Figures
Abstract
Experimental models implicate protease activated receptors (PARs) as important sensors of the proteolytic tumor microenvironment during breast cancer development. However, the role of the major PARs, PAR-1 and PAR-2, in human breast tumors remains to be elucidated. Here, we have investigated how PAR-1 and PAR-2 protein expression correlate with established clinicopathological variables and patient outcome in a well-characterized cohort of 221 breast cancer patients. Univariable and multivariable hazard ratios (HR) were estimated by the Cox proportional hazards model, distant disease-free survival (DDFS) and overall survival by the Kaplan–Meier method, and survival in different strata was determined by the log-rank test. Associations between PARs and clinicopathological variables were analyzed using Pearson’s χ2-test. We find that PAR-2 associates with DDFS (HR = 3.1, P = 0.003), whereas no such association was found with PAR-1 (HR = 1.2, P = 0.6). Interestingly, the effect of PAR-2 was confined to the ER-positive sub-group (HR = 5.5, P = 0.003 vs. HR = 1.2 in ER-negative; P = 0.045 for differential effect), and PAR-2 was an independent prognostic factor specifically in ER-positive tumors (HR = 3.9, P = 0.045). On the contrary, PAR-1 correlated with worse prognosis specifically in the ER-negative group (HR = 2.6, P = 0.069 vs. HR = 0.5, P = 0.19 in ER-positive; P = 0.026 for differential effect). This study provides novel insight into the respective roles of PAR-1 and PAR-2 in human breast cancer and suggests a hitherto unknown association between PARs and ER signaling that warrants further investigation.
Citation: Lidfeldt J, Bendahl P-O, Forsare C, Malmström P, Fernö M, Belting M (2015) Protease Activated Receptors 1 and 2 Correlate Differently with Breast Cancer Aggressiveness Depending on Tumor ER Status. PLoS ONE 10(8): e0134932. https://doi.org/10.1371/journal.pone.0134932
Editor: William B. Coleman, University of North Carolina School of Medicine, UNITED STATES
Received: May 26, 2015; Accepted: July 16, 2015; Published: August 5, 2015
Copyright: © 2015 Lidfeldt et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited
Data Availability: All relevant data are within the paper and its Supporting Information files.
Funding: This work was supported by grants from the Swedish Cancer Fund (MB); the Swedish Research Council (MB); the Swedish Society of Medicine (MB); the Physiographic Society, Lund (MB); the Gunnar Nilsson, Anna Lisa and Sven Eric Lundgren, and Kamprad Foundations (MB); the Skåne University Hospital donation funds (MB); the Skåne County Research Foundation (PM); and the Governmental funding of clinical research within the national health services (MB). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Breast cancer is a heterogeneous disease with a substantial variation in aggressiveness and prognosis [1]. Proteases of the tumor microenvironment have emerged as important regulators of cancer cell invasiveness and metastatic capacity through stroma remodeling and increased angiogenesis. Moreover, proteolytic activity in the extracellular environment through e.g. matrix metalloproteinases and coagulation proteases may directly cleave and activate a unique class of G protein-coupled protease activated receptors (PARs), most importantly PAR-1 and PAR-2. PARs are known to be expressed at variable levels by malignant as well as tumor stromal cells, and have been implicated as regulators of tumor vascularization and metastasis [2–4]. Collectively, experimental studies point at a major role of PAR-2 in breast tumor development, whereas the role of PAR-1 is less clear. PAR-1 deficiency had no effect on tumor development and metastasis in a transgenic model of spontaneous breast cancer, whereas PAR-2 knock-out mice displayed delayed tumor formation and decreased lung metastases [5]. Moreover, blocking antibodies directed at PAR-2 but not PAR-1 were shown to attenuate tumor growth and metastasis in a breast xenograft model [6], and shRNA-mediated silencing of PAR-2 but not PAR-1 mRNA in breast cancer cells showed a specific role of PAR-2 in promoting the malignant cell phenotype [7]. In one study, PAR-1 activation was even found to inhibit breast cancer cell migration [8]. Several other studies, however, suggest that PAR-1 has an important role in the progression of breast cancer [9–12].
Interestingly, there may be a more complex interrelationship between the PARs, as suggested by experimental studies showing that PAR-1 cleavage can transactivate PAR-2 [13, 14]. At the molecular level, it has been demonstrated that PAR-1 and PAR-2 can heterodimerize and co-traffic during internalization [15]. PAR-1 and PAR-2 heterodimerization may have functional importance as suggested from studies showing that PAR-2 expression and co-signaling are necessary for PAR-1-induced hyperplasia of vessel intima [16]. More recently, it was proposed that the presence of PAR-2 is required for PAR-1-induced signaling events associated with breast tumor development. The same study suggested that this is not a reciprocal mechanism since PAR-2-dependent stimulatory effects in breast cancer cells were intact even in the absence of PAR-1 [17].
Together, previous investigations in experimental systems thus implicate that PAR-1 and PAR-2 may act either independently or together as a functional unit to regulate breast tumor development. However, the role of PARs and the interrelationship of PAR-1 and PAR-2 in human breast cancer remain poorly defined [18, 19]. In the present study, we used a well-characterized cohort of premenopausal patients with lymph node-negative breast cancer to investigate the role of PARs with a specific focus on whether the prognostic value of PARs in breast cancer differs depending on tumor ER status.
Materials and Methods
Patient characteristics
The patient population encompassed 237 premenopausal patients with lymph node-negative breast cancer from a prospective study in southern Sweden during 1991 to 1994 [20]. Our studies were performed according to the recommendations of "REMARK" guidelines [21]. The study was approved by the ethics committee of Lund University Hospital. All participants provided their written consent to participate in the study. From the initial 237 patients, 221 tumors samples were scored for PAR-1 and PAR-2 expression. In 14 cases, paraffin blocks were not retrieved from the pathology departments, and in the remaining two cases individual tumor sections were either lost in the preparation of tissue microarray (TMA) or judged non-evaluable due to insufficient number of malignant cells or insufficient malignant tissue. Primary surgical treatment, postoperative radiation, and adjuvant systemic treatment have been described in detail earlier [20] (see also, Table 1). The median follow-up for the end-point distant metastasis was 10.9 years for the 168 patients who were alive and free from distant metastases at the latest review of the patients’ records. Results for the first 5 and 10 years are presented, as indicated. Histological grading of tumors was performed according to Elston and Ellis [22]. All tumor specimens were re-evaluated by seven experienced pathologists without knowledge of patient history [20]. Patient and tumor characteristics are summarized in Table 1.
Tumor tissue microarray
A TMA was obtained from the paraffin embedded tumor specimens. Two 0.6 mm core biopsies were taken from representative areas of each tumor, and transferred into a new paraffin block using a manual arrayer (Beecher Instruments, MD, USA). Sections of 4 μm were stained with haematoxylin and eosin B.
Immunohistochemistry
ER, PR, HER-2, VEGF-A, and Ki-67 analyses were performed as described earlier [23, 24]. Seven tumors were non-evaluable for HER-2 due to insufficient tumor material or fixation artifacts. All patients with amplified tumors according to FISH analyses, and all with Herceptest 3+ where FISH analysis could not be evaluated, were considered HER-2 positive. Expression of PAR-1 and PAR-2 were determined using the DAKO Envision kit K 5007 (an indirect polymer reinforcement technique) in a TechMate 500Plus, (DAKO, Copenhagen, Denmark). Antigen retrieval was performed by treatment in a microwave oven in target retrieval solutions pH 6 (PAR-2) or pH 9 (PAR-1). Sections were incubated with the primary antibody for 30 min (PAR-1) or 2 h (PAR-2). Antibodies used were mouse anti-human PAR-1 (sc-13503, Santa Cruz; 1:150 dilution) and mouse anti-human PAR-2 (sc-13504, Santa Cruz; 1:100 dilution). Diaminobenzidine (DAB) was used for visualization. Negative control sections were performed by omitting the primary antibody in each staining batch, and sections were counter-stained with haematoxylin. Slides were reviewed by two independent examiners (J.L. and M.B.) without knowledge of clinical and pathological information. A homogenous staining of tumors for PAR-1 and PAR-2 was observed; therefore, a scoring system based on percentage of positive cells was not further considered. Scoring of PAR-1 and PAR-2 was performed semi-quantitatively according to staining intensity on a scale as follows: 0 = total negative slide, 1 = weak, 2 = moderate, 3 = strong and 4 = very strong intensity (S1 Fig). Magnifications ranging from 4x to 40x were used during scoring.
Statistical analyses
Distant disease-free survival (DDFS) was primary end-point and breast cancer mortality (BCM) secondary end-point. The Cox proportional hazards model was used for estimation of univariable and multivariable hazard ratios (HR). Proportional hazards (PH) assumptions were checked both graphically and by Schoenfeld’s test [25]. Deviations from PH were observed, motivating truncation of follow-up for DDFS at 5 years. The deviations from PH were less in analyses of BCM. Hence, also 10 years of follow-up could be used for this endpoint. Estimated HRs should, however, be interpreted as average effects over time. The Kaplan–Meier method was used to estimate DDFS and overall survival (OS) whereas a slightly modified method [26] accounting for competing events, i.e. deaths from other causes, was used to estimate BCM. The log-rank test was used to compare survival in different strata. All factors were used as dichotomous covariates in the statistical analyses except for histological grade (three groups) and age which was analyzed as a continuous variable. Cut-off values were defined before statistical analyses. For the established prognostic factors (ER, PR, HER-2) standard cut-off values were used, and were the same as in previously published patient series [20]. Associations between the dichotomized PAR variables and other dichotomized variables were analyzed using Pearson’s χ2-test. The trend version of the test was used for histological grade. All P-values corresponded to two-sided tests. When referring to a statistically significant effect, we mean a P-value below the threshold 0.05, but the P-value should rather be interpreted as level of evidence against the null hypothesis. The statistical calculations were performed using Stata Version 13.1 (StataCorp LP, 2014, College Station, TX, USA).
Results
Patient and tumor characteristics
Detailed characteristics of the patients and tumors are presented in Table 1; notably, the vast majority (87%) of patients in this cohort received no adjuvant systemic therapy, which makes it suitable to more specifically assess the prognostic value of biomarkers. Among more established clinicopathological variables, high PAR-1 was only significantly associated with high Ki-67 (>20%), whereas high PAR-2 was significantly associated with younger age (<50), larger tumor size (>20 mm), high histological grade, high Ki-67 and ER- and PR-negativity (Table 2). Further, PAR-1 and PAR-2 expressions were shown to be positively associated (P = 0.019). Whereas PAR-2 was specifically found in malignant cells, high PAR-1 expression was found in malignant as well as neighbouring stromal cells (S1 Fig).
Association of PAR-1 and PAR-2 expression to patient outcome depends on ER status
In univariable analysis, PAR-2 was a prognostic factor for DDFS (HR: 3.1, 95% CI: 1.5–6.4, P = 0.003), whereas PAR-1 showed no such correlation (HR: 1.2, 95% CI: 0.6–2.3, P = 0.6) (Table 3). The DDFS was 92 and 76% in low- and high-PAR-2 expressing groups, respectively (Fig 1A). In univariable analysis of BCM during the first 10 years after diagnosis, PAR-2 remained as a significant prognostic factor (HR: 2.4, 95% CI: 1.3–4.5, P = 0.006) (Table 3). The corresponding cumulative BCM (95% CI) was 13% (7–19%) and 27% (19–36%) in low- and high-PAR-2 expressing groups, respectively (S2A Fig). Overall, HER-2, PAR-2, Ki-67, histological grade, ER age and PR were significant prognostic factors in univariable analysis of DDFS whereas tumor size and PAR-1 were not significantly associated to DDFS (Table 3 and Fig 1B).
Prognosis in relation to PAR-2 (a) and PAR-1 (b) status in the entire cohort.
The prognostic value of the PAR variables was evaluated in subgroups defined by established prognostic factors (Table 4). These analyses revealed a negative effect of high PAR-2 in younger patients whose tumors were small, low grade, low Ki-67, HER-2-negative, and ER- and PR-positive. Interestingly, the most striking differential effect of high PAR-2 was found depending on ER status; the effect in the ER-positive group was HR: 5.5 (95% CI: 1.8–17, P = 0.003) compared to HR: 1.2 (95% CI: 0.4–3.2, P = 0.7) in the ER-negative group. The differential effect was found to be significant (P = 0.045) in a Cox model with a term for the interaction between the two variables and it remained significant in analysis of BCM (Table 4 and S3 Fig). In ER-positive tumors, the DDFS was 96% and 78% in low- and high-PAR-2 expressing groups, respectively (Fig 2A). In multivariable analysis of DDFS, PAR-2 was an independent prognostic factor in the ER-positive group (HR: 3.9, 95% CI: 1.03–15.0, P = 0.045) when adjusting for age, tumor size, grade, Ki-67and HER-2 status.
Prognosis in relation to PAR-2 (a) and PAR-1 (b) status in patients with ER-positive and ER-negative tumors.
In contrast, high PAR-1 had no significant effect in any of the analyzed subgroups. Interestingly, however, the strongest PAR-1 effects were observed in subgroups of ER and these effects were in opposite directions as compared with PAR-2, indicating an interaction effect on prognosis also between ER and PAR-1; high PAR-1 was found to be associated to worse prognosis in the ER-negative group (HR: 2.6, 95% CI: 0.9–7.3, P = 0.069), whereas there was no significant effect in the ER-positive group (HR: 0.5, 95% CI: 0.17–1.4, P = 0.19) (Table 4). This differential effect was also found to be significant (P = 0.026). In ER-negative tumors, the DDFS was 86% and 68% in low- and high-PAR-1 expressing groups, respectively (Fig 2B). In multivariable analysis of DDFS, however, the effect of PAR-1 in ER-negative tumors was insignificant (HR: 1.5, 95% CI: 0.42–5.7, P = 0.5).
Interactions between ER, PAR-1, and PAR-2
Previous experimental studies have established that PAR-1 and PAR-2 may heterodimerize, and co-signal during breast tumor development [13–17]. These findings, together with our above findings suggesting differential prognostic effects of PAR-1 and PAR-2 depending on ER status, motivated further analyses of potential interactions between these three factors. A Cox-model for DDFS with the three main effects for ER, PAR-1 and PAR-2, the three two-way interaction terms ER*PAR-1, ER*PAR-2 and PAR-1*PAR-2, and finally a term ER*PAR-1*PAR-2 for the three-way interaction, suggested a three-way interaction, which was almost significant (P = 0.070). To illustrate this interaction effect, prognosis in subgroups defined by PAR-1 and PAR-2 was studied separately for patients with ER-positive and ER-negative tumors (Fig 3). The HR for PAR-2 high vs. PAR-2 low in the PAR-1 high subgroup was 1.9 (95% CI: 0.31–11; P = 0.5) compared to HR = 12 (95% CI: 2.7–57; P = 0.001) in the PAR-1 low group. The DDFS in ER-positive/PAR-2 high/PAR-1 low and ER-positive/PAR-2 high/PAR-1 high was 62% and 90%, respectively (Fig 3A). The HR for PAR-1 high vs. PAR-1 low in the PAR-2 high subgroup was 4.2 (95% CI: 0.91–19; P = 0.065) compared to HR = 1.4 (95% CI: 0.28–6.9; P = 0.7) in the PAR-2 low group. The DDFS in ER-negative/PAR-1 high/PAR-2 low and ER-negative/PAR-1 high/PAR-2 high was 75% and 64%, respectively (Fig 3B). Although these subgroup analyses were clearly limited by reduction of sample size and should be interpreted with caution, the prognostic effect of PAR-2 in ER-positive patients appeared to be attenuated by concomitant high PAR-1 expression. On the contrary, the effect of PAR-1 in ER-negative tumors may be reinforced by concomitant high PAR-2 expression.
Prognosis in relation to PAR-1 and PAR-2 status in patients with (a) ER-positive and (b) ER-negative tumors.
Discussion
The major finding of the present study is that high PAR-2 expression strongly correlates with poor prognosis in a large patient subgroup, i.e. with luminal A like tumors [27], whereas PAR-1, on the contrary, appeared to be a negative prognostic factor specifically in the ER-negative subgroup. The classical view of ERα as an intracellular receptor that becomes activated and translocates to the nucleus only upon binding to its steroid hormone ligand has been abandoned through the elucidation of several mechanisms of nonclassical, estrogen-independent ER activation. These include post-translational ER modifications by e.g. phosphorylation at several positions dependent on receptor tyrosine kinases and G-protein coupled receptors and their downstream signaling molecules. This crosstalk should be of particular importance in the context of endocrine therapy resistance that may evolve as a result of estrogen-independent ER activation [28–32]. Interestingly, unrelated studies have shown that PI3K/AKT and ERK1/2 pathways are major downstream targets of PAR-2 activation [3], and that the same kinases can phosphorylate and activate ER independently of estrogen [27, 31]. Notably, several groups have shown that whereas PAR-1 transiently recruits β-arrestins, PAR-2 forms stable complexes with β-arrestins that function as a scaffold to promote ERK1/2 activation [15, 33–35]. Further, PAR-2 and ER signaling may merge at and synergize through common downstream signaling pathways, such as the MAPKs, or at the level of co-transcriptional regulation. ER can be recruited to transcriptional initiation sites other than estrogen responsive elements, which requires the association with other transcription factors [36–38] that may be connected with PAR-2 signaling. These potential signaling cross-talks between proteolytic activation of PARs and estrogen-dependent signaling through e.g. PI3K/AKT and MAPK pathways should be interesting avenues of future studies.
Our observation on the role of PAR-1 in ER-positive vs. ER-negative breast tumors should be discussed in the context of a previous study showing that tumors positive for ER and PAR-1 had a worse prognosis as compared with ER-positive tumors negative for PAR-1 [19]. The patient cohort in the previous study included pre- and postmenopausal patients (age range, 20–82) that were both lymph node-negative and–positive, whereas our study is based on a more homogenous cohort of mostly premenopausal (age range, 30–57), and lymph node-negative patients. Also, while the extent of adjuvant treatment (e.g. with antiestrogens) in the previous study is unknown, 87% of patients in the present study did not receive such treatment. Thus, differences in ER signaling status and available systemic estrogen levels between the respective patient cohorts may be a contributing factor to the discrepant results between studies.
Together, our results suggest that expression levels of PAR-1 and PAR-2 associate with breast cancer outcome in an ER-dependent manner. These observations motivate further mechanistic studies to unravel how the proteolytic activity of the tumor microenvironment and PAR activation may dictate ER-dependent signaling events during breast tumor development and metastasis.
Supporting Information
S1 Fig. Representative IHC stainings according to graded score for PAR-1 (upper panels) and PAR-2 (lower panels).
https://doi.org/10.1371/journal.pone.0134932.s001
(TIFF)
S2 Fig. Cumulative incidence of breast cancer mortality in relation to PAR-2 (a) and PAR-1 (B) status.
https://doi.org/10.1371/journal.pone.0134932.s002
(TIF)
S3 Fig. Cumulative incidence of breast cancer mortality in relation to ER and (a) PAR-2 or (b) PAR-1 status.
https://doi.org/10.1371/journal.pone.0134932.s003
(TIF)
Author Contributions
Conceived and designed the experiments: JL POB CF PM MF MB. Performed the experiments: JL POB CF. Analyzed the data: JL POB CF MF MB. Contributed reagents/materials/analysis tools: POB PM MF. Wrote the paper: JL POB CF PM MF MB.
References
- 1. Senkus E, Kyriakides S, Penault-Llorca F, Poortmans P, Thompson A, Zackrisson S, et al. (2013) Primary breast cancer: ESMO Clinical Practice Guidelines for diagnosis, treatment and follow-up. Ann Oncol. 24: vi7–23. pmid:23970019
- 2. Coughlin SR (2000) Thrombin signalling and protease-activated receptors. Nature. 407: 258–264. pmid:11001069
- 3. Belting M, Ahamed J, Ruf W (2005) Signaling of the tissue factor coagulation pathway in angiogenesis and cancer. Arterioscler Thromb Vasc Biol. 25: 1545–1550. pmid:15905465
- 4. Gieseler F, Ungefroren H, Settmacher U, Hollenberg MD, Kaufmann R (2013) Proteinase-activated receptors (PARs)—focus on receptor-receptor-interactions and their physiological and pathophysiological impact. Cell Commun Signal. 11: 86. pmid:24215724
- 5. Versteeg HH, Schaffner F, Kerver M, Ellies LG, Andrade-Gordon P, Mueller BM, et al. (2008) Protease-activated receptor (PAR) 2, but not PAR1, signaling promotes the development of mammary adenocarcinoma in polyoma middle T mice. Cancer Res. 68: 7219–7227. pmid:18757438
- 6. Versteeg HH, Schaffner F, Kerver M, Petersen HH, Ahamed J, Felding-Habermann B, et al. (2008) Inhibition of tissue factor signaling suppresses tumor growth. Blood. 111: 190–199. pmid:17901245
- 7. Morris DR, Ding Y, Ricks TK, Gullapalli A, Wolfe BL, Trejo J (2006) Protease-activated receptor-2 is essential for factor VIIa and Xa-induced signaling, migration, and invasion of breast cancer cells. Cancer Res. 66: 307–314. pmid:16397244
- 8. Kamath L, Meydani A, Foss F, Kuliopulos A (2001) Signaling from protease-activated receptor-1 inhibits migration and invasion of breast cancer cells. Cancer Res. 61: 5933–5940. pmid:11479236
- 9. Even-Ram S, Uziely B, Cohen P, Grisaru-Granovsky S, Maoz M, Ginzburg Y, et al. (1998) Thrombin receptor overexpression in malignant and physiological invasion processes. Nat Med. 4: 909–914. pmid:9701242
- 10. Booden MA, Eckert LB, Der CJ, Trejo J (2004) Persistent signaling by dysregulated thrombin receptor trafficking promotes breast carcinoma cell invasion. Mol Cell Biol. 24: 1990–1999. pmid:14966279
- 11. Yang E, Boire A, Agarwal A, Nguyen N, O'Callaghan K, Tu P, et al.(2009) Blockade of PAR1 signaling with cell-penetrating pepducins inhibits Akt survival pathways in breast cancer cells and suppresses tumor survival and metastasis. Cancer Res. 69: 6223–6231. pmid:19622769
- 12. Cohen I, Maoz M, Turm H, Grisaru-Granovsky S, Maly B, Uziely B, et al. (2010) Etk/Bmx regulates proteinase-activated-receptor1 (PAR1) in breast cancer invasion: signaling partners, hierarchy and physiological significance. PLoS One. 5: e11135. pmid:20559570
- 13. Blackhart BD, Emilsson K, Nguyen D, Teng W, Martelli AJ, Nystedt S, et al. (1996) Ligand cross-reactivity within the protease-activated receptor family. J Biol Chem. 271: 16466–16471. pmid:8663335
- 14. O'Brien PJ, Prevost N, Molino M, Hollinger MK, Woolkalis MJ, Woulfe DS, et al. (2000) Thrombin responses in human endothelial cells. Contributions from receptors other than PAR1 include the transactivation of PAR2 by thrombin-cleaved PAR1. J Biol Chem. 275: 13502–13509. pmid:10788464
- 15. Lin H, Trejo J (2013) Transactivation of the PAR1-PAR2 heterodimer by thrombin elicits beta-arrestin-mediated endosomal signaling. J Biol Chem. 288: 11203–11215. pmid:23476015
- 16. Sevigny LM, Austin KM, Zhang P, Kasuda S, Koukos G, Sharifi S, et al. (2011) Protease-activated receptor-2 modulates protease-activated receptor-1-driven neointimal hyperplasia. Arterioscler Thromb Vasc Biol. 31: e100–106. pmid:21940952
- 17. Jaber M, Maoz M, Kancharla A, Agranovich D, Peretz T, Grisaru-Granovsky S, et al. (2014) Protease-activated-receptor-2 affects protease-activated-receptor-1-driven breast cancer. Cell Mol Life Sci. 71: 2517–2533. pmid:24177339
- 18. Ryden L, Grabau D, Schaffner F, Jonsson PE, Ruf W, Belting M (2010) Evidence for tissue factor phosphorylation and its correlation with protease-activated receptor expression and the prognosis of primary breast cancer. Int J Cancer. 126: 2330–2340. pmid:19795460
- 19. Salah Z, Uziely B, Jaber M, Maoz M, Cohen I, Hamburger T, et al. (2012) Regulation of human protease-activated receptor 1 (hPar1) gene expression in breast cancer by estrogen. FASEB J. 26: 2031–2042. pmid:22291441
- 20. Malmstrom P, Bendahl PO, Boiesen P, Brunner N, Idvall I, Ferno M (2001) S-phase fraction and urokinase plasminogen activator are better markers for distant recurrences than Nottingham Prognostic Index and histologic grade in a prospective study of premenopausal lymph node-negative breast cancer. J Clin Oncol. 19: 2010–2019. pmid:11283134
- 21. McShane LM, Altman DG, Sauerbrei W, Taube SE, Gion M, Clark GM; Statistics Subcommittee of NCI-EORTC Working Group on Cancer Diagnostics. (2006) Reporting recommendations for tumor MARKer prognostic studies (REMARK). Breast Cancer Res Treat. 100: 229–235. pmid:16932852
- 22. Elston CW, Ellis IO (1991) Pathological prognostic factors in breast cancer. I. The value of histological grade in breast cancer: experience from a large study with long-term follow-up. Histopathology. 19: 403–410. pmid:1757079
- 23. Goldhirsch A, Ingle JN, Gelber RD, Coates AS, Thurlimann B, Senn HJ (2009) Thresholds for therapies: highlights of the St Gallen International Expert Consensus on the primary therapy of early breast cancer 2009. Ann Oncol. 20: 1319–1329. pmid:19535820
- 24. Beresford MJ, Wilson GD, Makris A (2006) Measuring proliferation in breast cancer: practicalities and applications. Breast Cancer Res. 8: 216. pmid:17164010
- 25. Schoenfeld D (1982) Partial residuals for the proportional hazards regression model. Biometrika. 69: 239–241.
- 26.
Marubini E, Valsecchi MG (2004) Analysing survival data from clinical trials and observational studies, vol. 15: John Wiley & Sons, New York
- 27. Goldhirsch A, Winer EP, Coates AS, Gelber RD, Piccart-Gebhart M, Thurlimann B, et al. (2013) Personalizing the treatment of women with early breast cancer: highlights of the St Gallen International Expert Consensus on the Primary Therapy of Early Breast Cancer. Ann of Oncol. 24: 2206–2223.
- 28. Kato S, Endoh H, Masuhiro Y, Kitamoto T, Uchiyama S, Sasaki H, et al. (1995) Activation of the estrogen receptor through phosphorylation by mitogen-activated protein kinase. Science. 270: 1491–1494. pmid:7491495
- 29. Levin ER (2003) Bidirectional signaling between the estrogen receptor and the epidermal growth factor receptor. Mol Endocrinol. 17: 309–317. pmid:12554774
- 30. Cascio S, Bartella V, Garofalo C, Russo A, Giordano A, Surmacz E (2007) Insulin-like growth factor 1 differentially regulates estrogen receptor-dependent transcription at estrogen response element and AP-1 sites in breast cancer cells. J Biol Chem. 282: 3498–3506. pmid:17166846
- 31. Fan P, Wang J, Santen RJ, Yue W (2007) Long-term treatment with tamoxifen facilitates translocation of estrogen receptor alpha out of the nucleus and enhances its interaction with EGFR in MCF-7 breast cancer cells. Cancer Res. 67: 1352–1360. pmid:17283173
- 32. Schiff R, Osborne CK (2005) Endocrinology and hormone therapy in breast cancer: new insight into estrogen receptor-alpha function and its implication for endocrine therapy resistance in breast cancer. Breast Cancer Res. 7: 205–211. pmid:16168139
- 33. Pawlinski R, Holinstat M: We can do it together (2011) PAR1/PAR2 heterodimer signaling in VSMCs. Arterioscler Thromb Vasc Biol. 31: 2775–2776. pmid:22096094
- 34. Stalheim L, Ding Y, Gullapalli A, Paing MM, Wolfe BL, Morris DR, et al. (2005) Multiple independent functions of arrestins in the regulation of protease-activated receptor-2 signaling and trafficking. Mol Pharmacol. 67: 78–87. pmid:15475570
- 35. McCoy KL, Traynelis SF, Hepler JR (2010) PAR1 and PAR2 couple to overlapping and distinct sets of G proteins and linked signaling pathways to differentially regulate cell physiology. Mol Pharmacol. 77: 1005–1015. pmid:20215560
- 36. McKenna NJ, O'Malley BW (2002) Minireview: nuclear receptor coactivators—an update. Endocrinology. 143: 2461–2465. pmid:12072374
- 37. Wang W, Dong L, Saville B, Safe S (1999) Transcriptional activation of E2F1 gene expression by 17beta-estradiol in MCF-7 cells is regulated by NF-Y-Sp1/estrogen receptor interactions. Mol Endocrinol. 13: 1373–1387. pmid:10446910
- 38. Stein B, Yang MX (1995) Repression of the interleukin-6 promoter by estrogen receptor is mediated by NF-kappa B and C/EBP beta. Mol Cell Biol. 15: 4971–4979. pmid:7651415