Research Article
The Tumor Microenvironment Shapes Lineage,Transcriptional, and Functional Diversity of InfiltratingMyeloid Cells
Kutlu G. Elpek1, Viviana Cremasco1, Hua Shen4,5, Christopher J. Harvey1, Kai W. Wucherpfennig1,Daniel R. Goldstein4,5, Paul A. Monach2, and Shannon J. Turley1,3
AbstractMyeloid cells play important regulatory roles within the tumor environment by directly promoting tumor
progression and modulating the function of tumor-infiltrating lymphocytes, and as such, they represent apotential therapeutic target for the treatment of cancer. Although distinct subsets of tumor-associated myeloidcells have been identified, a broader analysis of the completemyeloid cell landscape within individual tumors andalso across different tumor types has been lacking. By establishing the developmental and transcriptomicsignatures of infiltrating myeloid cells from multiple primary tumors, we found that tumor-associated macro-phages (TAM) and tumor-associated neutrophils (TAN), while present within all tumors analyzed, exhibitedstrikingly different frequencies, gene expression profiles, and functions across cancer types.We also evaluated theimpact of anatomic location and circulating factors on themyeloid cell composition of tumors. Themakeup of themyeloid compartment was determined by the tumor microenvironment rather than the anatomic location oftumor development or tumor-derived circulating factors. Protumorigenic and hypoxia-associated genes wereenriched in TAMs and TANs compared with splenic myeloid-derived suppressor cells. Although all TANs had analtered expression pattern of secretory effector molecules, in each tumor type they exhibited a unique cytokine,chemokine, and associated receptor expression profile. One such molecule, haptoglobin, was uniquely expressedby 4T1 TANs and identified as a possible diagnostic biomarker for tumors characterized by the accumulation ofmyeloid cells. Thus, we have identified considerable cancer-specific diversity in the lineage, gene expression, andfunction of tumor-infiltrating myeloid cells. Cancer Immunol Res; 2(7); 655–67. �2014 AACR.
IntroductionThe tumor microenvironment contains a multiplicity of
stromal cells of hematopoietic and nonhematopoietic develop-mental origin, such as T cells, B cells, natural killer (NK) cells,myeloid cells, fibroblasts, pericytes, adipocytes, and endothelialcells,which collectively shape thedisease course (1–4). Althoughspecific roles have been identified for discrete stromal subsets,factors controlling their recruitment, expansion, and function indifferent tumors remain enigmatic. Therefore, a more completecharacterization of these subsets and a better understanding of
how they are recruited to and expand within growing tumorsand metastases are of utmost importance to developing noveltherapies and improving existing ones against cancer.
Tumor growth is associated with the accumulation of avariety of myeloid cell types (2). Common myeloid cell pro-genitors in the bone marrow can give rise to myeloid cells withimmunosuppressive potential, often referred to as myeloid-derived suppressor cells (MDSC). Monocyte-like CD11bþ
Gr1low and granulocyte/neutrophil-like CD11bþGr1hi subsetsof MDSCs have been reported to accumulate in the spleen,liver, blood, and bone marrow during tumor progression.Within tumors, myeloid cells with similar phenotypes arereferred to as tumor-associated macrophages (TAM) or neu-trophils (TAN), possibly reflecting a more differentiated iden-tity. In vitro studies have shown that differentiation of bonemarrow progenitors into MDSCs requires a combination ofcytokines, particularly interleukin (IL)-6 and granulocyte col-ony-stimulating factor (G-CSF) or granulocyte macrophagecolony-stimulating factor (GM-CSF), and the transcriptionalregulator CCAAT/enhancer-binding protein (C/EBP; ref. 5).Although splenic MDSCs are considered a reservoir for tumor-infiltrating myeloid cells (6), the exact relationship betweenthese cells remains elusive. Accumulating evidence indicatesthat MDSCs, whether in the spleen or in the tumor, have directsuppressive effects on cytotoxic leukocytes. In addition to
Authors' Affiliations: 1Department of Cancer Immunology and AIDS,Dana-Farber Cancer Institute; 2Boston University School of Medicine;3Department of Microbiology and Immunobiology, Harvard MedicalSchool, Boston, Massachusetts; Departments of 4Internal Medicine and5Immunobiology, Yale School of Medicine, New Haven, Connecticut
Note: Supplementary data for this article are available at Cancer Immu-nology Research Online (http://cancerimmunolres.aacrjournals.org/).
Current address for K.G. Elpek: Jounce Therapeutics, Inc., Cambridge, MA02138.
Corresponding Author: Shannon J. Turley, Dana-Farber Cancer Institute,44 Binney Street, D1440a, Boston, MA 02115. Phone: 617-632-4990; Fax:617-582-7999; E-mail: [email protected]
doi: 10.1158/2326-6066.CIR-13-0209
�2014 American Association for Cancer Research.
CancerImmunology
Research
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MDSCs, conventional and plasmacytoid dendritic cells (DC)may exert immunoregulatory effects in tumors (2) using avariety of mediators such as indoleamine 2,3-dioxygenase(IDO), inducible nitric oxide synthase (iNOS), and arginase Ito suppress T-cell proliferation, cytotoxicity, and effectorcytokine production.
Given that myeloid cells with protumorigenic and immu-nomodulatory functions have been observed in multiple ani-mal tumor models and in patients with cancer, they representimportant targets for immunotherapy. Efforts are underway toidentify myeloid-focused strategies. Approved chemotherapyagents, such as gemcitabine (7), 5-fluorouracil (8), and suni-tinib (9), can eliminate or prevent the accumulation of MDSCs,especially in lymphoid organs, and retard tumor progression.Likewise, agents that block myeloid recruitment to tumors,such as CSF1R inhibitors (10), hold clinical promise. However,to improve current strategies and identify new universaltargets for therapeutic intervention, it is essential to under-stand how each myeloid cell subset from one tumor relates tothe same population in other tumor types.
In this study, we analyzed myeloid subsets in multiplemurine tumors to study how phenotype, frequency, and tran-scriptional profiles relate within different tumors, using triple-negative 4T1 breast cancer, Her2þ breast cancer, and B16melanoma as models. Strikingly, each tumor type containeda distinct myeloid cell landscape, with TAMs, TANs, and DCsrepresented in all tumors but at markedly different ratios,while systemic MDSC accumulation was exquisitely tumor-specific. Our data suggest that tumor type, rather than ana-tomic location, dictates myeloid composition in the tumorlesion. Furthermore, although each subset exhibits similartranscriptional signatures associated with its identity in dif-ferent tumors, our study demonstrates that functional differ-ences exist across myeloid subsets from different tumors. Inparticular, our data suggest that haptoglobin may represent abiomarker for tumors characterized by systemic accumulationof myeloid cells. Thus, our study provides important insightsinto the identity and functional characteristics of tumor-asso-ciated myeloid subsets. Perhaps more importantly, our datasupport that in-depth transcriptomic analysis of tumor-infil-trating myeloid cells may reveal novel therapeutically attrac-tive targets for cancer.
Materials and MethodsEthics statement
All animal work has been carried out in accordance with U.S.NIH guidelines. This study is reviewed and approved by theDana-Farber Cancer Institute Animal Care andUse Committee(protocol IDs: 04-025 and 07-038).
MiceSix-week-old, sex-matched C57BL/6, Balb/c, or CD45.1þ (B6.
SJL-PtprcaPepcb/BoyJ and CBy.SJL(B6)-Ptprca/J) mice werepurchased from The Jackson Laboratory. F1 (Balb/cxC57BL/6) mice were bred in-house. RIP1-Tag2 mice were obtainedfrom Mouse Model of Human Cancer Consortium [NationalCancer Institute (NCI)]. Mice with spontaneous invasive pan-creatic ductal adenocarcinoma (PDA; Pdx1-Cre LSL-KrasG12D
PtenL/þ) were kindly provided by Dr. DePinho [while at theDana-Farber Cancer Institute (Boston, MA); currently at theMD Anderson Cancer Center (Houston, TX); ref. 11].
Cell lines and tumor modelsB16, EL4, 4T1, A20, and CT26 cells were obtained from
American Type Culture Collection. Pan02 cells were obtainedfrom the NCI Developmental Therapeutics Program reposito-ry. The 4T07 cells were obtained from Dr. J. Lieberman (Har-vard University, Cambridge, MA); they were expanded, ali-quoted, and banked in liquid nitrogen. No additional authen-tication was performed on these cells. The Her2 cell line wasderived from a spontaneous breast tumor in a Balb/c Her-2/neu–transgenic mouse that was found to lose Her-2/neuexpression in vitro. Transgenic rat Her-2/neu sequence wasinserted into a pMFG retroviral vector to obtain a stablyoverexpressing cell line. Cell lines were maintained in Dulbec-co'sModified EagleMedium (B16 and EL4) or RPMI (4T1, Her2,A20, Pan02, CT26, and 4T07) supplemented with 10% FBS and1� penicillin/streptomycin.
For subcutaneous tumors, 1 to 2.5 � 105 cells were injectedinto the flanks of na€�ve mice (4T1, Her2, CT26, and 4T07 intoBalb/c; B16 and Pan02 into C57BL/6; A20 into Balb/cxCD45.1;and EL4 into C57BL/6xCD45.1), and tumor growth was moni-toredusing calipers until tumor size reached0.5 to 1 cmdiameter.For transgenic models, tumors were monitored and analyzed atdifferent time points based on tumor growth (RIP-Tag2 at 11–12weeks, and PDA and Her2 transgenic at 11–24 weeks).
Cell preparation and flow cytometrySpleens and tumors were processed by gentle mechanical
disruption with forceps followed by enzymatic digestion using0.2 mg/mL collagenase P (Roche), 0.8 mg/mL dispase (Invitro-gen), and 0.1mg/MLDNase I (Sigma). Tissueswere incubated indigestion medium at 37�C for 30 minutes; released cells werecollected and filtered, and the remaining tissue was further pro-cessed. Blood was collected into tubes containing 2 mmol/LEDTA, and bone marrow cells were isolated by flushing mediathrough tibias and femurs. Red blood cells were lysed usingammonium–chloride–potassium solution. Cells were resus-pended in fluorescence-activated cell sorting (FACS) buffercontaining 1% FBS and 2 mmol/L EDTA.
Cells were stained in FACS buffer containing FcR-blockingantibody (2.4G2) with combinations of fluorochrome-conju-gated or biotinylated antibodies against CD11b (M1/70),CD11c (N418), CD45 (30.F11), Gr1 (RB6-8C5), MHC class II(M5/114.15.2), CD80 (16-10A1), CD86 (GL-1), CD40 (HM40-3),CD26 (H194-112), CD103 (2E7), cKit (2B8), Flt3 (A2F10), orisotype controls purchased from BioLegend and BD Bios-ciences. Cells were analyzed using BD FACSAria II or BDFACSCalibur (BD Biosciences), and FlowJo Software (TreeStar,Inc.). For cell sorting from spleens, myeloid cells were enrichedby depletion of CD3eþ, CD19þ, and CD49bþ cells using bio-tinylated antibodies and anti-biotin beads (MACS; MiltenyiBiotec). In tumor samples, CD45þ cells were enriched bypositive selection using a biotinylated antibody and anti-biotinbeads (EasySep; STEMCELL Technologies). After enrichment,cells were stained with fluorochrome-conjugated antibodies
Elpek et al.
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and propidium iodide (Sigma) to exclude dead cells. Cells weresorted using a BD FACSAria II equipped with a 100-mm nozzlerunning at 20 psi. After an initial sort to verify purity, a secondsort was performed to collect myeloid cell populations of 95%to 100% purity directly into TRIzol reagent (Invitrogen). Sam-ple size for each population was as follows: CD11b�/int
Gr1�CD11cþMHCIIþ (N ¼ 4), CD11bþGr1lowCD11cþMHCIIþ
(N ¼ 3), CD11bþGr1lowCD11c�MHCII� (N ¼ 3), and CD11bþ
Gr1hiCD11c�MHCII� (N ¼ 2) from B16 tumors; CD11bþ
Gr1lowCD11cþMHCIIþ (N¼ 3), CD11bþGr1lowCD11c�MHCII�
(N ¼ 3), and CD11bþGr1hiCD11c�MHCII� (N ¼ 2) from4T1 tumors; CD11bþGr1lowCD11cþMHCIIþ (N ¼ 3) andCD11bþGr1hiCD11c�MHCII� (N ¼ 3) from Her2 tumors;CD11bþGr1lowCD11c�MHCII� (N ¼ 2) and CD11bþ
Gr1hiCD11c�MHCII� (N ¼ 3) from spleens of 4T1 tumor-bearing mice.
RNA isolation and microarray analysisTotal RNA was prepared from TRIzol using chloroform ex-
traction according to the manufacturer's protocol, and 100 ngof RNA from each sample was used for amplification, labeling,and hybridization by Expression Analysis, Inc. Mouse Gene ST1.0 chips (Affymetrix) were used formicroarray analysis. All dataare Minimum Information About a Microarray Experiment(MIAME)-compliant, and the raw data generated as part ofthe Immunological Genome Project (ImmGen) have beendeposited in a MIAME-compliant database [National Centerfor Biotechnology Information (NCBI) Gene Expression Omni-bus (GEO) data repository; record no: GSE15907 andGSE37448].Various modules included in GenePattern platform (BroadInstitute, Cambridge, MA) were used for data analysis. Addi-tional myeloid cell populations from healthy tissues analyzedwithin the same microchip batch of ImmGen were used as acomparison [F4/80 macrophages from peritoneal cavity (PC;n ¼ 2), Ly6Cþ DCs from bone marrow (n ¼ 2), CD24�Sirpaþ
DCs from bone marrow (n ¼ 3), CD24þSirpaþ DCs from bonemarrow (n ¼ 3), CD4 DC from spleen (n ¼ 1), CD11c�CD103þ
DC from small intestine (n ¼ 1), neutrophil from bone marrow(C57BL/6; n¼ 2), and neutrophil from bone marrow (Balb.c; n¼2)]. Raw data were normalized with ExpressionFileCreator mod-ule using the Robust Microarray Average (RMA) method. TheMultiPlot module was used for dataset comparisons, includingfold-change analysis and statistical filtering. In each analysis, wepreprocessed the dataset for populations included in specificanalyses. In fold-change analyses, an arbitrary cutoff value of 2was used, in combination with coefficient of variation (CV) < 0.5for replicates. The t test P < 0.05 were considered statisticallysignificant for each probe. After filtering, we selected all probeswith a mean expression above 100 in at least one of the popula-tions analyzed, which indicates actual expression with 95%confidence level. For hierarchical clustering, Pearson correlationwas used with datasets following log2 transformation, row cen-tering, and row normalization in HierarchicalClustering module.Heatmaps were constructed using HeatmapViewer module.Pathway enrichments were analyzed by Ingenuity Pathway Anal-ysis. DC- and macrophage-associated genes were determinedpreviously (12, 13), and a similar analysis was performed toidentify neutrophil-associated genes (unpublished data; K.G.
Elpek and S.J. Turley). Principal component analyses were con-ducted using the PopulationDistances module created by Imm-Gen (probes with mean expression value >120 selected, datasetlog2 transformed, probes with top 15% variability selected).
Cytokine arraysCell culture supernatants from 4T1, Her2, and B16 cells were
collected in two separate batches when cells were approxi-mately 80% confluent and analyzed with Mouse CytokineAntibody Array 3 (RayBiotech, Inc.) according to the manu-facturer's protocol. Spot densities weremeasured using ImageJ(NIH), and relative amounts were calculated on the basis ofpositive and negative controls. Only cytokines and chemokineswith a positive signal are shown.
ELISA for haptoglobinSerum was obtained from na€�ve or tumor-bearing mice.
Human sera were obtained from patients with metastaticbreast carcinoma upon enrollment into Institutional ReviewBoard (IRB)–approved vaccine trials at the Dana-Farber Can-cer Institute. Informed consent was obtained for each partic-ipant about usage of collected samples for research purposes.Samples were collected by routine procedures before begin-ning study treatment. Haptoglobin levels were quantified usingMouse or Human Haptoglobin ELISA (ICL, Inc.) according tothe manufacturer's protocol. Concentrations were calculatedusing a four-parameter logistics curve.
Statistical analysis for nonmicroarray dataData are expressed as mean � SD and were analyzed using
one-tailed, unpaired Student t test. ELISAswere analyzed usingANOVA and Tukey test. P < 0.05 was considered statisticallysignificant.
Results and DiscussionIdentification and enumeration of tumor-associatedmyeloid cells reveal tumor-specific diversity
Thus far, it remains uncertain how tumor origin, localization,and history influence the myeloid cell landscape of differentsolid malignancies. To address these questions, we initiallysought to compare the composition of myeloid cell infiltratesamong 4T1 and Her2, two distinct murine tumors sharing thesame mammary tissue origin. Tumors were established subcu-taneously in the flanks of Balb/c mice and analyzed when theyreached different tumor sizes. We characterized multiple mye-loid cell populations isolated from each tumor type on the basisof myeloid-specific surface markers CD11b, Gr1, and CD11c bycytofluorimetry. In both types of tumors and throughout tumorhistory, the CD45þ hematopoietic compartment was dominat-ed by CD11bþ cells (>75%; Fig. 1A and Supplementary Fig. S1A).The intratumoral CD11bþ cells comprised three subpopula-tions based on Gr1 and CD11c expression (Fig. 1A). In 4T1tumors, the hematopoietic compartment contained approxi-mately 20% CD11bþGr1hiCD11c� cells and >45% CD11bþ
Gr1low; with >60% of the latter expressing CD11c. Comparedwith 4T1, Her2 tumors were infiltrated by a relatively smallpopulation of CD11bþGr1hiCD11c� cells (3%), while themajority(>95%) of myeloid cells were CD11bþGr1lowCD11cþ. We also
Heterogeneity of the Tumor Myeloid Cell Landscape
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Cancer Immunol Res; 2(7) July 2014 Cancer Immunology Research658
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found a Gr1�CD11cþ population among CD11b� cells, whichcomprised <1% of all hematopoietic cells in both 4T1 and Her2tumors. Further analysis showed thatCD11bþGr1lowCD11cþ andCD11b�Gr1�CD11cþ cells in the tumor were largely MHCIIþ,whereas CD11bþGr1lowCD11c� and CD11bþGr1hiCD11c� cellswere MHCII� (Fig. 1B). A marked accumulation of splenicCD11bþGr1low and CD11bþGr1hi cells (Fig. 1C) was observedin 4T1-bearing mice, whereas the splenic numbers in micewith Her2 tumors were similar to na€�ve mice. These datasuggest that each tumor type may contain a distinct myeloidcell infiltrate.
Lineage determination of tumor-infiltratingmyeloid cellsubsets based on transcriptional profilingWe next sought to determine the lineage of each tumor-
infiltrating myeloid cell population using transcriptomic anal-ysis. To this end, myeloid subsets from 4T1 and Her2 breastcarcinomas and B16 melanoma were sorted to high purity,according to the ImmGen standard operating procedure.Transcriptional profiling data were generated on AffymetrixST1.0 microarrays adhering to profiling and quality controlpipelines of ImmGen (14). We used hierarchical clustering ofapproximately 13.5 K probes, after excluding those withCV < 0.5 andmean expression values <120 to compare popula-tions of tumor-infiltrating myeloid cells with representativemyeloid cell subsets (DCs,macrophages, andneutrophils) from
lymphoid and nonlymphoid tissues of healthy animals. Den-dogram analysis based on gene clustering depicted similaritiesbetween neutrophils and tumor-derived Gr1hi cells, macro-pahges and Gr1low cells (regardless of CD11c expression), andconventional DCs and CD11b�Gr1�CD11cþ cells (Fig. 1D).Hierarchical clustering of 139 probes corresponding to signa-ture genes of DCs, macrophages (12, 13), and neutrophils(unpublished data; K.G. Elpek and S.J. Turley) demonstratedthat tumor-infiltrating myeloid cell populations are indeedCD11cþ and CD11c� TAMs, TANs, and DCs (Fig. 1E andSupplementary Table S1).
Striking heterogeneity in myeloid cell infiltrates acrossdifferent tumor types
Among the three tumor types analyzed, Her2 tumors wereuniquely characterized by the presence of a large CD11cþ
TAM population, whereas 4T1 tumors contained a relativelylarge TAN population (Fig. 2A). In B16 tumors, myeloid cellscomprised only 40% of tumor-infiltrating leukocytes com-pared with >75% in 4T1 and Her2 tumors (Fig. 2A). Theaforementioned differences in myeloid abundance alsoreflected variation in the abundance of other leukocytesinfiltrating tumors, including T, B, NK, NKT cells, and pDCs.For example, B16 tumors were enriched in CD3þ T cellscompared with 4T1 and Her2 tumors, consistent with a moreimmunogenic environment in B16 melanoma (Fig. 2B). To
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within
Figure 2. Abundance ofmyeloid cellsubsets across different tumors. A,Whisker box plots summarizing therelative frequency of myeloidsubsets among hematopoieticcells within 4T1, Her2, and B16tumors. B, frequency of CD3þ Tcells within hematopoietic cells in4T1, Her2, and B16 tumors. C,frequency of myeloid cells in 4T07,Pan02, EL4, CT26, PDA, RIP-Tag2,and A20 tumors (n ¼ 3–7).�, P < 0.05; ��, P < 001; ���,P < 0.001.
Figure 1. Multiple myeloid cell subsets are present within tumors of different origin. A, analysis of myeloid cell subsets within subcutaneous 4T1 and Her2tumors by flow cytometry. Hematopoietic cells were analyzed for the expression of CD11b and Gr1, and gated populations in the dot plots werefurther analyzed for CD11c expression. B,MHCII expression by indicated subsets. C, accumulation of CD11bþGr1þ cells in the spleens of 4T1 tumor-bearingmice (top) and Gr1 expression (bottom). Numbers indicate percentage of cells for each gate or region. D, dendrogram analysis based on hierarchicalclustering of tumor-associated and steady-state myeloid cells (BM, bone marrow; SI, small intestine; Spl, spleen; Tmr, tumor). Sample sizes are indicated inMaterials and Methods. E, hierarchical clustering of the same populations based on a list of 139 genes associated with DCs, macrophages, or neutrophils.
Heterogeneity of the Tumor Myeloid Cell Landscape
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further ascertain the degree of myeloid heterogeneity, weextended our analysis to five additional transplantedtumors, including 4T07 breast cancer, CT26 colon carcino-ma, EL4 T lymphoma, A20 B lymphoma, and Pan02 PDA, andthree autochthonous mouse models, including RIP-Tag2(insulinoma), Her-2/neu (mammary carcinoma), andPdx1-Cre LSL-KrasG12D PtenL/L (PDA) mice. The samefour major populations were present within each tumormodel but at significantly different frequencies across thetumors analyzed (Fig. 2A–C).
In all tumors, DCs were present at very low frequencies, withthe highest levels in B16, EL4, and RIP-Tag2 tumors (4%–10%; Fig. 2). Given that DCs account for only a small percentageof hematopoietic cells within the tumors, and that the majorsubset expressing CD11c in tumors is TAMs, our study alsosuggests that CD11c alone is an unreliable marker for DCs inneoplastic lesions. Further analysis comparing DCs in B16tumors with TAMs indicated that while TAMs expressed avariety of endocytic and regulatory receptors, including Pilrb,Sirpa, Lilrb4, and Clec5a (Supplementary Fig. S1B), tumor DCsexpressed signature genes such asDpp4, Flt3, andKit, as well asCD8/CD103 DC-associated genes (13), including Itgae, Batf3,Tlr3, Ifi205, and Xcr1, identifying them as CD11b�CD103þ
tissue-resident DCs. Flow cytometric analysis confirmed thatDCs were the myeloid cells expressing high levels of CD26(Dpp4), Flt3, cKit, and CD103 (Itgae) protein in these tumors(Supplementary Fig. S1C; and data not shown). On the basis ofthese distinctions, DCs may be considered as a referencepopulation in future studies to identify unique targets onTAMs and TANs to modulate their tumor-promoting func-tions. For example, DCs lack the surface receptorClec5a (MDL-1), whereas expression in TAMs, TANs, and neutrophils isrelatively high (>18-fold higher than in DCs), suggesting thatit may represent an attractive target for antibody-mediateddepletion of CD11bþGr1þ cells in tumors (15).
Differences in Gr1low and Gr1hi cells across several diversetumors were not restricted to the tumor lesion itself. Forexample, a substantial increase in MDSCs was observed inthe spleen and blood of 4T1 tumor-bearing mice throughouttumor progression but not in mice bearing other tumor types(Supplementary Fig. S1D and S1E).
Differences in myeloid cell composition arise fromspecificity of the tumor microenvironment
Themyeloid composition of different tumors is likely shapedby a combination of tumor-specified growth factors. Indeed,4T1, Her2, and B16 cell lines produce unique combinations ofcytokines and chemokines, suggesting that each tumor maycreate a distinctive microenvironment (Supplementary Fig.S2A). These differences may also explain why MDSCs prefer-entially accumulate in certain tumors. For example, high levelsof G-CSF and LIX (CXCL5) expression by 4T1 cells maycontribute to systemic accumulation of MDSCs in vivo (16,17). To assess whether specific tumor microenvironmentsdirectly influence the myeloid cell content, we analyzed mye-loid cells within the same tumor type growing at differentanatomic locations. Comparison of myeloid cell compositionin subcutaneous Her2 tumors and the parental spontaneous
tumor in mammary glands revealed that both lesions con-tained high frequencies of CD11cþ TAMs (50%–72%) andrelatively low frequencies of TANs (<5%) among hematopoieticcells (Fig. 3A and Supplementary Fig. S2B). A strong similaritywas observed between the myeloid cell composition of sub-cutaneous 4T1 tumors and spontaneous metastatic lesions inthe peritoneal cavity, occurring within 2 to 3 weeks after tumorchallenge. Similar to primary 4T1 tumors, thesemetastases areenriched with TAMs (�50%, of which >60% are CD11cþ) andTANs (15%–21%) among hematopoietic cells (Fig. 3A andSupplementary Fig. S2C). Furthermore, these results werecorroborated in a B16 metastatic model. When B16 cells areinjected intravenously, tumor nodules grow in lungs andkidneys within 2 to 3 weeks and contain a similar myeloidlandscape to that of subcutaneous tumors: approximately 30%TAMs (�45% expressing CD11c) and 4% to 9% TANs amonghematopoietic cells (Fig. 3A and Supplementary Fig. S2D).Altogether, these data provide evidence that tumor type ratherthan its anatomic location shapes the myeloid infiltrate.
Next, we tested the possible dominant effect of the micro-environment in dictating myeloid cell composition by analyz-ing myeloid cells in mice with two tumors growing simulta-neously. For this purpose, we compared Her2 and 4T1 or Her2and B16 tumors, as each of these tumors has distinct myeloidinfiltrates (Figs. 1 and 2). Balb/c mice were inoculated withHer2 tumors under one flank and simultaneously with 4T1tumors under the contralateral flank (Fig. 3B and Supplemen-tary Fig. S2E). Similarly, we established Her2 tumors in thepresence of B16 tumors on the opposite flank in F1 (Balb/c xC57BL/6) mice (Fig. 3C and Supplementary Fig. S2F). In bothmodels, we did not observe a difference in growth rate of eithertumor when compared with tumors grown alone (data notshown). Likewise, the myeloid content of each tumor, eitheralone or in the presence of a second tumor in the samehostwassimilar (Fig. 3B and C, left and Supplementary Fig. S2E andS2F), even though there was pronounced systemic accumula-tion of MDSCs associated with 4T1 tumor growth (Fig. 3B andC, right). Overall, these results suggest that the signals attract-ing specificmyeloid cells into tumors are driven by cancer cellsin the primary lesion, regardless of anatomic location orpresence of distant signals from other microenvironments.
Tumor-infiltrating myeloid cells exhibit a hypoxia-associated signature compared with their spleniccounterparts
As shown in Fig. 1, MDSCs accumulate in the spleens of 4T1tumor-bearing mice at high frequencies. As splenic MDSCsmay serve as reservoirs for tumor-infiltrating cells (6), it isimportant to understand how they relate to their counterpartswithin tumors. Thus, we compared the gene expression profilesof CD11bþGr1þ cells from the spleens and tumors of 4T1tumor-bearing mice. As shown in Fig. 4A, 263 probes wereupregulated in TAMs (both CD11c� and CD11cþ subsets)within 4T1 tumors comparedwithGr1lowMDSCs from spleens,whereas 152 probes were enriched in splenic cells. In addition,201 probeswere enriched in TANs comparedwith splenic Gr1hi
MDSCs, while 647 probes were enriched in Gr1hi MDSCs (Fig.4B). Next, we compared expression of probes upregulated in
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Gr1
CD11c
CD
11b
Primary
(s.c.)
100
101
102
103
104
100
101
102
103
104
59
7
100
101
102
103
104
100
101
102
103
104
696
4 96
Mammary gland
(transgenic)
CD45+
TAMs
100
101
102
103
104
100
101
102
103
104
44 12
100
101
102
103
104
100
101
102
103
104
60 21
Peritoneal met
(spont.)
100
101
102
103
104
100
101
102
103
104
333.8
100
101
102
103
104
100
101
102
103
104
314
100
101
102
103
104
100
101
102
103
104
283
Lung met
(i.v.)Kidney met
(i.v.)
Gr1
CD11c
A Her2 4T1 B16
B
100
101
102
103
104
100
101
102
103
104
72
2
100
101
102
103
104
100
101
102
103
104
322.3
100
101
102
103
104
100
101
102
103
104
831.3
100
101
102
103
104
100
101
102
103
104
3310
100
101
102
103
104
100
101
102
103
104
713.7
100
101
102
103
104
100
101
102
103
104
5817.3
100
101
102
103
104
100
101
102
103
104
77.411.4
100
101
102
103
104
100
101
102
103
104
5821
C
CD
11b
Her2 4T1
Gr1
CD11c
Her2 4T1
Single tumor Double tumor
CD45+
TAMs
100
101
102
103
104
0
20
40
60
100
101
102
103
104
0
30
60
90
120
298
100
101
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104
0
10
20
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50
25
75
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0
10
20
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29
71
100
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104
0
5
10
1556 44
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104
0
5
10
15
20
25 61 39
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104
0
5
10
15
20
25
62 38
4
0
20
40
60
80
100
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103
10 100
101
102
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104
0
20
40
60
80
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100
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102
103
104
0
10
20
30
40
793
2674
0
20
40
60
100
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102
103
104 10
010
110
210
310
4
0
10
20
30
40
51 49
100
101
102
103
104
0
20
40
60
36 64694
100
101
102
103
104
0
50
100
150
5 95
100
101
102
103
104
0
20
40
60
80
4 96 54 46
Primary
(s.c.)
CD11c
Gr1
Primary
(s.c.)
CD
11b
Gr1
CD11c
CD45+
TAMs
Her2 B16 Her2 B16
Single tumor Double tumor
%C
ells
in C
D45
+ N.S.N.S.
Her2 4T1 Double0
20
30
40
10
Gr1low MDSC Gr1hi MDSC
***
*
Spleen
%C
ells
in C
D45
+ N.S.
N.S.
Her2 B16 Double0
4
6
8
2
Gr1low MDSC Gr1hi MDSC
Spleen
Figure 3. Tumor type dictates the composition of myeloid cell subsets within tumors. A, myeloid cells within subcutaneous and mammary gland oftransgenic Her2 tumors (n ¼ 4–7); within primary subcutaneous and spontaneous peritoneal metastatic 4T1 tumors (n ¼ 3); and within subcutaneousB16 tumors or lung and kidney metastases (n ¼ 3–4). B, left, analysis of myeloid subsets within tumors from Balb/c mice with single (Her2 or4T1; n ¼ 5) or double (Her2 and 4T1 on opposite flanks; n ¼ 8) tumors. Right, frequency of myeloid cells in the spleens of tumor-bearing mice. C, left,analysis of myeloid cell subsets within tumors from F1 (Balb/c � C57BL/6) mice with single (Her2 or B16; n ¼ 3) or double (Her2 and B16 onopposite flanks; n ¼ 3) tumors. Right, frequency of myeloid cells in the spleens of tumor-bearing mice. Numbers indicate percentage of cells for eachgate or region. N.S., not statistically significant; �, P < 0.05; ���, P < 0.001.
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4T1 tumorswith that ofmyeloid cells originated in other tumormodels. Hierarchical clustering indicated that TAMs, TANs,and splenic MDSC populations clustered separately, confirm-ing differences between tumor and splenic myeloid cells.Notably, similar profiles were obtained from equivalent popu-lations originated from different tumor types (Fig. 4C), sup-porting that transcriptomic analysis may illuminate universalfeatures of tumor myeloid cells. Indeed, this analysis identifiedseveral genes that highlight the protumorigenic roles of tumor-infiltrating myeloid cells. For example, genes involved inextracellular matrix remodeling (Mmp12, Mmp13, Mmp14,Adam8, and Tgm2), immunomodulation (Arg1, Nos2, Cd274,Ptgs2, and Spp1), and hypoxia regulation (Vegfa, Hif1a, andSlc2a1) were markedly upregulated in TAMs and TANs com-pared with splenic MDSCs. Interestingly, expression of thesegenes was similar between CD11b�CD103þ tumor DCs andDCs from tumor-free mice. This result suggests that hypoxicresponses are not uniform within the samemicroenvironmentand may be tightly regulated among tumor-infiltrating leuko-cytes. Immunosuppression and tissue remodeling are criticalfunctions for promoting tumor progression, and hypoxia,through hypoxia-inducible factor-1a (Hif-1a; ref. 18), canpromote transcriptional changes that facilitate the selection
of aggressive tumor cells. Expression analysis of Hif-1a–reg-ulated hypoxia-associated genes (19) revealed that these genesare indeed enriched in TAMs and TANs compared with splenicMDSCs and steady-state populations, indicating reprogram-ming in the tumor environment (Fig. 4D and SupplementaryTable S2). Hypoxia and Hif-1a have been implicated in pro-longed survival and reduced oxidative burst in neutrophils(20, 21), and as suchmay also contribute to the accumulation ofthese short-lived cells.
Neutrophils in the tumor environment areprotumorigenic and exhibit an altered functional profile
Our finding that the myeloid cell landscape of each tumortype is distinctive raises the possibility that different tumormicroenvironments impart unique functional attributes in themyeloid cells therein. Although TAMs in different tumors havebeen extensively characterized by functional and transcriptionalprofiling approaches (22–26), our understanding of TANs islimited. Recently, Fridlender and colleagues compared steady-state neutrophils to splenic MDSCs and TANs in a mesotheli-oma model by transcriptional profiling and identified strikingdifferences (27). However, this study focused only on a singletumor and it is not known if such characteristics of TANs are
1 100.1Fold change
(4T1 CD11c+ TAM vs Gr1low MDSC)
263
152
1
0.2
10
Fold
cha
nge
(4T1
CD
11c– T
AM
vs
Gr1
low M
DS
C)A
1 100.2Fold change (4T1 TAN vs Gr1hi MDSC)
100
10–1
10–2
10–3
10–4
10–5
647 20110–6
10–7
KdrCar9Pdk1Cdh1Ccnd1PdgfbIgf2Igfbp2TgfaSerpine1Flt1Cxcl12Mmp2MetCdkn1aPfkfb3Egln3Nos2Slc2a1Arg1VegfaHif1aHk2Hk1Gys1LdhaPgk1Pkm2Eno1AldoaMmp9Slc2a3Kdm5bCcng2Cxcr4PlaurCrebbpCrebbp
B
C
Gr1
low M
DS
C 4
T1G
r1hi M
DS
C 4
T1C
D11
c– TA
M 4
T1C
D11
c– TA
M B
16C
D11
c+ TA
M B
16C
D11
c+ TA
M 4
T1C
D11
c+ TA
M H
er2
TAN
4T1
TAN
B16
TAN
Her
2
CD
11b– C
D10
3+ DC
SI
Ly6C
+ PD
CA
1+ DC
BM
CD
4+ DC
Spl
CD
24+ S
irpa– D
C B
MC
D24
– Sirp
a+ DC
BM
DC
B16
Tm
r
F4/8
0hi M
ac P
C
Neu
tro B
6N
eutro
Bal
bcG
r1hi M
DS
C 4
T1G
r1lo
w M
DS
C 4
T1TA
N 4
T1TA
N B
16TA
N H
er2
CD
11c– T
AM
4T1
CD
11c– T
AM
B16
CD
11c+ T
AM
B16
CD
11c+ T
AM
4T1
CD
11c+ T
AM
Her
2
D
Expression (log2)3.87 13.68
Expression (log2)4.74 13.54
Mmp14
Mmp12Spp1
Cd274
Ptps2
Arg1Tgm2
VegfaNos2
Adam8Slc2a1
Hif1a
Arg1
Cd274
Tgm2
VegfaSlc2a1
t tes
t P v
alue
(log
10)
Abca1Cxcl16
Serpinb9Mgl2
Havcr2
Cxcl10
Il1a
Niacr1Arg1Egln3
Cstb Tnfrsf26
Hypoxia-associated genes
Figure 4. Tumor-infiltrating myeloid cells express immunomodulatory genes. A, comparison of gene expression profiles of CD11cþ and CD11c� TAMs toGr1low MDSCs from 4T1 tumor-bearing mice based on 2-fold change (fold-change vs. fold-change plot). B, comparison of gene expression profilesof TANs and Gr1hi MDSCs from 4T1 tumor-bearing mice (fold-change vs. t test P value plot). C, heatmap generated by hierarchical clustering usingprobes identified in A and B for all tumor myeloid subsets. D, heatmap showing the expression of hypoxia-related genes by tumor-associated andsteady-state myeloid cells. Selected genes associated with the populations are indicated on the plots.
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common across different tumors. By comparing TANs from 4T1,B16, and Her2 tumors to Gr1hi MDSCs from 4T1 tumor-bearingmice and neutrophils from the bone marrow of na€�ve mice (Fig.4), we identified a conserved expression pattern of immuno-modulatory and hypoxia-related genes across these tumors. Wealso compared genes highly expressed in both Gr1hi MDSCs andTANs from 4T1 tumors to their expression in steady-stateneutrophils (Fig. 5A, left) and found 214 probes selectivelyenriched in 4T1-associated neutrophils. Interestingly, many ofthese genes were similarly enriched in TANs from B16 and Her2tumors compared with steady-state neutrophils (170 of 214passed CV < 0.5 filter; Fig. 5A, right). Heatmap analysis alsoindicated that these probes were highly expressed by all TANsand Gr1hi MDSCs compared with steady-state neutrophils (Fig.5B and Supplementary Table S3). Importantly, these genes areinvolved in pathways critical for tumor growth and immuneresponses, such as iNOS, IL-10, IL-6, and peroxisome prolifera-
tor-activated receptor (PPAR) signaling (Fig. 5C). Collectively,our data support that tumor-associated myeloid cells exhibit aprotumorigenic transcriptional program.
To further interrogate molecular programs in TANs acrossdifferent tumors, a side-by-side comparison of TANs from4T1, Her2, and B16 tumors was performed. We identified 43probes enriched in 4T1 TANs, 61 in Her2 TANs and 93 in B16TANs (Fig. 6A). Genes involved in cell trafficking or differ-entiation, such as Cxcr1, Foxo3, and Slc28a2, were enriched2- to 5-fold in 4T1 TANs and may regulate the markedaccumulation of TANs in this cancer type (28). Given thatour data point to a direct, tumor cell–specific involvement inthe recruitment and expansion of TANs, we analyzed theexpression levels of cytokines, cytokine receptors, chemo-kines, and chemokine receptors by TANs, as these mayaccount for the tumor–myeloid cell cross-talk regulatingcell infiltration (Fig. 6B and Supplementary Table S4).
A
1 100.1
Fold change (4T1 TAN vs. naïve neutrophil)
214
1
0.1
10
Fo
ld c
ha
ng
e
(4T
1 G
r1h
i MD
SC
vs. n
aïv
e n
eu
tro
ph
il)
1 100.1
Fold change (Her2 TAN vs. naïve neutrophil)
170
1
0.1
10
Fo
ld c
ha
ng
e
(B1
6 T
AN
vs. n
aïv
e n
eu
tro
ph
il)
B
0 1 2 3 4 5 6 7 8 9
IL10 signaling
Hepatic fibrosis/hepatic stellate
cell activation
LXR/RXR activation
Hepatic cholestasis
iNOS signaling
VDR/RXR activation
IL6 signaling
PPAR signaling
AHR signaling
Role of macrophages/fibroblasts/
endothelial cells in RA
Glucocorticoid receptor signaling
MIF regulation of innate immunity
Eumelanin biosynthesis
LPS/IL1–mediated inhibition
of RXR function
Acute phase response signaling
Molecular mechanisms of cancer
Production of NO and ROS
in macrophagesIL12 signaling and production
in macrophages
HGF signaling
PPARα/RXRα activation
Ingenuity canonical pathway
Top 20 –log10
(P )
Gr1
hi M
DS
C 4
T1
TA
N 4
T1
TA
N B
16
TA
N H
er2
Ne
utr
o B
6N
eu
tro
Ba
lb
C
Expression (log2)
4.23 13.73
Figure 5. Expression ofprotumorigenic genes by TANs. A,comparison of gene expressionprofiles of TANs and Gr1hi MDSCsfrom 4T1 tumor-bearing mice tonaïve neutrophils (left, fold-changevs. fold-change, 2-fold change).Expression of these probes wasfurther analyzed in fold-changeversus fold-change plotscomparing TANs from B16 andHer2 tumors with naïve neutrophils(right); 170 of the 214 probespassed the CV < 0.5 filter. B,heatmap showing the expressionof the 170 probes identified in Aacross neutrophils. C, top 20canonical pathways enriched forTANs and Gr1hi MDSCs comparedwith naïve neutrophils analyzed byIngenuity Pathway Analysis. ROS,reactive oxygen species.
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Strikingly, we identified different expression profiles for eachTAN population, which may reflect the differences observedin the frequencies of these populations in each tumor. Inparticular, TANs from 4T1 tumors expressed significantlygreater levels of Ltb4r1 (BLT1), a leukotriene B4 chemotacticfactor for neutrophils (29, 30). Interestingly, we also foundenrichment of genes in the anti-inflammatory PPARa sig-naling pathway (Fig. 5D), which is also a target for leuko-
triene B4. We further analyzed the expression of PPARatarget genes associated with inflammation (31) in neutrophilsubsets (Fig. 6C and Supplementary Table S5). Althoughmany of these genes are expressed at higher levels in TANscompared with Gr1hi MDSCs and steady-state neutrophils,neutrophils from 4T1-bearing mice expressed higher levelsof Stat1, Stat2, and Stat3, among other genes. Stat3 is amediator of CXCR2 expression in neutrophils upon G-CSF
Ccl12Ccl2Ccl5Ccl4Ccl7Ccl9Ccl22Ccl8Ccl3Ccl6Ccl27aCxcl2Cxcl3Ccl1Cx3cl1Ccl17Cxcl1Cxcl14Cxcl16Xcl1Cxcl10Cxcl9Ccl19Ccl11Cxcl17Ccl25Cxcl11Ccrl2
BA
Ifna1Ifna9IfnzFlt3lIfna7Il1bIfna5Il17aIl31Il13Il25Il16LtbIfna2MifIl12aIl15Il18Il1f9Il17cCsf3Ifna14Il23aTn fIl12bIl1aTgfb1
Il2raIl2rbIl7rIl2rgIl10rbIl12rb1Il9rIl17rbIl11ra1Il6raIl17raIl13ra1Il28raIl15raIl27ra
Ccr2Ccr5
Ccr1Ccr10Ccr7Xcr1Cxcr3Cxcr4Cxcr1Cxcr2Ltb4r1
Fold change (4T1 vs. B16 TANs)
Fold
change (
4T
1 v
s. H
er2
TA
Ns)
TA
N 4
T1
TA
N B
16
TA
N H
er2
TA
N 4
T1
TA
N B
16
TA
N H
er2
TA
N 4
T1
TA
N B
16
TA
N H
er2
Expression (log2)
5.73 13.37
Expression (log2)
5.53 11.34
Expression (log2)
5.67 13.68
Expression (log2)
5.91 12.47
B6
Balb/cMDSC
4T1TAN
B16TAN
Her2TAN
C
TA
N B
16
TA
N 4
T1
TA
N H
er2
1 100.1
1
0.1
10
Ltb4r1
Slc28a2Foxo3Cxcr1
6143
93
Ccgn2Gbp1
Irgm2 Irf47
Irf1
Plxdc2
ArsbItgb5
Axl
Ccr2
Ccl8Trim12a
Cd36
Ly6a
Thbs1
Ccl7
LifrEmr1Vcam1Il18Pla1aCcl2Il1rnMt2Mt1Ccl3Cxcl10NfkbiaIcam1Ifi47 7CebpbIl1b bBirc3Irgm2Stat2Stat3Il1rapSteap4Stat1Il6raOrm2Lcn2Traf2Nfkb1
Cx3cr1
Gr1
hi M
DS
C 4
T1
TA
N 4
T1
TA
N B
16
TA
N H
er2
Neutr
o B
6N
eutr
o B
alb
D
Expression (log2)
5.77 13.87
–0.2
0
0.2
0.4
–0.20
0.20.4
−0.4
−0.2
0
0.2
0.4
PC2 (14.6%)
PC1
(66.4%)
PC3
(5.9%)
Cytokine ChemokineCytokine
receptor
Chemokine
receptor
Figure 6. Tumor type–specific transcriptional profiles of TANs. A, fold-change versus fold-change plot comparing 4T1 TANswith TANs inHer2 andB16, basedon 2-fold change. Selected genes associated with the populations are indicated on the plots. B, chemokine, chemokine receptor, cytokine, and cytokinereceptor expression profiles of TANs. C, PPARa-associated gene expression profiles of neutrophils. D, principal component analysis of neutrophilpopulations.
Elpek et al.
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stimulation (32). In agreement with this, G-CSF is highlyexpressed by 4T1 cells (Supplementary Fig. S2A) and Cxcr2 isexpressed at higher levels by 4T1 TANs (Fig. 6B). Overall,these signaling pathways may incite the marked accumula-tion of TANs and Gr1hi MDSCs in the 4T1 model. Therelationship between neutrophil populations from differenttumors was also confirmed by the principal componentanalysis to highlight functional differences. Neutrophils fromna€�ve mice clustered separately and more closely to MDSCson PC2 (Fig. 6D). On the other hand, while TANs clusteredseparately from neutrophils and MDSCs, variability on PC1reflected tumor-to-tumor differences among TANs.
Haptoglobin levels are associated with myeloid cellaccumulationDuring acute inflammatory responses, neutrophils exocy-
tose effector molecules stored in specific granules (33).Recently, Fridlender and colleagues showed that some ofthese molecules are actually downregulated in TANs com-pared with those in steady-state neutrophils and Gr1hi
MDSCs (27). To understand how this critical function isinfluenced by different tumors, we compared the expressionof these effector molecules in steady-state neutrophils, in
splenic Gr1hi MDSCs from 4T1 tumor-bearing mice, and inTANs from 4T1, Her2, and B16 tumors. Heatmap analysisand hierarchical clustering indicated that all TANs sharedan altered expression profile compared with na€�ve granulo-cytes (Fig. 7A and Supplementary Table S6). Interestingly,Gr1hi MDSCs expressed the majority of the effector mole-cules. Among the molecules associated with neutrophilgranules is the acute-phase responder haptoglobin (Hp; ref.34). Haptoglobin is known to be produced in the liver;however, recent studies indicate that it is also expressedby neutrophils and packaged into secretory granules (35).Analysis of haptoglobin expression by tumor-associatedmyeloid cells revealed that haptoglobin is not expressed byDCs or CD11cþ TAMs in tumors, and its level is moderate inCD11c� TAMs and in TANs from B16 and Her2 tumors (Fig.7B). However, haptoglobin expression is high in na€�ve gran-ulocytes, Gr1hi MDSCs, and TANs from 4T1 tumors. Accord-ingly, serum haptoglobin levels were elevated in mice bear-ing advanced 4T1 tumors but not in Her2 or B16 tumor-bearing hosts (Fig. 7C). Indeed, serum haptoglobin levelscorrelated with the frequency of Gr1hi MDSCs in the blood of4T1 tumor-bearing mice (Fig. 7D). This select pattern sug-gests that haptoglobin expression may be associated with
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Figure 7. Altered expression profileof secretory granule molecules inTANs. A, expression of granulareffector molecules by neutrophils.B, mean expression value ofhaptoglobin (Hp, HP) acrossneutrophils and tumor-associatedmyeloid cells. C, serumhaptoglobin levels in mice withsmall (S), medium (M), large (L)tumors and naïve mice. D,correlation between the frequencyof Gr1hi cells in blood and theserum haptoglobin concentration.E, haptoglobin levels in serum fromhealthy donors (n¼ 4) and patientswith breast cancer (n ¼ 10).�, P < 0.05; ��, P < 0.01.
Heterogeneity of the Tumor Myeloid Cell Landscape
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the considerable myelopoiesis observed in the 4T1 setting(Supplementary Fig. S1E). Although further studies arerequired to confirm a direct relationship between neutro-phils and haptoglobin levels, we detected elevated serumhaptoglobin in patients with breast cancer (Fig. 7E), con-sistent with reports for patients with glioblastoma andovarian cancer (36, 37). Thus, haptoglobin may serve as adiagnostic marker indicative of cancers with myeloid cellaccumulation.
Tumors require a sustained influx of myeloid cells tosupport angiogenesis, remodel peritumoral stroma, andsuppress antitumor immunity. Therefore, tumor-associatedmyeloid cells represent potential targets to improve immu-notherapy as well as chemotherapy against cancer. Althoughthere are limited strategies available, identifying novel tar-gets for elimination or functional differentiation of thesecells requires a deeper understanding of their development,trafficking, and phenotypic and functional characteristics.Moreover, to ascertain whether a broader therapeutic appli-cation is feasible, it is critical to determine whether keymolecular attributes are conserved among specific myeloidpopulations from tumors of different origins. A betterunderstanding of the functional differences among discretemyeloid subsets in tumor lesions, as well as secondarylymphoid organs, may lay the groundwork for developmentof novel therapeutics. In this regard, our study providesfundamental insights into functional differences of tumor-infiltrating myeloid cells, and identifies potential molecularpathways that could be investigated for therapies aimed atreducing infiltration and/or reprogramming function oftumor myeloid cells.
Disclosure of Potential Conflicts of InterestK.W.Wucherpfennig reports serving as a consultant/advisory board member
for Novartis and Ipsum. No potential conflicts of interest were disclosed by theother authors.
Authors' ContributionsConception and design: K.G. Elpek, S.J. TurleyDevelopment of methodology: K.G. Elpek, K.W. Wucherpfennig, S.J. TurleyAcquisition of data (provided animals, acquired and managed patients,provided facilities, etc.): K.G. Elpek, V. Cremasco, C.J. Harvey, D.R. Goldstein,P.A. Monach, S.J. TurleyAnalysis and interpretation of data (e.g., statistical analysis, biostatistics,computational analysis):K.G. Elpek, V. Cremasco, C.J. Harvey, K.W.Wucherp-fennig, P.A. Monach, S.J. TurleyWriting, review, and/or revision of the manuscript: K.G. Elpek, V.Cremasco, D.R. Goldstein, P.A. Monach, S.J. TurleyAdministrative, technical, or material support (i.e., reporting or orga-nizing data, constructing databases): H. Shen
AcknowledgmentsThe authors thank the Immunological Genome Project team for technical
help and discussions; Drs. Dobrin Draganov and Glenn Dranoff for the Her2 cellline; and Dr. Ronald DePinho for PDA mice.
Grant SupportThis study was supported by research funding from NIH T32 grant to K.G.
Elpek, NIH T32 CA 070083-15 and Postdoctoral Fellowship from the CancerResearch Institute to V. Cremasco, NIH grants (AG028082, AG033049, AI098108,and AI101918) and an Established Investigator Award (0940006N) from Amer-ican Heart Association to D.R. Goldstein, NIH grants (ROI DK074500, PO1AI045757, and R21 CA182598), American Cancer Society Research Scholar Grant,and Claudia Adams Barr Award for Innovative Cancer Research to S.J. Turley.
The costs of publication of this article were defrayed in part by the payment ofpage charges. This article must therefore be hereby marked advertisement inaccordance with 18 U.S.C. Section 1734 solely to indicate this fact.
Received November 30, 2013; revised February 19, 2014; accepted March 12,2014; published OnlineFirst March 31, 2014.
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