MicroRNA expression in pre-treatment plasma of patients with benign breast diseases and breast cancer

INTRODUCTION

Early diagnosis improves breast cancer survival [1]. National screening programs aim to detect breast cancer at an early stage. Woman aged 50–75 are invited for biennial screening with additional annual screening programs for patients with a cumulative life time risk of breast cancer of over 20% (40–50 years) and BRCA1/2-mutation carriers (25–75 years). Mammography and breast MRI (BRCA1/2-mutation carriers) are the radiological modalities used in these programs. Mammographic sensitivity is, however, generally impaired in patients with dense breast tissue found especially in the younger population [2]. In the national screening program performed in the general population 20% of the carcinomas is detected between two screening moments [3]. Improved sensitivity of screening could possibly reduce the number of these interval carcinomas. Improved specificity could diminish distress as a result of false-positive (mammographic) result. Biomarkers detectable in body fluids could be valuable as this allows for minimally invasive screening and repetitive monitoring [4].

Blood-based microRNAs (miRs) are potential biomarkers for breast cancer. MiRs are small RNA molecules that influence regular messenger RNA (mRNA) expression and translation by binding with (partially) complementary sequences on target mRNAs aided by the RNA-induced slicing complex [5]. The resulting post-transcriptional gene modulation can lead to mRNA degradation, translational inhibition or translational activation [6]. MiRs, as opposed to mRNAs, are extremely stable under different conditions and readily detectable in serum and plasma [7].

In breast cancer, multiple miRs have been associated with oncogenic driver events, cancer invasiveness, adverse clinical outcome and therapy resistance [5, 8–12]. Most of these studies used tissue samples whereas blood-based markers are needed for screening purposes. Previous studies focusing on miRs present in the circulation (serum or plasma) showed that the quantity and composition of blood-based miRs can predict the presence of tumour [7, 9, 13, 14]. Differences in miR expression levels between breast cancer patients and healthy controls enables the use of miRs as a blood-based diagnostic biomarker.

This study aimed to identify and validate miRs indicative for breast cancer in plasma of patients prior to surgery who did not receive neo-adjuvant treatment with a long follow-up term. The cohort consisted of patients without and with a family history of breast cancer including BRCA1-mutation carriers. MiRs discriminative for benign and malignant breast disease in a discovery cohort and miRs reported in literature to be differentially expressed between breast cancer patients and healthy controls [15–21] were validated in an independent validation cohort.

RESULTS

One discovery sample (3.3%) was excluded based on a high haemolysis score resulting in 29 suitable samples. In the validation cohort 4/84 (4.7%) and 1/84 (1.2%) samples were excluded based on a too low expression level of the 5 reference miRs and/or a high haemolysis score, respectively, resulting in 79 suitable samples. Baseline characteristics are specified in Table 1. The two cohorts were well balanced considering the clinical parameters. The median follow-up time was shorter in the discovery cohort than the validation cohort: 9.2 [interquartile range (IQR) 7.7.-10.1] versus 11.0 [IQR 7.4-11.8] years, P = 0.043. Breast cancer metastases occurred in 6 (32%) and 8 (16%) of the breast cancer patients during follow-up with a median time since blood sampling of 0.9 [IQR 0.3-4.4] and 2.1 [IQR 0.3-4.4] years for the discovery and validation cohort, respectively, P = 0.53. Local breast cancer recurrence was not reported in either cohort during follow-up.

Discovery phase

The unsupervised analysis of the 756 miRs detected with the microarray clearly showed a separated hierarchical clustering of the benign wildtype BRCA1 and the other benign samples (Figure 1). The benign BRCA1-mutations carrier samples, however, clustered with the malignant cases.

Of the 756 miRs, 7 miRs were significantly differentially expressed between benign and malignant pooled samples and were therefore selected for validation (Supplementary Table 1). Since the benign BRCA1-mutations carriers samples, clustered with the malignant cases, 4 additional miRs most discriminatory between benign BRCA1-mutation carriers and wildtype samples were added to our selection to further investigate this observation (Figure 2 and Supplementary Table 1). In addition, 11 literature-based miRNA and 6 stable expressed reference miRs selected from the microarray were included for analysis in the validation cohort (Supplementary Table 2). Twenty-five out of 30 miRs (5 reference miRs for quantification, 2 haemolysis markers and 18 candidate miRs) passed our quality control steps with respect to reproducibility and PCR efficiency (Figure 2). The 18 candidate miRs were quantified in the validation samples by RT-qPCR using validated Taqman mature MicroRNA Assays (ThermoScientific).

Validation phase

Benign versus malignant

Hsa-miR-652-5p, a selected candidate-miR in the discovery cohort, was significantly upregulated in the validation cohort and therefore validated as a potential biomarker for the detection of breast cancer. Has-miR-652-5p was statistically significant upregulated in the malignant samples (n = 49) compared to the benign samples (n = 30), fold change 1.26 (P = 0.006) (Table 2 and Figure 3). Hsa-let-7b, a literature-based miR, also was statistically significant upregulated in malignant samples compared to benign samples, fold change 1.53 (P = 0.011) (Table 2 and Figure 3). Neither hsa-miR-652-5p nor hsa-let-7b showed a significant correlation with age (Spearman’s’ rank correlation coefficient -0.044 (P = 0.77) and 0.169 (P = 0.257), respectively). Within the n = 49 breast cancer cases, no statistical differences in the expression levels of both miRs were found regarding tumour stage, nodal status, hormonal receptor status, HER2 status or triple negative breast cancer (TNBC) status (data not shown).

BRCA1-mutation carriers

The 4 miRs selected in the discovery cohort based on a 2-fold higher expression in the benign BRCA1-mutation carriers versus wildtype benign cases showed no differential expression in the validation cohort (data not shown). When investigating expression in the individual benign samples (discovery and validation cohort) of BRCA1-mutation carriers (due to the low numbers, discovery and validation cohort combined) with wildtype benign samples (validation cohort) both hsa-miR-185-5p and hsa-miR-675-5p showed an differential expression with a fold change 2.16 (P = 0.005) and 0.25 (P = <0.001), respectively (Table 3). No differences were found comparing malignant BRCA1-mutation carriers (discovery and validation cohort, n = 3) to wildtype malignant samples (validation cohort, n = 39) (data not shown).

Malignant; non-metastatic versus metastatic breast cancer

Eight out of 49 (16.3%) breast cancer patients were diagnosed with metastatic breast cancer during follow-up (Table 1). Comparing metastatic to non-metastatic breast cancer samples hsa-miR-135a, hsa-miR-195-5p and hsa-miR-675-5p showed an upregulated expression whereas hsa-miR-18b-5p, hsa-miR-21-5p, hsa-miR-29b, hsa-miR-202-3p and hsa-miR-382-3p showed a downregulated expression in metastatic samples (Table 2 and Figure 4).

DISCUSSION

MiRs can be useful biomarkers and we identified one, hsa-miR-652-5p, for which pre-treatment plasma levels are different between malignant and non-malignant disease. The higher expression of this miR in breast cancer patients was confirmed in an independent validation cohort. As the expression did not correlate with either patients’ age, tumour stage, nodal stage or hormonal receptor status and Her-2/Neu status, hsa-miR-652-5p may be widely applicable as a possible blood-based biomarker for breast cancer detection. The use of a miR signature is, however, preferred over the use of a single miR as a potential biomarker since a combination of miRs usually improves diagnostic accuracy [17, 25, 26]. In the current cohort only miR hsa-miR-652-5p was validated as a potential biomarker. In line with these results, hsa-miR-652 has previously been reported as a breast cancer biomarker with a upregulated expression comparing benign breast diseases to breast cancer patients [26] and healthy controls versus benign and versus malignant breast diseases [27]. As in our cohort, both previously published studies showed an upregulated expression irrespective of tumour stage, thus supporting the use of hsa-miR-652 as a potential biomarker for early stage breast cancer detection. To the best of our knowledge the genome context or target context of hsa-miR-652-5p has not been described previously.

The literature based candidate hsa-let-7b was also significantly differentially expressed between benign and malignant samples within the validation cohort. The let-7-family is associated with multiple oncogenes and upregulated let-7-levels have been associated with a poor prognosis and poor overall survival [20, 28]. The upregulation observed is in line with other studies showing an upregulated expression in breast cancer patients [17, 28, 29] with higher levels in metastatic breast cancer [29]. Higher levels of hsa-let-7b between metastatic and non-metastatic patients were, however, not observed in the current cohort. The validation cohort, however, did show 8 miRs that were significantly different in breast cancer patients with metastasis compared to those without. These miRs could possibly be used to predict the onset of breast cancer metastasis. Although some of these miRs have been described as possible biomarkers differentiating between healthy and malignant samples [15, 18, 19, 30, 31], only the downregulation of hsa-miR-29b has previously been reported to differentiate non-metastatic from metastatic breast cancer samples [31]. When performing an additional sensitivity analysis comparing the individual non-metastatic (n = 13) to metastatic samples (n = 6) of the discovery cohort no significant differences were found in miR expression levels. This can possibly be explained by the limited patient number available in the discovery cohort and overall small differences in absolute miR expression levels found in both cohorts. Therefore, independent validation of these miRNAs in a large cohort is needed.

Although promising as potential biomarkers, several methodological issues have to be resolved to take miR expression data to the clinical arena. Multiple techniques are described for miR detection and selection or the type of normalisation of miR-data, possibly influencing the results or interpretation. The range of the miR expression level is influenced by the normalisation on which a relative expression or fold change is calculated. The normalisation of the expression levels varies between studies potentially hampering validation of previously obtained results. In the search for a potential breast cancer biomarker differences in clinical characteristics influencing miR expression levels should be accounted for when comparing cohorts. As shown in multicentre cohorts harbouring breast cancer patients, differences in MIR expression are also present between patients with benign breast disease(s) and healthy controls [25, 26]. In a large cohort, Shimomura et al. underlined the wide variation in miR expression levels present within the healthy population [25].

The strength of the current study is the use of a validation phase after an initial discovery phase. The cohorts investigated reflect a general population but included also women with a high familial risk of breast cancer and BRCA1-mutation carriers (4 benign and 4 malignant samples). The use of pre-treatment breast cancer samples enabled a comparison of miR expression levels without a possible influence of (systemic) therapy.

Limitations of the current study may include the pooled sample-design of the discovery phase. This could have limited the identification of candidate miRs for use in the validation phase. Furthermore, subgroups analyses in the validation cohort were performed with a limited patient number. The relative low expression of hsa-miR-652-5p as compared to other miRs (–0.25) in the validation cohort limits the use of the miR as a potential biomarker due to an increased risk of measurements errors influencing the diagnostic accuracy. Given that only hsa-miR-652-5p showed an differential expression in both cohorts the diagnostic accuracy for this single miR was not evaluated.

Unexpectedly, when evaluating the results of the unsupervised hierarchical clustering in the discovery phase, benign samples of BRCA1-mutation carriers clustered with the malignant samples. A differential expression for two other miRs (hsa-miR-185-5p and hsa-miR-675-5p) was additionally found when comparing BRCA1 mutant versus wildtype cases. These results and the differential expression as found by Erturk and colleagues [32, 33] emphasize the need for validation of miR biomarkers as a screening tool in well-balanced cohorts including BRCA1-mutation carriers, especially since in the general population individuals may be unaware of their BRCA-mutation status. This underlines the need for well-balanced cohorts. In this field of research it is of utmost importance that expression data is confirmed in other cohorts before these miRs are used to guide screening and treatment. Furthermore, differences in measurement techniques and normalization methodologies should be minimized enabling an adequate comparison and thus meaningful validation.

METHODS

Patients

After informed consent, pre-treatment blood samples were obtained of patients with benign breast disease and those with breast cancer at Erasmus MC, the university hospital in Rotterdam, the Netherlands. This study was approved by the institutional review board (Medical Ethical committee number; MEC-2005-002). Following inclusion 114 samples were separated over the discovery cohort (n = 30) and the validation cohort (n = 84) dividing the benign and malignant cases. At time of blood sampling patients were allocated to the benign or malignant group. Patients were included only if the diagnosis was histologically proven (if applicable) and long-term follow-up was available. Sufficient plasma (more than 500 μL) had to be available. Patients with a previous history of invasive carcinoma, patients for whom less plasma was available and breast cancer patients with metastasis at time of diagnoses were excluded. Male patients were excluded. Patients who were allocated to the benign group but turned out to have malignant disease during follow-up were additionally excluded in this study. Survival status and recurrence status was updated regularly using patients’ files. Last follow-up date was June 13th 2017.

Samples

Blood was obtained at the outpatient laboratory of the Erasmus MC. Following venous blood withdrawal (4 tubes per patients), samples were directly divided over micronics tubes (1 mL) separating whole blood, serum and plasma and stored in the freezer (–80° C). Prior to defrosting, dithiothreitol (DTT 5 mM final) was added to the plasma to prevent degradation of nucleic acids during defrosting and handling. Total RNA was isolated from 200 uL plasma with the Norgen Total RNA Purification Kit as recommended by the manufacturer (Norgen Biotek Corp., Canada), adjusted to 43% ethanol during isolation to optimize the miRNA recovery yield.

For the discovery phase, 12 samples were prepared, each sample containing a pool of 2 to 3 plasma RNA aliquots of patients with similar clinical characteristics (Supplementary Table 3). For the validation phase, only individual samples were used.

To ensure that good quality RNA was used only, all RNA samples were checked according to two sample quality control steps. First, 3 uL (5%) of the isolated total RNA was used in a multiplex RT-qPCR pre-screen with 8 validated Taqman MicroRNA Assays (ThermoScientific, The Netherlands). The median value of 5 stable-expressed reference miRs (Figure 2 and Supplementary Table 4) included in this 8-miR pre-screen panel served as a reference value by applying a cut-off value of 20 qPCR cycles. Second, haemolysis miR (Figure 2) expression was evaluated. The ratio of miR-451 over miR-23a was used to evaluate the possible presence of haemolysis in the samples as described previously [22]. As we had the median of 25 miRs (Figure 2) available quantified by RT-qPCR, we decided to use the more robust 25 miR median normalized miR-451 levels in the final analysis. Samples were excluded from the final analysis if a median normalized miR-451 value > 6.0 was measured.

Discovery phase

miR profiling

Pooled discovery samples containing either 400 or 600 μL plasma were shipped to TATAA (TATAA BioCenter, Sweden) for 3D-Gene miRNA profiling (Toray Industries, Japan). The 3D-Gene DNA chips contain 2,000 human miRNAs selected from database mirBase release 19.0. The chips were processed according to the standard protocol of the manufacturer (http://www.3d-gene.com/en/).

Data processing

Analysing the microarray data, the presence or absence of a signal was calculated as follows: spots with intensities higher than the background average + 2-standard deviations were considered “present”. The background average was subtracted from the signal intensities to give the background subtracted values, after which the median signal intensity was calculated. Finally, a normalisation factor was calculated as: 25 divided by the median signal intensity of all background-subtracted data, after which the background subtracted data were multiplied by this normalisation factor. Next, only miRs that were detectable in at least 20% of the groups (Supplementary Table 3) and for which validated Taqman assays were expected to be available [miR-1 to miR-700] were selected for further analysis in the unsupervised analysis (Supplementary Table 4). GeNorm and NormFinder, both present in the software package of GenEx v.6.1 from MultiD, were used to identify the most stable expressed miRs to uniformly normalise the microarray and Taqman reverse transcriptase polymerase chain reaction (RT-qPCR) data. For the microarray data, after background subtraction, thus identified 5 reference miRs (Figure 2) were used for normalizing the RT-qPCR data before identifying the differentially expressed miRs.

Apart from the miR expression present in the unsupervised analysis, 11 additional literature-based miRs (Figure 2 and Supplementary Table 3) previously reported to differentiate benign from malignant breast disease were selected [15–20].

Validation phase

miR profiling

Twenty-five miRs (20 selected miRs and 5 reference miRs) were quantified in the validation cohort by RT-qPCR using validated Taqman mature MicroRNA Assays (ThermoScientific) (Supplementary Table 4). To enable accurate and reliable quantification of multiple miRs in small RNA samples, an extended multiplex RT reaction (40 cycles) was performed as described by the manufacturer for their custom Taqman Array MicroRNA fluidic cards. This was followed by 15 PCR rounds of pre-amplification (PreAmp mastermix from ThermoScientific) and 40 rounds of PCR for quantification [14]. The performance of the RT-qPCR assays was checked using a serially diluted human breast cancer cell line control sample. The control consisted of total RNA isolated from different breast cancer cell lines to ensure all miRs were present in this control sample. A second check was performed with a cell line control sample containing total RNA from the same cell lines, this time however isolated from FFPE to evaluate the performance of the assays with degraded RNA. Only Taqman miRNA assays that could amplify miR targets homogeneously in a multiplexed reverse transcriptase setting within both serially diluted control samples were used for sample validation. This was defined as a specific, with 90-110% efficiency measured, linearly amplified end product [23].

Data processing

The median of all 25 miRs selected showed the lowest M-value and smallest inter- and intragroup variation and was therefore used as reference value to normalise RT-qPCR data in the validation phase (Supplementary Table 4).

MiR expression levels were compared in the validation cohort between 1) benign versus malignant samples and 2) non-metastatic versus metastatic breast cancer samples. Secondly the expression of the differentially expressed miRs were evaluated according to patients’ age (≤50 versus >50), familial breast cancer (no versus yes), tumour stage (T1 versus >T1), nodal stage (N0 versus N+), hormone receptor status, Her2Neu receptor status and triple negative status (negative for ER, PR and Her2Neu). Hormonal receptor status was considered positive in case of ≥10% nuclear staining of the oestrogen receptor and/or progesterone receptor. Based on the unsupervised clustering of miRs in the discovery cohort, separate analyses were performed with the BRCA1-mutation carrier samples (due to low numbers, combined from both the discovery and validation phase). Benign and malignant samples from BRCA1 carriers were compared to respectively wildtype benign and malignant samples of the validation cohort.

Statistics

All data were analysed with SPSS version 21 (IBM). To compare groups with numerical variables, the Mann–Whitney U test was used. The Fisher’s exact test was used to compare groups in 2×2 contingency tables. For 2×3 and 2×4 tables, the Freeman-Halton extension of the Fisher’s exact probability test was used. To correct for multiple comparisons P-values were adjusted for type I errors by using the Benjamini-Hochberg false discovery rate (FDR) method at a cut off of 10% [24]. All P-values are 2-sided and P < 0.05 was considered statistically significant.

CONCLUSIONS

With hsa-miR-652-5p showing promising results as a potential early breast cancer biomarker and multiple studies showing discriminative blood-born miR expression for the detection of breast cancer, future research should focus on validating previously detected miRs and preferably miR-signatures in cohorts representative of the screening population. This could lead to sufficient validation of a miR-signature serving as biomarker and thereby enabling improved early breast cancer as well as early metastasis detection.

Abbreviations

FDR: False-Discovery Rate; FFPE: Formalin-Fixed Paraffin-Embedded; HER2: Human Epidermal growth factor Receptor 2; IQR: Interquartile Range; MIR: MicroRNA; MRNA: Messenger RNA; PCR: Polymerase Chain Reaction; RT-qPCR: Quantative Reverse Tran­scription PCR; TNBC: Triple Negative Breast Cancer.

Author contributions

The authors ML, SS, AS, MT, LK, and JM designed the study. Author MT included the patients and ML and SS gathered the patient data. Author ML, SS and AS drafted the manuscript. Measurements were performed by VW, RR-M and AS. Author MS performed the statistical analysis. All authors critically revised the manuscript for intellectual content. Author AS is guarantor of the study.

ACKNOWLEDGMENTS

The authors would like to thank the foundations: Stichting Physico Therapeutisch Instituut, ‘A Sister’s Hope’ and ‘Boezemvriendinnen’ for their financial support and their given trust in the research project.

CONFLICTS OF INTEREST

All authors declare to have no potential or actual conflicts of interest regarding the manuscript submitted.

FUNDING SUPPORT

The study was financially supported by the foundations: Stichting Physico Therapeutisch Instituut, ‘A Sister’s Hope’ and ‘Boezemvriendinnen’. Author AMS was funded through the cancer genomics Netherlands grant from the Netherlands organization of Scientific research (NWO). Funding was to finance the materials used to perform the analysis within the laboratory. No funding was used for generating the research question and study design, interpretation of the data or the writing of the manuscript.

REFERENCES

1. Saadatmand S, Bretveld R, Siesling S, Tilanus-Linthorst MM. Influence of tumour stage at breast cancer detection on survival in modern times: population based study in 173 797 patients. BMJ. 2015; 351:h4901.

2. Boyd NF, Guo H, Martin LJ, Sun L, Stone J, Fishell E, Jong RA, Hislop G, Chiarelli A, Minkin S, Yaffe MJ. Mammographic density and the risk and detection of breast cancer. N Engl J Med. 2007; 356:227–236.

3. Fracheboud J. vLPA, Sankatsing VDV, Ripping TM, Broeders MJM, van Ineveld BM, Heijnsdijk EAM, Verbeek ALM, Holland R, den Heeten GJ, de Bruijn A.E, de Koning HJ. National evaluation of breast cancer screening in the Netherlands 1990-2011/2012. http://wwwerasmusmcnl/public-health/publications-collaborations/reports/evaluatie-borstkanker/pdf/.

4. Liang W, Lawrence WF, Burnett CB, Hwang YT, Freedman M, Trock BJ, Mandelblatt JS, Lippman ME. Acceptability of diagnostic tests for breast cancer. Breast Cancer Res Treat. 2003; 79:199–206.

5. Iorio MV, Casalini P, Tagliabue E, Menard S, Croce CM. MicroRNA profiling as a tool to understand prognosis, therapy response and resistance in breast cancer. Eur J Cancer. 2008; 44:2753–2759.

6. Vasudevan S, Tong Y, Steitz JA. Switching from repression to activation: microRNAs can up-regulate translation. Science. 2007; 318:1931–1934.

7. Mostert B, Sieuwerts AM, Martens JW, Sleijfer S. Diagnostic applications of cell-free and circulating tumor cell-associated miRNAs in cancer patients. Expert Rev Mol Diagn. 2011; 11:259–275.

8. van Schooneveld E, Wouters MC, Van der Auwera I, Peeters DJ, Wildiers H, Van Dam PA, Vergote I, Vermeulen PB, Dirix LY, Van Laere SJ. Expression profiling of cancerous and normal breast tissues identifies microRNAs that are differentially expressed in serum from patients with (metastatic) breast cancer and healthy volunteers. Breast Cancer Res. 2012; 14:R34.

9. Zhu W, Qin W, Atasoy U, Sauter ER. Circulating microRNAs in breast cancer and healthy subjects. BMC Res Notes. 2009; 2:89.

10. Iorio MV, Ferracin M, Liu CG, Veronese A, Spizzo R, Sabbioni S, Magri E, Pedriali M, Fabbri M, Campiglio M, Menard S, Palazzo JP, Rosenberg A, et al. MicroRNA gene expression deregulation in human breast cancer. Cancer Res. 2005; 65:7065–7070.

11. Rodriguez-Gonzalez FG, Sieuwerts AM, Smid M, Look MP, Meijer-van Gelder ME, de Weerd V, Sleijfer S, Martens JW, Foekens JA. MicroRNA-30c expression level is an independent predictor of clinical benefit of endocrine therapy in advanced estrogen receptor positive breast cancer. Breast Cancer Res Treat. 2011; 127:43–51.

12. Foekens JA, Sieuwerts AM, Smid M, Look MP, de Weerd V, Boersma AW, Klijn JG, Wiemer EA, Martens JW. Four miRNAs associated with aggressiveness of lymph node-negative, estrogen receptor-positive human breast cancer. Proc Natl Acad Sci U S A. 2008; 105:13021–13026.

13. Shao Y, Geng Y, Gu W, Huang J, Pei H, Jiang J. Prognostic role of tissue and circulating microRNA-200c in malignant tumors: a systematic review and meta-analysis. Cell Physiol Biochem. 2015; 35:1188–1200.

14. Sieuwerts AM, Mostert B, Bolt-de Vries J, Peeters D, de Jongh FE, Stouthard JM, Dirix LY, van Dam PA, Van Galen A, de Weerd V, Kraan J, van der Spoel P, Ramirez-Moreno R, et al. mRNA and microRNA expression profiles in circulating tumor cells and primary tumors of metastatic breast cancer patients. Clin Cancer Res. 2011; 17:3600–3618.

15. Si H, Sun X, Chen Y, Cao Y, Chen S, Wang H, Hu C. Circulating microRNA-92a and microRNA-21 as novel minimally invasive biomarkers for primary breast cancer. J Cancer Res Clin Oncol. 2013; 139:223–229.

16. Kleivi Sahlberg K, Bottai G, Naume B, Burwinkel B, Calin GA, Borresen-Dale AL, Santarpia L. A serum microRNA signature predicts tumor relapse and survival in triple-negative breast cancer patients. Clin Cancer Res. 2015; 21:1207–1214.

17. Chan M, Liaw CS, Ji SM, Tan HH, Wong CY, Thike AA, Tan PH, Ho GH, Lee AS. Identification of circulating microRNA signatures for breast cancer detection. Clin Cancer Res. 2013; 19:4477–4487.

18. Heneghan HM, Miller N, Kelly R, Newell J, Kerin MJ. Systemic miRNA-195 differentiates breast cancer from other malignancies and is a potential biomarker for detecting noninvasive and early stage disease. Oncologist. 2010; 15:673–682.

19. Madhavan D, Zucknick M, Wallwiener M, Cuk K, Modugno C, Scharpff M, Schott S, Heil J, Turchinovich A, Yang R, Benner A, Riethdorf S, Trumpp A, et al. Circulating miRNAs as surrogate markers for circulating tumor cells and prognostic markers in metastatic breast cancer. Clin Cancer Res. 2012; 18:5972–5982.

20. Schrauder MG, Strick R, Schulz-Wendtland R, Strissel PL, Kahmann L, Loehberg CR, Lux MP, Jud SM, Hartmann A, Hein A, Bayer CM, Bani MR, Richter S, et al. Circulating micro-RNAs as potential blood-based markers for early stage breast cancer detection. PLoS One. 2012; 7:e29770.

21. Li L, Guo Y, Chen Y, Wang J, Zhen L, Guo X, Liu J, Jing C. The Diagnostic Efficacy and Biological Effects of microRNA-29b for Colon Cancer. Technol Cancer Res Treat. 2016; 15:772–779.

22. Blondal T, Jensby Nielsen S, Baker A, Andreasen D, Mouritzen P, Wrang Teilum M, Dahlsveen IK. Assessing sample and miRNA profile quality in serum and plasma or other biofluids. Methods. 2013; 59:S1–6.

23. Sieuwerts AM, Kraan J, Bolt-de Vries J, van der Spoel P, Mostert B, Martens JW, Gratama JW, Sleijfer S, Foekens JA. Molecular characterization of circulating tumor cells in large quantities of contaminating leukocytes by a multiplex real-time PCR. Breast Cancer Res Treat. 2009; 118:455–468.

24. Hochberg Y, Benjamini Y. More powerful procedures for multiple significance testing. Stat Med. 1990; 9:811–818.

25. Shimomura A, Shiino S, Kawauchi J, Takizawa S, Sakamoto H, Matsuzaki J, Ono M, Takeshita F, Niida S, Shimizu C, Fujiwara Y, Kinoshita T, Tamura K, et al. Novel combination of serum microRNA for detecting breast cancer in the early stage. Cancer Sci. 2016; 107:326–334.

26. McDermott AM, Miller N, Wall D, Martyn LM, Ball G, Sweeney KJ, Kerin MJ. Identification and validation of oncologic miRNA biomarkers for luminal A-like breast cancer. PLoS One. 2014; 9:e87032.

27. Cuk K, Zucknick M, Madhavan D, Schott S, Golatta M, Heil J, Marme F, Turchinovich A, Sinn P, Sohn C, Junkermann H, Schneeweiss A, Burwinkel B. Plasma microRNA panel for minimally invasive detection of breast cancer. PLoS One. 2013; 8:e76729.

28. Joosse SA, Muller V, Steinbach B, Pantel K, Schwarzenbach H. Circulating cell-free cancer-testis MAGE-A RNA, BORIS RNA, let-7b and miR-202 in the blood of patients with breast cancer and benign breast diseases. Br J Cancer. 2014; 111:909–917.

29. Freres P, Wenric S, Boukerroucha M, Fasquelle C, Thiry J, Bovy N, Struman I, Geurts P, Collignon J, Schroeder H, Kridelka F, Lifrange E, Jossa V, et al. Circulating microRNA-based screening tool for breast cancer. Oncotarget. 2016; 7:5416–5428. https://doi.org/10.18632/oncotarget.6786.

30. Wang G, Wang L, Sun S, Wu J, Wang Q. Quantitative measurement of serum microRNA-21 expression in relation to breast cancer metastasis in Chinese females. Ann Lab Med. 2015; 35:226–232.

31. Shaker O, Maher M, Nassar Y, Morcos G, Gad Z. Role of microRNAs -29b-2, -155, -197 and -205 as diagnostic biomarkers in serum of breast cancer females. Gene. 2015; 560:77–82.

32. Erturk E, Cecener G, Egeli U, Tunca B, Tezcan G, Gokgoz S, Tolunay S, Tasdelen I. Expression status of let-7a and miR-335 among breast tumors in patients with and without germ-line BRCA mutations. Mol Cell Biochem. 2014; 395:77–88.

33. Erturk E, Cecener G, Tezcan G, Egeli U, Tunca B, Gokgoz S, Tolunay S, Tasdelen I. BRCA mutations cause reduction in miR-200c expression in triple negative breast cancer. Gene. 2015; 556:163–169.