed, and it showed elevated photoinhibition at warmer temperatures.     

Thermal inhibition of repair of methylmethane sulfonate-damaged DNA in chick embryo fibroblasts

Chick embryo fibroblasts were treated with the monofunctional alkylating agent methylmethane sulfonate at various concentrations for 1 h at 42°C, rinsed and then incubated post-treatment at various temperatures at which the kinetics of alkali-labile bond disappearance was followed. Growth experiments showed that these cells grew similarly at temperatures of either 37°C or 42°C. Repair as assessed by removal of alkali-labile bond was also similar for postincubation in the temperature range 37–42°C for damage due to methylmethane sulfonate treatment at concentrations less than 1.5 mM. When the postincubation temperature was raised higher than 42.5–43°C, this type of repair was stopped. The normal internal body temperature of adult chickens is about 41.6°C. Hence the present finding indicates that chick cells are much more severely restricted in DNA repair at temperatures above normal than are mammalian cells, which can function in this respect for several deg. C above 37°C.     

Temperature management strategy for efficient gene expression in a thermally inducible <Emphasis Type="Italic">Escherichia coli</Emphasis>/bacteriophage system

In a two-phase operation, E. coli containing λSNNU1 (Q ⁻ S ⁻) in the chromosome is typically cultured at 33°C and cloned gene expression is induced by elevating the temperature. At least 40°C is necessary for complete induction of cloned gene expression; however, temperatures above 40°C have been shown to inhibit cloned gene expression. This suggests that a three-phase operation, which has an induction phase between the growth and production phases, may result in higher gene expression. In this study, optimal temperature management strategies were investigated for the three-phase operation of cloned gene expression in thermally inducible E. coli/bacteriophage systems. The optimal temperature for the induction phase was determined to be 40°C. When the temperature of the production stage was 33°C, the optimal time period for the induction phase at 40°C was determined to be 60 min. In contrast, when the temperature of the production phase was 37°C, the optimal period for the induction phase at 40°C was 20∼30 min. When the three-phase temperature and temporal profile were set at a growth phase of 33°C, an induction phase at 40°C for 30 min, and a production phase at 37°C, the highest level of cloned gene expression was achieved.     

An Analysis of Specific Temperature Blocks in the Conjugation Sequence of Paramecium tetraurelia1

ABSTRACT. Temperature shifts have been used to block critical points in the conjugation sequence of Paramecium tetraurelia. Increasing temperatures above 27^°C reduced ciliary agglutination, pair formation, and nuclear exchange; a complete inhibition of these stages occurred at 37^°C. Temperatures below 19^°C had no effect on ciliary agglutination or nuclear exchange but completely inhibited pair formation. The bases for the cells’ inability to form pairs at 19^°C and 37^°C were sought. Cells placed below 19^°C were unable to deciliate or fuse membranes in the holdfast region; at 37^°C, membrane fusion in both the holdfast and paroral regions was prevented. Time course studies on cross-fertilization reveal that temperatures 35^°C block all stages of the process up to the actual exchange of pronuclei. After the exchange has begun, the process continues despite the elevated temperature. Temperature shifts are discussed as a means of conditionally blocking critical points in the developmental program of conjugation.     

A model-dependent approach to correlate accelerated with real-time release from biodegradable microspheres

The purpose of this study was to determine the feasibility of applying accelerated in vitro release testing to correlate or predict long-term in vitro release of leuprolide poly(lactideco-glycolide) microspheres. Peptide release was studied using a dialysis technique at 37°C and at elevated temperatures (50°C–60°C) in 0.1 M phosphate buffered saline (PBS) pH 7.4 and 0.1 M acetate buffer pH 4.0. The data were analyzed using a modification, of the Weibull equation. Peptide release was temperature dependent and complete within 30 days at 37°C and 3 to 5 days at the elevated temperatures. In vitro release profiles at the elevated temperatures correlated well with release at 37°C. The shapes of the release profiles at all temperatures were similar. Using the modified Weibull equation, an increase in temperature was characterized by an increase in the model parameter, α, a scaling factor for the apparent rate constant. Complete release at 37°C was shortened from ∼30 days to 5 days at 50°C, 3.5 days at 55°C, 2.25 days at 60°C in PBS pH 7.4, and 3 days at 50°C in acetate buffer pH 4.0. Values for the model parameter β indicated that the shape of the release profiles at 55°C in PBS pH 7.4 (2.740) and 50°C in 0.1 M acetate buffer pH 4.0 (2.711) were similar to that at 37°C (2.577). The E_a for hydration and erosion were determined to be 42.3 and 19.4 kcal/mol, respectively. Polymer degradation was also temperature dependent and had an E_a of 31.6 kcal/mol. Short-term in vitro release studies offer the possibility of correlation with long-term release, thereby reducing the time and expense associated with longterm studies. Accelerated release methodology could be useful in the prediction of long-term release from extended release microsphere dosage forms and may serve as a quality control tool for the release of clinical or commercial batches. Selected for the 2005 AAPS Outstanding Graduate Student Research Award in Pharmaceutical Technologies Sponsored by Solvay Pharmaceuticals.     

Membrane phase transitions and the transport of chlortetracycline.

When chlortetracycline is added to a suspension of respiring Staphylococcus aureus cells, the active transport of the antibiotic may be monitored by its fluorescence enhancement as it moves from a polar aqueous environment into the apolar regions of the membrane. The initial rates of transport are temperature dependent with a maximal rate between 35 and 45 °C. Arrhenius plots of the initial rates are biphasic with a transition temperature of 27 °C for control cells. This transition temperature is sensitive to the fatty acid composition of the S. aureus cells. By culturing the cells in the presence of oleic acid or at 10 °C, the S. aureus cells incorporate a larger percentage of unsaturated and branched chain fatty acids into their membranes, resulting in transition temperatures 8–9 °C lower than the control cells. Studies of depolarization of fluorescence also indicate that the mobility of the bound chlortetracycline is temperature-dependent. Temperature transitions occur at the same temperatures as those measured by Arrhenius plots. The transition temperatures indicated by the Arrhenius plots and the polarization studies are believed to reflect order-disorder phase transitions associated with the melting of the phospholipids in the cell envelope.