Tat Protein of Human Immunodeficiency Virus Type 1 Induces Interleukin-10 in Human Peripheral Blood Monocytes: Implication of Protein Kinase C-Dependent Pathway

doi:10.1128/JVI.74.22.10551-10562.2000

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Journal of Virology, November 2000, p. 10551-10562, Vol. 74, No. 22
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Tat Protein of Human Immunodeficiency Virus Type 1 Induces Interleukin-10 in Human Peripheral Blood Monocytes: Implication of Protein Kinase C-Dependent Pathway

Abdallah Badou,¹ Yamina Bennasser,¹ Marc Moreau,² Catherine Leclerc,² Monsef Benkirane,³ and Elmostafa Bahraoui¹^,^*

Laboratoire d'Immuno-Virologie EA3038¹ and CNRS, Unité Mixte de Recherche 5547,² Université Paul Sabatier, 31062 Toulouse Cedex, and Institut de Génétique Humaine, UPR1142, 34 396 Monpellier,³ France

Received 19 June 2000/Accepted 4 August 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

The clinical manifestations observed in human immunodeficiency virus type 1 (HIV-1)-infected patients are primarily due tothe capacity of the virus and its components to inactivate theimmune system. HIV-1 Tat protein could participate in this immunesystem disorder. This protein is secreted by infected cells ofHIV-infected patients and is free in the plasma, where it caninteract and be taken up by both infected and noninfected cells.In asymptomatic patients infected by HIV-1, production of interleukin-10(IL-10), a highly immunosuppressive cytokine, is associated withdisease progression to AIDS. In the present work, we tested thecapacity of Tat to induce IL-10 production by peripheral bloodmonocytes of healthy donors. The results show that Tat causesthe production of IL-10 in a dose- and stimulation time-dependentmanner. Investigations of the mechanisms involved in signal transductionshow that (i) the calcium pathway is not or only slightly involvedin Tat-induced IL-10 production, (ii) the protein kinase C pathwayplays an essential role, and (iii) monocyte stimulation by Tatresults in the intranuclear translocation of transcription factorNF- $kappa$ B and in the induction of phosphorylation of the mitogen-activatedprotein kinases ERK1 and ERK2; activation of these two potentialsubstrates of protein kinase C is required for the productionof IL-10. Finally, our results suggest that the effect of Tatis exerted at the membrane level and that the active domain islocated within N-terminal residues 1 to 45. This production ofIL-10 induced by Tat could participate in the progression of HIVinfection toAIDS.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

The clinical manifestations observed in patients infected by human immunodeficiency virus (HIV) are primarily due to the capacityof the virus to inactivate the immune system. Before the decreasein the number of CD4 T lymphocytes, a disorder in the immune responseis observed (17, 18, 38). The cellular and molecular mechanismsof this deficiency of the immune system cannot be explained solelyby the direct lytic effect of the virus on infected CD4 T lymphocytes.HIV-1 can infect target cells and remain in the form of a latentprovirus. In addition to this mechanism to escape the defensesof the immune system, the virus uses other strategies involvingviral and cellularfactors.

One of the potential candidates is HIV Tat gene product, a 14-kDa protein known for its transactivating activity on the viralgenome (34). Tat binds to the secondary-structure sequence TAR(Tat activation region) 5' of viral RNA during transcription andthereby enables the recruitment of cellular factors forming thecomplex of cyclin T1 and cdk9, called TAK (Tat-associated kinase),that phosphorylates the C-terminal domain on RNA polymerase 2,thereby activating transcription elongation (28). Tat also participatesin the pathogenesis of HIV-1 infection by its capacity to interactwith different cell types. Tat is found in the serum of HIV-infectedpatients (26, 54). It is secreted by infected cells (26)and can act on other cells, whether or not they are infected (10,21, 22, 39, 57). Tat activates quiescent CD4⁺ T cells, rendering them permissive for HIV-1 infection (37).This effect is accentuated by the capacity of Tat to increasethe rate of expression of coreceptors for the chemokines CXCR4and CCR5 (29). Tat also contributes to immune system disordersby inducing apoptosis of T lymphocytes (36). Tat interfereswith the cell-mediated immune response by inhibiting major histocompatibilitycomplex class I molecule expression, as reported for Jurkat cells(30), NK cell activity (59), and interleukin-12 (IL-12) productionby dendritic cells (45) and by monocytes (31).

It is now established that deregulation of cytokine production contributes to the attenuated functioning of the immune systemin the course of HIV-1 infection. HIV-1-infected patients thusdevelop a progressive decrease in the TH1-type cellular immuneresponse that results in an increase in the TH2-type humoral immuneresponse mediated by IL-4, IL-6, and IL-10 (16, 17, 38).

The infection of T-cell (H9) or promonocytic (U937) lines by HIV in vitro stimulates the secretion of IL-10 (40). In linewith these reports, Shearer's group, in a study including morethan 1,000 patients (18), identified four patient classes dependingon the capacity of their CD4 T lymphocytes to respond to differentstimuli (mitogen, alloantigen, influenza virus, and HIV-1 antigens).The progressive loss of the response of the immune system to thesestimuli was found to be associated with a course leading to AIDS.Considerable production of IL-10 by peripheral blood mononuclearcells (PBMC) was observed in these patients and paralleled thealteration in CD4⁺ T-cell proliferative function (18). In addition, the immunosuppressiveeffect of IL-10 also correlated with the capacity of isolatedmononuclear cells of patients infected by HIV and immunodepressedto proliferate in vitro after stimulation by peptide antigensof the HIV envelope glycoproteins in the presence of a neutralizinganti-IL-10 antibody (18).

The production of cytokines involves primarily two signaling pathways, the calcium pathway and activation of protein kinaseC (PKC) (13, 3). The simultaneous use of a calcium ionophoresuch as ionomycin and a PKC activator such as phorbol myristateacetate (PMA) would thus lead to the stimulation of productionof most cytokines (in particular IL-2 and IL-4). These pathwaysare activated following the binding of a ligand to its receptor.Activated phospholipase C (PLC) cleaves phosphatidylinositol biphosphateto inositol 1,4,5-triphosphate, responsible for the mobilizationof intracellular calcium, and to diacylglycerol, which initiatesPKC activation. These two pathways lead to the phosphorylationand activation of cellular proteins (mitogen-activated protein[MAP] kinases) and of transcription factors (NF-AT, NF- $kappa$ B, AP-1,and CREB) responsible for the induction of cytokine genes (25).

The HIV-mediated production of IL-10, a cytokine with immunosuppressive properties (41), seems to be a crucial event duringHIVinfection.

The aims of the present work were to determine if Tat could have a direct effect on human monocytes, a prime target of HIVbut also a key cell in the immune system, by inducing the productionof IL-10 and to elucidate the intracellular mechanisms responsiblefor this production of IL-10.

Our results show that Tat from HIV-1 induces the production of IL-10 by human peripheral blood monocytes. This IL-10 productionis highly dependent on the activation of PKC. Transcription factorNF- $kappa$ B and MAP kinases ERK1 and ERK2 (ERK1/2), potential substratesof PKC, are active and are apparently involved in the productionof IL-10 induced byTat.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Monocyte isolation. PBMC were isolated from blood or the buffy coat from healthy HIV-negative donors in a Ficoll density gradient (Pharmacia).The PBMC were resuspended in 60/30 complete medium (60% AIM Vand 30% Iscove [Gibco]) containing penicillin (100 IU/ml), streptomycin(100 µg/ml), and 10% fetal calf serum (FCS). PBMC were then platedat a density of 10⁶ cells/well in 24-well Primaria (Becton Dickinson) tissue cultureplates. After 24 h of culture at 37°C in 5% CO₂, nonadherent cellswere removed, and the remaining cells were washed twice and thenincubated with the different compoundstested.

Recombinant HIV-1 Tat protein. (i) Native recombinant Tat. Recombinant HIV-1 Tat protein was obtained from Agence Nationale de la Recherche sur le SIDA (Paris, France). The level ofendotoxin contamination in purified HIV-1 Tat was assessed byusing the Limulus amebocyte lysate assay (BioSepra, Villeneuvela Garenne, France). HIV-1 Tat protein contained less than 0.3EU/µg. This Tat preparation has been shown to be biologicallyactive (7, 53).

(ii) Chemically oxidized Tat. Native recombinant Tat was oxidized with 3% H₂O₂ in phosphate-buffered saline (PBS) for 1 h at 25°C as previously described(19). In contrast to unmodified native Tat, no transactivationactivity was found with this oxidized Tat (data not shown), inaccordance with data reported by Cohen et al. (19).

(iii) Tat mutants. HIV Tat mutants were produced as glutathione-S-transferase (GST) fusion proteins in Escherichia coli. The wild-type GST-Tat1-101 and Tat-deleted mutants GST-Tat 1-72, GST-Tat 1-55, GST-Tat1-45, GST-Tat 20-72, and GST-Tat 30-72 were purified as previouslydescribed (8). As a control, GST was purified in the same conditionsand used in the same experiments. All these constructions arelipopolysaccharide (LPS) free (less than 0.3 EU/µg) and biologicallyactive, as previously described (8).

Signal transduction experiments. Isolated monocytes were cultured in 60/30 complete medium in the absence or presence of HIV-1 Tat protein or LPS. HIV-1 Tat(3.6 × 10⁵ M) and LPS (500 µg/ml) were prepared as stock solutions in PBSand water, respectively. Further dilutions were done in FCS-freemedium.

Monocytes were incubated for 30 min with various signal transduction pathway inhibitors, and HIV-1 Tat (10 nM) was added foran additional 24 h. The following inhibitors were used: U73122(1-[6-((17 $beta$ -3-methoxyestra-1,3,5(10)-trien-17-yl)amino)hexyl]-1H-pyrrole-2,5-dione)(Calbiochem, La Jolla, Calif.) as an inhibitor of PLC; cyclosporinA (Calbiochem) as an inhibitor of calcineurin; BAPTA/AM (Calbiochem)as an intracellular calcium chelator; RO31-8220 (3-[1-[3-(amidinothio)propyl-1H-indol-3-yl]-3-(1-methyl-1H-indol-3-yl)maleimide methane sulfonate) (Calbiochem) as a specific inhibitorof PKC that competes with ATP (29); H89 (N-[2-((p-bromocinnamyl)amino)ethyl]-5-isoquinolinesulfonamideHCl) (Calbiochem) as a selective inhibitor of PKA; TLCK HCl (N-tosyl-lysine chloromethyl ketone hydrochloride) (Calbiochem)as an inhibitor of trypsin-like serine proteinases; and PD98059(2'-amino-3'-methoxyflavone) (Calbiochem) as a selective inhibitorof MAP kinase kinase (MEK) that acts by inhibiting the activationof MAP kinase (ERK) and subsequent phosphorylation of MAP kinasesubstrates.

Cyclosporin A (25 or 10 mg/ml) was dissolved in ethanol; BAPTA/AM (10² M), RO31-8220 (1.81 mM), H89 (10² M), U73122 (10² M), TLCK (1.35 10¹ M), and PD98059 (1.87 10² M) were initially dissolved in dimethyl sulfoxide (DMSO). Furtherdilutions were done in FCS-free Iscove modified Dulbecco'smedium.

PMA (phorbol-12-myristate-13-acetate) (Calbiochem) was used as an activator of PKC. It was prepared at 1.62 × 10³ M in DMSO, and further dilutions were done in FCS-freemedium.

Rolipram (4-[3-(cyclopentyloxy)-4-methoxy-phenyl]-2-pyrolidinone) (Sigma), a cyclic AMP (cAMP)-specific phosphodiesteraseinhibitor, was used as a PKA activator. It was initially dissolvedin ethanol at 9 mM, and further dilutions were done in FCS-freemedium.

A putative cytotoxic effect of the different inhibitors was tested by a trypan blue dye exclusion assay, and none was foundto be cytotoxic (viability was >90%) at the concentrationsused.

Immobilized HIV Tat protein. Tat was immobilized in wells by incubation for 2 h at 37°C. After two washes to eliminate nonfixed Tat, monocytes (10⁶) were added and cultured for 24 h with different concentrationsof Tat (5, 50, or 500 nM). To control that in these conditionsTat protein could not enter cells, an intracellular Tat-dependenttransactivation assay was performed. HeLa P4 cells stably transfectedwith an HIV-1 long terminal repeat (LTR)-lacZ construct as previouslydescribed (47) were added to Tat-coated wells. LacZ expression,which reflects Tat penetration into cells and LTR transactivation,was analyzed by monitoring blue staining of the cells in the presenceof X-Gal (5-bromo-4-chloro-3-indolyl- $beta$ -D-galactopyranoside) (53).Briefly, cells were cultured overnight at 37°C in 5% CO₂. Theywere washed twice with PBS (0.5 mM MgCl₂, 1 mM CaCl₂), fixed with0.5% glutaraldehyde for 10 min, and washed twice with the samebuffer. Cells were then incubated for 3 h in a mixture containing1 mg of $beta$ -galactosidase substrate (X-Gal) per ml in PBS containing5 mM potassium ferricyanide, 5 mM potassium ferrocyanide, and2 mM magnesium chloride. X-Gal had been previously dissolved inDMSO at 40 mg/ml. The enzymatic reaction was stopped by removingthe X-Gal reaction mixture. Stained cells were stored in PBSbuffer.

IL-10 detection by ELISA. IL-10 production was quantified by using a two-site sandwich enzyme-linked immunosorbent assay (ELISA). MAB217 (R & D Systems,Oxon, U.K.) monoclonal antibody (MAb) (4 µg/ml) was used for captureovernight at room temperature. After three washes with PBS containing0.05% Tween 20 (wash buffer), plates were blocked by adding 300µl of PBS containing 1% bovine serum albumin and 5% sucrose toeach well for a minimum of 1 h. After three washes, culture supernatants(100 µl/well) were incubated for 2 h at room temperature. Plateswere then washed three times and incubated with biotinylated anti-humanIL-10 polyclonal antibody (BAF217), obtained from R & D Systems,for 2 h at room temperature. After washing, the bound biotinylatedpolyclonal antibody was visualized by an additional 20 min ofincubation with streptavidin-peroxidase (Sigma, Saint QuentinFallavier, France) diluted 1:16,000 in PBS-Tween-bovine serumalbumin. After washing, the plates were incubated with the substrateO-phenylendiamine dihydrochloride plus H₂O₂ (Sigma). The reactionwas stopped by adding 50 µl of H₂SO₄ (4 N) to each well. Absorbancewas read at 490 nm, with a wavelength correction of 600 nm. Cytokineswere quantified from a standard curve generated by using variousconcentrations of recombinant human IL-10 (R & D Systems). Thelimit of detection was 15 pg/ml.

Intracellular Ca²⁺ concentrations. Intracellular Ca²⁺ concentrations were determined by emission microspectrofluorimetry as previously described (3, 41).Cells were incubated with 5 µM 3-fluo-acetoxymethylester (AM;Molecular Probes, Leiden, The Netherlands) for 30 min at 37°C.Intracellular Ca²⁺ concentrations were measured in cells stimulated by Tat (10 or100 nM) or 1 µM ionomycin (Sigma). Ionomycin was initially dissolvedin DMSO at a concentration of 2 mM. Cell preparations were placedon the stage of an inverted Diaphot microscope (Nikon) and observedwith a 40× objective. The excitation wavelength was 490 nm, witha 525-nm barrier filter. Fluorescence was detected by an intensifiedcharge coupled device camera (C2400-80; Hamamatsu, Photonics,Hamamatsu, Japan). With the magnification used (40×) a field of200 by 200 µm was recorded by the camera. Three to five fieldswere observed for each type of experiment, and in each field 12windows (9 µm) were distributed on different cells and analyzedfor fluorescence. Images were captured at intervals of 5 s andprocessed with the Argus 50 image processing system (HamamatsuPhotonics). Time courses of Ca²⁺ signals in cells were analyzed with Argus 50 software. Data arepresented as the ratio of fluorescence (F) in stimulated cellsto fluorescence (F₀) at the baseline level. Cells were scoredas positive if the variation in fluorescence intensity was 5%above the baselinelevel.

EMSA. For the electrophoretic mobility shift assay (EMSA), nuclear extracts were prepared as previously described (50). Briefly,cold Tris-buffered saline (TBS, pH 7.8) was added to monocytes(2 × 10⁶ cells), which were scraped and harvested after 16 h of incubation.Monocytes, whole PBMC, or monocyte-depleted PBMC (2 × 10⁶ cells) were washed and collected. Cells were transferred to 1.5-mlEppendorf tubes and microcentrifuged at 4°C for 15 s. The pelletwas resuspended in 400 µl of lysis buffer (10 mM HEPES [pH 7.9],0.1 mM EGTA, 0.1 mM EDTA, 10 mM KCl, 1 mM dithiothreitol [DTT],and 0.5 mM phenylmethylsulfonyl fluoride [PMSF]). After 15 minon ice, 25 µl of 10% Nonidet P-40 (Sigma) solution was added tothe samples, and cells were homogenized with a Vortex and microcentrifugedat 4°C for 30 s. The pellets were resuspended in 50 µl of B lysisbuffer (20 mM HEPES [pH 7.9], 0.4 M NaCl, 1 mM EDTA, 1 mM DTT,1 mM PMSF), and the cells were agitated vigorously for 15 minat 4°C on a shaking platform. The nuclear extracts were microcentrifugedfor 5 min at 4°C, and aliquots of supernatants were frozen at $-$ 80°C. Total protein levels were determined with the Bradfordassay, using a commercial protein assay reagent (Bio-Rad, IvrySur Sein Cedex, France). The NF- $kappa$ B mobility shift assays wereperformed using 6 µg of protein of nuclear extract, 10⁴ cpm of radiolabeled double-stranded NF- $kappa$ B probe in C buffer (100mM KCl, 1 mM DTT, 1 µM ZnSO₄, 20% glycerol, 0.01% Nonidet P-40,50 mM HEPES [pH 7.9]) supplemented with bovine serum albumin,tRNA, and poly(dI:dC) in a final volume of 20 µl. After 20 minat room temperature, electrophoresis of the mixture was carriedout at 120 V in a 5% polyacrylamidegel.

Two oligonucleotide sequences were used. The first was the HIV-1 LTR NF- $kappa$ B sequence 5'-GCTGGGGACTTTCCAGGGAG-3', and in orderto determine specificity of binding, the second was the NF- $kappa$ Bmutated sequence 5'-GCTGTTTACTGGCCCAGGGAG-3'.

SDS-PAGE and Western blot. After incubating cells (10⁶) in the presence or absence of Tat or PMA for 15 or 30 min, cold TBS (pH 7.8) was added, and thecells were transferred to 1.5-ml Eppendorf tubes and microcentrifugedat 4°C for 15 s. The pellet was resuspended in 200 µl of lysisbuffer (10 mM HEPES [pH 7.9], 0.1 mM EGTA, 0.1 mM EDTA, 10 mMKCl, 1 mM DTT, 0.5 mM PMSF). After 15 min on ice, 7 µl of 10%Nonidet P-40 solution was added to the samples and the cells werehomogenized with a Vortex. The cytoplasmic extracts were microcentrifugedat 4°C for 30 s, and the supernatants were stored at $-$ 80°C untilused.

Generated extracts were subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), and separated proteinswere transferred to nitrocellulose membranes. Immunoblotting wasconducted using either rabbit polyclonal anti-phospho-p44/42 MAPkinase (Thr-202/Tyr-204) antibody (1:1,000) (New England Biolabs,Hertfordshire, England) or rabbit anti-p44/42 MAP kinase antibody(1:1,000) (New England Biolabs). Membranes were incubated withthe primary antibody (2 h at room temperature). Immunoreactivebands were then detected by incubation for 2 h at room temperaturewith swine anti-rabbit immunoglobulins conjugated with horseradishperoxidase (1:1,000) (Dako A/S, Roskilde, Denmark). The membraneswere then visualized using a chemiluminescent substrate (Pierce,Rockford, Ill.).

Statistical analysis. The Mann-Whitney nonparametric test was used in this study to compare data for stimulated cells in the absence and presenceofinhibitors.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Tat induces the production of IL-10 by human monocytes. Monocytes from healthy donors were purified from the buffy coat and cultured for 24 h in the presence of Tat at 1, 10, 100,or 500 nM Tat or LPS at 100 ng/ml. No IL-10 production was detectedin the supernatant of monocytes cultured in the absence of Tator LPS (Fig. 1). In contrast, addition of various concentrationsof Tat induced strong and dose-dependent IL-10 production by monocytesfrom 1,234 ± 186 pg/ml with 10 nM Tat up to 3,280 ± 427 pg/mlby cells treated with Tat at 500 nM (Fig. 1A). Production thatwas observed at 24 h increased when Tat and monocytes were incubatedfor 48 and 72 h (Fig. 1B). The quantity of IL-10 produced by monocytesin response to Tat is thus dose and stimulation time dependent.To verify the specificity of the Tat effect, a chemically inactivatedTat mutant was used as a control. When tested in the same conditions,oxidized Tat was unable to induce IL-10 production by human monocytes(Fig. 1C). This specificity was further characterized using amixture of three monoclonal antibodies directed against Tat. Preincubationof Tat (10 nM) with these antibodies totally inhibits IL-10 production(Fig. 2B).

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FIG. 1. Production of IL-10 by monocytes treated with Tat. (A) Monocytes (10⁶) were incubated in the absence or presence of Tat (1, 10, 100, or 500 nM) or LPS (100 ng/ml) for 24 h. (B) Monocytes were identically treated with LPS (100 ng/ml) or Tat (10 or 100 nM) but for 24, 48, or 72 h. (C) Specificity of Tat. Monocytes (10⁶) were incubated in the absence or presence of native Tat (10 or 100 nM), oxidized Tat (1 h at 25°C in PBS plus 3% H₂O₂ at 10 and 100 nM), or LPS (100 ng/ml) for 24 h. (D) PBMC were depleted of monocytes by three successive adherence steps (1°, 2°, and 3°) in 24-well plates. After each adherence step, cells remaining in suspension (10⁶) were incubated in the absence or presence of LPS at 100 ng/ml or Tat at 1, 10, or 100 nM. Culture supernatants were recovered, and the presence of IL-10 was determined by ELISA. For A, B, and D, the values are the means ± standard deviation (SD) of three experiments with cells from one donor. Similar results were obtained with cells from three different donors. For C, the values are from results obtained with three different donors. Ctr, control.

As expected, LPS used at 100 ng/ml also induced high IL-10 production (Fig. 1A). Thus, the recombinant protein Tat was testedto detect possible contamination by this component. The Tat preparationused in this work contained no LPS within the limit of sensitivityof the test. Furthermore, LPS at the limit of detection in thistest, 50 pg/ml, does not cause the production of IL-10 by monocytesin our system (data not shown). The production of IL-10 by monocytesis thus due to HIV-1Tat.

Since our experiments were run with monocytes obtained from the buffy coat, the induction of IL-10 production was also confirmedwith monocytes isolated from the fresh whole blood of healthydonors (data not shown). In order to determine if cells otherthan monocytes from peripheral blood can produce IL-10 followingstimulation by Tat, monocytes in the PBMC population were depletedby several adherence steps and treated with Tat in the same conditions.The monocyte-free nonadherent cells did not produce IL-10 aftertreatment with 1, 10, and 100 nM Tat (Fig. 1D), indicating thedirect implication of monocytes in the production of IL-10.

To determine the Tat region implicated in IL-10 production, we used first exon-deleted mutants GST-Tat 1-72 (RGD domain deleted),GST-Tat 1-55 (RGD and glutamic domains deleted), GST-Tat 1-45(RGD, glutamic, and basic domains deleted), GST-Tat 20-72 (N-terminaldomain deleted), and GST-Tat 30-72 (cysteine-rich region deleted).Results show that the C-terminally deleted mutants GST-Tat 1-72,GST-Tat 1-55, and GST-Tat 1-45 induced the same amount of IL-10as the wild-type GST-Tat 1-101. Weak stimulation was observedwith GST-Tat 20-72 (10 nM), while no stimulation was observedwith GST-Tat 30-72 or with GST alone (Fig. 2A). These resultsindicate that the critical region responsible for the stimulationwas located within residues 1 to 45. In a second approach, weused three anti-Tat MAbs recognizing epitopes located within regions1 to 15, 46 to 60, and 74 to 86. Preincubation of Tat with MAb1-15 greatly inhibited (80.7%) the capacity of Tat to induce IL-10production (Fig. 2B). Only a weak inhibition was obtained withTat MAb 46-60, and no inhibition was observed with MAb 74-86.Thus, in agreement with the results with Tat recombinant mutants,the N-terminal region of Tat, amino acids 1 to 45, seems to becrucial for IL-10 stimulation.

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FIG. 2. Specificity of Tat-induced IL-10 production and mapping of the active domain. (A) Monocytes (10⁶) were incubated with wild-type GST-Tat 1-101 (1 or 10 nM) or with recombinant mutants GST-Tat 1-72, GST-Tat 1-55, GST-Tat 1-45, GST-Tat 20-72, or GST-Tat 30-72 (1 or 10 nM) or with GST as a negative control for 24 h. Culture supernatants were recovered, and the presence of IL-10 was determined by ELISA. The values are the means ± SD of three experiments with cells from one donor. Similar results were obtained with cells from three different donors. (B) Tat (10 nM) was incubated for 1 h or not with MAbs directed against Tat epitopes 1 to 15, 46 to 60, or 74 to 86 (2.5 or 0.025 µg/ml) or the mixture of the three MAbs. After 24 h, culture supernatants were recovered, and the presence of IL-10 was determined by ELISA. As control, an MAb directed against gp140 of simian immunodeficiency virus was used as a control in the same conditions. Results represent the ratio of production of IL-10 by monocytes stimulated by Tat (10 nM) incubated with MAb and production of IL-10 produced after stimulation by Tat (10 nM) alone (P/P₀). On the right, the percent inhibition of IL-10 production induced by Tat (10 nM) is represented. Mouse MAbs were obtained from the Agence Nationale de la Recherche sur le SIDA (Paris, France).

Tat contains a nuclear localization sequence, and so there are two possible levels of action, the membrane and the nucleus.Tat was immobilized in wells in order to test whether it mustpenetrate monocytes to induce IL-10 production. In these conditions,monocyte stimulation by increasing concentrations of immobilizedTat led to dose-dependent production of IL-10 (Fig. 3A). In orderto rule out the possibility that under these conditions some Tatentered the monocyte and induced IL-10 by an intracellular mechanism,Tat transactivation activity was evaluated in a comparative assay,depending on the intracellular localization of Tat, using HeLaP4 cells cultured with immobilized or soluble Tat. Tat immobilizedin these conditions was unable to transactivate the HIV LTR, contraryto soluble Tat added at the same concentrations (Fig. 3B). Thus,Tat coated on the wells did not enter the cells, at least at thelimit of sensitivity of the test. This suggests that Tat probablymediates its effect by direct interaction with the cell membrane.On the other hand, using flow cytometry analysis, we have shown,in agreement with previous reports (2, 21, 27, 58, 49),that fluorescein isothiocyanate (FITC)-labeled Tat was able tobind to the cell membrane in a dose-dependent manner (data notshown).

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FIG. 3. Production of IL-10 by monocytes stimulated by Tat immobilized in wells. (A) Tat was immobilized in wells by incubation for 2 h at 37°C. After two washes to eliminate nonfixed Tat, monocytes (10⁶) were added and cultured for 24 h with different concentrations of Tat (5, 50, or 500 nM). Culture supernatants were recovered, and the presence of IL-10 was determined by ELISA. (B) HeLa P4 cells were incubated with soluble (solid bars) or immobilized (shaded bars) Tat, and a Tat-dependent-transactivating test was done as described in Materials and Methods. The values are the means ± SD of three experiments. For A, similar results were obtained with cells from two different donors.

Calcium pathway seems not to be involved in the production of IL-10 induced by Tat. We then sought to determine the signal transduction pathways involved in this production of IL-10. Two predominant signalingpathways known to induce the expression of cytokine genes werestudied, the calcium pathway and the PKC pathway. These pathwaysare activated after stimulation of a membrane receptor that activatesPLC, an enzyme that hydrolyzes phosphatidylinositol biphosphateto inositol 1,4,5-triphosphate, which initiates the calcium pathway,and to diacylglycerol, which activatesPKC.

We initially used U73122, an inhibitor of PLC, to determine if this enzyme, the starting point for these signaling pathways,was involved in the activation by Tat. Significant inhibition(36 and 61.2%) of Tat-induced IL-10 production was observed whenU73122 was used at 2.5 and 7.5 µM, respectively (Fig. 4). Thissuggests that the PLC pathway is involved in Tat-induced IL-10production.

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FIG. 4. Effect of PLC inhibitor U73122 on Tat-induced production of IL-10. Monocytes (10⁶) were treated or not with U73122 (2.5 or 7.5 µM) for 30 min. Tat (10 nM) was then added for 24 h. Culture supernatants were recovered, and the presence of IL-10 was determined by ELISA. The values are the means ± SD of three experiments. Similar results were obtained with cells from three different donors.

The calcium pathway is initiated by the presence of IP3, responsible for mobilizing intracellular calcium stores and thusthe increased concentration of intracellular calcium. This pathwayleads to the activation of calcineurin, a phosphatase that dephosphorylatestranscription factor NF-AT. This enables the factor to undergotranslocation to the nucleus, where it binds to specific siteson gene promoters, especially those coding for cytokines (47).

Two complementary approaches were used to determine the involvement of the calcium pathway in IL-10 induction by Tat, thefirst of which involved inhibitors. The compounds used were cyclosporinA (0.1 and 1 µg/ml), which inhibits calcineurin and acts by sequesteringphosphorylated NF-AT in the cytoplasm, and BAPTA/AM (1.5 or 15µM), a chelator of intracellular calcium. These two compoundsdid not significantly modify the Tat-mediated production of IL-10by monocytes (Fig. 5A). As controls, we verified that the concentrationsof cyclosporin A and BAPTA/AM used are biologically active (Fig.5B). To this end, monocytes were stimulated with the calcium ionophoreionomycin, and production of tumor necrosis factor-alpha (TNF- $alpha$ )was measured in the presence of these inhibitors. The resultsshow that TNF- $alpha$ induced by ionomycin was totally inhibited bycyclosporin A and markedly reduced (81%) by BAPTA/AM (Fig. 5B).

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FIG. 5. Involvement of the calcium pathway. (A) Effect of calcineurin inhibitor cyclosporin A (Cs A) and of the chelator of intracellular calcium BAPTA/AM on the Tat-induced production of IL-10. Monocytes were treated or not for 30 min as indicated and then treated or not with Tat at 10 nM. Culture supernatants were recovered, and the presence of IL-10 was determined by ELISA. (B) Positive control of inhibition by cyclosporin A and BAPTA/AM on the ionomycin-induced production of TNF- $alpha$ . Monocytes were treated or not for 30 min as indicated and then treated or not with ionomycin (1 µM) for 24 h. Culture supernatants were then collected, and the presence of TNF- $alpha$ was determined by ELISA. These results are representative of three independent experiments done on cells from two donors. (C and D) Variations in intracellular calcium concentrations determined by microspectrofluorimetry using fluo-3AM as the probe. Cells were incubated for 30 min in the presence of fluo-3 (5 µM) and observed microscopically after two washes. Monocytes were stimulated by 100 nM Tat (C) or 1 µM ionomycin (D). The curves are the results obtained from the means for 11 different cells from a single donor. Similar results were obtained with cells from two different donors.

In the second approach, the role of calcium in the production of IL-10 was investigated by following the variations in cytoplasmicfree Ca²⁺ concentrations ([Ca²⁺]_i) at the cellular level by microspectrofluorimetrywith the fluorescent probe fluo3-AM. Monocyte stimulation by Tat(100 nM) led to a very slight increase in the intracellular calciumconcentration (Fig. 5C) that was at the limit of significance.These results were the mean for 11 cells analyzed. The calciumionophore ionomycin was used as a positive control in the sameexperimental conditions. The addition of 1 µM ionomycin causeda transient increase in [Ca²⁺]_i that returned to the baseline after 15 min of stimulation(Fig. 5D).

These results show that the calcium pathway does not play an essential role in the induction of IL-10 production byTat.

PKC is indispensable for Tat-induced production of IL-10. Monocytes treated with RO31-8220 (2.5 or 5 µM), a specific inhibitor of PKC that competes with ATP, could no longer produceIL-10 after treatment with Tat. Inhibition by the PKC inhibitorused was dose dependent, being partial (58%) at 2.5 µM and totalat 5 µM (Fig. 6A). This result suggests that PKC plays an importantrole in the mechanism of induction of IL-10 by Tat. In order torule out a possible interference with PKA sometimes observed withPKC inhibitors, a PKA inhibitor, H89, was used at 50 or 100 µM.In these conditions, H89 had no significant effect on Tat-inducedproduction of IL-10 (Fig. 6A). The specific inhibitory effectsof RO31-8220 and H89 were tested in an alternative IL-10 productionassay in which the stimulation of IL-10 was mediated by the PKApathway. To this end, monocytes were treated with rolipram, aphosphodiesterase inhibitor known to induce IL-10 production viathe PKA pathway (20). H89 inhibits in a dose-dependent mannerthe IL-10 production mediated by rolipram, and this inhibitionbecame total at 100 µM. In contrast, no significant inhibitionwas observed with the PKC inhibitor RO318220 (Fig. 6B). Togetherthese results argued for the specific effect of protein kinaseinhibitors used in this study and underlined the major role ofPKC in Tat-induced IL-10 production.

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FIG. 6. Involvement of PKC in Tat-induced production of IL-10. (A) Monocytes (10⁶) were treated or not with the PKC inhibitor RO318220 (RO) at the concentrations indicated (2.5 and 5 µM) or by the PKA inhibitor H89 (50 and 100 µM) for 30 min. Tat was then added for 24 h. These results are representative of three independent experiments done on cells from three donors. (B) Control of the specificity of the kinase inhibitors H89 and RO318220. Monocytes (10⁶) were treated or not with the PKC inhibitor RO318220 (2.5 and 5 µM) or by the PKA inhibitor H89 (50 and 100 µM) for 30 min. Rolipram was then added for 24 h. Culture supernatants were then collected, and the presence of IL-10 was determined by ELISA. (C and D) Monocytes were treated or not with PMA (50 or 100 ng/ml), a PKC activator, for 24 h (C) or 48 h (D), and Tat (10 nM) was then added. After 24 h, culture supernatants were recovered, and the presence of IL-10 was determined by ELISA. The values in C are the means ± SD of three experiments. The results in C and D are representative of three independent experiments done on cells from three donors.

The involvement of the PKC pathway was further characterized. Monocytes were depleted of PKC by a long treatment (24 or 48h) with PMA (a PKC activator) at 50 or 100 ng/ml. Treated monocyteswere then incubated with Tat (10 nM) for 24 h, and the concentrationof IL-10 was measured. The results showed a strong inhibitionof IL-10 production, up to 70% (Fig. 6C), with monocytes treatedwith PMA for 24 h. Inhibition became total after 48 h of treatmentwith PMA (Fig. 6D). Residual production of IL-10 after 24 h oftreatment would be due to activation by PMA and not to activationby Tat, since it was also detected in cells treated with PMA alone(Fig. 6C). In this procedure, PKC depletion was checked in experimentsinvolving restimulation of monocytes treated with PMA for 24 or48 h. In these conditions of PMA restimulation, the cells becameunable to produce TNF- $alpha$ (data not shown). We can note that therewas no cell toxicity in these experimental conditions, as shownby the trypan blue dye exclusion test. These results stronglysuggest that PKC plays an essential role in the production ofIL-10 by human monocytes after stimulation byTat.

We then attempted to investigate pathways activated downstream from the PKC by studying the known PKC substrate transcriptionfactor NF- $kappa$ B and the PKC-activated MAP kinase ERK1/2pathway.

Involvement of transcription factor NF- $kappa$ B. Transcription factor NF- $kappa$ B is a likely candidate for the transactivation of the IL-10 gene, since the organization of theIL-10 promoter shows the presence of nine potential NF- $kappa$ B sites(23).

In inactivated cells, NF- $kappa$ B is sequestered in the cytoplasm by the inhibitor protein I $kappa$ B, which masks its nuclear localizationsequence. In order to be active, NF- $kappa$ B must be translocated intothe nucleus, and this translocation required the degradation ofI $kappa$ B, which, once phosphorylated, is degraded in the proteasomepathway (4).

We examined the involvement of NF- $kappa$ B by first testing the capacity of Tat to activate the nuclear translocation of this factorwith the electrophoretic mobility shift technique. These experimentswere done with an NF- $kappa$ B site and showed the formation of a complexwith nuclear extracts of monocytes stimulated with 10 and 100nM Tat (Fig. 7A, lanes 3 and 5). The observed interaction betweenfactor NF- $kappa$ B and the probe seems to be specific, since no complexwas observed when the protein extract was incubated in the sameconditions with the mutated NF- $kappa$ B site (Fig. 7A, lane 4). Similarresults were obtained with nuclear proteins obtained from wholePBMC (Fig. 7A, lanes 6 to 11) using phytohemagglutinin (PHA, 3µg/ml) plus IL-2 (10 U/ml) as a positive control. On the otherhand, no complex was detected when monocyte-depleted PBMC weretreated with PHA plus IL-2 or with different concentrations ofTat (1, 10, and 100 nM) (Fig. 7A, lanes 12 to 16). To verify thatNF- $kappa$ B activation was specifically mediated by Tat, monocytes weretreated with a chemically mutated Tat (oxidized Tat, used at 10and 100 nM), and nuclear extracts were analyzed by EMSA. In agreementwith the inability of this mutant Tat to stimulate the productionof IL-10, no complex was detected in these conditions (Fig. 7B).These results indicate that Tat induces NF- $kappa$ B activation specificallyin monocytes. We then investigated if the region involved in IL-10production was able to induce NF- $kappa$ B activation. EMSA results showthat only the C-terminally deleted mutants tested (GST-Tat 1-72and GST-Tat 1-45) activate NF- $kappa$ B as the wild-type GST-Tat 1-101does (Fig. 7C, lanes 3 to 5). In contrast, no activation was observedwith GST-Tat 20-72, GST-Tat 30-72 (Fig. 7C, lanes 6 and 7), orGST (Fig. 7C, lane 2). This result shows that NF- $kappa$ B activationis correlated with the ability of Tat and Tat mutants to mediateIL-10 production.

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FIG. 7. Activation of NF- $kappa$ B by Tat in human monocytes. (A) Activation of NF- $kappa$ B determined by EMSA. Nuclear protein extracts of monocytes, total PBMC, or monocyte-depleted PBMC (PBMC-mono.) were treated with Tat at 1 nM (lanes 8 and 14), 10 nM (lanes 3, 9, and 15), or 100 nM (lanes 5, 10, and 16) or with PHA (3 mg/ml) plus IL-2 (10 U/ml) (lanes 7 and 13) for 16 h and then incubated with a sequence containing the wild-type NF- $kappa$ B site. The specificity of interaction was tested by using a ³²P-labeled mutated NF- $kappa$ B probe (NF- $kappa$ B mut.) incubated with extracts from cells treated with 100 nM Tat (lanes 4 and 11). These results are representative of two independent experiments done on cells from two donors. Ctr, control. (B) Specificity of Tat-mediated NF- $kappa$ B activation. Nuclear protein extracts of monocytes treated with native Tat (10 and 100 nM) (lanes 3 and 5, respectively) or with oxidized Tat (10 and 100 nM) (lanes 4 and 6, respectively) for 16 h were incubated with the ³²P-labeled wild-type NF- $kappa$ B probe as described above. (C) Localization of the domain of Tat involved in NF- $kappa$ B activation. Nuclear protein extracts of monocytes treated with wild-type GST-Tat 1-101 (lane 3) or Tat-deleted mutants (GST-Tat 1-72, GST-Tat 1-45, GST-Tat 20-72, and GST-Tat 30-72) at 10 nM (lanes 4 to 7) or as a negative control with GST (10 nM) for 16 h were incubated with ³²P-labeled NF- $kappa$ B probe.

We next tested the role of NF- $kappa$ B activation in the production of IL-10. Monocytes were treated with nontoxic doses (50 and100 µM) of TLCK and stimulated by Tat at 10 nM. NF- $kappa$ B activationand IL-10 production were analyzed by EMSA and ELISA, respectively.The results depicted in Fig. 8A and 6B clearly showed that TLCKprevents both NF- $kappa$ B translocation (Fig. 8A, lanes 7 and 8) andIL-10 production (Fig. 8B). These results indicate that the Tat-inducedIL-10 production is correlated with Tat-induced NF- $kappa$ B activationin monocytes. Tat thus activated transcription factor NF- $kappa$ B, oneof the substrates of PKC, thereby causing induction of the IL-10gene.

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FIG. 8. Role of NF- $kappa$ B in Tat-induced IL-10 production. (A) Effect of the serine protease inhibitor TLCK (50 and 100 µM) on NF- $kappa$ B nuclear translocation induced by Tat (10 nM) (lanes 7 and 8). Lanes 3 and 4 correspond to the activation of NF- $kappa$ B with Tat (10 and 1 nM, respectively). Ctr, control. (B) Effect of treatment with TLCK (TL) at 50 and 100 µM on IL-10 production by monocytes (10⁶) treated with 10 nM Tat (T). The values are the means ± SD of three experiments. Similar results were obtained with cells from three different donors.

Involvement of MAP kinases ERK1/2. MAP kinases p42 and p44, also called ERK1 and ERK2, can be activated by PKC (11, 12, 14, 51). This activation occursafter their phosphorylation by a cascade of kinases (Raf, MEK,and ERK) initiated by PKC. Once ERK1/2 are phosphorylated, theycan activate transcription factors that bind to the promotersof cytokinegenes.

In order for MAP kinases p42 and p44 to be activated, they must be phosphorylated on their tyrosine and threonine residues.The extent of activation of p42 and p44 was determined by treatingmonocytes with Tat (10 or 100 nM) for 15 or 30 min. Immunoblottingof the cytoplasmic extracts was then carried out, initially withan antibody against total p42 and p44 and then with an antibodyagainst phosphorylated tyrosine and threonine residues. Westernblots immunolabeled by specific antibodies against the phosphorylatedresidues showed a nonsignificant activation of ERK1/2 in cellstreated with Tat (10 and 100 nM) after 15 min of stimulation (Fig.9A). In contrast, treatment of monocytes with Tat for 30 min (10and 100 nM) allowed a dose-dependent activation of MAP kinasesERK1/2. The amounts of total MAP kinases analyzed were equivalentin all the lanes (Fig. 9A). Tat thus activates MAP kinases ERK1/2in human monocytes.

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FIG. 9. Involvement of MAP kinases ERK1/2 in the Tat-induced production of IL-10. (A) Western blot analysis of the activation of MAP kinases ERK1/2 by Tat. Cytoplasmic protein extracts were prepared from monocytes (2 × 10⁶) treated with PMA at 50 ng/ml (lanes 2 and 6) or 10 nM (lanes 3 and 7) or 100 nM (lanes 4 and 8) Tat for 15 or 30 min. Visualization was done with an antibody recognizing total ERK1/2 or only phosphorylated ERK1/2 (pERK1/2). These results are representative of two independent experiments done on cells from two different donors. Ctr, control. (B) Effect of PD 98 059 (PD) at 10 or 100 µM, an inhibitor of MAP kinases ERK1/2, on monocytes (10⁶) treated with 10 nM Tat (T). Similar results were obtained with cells from three different donors.

The involvement of MAP kinases ERK1/2 in the Tat-induced production of IL-10 was tested by using a specific inhibitor of theseMAP kinases PD98 059. When monocytes were treated with PD98 059(10 and 100 µM), IL-10 production was partially inhibited. Inhibitionwas significant and was 52% with 100 µM inhibitor (Fig. 9B). Theseresults suggest that Tat also activates MAP kinases ERK1/2 andthereby contributes to the production of IL-10.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

There are now a large number of arguments in favor of a role of Tat protein in immune disorders occurring during HIV infection.Tat has a direct involvement in the stimulation of viral replication(34), activation of the provirus, and overexpression of viruscoreceptors CXCR4 and CCR5 (30). It also disturbs the equilibriumof the immune system, e.g., by inducing the apoptosis of T cells(26), by inhibiting the activity of superoxide dismutase (55),and by acting on the expression of genes of numerous cytokines,both those that it activates, such as IL-2 (44), IL-4, IL-8,IL-6, IL-1 $beta$ , transforming growth factor beta, TNF- $alpha$ , and TNF- $beta$ (26, 48) and those that it inhibits, such as IL-12 (45).IL-12 is a key cytokine that causes the differentiation of precursorT cells to TH1 cells (43).

In the present work, we have shown that HIV-1 Tat induces the production of IL-10 by human peripheral blood monocytes. Theanalysis of the signal transduction pathways showed that the calciumpathway is not or is only slightly involved; the PKC pathway apparentlyplays an essential role in the production of IL-10; transcriptionfactor NF- $kappa$ B, one of the main targets of PKC, is activated andis involved in this Tat-induced production of IL-10; and in parallelto the activation of NF- $kappa$ B, MAP kinases ERK1/2 are also partiallyinvolved in the production of IL-10.

Tat also induces the production of TNF- $alpha$ by human monocytes (15 and data not shown). It has been reported that TNF- $alpha$ canpotentiate the production of IL-10 (24). It is important tonote, however, that TNF- $alpha$ alone cannot induce the production ofIL-10 by human monocytes (24). In agreement with these results,the addition of a neutralizing anti-TNF- $alpha$ antibody in our workdid not block the production of IL-10 (notshown).

Prior immobilization of Tat in the culture wells to prevent its intracellular penetration also allowed the stimulation ofIL-10 production. This indicates that the interaction of Tat witha membrane receptor suffices to induce the production of IL-10by human monocytes. Different regions of Tat have been implicatedin interactions with membrane proteins: the N-terminal regionwith receptor CD26 (27), the tripeptide RGD (arginine-glycine-aspartate)with integrins $alpha$ _v $beta$ ₃ and $alpha$ ₅ $beta$ ₁ of dendritic cells (58), and thebasic region with membrane lipids (49) or with the vegetativeepidermal growth factor receptor of endothelial cells (2).Among this panoply of potential Tat receptors, it would be interestingto determine the receptor(s) that participates in the transductionof the signal leading to the production of IL-10 after stimulationby Tat. However, the observation that oxidized Tat is unable tomediate the production of IL-10 by monocytes suggests the importanceof the cysteine-rich domain in the activity of Tat to stimulateIL-10 induction. To map the Tat domain implicated in this activity,the use of both recombinant Tat mutants and MAbs directed againstthe N-terminal, central, or C-terminal region of Tat showed theinvolvement of N-terminal residues 1 to 45 of Tat in this activity.It is interesting to note that the implication of the N-terminalregion, which contains the cysteine-rich domain but not the basicdomain (responsible for penetration and nuclear localization ofTat), is in agreement with (i) the absence of activity of thecysteine-oxidized Tat and (ii) the fact that the effect of Tatis exerted at the membranelevel.

It has recently been reported that Nef protein (9) and the transmembrane glycoprotein gp41 (5) can also induce the productionof IL-10. Comparison of these results with ours suggests thatTat operates via a signaling pathway different from those usedby Nef and gp41. Nef apparently uses the calcium/calmodulin phosphodiesterasepathway. In the presence of W7, an inhibitor of this phophodiesterase,or in the presence of EGTA, a calcium chelator, the inductionof IL-10 is inhibited (9). In the case of Tat, on the contrary,the calcium pathway is not or is only very slightly involved,as shown by the absence of inhibition by cyclosporin A, an inhibitorof calcineurin, and BAPTA/AM, a chelator of intracellular calcium.These results obtained with calcium pathway inhibitors are consistentwith microspectrofluorimetry determinations, at the cellular level,of variations in intracellular calcium concentrations. In addition,it has been reported that Tat blocks L-type calcium channels indendritic cells (45) and NK cells (59). In contrast to thesestudies, it has been reported that synthetic Tat can induce acalcium signal in monocytes at concentrations from 6.6 to 33 nM(1). This effect was also observed with a peptide (CysL_24-51)containing the cysteine-rich region and the core region (1).Confocal microscopy will lead to a finer determination of theexistence of possible variations in calcium concentrations indifferent cellcompartments.

The induction of IL-10 by gp41 of HIV-1 rather seems to involve adenylate cyclase and cAMP (6). Sequences of the promoterof the IL-10 gene contain a cAMP-responsive element for transcriptionfactors activated by cAMP. This pathway involves PKA and apparentlyis not involved in the mechanism of induction of IL-10 by Tat,since H89, a PKA inhibitor, has no effect on this production.In contrast, PKC activation is essential because the PKC inhibitorRO318220 inhibits the Tat-induced production of IL-10 in a dose-dependentmanner; PKC depletion of monocytes by treatment with PMA abolishesthe Tat-induced production of IL-10; and PMA, a direct activatorof PKC, induces the production of IL-10. Thus, in contrast tothe mechanisms used by Nef and gp41, the induction of IL-10 byTat does involve the PKC pathway. This difference in signal transductionbetween Nef, gp41, and Tat can be partially explained by the natureof the membrane receptors involved, upstream, in the ligand-receptorinteraction.

In the activation cascade involving PKC, we have thus demonstrated the activation of NF- $kappa$ B, which is translocated into thenucleus as shown by gel mobility shift. We have also demonstratedthe activation of the MAP kinases ERK1/2 pathway, leading to theactivation of transcription factors, including AP-1, known forits involvement in the induction of several genes, including thoseof cytokines (25). It has also been reported that Tat producedendogenously in the U937 promonocyte line can induce c-Jun N-terminalkinase (33), another member of the family of MAP kinases. Itnevertheless remains to be determined if activation is accompaniedby the modulation of expression of certain cellulargenes.

The induction of inflammatory and immunomodulating cytokine genes (26, 44, 48), as well as the chemotaxis that can beexerted by Tat (1), suggests an activating role in the immuneresponse. In spite of this, the overall effect of Tat in patientsinfected by HIV-1 appears rather suppressive. This can be explainedby the inhibition of the proliferative T response (52, 56),the induction of T-lymphocyte apoptosis (26), the inhibitionof phagocytosis of apoptotic bodies by dendritic cells (58),the cytotoxic activity of NK cells (59), and finally the suppressionof IL-12 production by dendritic cells (45) and monocytes (31).The effect of Tat on IL-10 production reported here agrees withall of these reports concerning the potential immunosuppressiverole of Tat during infection byHIV.

IL-10 is a cytokine produced by monocytes/macrophages, B cells, and T lymphocytes that suppresses cell-mediated immunity (41).IL-10 acts at different levels and is able to inhibit macrophageactivity and to suppress the production of cytokines such as IL-1,TNF- $alpha$ , and granulocyte-macrophage colony-stimulating factor (41).IL-10 also inhibits the proliferation of T lymphocytes by reducingmajor histocompatibility complex class II molecule expressionon the surface of monocytes (41).

In summary, we have identified a signal transduction pathway used by Tat that leads to the production of IL-10 by human monocytes.Tat acts on membranes to initiate the activation of PKC, a keyprotein that can mobilize and activate NF- $kappa$ B and also the membersERK1/2 of the MAP kinase family. NF- $kappa$ B and other transcriptionfactors activated by ERK1/2 are likely implicated in IL-10 geneinduction. The multiple effects of IL-10 could contribute to thecourse of HIV infection to AIDS. The understanding of the molecularand cellular mechanisms involved in the production of this cytokine,by the identification of new specific targets, may suggest possibletargeted therapeutic approaches to neutralize theseeffects.

	ACKNOWLEDGMENTS

Abdallah Badou was supported by SIDACTION (ensemble contre le SIDA). This work was supported by Agence Nationale de Recherchesur le SIDA, Conseil Régional Midi-Pyrénées, andSIDACTION.

We acknowledge P. Druet and L. Pelletier for helpfuldiscussions.

	FOOTNOTES

^* Corresponding author. Mailing address: Laboratoire d'Immuno-Virologie, Université Paul Sabatier, 118, route de Narbonne,31062 Toulouse Cedex, France. Phone: (33) 561 558 667. Fax: (33)561 558 667. E-mail: bahraoui{at}cict.fr.

REFERENCES

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

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29. Howcroft, T. K., K. Strebel, M. A. Martin, and D. S. Singer. 1993. Repression of MHC class I gene promoter activity by two-exon Tat of HIV. Science 260:1320-1322[Abstract/Free Full Text].

30. Huang, L., I. Bosch, W. Hofmann, J. Sodroski, and A. Pardee. 1998. Tat protein induces human immunodeficiency virus type 1 (HIV-1) coreceptors and promotes infection with both macrophage-tropic and T-lymphotropic HIV-1 strains. J. Virol. 72:8952-8960[Abstract/Free Full Text].

31. Ito, M., T. Ishida, L. He, F. Tanabe, Y. Rongge, Y. Miyakawa, and H. Terunuma. 1998. HIV type 1 Tat protein inhibits interleukin 12 production by human peripheral blood mononuclear cells. AIDS Res. Hum. Retroviruses 14:845-849[Medline].

32. Keller, H. U., and V. Niggli. 1993. The PKC inhibitor RO 31-8220 selectively suppresses PMA- and diacylglycerol-induced fluid pinocytosis and actin polymerisation in PMNs. Biochem. Biophys. Res. Commun. 194:1111-1116[CrossRef][Medline].

33. Kumar, A., S. Manna, S. Dhawan, and B. B. Aggarwal. 1998. HIV-1 protein activates c-Jun N-terminal kinase and activator protein-1. J. Immunol. 161:776-781[Abstract/Free Full Text].

34. Laspia, M. F., A. P. Rice, and M. B. Mathews. 1989. Tat protein increases transcription initiation and stabilizes elongation. Cell 59:283-292[CrossRef][Medline].

35. Lehmann, M. H., and H. Berg. 1998. Interleukin-10 expression is induced by increase of intracellular calcium levels in the monocytic cell line U937. Pflugers Arch. 435:868-870[CrossRef][Medline].

36. Li, C. J., D. J. Friedman, C. Wang, V. Metelev, and A. Pardee. 1995. Induction of apoptosis in uninfected lymphocytes by HIV-1 Tat protein. Science 268:429-431[Abstract/Free Full Text].

37. Li, C. J., Y. Ueda, B. Shi, L. Borodyansky, L. Huang, Y. Li, and A. Pardee. 1997. Tat protein induces self-perpetuating permissivity for productive HIV-1 infection. Proc. Natl. Acad. Sci. USA 94:8116-8120[Abstract/Free Full Text].

38. Maggi, E., M. Mazetti, A. Ravina, F. Annunziato, M. De Carli, M. P. Piccini, R. Manetti, M. Carbonari, A. M. Pesce, G. Del Prete, and S. Romagnani. 1994. Ability of HIV to promote a TH1 to TH2 shift and to replicate preferentially in TH2 and TH0 cells. Science 265:244-246[Abstract/Free Full Text].

39. Mann, D. A., and A. D. Frankel. 1991. Endocytosis and targeting of exogenous HIV-1 Tat protein. EMBO J. 10:1733-1739[Medline].

40. Masood, R., Y. Lunardi-Iskandar, T. Moudgil, Y. Zhang, R. E. Law, C. L. Huang, R. K. Puri, A. M. Levine, and P. S. Gill. 1994. IL-10 inhibits HIV-1 replication and is induced by tat. Biochem. Biophys. Res. Commun. 15:374-383.

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30.	Huang, L., I. Bosch, W. Hofmann, J. Sodroski, and A. Pardee. 1998. Tat protein induces human immunodeficiency virus type 1 (HIV-1) coreceptors and promotes infection with both macrophage-tropic and T-lymphotropic HIV-1 strains. J. Virol. 72:8952-8960[Abstract/Free Full Text].
31.	Ito, M., T. Ishida, L. He, F. Tanabe, Y. Rongge, Y. Miyakawa, and H. Terunuma. 1998. HIV type 1 Tat protein inhibits interleukin 12 production by human peripheral blood mononuclear cells. AIDS Res. Hum. Retroviruses 14:845-849[Medline].
32.	Keller, H. U., and V. Niggli. 1993. The PKC inhibitor RO 31-8220 selectively suppresses PMA- and diacylglycerol-induced fluid pinocytosis and actin polymerisation in PMNs. Biochem. Biophys. Res. Commun. 194:1111-1116[CrossRef][Medline].
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34.	Laspia, M. F., A. P. Rice, and M. B. Mathews. 1989. Tat protein increases transcription initiation and stabilizes elongation. Cell 59:283-292[CrossRef][Medline].
35.	Lehmann, M. H., and H. Berg. 1998. Interleukin-10 expression is induced by increase of intracellular calcium levels in the monocytic cell line U937. Pflugers Arch. 435:868-870[CrossRef][Medline].
36.	Li, C. J., D. J. Friedman, C. Wang, V. Metelev, and A. Pardee. 1995. Induction of apoptosis in uninfected lymphocytes by HIV-1 Tat protein. Science 268:429-431[Abstract/Free Full Text].
37.	Li, C. J., Y. Ueda, B. Shi, L. Borodyansky, L. Huang, Y. Li, and A. Pardee. 1997. Tat protein induces self-perpetuating permissivity for productive HIV-1 infection. Proc. Natl. Acad. Sci. USA 94:8116-8120[Abstract/Free Full Text].
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39.	Mann, D. A., and A. D. Frankel. 1991. Endocytosis and targeting of exogenous HIV-1 Tat protein. EMBO J. 10:1733-1739[Medline].
40.	Masood, R., Y. Lunardi-Iskandar, T. Moudgil, Y. Zhang, R. E. Law, C. L. Huang, R. K. Puri, A. M. Levine, and P. S. Gill. 1994. IL-10 inhibits HIV-1 replication and is induced by tat. Biochem. Biophys. Res. Commun. 15:374-383.