Interleukin (IL)-6 Directs the Differentiation of IL-4-producing CD4+ T Cells

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© The Rockefeller University Press, 0022-1007/1997/2/461/ $5.00
The Journal of Experimental Medicine, Volume 185, Number 3, February 3, 1997 461-470

Articles

Interleukin (IL)-6 Directs the Differentiation of IL-4–producing CD4⁺ T Cells

Mercedes Rincón^*, Juan Anguita, Tetsuo Nakamura^*^,, Erol Fikrig, and Richard A. Flavell^*^,

From the ^* Section of Immunobiology, Yale University School of Medicine, New Haven, Connecticut 06520-8011; Section of Rheumatology, Department of Internal Medicine, Yale University School of Medicine, New Haven, Connecticut 06520-9031; and Howard Hughes Medical Institute, Yale University School of Medicine, New Haven, Connecticut 06520-8011

Abstract

Top
Abstract
Materials and Methods
Results and Discussion
References

Interleukin (IL)-4 is the most potent factor that causes naiveCD4⁺ T cells to differentiate to the T helper cell (Th) 2 phenotype,while IL-12 and interferon ${gamma}$ trigger the differentiation of Th1 cells. However, the source of the initial polarizing IL-4remains unclear. Here, we show that IL-6, probably secretedby antigen-presenting cells, is able to polarize naive CD4⁺T cells to effector Th2 cells by inducing the initial productionof IL-4 in CD4⁺ T cells. These results show that the natureof the cytokine (IL-12 or IL-6), which is produced by antigen-presenting cells in response to a particular pathogen, is a key factorin determining the nature of the immune response.

Address correspondence to Dr. Richard A. Flavell, Section ofImmunobiology, Yale University School of Medicine, PO Box 208011,New Haven, CT 06520-8011. M. Rincón's present addressis the University of Vermont, Department of Medicine, GivenMedical Bldg., Burlington, VT.

In response to pathogens, naive CD4⁺ T cells differentiate intoeffector Th1 and Th2 cells. Th1 cells produce IL-2, IFN- ${gamma}$ , andTNF-β, which are involved in cellmediated inflammatoryreactions. Th2 cells secrete mainly IL-4, IL-5, IL-6, IL-10,and IL-13, which mediate B cell activation, antibody production,and the regulation of Th1 responses (for review see reference1). In general, a Th1 response helps eradicate intracellularmicroorganisms, whereas a Th2 response can control extracellularpathogens. Development of an inappropriate response can leadto ineffective immunity and may even be pathogenic. Thus, thefactors that regulate the polarization to either a Th1 or Th2immune response are critical, but remain unclear. The dose of antigen and the type of APC, and/or the co-stimulatory pathways(2–6), have been postulated to be some of the polarizingfactors. However, the most effective inducer of CD4⁺ T celldifferentiation appears to be the local cytokine environment.It is clear that the cytokine IL-12 directs differentiationto a Th1 phenotype (7, 8), while IL-4 can drive differentiationto a Th2 phenotype (9, 10).

If cytokines are indeed the driving force behind CD4⁺ T celldifferentiation, where does the initial polarizing cytokinecome from? Several findings suggest that during the initiationof a Th1 response, IL-12 is produced particularly by macrophagesin response to certain microbial antigens, while NK cells arethe main source of IFN- ${gamma}$ in response to IL-12 (7, 11). In thecase of a Th2 response, the initial source of IL-4 is lessclear, since none of the classical APCs make IL-4. Some non-APCs,such as mast cells and basophils, can produce IL-4, but thesecells are not abundant in the lymphoid organs where T cellpriming occurs (12). Recently, it has been shown that IL-4is also produced by a minor subpopulation of T cells, the CD3⁺CD4⁺NK1.1⁺ cells, which may therefore have a role (13). However, the production of IL-4 by mast cells and basophils is a late eventand it is not yet clear how the CD4⁺NK1.1⁺ cells become activated.An alternative possibility, however, is that other cytokinesmay induce the initial production of IL-4 by the CD4⁺ T cells;after this initial stimulus, the secreted IL-4 could act inan autocrine fashion, upregulating IL-4 production and inhibitingIFN- ${gamma}$ production, thereby polarizing the differentiation ofTh2 cells.

In an attempt to find potential cytokines that, like IL-12, could be produced by classical APCs and could trigger the initial IL-4 production by CD4⁺ T cells, we analyzed the modulatoryeffects of IL-6, a cytokine involved in different aspects ofthe immune response and acute phase response (for review seereferences 14 and 15). Here we show that IL-6 is able to initiatethe polarization of naive CD4⁺ T cells to effector Th2 cellsby inducing the production of endogenous IL-4. In addition,IL-6 also antagonizes the IL-12– mediated differentiationof Th1 cells. We postulate that IL-6 is a key factor in thechoice between a Th1 or Th2 immune response.

Materials and Methods

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Abstract
Materials and Methods
Results and Discussion
References

Cell Preparation and Reagents.
Total CD4⁺ T cells were isolated from spleen and lymph nodesfrom either wild-type B10.BR, wild-type C57BL/6J, or C57BL/6J-backcrossedIL-6–deficient mice by negative selection as previouslydescribed (16). The naive population (CD4⁺CD45RB^highCD44^low)was purified from total CD4⁺ T cells obtained from cytochrome(Cyt)¹ c TCR transgenic mice by staining with a red⁶¹³-conjugatedanti-CD4 mAb, a biotinylated anti-CD44 mAb, FITC-conjugatedanti-CD45RB mAb, and PE-conjugated streptavidin (PharMingen,San Diego, CA) and cell sorting by using a FACS^PLUS®. MitomycinC-treated (50 µg/ml) syngeneic splenocytes were usedas source of APCs.

Total or naive CD4⁺ T cells were cultured at 10⁶ cells/ml in the presence of syngeneic APCs (5 x 10⁵ cells/ml) with ConA (Boehringer Mannheim GmbH, Mannheim, Germany) or syntheticmoth Cyt c peptide (Yale University, New Haven, CT) plus IL-6(R&D Sys., Inc., Minneapolis, MN), IL-12 (provided by GeneticsInstitute, Cambridge, MA), or IL-4 (provided by DNAX, PaloAlto, CA). After 4 d, a 40–60% increase in the numberof cells was observed in the different conditions. EffectorTh cells were exhaustively washed, counted, and restimulatedat 10⁶ cells/ml with Con A (in the absence of APCs) or Cytc peptide plus APCs (5 x 10⁵ cells/ml). Anti-CD3 mAb (2C11)was immobilized on plastic at 5 µg/ml and anti-CD28 (PharMingen) was used in a soluble form (1 µg/ml).

Cell Surface Staining.
Expression of IL-6R ${alpha}$ was analyzed by FACS^® by double stainingwith a FITC-conjugated anti-CD4 mAb and a biotinylated anti–IL-6R ${alpha}$ mAb (PharMingen) in combination with PE-conjugated streptavidin.

Competitive Reverse Transcriptase-PCR.
Total RNA was extracted as described (17) from 2 x 10⁵ cellsmixed with 10⁴ Raji cells which were added at harvest as aninternal control, and the amount of human MHC class II HLA-DRcDNA from Raji cells was used as an internal standard. In brief,after dilution (1/2) of reverse transcription reaction mixture,5 µl was assayed for levels of DR cDNA by PCR using DR-specificprimers in the presence of DR competitor construct (50 pg)to confirm the efficiency of RNA extraction and reverse transcriptase(RT)-PCR procedure in each group. IL-4 transcript levels inthe 5 µl of diluted (1/2) reverse transcription reactionmixture was semi-quantitated using the competitor (167 fg)in the presence of specific primers as described (18). DR primersused were (5'-CGAGTTCTATACTGAATCCTG, and 3'-GTTCTGCTGCATTGCTTTTGC).Competitor amounts shown (competition cDNA, fg or pg) are correctedto represent the amount of IL-4 or DR gene and not as the totalplasmid amount. A multiple cytokine-containing competitor constructwas a gift from R.M. Locksley (University of California, SanFrancisco, CA).

Cytokine Production.
ELISA assays were performed using purified anti–IL-4,anti–IL-12, and anti–IL-6 mAbs (3 µg/ml) as primary antibodies, the corresponding biotinylated anti–IL-4, anti–IL-12 and anti–IL-6 mAbs (1 µg/ml; PharMingen),and horseradish peroxidase-conjugated avidin D (2.5 µg/ml)(Vector Labs., Inc., Burlingame, CA), the TMB microwell peroxidase substrate and stop solution (Kirkegaard & Perry Labs.,Inc., Gaithersburg, MD), using the recommended protocol (PharMingen).Recombinant IL-4 (DNAX) and IFN- ${gamma}$ (GIBCO BRL, Gaithersburg, MD)were used as standards. The specific activity of the IL-4 andthe IFN- ${gamma}$ that were used as standards for the ELISA assays were10⁸ U/mg for IL-4 and 10⁷ U/mg for IFN- ${gamma}$ .

Results and Discussion

Top
Abstract
Materials and Methods
Results and Discussion
References

IL-6 is produced by a wide spectrum of cells including fibroblasts,endothelial cells, neuronal cells, macrophages, mast cells,tumor cell lines, and CD4⁺ Th2 cells, but from an immunologicalpoint of view, APCs represent the major source of IL-6 (14,19). To determine the potential role of IL-6 in differentiationof naive CD4⁺ T cells into effector Th1 and Th2 cells, we firstanalyzed the effect of exogenous IL-6. Total mouse CD4⁺ T cellswere isolated (16) and stimulated to differentiate with ConA with or without IL-4 (Th2) or IL-12 (Th1) in the presenceor absence of exogenous IL-6. After 4 d, the effector Th1 orTh2 cells were exhaustively washed, counted, and equal numberof cells were restimulated with Con A for 24 h before harvestingthe supernatant which was then analyzed for cytokine production.Interestingly, even in the absence of any polarizing cytokine,IL-6 directed the differentiation of the CD4⁺ cells to a Th2phenotype, since the cells produce high amounts of IL-4, butnot IFN- ${gamma}$ (Fig. 1 A). IL-6 did not modify the differentiationof the Th2 cells directed by IL-4. However, differentiationinto Th1 cells by IL-12, was impaired in the presence of IL-6.Thus, Th1 cells differentiated with Con A and IL-12 in the presenceof IL-6, produced less IFN- ${gamma}$ , and more IL-4 (Fig. 1 A). IL-6,like IL-2, has been described to be a growth factor for a numberof cells (14, 15). However, only IL-6, but not IL-2, was ableto modify the polarization of the CD4⁺ cells to Th2 phenotype(Fig. 1 A), indicating that IL-6 is involved in differentiationrather than growth of T cells. To eliminate the possibilitythat IL-6 could favor the expansion or IL-4 secretion of theCD4⁺ memory subpopulation, which has been described to displaya Th2 phenotype (20), we analyzed the role of IL-6 in the differentiationof purified naive CD4⁺ T cells. Thus, we used CD4⁺ T cells fromTCR transgenic mice (21), which express the ${alpha}$ and β chainof the TCR that recognizes a pigeon Cyt c peptide; before further purification, 90–95% of the CD4⁺ T cells express the naive phenotype. Total CD4⁺ T cells were stained with anti-CD44 and anti-CD45RB mAbs and the naive CD4⁺ CD44^lowCD45RB^highpopulation was isolated by cell sorting and activated with thesame polyclonal stimulus, Con A, in the presence or absenceof different cytokines. We observed that IL-6, in the absenceof any other cytokine, was able to promote the differentiationof naive CD4⁺ cells to IL-4–producing cells (Fig. 1 B).In addition, we also analyzed the effect of IL-6 in the differentiationof naive CD4⁺ T cells stimulated by specific antigen. The presence of IL-6 during the activation with Cyt c peptide drove differentiationof naive CD4⁺ T cells into IL-4–producing effector Th2cells as well or better than IL-4 (Fig. 1 C). Therefore, themodulatory effect of IL-6 in T cell differentiation is not aconsequence of an expansion of the memory subpopulation.

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Figure 1 IL-6 directs differentiation of CD4⁺ T cells into Th2 cells. (A) Total CD4⁺ T cells (10⁶/ml) were purified from normal B10.BR mice and stimulated (in the presence of 5 x 10⁵ cell/ml syngeneic APCs) with Con A (2.5 µg/ml) alone, Con A plus IL-4 (10³ U/ml) or Con A plus IL-12 (3.5 ng/ml), in the absence (–) or presence of IL-6 (100 ng/ml) or IL-2 (50 U/ml). After 4 d, cells were exhaustively washed and restimulated (10⁶ cells/ml) with Con A alone (2.5 µg/ml) in the absence of APCs or additional cytokines. Supernatants were harvested 24 h later and analyzed for IL-4 and IFN- ${gamma}$ production by ELISA. (B) Total CD4⁺ population was isolated from Cyt c TCR transgenic mice, and the naive CD4⁺ CD45RB^highCD44^low subpopulation was purified by cell sorting. Naive CD4⁺ T cells were then stimulated with Con A alone, Con A plus IL-4, or Con A plus IL-12, and APCs, in the presence or absence of IL-6. After 4 d, cells were exhaustively washed and restimulated (10⁶ cell/ ml) with Con A alone for 24 h before harvesting the supernatants for cytokine measurement. (C) Naive CD4⁺CD45RB^highCD44^low CD4⁺ T cells isolated from Cyt c TCR transgenic mice were stimulated with Cyt c peptide and APCs, in the presence of medium, IL-6 (100 ng/ml), or IL-4, (10³ U/ml). After 4 d, cells were exhaustively washed and restimulated (10⁶ cell/ml) with Cyt c peptide and APCs for 24 h. (D) Total CD4⁺ T cells from normal B10.BR mice were stimulated with immobilized anti– CD3 mAb (5 µg/ml) and soluble anti–CD28 (1 µg/ml) in the presence of medium (–), IL-6 (100 ng/ml), or IL-4 (10³ U/ml) and, after 4 d, they were restimulated with immobilized anti–CD3 mAb. (E) Total CD4⁺ T cells from normal B10.BR mice were stimulated with Con A and APCs in the presence of medium (–), IL-6 (100 ng/ml) (IL-6), or IL-6 (100 ng/ml) plus anti–IL-4 mAb (10 µg/ml) (IL-6 + anti–IL-4), for 4 d. Cells were then restimulated (10⁶ cells/ml) with Con A alone as described in A.

Other cytokines have also been described to indirectly modulatethe polarization towards Th1 and Th2. IL-10, a Th2 cytokine,promotes Th2 and inhibits Th1 cells, their cytokines, and relatedimmune phenomena. Although the mechanism is not clear yet,several lines of evidence indicate that IL-10 reduces the Th1response by an inhibitory effect on the IL-12 expression byAPCs such as macrophages (22–24). In contrast, the immunoregulatoryrole of IL-6 in the polarization of Th1 and Th2 is not an indirecteffect on the APCs. Thus, IL-6 inhibited IFN- ${gamma}$ production and stimulated IL-4 synthesis by Th1 cells that have been differentiatedin the presence of exogenous IL-12 (Fig. 1, A and B), eliminatingthe possibility of inhibiting the production of IL-12 by APCs.In addition, IL-6 did not affect the expression on the APCsof co-stimulatory molecules such as B7.1 and B7.1, which havealso been involved in the differentiation of Th1 and Th2 cells(5, 6; data not shown). To further prove that the effect ofIL-6 was on T cells directly, rather than APCs, we differentiatedCD4⁺ T cells with immobilized anti-CD3 mAb plus anti-CD28 mAbin the complete absence of APCs, and then restimulated these cells with anti-CD3 mAb alone. The presence of IL-6 (or IL-4as a control) during the first culture resulted in an increaseof IL-4 production and a dramatic reduction of IFN- ${gamma}$ production(Fig. 1 D) by the cells that were elicited, showing that IL-6directly favors the polarization of naive CD4⁺ T cells to Th2cells via the T cell.

IL-4 is the most effective differentiation factor for Th2 cells;it acts by promoting the secretion of more IL-4 and inhibitingthe production of IFN- ${gamma}$ by T cells (9, 10). It was thereforepossible that IL-6 could directly upregulate the synthesisof IL-4 by T cells and, consequently, that the IL-6 effectwas mediated through IL-4, which would be responsible for thesuppression of Th1 differentiation, while favoring a Th2 response.To address this hypothesis, CD4⁺ T cells were differentiatedwith Con A and IL-6 in the presence or absence of neutralizinganti–IL-4 mAb, and after 4 d, the cells were washed andrestimulated with Con A. The ability of IL-6 to polarize CD4⁺T cells toward the Th2 phenotype was blocked by anti–IL-4mAbs, since the cells were unable to produce IL-4 upon restimulation(Fig. 1 E). These results indicated that the differentiationof Th2 cells by IL-6 is dependent on the endogenous production of IL-4. It was therefore possible that IL-6 may trigger the Th2 pathway by inducing small amounts of IL-4, which in turnwould act as an autocrine differentiation factor for the Th2cells.

As mentioned above, APCs represent the major source of IL-6early in the immune response. To examine the physiologicalrole of IL-6 in T cell differentiation, we first measured theproduction of IL-6 during the differentiation of Th1 and Th2cells. CD4⁺ T cells were stimulated with Con A and IL-4 orIL-12 in the presence of APCs, and supernatants were harvestedafter different periods of time to measure IL-6 secretion.After 2 d of culture, identical levels of IL-6 were detectedin the IL-4 and IL-12 cultures (Fig. 2 A). However, while theIL-6 level in the presence of IL-12 was sustained during thecourse of T cell differentiation, it decayed dramatically duringthe differentiation of Th2 cells in the presence of IL-4. NoIL-6 was detected after restimulation of either Th1 or Th2 cellswith Con A in the absence of APCs (data not shown), suggestingthat the IL-6 that we detected during the first stimulationwas secreted mainly by the APCs. The difference in the kinetics of IL-6 synthesis during the differentiation of Th1 and Th2 could, therefore, be due either to upregulation of IL-6 on the APCs in the presence of IL-12, or greater IL-6 consumptionby Th2 cells than by Th1 cells. To test this, we examined IL-6production during the differentiation of Th1 and Th2 in thepresence of an anti–IL-6 receptor (IL-6R) mAb, to blockIL-6 consumption. In the presence of anti– IL-6R mAb IL-6did not diminish during the differentiation of Th2 cells (Fig.2 B). These data indicate that the IL-6 produced by APCs wasconsumed during the differentiation of Th2 cells, but not duringdifferentiation of Th1 cells, supporting the idea that IL-6plays a role during Th2 polarization by acting directly onT cells. IL-6R is a heterodimer of the signal transducer gp130(which is also a component of the IL-11, ciliary neurotrophicfactor, leukemia inhibitory factor, and onconstatin M receptors)and the specific IL-6R ${alpha}$ chain (25–30). IL-6R has beenfound in both unstimulated CD4⁺ and CD8⁺ T cell subsets andits expression is downregulated upon activation (31). Differentialexpression of the IL-6R ${alpha}$ chain during Th1 or Th2 differentiationcould explain the higher IL-6 consumption by the Th2 cells.We also analyzed, therefore, the expression of IL-6R ${alpha}$ duringthe differentiation of CD4⁺ T cells in effector Th1 or Th2cells. However, the expression of cell surface IL-6R ${alpha}$ was regulatedsimilarly during the differentiation of Th1 or Th2 cells inthe presence of either IL-4 or -12 (Fig. 2 C). Low levels ofIL-6R ${alpha}$ were present on unstimulated CD4⁺ T cells, and downmodulationoccurred after the first day of stimulation, remaining at almost undetectable levels during the differentiation of both Th1 and Th2 cells. These results indicated that the effects ofIL-6 in the differentiation of Th2 cells were not due to adifferential distribution of the IL-6R ${alpha}$ .

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Figure 2 Regulation of IL-6 secretion by APCs during the differentiation of Th1 and Th2 CD4⁺ T cells. (A) Total CD4⁺ T cells (B10.BR) were stimulated with Con A (2.5 µg/ml) plus IL-4 (10³ U/ml) or IL-12 (3.5 ng/ml) in the presence of APCs. Supernatants were harvested at different times of stimulation (day 2, 3, or 4) and IL-6 secretion was analyzed. (B) Total CD4⁺ T cells were stimulated as described in A, but in the presence of anti–IL-6R ${alpha}$ chain mAb (10 µg/ml). The arrow indicates the production of IL-6 after 4 d of stimulation with Con A and IL-4, in the absence of anti–IL6R ${alpha}$ mAb. (C) Expression of IL6R ${alpha}$ during the differentiation of Th1 and Th2 cells. CD4⁺ T cells unstimulated (day 0) or stimulated in the presence of APCs, with Con A plus IL-4 (Con A/IL-4) or IL-12 (Con A/ IL-12) for different periods of time (day 1, 2, or 4) were harvested, stained with anti-CD4 and anti–IL-6R ${alpha}$ mAbs, and analyzed by FACS^®. Fluorescence profiles show the expression of IL-6R ${alpha}$ in the CD4⁺ population.

If IL-6 was required for Th2 cell differentiation in vitro, it would follow that T cells from IL-6^–/– miceshould be incapable of developing Th2 effector cells. The experimentsdescribed below show that this appears to be true. In correlationwith the previous characterization of IL-6^–/– mice(32, 33), analysis of cellular populations in the spleen andthymus did not show any differences between wildtype (WT) andIL-6^–/– mice (data not shown), and IL-6^–/– mice developed normally. We therefore used splenocytes fromIL-6^–/– mice as APCs to further establish that the production of endogenous IL-6 by the APC plays a critical role in the polarization of the CD4⁺ T cells to effector Th2 cells. We purified CD4⁺ T cells from WT mice and stimulatedthem for 4 d with Con A in the presence of APCs from WT miceor IL-6^–/– mice in the absence of any added exogenouscytokines. Restimulation with Con A resulted in significantlyless IL-4 production in cells differentiated in the presenceof IL-6^–/– than in WT APCs (Fig. 3 A). Althoughthe production of IFN- ${gamma}$ under these conditions (absence of exogenousIL-12) was low, the levels of IFN- ${gamma}$ produced by CD4 cells differentiatedin the presence of IL-6^–/– APCs were higher thanthose produced by cells stimulated in the presence of WT APCs(data not shown).

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Figure 3 IL-6–producing APCs are required for the differentiation of Th2 cells. (A) Total CD4⁺ T cells (10⁶/ml) were isolated from WT mice and stimulated with Con A (2.5 µg/ml) alone in the presence of APCs (5 x 10⁵ cells/ml) from WT (WT APC) or IL-6–deficient (IL-6^–^/– APC) mice. After 4 d, CD4⁺ T cells were washed and restimulated (10⁶ cells/ml) with Con A in the absence of APCs, and supernatants were collected after 24 h. (B) Total CD4⁺ T cells were isolated from IL-6–deficient (IL-6^–^/–) mice and stimulated with Con A plus medium (–), neutralizing anti–IL-6 mAb (10 µg/ml) (anti–IL-6), IL-6 (100 ng/ml), IL-4 (10³ U/ml), or both (IL-4 + IL-6), in the presence of APCs from WT (WT APC) or IL-6– deficient (IL-6^–^/–) mice. After 4 d, cells were washed and restimulated (10⁶ cells/ml) with Con A alone for 24 h. Only in the case where all cells (both CD4 T cells and APCs) were from IL-6^–/– mice did we observe a slightly lower recovery (70–80% of the recovery from other conditions) after 4 d of primary culture. Nevertheless, cell number was normalized (10⁶ cells/ml) before restimulation. (C) Induction of IL-4 gene expression in CD4⁺ Th2 cells differentiated in the presence of IL-6. Naive CD4⁺ T cells (12) from Cyt c TCR transgenic mice were primary cultured with moth Cyt c peptide (5 µg/ml) and APCs in the absence (–) or the presence of IL-6 (100 ng/ml) or IL-4 (10³ U/ml) for 4 d. Cells were then washed and stimulated with Cyt c peptide and APCs. After 20 h, 2 x 10⁵ cells were harvested and used for the quantitation of IL-4 mRNA by competitive RT-PCR. (Top) The expression of IL-4 transcripts. (Bottom) The expression of DR transcripts. Small arrow, the competitor DNA.

In vivo experiments have showed an impaired immune responsein IL-6^–/– mice. These mice fail to control infectionwith Listeria monocytogenes and have a diminished T cell–dependent body response against vesicular stomatitis virus (32–34). In addition, CD4⁺ cells from WT mice infected with Candida albicans express IL-4, but reduced IgE and IL-4 mRNA was observed in IL-6^–/– mice (35). Nevertheless, due to the numerous effects of IL-6 in vivo, it is difficultto study by which mechanism IL-6 affects the immunopathologyof infection and whether this is mediated by a modificationin T cell differentiation. We examined, therefore, the in vitrodifferentiation of CD4⁺ T cells from IL-6–deficient mice.IL-6^–/– CD4⁺ T cells stimulated with Con A in thepresence of WT APCs, which can provide the IL-6 required, producedIL-4, but this IL-4 production was impaired when the IL-6 pathwaywas blocked by the addition of anti–IL-6 mAbs (Fig. 3B). Most significantly, however, was that in the complete absenceof IL-6, when IL-6^–/– CD4⁺ T cells were stimulatedin the presence of IL-6^–/– APCs, no in vitro Th2response was obtained (Fig. 3 B). The difference between completeabsence of IL-4 production when IL-6^–/– APCs wereused with IL-6^–/– T cells compared with IL-6^–/–APCs and WT T cells may have been the result of either IL-6production from contaminating WT APCs in the T cells or a contributionof IL-6 from the WT T cells. Moreover, high IL-4 productionwas restored in cells that were differentiated in the presenceof IL-6^–/– APCs together with an exogenous sourceof IL-6 (Fig. 3 B). Similar levels of IL-4 were detected when CD4⁺ T cells were differentiated in the presence of IL-4, and no significant additional increase was observed when bothIL-4 and IL-6 were present during the differentiation, indicatingagain that both IL-4 and IL-6 were using the same pathway.

To demonstrate whether the upregulation of IL-4 production byIL-6 was due to an induction of IL-4 gene expression ratherthan a posttranslational mechanism, e.g., increasing IL-4 secretion,we examined the levels of IL-4 mRNA. Naive CD4⁺ T cells wereisolated from Cyt c TCR transgenic mice (see above) and stimulatedwith specific Cyt c peptide in the absence or presence of IL-6or IL-4. After 4 d, cells were washed and restimulated with Cyt c peptide, and total RNA was isolated 20 h later. The expression of the IL-4 gene was determined by competitive RT-PCRof IL-4–specific transcripts (18). The presence of exogenousIL-6 or IL-4 during the differentiation (Th2 cells) resultedin the induction of high levels of IL-4 mRNA upon antigen restimulation(Fig. 3 C). Quantitation of IL-4 transcripts in cells differentiatedin the presence of IL-6 or IL-4 were 100-fold higher than inthe absence of cytokines (data not shown). Together, thesedata indicate that IL-6 causes the differentiation of Th2 cellsby upregulating IL-4 gene expression. The transcriptional regulation of the IL-4 gene has not yet been characterized as extensivelyas the regulation of the IL-2 gene. Several positive and negativeregulatory elements in the 5' flanking region of the IL-4 genehave been described (36–39). Among five different nuclearfactor of activated T cells (NFAT) binding elements, one locatedbetween –90 and –60 is important for the activationof the IL-4 gene expression. Like the distal NFAT site in theIL-2 promoter (40–42), this element binds NFAT (eitherNFATp or NFATc) in association with AP-1 components (37, 43).In addition, recently three functional binding sites for theC/EBP family of transcriptional factors have been identifiedin the IL-4 promoter (44), which might be regulated by IL-6since members of this family (NF-IL6) have already been describedas having been activated by IL-6 in other systems (45–50).Whether IL-6 acts through these sites will be the subject offuture studies.

Both in vivo and in vitro experiments support the idea that,although other factors can play immunomodulatory roles, IL-4and IL-12 are both necessary and sufficient for the polarizationof Th1 and Th2 during the response to different pathogens. Considerableinterest in the initial source of the IL-4 that drives Th2cell differentiation has been expressed and recent attentionhas focused on mast cells or NK1.1⁺ CD4 T cells. We proposehere that IL-6 is one of the stimuli in the initial productionof IL-4 which provides a new mechanism to initiate Th2 CD4⁺T cell differentiation. The levels of IL-6 that we used in theseexperiments are relatively high, just as the levels of IL-4that also must be used to direct Th2 differentiation in vitroare (500– 1,000 U/ml IL-4). Presumably, for both IL-4and IL-6 produced endogenously, lower levels produced in alocal microenvironment suffice. Consistent with this idea,although the IL-6 effect is mediated through IL-4 (since itis blocked by anti–IL-4), the levels of IL-4 that canbe detected are very low, presumably because of local consumption,but are sufficient to direct Th2 cell differentiation. Ourdata suggest a model (Fig. 4) for Th2 differentiation thatis strikingly similar to the mechanism used for Th1 differentiation.In both cases, the source of the polarizing cytokine is theAPC, IL-12 in the case of Th1 cells and IL-6 in the case ofTh2 cells. Although APCs are the major source of IL-6 in vitro,other cell types that produce IL-6, such as fibroblasts, endothelialcells, keratinocytes or others, could also contribute to theoverall in vivo IL-6 production. In our in vitro model, activationof the APC is proposed to result in the secretion of IL-6 which,in combination with the antigen, will participate in the inductionof IL-4 gene expression in naive CD4⁺ T cells. In the second step, the low levels of IL-4 secreted by the T cells is sufficientto induce upregulation of the IL-4 and IL-4 receptor genesin an autocrine manner, while it inhibits the expression ofthe IFN- ${gamma}$ gene. Cells are therefore subsequently polarized toa Th2 phenotype using their own source of IL-4.

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Figure 4 Schematic model for the differentiation of precursors Th cells (pTh) into effector Th1 and Th2 cells.

	Acknowledgments

We thank S. Samanta for technical assistance and F. Manzo forassistance with manuscript preparation. We also thank GeneticsInstitute for providing the IL-12 and DNAX Institute for a giftof IL-4.

Submitted: 30 October 1996
Revised: 21 November 1996

This work was supported by National Institutes of Health grantsCA65861 and 1-P01-AI30548. R.A. Flavell is an investigatorand T. Nakamura was an associate of the Howard Hughes MedicalInstitute. E. Fikrig is a Pew Scholar.

¹ Abbreviations used in this paper: Cyt, cytochrome; NFAT, nuclearfactor of activated T cells; RT, reverse transcriptase; WT,wild type.

References

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Abstract
Materials and Methods
Results and Discussion
References

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