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Clinical and Diagnostic Laboratory Immunology, May 1998, p. 281-287, Vol. 5, No. 3
1071-412X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Interleukin-1beta Expression after Inhibition of Protein Phosphatases in Endotoxin-Tolerant Cells

Barbara K. Yoza,* Jon D. Wells, and Charles E. McCall

Department of Medicine, Wake Forest University School of Medicine, Winston-Salem, North Carolina

Received 1 October 1997/Returned for modification 18 December 1997/Accepted 21 January 1998

    ABSTRACT
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Endotoxin (lipopolysaccharide [LPS]) is a potent activator of a number of inflammatory genes in blood leukocytes, including interleukin-1 (IL-1). Blood leukocytes isolated from patients with septic shock fail to produce IL-1 in response to LPS, a phenomenon known as endotoxin tolerance. To study the regulation of IL-1 expression in endotoxin-tolerant cells, the protein phosphatase inhibitor okadaic acid was used to examine the effects of protein phosphorylation on IL-1beta gene expression. We found that endotoxin-tolerant cells produced normal levels of IL-1beta when protein phosphatases were inhibited. In the human pro-monocytic cell line THP-1, okadaic acid increased mRNA accumulation and synthesis of IL-1beta protein. Normal and endotoxin-tolerant THP-1 cells accumulated IL-1beta mRNA and protein with similar delayed kinetics. Okadaic acid stabilization of IL-1beta mRNA appears to be the primary mechanism through which endotoxin-tolerant cells accumulate IL-1beta mRNA and protein. Endotoxin-tolerant cells were unable to activate transcription in response to okadaic acid. However, the transcription factor NF-kappa B, which is known to be involved in IL-1beta expression, was translocated to the nucleus in both normal and endotoxin-tolerant cells after treatment with okadaic acid. These studies revealed that protein phosphorylation can affect gene expression on at least two distinct levels, transcription factor activation and mRNA stability. Endotoxin-tolerant cells have decreased transcription activation potential, while IL-1beta mRNA stability remains responsive to protein phosphorylation.

    INTRODUCTION
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Septic shock is a lethal syndrome and the principal cause of death in patients in intensive care units (26). A number of microbial products, including bacterial lipopolysaccharide (LPS) (endotoxin), cause septic shock by inducing the expression of proinflammatory genes. Phagocytic cells, monocytes and neutrophils, respond to LPS by producing the potent immune and inflammatory mediator interleukin-1 (IL-1) (for a review, see reference 41). In these cells, LPS-stimulated IL-1beta production can be attributed to rapid increases in transcription of the IL-1beta gene, which occurs in the absence of new protein synthesis (10, 17). Expression of IL-1beta and other cytokines, such as tumor necrosis factor alpha (TNF-alpha ), has been shown to be dependent on the activation of the transcription factor NF-kappa B (6, 14, 31, 40). In addition to transcription regulatory events, IL-1beta gene expression is controlled at the level of mRNA stability, translation, and IL-1beta precursor protein processing (for a review, see reference 1).

Cells exposed to LPS become refractory to further stimulation by LPS. This adaptive, and perhaps protective, response is a phenomenon known as endotoxin tolerance and has been observed in peripheral blood mononuclear cells isolated from subjects given a single intravenous dose of LPS (11). LPS-stimulated whole blood from septic patients showed a markedly depressed ability to release TNF-alpha , IL-1beta , and IL-6 for up to 10 days after diagnosis of sepsis (15). Monocytes (24) and neutrophils (20) isolated from patients with septic shock fail to produce IL-1 in response to LPS. The molecular mechanisms which regulate IL-1beta expression in endotoxin tolerance are unclear but appear to involve repressed transcription (17) and altered cytokine processing and/or secretion (15).

Phosphatase inhibition has been shown to stimulate inflammatory cytokine gene expression, through increases both in transcription and in mRNA stabilization (34, 35, 38). In particular, inhibition of protein phosphatases by okadaic acid markedly increased the production of IL-1beta in human monocytes through increases in transcription and protein processing (36), two regulatory mechanisms thought to be altered in endotoxin tolerance. Using an in vitro model (17), we sought to investigate the role of protein phosphatases in the endotoxin-tolerant cell. We found that normal and endotoxin-tolerant THP-1 cells accumulated IL-1beta in response to protein phosphatase inhibition by okadaic acid. In endotoxin-tolerant cells, however, okadaic acid was unable to activate transcription of transfected reporter genes containing IL-1beta enhancer/promoter sequences, despite activation and nuclear translocation of the transcription factor NF-kappa B. We demonstrate that differences in IL-1beta mRNA stability induced by okadaic acid allowed the production of normal levels of IL-1 protein in the endotoxin-tolerant cell.

    MATERIALS AND METHODS
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Cell culture and induction of endotoxin tolerance. THP-1 cells (a human pro-monocytic cell line) (American Type Culture Collection, Rockville, Md.) were cultured in RPMI 1640 medium (Gibco BRL, Gaithersburg, Md.) supplemented with 10 U of penicillin G per ml, 10 µg of streptomycin per ml, 2 mM L-glutamine, and 10% fetal calf serum (HyClone Laboratories, Logan, Utah). THP-1 5A cells, a generous gift from John G. Gray (Department of Molecular Genetics, Glaxo Wellcome, Inc., Research Triangle Park, N.C.) are THP-1 cells stably transfected with pIL-1 (4.0 kb)-secreted placental alkaline phosphatase (SPAP) (19). Transient transfections with a plasmid containing six NF-kappa B binding sites and a chloramphenicol acetyltransferase (CAT) reporter gene were performed as previously described (42). Endotoxin (LPS) tolerance was induced for both THP-1 cells and THP-1 5A cells as previously described (17). Briefly, cells were made tolerant with a primary dose of LPS (1 µg of LPS [E. coli O111:B4; Sigma Chemical Co., St. Louis, Mo.] per ml) for 18 h. The cells were then pelleted, washed once, and stimulated as described in legends to the figures. For all experiments, normal cells were treated similarly but were not given the primary LPS dose. A complete characterization of the tolerant THP-1 model has been previously published (17).

RNA isolation and Northern blot analysis. Total RNA was isolated from cells by using RNA STAT-60 (Tel-Test "B", Inc., Friendswood, Tex.) according to the manufacturer's instructions. After transfer to nylon membranes, IL-1beta and glyceraldehyde-3-phosphate dehydrogenase (GAPDH) mRNAs were visualized by autoradiography as described previously (17).

IL-1beta enzyme-linked immunosorbent assay (ELISA). Total IL-1beta protein (intracellular and secreted) was assessed with an IL-1beta immunoassay kit (sensitivity range, 5 to 1,000 pg of IL-1beta /ml; Immunotech, Inc., Westbrook, Maine) according to the manufacturer's instructions. Samples were obtained by lysis of cells plus media in RIPA buffer (150 mM NaCl, 1% desoxycholate, 1% Triton, 0.1% sodium dodecyl sulfate, 10 mM Tris [pH 7.4]), cleared by centrifugation, assayed in duplicate, and read on a Thermomax microplate reader (Molecular Devices, Sunnyvale, Calif.). Data were analyzed and plotted with Microsoft Excel (version 5.0).

IL-1beta mRNA half-life determination. Normal and tolerant THP-1 cells (106/ml) were stimulated with LPS (1 µg/ml) or okadaic acid (100 nM) for 3 or 6 h, respectively. Following stimulation, the cells were treated with actinomycin D (5 µg/ml) (Sigma Chemical Co.), and total RNA was prepared at various times after addition of actinomycin D. IL-1beta mRNA half-life was assessed by Northern blot and quantitated with a PhosphorImager 425 SI (Molecular Dynamics) and ImageQuaNT 4.1 software (Molecular Dynamics). IL-1beta mRNA levels were normalized to GAPDH mRNA levels and expressed as percent mRNA by using Microsoft Excel software (version 5.0). Alternatively, RNA half-life was determined by reverse transcription (RT) of sample RNA and amplification of the reverse-transcribed cDNA with the GeneAmp RNA PCR kit (Perkin-Elmer, Foster City, Calif.) and the GeneAmp PCR System 9600 (Perkin-Elmer Cetus, Emeryville, Calif.) according to the manufacturer's instructions. The primers used were IL-1beta 5' primer, 5'-GCAAGGGCTTCAGGCAGGCCGCG-3'; IL-1beta 3' primer, 5'-GGTCATTCTCCTGGAAGGTCTGTGGGC-3'; GAPDH 5' primer, 5'-CCATGGAGAAGGCTGGGG-3'; and GAPDH 3' primer, 5'-CAAAGTTGTCATGGATGACC-3'. Times and temperatures for the RT cycle were 60 min at 42°C, 5 min at 98°C, and 5 min at 4°C. The PCR was performed in the presence of 5 µCi of [alpha -32P]dATP, and the reverse-transcribed cDNA was amplified for 1 min at 93°C, 1 min at 55°C, and 1 min at 72°C for each of 15 cycles and a final hold for 5 min at 72°C. Radiolabeled PCR products were resolved on an 8% polyacrylamide gel, quantitated with a Molecular Dynamics PhosphorImager 425 SI and ImageQuaNT 4.1 software, normalized to GAPDH mRNA levels, and expressed as percent mRNA by using Microsoft Excel (version 5.0) software.

SPAP assays. SPAP was assayed from THP-1 5A cell culture supernatants with the Great Escape detection kit (Clontech, Palo Alto, Calif.) according to the manufacturer's instructions. Data were analyzed and plotted with Microsoft Excel software (version 5.0).

Nuclear extract preparation and EMSA. Following treatment as described in the figure legends, THP-1 cells were harvested and nuclear extracts were prepared and stored at -70°C for use in electrophoretic mobility shift assays (EMSAs) as previously described (42). Oligonucleotide probes for the binding sites of NF-kappa B and octamer 1 were synthesized by using an Applied Biosystems model 380B automated DNA synthesizer as previously described (42). Specificity of DNA binding was also determined as previously described (42; also, data not shown).

    RESULTS
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

IL-1beta mRNA expression in endotoxin-tolerant cells as a result of phosphatase inhibition. Phosphatase inhibition by okadaic acid has been reported to induce gene transcription of IL-1beta in human monocytes (36). To determine whether okadaic acid could induce IL-1beta expression in our endotoxin-tolerant-cell model, normal and tolerant cells were stimulated for various times with 100 nM okadaic acid and IL-1beta mRNA was visualized on a Northern blot of total RNA (Fig. 1A). As we had observed previously (17), endotoxin-tolerant cells were impaired in their ability to induce IL-1beta mRNA expression when challenged with LPS (Fig. 1; compare lanes L). However, okadaic acid induced IL-1beta mRNA in both normal and tolerant cells with maximal accumulation at approximately 6 h in both phenotypes. These results show that okadaic acid can induce IL-1beta mRNA in tolerant cells, where IL-1beta expression in response to LPS is impaired.


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  		FIG. 1.   Inhibition of protein phosphatases by okadaic acid induces IL-1beta mRNA and protein accumulation in normal and endotoxin-tolerant cells. THP-1 cells (106/ml) were treated with LPS (1 µg/ml) for 18 h to induce tolerance. (A) Normal and endotoxin-tolerant cells were stimulated with okadaic acid (OA) (100 nM) for the indicated times, and total RNA was isolated as described in Materials and Methods. Northern blots of total RNA were hybridized with a nick-translated, 32P-labeled IL-1beta cDNA probe and visualized by autoradiography. Northern blots were stripped and reprobed with a nick-translated, 32P-labeled GAPDH cDNA probe as a control. Normal and endotoxin-tolerant cells were also treated with LPS (lanes L) (1 µg/ml) for 3 h to verify the tolerant phenotype. (B) Normal and endotoxin-tolerant transfected cell lysates were assayed for IL-1beta production at various times after addition of okadaic acid (100 nM). IL-1beta protein was measured by ELISA as described in Materials and Methods.

Okadaic acid increases IL-1beta expression in endotoxin-tolerant cells. As shown in Fig. 1B, okadaic acid induced similar amounts of total IL-1beta protein in normal and tolerant cells. The kinetics of IL-1beta protein accumulation correlates with the accumulation of IL-1beta mRNA, and tolerant cells do not show the lag phase observed in normal cells in their response to okadaic acid.

Okadaic acid increases IL-1beta mRNA half-life. While LPS-induced IL-1beta mRNA expression is rapid and transient (10, 17), LPS-stimulated IL-1beta mRNA in THP-1 cells has half-lives of 50 and 100 min in normal and tolerant cells, respectively (Fig. 2). In contrast, okadaic acid treatment resulted in a delayed and prolonged expression of IL-1beta transcripts (Fig. 1A) in both normal and tolerant phenotypes. Okadaic acid could increase IL-1beta mRNA levels through increased transcription or stabilization of IL-1beta mRNA, mechanisms both of which are known to be important in the regulation of IL-1beta expression (1). To determine the effect of phosphatase inhibition on IL-1beta mRNA stabilization, normal and tolerant cells were treated with 100 nM okadaic acid for 6 h, at which time further transcription was inhibited by the addition of 5 µg of actinomycin D per ml. Total RNA was isolated at various times after addition of actinomycin D, and IL-1beta mRNA was quantitated by RT-PCR (Fig. 3A) or on Northern blots (Fig. 3C) with similar results (Fig. 3B and D, respectively). Okadaic acid stabilized IL-1beta mRNA in normal and tolerant cells (half-life, >2 h), with no degradation of IL-1beta mRNA observed over the times tested.


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  		FIG. 2.   LPS-induced IL-1beta mRNA has a relatively short half-life in both normal and endotoxin-tolerant cells. THP-1 cells (106/ml) were treated with LPS (1 µg/ml) for 18 h to induce tolerance. Normal and endotoxin-tolerant cells were stimulated with LPS (1 µg/ml; 3 h), and total RNA was prepared at various times after addition of actinomycin D (min/ActD). Radiolabeled PCR products (IL-1beta ) were resolved on an 8% polyacrylamide gel, quantitated by phosphorimaging analysis, and normalized to GAPDH as a control. (A) Representative autoradiograph; (B) results of an analysis. The data represents one of at least three separate experiments.


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  		FIG. 3.   Okadaic acid increases IL-1beta mRNA half-life. (A) Representative autoradiograph of an mRNA half-life determination by RT-PCR performed as described in Materials and Methods. THP-1 cells (106/ml) were treated with LPS (1 µg/ml) for 18 h to induce tolerance. Normal and endotoxin-tolerant cells were stimulated with okadaic acid (100 nM; 6 h), and total RNA was prepared at various times after addition of actinomycin D (Hrs/ActD). Radiolabeled PCR products (IL-1beta ) were resolved on an 8% polyacrylamide gel, quantitated by phosphorimaging analysis, and normalized to GAPDH as a control. (B) Results of an analysis. The data represents one of at least three experiments, with similar results. (C) Representative autoradiograph of an mRNA half-life determination by Northern analysis performed as described in Materials and Methods. THP-1 cells (106/ml) were treated with LPS (1 µg/ml) for 18 h to induce tolerance. Normal and endotoxin-tolerant cells were stimulated with okadaic acid (100 nM; 6 h), and total RNA was prepared at various times after addition of actinomycin D (Hrs/ActD). Northern blots of total RNA were hybridized with a nick-translated, 32P-labeled IL-1beta cDNA probe (IL-1B) and visualized by autoradiography. Northern blots were stripped and reprobed with a nick-translated, 32P-labeled GAPDH cDNA probe as a control. Radiolabeled IL-1beta mRNA/cDNA hybrids were quantitated by phosphorimaging analysis and normalized to radiolabeled GAPDH mRNA/cDNA hybrids as a control. (D) Results of an analysis. The data shown represents one of at least three experiments, with similar results.

Phosphatase inhibition by okadaic acid does not activate transcription of reporter genes in tolerant cells. To determine the role of transcription activation in okadaic acid-induced IL-1beta expression, we used an SPAP reporter gene linked to enhancer/promoter elements from the IL-1beta gene. Normal and endotoxin-tolerant cells stably transfected with pIL-1 (4.0 kb)-SPAP, THP-1 5A cells (19), were stimulated with 100 nM okadaic acid, and transcription activation was measured by expression of SPAP in the cell culture supernatant. Figure 4A shows that LPS strongly induced transcription of the SPAP reporter gene in normal cells and that this induction was repressed in a tolerant cell. This result confirms and extends our previous observation of repressed transcription in endotoxin-tolerant cells (17). We also found that, although okadaic acid is a less potent inducer of SPAP transcription relative to LPS, okadaic acid-induced SPAP expression was similarly repressed in a tolerant cell. Control experiments showed that okadaic acid had no direct effect on the phosphatase assays used to measure SPAP reporter gene expression (data not shown). As expected, LPS did not induce IL-1beta protein in tolerant cells compared to the normal cells, while okadaic acid induced similar amounts of IL-1beta protein in both phenotypes (Fig. 4B). These results show that endotoxin-tolerant cells are repressed at the level of transcription in that both LPS and okadaic acid are unable to induce SPAP reporter gene expression through promoter/enhancer sequences of the IL-1beta gene. These results suggest that, in endotoxin-tolerant cells, IL-1beta mRNA accumulation in response to phosphatase inhibition by okadaic acid occurs through a mechanism which is independent of transcription activation. LPS stimulation and phosphatase inhibition are apparently unable to activate transcription of the IL-1beta gene in endotoxin-tolerant cells.


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  		FIG. 4.   Inhibition of protein phosphatases by okadaic acid induces similar amounts of IL-1beta , but not similar amounts of alkaline phosphatase (AP) activity, in normal and endotoxin-tolerant cells. THP-1 cells and/or THP-1 5A cells (106/ml) were treated with LPS (1 µg/ml) for 18 h to induce tolerance. (A) Relative AP activity from normal and endotoxin-tolerant THP-1 5A cells (THP-1 cells stably transfected with pIL-1 [4.0 kb]-SPAP). At 6 or 18 h after okadaic acid (OA) stimulation, cell supernatants were assayed for AP activity as described in Materials and Methods. For each time, normal-cell AP activity was used as 100% and compared to tolerant-cell AP activity to determine relative AP activity. Normal and endotoxin-tolerant cells were also treated with LPS (1 µg/ml) to verify the tolerant phenotype at each time tested. Error bars indicate standard errors of the means (SEM) for three experiments. Average actual values for 100% are indicated below. (B) Normal and endotoxin-tolerant cells were stimulated with OA (100 nM) for 6, 10, or 18 h, and total IL-1beta protein was measured by ELISA as described in Materials and Methods. For each time, normal-cell IL-1beta protein levels were used as 100% and compared to tolerant-cell IL-1beta protein levels to determine relative IL-1beta protein levels. Error bars indicate SEM of 11 experiments. Normal and endotoxin-tolerant cells were also treated with LPS (1 µg/ml) to verify the tolerant phenotype at each time tested.

Okadaic acid does not activate NF-kappa B-dependent transcription in endotoxin-tolerant cells. The expression of IL-1beta has been shown to be dependent on the activation of the transcription factor NF-kappa B (6, 14). NF-kappa B is a potential regulatory target in the activation/repression we have observed in the normal and tolerant phenotypes. We therefore sought to determine the effect of phosphatase inhibition on NF-kappa B-dependent transcription in normal and endotoxin-tolerant cells. THP-1 cells were transiently transfected with a CAT reporter gene containing an enhancer of six NF-kappa B binding sites (42). Normal- and endotoxin-tolerant-cell lysates were assayed for CAT activity at various times after addition of okadaic acid. Figure 5A shows okadaic acid induction of NF-kappa B-dependent transcription of the transfected CAT reporter gene in normal cells. In contrast, CAT activity is not induced to high levels in endotoxin-tolerant cells. These results show that okadaic acid does not activate NF-kappa B-dependent transcription in endotoxin-tolerant cells and suggest a defect in NF-kappa B transcription factor activation in the tolerant phenotype. Control transfections with constitutively expressed cytomegalovirus CAT reporter genes show similar levels of CAT activity in normal and endotoxin-tolerant cells, indicating similar transfection efficiency and constitutive transcription in the two phenotypes.


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  		FIG. 5.   Okadaic acid does not activate NF-kappa B-dependent transcription in endotoxin-tolerant cells but can induce NF-kappa B nuclear translocation and DNA binding in normal and tolerant cells. (A) THP-1 cells were transiently transfected with a CAT reporter gene containing six NF-kappa B binding sites. Transfected cells were treated with LPS (1 µg/ml) for 18 h to induce tolerance. Normal and endotoxin-tolerant transfected cell lysates were assayed for CAT activity at various times after addition of okadaic acid (100 nM). CAT activity is expressed relative to normal and tolerant transfected cells in the absence of okadaic acid. (B) THP-1 cells (106/ml) were treated with LPS (1 µg/ml) for 18 h to induce tolerance. Normal and endotoxin-tolerant cells were stimulated with okadaic acid (OA) (100 nM) for the indicated times, and nuclear extracts were prepared as described in Materials and Methods. DNA binding of NF-kappa B was assessed by EMSA, and a representative autoradiograph of three separate experiments is shown. Octamer factor 1 (OCT) DNA binding was used as a control.

Okadaic acid activates NF-kappa B nuclear translocation in normal and endotoxin-tolerant cells. Okadaic acid had previously been shown to induce NF-kappa B nuclear translocation and activation (29, 39). Given the apparent inability of okadaic acid to induce NF-kappa B-dependent transcription activity in endotoxin-tolerant cells, we determined whether okadaic acid could mediate the nuclear localization of NF-kappa B in the tolerant phenotype. Nuclear extracts were prepared from okadaic acid-treated normal and tolerant cells over a time course of 9 h, and NF-kappa B binding activity was determined by EMSA. As shown in Fig. 5B, the nuclear translocation and DNA binding activity of NF-kappa B in nuclear extracts from control and tolerant cells were increased in response to okadaic acid. In normal cells, nuclear translocation appears to correlate with the induction of NF-kappa B-dependent CAT reporter gene transcription (Fig. 5A). Tolerant cells have an increased basal level of NF-kappa B binding (Fig. 5B; compare lanes 0) due to some induction by LPS during the tolerizing step; increased nuclear localization and DNA binding of NF-kappa B by okadaic acid do not, however, result in high levels of CAT activity.

These results show that phosphatase inhibition can induce nuclear localization of NF-kappa B in normal and tolerant cells. Despite the quantitatively similar nuclear localization in normal and tolerant cells, NF-kappa B-dependent transcription activation is not observed in the tolerant phenotype. However, there may be qualitative differences (43) in DNA binding in the tolerant phenotype (Fig. 5B; compare the relative increase in the amount of the upper NF-kappa B-specific protein-DNA complex in normal cells with the relative increases in the amounts of both upper and lower NF-kappa B-specific protein-DNA complexes in tolerant cells). The nature of this qualitative difference was not further investigated. Taken together, these results indicate that phosphatase inhibition stabilizes IL-1beta mRNA and is the predominant mechanism by which IL-1beta can be expressed in a tolerant cell where a repressor (17) may inhibit high levels of increased transcription activation.

    DISCUSSION
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

LPS induction of IL-1beta is rapid and transient, and the kinetics of IL-1beta production can be physiologically related to the inflammatory response induced by this potent bacterial toxin. Okadaic acid, in contrast, is a potent tumor promoter whose growth-regulatory mechanisms do not require such immediate physiological responses. Early studies showed that okadaic acid mimicked protein phosphorylation and gene expression patterns induced by IL-1 and TNF-alpha , two lymphokines with definitive growth-regulatory properties---IL-1 as a comitogen for thymocyte maturation and TNF-alpha as a cytotoxic agent for tumor cells (12). We (this study) and others (36, 38) have shown that okadaic acid increased IL-1beta production in monocytic cells. We further show that, in a normal cell, protein phosphorylation can affect IL-1beta expression on at least two levels, transcription activation and mRNA stability. Previous studies by Sung and Walters (36) also showed increases in transcription of the IL-1beta gene; however, they did not observe any effect of okadaic acid on IL-1beta mRNA stability compared to LPS-induced IL-1beta mRNA. In contrast, we find a significant change in mRNA stability in the presence of okadaic acid (half-life, >2 h) compared to mRNA stability in the presence of LPS (half-life, <2 h). The discrepancy between our results and those of Sung and Walters is most likely due to the time at which mRNA stabilization was assessed; Sung and Walters measured IL-1beta mRNA stability at only 2 h of okadaic acid treatment, a time which, we have shown, is less than optimal for inhibition of phosphatase activity (data not shown) and peak induction of IL-1beta mRNA accumulation by okadaic acid (Fig. 1).

We confirm and extend our previous studies showing that IL-1beta expression in endotoxin-tolerant cells is repressed at the level of transcription (17), while mRNA stability remains responsive to regulation by protein phosphorylation. Our results indicate that these two regulatory mechanisms in IL-1beta expression, transcription activation and mRNA stability, are distinct and separable. Transcription repression appears to be the dominant defect in endotoxin-tolerant cells. Okadaic acid, like LPS, is unable to activate transcription of the IL-1beta gene in endotoxin-tolerant cells. We have observed, however, that some inducers of IL-1beta , cycloheximide for example, are able to overcome transcription repression, perhaps by inhibiting the synthesis of a transcription repressor (17). Despite the inability to induce high levels of IL-1beta transcription, endotoxin-tolerant cells can produce normal levels of IL-1 when protein phosphatases are inhibited. IL-1beta mRNA, which is transcribed at basal levels both in normal untreated and in endotoxin-tolerant cells, becomes stabilized by okadaic acid, resulting in a slow accumulation of IL-1beta mRNA and synthesis of similar levels of IL-1beta protein (Fig. 1).

The IL-1beta gene is expressed in response to a number of stimulants in addition to LPS and okadaic acid, including phorbol myristate acetate, cyclic AMP, and cytokines, such as TNF-alpha , IL-6, and IL-1 itself (reviewed in reference 1). Accordingly, a number of signal transduction pathways regulate the expression of IL-1. For example, LPS induces activation of p38, a member of the mitogen-activated protein kinase/extracellular regulated kinase (MAPK/ERK) family of protein kinases (13). p38 MAP kinases, in turn, regulate intracellular events including activation of transcription factors such as ATF-2 (27) and Elk-1 (28) and mRNA translation (18). The requirement for dual phosphorylation on adjacent tyrosine and threonine residues for activation is a salient feature of MAPK/ERK family members. Okadaic acid activates MAPK/ERK p42 (5, 22), but whether these kinases are directly or indirectly involved in the regulation of mRNA stabilization by okadaic acid is not known. A recent study using another serine/threonine phosphatase inhibitor, calyculin A, suggested that MAPK activation alone is not sufficient for induction of IL-1beta (2).

While the role of protein kinases in signal transduction has been well recognized, protein phosphatases have only recently emerged as important regulators of cellular function (7, 37). Our understanding of phosphatases in cellular regulation has progressed from the assumption of a passive role for phosphatases in returning kinase-activated cascades to equilibrium to one of a dynamic signal transduction mechanism. This insight has been provided largely through studies employing serine- and threonine-specific protein phosphatase inhibitors, such as okadaic acid, and the identification, purification, and cloning of their specific phosphatase targets (30). More recently, a number of tyrosine (reviewed in reference 33) and dual-specificity (tyrosine and serine/threonine) phosphatases have also been identified (16, 21, 23). Collectively, the number, specificity, and cyclic nature of the phosphorylation-dependent regulatory mechanisms enables diversity in response to physiological stimuli. Our studies emphasize an important role for protein phosphatases in the regulation of mRNA stability, particularly in the absence of the ability to induce transcription. Endotoxin-tolerant cells, while unable to initiate new transcription of the IL-1beta gene, can utilize basal levels of expression to produce normal levels of IL-1 through phosphorylation-dependent mechanisms. This regulatory pathway could be important as a survival mechanism in animal models of sepsis: the endotoxin-resistant mouse strain C3H/HeJ does not develop rapid inflammatory responses and has a significantly decreased ability to resist infections (8). Utilization of phosphatase inhibitors might increase survival in these animals by restoration of some measure of cytokine-mediated host defense. We have observed that peripheral blood mononuclear cells from a septic patient (endotoxin tolerant) and a healthy individual produce similar levels of IL-1beta when treated ex vivo with okadaic acid (data not shown). Further studies on septic patients and animal models of endotoxin tolerance are necessary to evaluate the therapeutic value of phosphatase inhibition.

The mechanisms involved in tolerance to LPS are largely unknown but do not appear to involve down-regulation or alteration of LPS receptors on the cell surface (9). We did not observe any change in total phosphatase activity in tolerant cells (data not shown), and the inactivation of phosphatases by okadaic acid follows a similar time course in normal and tolerant cells. The similarly delayed kinetics of NF-kappa B induction and IL-1beta mRNA and protein accumulation in response to okadaic acid further suggest that some signal transduction pathways (e.g., those sensitive to serine/threonine dephosphorylation by protein phosphatases 1 and 2A, two phosphatases directly inhibited by okadaic acid), are intact in endotoxin-tolerant cells. Recent evidence suggests that NF-kappa B activation by okadaic acid is indirect and mediated by the induction of reactive oxygen intermediates rather than through directly influencing the phosphorylation state of Ikappa B (29). Whether direct or indirect, okadaic acid induction of IL-1beta appears not to be altered in the endotoxin-tolerant phenotype. IL-1beta mRNA half-life was somewhat prolonged in LPS-stimulated tolerant cells. This increase in mRNA stability did not result in an accumulation of mRNA (Fig. 1A; compare lanes L). This contrasts with the pronounced effect of okadaic acid on IL-1beta mRNA stability, which leads to increases in the levels of IL-1beta mRNA and IL-1beta protein (Fig. 1B and 4B). Taken together, these observations emphasize the importance of a transcriptional defect in maintaining the endotoxin-tolerant phenotype (17).

Results of this study provide further insight into the nature of the transcriptional defect in endotoxin-tolerant cells. The basal level of NF-kappa B binding is increased in the tolerant phenotype, and okadaic acid mediates a further increase in NF-kappa B. However, transcription activation by NF-kappa B remains repressed despite an increase in binding of the putative transcription factors. Similarly, the stably transfected SPAP reporter linked to enhancer/promoter elements from the IL-1beta gene (which contains several NF-kappa B enhancer elements, in addition to other transcription regulatory elements) was also repressed in the tolerant phenotype and did not respond to okadaic acid. A recent study of blood mononuclear cells obtained from patients with sepsis showed increases in NF-kappa B binding (3). Increased NF-kappa B binding correlated with increased mortality. We have also observed increased binding of NF-kappa B in polymorphonuclear cells from patients with severe sepsis (unpublished observations). Polymorphonuclear cells from septic patients do not induce IL-1beta expression in response to endotoxin (20). Collectively, the data support a model of transcription inhibition which is independent of the binding of transcription factors to their regulatory elements. The tolerant phenotype may involve qualitative differences in transcription factors, as suggested by a study with Mono-Mac-6 cells (43) and/or may involve other components of the transcriptional apparatus (e.g., transcription coactivators).

The control of mRNA degradation is a major contributor to the regulation of expression of many cytokines and proto-oncogenes. A common feature of these and other rapidly degraded mRNAs is the presence of multiple copies of AU-rich sequences in the 3'-untranslated region of the mRNA (32). These AU-rich motifs are thought to act as destabilizing elements, perhaps through interaction with a number of RNA-binding proteins which have been recently described (25). IL-1beta and other inflammatory mediators, such as TNF-alpha , contain AU-rich sequences (4), although the roles of these elements and their cognate binding proteins in regulating mRNA stability are not yet known. Interestingly, it appears that no significant quantitative changes in the binding activity of AU-rich elements occur in response to several stimuli which stabilize mRNA (25), suggesting that perhaps mRNA stability is regulated by additional events, such as changes in protein phosphorylation of the RNA-binding proteins. We are currently examining whether okadaic acid may affect AU-rich binding proteins and determining the role these proteins may have in stabilization of IL-1beta mRNA in normal and endotoxin-tolerant cells.

In summary, (i) okadaic acid facilitates IL-1beta gene expression; (ii) okadaic acid regulates IL-1beta mRNA stability, even in the endotoxin-tolerant phenotype; (iii) IL-1beta mRNA stabilization in the endotoxin-tolerant phenotype results in the accumulation of mRNA and synthesis of IL-1beta protein; (iv) the tolerant phenotype is associated with a defect in transcription activation of IL-1beta which does not appear to be alleviated by okadaic acid; and (v) okadaic acid induces DNA binding of NF-kappa B in normal and tolerant cells; however, tolerant cells are unable to activate NF-kappa B-dependent transcription. This suggests that the tolerant phenotype may involve defects in other mechanisms that regulate transcription.

    ACKNOWLEDGMENTS

This work was supported by Public Health Service grants HL-29293 and AI-09169 and General Clinical Research Center grant RR07122 from the National Institutes of Health.

THP-1 5A cells were a gift from John Gray, and the NF-kappa B/CAT reporter construct was a gift from Ed O'Neill.

    FOOTNOTES

* Corresponding author. Mailing address: Department of Medicine, Section on Infectious Diseases, Wake Forest University School of Medicine, Medical Center Blvd., Winston-Salem, NC 27157. Phone: (336) 716-9397. Fax: (336) 716-7492. E-mail: byoza{at}wfubmc.edu.

    REFERENCES
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

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Clinical and Diagnostic Laboratory Immunology, May 1998, p. 281-287, Vol. 5, No. 3
1071-412X/98/$04.00+0
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