Background
Worldwide, breast cancer is responsible for more than half a million deaths each year, but the ability to predict clinical outcome of the disease is still limited [
1]. Breast cancer is a complex multi-gene disease involving the activation of oncogenes, loss of tumor suppressor genes, and disruption of vital cell-signaling pathways responsible for cell survival, growth, differentiation, and apoptosis. In recent years, the cellular and molecular characterization of breast cancer has catalyzed a shift toward the development of improved diagnosis and treatment of this disease [
2,
3]. To improve long-term survival rates and quality of life, several treatment regimens are currently available, including surgery combined with adjuvant therapy. Furthermore, several clinicopathological factors are also used to stratify patients into groups with different prognoses and to predict their response to adjuvant systemic therapies, including histological tumor grade, stage, size, age at diagnosis, axillary lymph node status, human epidermal growth factor receptor 2 (HER2/
neu) status, steroid hormone receptor expression, and vascular invasion [
4,
5]. However, despite improvements in the treatment of breast cancer, it remains the second most common cause of death in women after lung cancer. Moreover, breast cancer incidence has risen steadily in recent years and many patients are exposed to ineffective therapies, as well as, to unnecessary treatment-related toxicity [
6]. Therefore, there is intense focus on the development of improved treatment for breast cancer, especially targeted therapies.
Recently, we performed a detailed analysis of copy number and gene expression in 97 primary invasive diploid breast tumors [
7]. We identified molecular gene signatures in aggressive tumors that resulted in different clinical outcomes. In the present investigation, five genes (
CCNB2, CDCA7, ASPM, KIAA0101, and
SLC27A2) were selected from these gene signatures based on their significantly deregulated gene expression according to short-term disease-specific survival, triple-negative status, and/or stratified according to histological grade as defined by Bloom, Richardson, Elston/Ellis (BRE) grading system [
8]. In addition,
CCNB2, ASPM, KIAA0101, and
CDCA7 are known to be involved in DNA repair, DNA replication, and cell cycle arrest [
9‐
13], whereas
SLC27A2 plays a role in fatty acid transport [
14]. We then further analyzed their protein levels and subcellular localization in relation to patient clinical outcome as well as with clinicopathological features in an independent cohort of 80 primary invasive breast tumors.
Methods
Tumor specimens
Primary invasive tumors were obtained from 80 patients who had undergone surgery from the 1990 to 2006 at Sahlgrenska University Hospital, Gothenburg, Sweden. Formalin-fixed, paraffin-embedded tissues (FFPE) and fresh-frozen primary invasive breast carcinomas were obtained from the Departments of Pathology and Oncology at Sahlgrenska University Hospital in accordance with the Declaration of Helsinki and approved by the Medical Faculty Research Ethics Committee (Gothenburg, Sweden). The clinical and morphologic characteristics of the tumors are summarized in Table
1. To examine potential variations in protein expression of candidate biomarkers, the tumors were stratified according to disease-specific survival (DSS) with 8-year censoring, and histological grade as defined by Bloom, Richardson, Elston/Ellis (BRE) grading system [
8].
Table 1
Clinicopathological characteristics of 80 invasive breast cancer patients
Mean age (y)
| 58 (39–72) | 52 (27–7) | 55 (39–71) | 53 (33–72) |
Histologic type
| | | | |
Ductal | 15 (71) | 18 (95) | 15 (75) | 16 (80) |
Lobular | 2 (10) | 1 (5) | 4 (20) | 3 (15) |
Ductal + lobular | 0 (0) | 0 (0) | 1 (5) | 0 (0) |
Other | 3 (14) | 0 (0) | 0 (0) | 1 (5) |
Not available | 1 (5) | 0 (0) | 0 (0) | 0 (0) |
Pathologic tumor size (mm)
| | | | |
pT1 (0–20) | 2 (9) | 6 (32) | 3 (15) | 5 (25) |
pT2 (>20-50) | 18 (86) | 9 (47) | 16 (80) | 13 (65) |
pT3 (>50) | 1 (5) | 4 (21) | 1 (5) | 2 (10) |
pT4 | 0 (0) | 0 (0) | 0 (0) | 0 (0) |
BRE grade
| | | | |
I-II | 21 (100) | | 20 (100) | |
III | | 19 (100) | | 20 (100) |
No. of axillary lymph nodes
| | | | |
0 | 7 (33) | 7 (37) | 7 (35) | 7 (35) |
1-3 | 5 (24) | 7 (37) | 6 (30) | 6 (30) |
≥4 | 9 (43) | 5 (26) | 7 (35) | 7 (35) |
Surgery
| | | | |
Lumpectomy | 9 (43) | 6 (32) | 9 (45) | 6 (30) |
Mastectomy | 12 (57) | 13 (68) | 11 (55) | 14 (70) |
ER/PR status
| | | | |
Negative | 11 (52) | 8 (42) | 13 (65) | 7 (35) |
Positive | 9 (43) | 11 (58) | 7 (35) | 13 (65) |
Not available | 1 (5) | | | |
HER2/
neu
status
| | | | |
Positive | 7 (33) | 8 (42) | 8 (40) | 3 (15) |
Negative | 11 (52) | 10 (53) | 11 (55) | 9 (45) |
Not available | 3 (15) | 1 (5) | 1 (5) | 8 (40) |
Immunohistochemistry (IHC)
Antibodies corresponding to CCNB2, CDCA7, KIAA0101, SLC27A2, and ASPM were optimized using 12 independent primary invasive breast tumors with different stage I-III as controls. Four micrometer FFPE sections were applied onto positively charged slides (FLEX IHC microscope slides, Dako, Sweden) and subsequently immunostained with rabbit anti-CCNB2 (Sigma-Aldrich, Stockholm, Sweden, HPA008873, 1:100 dilution), rabbit anti-CDCA7 (Sigma-Aldrich, HPA005565, 1:50 dilution), rabbit anti-SLC27A2 (Sigma-Aldrich, HPA026089, 1:50 dilution), mouse anti-KIAA0101 (Abnova, Stockholm, Sweden, H00009768-M01, 1:200 dilution), and rabbit anti-ASPM (Novus Biologicals, England, UK, 25970002, 1:1100 dilution) to determine protein expression levels and subcellular localization of the corresponding proteins in breast tumors. The FFPE sections were processed with the Dako EnVision™ FLEX antigen retrieval EDTA buffer (pH 9) for 20 minutes at 97°C using DAKO PT Link module (PT Link, Dakocytomation, Denmark) according to the manufacturer's instructions. The IHC procedure was performed using DAKO stainer (DAKO Auotstainer plus, Dakocytomation, Denmark) following the manufacturer's instructions. Antibody staining was evaluated by a single pathologist (AK). At the time of examination, the pathologist was blinded as to the diagnosis and other clinicopathological data. Immunoreactivity was defined as negative with a score of 0 (no staining in any cells or very weak cytoplasmic or nucleus staining in less than 10% of the invasive tumor cells). Positive immunoreactivity was defined as 1+ (weak to moderate staining in more than 10% of the invasive tumor cells) or 2+ (moderate to strong staining in more than 10% of the invasive tumor cells). Areas with intraductal carcinoma were excluded from the evaluation.
Fluorescence in situhybridization (FISH)
To assess
HER2/neu gene status in the 67/80 available fresh-frozen tumor samples, fluorescence
in situ hybridization was performed. A bacterial artificial chromosome (BAC) clone covering the
HER2/neu locus (RP11-94L15) was purchased from BACPAC Resource Center (Oakland, CA, USA,
http://bacpac.chori.org/) and used as a FISH probe. FISH was performed on tumor touch-prints prepared from fresh-frozen tumors as described elsewhere [
15]. The analysis was performed on a Leica DMRA2 fluorescence microscope (Leica, Stockholm, Sweden) equipped with an ORCA Hamamatsu charged-couple devices camera (Hamamatsu Corporation, Stockholm, Sweden). Scoring of HER2/
neu hybridization signals was carried out in each tumor specimen by counting the number of signals in at least 100 nuclei. Specimens were scored as either positive (1) when
HER2/neu gene amplifications were detected in more than 10% of the analyzed cells or negative (0) in all other cases.
Quantitative real-time PCR (qRT-PCR)
Total RNA was isolated from fresh-frozen tumor specimens using TRIzol reagent (Life Technologies, Stockholm, Sweden) and the Qiagen RNeasy mini kit (Qiagen, Stockholm, Sweden) according to the manufacturer's instructions, followed by treatment with RNase-free DNase (Ambion, Texas, USA). One microgram total RNA was converted to cDNA using random hexamers and Superscript III (Life Technologies) according to standard procedures. Validation of the IHC and FISH results was performed using qRT-PCR with TaqMan Gene Expression Assays (Life Technologies) for CCNB2 (Hs00270424_m1), KIAA0101 (Hs00207134_m1), SLC27A2 (Hs00186324_m1), and HER2/neu (Hs01001580_m1) on a cohort of 62/80 tumors which were also used in the IHC and FISH analyses. The qRT-PCR reactions for each sample were performed in duplicate in independent experiments.
The
HPRT1 gene (Hs02800695_m1) was initially selected as an endogenous control because it exhibited low variance in mRNA expression between samples (data not shown). The qRT-PCR reactions (10 μl total) included 2 μl of cDNA template, 2x TaqMan Universal PCR Master Mix (ABI, Foster City, USA), and 1x FAM labeled gene-specific assay. All qRT-PCR reactions were performed in 384-well plates using the ABI PRISM 7900HT Sequence Detection System (ABI, Foster City, USA) with an initiation step at 95°C for 10 minutes, followed by 40 cycles at 95°C for 15 seconds and at 60°C for 1 minute. For each assay, a template dilution standard curve (5-fold range) was recorded. Genomic DNA and no-template samples were included as controls. Relative gene expression levels were calculated with the relative standard curve method using CT values of the analyzed genes normalized with
HPRT1[
16].
Statistical analysis
Protein expression was examined in relation to DSS using the Kaplan-Meier method and was compared with the log-rank test. Univariate and multivariate models using proportional hazards regression were applied as an exploratory tool to assess the effect of the selected markers on DSS. Multivariate models were employed to adjust for possible confounding effect to classical clinicopathological features including tumor grade, tumor size, axillary lymph node status, HER2/
neu, and estrogen receptor (ER)/ progesterone receptor (PR) status. The predictive power of the models was assessed as time dependent Area Under the Receiver Operatic Characteristic Curves (AUC(t)) and summarized by the concordance index (C-index) [
17]. The C-index varies between 0.5 (no predictive power) and 1 (perfect prediction). Associations were evaluated by using the
χ2-test or
t-test, where appropriate. The probability (
P) values were two-sided and considered statistically significant if
P <0.05. All statistical manipulations were performed using the SPSS version 20.0 and R 2.14.0 statistical software.
Discussion
Despite the use of combination therapies including surgery and other systemic treatments (radiotherapy, endocrine therapy, and anticancer agents), many breast cancer patients will ultimately develop metastatic disease, which remains to be essentially incurable. Therefore, identification of novel prognostic and predictive biomarkers for breast tumors is needed and remains a long awaited priority to enhance individualized treatment. Recently, we identified molecular gene signatures associated with aggressive breast cancer [
7]. Here, we present a validation of the prognostic role of five selected candidate biomarkers (CCNB2, ASPM, KIAA0101, CDCA7, and SLC27A2) included in these gene signatures using an independent breast cancer cohort.
In the present study, elevated CCNB2 protein levels were significantly associated with shorter DSS. Prominently, the HR of patients whose tumors were CCNB2-positive was 6.1 corresponding to a dramatic increase in probability of mortality compared with patients whose tumors had very little or no expression.
It is well-known that different cyclins regulate the eukaryotic cell cycle in association with cyclin dependant kinases (cdks) at specific points of the mitotic cycle. Cell cycle progression follows periodic alternations in the protein levels of cyclins, D, E, A and B. Deregulated levels of cyclins have been frequently observed in breast cancer [
18]. Elevated levels of cyclin E was significantly correlated with DSS in patients with breast cancer [
19]. Amplification and/or overexpression of cyclin D1 have been correlated to poor prognosis in breast cancer patients [
20]. The Cyclin A upregulation was reported to be associated with increased risk of recurrence among breast cancer patients with node negative tumors [
21]. The
CCNB2 gene is a member of the B-type cyclin family, including cyclin B1 and B2. It is involved in the G2-M transition in eukaryotes by activating CDC2 kinase and its inhibition induces cell cycle arrest [
9,
22,
23]. In agreement with a crucial role in cell growth, numerous studies detected overexpression of CCNB2 in human tumors, including lung, colorectal adenocarcinoma, and pituitary adenomas [
24‐
27]. Serum circulating
CCNB2 mRNA levels were found to be higher in lung and digestive tract cancer patients compared to normal controls and were correlated with cancer stage and metastasis status [
28]. Furthermore, the
CCNB2 gene was included in the set of genes detected in node-negative breast tumors associated with poor prognosis [
29]. Our results suggest that CCNB2 has an oncogenic potential and its overexpression may give some proliferative advantage. We have shown a significant association of CCNB2 protein expression with breast tumor type, indicating that the CCNB2 protein levels were unevenly distributed among the histological types. Notably, no statistically significant differences were identified between CCNB2 protein levels in relation to patient age, tumor size, tumor grade, ER/PR status, HER2/
neu, stage, and axillary lymph node status. However, a dissimilar trend has been reported in serum circulating
CCNB2 mRNA, since it was found to correlate with both grade and metastasis status [
28]. The multivariate analysis including CCNB2 and several clinicopathological parameters further verified that CCNB2 remained an independent prognostic indicator for DSS. These data indicate that tumors with histological grade (I, II and III), axillary lymph node status (positive, negative), tumor size (0–2, 2–5, and >5), ER/PR status (positive, negative) and HER2/
neu status, exhibiting CCNB2 protein expression, have a more unfavorable prognosis, with an increased risk of overall shorter survival rates. Moreover, the predictive power of CCNB2 in addition to the clinicopathological parameters model was slightly higher compared to the lower C-index of the model including all clinicopathological parameters alone. Thus, the accuracy in patient prognosis may be improved by measuring CCNB2 expression in cases of breast cancer.
The ASPM protein was reported to participate in spindle organization, spindle orientation, mitotic progression, and cytokinesis [
10,
11,
30,
31]. Furthermore, the ASPM protein is over-expressed in various cancers [
10,
32‐
35] and its knockdown inhibits tumor proliferation [
32]. There was no association between elevated ASPM protein levels and DSS or any other clinical parameters, suggesting that ASPM may be involved only in cancer initiation. A significant correlation between CCNB2 and ASPM was observed. The induction of ASPM and CCNB2 has previously been reported to regulate the G2/M cell cycle progression [
36]. Thus, elevated levels of CCNB2 may reflect a functional correlation with ASPM overexpression, which could play a role in the progression of breast carcinoma. Furthermore, up-regulation of CCNB2 and ASPM was detected in glioblastoma multiforme xenograft tumors and
de novo glioblastoma multiforme tumors [
37]. Activation of
CCNB2 and
ASPM genes induces tumorigenic phenotypes in a number of cancers, whereas their inhibition abrogates cellular proliferation in mice and induces genomic instability [
23,
38].
The
CDCA7 gene has been implicated in neoplastic transformation and it is one of the downstream targets of the
Myc oncogene [
13]. Interestingly, high nuclear expression of CDCA7 was seen in all the analyzed tumors in the present study. It is known that deregulation of cell cycle control is a fundamental feature of cancer pathogenesis, therefore it was not unexpected that CDCA7 protein has been observed to be expressed at high levels in almost all selected tumors. KIAA0101 is predominantly expressed in mitochondria and partially in nuclei, playing an essential role in the regulation of DNA repair, cell cycle progression, and cell proliferation [
12]. Moreover, the
KIAA0101 gene is over-expressed in tumors of the esophagus [
39], colon [
40], lungs [
41,
42], and breast [
43]. KIAA0101-positivity was observed in 79% of the immunostained tumors. Up-regulation of KIAA0101 was confirmed by real time qRT-PCR, which showed the over-expression of the gene at the mRNA level in 92% of the studied tumors. The possibility of tissue heterogeneity, accounting for the discordance between mRNA and protein expression cannot be excluded. In addition, there was no association between elevated CDCA7 and KIAA0101 protein levels and DSS or any other clinical parameters. The CDCA7, and KIAA0101 may therefore only have role in tumor initiation. Discordant results were detected between mRNA and protein expression of SLC27A2. High mRNA expression was detected in 83% of the analyzed tumors, but protein expression was only seen in 25%, possibly owing to posttranscriptional regulation and differences in mRNA, and protein turnover rates or poor specificity of the antibody used for IHC [
44,
45]. These findings suggest that down-regulation of SLC27A2 in the selected tissues at the protein level may contribute to disease progression. Indeed, this gene was reported to regulate the tumor suppressor gene PARP and decreased SLC27A2 expression levels were found in the metastatic compared to the non-metastatic neuroendocrine tumors [
46]. However, no significant difference could be seen on the effect of SLC27A2 protein expression on DSS in breast cancer, nor could any association between the protein expression of SLC27A2 and the conventional clinical characteristics be observed.
To our knowledge, this is the first study in breast cancer patients reporting CCNB2 as a prognostic marker for unfavorable patient prognosis. Since several publications revealed that altered CCNB2 expression is seen in many cancer types, therefore further investigation to elucidate the mechanism by which CCNB2 exerts its effects may prove useful in the development of novel anticancer agents.
Competing interests
The authors declare that they have no competing interests.
Authors' contributions
ES and SH performed the immunohistochemistry. AK evaluated the immunostained breast cancer tissues. AK, ZE, and KG provided the clinical information. ES performed the fluorescence in situ hybridization and the qRTPCR. ES and SN performed the statistical analysis. ES interpreted the results. ES and KH wrote the paper. TP, SN, SH, AK, ZE, PK, and KH critically revised the manuscript. All authors read and approved the final manuscript.