Abstract
Myeloid derived suppressor cells (MDSC) are a heterogeneous group of immature cells that accumulate in the peripheral blood and tumor microenvironment and are barriers to cancer therapy. MDSCs serve as prognostic biomarkers and are targets for therapy. On the basis of surface markers, three subsets of MDSCs have been defined in humans: granulocytic, monocytic, and early stage (e-MDSC). The markers attributed to e-MDSCs overlap with those of basophils, which are rare circulating myeloid cells with unrecognized roles in cancer. Thus, we asked whether e-MDSCs in circulation and the tumor microenvironment include basophils. On average, 58% of cells with e-MDSC surface markers in blood and 36% in ascites from patients with ovarian cancer were basophils based on CD123high expression and cytology, whereas cells with immature features were rare. Circulating and ascites basophils did not suppress proliferation of stimulated T cells, a key feature of MDSCs. Increased accumulation of basophils and basogranulin, a marker of basophil degranulation, were observed in ascites compared to serum in patients with newly diagnosed ovarian cancer. Basophils recruited to the tumor microenvironment may exacerbate fluid accumulation by their release of proinflammatory granular constituents that promote vascular leakage. No significant correlation was observed between peripheral basophil counts and survival in patients with ovarian cancer. Our results suggest that studies in which e-MDSCs were defined solely by surface markers should be reevaluated to exclude basophils. Both immaturity and suppression are criteria to define e-MDSCs in future studies.
Introduction
Myeloid-derived suppressor cells (MDSC) are an immature, heterogeneous group of myeloid cells that suppress T-cell responses (1, 2). In cancer, disordered myelopoiesis driven by tumor-derived factors (e.g., G-CSF, GM-CSF, and IL6) can result in an expansion of immature suppressive myeloid cells that impairs antitumor immunity. In addition, MDSCs can secrete proangiogenic factors that facilitate tumor progression.
Two MDSC subpopulations have been described in tumor-bearing mice: granulocytic (CD11b+Ly6G+Ly6Clow) and monocytic (CD11b+Ly6G−Ly6Chigh) cells. These myeloid cells expand in various organs, including bone marrow, blood, secondary lymphoid organs, and within tumor (3–5). Because of difficulties in obtaining and purifying MDSC populations from the tumor microenvironment, most human studies focus on circulating MDSCs. Consensus guidelines define granulocytic MDSCs (polymorphonuclear MDSCs, PMN-MDSC) as CD11b+CD14−CD115+ or CD11b+CD14−CD66b+ and monocytic MDSCs (M-MDSC) as CD11b+CD14+HLA-DR–/lowCD15− (6). Although M-MDSCs are CD33high, PMN-MDSCs are CD33dim. Early-stage MDSCs (e-MDSC) likely a mixed group of immature progenitor cells, are defined as Lin− (including CD3, CD14, CD15, CD19, CD56) and HLA-DR−CD33+ (6, 7). In contrast to conventional mature normal-density neutrophils, MDSCs, including various maturation stages of PMN-MDSCs, cosediment with peripheral blood mononuclear cells (PBMC) following density gradient separation. Because expression of surface markers does not uniquely define MDSCs, functional assays can further identify MDSCs through their ability to inhibit T-cell activity. However, these functional assays are often not performed because of the paucity of MDSCs in human samples and the practical limitations of performing such labor-intensive studies when large numbers of patients’ samples are used for epidemiologic or biomarker studies. Thus, the identification of putative MDSCs based on surface marker expression of myeloid cells within the PBMC fraction is commonly used as a practical standard for MDSC quantification. Although MDSCs are typically defined as immature, microscopic analysis of putative MDSCs to demonstrate immaturity is not performed routinely and not a part of consensus criteria for defining MDSCs. MDSC status as immature underlies the rationale for therapeutic approaches intended to drive differentiation of immature suppressive cells into mature nonsuppressive myeloid cells (8–10).
Almand and colleagues (11) described the expansion of circulating myeloid cells in patients with cancer that were defined by morphologic immaturity, CD33+CD15−CD14−HLA-DR− expression, and suppression of antigen-specific T-cell responses. These findings established the foundation for the subsequent definition of MDSCs. Of the three MDSC populations, e-MDSCs are considered to be the least mature (hence the description “Early stage”) based on lack of expression of granulocytic or monocytic markers. e-MDSCs have been identified on the basis of surface markers in circulating myeloid cells, and, to a lesser extent, in myeloid cells in the tumor microenvironment of various cancers (12–16) without well-defined morphologic criteria. Additional MDSC subsets have been defined based on variation in surface markers (16). The fraction of e-MDSCs in PBMCs is similar between healthy donors (about 1%) and patients with head and neck cancer and patients with ovarian cancer, and does not correlate with survival (13, 16). Although higher amounts of circulating e-MDSCs are evident in patients with ovarian cancer (0.06%) than healthy donors (0.01%), the fraction of circulating e-MDSCs does not correlate with survival (15). Putative circulating e-MDSCs from patients with head and neck cancer (13) and from patients with ovarian cancer (16) show little to no T-cell suppression ex vivo depending on the mode of T-cell stimulation. These findings suggest that the population of cells defined in the field as e-MDSCs shows inconsistent immunosuppressive properties. Improved definition of e-MDSCs will aid study of their functional roles in the tumor microenvironment.
Basophils are a subset of myeloid cells that make up only about 0.5% of circulating leukocytes, mediate antiparasitic host defense, and drive allergic and anaphylactic disorders (17). IL3 promotes development of progenitor cells. Its receptor CD123 (IL3R-α) is expressed on common myeloid progenitors (18, 19). CD123 expression is lost in most mature myeloid cells, although expression is retained in plasmacytoid dendritic cells (DC) and mature basophils. Surface markers of basophils (CD33+CD14−CD15−HLA-DR−CD3−CD19−CD56−; ref. 20) and e-MDSCs overlap. Indeed, basophils may contaminate samples identified as circulating e-MDSCs (21). We therefore evaluated the putative e-MDSC population in circulation and in the tumor microenvironment of patients with newly diagnosed metastatic ovarian cancer. We found that, in healthy donors and in patients with newly diagnosed metastatic ovarian cancer, an average of 58% of what has been defined as circulating e-MDSCs were actually basophils. In addition, basophils constituted an average of 36% of the putative e-MDSC population in the ascites of patients with ovarian cancer, whereas cytologically immature myeloid cells that could be e-MDSCs were rare. Purified basophils from blood and ascites of patients with ovarian cancer did not suppress stimulated T-cell proliferation. Peripheral basophils from healthy donors did not suppress stimulated T-cell proliferation nor did they acquire a suppressor phenotype when cultured with ovarian cancer ascites supernatants. The peripheral basophil concentration at diagnosis did not correlate with subsequent progression-free survival (PFS) or overall survival (OS) of patients with ovarian cancer. Together, our results demonstrate the need to reevaluate prior studies of e-MDSCs based on the potential for basophil contamination and to exclude basophils from future studies of e-MDSCs. We propose criteria for defining e-MDSCs that include morphologic evidence of immaturity and suppressive function.
Materials and Methods
Patients and specimens
Participants included healthy donors (HD), patients with benign adnexal mass undergoing resection surgery, and patients with advanced ovarian cancer. Blood and ascites samples were prospectively collected from patients with newly diagnosed advanced ovarian cancer during 2015–2019 at Roswell Park Comprehensive Cancer Center (Roswell Park, Buffalo, NY), as described previously (22). Blood samples were collected prior to primary surgeries, and ascites were collected either by diagnostic paracentesis or in the operating room prior to surgery. Serum was collected from peripheral blood of healthy donors (n = 3) and patients with ovarian cancer (n = 17). Ascites were filtered through 300-μm filters and then centrifuged (500 × g, 10 minutes). Serum and ascites supernatants were stored at −80°C until further use and ascites cells were preserved (in RPMI 1640 + 5% DMSO + 20% FBS) in liquid nitrogen. When available, postoperative fluid from an abdominal drainage tube was collected the day after primary surgery for ovarian cancer. Ascites and postoperative fluid were evaluated for complete blood count (CBC) with differential prior to processing. The medical records of these patients were retrospectively reviewed for demographics, tumor stage and grade, and peripheral blood CBC with differential. The electronic medical records of 325 patients with ovarian cancer who underwent debulking surgery followed by standard adjuvant chemotherapy at Roswell Park from 1995 to 2015 were also retrospectively reviewed for pretreatment basophil concentrations, demographics, FIGO stage, histology, debulking status, PFS, and OS.
Study approval
This study was approved by the Institutional Review Board of Roswell Park and followed federal and state requirements. All participants gave written informed consent prior to inclusion in the study (protocols I-215512 and I-188310). All studies were conducted in compliance with the Declaration of Helsinki.
Isolation and characterization of e-MDSCs in peripheral blood and ascites
PBMCs were isolated from peripheral blood of patients (n = 18) and healthy donors (n = 5) using lymphocyte separation media (Mediatech, 25-072-CV) and SepMate tubes (Stemcell, 85450) following manufacturer's protocol. PBMCs were used fresh or cryopreserved. Cell count and viability were assessed by Trypan blue staining. CD3+ cells were depleted from PBMCs and ascites cells (n = 5) using CD3 microbeads (Miltenyi Biotec, 130-050-101) and autoMACS. CD3-depleted PBMCs were analyzed by flow cytometry after staining with anti-human CD45, CD11b, CD33, CD14, CD15, HLA-DR, CD123, CD11c, CD303 mAb (Supplementary Table S1) and L/D-Aqua (Thermo Fisher Scientific, L34959). Nonaggregate and viable CD45+CD11b+CD33+ cells were gated to get CD15−CD14− fractions and those cells were gated to obtain HLA-DR−CD123+ and HLA-DR−CD123− cells. CD45+CD11b+CD33+CD14−CD15−HLA-DR− CD123high (putative basophils), CD45+CD11b+CD33+CD14−CD15− HLA-DR+CD123mid (putative DCs), and CD45+CD11b+CD33+ CD14−CD15−HLA-DR−CD123− (HLA-DR−CD123−) L/D-aqua-negative cells from PBMCs and ascites cells were flow sort-purified and assessed by cytology. Purified ascites-basophils were also assessed for T-cell suppression.
Cytology slide preparation, staining, and review
Cytospins were prepared using sort-purified cells from PBMCs and ascites cells, micro slides (VWR, 48311-703) and a Shandon Cytospin2 Centrifuge. A Wright-Giemsa staining protocol was used. Slides were fixed with methanol (1 minute), residual methanol was decanted, and slides were stained with a modified-Wright stain (Sigma-WS-128, 0.3%, buffered at pH 6.9 in methanol, contains stabilizer and surfactant; 5 minutes). Three milliliter layers of freshly prepared modified-Giemsa stain (Sigma-GS-128, 0.4% in buffered methanol solution pH 6.8 with stabilizers) were placed onto the slides for 30 minutes. Afterwards, slides were rinsed with tap water, air dried, rinsed with methanol, and washed under running tap water, dried and then coverslips were placed. Toluidine blue staining was performed to confirm magenta-colored staining of basophil granules. Morphologic evaluation was performed by a hematopathologist (to J.T. Wong).
ELISA
The levels of basogranulin in frozen serum samples, supernatants collected from ascites and day-1 postoperative drainage fluid samples of patients with ovarian cancer were plated in duplicate wells and analyzed by human basogranulin ELISA kit (MyBiosource, MBS2602918), following the manufacturer's protocol.
Assessment of suppressive function of basophils
We previously observed that circulating neutrophils acquire a suppressor phenotype when incubated with ovarian cancer ascites and other malignant fluid supernatants (23, 24). In this study, neutrophils were used as a comparator with basophils in T-cell suppression assays. Neutrophils and T cells were isolated from peripheral blood (HD) <1 hour postcollection using the MACSxpress Neutrophil Isolation Kit (Miltenyi Biotec, 130-104-434) and the Pan T-cell Isolation Kit (Miltenyi Biotec, 130-098-193), respectively. The purity of neutrophils was >90% based on cytology and CD33midCD15+ expression. The purity of T cells was >90% based on CD45+CD3+, CD45+CD3+CD4+ and CD45+CD3+CD8+ expression. Circulating basophils were isolated from PBMCs of HD (fresh) and patients with ovarian cancer (cryopreserved) using the basophil isolation kit II (Miltenyi Biotec, 130-092-662) and autoMACS. The purity of basophils was >90% based on cytology and viability was >95% based on Trypan blue exclusion. Freshly isolated T cells (1 × 105) were stimulated with anti-CD3/CD28 Dynabeads (2.5 μL; Thermo Fisher Scientific, 11132D) and cocultured with basophils or neutrophils (from HD in 1:1 ratio) and ascites supernatants (50% final well volume) in a 5% CO2 incubator at 37°C. Similarly, stimulated T cells (1 × 105) were used in coculture with circulating basophils from patients with ovarian cancer (1:1 ratio) in media. Because of limited recovery of sort-purified basophils from cryopreserved ovarian cancer ascites cells, a lower number of basophils (0.5 × 105) and T cells (1:1 ratio) were used in coculture. After 72 hours, [3H] thymidine (1 μCi per well, PerkinElmer, NET027X001MC) was added and allowed to incorporate for 16–18 hours. Cells were harvested onto a filter mat and counted on a beta counter. Results are expressed as net CPM = average CPM of stimulated T–average CPM of unstimulated T cells.
Statistical analysis
Comparisons between two groups were assessed by the Mann–Whitney test (two-tailed) using Graph Pad Prism 8.3.0 (538). A nominal significance threshold of 0.05 was used for P values. The association between basophil concentration prior to surgery and PFS/OS was assessed using a Cox regression model adjusting for standard prognostic factors: age, FIGO stage, histology, and surgical debulking (R0 vs. other) using R 3.4.0 statistical language.
Results
Putative circulating e-MDSCs, with and without cancer, contain basophils
Because putative e-MDSCs and basophils are present at low frequencies in peripheral blood and express overlapping surface markers, we asked to what extent basophils are components of the e-MDSC fraction. On the basis of consensus recommendations (6), we defined putative e-MDSCs as CD3−CD45+CD33+CD11b+CD14−CD15− HLA-DR−. Basophils were defined on the basis of the same surface expression criteria, but with the addition of CD123high (20, 25). CD123 is highly expressed on basophils, but its expression can be reduced with basophil activation (26).
CD3-depleted frozen or fresh PBMCs from patients with ovarian cancer and healthy donors were analyzed for CD123-expressing cells. Representative plots show that CD3−CD45+CD33+CD11b+CD14− CD15− fractions contain three populations based on CD123 and HLA-DR expression: (i) HLA-DR−CD123high, (ii) HLA-DR−CD123−, and (iii) HLA-DR+CD123mid (occasionally, distinct HLA-DR+CD123mid and HLA-DR+CD123low populations were observed; Fig. 1A–D). Because e-MDSCs are HLA-DR−, we sort-purified HLA-DR− CD123high and HLA-DR−CD123− populations for morphologic evaluation. We found that the CD123high cells were basophils (Fig. 1E). Basophils are round to ovoid in shape, range in size from 10 to 15 μm in diameter, and have basophilic cytoplasmic granules that are coarse and blue-black or purple-red. The presence of coarse granules in basophils was confirmed by toluidine blue staining (Fig. 1E, middle). Mature basophils have segmented nuclei and clumped chromatin. The segmented nuclei usually have 2–3 lobes but can range from 1–4 lobes. Cryopreserved basophils showed variable degranulation, which might be a freeze–thaw artifact (Fig. 1E, right). The CD45+CD33+CD11b+ CD14−CD15− cell fraction in PBMCs also contains a variable percentage (6%–74%) of HLA-DR+CD123mid cells, that were in some samples divided into CD123mid and CD123low populations (Fig. 1D).
The CD123− cells population contained agranular mononuclear cells, including lymphocytes and monocytes. Lymphocytes are generally 7–15 μm in diameter with round to ovoid nuclei, diffusely dense to clumped chromatin and scant agranular cytoplasm (Fig. 1F). Monocytes are usually larger than lymphocytes (12–20 μm in diameter) with variably shaped nuclei, (including indented, band-shaped, folded, and nonspecifically irregular), mature-appearing chromatin, and moderate amounts of cytoplasm (Fig. 1F, left). Agranular mononuclear cells with more round nuclei, higher nuclear–cytoplasmic ratio, and nucleoli were also present among CD123− cells and may represent immature myeloid cells.
Additional frozen samples of circulating PBMC from patients with ovarian cancer were analyzed for CD123+ basophils in putative e-MDSC fractions. Without exclusion of CD123high cells, the proportion of putative e-MDSCs in the PBMCs fraction ranged between 0% and 1.77%; after exclusion of CD123+ cells, the proportion ranged between 0% and 0.38% when gated on CD45+ cells (Fig. 2A). Figure 2B shows a range in the proportion of basophils within the putative e-MDSC population and demonstrates that basophils comprised a substantial proportion (mean = 58%) of putative e-MDSCs in patients with ovarian cancer. Similarly processed circulating PBMCs from healthy donors showed a proportion of basophils ranging from 81% to 97%, whereas a patient with benign adnexal mass had 72% basophils in the putative e-MDSC fraction (Fig. 2B). Thus, in patients with ovarian cancer, basophils make up 58% of the cells in the putative circulating e-MDSC population defined by existing criteria of surface antigen expression and morphology.
Variable proportions of basophils accumulate in the ovarian cancer microenvironment
Previously, we observed variable numbers of CD33+CD14−CD15− HLA-DR− cells in the ascites of patients with ovarian cancer (12) and have now found basophils in the putative peripheral e-MDSC population from patients with ovarian cancer. We next evaluated phenotypic and morphologic characteristics of the putative e-MDSCs in the ascites from patients with newly diagnosed metastatic ovarian cancer. Ascites was drained prior to debulking surgery and cells in ascites were cryopreserved. After thawing and CD3+ T-cell depletion, cells in the putative e-MDSC fraction were sort-purified into CD123high and CD123− populations and analyzed by cytology. Similar to circulating PBMCs, the putative e-MDSCs fraction in ascites contains variable proportions of CD123+ and CD123− cells (Fig. 3A–D; Supplementary Fig. S1A–S1D). HLA-DR−CD123high cells comprised 36% (range 15%–71%) of the putative e-MDSC population (n = 5). Cytologic review of HLA-DR−CD123high cells shows variably degranulated granulocytic cells that are morphologically most consistent with basophils (Fig. 3E), whereas HLA-DR−CD123− cells were mostly lymphocytes and monocytes (Fig. 3F). The HLA-DR−CD123− fractions of ascites cells also contained presumptive immature myeloid cells based on high nuclear to cytoplasmic ratio, rounder nuclei, finer chromatin, and presence of nucleoli (Fig. 3F, box). Differential counts performed on representative slides of circulating and ascites cells showed that immature cells comprised approximately 20%–30% of the HLA-DR−CD123− fraction. On the basis of surface expression and morphology, this may be the population of immature myeloid cells expanded in patients with cancer (11) and defined as MDSCs. However, these cells were too few to assess for T-cell suppression, and therefore we are unable to determine whether they are actual MDSCs. Thus, the putative e-MDSC fraction in ovarian cancer ascites is composed of a variety of cell types, including basophils; morphologically immature myeloid cells are about 20%–30% of the HLA-DR−CD123− fraction.
Similar to circulating PBMCs (Fig. 1D), a variable percentage (19%–90%) of HLA-DR+CD123mid cells was observed in CD45+ CD33+CD11b+CD14−CD15− cell fraction of ovarian cancer ascites (Fig. 3D; Supplementary Fig. S1A–S1D). From surface expression (CD11c+ and CD11b+) and morphology, these HLA-DR+CD123mid cells resemble myeloid DCs, although they are also CD303+, which is expressed on plasmacytoid DCs. In some of the ascites samples, HLA-DR+CD123mid cells had plasmacytoid DC morphology (Supplementary Fig. S1E and S1F). These results suggest that both HLA-DR and CD123 should be used to identify putative e-MDSCs by flow cytometry and, by extension, immunostaining of tumor samples.
Basophils feature in ascites of ovarian cancer and increase following surgery
Because the microenvironment in advanced ovarian cancer is inflammatory and injurious (24, 27, 28) and basophils play a role in inflammation and in wound healing (17, 29), we compared basophil concentrations in blood, ascites and postoperative peritoneal drainage fluids. We found that the percentage of basophils in blood from patients with ovarian cancer are within normal range (<2%), whereas the percentage of basophils in paired ascites are variable (0%–7%) and significantly (P = 0.008) higher than the amounts in blood (Fig. 4A). In a cohort of 5 patients with ovarian cancer with banked postoperative fluid supernatants 1 day after debulking surgery, the percentage of basophils was higher in postoperative drainage fluid than preoperative blood (Fig. 4B). Basogranulin is located in basophil granules (30), and its release is a marker of basophil activation (30, 31). Elevated plasma basogranulin is observed in patients with allergic asthma (32). Because basophil concentrations were elevated in the ascites and postoperative fluid versus blood, we evaluated basogranulin amounts in serum, ascites, and postoperative drainage fluid samples from patients with ovarian cancer. Like healthy donor serum, basogranulin was generally not detectable in the serum of patients with newly diagnosed ovarian cancer. In contrast, patients with ovarian cancer had significantly higher basogranulin amounts in ascites and postoperative drainage fluid than in serum (Fig. 4C). These results point to increased basophil accumulation and degranulation at sites of injury, both in the tumor microenvironment and following surgery.
Basophils are not immunosuppressive in the ovarian cancer microenvironment
Although circulating neutrophils in healthy donors and in patients with newly diagnosed metastatic ovarian cancer are not suppressive, circulating neutrophils acquire a suppressor phenotype, defined as abrogation of stimulated T-cell proliferation, following exposure to ovarian cancer ascites supernatants (23, 24). Because the putative e-MDSCs fraction in peripheral circulation and ovarian cancer microenvironment contains basophils, we asked whether ovarian cancer ascites can induce peripheral basophils to become T-cell suppressive. Basophils incubated in media or in ascites supernatants from patients with ovarian cancer did not suppress anti-CD3/CD28-stimulated proliferation of healthy donor T cells, whereas neutrophils exposed to ascites acquired a suppressor phenotype (Fig. 4D). Next, we evaluated the T-cell–suppressive capacity of basophils isolated from peripheral blood or ascites of patients with ovarian cancer. Viable basophils magnetically isolated from PBMCs did not suppress stimulated T-cell proliferation (Fig. 4E). Similarly, sort-purified basophils from ovarian cancer ascites cells were not T-cell suppressive (Fig. 4F). Together, these data show that basophils in circulation and in ascites of ovarian cancer are not T-cell suppressive and that normal basophils do not acquire a T-cell suppressive phenotype in ovarian cancer ascites.
Basophil concentrations in blood are not independent prognostic factors in ovarian cancer
We next performed a retrospective analysis of pretreatment basophil concentrations from CBC and differential recordings and PFS and OS in 325 patients with newly diagnosed ovarian cancer who underwent debulking surgery followed by standard adjuvant chemotherapy at Roswell Park. Patient demographics, clinicopathologic features, and summary of basophil concentrations are shown in Tables 1 and 2. Baseline peripheral basophil concentrations (0.01–0.17 × 103/μL) were not associated with PFS (median 20 months) or OS (median 48.8 months) when analyzed using a Cox regression model adjusting for standard prognostic factors: age, FIGO stage, histology, and surgical debulking (Table 3). These data show that basophil concentrations in blood are not independent prognostic factors in ovarian cancer.
Discussion
Because MDSCs are considered potential prognostic biomarkers and various therapeutic studies aim to deplete MDSCs or alter their function to enhance antitumor immunity, it is essential to define MDSC subsets accurately in a standardized and reproducible fashion. We found that mature basophils, based on surface markers and cytology make up an average of 58% of the putative e-MDSC fraction in peripheral blood and 36% in ascites from patients with ovarian cancer. Basophils from circulation and tumor microenvironment of patients with ovarian cancer are not immunosuppressive and peripheral basophils from healthy donors do not acquire a suppressor phenotype in the ovarian cancer microenvironment.
Uhel and colleagues (21) showed that CD123+ basophils comprised 68% of the putative e-MDSC fraction of circulating PBMC from patients with B-cell lymphoma, whereas the CD123− fraction included immature myeloid cells with agranular cytoplasm-containing vacuoles morphologically consistent with e-MDSCs. These results and our studies of basophils in circulation and in the tumor microenvironment raise a cautionary note in defining e-MDSCs based on standard surface markers. Because our study was small and restricted to patients with newly diagnosed ovarian cancer, we cannot make generalizations about e-MDSCs in patients with different cancer types or other chronic inflammatory diseases or disorders. Nonetheless, at a minimum, we recommend that studies of e-MDSCs include the following criteria: (i) demonstration of immaturity based on standard morphologic criteria; (ii) exclusion of basophils; and (iii) evidence of suppression of T cells.
In addition to basophils (CD123highHLA-DR−), there were CD123dimHLA-DR+ cells in purified CD45+CD33+CD11b+CD14− CD15− cell fraction of PBMC and ascites cells from patients with OC, which may be dendritic cells. The remaining populations included CD123−HLA-DR− cells, which, based on cytology, consisted of monocytes, lymphocytes, and cells that may be immature myeloid cells. Monocytes and lymphocytes should have been excluded by sorting, which points to the potential for contamination even with purification by sorting when attempting to isolate rare cells from large populations. As the morphologically immature cells within the putative e-MDSC population were rare, we could not sort-purify them for functional studies; these cells should not be defined as e-MDSCs.
We observed increased accumulation of basophils in ascites and in postoperative drainage fluid compared with circulating basophils in patients with newly diagnosed ovarian cancer. Basogranulin, a marker of activated basophils (33), was variably elevated in ascites and post-operative drainage fluid, but not in serum. Activated basophils can participate in the complex network of inflammation and angiogenesis by releasing various molecules such as histamine, platelet activation factor and VEGF, and by priming Th2 responses (34, 35). These findings suggest that basophils may be involved in the chronic inflammatory response in the ovarian cancer microenvironment and also in the wound healing response after surgery. Basophil recruitment to the tumor microenvironment may aggravate fluid accumulation by the release of proinflammatory granular constituents that promote vascular leak.
Although the role of basophils in allergic disorders and anaphylaxis is established, the role of basophils in the tumor microenvironment is relatively unexplored. Basophils and mast cells express similar receptors and cytokines and infiltrate tissue in the presence of inflammation. Basophil-derived IL4 contributes to differentiation of monocytes into M2-macrophages in an allergic skin model (36). An increased percent of IL4-expressing basophils in tumor-draining lymph nodes correlated with increased tumor-infiltrating Th2 cells and worse disease-free survival after surgery in patients with pancreatic cancer (35). Mast cells can augment the activity of PMN-MDSCs through CD40L–CD40 interaction, resulting in impaired antitumor immunity and increased tumor growth in murine prostate cancer (37). These findings and our results point to the need for further investigation of the role of basophils in regulating immune responses in the tumor microenvironment.
Associations between circulating basophils with various hematologic and solid tumors and with clinical outcomes are variable. Pretreatment circulating basophil counts were associated with recurrence in patients who received bacillus Calmette-Guerin after transurethral resection of the bladder tumor (38). Pretreatment basophil counts did not correlate with survival in gastric cancer (39), whereas a higher basophil count was associated with improved outcome in patients with colorectal cancer (40) and in patients with melanoma who received checkpoint inhibitor therapy (41). With a clear distinction between basophils and e-MDSCs, the field will be better equipped to evaluate the roles of these cell populations in the context of newly diagnosed cancer and in response to therapy.
Disclosure of Potential Conflicts of Interest
K. Odunsi reports receiving commercial research grants from AstraZeneca and Tessaro and has ownership interest (including patents) in TCRs and Tactiva Theraputics. No potential conflicts of interest were disclosed by the other authors.
Disclaimer
The opinions expressed in this article are the author's own and do not reflect the view of the NIH, the Department of Health and Human Services, or the US government. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Authors' Contributions
Conception and design: A.N.H. Khan, T.R. Emmons, E. Alqassim, K.B. Moysich, S.I. Abrams, B.H. Segal
Development of methodology: A.N.H. Khan, T.R. Emmons, K.H. Eng, B.H. Segal
Acquisition of data (provided animals, acquired and managed patients, provided facilities, etc.): A.N.H. Khan, T.R. Emmons, E. Alqassim, J. Mark, B.E. Smith, J.D. Tario
Analysis and interpretation of data (e.g., statistical analysis, biostatistics, computational analysis): A.N.H. Khan, T.R. Emmons, J.T. Wong, E. Alqassim, K.L. Singel, J. Mark, B.E. Smith, J.D. Tario, K.H. Eng, K.B. Moysich, B.H. Segal
Writing, review, and/or revision of the manuscript: A.N.H. Khan, T.R. Emmons, J.T. Wong, K.L. Singel, J. Mark, K.H. Eng, K.B. Moysich, K. Odunsi, S.I. Abrams, B.H. Segal
Administrative, technical, or material support (i.e., reporting or organizing data, constructing databases): A.N.H. Khan, K.H. Eng, S.I. Abrams
Study supervision: B.H. Segal
Acknowledgments
This work was supported by Roswell Park Comprehensive Cancer Center grants NCI P30CA016056, the Roswell Park-University of Pittsburgh Cancer Institute (UPCI) Ovarian Cancer SPORE P50CA159981 (to K. Odunsi), R01CA172105 (to S.I. Abrams), R01CA188900 (to B.H. Segal and K.B. Moysich), T32085183 (to K.L. Singel), and T32CA108456 (to J. Mark).
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.