A simple immunohistochemical panel comprising 2 conventional markers, Ki67 and p53, is a powerful tool for predicting patient outcome in luminal-type breast cancer

Approximately 70% of breast cancers express a hormone receptor (HR). HR status is a powerful predictor of response to therapies that inhibit estrogen synthesis or block the action of its receptor [1]. Endocrine therapies are established in the adjuvant setting [2‐4]. For example, women with node-negative, HR-positive breast cancer who are treated with tamoxifen alone after surgery have an average 10-year recurrence rate of only 15% [5]. If all of these patients were offered chemotherapy, 85% would be over-treated [6]. It is therefore important to distinguish patients with HR-positive tumors at high risk for recurrence who need additional chemotherapy from those for whom adjuvant hormonal therapy alone may suffice [7].

Multi-gene assays are strong candidate tools for predicting the risk of recurrence in HR-positive patients. For example, the Oncotype DX™ assay analyzes the expression levels of 21 genes (including 5 reference genes) in formalin-fixed paraffin embedded tissues and produces a Recurrence Score (RS) that predicts the likelihood of distant recurrence [6] and the benefit of chemotherapy in women with early HR-positive breast cancer [8]. Although Oncotype DX™ is a potentially powerful tool for stratification of HR-positive patients, it is too expensive to use in routine clinical practice. Many oncologists are eager for an alternative assay that is inexpensive as well as easy to use; one possible approach would be an immunohistochemical (IHC) assay.

Sorlie et al. reported that breast cancers could be divided, based on their gene expression profiles, into at least 4 groups: luminal-type, HER2-type, normal-like-type, and basal-type. Luminal-type cancers are characterized by an activated estrogen receptor (ER) signaling pathway and are divided into 2 subtypes, luminal subtypes “A” and “B. In general, luminal-subtype-A tumors express higher levels of ER and carry a better prognosis than do luminal-subtype-B tumors [9]. Recent studies have shown that tumors of luminal subtype A have a lower rate of p53 mutation [9‐12] and are less proliferative [13, 14] than those of luminal subtype B, suggesting that the combination of p53 status and proliferation markers could be useful to distinguish between luminal subtypes A and B.

The tumor suppressor gene p53 plays a most important role in regulating normal cell fate in response to various stresses, and disruption of p53 function is often involved in tumor progression. Since the co-authors first reported in 1991 that distinct immunoreaction with p53 in the nuclei of breast cancer cells is an independent prognostic indicator [15], more than 1000 articles about the correlation between p53 status and breast cancer prognosis have been published. Recent studies have shown that abnormalities of the p53 gene [16] and accumulation of p53 protein in the nuclei [17, 18] are also robust prognostic indicators in HR-positive patients.

Ki67 is the marker most often used to evaluate tumor proliferation status. The Ki67 protein is a large (395 kD) nuclear protein that is present during all active phases of the cell cycle except for the G0 phase. Because proliferation status is closely correlated with tumor aggressiveness, the Ki67 labeling index (LI) is considered an established prognostic marker for various tumor types, including breast cancer [19, 20]. Previous clinical studies have revealed Ki67 LI to be a good prognostic indicator for HR-positive breast cancer patients [7, 21].

Although Ki67 is a strong prognostic indicator for HR-positive breast cancer patients, adding Ki67 to the commonly used indices in daily practice is controversial [19]. Furthermore, its predictive value is weaker than that of multi-gene expression assays such as Oncotype DX™. In this study, we attempted to validate the classification of HR-positive breast cancer patients by combined analysis of Ki67 LI and p53 status. We performed immunohistochemical examination of Ki67 and p53 expression in 150 samples of surgically resected HR-positive invasive breast cancers and analyzed the relationships between combined Ki67-p53 status and clinicopathological factors, including prognosis.

The international expert panel at the 2009 St. Gallen Consensus meeting referred to the importance of proliferation markers in deciding whether to include adjuvant chemotherapy in the treatment of patients with HR-positive HER-2-negative breast cancers. Several large-scale studies have evaluated the clinical significance of the Ki67 LI among patients with HR-positive breast cancer [7, 18, 21]. In this study, we showed that an IHC panel comprising p53 status and Ki67 LI is more accurate than Ki67 LI alone at predicting the prognosis for patients with HR-positive and HER2-negative breast cancer.

The results of our IHC panel divided the patients with HR-positive and HER2-negative invasive breast cancers into 2 distinct prognostic subtypes, those with favorable-phenotype (Ki67 LI-low and p53-negative) and unfavorable-phenotype group (Ki67 LI-high and/or p53-positive) tumors. Multivariate analysis showed that the IHC panel results, tumor size and chemotherapy were independent prognostic factors for DFS and that the IHC panel results was an only independent prognostic factor for OS. Furthermore, 76 of the 78 patients (97%) with early-clinical-stage (I or II) cancers showing the favorable phenotype were alive at the end of this study. The results of a similar immunohistochemical biomarker panel for 6 markers, including p53 and Ki67, were reported by Brian et al. to be a significant prognostic factor [32]. Ross et al. also showed that the immunohistochemical detection of 5 markers, including p53, was significantly associated with clinical outcome [33]. These reports support our data, at least in part; moreover, our immunohistochemical panel using 2 easy-to-use antibodies (Ki67 and anti-p53 antibodies) was both simpler than the cited panels. Miller et al. reported the similar results to this reports [24]. They evaluated the three molecular marker (Ki67, p53 and HER2) using the whole cases with HR-positive tumors. On the other hand, we excluded the HER2-positive tumors from the whole HR-positive tumors and then evaluate the clinicopathological implication of combined Ki67-p53 status in the patients with HR-positive and HER2-negative tumors. Nowadays, the patients with HER2-positive tumors are treated with anti-HER2 drugs and show different clinical outcome to those with HER2-negative tumors. So, our results give the more precise information and are more applicable to the dairy practice than the results of Miller et al.

The results of the immunohistochemical panel divided the HR-positive and HER2-negative breast cancer patients as follows: the 10-year DFS rates were 81% for the favorable phenotype group and 46% for the unfavorable phenotype group, while the 10-year OS rates were 97% and 65% for the favorable and unfavorable phenotype groups, respectively. To exclude the influence of adjuvant chemotherapy on the predictive value of the panel, we examined the prognostic significance of the panel separately in patients who received either pre- or post- operative chemotherapy and those who received no chemotherapy. As the immunohistochemical panel results were also identified as a significant prognostic factor in the patients who did not receive chemotherapy, we were able to exclude the influence of chemotherapy on our results. Our data indicate that patients with favorable-phenotype cancers have a clinical choice to avoid cytotoxic chemotherapy, as the baseline prognosis with adjuvant hormonal therapy alone is very good for this group.

In this report, the unfavorable phenotype-tumors exhibited significantly higher rates of positivity for HER2, basal phenotype markers (CK5/6, CK14, and EGFR), and P-cadherin than did the favorable-phenotype tumors. P-cadherin has been previously shown to be overexpressed on basal-type tumors [14, 34]. These properties suggest that unfavorable-phenotype tumors take on not only the “HER2” phenotype [7] but also the “basal” phenotype. To our knowledge, this is the first clinical study to reveal an obvious correlation between luminal subtype-B and basal-type breast tumors. Basal-type tumors exhibit more p53 mutations [9, 35] and nuclear p53 protein accumulation [36] than do luminal-type or HER2-type tumors, so p53 mutation is thought to be one of the characteristics of basal-type tumors [37, 38]. Our results would be consistent with this viewpoint. We suspect that some tumors should be considered “mixed intrinsic subtype” tumors, that is, tumors that exhibit characteristics of 2 or more intrinsic subtypes and therefore cannot be classified as any “pure” intrinsic subtype.

In conclusion, our results revealed that the cases with Ki67 LI-high and p53 positive showed a mixed tendency towards the “HER2” and “basal” types ,and that a simple immunohistochemical panel comprising Ki67 and p53 could distinguish between the cases with a favorable phenotype group and those with an unfavorable phenotype group among HR-positive and HER2-negative breast cancer patients. These suggest that our simple immunohistochemical panel comprising Ki67 and p53 is a promising tool for distinguishing between “luminal-subtype-A” and “luminal-subtype-B” breast cancers and management of patients with HR-positive breast cancer.