Protection from T Cell-Mediated Murine Liver Failure by Phosphodiesterase Inhibitors

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Vol. 280, Issue 1, 53-60, 1997

Protection from T Cell-Mediated Murine Liver Failure by Phosphodiesterase Inhibitors¹

Florian Gantner, Sabine Küsters, Albrecht Wendel, Armin Hatzelmann, Christian Schudt and Gisa Tiegs

Biochemical Pharmacology, Faculty of Biology, University of Konstanz, D-78434 Konstanz (F.G., S.K., A.W., G.T.); Byk Gulden, D-78462 Konstanz (A.H., C.S.), Germany

	Abstract

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Injection of the T cell mitogens concanavalin A (Con A) into nonsensitized or of staphylococcal enterotoxin B (SEB) into D-galactosamine(GalN)-sensitized mice is known to cause fulminant liver failurevia a cytokine response syndrome with tumor necrosis factor- $alpha$ (TNF) as the pivotal mediator. We examined in vivo whether thephosphodiesterase (PDE) inhibitors motapizone (PDE3-selective)and rolipram (PDE4-selective) affected cytokine release and hepaticinjury after T cell activation. Both motapizone as well as rolipramdose-dependently (0.1-10 mg/kg) attenuated the systemic releaseof TNF and interferon- $gamma$ as initiated by injection of Con A (25mg/kg) or SEB (2 mg/kg). Although interleukin-4 production wasnot affected by motapizone or decreased by rolipram, circulatinglevels of interleukin-10, however, were significantly increasedin PDE inhibitor-treated mice compared with controls. Associatedwith the suppression of the central mediator TNF, motapizone androlipram protected mice from liver injury in the Con A as wellas in the SEB model. Moreover, the combined administration ofmotapizone plus rolipram at doses which were ineffective whengiven alone completely protected mice from GalN/SEB toxicity.These data demonstrate that PDE inhibitors effectively attenuatean inflammatory T cell response in vivo and strongly suggest atherapeutic potential as anti-inflammatory drugs in T cell-relateddisorders. We conclude that cAMP-elevating drugs shift the balanceof T cell-derived cytokines from a proinflammatory to an enhancedanti-inflammatory factor release, thus protecting mice from TNF-mediatedhepatic failure.

	Introduction

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T lymphocytes are causally involved as effector cells evoking liver disease caused by viral infection (i.e., viral hepatitis)or autoimmune disorders such as chronic active hepatitis, autoimmunehepatitis, primary biliary cirrhosis or primary sclerosing cholangitis(reviewed in Meyer zum Büschenfelde et al., 1993). As a consequenceof the activation of these cells, proinflammatory cytokines aresystemically released, which possibly accounts for the pathophysiologicaloutcome and clinical manifestation of liver disease. The mostpotent proinflammatory cytokine in this context is TNF. TNF causeshepatic failure in humans (for review, see Jones and Selby, 1989;Waage, 1993), a phenomenon that has been widely studied in variousexperimental animal models, mostly in rodents. Pretreatment ofmice with inhibitors of hepatic transcription such as GalN rendersthem extremely sensitive towards TNF-inducible liver failure (Tiegset al., 1989, 1990; Wendel, 1990) and lethality (Galanos et al.,1979; Lehmann et al., 1987). In these experimental models eitherTNF itself, or more commonly, LPS, a potent inducer of endogenousTNF production by activation of monocytes and macrophages, isinjected into mice. The use of superantigens such as SEB (Miethkeet al., 1992; Nagaki et al., 1994; Gantner et al., 1995a) or ofagonistic T cell receptor antibodies (Gantner et al., 1995a) asT cell activators in GalN-sensitized animals or of the T cellmitogen Con A in nonsensitized mice (Tiegs et al., 1992) expandedthese experimental settings to a variety of different T cell-specificmodels. In any of them, TNF has been identified as the distalhepatotoxic mediator because passive immunization against TNFcompletely protected mice from liver injury independent of theT cell activator used (Miethke et al., 1992; Nagaki et al., 1994;Mizuhara et al., 1994; Gantner et al., 1995a,b).

These facts suggest that TNF suppression might be a promising pharmacological approach to prevent liver damage induced byT cell activation. Cyclic AMP-elevating drugs such as PDE inhibitorsare known to inhibit monocyte- and macrophage-derived TNF productionafter LPS stimulation in vitro (Semmler et al., 1993; Fischeret al., 1993; Reinstein et al., 1994; Prabhakar et al., 1994;Seldon et al., 1995; Jilg et al., 1996) and in vivo (Fischer etal., 1993; Jilg et al., 1996). In human peripheral blood mononuclearcell cultures (Essayan et al., 1994; Gantner et al., 1995c) orin the murine T_H2 cell line D10G4.1 (Schmidt et al., 1995), thecombined inhibition of PDE3 and PDE4 was most effective in blockingT cell proliferation and in modulating cytokine production. Recentreports gave a first hint that PDE4-selective inhibitors suchas the antidepressant rolipram might be beneficial in vivo inchronic T cell-mediated disorders such as experimental allergicencephalomyelitis, thought to be a model for multiple sclerosis,in which TNF also plays a significant role (Sommer et al., 1995;Genain et al., 1995). We investigated the in vivo potential ofPDE inhibitors selective for PDE3 (motapizone) or PDE4 (rolipram),respectively, in our acute models of T cell-mediated hepatic failure.With these inhibitors, we studied their modulatory effects onthe T cell activation-induced cytokine pattern released and onthe outcome of liver failure after T cell activation in naivemice (Con A model) and in animals sensitized by transcriptionalinhibition (GalN/SEB model).

	Materials and Methods

Top Abstract Introduction Materials & Methods Results Discussion References

Animals. Male BALB/c mice weighing 25 ± 3 g were purchased from the internal breeding stock of the animal house of University of Konstanz,Germany. All mice were kept at 22°C and 55% relative humidityin a 12-h day/night rhythm with free access to food (Altromin1313) and water. Sixteen hours before the experiment started foodwas withdrawn, and the mice were not fed overnight. All animalsreceived humane care in compliance with National Institutes ofHealth guidelines and according to legal requirements in Germany.

Treatment schedules. Con A was purchased from Sigma Chemical Co. (St. Louis, MO) and 25 mg/kg were administered i.v. in a volume of 300 µl pyrogen-freesaline into the tail vein. GalN (Roth Chemicals, Karlsruhe, Germany)was given intraperitoneally at a dose of 700 mg/kg in 200 µl saline15 min before injection of SEB (Sigma; 2 mg/kg i.p. in 200 µlsaline). Rolipram (4-(3 $'$ -cyclopentyloxy-4 $'$ -methoxyphenyl)-2-pyrrolidone)and motapizone (4,5-dihydro-6-[4-(11-imidazol-1-yl)-2-thienyl]-5-methyl-3-pyridazinone)were administered i.p. 30 min before challenge in a volume of200 µl solvent (Sandimmune placebo, Sandoz, Basel, Switzerland).The same volume of solvent solution was injected into controlanimals. For determination of time courses of cytokine releaseinto the circulation, animals were sacrificed at various timepoints after challenge by injection of heparinized pentobarbital(150 mg/kg), and blood was withdrawn by heart puncture into heparinizedsyringes. Blood sampling from the tail vein for determinationof plasma cytokine peak concentrations was performed at the timepoints indicated. Plasma samples were kept frozen at $-$ 70°C untilfurther use.

Cytokine assays. All enzyme-linked immunosorbent assays were performed on flat-bottomed, high-binding polystyrene microtiter plates (Greiner,Nürtingen, Germany) with use of specific rat anti-mouse monoclonalantibody pairs purchased from Pharmingen (San Diego, CA). A polyclonalmonospecific ovine anti-mouse TNF antibody prepared by S. Jilgin the laboratory of Dr. A. Wendel (immunoglobulin G fraction;protein content, 20 mg/ml) after immunization of a ram with recombinantmuTNF- $alpha$ was used for coating instead of the Pharmingen antibody.Streptavidin-peroxidase was from Jackson Immuno Research (WestGrove, PA) and the peroxidase substrate BM blue was from Boehringer(Mannheim, Germany). IL-10 was determined with the INTERTEST-10×TMELISA kit (Genzyme, Cambridge, MA). The detection limits of theassays were 15 pg/ml for IL-10, 10 pg/ml for TNF and IFN $gamma$ and5 pg/ml for IL-4, respectively.

Assessment of liver failure. Eight hours after Con A or SEB injection animals were sacrificed by cervical dislocation, and blood was collected by heartpuncture. Plasma enzyme activities of ALT, AST and SDH, respectively,were assessed according to Horder and Rej (1984).

Statistics. Unless otherwise stated, data are expressed as means ± S.D. of experiments carried out in triplicate. Data were analyzed bynonparametric analysis of variance (Kruskal-Wallis), and wherethere were differences among the groups (P > .05) data were subjectedto one-sided nonparametric multiple comparisons of the diseasecontrol group against all other groups (Zar, 1984). P < .05 wasconsidered to be significant.

	Results

Top Abstract Introduction Materials & Methods Results Discussion References

T cell activation-induced cytokine release in vivo. In previous studies we have shown the plasma kinetics of the cytokines TNF, IFN $gamma$ , IL-2 and GM-colony-stimulating factor afterCon A challenge of mice (Gantner et al., 1995b). Because PDE inhibitorswere recently demonstrated to affect murine T_H2-type cytokineproduction in vitro (Schmidt et al., 1995), we first checked whetherand when the T_H2-type cytokines IL-4 and IL-10 were released inour in vivo models. The T cell activation-induced IL-4 and IL-10plasma cytokine levels are shown in figure 1 in comparison withthe time course of TNF release, i.e., the central mediator ofCon A- and GalN/SEB-induced liver failure, and in comparison withthe T_H1-type cytokine IFN $gamma$ . Con A induced detectable amounts ofIL-4 as early as 30 min after challenge with a further increaseup to a maximum concentration of about 900 pg/ml at 2 to 2.5 hthat declined afterward. IL-10 was released in a biphasic mannercharacterized by a high first peak at 30 min (4600 ± 420 pg/ml).This was followed by complete absence of circulating IL-10 at4 h, before a second phase of IL-10 production was noted 6 to8 h after Con A challenge.

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Fig. 1. Time course of cytokine release into plasma of BALB/c mice injected i.v. with 25 mg/kg Con A (filled symbols) or GalN (700mg/kg i.p.)/SEB (2 mg/kg i.p., open symbols). Data are expressedas mean values from a single experiment with three mice (IL-4)or as mean values from two independent experiments using threeanimals each (n = 6; TNF, IFN $gamma$ , IL-10) ± S.D. At the time pointsindicated mice were sacrificed and the plasma samples taken werefrozen at $-$ 70°C until cytokine determination by enzyme-linkedimmunosorbent assay. The maximum circulating cytokine concentrations(in pg/ml) were as follows: for Con A: TNF, 1120 ± 160; IFN $gamma$ ,4130 ± 110; IL-4, 930 ± 120; IL-10, 4460 ± 420; for SEB: TNF,360 ± 120; IFN $gamma$ , 19,200 ± 8,160; IL-4, 220 ± 120; IL-10, 6470± 1870. None of the four cytokines was detectable in mice treatedwith pyrogen-free saline or GalN alone (700 mg/kg i.p.).

When the superantigen SEB was used for T cell activation in vivo in GalN-sensitized mice, similar but somewhat delayed kineticsof TNF (plasma peak at 2.5 h compared with the peak observed onCon A challenge at 2 h), IL-4, IL-10 and IFN $gamma$ , respectively, werenoted (fig. 1). The maximum circulating IFN $gamma$ concentration, however,was severalfold higher than the one observed by Con A injection.IL-4 plasma concentrations reached about 20% of the peak concentrationsevoked by Con A. They were maximal 4 h after challenge and thendeclined continuously. Amounts of IL-10 similar to those notedafter Con A administration were measured at 1.5 h, steadily increasingup to 6 h after SEB administration before IL-10 concentrationsreached a plateau of about 5000 pg/ml until the end of the experiment.In contrast to Con A, SEB failed to evoke an early IL-10 peakwithin the first hour after challenge. Notably, GalN treatmentdid not affect SEB-induced cytokine production (data not shown).Thus both treatment regimens, i.e., injection of Con A or SEBinduced the release of substantial amounts of T_H2-type cytokines.

Modulation of the cytokine pattern by PDE inhibition. We then examined the pharmacological consequences of PDE inhibition on cytokine production after T cell activation in vivo.For this purpose we treated mice with various doses of eithermotapizone, a PDE3 inhibitor, or rolipram, a type 4-selectivePDE inhibitor, before injection of Con A or GalN/SEB, respectively,and determined the circulating levels of TNF, IL-4 and IL-10 2h after Con A and 2.5 h after GalN/SEB administration. IFN $gamma$ wasdetermined 8 h after challenge, i.e., at the end of the experiment.These time points were chosen, because then all cytokines of interestwere present in considerable amounts in the circulation of theanimals and could be determined out of one single sample of eachindividual animal.

Either pretreatment had a drastic effect on the concentrations of cytokines released into the circulation. As shown in figure2A, motapizone dose-dependently decreased plasma TNF and IFN $gamma$ levels induced by Con A (25 mg/kg). In contrast, IL-10 concentrationswere significantly increased at the highest dose of motapizoneused (10 mg/kg). These remarkable changes observed in Con A-inducedcytokine levels after PDE3 inhibition were even more pronouncedin the SEB model (fig. 2B). Again, TNF and IL-10 levels were inverselymodulated by motapizone pretreatment, i.e., an attenuation ofTNF concentrations to below 100 pg/ml and a 5-fold increase inIL-10 2.5 h after SEB challenge were observed at doses from 1to 10 mg/kg motapizone.

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Fig. 2. Modulation by motapizone of the cytokine pattern induced by Con A (25 mg/kg i.v.) in nonsensitized (A) or SEB (2 mg/kg i.p.)in GalN (700 mg/kg i.p.)-sensitized (B) mice. Motapizone was administeredi.p. 30 min before challenge at the doses indicated. The correspondingvolume of solvent was injected into control animals. Blood samplesfor the determination of TNF, IL-4 and IL-10 were taken from thetail vein at 2 h after Con A or 2.5 h after SEB injection. IFN $gamma$ concentrations were determined 8 h after challenge. Data are meanvalues ± S.D. (n = 3 mice per group) from one out of two analogousexperiments. *P < .05 versus solvent control.

In the next set of experiments we wanted to clarify whether the changes in the cytokine pattern were caused by a specificeffect of the PDE3 inhibitor or whether rolipram, a commonly usedPDE4 inhibitor, would also modulate the in vivo T cell response.Mice were injected with various doses of rolipram before administrationof Con A or SEB, respectively, and cytokine release was determined.Like motapizone, rolipram pretreatment resulted in a significantreduction of plasma TNF and IFN $gamma$ concentrations, whereas significantlyelevated IL-10 levels were found in response to Con A in the circulationof the animals. In contrast to motapizone, however, rolipram alsosuppressed Con A-induced IL-4 release. Essentially similar roliprameffects were observed in the SEB model, i.e., a dose-dependentinhibition of TNF release and a strongly augmented IL-10 production(fig. 3). In this particular SEB experiment circulating IL-4 concentrationsin control animals were relatively low (35 ± 15 pg/ml), i.e.,close to the detection limit of our assay, and therefore not shown.However, in PDE inhibitor-pretreated animals, no IL-4 was detectable2.5 h after GalN/SEB treatment.

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Fig. 3. Modulation by rolipram of the cytokine pattern induced by Con A (25 mg/kg i.v.) in nonsensitized (A) or SEB (2 mg/kg i.p.)in GalN (700 mg/kg i.p.)-sensitized (B) mice. Rolipram was administeredi.p. 30 min before challenge at the doses indicated. The correspondingvolume of solvent was injected into control animals. Blood samplesfor the determination of TNF, IL-4 and IL-10 were taken from thetail vein at 2 h after Con A or 2.5 h after SEB injection. IFN $gamma$ concentrations were determined 8 h after challenge. Data are meanvalues ± S.D. (n = 3 mice per group) from one out of two independentexperiments. *P < .05 versus solvent control.

These data clearly demonstrate that PDE inhibitors are potent modulators of a T cell activation-induced systemic inflammatoryresponse. In general, a diminished release of proinflammatorycytokines such as TNF and IFN $gamma$ was noted. The production of IL-10,which is considered as a typical anti-inflammatory cytokine, wasgreatly increased.

Prevention of T cell-dependent hepatic failure by PDE inhibition. Based on the observation that PDE inhibition in vivo strongly suppressed the release of the central mediator for developmentof hepatic failure, i.e., TNF, we tested the hypothesis that motapizoneand rolipram might prevent liver failure after injection of hepatotoxicamounts of Con A or GalN/SEB. Injection of Con A (25 mg/kg i.v.)in naive mice or of SEB (2 mg/kg i.p.) in GalN-sensitized animals(700 mg/kg) evoked fulminant liver failure within 8 h as assessedby highly increased plasma activities of liver-specific enzymesALT and SDH, which indicated massive liver cell destruction (cf.figs. 4 and 5). Pretreatment of such mice with either motapizone(fig. 4) or rolipram (fig. 5) dose-dependently prevented developmentof liver failure in both models. Plasma ALT activities were indistinguishablefrom untreated control values (35 ± 15 U/l) at the highest drugdose used, and the behavior of the animals was normal. It is importantto point out that the dose-response relation of either compoundwith regard to TNF suppression and protection from liver failurewas similar. Thus, protection by the PDE3 inhibitor motapizoneas well as by rolipram, a PDE4 inhibitor, was most likely causedby suppression of TNF production.

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Fig. 4. Protection from T cell-dependent murine liver failure by motapizone. Liver damage was induced by injection of Con A (25 mg/kgi.v.) in nonsensitized (A) or SEB (2 mg/kg i.p.) in GalN (700mg/kg i.p.)-sensitized (B) mice. Motapizone was administered i.p.30 min before challenge at the doses indicated. The correspondingvolume of solvent was injected into control animals. Eight hoursafter challenge, animals were sacrificed, and plasma enzyme activitiesof ALT, AST and SDH were determined. Data are mean values ± S.D.of n = 3 animals from a single experiment (0.01 mg/kg motapizone)or of two independent experiments using three animals each (n= 6 for all other groups). *P < .05 versus solvent control.

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Fig. 5. Protection from T cell-dependent murine liver failure by rolipram. Liver damage was induced by injection of Con A (25 mg/kgi.v.) in nonsensitized (A) or SEB (2 mg/kg i.p.) in GalN (700mg/kg i.p.)-sensitized (B) mice. Rolipram was administered i.p.30 min before challenge at the doses indicated. The correspondingvolume of solvent was injected into control animals. Eight hoursafter challenge, animals were sacrificed, and plasma enzyme activitiesof ALT, AST and SDH were determined. Data are mean values ± S.D.of n = 3 animals from a single experiment (0.01 mg/kg rolipram)or of two independent experiments using three animals each (n= 6 for all other groups). *P < .05 versus solvent control.

Finally, we asked whether the combined use of motapizone plus rolipram would result in a additive or synergistic action ofthese drugs. Therefore, we used dosages of both compounds thatwere not protective when administered alone, i.e., 0.1 mg/kg each(cf. figs. 4 and 5), and looked for the outcome of liver failureafter GalN/SEB injection. A 20% reduction of plasma ALT activitywas achieved with the PDE4 but not with the PDE3 inhibitor, andall animals survived after motapizone or rolipram pretreatment,whereas a 33% mortality rate was noted in the GalN/SEB controlgroup. However, combined administration of motapizone plus rolipramfully protected mice from liver failure, i.e., a reduction ofplasma liver enzyme activity >95% compared with GalN/SEB-treatedmice was noted. In analogy, TNF formation was completely abrogatedby the combined use of the PDE3 and PDE4 inhibitors, and IL-10concentrations were doubled in comparison with the effect of eachcompound alone (table 1).

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TABLE 1
Effects on GalN/SEB-induced inflammatory responses in mice by combined use of motapizone and rolipram^a

These data are in line with the recent observation that both putative cytokine-producing cell populations, i.e., murine Tcells as well as murine macrophages, express PDE3 and PDE4 isozymes(Schmidt et al., 1995

; Prpic et al., 1993

). In addition, our resultsunderline PDE3 and PDE4 as potentially interesting therapeutictargets to prevent T cell-mediated inflammatory disorders.

	Discussion

Top Abstract Introduction Materials & Methods Results Discussion References

This study investigated the pharmacological influence of PDE inhibitors on T cell activation-induced, cytokine-dependent liverinjury in mice. We showed in two different murine models of fulminanthepatic failure, i.e., the Con A model and the GalN/SEB model,that motapizone, a PDE3 inhibitor, as well as rolipram, a PDE4-selectiveinhibitor, shifted the T cell-dependent cytokine response fromproinflammatory cytokine production toward increased release ofthe anti-inflammatory cytokine IL-10. We conclude that this changein cytokine response conferred protection of mice from T cell-dependentliver damage.

There are two principles by which PDE inhibitors could have exerted their protective effects: 1) either by acting on the effectorcell level, i.e., on the cell population(s) producing liver-toxiccytokines such as TNF and IFN $gamma$ , or 2) by acting on the targetcell level, i.e., by interfering with the toxic signal(s) leadingto hepatocyte destruction, or 3) by both principles. Indeed, ithas been shown that rolipram protects mice not only from GalN/LPS-inducedliver injury by reduction of TNF production but also from GalN/TNF-inducedhepatic failure (Fischer, et al., 1993). This observation is inaccordance with recent in vitro results demonstrating cytoprotectionin murine hepatocyte cultures by mixed PDE inhibitors againstactinomycin D/TNF exposure (Jilg et al., 1996).

With respect to this study the reduced circulating TNF levels measured in PDE-inhibitor-pretreated animals are sufficientto explain the protective effect of these drugs against T cell-dependenthepatic failure. Protection from Con A might have been potentiatedby simultaneous inhibition of IFN $gamma$ generation, a lymphokine thathas been identified recently as an additional critical mediatorin Con A-induced liver injury (Küsters et al., 1996). Our resultsare in line with the known capacity of PDE4 inhibitors to suppressLPS-induced TNF production (Zabel et al., 1993; Semmler et al.,1993; Schade and Schudt, 1993; Fischer et al., 1993; Molnar-Kimberet al., 1993; Prabahkar et al., 1994; Seldon et al., 1995; Leistet al., 1996). Most likely, elevated cAMP levels account for themechanism of action of these drugs. This nucleotide mediator actsvia a PKA pathway that finally can result in negative (IL-2) orpositive (IL-6, IL-10) regulation of cytokine gene expressionvia a so-called CRE sequence on the promoter region (Novak andRothenberg, 1990; Munoz et al., 1990; Dendorfer et al., 1994;Platzer et al., 1995). The mechanism leading to cAMP-dependentinhibition of TNF production is less clear, because a CRE consensussequence has been identified neither on the murine nor on thehuman TNF gene promoter enhancer region. Moreover, rolipram failedto influence TNF mRNA expression in murine peritoneal macrophagesstimulated with endotoxin (Kambayashi et al., 1995). Alternatively,cAMP-dependent regulation of TNF production at the posttranscriptionallevel has been suggested (Severn et al., 1992). Recently, an indirectmode of cAMP-regulated cytokine synthesis involving the PKA pathwayhas been demonstrated for IL-5 (Lee et al., 1993). Another explanationmight be a cAMP/PKA-mediated modulation of the activity of nuclearfactors. In activated T cells, cAMP was shown to decrease NF-ATinduction and that consequently leads to up-regulation of IL-4and IL-5 (Lacour et al., 1994). Inhibition by cAMP of NF- $kappa$ B activation,a molecular event necessary for the induction of the TNF geneexpression in B and T cells (Goldfeld et al., 1994), could representan alternate mechanistic explanation of diminished TNF productionobserved after PDE inhibition.

In addition to a possible NF- $kappa$ B effect, two more TNF-regulatory principles should be taken into account: first, the reducedTNF plasma levels noted on PDE inhibition could be the consequenceof increased TNF receptor shedding after cAMP elevation. Sucha mechanism is believed to account for the protective effect ofmethylxanthines in murine models of septic liver failure (Jilget al., 1996). Second, recent reports as well as our present studymake endogenous IL-10 a likely candidate to contribute to thesequence of events finally resulting in low plasma concentrationsof TNF. IL-10 is known to suppress TNF production in a varietyof experimental settings and IL-10 neutralization leads to elevationof LPS-induced TNF (Fiorentino et al., 1991; Bogdan et al., 1991;reviewed in Moore et al., 1993). Moreover, it has been shown thatendogenously produced IL-10 (Florquin et al., 1994) or exogenouslyadministered rmuIL-10 (Bean et al., 1993) counteract the toxiceffects of TNF induced by GalN/SEB challenge of mice. Sequenceanalysis studies have demonstrated a CRE on both the murine andhuman IL-10 promoter region (Kim et al., 1992; Platzer et al.,1995), which indicates cAMP regulation of IL-10 synthesis. Indeed,cAMP-elevating drugs such as mixed-type PDE inhibitors or adenylylcyclase stimulants as well as direct administration of dibutyrylcAMP have been reported to increase LPS-induced IL-10 production(Platzer et al., 1995; Jilg et al., 1996; Arai et al., 1995).Moreover, anti-TNF antibodies have been shown to result in anincrease of LPS-induced IL-10 production in mice (Barsig et al.,1995). Regarding the IL-10 plasma kinetics after in vivo T cellactivation in comparison with plasma TNF levels (cf. fig. 1),a role of IL-10 in down-regulation of TNF in our T cell-dependentmodels seems possible.

Finally, the question arises of whether motapizone and rolipram, respectively, at their protective doses used, still affectedPDE3 or PDE4 isozymes selectively. On the basis of our presentin vivo data, this question remains open. However, the fact thatzaprinast, a PDE5-selective compound, did not protect mice fromGalN/SEB-induced liver failure (data not shown), makes a criticalregulatory contribution of PDE families other than PDE3 and PDE4to T cell cytokine synthesis rather unlikely. This assumptionis further supported by the complete protection from GalN/SEB-initiatedliver failure that was observed by the combined use of both compounds(cf. table 1) at doses at which these drugs were ineffectivewith regard to plasma liver enzyme activities when given alone.Whether motapizone and rolipram in vivo act in an additive orin a synergistic manner is difficult to answer for several reasons.First, although these drugs are selective for PDE3 or PDE4, respectively,they loose their selectivity at higher concentrations and mighthave affected both isoenzymes, probably even at the dose of 0.1mg/kg. Second, regarding modulation of circulating cytokines,the combined use of motapizone and rolipram was additive, whereasALT levels were reduced synergistically. This apparent synergismwith regard to protection from liver injury might be the consequenceof an additive effect on TNF reduction (cf. table 1).

However, our observations argue in favor of an important role of both isozymes for the regulation of T cell-mediated inflammatoryprocesses. Accordingly, T cells mainly express PDE3 and PDE4 isozymes(Tenor et al., 1995) and from several in vitro studies in human(Essayan et al., 1994; Gantner et al., 1995c) as well as murineT cells (Schmidt et al., 1995), a prominent role of both PDE3and PDE4 in regulation of T cell activation became evident. Thus,our data seem to translate these in vitro findings to the in vivosituation by demonstrating that PDE3 and PDE4 inhibitors potentlyprotect from fulminant T cell-dependent liver failure in mice.We ascribe this protection to a shift of the cytokine responsefrom a proinflammatory to an anti-inflammatory profile. In thissense, our findings corroborate the concept that cAMP elevationresults in suppression of T_H1-type cytokines, whereas T_H2-cytokinesare up-regulated (reviewed in Haraguchi et al., 1995). However,the production of the specific T_H2-type cytokine IL-4 was notaffected by PDE3 inhibition but was significantly suppressed byrolipram. In contrast to IL-4, IL-10 is not a T_H2-specific cytokineand is also produced by monocytes and macrophages. We recentlyreported that upon stimulation of macrophages by LPS in vivo theliver and the spleen are the two major IL-10-producing organsof the mouse (Barsig et al., 1995). Hence, it seems likely thatthe accessory cells of T cell activation in our models, i.e.,the macrophages, were rather affected by PDE inhibitors to releaseincreased amounts of IL-10 than were the T_H2-lymphocytes.

Because an increase of T_H2 lymphokines such as IL-4 and IL-5 may evoke complications in patients with allergic disease, ourresults which showed a selective increase of IL-10 seem to beof considerable interest with respect to the therapeutic use ofPDE inhibitors for the treatment of T cell-related disorders.

	Acknowledgments

The authors thank Schering AG (Berlin, Germany) for the generous gift of rolipram and Nattermann (Cologne, Germany) for providingmotapizone. The perfect technical assistance of U. Gebert is gratefullyacknowledged. Special thanks are addressed to D. Bundschuh andC. Hänisch for helpful experimental support.

	Footnotes

Accepted for publication September 12, 1996.

Received for publication June 14, 1996.

¹ This work was supported by a postdoctoral grant from the Ministerium für Wissenschaft und Forschung Baden-Württemberg (720.61-11/21)and by grants of the Graduiertenkolleg Biochemical Pharmacology(We 686/15-1).

Send reprint requests to: Dr. Gisa Tiegs, Biochemical Pharmacology, Faculty of Biology, University of Konstant, D-78434 Konstant, Germany.

	Abbreviations

ALT, alanine aminotransferase; AST, aspartate aminotransferase; Con A, concanavalin A; CRE, cyclic AMP-responsive element; GalN, D-galactosamine; IL, interleukin; IFN $gamma$ , interferon- $gamma$ ; LPS, lipopolysaccharide; mu, murine; NF, nuclear factor; PDE, phosphodiesterase; PKA, protein kinase A; SDH, sorbitol dehydrogenase; SEB, staphylococcal enterotoxin B; TNF, tumor necrosis factor- $alpha$ .

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