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. Author manuscript; available in PMC: 2018 Oct 6.
Published in final edited form as: Breast Cancer Res Treat. 2018 Jun 1;171(2):273–282. doi: 10.1007/s10549-018-4834-7

The combined presence of CD20+ B cells and PD-L1+ tumor infiltrating lymphocytes in inflammatory breast cancer is prognostic of improved patient outcome.

H Arias-Pulido 1,#, A Cimino-Mathews 2,3,#, N Chaher 4, C Qualls 5, N Joste 5, C Colpaert 6, J D Marotti 7, M Foisey 1, E R Prossnitz 5, LA Emens 3, S Fiering 1
PMCID: PMC6173952  NIHMSID: NIHMS988613  PMID: 29858752

Abstract

Purpose:

To evaluate protein expression of PD-L1 and CD20 as prognostic biomarkers of patient outcome in inflammatory breast cancer (IBC) samples.

Methods:

PD-L1 and CD20 protein expression was measured by immunohistochemistry in 221 pretreatment IBC biopsies. PD-L1 was assessed in tumor cells (PD-L1+ tumor cells) and tumor stromal infiltrating lymphocytes (PD-L1+ TILs); CD20 was scored in tumor-infiltrating B cells. Kaplan–Meier curves and Cox proportional hazard models were used for survival analysis.

Results:

PD-L1+ tumor cells, PD-L1+ TILs, and CD20+ TILs were found in 8%, 66%, and 62% of IBC, respectively. PD-L1+ tumor cells strongly correlated with high TILs, pathological complete response (pCR), CD20+ TILs, but marginally with breast cancer-specific survival (BCSS, P=0.057). PD-L1+ TILs strongly correlated with high TILs, CD20+ TILs, and longer disease-free survival (DFS) in all IBC and in triple-negative (TN) IBC (P<0.035). IBC and TN IBC patients with tumors containing both CD20+ TILs and PD-L1+ TILs (CD20+TILs/PD-L1+TILs) showed longer DFS and improved BCSS (P<0.002) than patients lacking both, or those with either CD20+ TILs or PD-L1+ TILs alone. In multivariate analyses, CD20+TILs/PD-L1+TILs status was an independent prognostic factor for DFS in IBC (hazard ratio (HR): 0.53, 95% CI 0.37–0.77) and TN IBC (HR: 0.39 95% CI 0.17–0.88), and for BCSS in IBC (HR: 0.60 95% CI 0.43–0.85) and TN IBC (HR: 0.38 95% CI 0.17–0.83).

Conclusion:

CD20+TILs/PD-L1+TILs status represents an independent favorable prognostic factor in IBC and TN IBC, suggesting a critical role for B-cells in anti-tumor immune responses. Anti-PD-1/PD-L1 and B-cell-activating immunotherapies should be explored in these settings.

Keywords: PD-L1, CD20, immuno-oncology, inflammatory breast cancer, triple-negative, patient outcome

Introduction:

Inflammatory breast cancer (IBC) is a rare, poorly understood, and highly aggressive form of breast cancer. It accounts for less than 3% of all breast cancers, but is responsible for ~10% of all breast cancer-related deaths [1]. While multidisciplinary approaches incorporating neoadjuvant chemotherapy (NACT), surgery, and radiation therapy have modestly improved survival of IBC patients [2,3], IBC has worse survival than stage-matched non-IBC with a 5-year survival of ~30% [46]. Hence, there is an urgent unmet clinical need to develop more effective therapies for IBC, and to develop prognostic and predictive biomarkers that identify patients who will potentially benefit from various treatment interventions.

Immune checkpoint inhibitors targeting the programmed cell death receptor 1 (PD-1) and/or its ligand (PD-L1) have shown clinical efficacy in various tumors [7,8], including breast cancer [9]. PD-L1 is expressed on tumor-infiltrating immune cells and tumor cells where it plays a major role in immune suppression by binding to its receptors, PD-1 and B7.1 (CD80). This interaction results in suppression of T cell activation, induction of T cell apoptosis, and promotion of tumor immune escape [10,11]. Blocking PD-L1 and PD-1 can relieve this inhibition and increase tumor-specific T cell immunity. Several antibodies specific for PD-1/PD-L1 have shown positive clinical responses in metastatic triple-negative (TN) breast cancer patients [9,12]. Antibody blockade of the PD-1/PD-L1 axis therefore represents an attractive therapeutic approach for IBC. The protein levels of PD-L1 and the cells expressing PD-L1 in IBC, however, are unknown.

While there are several studies associating PD-L1 with favorable outcome in breast cancer [1316], the prognostic role of B cells has not been well-studied. A few reports identify CD20+ B cells within the tumor microenvironment as an important and clinically relevant factor that is strongly associated with response to NACT [17] and better patient outcome [18]. The clinical and prognostic role of B cells (identifiable by constitutive CD20 expression) in IBC is unknown. The objective of this study was to determine the clinical value of PD-L1 and CD20 as prognostic factors of disease-free (DFS) and breast cancer-specific survival (BCSS) in a large well-characterized cohort of IBC specimens.

Methods

Ethical approval:

All procedures performed in studies involving human participants were in accordance with the ethical standards of the Committee for the Protection of Human Subjects at Dartmouth College (STUDY00029655), and with the 1964 Helsinki declaration and its later amendments or comparable ethical standards. For this type of study, formal consent is not required.

Clinical specimens:

Formalin-fixed paraffin embedded tissues (FFPETs) collected before initiation of neoadjuvant chemotherapy from 221 primary IBC patients diagnosed and treated at the Pierre et Marie Curie Cancer Center (PMCCC, Algiers, Algeria) between 2005–2009 were utilized in this study. This cohort has previously been partially described [19]. IBC was clinically defined according to the international consensus criteria [20]: Rapid onset (less than 6 months) of breast erythema, edema, and/or “peau d’orange”, and/or warm breast, with or without an underlying palpable mass. IBC samples were diagnostic biopsies (AJCC stages 3–4). The histological grading of the tumors was performed in accordance with the Bloom-Richardson classification. Pathological Complete Response (pCR) was defined as the absence of any residual invasive cancer in the breast and the absence of any metastatic cells in the regional lymph nodes (ypT0/is, ypN0) following completion of NACT [21]. Clinical and pathologic patient parameters are summarized in Supplementary Table S1. To establish the basal levels of CD20 expression in normal tissues, we used 50 breast tissue samples obtained from patients who underwent surgery for non-cancer-related treatments at the PMCCC during the same time period.

Evaluation of tumor-infiltrating lymphocytes (TILs)

Standard hematoxylin and eosin-stained full sections of pre-treatment tumor tissue were used to evaluate the presence of TILs per international guidelines [22]. Briefly, stromal lymphocytic infiltration was defined as the percent of stromal areas containing mononuclear cells including lymphocytes, plasma cells and macrophages, and stratified using a median cut-point (with infiltration in ≥15% tumor stroma area defined as high TILs).

Immunohistochemistry and scoring of CD20 and PD-L1 expression.

CD20 and PD-L1 protein expression levels were evaluated and reported following REMARK guidelines [23]. FFPETs were used to build tissue microarrays (TMAs; two 1.5 mm cores per case) as described elsewhere [19]. CD20 and PD-L1 protein expression was determined by IHC staining at the University of New Mexico Cancer Center and Johns Hopkins Hospital, respectively. IHC for CD20 (mouse monoclonal antibody; clone L26 at a concentration of 0.16 μg/mL for 20 minutes at room temperature; Dako, Carpintería, CA, USA) was performed on the Ventana’s BenchMark Ultra automatic stainer (Ventana Medical Systems, Tucson, AZ) per manufacturer’s instructions. IHC for PD-L1 was performed with the anti-PD-L1 monoclonal antibody SP142 (Spring Bioscience, Pleasanton, CA) at a concentration of 0.096 μg/mL, and antigen retrieval was performed in a citrate buffer, pH 6.0, as previously described in detail [24]. A biotinylated anti-rabbit IgG (Becton-Dickinson Biosciences, San Jose, CA) was used as a secondary antibody. Signal was developed using the ABC kit (Vector Elite PK-6100, Burlingame, CA) followed by amplification with the Perkin Elmer (Waltham, MA) tyramide signal amplification plus biotin kit (dilution 1:50). Samples were visualized using Streptavidin-HRP at a 1:300 dilution in TBST (Dako, Carpintería, CA) followed by DAB chromogen (Sigma, St. Louis, MO) and a hematoxylin counterstain. Breast tissues with known CD20+TILs and PD-L1+ status were used as positive controls; the same tissues, incubated with an isotype-matched antibody, were used as negative controls. Immunostaining was scored by board-certified pathologists (CD20 by NJ and PD-L1 by ACM) blinded to patient clinicopathologic characteristics. The percentages of membranous PD-L1 immunostaining in invasive carcinoma (epithelial) cells (PD-L1+ tumor cells) and in TILs (PD-L1+ TILs) were scored separately. PD-L1 positivity was defined as ≥5% of TILs or tumor cells expressing PD-L1, and staining was scored as an average percentage across all tissue microarray spots. The ≥5% cut-off point has been reported to be associated with clinical response to anti-PD-1 therapy [8]. Membranous CD20 immunostaining in ≥1% TILs was considered positive; this cut-off point has been associated with patient outcome in breast cancer [25]. Immunostaining and scoring for estrogen receptor (ER), progesterone receptor (PR), and human epidermal growth factor receptor 2 (HER-2) on this cohort were described previously [19].

Chemo-, hormone, and radiotherapy.

Neoadjuvant anthracycline and taxane-based chemotherapy was administered to 95% of IBC patients. HER2+ patients (3+ IHC) received trastuzumab starting in 2008 when the drug became available in the Algerian cancer center. A combination of tamoxifen and goserelin was provided to 39% of IBC patients. Aromatase inhibitors were provided to 25% of IBC. Ninety-seven percent of IBC patients underwent mastectomy, while the remaining 3% of patients died before surgery could be performed. Radiotherapy was provided to 84% of IBC patients.

Statistics

Primary outcomes were BCSS and DFS. BCSS was calculated from the date of diagnosis with death from breast cancer scored as an event and censoring of other patients at the date of last follow-up or non-disease-related death. The DFS interval was calculated from the date of diagnosis to development of first recurrence. Patients without recurrence were censored at the time of last follow-up or death. Ten stage IV IBC samples were excluded from the DFS analysis. Chi-square and Fisher’s exact tests were used to compare demographic, clinical, and pathological data between IBC patients and PD-L1+ and CD20+ results between samples. For the analysis of PD-L1+, CD20+TILs, and combined CD20+ TILs and PD-L1+ TILs, patients were divided into two groups (positive and negative) as described above. BCSS and DFS for the groups defined by PD-L1+, CD20+TILs, and CD20+TILs/PD-L1+TILs and other variables (age, size, tumor grade, pCR, lymph node status, lymphovascular invasion (LVI), TILs, ER, PR, HER2, TN, CD+20, PD-L1+ tumor cells, PD-L1+ TILs, and CD20+TILs/PD-L1+TILs) were plotted using Kaplan–Meier curves and compared using the log-rank test. The Cox proportional hazard model with single covariates was used to obtain the hazard ratios (HRs) and associated 95% confidence intervals (CIs) for the groups compared. Primary multivariable analyses were performed using the Cox model, with candidate variables of age (<50, ≥ 50 years), number of positive nodes (≤ 3, ≥ 4), LVI (yes, no), nuclear grade (2 vs. 3), and ER, PR, HER2, CD20, PD-L1 (positive vs. negative), and the presence of CD20+TILs/PD-L1+TILs (presence of both vs. others) statuses. Variables found to be statistically significant in univariate analyses were considered for inclusion in the multivariate model. Multivariate Cox proportional models were built to examine the effect of CD20+TILs, PD-L1+, and CD20+TILs/PD-L1+TILs statuses on BCSS and DFS adjusted by the effect of age, size, tumor grade, pCR, lymph node status, lymphovascular invasion, TILs, ER, PR, HER2, and TN as covariates. Final multivariate models were obtained by a Cox step-wise procedure and verified by backward elimination [26]. For each ordinal variable, the lowest value was used as the reference in computing hazard ratios (HR). Survival rates and HRs are presented with their 95% CIs. Wald tests were used to test for significance of HRs. Two-tailed P values less than 0.05 were considered statistically significant. Statistical analyses were carried out using SAS (version 9.3) and GraphPad Prism (version 7.02) software.

Results

Increased stromal TILs correlates with PD-L1 and CD20 expression.

A majority (66%) of IBCs contained PD-L1+ TILS, whereas 8% of IBCs showed PD-L1 expression on tumor cells (Fig. 1a, and Table S1). Sixty-two percent of IBCs contained CD20+ TILs; none of the tumors expressed CD20 on the malignant epithelial cells. The CD20+ TILs showed both diffuse and aggregate localization patterns, with higher numbers of B-cells generally observed within the stroma rather than within tumor cell nests (Fig. 1b).

Fig. 1. Immunostaining for PD-L1 and CD20 in inflammatory breast cancer (IBC) samples.

Fig. 1.

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(a) PD-L1+ TILs in the tumor stromal area, but not in tumor cells. (b) The same case also displays scattered CD20+ B cells. (c) There is a greater distribution of percentage PD-L1+ TILs compared to percentage PD-L1+ tumor cells across IBC cases. (d) Similarly, there is a greater distribution of percentage of CD20+ B cells across IBC cases compared to normal breast tissue. The percentage of positive cells is shown on the y-axis. Data are mean ± SD of PD-L1 or CD20 expression. Analysis was carried out using the Student’s t-test. *, P<0.001 for all.

Overall, there was a strong correlation between the presence of PD-L1+ tumor cells and PD-L1+ TILs (P=0.037; data not shown). PD-L1 expression levels in TILs were heterogeneous, with a wider range relative to tumor cells. In particular, the distribution of PD-L1+ TIL levels across the 221 tumors was statistically higher than tumor PD-L1+ (Fig. 1c). A similar range of CD20 expression levels was observed in IBC samples compared to normal non-cancer-related breast tissues (Fig. 1d).

There was a statistically significant association between high stromal TILs and the presence of either CD20+ TILs, PD-L1+ tumor cells, or PD-L1+ TILs (P<0.005; Table S2). When tumors were stratified as lymphocyte predominant breast cancer (LPBC; ≥50% tumor stromal area occupied by TILs), 15% of IBC patients were identified as LPBC (Table S1). As with high stromal TILs, LPBC status also significantly correlated with the presence of CD20+ TILs, PD-L1+ tumor cells, and PD-L1+ TILs (P<0.02; Table S2).

Tumor cell PD-L1 and TILs PD-L1 expression differentially correlates with clinical variables and outcome in IBC.

Univariate analysis showed that the presence of PD-L1+ tumor cells was significantly associated with higher survival and pCR rates, TN status, and the presence of CD20+ TILs (Table 1); the presence of PD-L1+ TILs was significantly associated with higher survival rates and the presence of CD20+ TILs (Table 1). In addition, the presence of PD-L1+ TILs was significantly associated with histologic grade 3 tumors (75% vs. 60% in grade 2 tumors; P=0.030; data not shown). These correlations persisted when the presence of PD-L1+ TILs was analyzed as a continuous variable (Wilcoxon Rank sum test; data not shown). The presence of PD-L1+ tumor cells was marginally associated with improved BCSS (Fig. 2a), but not with DFS (P =0.122; data not shown). In contrast, the presence of PD-L1+ TILs was significantly associated with better DFS (Fig. 2b), but not with BCSS (P =0.108; data not shown). Further, in TN IBC patients, PD-L1+ TILs showed a trend towards better DFS (Fig. 2c) and significantly improved BCSS (Fig. 2d).

Table 1.

Correlation of PD-L1 and CD20 expression with clinical parameters.

Variable PD-L1+ tumor cells PD-L1+ TILs* CD20+ TILs
Negative Positive P Negative Positive P Negative Positive P
Survival
Alive 57 (85.1) 146 (94.8) 0.029 16 (23.9) 59 (38.3) 0.045 18 (27.3) 64 (42.7) 0.034
Dead 10 (14.9) 8 (5.2) 51 (76.1) 95 (61.7) 48 (72.7) 86 (57.3)
Relapses
Absent 81 (89.0) 122 (93.8) 0.218 24 (26.4) 51 (39.2) 0.060 26 (29.2) 56 (44.1) 0.032
Present 10 (10.1) 8 (6.2) 67 (73.6) 79 (60.8) 63 (70.8) 71 (55.9)
pCR*
Absent 166 (93.3) 12 (70.6) 0.009 63 (94.0) 115 (89.8) 0.427 72 (98.6) 103 (86.6) 0.003
Present 12 (6.7) 5 (29.4) 4 (6.0) 13 (10.2) 1 (1.4) 16 (13.5)
TN*
Others 167 (82.3) 10 (55.6) 0.012 58 (77.3) 119 (81.5) 0.480 70 (85.4) 105 (78.4) 0.217
ERPRHER2 36 (17.7) 8 (44.4) 17 (22.7) 27 (18.5) 12 (14.6) 29 (21.6)
CD20
Negative 80 (97.6) 118 (88.1) 0.020 36 (51.4) 46 (31.5) 0.006
Positive 2 (2.4) 16 (11.9) 34 (48.6) 100 (68.5)
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*

pCR, pathological complete response; TN, triple-negative breast cancer; TILs, tumor-infiltrating lymphocytes

Fig. 2. PD-L1+ tumor cells and PD-L1+ TILs are associated with improved outcome in IBC and TN IBC patients.

Fig. 2.

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Kaplan-Meier survival estimates of BCSS (a, d) and DFS (b, c) in patients with PD-L1+ tumor cells (a) or PD-L1+ TILs (b-d) compared to negative (<5%) PD-L1+ tumor cells or PD-L1+ TILs. The number of patients at risk of death and/or relapse from IBC are shown at 0, 12, 24, 36, 48, 72, 84, and 96 months below the x-axis.

CD20 TILs expression prognosticates DFS in IBC patients.

The presence of CD20+ TILs was significantly associated with higher survival rates, absence of relapses, and higher pCR (Table 1). The presence of CD20+ TILs was also associated with improved DFS, but not with BCSS in IBC patients (Fig. S1).

Co-existence of CD20+ TILs and PD-L1+ TILs shows a synergistic effect on clinical variables and improved outcome in IBC patients.

Given the significant association of CD20+ TILs, PD-L1+ TILs, and PD-L1+ tumor cells with clinical outcomes (Table 1), we next analyzed the effect of the presence of CD20+ TILs plus PD-L1+ TILs, and CD20+ TILs plus PD-L1+ tumor cells on clinical variables. We found that the presence of CD20+ TILs with PD-L1+ tumor cells was significantly associated with high survival rates, high pCR rates, high TILs, and TN IBC (Table 2). The presence of CD20+ TILs and PD-L1+ TILs was associated with high survival rates, absence of relapses, high pCR and high TILs (Table 2). Next, we analyzed the effect of the presence of CD20+ TILs and PD-L1+ TILs on BCSS and DFS. We found that combining CD20+ TILs with PD-L1+ TILs resulted in a highly significant improvement in both DFS (Fig. 3a) and BCSS (Fig. 3b). As illustrated in Fig. 2b, a 50% DFS rate was observed at ~54 months for patients with PD-L1+ TILs irrespective of CD20 status, whereas the same DFS rate was observed at ~62 months for patients with both CD20+ TILs and PD-L1+ TILs (compare Fig. 2b (P=0.035) with 3a (P=0.0005)). Further, while the DFS curves are nearly parallel for patients with PD-L1+ TILs until ~50 months (Fig. 2b), the survival curve for patients with CD20+ TILs and PD-L1+ TILs separates as early as ~30 months and remains higher for the period analyzed (Fig. 3a). This pattern was striking in BCSS for the combination of the two biomarkers. In particular, the presence of PD-L1+ TILs was not associated with BCSS (P=0.108; data not shown), but patients with both CD20+ TILs and PD-L1+ TILs showed an improved BCSS as early as 30 months (P=0.002; Fig. 3b). Further, subset analysis in TN IBC patients showed that while the presence of PD-L1+ TILs was not associated with DFS (Fig. 2c), the presence of CD20+ TILs and PD-L1+ TILs was significantly associated with improved DFS (Fig. 3c), and with BCSS (Fig. 3d).

Table 2.

Correlation of CD20/PD-L1 expression with clinical parameters.

Variable CD20+TILs/PD-L1+ tumor cells CD20+TILs/PD-L1+TILs
Negative Positive P Negative Positive P
Survival
Alive 57 (27.8) 10 (62.5) 25 (20.7) 42 (42.0)
Dead 148 (72.2) 6 (37.5) 0.008 96 (79.3) 58 (58.0) 0.0007
Relapses
Absent 81 (38.5) 10 (62.5) 39 (32.2) 52 (52.0)
Present 124 (60.5) 6 (37.5) 0.111 82 (67.8) 48 (48.0) 0.004
pCR*
Absent 168 (93.3) 10 (66.7) 101 (95.3) 77 (86.5)
Present 12 (6.7) 5 (33.3) 0.005 5 (4.7) 12 (13.5) 0.041
TILs*
Low (<15%) 105 (51.2) 1 (6.3) 72 (59.5) 34 (34.0)
High (≥15%) 100 (48.8) 15 (93.7) 0.0004 49 (40.5) 66 (66.0) 0.0002
TN*
Others 168 (81.9) 9 (56.2) 98 (81.0) 79 (79.0)
ERPRHER2 37 (18.1) 7 (43.7) 0.021 23 (19.0) 21 (21.0) 0.737
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*

pCR, pathological complete response; TILs, tumor-infiltrating lymphocytes; TN, triple-negative breast cancer.

Fig. 3. Co-existence of CD20+ TILs and PD-L1+ TILs prognosticates better outcome in IBC and TN IBC patients.

Fig. 3.

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Kaplan-Meier survival estimates of DFS (a, c) and BCSS (b, d) for patients with CD20+ TILs and PD-L1+ TILs (positive) in IBC (a, b) and TN IBC (c, d) compared to patients without both CD20+ TILs and PD-L1+ TILs (negative). The number of patients at risk of death and/or relapse from TN IBC are shown at 0, 12, 24, 36, 48, 72, 84, and 96 months below the x-axis.

Expression of tumor cell PD-L1, TILs PD-L1, and TILs CD20, as well as the co-existence of CD20 and PD-L1 expression, by tumor subytpe, is shown in Supplementary Table S3. Other than the associations with TN IBC described above, there were no significant associations with ER, PR, and HER2 status.

Multivariate analysis

Multivariate analysis, using a stepwise evaluation, and verified by backward and subset variable analyses, determined that the presence of both CD20+ TILs and PD-L1+ TILs was the best predictor tested as a significant favorable prognostic factor of DFS and BCSS in the entire IBC cohort and among TN IBC patients (Table 3).

Table 3.

Multivariate analyses for CD20 and PD-L1 expression in IBC and TN IBC subgroup.

Variable HR 95%CI P
DFS*
IBC CD20+TILs/PDL1+ TILs 0.53 0.37–0.77 0.001
TN IBC CD20+TILs/PDL1+ TILs 0.39 0.17–0.88 0.023
BCSS*
IBC CD20+TILs/PDL1+ TILs 0.60 0.43–0.85 0.003
TN IBC CD20+TILs/PDL1+ TILs 0.38 0.17–0.83 0.016
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*

DFS, disease-free survival; BCSS, breast cancer-specific survival; TN, triple-negative breast cancer.

Discussion

To our knowledge, this is the largest cohort used to characterize immune infiltrates in IBC, and the first study to examine both an immune checkpoint inhibitor and CD20 in IBC. The strong correlation between PD-L1 expression, independent of the cellular location, with the presence of high stromal TILs, suggests the existence of a preexisting immune-active microenvironment suppressed by PD-L1 [7], and strongly supports the exploration of anti-PD-1/PD-L1 therapy in IBC patients. As part of standard neoadjuvant therapy similar to that administered in the United States, Algerian IBC patients receive doxorubicin, cyclophosphamide, and taxanes, all of which are bona fide inducers of immunogenic cell death [27]. Hence, one could expect that pre-existing immunity could be activated with these agents and further amplified with anti-PD1/PD-L1 treatment to result in efficacious treatments in IBC patients whose tumors contain PD-L1+ TILs.

Only a few prior studies have examined PD-L1 expression in IBC [28,29]. A study of 112 IBCs by Bertucci, et al. reported high PD-L1 mRNA in pretreatment IBC samples, a strong association between PD-L1 mRNA with pCR, TILs, basal and HER2 tumor types, and a gene signature characteristic of a strong cytotoxic response involving T cells, dendritic cells, and B cells [28]. He et al. analyzed 68 post-neoadjuvant IBC tumor samples and report that worse overall survival was significantly associated with positive PD-L1 status [29]. We found that PD-L1 in either tumor or TILs was associated with pCR and high TILs. However, unlike Bertucci, et al. and He et al., our study found significant associations between PD-L1+ tumor cells and improved BCSS, and between PD-L1+ TILs and longer DFS. The prognostic role of PD-L1 in breast cancer remains unclear, with studies often describing contradicting results. As He et al. summarize in their recent report, PD-L1 expression has been shown to be both a favorable and an adverse variable [29]. The discrepancy in outcome correlations amongst studies may be the result of variations in cohort size, specimen types, IHC techniques, and cutoff values. The divergence in cell type expressing PD-L1 and BCSS versus DFS points to potential immune differences in cellular or cytokine variables that induce PD-L1 on tumors versus on TILs. It is possible that the improved DFS association with expression of PD-L1 on TILs may imply a more systemic antitumor immune response.

The study reported here is the first to highlight the clinical relevance of CD20+ B cells in IBC. Our findings suggest that, in addition to T cell-mediated immunity, B cells play an important role in antitumor immunity in IBC. It has been shown that CD20+ TILs was strongly associated with breast cancer response to NACT [17] and with improved BCSS and longer DFS [18]. Of note, in both of these studies, the prognostic role of CD20+ TILs was independent of CD8+ TILs, underscoring the biological relevance of B cell immunity in conjunction with the cellular immune response in breast cancer [17,18].

It has been proposed that there is a clonally restricted, antigen-directed B cell antitumor response, and the presence of somatic hypermutation sequences is suggestive of antigen-experienced B cells in the tumor microenvironment [30]. The positive prognostic synergy observed in IBC tumors with both CD20+ TILs and PD-L1+ TILs might be the result of cooperation between the cellular and humoral immune responses. While cellular injury and immunogenic cell death induced by chemotherapy can lead to formation of new immunogenic epitopes, chemokine and cytokine secretion, antigen cross-presentation, activation of dendritic cells, and induction of tumor-specific cytotoxic T cells (cellular response) [31], the presence of B cells might enhance such T cell responses by producing antibodies against breast tumor antigens, stimulating cytokine and chemokine secretion, serving as local antigen-presenting cells, and organizing the formation of tertiary lymphoid structures that sustain long-term immunity (humoral response) [32]. As immunotherapy for breast cancer advances, it will be important to evaluate B cell presence, antigen specificity, and activity to determine the extent of B cell modulation and its relationship to patient response. Additional studies, including validation in a second cohort, are warranted to confirm the synergistic relationship between T cells and B cells in IBC.

In addition to the large number of IBC samples evaluated, this study has a few other strengths that should be noted. First, the diagnosis of IBC in all patients was confirmed using standard clinical and histopathological methods [20]. Second, the IBC database is well-annotated and from the main cancer center in Algeria, and is likely well representative of the general population in Algeria. Due to socialized health care in Algeria, the IBC patients received similar standard of care treatments, which reduces treatment variability when analyzing clinical outcomes. Third, the CD20 and PD-L1 labeling were characterized with validated antibodies, and PD-L1 scoring was performed separately on tumor cells and TILs in each cancer sample providing a unique opportunity to evaluate the individual effect of PD-L1 expression on clinical associations and patient outcome.

By identifying IBC as a disease likely to benefit from immunomodulatory treatments, this study provides a rationale for the use of targeted immunotherapies. Antibodies that block the PD-1/PD-L1 axis and immunomodulatory therapies supporting B cell responses are potentially valuable therapeutic approaches targeting T and B cell infiltrated tumors in IBC, which currently has poor prognosis with the currently available treatment strategies.

Supplementary Material

Fig. S1. The presence of CD20+ TILs is associated with improved DFS, but not BCSS in IBC patients.

Kaplan-Meier survival estimates of DFS (a) and BCSS (b) in IBC patients with positive (≥1%) CD20+ TILs compared to negative (<1%) CD20+ TILs. The number of patients at risk of death and/or relapse from IBC are shown at 0, 12, 24, 36, 48, 72, 84, and 96 months below the x axis.

Table S1
Table S2
Table S3

Acknowledgements

This study was supported in part by the GlaxoSmithKline Oncology Ethnic Research Initiative Grant (Drs. Arias-Pulido and Chaher; no grant number), and the UICC ICRETT fellowship (Dr. Chaher; ICR/09/043), and the National Institutes of Health (Dr. Prossnitz; CA163890). We would like to thank the PMCCC Human Tissue Repository for providing tissue samples and clinical data (Algiers, Algeria); Karen Buehler (Tricore, NM) for technical support with IHC.

Abbreviations:

IBC

Inflammatory breast cancer

TN

Triple-negative

PD-1

Programmed cell death 1

PD-L1

Programmed cell death ligand 1

TILs

Tumor infiltrating lymphocytes

pCR

Pathological complete response

BCSS

Breast cancer-specific survival

DFS

Disease-free survival

HR

Hazard ratio

CI

Confidential interval

NACT

Neoadjuvant chemotherapy

FFPETs

Formalin-fixed paraffin embedded tissues

Footnotes

Disclosure/conflict of interest

LAE receives research funding from Genentech, Roche, EMD Serono, Merck, Astra Zeneca, and Corvus. She has served on advisory boards for Astrazeneca, Medimmune, Syndax, Bayer, and Abbvie. ACM receives research funding from Bristol-Myers Squibb. The remaining authors declare no conflict of interest.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Fig. S1. The presence of CD20+ TILs is associated with improved DFS, but not BCSS in IBC patients.

Kaplan-Meier survival estimates of DFS (a) and BCSS (b) in IBC patients with positive (≥1%) CD20+ TILs compared to negative (<1%) CD20+ TILs. The number of patients at risk of death and/or relapse from IBC are shown at 0, 12, 24, 36, 48, 72, 84, and 96 months below the x axis.

NIHMS988613-supplement-Fig__S1.tif (3.1MB, tif)
Table S1
NIHMS988613-supplement-Table_S1.xlsx (12.5KB, xlsx)
Table S2
NIHMS988613-supplement-Table_S2.xlsx (11.8KB, xlsx)
Table S3
NIHMS988613-supplement-Table_S3.xlsx (12.6KB, xlsx)

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