ATP-stimulated Release of Interleukin (IL)-1beta and IL-18 Requires Priming by Lipopolysaccharide and Is Independent of Caspase-1 Cleavage*

Veela B. Mehta, Judith Hart, and Mark D. WewersDagger

From the Dorothy M. Davis Heart and Lung Research Institute and Pulmonary and Critical Care Division, The Ohio State University, Columbus, Ohio 43210

Received for publication, July 28, 2000



    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Interleukin (IL)-1beta and IL-18 are structurally similar proteins that require caspase-1 processing for activation. Both proteins are released from the cytosol by unknown pathway(s). To better characterize the release pathway(s) for IL-1beta and IL-18 we evaluated the role of lipopolysaccharide priming, of interleukin-1beta -converting enzyme (ICE) inhibition, of human purinergic receptor (P2X7) function, and of signaling pathways in human monocytes induced by ATP. Monocytes rapidly processed and released both IL-1beta and IL-18 after exogenous ATP. Despite its constitutive cytosolic presence, IL-18 required lipopolysaccharide priming for the ATP-induced release. Neither IL-1beta nor IL-18 release was prevented by ICE inhibition, and IL-18 release was not induced by ICE activation itself. Release of both cytokines was blocked completely by a P2X7 receptor antagonist, oxidized ATP, and partially by an antibody to P2X7 receptor. In evaluating the signaling components involved in the ATP effect, we identified that the protein-tyrosine kinase inhibitor, AG126, produced a profound inhibition of both ICE activation as well as release of IL-1beta /IL-18. Taken together, these results suggest that, although synthesis of IL-1beta and IL-18 differ, ATP-mediated release of both cytokines requires a priming step but not proteolytically functional caspase-1.



    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

IL-1beta 1 and IL-18 are proinflammatory cytokines that require processing by the IL-1-converting enzyme, caspase-1, at specific aspartic acid residues to generate functional molecules (1-3). Although lacking in sequence homology, IL-1beta and IL-18 share significant structural homology (4, 5), bind to receptors from the IL-1 family of receptors (6), exist in the cytosol without a classic signal sequence (3, 7), and are released from cells in a noncanonical fashion (8). Both molecules are regulated posttranscriptionally, and a particularly important aspect of regulation occurs at the level of release (9-14). In this context, recent studies show that this release pathway can be rapidly induced by stimulation with exogenous ATP (15-18). In macrophages, exogenous ATP works via the recently cloned P2X7 receptor, a member of the P2X family of nucleotide-gated channels that are activated by extracellular ATP (19). However, it has been suggested that monocytes do not express P2X7 receptors (20, 21). P2X7 is a 595-amino acid polypeptide with two membrane-spanning domains and intracellular N- and C-terminal domains (22, 23). P2X7 receptor is the only pore-forming P2X family member, and its activation results in the opening of a cationic channel with increased permeability to calcium and intracellular depolarization (20). The present work focuses on release mechanisms by taking advantage of the dramatic ability of ATP to telescope the processing and release down to a 15-30-min interval while enhancing the overall release signal (15).

In this report we examine the mechanism of ATP-induced release of IL-18 and compare it to IL-1beta in human monocytes. We show that fresh monocytes express functional P2X7 receptors that modulate IL-1beta and IL-18 processing and release in response to ATP. Of note, our data suggest that ATP stimulation alone is insufficient to trigger IL-18 processing and release, since priming with LPS was shown to be necessary. Additionally, the ATP effect on release does not require functional caspase-1, confirming for IL-18 what has been previously shown for IL-1beta , i.e. precursor cleavage is not required for release. Finally, attempts to characterize the signaling pathway involved in the ATP effect show that a protein-tyrosine kinase inhibitor, AG126, can potently block activation of caspase-1 and IL-1beta /IL-18 release events, whereas mitogen-activated protein kinase, PKC and PKA inhibitors do not.


    MATERIALS AND METHODS
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Reagents-- ProIL-1beta -specific rabbit polyclonal antibody (amino acids, 3-21) was developed in our laboratory. Human recombinant IL-1beta , biotinylated IL-18, anti-human monoclonal IL-1beta antibody (clone 8516), and IL-18 ELISA kit were purchased from R&D Systems (Minneapolis, MN). Mature IL-1beta and precursor IL-1beta -specific ELISA were from our own laboratory. Polyclonal anti-human P2X7 antibody was from Alamone Laboratories (Jerusalem, Israel), and monoclonal antibody to P2X7 was a gift from Dr. Ian Chessell (University of Cambridge, Cambridge, UK). Recombinant caspase-1 (ICE) and caspase-1 antibody were gifts from Dr. Nancy Thornberry and Dr. Doug Miller (Merck). Herbimycin A, caspase-1 inhibitor (Ac-Tyr-Val-Ala-Asp-chloromethyl ketone (YVAD-cmk)), and tyrphostins and other protein kinase inhibitors were obtained from Calbiochem. Bacterial lipopolysaccharide, Escherichia coli strain 0127:B8, Westphal preparation, was from Difco. LNAME was from Biomol (Plymouth Meeting, PA). Phospho-ERK antibody was obtained from New England Biolab (Plymouth Meeting, PA), and total ERK antibody was from Upstate Biotechnology Inc. (Lake Placid, NY). RPMI 1640 and phosphate-buffered saline were purchased from Biowhittaker Inc. (Walkersville, MD), and fetal bovine serum was from Hyclone Laboratories (Logan, UT). All other reagents were obtained from Sigma unless otherwise specified.

Isolation of Human Peripheral Blood Monocytes and Cell Culture-- Human peripheral blood monocytes were isolated from the heparinized blood of normal donor using histopaque density gradient followed by a monocyte clumping method as described (24). This method yields about 65-75% pure monocytes. Isolated monocytes were cultured at 106/ml in RPMI 1640 supplemented with 5% fetal bovine serum at 37 °C in humidified incubator. Some cells were cultured for 3 h in the presence of LPS (1 ng/ml) and in the presence or absence of caspase-1 (ICE) inhibitor YVAD-cmk (100 µM).

Preparation of Cell Lysates and Western Blot Analysis-- Where indicated, LPS-primed human monocytes were challenged with 5 mM ATP and incubated for an additional 30 min. Culture media was removed from the cells and centrifuged at 800 × g for 5 min, and the supernatants and cell pellets were collected. Cells were lysed in lysis buffer (50 mM Tris-Cl, pH 8.0, 150 mM NaCl, 2 mM EDTA, and 1% Nonidet P-40) containing 2 µg/ml leupeptin, aprotinin, chymostatin, pepstatin, antipain, 0.5 mM phenylmethylsulfonyl fluoride, and 50 µM N-methoxysuccinyl-Ala-Ala-Pro-Val chloromethyl ketone. The cell debris and nuclei were removed by centrifugation at 14,000 × g for 20 min. For the analysis of phospho-ERK in cell lysates of monocytes, 1 mM Na3VO4 and 50 mM NaF were included in lysis buffer. The protein concentration in cell lysates was determined using the Bio-Rad protein assay reagent. The proteins were resolved by SDS-PAGE and transferred to nitrocellulose membrane. Nonspecific sites on nitrocellulose membrane were blocked with 5% nonfat dry milk (Carnation) in TBST (25 mM Tris-Cl, pH-7.5, 150 mM NaCl, 0.05% Tween 20) for 3 h at room temperature. For immunoblotting with phospho-ERK antibody, the membrane was blocked with 3% bovine serum albumin in TBST. The membranes were then probed with primary antibodies as indicated followed by peroxidase-conjugated secondary antibodies, and protein bands were visualized by enhanced chemiluminescence (ECL, Amersham Pharmacia Biotech).

Flow Cytometric Analysis of P2X7 Receptors-- Isolated monocytes were cultured in complete media alone or in complete media containing LPS (1 ng/ml) for 3 h or overnight in LPS (1 µg/ml). For flow cytometric analysis, cells were stained with monoclonal antibody to P2X7 essentially as described (25). Briefly, cells were pelleted, washed twice with wash buffer (1% bovine serum in phosphate-buffered saline), and incubated in wash buffer containing 4 µg/ml monoclonal P2X7 or an isotype (IgG2b) control antibody for 30 min at 4 °C followed by fluorescein isothiocyanate-labeled or rhodamine-labeled rat anti-mouse IgG-specific F(ab')2 fragments (Jackson Immunoresearch laboratories, Westgrove, PA). Some cells were also stained for CD14. For the analysis of P2X7 receptor expression, monocytes were gated for CD14 fluorescence. Flow cytometric analysis was performed using Becton Dickinson FACS Calibur.

IL-1beta and IL-18 ELISA-- Sandwich ELISAs were developed in our laboratory to detect pro- and mature IL-1beta as described (13). The coating antibody has been modified since the previous description. Briefly, anti-human mouse monoclonal IL-1beta antibody (clone 8516, R&D Systems) was used as a coating antibody, and rabbit polyclonal proIL-1beta -specific peptide antibody generated against amino acids 3-21 was used to sandwich the antigen. Horseradish peroxidase (Bio-Rad)-conjugated goat anti-rabbit antibody was used as a developing antibody. The mature IL-1beta ELISA used monoclonal antibody clone 8516 and a rabbit polyclonal mature IL-1beta antibody (raised against entire 17-kDa mature IL-1beta ) as coating and sandwich antibodies, respectively. For the measurement of IL-18, ELISA kits were purchased from R&D Systems, and cell associated and released IL-18 contents were determined per manufacturer instructions.

Statistical Analysis-- Data are presented as the means ± S.E. of the mean from at least three independent experiments. Simple comparisons were done by paired t test, with p < 0.05 considered to represent statistical significance.


    RESULTS
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

ATP Promotes IL-1beta Release-- To establish the optimum timing for future analyses of IL-1beta processing, we initially examined the kinetics of ATP-induced IL-1beta release from LPS-primed human peripheral blood monocytes (Fig. 1). After 3 h of LPS (1 ng/ml), monocytes contained high levels of intracellular IL-1beta with only minimal release. However, ATP (5 mM) induced a dramatic release of mature IL-1beta , most pronounced between 15-20 min, that began to level off after 30 min of ATP. The accumulation of IL-1beta in culture medium correlated with a decrease in cell-associated IL-1beta . In all subsequent experiments, ATP treatment was standardized at 30 min.



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Fig. 1.   Kinetics of IL-1beta release from LPS-primed peripheral blood monocytes after ATP challenge. Human blood monocytes from a normal donor were cultured at a density of 106 cells/ml in 24-well plates. Cells were primed with LPS (1 ng/ml) and incubated at 37 °C for 3 h. ATP (5 mM) was then added to the cells, and at indicated times, cells and supernatants were collected. Cell-associated and -released IL-1beta s were measured by proIL-1beta -specific and mature sandwich ELISA, respectively.

ATP-stimulated Release of IL-1beta and IL-18 Requires LPS Priming-- Having established the kinetics of the ATP effect on IL-1beta , we next compared the related cytokine IL-18 to IL-1beta for ATP-mediated release. As shown in Fig. 2, A and B, the LPS priming induced a dramatic release of both IL-1beta and IL-18 at 30 min after ATP treatment. However, there were significant differences in the ability of LPS to induce IL-1beta compared with IL-18. Whereas unprimed monocytes contained very little IL-1beta intracellularly (Fig. 2C) (2.2 ± 1.5 ng/106 cells), low dose LPS induced a dramatic induction of intracellular proIL-1beta (30.2 ± 12.1 ng/106 cells). In contrast, there was no difference between unprimed and LPS-primed monocytes for the presence of intracellular IL-18 (Fig. 2D) (378 ± 22 versus 409 ± 5 pg/106 cells, p = not significant).



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Fig. 2.   ATP-stimulated release of IL-18 requires priming by LPS. Monocytes were plated in the presence or absence of LPS (1 ng/ml) for 3 h at 37 °C. Cells were then exposed to 5 mM ATP for 30 min. Released (A and B) and cell-associated (C and D) IL-1beta and IL-18 were determined by sandwich ELISA as described. The data represent the mean ± S.E. of three independent experiments performed in duplicate.

The constitutive presence of IL-18 in unprimed monocytes provided a unique opportunity to determine whether monocyte IL-18 processing and release induced by ATP requires a priming signal. Of particular note, despite the constitutive presence of intracellular IL-18 in the unprimed monocytes, ATP alone had no effect on inducing its release (Fig. 2B) (control, 54 ± 19 versus ATP, 67 ± 28 pg/106 cells). However, after priming with LPS, ATP-induced IL-18 release increased 4-fold (215 ± 60 pg/106 cells; p < 0.05 compared with control). Our data thus demonstrate that ATP-stimulated release of IL-18 requires priming by LPS.

Caspase-1 Inhibition Does Not Prevent the Release of IL-1beta and IL-18-- Caspase-1, which is critical for processing IL-1beta and IL-18, has been variably linked to the release pathway for these cytokines. It has been shown for example that caspase-1 -/- macrophages are impaired for IL-1beta release (26). To investigate the requirement for caspase-1 function in ATP-induced IL-1beta and IL-18 release, we inhibited caspase-1 with the tetrapeptide, YVAD-cmk (100 µM). We analyzed IL-1beta and IL-18 release with ELISAs able to detect both cytokines in the precursor form (13). Human monocytes were cultured with YVAD and LPS in varying combinations (Fig. 3). As we and others have previously shown (13, 27), the presence of an ICE inhibitor prevented mature IL-1beta release from LPS-primed, ATP-stimulated, monocytes (data not shown). Importantly, however, a significant quantity of proIL-1beta was detected in supernatants using a proIL-1beta -specific ELISA (Fig. 3, A and C).



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Fig. 3.   Processing of IL-1beta and IL-18 is not required for ATP-induced release. Monocytes were cultured in the presence of either Me2SO (DMSO) alone, YVAD (100 µM) alone, or LPS and YVAD combined. Where indicated, after 3 h cells were challenged with ATP (5 mM) for 30 min. Samples were analyzed with ELISAs that detect the cytokines in their precursor forms. IL-1beta . Released (A) and cell-associated (C) IL-1beta and IL-18 were measured by the proIL-1beta -specific ELISA. Released (B) and cell associated (D) IL-18 was measured by R&D Systems IL-18 ELISA.

As was shown for IL-1beta , after LPS priming, ATP induced monocytes to release IL-18 (Fig. 3, B and D). Although ATP alone did not stimulate the release of IL-18 from cells treated with caspase-1 inhibitor, ICE inhibition did not prevent IL-18 release from LPS-primed, ATP-stimulated monocytes (Fig. 3, B and D). These data suggest that release of IL-1beta and IL-18 does not require active ICE. Therefore, as has been shown for IL-1beta , the processing of IL-18 is not required for its externalization.

ATP Treatment Promotes IL-1beta and IL-18 Processing-- To confirm that the ATP treatment not only induces release but also promotes processing of IL-1beta and IL-18, monocyte samples were also assayed by immunoblots (Figs. 4, A and B). We assessed the effects of ATP on the processing of IL-18 and IL-1beta in untreated monocytes or in monocytes treated with YVAD or LPS alone or combined LPS and YVAD. Only the 24-kDa precursor form of IL-18 and the 31-kDa form of IL-1beta were detectable in cell lysates. In cell supernatants of unstimulated or LPS-primed cells, no IL-1beta was detected; however, low levels of the precursor form of IL-18 were detectable. In LPS-primed, ATP-stimulated monocyte supernatants, a large amount of 18-kDa IL-18 was detected. In the same supernatants, the 31-kDa form of proIL-1beta was not observed, but a large amount of mature 17-kDa IL-1beta was detected.



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Fig. 4.   ATP stimulates processing and release of IL-1beta and IL-18. Monocytes were stimulated with LPS (1 ng/ml) in the presence or absence of 100 µM YVAD for 3 h and challenged with ATP for 30 min. Lysates and supernatants were analyzed by 10-20% gradient SDS-PAGE for IL-1beta (A) or 15% SDS-PAGE for IL-18 (B). The proteins were transferred to nitrocellulose and blotted with anti-proIL-1beta -specific or biotinylated IL-18 antibodies. In the lower panel of A the blot was stripped and reprobed with anti-mature IL-1beta antibody. rIL-1beta , recombinant IL-1beta .

In the presence of YVAD-cmk, only precursor forms of IL-18 and IL-1beta were detected in supernatants of LPS-primed, ATP-treated monocytes (Fig. 4, A and B). There was no obvious difference in the amount of secreted IL-18 and IL-1beta in the presence or absence of YVAD. These observations show that YVAD blocks maturation of proIL-1beta and IL-18 but does not block the release. Thus, both IL-18 and IL-1beta require functional caspase-1 for processing during export.

ATP Induces ICE Activation-- It has been reported that prolonged ATP treatment (3 h) activates caspase-1 in LPS-primed human monocytes (28). It is not clear whether the short exposure to ATP (30 min) in our experimental system also activates ICE in LPS-primed human monocytes. Therefore, we examined the effect of ATP and YVAD on activation of ICE by immunoblot analysis (Fig. 5A). Monocytes were cultured in the presence or absence of LPS and with or without YVAD for 3 h. ATP (5 mM) was then added where indicated, and cells were incubated for an additional 30 min. In control and LPS-primed cells, the 45-kDa precursor and intermediate forms of ICE were detected, but very little 20-kDa (active form of ICE) was seen. However, LPS-primed monocytes treated with ATP generated a significantly higher level of mature subunits (p20 and p10) of ICE, which was blocked by the presence of YVAD-cmk.



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Fig. 5.   ATP induces activation of caspase-1. A, cells were cultured either alone or in the presence of LPS (1 ng/ml) and with or without YVAD-cmk (100 µM) for 3 h, and then ATP (5 mM) was added where indicated. Lysates were resolved on 10-20% gradient SDS-PAGE, transferred to polyvinylidene difluoride (Amersham Pharmacia Biotech) membrane, and probed with polyclonal anti-caspase-1 (ICE) antibody. rICE, recombinant ICE. B, to show the effect of ATP alone, the experiment in A was repeated with the inclusion of ATP without LPS.

Since, in the absence of LPS priming, ATP alone had no effect on IL-18 processing and release, it was important to determine whether ATP alone could activate ICE. As shown in Fig. 5B, ATP without LPS activated ICE to the p20 form in both LPS-primed and unprimed monocytes. Thus, the data from ELISA and immunoblots, taken together with the evidence of ICE activation, show that ATP not only activates ICE but also the processing and release of IL-1beta and IL-18. Although YVAD-cmk blocks the activation of ICE and the maturation of these precursor cytokines, it fails to inhibit the release of proIL-1beta and proIL-18. Conversely, in the absence of LPS priming, ATP-induced ICE activation does not induce processing and release. Thus, although ATP induces ICE activation, it requires an additional signal to induce processing and release of IL-1beta and IL-18.

Monocyte Expression of P2X7 Receptors-- A number of reports to date suggest that ATP-induced release of IL-1beta in LPS-primed monocytes occurs via P2X7 receptors (15, 25, 29). Human monocytes cultured for 1-3 days in the presence of LPS or monocytes cultured overnight in the absence of any stimulus contain P2X7 receptors (25). However, it is not yet clear if fresh human monocytes cultured for 3 h with or without LPS express P2X7 receptors. To address this question, we analyzed human monocytes cultured in the presence or absence of LPS for 3 h for the expression of P2X7 receptors by flow cytometry and immunoblot analysis. By flow cytometry, a significant signal for P2X7 receptor was observed in human monocytes when compared with the isotype control. Importantly, the reactivity with P2X7 antibody was only minimally enhanced in cells cultured in the presence of LPS for 3 h (Fig. 6). Immunoblot analysis confirmed the results of flow cytometry. A 55-kDa band was detected in LPS-stimulated and unstimulated monocyte lysates that was competed away with the immunizing peptide (Fig. 7). These data confirm that fresh monocytes express P2X7 receptors that are only minimally increased by LPS.



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Fig. 6.   Characterization of P2X7 receptors on human blood monocytes. Human monocytes were cultured alone or with LPS (1 ng/ml) for 3 h. Cells were washed with PBS and incubated on ice with 4 µg/ml monoclonal anti-P2X7 antibody for 30 min. The P2X7 receptors were detected with a fluorescein isothiocyanate-labeled donkey anti-mouse F(ab')2 fragment. An IgG2b antibody was used an isotype control. The monocytes were gated by anti-CD14 antibody fluorescence for the presence of P2X7 receptors by flow cytometric analysis.



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Fig. 7.   Immunoblot of P2X7 receptor expression on human monocytes. Cells lysates from LPS-primed or unprimed monocytes were subjected to 10-20% gradient SDS-PAGE, transferred to nitrocellulose, and probed with polyclonal anti-P2X7 receptor antibody (Alamone Laboratories) as described. A, blot probed with P2X7 receptor antibody; B, parallel blot probed with anti-P2X7 antibody containing immunizing peptide (1:1 w/w). Lysate of rat brain (R.B.) membrane showing 56- and 80-kDa P2X7 was used as positive control. hP2X7, human P2X7.

Oxidized ATP Blocks the ATP-stimulated Release of IL-1beta in LPS-primed Human Monocytes-- We then asked the question whether monocytes express functional P2X7 receptors. Therefore, we attempted to determine if the P2X7 receptor antagonist, oxidized ATP, and a P2X7-specific antibody prevents the ATP-stimulated release of IL-1beta in LPS-primed human monocytes. Pretreatment with 300 µM oxidized ATP for 30 min completely abolished the ATP-induced release of IL-1beta in human monocytes (Fig. 8). Pretreatment with P2X7-specific monoclonal antibody also blocked the ATP-stimulated release of IL-1beta but to a lesser extent (Fig. 8). The data suggest that the P2X7 receptor is responsible for the ATP effects.



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Fig. 8.   Effect of oxidized ATP and P2X7 blocking antibody on ATP-induced release of IL-1beta from human monocytes. Monocytes were cultured alone or with LPS for 3 h. ATP was added to selected samples for the final 30 min. Where indicated, P2X7 monoclonal antibody (P2X7ab) was given with the LPS, and oxidized ATP (oATP) was added 30 min before ATP. Released (A) IL-1beta contents were measured by mature IL-1beta ELISA, and cell-associated (B) was measured by proIL-1beta -specific ELISA. Results from duplicate experiments are shown.

Effect of Signaling Inhibitors on ATP-stimulated Release of IL-1beta -- We hypothesized that protein kinases may play a significant role in the release of IL-18 and IL-1beta from LPS-primed human monocytes. Initially, we compared the effects of various inhibitors of protein-tyrosine kinases, protein kinase C, and protein kinase A on release of IL-1beta from LPS-primed human monocytes (Table I). Whereas platelet-derived growth factor (AG1296) and epidermal growth factor (AG1478) receptor kinase inhibitors and PKA or PKC pathway inhibitors had no effect, tyrphostin AG126, a PTK inhibitor, prevented ATP-induced release of IL-1beta from LPS-primed monocytes (~80% inhibition). The effect was dose-dependent and not cytotoxic to the cells in the concentrations used in the experiment. It therefore appears that ATP-stimulated IL-1beta release is mediated by an AG126-sensitive tyrosine kinase(s).


                              
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Table I
Effect of protein kinase inhibitors on ATP mediated release of IL-1beta from LPS-primed monocytes

MEK Inhibitors Do Not Block IL-1beta Release-- AG126 is a potent inhibitor of PTK and inhibits NO production and ERK activation while protecting mice from LPS-induced septic shock (30, 31). Therefore, we asked whether the AG126 effect on monocyte IL-1beta and IL-18 release is due to the block in NO production or inhibition of ERK activation.

Using ELISA detection, we first assessed the effects of PTK inhibitors herbimycin A and AG126, mitogen-activated protein kinase kinase inhibitors UO126 and PD98059, and nitric-oxide synthase inhibitor LNAME on ATP-induced release of IL-1beta in LPS-primed monocytes (Fig. 9A). Again, AG126 inhibited IL-1beta release in a dose-dependent manner, whereas the other PTK inhibitor herbimycin A and the MEK inhibitors UO126 and PD98059 did not inhibit ATP induced IL-1beta release (Fig. 9A).



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Fig. 9.   AG126 blocks ATP-stimulated release of IL-1beta but not ERK activation. LPS-activated cells were preincubated with various inhibitors for 15 min and then exposed to 5 mM ATP for 30 min. A, released IL-1beta was analyzed in cell supernatants using the mature IL-1beta ELISA. The bar graph represents the average ± S.E. of three independent experiments performed in duplicate. Inhibitors include PD98059 (PD) and herbimycin A (HA). DMSO, Me2SO. B, cell lysates were analyzed by blotting with polyclonal anti-phospho-ERK antibody (top). The blot was stripped and reprobed with total ERK antibody (bottom), and proteins were visualized by ECL. The p42 and p44 forms of ERK are abbreviated as p42ERK and p44ERK, whereas the corresponding phosphorylated ERK forms are abbreviated as pp42ERK and pp44ERK.

To examine whether the AG126 effect was due to the inhibition of NO production, we analyzed ATP-induced IL-1beta release in the presence of LNAME, a nitric-oxide synthase inhibitor. Interestingly, instead of the inhibition of release, LNAME enhanced IL-1beta release by 2-3-fold. Of note, AG126 totally abolished the LNAME activated release of IL-1beta (Fig. 9A).

Effect of AG126 on ERK Phosphorylation-- We then evaluated whether AG126 inhibits ATP-induced ERK phosphorylation (Fig. 9B). Whereas the classic MEK inhibitors, UO126 and PD98059, prevented ERK phosphorylation, AG126 did not. In contrast, the MEK inhibitors did not prevent IL-1beta and IL-18 release, but AG126 did. Therefore, the results indicate that the activation of mitogen-activated protein kinase pathway is not essential for ATP-induced IL-1beta release from LPS-primed monocytes.

The Mechanism of the AG126 Effect-- It is possible that the tyrosine kinase activity inhibited by AG126 regulates caspase-1 activation. We therefore asked if the inhibition of ATP-stimulated release of cytokines by AG126 is mediated by the inactivation of ICE. To accomplish this we examined the ATP-induced processing and release of IL-1beta and IL-18 in the presence of kinase inhibitors. Western blot analysis of the cell supernatants for IL-1beta (Fig. 10A) and IL-18 (Fig. 10B) confirmed the ELISA (Fig. 9) results. As it did for IL-1beta , AG126 inhibited the processing and release of IL-18. The MEK inhibitors, herbimycin A and the nitric-oxide synthase inhibitor LNAME, did not affect ATP-induced processing and release of the cytokines.



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Fig. 10.   AG126 inhibits caspase-1 activation and processing and release of IL-1beta and IL-18. LPS-primed monocytes were treated with various inhibitors as described for Fig. 9, and supernatants were subjected to Western blot analysis for mature IL-1beta (A) and for IL-18 (B), and p20 caspase-1 (C). The position of both pro- and mature proteins are shown for IL-18. DMSO, Me2SO.

Finally, we examined the effect of AG126 on caspase-1 activation by Western blot analysis. Interestingly, AG126 also inhibited the ICE activation, as the 20-kDa active form of ICE was not detected; whereas, herbimycin A, MEK, and nitric-oxide synthase inhibitors had no effect on ATP-induced activation of ICE (Fig. 10C). Thus the inhibition of IL-1beta release by AG126 correlates with the inhibition of ATP-induced ICE activation, and the processing of ICE appears to be regulated by AG126-sensitive protein-tyrosine kinases.


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The processing of precursor IL-1beta and IL-18 and their secretion into the exterior are key regulatory events in inflammation, yet remain poorly understood. Both proIL-1beta and proIL-18 are biologically inactive proteins that require cleavage by caspase-1 for biological activation (8, 9, 32). Both IL-1beta and IL-18 share significant structural homology (4, 5), and both lack a leader sequence required for their secretion. Furthermore, although the release of mature IL-1beta and IL-18 appears to be linked to the processing of precursor forms by caspase-1, functional ICE has not been detected in monocytes, macrophages, or monocytes cell line THP-1 even when the processing and release of IL-1beta was induced by LPS (13, 33).

Previous studies provide strong evidence that extracellular ATP enhances both the magnitude and the velocity of the posttranslational processing and release of proIL-1beta from peritoneal murine macrophages and human and microglial cells stimulated with LPS and monocytes (15, 18, 27, 34, 35). This ATP-triggered release of IL-1beta occurs via activation of the P2X7 receptor (15, 29). The telescoping of the release and processing events provided by ATP allow a more detailed dissection of the events that regulate the processing and release of IL-1beta and IL-18.

In this context, we utilized this unique activity of ATP to compare IL-18 and IL-1beta processing and release. We provide evidence that there are marked similarities between IL-1beta and IL-18 in this regard, and we used the constitutive presence of proIL-18 to evaluate the role of priming in the release event. First of all, we show that, although IL-18 is present in fresh monocytes, the addition of ATP alone is insufficient to induce IL-18 release. Second, utilizing assays specific for the mature and precursor forms of these cytokines, we demonstrate that the ICE inhibitor, YVAD-cmk, inhibits the ATP-induced maturation of both IL-1beta and IL-18 but not their release. Third, we show that exogenous ATP rapidly activates caspase-1 in both primed and unprimed monocytes. Furthermore, this ATP effect is mediated through constitutively present and functional P2X7 receptors. Finally, we show that the ATP-induced activation is, at least in part, dependent upon protein-tyrosine kinase activity, since it is inhibited by the PTK inhibitor AG126 but not by nitric-oxide synthase inhibition or by mitogen-activated protein kinase, PKC, or PKA inhibitors. Thus, we demonstrate that both IL-1beta and IL-18 are released in a similar fashion and that LPS priming is necessary for this activation for IL-18 and by implication for IL-1beta as well. Furthermore, we provide the first report showing evidence that caspase-1 activation is regulated by a protein-tyrosine kinase activity.

The requirement for LPS priming for the ATP induction of IL-18 was unexpected and is particularly noteworthy. Since LPS priming was necessary for the generation of intracellular IL-1beta , we expected that the ATP effect was simply a direct trigger of the ICE activation and protein release pathway. However, the findings with IL-18 provide the first evidence to suggest that ATP alone is not able to trigger either processing or release. This LPS "priming" event was not due to an up-regulation of P2X7 receptors, since our flow cytometry and immunoblot analyses showed constitutive presence of P2X7 receptors with only minimal induction by LPS (Fig. 6).

The role of LPS priming in caspase-1 activation is also worthy of comment. As shown in Fig. 5B, ATP stimulation alone activates caspase-1 without inducing processing of constitutive IL-18 or inducing its export from the cell (Fig. 4B, lanes 4 and 13). However, ATP stimulation after LPS priming induces both caspase-1 activation (Fig. 5B, fourth lane) and IL-18 processing and release (Fig. 4B, lanes 3 and 12). These observations suggest that the ATP effect on the release pathway is distinct from its effect on ICE activation.

In confirmation of prior studies, we found it difficult to document the presence of mature IL-1beta or mature IL-18 inside LPS-primed, ATP-stimulated monocytes (Fig. 4, A and B). These data suggest that the processing and release of IL-1beta and IL-18 are rapid and probably concurrent events. However, these concurrent events are likely independent of each other, since the caspase-1 inhibitor, YVAD-cmk, did not prevent the release of the larger precursor forms. Nevertheless, these findings do not exclude the possibility that caspase-1 may have a role in release that is separate from its function as a protease. For example, in ICE knockout animals, there is a deficit in release of both the mature and precursor forms of IL-1beta (26). This raises the possibility that either caspase-1 itself or caspase-1-affiliated molecules make up part of the protein machinery involved in IL-1beta and IL-18 release. Since caspase-1 contains a classic caspase recruitment domain (CARD), one can speculate that CARD-interacting molecules may make up part of this release machinery (37). The protein-protein interactions induced by similar recruitment domains are known to be important in the function of apoptotic caspases (38).

Since it has been reported that freshly isolated human monocytes do not express P2X7 receptors, we were intrigued by the responsiveness of fresh monocytes to ATP in our experiments (20). Flow cytometric and Western blot analysis showed that indeed monocytes constitutively express P2X7 receptors and the addition of LPS only marginally induced P2X7 receptor expression. The role of the P2X7 was confirmed by several experiments. First of all, oxidized ATP, a selective inhibitor of P2X7 receptor, completely and irreversibly blocked the ATP-mediated release of IL-1beta in LPS-primed monocytes. In addition, the effect was also significantly inhibited by a monoclonal antibody directed at the P2X7 receptor but not by an isotype control. Finally, the presence of P2X7 receptors was shown by both fluorescence flow cytometry and by immunoblot analysis. Thus, monocytes are extremely responsive to ATP-induced IL-1beta activation via P2X7 receptors.

Signaling pathways regulate many cellular processes. We therefore hypothesized that activation of protein kinases may play a crucial role in release of IL-1beta and IL-18. Using classic protein kinase inhibitors, we screened for kinases that might control release-related events. We were intrigued by the potent inhibition provided by the tyrphostin AG126. AG126 is a protein-tyrosine kinase inhibitor that has been reported to be protective of endotoxin-induced shock in a mouse model (31). This is particularly intriguing from the perspective that the AG126 effect mimics that seen in ICE knockout animals. AG126 blocks both ICE processing and IL-1beta and IL-18 release. This inhibition resembles the defect seen in macrophages from ICE-deficient animals (26). Although IL-18 and IL-1beta knockout animals are not protected from septic shock, ICE knockout animals are protected (26). Thus, events centered at the caspase-1 molecule may be critical. In this context, it is important to note that inhibition of ICE activity by YVAD-cmk does not prevent release, whereas genetic deletion of caspase-1 or treatment with AG126 does. One can hypothesize that there are release-related molecules that are linked to caspase-1. Thus, it appears that an aspect of caspase-1 independent of its proteolytic function is critical to release. Since AG126 inhibits both caspase-1 functions, the identification of this AG126-sensitive tyrosine kinase will likely represent a crucial activation step in IL-1beta /IL-18 processing and release, which appears to be critical to the sepsis response pathway.

In an effort to put the present findings in context, it may be helpful to review the relationship of our results to the known signaling pathways for ATP and LPS. For example, ATP activates phospholipase D in THP-1 cells, p42/p44 ERK phosphorylation in astroglial cells, and NFkappa B activation in microglial cells (39-41). LPS is known to induce activation of PTK-, PKC-, PKA-, and ceramide-activated protein kinase signaling pathways (42). LPS also induces activation of src family of tyrosine kinases Hck, Fgr, and Lyn. However, these members of src family of tyrosine kinases do not appear to be the targets of AG126 because the production and secretion of IL-1beta , IL-6, and tumor necrosis factor-alpha in mice lacking Hck, Fgr, and Lyn is normal (36). In addition, p42/p44 ERK is not required for the ATP-activated release of IL-1beta and IL-18, since PD98059 and UO126 did not prevent processing and release but did block ERK phosphorylation. Thus the protein-tyrosine kinase inhibited by AG126 remains uncharacterized.

Taken together these findings suggest that the regulation of the processing and release of IL-1beta and IL-18 is similar and critical to the outcome in endotoxin responses. More importantly, these findings suggest that that this regulatory event is linked to caspase-1 activation. Thus, the molecular events that control the processing and release of IL-1beta and IL-18 are likely to be similar and to be critical to regulation of inflammatory responses.


    ACKNOWLEDGEMENTS

We thank Dr. Ian Chessell for providing monoclonal antibody to P2X7 and Dr. Doug Miller and Dr. Nancy Thornberry of Merck for recombinant caspase-1 and caspase-1 antibody. We also thank Tina Bees for the preparation of figures.


    FOOTNOTES

* This work was supported by NHLBI, National Institutes of Health Grant 40871 (to M. D. W.).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Dagger To whom correspondence should be addressed: 110L Davis Heart and Lung Research Institute, 473 W. 12th, Columbus, OH 43210. Tel.: 614-293-4925; Fax: 614-293-4799; E-mail: wewers.2@osu.edu.

Published, JBC Papers in Press, October 30, 2000, DOI 10.1074/jbc.M006814200


    ABBREVIATIONS

The abbreviations used are: IL, interleukin; ICE, interleukin-1beta -converting enzyme; PTK, protein-tyrosine kinase; P2X7, human purinergic receptor; MEK, mitogen-activated protein kinase/extracellular signal-regulated kinase kinase; PKA and PKC, protein kinases A and C, respectively; ELISA, enzyme-linked immunosorbent assay; YVAD-cmk, acetyl-Tyr-Val-Ala-Asp-chloromethyl ketone; ERK, extracellular signal-regulated kinase; LPS, lipopolysaccharide; PAGE, polyacrylamide gel electrophoresis.


    REFERENCES
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES


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