Contributors DPS, MGC and SB reviewed the literature, wrote the manuscript and AJ revised the text.
Competing interests None declared.
Patient consent Obtained.
Ethics approval Hospital Prof Doutor Fernando da Fonseca.
Provenance and peer review Not commissioned; externally peer reviewed.
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Breast cancer (BC) is the most common malignancy and the second cause of death in women of high income countries.1 WHO estimates that by 2020 one in every eight women will develop BC.1 The 5-year survival for BC is 98% for localised disease, 84% for regional disease, but only 23% for distant disease.2 A quarter of patients with early BC will relapse and half of the women with axillary lymph node involvement will relapse.2 There are several clinical types of BC, defined by amplification of specific markers. Steroid hormone receptor overexpression (oestrogen and/or progesterone receptors: ER, PgR) define the most abundant type of BC. Roughly 70% of BC is ER-positive and/or PgR-positive3 4 and this type of BC is amenable to hormonal therapy. Human epidermal growth factor receptor type 2 (HER2) amplification, defines a second type, with an incidence of roughly 20%5 and it is responsive to anti-HER2 directed therapy, namely trastuzumab and, more recently, lapatinib, pertuzumab and TDM1.6 HER2+ BC can be either ER+ or ER−, but its dominant biological driver and clinical feature is traceable to HER2 gene amplification, a potent oncogene. The disease-free survival at 5 years for these two BC subtypes is over 95%.2 The ALTTO trial revealed that the addition of lapatinib to trastuzumab in patients with HER2+ BC had no benefit in disease-free survival.7
The remaining cases are termed triple negative BC (TNBC), breast carcinomas that neither express ER nor PgR and do not have overexpression of HER2. TNBC can represent between 10% to 20% of all BC cases8 and it is the subtype with the worse prognosis when compared with OR-positive (and/or PgR-positive) disease and HER2-positive disease.9 10 In fact, half a million women die in the world every year with BC, of which 150 000 are estimated to be TNBC cases,1 representing around 30% of the BC associated deaths. This may be due in part to the fact that it is the only clinical subtype of BC for which there is no approved adjuvant targeted therapy. In fact, in the pre anti-HER2 therapy era, HER2+ BC had an even more dismal survival than TNBC11 12 and currently HER2+ BC has a disease-free survival at 5 years comparable to hormone-positive disease. When faced with TNBC, clinicians are limited to the use of surgery, radiotherapy and chemotherapy. However, not all patients with TNBC respond to chemotherapy13–15 and this exemplifies what our clinical experience and emerging data suggest—TNBC may be more than a single disease.
Indeed, in the past few years there has been an effort to further divide TNBC cases in order to better understand the distinct patient outcome and to develop new specific therapies for each TNBC subclass.16–18 In this review, we will analyse these new classifications and try to explore new targets that can be used in new therapies.
Clinical and epidemiological heterogeneity in TNBC
TNBC presents a considerable heterogeneity concerning the age of diagnosis, prognosis and response to treatment, to name a few. The clinical evidence for such heterogeneity is summarised in table 1. Normally and succinctly, TNBC is associated with African women, younger age, higher grade tumours, high mitotic index, more advanced stage at diagnosis, namely inflammatory BC, aggressive biology and poor prognosis, as shown in figure 1.19 The peak risk of relapse is at the third year and in this scenario the clinical outcome worsens. Also, survival after metastasis relapse is reduced when compared with other BC subtypes.8
Considering the age at diagnosis, there is increasing evidence that TNBC may have a bimodal distribution with the first incidence peak in premenopausal patients and a second peak after 70 years of age.20–23 Prognosis of stage-matched premenopausal TNBC is worse than older age TNBC. One can speculate on the underlying biology that explains this difference in outcome. Premenopausal TNBC would be a disease with a few very powerful molecular drivers, more akin to single hit neoplasms; whereas, geriatric TNBC would be a disease of generalised chromosomal instability, a hallmark of ageing tissues and of geriatric cancer.24 In fact, such genomic heterogeneity has been observed in TNBC using deep sequencing.12 25
TNBC has an aggressive behaviour with presentation of de novo metastatic BC, large locally advanced breast lesion or metastatic disease developing shortly after adjuvant chemotherapy.26–28 TNBC frequently metastasises to the viscera, liver, lung or brain.29–32 However, this is not always the case as it may also have an oligometastatic phenotype closer to ER+ BC, with only lymph node and bone disease.33 TNBC is also heterogeneous in terms of time of recurrence (figure 2). Unlike ER+ BC, whose recurrence curve is linear, TNBC has a higher rate of recurrence in the first 5 years and a lower rate of recurrence afterwards; nevertheless, there appears to be two distinct recurrence peaks.23 34 The pattern of late recurrence is generally associated with less aggressive disease, frequently with bone metastases.9 33 The apparent different paths of tumour progression in TNBC might be driven by confounding factors. These differences may be just a proxy for age of incidence;35 additionally, the group of patients that have late recurrence and good prognosis, may represent the 10% of tumours that are false negatives for ER.36
The association between African women or women with African ancestry and increased susceptibility to more aggressive BC goes back to the 1990s, before BC subtypes were part of our thought process. At this time, it was known that BC in African women was more frequently ER-negative, affected younger women and, when stage and age matched, had worse prognosis.37–39 Indeed, African women have more frequently premenopausal aggressive TNBC21 40–42 and their risk of developing TNBC is three times higher, independent of other risk factors for BC.43 Moreover, Caucasian and Asian women tend to have TNBC with a later age of onset and less aggressive clinical course,44–46 but still with bad prognosis.47 African women are less responsive to neoadjuvant chemotherapy (NACT) and have worse prognosis when diagnosed with locally advanced TNBC.48
Regarding incidence, TNBC has been defined as a rare disease in northern Europe and in some states of the USA,49 accounting for less than 15% of BC cases.50 Whereas in some US states, where more than 20% of the population is African, the frequency of TNBC is substantially higher. African premenopausal women were twice as likely to have TNBC than Caucasian women in North Carolina (39% vs 14%)40 and Atlanta cohorts (47% vs 22%).21 Additionally, an epidemiological study from Nigeria reported that 59% of BC cases in their country were TNBC.41
A possible explanatory factor for these ethnicity-based differences may be the breast density, which is higher in African women, and the rigidity of the extracellular matrix can be a factor that drives the malignancy.51 52 Also, cancer in dense breasts is harder to diagnose by mammography,51 53 raising the possibility that the worse prognosis in these cases might be due to a delay in diagnosis. However, stage matching in epidemiological studies eliminates this hypothesis.54 55 Additionally, denser mammary glands may have distinct growth factor profiles that predispose women to more aggressive cancer with oestrogen independence. This difference may also be caused by the fact that African women can have a distinct subtype of TNBC that could be more aggressive and more resistant to chemotherapy when compared with women from other ethnicities. This hypothesis will be further explored later in this review.
An analysis of outcome of 25 000 patients with cancer enrolled in the Southwest Oncology Group phase III clinical trial54 showed that ethnicity does not affect outcome of carcinoma of the lung, colon, lymphoma, leukaemia or multiple myeloma; but that it affects sex hormone responsive carcinomas of the breast, ovary and prostate. Biologically, there are data suggesting TNBC in Africans has more signalling through growth factor pathways such as insulin growth factor receptor type 1 (IGF1) and the vascular endothelial growth factor-activated genes,56 although IGF1 signalling is increased in obese individuals, which was not controlled in this study, and African women have higher body mass index than Caucasians. In fact, the link between obesity and TNBC was shown in the Carolina Breast Study.40 Moreover, the stem cell renewal pathway Wnt β-catenin is active in TNBC57 and specifically more active in tumours of African patients.58 The stem cell marker ALDH1 was studied with tissue microarrays in a cohort of 192 TNBCs from Ugandan patients and was found to be present in 48% of the tumours and correlated with high histological and nuclear grades.59
Response to chemotherapy
One of the most striking causes of heterogeneity of TNBC is the different sensitivity to chemotherapy, where patients are either chemoresponsive or chemoresistant.60 On one hand, TNBCs are among the most chemoresponsive BCs: data from neoadjuvant studies show that the fraction of tumours experiencing pathological complete response (pCR) is mostly comprised of TNBC.60–65 On the other hand, TNBCs are frequently chemoresistant tumours as documented by the short survival of patients with metastatic disease in published series.66 67 One could argue that the apparent chemoresponsiveness found in neoadjuvant studies evolves into a chemoresistant phenotype. Nevertheless, this does not seem to be the case since, in large neoadjuvant trials with long follow-up, those women that obtain a pCR consistently maintain survival advantage over the years.68 This suggests that chemosensitivity is a hard-wired feature of a particular tumour.69 Chemoresistance is linked to abundance of stem-like cells that are pluripotent and quiescent and are therefore able to undergo epithelial to mesenchymal transition (EMT) and are resistant to therapy that targets dividing cells. In gene expression studies, these TNBCs enriched in cells that have properties similar to stem cells are classified as claudin low tumours.70
Due to this heterogeneity in response rates to standard chemotherapy, several other therapeutic strategies are being analysed (table 2). These strategies encompass poly (ADP-ribose) polymerase inhibitors (PARPi) and platinum agents (see next section); anti-VEGF drugs,71 72 namely bevacizumab; capecitabine, which is a prodrug that is converted to fluorouracil;72 or ixabepilone that stabilises microtubules.73 74 Although these approaches are still being tested in clinical trials, the most promising one is the use of olaparib (a PARPi) in HER2-negative metastatic disease with germline BRCA mutation (gBRCAm).75 The other clinical trials are still ongoing or haven’t shown significant differences between patient arms.
Moreover, there is increasing evidence that anticancer immune responses may contribute to the control of cancer after conventional chemotherapy.76 Therefore, as we later explore, the fact that TNBC tumours exhibit a high heterogeneous immune microenvironment, may also be associated with the different chemoresistance/chemosensitivity profiles among TNBC.
Due to the different levels of heterogeneity in TNBC here described, it was essential to come up with a subclassification of TNBC in order to develop new targeted therapies, especially in the cases where chemotherapy is not effective.
The triple negative subclassification
In general, BC can be classified into multiple subtypes according to different criteria. TNBC can be further subtyped using histological, developmental and molecular criteria.
Histologically, the majority of TNBC is grade 3 or poorly differentiated (figure 3).77 78 The few remaining cases are rare histological types like adenoid-cystic, medullary, apocrine, metaplastic or inflammatory BCs.79–82
There have been attempts to establish a relationship between normal mammary gland development and occurrence of BC, that is, to map different types of BCs into different stages of the mammary gland development,83 as has been done for acute myeloid leukaemia.84 Some TNBCs would correspond to a more primitive subtype of tumour, closer to the most undifferentiated BC progenitor cell (stem cell). This reasoning is supported by the observation that the putative BC stem cells in in vitro models are ER-negative and that, as they subsequently differentiate into mammary gland luminal cells, acquire ER.85 86 Thus, some TNBCs might be more similar to the BC stem cell phenotype, showing a capacity to undergo EMT and reprogramming of embryonic genes, whereas others would not.87 88 This hypothesis is now being analysed in the new molecular characterisation of TNBC studies16–18 and would be concordant with the data on chemoresistance of some TNBCs. The link between breast development and tumorigenesis is conceptually appealing, however more studies need to be performed on this topic.44 89
Although histological and developmental classifications are informative, most of the progress in TNBC subclassification has been performed by molecular studies.
The first molecular observation was based on BRCA1 mutations; however, only for a small number of TNBC cases, since at the most only 20% of patients with TNBC have this mutation.90 91 A proportion of the women with TNBC carry BRCA1 germline mutations, but this proportion varies with age of diagnosis and family history (figure 3).92 The role of BRCA1 null TNBC arising in non-BRCA1 germline mutation carriers is not yet clear. Furthermore, 80% of the BCs arising in BRCA1 germline mutation carriers are TNBC but with good prognosis.93 Deep sequencing of BC genomes revealed that the BRCA1 null TNBC shows less genomic instability than the non-BRCA null TNBC.12 25 BRCA1 status may thus be suggesting two distinct TNBCs. BRCA1-deficient TNBC, germline or somatic, is likely a different biological entity, deficient in DNA repair, and, therefore, responsive to therapy with PARPi and platinum salts.94 This assumption is being tested in current randomised clinical trials in TNBC. However, clinical trials with PARPi have shown distinct outcomes, as the results are either quite promising95 96 or have failed to achieve any response in these patients.97 98 Platinum salts are also being used in trials with promising results, as depicted in this meta-analysis.99 New data on neoadjuvant platinum trials in TNBC have shown a high pCR100 (table 2). More recently, olaparib and talazoparib, both PARPi, are being used in several clinical trials (table 2) to treat patients with gBRCAm. The OlympiAD—a phase III clinical trial that analyses the use of olaparib versus standard chemotherapy in HER2-negative metastatic BC with gBRCAm, found that progression-free survival was improved in the olaparib arm, the time to second progression was longer and there were less adverse events, increasing the health-related quality of life in these patients.75
Besides BRCA1 mutations, other TNBC categories have been described. For instance, Lehmann et al molecularly divided TNBC in six different subtypes according to their unique gene expression profiles.17 These subtypes were classified as basal-like (BL1 and BL2), immunomodulatory (IM), mesenchymal (M), mesenchymal stem-like (MSL) and luminal androgen receptor (LAR). The first two subclasses had a basal-like phenotype with higher expression of cell cycle and DNA damage response genes and BL2 also had increased growth factor signalling. The IM subtype had elevated immune cell signalling and cytokine signalling. Mesenchymal and MSL subtypes had augmented gene expression for EMT events, cell motility and differentiation. In addition, the MSL class had lower levels of proliferation genes and increased gene expression related with stem cells. Finally, the LAR subclass had increased levels of androgen receptor (AR) and luminal gene expression patterns. Within these subclasses, the response to therapeutic inputs was distinct, as well as the relapse-free survival and distant metastasis-free survival.
More recently, a new classification was described by Burstein et al.18 In this study, the authors assessed 198 tumour tissues, mainly from Caucasian women, according to their expression profile data. They were able to divide TNBC in four different classes—LAR, mesenchymal (MES), basal-like immunosuppressed (BLIS) and basal-like immune-activated (BLIA). Each subtype had unique gene expression profiles and specific targets. For instance, LAR, which was similar to the subtype described by Lehmann, exhibited AR, ER, prolactin and ErbB4 signalling. MEShad increased cell cycle pathways, mismatch repair of DNA, DNA damage networks and higher IGF1. BLIS had low levels of B cells, T cells and natural killer (NK) cells, reduced immune-regulating pathways and cytokine expression; on the other hand, had elevated expression of SOX1. Opposite of BLIS is BLIA with high levels of immune cells and activation of STAT transcription factor mediator pathways. The BLIS subtype had worst prognosis with low disease-free survival, while BLIA had the better prognosis. Specific targets for each class were found: mucin 1 for LAR; platelet-derived growth factor (PDGF) receptor A and c-Kit for MES; V-Set domain containing T cell activation inhibitor 1 (VTCN1) for BLIS and STAT signal transduction molecules and cytokines for BLIA.
Interestingly, Lehmann recently published another work where he acknowledges the existence of only four subtypes, denominated TNBCtype-4.16 These subtypes were BL1, BL2, M and LAR. In addition to the gene expression profiles that were executed in the first article, histopathological quantification and laser-capture microdissection (LCM) were used. As so, the lymphocytic infiltration was found to be present in all six subtypes, in different percentages, leading to the conclusion that IM is not really an independent subtype but that its components are present in the other classes. Moreover, the authors found that the characteristics of the MSL subtype were mainly derived by the stromal component surrounding the tumour. Again, each of the subtypes had different responses to the same treatment, with 41% of BL1 patients and only 18% of BL2 patients achieving pCR.
Even though the subtypes described by Burstein or by Lehmann are not exactly superimposable, there seems to be a tendency—one class with high expression of AR, another with mesenchymal features and two basal-like. In addition, lymphocytic infiltration appears to be present in distinct proportions across the subtypes, or at least prevalent in two subclasses (BLIS and BLIA). The important message to retrieve from these attempts to classify TNBC is that indeed tumours differ between patients as well as their response to the same treatment and this could be the basis of the heterogeneity found in the clinic that was described in the previous section. It is possible to hypothesise that young women with TNBC can have a subtype that is more aggressive or that doesn’t have a good response to a systemic untargeted treatment, such as BLIS for instance, when compared with menopausal women with TNBC. Moreover, a tumour with mesenchymal phenotype and with stem cell characteristics can be more chemoresistant than a basal-like subtype. This subtype could be more prevalent in African women, since they have a more aggressive phenotype that is more intolerant to treatment.
Another point in common between all classifications is the presence of immune cells within the tumour, either as a subgroup on its own—IM in Lehmann’s first classification or BLIS and BLIA in Burstein’s study, or widespread through all groups as depicted in the second classification published by Lehmann. Moreover, BLIS and BLIA subtypes were the ones with the worst and best prognoses, respectively. Thus, it seems clear that the immune system plays a critical role in the progression of TNBC.
The role of immune cells in TNBC progression
Indeed, a few studies have described the relationship between tumour infiltrating lymphocytes (TILs) and cancer progression and patient survival, namely in melanoma and ovarian, breast, bladder, cervical, colon, prostate, rectum and lung cancers.101–107 TILs enclose cytotoxic CD8+ T cells, CD4+ T helper cells (Th), CD4+/FOXP3+ regulatory T cells (Treg), B cells and NK cells. It was observed that in BC and in the adjacent stroma, the number of TILs is higher when compared with normal breast tissue.108 109 Overall, the presence of TILs in BC seem to lead to a better prognosis and an increased survival rate, since chemotherapeutic drugs are more efficient against tumours implanted in immunocompetent, with respect to immunodeficient hosts.110 111 Severe lymphopenia negatively affects the chemotherapeutic response of multiple distinct solid cancers112 and depletion of CD8+ T lymphocytes in animal models also reduced the efficacy of chemotherapy.110 111 Hence, several reports have been advocating that TILs could serve as a robust marker for predicting pCR rate in respect to NACT.113
In a meta-analysis of studies published with predictive significance of TILs in pCR in cases of BC with NACT,114 the authors observed that an increase in TILs (especially CD8+ and FOXP3+ cells) in biopsies from patients with no previous treatment led to better pCR after NACT. Another meta-analysis observed that an increase in TILs led to a reduction of 30% in the risk of recurrence, a decrease in 22% in the risk of distant recurrence and 34% less risk of death.115
Within patients with BC, the presence of TILs has been associated with increased pCR rates and a decreased risk of mortality in HER2+ and TNBC, but not in ER+ disease.114 116–118 We will now focus on the role of TILs specifically in TNBC.
A study observed that in TNBC samples, the presence of CD8+ cells within the tumour was associated with a reduction of 28% in mortality and the presence of these cells in the stroma led to a decrease of 21%.116 The presence of TILs correlates with pCR, and the quantity of TILs in the tumour microenvironment is also important, as it was found that the higher the number of CD8+ T cells present at the tumour site, the better the prognosis of patients with TNBC.119–121 In the past few years, a number of clinical trials in BC, namely in TNBC, started to implement the quantification of TILs and the possible association with survival. For instance, in ECOG 2197 and ECOG 1199 trials, it was observed that for each 10% increment in TILs (within the stroma), there was a 19% reduction in the risk of death.91 Loi et al observed that each 10% increase in TILs was associated with 27% reduction in the risk of death (BIG 02–98 clinical trial)117 and 13% reduction in the relative risk of distant recurrence (FinHER trial).122 If the patients were treated with chemotherapy, this reduction was of 18%.122 Thus, it is possible that the clinical efficacy of therapeutic regimens commonly employed to treat TNBC, namely chemotherapy, is largely determined by T lymphocyte-dependent immune response. Indeed, in a prospective study, it was found that an increase in TILs in BC supports a better response to anthracycline/taxane-based NACT.123
However, not all studies corroborate this association between presence of TILs and patient outcome. In fact, and just as an example, Liu et al, determined that there was no association between CD8+ TILs infiltration and improved survival in TNBC that showed no expression of basal markers.120
Moreover, CD8+ T cells are present in immune infiltrates within the tumour, and other T cells, such as CD4+ Th and FOXP3 are also present in the tumour microenvironment. CD4+ Th may be correlated with good prognosis (higher Th1) and with poor prognosis (higher Th2) in BC, but not specifically in TNBC.124 Treg effect on prognosis is controversial, with different studies in TNBC affirming distinct consequences from the presence of Tregs in tumours. For instance, Mahmoud et al described that Treg is not an independent prognostic factor,119 while Lee et al claimed that improved survival in patients with TNBC was associated with highly infiltrating Treg.125 It was also described that the presence of FOXP3 + in patients post-NACT was found to be a predictive marker for a low pCR rate.114 Interestingly, it was described that a ratio of CD8+/FOXP3+ ≥3 in primary BC led to an improved overall survival, whereas if this ratio is <3 in metastatic BC (at first relapse), it also led to improved overall survival.126 In metastatic TNBC, the levels of CD3+, CD4+, CD8+ and FOXP3+ TILs were inferior than the matched primary tumour, and metastatic TNBCs had fewer TILs compared with metastatic HER2+, ER+ or PgR+ tumours.126
Besides CD4+, CD8+ and FOXP3+ TILs, other cells from the immune system can have a pivotal role in TNBC progression, as tumour associated macrophages (TAMs), dendritic cells (DCs), tumour associated neutrophils (TANs), myeloid derived suppressor cells (MDSCs) and NK cells.127–129 Nevertheless, few studies have been developed that focus on these cells from the immune system and their possible association with patient outcome.
The information input that is used nowadays in the clinic for patients with TNBC is not sufficient to distinguish between patients who have a high chance to have a pCR when treated with conventional NACT from patients who cannot achieve a pCR and could benefit more from alternative immunotherapies. The information provided by the clinical measure of TILs pretreatment could be an answer to help in decision making regarding the treatment of different patients with TNBC. Stratification of patients based on the presence of TILs, and more specifically the subtype and the phenotype of TILs, will be paramount in the future to provide quality treatment to non-responders to conventional systemic therapy. Indeed, immunotherapy is not yet a reality for patients with TNBC, since the clinical trials implemented so far had a low response rate,130 probably due to poor characterisation of the immune environment and subsequent suboptimal patient stratification.
Potential new targeted therapies for TNBC considering its immune microenvironment
The success of NACT may be interrupted by distinct strategies employed by tumour cells to induce anergy/exhaustion of effector CD8+ T cells and Th1 cells, namely by defective antigen presentation, by engaging the T cell receptor in the absence of co-stimulation, by shifting the balance from Th1 to Th2 (immune deviation), by expressing inhibitory molecules like PD-L1 which bind the inhibitory receptor PD-1 in effector T lymphocytes, inducing negative regulatory pathways that limit the activity of these cells.131 132 Other inhibitory immune checkpoints, such as CTLA-4, Tim-3 or LAG-3 and the secretion of extrinsic immunosuppressing molecules such as interleukin (IL) 10, TGF-β, indoleamine 2,3-dioxygenase (IDO) or arginase could also directly or indirectly (by recruiting MDSCs and Tregs) negatively impact effector T cells’ actions.131 132 CTLA-4 is also expressed at the surface of T cells and can suppress their function by binding to B7 ligands. Tumour cells can express these ligands on their surface to escape the immune system.133 Tim-3 is a cell surface receptor present in CD4+ and CD8+ T cells with an inhibitory function.134 Tests performed in mouse models of BC found a high number of CD8+ T cells with Tim-3 expression infiltrating the tumour120 and the blockage of Tim3 led to an increase in antitumour immunity.120 121 IDO is an immunosuppressive enzyme present in DCs, macrophages and tumour cells.122 By using an IDO inhibitor, it would be possible to increase the level of maturation of these cells that are able to present tumour-associated antigens to effector cells. Another interesting approach to boost the antitumour response would be by the use of Ox40 agonists, since Ox40 is a co-stimulatory receptor present in T cells.123 124 Moreover, several other molecules with immune checkpoint properties are now being discovered and studied in different malignancies, such as CD39, CD73, TIGIT, CD96 and CD47.135–137
Blocking these immunosuppressing mechanisms to augment T lymphocyte function seems a promising approach to treat cancer.131 132 138 Indeed, these proteins are beginning to be used in anticancer therapeutics, as FDA approved one antibody against CTLA-4 (ipilimumab), two against PD-1 (pembrolizumab and nivolumab) for the treatment of melanoma and also two against PD-L1—atezolizumab and avelumab, for bladder cancer and squamous non-small cell lung cancer treatment, respectively.139
As TNBC appears to have high infiltration of cells from the immune system, it would be interesting to analyse the level of these immune checkpoints on TNBC samples. In fact, the PD-1 inhibitor pembrolizumab is being tested on patients with TNBC in a phase II clinical trial with some promising results.125 Pembrolizumab is also being analysed as an addition to standard NACT in two different trials—KEYNOTE 173 and I-SPY 2. In the first clinical trial, TNBC pCR rates are 90% (NACT+pembrolizumab) and 100% with carboplatin addition.140 In the I-SPY trial, pCR rates were 2%.141 In a metastatic setting (KEYNOTE 86), it was possible to observe that patients that had increased response to pembrolizumab had lower LDH and no liver nor visceral metastasis.142 Thus, it seems that immunotherapy in a metastatic setting has a higher response in less aggressive cases.
A growing body of evidence shows that the type of immune response influences the efficiency of several chemotherapeutic drugs116 and therefore selective immunotherapeutic interventions alone or in synergism with more conventional anticancer agents are now more appealing.
The blockade antibodies against T cell checkpoint molecules including CTLA-4 and the PD-1/PD-L1 axis in monotherapy or combination therapies have begun to revolutionise the current standard cancer treatment in various cancer types, such as melanoma, lung cancer, bladder cancer and Hodgkin’s lymphoma.132 This treatment is still not used in TNBC, because the genetic instability of tumour cells, which is frequent in this type of disease, make it a bad candidate for the success of targeted immunotherapies. However, the implementation of patient stratification by evaluating TILs and their phenotype in the clinic may improve the use of immunotherapies in this subtype of BC. Indeed, with the evaluation of the tumour-immune microenvironment it would be possible to distinguish patients that benefit from standard chemotherapy alone from those who would benefit more from these new monoclonal antibodies alone or in combination with chemotherapeutic agents.
Besides these immune checkpoint inhibitors, other approaches could be interesting for the development of new therapies. For instance, the BLIS subtype described by Burstein has an immunosuppressed environment that is translated to the gene expression profile of these tumours. There are some genes important for the regulation and activation of the immune system effectors that are downregulated in BLIS samples compared with controls. Since this subtype is the one with the worst prognosis it is of foremost importance to discover new ways to treat these patients. The external upregulation of these genes may be one of the methods to overcome the immunosuppression in this subtype. Interestingly, some of these genes are upregulated in BLIA, which demonstrates their importance in the activation of the immune environment. Among these genes are CXCL9, CXCL13, GZMB, GZMA, CD2, CD69, PTPRC and TLR8.
TNBC is still a problem in the clinic, due to the lack of targeted therapies. Additionally, patients with TNBC have a high level of divergence between them, concerning age of diagnosis, the prognosis and the response to treatment. Thus, we are convinced from our clinical observations, laboratory data and from the literature that TNBC is not a single disease and that the subclassification of this clinical entity with clinical phenotype correlates is an unmet clinical need in BC.
In order to understand this heterogeneity and to develop new therapies, researchers have tried to uncover the basis of this diversity, using histological and molecular tools. Although it seems that no consensus has yet been made, some advances point to the same direction and patient segregation can be achieved: TNBC arising in patients with the BRCA1 germline mutation, TNBC associated with an immune phenotype with lymphocytic infiltration or TNBC arising in African-descent patients that is more chemoresistant.
So, to improve patient welfare, it is likely that several therapeutic strategies will be implemented according to the subtype of TNBC. These therapies can go from PARPi or platinum agents, for BRCA1 mutation carriers, to immune checkpoint inhibitors, that can modulate the tumour immune microenvironment to stimulate immune responses and control tumour progression.
Nevertheless, the findings in this area are still preliminary and more studies need to be performed to ascertain the true effect of these treatments in TNBC treatment.
Contributors DPS, MGC and SB reviewed the literature, wrote the manuscript and AJ revised the text.
Competing interests None declared.
Patient consent Obtained.
Ethics approval Hospital Prof Doutor Fernando da Fonseca.
Provenance and peer review Not commissioned; externally peer reviewed.
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