Cytokine modulation by PX differently affects specific acute phase proteins during sepsis in rats

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Cytokine modulation by PX differently affects specific acute phase proteins during sepsis in rats

Laure Voisin¹, Denis Breuillé², Benoît Ruot¹, Cécile Rallière¹, Fabienne Rambourdin¹, Michel Dalle³, and Christiane Obled¹

¹ Centre de Recherche en Nutrition Humaine et Institut National de la Recherche Agronomique, Unité d'Etude du Métabolisme Azoté, 63122 Ceyrat; ³ Laboratoire de Physiologie du Développement, Université Blaise Pascal, Aubière Cedex 63177, France; and ² Centre de Recherches Nestlé, CH 1000 Lausanne 26, Switzerland

ABSTRACT

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

To explore the regulation of the acute phase response in vivo, the effects of pentoxifylline (PX) treatment (100 mg/kg ip1 h before infection) were investigated in infected and pair-fedrats 2 and 6 days after an intravenous injection of live bacteria(Escherichia coli). PX treatment prevented the increase in plasmatumor necrosis factor (TNF)- $alpha$ (peak 1.5 h after the infection)and resulted in an 84 and 61% inhibition of plasma interleukin(IL)-1 $beta$ and IL-6, respectively (peaks at 3 h). Plasma corticosteronekinetics were not modified by the treatment. Infection increased $alpha$ ₁-acid glycoprotein (AGP), $alpha$ ₂-macroglobulin (A2M), and fibrinogenplasma concentrations and decreased albumin levels. PX significantlyreduced AGP plasma concentration as early as day 2 in infectedanimals but reduced A2M and fibrinogen plasma levels only at day6. The treatment had no effect on the albumin plasma concentration.Hepatic AGP and fibrinogen mRNA levels increased in infected rats,whereas those of A2M were unchanged and those of albumin weredecreased. Two days after infection, AGP and fibrinogen mRNA levelswere reduced in treated infected animals. PX was ineffective inmodifying those of A2M and albumin. These data demonstrate, invivo, that different acute phase proteins are individually regulatedin sepsis. The in vivo effects of PX treatment support the hypothesisthat TNF- $alpha$ plays an important role in the regulation of AGP production,whereas other factors seem to be involved in the regulation ofA2M, fibrinogen, and albumin expression.

tumor necrosis factor; interleukin-1; interleukin-6

	INTRODUCTION

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AMONG OTHER METABOLIC disturbances, sepsis causes a marked loss of weight and body proteins, muscle wasting, and a hepaticacute phase response. Total liver protein synthesis was markedlyenhanced (11, 44), mainly due to an increased synthesis ofexported proteins (acute phase proteins; see Ref. 44). Thusthe liver response results in a concomitant increase in the circulatinglevels of these proteins. However, the levels of some plasma proteinssuch as albumin, named negative acute phase proteins, decrease(33, 42).

Cytokines, and especially tumor necrosis factor (TNF)- $alpha$ (43) and interleukins-1 (IL-1; see Ref. 35) and 6 (IL-6; see Ref.6), are considered to play key roles in the pathogenesis ofsepsis. With respect to liver, administration of cytokines tohealthy animals can reproduce the stimulation of protein synthesis(5, 13). The roles of cytokines in inducing individual acutephase protein changes have been studied extensively in variousin vitro systems as hepatocyte primary cultures or hepatoma celllines. Based on these studies, IL-6 appears to be the main cytokineregulating the expression of the majority of the acute phase proteingenes, whereas IL-1 $beta$ and TNF- $alpha$ regulate a different set of genes(17, 29, 33). Maximal expression of several acute phaseprotein genes is dependent on the presence of glucocorticoids(29). However, for a particular protein, different responsescan be obtained in various cell systems (29), and the regulatoryprocesses involved in the in vivo acute phase response might bemuch more complex. Some studies have been reported in which therole of IL-1 (28, 37) and IL-6 (20, 31) on the acute phaseinduction was studied in vivo. However, a major difficulty indefining the roles of various cytokines in vivo is their abilityto induce each other (35, 43). Another approach, poorly documentedin sepsis, consists of inhibiting the production or action ofindividual cytokines (21, 32, 42).

TNF- $alpha$ is the first cytokine to appear in the circulation after administration of endotoxin or living bacteria in various species(43). Thus TNF- $alpha$ is thought to be a proximal mediator of theinflammatory response and most likely triggers the release ofother secondary mediators, including other cytokines. Pentoxifylline(PX), a methylxanthine derivative, has been demonstrated bothin vitro and in vivo to suppress lipopolysaccharide (LPS)-inducedTNF- $alpha$ secretion (12, 30, 39, 41). PX may also modulateother cytokines, but this effect is more controversial (30,39, 41), and its effect on glucocorticoid level is unknown.Thus, in this study, we explored in vivo the effect of PX treatmenton TNF- $alpha$ , IL-1, IL-6, and corticosterone levels in a rat modelof gram-negative sepsis. Furthermore, we examined whether inhibitionof TNF- $alpha$ production could modulate the expression and plasma appearanceof individual acute phase proteins during the acute septic phase(2 days postinfection) and the chronic septic phase (6 days postinfection).

	MATERIALS AND METHODS

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Animals. Male Sprague-Dawley rats (Iffa Credo, Saint-Germain sur l'Arbresle, France) were individually housed in wire-bottomcages in a temperature-controlled room (22-23°C) with a 12:12-hlight-dark cycle. During a 6-day acclimatization period, all ratsreceived a semisynthetic diet containing 12% protein distributedby an automatic device (12). Animals were weighed every morning,and food intake was measured every day.

At an initial body weight of 300 g, rats were divided into the following four groups: infected rats (INF) and their pair-fedcontrol (PF) and infected rats treated with PX (PX-INF) and theirpair-fed controls treated with PX (PX-PF). The INF group receivedsaline intraperitoneally 1 h before injection of Escherichia coli(serotype 0153-K-H; 7 × 10⁸ colony-forming units) into a lateral tail vein. Control animalsof the INF group (PF) received saline intraperitoneally 1 h beforean intravenous saline injection; because infection dramaticallydecreases food intake (11), the animals were pair fed to theintake of infected rats. In the PX-INF group, PX (100 mg/kg) wasinjected intraperitoneally 1 h before bacteria administration.Control animals of the PX-INF group (PX-PF) received an equalvolume of PX injected intraperitoneally 1 h before saline intravenousinjection. Because PX treatment increases voluntary food consumptionin infected rats, this control group (PX-PF) was pair fed to PX-INFanimals. Pair feeding was conducted as previously described (11).Animals were weighed every day until the completion of the study.Animals of each group were studied at days 2 and 6 after the infection,which represents, respectively, the acute and chronic septic phasespreviously described (11). In infected rats, the mortality was7%, and there was no mortality in infected rats pretreated withPX. After anesthesia with pentobarbital sodium (6.0 mg/100 g bodywt), gastrocnemius and soleus muscles were dissected and weighed.Blood samples were collected into EDTA tubes, and plasma was storedat $-$ 20°C for acute phase protein assays. Liver samples were takenby freeze clamping and kept at $-$ 80°C until analysis. The protocolwas approved by the Ethics Committee of the Institute Nationalde la Recherche Agronomique and was conducted in conformity withthe guiding principles in the care and use of laboratory animals.

TNF- $alpha$ -, IL-1 $beta$ -, and IL-6-like bioactivity and corticosterone assays. A preliminary kinetic study of TNF- $alpha$ , IL-1 $beta$ , and IL-6production in plasma from 1 to 24 h after the infection showedthat maximal plasma levels occurred at 1.5 h for TNF- $alpha$ and 3 hfor IL-1 $beta$ and IL-6 after bacteria administration (Fig. 1). Thusblood samples were collected in a lateral tail vein 1.5 and 3h after the infection in heparinized tubes, and plasma was storedat $-$ 80°C for TNF- $alpha$ and IL-1 $beta$ and at $-$ 20°C for IL-6 assays. TNF- $alpha$ and IL-1 plasma concentrations were measured by using ELISA kits,according to the manufacturer's instructions (Genzyme, Cambridge,MA, and Amersham, Bucks, UK, respectively). Biological activityof IL-6 was estimated in a bioassay using the B-9 hybridoma cellline (1). Briefly, B-9 cells (5,000/100 µl) were cultured in96-well microtiter plates with serial dilutions of test samples(22). The IL-6 standard was human recombinant IL-6 (no. 89/548;National Institute for Biological Standards and Control, Hertfordshire,UK), which was serially diluted. After 48 h of incubation at 37°Cwith 5% CO₂, 20 µl of 3-(4,5-dimethylthiazol-2-yl)-5-(3-carboxymethoxyphenyl)-2-(4-sulfophenyl)-2H-tetrazolium,inner salt (2 mg/ml) was added to each well in the presence ofphenazine methosulfate and incubated for an additional 2 h todetermine cell proliferation (16). The water-soluble formazanproduct was quantitated at 490 nm in an MR 700 microplate reader(Dynatech Laboratories, Guernsey, UK). Plasma corticosterone concentrationswere assayed by RIA as described by Pradier and Dalle (34).

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Fig. 1. Time course of plasma tumor necrosis factor (TNF)- $alpha$ , interleukin (IL)-1 $beta$ , and IL-6 concentrations within 24 h after infection. TNF- $alpha$ and IL-1 $beta$ were measured with the use of ELISA kits. Biological activity of IL-6 was estimated in a bioassay using the B-9 hybridoma cell line. Values are means ± SE for 6-8 animals.

Acute phase protein concentration. Fibrinogen, $alpha$ ₁-acid glycoprotein (AGP), $alpha$ ₂-macroglobulin (A2M), and albumin plasma levelswere measured by single radial diffusion, using anti-rat fibrinogenand albumin from Cappel and anti-rat AGP and A2M produced in thelaboratory.

Northern blot analysis. Total RNA was extracted from 0.2 g of liver by the method of Chomczynsky and Sacchi (14). Twentymicrograms of RNA were electrophoresed in formaldehyde agarosegels (1%) and transferred electrophoretically to nylon membranes(GeneScreen; NEN Research Products, Boston, MA). RNA was covalentlybound to the membrane by ultraviolet cross-linking. Membraneswere hybridized with cDNA probes AGP (36), A2M (no. 63099; AmericanType Culture Collection, Rockville, MD; see Ref. 19), $alpha$ -fibrinogen(7), and albumin (25). Hybridizations were conducted overnightat 65°C with [³²P]cDNA fragments labeled by random priming. After washing at thesame temperature, filters were autoradiographed at $-$ 80°C withintensifying screens on Hyperfilm-MP (Amersham). After strippingof the different probes, the filters were reprobed with a mouse18S ribosomal probe (no. 63178; American Type Culture Collection).Autoradiographic signals were quantified by digital image processingand analysis (NIH Image 1.54) and normalized using the corresponding18S rRNA signals to correct for uneven loading.

Statistics. All data are expressed as means ± SE. The significance of differences was analyzed by one-way ANOVA and by Student'st-test where appropriate. Differences among means were consideredsignificant at P < 0.05.

	RESULTS

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Food intake, body weight, and muscle weight. Results presented in Figs. 2 and 3 show values obtained on rats studied for 6days after the infection. Similar results were observed duringthe acute period in the group killed at day 2. Infection decreasedfood intake, especially during the acute phase period since ratsate only 5-15% of the preinfection intake (20-25 g). Thereafter,food intake of infected animals gradually increased to reach 75%of preinfection food consumption at the end of the study. Pretreatmentof animals with PX before infection reduced anorexia, mainly atdays 2 to 4 after infection compared with untreated rats (Fig.2). On day 2 postinfection, the decrease of body weight observedin infected rats (INF) was significantly higher (27.5%) than inpair-fed animals (PF; Fig. 3), and the difference between thesetwo groups strongly increased until 6 days after infection. Bycontrast, the body weight loss of septic rats treated with PX(PX-INF) was always similar to that of their pair-fed controls(PX-PF). Moreover, PX-INF rats began to gain weight on day 3 althoughINF rats continued to lose weight. Thus, 6 days after infection,septic rats had lost ~32 g, and infected rats treated with PXhad regained ~10 g body weight compared with their initial bodyweight.

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Fig. 2. Effect of pentoxifylline (PX) treatment on daily food intake within 6 days postinfection. Values are means ± SE for 6-11 animals. INF, infected rats; PF, pair-fed controls of INF rats; PX-INF, infected rats treated with PX; PX-PF, pair-fed controls treated with PX of PX-INF. * P < 0.05 vs. respective PF animals; d, days. $dagger$ P < 0.05 vs. respective animals without PX treatment.

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Fig. 3. Effect of PX treatment on cumulative weight change within 6 days postinfection. Values are means ± SE for 6-11 animals. $dagger$ P < 0.05 vs. respective animals without PX treatment.

During the acute phase, the weight of the various muscles studied was significantly reduced in infected animals compared withcontrol rats (15 and 13% for gastrocnemius and soleus, respectively;Table 1). In the same septic phase, similar decreases were observedfor infected animals treated with PX compared with their pair-fedcontrols (~13%). Six days postinfection, the observed atrophyof gastrocnemius and soleus muscles in INF rats was more severe(30 and 17%, respectively; Table 1). By contrast, PX treatmentreduced the atrophy of gastrocnemius (12% vs. respective pair-fedrats) and abolished the atrophy of soleus muscle.

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Table 1. Effect of PX treatment on muscle weights 2 and 6 days postinfection

TNF- $alpha$ -, IL-1 $beta$ -, and IL-6-like bioactivity and glucocorticoid plasma levels. Administration of PX 1 h before infection suppressedthe rise of the plasma TNF- $alpha$ level (by 99%; Table 2). PX treatmentinduced a reduction of 84 and 61% of plasma IL-1 $beta$ - and IL-6-likebioactivity concentrations, respectively, 3 h after infection(Table 2). In INF rats, plasma corticosterone levels were significantlyhigher 4 h after bacteria injection and were similar to normalvalues 24 and 48 h after the infectious stress (Fig. 4). PX treatmentdid not prevent the sepsis-induced increase in plasma corticosteronelevels (Fig. 4).

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Table 2. Effect of PX treatment on plasma TNF- $alpha$ (measured 90 min after infection)-, IL-1 $beta$ -, and IL-6-like bioactivity (measured 3 h after infection)

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Fig. 4. Effect of PX treatment on plasma corticosterone concentration 4, 24, and 48 h after infection. Plasma corticosterone levels were assayed by RIA. Values are means ± SE for 6-11 animals. $ P < 0.05 vs. basal value. * P < 0.05 vs. respective pair-fed animals.

Acute phase proteins. A2M, AGP, and fibrinogen concentrations were significantly increased 2 days after the infection (29-,59-, and 2.3-fold, respectively) and 6 days after the infection(18-, 14-, and 2-fold, respectively) in INF rats compared withPF controls (Table 3). By contrast, albumin concentration wassignificantly reduced 2 and 6 days postinfection (45 and 54%,respectively). Infection significantly increased hepatic mRNAconcentrations for AGP (19- and 8-fold, at days 2 and 6, respectively;Fig. 5) and fibrinogen (57 and 37% at days 2 and 6, respectively;Fig. 6). A2M mRNA levels increased significantly only on day 6postinfection but more moderately than those of AGP (55%; Fig.5). By contrast, albumin mRNA levels were decreased by infection(50 and 57% at days 2 and 6, respectively; Fig. 6).

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Table 3. Effect of PX treatment on $alpha$ ₁-acid glycoprotein, $alpha$ ₂-macroglobulin, fibrinogen, and albumin levels 2 and 6 days postinfection

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Fig. 5. Effect of PX treatment on mRNA levels for $alpha$ ₁-acid glycoprotein (A) and $alpha$ ₂-macroglobulin (B). RNA was extracted from liver of infected rats (INF) and their pair-fed controls (PF) and of infected rats treated with PX (PX-INF) and their pair-fed control treated with PX (PX-PF). Samples (20 µg) were electrophoresed, transferred to nylon membranes, and hybridized with [³²P]cDNAs encoding $alpha$ ₁-acid glycoprotein and $alpha$ ₂-macroglobulin. After stripping of the probes, blots were rehybridized with an 18S ribosomal oligonucleotide. Data were corrected for 18S rRNA abundance to take into account variations in RNA loading. Values are means ± SE for 4 or 5 rats. All data were referred to pair-fed day 2 value, which was arbitrarily chosen to equal 1. Representative Northern blots are also shown. d2, 2 days postinfection; d6, 6 days postinfection. * P < 0.05 vs. respective PF animals. $dagger$ P < 0.05 vs. respective animals without PX treatment.

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Fig. 6. Effect of PX treatment on mRNA levels for fibrinogen (A) and albumin (B). RNA was extracted from liver of infected rats (INF) and their pair-fed controls (PF) and of infected rats treated with PX (PX-INF) and their pair-fed control treated with PX (PX-PF). Samples (20 µg) were electrophoresed, transferred to nylon membranes, and hybridized with [³²P]cDNAs encoding fibrinogen and albumin. After stripping of the probes, blots were rehybridized with an 18S ribosomal oligonucleotide. Data were corrected for 18S rRNA abundance to take into account variations in RNA loading. Values are means ± SE for 4 or 5 rats. All data were referred to pair-fed day 2 value, which was arbitrarily chosen to equal 1. Representative Northern blots are also shown. * P < 0.05 vs. respective PF animals. $dagger$ P < 0.05 vs. respective animals without PX treatment.

Administration of PX significantly decreased by 29% the rise in plasma AGP concentration in INF rats as early as 2 days afterbacteria injection but did not significantly affect the increasein A2M and fibrinogen levels (Table 3). However, 6 days postinfection,the concentrations of these three positive acute phase proteinswere significantly decreased in PX-INF rats compared with INFrats (65, 50, and 21%). No modification of the decrease of albuminconcentration was observed with PX administration (Table 3).PX treatment reduced the increase in AGP and fibrinogen mRNA levelsin PX-INF rats compared with nontreated infected rats 2 days afterinfection (Figs. 5 and 6), although they were not significantlydifferent in PX-INF rats and nontreated infected rats on day 6postinfection. PX treatment did not induce any significant variationof the A2M and albumin mRNA levels 2 and 6 days after infection(Figs. 5 and 6).

	DISCUSSION

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PX has been shown to increase animal survival in lethal models of infection (38) and to block LPS fever (30). The beneficialeffects of PX in sepsis have been attributed to its ability toinhibit the production of TNF- $alpha$ in vitro (39, 41) and in vivo(12, 30, 38). TNF- $alpha$ is the first cytokine to appear in theplasma after endotoxemia or infection, and it induces the synthesisand release of other mediators, such as IL-1 and IL-6, generatinga cytokine cascade (43). The neutralization of endogenous TNF- $alpha$ with anti-TNF- $alpha$ antibodies greatly diminishes the increases inIL-1 $beta$ and IL-6 in endotoxemia and sepsis (18, 42). Our resultsdemonstrate that PX produced similar effects, decreasing IL-1 $beta$ and IL-6 plasma levels 3 h after the infection. However, the effectof PX on the IL-1 $beta$ plasma level was greater than on the IL-6 plasmalevel. IL-6 is produced later than TNF- $alpha$ , and more or less simultaneouslywith IL-1 $beta$ , both of which induced IL-6 (6, 22). Thus theremaining IL-1 $beta$ can be sufficient to produce a large increaseof IL-6 plasma level in PX-treated animals.

Plasma corticosterone levels were increased soon after administration of IL-1 $beta$ (47) and LPS (22, 26), after cecum ligatureand puncture in rats (23), or after bacteria injection as shownin our study. A novel result of this study is the inability ofPX administration to modify glucocorticoid levels. Proinflammatorycytokines, like TNF- $alpha$ and IL-1, were reported to increase glucocorticoidsynthesis and release via the stimulation of the hypothalamic-pituitaryaxis (29). The lack of effect of PX treatment on corticosteroneplasma level may be the result of remaining IL-1 $beta$ and/or the presenceof other factors sufficient to induce a maximum production ofglucocorticoids, since pretreatment of turpentine-injected micewith anti-IL-1 receptor antagonist (ra) did not affect the increasein circulating corticosterone (21). Nevertheless, TNF- $alpha$ didnot appear to be the main mediator of corticosterone productionin sepsis. Moreover, our results suggest that the mechanisms ofPX action are independent of corticosterone levels or that corticosteronehas only minor direct effects in sepsis.

PX administration reduced, but did not prevent, anorexia induced by infection, as previously observed in our laboratory (12)or by others using TNF- $alpha$ monoclonal antibody pretreatment in endotoxemicrats (42). These data are in agreement with the view that TNF- $alpha$ and IL-1 $beta$ have anorexic effects (45). PX treatment suppressedbody weight difference between INF rats and their PF control overthe entire course of the study. Thus the effect of infection onbody weight change completely disappeared in infected treatedanimals. Moreover, muscle atrophy linked to infection was significantlyreduced by PX treatment and even abolished at day 6 in soleusmuscle. This rapid recovery of muscle weight of treated animalsis consistent with the increase of protein synthesis (12, 15,27) and the inhibition of proteolysis (46, 48) reportedpreviously with inhibitors of TNF- $alpha$ secretion or action and IL-1ra.

The acute phase response associated with sepsis is accompanied by changes of the plasma concentration of a large number ofproteins. Increased rates of incorporation of radiolabeled aminoacids into proteins suggest, at least in part, that the increaseof the plasma concentration of acute phase proteins during inflammationor sepsis is due to increased rates of their synthesis (40).The regulation of protein synthesis may occur at different levels,including various steps in the transcriptional and translationalevents. The analysis of mRNA levels and the measurement of transcriptionactivity have provided evidence that transcriptional mechanismsplay a central role in the regulation of expression of many acutephase proteins (9, 31, 36). Our results are in agreementwith this view for AGP and fibrinogen, since mRNA levels wereincreased 2 and 6 days after the infection. By contrast, we foundno coordinated changes between mRNA levels and plasma concentrationof A2M, suggesting that the genes of these three proteins maybe partially regulated by different mechanisms during inflammation.However, the increase in A2M mRNA level could be achieved before48 h (19). Moreover, hepatic mRNA levels for A2M and AGP werefound to increase to a maximum 24 h after LPS injection, withnormal levels at 48 h for A2M but 10-fold over control valuesfor AGP (42). Regulation of A2M may also occur on posttranscriptionallevels, since Andus et al. (4) demonstrated that IL-6 markedlyaccelerated the secretion of A2M in hepatocyte primary cultures.For albumin, hepatic mRNA level and plasma concentration werediminished by ~50% 2 and also 6 days after infection. Such correlateddecreases, suggesting that hypoalbuminemia is due to a decreasedsynthesis of the protein, have been described 24-48 h after LPSand turpentine injections, but they were followed by recoveryover the next 48-72 h (2, 42). These results underline thelong-lasting perturbations associated with our model, as describedpreviously (11).

Cytokines have been implicated in the induction of the acute phase response. Most studies devoted to the exploration of therole of cytokines and hormones in inducing acute phase proteinshave been carried out in cell culture systems and have shown directcytokine effects. Prominent stimulatory functions have been ascribedto TNF- $alpha$ , IL-1 $beta$ , IL-6, and glucocorticoids (17, 29, 33).Two types of acute phase genes with different cytokine controlshave been described as follows: those that respond to IL-1 $beta$ andTNF- $alpha$ such as AGP and those that respond to IL-6 such as A2M andfibrinogen for the rat (8, 29, 33). Moreover, to achievemaximally regulated expression of some proteins, a combinationof cytokines and glucocorticoids is often required.

The qualitative pattern of the regulated positive acute phase proteins observed with PX treatment during the acute phase inour study was characteristic of that generally described in vitro.The first protein affected both at the transcriptional level andplasma concentration by the treatment was AGP, which is recognizedto be regulated mainly by TNF- $alpha$ and IL-1 $beta$ (8, 29, 33).These results were consistent with the findings of Sharma et al.(42) using TNF- $alpha$ monoclonal antibody treatment of endotoxemiain rats. Glucocorticoids alone are able to induce AGP (31),but there was no difference in the corticosterone level in treatedand nontreated infected rats. Although AGP is minimally affectedby IL-6 alone (31), some synergistic action with TNF- $alpha$ and IL-1can occur (8).

By contrast, A2M and fibrinogen plasma levels were not initially decreased by PX treatment, which did not modify A2M mRNAlevels but slightly decreased those of fibrinogen. Because IL-6secretion was not abolished by PX, these results are in agreementwith numerous studies attributing a predominant role of IL-6 ininducing these two proteins (3, 31, 37). Moreover, in vitrodata have shown that TNF- $alpha$ and IL-1 did not alter either the expressionor the synthesis of A2M (4). The regulation of fibrinogen geneexpression seems more complex, since IL-1 inhibits its stimulationand this inhibitory effect is reversed by endogenous IL-1ra (37).Moreover, glucocorticoids are required to achieved a maximal IL-6response for A2M but not for fibrinogen (31).

The decline in plasma albumin and mRNA levels appears not to be affected by PX treatment of septic rats, as shown with anti-TNF- $alpha$ antibody treatment of endotoxemic rats (42). Anti-IL-1 receptorantibody administration before turpentine injection in mice failedto restore albumin plasma concentration (21). However, in vivoadministration of TNF- $alpha$ , IL-1 $beta$ , or IL-6 is able to decrease albuminsynthesis (5, 10, 20), and the combination of these cytokines,especially IL-1 $beta$ and IL-6, resulted in an additive downregulationof albumin synthesis in vitro (4). On the other hand, glucocorticoidsare known to increase albumin synthesis (24) and could partiallyantagonize the inhibitory effect of cytokines. Taken together,these data suggest that a small amount of any cytokine is enoughto inhibit albumin synthesis and/or that unknown mediators ormechanisms play a predominant role in determining hypoalbuminemia.

During the chronic phase, the levels of AGP, A2M, and fibrinogen were significantly decreased in infected rats treated withPX compared with nontreated animals, indicating perhaps the rapidrecovery of treated animals. No evidence of return to normal levelsof albumin appeared at the end of the study, showing that albuminconstitutes a poor index of outcome. However, mRNA levels tendto increase at the end of the experiment. The function of thedecreased plasma level of albumin, and more generally of the negativeacute phase proteins, is not yet clear and deserves further studies(2).

In summary, in a rat model of long-lasting sepsis, the administration of PX before infection inhibited circulating TNF- $alpha$ ,depressed plasma IL-1 $beta$ and IL-6 levels, but had no effect on corticosteronelevels. Moreover, PX treatment reduced anorexia and body weightloss, suppressed muscle protein wasting, and modulated the acutephase response. Our results suggest that glucocorticoids exerttheir action not directly, but mainly in combination with, othermediators. Moreover, our re-sults underline in vivo that regulationof acute phase protein expression can occur at different levelsaccording to the protein (17, 33).

The effects of PX treatment of infected rats shown in this study support the hypothesis of an important role of TNF- $alpha$ in theregulation of protein metabolism during sepsis. However, furtherexperiments are needed to understand the link between the veryearly and transient TNF- $alpha$ secretion and the long-lasting effectsobserved in muscle and liver protein metabolism. Despite the complexityof the cytokine and hormonal network, the present study demonstratesin vivo that individual mediators have specific effects on particularacute phase proteins, making AGP a better index of recovery afterPX treatment than A2M. This emphasizes again that acute phaseproteins do not always respond in unison in disease states. Clearly,the role of the various acute phase proteins and the regulationof the acute phase response have to be evaluated in detail invarious diseases before acute phase proteins become a practicalclinical diagnostic and prognostic tool.

	ACKNOWLEDGEMENTS

We thank Dr. Jacques Dornand (Institut National de la Santé et de la Recherche Médicale U65, Montpellier, France) and Dr.André Mazur and Corinne Malpuèche (Institut National de la RechercheAgronomique, Clermont-Ferrand, Theix, France) for interleukin-6bioassay. We thank Dr. H. Baumann (Department of Molecular andCellular Biology, Roswell Park Cancer Institute, Buffalo, NY)for providing $alpha$ -fibrinogen cDNA and Drs. Y. Akira and K. Nakamura(Department of Applied Biological Sciences, Nagoya University,Nagoya, Japan) for providing albumin cDNA.

	FOOTNOTES

This study was supported by Clintec Technologies, the French Ministère de l'Enseignement Supérieur et de la Recherche, andthe Institut National de la Recherche Agronomique.

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.§1734 solely to indicate this fact.

Address for reprint requests: C. Obled, Institut National de la Recherche Agronomique, Unité d'Etude du Métabolisme Azoté, 63122 Ceyrat, France.

Received 5 May 1998; accepted in final form 13 July 1998.

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