Introduction
Cellular immunotherapy, which using immune cells to eliminate cancer, changes the
outlook for cancer patients. Immune checkpoint inhibition, Chimeric antigen receptor
T cells therapy, and dendritic cell (DC)-based cancer vaccine are now emerging immune-related
treatments for many malignancies.[1 ]
[2 ]
[3 ] DCs are the most important antigen presenting cells and have been categorized as
different subtypes that are conventional DC (cDC), plasmacytoid DC (pDC), and monocyte-derived
DC (MoDC).[4 ] To take advantage of its features, personalized DC-based vaccines have been extensively
utilized in numerous preclinical and clinical studies.[5 ]
[6 ] In 2010, Sipuleucel-T became the first approved DC cancer vaccine for the treatment
of late-stage prostate cancer.[7 ]
[8 ] Although Sipuleucel-T has not been very widely used, it demonstrated how the safety
and immunogenicity DC-based vaccine would be.[9 ]
[10 ]
The DCs for tumor vaccines are usually manufactured by inducing monocytes or hematopoietic
stem and progenitor cells from cancer patients' peripheral blood by recombinant granulocyte
macrophage–colony stimulating factor (GM-CSF) and interleukin-4 (IL-4) cytokines and
subsequently treated with tumor-associated antigens to acquire antitumor activity.[11 ]
[12 ]
[13 ] However, along with tumor progression, inflammatory cytokines and chemokines exert
tumor-promoting effect by “educating” normal immune cells to become immunosuppressive
types.[14 ]
[15 ]
[16 ] As our and other groups' data showed that a lot of myeloid-derived suppressive cells
(MDSCs) that are heterogeneous immature myeloid cells with immunosuppressive activity,
but not monocytes, accumulated in cancer patients' peripheral blood, especially in
patients with advanced cancer.[17 ]
[18 ]
[19 ] Therefore, DCs ex vivo differentiation from monocytes of peripheral blood in tumor
patients are actually MDSC-derived DCs (MDSC-DCs). Thus, how to improve the antitumor
activity of ex vivo differentiated DCs is undoubtedly the focus of DC-based tumor
vaccine research.
Our previous studies showed that CC chemokine ligand 5 (CCL5), which is associated
with poor prognosis and metastasis in many types of tumors,[20 ] plays an important role in myeloid cell's differentiation.[21 ]
[22 ] So, we wondered if CCL5 involves in maintaining the immunosuppressive capacity of
MDSCs and if CCL5-deficiency in MDSCs could make MDSC-DCs into a different phenotype.
In this project, we figured out the antitumor activity of MDSC-DCs as tumor vaccines
and tried to interrupt CCL5 gene in MDSC-DCs to enhance their antitumor activity. CCL5-deficiency induced the
formation of CD24+ MDSC-DCs and these cells showed enhanced antitumor abilities via inhibiting differentiation
of CD4+ T cells into regulatory T cells (Tregs). Our research provided a new method for the
development of DC-based cancer vaccines.
Results
DCs Derived from CCL5-deficiency MDSCs Showed High CD24 Expression
Plenty of research have proved that immune cells in tumor bearing mice's spleen can
basically mirror the situation of cancer patients' peripheral blood.[17 ]
[23 ]
[24 ] To choose the suitable tumor-bearing murine models to mimic the higher proportion
of MDSCs accumulated in peripheral blood at late stage of tumor patients, we first
constructed eight different models of prostatic cancer (TRAMP-C1), breast cancer (4T1,DA3),
colon cancer (CT26, MC38), melanoma (B16F10), and sarcoma (MethA,C3) developed in
BALB/C or C57BL/6 mice and examined the proportion of CD11b+ Gr-1+ MDSCs in spleens by FACS after 21 days of tumor cells inoculation. Compared with
control mice, the percentages of MDSCs in spleens were significantly increased in
all tumor-bearing murine models, particularly in 4T1-Balb/c and MC38-C57B6 models
([Supplementary Fig. S1A ] and [S1B ] [available in the online version only]). Thus, in our following experiments we utilized
splenocytes from these two tumor-bearing murine models as initial cells to induce
MDSC-DCs with GM-CSF and IL-4.
Our results showed that the differentiation efficiency of MDSCs into CD11c+ MDSC-DCs in the presence of GM-CSF and IL-4 was low, around 30%, in both 4T1-Balb/c
and MC38-C57B6 models ([Fig. 1A–D ]), which were consistent with the data reported by other groups.[5 ]
[25 ] Since all-trans-retinoic acid (ATRA) has been shown to have a strong effect on myeloid
cell differentiation,[26 ]
[27 ] we added 1.5uM ATRA into the MDSC-DCs culture medium with GM-CSF plus IL-4 and,
as expected, the production of MDSC-DCs significantly increased to around 80% in the
new culture system, independent of CCL5 protein ([Fig. 1A–D ]). For CCL5-deficiency MDSC-DCs, we constructed tumor models developed in CCL5-knockout
mice and induced MDSCs via GM-CSF and IL-4 into CCL5−/− MDSC-DCs. To further characterize MDSC-DCs obtained from different origins and culture
systems, we examined expression levels of several DC markers, such as CD24, CCR7,
CD117, and CD135 on the MDSC-DCs in 4T1-tumor bearing mice. FACS results showed that
the expression of CCR7, CD117, and CD115 among these MDSC-DCs did not have notable
changes, whereas CCL5-deficiency MDSC-DCs expressed higher amount of CD24 compared
with the other three cohorts ([Fig. 1E ] and [F ]). MDSC-DCs in MC38 tumor-bearing mice also showed similar expression level of DC
markers as MDSCs in 4T1 tumor-bearing mice ([Supplementary Fig. S2A ] and [S2B ], available in the online version only). Collectively, our results showed that ATRA
could enhance the induction-efficiency of MDSCs into MDSC-DCs and DCs derived from
CCL5-deficiency MDSCs showed higher CD24 expression.
Fig. 1 Knockout of CC chemokine ligand 5 (CCL5) induced the formation of CD24+ myeloid-derived suppressive cells-derived DCs (MDSC-DCs) derived from splenocytes
of tumor-bearing mice. (A ) Representative FACS plots of differentiated MDSC-DCs derived from 4T1 tumor mice
model. (B ) Representative FACS plots of differentiated MDSC-DCs derived from MC38 tumor mice
model. (C ) The percentage of CD11c+ MDSC-DCs derived from splenocytes of 4T1 tumor-bearing mice in different culture
systems. (D ) The percentage of CD11c+ MDSC-DCs derived from splenocytes of MC38 tumor-bearing mice in different culture
systems. (E ) Representative expression of the indicated surface markers on gated CD11c+ MDSC-DCs from 4T1 tumor-bearing mice splenocytes cultures. The isotype monoclonal
antibody of indicated markers was included as controls. (F ). CD24 expression in MDSC-DCs derived from different culture methods. The experiments
were repeated n = 3 for each group. *p < 0.05, **p < 0.01, ***p < 0.001. Data were represented as mean ± standard deviation.
Fig. 2 CC chemokine ligand 5 (CCL5)-deficiency myeloid-derived suppressive cells-derived
DCs (MDSC-DCs)-based tumor vaccine had potent antitumor activity. (A ). Flowchart of MDSC-DC vaccines preparation and treatment plan. (B ) Tumor growth curves of 4T1 tumor-bearing mice treated with different groups of MDSC-DC
vaccines. Tumor growth was monitored every 2 to 3 days. n = 10 mice per group. (C ) Tumor growth curves of MC38 tumor-bearing mice treated with different groups of
MDSC-DC vaccines. Tumor growth was monitored every 2 to 3 days. n = 10 mice per group. PBS, phosphate buffered saline.
CCL5-Deficiency MDSC-DCs-Based Tumor Vaccines Had Potent Antitumor Activity
CD24 is a cell surface heavily glycosylated glycosylphosphatidylinositol-anchored
protein not only expressed in many cancers but also showed in adaptive immune responses.[28 ] CD24 is a redundant costimulatory molecule expressed on variety of antigen-presenting
cells, including DCs and has been recognized as general DC marker for some subsets
of mouse DCs.[4 ] Previous studies have reported that CD24 expression determines antigen presenting
ability of DCs[29 ] and CD24 expression on DCs may also influence the T cell differentiation and activation.[30 ]
[31 ]
To determine whether MDSC-DCs derived from different conditions have differential
antitumor abilities, we utilized MDSC-DCs as tumor vaccines in both MC-38 colorectal
cancer (CRC) and 4T1 breast cancer models. We used the freeze-thaw processing to get
whole tumor cell lysates as a source of all potential antigens for antigen-loading
and lipopolysaccharide (LPS) for maturation. Mice at background of BALB/c or C57BL/6
were inoculated subcutaneously with 4T1 or MC38 cells, respectively, and, after 7
days for tumor establishment, 5 × 106 MDSC-DCs removed cell debris and death cells ([Supplementary Fig. S3A ] and [S3B ] [available in the online version only]) were injected intravenously into tumor-bearing
mice every 5 days for three times, whereas control mice received phosphate buffered
saline (PBS) only ([Fig. 2A ]). The tumor growth curves showed that tumor lysate-pulsed MDSC-DCs in either regular
or ATRA-plus culture medium only elicited subtle antitumor activity compared with
PBS group ([Fig. 2B ] and [C ]). However, CCL5−/− MDSC-DCs, particular in the present of ATRA, had dramatically tumor-inhibitory effects
on both 4T1 and MC38 tumor-bearing models ([Fig. 2B ] and [C ]). Collectively, CCL5-deficiency could enhance the antitumor activity of MDSC-DCs
as tumor vaccine and ATRA could not only increase the differentiation of MDSC-DCs
but also have a synergistic effect with CCL5-deficiency on boosting the tumor inhibition
activity of MDSC-DCs.
The Composition of Tumor-Infiltrated Leukocytes (TILs) Was Changed in CD24+ MDSC-DCs Tumor Vaccine-Treated Mice
In the following study, we defined CCL5−/− MDSC-DCs with ATRA as CD24+ MDSC-DCs to distinguish CCL5-deficiency MDSC-DCs with or without ATRA. To further
understand the mechanism involved in MDSC-DCs vaccine immunization, we analyzed by
flow cytometry the major subsets of TILs, which are highly relevant to the regulation
of tumor growth,[32 ] in 4T1 tumor-bearing mice treated with different MDSC-DCs vaccines. [Fig. 3A ] and [Supplementary Fig. S4A ] (available in the online version only) showed that the percentage of CD45+ TILs was slightly increased in mice vaccinated MDSC-DCs, compared with PBS group,
but no significant difference among them. Considering the prominent role of CD8+ T cells in antitumor effect,[33 ] we first analyzed tumor-infiltrated CD3+ CD8+ CD4- cells. All the MDSC-DCs vaccines treated mice had significantly increased frequency
of tumor-infiltrating CD8+ T cells, particularly CD24+ MDSC-DCs, compared with PBS-treated control ([Fig. 3B ] and [Supplementary Fig. S4B ] [available in the online version only]). Although CD8+ T cells can directly kill cancer cells, some other regulatory immune cells, such
as MDSCs and Tregs, play important roles on regulation of antitumor activity of CD8+ T cells.[34 ]
[35 ] FACS results showed that the percentages of MDSCs in MDSC-DCs-treated-groups were
only slightly lower than that of the PBS group, but there was no statistical difference
([Fig. 3C ] and [Supplementary Fig. S4C ] [available in the online version only]), suggesting that inhibition of MDSCs might
not contribute to the enhanced antitumor activity of CD24+ MDSC-DCs.
Fig. 3 The tumor immune microenvironment was changed after CD24+ myeloid-derived suppressive cells-derived DCs (MDSC-DCs) vaccines treatment. (A ) FACS qualification of tumor infiltrated CD45+ cells in different treatment groups. n = 5 mice per group. (B ) FACS qualification of tumor infiltrated CD8+ cells in different treatment groups. n = 5 mice per group. (C ) FACS qualification of tumor infiltrated Gr-1+ CD11b+ cells in different treatment groups. n = 5 mice per group. (D ) FACS qualification of tumor infiltrated CD4+ FOXP3+ cells in different treatment groups. n = 5 mice per group. (E ) FACS qualification of tumor infiltrated CD4+ cells in different treatment groups. n = 5 mice per group. All the significance in the plot were compared with phosphate
buffered saline (PBS) group. *p < 0.05, **p < 0.01, ***p < 0.001. Data were represented as mean ± standard deviation.
Tregs that also demonstrated strong ability in modulating CD8+ T cell function[36 ] and the results showed that the frequency of Tregs (CD4+ FOXP3+ ) cells in the PBS group were notably higher than MDSC-DCs-treated-groups, particularly
the proportion of Tregs in CD24+ MDSC-DCs-treated-group ([Fig. 3D ] and [Supplementary Fig. S4D ] [available in the online version only]), suggesting that low number of Tregs might
mediate the enhanced antitumor activity of CD24+ MDSC-DCs. Since Tregs are subsets of CD4+ T cells, next we examined the population
of CD3+ CD4+ T cells in TILs by FACS, and the results showed that there was no considerable divergence
in CD4+ T cells between each group ([Fig. 3E ] and [Supplementary Fig. S4E ] [available in the online version only]). These results suggested that polarization
of Tregs might be changed in CD24+ MDSC-DCs-treated-group.
Tregs Mediated the Antitumor Activity of CD24+ MDSC-DCs
To further investigate the Tregs' role in antitumor activity of CD24+ MDSC-DCs, 4T1 tumor-bearing mice were given three doses of CD24+ MDSC-DCs or control MDSC-DCs cultured with ATRA as tumor vaccines from 7 days after
tumor inoculation with 5-day intervals. Anti-CD25 neutralizing antibody (PC61) that
has been demonstrated to efficiently deplete Treg cells in vivo[37 ] or isotype antibody was intraperitoneally injected into mice 16 days after tumor
inoculation and tumor samples were collected at 30 days for FACS analysis ([Fig. 4A ]). FACS showed that there was a significant scavenging effect on tumor-infiltrated
Tregs after anti-CD25 antibody injection in control (CTR) and CD24+ MDSC-DCs groups, although the number of Tregs was low in CD24+ MDSC-DCs-treated mice ([Fig. 4B ] and [4D ]). In control (CTR) MDSC-DCs groups, the proportion of infiltrated CD8+ T cells increased significantly after anti-CD25 treatment compared with isotype antibody
treatment, whereas in the CD24+ MDSC-DCs groups, the percentage difference between anti-CD25 monoclonal antibody
(mAb) and isotype antibody was inconspicuous ([Fig. 4C ] and [E ]), which reflected the tendency on tumor growth of these mice. [Fig. 4F ] showed that anti-CD25 neutralizing mAb (PC61) significantly inhibited tumor growth
in control (CTR) MDSC-DCs groups, while there was no notable change on tumor growth
between anti-CD25 neutralizing antibody and isotype antibody in CD24+ MDSC-DCs vaccinated mice, suggesting that intratumoral Tregs might contribute to
the antitumor effect of CD24+ MDSC-DCs vaccines.
Fig. 4 Regulatory T cells (Tregs) mediated the antitumor activity of CD24+ myeloid-derived suppressive cells-derived DCs (MDSC-DCs). (A ) Flowchart of anti-CD25 monoclonal antibody (mAb) neutralization in MDSC-DCs vaccines
treated mice. (B ) Representative staining plots of tumor infiltrated Tregs after MDSC-DCs vaccines
treatment with/without anti-CD25 mAb treated. (C ) Representative staining plots of tumor infiltrated CD8+ T cells after MDSC-DCs vaccines treatment with/without anti-CD25 mAb treated. (D ) FACS qualification of tumor infiltrated Tregs in different treatment groups. n = 5 mice per group. (E ) FACS qualification of tumor infiltrated CD8+ T cells in different treatment groups. n = 5 mice per group. (F ) Tumor volume of tumor-bearing mice after MDSC-DCs vaccines treatment with/without
anti-CD25 mAb treated. n = 5 mice per group. (G ) Flowchart of adoptive Tregs transfer in MDSC-DCs vaccines treated mice. (H ) Tumor volume of tumor-bearing mice after MDSC-DCs vaccines treatment with/without
adoptive Tregs transfer. n = 5 mice per group. (I ). Representative staining plots of tumor infiltrated Tregs after MDSC-DC vaccines
with/without adoptive Tregs transfer. (J ) FACS qualification of tumor infiltrated Tregs after MDSC-DC vaccines with/without
adoptive Tregs transfer. n = 5 mice per group. *p < 0.05, **p < 0.01, ***p < 0.001. Data were represented as mean ± standard deviation. PBS, phosphate buffered
saline.
To further confirm these results, 1 × 106 isolated Treg cells were transferred into the 4T1 tumor-bearing mice at 16 day after
tumor challenge ([Fig. 4G ]). The frequency of infiltrated Treg increased notably in both groups ([Fig. 4I ]). Tumor volume increased in both groups after receiving Tregs, particularly in CD24+ MDSC-DCs groups and the difference on tumor volume between the two groups was reduced
after receiving Treg reinfusion ([Fig. 4H ]). Collectively, CD24+ MDSC-DCs achieved tumor growth inhibition by reducing the proportion of Tregs in
tumor microenvironment (TME), which alleviated the immune suppression of the TME.
CD24+ MDSC-DCs Inhibited Tregs' Polarization
To figure out the mechanism on the reduced quantity of Tregs in CD24+ MDSC-DCs vaccine-treated mice, we first examined the number of Tregs in peripheral
blood of control (CTR) and CD24+ MDSC-DCs groups in 4T1-bearing mice. And there was no significantly difference on
the percentage of Tregs in peripheral blood between these two groups ([Fig. 5A ]) suggesting that the migration of Tregs did not contribute to the lower level of
Tregs in CD24+ MDSC-DCs vaccine mice. Next, we wondered if CD24+ MDSC-DCs had an effect on the polarization of Tregs in TME.
Fig. 5 The genotype and phenotype of CD24+ myeloid-derived suppressive cells-derived DCs (MDSC-DCs). (A ) FACS qualification of the proportion of regulatory T cells (Tregs) in the peripheral
blood of MDSC-DCs vaccines treated 4T1 tumor-bearing mice. (B ) MDSC-DCs coculture with naïve CD4+ T cells isolated from OT-II mice in the presence of 10 ng/mL Ovalbumin323–339 peptide and 5 ng/mL transforming growth factor-β1 for 4 days. The ratio of MDSC-DCs
and naïve CD4+ T cells is 1 to 10. After 4 days cultured, the percentage of Tregs was analyzed by
FACS. Representative staining plots of Tregs after 4-day coculture. (C ) FACS qualification of the proportion of Tregs in the coculture system. The coculture
experiment was repeated, n = 3 for each group. (D ) Gene Ontology (GO) enrichment terms of differentially expressed regulation of immune
response and T cell activation biological process derived from RNA-sequencing. (E ) Expression of CD4+ T cell polarization-related and DCs function-related genes. (F ) Gene Set Enrichment Analysis (GSEA) analysis of control (CTR) MDSC-DCs and CD24+ MDSC-DCs.
We set up an antigen presentation assay by coculturing control (CTR) or CD24+ MDSC-DCs with microbeads-isolated naïve OT-II CD4+ CD62L+ T cells in the presence of Ovalbumin323–339 peptide and transforming growth factor-β1 (TGF-β1). After 4 days of coculture, control
(CTR) MDSC-DCs induced significant higher percentage of Tregs than CD24+ MDSC-DCs ([Fig. 5B ] and [C ]), indicating that CD24+ MDSC-DCs inhibited T cells polarization to Tregs in TME. To further explore the molecular
mechanism on the inhibitory effect of CD24+ MDSC-DCs on Tregs' polarization, the gene expressions of control (CTR) MDSC-DCs and
CD24+ MDSC-DCs were examined by RNA-seq and Gene Ontology (GO) enrichment analysis showed
that the main genes expression differences were distributed in innate immunity regulation,
cytokine production, and T cell activation ([Fig. 5D ]). Heatmap showed that CD24+ MDSC-DCs had a high expression of inhibiting Treg polarization relevant genes (Il12a,
Il12b, Il6, Il23a, Il1a) and T cell activation relevant genes (Nfkb1, Tnf, Cd80, Cd40, Cd24a, CD14, Icosl, Fth1 ), while control (CTR) MDSC-DCs expressed higher level of genes related to Tregs differentiation
and Tregs function (Apoe, Fcgr1, Tgfb1, Tgfbi, Parp10, Cd300a ) ([Fig. 5E ]). What's more, Gene Set Enrichment Analysis (GSEA) revealed that the percentage
of Treg downregulation was negatively associated with TGF-β signaling activity in
MDSC-DCs ([Fig. 5F ]). Collectively, these results suggested that CD24+ MDSC-DCs might inhibit polarization of Tregs by secreting cytokines and expressing
coactivators.
Decreasing CCL5 Protein in Culture Medium during In Vitro Differentiation Could also
Induce Similar Cells as CD24+ MDSC-DCs
Next, we tried to figure out if depletion of CCL5 protein during the differentiation
of MDSC-DCs could induce the formation of CD24+ MDSC-DCs, which would be important for CD24+ MDSC-DCs to be applied to clinical application. Previous studies have proved that
CCL5 mainly expressed in T-lymphocyte subsets of blood cells (17,18); our reverse-transcription
polymerase chain reaction (RT-PCR) results also showed that T-lymphocytes was the
main source of CCL5 in splenocytes of tumor-bearing mice ([Fig. 6A ]). We utilized murine CD3 microbeads to get rid of lymphocytes from splenocytes,
then induced MDSC-DCs as previous described, and FACS results showed that lymphocyte-depleted
MDSC-DCs displayed higher expression level of CD24 compared with control (CTR) MDSC-DCs
([Fig. 6B ] and [6 ]).
Fig. 6 Lymphocytes depletion from tumor-bearing mice splenocytes induced CD24+ myeloid-derived suppressive cells-derived DCs (MDSC-DCs). (A ) Relative gene expression of CC chemokine ligand 5 (CCL5) in T-lymphocytes and myeloid
cells isolated from 4T1 tumor-bearing mice was examined by reverse-transcription polymerase
chain reaction (RT-PCR). (B ) Representative histogram plots for expression of CD24 on gated CD11c+ MDSC-DCs. (C ) Mean Fluorescence Intensity (MFI) of CD24 in MDSC-DCs derived from lymphocytes depletion
and control group. (D ) MDSC-DCs coculture with naïve CD4+ T cells isolated from OT-II mice in the presence of 10 ng/mL Ovalbumin323–339 peptide and 5 ng/mL transforming growth factor-β1 (TGF-β1) for 4 days. The ratio
of MDSC-DCs and naïve CD4+ T cells is 1 to 10. After 4-day cultured, the percentage of Tregs was analyzed by
FACS. Representative staining plots of Tregs after 4-day coculture. (E ) FACS qualification of the proportion of Treg cells in the coculture system. (F ) The expression of CCL5 , TGFβ1 , TGFβ3 , IL-12a , IL-12b, and CD24a in control and MDSC-DCsLym-del were analyzed by RT-PCR. (G ) The tumor volume was measured after control and MDSC-DCsLym-del vaccines treated. (H ) Representative pictures of tumors isolated from tumor-bearing mice after control
and MDSC-DCsLym-del vaccines treated. n = 5 mice per group. *p < 0.05, **p < 0.01, ***p < 0.001. Data were represented as mean ± standard deviation.
To further confirm if the characteristics of lymphocyte-depleted MDSC-DCs were similar
to those of CD24+ MDSC-DCs, we first examined the effect of these cells on Tregs polarization, and
results showed that lymphocyte-depleted MDSC-DCs significantly inhibited the generation
of Tregs, compared with control (CTR) MDSC-DCs, which was similar to that of CD24+ MDSC-DCs ([Fig. 6D ] and [E ]). Next, we tested the mRNA levels of Treg-polarization-related genes that had been
demonstrated changed in CD24+ MDSC-DCs by quantitative PCR. The results showed that
the expression of IL-12a, IL-12b, and CD24a was higher and the expression of CCL5,
TGF-β1, and TGF-β3 was lower in lymphocyte-deplete MDSC-DCs compared with control
cells ([Fig. 6F ]), which were same tendency with that of CD24+ MDSC-DCs. At last, the therapeutic effect of lymphocyte-depleted MDSC-DCs based vaccine
was tested in 4T1 tumor-bearing mice and these cells could significantly inhibit tumor
growth, compared with control group ([Fig. 6G ] and H). These results suggested that CCL5-deficiency during in vitro differentiation
could also induce similar cells as CD24+ MDSC-DCs.
Decreasing the Level of CCL5 Protein Could Induce MDSCs from CRC Patients into CD24+ MDSC-DCs
Next, we tried to figure out if depletion of CCL5 protein could induce tumor patients-derived
MDSCs into CD24+ MDSC-DCs with similar antitumor function as murine CD24+ MDSC-DCs. For human CD24+ MDSC-DCs induction, we first collected peripheral blood
samples of CRC patients in TNM Classification of Malignant Tumors (TNM) stage III
or IV and enriched myeloid cells by Ficoll density gradient centrifugation. RT-PCR
results also showed that CCL5 was mainly expressed in T-lymphocytes, but not myeloid
cells (
[Fig. 7A ]). To reduce the influence of CCL5 produced by lymphocytes, we depleted lymphocytes
by human CD3 microbeads and utilized a similar method as what was used in induction
of murine MDSC-DCs. FACS data showed that CD24 expression in MDSC-DCLym-del was significantly higher than that of MDSC-DCCTR , indicating that CD24+ MDSC-DCS could be induced in vitro by getting rid of lymphocytes during the process
of human MDSC-DCs differentiation ([Fig. 7B ] and [C ]).
Fig. 7 Myeloid-derived suppressive cells-derived DCs (MDSCs) from colorectal cancer (CRC)
patients induced CD24+ MDSC-DC. (A ) Relative gene expression of CC chemokine ligand 5 (CCL5) in T-lymphocytes and myeloid
cells isolated from CRC cancer patients was examined by reverse-transcription polymerase
chain reaction. (B ) Representative expression of the indicated surface markers on gated CD11c+ MDSC-DCs from CRC patients' peripheral blood mononuclear cell cultures. The isotype
monoclonal antibody (mAb) of indicated markers was included as controls. (C ) Mean Fluorescence Intensity (MFI) of CD24 in MDSC-DCs derived from CCL5 knockdown
and control group. (D ) MDSC-DCs cocultured with CD4+ T cells isolated from CRC patients peripheral blood for 7 days. The ratio of MDSCs
and CD4+ T cells is 1 to 10 and CD4+ T cells were preactivated by CD3 and CD28 mAbs. After 7-day culture, the percentage
of Tregs was analyzed by FACS. Representative staining plots of Tregs after 7-day
coculture. (E ) FACS qualification of the proportion of Tregs in the coculture system. The coculture
experiment was repeated n = 3 for each group. *p < 0.05, **p < 0.01, ***p < 0.001. Data were represented as mean ± standard deviation.
To test whether CD24+ MDSC-DCS derived from CRC patients' peripheral blood could inhibit Tregs polarization,
CD4+ T cells collected from the peripheral blood of tumor patients were preactivated by
anti-CD3 and anti-CD28 and cocultured with human MDSC-DCS for 7 days. FACS analysis showed that CD24+ MDSC-DCs from tumor patients could significantly inhibit CD4+ T cells from differentiating into Tregs ([Fig. 7D ] and [E ]). These data suggested that not only in mice model, but also in human samples, CD24+ MDSC-DCs with antitumor activity could be induced in vitro in absent of CCL5 protein,
which provides a new method for DC-based vaccine development.
Discussion
In this study, we revealed that CCL5-deficiency MDSCs could be induced into a new
type of DCs with high CD24 expression (CD24+ MDSC-DCs), which had more antitumor activity than control MDSC-DCs. Antibody blocking
and adoptive transfer experiments showed that Tregs mediated the antitumor activity
of CD24+ MDSC-DCs. And CD24+ MDSC-DCs mainly inhibited Tregs' polarization, but not migration of Tregs. What's
important, decreasing CCL5 protein in culture medium of both murine and human MDSCs
during in vitro differentiation could also induce similar cells as CD24+ MDSC-DCs. These data suggest that knockdown of CCL5 levels in vitro might be used
as a new method to induction of patients' peripheral blood monocytes or MDSCs derived
DCs for tumor vaccines and gain higher antitumor activity.
Our previous study had shown that CCL5 could modulate the differentiation of MDSCs
to promote tumor progression in luminal and triple-negative breast cancer.[22 ]
[38 ] And in CRC model, CCL5-deficiency inhibited tumor growth and metastasis by resulting
in the metabolic disorders in CD11bhi F4/80low TAMs and suppressing the expression of S100a9 to promote the migration of CD8+ T cells in the TME.[21 ] All of above studies suggested that CCL5 involved in differentiation of myeloid
cells, besides its chemotaxis function. In this study, we further proved that CCL5
play an important role in the process of immature state of myeloid cells that differentiate
into DCs. What's more, we found that ATRA, an inducer of myeloid differentiation,[26 ]
[27 ] could not only promote the differentiation of CCL5−/− MDSCs and but also enhance the antitumor activity of CD24+ MDSC-DCS, suggesting that the signaling pathways between ATRA and CCL5 involved in
induction of MDSC-DCs had some overlap.
CD24 is a glycosyl-phosphatidyl-inositol-anchored glycoprotein on the plasma membrane
with a small protein core but extensive N-linked and O-linked glycosylation. CD24
is expressed by many immune cells[39 ] and previous studies showed that CD24 is primarily a costimulatory molecule for
T lymphocyte activation in autoimmunity.[28 ] Recently, it was found that CD24 is often overexpressed in human tumors and CD24
on tumor cells was identified as an inhibitor of phagocytosis in “do not eat me” signal
to play a suppressive role via binding to Siglec-10 on macrophages in tumor immunity.[40 ] However, what is the role of CD24 expression on MDSC-DCs? To prevent the phagocytosis
of MDSC-DCs by other immune cells? Or to involve the polarization of CD4 T cells?
The answers to this question might need our further studies to figure out in future
study.
In conclusion, the antitumor activity of CD24+ MDSC-DCs was achieved by inhibiting the polarization of CD4+ T cells toward Tregs, therefore reducing the proportion of Treg in tumor and changing
the immunosuppression of TME. In the process of inducing MDSC-DCs in vitro, we eliminated
lymphocytes and massively obtained CD24+ MDSC-DCs with antitumor activity in the presence of ATRA. This improvement for DC
vaccine provides a new idea for clinical transformation in the future to help tumor
patients improve the efficacy of tumor treatment.
Materials and Methods
Mice and Cell Lines
BALB/c, C57BL/6, and OT-II transgenic mice designated B6.cgTg (TcraTcrb)425Cbn/J were
purchased from the Jackson Laboratory, Bar Harbor, Maine, United States. CCL5-KO BALB/c
and CCL5-KO C57/B6 were acquired as previously described. KO mice have no morphologically
or functionally overt abnormal phenotype. Genotyping was done using PCR of tail DNAs.
Mice were kept in pathogen-free conditions and handled in accordance with the requirements
of the guideline for animal experiments.
The following s.c. tumor models were used: C57/B6 mice, B16F10 melanoma, MC38 colon
carcinoma; BALB/c mice, 4T1 mammary carcinoma, CT26 colon carcinoma. All of these
cell lines were purchased from American Type Culture Collection. The number of tumor
cells injected was different for each model and was selected based on the ability
to form tumor with 1.5 to 2 diameters within 3 to 4 weeks of injection.
Generation of MDSC-DCs from Tumor Bearing Mice
Splenocytes were obtained from spleens of tumor-bearing mice. 10 × 106 splenocytes
were cultured in Roswell Park Memorial Institute (RPMI) 1640 Medium supplemented with
10% fetal bovine serum, 20 ng/mL GM-CSF, 10 ng/mL IL-4, alone or in the presence of
1.5 μM ATRA. The culture was maintained at 37°C in 5% of CO2 -humified atmosphere in tissue-culture-treated 10 cm2 dishes in 15 mL of medium. The culturemediumwas entirely disregarded at day 3 and
replaced by fresh warm medium. On day 7, nonadherent cells in the culture supplement
and loosely adherent cells harvested by gentle scraping with PBS were pooled and used
as the starting source of material for most experiments.
Tumor Digestion and Generation of Single-Cell Suspension
Tumor tissue (300–500 mg) was mechanically minced and digested in 10 mL PBS containing
0.5 mg/mL collagenase A, 0.01 mg/mL DNase I, and 10 U/mL hyaluronidase for 2 hours
at 37°C and shaking at 80 rpm. The dissociated cells were collected, lysed by red
blood cell lysis buffer. Then cell suspensions were filtered through a 70-μm nylon
mesh. After centrifugation, cells were suspended in FACS buffer (2% (fetal calf serum
[FCS], 2mM ethylenediaminetetraacetic acid [EDTA] in PBS) and immediately used for
flow cytometry.
Flow Cytometry
Cells that were obtained from blood, spleen, lymph, or tumor were stained in ice-cold
PBS containing FCS (2%) and EDTA (2 mM) using appropriate antibody-fluorophore conjugates.
The concentration of a single-cell suspension was adjusted to 1 × 106 –107 /mL. Multiparameter analysis was performed on a Fortessa analyzer (BD Biosciences)
and analyzed with FlowJo software (Tree Star).
In Vivo Depletion of Treg Cells
Treg depletion was performed by a single injection of 200ug purified anti-CD25 mAb(PC61).
4T1 bearing mice were treated intraperitoneally with anti-CD25 antibody at day 16
after tumor challenge.
Adoptive Transfer of Isolated-Treg Cells
CD4+ CD25+ Tregs were purified from minced spleens obtained from female mice using
magnetic bead separation (CD4+ CD25+ Treg kit, Miltenyi Biotec). Cells were cultured
in RPMI-1640 media supplemented with 10% fetal bovine serum, 10,000 IU/mL penicillin,
10 mg/mL streptomycin, 1x GlutaMAX. Recombinant murine IL-2 were added at the concertation
of 2,000 IU/mL. Tregs were activated with Dynabeads anti-CD3/CD28 CTS anti-CD3/anti-CD28-coated
microbeads at a 2:1 bead/cell ratio. After 48-hour stimulation, magnetic beads were
removed according to manufacturer's instruction and cells were harvested for adoptive
transfer. At the onset of MDSC-DC treatment cases, 1 × 106 iTregs were adoptively transferred into MDSC-DCs vaccine-recipient mice (n = 5 per group) via the tail vein at day 16. Control mice were treated with PBS alone.
All the mice were sacrificed at day 30 after tumor inoculation or the time when tumor
volume reached 2 cm3 .
Murine naïve CD4+ T Cells Coculture with MDCS-DCs
Murine naïve CD4+ T cells were purified from minced spleens obtained from OT-II transgenic
mice by Ficoll-hypaque solution and naïve CD4+ T cells isolation kit according to
manufacturers' protocols. MDSC-DCs were cocultured with isolated CD4+ CD62L-OT-II
cells in RPMI at 37°C, 5% CO2 in a ratio 1MDSC-DC: 10 T cells. When stated, 40 µg/mL OVA323–339 peptide, 100 ng/mL LPS, and 5ng/mL TGF-β1 were added. Cells were harvested after
4 days of coculture and analyzed by flow cytometry.
Depletion of Lymphocytes by CD3 Microbeads
Splenocytes were harvested from 4T1 tumor-bearing mice and peripheral blood mononuclear
cells were harvested from peripheral blood samples of CRC patients in TNM stage III
or IV. T cells labeled with anti-CD3-coated beads were depleted with a commercially
available magnetic separation kit (CD3 microbeads, Miltenyi Biotec) with either for
human or for mouse.
Quantitative RT-PCR
Samples for gene expression analysis were homogenized with 1mL TRI reagent (Invitrogen)
to extract total RNA. cDNA was synthesized by reverse transcription of total RNA (Epicentre).
Gene expression was probed using the following primer pairs: CCL5 (F, 5′-CAGTCGTCTTGTCACCCGA-3′;
R, 5′-TGTAACTGCTGCTGTGTGGT -3′), TGFB1 (F, 5′-GAGTGGTTTGTTTGAGATGT-3′; R, 5′-GGTTCGTGCATCCATTTCCA
-3′), TGFB3 (F, 5′-GGAAAACACCGAGTCGGAATAC-3′; R, 5′-GCGGAAAACCTTGGAGGTAAT-3′) IL12A
(F, 5′-ACCACTCCCAAAACCTGC-3′; R, 5′-CCAGGCAACTCCCATTAG-3′) and IL12B (F, 5′-ACAAAGGAGGCGAGGTTCTG-3′;
R, 5′-CTGTGGTCCATGCTGACTT-3′). GAPDH (F, 5′-GGAGCCAAAAGGGTCATCATCTC-3′; R, 5′-GAGGGGCCATCCACAGTCTTCT-3′)
was used as a reference gene for normalization.
Study Approval
All animal procedures were reviewed and approved by the Institutional Animal Care
and Use Committee of Shanghai Jiao Tong University (BME (Ethics) 2017002).
All human samples were collected with the informed consent of the patients and the
procedures were approved by Renji Hospital of Shanghai Jiao Tong University (Renji
[2017] N017).
Statistical Analysis
The Student's t -test was used to analyze the data. Results are given as mean ± standard error of
mean unless otherwise indicated. p < 0.05 was considered statistically significant.
