Plasma miR-1273g-3p acts as a potential biomarker for early Breast Ductal Cancer diagnosis

Guo, Huan; Zeng, Xiangting; Li, Haining; Guo, Yanxiang; Wang, Tao; Guo, Hongyun; Zhu, Gongjian; Wang, Lan; Zhou, Haihong; Liu, Kedan; Chen, Xiaoyi; Wang, Haitao; Zhao, Xinke; Su, Haixiang; Li, Yingdong

doi:10.1590/0001-3765202020181203

Abstract

Circulating miRNAs presenting in plasma in a stable manner have been demonstrated their potential role as a promising biomarkers in many human diseases, such as Alzheimer’s disease, melanoma and ovarian carcinoma. However, few circulating miRNAs could be used for breast ductal cancer diagnosis. Here, we identified miR-1273g-3p as a biomarker for detecting breast ductal cancer. We detected miR-1273g-3p levels in the plasma of 39 sporadic breast ductal cancer patients and 40 healthy donors by Stem-loop Quantitative Real-time PCR (qRT-PCR). The results showed the plasma miR-1273g-3p level were significantly up-regulated in breast ductal cancer patients compared with healthy donors (p=0.0139). Receiver operating characteristic (ROC) curve also revealed the significantly diagnostic ability of miR-1273g-3p in patients (p=0.0414). In addition, the plasma level of miR-1273g-3p was closely related to IIIB-IIIC TNM stage. We also confirmed the higher expression level of miR-1273g-3p in breast cancer cell lines MCF-7 (4.872±0.537) than normal breast cells (Hs 578Bst). Taken together, miR-1273g-3p could represent as a potential biomarker for early breast ductal cancer diagnosis.

Key words
breast ductal carcinoma; plasma; miR-1273g-3p; circulating miRNA; biomarker

INTRODUCTION

Breast cancer is the most frequently diagnosed cancer in any of the five continents (BidoBIDOLI E, VIRDONE S, HAMDI-CHERIF M, TOFFOLUTTI F, TABORELLI M, PANATO C & SERRAINO D. 2019. Worldwide Age at Onset of Female Breast Cancer: A 25-Year Population-Based Cancer Registry Study. Sci Rep 9: 14111. et al. 2019). A higher frequency of early onset female breast cancer has been observed in low income countries than in high income countries (Bidoli et al. 2019), such as some Arab or Asian countries. Chinese Cancer Society estimated that the incidence and mortality of female breast cancer in china is increasing from 2000 to 2011, especially in women younger than 45 years (ChenCHEN W, ZHENG R, BAADE PD, ZHANG S, ZENG H, BRAY F, JEMAL A, YU XQ & HE J. 2016. Cancer statistics in China, 2015. CA Cancer J Clin 66: 115-132. et al. 2016). Furthermore, breast cancer is also the leading cause of death in women younger than 45 years (Chen et al. 2016). The high mortality rate of breast cancer is due to rapid cancer cells proliferation and a great degree of malignancy, which has not been early detected and treated. Early detection of breast cancer can reduce the high mortality rate and improve treatment outcomes (ChatterjeeCHATTERJEE SK & ZETTER BR. 2005. Cancer biomarkers: knowing the present and predicting the future. Future Oncol 1: 37-50. and Zetter 2005). Conventional diagnostic method (including gold standard, mammography) is not adequately sensitive for early tumor detection (TorreTORRE LA, BRAY F, SIEGEL RL, FERLAY J, LORTET-TIEULENT J & JEMAL A. 2015. Global cancer statistics, 2012. CA Cancer J Clin 65: 87-108. et al. 2015, BleyerBLEYER A & WELCH HG. 2012. Effect of three decades of screening mammography on breast-cancer incidence. N Engl J Med 367: 1998-2005. & Welch 2012, WeigeltWEIGELT B, GEYER FC & REIS-FILHO JS. 2010. Histological types of breast cancer: how special are they? Mol Oncol 4: 192-208. et al. 2010, KalinichKALINICH M & HABER DA. 2018. Cancer detection: Seeking signals in blood. Science 359: 866-867. & Haber 2018). Therefore, finding new diagnostic methods, such as identification of plasma biomarkers of breast cancer could serve as non-invasive biomarkers to prolong patient survival.

Currently, small non-coding RNAs (microRNAs) have opened a new avenue for early cancer diagnosis (CalinCALIN GA & CROCE CM. 2006. MicroRNA signatures in human cancers. Nat Rev Cancer 6: 857. & Croce 2006). MicroRNAs (miRNAs) are short, 18-24 nucleotide noncoding RNAs, which could regulate gene expression by binding to 3’-untranslated region (3’-UTR) of messenger RNAs (mRNAs) (EulalioEULALIO A, HUNTZINGER E & IZAURRALDE E. 2008. Getting to the root of miRNA-mediated gene silencing. Cell 132: 9-14. et al. 2008) and protein-coding exons regions (FormanFORMAN JJ, LEGESSE-MILLER A & COLLER HA. 2008. A search for conserved sequences in coding regions reveals that the let-7 microRNA targets Dicer within its coding sequence. Proc Natl Acad Sci USA 105: 14879-14884. et al. 2008, HausserHAUSSER J, LANDTHALER M, JASKIEWICZ L, GAIDATZIS D & ZAVOLAN M. 2009. Relative contribution of sequence and structure features to the mRNA binding of Argonaute/EIF2C-miRNA complexes and the degradation of miRNA targets. Genome Res 19: 2009-2020. et al. 2009, HendricksonHENDRICKSON DG, HOGAN DJ, MCCULLOUGH HL, MYERS JW, HERSCHLAG D, FERRELL JE & BROWN PO. 2009. Concordant regulation of translation and mRNA abundance for hundreds of targets of a human microRNA. PLoS Biology 7: e1000238. et al. 2009) leading to the inhibition of mRNAs translation or mRNAs degradation. MiRNAs are involved in a broad range of biological processes including cell proliferation, development, apoptosis, and cancer progress as well (HamamHAMAM R, HAMAM D, ALSALEH KA, KASSEM M, ZAHER W, ALFAYEZ M, ALDAHMASH A & ALAJEZ NM. 2017. Circulating microRNAs in breast cancer: novel diagnostic and prognostic biomarkers. Cell Death Dis 8: e3045. et al. 2017). Recent studies have reported that miRNAs were released into the blood circulation by various cell physiological events under both normal and pathological conditions (Chen et al. 2012). Compared with normal donors, the expression profiles of miRNAs in malignant tumors are different, and different stage of tumors have different expression profiles. The miRNAs that released into plasma or serum can be protected from endogenous RNase activity (SchwarzenbachSCHWARZENBACH H. 2017. Clinical Relevance of Circulating, Cell-Free and Exosomal microRNAs in Plasma and Serum of Breast Cancer Patients. Oncol Res Treat 40: 423-429. 2017, Schwarzenbach et al. 2014). Moreover, plasma miRNA profiles of cancer with high sensitivity and specificity could reflect disease development, tumor load, malignant progression towards metastasis (Calin et al. 2004). Several studies have demonstrated that circulating miRNAs in plasma or serum are stable and detectable, and the levels of circulating miRNAs specifically elevated in the patients with lung cancer(ChoCHO WC. 2012. [Promises and challenges in developing MiRNA as a molecular diagnostic tool for lung cancer]. Zhongguo fei ai za zhi = Chinese Journal of Lung Cancer 15: C1-3. 2012), colorectal cancer (YuanYUAN Z et al. 2017. Dynamic plasma microRNAs are biomarkers for prognosis and early detection of recurrence in colorectal cancer. Br J Cancer 117: 1202-1210. et al. 2017), gastric cancer, (KonishiKONISHI H et al. 2012. Detection of gastric cancer-associated microRNAs on microRNA microarray comparing pre- and post-operative plasma. Br J Cancer 106: 740-747. et al. 2012) breast cancer (HannafonHANNAFON BN, TRIGOSO YD, CALLOWAY CL, ZHAO YD, LUM DH, WELM AL, ZHAO ZJ, BLICK KE, DOOLEY WC & DING WQ. 2016. Plasma exosome microRNAs are indicative of breast cancer. Brest Cancer Res: BCR 18: 90. et al. 2016, CukCUK K et al. 2013. Circulating microRNAs in plasma as early detection markers for breast cancer. Int J Cancer 132: 1602-1612. et al. 2013). Therefore, plasma miRNAs are promising biomarkers for the early and minimally invasive diagnosis of breast ductal cancer (MitchellMITCHELL PS et al. 2008. Circulating microRNAs as s blood-based markers for cancer detection. Proc Natl Acad Sci USA 105: 10513-10518. et al. 2008). The assessment of plasma miRNAs disregulation may serve as an additional tool for breast cancer detection following by mammography screening and core needle biopsy.

To date, several studies explored circulating miRNAs as breast cancer indicators (Li et al. 2018, BertoliBERTOLI G, CAVA C & CASTIGLIONI I. 2015. MicroRNAs: New Biomarkers for Diagnosis, Prognosis, Therapy Prediction and Therapeutic Tools for Breast Cancer. Theranostics 5: 1122-1143. et al. 2015). However, the correlations between circulating miR-1273g-3p levels and breast cancer have not been identified. In this study, we detected that the plasma miR-1273g-3p level were significantly up-regulated in breast ductal cancer patients compared with healthy donors (p=0.0139). Receiver operating characteristic (ROC) curve also revealed the significantly diagnostic ability of miR-1273g-3p in patients (p=0.0414). In addition, the plasma level of miR-1273g-3p was closely related to IIIB-IIIC TNM stage. We also confirmed the higher expression level of miR-1273g-3p in breast cancer cell lines MCF-7 (4.872±0.537) than normal breast cells (Hs 578Bst). Taken together, miR-1273g-3p could represent as a promising candidate biomarker for early breast ductal cancer diagnosis.

MATERIALS AND METHODS

Study population

Blood samples were collected between 2015 and 2016 from patient at first clinic diagnosis from Gansu Province Cancer Hospital. All patients (n=39) and healthy controls (n=40) were Han women from Gansu province, China. All the patients had never got any surgery, radiation or systemic therapeutic procedures. For patients, the surgical resection tumor specimens were confirmed through histopathologic analysis and the tumor stage was determined according to the tumor-node-metastasis (TNM) system. Healthy control blood samples were collected from healthy women donors with no history of malignant diseases, no blood donations received in the previous 3 years and no current inﬂammatory condition. Patients’ clinical outcomes were listed in Table I. This study was approved by the Ethical Committee (the certificate number: A201503180009, Date: 03-18-2015) of Gansu Province Cancer Hospital in Lan Zhou, China. Written informed consent was obtained from all participants involved in this study.

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Table I
Clinical characteristics of the healthy volunteers, breast ductal cancer patients and pathological characteristics of breast ductal cancers in the discovery and validation cohorts.

Plasma samples

Blood samples were withdrawn in EDTA tubes and processed within 2 hours. Plasma were separated after twice centrifugation at 4°C (1000g for 10 minutes and 12000g for 10minutes) and stored at -80°C.

RNA extraction

Total RNA containing small RNA was extracted from 400µl plasma using miRVanaTM RNA Isolation Kit AM1561(Invitrogen, ThermoFisher scientific, CA, USA) according to the manufacturer’s instructions with a minor modification: 25 fmol of a C. elegans miR-39 (Cel-miR-39) was spiked-in of validation participants and eluted with 30 µl of nuclease free water. The concentration of all RNA samples were quantified by NanoDrop ND-2000 (Thermo scientific, CA, USA).

MiRNA quantification

Stem-loop Quantitative Real-time PCR (qRT-PCR) assay was used for miRNAs validation. In brief, miRNAs were transcribed to cDNA using the SuperScript™ III Reverse Transcriptase kit (Invitrogen, ThermoFisher scientific, CA, USA) and Bulge-loopTM miRNA RT primer (Bulge-loopTM miRNA qRT-PCR Primer Sets: one specific RT primer and a pair of qPCR primers for each set) specific for miRNA purchased from RiboBio (Guangzhou RiboBio Co., Guangzhou, China). Then, qRT-PCR was performed on QuantstudioTM 12k Flex Real-Time PCR system (Applied Biosystems, ThermoFisher scientific, CA, USA). The reaction was performed at 95 °C for 2 min, followed by 40 cycles at 95 °C for 15 s, 60 °C for 30 s and 72 °C 15 s, and then ramped from 65 °C to 95 °C to obtain the melting curve. Each sample was run in duplicates for analysis. The relative expression level of miRNA was normalized to Cel-miR-39, and fold change of miRNA was calculated by the 2-Δ Δ C^t method.

Target prediction

The potential target genes of miR-1273g-3p were predicted by PicTar (http://pictar.mdc-berlin.de/cgi-bin/PicTar_vertebrate.cgi), TargetScan7.1 (http://www.targetscan.org/) and microT-CDS (http://www.microrna.gr/microT-CDS). Considering that the predictn programs often suffer from high false positive rates, only the target genes predicted by both tools were taken into account.

Gene ontology (GO) term analysis of target genes

In order to infer the potential functions of the differentially expressed miRNAs, the functional analysis of their target genes was analyzed by Shanghai OE Biotech Technology Co, Ltd.(Shanghai, China). Functional categories were clustered using the Functional Annotation Clustering tool, and representative GO categories and KEGG pathways from each clustered set with a p-value<0.05 were selected and taken into consideration for further analysis.

Cell culture

Cell lines were purchased from ATCC. Hs 578Bst is breast normal cell. MDA-MB-231, MCF-7, T47-D, ZR-75-1 are breast cancer cell. Hs 578Bst and MDA-MB-231 were cultured in RPMI complete medium (RPMI/10% FCS/1% Sodium pyruvate/2mM L-glutamine/PenStrep). MCF-7, T47-D, ZR-75-1 were grown in DMEM complete medium (DMEM/10% FCS/2mM L-glutamine/PenStrep). Cells were maintained in an incubator with 5% CO₂, 21% O₂ at 37 °C.

Statistical Analysis

All statistical calculations were performed by GraphPad PRISM 7 software (GraphPad Software, CA, USA). The significance of plasma miRNA levels was determined by Mann-Whitney test, χ²-test or Kruskal–Wallis test where appropriate. ROC curve were established for determine the diagnostic value of miRNAs. All p-values are two-tailed and less than 0.05 was considered to be statistically significant.

RESULTS

Clinical characteristics of patients

The clinical characteristics and the pathology of the breast ductal cancer patients were summarized in Table I. Plasma samples from 39 patients and 40 healthy controls were used for this study. There were no significant differences in age between patients and healthy controls (49.91±9.795 vs 49.23±8.529, p=0.7369). All cases were histologically confirmed as ductal carcinoma of the breast with a tumor size ranging from 0.15 to 4.0 cm. Of the 39 patients with tumor ≤2 cm were 23.08% (n=9) and tumor >2 cm were 76.92% (n=30). For TNM stage in 39 patients, 33.33% were TNM stage I-IIa (n=13), 51.28% TNM stage IIb-IIIa (n=20) and 15.39% TNM stage IIIb-IIIc (n=6). 13 patients were ER-negative (33.33%) and 26 patients were ER-positive (66.67%). 21 patients were PR-negative (53.85%) and 18 patients were PR-positive (46.18%). 31 patients were Her2-negative (79.49%) and 8 patients were Her2-positive (20.51%). 8 patients were Ki67-negative (20.51%) and 31 patients were Ki67-positive (79.49%). 21 patients were P53-negative (53.85%) and 18 patients were P53-positive (46.15%). 20 patients were lymph node metastasis-negative (51.28%) and 19 patients were lymph node metastasis-negative-positive (48.72%).

Validation of miRNAs in Breast Ductal Cancer plasma

To identify the miRNAs candidates as biomarker in breast ductal cancer plasma, plasma levels of miR-21-5p and miR-1273g-3p were measured by Stem-loop qRT-PCR assays. The results showed that miR-21-5p (p=0.0043) and miR-1273g-3p (p=0.0139) in the plasma of patients had higher expression than healthy control (Fig. 1a).

Figure 1
Validation of miRNAs in breast ductal cancer and healthy controls (n = 79). (a) Box plot of plasma levels of miR-21-5p and miR-1273g-3p in breast cancer ductal patients. The expression of miRNAs was normalised to cel-miR-39. The lines inside the boxes represent the medians. The boxes mark the interval between the 25th and 75th percentiles. The whiskers denote the interval between the 10th and 90th percentiles. Statistically significant differences were determined using Mann–Whitney tests. (b) Receiver-operator characteristics (ROC) curve analysis of miRNAs to discriminate BC patients from healthy controls. *p<0.05.

Evaluate the diagnostic value for miRNAs

To further verify the discriminating power of two miRNAs for breast ductal cancer diagnosis, receiver operating characteristic (ROC) curve analysis was performed. The area under cure (AUC) closer to 1 reflected more substantial differences between breast cancer and healthy control. ROC analysis of miR-21-5p (AUC=0.6583, 95% CI: 0.5345-0.7822, p=0.0154) and miR-1273g-3p (AUC=0.6333, 95% CI: 0.5114-0.7552, p=0.0414) were shown in Fig. 1b. Although miR-21-5p and miR-1273g-3p alone generated satisfactory ROC values, the AUC value was not elevated when the two miRNAs were combined (Fig. 1b).

The relationship between plasma miRNAs levels and clinical features

To determine if two plasma miRNAs level were associated with clinical features, patients were stratified (Table II). We found there were no differences of two miRNA levels among tumor size, ER status, PR status, Her2 status, Ki67, P53 and Lymph node metastasis. The plasma levels of miR-21-5p, miR-1273g-3p in breast ductal cancer patients at different TNM stages were also evaluated to determine if the plasma miRNAs could be detected in breast ductal cancer (Fig. 2a). Patients with high miR-21-5p expression were associated with high risk of breast malignancy compared to those with low miR-21-5p expression profiles (Stage IIb-IIIa vs healthy control, p=0.0012; Stage IIIb-IIIC vs healthy control, p=0.0168, stage IIb-IIIa vs stage I-IIa, p=0.0127, stage IIIb-IIIc vs stage I-IIa, p=0.0365). While compared stage I-IIa patient with healthy control, miR-21-5p expression showed no significant difference (p=0.5741). The plasma miR-1273g-3p showed marked difference when stage IIIb-IIIc compare with healthy control (p=0.0392) (Fig. 2b).

Figure 2
Association of miRNAs expression with tumor stage. Plasma miR-21-5p (a) and miR-1273g-3p (b) expression in BC patients were stratified by TMN stage and had statistical significance with normal controls. *p<0.05, **p<0.01. The lines inside the plots represent the medians. Statistically significant differences were determined using Mann–Whitney tests.

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Table II
Correlation of the expression of plasma miRNA with clinicopathologic features.

Gene ontology (GO) term analysis of miR-1273g-3p

To address how functions and pathways could be affected by the complex interactions between the miRNAs and their target genes, we inferred the functions of miRNAs from their target genes. The functional analysis showed that miR-1273g-3p target genes were involved in a variety of positive regulation processes, such as protein complex assembly, phosphatidylinositol-mediated signaling, regulation of gene expression, Wnt signaling pathway, regulation of transcription and DNA-templated (Fig. 3a). Further analysis found that the target genes of miR-1273g-3p were enriched in the pathways related to cancer, Hippo signaling pathway (Fig. 3b). These results indicate that miR-1273g-3p may play a key role in carcinogenesis by regulating various biological processes. For detailed functional analysis of the miRNA in breast ductal cancer will be studied in the future.

Figure 3
Biological Process GO terms (a) and KEGG pathways (b) enriched in the target genes of miR-1273g-3p.

Cell expression of miR-1273g-3p

To test the level of miR-1273g-3p expression, we examined the miRNA expression in MCF-7, T47-D, ZR-75-1 and MDA-MB-231 cells. The results revealed relative high expression of miR-1273g-3p in MCF-7 (4.872±0.537) and in ZR-75-1 (1.551±0.410) cell, but low expression in T47-D (0.678±0.166) and in MDA-MB-231 (0.835±0.417) when compare with Hs 578Bst breast normal cell (Fig. 4).

Figure 4
Relative Expression of miR-1273g-3p in breast cancer cell lines.*** p<0.001.

DISCUSSION

According to the data from American Cancer Society, an estimated 252,710 cases of invasive breast cancer and an additional 63,420 new cases of in situ lesions of the breast were diagnosed in 2017, furthermore among them 40,610 patients would die from breast cancer (SiegelSIEGEL RL, MILLER KD & JEMAL A. 2017. Cancer Statistics, 2017. CA Cancer J Clin 67: 7-30. et al. 2017). In most cases, breast cancer is diagnosed after the symptoms, but in many cases the disease is already in advanced clinical stage when symptoms occur. Thus, early diagnosis plays a very important role to improve the survival rate and life quality for breast cancer patients. When early stage of cancer, there are many biological changes appearing in the body, some genes are over-expressed, while others are under-expressed. Therefore, identifying differentially expressed genes as an effective biological marker, which, the expression of these genes is stable and reliable, for early diagnosis of cancer is a promising direction for current cancer research.

MiRNAS is a class of small non-coding RNAs containing 22 nucleotides, which generally negatively regulate gene expression at the post-transcription stage. Recent studies revealed that miRNAs could have effect on cancer related processes, such as cell proliferation, differentiation and apoptosis(JanssonJANSSON MD & LUND AH. 2012. MicroRNA and cancer. Mol Oncol 6: 590-610. and Lund 2012). Consequently, many researchers using circulating miRNAs as cancer biomarkers are being carried out widely. In recent years, there is a great deal of studies demonstrated the genetic association between miRNAs and cancer, including lung cancer (HuHU L, AI J, LONG H, LIU W, WANG X, ZUO Y, LI Y, WU Q & DENG Y. 2016. Integrative microRNA and gene profiling data analysis reveals novel biomarkers and mechanisms for lung cancer. Oncotarget 7: 8441-8454. et al. 2016) colorectal cancer (SchetterSCHETTER AJ & HARRIS CC. 2009. Plasma microRNAs: a potential biomarker for colorectal cancer? Gut 58: 1318-1319. and Harris 2009) and breast cancer(TakahashiTAKAHASHI RU, MIYAZAKI H & OCHIYA T. 2015. The Roles of MicroRNAs in Breast Cancer. Cancers (Basel) 7: 598-616. et al. 2015, KurozumiKUROZUMI S, YAMAGUCHI Y, KUROSUMI M, OHIRA M, MATSUMOTO H & HORIGUCHI J. 2017. Recent trends in microRNA research into breast cancer with particular focus on the associations between microRNAs and intrinsic subtypes. J Hum Genet 62: 15-24. et al. 2017). Several previous studies have demonstrated the value of plasma/serum miRNA in breast cancer diagnosis (LagendijkLAGENDIJK M, SADAATMAND S, KOPPERT LB, TILANUS-LINTHORST MMA, DE WEERD V, RAMIREZ-MORENO R, SMID M, SIEUWERTS AM & MARTENS JWM. 2018. MicroRNA expression in pre-treatment plasma of patients with benign breast diseases and breast cancer. Oncotarget 9: 24335-24346. et al. 2018, Khodadadi-JamayranKHODADADI-JAMAYRAN A et al. 2018. Prognostic role of elevated mir-24-3p in breast cancer and its association with the metastatic process. Oncotarget 9: 12868-12878. et al. 2018, Li et al. 2017, SouzaSOUZA KCB et al. 2019. Identification of Cell-Free Circulating MicroRNAs for the Detection of Early Breast Cancer and Molecular Subtyping. J Oncol 2019: 8393769. et al. 2019). MiR-21 is involved in regulating the expression of multiple tumor suppressor genes, and plays a crucial role in the occurrence and development of a variety of diseases (FoliniFOLINI M et al. 2010. miR-21: an oncomir on strike in prostate cancer. Mol Cancer 9: 12. et al. 2010, Peralta-ZaragozaPERALTA-ZARAGOZA O et al. 2016. Relevance of miR-21 in regulation of tumor suppressor gene PTEN in human cervical cancer cells. BMC Cancer 16: 215. et al. 2016). MatamalaMATAMALA N et al. 2015. Tumor microRNA expression profiling identifies circulating microRNAs for early breast cancer detection. Clin Chem 61: 1098-1106. et al. (2015) reported that miR-21 had significantly higher expression in circulating of breast carcinoma patients compared to healthy donors. A plurality of studies have shown that up-regulation of miR-21 was detected in blood (Alunni-FabbroniALUNNI-FABBRONI M et al. 2018. Whole blood microRNAs as potential biomarkers in post-operative early breast cancer patients. BMC Cancer 18: 141. et al. 2018), and that plasma miR-21 could be used as a non-invasive biomarker for breast cancer diagnosis, as well as an indicator for tumor invasiveness (Hannafon et al. 2016). Our results were consist with previous study. Therefore, miR-21 is a promising biomarker for breast cancer diagnosis in clinics. However, breast cancer is a very complicated disease according to their clinical characteristics. Identifying new miRNAs as biomarkers are urgent need for breast cancer diagnosis. In our study, we found miR-1273g-3p is an important regulator in breast cancer cell proliferation (data not shown), and we also focus on the capacity of miR-1273g-3p as biomarker.

Currently, little is known about the functional role of miR-1273g-3p in breast cancer. MiR-1273g-3p located on chromosome 1 at 1p32.3, is a member of the miR-1273 family. MiR-1273 consists of miR-1273a, miR-1273c, miR-1273d, miR-1273e, miR-1273f, miR-1273g-3p, miR-1273g-5p, miR-1273h-3p and miR-1273h-5p (IvashchenkoIVASHCHENKO A, BERILLO O, PYRKOVA A & NIYAZOVA R. 2014. Binding sites of miR-1273 family on the mRNA of target genes. Biomed Res Int 2014: 620530. et al. 2014). GuoGUO J, SANG Y, YIN T, WANG B, YANG W, LI X, LI H & KANG Y. 2016. miR-1273g-3p participates in acute glucose fluctuation-induced autophagy, dysfunction, and proliferation attenuation in human umbilical vein endothelial cells. Am J Physiol Endocrinol Metab 310: E734-743. and his colleagues found that miR-1273g-3p participates in acute glucose fluctuation-induced autophagy, dysfunction, and proliferation attenuation in human umbilical vein endothelial cells (Guo et al. 2016). SahuSAHU I, HEBALKAR R, KAR S, TS S, GUTTI U & GUTTI RK. 2018. Systems biology approach to study the role of miRNA in promoter targeting during megakaryopoiesis. Exp Cell Res 366: 192-198. and his colleagues found that miR-1273g-3p had a relationship with megakaryocyte differentiation (Sahu et al. 2018). NiuNIU X et al. 2016. miR-1273g-3p modulates activation and apoptosis of hepatic stellate cells by directly targeting PTEN in HCV-related liver fibrosis. FEBS Lett 590: 2709-2724. et al. (2016) found that miR-1273g-3p was the most significantly up-regulated miRNA and correlated with the stage of HCV-related liver fibrosis. FangFANG R, ZHU Y, HU L, KHADKA VS, AI J, ZOU H, JU D, JIANG B, DENG Y & HU X. 2018. Plasma MicroRNA Pair Panels as Novel Biomarkers for Detection of Early Stage Breast Cancer. Front Physiol 9: 1879. et.al using next generation sequencing technology detected that miRNA1273g/miRNA382 was up regulated in breast cancer plasma (Fang et al. 2018).

In this study, we identify miR-1273g-3p and miR-21-5p as a potential biomarker for breast cancer diagnosis by Stem-loop Quantitative Real-time PCR (qRT-PCR). Our results also confirmed the plasma miR-1273g-3p level were significantly up-regulated in breast ductal cancer patients compared with healthy donors (p=0.0139). However, miR-21-5p has been confirmed as a robust biomarker by many groups. It suggested that miR-1273g-3p has the same ability as miR-21-5p to distinct breast cancer from healthy person. Therefore, miR-1273g-3p could be a very promising candidate for breast ductal cancer diagnosis. However, the detection efficiency of breast cancer was not enhanced when we combined the two miRNAs into diagnostic panles.

Some researchers found that hsa-miR-1273g-3p regulates several significant genes (Niu et al. 2016, GaoGAO X, QIN T, MAO J, ZHANG J, FAN S, LU Y, SUN Z, ZHANG Q, SONG B & LI L. 2019. PTENP1/miR-20a/PTEN axis contributes to breast cancer progression by regulating PTEN via PI3K/AKT pathway. J Exp Clin Cancer Res 38: 256. et al. 2019). Phosphatase and tensin homolog deleted on chromosome ten (PTEN) was known as a tumor suppressor gene and are low expressed in hepatocellular cancer(QianQIAN YY, LI K, LIU QY & LIU ZS. 2017. Long non-coding RNA PTENP1 interacts with miR-193a-3p to suppress cell migration and invasion through the PTEN pathway in hepatocellular carcinoma. Oncotarget 8: 107859-107869. et al. 2017), gastric cancer (ZhangZHANG R, GUO Y, MA Z, MA G, XUE Q, LI F & LIU L. 2017. Long non-coding RNA PTENP1 functions as a ceRNA to modulate PTEN level by decoying miR-106b and miR-93 in gastric cancer. Oncotarget 8: 26079-26089. et al. 2017), and breast cancer (Gao et al. 2019). Over-expression of miR-1273g-3p could inhibit translation of PTEN, increase the expression of α-SMA, Col1A1, and reduce apoptosis in HSCs. As PTEN can modulated tumor progression via PI3K/AKT pathway is tightly correlated with breast cancer aggressiveness, stage and prognosis (Gao et al. 2019). Here, we make a preliminary infer that hsa-miR-1273g-3p maybe have effect on tumorigenesis and progress of breast cancer by regulating the expression of PTEN.(^{Figure S1 - Supplementary Material} SUPPLEMENTARY MATERIAL Figure S1. Relative expression of miR-1273g-3p and target gene PTEN. ).

In conclusion, we demonstrated that miR-1273g-3p is over-expressed and may contribute to promoting progression of breast cancer, the miR-1273g-3p may have potential utility as both prognostic and diagnostic biomarker.

ACKNOWLEGMENTS

This study was supported by a grant from Scientific Research Project of Health and Family Planning Commission of Gansu Province, China (Grant No.GSWSKY-2015-25). This research was supported by the Natural Science Foundation for Young Scientists through Gansu provincial Science and Technology Department, China (Grant No.17JR5RA042& No.1606RJYA296). This research was supported by Gansu science and technology program (Grant No.17JR3TA013) through Gansu provincial Science and Technology Department, China. The authors thank the patients and the healthy donors who participated in this study.

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CHATTERJEE SK & ZETTER BR. 2005. Cancer biomarkers: knowing the present and predicting the future. Future Oncol 1: 37-50.
CHEN W, ZHENG R, BAADE PD, ZHANG S, ZENG H, BRAY F, JEMAL A, YU XQ & HE J. 2016. Cancer statistics in China, 2015. CA Cancer J Clin 66: 115-132.
CHEN X, LIANG H, ZHANG J, ZEN K & ZHANG CY. 2012. Secreted microRNAs: a new form of intercellular communication. Trends Cell Biol 22: 125-132.
CHO WC. 2012. [Promises and challenges in developing MiRNA as a molecular diagnostic tool for lung cancer]. Zhongguo fei ai za zhi = Chinese Journal of Lung Cancer 15: C1-3.
CUK K et al. 2013. Circulating microRNAs in plasma as early detection markers for breast cancer. Int J Cancer 132: 1602-1612.
EULALIO A, HUNTZINGER E & IZAURRALDE E. 2008. Getting to the root of miRNA-mediated gene silencing. Cell 132: 9-14.
FANG R, ZHU Y, HU L, KHADKA VS, AI J, ZOU H, JU D, JIANG B, DENG Y & HU X. 2018. Plasma MicroRNA Pair Panels as Novel Biomarkers for Detection of Early Stage Breast Cancer. Front Physiol 9: 1879.
FOLINI M et al. 2010. miR-21: an oncomir on strike in prostate cancer. Mol Cancer 9: 12.
FORMAN JJ, LEGESSE-MILLER A & COLLER HA. 2008. A search for conserved sequences in coding regions reveals that the let-7 microRNA targets Dicer within its coding sequence. Proc Natl Acad Sci USA 105: 14879-14884.
GAO X, QIN T, MAO J, ZHANG J, FAN S, LU Y, SUN Z, ZHANG Q, SONG B & LI L. 2019. PTENP1/miR-20a/PTEN axis contributes to breast cancer progression by regulating PTEN via PI3K/AKT pathway. J Exp Clin Cancer Res 38: 256.
GUO J, SANG Y, YIN T, WANG B, YANG W, LI X, LI H & KANG Y. 2016. miR-1273g-3p participates in acute glucose fluctuation-induced autophagy, dysfunction, and proliferation attenuation in human umbilical vein endothelial cells. Am J Physiol Endocrinol Metab 310: E734-743.
HAMAM R, HAMAM D, ALSALEH KA, KASSEM M, ZAHER W, ALFAYEZ M, ALDAHMASH A & ALAJEZ NM. 2017. Circulating microRNAs in breast cancer: novel diagnostic and prognostic biomarkers. Cell Death Dis 8: e3045.
HANNAFON BN, TRIGOSO YD, CALLOWAY CL, ZHAO YD, LUM DH, WELM AL, ZHAO ZJ, BLICK KE, DOOLEY WC & DING WQ. 2016. Plasma exosome microRNAs are indicative of breast cancer. Brest Cancer Res: BCR 18: 90.
HAUSSER J, LANDTHALER M, JASKIEWICZ L, GAIDATZIS D & ZAVOLAN M. 2009. Relative contribution of sequence and structure features to the mRNA binding of Argonaute/EIF2C-miRNA complexes and the degradation of miRNA targets. Genome Res 19: 2009-2020.
HENDRICKSON DG, HOGAN DJ, MCCULLOUGH HL, MYERS JW, HERSCHLAG D, FERRELL JE & BROWN PO. 2009. Concordant regulation of translation and mRNA abundance for hundreds of targets of a human microRNA. PLoS Biology 7: e1000238.
HU L, AI J, LONG H, LIU W, WANG X, ZUO Y, LI Y, WU Q & DENG Y. 2016. Integrative microRNA and gene profiling data analysis reveals novel biomarkers and mechanisms for lung cancer. Oncotarget 7: 8441-8454.
IVASHCHENKO A, BERILLO O, PYRKOVA A & NIYAZOVA R. 2014. Binding sites of miR-1273 family on the mRNA of target genes. Biomed Res Int 2014: 620530.
JANSSON MD & LUND AH. 2012. MicroRNA and cancer. Mol Oncol 6: 590-610.
KALINICH M & HABER DA. 2018. Cancer detection: Seeking signals in blood. Science 359: 866-867.
KHODADADI-JAMAYRAN A et al. 2018. Prognostic role of elevated mir-24-3p in breast cancer and its association with the metastatic process. Oncotarget 9: 12868-12878.
KONISHI H et al. 2012. Detection of gastric cancer-associated microRNAs on microRNA microarray comparing pre- and post-operative plasma. Br J Cancer 106: 740-747.
KUROZUMI S, YAMAGUCHI Y, KUROSUMI M, OHIRA M, MATSUMOTO H & HORIGUCHI J. 2017. Recent trends in microRNA research into breast cancer with particular focus on the associations between microRNAs and intrinsic subtypes. J Hum Genet 62: 15-24.
LAGENDIJK M, SADAATMAND S, KOPPERT LB, TILANUS-LINTHORST MMA, DE WEERD V, RAMIREZ-MORENO R, SMID M, SIEUWERTS AM & MARTENS JWM. 2018. MicroRNA expression in pre-treatment plasma of patients with benign breast diseases and breast cancer. Oncotarget 9: 24335-24346.
LI HY et al. 2017. miR-105/93-3p promotes chemoresistance and circulating miR-105/93-3p acts as a diagnostic biomarker for triple negative breast cancer. Brest Cancer Res: BCR 19: 133.
LI M, ZHOU Y, XIA T, ZHOU X, HUANG Z, ZHANG H, ZHU W, DING Q & WANG S. 2018. Circulating microRNAs from the miR-106a-363 cluster on chromosome X as novel diagnostic biomarkers for breast cancer. Breast Cancer Res Treat 170: 257-270.
MATAMALA N et al. 2015. Tumor microRNA expression profiling identifies circulating microRNAs for early breast cancer detection. Clin Chem 61: 1098-1106.
MITCHELL PS et al. 2008. Circulating microRNAs as s blood-based markers for cancer detection. Proc Natl Acad Sci USA 105: 10513-10518.
NIU X et al. 2016. miR-1273g-3p modulates activation and apoptosis of hepatic stellate cells by directly targeting PTEN in HCV-related liver fibrosis. FEBS Lett 590: 2709-2724.
PERALTA-ZARAGOZA O et al. 2016. Relevance of miR-21 in regulation of tumor suppressor gene PTEN in human cervical cancer cells. BMC Cancer 16: 215.
QIAN YY, LI K, LIU QY & LIU ZS. 2017. Long non-coding RNA PTENP1 interacts with miR-193a-3p to suppress cell migration and invasion through the PTEN pathway in hepatocellular carcinoma. Oncotarget 8: 107859-107869.
SAHU I, HEBALKAR R, KAR S, TS S, GUTTI U & GUTTI RK. 2018. Systems biology approach to study the role of miRNA in promoter targeting during megakaryopoiesis. Exp Cell Res 366: 192-198.
SCHETTER AJ & HARRIS CC. 2009. Plasma microRNAs: a potential biomarker for colorectal cancer? Gut 58: 1318-1319.
SCHWARZENBACH H. 2017. Clinical Relevance of Circulating, Cell-Free and Exosomal microRNAs in Plasma and Serum of Breast Cancer Patients. Oncol Res Treat 40: 423-429.
SCHWARZENBACH H, NISHIDA N, CALIN GA & PANTEL K. 2014. Clinical relevance of circulating cell-free microRNAs in cancer. Nat Rev Clin Oncol 11: 145-156.
SIEGEL RL, MILLER KD & JEMAL A. 2017. Cancer Statistics, 2017. CA Cancer J Clin 67: 7-30.
SOUZA KCB et al. 2019. Identification of Cell-Free Circulating MicroRNAs for the Detection of Early Breast Cancer and Molecular Subtyping. J Oncol 2019: 8393769.
TAKAHASHI RU, MIYAZAKI H & OCHIYA T. 2015. The Roles of MicroRNAs in Breast Cancer. Cancers (Basel) 7: 598-616.
TORRE LA, BRAY F, SIEGEL RL, FERLAY J, LORTET-TIEULENT J & JEMAL A. 2015. Global cancer statistics, 2012. CA Cancer J Clin 65: 87-108.
WEIGELT B, GEYER FC & REIS-FILHO JS. 2010. Histological types of breast cancer: how special are they? Mol Oncol 4: 192-208.
YUAN Z et al. 2017. Dynamic plasma microRNAs are biomarkers for prognosis and early detection of recurrence in colorectal cancer. Br J Cancer 117: 1202-1210.
ZHANG R, GUO Y, MA Z, MA G, XUE Q, LI F & LIU L. 2017. Long non-coding RNA PTENP1 functions as a ceRNA to modulate PTEN level by decoying miR-106b and miR-93 in gastric cancer. Oncotarget 8: 26079-26089.

Publication Dates

Publication in this collection
22 Apr 2020
Date of issue
2020

History

Received
14 Nov 2018
Accepted
12 Nov 2019

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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[16] GAO X, QIN T, MAO J, ZHANG J, FAN S, LU Y, SUN Z, ZHANG Q, SONG B & LI L. 2019. PTENP1/miR-20a/PTEN axis contributes to breast cancer progression by regulating PTEN via PI3K/AKT pathway. J Exp Clin Cancer Res 38: 256.

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[18] HAMAM R, HAMAM D, ALSALEH KA, KASSEM M, ZAHER W, ALFAYEZ M, ALDAHMASH A & ALAJEZ NM. 2017. Circulating microRNAs in breast cancer: novel diagnostic and prognostic biomarkers. Cell Death Dis 8: e3045.

[19] HANNAFON BN, TRIGOSO YD, CALLOWAY CL, ZHAO YD, LUM DH, WELM AL, ZHAO ZJ, BLICK KE, DOOLEY WC & DING WQ. 2016. Plasma exosome microRNAs are indicative of breast cancer. Brest Cancer Res: BCR 18: 90.

[20] HAUSSER J, LANDTHALER M, JASKIEWICZ L, GAIDATZIS D & ZAVOLAN M. 2009. Relative contribution of sequence and structure features to the mRNA binding of Argonaute/EIF2C-miRNA complexes and the degradation of miRNA targets. Genome Res 19: 2009-2020.

[21] HENDRICKSON DG, HOGAN DJ, MCCULLOUGH HL, MYERS JW, HERSCHLAG D, FERRELL JE & BROWN PO. 2009. Concordant regulation of translation and mRNA abundance for hundreds of targets of a human microRNA. PLoS Biology 7: e1000238.

[22] HU L, AI J, LONG H, LIU W, WANG X, ZUO Y, LI Y, WU Q & DENG Y. 2016. Integrative microRNA and gene profiling data analysis reveals novel biomarkers and mechanisms for lung cancer. Oncotarget 7: 8441-8454.

[23] IVASHCHENKO A, BERILLO O, PYRKOVA A & NIYAZOVA R. 2014. Binding sites of miR-1273 family on the mRNA of target genes. Biomed Res Int 2014: 620530.

[24] JANSSON MD & LUND AH. 2012. MicroRNA and cancer. Mol Oncol 6: 590-610.

[25] KALINICH M & HABER DA. 2018. Cancer detection: Seeking signals in blood. Science 359: 866-867.

[26] KHODADADI-JAMAYRAN A et al. 2018. Prognostic role of elevated mir-24-3p in breast cancer and its association with the metastatic process. Oncotarget 9: 12868-12878.

[27] KONISHI H et al. 2012. Detection of gastric cancer-associated microRNAs on microRNA microarray comparing pre- and post-operative plasma. Br J Cancer 106: 740-747.

[28] KUROZUMI S, YAMAGUCHI Y, KUROSUMI M, OHIRA M, MATSUMOTO H & HORIGUCHI J. 2017. Recent trends in microRNA research into breast cancer with particular focus on the associations between microRNAs and intrinsic subtypes. J Hum Genet 62: 15-24.

[29] LAGENDIJK M, SADAATMAND S, KOPPERT LB, TILANUS-LINTHORST MMA, DE WEERD V, RAMIREZ-MORENO R, SMID M, SIEUWERTS AM & MARTENS JWM. 2018. MicroRNA expression in pre-treatment plasma of patients with benign breast diseases and breast cancer. Oncotarget 9: 24335-24346.

[30] LI HY et al. 2017. miR-105/93-3p promotes chemoresistance and circulating miR-105/93-3p acts as a diagnostic biomarker for triple negative breast cancer. Brest Cancer Res: BCR 19: 133.

[31] LI M, ZHOU Y, XIA T, ZHOU X, HUANG Z, ZHANG H, ZHU W, DING Q & WANG S. 2018. Circulating microRNAs from the miR-106a-363 cluster on chromosome X as novel diagnostic biomarkers for breast cancer. Breast Cancer Res Treat 170: 257-270.

[32] MATAMALA N et al. 2015. Tumor microRNA expression profiling identifies circulating microRNAs for early breast cancer detection. Clin Chem 61: 1098-1106.

[33] MITCHELL PS et al. 2008. Circulating microRNAs as s blood-based markers for cancer detection. Proc Natl Acad Sci USA 105: 10513-10518.

[34] NIU X et al. 2016. miR-1273g-3p modulates activation and apoptosis of hepatic stellate cells by directly targeting PTEN in HCV-related liver fibrosis. FEBS Lett 590: 2709-2724.

[35] PERALTA-ZARAGOZA O et al. 2016. Relevance of miR-21 in regulation of tumor suppressor gene PTEN in human cervical cancer cells. BMC Cancer 16: 215.

[36] QIAN YY, LI K, LIU QY & LIU ZS. 2017. Long non-coding RNA PTENP1 interacts with miR-193a-3p to suppress cell migration and invasion through the PTEN pathway in hepatocellular carcinoma. Oncotarget 8: 107859-107869.

[37] SAHU I, HEBALKAR R, KAR S, TS S, GUTTI U & GUTTI RK. 2018. Systems biology approach to study the role of miRNA in promoter targeting during megakaryopoiesis. Exp Cell Res 366: 192-198.

[38] SCHETTER AJ & HARRIS CC. 2009. Plasma microRNAs: a potential biomarker for colorectal cancer? Gut 58: 1318-1319.

[39] SCHWARZENBACH H. 2017. Clinical Relevance of Circulating, Cell-Free and Exosomal microRNAs in Plasma and Serum of Breast Cancer Patients. Oncol Res Treat 40: 423-429.

[40] SCHWARZENBACH H, NISHIDA N, CALIN GA & PANTEL K. 2014. Clinical relevance of circulating cell-free microRNAs in cancer. Nat Rev Clin Oncol 11: 145-156.

[41] SIEGEL RL, MILLER KD & JEMAL A. 2017. Cancer Statistics, 2017. CA Cancer J Clin 67: 7-30.

[42] SOUZA KCB et al. 2019. Identification of Cell-Free Circulating MicroRNAs for the Detection of Early Breast Cancer and Molecular Subtyping. J Oncol 2019: 8393769.

[43] TAKAHASHI RU, MIYAZAKI H & OCHIYA T. 2015. The Roles of MicroRNAs in Breast Cancer. Cancers (Basel) 7: 598-616.

[44] TORRE LA, BRAY F, SIEGEL RL, FERLAY J, LORTET-TIEULENT J & JEMAL A. 2015. Global cancer statistics, 2012. CA Cancer J Clin 65: 87-108.

[45] WEIGELT B, GEYER FC & REIS-FILHO JS. 2010. Histological types of breast cancer: how special are they? Mol Oncol 4: 192-208.

[46] YUAN Z et al. 2017. Dynamic plasma microRNAs are biomarkers for prognosis and early detection of recurrence in colorectal cancer. Br J Cancer 117: 1202-1210.

[47] ZHANG R, GUO Y, MA Z, MA G, XUE Q, LI F & LIU L. 2017. Long non-coding RNA PTENP1 functions as a ceRNA to modulate PTEN level by decoying miR-106b and miR-93 in gastric cancer. Oncotarget 8: 26079-26089.

Clinicopathologic features	Cases n (%)	Healthy Controls	p-value
Number of patients	39	40
Age (mean ± SD)	49.91±9.795	49.23±8.529	0.7369
Tumor size (cm)^c
≤2 cm	9(23.08)
>2 cm	30(76.92)
TNM stage
I-IIa	13(33.33)
IIb-IIIa	20(51.28)
IIIb-IIIc	6(15.39)
ER status
Negative	13(33.33)
Positive	26(66.67)
PR status
Negative	21(53.85)
Positive	18(46.15)
Her-2
Negative	31(79.49)
Positive	8(20.51)
Ki67
<14%	8(20.51)
>14%	31(79.49)
P53
Negative	21(53.85)
Positive	18(46.15)
Lymph node metastasis
Negative	20(51.28)
Positive	19(48.72)

Clinicopathologic features	Relative expression of miR-21-5p^a	p-value^b	Relative expression of miR-1273g-3p^a	p-value^b
Tumor size (cm)^c		0.5660		0.8829
≤2 cm	1.564(0.9175-5.742)		5.236(0.1916-241)
>2 cm	1.465(0.7072-8.103)		3.159(0.3694-64.21)
TNM stage
I-IIa	0.8423(0.3855-2.035)	0.0188	0.9511(0.241-4.112)	0.1212
IIb-IIIa	1.823(1.237-10.110)		4.488(0.4059-80.34)
IIIb-IIIc	7.519(0.9565-23.13)		113.3(2.538-837.0)
ER status		0.9883		0.8716
Negative	1.518(0.3855-12.5200)		3.368(0.1242-466)
Positive	1.502(0.8433-5.318)		3.246(0.6003-17.52)
PR status		0.4944		0.6061
Negative	0.4944(0.6144-6.4990)		2.949(0.241-34.03)
Positive	1.823(0.8433-7.72)		5.5(0.3694-99.77)
Her-2		0.2087		0.1728
Negative	1.564(0.8445-6.59)		3.74(0.7432-56.15)
Positive	0.737(0.3098-10.34)		0.4186(0.07582-255)
Ki67		0.5730		0.3283
<14%	3.267(0.9761-6.972)		9.415(1.689-108.9)
>14%	1.412(0.8423-5.899)		1.718(0.3163-56.15)
P53		0.7487		0.1925
Negative	1.412(0.8327-5.397)		1.269(0.2169-34.1)
Positive	1.541(0.7439-12.2)		7.119(0.9798-120)
Lymph node metastasis		0.3653		>0.9999
Negative	1.406(0.8426-4.297)		3.456(0.4579-45.13)
Positive	2.295(0.7801-11.11)		2.949(0.1657-88.4)

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