X-ray-induced cell death in the testis of dermestid beetles (Dermestes: Coleoptera)

Cell killing by X-ray was studied in six species of dermestid beetle. Unencysted spermatogonia show dose-response kinetics typical of eukaryotic cells with a shoulder at low exposures followed by an exponential decline. In contrasts primary spermatocytes, which are encysted and have cytoplasmic connections, show unusual dose-response kinetics with no shoulder at low doses. Also, the spermatocytes do not die independently but in groups, usually with whole cysts degenerating synchronously. It thus appears that the mechanism of cell death may be quite different in the two cell types.     

The role of lysosomal enzymes in killing of mammalian cells by the lysosomotropic detergent N-dodecylimidazole

The sensitivity of cultured human and hamster fibroblast cells to killing by the lysosomotropic detergent N-dodecylimidazole (C12-Im) was investigated as a function of cellular levels of general lysosomal hydrolase activity, and specifically of cysteine cathepsin activity. Fibroblasts from patients with mucolipidosis II (I-cell disease) lack mannose-6-phosphate-containing proteins, and therefore possess only 10-15% of the normal level of most lysosomal hydrolases. I-cell fibroblasts are about one-half as sensitive to killing by C12-Im as are normal human fibroblasts. Overall lysosomal enzyme levels of CHO cells were experimentally manipulated in several ways without affecting cell viability: Growth in the presence of 10 mM ammonium chloride resulted in a gradual decrease in lysosomal enzyme content to 10-20% of control values within 3 d. Subsequent removal of ammonium chloride from the growth medium resulted in an increase in lysosomal enzymes, to approximately 125% of control values within 24 h. Treatment with 80 mM sucrose caused extensive vacuolization within 2 h; lysosomal enzyme levels remained at control levels for at least 6 h, but increased 15-fold after 24 h of treatment. Treatment with concanavalin A (50 micrograms/ml) also caused rapid (within 2 h) vacuolation with a sevenfold rise in lysosomal enzyme levels occurring only after 24 h. The sensitivity of these experimentally manipulated cells to killing by C12-Im always paralleled the measured intracellular lysosomal enzyme levels: lower levels were associated with decreased sensitivity while higher levels were associated with increased sensitivity, regardless of the degree of vacuolization of the cells. The cytotoxicity of the cysteine proteases (chiefly cathepsin L in our cells) was tested by inactivating them with the irreversible inhibitor E-64 (100 micrograms/ml). Cell viability, protein levels, and other lysosomal enzymes were unaffected, but cysteine cathepsin activity was reduced to less than 20% of control values. E-64-treated cells were almost completely resistant to C12-Im treatment, although lysosomal disruption appeared normal by fluorescent visualization of Lucifer Yellow CH-loaded cells. It is concluded that cysteine cathepsins are the major or sole cytotoxic agents released from lysosomes by C12-Im. These observations also confirm the previous conclusions that C12-Im kills cells as a consequence of lysosomal disruption.     

Comparison of protein synthesis inhibition kinetics and cell killing induced by immunotoxins

Immunotoxins comprised of a monoclonal antibody covalently coupled to recombinant ricin A chain or to a binding-defective form of diphtheria toxin were compared with respect to their rates of protein synthesis inhibition and efficiencies of killing target cells. Protein synthesis inhibition rates were established by measuring the incorporation of L-[14C]leucine in toxin-treated cells relative to untreated cells at several times after exposure of cells to an immunotoxin. Cell killing was assessed by a limiting dilution assay which measures the number of cells surviving toxin treatment relative to untreated cells. At equivalent protein concentrations, the diphtheria toxin immunotoxin inhibited protein synthesis significantly more rapidly than the ricin A immunotoxin but, contrary to previous predictions, achieved a significantly lower cell kill. Thus, the kinetics of protein synthesis inactivation do not necessarily correlate with killing efficiencies. Possible explanations for these results are that the effect of the diphtheria toxin immunotoxin on protein synthesis is partially reversible or that the diphtheria toxin immunotoxin enters the cytosol at a faster rate than the ricin A immunotoxin but also is degraded at a faster rate.     

In vitro generation of human activated lymphocyte killer cells: separate precursors and modes of generation of NK-like cells and "anomalous" killer cells

The activation of human peripheral blood mononuclear cells (PBM) in culture leads to the generation of nonspecific killer cells. These cells, termed activated lymphocyte killer (ALK) cells, can kill fresh tumor cells and tumor cell lines, in addition to the natural killer (NK) cell sensitive target K562. ALK cells have features in common with both T and NK cells, but their nature and origin are unknown. In the present study, it is shown that ALK cells are in fact heterogeneous and can be generated from both large granular lymphocytes with the same phenotype as NK cells and from T cells. Cell populations enriched for NK cells, when cultured with lymphokines, rapidly acquired a T cell phenotype, enhanced cytolytic activity against K562, and the ability to lyse NK-insensitive target cells such as a melanoma cell line LiBr; these ALK cells were described as NK-like cells. On the other hand, of the cloned cells derived from PBM stimulated with irradiated B lymphoblasts and grown in lymphokines, the major proportion of cytolytic T cells (CTC) able to kill the specific stimulator lymphoblasts were also found to kill LiBr but not K562 cells. These ALK cells, which were derived from the same precursors as CTC, were designated anomalous killer (AK) cells. Consistent with this, the presence of the pan T monoclonal antibody UCHT1 from the beginning of mixed cell cultures inhibited the generation of CTC and of the AK-type of ALK cell, which killed melanoma cells, but not the NK type, which killed K562 targets. By contrast, at the effector cell level, the antibodies UCHT1 and OKT8 only blocked specific killing by CTC but did not block the killing of LiBr or of K562 targets by ALK cells. However, at the effector cell level there was additional evidence for the heterogeneity of ALK cells. Thus, monoclonal antibody 9.1C3, which blocks killing by freshly isolated NK cells, also blocked the killing of K562 targets by NK-like cells, but did not block B lymphoblast killing by CTC or melanoma cell killing by AK cells. It is concluded that after mixed lymphocyte culture, the majority of ALK cells measured by the killing of melanoma target cells arise from the same precursors and are under the same influences as classical CTC (AK cells), whereas cells killing K562 targets are derived from NK cells (NK-like cells). Once generated, the AK cells have a different mechanism of killing from both classical CTC and from NK and NK-like cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

Effect of glycerol and low pH on heat-induced cell killing and loss of cellular DNA polymerase activities in Chinese hamster ovary cells

A whole-cell assay technique for DNA polymerase alpha and beta was used to measure the activities of both enzymes in Chinese hamster ovary (CHO) cells after hyperthermic treatment of 42.2 - 45.5 degrees C in acidic or basic environment and in the presence or absence of 5% glycerol. Cell survival was measured at the same time, and the DNA polymerase activities were correlated with survival. The results show a positive correlation between cell killing by heat and loss of DNA polymerase beta activity, both when cells were sensitized to heat by treatment at pH 6.7 with or without glycerol and when cells were protected from heat by treatment with 5% glycerol at pH 7.4 or 6.7. The results show a poor correlation between loss of DNA polymerase alpha activity and cell survival; i.e., compared to cell killing, the loss of DNA polymerase alpha activity was sensitized to heat more by acidic treatment without glycerol and was protected less from heat by glycerol treatment at normal physiological pH (pH 7.4). However, cell killing and loss of polymerase alpha activity did correlate well for sensitization to heat by acidic treatment in the presence of glycerol and for protection from heat by glycerol treatment at low pH. These results considered with other hyperthermia-polymerase studies suggest that heat effects on membranes can apparently result in changes in environmental conditions within the cell (secondary effects), which can in turn alter polymerase activities and/or the direct or secondary effect of heat on the polymerase enzymes. Furthermore, loss of polymerase beta activity serves as a better index of thermal damage resulting in cell death than loss of alpha activity.     

Cell killing by Frog Virus 3: Evidence for cell killing by single viral particles or single viral subunits

Cell killing by Frog Virus 3 was assayed after infection of chinese hamster ovary cells under non permissive conditions for virus multiplication. The kinetics of the loss in the efficiency of colony formation as a function of the virus multiplicity indicated that infection of a cell with a single viral particle brought about cell death. About 15 percent of the cells exhibited transient resistance to killing by single viral particles. Treatment of cells with proteins solubilized from Frog Virus 3 also resulted in cell killing with one hit kinetics thus implying that the interaction with a single viral subunit sufficed to entail cell death.     

Butachlor is cytotoxic and clastogenic and induces apoptosis in mammalian cells

The ability of butachlor to induce cytotoxicity, clastogenicity and DNA damage was assessed using Chinese hamster ovary cells (CHO), Swiss mouse embryo fibroblasts (MEF) and human peripheral blood lymphocytes. A dose and time dependent loss of viability was evident upon treatment of CHO cells with butachlor. Cell killing to an extent of 50% was observed when cells were treated with 16.2 micrograms/ml of butachlor for 24 hr or with 11.5 micrograms/ml for 48 hr. The herbicide induced micronuclei significantly in cultured lymphocytes at 24 and 48 hr of treatment suggesting that it is clastogenic. To understand the mechanism of cell death caused by butachlor, its effect on DNA strand breaks was studied in MEF. A concomitant decrease in cell viability was observed with increase in DNA strand breaks. Agarose gel electrophoresis of DNA from herbicide treated CHO cells and cytochemical staining indicate the induction of apoptosis by butachlor.     

Control of cytolysis of BALB/c-3T3 cells by platelet-derived growth factor: a model system for analyzing cell death

In culture medium supplemented with 10% clotted blood serum, the saturation density of BALB/c-3T3 cells is determined jointly by cell replication and cell loss. By prelabelling cellular DNA with ³H-thymidine and also by time lapse photography, we studied cell loss independently of replication. Cell loss was accelerated when BALB/c-3T3 cells were transferred from serum-supplemented medium, which contains the platelet derived growth factor (PDGF), to medium supplemented with platelet-poor plasma which lacks it. Loss occurred via the disintegration of cell attached to the surface of the tissue culture dish. Cytolysis of individual cells occurred rapidly; less than 15 minutes transpired between the first indication of a perturbance (by phase contrast microscopy) and fragmentation of the cell cytoplasm. Kinetic analysis was consistent with random cell death rather than a fixed lifetime. The percentage of cells undergoing cytolysis was governed by the cell density; at high densities, such as are present in confluent cultures, a higher percentage of cell loss was noted than at low density. Cell death was antagonized by partially purified or electrophoretically homogenous preparations of-PDGF. Pure PDGF stimulated cell survivial at ng/ml in a concentration dependent fashion. The process of cell replication was not necessary for survival because PDGF prevented cytolysis in the presence of methotrexate, an inhibitor of DNA synthesis. A brief (4 hour) treatment with PDGF prevented cell death; such PDGF treated cells displayed increased survival after being taken up with trypsin and planted onto a fresh surface in plasma supplemented medium. Pituitary fibroblast growth factor, a functional analogue of PDGF for induc of DNA synthesis in BALB/c-3T3 cells, also functioned as an anticytolytic agent. By contrast, epidermal growth factor and insulin did not. Cytolysis of SV40-transformed cells occurred at a constitutively low rate and was insensitive to PDGF.     

Caffeine-induced modulation of the lethal action of X rays on Chinese hamster V79 cells

Caffeine-mediated enhancement of the killing of V79 cells by 220-kV X rays at various times in the cell cycle was compared with that of HeLa cells by measuring (i) the dependence of cell survival on the duration of treatment with 5-10 mM caffeine, (ii) the effect of caffeine treatment on the X-ray dose-survival curve, and (iii) the loss of sensitivity to caffeine as a function of time after irradiation. The behavior of V79, while similar in many respects to that of HeLa (reported previously), differs in several ways. Caffeine treatment causes rapid killing immediately after irradiation irrespective of cell age, while HeLa is refractory in S phase and highly sensitive in G2. As with HeLa, the (multitarget) dose-survival curve parameters are reduced by caffeine treatment, but the age-dependent fluctuations in D0 are not eliminated as completely as with HeLa and the extrapolation number assumes values less than unity in the latter part of the cycle rather than in the early part. Loss of sensitivity to caffeine after irradiation early in the cycle appears to undergo a transient reversal in the middle of the cycle, a phenomenon not observed in HeLa.     

Heat-induced K+ loss, trypan blue uptake, and cell lysis in different cell lines: effect of serum

Experiments were performed with three different cell lines, mouse fibroblast LM cells, HeLa S3 cells, and Ehrlich Ascites Tumor (EAT) cells, to establish the possible importance of hyperthermic-induced alterations in cellular K+ content in the mechanism of cell killing by heat. At different time points after the hyperthermic treatment, the K+ content in the cells, the uptake of the dye Trypan Blue (TB), and cell lysis were assayed. Heat-induced K+ loss preceded TB uptake which was followed by the heat-induced cell lysis. Lysis was assayed as disappearance of cells by counting the cells at different time points in a hematocytometer. The presence of serum during and after the heat treatment was of considerable importance with respect to K+ loss and TB uptake. K+ loss and TB uptake after the heat treatment were less when serum was present during and after hyperthermia. To protect against cell lysis, however, the serum had to be present during a preincubation period of 24 h. Clonogenic ability was not affected by the presence of serum. It is concluded that the intracellular K+ level of hyperthermic-treated cells is not a direct cause for cell killing and that heat-induced alterations in the cell leading to cell lysis are different from the processes decreasing cellular K+ content and permeabilizing the plasma membrane for trypan blue.     

Spermatogonial stem cell killing in the mouse following single and fractionated X-ray doses,as assessed by length of sterile period

When length of sterile period is taken as a measure of spermatogonial stem cell killing, the dose-response curve following X-irradiation indicates the existence of two stem cell populations. It is not possible to distinguish whether these represent different cell types or different stages in the cell cycle of a single cell type but, on the basis of the published cytological and genetical evidence, the former is considered the more likely. It is suggested that the two cell populations may provide the basis for the heterogeneity of the spermatogonial stem cell, proposed as an explationation for the humped dose-response curves for genetic damage.24-h fractionated doses demonstrated diverse responses relative to the single treatments at different total doses. These suggested that the first fraction alters the relative sensitivities of the two stem cell populations to killing and/or genetic damage by the second fraction. It is concluded that (1) with higher single doses, drop in yield of genetic damage stems, not from greater cell killing as such, but from a tendency for coincidence of genetic damage and cell killing in the same cells, (2) with 24-h fractionated treatments, the cell killing brought about by the second fraction tends to occur in different cells from those in which genetic damage had been induced by the first fraction.     

Salivary histatin 5 internalization by translocation,but not endocytosis,is required for fungicidal activity in Candida albicans

Salivary histatin 5 (Hst 5) is a cationic salivary protein with high fungicidal activity against Candida albicans. Binding to the cell wall followed by intracellular translocation is required for killing; however, specific binding components and critical toxic events are not understood. In this study, laminarin (β‐1,3‐glucan) but not sialic acid, mannan or pustulan mediated Hst 5 binding to C. albicans, and was disassociated by 100 mM NaCl. Time‐lapse confocal microscopy revealed a dose‐dependent rate of cytosolic uptake of Hst 5 that invariably preceded propidium iodide (PI) entry, demonstrating that translocation itself does not disrupt membrane integrity. Cell toxicity was manifest by vacuolar expansion followed by PI entrance; however, loss of endocytotic vacuolar trafficking of Hst 5 did not reduce killing. Extracellular NaCl (100 mM), but not sorbitol, prevented vacuolar expansion and PI entry in cells already containing cytosolic Hst 5, thus showing a critical role for ionic balance in Hst 5 toxicity. Hst 5 uptake, but not cell wall binding, was blocked by pretreatment with azide or carbonyl cyanide m‐chlorophenylhydrazone; however, 10% of de‐energized cells had membrane disruption. Thus, Hst 5 is capable of heterogeneous intracellular entry routes, but only direct cytosolic translocation causes cell death as a result of ionic efflux.     

The role of nerve growth factor in vitro in cell resistance to 6-hydroxydopamine toxicity.

Cell resistance to the catecholaminergic neurotoxin 6-hydroxydopamine was studied in various cell lines: human neuroblastoma lines SK-N-MC. SK-N-SH, and SK-N-SH-SY5Y; and non-neuroblastoma lines CHO-K1, S-180, C-6, and L-M, the latter three of which synthesize nerve growth factor. Cells were treated one day after seeding for 1 h with 6OHDA. Cytotoxicity of the drug was quantified as the percent live cells, determined by the trypan blue exclusion test, 24 h after treatment. At 100 μg/ml, 6OHDA lethal toxicity was confined mainly to neuroblastoma cells. However, drug specificity was dependent not only on cell type, but also on cell density and presence of NGF. Thus, the non-neuroblastoma cell strain S-180-A, which produces less NGF than its parent line S-180, lost resistance to toxicity at low cell density, and even at high density was less resistant than SK-N-MC neuroblastoma cells. Moreover, when mouse β-NGF (500 BU/ml) was administered to human neuroblastoma clones SY5Y and IN one day after seeding for 24 h before drug treatment, the cell survival rate increased significantly, although only SY5Y cells were protected by a lower concentration (1 BU/ml) of exogenous NGF. Finally, cell line S-180 became susceptible to 6OHDA killing when incubated one hour with high titer anti-mouse β-NGF immediately prior to drug treatment, whereas cell line C-6 did not. NGF was therefore proposed to have an important, though not determinative, role in cell resistance to 6OHDA toxicity.     

Studies on the mechanisms of mammalian cell killing by a freeze-thaw cycle: conditions that prevent cell killing using nucleated freezing

Normally a freeze-thaw cycle is a very efficient method of killing mammalian cells. However, this report describes conditions that prevent killing of cultured mammalian cells by nucleated freezing at -24 degrees C. Optimal protection from cell killing at -24 degrees C was obtained in isotonic solutions containing an organic cryoprotectant such as dimethyl sulfoxide (DMSO; 10%, v/v), a saccharide such as sucrose over a broad concentration range from 50 to 150 mM, and glucose. Glycerol was also an effective cryoprotectant but other organic solvents were ineffective, although in some cases they appeared to protect cell membranes, while not protecting other vital components. A wide variety of saccharide structures were effective at protecting cells from freeze-thaw killing, with trehalose being particularly effective. The degree of resistance to killing by a freeze-thaw cycle under these conditions varied widely among different cell lines. If toxicity of DMSO was responsible for this variability of cryoprotection, it must have been due to short-term, not longer term, toxicity of DMSO. Studies on the mechanism by which cells are protected from killing under these conditions indicated that neither vitrification of the medium nor the concentrating of components during freezing were involved. One model not eliminated by the mechanistic studies proposes that the organic solvent cryoprotectant component acts by fluidizing membranes under the thawing conditions, so that any holes produced by ice crystals propagating through membranes can reseal during the thawing process. In this model one of the mechanisms by which the saccharide component could act is by entering the cells and stabilizing vital intracellular components. Consistent with this, a freeze-thaw cycle promoted the uptake of labeled sucrose into cultured cells.     

Effects of various physical and chemical factors on excystation of the encysted metacercariae of Echinostoma caproni

Various physical and chemical factors were studied to determine their effects on the viability of encysted metacercariae of Echinostoma caproni. Viability was equated with chemical excystation in an alkaline trypsin-bile salts (TB) medium. Control cysts showed excystation percentages of > 90% in TB. Excystation proved to be a more reliable criterion of cyst viability than observations by light microscopy. Isolated cysts and cysts left in the snail (in situ cysts) were studied. Generally, in situ cysts proved more resistant to various physical and chemical treatments than did isolated cysts. Cysts stored for 7 days at 28 C in a Locke's 1:1 solution showed 97% excystation, suggesting that cysts of this species would survive postal delays during shipment. Of numerous marinades tested, the one that was most harmful to isolated and in situ cysts was vinegar. Isolated and in situ cysts were killed by boiling (100 C) for 1 or 3 min, but freezing at -10 C did not kill all isolated or in situ cysts after 24 hr. Concentrations of potassium permanganate ranging from 300 to 1,200 mg/L killed most isolated cysts within 5 min, but in situ cysts survived these concentrations for 24 hr. Concentrated solutions of NaCl and sucrose had no effect on the viability of isolated and in situ cysts, suggesting that their use in food preparations for molluscs would not be effective in killing echinostomatid cysts in tainted snail tissues.     

A quantitative assessment of the cytotoxicity associated with chromosomal aberration detection in Chinese hamster ovary cells.

Regulatory guidelines suggest testing chemicals up to cytotoxic doses in chromosomal-aberration assays. To investigate the utility and limitations of various cytotoxicity indicators we used Chinese hamster ovary (CHO) cells to test 8 chemicals with differing ratios of cytotoxicity to clastogenicity. We measured immediate or delayed cell killing and growth inhibition (ATP levels, cell counts, colony-forming efficiency, CFE) and cell-cycle perturbations (mitotic index, MI; average generation time, AGT). Aberrations (abs) were scored 10 and 24 h from the beginning of the 3-h treatment. All 8 compounds induced abs at concentrations that reduced cell growth at 24 h by 50% or less. Concentrations of each chemical which induced at least 15% cells with abs, gave little loss of CFE (0-20%) for mitomycin C, adriamycin, cadmium sulfate and 2,6-diaminotoluene in contrast to the marked loss of CFE (70-80%) for eugenol (EUG), 2-aminobiphenyl and 8-hydroxyquinoline (8-HQ). 2,4-Diaminotoluene (2,4-DAT) was intermediate. Higher aberration yields were found at 24 h than at 10 h, even when minimal cell-cycle delay was detected by AGT estimates from BrdUrd-labeled cells. Cells with multiple abs were seen at 24 but not at 10 h, and often confirmed clastogenicity when there was only a weak increase in the percentage of cells with aberrations. Total ATP per culture did not always correlate with cell number, especially at later times after treatment. This is likely due to metabolic perturbations or altered cell biomass that are known to affect cell ATP content. MI suppression often did not correlate with AGT, e.g., only small increases in AGT were seen for 8-HQ, 2,4-DAT and EUG despite severe mitotic suppression at 10 h. By 24 h the MI for all chemicals had recovered, sometimes exceeding control levels. Marked mitotic accumulation was seen at 10 h for 2,4-DAT, indicating cell synchrony. Thus, the MI has limited value for dose selection. In conclusion, even weakly active chemicals were detected at a single time without exceeding a 50% growth reduction at 24 h.     

The interaction of Acanthamoeba castellanii cysts with macrophages and neutrophils

Acanthamoeba castellanii, a free-living amoeba, causes a sight-threatening form of keratitis. Even after extensive therapies, corneal damage can be severe, often requiring corneal transplantation to restore vision. However, A. castellanii cysts are not eliminated from the conjunctiva and stroma of humans and can excyst, resulting in infection of the corneal transplant. The aim of this study was to determine whether elements of the innate immune apparatus, neutrophils and macrophages, were capable of detecting and eliminating A. castellanii cysts and to examine the mechanism by which they kill the cysts. Results show that neither innate immune cell is attracted chemotactically to intact cysts, yet both were attracted to lysed cysts. Both macrophages and neutrophils were capable of killing significant numbers of cysts, yet neutrophils were 3-fold more efficient than macrophages. Activation of macrophages with lipopolysaccharide and interferon-gamma did not increase their cytolytic ability. Conditioned medium isolated from macrophages did not lyse the cysts; however, prevention of phagocytosis by cytochalasin D inhibited 100% of macrophage-mediated killing of the cysts. Conditioned medium from neutrophils did kill significant numbers of the cysts, and this killing was blocked by quercetin, a potent inhibitor of myeloperoxidase (MPO). These results indicate that neither macrophages nor neutrophils are chemoattracted to intact cysts, yet both are capable of killing the cysts. Macrophages killed the cysts by phagocytosis, whereas neutrophils killed cysts through the secretion of MPO.     

Mammalian cells are not killed by DNA single-strand breaks caused by hydroxyl radicals from hydrogen peroxide

Cell killing by ionizing radiation has been shown to be caused by hydroxyl free radicals formed by water radiolysis. We have previously suggested that the killing is not caused by individual OH free radicals but by the interaction of volumes of high radical density with DNA to cause locally multiply damaged sites (LMDS) (J. F. Ward, Radiat. Res. 86, 185-195, 1985). Here we test this hypothesis using hydrogen peroxide as an alternate source of OH radicals. The route to OH production from H2O2 is expected to cause singly damaged sites rather than LMDS. Chinese hamster V79-171 cells were treated with H2O2 at varying concentrations for varying times at 0 degree C. DNA damage produced intracellularly was measured by alkaline elution and quantitated in terms of Gray-equivalent damage by comparing the rate of its elution with that of DNA from gamma-irradiated cells. The yield of DNA damage produced increases with increasing concentration of H2O2 and with time of exposure. H2O2 is efficient in producing single-strand breaks; treatment with 50 microM for 30 min produces damage equivalent to that formed by 10 Gy of gamma irradiation. In the presence of a hydroxyl radical scavenger, dimethyl sulfoxide (DMSO), the yield of damage decreases with increasing DMSO concentration consistent with the scavenging of hydroxyl radicals traveling an average of 15 A prior to reacting with the DNA. In contrast to DNA damage production, cell killing by H2O2 treatment at 0 degree C is inefficient. Concentrations of 5 X 10(-2) M H2O2 for 10 min are required to produce significant cell killing; the DNA damage yield from this treatment can be calculated to be equivalent to 6000 Gy of gamma irradiation. The conclusion drawn is that individual DNA damage sites are ineffectual in killing cells. Mechanisms are suggested for killing at 0 degree C at high concentrations and for the efficient cell killing by H2O2 at 37 degrees C at much lower concentrations.     

Modulation of natural killer cell activity by surface phosphorylation reactions

To determine whether phosphorylation of cell surface proteins is involved in NK cell activity, the phosphorylation patterns of a rat NK cell line (RNK-16) incubated with 12.5 microM [gamma-32P]ATP were characterized before and after exposure to YAC-1 cells, which serve as targets for killing, and K562 cells, which are not killed by RNK-16 cells. By 51Cr release assays, the inhibitory effect of ATP on RNK-16 killing activity previously reported was corroborated. RNK-16 cells prelabeled with 12.5 microM ATP show enhanced labeling of a 70- to 72,000-Da protein after exposure to unlabeled target YAC-1 cells but not after exposure to K562 cells. A protein of similar apparent molecular size is also labeled upon exposure of RNK-16 cells to OX-34, an antibody which binds and inhibits killing, as well as upon exposure to OX-18, which also binds but does not inhibit NK activity. These findings are indicative of the activation of a kinase with high affinity for [gamma-32P]ATP, which phosphorylates an endogenous surface substrate of 70-72,000 Da upon binding of macromolecules to the RNK-16 cells. RNK-16 cells, previously labeled with micromolars [gamma-32P]ATP and subsequently treated with millimolars unlabeled ATP, showed loss of label from a 110,000-Da protein component, indicative of the rapid turnover of a phosphate group on a surface protein. Thus, extracellular ATP enhances the phosphorylation of a 70- to 72,000-Da component upon binding of RNK-16 cells to target cells or upon binding of antibodies at micromolar concentrations of ATP and catalyzes the loss of phosphate from a 110,000-Da component at millimolar concentrations of ATP. These findings reflect a complex repertoire of surface phosphorylation changes which occur in RNK-16 cells.     

Formation of tight junctions and desmosomes protects MDCK cells against hyperthermic killing

Cell density is known to modify the survival of mammalian cells exposed to elevated temperatures. We have examined the role that cell–cell contact plays in this phenomenon. The formation of cell–cell contact is carried out by cells' junctional complex, i.e., tight junctions, desmosomes, and gap junctions. Lack of formation of tight junctions and desmosomes, or their opening, could interfere with the functions and structures of cell membrane. Membrane damage is at least partially responsible for cell death at elevated temperatures. MDCK cells with high density plated in low calcium medium form confluent monolayers devoid of the formation of tight junctions and desmosomes but quickly assemble them after Ca²⁺ restoration. We used MDCK cells and the calcium switch technique to investigate effects of cell–cell contact and, independently, of cell density on hyperthermic cell killing. We found that MDCK cells that formed tight junctions and desmosomes were more resistant to hyperthermic treatment than those that did not. Blocking the formation pathway of tight junctions made cells sensitive to heat. Cells growing at lowdensity showed almost the same survival as did cells at high density in the absence of the formation of tight junctions and desmosomes. The results suggest that the formation of tight junctions and desmosomes play a more important role in determining hyperthermic response than does density per se. The formation of tight junctions and desmosomes appears to protect cells modestly against hyperthermic killing. © 1994 Wiley-Liss, Inc.