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Oesophageal cancer is one of the deadliest cancers worldwide. It is the sixth leading cause of cancer-related mortality and the eighth most common cancer worldwide (Napier et al, 2014). In the United States, 16 980 new oesophageal cancer cases and 15 590 deaths are estimated to occur in 2015 (Siegel et al, 2015). Oesophageal squamous cell cancer (ESCC) accounts for the majority of oesophageal cancer cases worldwide and is predominant in the highest risk geographic area referred to as the ‘oesophageal cancer belt’, which stretches from the Middle East to central and eastern Asia. Recently, more important techniques such as endoscopic ultrasonography, PET-CT and minimally invasive staging has been used for its diagnosis, and new methods such as minimally invasive oesophagectomy have been used for the treatment (Pennathur et al, 2013); however, the prognoses of ESCC patients remain to be poor. The overall 5-year survival of oesophageal cancer patients ranged from 15 to 25% (Pennathur et al, 2009). To identify the biological factors associated with the malignant behaviour of ESCC, several recent studies have elucidated that certain molecules, such as squamous cell carcinoma antigen (SCC-Ag), carcinoembryonic antigen (CEA), tissue polypeptide antigen and VEGF-C have important roles in tumour genesis and development of ESCC. These serum tumour markers, however, lack sufficient sensitivity and specificity to facilitate early detection of cancer (Zhang et al, 2015a). Therefore, the significance of detecting novel biomarkers for ESCC should be emphasised.

MicroRNAs (miRNAs) are small non-coding regulatory RNA molecules that inhibit the expression of specific target genes by binding to and cleaving their messenger RNAs or otherwise inhibiting their translation into proteins (Lauressergues et al, 2015). Accumulating evidence has shown that miRNAs can participate in tumour genesis, progression and metastasis either as oncogenes or tumour suppressors (Reddy, 2015). Measurement of miRNA expression in tumours may have diagnostic and prognostic implications, and aberrant miRNA expression is associated with the development and progression of various types of human cancer (Komatsu et al, 2011; Wagner et al, 2014; Rachagani et al, 2015; Xu et al, 2015). Several miRNAs, for instance, miR-25, miR-203 and miR-1290, prove to be associated with oesophageal cancer (Komatsu et al, 2014; Zhang et al, 2014b; Li et al, 2015). MiRNA-146a has been widely explored in various cancers. Downregulation of miR-146a is found in breast, lung, pancreatic and gastric carcinomas (Li et al, 2010; Chen et al, 2013; Yao et al, 2013; Kumaraswamy et al, 2014). Exogenous miR-146a expression could decrease the proliferation of several kinds of cancer cells (Chen et al, 2013; Yao et al, 2013). This contrasts with the fact that miR-146a is upregulated in melanoma, squamous cell carcinoma (SCC) of the cervix and thyroid carcinoma (Wang et al, 2008; Philippidou et al, 2010; Sun et al, 2015), which has led to the controversy as to its role in carcinogenesis. Taking the above findings as a whole, miR-146a seems to have a wide variety of roles in the regulation of different genes in various cancers. Low serum level of miR-146a has been shown to define a poor prognosis in patients with non-small-cell lung cancer (NSCLC) (Wu et al, 2014a). However, its expression level in ESCC remains to be unknown. In the present study, we first investigated miR-146a level of tumour tissue compared with normal tissue, and analysed miR-146a prognostic value using formalin-fixed paraffin-embedded (FFPE) tissue. Based on promising results in the tissue, we further investigated whether the serum miR-146a level could be used as a potential diagnostic factor for ESCC by comparing findings in patients and healthy controls. Moreover, the relationship between miR-146a expression level in tissue or serum samples and clinicopathological factors were analysed.

Materials and methods

Patients and samples

Serum samples from 154 ESCC patients (Discovery Group, n=70; Validation Group, n=84), and age- and sex-matched 154 healthy volunteers were recruited from October 2014 to June 2015 from Qilu Hospital of Shandong University. At the same time, 62 pairs of ESCC and paracancerous tissue of patients in the previous Discovery Group were collected (eight cases did not receive surgery because of their bad condition and the refusal on surgery). We also collected 140 FFPE cancerous tissue samples of patients who received surgery in Qilu Hospital during 2009. Owing to the fact that 25 patients lost to follow-up, we included 115 cases finally. All cases were pathologically confirmed as ESCC. Patients did not receive chemotherapy and radiotherapy before surgery. Serum samples were obtained before surgery, whereas fresh tissue were obtained at the time of surgery. All data, including age, sex, smoking and drinking habit, histologic grade, invasion depth (T stage), lymph node metastasis (N stage), distant metastasis(M stage), differentiation degree and the number of dissected lymph nodes, were obtained from the clinical or pathologic records. This study was approved by the Ethics Committee of Qilu Hospital. All participants were informed about the purpose, procedures, benefits and potential risks of the study, and their written consents were obtained.

RNA isolation

Tumour tissue samples

Tissue samples were preserved at −80 °C before RNA isolation. Total RNA was extracted from 50 mg tissue using miRNeasy Mini Kit (Qiagen, Duesseldorf, Nordrhein-Westfalen, Germany) in accordance with the manufacturer’s protocol. Total RNA was suspended in a fixed volume of 50 μl diethylpyrocarbonate-treated water. RNA yield was determined from the A260/A280 absorbance ratio using a DeNovix DS-11 spectrophotometer (DeNovix, Wilmington, DE, USA).

Serum samples

We collected 6 ml of venous blood from the antecubital fossa into a tube without clot activator or anticoagulants such as EDTA or citrate. The blood was centrifuged at 3000 r.p.m. at 4 °C (Sorvall Biofuge Stratos, Heraeus, Germany) for 10 min to spin down the blood cells. The supernatant was removed to a 1.5 ml Eppendorf tube followed by a second centrifugation at 16 000 g for 10 min at 4 °C (Heraeus Fresco 21 microcentrifuge; Thermo Electron Corporation, Langenselbold, Germany) to completely remove additional cellular nucleic acids attached to cell debris. Total RNA was extracted from 200 μl serum using miRNeasy Serum/Plasma Kit () in accordance with the manufacturer’s protocol.

FFPE tissue samples

Four 8-μm-thick sections were cut from each block and placed in sterile 1.5 ml centrifuge tubes ready for extraction. Total RNA including small RNAs was extracted using an miRNeasy FFPE Kit (Qiagen) according to the manufacturer’s instructions.

Quantitative reverse transcription–PCR

Reverse transcription of the total RNA was performed using an All-in-One miRNA qRT–PCR Detection Kit (GeneCopoeia, Rockville, MD, USA). The RT reaction system (25 μl) comprised 1 μl of 2.5 U μl−1 poly A polymerase, 1 μl of RTase Mix, 5 μl of 5 × PAP/RT buffer, 2 μg of Total RNA templates and RNase/DNase-free ddH2O. The reaction conditions were set as follows: 37 °C for 60 min and 85 °C for 5 min. The reaction system (20 μl) for qPCR comprised 10 μl of 2 × qPCR Mix, 2 μl of First-strand cDNA (diluted 1 : 5), 2 μl of Universal Adaptor PCR Primer, 2 μl of All-in-One miRNA qPCR Primer and 4 μl of ddH2O. Amplification was performed in a Bio-Rad Single Color Real-Time PCR system (Bio-Rad, Hercules, CA, USA) under the following reaction conditions: 95 °C for 10 min and 40 cycles of 95 °C for 10 s, 60 °C for 20 s and 72 °C for 10 s. RNU6 was used as an internal control for tissue samples (Guan et al, 2015), whereas the expression levels of serum miR-146a were normalised to miR-16 (Heneghan et al, 2010; Cookson et al, 2012; Lee et al, 2013; Xiang et al, 2014). Relative quantification of miR-146a expression was calculated with 2−ΔΔCt method in fresh tissue and serum, whereas 2−ΔCt method was used for FFPE tissue samples.

Statistical analysis

Differences in miR-146a level between ESCC and paired paracancerous tissue were compared using a paired Student’s t-test. Wilcoxon’s test was conducted to determine the intergroup differences in serum miR-146a expression. Patients were divided into relative high- and low-expression groups according to the cutoff value (mean miR-146a expression level of each cohort) in serum, frozen and FFPE tissue samples for survival analysis. Bilateral χ2 test was used to determine the correlations of miR-146a in tissue or serum samples with the clinical factors of patients. We also conducted the Pearson’s correlation coefficient analysis to value the association of miR-146a expression level in the tissue and serum. Receiver-operating characteristic curve was applied to assess the serum miR-146a diagnosis value in ESCC. We used the Kaplan–Meier method to analyse the survival curve. Univariate and multivariate Cox survival analyses were applied to assess the hazard ratios (HRs). Area under the ROC curve (AUC) was also provided for the Cox regression models. P<0.05 indicated significant difference. These statistical analyses were performed using the SPSS software (version 16.0; SPSS, Chicago, IL, USA).

Results

MiR-146a expression in ESCC tissue compared with paired paracancerous tissue

The expression levels of miR-146a in 62 pairs of ESCC cancerous and paracancerous tissue samples were analysed by qRT–PCR. MicroRNA-146a showed lower expression level in the cancerous tissue (0.50±0.36 vs 1.06±0.09, P<0.001) (Figure 1). And, we also found that the expression level of miR-146a was significantly reduced with increased T stage and TNM stage of ESCC (P=0.037 and P=0.004, respectively), whereas it had no significant relations with other clinicopathological features such as age, gender, smoking, drinking, N stage and differentiation stage (Table 1).

Figure 1
figure 1

MiR-146a expression level in frozen tissue samples.

Table 1 The correlation of ESCC clinicopathologic variables with miRNA-146a in cancerous tissue samples

The association of miR-146a with clinical outcomes of ESCC patients

We selected 115 patents to assess the expression level of miR-146a in FFPE tissue samples. The mean level of 0.65 was regarded as the cutoff value. It indicated no significant relationship between miR-146a expression level and patients’clinicopathological features (Table 2). The mean survival time of all patients was 45.5 months (range 12–80 months). Forty-three patients (37.39%) were alive and 72 patients (62.61%) died during our follow-up period. Among these patients, 61 cases (53.04%) received the adequate therapy (radiotherapy and/or chemotherapy) after surgery, whereas the others did not. Kaplan–Meier curve revealed that its downregulation level was related to worse overall survival (OS) and progression-free survival (PFS) (Figures 2A and B).The univariate survival analysis indicated that low miR-146a expression correlated with decreased OS and PFS (P=0.017 and P=0.004, respectively; Table 3). Furthermore, the multivariate analyses identified miR-146a expression as independent prognostic factor for OS and PFS (P=0.022 and P=0.004, respectively; Table 3). Besides, T stage, N stage and adequate therapy were also predictive indicators for OS and PFS. We also conducted ROC analysis for each clinicopathologic parameter. The AUC of miR-146a, T stage, N stage and adequate therapy were shown in Figure 3. The AUC value of miR-146a was 0.610 (P=0.049) in Cox regression model for OS and it was 0.654 (P=0.014) in the PFS model.

Table 2 The correlation of clinicopathologic variables of ESCC with miRNA-146a in FFPE tissue samples
Figure 2
figure 2

Kaplan–Meier curves of miR-146a in ESCC. (A) Kaplan–Meier curve relevant to OS. (B) Kaplan–Meier curve relevant to PFS.

Table 3 Univariate and multivariate analyses of prognostic variables
Figure 3
figure 3

The ROC analysis of clinicopathologic features in Cox regression model. (AD) Receiver operating curves of miR-146a, T stage, N stage and adequate therapy in the OS model. (EH) Receiver operating curves of miR-146a, T stage, N stage and adequate therapy in the PFS model.

The expression level of miR-146a in the serum of ESCC patients

We used qRT–PCR method to assess the expression level of serum miR-146a. In the Discovery Group, it is significantly downexpressed in ESCC patients compared with the normal controls (0.69±0.41 vs 1.79±0.85, P<0.001; Figure 4A). We also conducted the Pearson’s correlation coefficient analysis to value the association of miR-146a expression level in frozen cancerous tissue and serum of patients. It revealed that the Pearson’s correlation coefficient is 0.866 (P<0.001). The ROC curve analysis showed AUC=0.863±0.033. At the cutoff value of 0.82 for miR-146a, the sensitivity and specificity of this biomarker were 85.7% and 68.6%, respectively (Figures 4C and E). In the Validation Group, miR-146a was also downregulated in patients (0.57±0.29 vs 1.49±0.56, P<0.001; Figure 4B). And, the AUC, sensitivity and specificity values were 0.891±0.027, 82.1% and 83.3%, respectively (Figures 4D and E). We also compared serum miR-146a expression of patients in the Validation Group with their clinicopathological characteristics. The results revealed that serum miR-146a was negatively associated with T stage (P=0.002; Table 4).

Figure 4
figure 4

The expression and diagnostic value of serum miR-146a. (A) Examination of the serum miR-146a level in patients of the Discovery Group. (B) Examination of the serum miR-146a level in patients of the Validation Group. (C) The ROC curve of serum miR-146a in the Discovery Group. (D) The ROC curve of serum miR-146a in the Validation Group. (E) The relevant indicators of ROC curves in the Discovery and Validation groups.

Table 4 The correlation of clinicopathologic variables of ESCC with serum miRNA-146a in validation group

Discussion

Recent studies have revealed the importance of miRNAs as oncogenes or antioncogenes in cancers. microRNAs could have great roles in occurrence, progression and prognosis of cancers. The expression level of miR-146a is variable in different cancers. It was reported to be downregulated in breast, lung, pancreatic and gastric carcinomas (Li et al, 2010; Chen et al, 2013; Yao et al, 2013; Kumaraswamy et al, 2014) but upregulated in melanoma, SCC of the cervix, thyroid carcinoma and oesophageal adenocarcinoma (Wang et al, 2008; Philippidou et al, 2010; Sun et al, 2015; Warnecke-Eberz et al, 2015). For the first time, we found that miR-146a was significantly decreased in cancerous tissue of ESCC patients and it was related to TNM stage, which indicated the potential association between miR-146a and ESCC pathogenesis.

The prognostic value of miRNAs has been widely investigated. For example, miR-21, miR-29c, miR-148, miR-203, miR-100, miR-195, miR-335 and miR-503 can serve as promising prognostic biomarkers in oesophageal cancer (Zhou et al, 2014; Sun et al, 2014a; Zhang et al, 2014a; Hezova et al, 2015; Ide et al, 2015). In this article, we detect the miR-146a prognostic value with FFPE tissue samples. The Kaplan–Meier curve revealed that its downregulation level was related to worse OS and PFS. Via further univariate and multivariate analyses, miR-146a level proved to be an independent prognostic factor for OS and PFS in ESCC. Besides, we found that T stage, N stage and adequate therapy were also associated with OS or PFS. Most importantly, we could indicate that miR-146a was downregulated in ESCC tissue and it could predict OS and PFS of ESCC patients. Further, we analysed its correlation with clinical factors and revealed that its expression level is not significantly associated with TNM stage or differentiation, which was not consistent with the results in frozen tissues. The possibilities were listed as follows. First, the frozen and FFPE tissues are different in the save method and preservation period, which may affect the expression level of miRNAs. Second, samples of frozen and FFPE tissues were not from the same cohort. It could yield the sampling error. Thus, the association of miR-146a and clinicopathological characteristics need to be investigated using large samples.

Considering the limitations of condition and time for tissue sampling, circulating miRNAs are optimal diagnostic biomarkers for cancer. Although serum tumour biomarkers such as CEA and SCC-Ag have been used for diagnosis of ESCC, their sensitivity and specificity were not ideal. It has been reported that the AUC value for CEA, Cyfra21-1, P53, SCC-Ag and VEGF-C in oesophageal cancer patients was 0.71, 0.58, 0.73, 0.69 and 0.81, respectively (Zhang et al, 2015a). New tumour biomarkers were necessary for its diagnosis. In fact, accumulating reports have suggested the presence of circulating miRNAs and their potential use as novel biomarkers for cancers, such as HCC (Wang et al, 2015b), prostate cancer (Kachakova et al, 2015), lung cancer (Wang et al, 2015a), pancreatic cancer (Abue et al, 2015), colorectal cancer (Lu and Lu 2015), glioma (Wei et al, 2014; Lai et al, 2015) and gastric cancer (Kim et al, 2013). Similarly, it has been found that miR-21, miR-25, miR-218, miR-223, miR-375 and miR-1246 have diagnostic value for ESCC (Takeshita et al, 2013; Tanaka et al, 2013; Komatsu et al, 2014; Wu et al, 2014b, 2014c; Jiang et al, 2015). In this article, we included 154 ESCC patients and 154 normal controls to assess the diagnosis potential of miR-146 for this cancer. It indicated lower expression level of miR-146a in patients of the Discovery Group (0.69±0.41 vs 1.79±0.85) as well as in the Validation Group (0.57±0.29 vs 1.49±0.56). The Spearman’s correlation coefficient is 0.866 and it revealed that its expression level in the serum was consistent with that in the tissue. The AUC value was 0.863 in the Discovery Group and 0.891 in the Validation Group. The results indicated that miR-146a level could yield great diagnostic value with high sensitivity and specificity. In a word, serum miR-146a level could be a good noninvasive biomarker for ESCC diagnosis. Moreover, as mentioned, serum miR-146a has been reported in papillary thyroid carcinoma (Sun et al, 2015), lung cancer (Wu et al, 2014a; Wang et al, 2015a) and gastric cancer (Kim et al, 2013), and it is associated with diagnosis and can be used for early detection in tumour. Although miR-146a seems not to be a specific biomarker for oesophageal cancer, it can probably benefit patients because of its significance in the detection of tumour. Besides, miR-146a was reported to be upregulated in the exosomes isolated from the serum of oesophageal adenocarcinoma patient compared with the healthy controls (Warnecke-Eberz et al, 2015), which indicates that its expression level and function varies in different histologic type.

One possible concern in studies of circulating miRNA is the lack of consensus about internal controls for qRT–PCR. Several internal controls have been used in different tumour types, such as miR-16, miR-24 (Xiang et al, 2014) and RNU6B (Ng et al, 2009). It was reported that after one, two and four cycles of freezing and thawing, the expression of miR-16 and miR-24 in serum samples remained relatively stable while U6 expression gradually decreased (Xiang et al, 2014). Our results also showed that miR-16 expression in serum remains similar across the patient and control groups, and therefore it could be used as a reliable internal control in ESCC miRNA expression studies.

The mechanism of miR-146a has been widely explored in different cancers. (Ali et al, 2014) found that knockdown of miR-146a in AsPC-1 cells led to the upregulation of EGFR expression. Cornett and Lutz (2014) reported that decreased miR-146a expression leads to the overexpression of COX-2 in lung cancer cells. MicroRNA-146a also has a suppressive role via downregulation of Rac1 in prostate cancer (Sun et al, 2014b). Zhang et al (2015b) defined miR-146a as a crucial tumour suppressor by downregulating VEGF to inhibit hepatocellular carcinoma invasion or metastasis. Otherwise, it could act as an oncogene by targeting NUMB (Forloni et al, 2014) in melanoma and SMAD4 (Xiao et al, 2012) in gastric cancer. Most importantly, miR-146a may be a potential therapeutic target to prevent cancer progression or metastasis. We have revealed that miR-146a was significantly downregulated in cancerous tissue and serum of ESCC patients. However, the detailed mechanisms of miR-146a in ESCC remain to be unknown. It may target at VEGF, Notch, COX-2 or other gene sites in ESCC based on the miRWalk database (Dweep and Gretz, 2015). Further experiments in vivo and in vitro are necessary to reveal the relevant mechanisms.

Conclusion

In conclusion, we found that miR-146a is downregulated in ESCC tissue and serum samples. It could act as a valuable prognostic factor for OS or PFS of ESCC patients. Meanwhile, it could be used as a diagnosis factor for ESCC with high sensitivity and specificity. All findings suggested that miR-146a is an important tumour suppressor in ESCC and further studies are necessary to investigate its detailed mechanisms.