Reduction of ribonuclease by glutathione at elevated temperatures: the molecular mechanism

1. The mechanism of the reaction between ribonuclease and GSH at elevated temperatures has been studied by using N-(4-dimethylamino-3,5-dinitrophenyl)-maleimide to label the reduced ribonuclease. 2. After incubation for 2hr. at 35 degrees , enzymically active ribonuclease was recovered; at 50.8 degrees half of the initial ribonuclease was recovered as enzymically active ribonuclease and half as reduced labelled ribonuclease; at 55 degrees all of the initial ribonuclease was recovered in the labelled form. 3. It was inferred that the rate-limiting step was the reduction of the first disulphide bond in any one molecule. This was followed by rapid reduction of the other bonds in the same molecule.     

Interaction of hyperthermia and pentamidine in HeLa S-3 cells

Pentamidine is similar to rhodamine-123 in chemical structure and state of electron charge, and rhodamine-123 was previously shown to be a hyperthermic sensitizer under appropriate cell culture conditions. The present experiments were carried out to determine whether pentamidine would potentiate hyperthermic cell killing and, if so, under what cultural conditions. Exposure of HeLa cells to pentamidine (80 microM) up to 4 h was not cytotoxic in culture medium in the presence or absence of glucose at 37 degrees C and pH 7.4. Cells in the glucose-deprived medium became progressively sensitive to killing as temperature and drug concentration were increased. On the other hand, there was a moderate level of enhanced cell killing in the glucose-fed medium at 42 degrees C. The enhanced effects of heat by the drug were most pronounced under alkaline pH of the culture medium. The cell kill under acidic pH was far less than that observed at neutral or alkaline pH; these effects may be a result of decreased cellular uptake of pentamidine. Together with our previous results on rhodamine-123 and glycolytic inhibitors, the present data with pentamidine are consistent with the concept that deprivation of cellular energy increases sensitivity to cell killing by heat.     

Escherichia coli variants for gas and indole production at elevated incubation temperatures

Two strains of Escherichia coli were subjected to heat and cold-storage treatments to determine the stability of the fecal E. coli characteristics of gas production from lactose and indole production at elevated incubation temperatures. No variants were detected with repeated sublethal heat treatment. A high incidence of variants was observed with extended cold storage of the organisms in liquid and semisolid media, especially with poor nutrient composition, and in the absence of cryoprotective agents. The indole characteristic at elevated temperature was more stable than the production of gas from lactose. The critical temperature at which both gas production from lactose and the indole characteristic were lost was 44.5 degrees C. It appeared that the variants resulted from increased temperature sensitivity of the formic hydrogen lyase and tryptophanase enzymes, respectively.     

Extracellular protectants produced by Clostridium perfringens cells at elevated temperatures

Aim:  The mechanisms of adaptation of Clostridium perfringens to high temperatures are not well understood. In this work, the involvement of extracellular compounds in protection to heat was determined.
Methods and Results:  Cells were grown in fluid thioglycollate medium or chicken broth. When mid-log phase was reached, they were heat-shocked at 50°C for 30 min. Then cultures were centrifuged and supernatants were transferred to nonshocked cells. Heat tolerance of these cells was performed at 55°C. Viable cells were determined. In some cases, supernatants were heated at 65°C or 100°C or treated with trypsin. Supernatants were fractionated and PAGE was made of fractions showing heat-protective activity. When C. perfringens was exposed to a heat shock at 50°C, extracellular factors were found in the culture supernatant that provided protection to cells not exposed to a heat shock. The extracellular factors were sensitive to heat and trypsin treatment suggesting a protein component. SDS-PAGE analysis of supernatant fractions from heat-treated cells revealed two induced proteins (56 and 125 kDa) that could be involved in heat tolerance.
Conclusion:  In this work, the presence and thermoprotective activity of extracellular factors produced by C. perfringens under a heat shock was demonstrated.
Significance and Impact of the Study:  The detection of thermoprotective extracellular factors of C . perfringens will aid in our understanding of the physiology of survival of C. perfringens in foods.     

Escherichia coli variants for gas and indole production at elevated incubation temperatures.

Two strains of Escherichia coli were subjected to heat and cold-storage treatments to determine the stability of the fecal E. coli characteristics of gas production from lactose and indole production at elevated incubation temperatures. No variants were detected with repeated sublethal heat treatment. A high incidence of variants was observed with extended cold storage of the organisms in liquid and semisolid media, especially with poor nutrient composition, and in the absence of cryoprotective agents. The indole characteristic at elevated temperature was more stable than the production of gas from lactose. The critical temperature at which both gas production from lactose and the indole characteristic were lost was 44.5 degrees C. It appeared that the variants resulted from increased temperature sensitivity of the formic hydrogen lyase and tryptophanase enzymes, respectively.     

DNA damage production in CHO cells at elevated temperatures

Induction of DNA lesions in the nucleus of Chinese hamster ovary (CHO) cells was observed at hyperthermic temperatures using the alkaline filter elution and the alkaline sucrose gradient sedimentation methods. These lesions were observed principally at temperatures greater than 45 degrees C with an activation energy of 140 kcal/mole. On alkaline sucrose gradients the cell genome was reduced to a 140 S or 2 X 10(8) dalton subunit of DNA independent of increasing exposure time at temperatures above 45 degrees C. The large thermal activation energy and the limited DNA size reduction suggest the possible involvement of thermal denaturation of a nuclear polypeptide in the production of these nuclear lesions.     

Simultaneous assessment of Asp isomerization and Asn deamidation in recombinant antibodies by LC-MS following incubation at elevated temperatures

The degradation of proteins by asparagine deamidation and aspartate isomerization is one of several chemical degradation pathways for recombinant antibodies. In this study, we have identified two solvent accessible degradation sites (light chain aspartate-56 and heavy chain aspartate-99/101) in the complementary-determining regions of a recombinant IgG1 antibody susceptible to isomerization under elevated temperature conditions. For both hot-spots, the degree of isomerization was found to be significantly higher than the deamidation of asparagine-(387, 392, 393) in the conserved CH3 region, which has been identified as being solvent accessible and sensitive to chemical degradation in previous studies. In order to reduce the time for simultaneous identification and functional evaluation of potential asparagine deamidation and aspartate isomerization sites, a test system employing accelerated temperature conditions and proteolytic peptide mapping combined with quantitative UPLC-MS was developed. This method occupies the formulation buffer system histidine/HCl (20 mM; pH 6.0) for denaturation/reduction/digestion and eliminates the alkylation step. The achieved degree of asparagine deamidation and aspartate isomerization was adequate to identify the functional consequence by binding studies. In summary, the here presented approach greatly facilitates the evaluation of fermentation, purification, formulation, and storage conditions on antibody asparagine deamidation and aspartate isomerization by monitoring susceptible marker peptides located in the complementary-determining regions of recombinant antibodies.     

Replication of measles virus in Vero cells at elevated temperatures

In one-step growth experiment of measles virus (MV) in Vero cells at 39 C, the appearance of MV infectivity was delayed for 24 hr and the maximum titer was reduced by approximately 1,000-fold, when compared with those at 35 C. MV infectivity was thermolabile at the high temperature. Penetration was rather enhanced at 39 C. By Northern blot hybridization, viral RNAs including 50S genome-sized RNA and mRNAs were first detectable 24 hr post-infection (PI) at 35 C and 36 hr PI at 39 C, respectively. Rapid degradation of viral mRNAs was not observed in the infected cells at 39 C. The synthesis of N, F, and M proteins was relatively reduced at the high temperature and appearance of the other viral protein was delayed, in agreement with the time course of viral RNA synthesis. All these data suggest that less efficient synthesis of viral RNA, restriction of synthesis of N, F, and M proteins at translational level and thermolability of infectivity are all involved in the suppressed MV production in Vero cells at 39 C.     

Mitosis and protein synthesis. 3. Organelle relocation during normal and colcemid-arrested M-phase in HeLa S-3 cells

During M-phase, most organelles in HeLa S-3 cells are relocated in the 'cortex' or outer-zone of cytoplasm. Elements of the rough endoplasmic reticulum (rER) and polysome assemblies persist to varying degrees from cell to cell in this zone. Dilatation of rER cisternae becomes prominent in a small percentage of metaphases, and its occurrence and significance is discussed. Remnants of the Golgi apparatus are almost invariably peripheralized. Its cisternal elements are lost in early mitosis, and reappear in late telophase. The inner zone of the protoplasm around the chromosomes loses its associated intermediate filaments and excludes organelles until cytokinesis commences. A rapid repopulation occurs by mid-telophase. The same pattern of zoning is found in cells entering mitosis in the presence of colcemid, but is followed by some repopulation of the inner zone by a small minority of organelles after approximately 2 h of arrest. Centrioles are particularly prone to becoming enmeshed within the 'ball' of entangled c-metaphase chromosomes. An unusually high degree of pairing of cytoplasmic membranes, probably rER elements, also occurs in colcemid-arrested metaphases, which may further contribute to their reduced level of protein synthesis. These have been referred to as 'confronting cisternae' (Ghadially, 1988). The zoning of the cytoplasm may result from nuclear envelope breakdown during mitosis, and is not specifically related to or associated with microtubule redeployment during spindle formation in M-phase. Differences in the extent of zoning in other cell lines are discussed in comparison with HeLa S-3 cells.     

Assessment of the tolerance of Lactococcus lactis cells at elevated temperatures

When Lactococcus lactis strains were exposed directly to the lethal temperature of 50 C for 30 ;min, 0.1–31% of the cells survived. However, when pre-exposed to 40 °C, prior to exposure at 50 °C, 4–61% of the cells survived. A plasmid carrying a unique heat shock gene from the thermophile Streptococcus thermophilus was cloned into L. ;lactis. When the transformed cells were cultivated at 30 °C the introduction of the plasmid had no obvious effect on the growth of L. ;lactis. However, when the temperature was abruptly shifted from 30 °C to 42 °C at mid-growth phase the growth decreased by 50%.     

Rapid turnover of DOC in temperate forests accounts for increased CO2 production at elevated temperatures

The evidence for the contribution of soil warming to changes in atmospheric CO₂ concentrations and carbon stocks of temperate forest ecosystems is equivocal. Here, we use data from a beech/oak forest on concentrations and stable isotope ratios of dissolved organic carbon (DOC), phosphate buffer-extractable organic carbon, soil organic carbon (SOC), respiration and microbial gross assimilation of N to show that respired soil carbon originated from DOC. However, the respiration was not dependent on the DOC concentration but exceeded the daily DOC pool three to four times, suggesting that DOC was turned over several times per day. A mass flow model helped to calculate that a maximum of 40% of the daily DOC production was derived from SOC and to demonstrate that degradation of SOC is limiting respiration of DOC. The carbon flow model on SOC, DOC, microbial C mobilization/immobilization and respiration is linked by temperature-dependent microbial and enzyme activity to global warming effects of CO₂ emitted to the atmosphere.     

Inhibition of protein synthesis in reovirus-infected HeLa cells with elevated levels of interferon-induced protein kinase activity

Protein synthesis was inhibited in one line of interferon-treated HeLa cells (line 2) upon infection with reovirus, but not in different HeLa cells (line 1) treated in the same way. The inhibition resulted in polysome runoff, suggesting that it was due to an impairment of peptide chain initiation. Interferon induces the synthesis of a protein kinase, which is activated in cell-free systems by double-stranded RNA and phosphorylates the alpha subunit of eukaryotic initiation factor 2, thus inhibiting the initiation of protein synthesis. Therefore, we measured the level of this protein kinase in extracts prepared from the two HeLa cell lines. Cells of line 2 showed about 3-4 times more protein kinase activity than cells of line 1. The inhibition of protein synthesis upon infection with reovirus was correlated with an increased phosphorylation of the alpha subunit of eukaryotic initiation factor 2 in interferon-treated cells labeled with 32P. The kinase was presumably activated in intact cells by viral double-stranded RNA, but this activation resulted in inhibition of protein synthesis only in cells with elevated levels of the kinase.     

The turnover of nuclear DNA-like RNA in HeLa cells

The subcellular distribution of various types of RNA in HeLa cells is described. In addition, the relative rate of synthesis of the major classes of nuclear RNA has been determined. From these experiments it can be deduced that the heterogeneous nuclear RNA fraction is rapidly synthesized and degraded within the cell nucleus.