Engagement of tumor necrosis factor mRNA by an endotoxin-inducible cytoplasmic protein.

BACKGROUND: Tumor necrosis factor (TNF) production by macrophages plays an important role in the host response to infection. TNF-alpha gene expression in RAW 264.7 macrophages is predominantly regulated at the translational level. A key element in this regulation is an AU-rich (AUR) sequence located in the 3' untranslated region (UTR) of TNF mRNA. In unstimulated macrophages, the translation of TNF mRNA is inhibited via this AUR sequence. Upon stimulation with LPS, this repression is overcome and translation occurs. In this study, we attempted to identify cellular proteins that interact with the AUR sequence and thereby regulate TNF mRNA translation. MATERIALS AND METHODS: RNA probes corresponding to portions of TNF mRNA 3' UTR were synthesized. These labeled RNAs were incubated with cytoplasmic extracts of either unstimulated or lipopolysaccharides (LPS)-stimulated RAW 264.7 macrophages. The RNA/protein complexes formed were analyzed by gel retardation. Ultraviolet (UV) cross-linking experiments were performed to determine the molecular weight of the proteins involved in the complexes. RESULTS: TNF mRNA AUR sequence formed two complexes (1 and 2) of distinct electrophoretic mobilities. While the formation of complex 1 was independent of the activation state of the macrophages from which the extracts were obtained, complex 2 was detected only using cytoplasmic extracts from LPS-stimulated macrophages. Upon UV cross-linking, two proteins, of 50 and 80 kD, respectively, were capable of binding the UAR sequence. The 50-kD protein is likely to be part of the LPS-inducible complex 2, since its binding ability was enhanced upon LPS stimulation. Interestingly, complex 2 formation was also triggered by Sendaï virus infection, another potent activator of TNF mRNA translation in RAW 264.7 macrophages. In contrast, complex 2 was not detected with cytoplasmic extracts obtained from B and T cell lines which are unable to produce TNF in response to LPS. Protein tyrosine phosphorylation is required for LPS-induced TNF mRNA translation. Remarkably, the protein tyrosine phosphorylation inhibitor herbimycin A abolished LPS-induced complex 2 formation. Complex 2 was already detectable after 0.5 hr of LPS treatment and was triggered by a minimal LPS dose of 10 pg/ml. CONCLUSIONS: The tight correlation between TNF production and the formation of an LPS-inducible cytoplasmic complex suggests that this complex plays a role in the translational regulation of TNF mRNA.

Very low level of major BCR-ABL expression in blood of some healthy individuals.

The nested reverse transcriptase polymerase chain reaction (RT-PCR) provides a powerful tool for detection of minimal residual disease in CML. The RT-PCR used in the present study for detection of the major bcr-abl fusion gene, the hallmark and presumably the cause of CML, was optimized by: (a) increasing the amount of total RNA involved in the reverse transcription reaction to correspond to total RNA extracted from 10(8) cells; (b) using a specific abl primer in this reverse transcriptase reaction, and (c) reamplifying 10% of the RT-PCR product in a nested amplification. This optimized RT-PCR permitted to detect up to 1 copy of RNA bcr-abl synthesized in vitro, mixed with yeast RNA in a quantity equivalent to 10(8) white blood cells (WBC). Using the highly sensitive RT-PCR, a systematic study of the possible expression of bcr-abl RNA in WBC of healthy adults, children and umbilical cord blood (UCB) revealed the presence of bcr-abl transcripts in blood cells of 22/73 adults, 1/22 children but not in 22 samples of UCB. The comparison of these three groups indicated a significant tendency for the anomaly to increase in frequency with age.

Defective translation of tumor necrosis factor mRNA in lipopolysaccharide-tolerant macrophages.

Macrophage activation by lipopolysaccharide (LPS) results in the translational activation of tumor necrosis factor (TNF) mRNA. The initial phase of macrophage activation is followed by a refractory state called LPS tolerance characterized by an impaired TNF production in response to a secondary LPS challenge. LPS-tolerant macrophages contain high amounts of TNF mRNA, suggesting a translational regulation of TNF biosynthesis. The induction of LPS tolerance was studied in RAW 264.7 macrophages stably transfected with a chloramphenicol acetyl-transferase (CAT) reporter gene construct driven by a constitutive cytomegalovirus promoter and containing the 3' untranslated region of the murine TNF gene. We found that primary stimulation of transfected cells by LPS (1 ng/ml, 12 hr) resulted in a marked suppression (80%) of CAT accumulation in response to a secondary LPS challenge (1 microgram/ml, 6 hr). In contrast, the accumulation of CAT mRNA was not influenced by LPS tolerance. Using the same CAT reporter, we observed that the serine/threonine phosphatases 1 and 2A inhibitor okadaic acid induced TNF mRNA translation and that this activation was not inhibited by LPS-tolerance. In conclusion, these data indicate that deficient production of TNF in LPS-tolerant macrophages in response to a second LPS challenge is characterized by a defective translation of TNF mRNA. However, this hyporesponsiveness to LPS is specific, since translation of TNF mRNA induced by okadaic acid is not inhibited in LPS-tolerant macrophages.

Detection of major bcr-abl gene expression at a very low level in blood cells of some healthy individuals.

The major bcr-abl fusion gene is presently seen as the hallmark of chronic myeloid leukemia (CML) and presumably as the cause of its development. Accordingly, long-term disappearance of bcr-abl after intensive therapy is considered to be a probable cure of CML. The nested reverse transcriptase-polymerase chain reaction (RT-PCR) provides a powerful tool for minimal residual CML detection. The RT-PCR was optimized by (1) increasing the amount of total RNA involved in the reverse transcription reaction to correspond to total RNA extracted from 10(8) cells, (2) using a specific abl primer in this reverse reaction, and (3) reamplifying 10% of the RT-PCR product in nested amplification. This optimized RT-PCR permitted us to detect up to 1 copy of RNA bcr-abl synthesised in vitro, mixed with yeast RNA in an equivalent quantity to 10(8) white blood cells (WBCs). Using this highly sensitive RT-PCR during the follow-up of CML patients, a signal was unexpectedly found in healthy controls. Therefore, a systematic study of the possible expression of bcr-abl RNA in the WBCs of healthy adults and children and in umbilical cord blood was undertaken. It showed the presence of bcr-abl transcript in the blood of 22 of 73 healthy adults and in the blood of 1 of 22 children but not in 22 samples of umbilical cord blood.

Glutathione depletion increases tyrosinase activity in human melanoma cells.

The aim of the present work was to estimate the effect of intracellular glutathione depletion on melanogenesis in human melanoma cells. We determined tyrosine hydroxylation activity, the rate-limiting step of the pathway, and 14C-melanin formation, an assay reflecting the global eumelanogenic pathway. Intracellular glutathione was depleted by treatment with buthionine-S-sulfoximine, a well-known inhibitor of gamma-glutamylcysteine synthetase. The intracellular depletion of glutathione was substantial after 20 h of incubation with 50 microM buthionine-S-sulfoximine, although a significant effect could be observed after 6 h. Tyrosine hydroxylase activity increased in parallel with glutathione depletion, to reach 160% with respect to the control values during 24 h of buthionine-S-sulfoximine treatment. We have found the response to buthionine-S-sulfoximine to be dose dependent and the two different human cell lines HBL and LND1 to have similar, if not identical, responses. 14C-melanin formation assay revealed even greater activation, up to 400% of the control values. This indicates that glutathione depletion may have two distinct effects: first, a direct one on tyrosinase activity and, second, an effect on the promotion of eumelanogenesis. The stimulation of tyrosine hydroxylase can be explained by a possible inactivation of the enzyme by endogenous thiol compounds rather than by a direct effect of buthionine-S-sulfoximine itself on tyrosinase. The data suggest that thiol compounds may play a role for stimulation of melanogenesis by ultraviolet radiation.

Sensitivity of yeast cells to reactive oxygen species generated in the extracellular space.

Even when cytoplasmic scavenging activities are plentiful, yeast cells (S. cerevisiae) remain particularly sensitive towards reactive oxygen species generated in the extracellular space (either by the xanthine/xanthine oxidase reaction or by the redox cycling of menadione). A sharp reduction of the extent of cellular alterations when SOD and/or catalase were supplemented in the incubation buffer, points to a contribution of both O-.2 and H2O2 in the toxic process. Although oxygen metabolites as well as t-butylhydroperoxide (tBH), a highly toxic organic peroxide, may be directly responsible for cellular damage, their toxicity is largely reduced in the presence of Desferal. A role of metal ions in potentiating the toxicity points to the involvement of OH. radicals, actually produced in the medium. With tBH, metal cations would be rather active in promoting peroxidative chain reactions. In the case of an extracellular oxidative attack, it may be foreseen that the plasma membrane will form a preferential target. An increased permeability of the plasma membrane towards ionized molecules and uncharged polycarboxylic acids is indeed observed after an oxidative treatment. The loss of selective permeability is, as a rule, correlated with a drop in viability. Early alterations, disrupting the functional organization of the plasma membrane have been sought. The permease involved in the active transport of purine(s) has appeared to be an appropriate marker for checking its functional integrity. This transport function appears to be very sensitive to damage induced by O-.2 generators, particularly under conditions in which the resulting lethality is still kept low and in which the energization of active transport processes remains unimpaired.

Potentiation of oxygen toxicity by menadione in Saccharomyces cerevisiae.

The cytotoxicity of molecular oxygen can be sharply increased in the yeast Saccharomyces cerevisiae by the use of redox compounds capable of shunting electrons in vivo and of spontaneous reoxidation under aerobic conditions. Among these redox compounds, menadione (Vitamin K3) is particularly able to stimulate the cyanide-resistant respiration of the yeast cells. Under steady-state conditions, the efficiency of menadione is modulated by the physiological state of the yeast cells and also depends on the availability of reducing agents within the cell. Menadione shows lethal effects towards yeast cells in the presence of O2 only, as a result of the production of toxic metabolites like O2-. and H2O2 which are actually detected in the extracellular fluid. Inhibitors of the enzymes scavenging O2-. and H2O2 generally potentiate the lethal effects of this redox compound. On the other hand, superoxide dismutase and/or catalase supplemented into the incubation buffer have been found to protect the cells to various extents from the cytotoxic effects of menadione. Our data support the following conclusions: When the cellular enzymatic defences are functional, the moderate lethality induced by menadione is principally mediated by O2-. ions acting on the outer side of the cell (peripheral region). In the presence of cyanide, but not of azide, the loss of viability also results from additional damage occurring within the inner cell region. In this case, intracellular injury can be caused by H2O2 alone but our data also suggest that during redox cycling more reactive species--O2-. and probably OH.--are generally intracellularly and are involved in the cytotoxic process.

Inhibition studies in situ of yeast catalases.

The catalase activity of the intact yeast cells towards external substrate is generally lower than the 'cryptic' activity which is revealed after cell lysis. The physiological basis for the reduced catalytic activity of the intact cell ('patent' activity) has been investigated by establishing the inhibition profiles of catalases in situ using selected probes; to this end we utilized either non-penetrating acids and/or catalase poisons able to cross the plasmic membrane. Owing to the peculiar features of the reaction mechanism, competitive inhibitors, which are known to interact with the prosthetic group of catalases, show an efficiency that is unlinked to the hydrogen peroxide concentration under the usual assay conditions ([H2O2] much less than Km). This mode of interaction, which also characterizes the action of the penetrating probes HCOOH and HCN, is particularly well adapted to the study of the behaviour of the cytoplasmic catalases in situ. By this experimental approach, it has been shown that the catalase of the inner cellular region contributes, together with an isoenzyme present at the cell surface, to the patent activity. The mathematical processing of the data, which takes into account a rate-limiting diffusion of external substrate into the intact yeast cell, has allowed us to predict accurately the resulting apparent efficiency of inhibitors as a function of the physiological variations of the intracellular enzyme concentration.

Catalase anabolism in yeast: loss of regulation by oxygen of catalase apoprotein synthesis after mutation.

A mutant of Saccharomyces cerevisiae which displays catalase activity when grown under strictly anaerobic conditions has been selected on solid media. Although some preformed holoenzyme has accumulated in anaerobic cells, a sharp increase of activity is still measured during adaptation to oxygen in glucose-buffer; however, a striking difference with the wild-type strain is that in the mutant, catalase formation is observed in the presence of cycloheximide that totally inhibits cytoplasmic translation. It is concluded that kat 80 mutant has lost the regulatory control by oxygen of apocatalase synthesis; the later precursor, characterized as apocatalase synthesis; the latter precursor, characterized as apocatalase T, is thought to be activated in vivo, under aerobic conditions, by inclusion of prosthetic group. Regulation of enzyme synthesis by catabolite repression (glucose erfect) persists, unmodified by reference to the wild-type parental strain. Mutation kat 80 specifically hits catalase anabolism, as no significant variations were observed for the edification of the respiratory system and (apo)cytochrome c peroxidase production. Genetic analysis shows that kat 80 phenotype, recessive in heterozygotes, results from a single nuclear mutation.

Thermosensitive respiratory deficiency in yeast associated with specific effects on particulate cytochrome oxidase.

A mutant of Saccharomyces cerevisiae, unable to grow at the expense of non fermentable carbon sources at 37 degrees C, has been selected; at 25 degrees C the mutant strain behaves like the parental wild strain. Evaluations of respiration rates during aerobic growth at restrictive temperature on one hand, enzymatic and/or spectral evaluations of the individual components of the respiratory chain on the other hand show that the respiratory deficiency is specifically correlated with a reduced level of cytochrome oxidase. The decrease of enzyme activity is the direct consequence of a lowering of hemoprotein (a,a3) concentration. Temperature-activity relationship of cytochrome oxidase elaborated at the permissive temperature by the mutant strain is modified as far as the particulate enzyme is concerned, but no difference is observed after partial solubilization of the enzyme by non ionic surfactant. Genetic analysis shows that the mutant phenotype results from a nuclear gene mutation.