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miR-107 enhances the sensitivity of breast cancer cells to paclitaxel

  • Changpo Ma , Xuejun Shi , Wenchao Guo , Jianxin Niu and Guangshun Wang EMAIL logo
Published/Copyright: June 1, 2019
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Open Medicine
From the journal Open Medicine Volume 14 Issue 1

Abstract

Breast cancer remains the most commonly diagnosed cancer in Chinese women. Paclitaxel (PTX) is a chemotherapy medication used to treat breast cancer patients. However, a side effect of paclitaxel is the severe drug resistance. Previous studies demonstrated that dysregulation of microRNAs could regulate sensitivity to paclitaxel in breast cancer. Here, the present study aimed to lucubrate the underlying mechanisms of miR-107 in regulating the sensitivity of breast cancer cells to PTX. The results demonstrated that miR-107 was down-regulated in breast cancer tumor tissues, while TPD52 was significantly up-regulated compared with the non-tumor adjacent tissues. After confirming that TPD52 may be a major target of miR-107 via a dual-luciferase reporter assay, the western blot and RT-qPCR assays further demonstrated that miR-107 may reduce the expression level of TPD52 as well. In addition, miR-107 may prominently enhance PTX induced reduction of cell viability and the promotion of cell apoptosis in breast cancer, and the variation could be reversed by co-transfected with pcDNA3.1-TPD52. Finally, miR-107 could further reduce the decreased expression of TPD52, Wnt1, β-catenin and cyclin D1 that was induced by PTX in both mRNA and protein levels, which were rescued by pcDNA3.1-TPD52 indicating that miR-107 regulated breast cancer cell sensitivity to PTX may be targeting TPD52 through Wnt/β-catenin signaling pathway.

Keywords: miR-107; TPD52; Breast cancer; Paclitaxel

1 Introduction

Breast cancer is now the most frequently diagnosed cancer [1], remaining the sixth leading cause of cancer-related death in Chinese women [2]. Besides surgery, chemotherapy such as paclitaxel (PTX) is used for cases of breast cancer in stage 2-4 [3]. PTX is a chemotherapy medication used to treat various cancers, including breast cancer [4]. However, one of the serious side effects which could interfere with breast cancer treatment efficiency is drug resistance [5]. Therefore, it’s urging to increase the sensitivity of breast cancer cells to PTX in order to improve clinical treatment efficiency.

microRNAs (miRNAs) are a group of long small non-coding RNAs with ~22 nucleotides [6], involving in the regulation of many cellular processes, such as cell proliferation [7], apoptosis [8] and differentiation [9]. Furthermore, microRNAs were found to be dysregulated in various cancers, including breast cancer [10]. A previous study reported that miR-107 could inhibit proliferation and migration in breast cancer [11]. That is to say, miR-107 may function as a tumor suppressor candidate in breast cancer. In addition to regulating tumor evolution and development, microRNAs were also confirmed to participate in regulating the sensitivity of breast cancer cells to PTX [12]. However, whether or not miR-107 could regulate sensitivity to PTX in breast cancer still remains to be lucubrated.

Hence, in the present study, we aimed to demonstrate the underlying mechanisms of miR-107 on sensitivity to PTX in breast cancer. Based on the results, miR-107 may induce sensitivity of breast cancer cells to PTX may be targeting TPD52 through Wnt/β-catenin signaling pathway.

2 Materials and methods

2.1 Tissues

A total of 35 human breast cancer tumor tissues and non-tumor adjacent tissues were obtained from Tianjin Baodi People’s Hospital between June 2014 and October 2016 with the informed consent of patients pathologically diagnosed with breast cancer (Table 1). All the patients underwent surgical resection without receiving immunotherapy, chemotherapy or radiotherapy. Tissues were preserved in liquid nitrogen and stored at -80°C. This study obtained the approval of the appropriated ethics committee from Tianjin Baodi People’s Hospital.

Table 1

Clinicopathological features in 35 breast cancer tumor specimens

Clinicopathological variable Cases Expression level miR-107 high (n=20) miR-107 low (n=15) P value (*P<0.05)
Age
≤60 years 6 2 4 0.605
>60 years 29 13 16
Tumor size
≥2cm 23 6 17 0.006
<2cm 12 9 3
Fertility
Yes 23 14 9
No 12 1 11 0.003
Drinking
Yes 12 2 10
No 23 13 10 0.023
TNM stage
I/II 14 9 5 0.036
III/IV 21 6 15

2.2 Cell culture

Human breast cancer cell line MCF-7 was purchased from Cell Bank of the Chinese Academy of Sciences (Shanghai, China). MCF-7 cell line was cultivated at 37°C under 5% CO2 in Roswell Park Memorial Institute (RPMI; Gibco®, Thermo Fisher Scientific, Inc., Waltham, MA, USA) 1640 medium with 10% fetal bovine serum (MP Biomedicals, Costa Mesa, CA, USA) containing penicillin-streptomycin (Sigma-Aldrich, Shanghai, China).

2.3 Dual-luciferase reporter assay

The MCF-10A cells (Cell Bank of the Chinese Academy of Sciences, Shanghai, China) were seeded in 24-well plates with the density of 1×105 cells/well. Meanwhile, TPD52 3’UTR was amplified from cDNA of MCF-10A cells and inserted into pGL-3-Basic (Fenghbio, Changsha, China). Then, the MCF-7 cells were co-transfected with either wild-type or mutant TPD52 3’UTR, in combination with miR-NC mimics or miR-107 mimics via Lipofectamine® 2000 (Thermo Fisher Scientific, Inc., Waltham, MA, USA). After transfection, the cells were cultivated at 37°C, 5 % CO2 for 48 h. Afterward, cells were harvested and the luciferase activities were quantified using a dual-luciferase assay kit (Promega, Madison, WI, USA) following the manufacturer’s protocol. All the procedures were repeated in triplicate.

2.4 Cell transfection

The miR-NC mimics and miR-107 mimics were obtained from GenePharma (Shanghai, China). In order to confirm the transfection efficiency of miR-107, cells were divided into three different groups: i) the control group, un-treated cells; ii) miR-NC mimics group, cells transfected with miR-NC mimics and iii) miR-107 mimics group, cells transfected with miR-107 mimics. The MCF-7 cell line was seeded into 6-well plate with the density of 3×105 cells/well, then the miR-NC mimics or miR-107 mimics were transfected into cells with Lipofectamine® 2000 (Thermo Fisher Scientific, Inc., Waltham, MA, USA) according to the manufacturer’s instructions.

2.5 Vector reconstruction and transfection

A TPD52-expressing vector was constructed by inserting the TPD52 expression into the pcDNA3.1 vector. In brief, full-length TPD52 cDNA was cloned from MCF-10A cells

and reconstructed into the pcDNA3.1 vector (GeneChem, Shanghai, China). In order to confirm the transfection efficiency of TPD52, cells were divided into three different groups: i) the control group, un-treated cells; ii) pcDNA3.1 group, cells transfected with pcDNA3.1 and iii) pcD-NA3.1-TPD52, cells transfected with pcDNA3.1-TPD52. The MCF-7 cells were seeded into 6-well plate with the density of 3×105 cells/well, then the pcDNA3.1 or pcDNA3.1-TPD52 were transfected with Lipofectamine® 2000 (Thermo Fisher Scientific, Inc., Waltham, MA, USA) according to the manufacturer’s instructions.

2.6 The cell viability confirmed by MTT assay

According to the study, the following experiments were divided into five different groups: i) the control group, un-treated cells; ii) the PTX group, cells were exposed to PTX with the concentration of 0.1 μg/ml before transfection; iii) PTX + NC group, cells were exposed to PTX and then transfected with miR-107 NC mimics; iv) PTX + miR-107 group, cells were exposed to PTX and then transfected with miR-107 mimics; and v) PTX + TPD52 + miR-107, cells were exposed to PTX and then transfected with miR-107 mimics and pcDNA3.1-TPD52.

Cell viability was determined using the MTT kit (3-(4.5-Dimethylghiazol-2-yl)-2,5-diphenyltetrazolium Bromide; Thermo Fisher Scientific, Inc., Waltham, MA, USA). Briefly, cells were seeded on a 96-well plate with the density of 5×103 cells/well and cultivated for 24 h at 37°C and 5% CO2. Refer to a previous study [13], MCF-7 cells were exposed to PTX with the concentration of 0.1 μg/ml for 2 h (PTX; Sigma-Aldrich, St. Louis, MO, US) before transfection. Subsequently, 20 μl 5 mg/ml MTT was added into each well and culture for 4 h, and 100 μl DMSO (dimethyl sulfoxide; Solarbio®, Shanghai, China) was added in each well of the plate in order to dissolve the formazan crystal formed. Finally, the absorbance was read at 490 nm using a microplate reader (Bio-Tek Instruments, Winooski, VT, USA). The relative cell viability in different groups was quantified by comparing the absorbance values of treated cells with the un-treated cells. All the procedures were repeated in triplicate.

2.7 The apoptosis rate of breast cancer cells confirmed by flow cytometry assay

MCF-7 cells were seeded on a 6-well plate with a density of 3 × 105 cells/well and then exposed to PTX (with the concentration of 0.1 μg/ml) for 2 h. Then, cells were transfected and cultivated at 37°C and 5% CO2 for 48 h. After digested with 0.25% trypsin (Sigma-Aldrich, Shanghai, China) and washed with phosphate-buffered saline (PBS; Solarbio®, Beijing, China), cells were stained with Annexin V-FITC/PI reagent kit (Sigma-Aldrich, Shanghai, China) in the dark for 10 min. Cell apoptosis rate was evaluated via a flow cytometry (Beckman Coulter, Inc., CA, USA) and CellQuest Pro v.5.2 software (BD FACScan; BD Biosciences, Franklin Lakes, NJ, USA). All the procedures were repeated in triplicate.

RNA extraction and RT-qPCR assay. Total RNA was extracted from cells or tissues using TRIzol reagent (Thermo Fisher Scientific, Inc., Waltham, MA, USA) according to the manufacturer’s instructions. Meanwhile, miRNA was isolated from cells or tissues using the miR-Neasy Mini Kit (Qiagen, Valencia, CA, USA). Afterward, TaqMan MicroRNA Reverse Transcription Kit (Applied Biosystems, Carlsbad, CA, USA) was applied to synthesize cDNA from miRNA. Meanwhile, 2 μl RNA was reverse transcribed into cDNA using RrimeScript RT reagent kit (Epicentre, Madison, WI, USA) followed by RT-qPCR (Real-time Quantitative polymerase chain reaction) analysis. Briefly, the PCR reaction conditions were described as followed: i) denatured for 3 min at 95°C; ii) followed by the thermal cycling parameters with 35 cycles of denaturation for 30 s at 95°C, annealing for 45 s at 62°C, extension for 30 s at 72°C; and iii) extension for 10 min at 72°C. The relative expression level of miR-107 was normalized to U6, while the expression levels of TPD52 and related proteins were normalized to GAPDH according to the 2-△△Ct method. All the procedures were repeated in triplicate. The primer sequences were described as followed: miR-107 forward, 5’-GCCGAATTCAAAGCGAGATTCCATCAGCA-3’ and reverse, 5’-GCCGGATCCTGTCAACCCAGAACTCAAAGG-3’; U6 forward, 5’-CTCGCTTCGGCAGCACA-3’ and reverse, 5’-AACGCTTCACGAATTTGCGT-3’; TPD52 forward, 5’-AACAGAACATTGCCAAAGGGTG-3’ and reverse, 5’-TGACTGAGCCAACAGACGAAA-3’; Wnt1 forward, 5’-ATAGCCTCCTCCACGAACCT-3’ and reverse, 5’-GGAATTGCCACTTGCACTCT-3’; β-catenin forward, 5’-GCTGATTTGATGGAGTTGGA-3’ and reverse, 5’-TCAGCTACTTGTTCTTGAGTGAA-3’; Cyclin D1 forward, 5’-GGATGCTGGAGGTCTGCGAG-3’ and reverse, 5’-GAGAGGAAGCGTGTGAGGCG-3’; GAPDH forward, 5’-TGTTCGTCATGGGTGTGAAC-3’ and reverse, 5’-ATGGCATGGACTGTGGTCAT-3’.

2.8 Western blot

After 48 h transfection, cells in different groups were harvested and lysed by the RIPA buffer (Solarbio®, Beijing, China) and a protease inhibitor cocktail (Apexbio, Shanghai, China). And the concentration of the protein was quantified using a Bradford Protein Quantification Kit (Yeasen, Shanghai, China). Then, equal amounts (20 μg) of the cell lysates were separated by 10% SDS-PAGE (Bio-Rad, Hercule, CA, USA) and transferred onto polyvinylidene difluoride membranes (PVDF; Roche, Switzerland). Membranes were then blocked with 5% non-fat milk buffer at 37°C for 50 min. Afterward, the primary antibodies were added on the membranes at 37°C overnight: rabbit anti-TPD52 (1:1000; ab182578; Abcam, Cambridge, MA, USA); rabbit anti-Wnt1 (1:1000; ab15251; Abcam, Cambridge, MA, USA); anti-β-catenin (1:5000; ab32572; Abcam, Cambridge, MA, USA); rabbit anti-Cyclin D1 (1:10000; ab134175; Abcam, Cambridge, MA, USA) and rabbit anti-GAPDH (1:2500; ab9485; Abcam, Cambridge, MA, USA). After washing with phosphate-buffered saline (PBS; Solarbio®, Beijing, China) containing 0.1% Tween 20 (Sigma-Aldrich, Shanghai, China), the secondary antibody IgG H&L (HRP; 1:1000; ab7090; Abcam, Cambridge, MA, USA) was added at 37°C for 2 h. Finally, the membranes were washed with phosphate-buffered saline (PBS; Solarbio®, Beijing, China) containing 0.1% Tween 20 (Sigma-Aldrich, Shanghai, China). After that, the enhanced chemiluminescence (Amersham Pharmacia, Piscataway, NJ, USA) was added to the membrane. Acquisition and Analysis Software (UVP, Upland, CA, USA) was applied to determine the gray values of proteins. GAPDH functioned as the internal control. All the procedures were repeated in triplicate.

2.9 Statistical analysis

The SPSS version 18.0 statistical software ( SPSS; Chicago, IL, USA) was applied to analyze the data. Data were presented as the means ± standard deviation (SD). In table 1, the comparison of patients characteristics was achieved using the χ2 test. P<0.05 was considered to be statistically significant. Differences between two groups were assessed by student’s t-test method, while the one-way analysis of variation (ANOVA) followed by Newman-Keuls analysis was used to distinguish differences among the three groups or more.

3 Results

3.1 The expression level of miR-107 was down-regulated in breast cancer tumor tissues

As demonstrated in Fig. 1, the expression level of miR-107 was significantly decreased in the breast cancer tumor tissues, compared with non-tumor adjacent tissues (P<0.01).

Figure 1 The expression level of miR-107 is down-regulated in breast cancer tumor tissues. The relative expression level of miR-107 in breast cancer tumor tissues and non-tumor adjacent tissues were compared via RT-qPCR assay. **P<0.01, vs control group. Control, non-tumor adjacent tissues; breast cancer, breast cancer tumor tissues; miR-107, microRNA-107.
Figure 1

The expression level of miR-107 is down-regulated in breast cancer tumor tissues. The relative expression level of miR-107 in breast cancer tumor tissues and non-tumor adjacent tissues were compared via RT-qPCR assay. **P<0.01, vs control group. Control, non-tumor adjacent tissues; breast cancer, breast cancer tumor tissues; miR-107, microRNA-107.

3.2 TPD52 may be a target of miR-107

As demonstrated in Fig. 2A, the 3’UTR of the gene TPD52 was found to contain the binding sequence at the position 34-31 for the miR-107, implying that TPTD52 could be a downstream target gene of miR-107. Moreover, Fig. 2B further demonstrated that the relative luciferase activities in the wild-type (WT) TPD52 3’UTR plasmid-transfected cells were remarkably reduced by the transfection of miR-107 mimics, however, there were no differences in the mutant-type TPD52 3’UTR (TPD52-3’UTR) plasmid-transfected cells (P<0.01).

Figure 2 TPD52 is potentially a major target of miR-107. (A) Sequence alignment of the paired site of the 3’ URT of miR-107 and TPD52 ; (B) The luciferase activity in different groups. **P<0.01, vs miR-NC mimics group. WT, wild-type; TPD52, tumor protein D52; UTR, untranslated region; miR-107, microRNA-107; miR-107 NC mimics, microRNA-107 mimics negative control-transfected cells; miR-107 mimics, microRNA-107 mimics-transfected cells.
Figure 2

TPD52 is potentially a major target of miR-107. (A) Sequence alignment of the paired site of the 3’ URT of miR-107 and TPD52 ; (B) The luciferase activity in different groups. **P<0.01, vs miR-NC mimics group. WT, wild-type; TPD52, tumor protein D52; UTR, untranslated region; miR-107, microRNA-107; miR-107 NC mimics, microRNA-107 mimics negative control-transfected cells; miR-107 mimics, microRNA-107 mimics-transfected cells.

3.3 The expression level of TPD52 was up-regulated in breast cancer tumor tissues

As demonstrated in Fig. 3A, the expression level of TPD52 was significantly increased in the breast cancer tumor tissues, compared with non-tumor adjacent tissues via RT-qPCR assay (P<0.01). Meanwhile, the western blot

Figure 3 The expression level of TPD52 is up-regulated in breast cancer tumor tissues. (A) Relative TPD52 mRNA expression level in breast cancer tumor tissues and non-tumor adjacent tissues was compared by RT-qPCR assay. (B) Relative protein expression level of TPD52 in breast cancer tumor tissues and non-tumor adjacent tissues was compared by western blot assay. (C) The quantitative result of B was presented. **P<0.01, vs control group. Control, non-tumor adjacent tissues; breast cancer, breast cancer tumor tissues; TPD52, tumor protein D52; GAPDH, glyceraldehyde 3-phosphate dehydrogenase.
Figure 3

The expression level of TPD52 is up-regulated in breast cancer tumor tissues. (A) Relative TPD52 mRNA expression level in breast cancer tumor tissues and non-tumor adjacent tissues was compared by RT-qPCR assay. (B) Relative protein expression level of TPD52 in breast cancer tumor tissues and non-tumor adjacent tissues was compared by western blot assay. (C) The quantitative result of B was presented. **P<0.01, vs control group. Control, non-tumor adjacent tissues; breast cancer, breast cancer tumor tissues; TPD52, tumor protein D52; GAPDH, glyceraldehyde 3-phosphate dehydrogenase.

assay presented the similar trend of variation as well (Fig. 3B and 3C; P<0.01).

3.4 The transfection efficiency was confirmed

As demonstrated in Fig. 4A, the expression level of miR-107 was significantly increased in the miR-107 mimics group, compared with miR-NC mimics group (P<0.01). As demonstrated in Fig. 4B, the expression level of TPD52 mRNA was significantly increased in the pcDNA3.1-TPD52 group, compared with the pcDNA3.1 group (P<0.01).

Figure 4 The transfection efficiency of miR-107 and TPD52. (A) The expression level of miR-107 in different groups; (B) The expression level of TPD52 in different groups. **P<0.01, miR-107 mimics vs NC; pcDNA3.1-TPD52 vs pcDNA3.1. Control, un-treated cells; NC, microRNA-107 mimics negative control-transfected cells; miR-107 mimics, microRNA-107 mimics-transfected cells; pcDNA3.1, cells transfected with pcDNA3.1; pcDNA3.1-TPD52, cells transfected with pcDNA3.1-TPD52; miR-107, microRNA-107; TPD52, tumor protein D52.The expression level of miR-107 is significantly higher in miR-107 mimics group. The transfection efficiency of miR-107 was confirmed by RT-qPCR assay. **P<0.01, vs miR-NC mimics group. Control, untreated cells; NC, microRNA-107 mimics negative control-transfected cells; miR-107 mimics, microRNA-107 mimics-transfected cells.
Figure 4

The transfection efficiency of miR-107 and TPD52. (A) The expression level of miR-107 in different groups; (B) The expression level of TPD52 in different groups. **P<0.01, miR-107 mimics vs NC; pcDNA3.1-TPD52 vs pcDNA3.1. Control, un-treated cells; NC, microRNA-107 mimics negative control-transfected cells; miR-107 mimics, microRNA-107 mimics-transfected cells; pcDNA3.1, cells transfected with pcDNA3.1; pcDNA3.1-TPD52, cells transfected with pcDNA3.1-TPD52; miR-107, microRNA-107; TPD52, tumor protein D52.

The expression level of miR-107 is significantly higher in miR-107 mimics group. The transfection efficiency of miR-107 was confirmed by RT-qPCR assay. **P<0.01, vs miR-NC mimics group. Control, untreated cells; NC, microRNA-107 mimics negative control-transfected cells; miR-107 mimics, microRNA-107 mimics-transfected cells.

3.5 miR-107 significantly reduced the expression level of TPD52

As demonstrated in Fig. 5A, the mRNA expression level of TDP52 was significantly decreased in the miR-107 mimics groups, in contrast with NC group (P<0.01). Meanwhile, the protein results in Fig. 5B and 5C presented the similar trend of variation as well (P<0.01).

Figure 5 miR-107 reduces the expression level of TPD52. (A) The mRNA expression level of TPD52 in differing groups; (B) The protein expression level of TPD52 in different groups; (C) The quantitative result of B was presented. **P<0.01, vs NC group. Control, untreated cells; NC, microRNA-107 mimics negative control-transfected cells; miR-107 mimics, microRNA-107 mimics-transfected cells; TPD52, tumor protein D52; GAPDH, glyceraldehyde 3-phosphate dehydrogenase.
Figure 5

miR-107 reduces the expression level of TPD52. (A) The mRNA expression level of TPD52 in differing groups; (B) The protein expression level of TPD52 in different groups; (C) The quantitative result of B was presented. **P<0.01, vs NC group. Control, untreated cells; NC, microRNA-107 mimics negative control-transfected cells; miR-107 mimics, microRNA-107 mimics-transfected cells; TPD52, tumor protein D52; GAPDH, glyceraldehyde 3-phosphate dehydrogenase.

3.6 miR-107 significantly decreased breast cancer cell viability after treated with PTX

As to further illustrate the effect of miR-107 on the sensitivity of breast cancer cells to PTX, the cell viability was measured via MTT assay. As demonstrated in Fig. 6, the cell viability in the PTX group was markedly decreased compared to the control group (P<0.01), meanwhile, there were no differences in the PTX group and PTX + NC group. In contrast with PTX + NC group, the cell viability

Figure 6 miR-107 significantly decreases breast cancer cell viability after treated with PTX. The cell viability of breast cancer cells in different groups was measured by the MTT assay. **P<0.01, PTX vs control; PTX + miR-107 vs PTX + NC; PTX + TPD52 + miR-107 vs PTX +miR-107. Control, un-treated cells; PTX, cells were exposed to PTX with the concentration of 0.1μg/ml; NC, miR-107 mimics negative control-transfected cells; miR-107, miR-107 mimics-transfected cells; TPD52, tumor protein D52, cells transfected with pcDNA3.1-TPD52.
Figure 6

miR-107 significantly decreases breast cancer cell viability after treated with PTX. The cell viability of breast cancer cells in different groups was measured by the MTT assay. **P<0.01, PTX vs control; PTX + miR-107 vs PTX + NC; PTX + TPD52 + miR-107 vs PTX +miR-107. Control, un-treated cells; PTX, cells were exposed to PTX with the concentration of 0.1μg/ml; NC, miR-107 mimics negative control-transfected cells; miR-107, miR-107 mimics-transfected cells; TPD52, tumor protein D52, cells transfected with pcDNA3.1-TPD52.

in PTX + miR-107 was significantly decreased, while the variation could be reversed by co-transfected with the pcDNA3.1-TPD52 (P<0.01). Collectively, miR-107 may significantly reduce breast cancer cell viability after treated with PTX.

3.7 miR-107 significantly promoted breast cancer cell apoptosis rate after treated with PTX

As demonstrated in Fig. 7A-7F, compared with the control group, the apoptosis rate was remarkably higher after treated with PTX (P<0.01), while there was almost no variation between the PTX group and PTX + NC group. Moreover, after transfection, the apoptosis rate in miR-107 mimics group was remarkably higher than that in the PTX + miR-107 group (P<0.01), however, the variation could be reversed by co-transfected with the pcDNA3.1-TPD52 (P<0.01). Taken all together, miR-107 could significantly promote breast cancer cell apoptosis after treated with PTX.

Figure 7 miR-107 significantly promotes breast cancer cell apoptosis rate after treated with paclitaxel. (A) Control group; (B) PTX group; (C) PTX + NC group; (D) PTX + miR-107 group; (E) PTX +TPD52 +miR-107 group; (F) The corresponding quantified apoptosis rate results of A-E was exhibited. **P<0.01, PTX vs control; PTX + miR-107 vs PTX + NC; PTX + TPD52 + miR-107 vs PTX +miR-107. Control, un-treated cells; PTX, cells were exposed to PTX with the concentration of 0.1μg/ml; NC, miR-107 mimics negative control-transfected cells; miR-107, miR-107 mimics-transfected cells; TPD52, tumor protein D52, cells transfected with pcDNA3.1-TPD52.
Figure 7

miR-107 significantly promotes breast cancer cell apoptosis rate after treated with paclitaxel. (A) Control group; (B) PTX group; (C) PTX + NC group; (D) PTX + miR-107 group; (E) PTX +TPD52 +miR-107 group; (F) The corresponding quantified apoptosis rate results of A-E was exhibited. **P<0.01, PTX vs control; PTX + miR-107 vs PTX + NC; PTX + TPD52 + miR-107 vs PTX +miR-107. Control, un-treated cells; PTX, cells were exposed to PTX with the concentration of 0.1μg/ml; NC, miR-107 mimics negative control-transfected cells; miR-107, miR-107 mimics-transfected cells; TPD52, tumor protein D52, cells transfected with pcDNA3.1-TPD52.

3.8 Effect of miR-107 on the expression levels of TPD52, Wnt1, β-catenin and Cyclin D1

As to further confirm whether and how miR-107 and TPD52 participated in the regulation of breast cancer cell viability and apoptosis, the relative expression levels of Wnt1, β-catenin and Cyclin D1 were measured by RT-qPCR and western blot assays. As demonstrated in Fig. 8A-8D, the mRNA expression levels of TPD52, Wnt1, β-catenin and cyclin D1 were significantly decreased after treated with PTX (**P<0.01; *P<0.05), while there were no differences between PTX group and PTX + NC group. Subsequently, after transfection, the expression levels of TPD52, Wnt1, β-catenin and Cyclin D1 in PTX + miR-107 were remarkably lower than those in the PTX + NC group (**P<0.01; *P<0.05), however, the variation could be reversed by co-transfected with pcDNA3.1-TPD52 (**P<0.01; *P<0.05). Meanwhile, consistent with the results of the RT-qPCR assay, the western blot data (Fig. 9A and 9B) presented the similar trend of variation (P<0.01).

Figure 8 Effect of miR-107 on the mRNA expression levels of TPD52, Wnt1, β-catenin and cyclin D1. (A) The mRNA expression level of TPD52 in different groups; (B) The mRNA expression level of Wnt 1 in different groups; (C) The mRNA expression level of β-catenin in different groups; (D) The mRNA expression level of Cyclin D1 in different groups. *P<0.05, **P<0.01, PTX vs control; PTX + miR-107 vs PTX + NC; PTX + TPD52 + miR-107 vs PTX +miR-107. Control, un-treated cells; PTX, cells were exposed to PTX with the concentration of 0.1μg/ml; NC, miR-107 mimics negative control-transfected cells; miR-107, miR-107 mimics-transfected cells; TPD52, tumor protein D52, cells transfected with pcDNA3.1-TPD52.
Figure 8

Effect of miR-107 on the mRNA expression levels of TPD52, Wnt1, β-catenin and cyclin D1. (A) The mRNA expression level of TPD52 in different groups; (B) The mRNA expression level of Wnt 1 in different groups; (C) The mRNA expression level of β-catenin in different groups; (D) The mRNA expression level of Cyclin D1 in different groups. *P<0.05, **P<0.01, PTX vs control; PTX + miR-107 vs PTX + NC; PTX + TPD52 + miR-107 vs PTX +miR-107. Control, un-treated cells; PTX, cells were exposed to PTX with the concentration of 0.1μg/ml; NC, miR-107 mimics negative control-transfected cells; miR-107, miR-107 mimics-transfected cells; TPD52, tumor protein D52, cells transfected with pcDNA3.1-TPD52.

Figure 9 Effect of miR-107 on the protein expression levels of TPD52, Wnt1, β-catenin and cyclin D1. (A) The protein expression levels of TPD52, Wnt1, β-catenin and cyclin D1 in different groups; (B) The corresponding quantified results of A was presented. **P<0.01, PTX vs control; PTX + miR-107 vs PTX + NC; PTX + TPD52 + miR-107 vs PTX +miR-107. Control, un-treated cells; PTX, cells were exposed to PTX with the concentration of 0.1μg/ml; NC, miR-107 mimics negative control-transfected cells; miR-107, miR-107 mimics-transfected cells; TPD52, tumor protein D52, cells transfected with pcDNA3.1-TPD52; Wnt1, proto-oncogene protein wnt-1; GAPDH, glyceraldehyde 3-phosphate dehydrogenase.
Figure 9

Effect of miR-107 on the protein expression levels of TPD52, Wnt1, β-catenin and cyclin D1. (A) The protein expression levels of TPD52, Wnt1, β-catenin and cyclin D1 in different groups; (B) The corresponding quantified results of A was presented. **P<0.01, PTX vs control; PTX + miR-107 vs PTX + NC; PTX + TPD52 + miR-107 vs PTX +miR-107. Control, un-treated cells; PTX, cells were exposed to PTX with the concentration of 0.1μg/ml; NC, miR-107 mimics negative control-transfected cells; miR-107, miR-107 mimics-transfected cells; TPD52, tumor protein D52, cells transfected with pcDNA3.1-TPD52; Wnt1, proto-oncogene protein wnt-1; GAPDH, glyceraldehyde 3-phosphate dehydrogenase.

4 Discussion

In the present study, the underlying mechanisms of how miR-107 regulates the sensitivity of breast cancer cells to PTX were demonstrated. Firstly, the expression level of miR-107 was significantly lower in breast cancer tumor tissues. After confirming that TPD52 may be a target gene of miR-107, the expression level of TPD52 in breast cancer tumor tissues was further proved to be up-regulated, which were contrary to that of miR-107. Subsequently, the MTT and flow cytometry assays further illustrated that through targeting TPD52, miR-107 could significantly decrease breast cancer cell viability but promote apoptosis after treated with 0.1 μg/ml PTX. Finally, the western blot assay confirmed that miR-107 regulated the sensitivity of breast cancer cells to PTX by down-regulating the expression level of TPD52 through Wnt/β-catenin signaling pathway.

According to previous studies, miR-107 was proved to participate in regulating tumor development and evolution processes. For instance, miR-107 may suppress cell proliferation or promote apoptosis in lung cancer [14], gastric cancer [15] and breast cancer [16]. Another report also demonstrated that miR-107 was markedly downregulated in both breast cancer cell lines and breast tumors [16], functioning as an anti-metastasis factor in breast cancer as well [17]. Consistent with previous studies, the results in our study presented that the expression level of miR-107 was significantly decreased in breast cancer tumor tissues. Furthermore, miR-107 was considered to enhance chemosensitivity to PTX in NSCLC [18] and gastric cancer [19]. However, whether or not miR-107 participated in modulating PTX sensitivity in breast cancer remain to be lucubrated.

As the results presented, TPD52 was considered to be a target gene of miR-107 via a dual-luciferase reporter assay. Recently, TPD52 was reported to promote cell proliferation or suppress apoptosis in uterine leiomyoma cells [20], prostate cancer [21], and glioma cell [22]. TPD52 was also reported to be up-regulated in the breast cancer cell and promoting breast cancer metastasis as well [23, 24, 25], indicating that TPD52 functioned as the oncogene

in breast cancer. Consistent with previous studies, our results demonstrated that TPD52 was up-regulated in breast cancer tumor tissues. Furthermore, according to the MTT and flow cytometry assays, overexpression of miR-107 could further inhibit cell viability but promote apoptosis in breast cancer after treated with PTX, indicating that up-regulated miR-107 could enhance PTX sensitivity may be targeting TPD52 in breast cancer.

In order to lucubrate the underlying mechanisms of how miR-107 mediated the sensitivity to PTX in breast cancer cells, the expression levels of TPD52 and related proteins were measured by RT-qPCR and western blot assays. Wnt signaling pathway was first identified for its role in carcinogenesis and demonstrated by mutations leading to various diseases, including breast cancer [26,27]. Wnt1 protein is a member of Wnt signaling pathway proteins and a previous study also demonstrated that knockdown of wnt1 may induce apoptosis of human cancer cells [28], including breast cancer cells [29], indicating that wnt1 functioned as a tumor promoter in breast cancer. Wnt/β-catenin signaling pathway was considered to be involved in regulating tumor development in various cancers, including breast cancer [30,31]. Meanwhile, accumulating evidence illustrated that inhibition of Wnt/β-catenin pathway could suppress breast cancer proliferation or promote apoptosis as well [32, 33, 34, 35]. Cyclin D1 is a protein that in humans encoded by the CCND1 gene, and CCND1 genetic locus is commonly amplified in many human tumors including breast cancer [36]. Moreover, cyclin D1 overexpression was found in more than 50% of human breast cancers [37, 38], and suppression of cyclin D1 could inhibit breast cancer cell proliferation but induce apoptosis as well [39]. Recently, a study pointed out that knockdown of TPD52 could significantly decrease the expression level of cyclin D1 concerning cell apoptosis process [40]. According to our results, overexpressed miR-107 could further reduce PTX induced decrease of the expression levels of TPD52, Wnt1, β-catenin and cyclinD1 may be

targeting TPD52. Consistent with previous studies, we proposed the conjecture that suppression of TPD52 by up-regulating miR-107 could inhibit or inactivate Wnt/β-catenin signaling pathway and the expression level cyclin D1.

According to previous studies, TPD52 could activate or regulate NF-κB, PI3K/AKT, Raf/MEK/ERK or JAK/STAT3 signaling pathways concerning modulating cell proliferation and apoptosis [41,42]. However, whether or not other signal pathways beside the Wnt/β-catenin could regulate TPD52 remain to be further detected. Meanwhile, the underlying relationship and interaction between miR-107 and TPD52 need to be further detected in the future.

To sum up, miR-107 could enhance PTX sensitivity in breast cancer cells may be targeting TPD52 through Wnt/β-catenin signaling pathway.

  1. Conflict of interest

    Conflict of interest statement: Authors state no conflict of interest.

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Received: 2018-10-12
Accepted: 2019-01-11
Published Online: 2019-06-01

© 2019 Guangshun Wang et al., published by De Gruyter

This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

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https://doi.org/10.1515/med-2019-0049
Keywords for this article
miR-107; TPD52; Breast cancer; Paclitaxel
Creative Commons
BY-NC-ND 4.0

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  59. Solar urticaria, a disease with many dark sides: is omalizumab the right therapeutic response? Reflections from a clinical case report
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  62. Propofol versus 4-hydroxybutyric acid in pediatric cardiac catheterizations
  63. Nasointestinal tube in mechanical ventilation patients is more advantageous
  64. The change of endotracheal tube cuff pressure during laparoscopic surgery
  65. Correlation between iPTH levels on the first postoperative day after total thyroidectomy and permanent hypoparathyroidism: our experience
  66. Case Report
  67. Primary angiosarcoma of the kidney: case report and comprehensive literature review
  68. Research Article
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  70. Incidental findings in dental radiology are concerning for family doctors
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  73. Indications and outcomes of splenectomy for hematological disorders
  74. Expression of CENPE and its prognostic role in non-small cell lung cancer
  75. Barbed suture and gastrointestinal surgery. A retrospective analysis
  76. Using post transplant 1 week Tc-99m DTPA renal scan as another method for predicting renal graft failure
  77. The pseudogene PTTG3P promotes cell migration and invasion in esophageal squamous cell carcinoma
  78. Lymph node ratio versus TNM system as prognostic factor in colorectal cancer staging. A single Center experience
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  82. Anatomical workspace study of Endonasal Endoscopic Transsphenoidal Approach
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  89. microRNA-27a-3p down-regulation inhibits malignant biological behaviors of ovarian cancer by targeting BTG1
  90. PYCR1 is associated with papillary renal cell carcinoma progression
  91. Prediction of recurrence-associated death from localized prostate cancer with a charlson comorbidity index–reinforced machine learning model
  92. Colorectal cancer in the elderly patient: the role of neo-adjuvant therapy
  93. Association between MTHFR genetic polymorphism and Parkinson’s disease susceptibility: a meta-analysis
  94. Metformin can alleviate the symptom of patient with diabetic nephropathy through reducing the serum level of Hcy and IL-33
  95. Case Report
  96. Severe craniofacial trauma after multiple pistol shots
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  101. Review Article
  102. Oncological outcomes and quality of life after rectal cancer surgery
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  104. MiR-638 repressed vascular smooth muscle cell glycolysis by targeting LDHA
  105. microRNA-16 via Twist1 inhibits EMT induced by PM2.5 exposure in human hepatocellular carcinoma
  106. Analyzing the semantic space of the Hippocratic Oath
  107. Fournier’s gangrene and intravenous drug abuse: an unusual case report and review of the literature
  108. Evaluation of surgical site infection in mini-invasive urological surgery
  109. Dihydromyricetin attenuates inflammation through TLR4/NF-kappaB pathway
  110. Clinico-pathological features of colon cancer patients undergoing emergency surgery: a comparison between elderly and non-elderly patients
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  112. Appendix bleeding with painless bloody diarrhea: A case report and literature review
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  114. Protective effects of specneuzhenide on renal injury in rats with diabetic nephropathy
  115. PBF, a proto-oncogene in esophageal carcinoma
  116. Use of rituximab in NHL malt type pregnant in I° trimester for two times
  117. Cancer- and non-cancer related chronic pain: from the physiopathological basics to management
  118. Case report
  119. Non-surgical removal of dens invaginatus in maxillary lateral incisor using CBCT: Two-year follow-up case report
  120. Research Article
  121. Risk factors and drug resistance of the MDR Acinetobacter baumannii in pneumonia patients in ICU
  122. Accuracy of tumor perfusion assessment in Rat C6 gliomas model with USPIO
  123. Lemann Index for Assessment of Crohn’s Disease: Correlation with the Quality of Life, Endoscopic Disease activity, Magnetic Resonance Index of Activity and C- Reactive Protein
  124. Case report
  125. Münchausen syndrome as an unusual cause of pseudo-resistant hypertension: a case report
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  127. Renal artery embolization before radical nephrectomy for complex renal tumour: which are the true advantages?
  128. Prognostic significance of CD276 in non-small cell lung cancer
  129. Potential drug-drug interactions in acute ischemic stroke patients at the Neurological Intensive Care Unit
  130. Effect of vitamin D3 on lung damage induced by cigarette smoke in mice
  131. CircRNA-UCK2 increased TET1 inhibits proliferation and invasion of prostate cancer cells via sponge miRNA-767-5p
  132. Case report
  133. Partial hydatidiform mole and coexistent live fetus: a case report and review of the literature
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  135. Effect of NGR1 on the atopic dermatitis model and its mechanisms
  136. Clinical features of infertile men carrying a chromosome 9 translocation
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  138. Expression and role of microRNA-663b in childhood acute lymphocytic leukemia and its mechanism
  139. Case Report
  140. Mature cystic teratoma of the pancreas: A rare cystic neoplasm
  141. Research Article
  142. Application of exercised-based pre-rehabilitation in perioperative period of patients with gastric cancer
  143. Case Report
  144. Predictive factors of intestinal necrosis in acute mesenteric ischemia
  145. Research Article
  146. Application of exercised-based pre-rehabilitation in perioperative period of patients with gastric cancer
  147. Effects of dexmedetomidine on the RhoA /ROCK/ Nox4 signaling pathway in renal fibrosis of diabetic rats
  148. MicroRNA-181a-5p regulates inflammatory response of macrophages in sepsis
  149. Intraventricular pressure in non-communicating hydrocephalus patients before endoscopic third ventriculostomy
  150. CyclinD1 is a new target gene of tumor suppressor miR-520e in breast cancer
  151. CHL1 and NrCAM are primarily expressed in low grade pediatric neuroblastoma
  152. Epidemiological characteristics of postoperative sepsis
  153. Association between unstable angina and CXCL17: a new potential biomarker
  154. Cardiac strains as a tool for optimization of cardiac resynchronization therapy in non-responders: a pilot study
  155. Case Report
  156. Resuscitation following a bupivacaine injection for a cervical paravertebral block
  157. Research Article
  158. CGF treatment of leg ulcers: A randomized controlled trial
  159. Surgical versus sequential hybrid treatment of carotid body tumors
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