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Ability of Mature Dendritic Cells to Interact with Regulatory T Cells Is Imprinted during Maturation

Departments of ¹ Surgery, ² Infectious Diseases and Microbiology, and ³ Immunology, University of Pittsburgh; ⁴ University of Pittsburgh Cancer Institute, Pittsburgh, Pennsylvania

Requests for reprints: Pawel Kalinski, Department of Surgery, University of Pittsburgh, Hillman Cancer Center, UPCI Research Pavilion, Room 1.46b, 5117 Center Avenue, Pittsburgh, PA 15213-1863. Phone: 412-623-7712; Fax: 412-623-7713; E-mail: kalinskip{at}upmc.edu.

	Abstract

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Preferential activation of regulatory T (Treg) cells limits autoimmune tissue damage during chronic immune responses but can also facilitate tumor growth. Here, we show that tissue-produced inflammatory mediators prime maturing dendritic cells (DC) for the differential ability of attracting anti-inflammatory Treg cells. Our data show that prostaglandin E₂ (PGE₂), a factor overproduced in chronic inflammation and cancer, induces stable Treg-attracting properties in maturing DC, mediated by CCL22. The elevated production of CCL22 by PGE₂-matured DC persists after the removal of PGE₂ and is further elevated after secondary stimulation of DC in a neutral environment. This PGE₂-induced overproduction of CCL22 and the resulting attraction of FOXP3⁺ Tregs are counteracted by IFN, a mediator of acute inflammation, which also restores the ability of the PGE₂-exposed DC to secrete the Th1-attracting chemokines: CXCL9, CXCL10, CXCL11, and CCL5. In accordance with these observations, different DCs clinically used as cancer vaccines show different Treg-recruiting abilities, with PGE₂-matured DC, but not type 1–polarized DC, generated in the presence of type I and type II IFNs, showing high Treg-attracting activity. The current data, showing that the ability of mature DC to interact with Treg cells is predetermined at the stage of DC maturation, pave the way to preferentially target the regulatory versus proinflammatory T cells in autoimmunity and transplantation, as opposed to intracellular infections and cancer. [Cancer Res 2008;68(14):5972–8]

	Introduction

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Type 1 immune responses, dominated by the activation of type 1 effector T cells (Teff; CTLs and Th1) and natural killer (NK) cells, are critical for the elimination of intracellular pathogens and tumor cells but can lead to autoimmune tissue damage. The magnitude, duration, and eventual outcome of type 1 responses are decided by the balance between immune effector cells and regulatory T (Treg) cells, characterized by the CD4⁺CD25^high surface phenotype and the intracellular expression of FOXP3⁺ (1, 2). In accordance with the observations of immune dysfunction associated with advanced cancer, the numbers of FOXP3⁺ T cells are elevated in blood and affected tissues of cancer patients. Two mechanisms have been proposed to be responsible for this phenomenon: the preferential recruitment of Treg cells to tumor sites, mediated by the chemokines CCL22 (MDC/STCP-1) and CXCL12 (SDF-1), the respective ligands for the Treg-expressed chemokine receptors CCR4 and CXCR4 (3–8), and enhanced Treg induction (9–11).

Dendritic cells (DC) are the major type of antigen-presenting cells involved in the induction of immune responses and the regulation of its character (12–14). The high potency of mature DC in activating and reverting anergy of T cells has led to the application of ex vivo–generated DC as cancer vaccines (12, 13). The current cancer vaccines involving DC matured in the presence of the prostaglandin E₂ (PGE₂)-containing cytokine cocktail or macrophage-conditioned medium have proved to be highly effective in inducing circulating tumor-specific T cells in the blood of cancer patients (15–18), but their effectiveness in inducing clinical responses is still below expectations (19). Although this discrepancy is likely to result from multiple factors, the recently reported expansion of FOXP3⁺ Treg cells in the patients receiving such vaccines (20) represents one undesirable aspect of vaccination.

To develop a means of limiting the ability of DC-based vaccines to interact with Treg cells and to test if the ability of DC to interact with the different T-cell subsets can be imprinted by the conditions of DC maturation, we evaluated the mechanism of Treg attraction to human monocyte-derived DCs and analyzed the effect of different inflammatory mediators on the subsequent ability of mature DC to attract FOXP3⁺ Treg cells. We compared the effect of PGE₂, a factor prevalent in chronic inflammation and cancer (21) and previously implicated in the CCL22-mediated attraction of Th2 cells (22–24), and IFN, a mediator of acute inflammation (25) involved in the induction of Th1-attracting CXCR3 ligands (26–28).

Our data show that CCL22, but not other chemokines similarly implicated in Treg attraction to different tissues, constitutes the key DC-produced Treg-attracting chemokine. We report that the elevated Treg-promoting activity of DCs is a stable feature of the DCs that have matured in the presence of PGE₂, but it can be antagonized by the presence of IFN during DC maturation. The current observations that distinct chemokine profiles are imprinted in DCs during their maturation and are preserved in mature DCs after their removal from different inflammatory environments help to design vaccines that preferentially target the functionally different T-cell subsets.

	Materials and Methods

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Media and reagents. Serum-free CellGenix DC medium (CellGenix, Inc.) was used to generate DC. The following factors were used to generate mature DC: recombinant human (rhu) granulocyte macrophage colony-stimulating factor (GM-CSF) and interleukin (IL)-4 (gifts from Schering-Plough); IFN (Intron A, IFN-2b, Schering-Plough); rhuTNF, rhuIL-1β, and rhuIFN (Strathmann Biotech); rhuIL-6 (Genzyme); and PGE₂ and polyinosinic acid:poly-CMP (polyI:C; both from Sigma). CD40L-transfected J558 cells (gift from Dr. P. Lane, University of Birmingham, Birmingham, United Kingdom) were used as an equivalent to activated CD4⁺ T cells (29). All recombinant chemokines used in this study and all chemokine-specific primary and biotinylated secondary antibodies used in ELISA assays were purchased from PeproTech.

DC culture. Peripheral blood mononuclear cells obtained from healthy donors were isolated with lymphocyte separation medium (Cellgro, Mediatech). Monocytes were isolated on density gradients using Percoll (Sigma) or Isolate (Irving Scientific) followed by plastic adherence, resulting in purity of >90% (see refs. 36, 39). Monocytes were cultured for 6 d in 24-well plates (Falcon, Becton Dickinson Labware) at 5 x 10⁵ cells per well in rhuGM-CSF and IL-4 (both 1,000 IU/mL). On day 6, DC maturation (48 h) was induced using the indicated combinations of the following factors: IL-1β (25 ng/mL), TNF (50 ng/mL), IFN (1,000 units/mL), IL-6 (1,000 units/mL), PGE₂ (10^–6 mol/L), polyI:C (20 µg/mL), and IFN (3,000 units/mL). When indicated, DCs were harvested and seeded at density of 5 x 10⁴ in 500 µL with or without J558 cells in CellGenix medium without any additional factors for the following 24 h. The supernatants were filtered (0.22 µm) before their use in migration experiments.

Isolation of CD4⁺ T cells. Mononuclear cells from peripheral blood of healthy donors were isolated by density gradient separation using Lymphocyte Separation Medium (Cellgro, Mediatech). CD4⁺ T cells were isolated by negative magnetic selection using the EasySep Human CD4 T Cell Enrichment kit (StemCell Technologies, Inc.) according to the manufacturer's protocol.

Analysis of chemokine production by Taqman and ELISA. Based on preliminary kinetic experiments, we determined 6 h to be the optimum time to measure mRNA expression for IFN-inducible chemokines and 48 h to be the optimum for PGE₂-inducible chemokines. ELISA analysis of protein secretion by DC for all the chemokines was performed at 48 h, unless specifically indicated.

For the Taqman analysis, total RNA was extracted using Qiagen RNeasy kit according to the manufacturer's protocol. cDNA synthesis was performed on 2 µg of extracted RNA in 20 µL reaction volume using Retroscript kit (Ambion) according to the manufacturer's protocol. Real-time analysis was performed on 25 ng of sample cDNA using premade Taqman primers and probes (see Supplementary Table S1), either from GenScript or Applied Biosystems, in 25 µL reaction volume using Universal Taqman kit with UNG (Applied Biosystems) following the manufacturer's protocol. Samples were analyzed with an ABI Prism 7700 sequence analyzer (Applied Biosystems). The expression of each gene was normalized to HPRT1 and expressed as fold increase (2^–CT), where C_T= [C_{T (Target gene)}] – [C_{T (HPRT1)}].

Supernatants of DC cultures were analyzed for CCL5, CCL22, CXCL9, and CXCL10 proteins by indirect sandwich ELISA. Briefly, ELISA plates (Corning, Inc.) were coated overnight at room temperature with 100 µL of primary antibody at 10 µg/mL followed by washing and blocking with PBS + 4% bovine serum albumin (BSA) for 1 h. Samples (50 µL) were added to the wells and incubated for 1 h and subsequently washed and incubated with 50 µL of biotinylated secondary antibodies at 2.5 µg/mL for 1 h. The plates were washed and incubated for 30 min with streptavidin-horseradish peroxidase conjugate (Pierce Biotechnology, Inc.) and diluted 1:8,000 in wash buffer (50 mmol/L Tris, 0.2% Tween). The plates were washed and detected with 50 µL of 3,3',5,5'-tetramethylbenzidine substrate (Pierce Biotechnology). Reactions were stopped with 2% H₂SO₄ and absorbance at 450 nm was measured.

Chemotaxis. Chemotaxis assays were performed in 96-(Trans)well plates with a 3-µm-pore-size polycarbonate filter (Corning). The lower chamber was filled with 200 µL of rhuCCL22 (100 ng/mL) or CXCL10 (1,000 ng/mL) and CXCL11 (1,000 ng/mL) in RPMI 1640 with 0.5% BSA (chemotaxis medium) or DC culture supernatant and 50 µL (2.0 x 10⁵ cells) of purified CD4⁺ T cells were added to the upper chamber. When indicated, CD4⁺ T cells were treated for 30 min with anti-CCR4 antibody (1G1, 20 µg/mL; BD Biosciences) before chemotaxis to block the CCR4-dependent chemotaxis. Alternatively, CCL22 (200 ng/mL) was added to the upper chamber of the migration system to abrogate the CCL22 gradient and desensitize the CCR4 responsiveness. Migration chambers were incubated for 3 h at 37°C. Subsequently, cells from multiple wells were pooled and total RNA was extracted. The presence of Treg cells within the migrated cell population was analyzed by Taqman for the expression of FOXP3 or CTLA4 mRNA using the FOXP3-specific (Hs00203958_m1) and CTLA4-specific (Hs00175480_m1) expression Assay-on-Demand (Applied Biosystems) and expression was normalized to HPRT1. The FOXP3 protein expression was confirmed by flow cytometry using the FOXP3 staining kit (eBioscience). Photomicrographs of total (CD3⁺) T cells migrated in response to medium, DC1, or "standard" DC (sDC) supernatants were obtained using a Zeiss Axiovert200 inverted microscope with ZeissCAM.

Statistical analysis. All data were evaluated using Student's t test (two tailed), with P < 0.05 considered as significant.

	Results

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IFN and PGE₂ cross-regulate the chemokine production profiles of maturing DC. To develop a means to regulate the ability of DC to interact with Tregs (as opposed to Teff cells), we analyzed the production of the chemokines previously implicated in the attraction of Treg cells, CCL22 (3, 5) and CCL17 (as an alternative CCR4 ligand), CXCL12 (8), and CCL20 (4, 30), by the human monocyte-derived DC matured in different inflammatory conditions. As representatives of Teff-attracting chemokines, we analyzed the production of the known CXCR3 ligands (CXCL9, CXCL10, and CXCL11) and the production of CCL5, implicated in the attraction of type 1 immune cells (31–34). Because the CCL22-dependent attraction of Th2 cells can be enhanced by PGE₂ (22–24), we tested the effect of PGE₂ on production of the above Treg-attracting chemokines, contrasting it with IFN, as a representative mediator of acute inflammation.

Immature DC or DC matured in the presence of TNF expressed low levels of CCL22 but did not express any of the other known Treg-attracting chemokines (CCL17, CCL20, or CXCL12). In addition, TNF matured DC produced low levels of CCL5, but none of the CXCR3 ligands implicated in the attraction of Teff cells (Fig. 1A and B ). Analogous to TNF, exposure to PGE₂ alone failed to enhance the spontaneous levels of CCL22 expression. Strikingly, however, the combination of PGE₂ with TNF resulted in dramatic elevation of CCL22 gene expression (Fig. 1A) and the secretion of CCL22 protein (Fig. 1B). In accordance with previous reports (26–28), IFN strongly enhanced the production of CCL5 and all three CXCR3 ligands (CXCL9, CXCL10, and CXCL11; Fig. 1A).

View larger version (14K): [in this window] [in a new window] [Download PPT slide]   Figure 1. IFN and PGE2 cross-regulate the production of Teff- and Treg-attracting chemokines by DC. Day 6 monocyte-derived immature DCs were exposed to PGE2 and/or IFN either alone () or in the presence of TNF () as a DC maturation-inducing agent. A and B, dominant effect of IFN on the chemokine production profiles in maturing DC. A, expression of Treg-attracting (top) and Teff-attracting (bottom) chemokine genes in the differentially treated DC. *, the data are expressed as the ratios between the expression of the individual chemokine genes and HPRT1 (see Materials and Methods) and represent one of five experiments that all yielded similar results. B, secretion of CCL5, CXCL9, CXCL10, and CCL22 proteins by the differentially treated DC. PGE2-induced CCL22 production was significantly higher (P < 0.01) compared with the TNF treatment alone.

To determine if the low-level "spontaneous" CCL22 production by DC can be triggered by DC-produced endogenous PGE₂, DCs were treated with TNF in the presence or absence of indomethacin (an inhibitor of prostaglandin synthesis). In accordance with this possibility, indomethacin suppressed the spontaneous CCL22 production in TNF-matured DC (Fig. 2A ). The elimination of endogenous PGE₂ revealed the wide range of dose-dependent CCL22-inducing effect of exogenously added PGE₂ (Fig. 2B). The ability of PGE₂ to promote the CCL22 production by DC critically depended on the presence of TNF, as shown by the inability of PGE₂ to promote the CCL22 production in the absence of TNF and the dose dependence of the TNF effect (Fig. 2C). A similar synergistic activity of PGE₂ and TNF in inducing CCL22 production was also observed in the case of macrophages generated from monocytes in the presence of GM-CSF alone (Supplementary Fig. S1). This CCL22-enhancing effect of PGE₂ on the TNF-maturing DC was counteracted by IFN in a dose-dependent manner (Fig. 2D).

View larger version (10K): [in this window] [in a new window] [Download PPT slide]   Figure 2. Dose-dependent cross-regulation of CCL22 production by TNF, PGE2, and IFN. A, involvement of endogenous prostaglandins in the production of "baseline" levels of CCL22 by maturing DC. Please note the reduction (P < 0.05) of the baseline CCL22 production in the presence of prostaglandin synthesis inhibitor indomethacin (Indo; 50 µmol/L; added at the beginning of cultures). B, dose-dependent enhancement of CCL22 production in maturing DC by exogenous PGE2. Indomethacin (50 µmol/L) was present in all cultures to eliminate the endogenous PGE2 production. C, DCs were treated with 1 µmol/L PGE2 but with increasing doses of TNF to reveal TNF-dependent induction of CCL22 by PGE2. D, inhibition of CCL22 production by increasing doses of IFN in the TNF-treated (50 ng/mL) and PGE2-treated (1 µmol/L) DC. Data from one of two (C and D) or four (A and B) experiments that all yielded similar results.

Stability of the elevated CCL22 production by PGE₂-exposed DC. Consistent with the preferential activation of the Treg system at later stages of immune responses, the PGE₂-induced CCL22 secretion was undetectable until 24 h after DC stimulation but continued to accumulate throughout the following period (Fig. 3A ). Moreover, PGE₂-matured DC continued to produce high levels of CCL22 for 48 h after the removal of PGE₂ from the cultures (Fig. 3B). In contrast, the IFN-induced production of CXCL10 was evident within 6 h of DC activation (Fig. 3A), but its continued secondary secretion after the withdrawal of IFN required restimulation with CD40L (Fig. 3B), the interaction with CD40L-expressing CD4⁺ Th cells (data not shown), or additional Toll-like receptor–mediated activation during maturation (see below).

View larger version (14K): [in this window] [in a new window] [Download PPT slide]   Figure 3. The ability of DC to produce Teff- and Treg-attracting chemokines is imprinted during DC maturation. A, kinetics of CXCL10 and CCL22 protein secretion by DC maturing in the presence of IFN() or PGE2 (). TNF was added to both types of cultures. Figure represents combined data from two experiments that yielded similar results. The difference in CCL22 production between IFN-treated and PGE2-treated DC was significant at 24 h (P < 0.05) and 48 h (P < 0.01) of stimulation. B, stability of the maturation-induced chemokine profiles in DC matured with either IFN or PGE2 in the presence of TNF. Chemokine concentrations in the supernatants from the DC maturation cultures (top) and in the 48-h cultures of the DC harvested, washed, and replated in the absence (middle) or presence (bottom) of CD40L. In all three situations, the IFN- versus PGE2-treated DC showed significant differences in CCL22 production (P < 0.01, 0.05, and 0.01, respectively). *, below 0.05 ng/mL.

Preferential recruitment of FOXP3⁺ Treg cells by PGE₂-exposed DC: key role of CCL22. Because DC matured in the presence of PGE₂ or IFN had different abilities to produce the chemokines previously implicated in the preferential attraction of the regulatory versus Teff cells, we tested their ability to recruit FOXP3⁺ T cells, as opposed to other CD4⁺ T-cell subsets. Although the overall numbers of freshly isolated peripheral blood CD4⁺ T cells migrating in response to recombinant CCL22 were 2-fold lower compared with the migration to CXCL10 (or to CXCL11, used as an alternative CXCR3 ligand), the CCL22-responsive population of CD4⁺ T cells was enriched in FOXP3⁺ cells (and CTLA4⁺cells), as shown by Taqman analysis and intracellular staining (Fig. 4A ; Supplementary Figs. S2–S3), consistent with previous reports showing high activity of CCL22 in the recruitment of Treg cells (3, 5).

View larger version (10K): [in this window] [in a new window] [Download PPT slide]   Figure 4. PGE2 imprints a stable Treg-attracting function in maturing DC: key role of CCR4 in the ability of DC to attract FOXP3+ T cells. Purified CD4+ T cells were loaded into the upper chamber of the Transwells and allowed to migrate toward recombinant CCR4 or CXCR3 ligands or the supernatants of IFN- or PGE2-treated DC. The migrated CD4+ T cells from the bottom chambers were pooled (eight wells per group, with higher numbers needed for the intracellular staining experiments) and analyzed by Taqman for the presence of FOXP3+ cells. A, Taqman analysis of CD4+ T cells migrated in response to rhuCCL22 or to CXCL10 (see Supplementary Fig. S2 for the intracellular expression of FOXP3 protein in the individual CD4+ T cells). Similar data were obtained in two additional experiments. B, Taqman analysis of the CD4+ T cells migrated in response to the factors released during the TNF-driven maturation of DC exposed to IFN or PGE2. Insets, frequencies of FOXP3+ T cells in the CD4+ T-cell populations recruited by IFN- or PGE2-treated DC supernatants. Similar data were obtained in three additional experiments. C, CD4+ T cells migrating in response to the supernatants from harvested and reseeded DC after maturation. *, all mRNA data are normalized for HPRT1. **, the CD4+ T cells were pretreated with CCR4 blocking antibody before addition to the upper chambers of the chemotaxis plate. Similar data were obtained using excess CCL22 to abrogate the CCL22 gradient.

The recruitment of FOXP3⁺ cells was completely abrogated in the presence of CCR4 blocking antibody (Fig. 4C) or by the disruption of CCL22 gradient using excess CCL22 (data not shown). Because human DCs produce CCL22 but not an alternative CCR4 ligand, CCL17 (Fig. 1A), these data indicate that CCR4-CCL22 interaction, but not other chemokine systems similarly implicated in Treg attraction to different tissues (such as CXCL12-CXCR4 and CCL20-CCR6; refs. 3–8, 30), is responsible for the elevated ability of PGE₂-matured DC to attract FOXP3⁺ T cells.

Elevated Treg-attracting activity of the clinical-grade DC preparations generated in the presence of PGE₂. It has been recently shown that the vaccination of cancer patients with sDC matured in the presence of IL-1β, TNF, IL-6, and PGE₂ (35) can expand their FOXP3⁺ Treg cell population (20). In accordance with the possibility that PGE₂ used in the process of their generation may preferentially promote the interaction of the vaccine-carrying sDC with Tregs, we observed that sDCs showed high production of Treg-attracting CCL22 (rather than Teff-attracting chemokines; Fig. 5A and B ) and were highly effective in selectively attracting CD4⁺FOXP3⁺ T cells from freshly isolated bulk population of CD4⁺ T cells (Fig. 5C). In contrast, alternatively matured type 1–polarized DC (DC1) obtained in the presence of IL-1β, TNF, IFN, IFN, and polyI:C (36) showed strongly reduced production of CCL22 (Fig. 5A and B). Accordingly, although DC1s were more effective than sDCs in attracting high numbers of CD4⁺ T cells (Supplementary Fig. S2B), in contrast to sDCs, they did not preferentially recruit FOXP3⁺ T cells from the total population of CD4⁺ T cells (Fig. 5C, inset).

View larger version (13K): [in this window] [in a new window] [Download PPT slide]   Figure 5. Different clinically applied DC types display strong differences in the ability to attract FOXP3+ T cells. A, sDC () generated in the presence of IL-1β, TNF, IL6, and PGE2 (35) and DC1s () matured in the presence of IL-1β, TNF, IFN, IFN, and polyI:C (36) were tested for the expression of Teff- or Treg-attracting chemokine genes (left; also see Supplementary Fig. S5) and the secretion of the relevant chemokines (right; P < 0.05). Representative data from over 10 donors. B, stability of the chemokine production pattern in different types of clinically applied DC. Chemokine contents in the supernatants from DC maturation cultures (top) and in the 48-h cultures of the harvested, washed, and replated DC in the absence (middle) or presence (bottom) of CD40L. DC1 and sDC showed significant differences in CCL22 production in all stages tested (P < 0.01). *, below 0.05 ng/mL. Similar data were obtained in two to four additional experiments. C, Taqman analysis of freshly isolated purified CD4+ T cells (before migration) and of the CD4+ T cells migrated in response to medium (negative control, spontaneous migration only), DC1, or sDC supernatants. Data from one of five experiments that all yielded similar results. Inset, frequencies of FOXP3+ T cells in the CD4+ T-cell populations recruited by the supernatants from DC1s or sDCs were determined by flow cytometry.

	Discussion

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The current data indicate that the character of the inflammatory environment can affect the balance between Teff and Treg cell activation by instructing the maturing DC to adopt a stable propensity to interact with each of these T-cell types. Our results show that in analogy to the previously identified ability of maturing DC to memorize the conditions of their maturation and translate them into different ability to induce the functionally different T-cell responses (14, 36, 37), maturing DC can also be primed for preferential interaction with the functionally different T-cell subsets.

Although numerous chemokines, including CCL20, CCL22, and CXCL12, respectively, signaling via CCR20, CCR4, and CXCR4, are known to preferentially attract Treg to different tissues (refs. 3–8, 30 reviewed in ref. 38), our data show that the ability of human DC to attract FOXP3⁺ Treg cells is strictly CCR4 dependent (Fig. 4C), implicating the key role of CCL22, the only DC-produced CCR4 ligand (see Fig. 1A).

Furthermore, our data indicate that PGE₂, including the endogenously produced PGE₂ (Fig. 2A) and the PGE₂ produced by tumor tissues (Supplementary Fig. S4), is a potent inducer of the Treg-attracting propensity of human DCs. In contrast to this common mediator of chronic inflammation (21), IFN, a factor produced at the early stages of intracellular infections and known to promote the production of Teff-attracting chemokines (26–28), proved to be a potent antagonist of Treg-attracting DC function. Although similar CCL22-antagonistic function has been reported in the case of IFN (22), the factor produced by NK and T cells, the current data indicate that the suppression of Treg recruitment can be also driven by the factors released from directly infected stromal cells at the earliest stages of acute infection, facilitating the early induction of the pathogen-specific immunity.

Interestingly, the IFN-induced production of CXCL10 (and other CXCR3 ligands; data not shown) was evident within 6 h of DC activation and was terminated following the elimination of the IFN signal. In contrast, CCL22 induction occurred with substantial delay and was produced at high concentrations over prolonged period of time. This particular kinetics of the PGE₂-induced production of CCL22 and the resulting Treg attraction is consistent with the role of PGE₂ in preserving tissue homeostasis and limiting the duration of the inflammatory type responses.

The ability of PGE₂ to prime DC for elevated attraction of Treg cells adds to the previously postulated ability of this agent to promote the de novo induction of Treg cells (9–11), as well as to its previously defined ability to suppress the functions of Th1-type cells (39–42), and to promote the recruitment of Th2 cells (22–24). Although the ability of PGE₂ to promote the attraction of Tregs is likely to be advantageous in limiting the duration of physiologic immune responses and the associated tissue damage, it is also likely to contribute to the limited effectiveness of responses against PGE₂-overproducing cancers (43–46), able to imprint high CCL22-producing function in DC (Supplementary Fig. S4).

Importantly, the PGE₂-induced Treg-attracting phenotype persisted in DC even after the removal of PGE₂, with the second wave of the CCL22 production being further elevated after the secondary stimulation of the PGE₂-exposed DC with CD40L. Similarly, the elevated production of CXCL10 by IFN-matured DC could also be observed following CD40L-mediated restimulation of DCs in the absence of IFN. This ability of DC to memorize the conditions of their maturation, reflecting them in their subsequent chemokine production, is likely to have implications for the therapeutic use of DC to preferentially activate different T-cell subsets. Although PGE₂-matured DCs have been shown to expand the numbers of FOXP3⁺ Treg cells in cancer patients (20), it remains to be seen whether such undesirable effects can be reduced in the clinical trials involving DC1s or other DC types obtained in the absence of PGE₂.

In summary, the current data show that the inflammatory factors present during DC maturation imprint the differential ability of mature DC to interact with distinct T-cell subsets. Our data help to explain the hyperactivation of the Treg system in the setting of chronic infections and cancer and facilitate the design of the immunotherapies aimed at the selective activation of the inflammatory versus regulatory type of immune cells.

	Disclosure of Potential Conflicts of Interest

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No potential conflicts of interest were disclosed.

	Acknowledgments

 
Grant support: NIH grants CA095128, CA114931, CA101944, and EA055944 (P. Kalinski) and the institutional funds in support of CA137214.

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

We thank Dr. Eva Wieckowski, Mary Jo Buffo, and Seth Shaltes for their assistance with intracellular staining and flow cytometry; Erik Berk for providing monocytes; and Robbie Mailliard for technical advice.

	Footnotes

 
Note: Supplementary data for this article are available at Cancer Research Online (http://cancerres.aacrjournals.org/).

Received 12/27/07. Revised 4/28/08. Accepted 5/ 2/08.

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