“…Cells used for feeder layer experiments were first trypsinized and then irradiated on ice with 30 Gy of 250 kVp X-rays 24 hr prior to the experiment. These cells were plated to give a final cell number of at least 1 x lo5 cells/60 mm dish (Highfield et al, 1984).…”
Section: Drug Treatment and Survival Assay Zpmentioning
Survival after H2O2 exposure or heat shock of asynchronous Chinese hamster ovary cells (HA-1) was assayed following pretreatment with mildly toxic doses of either H2O2 or hyperthermia. H2O2 cytotoxicity at 37 degrees C, expressed as a function of mM H2O2 was found to be dependent on cell density at the time of treatment. The density dependence reflected the ability of cells to reduce the effectiveness of H2O2 as a cytotoxic agent. When the survival data were plotted as a function of mumoles H2O2/cell at the beginning of the treatment, survival was independent of cell density. Cells pretreated with 0.1 mM (3-5 mumoles/cell X 10(-7)) H2O2 for 1 hr at 37 degrees C (30-50% survival) became resistant to a subsequent H2O2 treatment 16-36 hr after pretreatment [dose modifying factor (DMF) at 1% isosurvival = 4-6]. Their resistance to 43 degrees C heating, however, was only slightly increased over controls 16-36 hr following pretreatment (DMF at 1% isosurvival = 1.2). During this same interval, the synthesis of protein migrating in the 70 kD region of a one-dimensional SDS-polyacrylamide gel was enhanced twofold in the H2O2-pretreated cells. When the cells were heated for 15 min at 45 degrees C (40-60% survival), the survivors became extremely resistant to 43 degrees C heating and somewhat resistant to H2O2 (DMF at 1% isosurvival = 2). The heat-induced resistance to heat developed much more rapidly (reached a maximum between 6 and 13 hr) following pretreatment than the heat-induced resistance to H2O2 (16-36 hr). The enhanced synthesis of 70 kD protein after heat shock was greater in magnitude and occurred more rapidly following preheating than following H2O2 pretreatment. The cells that became resistant to H2O2 by either pretreatment (H2O2 or heat shock) also increased their ability to reduce the H2O2 cytotoxicity from the treatment medium beyond that of the untreated HA-1 cells. This may be one of the mechanisms involved in the increased resistance and a common adaptive mechanism induced by both stresses. These data indicate that mammalian cells develop resistance to H2O2 following mild pretreatment with H2O2 or heat shock. The cross-resistance induced by H2O2 and heat shock reinforce the hypothesis that some overlap in mechanisms exist between the cellular responses to these two stresses. However, the failure of H2O2 pretreatment to induce much resistance to heat indicates that there are also differences in the actions of the two agents.
“…Cells used for feeder layer experiments were first trypsinized and then irradiated on ice with 30 Gy of 250 kVp X-rays 24 hr prior to the experiment. These cells were plated to give a final cell number of at least 1 x lo5 cells/60 mm dish (Highfield et al, 1984).…”
Section: Drug Treatment and Survival Assay Zpmentioning
Survival after H2O2 exposure or heat shock of asynchronous Chinese hamster ovary cells (HA-1) was assayed following pretreatment with mildly toxic doses of either H2O2 or hyperthermia. H2O2 cytotoxicity at 37 degrees C, expressed as a function of mM H2O2 was found to be dependent on cell density at the time of treatment. The density dependence reflected the ability of cells to reduce the effectiveness of H2O2 as a cytotoxic agent. When the survival data were plotted as a function of mumoles H2O2/cell at the beginning of the treatment, survival was independent of cell density. Cells pretreated with 0.1 mM (3-5 mumoles/cell X 10(-7)) H2O2 for 1 hr at 37 degrees C (30-50% survival) became resistant to a subsequent H2O2 treatment 16-36 hr after pretreatment [dose modifying factor (DMF) at 1% isosurvival = 4-6]. Their resistance to 43 degrees C heating, however, was only slightly increased over controls 16-36 hr following pretreatment (DMF at 1% isosurvival = 1.2). During this same interval, the synthesis of protein migrating in the 70 kD region of a one-dimensional SDS-polyacrylamide gel was enhanced twofold in the H2O2-pretreated cells. When the cells were heated for 15 min at 45 degrees C (40-60% survival), the survivors became extremely resistant to 43 degrees C heating and somewhat resistant to H2O2 (DMF at 1% isosurvival = 2). The heat-induced resistance to heat developed much more rapidly (reached a maximum between 6 and 13 hr) following pretreatment than the heat-induced resistance to H2O2 (16-36 hr). The enhanced synthesis of 70 kD protein after heat shock was greater in magnitude and occurred more rapidly following preheating than following H2O2 pretreatment. The cells that became resistant to H2O2 by either pretreatment (H2O2 or heat shock) also increased their ability to reduce the H2O2 cytotoxicity from the treatment medium beyond that of the untreated HA-1 cells. This may be one of the mechanisms involved in the increased resistance and a common adaptive mechanism induced by both stresses. These data indicate that mammalian cells develop resistance to H2O2 following mild pretreatment with H2O2 or heat shock. The cross-resistance induced by H2O2 and heat shock reinforce the hypothesis that some overlap in mechanisms exist between the cellular responses to these two stresses. However, the failure of H2O2 pretreatment to induce much resistance to heat indicates that there are also differences in the actions of the two agents.
“…nuclear lamina; f, nuclear matrix fibers; nu, nucleolus. (Highfield et al, 1984). Dishes were incubated at 37°C for 10-12 days, after which time they were stained and scored for colony formation.…”
Heat shock induces changes in G1 CHO cell nuclear matrix (NM) ultrastructure that may be related to heat-induced nuclear protein accumulation (Wachsberger and Coss, 1993, J. Cell. Physiol., 155:615-634). The present study quantitates recovery of alterations in NM fine structure in CHO cells heated in G1 and compares structural recovery with recovery of bulk RNA synthesis and surviving fraction (SF). Morphology of NM preparations was quantified 30 min and 20 hr following heat shock by 1) measurement of the number of fiber anastomosing points per unit area per NM, and 2) measurement of the length of fibers between points of anastomoses within individual NMs. Architectural recovery was nearly complete within 20 hr in cells heated at 43 degrees C or 45 degrees C with SFs of 0.27 or greater. No recovery of architecture was observed in heated cells with SFs of approximately 0.01 or less. The residual damage to NMs was associated with RNA-containing fiber networks as determined by means of RNase gold labeling. Recovery from inhibition of RNA synthesis following heat shock was related to recovery of NM architecture. It is suggested that 1) repair of NM architecture does not require full recovery of bulk RNA synthesis, and 2) partial or complete irreversible collapse of the NM may be responsible, in part, for heat-induced, interphase cell death.
“…After scoring the cell, the carrier was transferred to a 35mm petri dish containing medium at 37"C, pH 7.4, and with 3.9 x lo4 lethally irradiated (2500 rads) feeder cells (Highfield et al, 1984) which had been plated 6-24 hr prior to the experiment. Cells from the same spinner flasks were also plated into 25cm2 culture flasks, con- To prevent injury to the cell, two 2mm wide runners were used to provide spacing between the cell and the coverslip; this is most important for the heated cells.…”
Heating synchronous G1 cells at 45.5 degrees C for 3-20 min induced varying degrees of membrane blebbing ranging from nonblebbed cells indistinguishable from control cells to those with blebs larger than the cell itself. Both the proportion of cells exhibiting blebbing and the mean diameter of the blebs increased with heating duration. Scoring individual cells for both blebbing and colony formation demonstrated that cells with blebs larger than 50% of the cell diameter did not survive to form colonies. Electron microscopy showed that all subcellular organelles, save the ribosomes, were absent from the membrane blebs. Freeze fracture replicas revealed no changes in membrane ultrastructure, except on some 15% of the blebs that contained bald patches devoid of membrane particles.
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