GVHD-associated, inflammasome-mediated loss of function in adoptively transferred myeloid-derived suppressor cells - PubMed (original) (raw)
. 2015 Sep 24;126(13):1621-8.
doi: 10.1182/blood-2015-03-634691. Epub 2015 Aug 11.
Petya Apostolova 2, Jessica M Haverkamp 3, Jeffrey S Miller 4, Valarie McCullar 4, Jakub Tolar 1, David H Munn 5, William J Murphy 6, Willie June Brickey 7, Jonathan S Serody 7, Dmitry I Gabrilovich 8, Vincenzo Bronte 9, Peter J Murray 3, Jenny P-Y Ting 7, Robert Zeiser 10, Bruce R Blazar 1
Affiliations
- PMID: 26265697
- PMCID: PMC4582338
- DOI: 10.1182/blood-2015-03-634691
GVHD-associated, inflammasome-mediated loss of function in adoptively transferred myeloid-derived suppressor cells
Brent H Koehn et al. Blood. 2015.
Abstract
Myeloid-derived suppressor cells (MDSCs) are a naturally occurring immune regulatory population associated with inhibition of ongoing inflammatory responses. In vitro generation of MDSCs from bone marrow has been shown to enhance survival in an acute model of lethal graft-versus-host disease (GVHD). However, donor MDSC infusion only partially ameliorates GVHD lethality. In order to improve the potential therapeutic benefit and ultimately survival outcomes, we set out to investigate the fate of MDSCs after transfer in the setting of acute GVHD (aGVHD). MDSCs transferred to lethally irradiated recipients of allogeneic donor hematopoietic grafts are exposed to an intense inflammatory environment associated with aGVHD, which we now show directly undermines their suppressive capacity. Under a conditioning regimen and GVHD inflammatory settings, MDSCs rapidly lose suppressor function and their potential to inhibit GVHD lethality, which is associated with their induced conversion toward a mature inflammasome-activated state. We find even brief in vitro exposure to inflammasome-activating mediators negates the suppressive potential of cultured murine and human-derived MDSCs. Consistent with a role for the inflammasome, donor MDSCs deficient in the adaptor ASC (apoptosis-associated speck-like protein containing a CARD), which assembles inflammasome complexes, conferred improved survival of mice developing GVHD compared with wild-type donor MDSCs. These data suggest the use of MDSCs as a therapeutic approach for preventing GVHD and other systemic inflammatory conditions will be more effective when combined with approaches limiting in vivo MDSC inflammasome activation, empowering MDSCs to maintain their suppressive potential.
© 2015 by The American Society of Hematology.
Figures
Figure 1
BM-derived MDSC-IL13 enhance GVHD survival, but suppression is compromised after 5 days in vivo. (A) Lethally irradiated BALB/c recipients were given 1 × 107 C57Bl/6 BM (BM only), BM plus 2 × 106 CD25-depleted T-cells (GVHD), or BM, T cells, and 6 × 106 MDSC-IL13 (GVHD + MDSC) as indicated. Kaplan-Meier survival curve represents 4 pooled and independent experiments (n = 40 animals/group). GVHD vs GVHD + MDSC, P < .0001. (B-C) Surface expression of congenic (CD45.2+) MDSC-IL13 recovered from spleens 5 days after transfer to irradiated animals receiving BM only (no GVHD) or BM plus T cells (GVHD). Data represent 3 replicates per group with P < .001 for all markers shown. (D) Representative histograms indicating responding T-cell proliferation as denoted by CFSE dilution. Purified MDSC-IL13 from pooled spleens 5 days after transplant were plated at 5 × 105/mL with an equal number of CFSE-labeled responder T cells, 0.25 μg/mL anti-CD3ε mAb, and 2.5 × 105/mL irradiated T-cell–depleted splenocytes in specially formulated 150 μM
l
-arginine RPMI media. Shaded histogram indicates proliferation of unstimulated controls. Data are representative of 3 samples per group and a total of 3 independent experiments. (E) Summary data of recovered MDSCs showing viability and total cell numbers recovered, gated CD11b+ CD45.2+. Data represent 3 samples per group and are representative of 3 independent experiments. (F) Lethally irradiated BALB/c recipients transplanted as above or given 3 consecutive infusions of MDSC-IL13 as indicated on days 0, 3, and 6. All mice receiving MDSCs demonstrated increased survival vs GVHD (P < .001). MDSCs vs MDSCs on days 0, 3, and 6 (P < .0001). Survival curve represents 20 animals per group from 2 independent experiments and is representative of an additional experiment giving multiple infusions on days 0, 7, and 14. ns, not significant.
Figure 2
Inflammasome activity evident in recovered MDSCs. (A) Western blot of cell lysates from recovered wild-type or ASC−/− MDSC-IL13 probed for the active p10 form of caspase-1 and β-actin. ImageJ software was used to convert to grayscale and straighten and crop the gel image to highlight lanes of interest according to size. (B) Caspase-1 p10 blot quantification relative to β-actin; GVHD vs all other groups (P < .05). Quantification was carried out on scanned blots by densitometric analysis from ImageJ software (National Institutes of Health). (C) IL-1β enzyme-linked immunosorbent assay (ELISA) of supernatants after day 5–recovered MDSC-IL13 were plated in complete RPMI media overnight; GVHD vs all other groups (P < .05). Dotted line indicates limit of ELISA detection. All data are representative of 2 independent experiments. wt, wild-type.
Figure 3
In vitro inflammasome induction in MDSCs leads to loss of suppressor function. Inflammasome induction in freshly cultured wild-type and ASC−/− MDSC-IL13 was carried out by adding 0.2 µg/mL LPS for 3 hours, followed by addition of 2 mM ATP or 0.8 µg/mL poly(dT) transfection. (A) Culture supernatants were harvested after an additional 1 hour and assayed for IL-1β production by ELISA. Data are representative of 3 independent experiments. (B) Inflammasome-induced MDSC-IL13 were washed extensively and plated in a CFSE suppression assay at a 1:1 ratio; data are representative of gated CFSE-labeled CD8+ responder T cells (n = 6 samples/group from 2 independent experiments). NLRP3 indicates LPS + ATP treatment, and AIM2 indicates LPS + poly(dT) treatment; gray histogram represents the no-MDSC proliferation control. Gated CD4+ responder T cells shown in supplemental Figure 5. (C) Kaplan-Meier survival curve of the C57Bl/6 → BALB/c GVHD model using inflammasome-induced MDSC-IL13, treated as above. MDSC v no MDSC P < .0001, MDSC vs MDSC AIM2 P < .0001, MDSC v MDSC NLRP3 P = .0029. Data represent n = 18 animals per group, combined from 2 independent experiments. (D) Kaplan-Meier survival curve of GVHD using MDSC-IL13 generated from either wild-type or ASC−/− mice as indicated. Data represent n = 30 animals per group in 3 independent experiments. MDSC vs no MDSC P = .0399, MDSC vs ASC−/− MDSC P = .0006. (E) Histograms represent % divided CFSE-labeled responding T-cells when plated against recovered wild-type or ASC−/− MDSC-IL13 from day 5 posttransplant at a ratio of 1:1 and collected on day 3. Significant P values (< .05) were found when comparing any single group to wild-type MDSC-IL13 recovered from GVHD mice. Data are representative of 2 independent experiments. wt, wild-type.
Figure 4
Inflammasome induction in MDSC associated with loss of Arg1 expression. MDSC-IL13 were induced for NLRP3 or AIM2 inflammasomes as indicated, washed extensively, and replated in complete media overnight. (A) Enzymatic activity of cell-associated arginase for wild-type or (B) ASC−/− MDSCs, normalized to total cell number. Data are pooled from 2 independent experiments. MDSCs generated from YARG mice, followed by in vitro induction of inflammasomes (as previously discussed) and replating in complete media. (C) YFP fluorescence for CD11b-gated MDSCs after 2 additional days in culture indicated as representative histograms (shaded histogram represents unstimulated BM from YARG donor) and (D) summary data of % YFP+. (E) YFP detection for MDSC-IL13 recovered from day 5–transplanted animals with BM only (no GVHD) or BM plus whole T cells (GVHD). YARG BM (YFP-Arg1 bone marrow) indicates baseline YFP fluorescence. (F) IL-1β production before and after NLRP3 (ATP + LPS) inflammasome activation for bulk MDSC-IL13 or sorted granulocytic Ly6G+C+ (Ly6G+) and monocytic Ly6C+ subsets. (G) CFSE proliferation of anti-CD3ε driven CD8+ B6 T cell responses in the presence of sorted granulocytic (Ly6G+) or monocytic (Ly6C+) subsets of MDSC-IL13 at a 1:1 ratio. (H) Cell-associated arginase bioactivity for bulk MDSC-IL13 and sorted granulocytic (Ly6G+) or monocytic (Ly6C+) subsets. The dashed line indicates background activity for Arg1-deficient splenocytes. Data regarding MDSC subsets are representative of 3 independent experiments.
Figure 5
Inflammasome induction in human MDSC interferes with their suppressor function. Human MDSCs were generated from donor PBMCs. (A) IL-1β ELISA of supernatants from MDSCs treated with 0.2 µg/mL LPS for 3 hours followed by 2 mM ATP for 1 hour prior to harvest. Data are representative of 2 independent experiments. (B) Representative histograms of responder PBMCs labeled with CellTrace Violet (Life Technologies) in the presence of cultured human MDSCs from unrelated donors indicated by solid line. Dotted line indicates no-MDSC proliferation control, gray histogram indicates PBMCs alone (no CD3ε or MDSCs). No Stim represents the alloresponse against MDSCs with no anti-CD3ε. Stim indicates addition of anti-CD3ε microbeads (2:1) + IL-2 (100 U/mL) to demonstrate MDSC suppression of T-cell activation. Stim + Infl. Tx’d indicates MDSCs have been treated for inflammasome activation prior to plating with anti-CD3ε microbeads + IL-2. (C) Aggregate data show percent division of responding CD8 and CD4 T cells. Data represent responses from 3 unrelated PBMC donors and are representative of 2 independent experiments.
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