Abstract
Myeloid-derived suppressive cells (MDSC) have been reported to promote metastasis, but the loss of cancer-induced B cells/B regulatory cells (tBreg) can block metastasis despite MDSC expansion in cancer. Here, using multiple murine tumor models and human MDSC, we show that MDSC populations that expand in cancer have only partially primed regulatory function and limited prometastatic activity unless they are fully educated by tBregs. Cancer-induced tBregs directly activate the regulatory function of both the monocyte and granulocyte subpopulations of MDSC, relying, in part, on TgfβR1/TgfβR2 signaling. MDSC fully educated in this manner exhibit an increased production of reactive oxygen species and NO and more efficiently suppress CD4+ and CD8+ T cells, thereby promoting tumor growth and metastasis. Thus, loss of tBregs or TgfβR deficiency in MDSC is sufficient to disable their suppressive function and to block metastasis. Overall, our data indicate that cancer-induced B cells/B regulatory cells are important regulators of the immunosuppressive and prometastatic functions of MDSC. Cancer Res; 75(17); 3456–65. ©2015 AACR.
Introduction
The success of metastasis often depends on the ability of disseminating cancer cells to escape immune attack by using the help of regulatory immune cells, a heterogeneous group of specialized cells of granulocytic, myeloid, and lymphoid origins with seemingly redundant functions (1). Among these, myeloid-derived suppressive cells (MDSC) are thought to be key inhibitors of antitumor effector cells and, as such, an independent prognostic factor of patient survival (2). As a group of immature cells poised to differentiate into granulocytes, dendritic cells, and macrophages, MDSC are subdivided into PMN-MDSC and Mo-MDSC cells (1, 3) on the basis of expression of Ly6G+Ly6CInt/Low CD11b+ and Ly6CHighLy6G− CD11b+ in mice (4, 5) and CD14−CD11b+ CD15+CD33+ and CD14+CD11b+HLA-DRLow/− in humans (2, 6, 7), respectively. By producing granulocyte macrophage colony-stimulating factor (GM-CSF), VEGF, TGFβ, IL-6, IL10, IL13, and PGE4, cancer not only drastically expands MDSC but also evokes their regulatory function (for reviews, see refs. 1, 8, 9) by inducing their production of reactive nitrogen and oxygen species (NO, ROS, H2O2, and peroxinitrite) through the IL4–Stat6-dependent expression of arginase 1 (Arg-1; ref. 10) and Stat1- and Stat3-induced expression of nitric oxide synthase (iNOS) and NADPH oxidase (NOX2; refs. 11, 12). The expansion of MDSC is often used as a criterion of increased tumor burden and metastasis (1, 13). However, using tumor models where MDSC were reported to be essential, we failed to detect the primary importance of MDSC in cancer metastasis. The loss of regulatory T cells (Treg) or B cells was sufficient to almost completely block the metastasis of the highly aggressive 4T1 cancer in BALB/c mice, a human model of triple-negative breast cancer (14), and retard the growth of B16 melanoma in C57BL/6 mice (15–18). In the 4T1 model, cancer produces 5-lipoxygenase metabolites to convert B cells into a new subset of regulatory B cells, termed tumor-evoked regulatory B cells (tBreg; refs. 17, 19), that induce FoxP3+ Tregs to inactivate the antimetastatic natural killer (NK) and CD8+ T cells (15, 17, 19).
Here, using two different murine models and experimenting with human ex vivo–generated MDSC, we report that cancer only expands MDSC with partially activated regulatory function. As a result, the MDSC cannot support metastasis or promote tumor growth. We show that cancer uses B cells to evoke their full regulatory and thereby prometastatic function. Our modeling studies using specific TgfβR1 inhibitor and mice with TgfβR2 deficiency in myeloid cells suggest that cancer-induced B cells/tBregs evoke the full regulatory activity in MDSC via using, at least in part, the TgfβR1/TgfβR2 signaling axis. These results further underscore B cells/tBregs as key tumor messengers and initiators of the chain of suppressive events needed for metastasis.
Materials and Methods
Reagents, cells, and mice
TGFβRI (ALK5) inhibitor (SB431542) was purchased from Tocris Bioscience and catalase (1,000 U/mL) from Sigma Aldrich. l-NMMA and nor-NOHA (0.5 mmol/L) were from Cayman Chemical. Nitrate and NO were detected with the Griess Reagent Kit and DAF-FM diacetate, respectively, and ROS was detected with 1 μmol/L DHE (dihydroethidium) or DCFDA (2′,7′-dichlorodihydrofluorescein diacetate) and was from Molecular Probes and used as described elsewhere (5). α-TGFβ neutralizing antibody (clone 1D11.16.8), α-mouse Gr1 (clone RB6-8C5), mouse IgG, and rat IgG2b were purchased from BioXcell.
The following flow cytometric antibodies and their isotype controls (from Biolegend and eBioscience, except otherwise specified) were used: CD11b APC or FITC (M1/70), Gr1 PE or FITC (RB6-8C5), Ly6G Alexa Fluor700 or PerCP Cy 5.5 (1A8), Ly6C Pacific blue or FITC (HK1.4), IL4Rα PE (I015F8), F4/80 PerCP Cy5.5 or APC (BM8), CD40 PE Cy7 (3/23), CD115 PE (AFS98), CD80 brilliant violet 421 (16-10A1), CD83 brilliant violet 650 (Michel-19), GrB FITC (GB11), and IFNγ PE-Cy7 (XMG1.2). TgfβR antibodies were from R&D (TgfβR1, clone FAB5871A and TgfβR2, clone FAB532F).
For intracellular staining of phosphorylated Stat proteins, cells were fixed with 2% paraformaldehyde in PBS for 10 minutes at 37°C and resuspended in prechilled 90% methanol (in water). The cells were stained with anti-mouse CD11b Fitc, Ly6G PE-Cy7, Ly6C Pacific blue (Biolegend), and rabbit anti-mouse pStat1 or pStat3-Alexa Fluor 647 (Tyr705, Cell Signaling) at 1:200 dilution. For lineage-negative MDSC sorting, phycoerythrin (PE)-conjugated CD19 (clone 6D5), CD3 (clone 145-2C11), B220 (clone RA3-6B2), and CD49b (DX5) antibodies were used. Human sorting was performed using CD11b PE (clones M1/70) or CD14 Fitc (clone M5E2), CD19 PE (HIB19), CD3 PE, and CD56 PE antibodies (Biolegend and eBioscience).
4T1 adenocarcinoma cells and B16F10 melanoma cells were from ATCC. 4T1.2 cells, a subset of 4T1 cells, were a gift from Dr. Robin L. Anderson (Peter McCallum Cancer Center, Melbourne, Australia). Nonmetastatic 4T1.2-PE cells were described elsewhere (15). Female (8- to 15-week-old) BALB/c, C57BL/6 mice, and JHT mice in C57BL/6 background (JHT; B6.129P2-Igh-Jtm1Cgn/J) were from the Jackson Laboratory; μMT mice in BALB/c background were a gift from Professor Dr. Thomas Blankenstein (Max-Delbrück-Center for Molecular Medicine, Berlin, Germany); C57BL/6 mice with spontaneous ovarian cancer due to murine oviduct–specific glycoprotein promoter-driven expression of simian virus 40 large T-antigen (20) were housed at National Institute on Aging (Baltimore, MD) and TGFβRIImyeKO mice at NCI (Bethesda, MD; ref. 21).
In vitro manipulations
tBreg generation and T-cell suppression assays were performed as previously described (15). Unless specified, control B cells were treated with 100 ng/mL of recombinant mouse BAFF/BlyS (R&D) in cRPMI. tBregs were characterized as CD81hiCD25+CD20low4-1BBLlow cells gated within CD19+ cells using mAbs [CD19-APC-eFluor780, CD81-APC, CD25 Pacific blue, CD20-PE, and 4-1BBL-PerCP Cy5.5 (Biolegend and eBioscience)]. Flow cytometric data were collected on a FACS Canto II (BD) and analyzed with FlowJo software (Tree Star, Inc.). Cell sorting was performed on FACS Aria III (BD) or MoFlo XDP (Beckman Coulter, Inc.). Mo-MDSC were isolated as Lin−, CD11b+, Ly6G−, Ly6Chi, and PMN-MDSC were isolated as Lin−, CD11b+, Ly6G+, Ly6C low-int. Magnetic sort purity was more than 96% and flow cytometric sort purity was more than 98%. All magnetic sorts performed in these experiments were double sorts to increase purity. For the majority of the experiments, PMN- and Mo-MDSC were cell-sorted (purity > 98%) or isolated using the Miltenyi Biotech Myeloid-derived Suppressor Cell Isolation Kit. MDSC isolated from peripheral blood or spleen yielded similar results. For MDSC education, Gr1+ cells were isolated from tumor-bearing mice by magnetic positive selection (Miltenyi Biotech) and mixed at experiment ratios (10:1) with B cells (B-cont or tBregs) for 5 hours. Then, Gr1 cells were resorted by magnetic positive selection prior to assays, such as testing for in vitro T-cell suppression or adoptive transfer experiments. When MDSC education was done with B tumor cells, negatively isolated MDSC (using Miltenyi Biotech MDSC isolation kit) were cocultured overnight with positively isolated CD19+ B cells and isolated from spleen or lymph node (yielded similar results) of naïve or 4T1 tumor–bearing BALB/c mice. After coculture, B cells were depleted and MDSC used in T-cell suppression assays or adoptive transfer experiments. For suppression assay, MDSC were cocultured at 1:2 to 1:16 ratios with splenic CD3+ T cells, which were isolated with the mouse T-cell enrichment columns (R&D Systems), labeled with the cell proliferation dye eFluor450 (eBioscience), and stimulated with anti-CD3/28 beads (Life Technologies) for 4 to 5 days. Dilution of eFluor450 in CD4+ and CD8+ T cells (stained with anti-mouse CD4-PerCPCy5.5, clone GK1.5, and CD8-FITC, clone 53-6.7, Biolegend) is considered proliferation. TGFβ, GrB, and IFNγ were detected by intracellular staining of splenic B cells from tumor-bearing mice after 4-hour stimulation with phorbol 12-myristate 13-acetate (PMA; 50 ng/mL and 500 ng/mL ionomycin, Tocris Bioscience) and 10 μmol/L monensin (eBioscience). To test TgfβR signaling, we used 20 μmol/L SB431542 in the coculture of B cells with MDSC. Alternatively, wild-type (WT) B cells were cultured with MDSC from tumor-bearing TgfβR2 KO mice.
Human peripheral blood cell isolation and suppressive myeloid cell assays
Human peripheral blood was collected by the Health Apheresis Unit and the Clinical Core Laboratory, the National Institute on Aging, under Human Subject Protocol # 2003054 and Tissue Procurement Protocol # 2003-071. Peripheral blood mononuclear cells (PBMC) were isolated using Ficoll-Paque (GE Healthcare) density gradient separation, and B, T, and NK cells were depleted with PE-coupled antibodies to CD19, CD3, CD56, and anti-PE microbeads following the manufacturer's instructions (Miltenyi Biotech). To educate myeloid cells, PBMCs (1 × 106 cells/mL, with or without B cells) were cultured with conditioned media from human breast cancer cell line (MDA-MB-231, 50%, volume) and 20 ng/mL GM-CSF with or without 20 μmol/L SB431542 for 4 days. Then, CD11b+ or CD14+ cells were isolated by positive selection (Miltenyi Biotech) and used in T-cell suppression assay. Healthy donor PBMCs (depleted of T and NK cells) were cocultured with CD19+ cells from peripheral blood of patients with B-CLL for 48 hours. Then, CD19+ cells were depleted and CD14+ cells were positively isolated by magnetic selection and used in T-cell suppression assays.
In vivo manipulations
Mouse experiments were performed in a pathogen-free environment at the National Institute on Aging Animal Facility in accordance with the procedures outlined in the Guide for the Care and Use of Laboratory Animals (NIH Publication No. 86-23, 1985). 4T1.2 cells and B16-F10 cells (1 × 105) were subcutaneously injected into BALB/c mice or congenic μMT and TgfβR2myeKO or JHT and C57BL/6 mice, respectively. At days 32 and 20 after 4T1 and B16-F10 cell injections, respectively, lung metastasis and tumor weight were evaluated as described elsewhere (15). MDSC were isolated from mice after 25 to 30 and 18 to 20 days after 4T1 and B16 tumor challenge, respectively. Mice with spontaneous ovarian cancer were 12 to 15 weeks old. For adoptive transfer experiments, mice were intravenously injected with congenic 1.5 × 106 to 10.0 × 106 MDSC or tBregs at 1 to 3 days after tumor challenge. For Fig. 2B, the mice were tumor inoculated at day 0, and B-cell adoptive transfer was performed on day 18 (the late B-cell transfer was done to allow sufficient MDSC accumulation). MDSC were sorted 3 days after B-cell transfer to avoid the conversion of naïve B cells due to the tumor pressure.
α-mouse Gr1 depletion antibody was used at 100 μg/mouse intraperitoneal injections every fourth day. For the B-cell depletion experiments, mice were intraperitoneally injected with α-CD20 antibody (250 μg/mouse) on day 7 after tumor inoculation. Peripheral blood MDSC were assessed on day 28 after tumor inoculation.
Statistical analysis
The results are presented as the mean ± SEM. To assess significance between two groups, we used the Mann–Whitney test, whereas the Holm–Sidak method with α of 5.0% was used to correct for multiple comparison tests of tumor growth and titration curve analysis (Prism 6, GraphPad Software, Inc.).
Results
B-cell deficiency impairs the regulatory activity of MDSC
To understand the prometastatic role of MDSC, we subcutaneously implanted 4T1 cancer cells in the mammary gland of WT mice and B-cell–deficient μMT mice that do not generate tBregs (16, 17). Tumor growth in the mammary gland was retarded (P < 0.005), and lung metastasis was blocked in μMT mice as compared with WT mice (P = 0.028; Fig. 1A). However, both mice comparably and strongly expanded MDSC (CD11b+Gr1+; Supplementary Fig. 1A), such as Mo-MDSC (Ly6G−Ly6C+) and PMN-MDSC (Ly6G+Ly6CInt/Low) in the peripheral blood as well as in the secondary lymphoid organs, lungs, and tumors of both mice (Fig. 1B). Because these results question the importance of MDSC in metastasis, we tested their role by either treating tumor-bearing WT mice with RB6-8C5 Ab that depletes Gr1+ myeloid cells (including MDSC) or, conversely, by the adoptive transfer of MDSC from tumor-bearing WT mice (WT-MDSC) into μMT mice. While the depletion of Gr1+ cells reduced metastasis in WT mice (P = 0.004; Supplementary Fig. 1B), metastasis was restored in μMT mice transferred with WT-MDSC at a similar extent with the mice injected with ex vivo–generated metastasis-supporting tBregs (tBregs; Fig. 1C). The transfer of MDSC from tumor-bearing μMT mice (μMT-MDSC; Fig. 1C) failed to affect metastasis in μMT mice, confirming the importance of B cells/tBregs in the prometastatic function of MDSC.
B-cell deficiency impairs the regulatory and prometastatic function of MDSC. Tumor size, lung metastasis (inset, A), and frequency of MDSC (B) were evaluated in μMT and WT mice with subcutaneously injected 4T1.2 cancer cells (1 × 105 cells). To assess metastasis-inducing ability of tBregs and MDSC (from mice with 4 week old tumor), they (10 × 106 cells) were adoptively transferred in μMT mice (n = 4–5 mice per group) 24 hours after tumor implantation (C). MDSC (D–F) or MDSC subsets (G and H) were sorted from μMT and WT mice 4 weeks after tumor inoculation and tested for their ability to suppress T cells stimulated with anti-CD3/CD28 Abs at indicated (x-axis, D–F) or at 1:8 (G) effector-to-target ratio. To test expression of GrB and IFNγ, MDSC were intracellularly stained (E and F); and nitrate production (H) was assessed in conditioned media of cells used in G. The DCFDA staining of MDSC subsets in indicated tissues from μMT and WT mice with 4 week tumor is shown in I. The y-axis shows tumor size (A) or number of metastatic foci (inset, A), percentage of total cells per indicated tissue (B), μM of nitrate (H) ± SEM of 3 to 5 mice per group, experiments reproduced at least three times. *, P < 0.05; **, P < 0.01; ***, P < 0.001; ****, P < 0.0001. NS, not significant.
B-cell deficiency impairs the regulatory and prometastatic function of MDSC. Tumor size, lung metastasis (inset, A), and frequency of MDSC (B) were evaluated in μMT and WT mice with subcutaneously injected 4T1.2 cancer cells (1 × 105 cells). To assess metastasis-inducing ability of tBregs and MDSC (from mice with 4 week old tumor), they (10 × 106 cells) were adoptively transferred in μMT mice (n = 4–5 mice per group) 24 hours after tumor implantation (C). MDSC (D–F) or MDSC subsets (G and H) were sorted from μMT and WT mice 4 weeks after tumor inoculation and tested for their ability to suppress T cells stimulated with anti-CD3/CD28 Abs at indicated (x-axis, D–F) or at 1:8 (G) effector-to-target ratio. To test expression of GrB and IFNγ, MDSC were intracellularly stained (E and F); and nitrate production (H) was assessed in conditioned media of cells used in G. The DCFDA staining of MDSC subsets in indicated tissues from μMT and WT mice with 4 week tumor is shown in I. The y-axis shows tumor size (A) or number of metastatic foci (inset, A), percentage of total cells per indicated tissue (B), μM of nitrate (H) ± SEM of 3 to 5 mice per group, experiments reproduced at least three times. *, P < 0.05; **, P < 0.01; ***, P < 0.001; ****, P < 0.0001. NS, not significant.
Next, we tested whether the loss of B cells/tBregs can impair the regulatory function of MDSC. To do this, we cocultured purified WT- and μMT-MDSC isolated from individual mice challenged with 4T1 cancer at the same time (n = 9, from here on, unless specified, the MDSC were only isolated from tumor-bearing mice) with naïve mouse T cells stimulated with anti-CD3/CD28 Abs for 5 days. At the cell-to-cell comparisons, while WT-MDSC strongly inhibited proliferation (Fig. 1D) and production of granzyme B (GrB; Fig. 1E) and IFNγ (Fig. 1F) in CD8+ T cells, μMT-MDSC were significantly less efficient (P < 0.001; Fig. 1D–F). To further confirm this result, we also tested suppressive activity of individual subsets of MDSC by coculturing sort-purified PMN-MDSC and Mo-MDSC with T cells stimulated with anti-CD3/CD28 Abs. Despite overall stronger activity of PMN-MDSC over Mo-MDSC, both μMT-MDSC subsets inhibited less efficiently CD4+ and CD8+ T cells as compared with their respective WT subsets (P < 0.001; Fig. 1G and Supplementary Fig. S1C). Because the suppression involves NO and ROS, their production could be impaired in μMT-MDSC. In support, specific inhibitors NOHA, l-NMMA, and particularly catalase (scavenges H2O2, dismutation product of ROS), almost completely abolished the ability of MDSC to suppress T-cell proliferation (Supplementary Fig. S1D and S1E). The relative expression levels of NOX2 and Arg genes were significantly reduced in μMT-MDSC as compared with WT-MDSC (Supplementary Fig. S2A and S2B). In concordance, nitrate production (the NO readout) was only detected in WT Mo-MDSC, but not PMN-MDSC or μMT-MDSC, cultured with T cells (P = 0.028 as compared with μMT-MDSC; Fig. 1H). Both subsets of μMT-MDSC also produced significantly less ROS (detected by staining for O2− with DHE; Supplementary Fig. S2C) and H2O2 (Fig. 1I and Supplementary Fig. 2D, detected by DCFDA; ref. 22) as compared with WT-MDSC. For example, the median fluorescence index (MFI) of DCFDA+Mo-MDSC was decreased from 14,400 ± 150 to 6,459 ± 247 (P < 0.001) in the lungs and from 17,565 ± 1,153 to 12,109 ± 345 (P < 0.001; Fig. 1I) in the tumor of μMT mice compared with WT mice, respectively. For DCFDA+ PMN-MDSC, it was reduced from 14,569 ± 64 to 6,082 ± 41 (P < 0.001) and 29,616 ± 251 to 21,847 ± 74 (P < 0.001; Fig. 1I), respectively. Moreover, ROS production in WT-MDSC of tumor-bearing WT mice was further increased (P < 0.03; Supplementary Fig. 2C) if the mice were treated with α-CD20 Ab that enriches for tBregs via depleting B cells (17). Thus, given that μMT mice do not generate tBregs (17), these results suggest that the regulatory function of MDSC requires tBregs.
tBregs activate the regulatory function of cancer-primed MDSC
To test this possibility, we transferred B cells from naïve (B-cont) or tumor-bearing WT mice (B-tumor, which contain tBregs; ref. 17) into μMT mice (n = 5 per group; Fig. 2A). After 3 days, peripheral blood MDSC were isolated and tested for suppression of T-cell proliferation. μMT-MDSC from B-cont–transferred mice suppressed proliferation of CD8+ T cells slightly stronger than the ones from mock-treated mice (Fig. 2B), presumably due to some in vivo conversion of B-cont cells into tBregs (16, 17). However, μMT-MDSC from mice transferred with B-tumor inhibited T-cell proliferation significantly stronger (P < 0.001; Fig. 2B) and produced higher levels of ROS (P = 0.029 as compared with B-cont–transferred mouse Mo-MDSC and PMN-MDSC, respectively; Fig. 2C). Thus, these experiments reproduced at least 3 independent times indicate that the full regulatory function of MDSC in mice requires tBregs. In concordance, the transfer of ex vivo–generated tBregs also significantly increased the suppressive activity of MDSC in μMT mice (P < 0.008; Fig. 2D), besides restoring lung metastasis (Fig. 1C and also refs. 16–18).
The prometastatic activity of MDSC requires tBregs. Adoptive transfer of B cells in μMT mice modulates the T-cell suppressive potential of MDSC (B, D) and ROS production (C). Schema of the experiment (A) depicted in B–D. MDSC were isolated from μMT mice and cultured with T cells in Fig. 1G at 1:8 effector-to-target ratio (B, D) or stained with DHE (C). A representative figure (top) and summary results (as percentage and MFI, bottom, C) are from four mice per group experiment reproduced twice. The y-axis is the percentage of proliferated CD4+ (B) and CD8+ T cells (B, D) ± SEM of 4 to 5 mice per group experiments reproduced at least three times. *, P < 0.05; **, P < 0.01; ***, P < 0.001. NS, not significant.
The prometastatic activity of MDSC requires tBregs. Adoptive transfer of B cells in μMT mice modulates the T-cell suppressive potential of MDSC (B, D) and ROS production (C). Schema of the experiment (A) depicted in B–D. MDSC were isolated from μMT mice and cultured with T cells in Fig. 1G at 1:8 effector-to-target ratio (B, D) or stained with DHE (C). A representative figure (top) and summary results (as percentage and MFI, bottom, C) are from four mice per group experiment reproduced twice. The y-axis is the percentage of proliferated CD4+ (B) and CD8+ T cells (B, D) ± SEM of 4 to 5 mice per group experiments reproduced at least three times. *, P < 0.05; **, P < 0.01; ***, P < 0.001. NS, not significant.
tBregs educate MDSC promoting cancer escape and metastasis
To understand how tBregs activate MDSC, we performed in vitro experiments by coculturing freshly purified μMT-MDSC with naïve mouse B cells (B-cont), or with tBregs, or B cells from tumor-bearing mice (B-tumor). After 5-hour incubation, the MDSC were depleted of B cells and mixed with T cells stimulated with anti-CD3/CD28 Ab. Unlike B-cont, the pretreatment of μMT-MDSC with B-tumor (Fig. 3A and B) or tBregs (Fig. 3C and D and Supplementary Fig. S3A) strongly (P = 0.029) and in a dose-dependent manner inhibited T-cell proliferation and ROS. The treatment also blocked production of key factors required for successful antitumor activity of CD8+ T cells (17, 23), such as GrB and IFNγ (Supplementary Fig. S3A–S3C). The B-tumor and tBreg-stimulated μMT-MDSC also expressed higher levels of NOX2, iNOS, and Arg1 genes (Supplementary Fig. S4A–S4G) and produced more ROS (P < 0.03; Fig. 3B and D) than B-cont–treated MDSC. They also upregulated expression of IL10 and TGFβ (Supplementary Fig. S4E and S4F) and other factors associated with regulatory MDSC, such as IL4Rα, CD80, CD83, CD40, and phosphorylated Stat1 and Stat3 (Fig. 3E and Supplementary Fig. S4H). The μMT-MDSC also upregulated surface expression of TgfβR1 (P < 0.03) and TgfβR2 (P < 0.002) upon stimulation with tBregs (Supplementary Fig. S4I). When we transferred these μMT-MDSC (pretreated with B-tumor/tBregs) into μMT mice, the mice succumbed to significant lung metastasis (P < 0.03; Fig. 3F). In contrast, B-cont–pretreated μMT-MDSC failed to restore metastasis in μMT mice. Thus, these results, which were independently confirmed in multiple experiments, indicate that tBregs directly evoke the regulatory and thereby prometastatic function of MDSC.
tBregs directly activate cancer-expanded MDSC rendering them regulatory. MDSC from peripheral blood of μMT mice with 4T1 cancer were cultured with B naïve/B-cont or B-tumor/tBregs. After 5- to 16-hour incubation (longer for B-tumor cells), the cells were stained with DHE (B, D) or for several surface and intracellular molecules (E). After B-cell depletion, the MDSC were used in T-cell suppression assays as in Fig. 1G (A, C) or adoptively transferred in tumor-bearing μMT mice to assess lung metastasis (F). For the education experiment, we used ex vivo–generated tBregs or B-tumor cells sort-purified from at least three WT mice with tumor. B cells were mixed with MDSC isolated from three μMT tumor–bearing mice. Each experiment was reproduced at least three times. *, P < 0.05; **, P < 0.01; ***, P < 0.001. NS, not significant.
tBregs directly activate cancer-expanded MDSC rendering them regulatory. MDSC from peripheral blood of μMT mice with 4T1 cancer were cultured with B naïve/B-cont or B-tumor/tBregs. After 5- to 16-hour incubation (longer for B-tumor cells), the cells were stained with DHE (B, D) or for several surface and intracellular molecules (E). After B-cell depletion, the MDSC were used in T-cell suppression assays as in Fig. 1G (A, C) or adoptively transferred in tumor-bearing μMT mice to assess lung metastasis (F). For the education experiment, we used ex vivo–generated tBregs or B-tumor cells sort-purified from at least three WT mice with tumor. B cells were mixed with MDSC isolated from three μMT tumor–bearing mice. Each experiment was reproduced at least three times. *, P < 0.05; **, P < 0.01; ***, P < 0.001. NS, not significant.
Murine and human cancer B cells can also educate MDSC
Similar “education” of MDSC appears to also occur in other mouse backgrounds and tumor models, as the growth of a highly aggressive B16 melanoma is also retarded in B-cell–deficient JHT mice compared with congenic C57BL/6 mice (17–19, 24). To test this possibility, we adoptively transferred JHT mice bearing B16 melanoma with MDSC purified from WT C57BL/6 mice with orthotopic B16 melanoma or with spontaneous ovarian cancer (WT B16-MDSC and OC-MDSC, respectively; ref. 20). Unlike MDSC from JHT mice with B16 melanoma (JHT B16-MDSC), the transfer of WT B16-MDSC and OC-MDSC reversed the retarded tumor growth in JHT mice yielding significantly larger tumors (P < 0.05; Fig. 4A). Moreover, WT B16-MDSC and OC-MDSC also produced higher levels of ROS (P < 0.03; Fig. 4B) and nitric oxide (P < 0.03; Fig. 4C) and strongly inhibited CD4+ and CD8+ T-cell proliferation (P = 0.03; Fig. 4D).
Murine and human cancer B cells also educate MDSC. MDSC (5 × 106) purified from peripheral blood and spleen of B16 melanoma–bearing JHT mice or WT mice (B16-MDSC) or mice with spontaneous ovarian cancer (OC-MDSC) were adoptively transferred into JHT mice (n = 4–5 mice per group) 24 hours after B16 tumor challenge (A). Peripheral blood MDSC from WT, JHT, TgfβR2 KO mice with B16 melanoma (WT B16, JHT B16, and TβR2KO B16, respectively) or mice with ovarian cancer (WT OC) were tested for ROS and NO production by DHE and DAF-FM staining (B, C) or used in T-cell suppression assay as in Fig. 1G (D). Experiments in A and C and D were reproduced three and two times, respectively. PBMC (n = 7, healthy human donors), depleted of CD19+ cells, were incubated with conditioned media of MDA-MB-231 cancer cells with or without SB 431542 (20 μmol/L) in the presence of 20 ng/mL GM-CSF for 48 hours. CD11b+ or CD14+ cells were sorted and used in T-cell suppression assay (E). In a similar experiment, human PBMCs (n = 3, healthy human donors), depleted of T cells and NK cells, were incubated with B cells from patients with B-CLL. After 48 hours, CD14+ cells were sorted and used in T-cell suppression assays (F). *, P < 0.05; **, P < 0.01; ***, P < 0.001.
Murine and human cancer B cells also educate MDSC. MDSC (5 × 106) purified from peripheral blood and spleen of B16 melanoma–bearing JHT mice or WT mice (B16-MDSC) or mice with spontaneous ovarian cancer (OC-MDSC) were adoptively transferred into JHT mice (n = 4–5 mice per group) 24 hours after B16 tumor challenge (A). Peripheral blood MDSC from WT, JHT, TgfβR2 KO mice with B16 melanoma (WT B16, JHT B16, and TβR2KO B16, respectively) or mice with ovarian cancer (WT OC) were tested for ROS and NO production by DHE and DAF-FM staining (B, C) or used in T-cell suppression assay as in Fig. 1G (D). Experiments in A and C and D were reproduced three and two times, respectively. PBMC (n = 7, healthy human donors), depleted of CD19+ cells, were incubated with conditioned media of MDA-MB-231 cancer cells with or without SB 431542 (20 μmol/L) in the presence of 20 ng/mL GM-CSF for 48 hours. CD11b+ or CD14+ cells were sorted and used in T-cell suppression assay (E). In a similar experiment, human PBMCs (n = 3, healthy human donors), depleted of T cells and NK cells, were incubated with B cells from patients with B-CLL. After 48 hours, CD14+ cells were sorted and used in T-cell suppression assays (F). *, P < 0.05; **, P < 0.01; ***, P < 0.001.
To see whether similar education can also occur in human MDSC, healthy donor PBMC depleted of T and NK cells (but with or without CD19+ B-cell depletion) were treated with conditioned medium (CM) from MDA-MB-231 breast cancer cell line, the procedure that induces the generation of tBreg-like cells. Then, myeloid cells were sort-purified and tested for suppression of human CD8+ T cells stimulated with anti-CD3/CD28 Abs. While myeloid cells strongly inhibited T-cell proliferation if pretreated with CM in the presence of B cells (P = 0.03, MDA), mock-treated cells failed to do so (mock; Fig. 4E; and Supplementary Fig. S5A and S5B). Importantly, if we treated PBMCs depleted of B cells, the cells failed to inhibit T-cell proliferation (MDA-CD19; Fig. 4E and Supplementary Fig. S5A and S5B). To further confirm the link between B cells and the induction of suppressive activity of MDSC, we cocultured healthy donor peripheral blood myeloid cells (depleted of B, T, and NK cells) with B cells from patients with B-CLL, which we previously reported either did (PS #154) or did not (PS #174) contain tBreg-like cells (17), for 2 days in the presence of GM-CSF. Then, myeloid cells were reisolated and tested in T-cell suppression assays. Unlike mock or PS #174 cocultured cells, myeloid cells treated with PS #154 (which contained tBreg-like cells) strongly inhibited proliferation of T cells (P < 0.03; Fig. 4F and Supplementary Fig. S5C). Taken together, these results indicate that both murine and human cancer–exposed B cells/Bregs can evoke the regulatory function of MDSC.
tBregs educate MDSC by triggering TGFβ signaling
Given that murine and human tBregs convert metastasis-promoting FoxP3+ Tregs by overexpressing TGFβ (16, 18) and the fact that the TgfβR2 deficiency in myeloid cells abrogates 4T1 cancer metastasis (21), we tested whether TGFβ can be involved in the education of MDSC. As murine tBregs and human tBreg-like cells generated after treatment with CM of MDA-MB-231 cells (16, 18), the B16/OC-associated B cells expressed elevated levels of TGFβ compared with naïve B cells (Supplementary Fig. S6A). Thus, we tested the role of TGFβ in this process by coculturing tBregs with μMT-MDSC in the presence of TGFβ blocking or control Ab. Then, MDSC (after removal of B cells) were tested in T-cell suppression assay. The TGFβ neutralization during the education of MDSC significantly abrogated the ability of MDSC to inhibit T-cell proliferation (P < 0.03; Fig. 5A and Supplementary Fig. S3). To confirm this finding, we also cocultured μMT-MDSC with tBregs in the presence of a specific TgfβR1 inhibitor SB431542. The inhibitor indeed abrogated expression of iNOS, NOX2, and Arg (Supplementary Fig. S4A–S4C) and ROS production in MDSC (P < 0.03; Fig. 5B and Supplementary Fig. S6B). Importantly, upon transfer of the μMT-MDSC educated in the presence of SB431542 (after depletion of B cells and several washes with PBS to remove traces of the inhibitor) into μMT mice with 4T1 cancer, they yielded significantly fewer metastatic foci in the lungs than control tBreg-educated μMT-MDSC (P < 0.03; Fig. 5C). Note the fact that the residual metastasis after the transfer of TgfβR1-inactivated μMT-MDSC could be due to the fact that SB431542 only partially blocked ROS production in PMN-MDSC (Fig. 5B and Supplementary Fig. S6B). To further verify the importance of TGFβ signaling, we also used MDSC from mice with TgfβR2 deficiency in myeloid cells (TgfβR2 KO). Although ROS/NO was reduced in TgfβR2 KO MDSC of mice with B16 melanoma (Fig. 4B and C) and 4T1 cancer (Supplementary Fig. S6C) as in μMT-MDSC, tBregs failed to upregulate its expression as in μMT-MDSC (Supplementary Fig. S6C). Importantly, unlike μMT-MDSC, tBregs failed to increase the suppressive activity of TgfβR2 KO MDSC on CD4+ and CD8+ T cells (P < 0.03; Fig. 5D). Upon their transfer into μMT mice, they also supported the lung metastasis of 4T1 cancer cells less efficiently (P < 0.03; Fig. 5E). In summary, these results confirmed in multiple independent experiments suggest that tBregs educate MDSC, at least in part, by targeting the TgfβR1/2 axis. A similar mechanism appears to be used by human myeloid cells, as SB431542 also impaired their education with ex vivo–generated tBregs (Fig. 4E and Supplementary Fig. S5B) and tBreg-like cells of B-CLL (Fig. 4F and Supplementary Fig. S5C), significantly (P < 0.03) reducing their ability to suppress T-cell proliferation.
tBregs educate MDSC via the TGFβ-TgfβR1/TgfβR2 axis. 4T1 cancer–bearing mouse μMT-MDSC (A–C) and TgfβR2 KO-MDSC (D and E) were stimulated in vitro with B-cont and tBregs with anti-TGFβ neutralizing antibody or mouse IgG (50 μg/mL; A) in the presence or absence of SB431542 (20 μmol/L, SB; B and C). Then, MDSC were tested for T-cell suppression as in Fig. 1G at indicated effector-to-target ratio (A, D) or for expression of ROS (B) or induced metastases upon transfer into μMT mice (C, E). Prior to the transfer or use in suppression assays, MDSC were depleted of B cells. The y-axis shows DHE staining (MFI) in Mo-MDSC and PMN-MDSC (B), percentage of T-cell proliferation (gated in CD4+ and CD8+ T cells; A, D), and number of metastatic foci in the lungs of μMT mice (C, E) ± SEM in 4 to 5 mice per group experiments reproduced three times. F, schematic: tumor initiates an expansion of MDSC (1) and conversion of tBregs from naïve B cells (2). Cancer-activated B cells/tBregs use TGFβ (3) to induce TGFβ receptors on MDSC (4) and to upregulate ROS and NO production in MDSC. As a result, MDSC become fully suppressive for T cells and thereby prometastatic (5). *, P < 0.05; **, P < 0.01; ***, P < 0.001. NS, not significant.
tBregs educate MDSC via the TGFβ-TgfβR1/TgfβR2 axis. 4T1 cancer–bearing mouse μMT-MDSC (A–C) and TgfβR2 KO-MDSC (D and E) were stimulated in vitro with B-cont and tBregs with anti-TGFβ neutralizing antibody or mouse IgG (50 μg/mL; A) in the presence or absence of SB431542 (20 μmol/L, SB; B and C). Then, MDSC were tested for T-cell suppression as in Fig. 1G at indicated effector-to-target ratio (A, D) or for expression of ROS (B) or induced metastases upon transfer into μMT mice (C, E). Prior to the transfer or use in suppression assays, MDSC were depleted of B cells. The y-axis shows DHE staining (MFI) in Mo-MDSC and PMN-MDSC (B), percentage of T-cell proliferation (gated in CD4+ and CD8+ T cells; A, D), and number of metastatic foci in the lungs of μMT mice (C, E) ± SEM in 4 to 5 mice per group experiments reproduced three times. F, schematic: tumor initiates an expansion of MDSC (1) and conversion of tBregs from naïve B cells (2). Cancer-activated B cells/tBregs use TGFβ (3) to induce TGFβ receptors on MDSC (4) and to upregulate ROS and NO production in MDSC. As a result, MDSC become fully suppressive for T cells and thereby prometastatic (5). *, P < 0.05; **, P < 0.01; ***, P < 0.001. NS, not significant.
Discussion
Here, we attempted to mechanistically reconcile the issue raised in our previous studies questioning the importance of MDSC in metastasis. We repeatedly noticed that metastasis was blocked if B cells/tBregs were lost (16–19) despite the fact that cancer drastically expanded MDSC, the key facilitators of cancer escape and metastasis (1, 13). By comparing MDSC in WT BALB/c and C57BL/6 mice with their congenic B-cell–deficient mice (μMT and JHT) with highly aggressive tumors, such as 4T1 cancer and B16 melanoma, we demonstrate that tumors only expand and prime the regulatory function of MDSC. As such, MDSC from tumor-bearing μMT and JHT less efficiently produced ROS/NO, inhibited proliferation of CD4+ and CD8+ T cells, and promoted tumor growth and metastasis. However, these impaired functions were completely reversed if the MDSC were briefly stimulated with B cells from WT mice with tumors (which contains tBregs and cancer-induced B cells) but not naïve mouse B cells. Similarly, using modeling studies, we demonstrate that human cancer-induced B cells and tBreg-like cells from patients with B-CLL are also required in the activation of human MDSC. Thus, these results clearly indicate that the cancer-primed MDSC require help from tBregs/cancer-associated B cells to empower them fully regulatory and thereby prometastatic. Our data also uncouple the regulatory activity of MDSC from their expansion in response to cancer, suggesting that the expansion of MDSC per se is not a criterion of their regulatory and prometastatic activity. Although we can readily detect activated MDSC in various sites, such as peripheral blood, spleen, the lungs, and tumor, the site of their encounter with tBregs remains unknown.
Activated B cells and Bregs are known to upregulate and use TGFβ, for example, in conversion of FoxP3+ T cells and modulation of macrophages (25, 26). Similarly, we recently reported that murine and human tBregs also convert FoxP3+ T cells by overexpressing TGFβ (16, 18). Here, using various complementary in vitro and in vivo modeling studies, we demonstrate that tBregs and cancer-induced B cells also use the TGFβ-TgfβR1/2 axis in the activation (education) of both Mo and PMN subsets of cancer-expanded MDSC. First, the presence of TGFβ neutralizing, but not control, Ab was sufficient to inhibit the MDSC education in vitro. Second, when we blocked TgfβR1 signaling with a specific inhibitor SB431542 during the education of μMT-MDSC with tBregs, we failed to detect the upregulation of ROS production and suppression of T cells. As a result, these MDSC supported metastasis less efficiently in μMT mice upon their adoptive transfer. Similarly, the TgfβR1 inhibitor also blocked the education of human MDSC by tBregs induced by CM of MDA-MB-231 cells and tBreg-like cells of patients with B-CLL. We also confirmed these results using MDSC from tumor-bearing mice with myeloid cells deficient in TgfβR2, which is required for the signaling of TgfβR1 (27). Unlike μMT-MDSC, tBregs failed to educate MDSC with TgfβR2 KO, as shown by the loss of upregulation of ROS production, T-cell inhibition, and ability to support metastasis upon transfer into μMT mice. Thus, these results unequivocally indicate that cancer-induced B cells and tBregs render the full regulatory function of MDSC by, at least, targeting their TgfβR1/TgfβR2 signaling axis. In support, others recently reported that 4T1 cancer also fails to metastasize in BALB/c mice deficient in TgfβR2 in myeloid cells (21), suggesting that this is due to the inability of their MDSC to get education from tBregs.
Our ex vivo studies with human MDSC and 3 murine tumor models tested so far, such as mice with 4T1 cancer, B16 melanoma, and spontaneous ovarian cancer, suggest that the MDSC education is a common feature of cancer-activated B cells/Bregs. As in 4T1 cancer model (where tBregs induce MDSC), the loss of mature B cells also impaired the regulatory and tumor-augmenting functions of MDSC in mice with B16 melanoma that does not generate tBregs. Moreover, unlike naïve mouse B cells that cannot educate MDSC nor promote tumor growth (17–19), B cells from mice with B16 melanoma and spontaneous ovarian cancer not only induced regulatory activity of MDSC and reversed the retarded tumor growth in B-cell deficient mice but also upregulated TGFβ as in tBregs (18). Similarly, B cells were required for the ex vivo generation of suppressive myeloid cells from the peripheral blood of healthy human donors, as their removal or the blockage of TgfβR1 signaling abrogated the generation of suppressive myeloid cells. Finally, tBreg-like cells of patients with B-CLL, but not B cells from patients without tBregs or from healthy donors, also induced the generation of suppressive myeloid cells using TgfβR1 signaling.
In summary, our data indicate that the generation of regulatory MDSC is a 2-step process (Fig. 5F). While drastically expanding MDSC, probably using GM-CSF, IL1β, VEGF, TGFβ, and other factors (1, 13, 28), cancer also activates their inducers, such as tBregs in mice with 4T1 cancer and ovarian cancer (16, 17) or/and yet to be identified Bregs in mice with B16 melanoma. Naïve B cells do not educate MDSC. Although the nature and induction of cancer-induced B cells in mice with B16 melanoma is a focus of a separate study, we recently reported that 4T1 cancer directly induces the generation of tBregs from B2 cells via production of 5-lipoxygenase metabolites (19). The reasons behind the 2-step activation process for MDSC remain unclear. This can be a way to limit the use of MDSC only at the sites of inflammation and metastasis, such as the tumors and lungs, via triggering the feedback loop induced by TGFβ and ROS/NO, as shown for other cells (29–31) where the activation of TGFβ and production of ROS/H2O2/NO are mutually regulated. In concordance, μMT-MDSC became fully regulatory and prometastatic within a brief (<5 hours) encounter with tBregs. The education not only increased a number of surface molecules linked with regulatory MDSC (e.g., IL4Rα, TGFβ, and IL10) but also upregulated surface expression of TgfβRs presumably as a part of the feedback loop. Thus, the education may also bring additional factors that further augment the differentiation and regulatory function of MDSC, the focus of a different study. On the other hand, it is tempting to speculate that the early stage of cancer requires tBregs to support metastasis of 4T1 cancer via inducing metastasis-protecting FoxP3+Tregs (17), as we detect tBregs at least 1 week before the massive expansion of MDSC. As such, the loss of Tregs mostly blocks 4T1 cancer metastasis without affecting primary tumor growth (15, 17). At the later stage of cancer, tBregs appear to be needed to counteract the induction of antitumor myeloid cells (8) by switching and enhancing their regulatory function. Overall, the data presented here further underscore the importance of B cells in cancer (24, 32–36) by adding for the first time the education of MDSC to a growing list of protumorigenic functions, such as the inhibition of cytotoxic CD8+ T and NK cells (37), Treg conversion (38), and M1-to-M2 macrophage polarization (39, 40). As such, B cells have to be targeted to enhance antitumor immune responses.
Disclosure of Potential Conflicts of Interest
No potential conflicts of interest were disclosed.
Authors' Contributions
Conception and design: M. Bodogai, A. Biragyn
Development of methodology: M. Bodogai, C. Lee-Chang
Acquisition of data (provided animals, acquired and managed patients, provided facilities, etc.): M. Bodogai, K. Moritoh, C.M. Hollander, R.P. Wersto, Y. Araki, I. Miyoshi, L. Yang
Analysis and interpretation of data (e.g., statistical analysis, biostatistics, computational analysis): M. Bodogai, A. Biragyn
Writing, review, and/or revision of the manuscript: M. Bodogai, R.P. Wersto, L. Yang, G. Trinchieri, A. Biragyn
Administrative, technical, or material support (i.e., reporting or organizing data, constructing databases): M. Bodogai, C.A. Sherman-Baust, R.P. Wersto
Study supervision: A. Biragyn
Acknowledgments
The authors thank Dr. Kathy Perdue (NIA/NIH) for the help with re-derivation of μMT mice, Dr. Charles Hesdorffer (VA, Washington, DC) for B-CLL cells, Drs. Salman Tajuddin and Ilya Goldberg (NIA/NIH) for help with statistical analysis, Ana Lustig and Dr. Nicole N. Hooten (NIA/NIH) for critical reading this article.
Grant Support
This research was supported by the Intramural Research Program of the National Institute on Aging, NIH, and CRADA with Janssen Research Development program.
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.