Increase of MnSOD expression and decrease of JNK activity determine the TNF sensitivity in bcl2-transfected L929 cells.

To investigate the protection mechanism of Bcl-2 against tumour necrosis factor (TNF)-mediated cell death, the bcl2 gene was transfected into the L929 cells and stably expressed. Two clones having different sensitivity among bcl2-transfected L929 clones had been isolated, and termed clone R1 and R2. It was observed that activation of manganese superoxide dismutase (MnSOD) and suppression of Jun kinase of clone R1 and R2 were correlated with protection from TNF cytotoxicity. Upon treatment with TNF, clone R1 and R2 were more resistant than control L929 cells against TNF cytotoxicity and the protective effect of clone R1 was stronger than clone R2. However, in case of TNF plus actinomycin D treatment, clone R1 was still resistant against TNF cytotoxicity, whereas clone R2 became more sensitive than control L929 cells. The JNK activities of clone R1 and R2 were suppressed upon TNF treatment and in case of TNF plus actinomycin D treatment, clone R2 showed a marked increase in JNK activities and had higher activity than control L929 cells. The specific activities of MnSOD of clone R1 and R2 upon TNF treatment were 70 U/ml and 33 U/ml, respectively, while the MnSOD activity was not detectable in control L929 cells. When TNF and actinomycin D were treated simultaneously, MnSOD activity was not detectable in control L929 cells and bcl2 -transfected L929 cells (clone R1, R2). Consistent with these results, both clone R1 and R2 showed higher levels of MnSOD mRNA expression than control L929 cells after TNF treatment. These data suggest that suppression of Jun kinase and increase of MnSOD may be involved in inhibitory action of Bcl-2 against TNF, and the balance between MnSOD and JNK signalling pathway may be an important factor for the protection of bcl2-transfected L929 cells from TNF cytotoxicity.     

Binding of human tumor necrosis factor to high affinity receptors on HeLa and lymphoblastoid cells sensitive to growth inhibition

Purified human tumor necrosis factor (TNF) was iodinated to high specific activity with good retention of its biological activity, as determined by the cytotoxic titer on murine L929 cells. The binding of 125I-TNF to L929 and human HeLa S2 cells grown in monolayer was initially measured, but high levels of nonspecific binding were observed. Specific binding to high affinity receptors of HeLa S2 cells grown in suspension culture was demonstrated by competitive displacement experiments and analysis of the binding data with the LIGAND program. A KD of 2 X 10(-10) M and 6000 receptors/cell were calculated in this way. These observations provide the first direct evidence for a cellular receptor for TNF. The cell-bound 125I-TNF was internalized at 37 degrees C, presumably by receptor-mediated endocytosis, and subsequently degraded to acid-soluble products. Three lines of human lymphoblastoid cells were examined for sensitivity to the cytostatic effect of TNF and for the presence of high affinity receptors. Daudi and Raji cells were insensitive to TNF and showed very few specific binding sites when incubated with 125I-TNF. Jurkat cells were growth-inhibited by TNF and showed a significantly greater number of specific binding sites than the other lymphoblastoid cells. These findings suggest that the sensitivity of some cell lines to the biological effects of TNF may be correlated with the presence of a relatively high number of receptors for this factor.     

Human papillomavirus type 16 E6-enhanced susceptibility of L929 cells to tumor necrosis factor alpha correlates with increased accumulation of reactive oxygen species.

Human papillomavirus type 16 (HPV-16) E6 has been shown to prevent or enhance apoptosis depending on the stimulus and cell type. Here we present evidence that HPV-16 E6 sensitized murine fibrosarcoma L929 cells to tumor necrosis factor alpha (TNF)-induced cytolysis. The E6-enhanced cytolysis correlated with a precedent increase in reactive oxygen species (ROS) level and antioxidant treatment could completely block the E6-dependent sensitization. These findings represent the first demonstration of a link between a viral oncogene-sensitized cytolysis and ROS. Previous studies have shown conflicting results regarding whether TNF-induced cytolysis of L929 cells is through necrosis or apoptosis. Here we report that, although L929 cells underwent DNA fragmentation after exposure to TNF, they retained the morphology of intact nuclei while gaining permeability to propidium iodide, features characteristic of necrosis rather than apoptosis. We confirmed that the broad spectrum caspase inhibitor benzyloxycarbonyl-Val-Ala-Asp(OMe)-fluoromethylketone markedly increased the susceptibility of L929 cells to TNF, and further demonstrated that E6 enhanced this susceptibility, which again correlated with increased ROS accumulation. We showed that the expression of E6 in L929 cells did not alter the stability of p53, and the cells retained a p53 response to actinomycin D. Furthermore, two E6 mutants defective for p53 degradation in other systems exhibited differential effects on TNF sensitization. These results suggest that the enhancement of TNF-induced L929 cytolysis by E6 is independent of p53 degradation. We also found that TNF-induced activation of NF-kappaB did not account for the enhanced TNF susceptibility by E6.     

The effect of modifying terminal oligonucleotide linkages on their stability in cell cultures

The effect of modification of terminal groups of deoxyribooligonucleotides on their stability in cell culture and inside mammalian cells, namely Krebs 2, ascite carcinoma (KAC) and mouse fibroblasts L929, has been investigated. Oligonucleotides and their derivatives were found to be stable in culture medium without serum during 24 h. In the medium with KAC cells or ascitic fluid, orthophosphate was rapidly eliminated from the 5'-terminus of the oligonucleotides. In KAC cells, the scission of 5'-phosphomonoester bonds was accompanied by reutilization of the phosphate and by degradation of oligonucleotides to mononucleotides. In the medium with fibroblasts L929, the oligonucleotides were degraded from the 3'-end to tetranucleotides. Modification of oligonucleotides at the 5'-terminus by amidation made the 5'-phosphate groups resistant to KAC. Modification of the oligonucleotides by coupling of cholesterol or phenazinium to the 3'-terminus sufficiently increases their stability in the medium with fibroblasts L929, in that with Krebs 2 ascite carcinoma cells and inside the cells.     

TGF-beta-induced matrix proteins inhibit p42/44 MAPK and JNK activation and suppress TNF-mediated IkappaBalpha degradation and NF-kappaB nuclear translocation in L929 fibroblasts

The role of transforming growth factor beta1 (TGF-beta1)-induced extracellular matrix proteins in the modulation of cellular response to the cytotoxic effect of tumor necrosis factor (TNF) or Fas ligand was investigated. Murine L929 fibroblasts were prestimulated with or without TGF-beta1 for 1-24 h and the resulting extracellular protein matrices were prepared. Unstimulated control L929 cells were then cultured on these matrices. Compared to control matrix-stimulated L929 cells, the TGF-beta1 matrix-stimulated cells resisted TNF killing in the presence of actinomycin D (ActD), but became more susceptible to killing by anti-Fas antibodies/ActD. The induced TNF resistance is independent of the NF-kappaB antiapoptotic effect. For example, exposure of TGF-beta1 matrix-stimulated L929 cells to TNF failed to result in IkappaBalpha degradation and NF-kappaB nuclear translocation or activation. Also, control matrix stimulated the activation of p42/44 mitogen-activated protein kinase (MAPK) and c-Jun N-terminal kinase (JNK) in L929 cells, whereas TGF-beta1 matrix suppressed the activation. Nonetheless, in response to TNF, JNK activation was restored in the TGF-beta1 matrix-stimulated cells. By metabolic labeling, ammonium sulfate precipitation and N-terminal amino acid microsequencing, TGF-beta1 was shown to induce a novel matrix protein of 46 kDa (p46) from L929 cells. Adsorption of p46 by peptide antibodies against its N-terminus removed the TGF-beta1 matrix protein-mediated protection against TNF/ActD cytotoxicity and its enhancement of anti-Fas/ActD killing, indicating that p46 is responsible for these effects. Immunostaining of L929 cells revealed that the antibodies were bound to a membrane protein of 100 kDa (p100). Thus, the matrix p46 is likely derived from the released membrane p100.     

Continuous internalization of tumor necrosis factor receptors in a human myosarcoma cell line

The cell dynamics of the receptor for tumor necrosis factor (TNF) were examined in TNF-sensitive KYM cells derived from human myosarcoma. With receptor synthesis inhibited by cycloheximide, the half-life of the surface TNF receptor was 2 h in the absence of TNF and 30 min in its presence, suggesting that the TNF receptor is non-recycling and that its internalization is accelerated by TNF. During cell incubation with TNF receptor degradation suppressed by chloroquine, the number of surface TNF receptors remained approximately constant, but the total number of surface and internal TNF receptors increased gradually, at 3 h reaching 1.5 times the initial number, thus suggesting continuous synthesis, externalization, internalization, and degradation of the TNF receptor in the absence of cycloheximide. On cell incubation with 125I-TNF, the intracellular quantity of the pulse-labeled TNF-receptor complex promptly increased, reaching a maximum at 20 min, and then gradually declined, thus confirming that the TNF receptor is internalized as a TNF-receptor complex in the presence of TNF. During incubations with protein synthesis suppressed by cycloheximide following surface TNF receptor digestion by trypsin, TNF receptors reappeared on the cell surface, increasing in number to a peak at 60 min and gradually decreasing, and cells previously exposed to cycloheximide with or without TNF showed no recurrence of surface TNF receptors, suggesting that the TNF receptor is non-recycling. The results of the study thus suggest that the TNF receptor is continuously internalized and degraded intracellularly by lysosomes without being recycled regardless of the presence or absence of TNF and, further, that its internalization is accelerated when it is part of the TNF-receptor complex.     

Involvement of prostaglandin-producing pathway in the cytotoxic action of tumor necrosis factor.

To elucidate the cytotoxic mechanism of tumor necrosis factor (TNF), we isolated TNF-resistant sublines of L929 cells. As compared with L929 cells, TNF-resistant cells retained similar number and affinity of TNF-binding sites, and showed a similar growth rate. TNF stimulated arachidonate release from L929 cells, while no stimulation was observed at all in TNF-resistant cells tested. The cytotoxic action of TNF on L929 cells was inhibited by indomethacin, suggesting that prostaglandin may be involved in the action. Therefore, TNF-stimulated prostaglandin production was examined in L929 and TNF-resistant sublines. The amount of PGE2 produced by L929 cells was increased more than 5-fold after the addition of TNF, whereas the amount of PGE2 did not change in the resistant sublines following addition of the factor. TNF-stimulated arachidonate release and PGE2 production were reversed by islet-activating protein (IAP)-treatment of L929 cells. These results suggest that arachidonate release and subsequent prostaglandin production are important for the cytotoxic action of TNF and that these processes are mediated by GTP-binding protein (G protein) that is coupled to the TNF-receptor.     

Binding, internalization and degradation of colony-stimulating factor by peritoneal exudate macrophages

Iodinated colony-stimulating factor produced by L-cells (125I-CSF-1) binds specifically to murine peritoneal exudate macrophages. At 37 degrees C, the cell-bound 125I-CSF-1 was internalized and degraded very rapidly, with the appearance of radioactive iodotyrosine in the medium. At 0 degree C, the cell-bound 125I-CSF-1 was not internalized and degraded, nor did it dissociate from the membrane. The internalization and degradation at 37 degrees C could be blocked or reduced by the presence of phenylglyoxal, methylamine and NH4Cl. The chemical nature of the CSF-1 binding site is polypeptide as judged by its sensitivity to trypsin treatment. After the binding and degradation of unlabeled CSF-1, the exudate cells were no longer able to rebind freshly added 125I-CSF-1, indicating the removal of CSF-1 binding site. The binding capacity of these cells, however, could be restored by prolonged incubation at 37 degrees C but not at 0 degrees C in culture medium containing fetal calf serum.     

Production of interleukin-1 and tumor necrosis factor by cisplatin-treated murine peritoneal macrophages

Supernatants collected from cisplatin-treated macrophages demonstrated enhanced cytotoxicity against actinomycin-D-treated L929 cells and also enhanced the thymocyte proliferation in response to concanavalin A, showing that cisplatin-treated macrophages release interleukin-1 (IL-1) and tumor necrosis factor (TNF) into the culture supernatant. The supernatant collected from untreated macrophages showed little TNF and IL-1 activity. The release of TNF and IL-1 was observed to be dependent on the dose and duration of cisplatin treatment. Medium alone containing cisplatin did not enhance thymocyte proliferation and had little cytotoxic effect on actinomycin-D-treated L929 cells. Cisplatin-treated macrophage culture supernatants were chromatographed over a Superose 12 column on an FPLC system. TNF activity eluted in two major peaks with apparent molecular weights of 50-55 and 15-20 kilodaltons, respectively. The kinetics of IL-1 release was also studied. Maximum production and release of IL-1 were observed up to 24 h after cisplatin treatment and then gradually declined. Freeze-thaw lysates of cisplatin-treated macrophages also showed enhanced IL-1 activity. Paraformaldehyde (PFA)-fixed cisplatin-treated macrophages showed significantly enhanced cytotoxic activity against L929 cells as compared to PFA-fixed untreated macrophages. PFA-fixed cisplatin-treated macrophages also enhanced thymocyte proliferation. These results suggest that cisplatin treatment of murine macrophages also results in increased expression of membrane-associated IL-1 and TNF activity.     

Comparative studies of the biological activities of human tumor necrosis factor and its derivatives

Biological activities of human tumor necrosis factor (TNF) and its derivatives were compared. In cytotoxicity assay with L929 cells, one derivative, designated as TNF(Asn), showed significantly lower activity than any other TNF examined. In binding assay, this derivative was also shown to have lower affinity for TNF receptors on L929 cells, suggesting that the cytotoxic activity of TNFs on L929 cells correlates with their affinity for receptors. We also found that the cytotoxic activity of TNF on A673 cells and its inhibitory effect on lipoprotein lipase were parallel with the cytotoxic activity on L929 cells, but the growth-enhancing activity on FS-4 cells and the cytotoxic activity on endothelial cells were not. It was also shown that TNF(Asn) had lower affinity than any other TNF for receptors on these target cells tested. These results suggested that there might be at least two types of cellular responses to TNF; one might correlate with the receptor-binding affinity of TNFs and the other not.     

Characterization of serum adhesive proteins that block tumor necrosis factor-mediated cell death

Previously we have shown that TGF-beta1 protects murine L929 fibroblasts from TNF/ActD-mediated cell death by inducing the expression of an extracellular matrix TNF-resistance triggering (TRT) protein. TRT promotes TNF-resistance via activation of tyrosine and serine/threonine kinases in L929 cells. To examine the presence of TRT activity in serum (designated STRT), human sera were diluted, treated with or without PMSF and subjected to sequential ammonium sulfate precipitation (ASP). Aliquots of the ASP protein fractions were coated onto 96-well plates, followed by thorough washing. When L929 cells were seeded and cultured on the wells coated with STRT proteins, these cells resisted killing by TNF, TNF/ActD, doxorubicin and serum deprivation, but not by anti-Fas/ActD, staurosporine and ActD. STRT activity was found at the 15% ASP fraction of untreated sera, but shifted to the 20% ASP fraction of PMSF-treated sera. Two likely STRT proteins of approximately 226 and 265 kDa were found in these fractions, compared to the corresponding nonfunctional ASP fractions. Functionally, STRT was inactivated by trypsin, but not by 5 M salt, various serine and/or cysteine protease inhibitors, and antibodies against fibronectin, vitronectin, C1q, histidine-rich glycoprotein, CD44, chondroitin sulfate and hyaluronic acid. STRT failed to alter the expression of proteins involved in apoptosis such as RIP, ICH-1L, BCL-X, TIAR and IkappaBalpha, and could not induce IkappaBalpha degradation. The induced TNF-resistance could be reversed by treatment of STRT-stimulated cells with testicular hyaluronidase, as well as with tyrosine kinase inhibitors tyrophostin, lavendustin A and AG-490 (a selective inhibitor of JAK2 kinase). However, the STRT function could not be blocked by the MEK kinase inhibitor PD98059 and the NF-kappaB inhibitors curcumin and a synthetic inhibitor peptide for NF-kappaB translocation. Together, our data suggest that tyrosine kinase activation is involved in the STRT-mediated resistance to TNF and TNF/ActD in L929 cells.     

TNFalpha-induced glutathione depletion lies downstream of cPLA(2) in L929 cells.

Both glutathione (GSH) depletion and arachidonic acid (AA) generation have been shown to regulate sphingomyelin (SM) hydrolysis and are known components in tumor necrosis factor alpha (TNFalpha)-induced cell death. In addition, both have hypothesized direct roles in activation of N-sphingomyelinase (SMase); however, it is not known whether these are independent pathways of N-SMase regulation or linked components of a single ordered pathway. This study was aimed at differentiating these possibilities using L929 cells. Depletion of GSH with L-buthionin-(S,R)-sulfoximine (BSO) induced 50% hydrolysis of SM at 12 h. In addition, TNF induced a depletion of GSH, and exogenous addition of GSH blocked TNF-induced SM hydrolysis as well as TNF-induced cell death. Together, these results establish GSH upstream of SM hydrolysis and ceramide generation in L929 cells. We next analyzed the L929 variant, C12, which lacks both cytosolic phospholipase A(2) (cPLA(2)) mRNA and protein, in order to determine the relationship of cPLA(2) and GSH. TNF did not induce a significant drop in GSH levels in the C12 line. On the other hand, AA alone was capable of inducing a 60% depletion of GSH in C12 cells, suggesting that these cells remain responsive to AA distal to the site of cPLA(2). Furthermore, depleting GSH with BSO failed to effect AA release, but caused a drop in SM levels, showing that the defect in these cells was upstream of the GSH drop and SMase activation. When cPLA(2) was restored to the C12 line by expression of the cDNA, the resulting CPL4 cells regained sensitivity to TNF. Treatment of the CPL4 cells with TNF resulted in GSH levels dropping to levels near those of the wild-type L929 cells. These results demonstrate that GSH depletion following TNF treatment in L929 cells is dependent on intact cPLA(2) activity, and suggest a pathway in which activation of cPLA(2) is required for the oxidation and reduction of GSH levels followed by activation of SMases.     

Tumor necrosis factor-mediated cytotoxicity involves ADP-ribosylation

The mechanism of TNF-mediated cytotoxicity was studied in several cell lines, including L929 murine fibroblasts. TNF caused a time- and dose-dependent increase of ADP-ribosylation in L929 target cells parallel to cell death. During the course of TNF-mediated cytotoxicity in the presence of actinomycin D, an increase in ADP-ribosylation became apparent between 4 and 6 h after exposure to TNF. Intracellular NAD+ and ATP levels decreased parallel to but not preceding cell death. Two inhibitors of ADP-ribosylation, namely 3-aminobenzamide and nicotinamide, prevented TNF-mediated cytotoxicity. Another target, the human cervical carcinoma cell line ME-180, showed an increase in ADP-ribosylation when treated with TNF, and the cytotoxic action of TNF on this target cell was inhibited by these two inhibitors. In the absence of actinomycin D, treatment of L929 cells with TNF also increased ADP-ribosylation, and the cytotoxic action of TNF was inhibited by nicotinamide. These results indicate that ADP-ribosylation may be involved in the TNF-mediated cytotoxic reaction.     

Internalization and degradation of receptor-bound human choriogonadotropin in Leydig tumor cells. Fate of the hormone subunits

The studies presented herein were aimed at characterizing the pathway involved in the internalization and degradation of human choriogonadotropin by cultured Leydig tumor cells. A quick biochemical method that differentiates between the surface-bound and internalized hormone was developed. Using this method and two hormone derivatives labeled exclusively (with 125I) in the alpha or beta subunits, it was possible to follow the fate of each hormone subunit during hormone binding, internalization, and degradation. The results show that the hormone is internalized in the intact form and that it reaches its place of degradation (presumably the lysosomes) in the intact form. The pathway for degradation of the internalized hormone is complex, and it appears to involve processing of one or both subunits of the intact hormone, followed by subunit dissociation and further degradation of the individual subunits. The alpha subunit is quickly degraded by the cells. The only detectable degradation products are extracellular amino acids. The beta subunit is degraded slower, and several intracellular degradation products are detectable before amino acids appear in the medium.     

Internalization of transforming growth factor-beta and its receptor in BALB/c 3T3 fibroblasts

The fate of 125I-labeled transforming growth factor-beta (125I-TGF beta) after binding to its cells surface receptor has been investigated in BALB/c 3T3 mouse fibroblasts. Binding of 125I-TGF beta to cellular receptors at 4 degrees C is pH-sensitive, being markedly decreased at pH less than 6. Most (approximately 90%) of the 125I-TGF beta bound to cells at 4 degrees C can be removed by a brief treatment with acidic medium but is converted into an acid-resistant state rapidly after shifting the cells to 37 degrees C. Cell-bound 125I-TGF beta is degraded at 37 degrees C and the degradation products are released into the medium. The lysosomotropic bases chloroquine, methylamine, and ammonium and the carboxylic ionophore monensin inhibit the degradation and release of 125I-TGF beta from the cells. Cells allowed to accumulate 125I-TGF beta intracellularly by the action of chloroquine or monensin were treated with the bifunctional agent disuccinimidyl suberate in the presence of detergent Triton X-100; this treatment caused the cross-linking of internalized 125I-TGF beta with the 280-kilodalton TGF beta receptor component. Under conditions in which sustained binding and degradation of saturating 125I-TGF beta concentrations occurs, there is no marked decrease in the binding capacity of the cells even when protein synthesis is blocked with cycloheximide. These results indicate that after TGF beta binding the TGF beta:receptor complex becomes rapidly internalized and that TGF beta is directed towards lysosomes where it is degraded and released. However, the cell surface is replenished with TGF beta receptors recycled after internalization or supplied by a large intracellular pool.     

Receptor-mediated internalization and degradation of urokinase is caused by its specific inhibitor PAI-1.

The receptor for urokinase plasminogen activator (uPA) has been previously shown not to internalize its ligand, but rather to focalize its activity at the cell surface, allowing a regulated cell surface plasmin dependent proteolysis. The receptor in fact binds the proenzyme pro-uPA and allows its very efficient conversion to the active two chains form. Receptor bound active uPA can also interact with its specific type 1 inhibiror (PAI-1) which is therefore able to inhibit the cell surface plasmin formation. In this paper we show that the uPA-PAI-1 complex bound to the uPA receptor is internalized and degraded. U937 cells were incubated at 4 degrees C with labeled uPA-PAI-1 (and other ligands), the temperature then raised to 37 degrees C and the fate of the ligand followed for 3 h thereafter. The uPA-PAI-1 complex was internalized into the cells (i.e. could not be dissociated by acid treatment) and thereafter degraded (i.e. appeared in the supernatant in a non TCA-precipitable form). Other ligands (free uPA, ATF and DFP-treated uPA) were not internalized nor degraded. The degradation of the uPA-PAI-1 complex is preceded by internalization and is inhibited by chloroquine, an inhibitor of lysosomal protein degradation. These data suggest the existence of a cellular cycle of uPA. After synthesis pro-uPA is secreted, bound to the receptor and activated to two chain uPA. On the surface, uPA can activate surface bound plasminogen to produce surface bound plasmin. In the presence of PAI-1 uPA activity is inhibited and plasmin production interrupted, while the uPA-PAI-1 complex is internalized and degraded.     

Tumor necrosis factor is partly responsible for the differentiation of mouse myeloid leukemia cells

When mouse myeloid leukemia M1 cells were incubated with 0.1% TNS(serum containing tumor necrosis factor, TNF), they were induced to differentiate into macrophage-like cells within 14 h. The stability of the differentiation activity to heat treatment was very similar to that of the cytotoxicity of TNF for L929 cells. The differentiation activity could not be separated from the TNF activity by sequential chromatography procedures using DEAE-Sephadex and Sephacryl S-200 or by isoelectric focusing. These results suggest that the differentiation activity of TNS is due to TNF. Indeed, recombinant human TNF induced differentiation of M1 cells.     

Induction of TNF-like factor by murine macrophage-like cell line J774.1 on treatment with Sarcophaga lectin

On stimulation with Sarcophaga lectin, the mouse macrophage-like cell line J774.1 secreted a factor like the tumor necrosis factor (TNF) into the culture medium. This factor was a protein with a molecular weight of 40000-45000, and was cytotoxic to L-929 cells, but not to normal embryonic fibroblasts. This factor was effective on both the ascites form and solid form of sarcoma 180 transplanted into ICR mice.     

Hypoxia and resistance to hydrogen peroxide confer resistance to tumor necrosis factor in murine L929 cells.

The mechanism whereby tumor necrosis factor (TNF) kills mammalian cells is not well understood, although oxidative damage has been suggested by several investigators. Further, it is not known why cells vary in their responsiveness to TNF. We show that the cytotoxic effect of TNF toward TNF-sensitive L929 cells is blocked under hypoxic conditions, suggesting a critical role of molecular oxygen and reactive oxygen species. To test whether cellular resistance to reactive oxygen species could provide resistance to TNF, we derived a variant strain from L929 cells by chronic exposure to an oxidizing agent, hydrogen peroxide (H2O2). These cells exhibit marked resistance to TNF as well as to H2O2. This cross-protection provides additional evidence that mechanisms of resistance to oxidative damage are causally related to TNF-induced cell death. Scatchard analysis of TNF binding did not reveal significant differences between the H2O2-resistant line and the wild-type L929 line. On the other hand, analyses of antioxidant enzymes and glutathione levels in cells of the wild-type and the H2O2-resistant lines revealed several potentially important differences. Before exposure to TNF, the H2O2-resistant variants have elevated catalase activity, decreased activity of total glutathione-S-transferase (GST), and similar superoxide dismutase (SOD) activities. Exposure to TNF led to alteration in CuZnSOD activity, and much more so in the variants than in the wild-type L929 cells. However, no significant change in MnSOD activities in cells of either cell line was observed. Total GST activity was not altered appreciably by TNF in either cell line, but Western analysis showed that the level of alpha GST isozyme was increased and mu GST isozyme decreased in the H2O2-resistant variants. Furthermore, alterations in total glutathione content were observed in both the control and the variant cells.     

Quantitative phosphoproteomic analysis of RIP3‐dependent protein phosphorylation in the course of TNF‐induced necroptosis

Tumor necrosis factor (TNF) induced cell death in murine fibrosarcoma L929 cells is a model system in studying programed necrosis (also known as necroptosis). Receptor interacting protein 3 (RIP3), a serine–threonine kinase, is known to play an essential role in TNF‐induced necroptosis; however, the phosphorylation events initiated by RIP3 activation in necroptotic process is still largely unknown. Here, we performed a quantitative MS based analysis to compare TNF‐induced changes in the global phosphoproteome of wild‐type (RIP3^+/+) and RIP3‐knockdown L929 cells at different time points after TNF treatment. A total of 8058 phosphopeptides spanning 6892 phosphorylation sites in 2762 proteins were identified in the three experiments, in which cells were treated with TNF for 0.5, 2, and 4 h. By comparing the phosphorylation sites in wild‐type and RIP3‐knockdown L929 cells, 174, 167, and 177 distinct phosphorylation sites were revealed to be dependent on RIP3 at the 0.5, 2, and 4 h time points after TNF treatment, respectively. Notably, most of them were not detected in a previous phosphoproteomic analysis of RIP3‐dependent phosphorylation in lipopolysaccharide‐stimulated peritoneal macrophages and TNF‐treated murine embryonic fibroblasts (MEFs), suggesting that the data presented in this report are highly relevant to the study of TNF‐induced necroptosis of L929 cells.