Background
Breast cancer has not been traditionally considered an immunogenic cancer type. However, there is an increasing body of evidence suggesting that an effective immune response may greatly impact on the clinical behavior of this malignancy. Tumor lymphocyte infiltration is associated with favorable prognosis in early triple-negative and human epidermal growth factor receptor type 2 (HER2)-positive breast cancer phenotypes [
1‐
4] and may influence the response to systemic therapies [
3‐
6]. Information on the association between the immune host response and the colonization of the brain by tumor cells is scarce. The central nervous system (CNS) has long been considered an immunologically privileged site [
7]. Actually, CNS is an immune specialized site under a tight regulatory control network linking microglia, astrocytes and lymphocytes [
8].
Brain metastases in preclinical and clinical models are characterized by high proliferation, apoptosis, and inflammatory response in the form of surrounding extensive reactive gliosis [
9]. It is postulated that the reactive astrocytes reduce apoptosis mediated by the cytotoxic agents by sequestering calcium from the cytoplasm of tumor cells or by secreting metastasis-stimulating chemokines [
10]. In the inflammatory and degenerative processes, CNS reactive glial cells actively participate in the restimulation of T cells through the secretion of some chemokines [
9,
11,
12]. This increases the influx of regulatory T cell (T
reg) lymphocytes, resulting in silencing of the immune response.
The programmed cell death protein 1 receptor (PD-1) and its ligands, programmed cell death protein 1 receptor ligand (PD-L)1 and PD-L2, also known as B7-H1 and B7-DC, respectively, play a crucial role in the induction and maintenance of peripheral tolerance, and protect tissues from autoimmune attack [
13]. The PD-1/PD-L axis is also a key getaway pathway serving in many cancers as an “immune control” [
14,
15]. Several studies suggest that immune response to malignant processes in the brain may be related to the type of cancer [
16‐
19]. Better understanding of the local immune response accompanying brain metastases (BM) may pave the way to the development of novel preventive and therapeutic strategies in breast cancer patients. This retrospective study aimed to assess the correlation between selected parameters of immune response in breast cancer brain metastases (BCBM) and their impact on overall survival.
Discussion
We have presented a comprehensive analysis of several immune parameters in BCBM. This is also the largest study analyzing the clinical relevance of these parameters. Our data indicate that the PD-1/PD-L axis may play an important role in the local immune response accompanying BCBM. Furthermore, we observed that the infiltration of the brain microenvironment by CD4+ and CD8+ lymphocytes, macrophages/microglia and reactive astrocytes is a common occurrence, and these features are probably independent of BCBM phenotype and previous systemic therapies.
There are two leading hypotheses explaining PD-L1 expression in tumors: the first based on the innative, and the second on the adaptive model [
20]. In the innative model, PD-L1 expression is independent of the tumor microenvironment and is influenced by intrinsic cell signaling pathways. The adaptive model assumes that TILs are the key factor driving PD-L1 expression and that immune resistance is exerted by tumor cells in response to endogenous antitumor activity [
13,
21‐
23]. This allows tumor cells to escape immune destruction despite endogenous antitumor immune reactions. Previous studies showed that the PD-1/PD-L axis regulates the induction and maintenance of peripheral tolerance and protects tissues from autoimmune attack (reviewed by Jin et al. [
23]). PD-L1 expression in the CNS was identified in glioblastoma and in human brain metastases from melanoma, renal cell carcinoma, lung cancer, colon cancer, and breast cancer, and the PD-1/PD-L1 axis in primary brain lymphomas [
16‐
19]. Here, we demonstrated that PD-L1 and PD-L2 expression is also a common occurrence in BCBM, irrespective of the primary tumor and brain metastasis phenotype.
Recently, PD-L1 expression was found to be more common in primary triple-negative breast cancer [
24,
25], but we did not find such a correlation in BCBM. However, PD-L1 expression is a dynamic process in normal conditions and is influenced by cytokines, such as interferon (INF)-γ [
26]. In turn, PD-L1 expression in tumor cells may be influenced by systemic therapy. Moreover, biopsy timinig (at diagnosis vs. at progression) to determine PD-L1 expression may be critical in patient selection for immune checkpoint inhibitors or other experimental therapies [
27]. Hitherto, there are no data on the comparison of PD-L expression in primary breast cancer and in the corresponding BCBM. In a recent study by Berghoff et al. [
28] there was no correlation between PD-L1 expression in brain metastases from various solid tumors and TIL density, and the authors also postulated that the density of CD3+, CD8+ and CD45RO+ TILs, and the calculated immunoscore, are positively correlated with survival. In the recent study by Harter et al. [
19], which included several tumor types, there was no significant prognostic impact of TIL expression in brain metastases in the entire population, and there was a strong trend towards better survival in brain metastases from melanoma with high levels of PD-L1 [
19].
The biological role of PD-L2 is less well-understood. Recent studies showed that PD-L2 can be induced on antigen-presenting cells, such as macrophages, dendritic cells, T cells and a wide variety of non-immune cells, depending on the microenvironmental stimuli [
29]. Some studies suggest an adverse prognostic impact of PD-L expression, whereas others, including ours, did not find such a relationship, or even showed the opposite [
18,
19,
30,
31]. These differences may likely be due to different methods used for the detection of ligand expression and the lack of standardized criteria for assessment of PD-L expression.
PD-1 is an inhibitory co-receptor expressed on activated and exhausted T cells [
13‐
15,
32,
33]. We demonstrated that PD-1 expression on TILs in BCBM is independently associated with increased OS. However, our study included patients with limited numbers of BCBM eligible for resection and with good performance status, and most had controlled extracranial disease. Hence it is unknown whether this observation applies to all patients with BCBM. Although PD-1 expression correlated with CD4+ and CD8+ TILs, increased OS was not directly related to the mere presence of TILs, an observation suggesting the importance of preexisting active immunity. Interestingly, in the abovementioned study by Harter et al. [
19], PD-1+ lymphocytes and the ratio between PD-1 and CD8+ cells were higher in smaller than in larger metastases. This finding may indicate that in smaller metastases the lymphocytic immune response is activated but functionally impaired. It is also possible that T cells may control the tumor size transiently before becoming exhausted.
Data on the prognostic value of PD-1 expression on TILs in various malignancies are scarce and inconsistent. In primary renal cell carcinoma, on univariate analysis PD-1 expression on mononuclear immune cell infiltrates was found to increase the risk of cancer-specific death and overall mortality [
34]. However, in this study PD-1 was associated with more advanced disease, the presence of coagulation, tumor necrosis, and sarcomatoid differentiation. Hence, this feature may be associated with more aggressive disease characteristics rather than be an adverse prognostic factor per se. Similarly, in operable breast cancer, PD-1+ immune cell infiltration in the primary tumor is reported to correlate with shorter survival [
35]. In contrast to these reports, in a series of recent studies the PD-1/PD-L1 axis had a favorable effect, supporting the role of preexisting antitumor immunity [
5,
36,
37]. Notably, all these studies relate to primary tumors, whereas we included BCBM, in which immune mechanisms may be substantially different due to the immune privilege of the CNS [
7,
37]. Nonetheless, evidence of a favorable prognostic role of PD-1 expression on TILs in BCBM should be considered cautiously and warrants confirmation.
We did not observe a relationship between expression of PD-1 on TILs, and PD-Ls expression in BCBM, and neither did we find major differences across breast cancer phenotypes, except for more common PD-1 expression in
HER2-amplified primary tumors. According to the adaptive resistance hypothesis, cancer cells can upregulate the expression of PD-L1 after encountering T cells, mostly via IFN-γ. However, there are data suggesting that cancer cells also express PD-L1 by an intrinsic, INF-γ independent mechanism [
38,
39]. Further, some genetic abnormalities, such as a loss of phosphatase and tensin homolog in glioma or triple-negative breast cancer, and epidermal growth factor receptor mutations in lung cancer, can directly upregulate PD-L1 on cancer cells [
24,
40,
41]. On the other hand, it has been speculated that the local CNS microenviroment may in some way suppress the INF-γ mediated response, thus, paradoxically decreasing brain tissue damage [
37]. Interestingly, only an undetermined fraction of lymphocyte infiltration dies through the interaction with the PD-1/PD-L axis. Additionally, there are non-PD-1 costimulatory receptors for PD-L, which are responsible for the enhanced effector function of PD-L-expressing tumor cells [
42,
43].
In this series, besides PD-1 expression, macrophages/microglia infiltration was also found to be associated with significantly longer survival after the excision of BCBM. The macrophages/microglia play a key role in the development of innate and adaptive immune response in the brain [
44]. These cells are perceived as a main source of proinflammatory cytokines and more as antigen-presenting cells, and actively participate in the T cell restimulation [
8,
9,
44]. The limitation of our study was identifying macrophages/microglia exclusively by CD68 staining, as other markers (such as CD14, CD11b, and/or MHC-II) might have likely provided more data on the prognostic role of these cells.
Some preclinical studies suggest a potential role for immune checkpoint inhibitors in mammary tumors, particularly HER2+ phenotypes. Combining trastuzumab with inhibitors of negative T cell regulation, such as anti-PD-1, anti-PD-L1 or anti-CTLA4 antibodies, may increase antitumor efficacy [
45,
46]. In HER2+ patients receiving trastuzumab, PD-1 inhibition stimulates CD8+ cells producing INF-γ, and may increase the therapeutic effect of this antibody [
46]. However, in our study trastuzumab administered before the development of BCBM did not affect the expression of TILs, CD68+ cell infiltration, or PD-1 and its ligands in BCBM. The brain microenvironment may promote HER2 expression via secretion of specific cytokines, such as neuregulin [
47]. We recently demonstrated that expression of quantitative HER2 and p95 - its truncated, constitutively active form - is significantly increased in BCBM compared to primary breast cancers [
48]. In that study, p95 expression in brain metastases also correlated with poorer clinical outcome.
Currently, PD-1 inhibitors, such as pembrolizumab and nivolumab, are a subject of clinical investigation in non-small cell lung cancer and melanoma with brain metastases (NCT02085070, NCT02320058), whereas no data are available for anti-PD therapies in BCBM. Hence, there is a rationale for investigation into boosting the host antitumor immune response by inhibiting the inhibitors (via increasing lymphocyte influx to the brain or inhibiting PD-L expression in tumor cells) also in BCBM. Pembrolizumab has shown promising effects and a good safety profile in PD-L1-positive advanced triple-negative breast cancer (KEYNOTE-012 study; NCT01848834) and in heavily pretreated ER+/HER2– breast cancer (KEYNOTE-028 study; NCT02054806) [
49,
50]. PD-L1 inhibitors, atezolizumab (MPDL3280A) and avelumab (MSB0010718C) appear to be particularly active in triple-negative breast cancer [
51,
52]. Several ongoing clinical trials are investigating other immune checkpoint inhibitors in both in locally advanced and/or metastatic breast cancer and in the adjuvant setting (reviewed in Chawla et al. [
53]).
Competing interests
The authors declare that they have no competing interests.
Authors’ contributions
RD was the principal investigator who conceived, coordinated and oversaw the study and wrote the manuscript. RP carried out the immunoassays and data analysis and drafted the manuscript. BR, TM, and TT participated in the collection of clinical data, performed data analysis, and drafted the manuscript. BJ, BCA, WO, and WK participated in the preparation of the biological samples, performed data analysis, and drafted the manuscript. WAO, EKW, and AK participated in the collection of clinical data, performed data analysis, and drafted the manuscript. SL participated in data analysis and drafted the manuscript. WB carried out the immunoassays and data analysis and drafted the manuscript. JJ conceived, coordinated and oversaw the study, and wrote the manuscript. All authors read and approved the final manuscript.
Renata Duchnowska, MD, PhD, oncologist; Rafał Pęksa, MD, PhD, pathologist; Barbara Radecka, MD, PhD, oncologist; Tomasz Mandat, MD, PhD, neurosurgeon; Tomasz Trojanowski, MD, PhD, neurosurgeon; Bożena Jarosz, MD, PhD, pathologist; Bogumiła Czartoryska-Arłukowicz, MD, oncologist; Wojciech P. Olszewski, MD, PhD pathologist; Waldemar Och, MD, neurosurgeon; Ewa Kalinka-Warzocha, MD, PhD, oncologist; Wojciech Kozłowski, MD, PhD, pathologist; Anna Kowalczyk, MD, PhD, oncologist; Sherene Loi, MD, PhD, oncologist; Wojciech Biernat, MD, PhD, pathologist; Jacek Jassem, MD, PhD, oncologist.