1. Introduction
Breast cancer (BC) is a complex neoplastic disease with various stages, from benign to invasive malignant tumors, and represents the most commonly diagnosed cancer in women [Reference Hong, Fritz and Zaidi1]. Despite remarkable advances in diagnosis and treatment in recent years, the complexity of the molecular pathways underlying BC has largely prevented the development of targeted treatments for this disease. In recent decades, the role of noncoding RNAs in gene regulation has attracted widespread attention in medical research [Reference Palazzo, Lee and Non-coding2]. Long noncoding RNAs (lncRNAs) and miRNAs are presented as two major classes of noncoding RNAs whose functions in a variety of cancers such as BC have been extensively studied; therefore, some lncRNAs/miRNAs are regarded as promising therapeutic targets in BC [Reference Abdollahzadeh, Daraei, Mansoori, Sepahvand, Amoli and Tavakkoly-Bazzaz3].
LncRNAs with a length greater than 200 nucleotides are defined as a major class of non-protein-coding RNAs and are involved in many physiological and pathological processes [Reference Tuersong, Li, Abulaiti and Feng4]. It is well established that lncRNAs are involved in various steps of cancer pathophysiology, including proliferation, angiogenesis, immortality, invasion, and metastasis [Reference El-Ashmawy, Hussien, El-Feky, Hamouda and Al-Ashmawy5]. MiRNAs are short noncoding RNAs, typically 17–25 nucleotides in length, and their dysregulation is associated with an increased risk of cancers, including BC [Reference Mulrane, McGee, Gallagher and O’Connor6].
LncRNAs and miRNAs not only control gene transcription but also participate in gene expression through the lncRNA-miRNA-mRNA network. It is noteworthy that lncRNAs act as competing endogenous RNAs (ceRNA) and can function against miRNAs to regulate the expression of neighboring genes in the physiological process, influencing tumor development [Reference Xia, Liu, Cheng, Xu, Dong and Hu7, Reference Chen and Shan8]. The ceRNA theory assumes that lncRNAs and mRNAs sharing the same miRNA response elements (MREs) compete for linkage to the same miRNA, thereby regulating each other’s expression [Reference Brex, Barbagallo and Mirabella9]. The performance of the lncRNAs-associated ceRNA network has been demonstrated in several cancers, namely, breast, gastric, glioblastoma [Reference Tuersong, Li, Abulaiti and Feng4, Reference Liu, Zhang and Wu10, Reference Luo, Tu and Zhong11]. In addition, dysregulation of lncRNA can also intervene in favor of hematological malignancies, e.g., leukemia [Reference Wong, Huang, Islam and Yip12]. LncRNAs also play an important role in several human diseases such as diabetes [Reference Lemos, Rodrigues, Corre and Dieter13], infertility, e.g., lncRNA H19 [Reference Rotondo, Lanzillotti, Mazziotta, Tognon and Martini14], as well as cardiovascular diseases [Reference Fang, Xu and Wang15]. The interaction of lncRNAs and miRNAs creates a complex regulatory network through which it ultimately modulates gene and/or protein expression at many levels, i.e., transcriptional, posttranscriptional, and posttranslational [Reference Zhang, Pian and Chen16].
The SFN gene (14-3-3σ proteins or stratifin) is one of various genes implicated in several cancer pathways, as it plays multifunctional regulatory role in several cellular processes related to cancer pathophysiology, including cell cycle progression, cell growth, and apoptosis [Reference Ko, Kim, Jeong, Lee, Yang and Jung17]. The functions of SFN may vary depending on the organs and/or tissues, and several studies have shown that upregulation of SFN promotes cancer of pancreas [Reference Friess, Ding and Kleeff18], head and neck [Reference Villaret, Wang and Dillon19], lower gastrointestinal tract [Reference Perathoner, Pirkebner and Brandacher20], lung [Reference Kim, Shiba-Ishii and Nakagawa21], and gallbladder [Reference Sirivatanauksorn, Dumronggittigule and Dulnee22]. Nonetheless, SFN has been identified as well as a tumor suppressor/modulator gene in colon [Reference Young, Radhakrishnan, Centuori, Gomes and Martinez23], ovaries [Reference Kaneuchi, Sasaki and Tanaka24], breast [Reference Moreira, Ohlsson, Rank and Celis25], bladder [Reference Moreira, Gromov and Celis26], and lung [Reference Liu, Chen and Zhang27] and its expression was downregulated in these cancers [Reference Friess, Ding and Kleeff18–Reference Sirivatanauksorn, Dumronggittigule and Dulnee22]. In most cancers, including BC, this downregulation is known to be due to SFN gene inactivation, generally through promoter methylation; for this reason, DNA hypermethylation in the promoter of SFN has been used as a biomarker for cancer diagnosis [Reference Lodygin and Hermeking28].
In this study, we used gene set enrichment analysis (GSEA) and microarray analysis to identify the most differentially expressed genes (DEGs) in BC and control breast tissues from the GEO database. Finally, the SFN gene was selected as a target for further investigation. For data validation, the expression of the SFN gene, the LINC01343, and CCDC18-AS1 lncRNAs (which were determined by bioinformatic analysis) was analyzed by qRT-PCR in tumor and paired control breast tissues.
2. Materials and Methods
2.1. Identification of Differentially Expressed mRNA Using GSEA
GSEA (Gene Set Enrichment Analysis) represents a proper computational method for identifying genes with a common biological function and pathway enrichment. In this study, GSEA was performed using the GSEA V 4.1.0 software to analyze the GSE71053 dataset [Reference Liberzon, Birger, Thorvaldsdóttir, Ghandi, Mesirov and Tamayo29–Reference Subramanian, Tamayo and Mootha31] extracted from Gene Expression Omnibus (GEO) (https://www.ncbi.nlm.nih.gov/geo/). Subsequently, the Wilcoxon rank-sum test was used to analyze differentially expressed genes (DEGs). False discovery rate (FDR) <0.25 was considered as the significance threshold.
2.2. Identification of Differentially Expressed mRNA Using Microarray Analysis
We used the GSE71053 entry from the GEO database (https://www.ncbi.nlm.nih.gov/geo/) and analyzed it to find the DEGs in BC samples compared to normal samples. Data were analyzed using the “limma” [Reference Ritchie, Phipson and Wu32] and “affy” [Reference Gautier, Cope, Bolstad and Irizarry33] packages in R software 4.1.0, and graphs and figures of the microarray analysis were drawn by ggplot2 and pheatmap packages. Based on the distribution of expression data of all genes investigated in this experiment, genes with logFC greater than the third quartile were selected as overexpression genes (logFC = 0.156276), and those with logFC less than the first quarter were selected as low-expressed genes (logFC = −0.194726).
2.3. Bioinformatic Analyses
The ceRNA network was created based on the hypothesis that lncRNAs affect miRNAs to regulate the mRNA’s activity and expression. lncRNA-miRNA-mRNA network was established using three databases: (1) miRWalk V.3 (https://mirwalk.umm.uni-heidelberg.de/) [Reference Dweep, Sticht, Pandey and Gretz34], (2) LncRRIsearch-rtools V.1.00 (https://rtools.cbrc.jp/LncRRIsearch/n.d) [Reference Fukunaga, Iwakiri, Ono and Hamada35], and (3) lncBase Module-DIANA TOOLS V.2 (https://diana.imis.athena-innovation.gr/DianaTools/n.d) [Reference Paraskevopoulou, Georgakilas and Kostoulas36]. Then, the regulatory network was built based on lncRNAs-miRNA-mRNA interaction pairs and visualized by PowerPoint (Microsoft, 2019) software.
2.4. Patients and Tissue Samples
In this study, samples were collected from 24 paired tumors and adjacent nontumor tissues after surgical resection (mean of the ages: 47 ± 12.59). After washing with distilled water, the tissues were immediately immersed in RNA-later (Yekta Tajhiz Azma, Iran). They were stored at −70°C before usage. None of the patients had previously received radiotherapy or chemotherapy. The pathological characteristics of patients were reviewed by the pathologist and summarized in Table 1. All patients signed written informed consents before the beginning of the study. In addition, study protocols in this experiment were approved by the Ethics Committee from Al-Zahra Hospital Isfahan University of Medical Sciences, based on the Helsinki Declaration of 1964.
2.5. Total RNA Extraction and Real-Time Quantitative Reverse Transcription PCR
The total RNA was extracted from tumor and normal tissues samples using YTzol Kit (YTzol Pure RNA, Yekta Tajhiz Azma, Iran). According to the manufacturer’s protocol, cDNA was synthesized using the cDNA Synthesis Kit (Takara, Japan). Specific PCR primers were designed using Oligo7 for the SFN gene, CCDC18-AS1, LINC01343, and GAPDH (listed in Table 2). Quantitative RT-PCR assay was performed using a real-time PCR instrument (Biomolecular Systems, Magnetic Induction Cycler (MIC), Australia). GAPDH was used as the housekeeping gene, and SFN CT (the cycle threshold) values were normalized with the CT value of GAPDH [Reference Jabbari, Nawaz and Rezaie37, Reference Sayar, Karahan, Konu, Bozkurt, Bozdogan and Yulug38].
2.6. Statistical Analysis
QRT-PCR data was analyzed using -ddCT method. Statistical analysis was performed using paired t-test and Wilcoxon test to compare and analyze expression data between BC and normal tissue samples using GraphPad Prism software version 8.0 (GraphPad Software, San Diego) and GenEx software (version 6). DEGs analysis was assessed using Bioconductor packages in RStudio software (version 4.0.2). GraphPad Prism also created receiver operating characteristic (ROC) curves. In addition, the Kruskal-Wallis test was performed for clinicopathological analysis. Spearman correlation test was performed to detect the correlation between lncRNAs and genes in BC. Survival curves were plotted using GEPIA2 [Reference Tang, Kang, Li, Chen and Zhang39]. In GSEA, FDR <0.25 and p ≤ 0.05 were considered statistically significant in all other analyses [Reference Sayar, Karahan, Konu, Bozkurt, Bozdogan and Yulug38, Reference Perkins, Dawes, Mcmahon, Bennett, Orengo and Kohl40].
3. Result
3.1. Gene Set Enrichment Analysis (GSEA) in Response to BC
To extract biological information, GSEA was used to analyze gene expression data. In this study, the upregulated genes were annotated from 34846 genes, which were extracted from the GSE71053 dataset and are available in Figure 1(a). Heatmap for DEGs was created by comparison of the high-score and low-score groups in BC. GSEA was performed against Kyoto Encyclopedia of Genes and Genomes (KEGG) or hallmark gene set signatures to get further information at the gene set level and the main implicated pathways (Figure 1(b)). According to the heatmap, GSEA presented that SFN is the highly enriched gene in BC samples (FDR <0.25). Besides, the P53 pathway was significantly enriched using GSEA of KEGG v99.0 (Figure 1(b)). Our findings demonstrate the important use of GSEA for gene expression analysis and highlight novel cancer cell signaling data.
3.2. Microarray Analysis
R software was used for the preparation, normalization, and utilization of the GSE71053 dataset. According to the results of the differentially expressed genes (DEGs) analysis using the “limma” and “affy” packages, SFN was selected as a significant differential expression gene (logFC = 0.8226, p = 0.02568) between upregulated DEGs in BC (Figures 2(a) and 2(c)). The quality of microarray samples was evaluated by principal component analysis (PCA) (Figure 2(b)).
3.3. Construction of the ceRNA Regulatory Network in BC
In this study, we used miRWalk V.2 [Reference Dweep, Sticht, Pandey and Gretz34], LncRRIsearch-rtools V.1.00 [Reference Fukunaga, Iwakiri, Ono and Hamada35], and DIANA-LncBase V.2 (DIANA Tools) [Reference Paraskevopoulou, Georgakilas and Kostoulas36] to construct a regulatory network in BC. First, we predicted the miRNAs that interacted with SFN (acquired from microarray and GSEA) using miRWalk V.2, and it was set based on a “0.95” score, “5UTR,” and “RNAhybrid.” Secondly, we used LncRRIsearch-rtools V.1.00 to assess the lncRNAs-mRNA interactions related to our mRNA, and finally, DIANA-LncBase Version 2 identified the lncRNA-miRNA interactions with 0.956 and 0.911 scores. Ultimately, we concluded the lncRNAs, miRNA, and mRNA interactions and created a lncRNA-related ceRNA network. In addition, using this method, the TP53 protein has been shown to coexpress (and thus interact) with the SFN protein (Figure 3) using String web V.11.5 (https://string-db.org/) [Reference Jensen, Kuhn and Stark41].
3.4. Expression Levels of SFN, lncRNAs CCDC18-AS1, and LINC01343 in BC
The expression of the SFN gene and two lncRNAs, including CCDC18-AS1 and LINC01343, was acquired based on bioinformatic as well as microarray analysis and assessed in tissue samples of BC (n = 24) and control (n = 24) using the qRT-PCR method. SFN gene expression in cancer tissues was significantly increased (p = 0.0001) in comparison to control tissues (Figure 4(a)). In addition, a significant elevation of CCDC18-AS1 and LINC01343 expression was observed in the cancer tissues as compared to control groups (p < 0.0001 and p = 0.0002, respectively) (Figures 4(b) and 4(c)). In other words, we identified higher expression of 2.366-fold of SFN (|LogFC| = 1.243), 12.915-fold of LINC01343 (|logFC| = 3.691), and 10.584-fold of CCDC18-AS1 (|logFC| = 3.397) in the cancer tissue in comparison to the control group.
3.5. Diagnostic Performance of Studied mRNA and lncRNAs for BC Detection
To assess the potential of lncRNAs and mRNA as diagnostic biomarkers for assessing the health or disease status, these lncRNAs and mRNA were analyzed using RT-PCR by the receiver operating characteristic (ROC) analysis in both groups. The ROC curve analysis revealed SFN gene as a potential biomarker (AUC: 0.7222, p = 0.0083), the LINC01343 gene as a good biomarker (AUC: 0.7951, p = 0.0005) in discriminating BC patients from healthy individuals, and the CCDC18-AS1 gene as the strongest biomarker (AUC: 0.8958, p < 0.0001) (Figures 5(a)–5(c)). These findings highlight each of the three genes as a promising screening tool in different respects.
3.6. lncRNAs Expression Level is Positively Correlated in BC
In order to explore the relationship between SFN, LINC01343, and CCDC18-AS1, the correlation between each of the three mRNAs in BC was investigated. It was found that there is a significant (positive) correlation between LINC01343 expression levels and CCDC18-AS1 (r = −0.4119, p = 0.0455). This implies that the higher expression of CCDC18-AS1 lncRNA was linked with the increased expression of LINC01343 in BC patients (Figure 6).
3.7. Clinicopathological Analyses in BC Sample Tissues
We further investigated whether the expression levels of SFN, LINC01343, and CCDC18-AS1 are statistically related to the clinical features of BC. Our findings are that the expression of SFN gene was significantly higher in the BC tissues with tumor size less than 5 cm and also in nonmenopause ages compared to the normal group (p = 0.0207 and p = 0.0145, respectively) (Figures 7(a) and 7(b)). As shown in Figures 7(c) and 7(d), no significant difference in the expression of lncRNAs was observed in early stage of BC when comparing normal and tumor tissues, while the expression of the CCDC18-AS1 was significantly increased in stages II-III of disease compared to the control group (|−dct| = 1.5 and 2, respectively, and p < 0.0001). On the other hand, LINC01343 also showed significant overexpression at stage III of BC (|−dct| = 4 and p = 0.0032), as well as nonmenopause ages (|−dct| = 4 and p = 0.0024) compared to the control group (Figure 7(d) and 7(e)).
3.8. Survival Analysis
GEPIA (Gene Expression Profiling Interactive Analysis) web server provides publicly available, customized analysis for gene expression analysis based on TCGA, GTEx, and RNA-seq databases from tumor and normal samples (https://gepia.cancer-pku.cn/) [Reference Tang, Kang, Li, Chen and Zhang39]. Using this database, we performed differential expression analysis related to the SFN gene and CCDC18-AS1 for patients with BC. In the expression analysis, the overall survival anticipated that patients who had positive SFN expression survived significantly more than patients who had negative SFN expression (p value = 0.34, Figure 8(a)). Furthermore, patients in the CCDC18-AS1 negative group had better survival than patients with positive CCDC18-AS1 expression (p value = 0.36, Figure 8(b)).
4. Discussion
BC remains a major threat to the health of women in all ages and is the second leading cause of malignant death worldwide [Reference Majeed, Aslam and Javed42]. Therefore, identifying the molecular factors and mechanisms underlying the development and progression of BC may be effective in early diagnosis and (timely) targeted treatment of these patients.
A large number of studies highlighted that the interactions between lncRNAs, miRNAs, and mRNAs constitute specific regulatory networks and influence genes expression in cancer [Reference Müller, Raulefs and Bruns43, Reference Zhang, Liu, Li and Le44]. In this study, by using several bioinformatics tools, we predicted the lncRNA-miRNA-mRNA regulatory network and proposed a novel ceRNA regulatory network (CCDC18-AS1, LINC01343, hsa-miR-4462, SFN) underlying BC pathophysiology. Traditionally, lncRNAs have been considered as a “sponge” or competitive endogenous RNA (ceRNA), interacting with miRNA, and decrease the inhibition effect of miRNAs on mRNAs [Reference Raziq, Cai, Dong, Wang, Afrifa and Fu45]. Therefore, this study suggests that CCDC18-AS1 can control SFN gene expression by repressing hsa-miR-4462, whereas LINC01343 can directly targets the SFN gene [Reference Fukunaga, Iwakiri, Ono and Hamada35].
Following the identification of SFN as a potentially upregulated gene in BC (based on GSEA and microarray analysis) we also showed a potential interaction of SFN with CCDC18-AS1 and LINC01343 based on in silico protein-protein interaction. Our experimental analysis also revealed high expression of SFN, CCDC18-AS1, and LINC01343, supporting the oncogenic activities of these factors in the context of BC pathophysiology. Last but not least, our analyses indicated the high expression of CCDC18-AS1 and LINC01343 in BC at stages II-III and III, suggesting that the dysregulation of these factors may play a role implicated in both tumor invasion and metastasis. In contrast, high expression of SFN in tumors of size <5 cm can present its oncogenic effect in very early stages of BC, such as tumor initiation.
A study of colorectal carcinoma (CRC) has reported a negative correlation between CCDC18-AS1 and downregulated BGs (bait genes), suggesting that CCDC18-AS1 may be a potential oncogenic lncRNA associated with CRC [Reference Brex, Barbagallo and Mirabella9]. Moreover, our results also showed that CCDC18-AS1 could be a potential biomarker in BC and that patients with negative expression of CCDC18-AS1 have a better survival compared to patients with positive expression of CCDC18-AS1.
LINC01343 has been shown to be associated with type 2 diabetes (T2D) and coronary artery disease (CARD) [Reference Zhang, Liu and Lv46]. Consistent with the bioinformatics data, the upregulation of LINC01343 detected by qRT-PCR in our study may indicate its possible role in BC pathophysiology. In addition, our findings presented LINC01343 as a promising biomarker in BC which may be a hallmark for diagnosis and treatment of patients in the future.
It has been shown that lncRNAs exert their role as tumor suppressor or oncogene through interaction with miRNAs and mRNAs [Reference Brex, Barbagallo and Mirabella9, Reference Yu, Xiang and Jia47]. In our study, CCDC18-AS1 and LINC01343 affect SFN gene and regulate its expression and function. SFN is one of the members of the 14-3-3 family, which is known as human mammary epithelial cell marker (HME-1) and has been directly associated with cancer. SFN has been reported to function as a tumor suppressor gene whose functional inactivation may be associated with tumorigenesis. Several studies support this hypothesis and have demonstrated downregulation of the SFN gene in several human cancers, including breast [Reference Shiba-Ishii and Noguchi48], ovaries [Reference Mhawech, Benz and Cerato49], lung [Reference Osada, Tatematsu and Yatabe50], liver [Reference Iwata, Yamamoto and Sasaki51], prostate [Reference Oh, Shin, Lightfoot and Janknecht52], and oral cavity [Reference Meeran, Patel and Tollefsbol53]. However, many conflicting studies have represented upregulation of SFN in the head and neck [Reference Rotondo, Lanzillotti, Mazziotta, Tognon and Martini14], gastric [Reference Mühlmann, Öfner and Zitt54], pancreas [Reference Neupane and Korc55], and colorectal cancers [Reference Perathoner, Pirkebner and Brandacher20]. In our study, the SFN gene was also abnormally overexpressed in BC samples, defining SFN as an oncogene and a biomarker in BC. Similar to our results, studies have also reported that overexpression of SFN can be used as a better prognostic biomarker in gallbladder cancer [Reference Sirivatanauksorn, Dumronggittigule and Dulnee22] and the stroma of pancreatic ductal adenocarcinoma (PDAC) treatment [Reference Syren, Andersson, Bauden and Ansari56]. In patients with esophageal squamous cell carcinoma (ESCC), a low level of SFN is associated with a poorer prognosis and survival rate [Reference Ren, Pan and Wang57]. Our analysis also showed the shorter overall survival in patients with low expression of SFN in BC. Furthermore, SFN could be positively implicated as an oncogene in a variety of diseases, including Alzheimer’s disease, Parkinsonian syndromes, and autoimmune disorders affecting the central nervous system [Reference Dou, Zhou and Li58].
Considering the direct contribution of SFN to the cancer development, it seems that several molecular landscapes may control its downstream expression. P53, an important tumor suppressor gene, may be among the most important regulators of SFN expression [Reference Sullivan, Galbraith, Andrysik and Espinosa59]. Activation of p53 in response to cellular DNA damage and its direct binding to the promoter region leads to transactivation of SFN expression. Subsequently, SFN regulates the cell cycle by triggering G1/S mediated by p21. SFN specifically affects Cdk1/cyclin B1, cyclin-dependent kinase-2, and cyclin-dependent kinase-4 (CDK2, CDK4) and prevents cells from entering mitosis [Reference Lodygin and Hermeking28]. SFN negatively regulates the cell cycle and suppresses tumor. Overall, SFN exerts the tumor suppressor effects arresting the cell cycle by two different mechanisms: (a) by inhibiting the formation of the Cdc2-cyclin B1 complex (via the G2/M checkpoint) or (b) by blocking MDM2 (preventing MDM2-mediated ubiquitination of p53) [Reference Yang, Wen, Chen, Lozano and Lee60].
On the other hand, it was reported that SFN could have positive effects on the cell cycle and also accelerate cell proliferation. Zhang et al. illustrated that SFN is a positive mediator of IGF-I receptor-induced cell proliferation. SFN interacts with the PI3K/Akt pathway independently of p53 and promotes the cell cycle progression in MCF-7 BC cells. Moreover, upregulation of the SFN gene was associated with an increase in cyclin D1 level in MCF-7 cells, shortening the duration of G1 phase, and accelerating the cell cycle [Reference Zhang, Karas, Zhao, Yakar and LeRoith61]. Furthermore, SFN could positively contribute to the activation of receptor tyrosine kinases (RTKs) and prevent its degradation [Reference Wu, Fan and Lang62], leading to increase in the activation of the RTKs signaling pathway and induction of different cellular processes such as proliferation, growth, motility, and differentiation [Reference Du and Lovly63]. Accordingly, increased SFN levels appear to be associated with upregulation of p-Akt and cyclin D1, leading to the cell cycle progression [Reference Wu, Fan and Lang62]. In addition, elevated p-Akt level in response to the SFN can also be involved in tumorigenesis through activation of MDM2 and inhibition of p53 [Reference Ogawara, Kishishita and Obata64]. Furthermore, silencing of SFN is associated with the upregulation of proapoptotic proteins (Bim and Bax) in cholangiocarcinoma cells, suggesting the oncogenic potential of SFN through inhibition of apoptosis [Reference Wu, Fan and Lang62]. Moreover, the antiapoptotic function of SFN may be associated with its inhibitory interaction with Bad and Bax (both proapoptotic proteins) [Reference Guweidhi, Kleeff and Giese65].
As we have shown in Figure 9, upstream signaling pathways of IGF1 and RTKs can increase SFN level and activity in cancer cells [Reference Zhang, Karas, Zhao, Yakar and LeRoith61, Reference Wu, Fan and Lang62]. SFN can sequester phosphorylated Bad in the cytosol, thus preventing apoptosis exerted by Bad [Reference Guweidhi, Kleeff and Giese65]. In addition, SFN can increase the cyclin D1 level and accelerate the cell cycle and proliferation [Reference Zhang, Karas, Zhao, Yakar and LeRoith61]. Consequently, the accumulation of SFN can be proposed as a hallmark of BC. However, the direct role of SFN in inhibiting apoptosis and the cell cycle progression was not investigated in our study.
To better understand this ceRNA network, a significant correlation between CCDC18-AS1 and LINC01343 lncRNAs was observed experimentally, which could bioinformatically establish the interaction of these lncRNAs with SFN, which may induce the oncogene effect of SFN gene in the p53 pathway in the BC process. In this experiment, there were some drawbacks, such as limited access to human clinical samples and investigation of high-throughput genes within the study, and some of our graphs were obtained from the GEPIA2 online database, such as patients’ survival. For future studies, we recommend that the expression level of SFN, CCDC18-AS1, and LINC01343 be examined in animal samples to determine the accurate expression pattern of these lncRNAs and SFN gene in BC.
5. Conclusion
Our study reported overexpression of SFN, CCDC18-AS1, and LINC01343 in BC tissues, which could describe them as novel and promising biomarkers for BC diagnosis. These findings could lead to a new understanding of the clinical significance of lncRNA-mediated ceRNA networks as potential prognostic biomarkers and therapeutic targets of BC. Nevertheless, these results need to be validated and confirmed by using a range of detailed statistical approaches in larger sample cohorts. According to the various downstream partner interaction changes, SFN does not seem to perform its crucial operations, in particular antiapoptotic action and maintenance of the G2 checkpoint. The identification of alternative molecular pathways in which SFN, CCDC18-AS1, and LINC01343 contribute to timely diagnosis of BC which may provide novel approaches for the prognosis and treatment of BC. Therefore, for future studies, investigating the exact molecular pathways of SFN, CCDC18-AS1, and LINC01343 in cancer may shed new light on the important and emerging role and function of these factors in tumorigenesis and lead to newer approaches for both the diagnosis and treatment of BC. Due to the limited data available on CCDC18-AS1 and LINC01343, functional studies on these lncRNAs will help to unravel their role at the cellular level in both health and diseases, which could also provide potentially useful information for BC diagnosis and treatment.
Data Availability
The data used to support the findings of this study are available from the corresponding author upon request.
Conflicts of Interest
The authors declare that there are no conflicts of interest.
Authors’ Contributions
Mansoureh Azadeh supervised the research. Mehrnoush Rishehri, Tahereh Etemadi, Leila Pisheh, and Ghazaleh Koufigar contributed equally as co-first authors and carried out the whole experiment and analysis and wrote the paper. All authors contributed to the article and approved the submitted version.
Acknowledgments
The authors are heavily indebted to Prof. Vincenzo Salpietro Damiano (Department of Human and Molecular Genetics at the University of Genova) for invaluable discussion and critical reading of the manuscript. The authors thank Mrs. Shadi Omidghaemie and Mr. Mohammad Rezaei for their friendly helps.