eISSN: 1897-4309
ISSN: 1428-2526
Contemporary Oncology/Współczesna Onkologia
Current issue Archive Manuscripts accepted About the journal Supplements Addendum Special Issues Editorial board Reviewers Abstracting and indexing Subscription Contact Instructions for authors Publication charge Ethical standards and procedures
Editorial System
Submit your Manuscript
SCImago Journal & Country Rank
Search
Editorial Policies
Sarajevo Declaration on Integrity and Visibility of Scholarly Publications
2/2020
vol. 24
 
Share:
Send email
Share:
Original paper

The role of NEAT1 lncRNA in squamous cell carcinoma of the head and neck is still difficult to define

Joanna Kozłowska
1
,
Kinga Kozioł
1
,
Maciej Stasiak
1
,
Justyna Obacz
1
,
Kacper Guglas
2, 3
,
Paulina Poter
4, 5
,
Andrzej Mackiewicz
1, 6
,
Tomasz Kolenda
1, 6

  1. Department of Cancer Immunology, Chair of Medical Biotechnology, Poznan University of Medical Sciences, Poznan, Poland
  2. Laboratory of Cancer Genetics, Greater Poland Cancer Centre, Poznan, Poland
  3. Postgraduate School of Molecular Medicine, Medical University of Warsaw, Warsaw, Poland
  4. Department of Oncologic Pathology and Prophylaxis, Poznan University of Medical Sciences, Greater Poland Cancer Centre, Poznan, Poland
  5. Department of Pathology, Pomeranian Medical University, Szczecin, Poland
  6. Department of Diagnostics and Cancer Immunology, Greater Poland Cancer Centre, Poznan, Poland
Contemp Oncol (Pozn) 2020; 24 (2): 96-105
DOI: https://doi.org/10.5114/wo.2020.97635
Online publish date: 2020/07/03
Article file
- The role.pdf  [0.24 MB]
Get citation
 
PlumX metrics:
 

Introduction

Head and neck squamous cell carcinoma (HNSCC) is the ninth leading type of cancer in the world by incidence, which causes over 90% of epithelial-origin tumours localised in the upper aerodigestive tract [1]. The major risk factors for the development are environmental carcinogens, excessive alcohol and tobacco consumption, and human papillomavirus (HPV) infections [1] – which are driving an increase in HNSCC incidence among younger, non-smoking patients [1]. HNSCC has a high rate of mortality due to metastasis to the regional lymph nodes [2], the tendency to subsequently relapse, and resistance to therapy [3]. However, it has been proven that undergoing an HPV infection is associated with a better prognosis compared to HPV-negative HNSCC patients [1]. Multiple studies have shown that deregulation of different non-coding RNAs (ncRNAs) has an important impact on HNSCC pathology, and they could be used as specific biomarkers in personalised medicine to improve the treatment [4].

Nuclear paraspeckle assembly transcript (NEAT1) is a recently discovered molecule with a critical role in cancer biology [5]. The NEAT1 gene is located on the 11q13.1 chromosome and belongs to the family of ncRNAs of more than 200 nucleotides in length [5, 6]. Although this molecule does not code a protein, it has a very important structural and regulatory function and is a part of complex machinery involving multiple RNA-binding proteins (RBPs) [7, 8], which act as fundamental regulators of gene expression, probably through retention of different molecules in nuclear structures called paraspeckles [8]. NEAT1 also acts as a molecular sponge and regulates the abundance and availability of miRNAs in the cellular environment [911]. In recent years, there have been many reports regarding the activity of NEAT1 as an oncogene that promotes proliferation [1113], inhibits apoptosis and cell cycle arrest [11], regulates blood-tumour barrier permeability, participates in mesenchymal-epithelial transition leading to metastasis, and tumour sensitivity to chemotherapeutics [14, 15]. In addition, NEAT1 promotes the growth of cancer cells, even under hypoxic conditions, and is overexpressed in a wide spectrum of solid tumours resulting in unfavourable overall survival (OS) [11, 14, 1629] and downregulated in haematological malignancies [30].

In this study, we have analysed the expression of NEAT1 in HNSCC patients’ samples and in HNSCC cell lines as well as using data taken from The Cancer Genome Atlas project. Furthermore, we investigated the correlations between the levels of NEAT1 and some of its target genes in HNSCC patients to determine the role they play in cancer biology.

Material and methods

HNSCC cell lines and patients’ samples

The HNSCC cell lines: SCC-040 (oral cancer model), SCC-25 (tongue cancer model), FaDu (hypopharyngeal cancer model), CAL27 (tongue cancer model), and DOK (dysplastic oral keratinocyte cells from a tongue as a model of healthy tissue) were used for the study and cultivated as described previously [31]. Patients’ RNA samples, tumour and matched adjacent normal, were taken from a previous study [31]. Expression levels of NEAT1 (family) in cell lines and patients’ samples were measured using lncProfiler qPCR Array Kit (SBI) and SYBR Green 2x Master Mix (Roche) as described previously [32]. All real-time PCR data were analysed by calculating the 2-ΔCT, normalising against the mean of reference genes (18S rRNA, RNU43, GAPDH, LAMIN A/C, U6) from the quantification plate.

TCGA data

TCGA expression data of lncRNA NEAT1, as well as the clinical data, were downloaded from the University of California Santa Cruz, cBioPortal, and the UALCAN databases. The above expression values were presented as RNAseq (pan-cancer normalised log2 [norm_count+1]) and mRNA expression z-scores (RNA Seq V2 RSEM).

Data analysis

The expression levels of lncRNA NEAT1 were analysed in all HNSCC sample localisations depending on the clinicopathological parameters, such as age (< 61 vs. > 61), gender (female vs. male), alcohol consumption (positive vs. negative), smoking regularly (no/ex vs. yes), cancer stage (I + II vs. III + IV), T-stage (T1 + T2 vs. T3 + T4), N-stage (N0 vs. N1 + N2 + N3), cancer grade (G1 + G2 vs. G3 + G4), perineural invasion (positive vs. negative), lymphoid node neck dissection status (positive vs. negative), HPV p16 status (negative vs. positive), and angiolymphatic invasion (positive vs. negative). The expression level of NEAT1 was also analysed depending on tumour localisation (oral cavity vs. pharynx vs. larynx). The average value of NEAT1 expression was determined in a group of 566 patients, and subgroups were selected based on its high (n = 284) and low (n = 282) expression. Next, relapse-free survival (RFS) and overall survival (OS) were analysed in these subgroups.

Genes correlated with NEAT1

Genes positively and negatively correlated with NEAT1 (Spearman’s correlation > +0.3 or < −0.3, respectively) were obtained from cBioportal (TCGA) and analysed using the REACTOME pathway tool [33].

Functional enrichment analysis and prediction of gene function

Gene set enrichment analysis (GSEA) software version 3.0 was used for the analysis of functional enrichment, as described previously [34, 35]. HNSCC patients were divided into two groups with high and low expression of NEAT1. The input file contained expression data for 20530 genes and 565 patients. The 1000 gene set permutations for the analysis and pathways (the oncogenic signatures [C] and hallmark gene sets [H] and collection from MSigDB) was used, and a nominal p-value ≤ 0.05 and false discovery rate (FDR) ≤ 0.25 were considered as significant. Next, the interactions between protein-encoding genes in the pathway, which were the most significantly enriched in a group of patients with low vs. high NEAT1 expression, were analysed using the GeneMANIA prediction tool [36].

Statistical analysis

All statistical analyses were performed using GraphPad Prism 5 (GraphPad, San Diego, CA,USA) and Statistica 13 (StatSoft Polska). The t-test, Mann-Whitney U test, or one-way ANOVA test were used in analysed subgroups depending on the data normality, which was assessed using the Shapiro-Wilk normality test. In all analyses, p < 0.05 was used as statistically significant. The RFS and OS analyses were carried out using the log-rank (Mantel-Cox) and Gehan-Breslow-Wilcoxon tests, respectively.

Results

NEAT1 was up-regulated only in some HNSCC patients’ samples and cell lines

First, the NEAT1 expression was checked in patients’ samples and five HNSCC cell lines. Only in the case of a few patients were upregulation (fold change 2.15–34.73) and downregulation (fold change 0.27–0.48) of NEAT1 (family) observed in tumours, compared to the matched adjacent normal samples (0.1348 ±0.2974 vs. 0.0886 ±0.2910; p = 0.5842) (Figs. 1A and 1B). Moreover, only in the case of two aggressive cell lines, FaDu and SCC-040, was significant up-regulation of NEAT1 (family) expression compared to the dysplastic oral keratinocyte (DOK) cell line observed (p = 0.0154 and p = 0.0479, respectively) (Fig. 1C).

Fig. 1

The expression level of NEAT1 (family) in HNSCC patients’ samples (A and B) and in HNSCC cell lines (C) that display different morphology (D); paired t-test, ns – not statistically significant, * p < 0.05; microscopic pictures of FaDu, SCC-040 and dysplastic oral keratinocyte (DOK) cell lines, 20× magnification

/f/fulltexts/WO/41417/WO-24-97635-g001_min.jpg

Compared to normal tissues, NEAT1 is up-regulated in most cancers, including HNSCC

Next, the NEAT1 expression level was checked across 24 different cancers analysed during the TCGA project. In the squamous cell carcinomas, the highest fold change (1.22) of NEAT1 was observed for cervical squamous cell carcinoma (CESC) and the lowest for lung squamous cell carcinoma (LUSC; 0.96); in the case of HNSCC, a 1.17-fold change was indicated. In the group of adenocarcinomas, the greatest fold change of NEAT1 was observed for prostate adenocarcinoma (PRAD; 1.24) and the lowest for rectum adenocarcinoma (READ; 1.01). In the group of other cancers, the greatest fold change of NEAT1 was observed in sarcoma (SARC; 1.24) and the lowest in thymoma (THYM; 0.77). All results are presented in Figure 2.

A significant up-regulation of NEAT1 expression in HNSCC relative to normal samples was observed (68.332 vs. 38.350 transcripts per million; p = 0.0004) (Fig. 3A). Next, based on the National Institute of Health (NIH) classification, patients were divided into three groups according to the localisation of HNSC: oral cavity (n = 346), pharynx (n = 92), and larynx (n = 128). Subsequently, the levels of NEAT1 expression were analysed. No significant differences between tumours in various localisations were observed (p = 0.5058) (Fig. 3B).

Fig. 2

Expression of NEAT1 across 24 TCGA cancers. Graph from UALCAN database, modified; fold change was estimated based on median expression in tumour samples versus normal samples (BLCA – bladder urothelial carcinoma, BRCA – breast invasive carcinoma, CEST – cervical squamous cell carcinoma, CHOL – cholangiocarcinoma, COAD – colon adenocarcinoma, ESCA –esophageal carcinoma, GBM – glioblastoma multiforme, HNSC – head and neck squamous cell carcinoma, KICH – kidney chromophobe, KIRC – kidney renal clear cell carcinoma, KIRP – kidney renal papillary cell carcinoma, LIHC – liver hepatocellular carcinoma, LUAD – lung adenocarcinoma, LUSC – lung squamous cell carcinoma, PAAD – pancreatic adenocarcinoma, PRAD – prostate adenocarcinoma, PCPG – pheochromocytoma and paraganglioma, READ – rectum adenocarcinoma, SARC – sarcoma, SKCM – skin cutaneous melanoma, THCA – thyroid carcinoma, THYM – thymoma, STAD – stomach adenocarcinoma, UCEC – uterine corpus endometrial carcinoma)

/f/fulltexts/WO/41417/WO-24-97635-g002_min.jpg
Fig. 3

Expression of NEAT1 in HNSCC patients. A) Expression in normal (n = 44) and tumour (n = 520) tissues. B) Expression in various HNSCC localisations (n = 566). Graph A from UALCAN database, modified, *** p ≤ 0.001, ns – not statistically significant

/f/fulltexts/WO/41417/WO-24-97635-g003_min.jpg

The expression levels of NEAT1 differ based on patients’ smoking status

Expression levels of NEAT1 were analysed, determined by group division depending on available clinicopathological parameters in all HNSCC samples. The only significant difference between expression levels of NEAT1 was observed in patients who either smoked regularly or were ex-smokers/non-smokers (p = 0.005), but it is worth noting that there was a considerable difference in the number of patients in these groups (n = 221 vs. n = 20). Other parameters that were analysed did not show any differences between various groups. All data are presented in Table 1.

Table 1

NEAT1 expression levels are dependent on clinicopathological parameters in all localisations of HNSCC

ParameterGroupMean ±SEMCasesp-value
Age< 61 years–0.5152 ±0.073092990.8663
> 61 years–0.5330 ±0.07644266
GenderFemale–0.4300 ±0.10821510.2811
Male–0.5585 ±0.06014415
AlcoholPositive–0.5629 ±0.062073710.5075
Negative–0.4879 ±0.1002182
Smoking regularlyNo/Ex–0.5589 ±0.081402210.0050
Yes0.2366 ±0.249420
Cancer stageI + II–0.6507 ±0.11621350.2373
III + IV–0.5045 ±0.05941417
T stageT1 + T2–0.6108 ±0.089882060.3402
T3 + T4–0.5059 ±0.06589344
N stageN0–0.5015 ±0.079502760.3633
N1 + N2 + N3–0.5990 ±0.07149267
GradeG1 + G2–0.4769 ±0.062893980.1091
G3 + G4–0.6737 ±0.1051142
Perineural invasionPositive–0.5520 ±0.096051860.8610
Negative–0.5302 ±0.08036207
Lymph node neck dissectionPositive–0.4843 ±0.058434510.1874
Negative–0.6588 ±0.1228112
HPV p16 statusNegative–0.5673 ±0.1387750.2701
Positive–0.3218 ±0.152039
Angiolymphatic invasionPositive0.06404 ±0.083791250.5322
Negative–0.004396 ±0.06698225

Patients with high NEAT1 expression display slightly better overall survival with close to statistical significance

Next, to determine if lncRNA NEAT1 could be used as a prognostic biomarker, HNSCC samples were divided into low and high NEAT1 expression groups using the mean of NEAT1 expression in all samples as a cut-off. A slightly longer OS of patients with low NEAT1 expression was observed (p = 0.0553). However, there was no difference in RFS time between patients with low and high NEAT1 expression levels (p = 0.6478) (Fig. 4). Moreover, no statistically significant differences in OS and RFS in the case of patients divided into subgroups according to tumour localisation (oral cavity, pharynx, and larynx) were observed (data not shown).

Fig. 4

Relapse-free survival (A) and overall survival (B) of HNSCC patients in groups with low/high expression of NEAT1

/f/fulltexts/WO/41417/WO-24-97635-g004_min.jpg

Genes correlated with NEAT1 are involved in mRNA metabolism and cellular transport

Genes correlated with NEAT1 (Spearman’s correlation > +0.3 or < −0.3, respectively) were analysed, and expressions of 859 were positively (p < 0.05) and 112 negatively (p < 0.05) connected with analysed lncRNA. Analysis of genes positively correlated with NEAT1 indicated that they are involved mostly in mRNA metabolism (transcription, maturation, and transport). For genes negatively correlated, involvement in protein transport and modification as well as membrane trafficking and vesicle-mediated transport was indicated, Figure 5.

Fig. 5

Positive and negative correlation of NEAT1 with genes involved in the important cellular processes. Only genes with Spearman’s correlation > 0.3, < –0.3 and p < 0.05 were indicated in REACTOME pathway analysis

/f/fulltexts/WO/41417/WO-24-97635-g005_min.jpg

Patients with high and low expression of NEAT1 have a different pattern of genes

The functional implications of NEAT1 expression signature were investigated using gene set enrichment analysis (GSEA), and the six top enriched datasets are shown in Figure 6A. It was found that the most up-regulated genes in the NEAT1 low-expressing group of patients were clustered most significantly in the cAMP (the cAMP-dependent pathway), the MYC pathway, the unfolded protein response, the MTORC1 signalling pathway, the oxidative phosphorylation, and DNA repair (NES = 1.745, 1.673, 1.766, 1.470, 1.630, and 1.631, respectively). We identified 66 genes in the cAMP-dependent pathway, 54 genes in MYC pathway, 44 genes in unfolded protein response, 59 genes in the MTORC1 signalling pathway, 91 genes in oxidative phosphorylation, and 67 genes in DNA repair, of which 73.40%, 70.28%, 48.90%, 70.65%, 71.98%, and 54.54% were co-expressed, respectively (Fig. 6B).

Fig. 6

GSEA results of HNSCC patients analysed in groups with low (red)/high (violet) expression of NEAT1. A) GSEA plots of the most enriched datasets, NES (normalised enrichment score), p-value (nominal p-value), FDR q-value (false discovery rate). B) Interactions between protein-encoding genes in the pathways, which were the most enriched in a group of patients with low vs. high expression of NEAT1

/f/fulltexts/WO/41417/WO-24-97635-g006_min.jpg

Discussion

NEAT1 belongs to the highest regulated lncRNAs among various types of cancer [16]. Moreover, high levels of lncRNA NEAT1 were positively correlated with poor OS [5, 13, 19], cancer stage, and metastasis in the head and neck area, such as in oesophageal and laryngeal squamous cell carcinoma [20, 37]. This molecule can be found in high levels in the cell’s nucleus and cytoplasm [38], where it might induce apoptosis or promote invasion [27], stem cell-like phenotype, epithelial-to-mesenchymal transition (EMT), and resistance to various therapies [14]. Accordingly, NEAT1 might prove a good, prognostic biomarker of HNSCC. Thus, the elucidation of the NEAT1 expression in HNSCC patients’ samples, cell lines, and TCGA data were analysed. Moreover, the NEAT1 network and its target genes, patients’ clinicopathological parameters, and the impact of these interactions on disease pathogenesis data from TCGA databases were used.

The first important finding was that NEAT1 was up-regulated in some HNSCC patients’ samples and in invasive cell lines. However, the TCGA data indicated significant up-regulation of NEAT1 in HNSCC tissue compared to the healthy samples. Moreover, significant differences in the expression levels between cancers localised in the oral cavity, pharynx, or larynx were seen. In contrast to Chen et al., we did not observe the association of high NEAT1 expression with tumour stage [20]. Moreover, we only found a statistically significant difference between the groups of smokers and non-smokers. However, the disproportion in the number of patients in these subgroups was substantial. Information from databases provides the opportunity to analyse a large number of patient phenotypes, but this also makes it impossible to select more evenly distributed subgroups of individuals, which is a limitation of this study. Only the OS analysis of HNSCC patients detected a difference close to statistical significance. Surprisingly, patients with higher expression of NEAT1 tend to present slightly better survival outcomes. This is interesting because our results contradict other reports of the negative impact of high NEAT1 expression levels on patients’ survival [5, 11, 12, 1618, 2022, 2527, 29, 37].

Indeed, in our analysis, we used data for which the NEAT1 isoforms present in the samples were not distinguished. In recent years, there has been growing evidence indicating the need to analyse lncRNA NEAT, not as a whole but considering its two isoforms, NEAT1_1 (3.7kb) and NEAT1_2 (22.7kb), which seem to display completely distinct roles in cancer pathogenesis [8, 39]. Wu et al. proposed that in colorectal cancer, NEAT1_1 might act as an oncogene, promoting cell proliferation, while NEAT1_2 was pivotal for paraspeckle formation [8] and might play a suppressor role [40]. Moreover, comparing the expression of these isoforms in liver metastatic lesions with adjacent normal colorectal tissue and primary colorectal tumour demonstrated significant overexpression of NEAT 1_1 in metastatic tissue [40]. In mice, Nakagawa et al. showed that the expression of lncRNA NEAT1 isoforms is tissue-specific, which might indicate a variable ratio of these molecules in different types of cancers [41]. These changes might occur dynamically, leading NEAT1 to take on oncogene or tumour suppressor functions [39]. Accordingly, the association of high NEAT1 expression with patient survival observed in our study might be due to the greater amount of NEAT1_2 over NEAT1_1. However, we have no direct evidence to validate the finding (hypothesis) because access to the entire TCGA data is restricted. Moreover, in multiple studies of NEAT1 expression in cancer tissues, the issue of its isoforms was either not investigated or not reported [5, 6, 20, 27, 29]. Our analyses highlight the contribution of isoforms of the above lncRNA to cancer pathogenesis and indicate that it is an important aspect that should be further studied.

One of the key factors contributing to the effect of NEAT1 expression levels on tumour development is its interaction with the p53 protein. Interestingly, NEAT1 is a direct transcriptional target of p53, which is a suppressor that is mutated in approximately half of the human cancers [42]. Idogawa et al. analysed the effect of NEAT1 expression level on the prognosis of patients subgroups with and without mutations in the TP53 gene [43]. These authors confirmed their previously formulated thesis, which assumed that NEAT1 supports the suppressor function of the p53 protein. However, this statement seems to apply to wild-type TP53 only, because its mutation alters the function of lncRNA NEAT1, which becomes an oncogene and promotes tumour proliferation. Moreover, in an analysis of the survival probability of patients with 32 types of cancers, 11 of them with high levels of NEAT1 and wild-type TP53 showed longer survival [43]. Moreover, the higher expression of NEAT1 was observed by us in FaDu cell line, which has mutation in TP53 (missense mutation in codon 248), CAL27 (missense mutation in codon 193), SCC-25 and SCC-040 are wild type, but some data indicate mutation in the case of SCC-25 cell line [44, 45]. It should be noted that the frequently used DOK cell line also possesses changed TP53 [46]. In spite of this, data from the UALCAN database indicated no significant differences in NEAT1 expression levels depending on TP53 status in HNSCC. We suspect that TP53 changes the biological function of NEAT1 rather than its expression level. The in vitro analysis of the biological role of NEAT1 depending on different mutations in TP53 should explain this phenomenon in the future.

In mice, Mello et al. indicated that NEAT1 is induced by DNA damage, and its overexpression can suppress transformation in various cell types due to an increase in the number of paraspeckles [47]. The relationship between NEAT1 and TP53 expression is ambiguous for all types of cancers, thus requiring more extensive research.

To better understand the lncRNA NEAT1 interaction network, including its target genes, we checked the gene correlation and we used GSEA. We found that positively correlated genes are connected with mRNA metabolism, and in the case of negatively correlated genes they are connected with cellular transport. Moreover, in patients with low levels of NEAT1, the most enriched genes were clustered in the cAMP-dependent pathway, the MYC pathway, the unfolded protein response, the MTORC1 signalling pathway, oxidative phosphorylation, and DNA repair in a group of patients with low levels of NEAT1. Here, it should be emphasised that we indicate that patients with low NEAT1 expression levels have a worse OS compared to patients with high NEAT1 expression.

The cAMP-dependent pathway is enriched in HNSCC patients with low NEAT1 expression, which is an important signal transduction pathway connecting the internal environment of the cell with external stimuli, such as hormones or cytokines [48]. It has been proven that, with impaired expression, this second messenger has oncogene properties that are responsible for the activation of protein kinase A in selective epithelial tumours [49, 50].

MYC is a proto-oncogene whose expression (under physiological conditions) is strictly controlled by genetic and epigenetic mechanisms [51]. In most cancers, there is pathological activation or overexpression of MYC [52], resulting in cancer growth, inducing stemness, and promoting angiogenesis [51]. It has been demonstrated that following the loss of p53 suppressor function, the MYC protein promotes tumourigenesis [53].

Low expression of lncRNA NEAT1 is also associated with the up-regulation of genes involved in the unfolded protein response. This pathway is responsible for preventing the negative effects of improper protein folding, which acts cytoprotectively not only on healthy cells but also on some cancer cells [54, 55].

The MTORC1 signalling pathway is a complex network involved in the activation of protein synthesis and the promotion of cell growth [56, 57]. Disturbed activation of this pathway in tumours leads to better survival and excessive proliferation [58].

Oxidative phosphorylation (OXPHOS) genes are also overexpressed in a subgroup of patients with low levels of NEAT1. It has been shown that hypoxia present in the tumour of the HNSCC plays a major role in cancer biology and is promoted by OXPHOS up-regulation [59, 60].

Also, patients with low NEAT1 expression had enriched expression of genes involved in DNA repair. The up-regulation of DNA damage response genes leads to resistance to treatment and the development of the ability to metastasise [61, 62].

To summarise, the influence of lncRNA NEAT1 on oncogenic pathways in HNSCC patients supports our observations about the survival rate depending on the NEAT1 expression levels. It seems likely that high expression of NEAT1, through the downregulation of cAMP and MYC pathways, influences the unfolded protein response, the MTORC1 signalling pathway, oxidative phosphorylation, and DNA repair, and thus creates a specific cellular phenotype that is clinically manifested by better patient survival.

Conclusions

The major findings of this study are: (1) NEAT1 expression is up-regulated in some patients’ samples and cell lines. Moreover, the TCGA revealed that NEAT1 is up-regulated in cancer compared to normal tissue in most solid tumours, including HNSCC; (2) Smoking tobacco has a significant impact on NEAT1 expression in patients with HNSCC; (3) Patients with high levels of NEAT1 demonstrate slightly better overall survival with close to statistical significance; (4) Low NEAT1 expression is associated with the up-regulation of oncogenic signalling pathways, such as cAMP, MYC, unfolded protein response, MTORC1, oxidative phosphorylation, and DNA repair.

Acknowledgments

Publication was made during the class “Analysis of experimental data”, performed in the Chair of Medical Biotechnology, Department of Cancer Immunology, Poznan University of Medical Sciences, in 2019/2020.

This work was supported by Poznan University of Medical Sciences: scientific and education activity of the Chair of Medical Biotechnology Department of Cancer Immunology

Notes

[1] Conflicts of interest The authors declare no conflict of interest.

References

1 

Cohen N, Fedewa S, Chen AY. Epidemiology and Demographics of the Head and Neck Cancer Population. Oral Maxillofac Surg Clin North Am 2018; 30: 381-395.

2 

Irani S. miRNAs signature in head and neck squamous cell carcinoma metastasis: a literature review. J Dent (Shiraz) 2016; 17: 71-83.

3 

Alsahafi E, Begg K, Amelio I, et al. Clinical update on head and neck cancer: molecular biology and ongoing challenges. Cell Death Dis 2019; 10: 540.

4 

Denaro N, Merlano MC, Russi EG, Lo Nigro C. Non coding RNAs in head and neck squamous cell carcinoma (HNSCC): a clinical perspective. Anticancer Res 2014; 34: 6887-6896.

5 

Chen T, Wang H, Yang P, He ZY. Prognostic role of long noncoding RNA NEAT1 in various carcinomas: a meta-analysis. Onco Targets Ther 2017; 10: 993-1000.

6 

Klec C, Prinz F, Pichler M. Involvement of the long noncoding RNA NEAT1 in carcinogenesis. Mol Oncol 2019; 13: 46-60.

7 

Engreitz JM, Ollikainen N, Guttman M. Long non-coding RNAs: spatial amplifiers that control nuclear structure and gene expression.Nat Rev Mol Cell Biol 2016; 17: 756-770.

8 

Yamazaki T, Souquere S, Chujo T, et al. Functional Domains of NEAT1 Architectural lncRNA Induce Paraspeckle Assembly through Phase Separation. Molecular Cell 2018; 70: 1038-1053.e7.

9 

Liu F, Tai Y, Ma J. LncRNA NEAT1/let-7a-5p axis regulates the cisplatin resistance in nasopharyngeal carcinoma by targeting Rsf-1 and modulating the Ras-MAPK pathway. Cancer Biol Ther 2018; 19: 534-542.

10 

Yong L, Dong C, Xiang G, Xiaohui L, Gongning S. LncRNA NEAT1 Regulates Cell Viability and Invasion in Esophageal Squamous Cell Carcinoma through the miR-129/CTBP2 Axis. Dis Markers 2017; 2017: 5314649.

11 

Wang P, Wu T, Zhou H. Long noncoding RNA NEAT1 promotes laryngeal squamous cell cancer through regulating miR-107/CDK6 pathway. J Exp Clin Canc Res 2016; 35: 22.

12 

Fang J, Qiao F, Tu J, et al. High expression of long non-coding RNA NEAT1 indicates poor prognosis of human cancer. Oncotarget 2017; 8: 45918-45927.

13 

Yu X, Li Z, Zheng H, Chan MTV, Wu WKK. NEAT1: A novel cancer-related long non-coding RNA. Cell Prolif 2017; 50: e12329.

14 

Lu Y, Li T, Wei G, et al. The long non-coding RNA NEAT1 regulates epithelial to mesenchymal transition and radioresistance in through miR-204/ZEB1 axis in nasopharyngeal carcinoma. Tumour Biol J Int Soc Oncodevelopmental Biol Med 2016; 37: 11733-11741.

15 

Cao J, Zhang Y, Yang J, et al. NEAT1 regulates pancreatic cancer cell growth, invasion and migration though mircroRNA-335-5p/c-met axis. Am J Canc Res 2016; 6: 2361-2374.

16 

Choudhry H, Albukhari A, Morotti M, et al. Tumor hypoxia induces nuclear paraspeckle formation through HIF-2alpha dependent transcriptional activation of NEAT1 leading to cancer cell survival. Oncogene 2015; 34: 4482-4490.

17 

Ning L, Li Z, Wei D, Chen H, Yang C. LncRNA, NEAT1 is a prognosis biomarker and regulates cancer progression via epithelial-mesenchymal transition in clear cell renal cell carcinoma. Cancer Biomark 2017; 19: 75-83.

18 

Zhang C, Li JY, Tian FZ, et al. Long Noncoding RNA NEAT1 Promotes Growth and Metastasis of Cholangiocarcinoma Cells. Oncology Res 2018; 26: 879-888.

19 

Li Y, Li Y, Chen W, et al. NEAT expression is associated with tumor recurrence and unfavorable prognosis in colorectal cancer. Oncotarget 2015; 6: 27641-27650.

20 

Chen X, Kong J, Ma Z, Gao S, Feng X. Up regulation of the long non-coding RNA NEAT1 promotes esophageal squamous cell carcinoma cell progression and correlates with poor prognosis. Am J Cancer Res 2015; 5: 2808-2815.

21 

Fu JW, Kong Y, Sun X. Long noncoding RNA NEAT1 is an unfavorable prognostic factor and regulates migration and invasion in gastric cancer. J Cancer Res Clin Oncol 2016; 142: 1571-1579.

22 

Ma Y, Liu L, Yan F, Wei W, Deng J, Sun J. Enhanced expression of long non-coding RNA NEAT1 is associated with the progression of gastric adenocarcinomas. World J Surg Oncol 2016; 14: 41.

23 

Chai Y, Liu J, Zhang Z, Liu L. HuR-regulated lncRNA NEAT1 stability in tumorigenesis and progression of ovarian cancer. Cancer Med 2016; 5: 1588-1598.

24 

Huang B, Liu C, Wu Q, et al. Long non-coding RNA NEAT1 facilitates pancreatic cancer progression through negative modulation of miR-506-3p. Biochem Biophys Res Commun 2017; 482: 828-834.

25 

Chakravarty D, Sboner A, Nair SS, et al. The oestrogen receptor alpharegulated lncRNA NEAT1 is a critical modulator of prostate cancer. Nat Commun 2014; 5: 5383.

26 

Li JH, Zhang SQ, Qiu XG, Zhang SJ, Zheng SH, Zhang DH. Long non-coding RNA NEAT1 promotes malignant progression of thyroid carcinoma by regulating miRNA-214. Int J Oncol 2016; 50: 708-716.

27 

Li Z, Wei D, Yang C, Sun H, Lu T, Kuang D. Overexpression of long noncoding RNA, NEAT1 promotes cell proliferation, invasion and migration in endometrial endometrioid adenocarcinoma. Biomed Pharmacother 2016; 84: 244-251.

28 

Guo S, Chen W, Luo Y, et al. Clinical implication of long non-coding RNA NEAT1 expression in hepatocellular carcinoma patients. Int J Clin Exp Pathol 2015; 8: 5395-5402.

29 

He C, Jiang B, Ma J, Li Q. Aberrant NEAT1 expression is associated with clinical outcome in high grade glioma patients. APMIS 2015; 124: 169-174.

30 

Zeng C, Xu Y, Xu L, et al. Inhibition of long non-coding RNA NEAT1 impairs myeloid differentiation in acute promyelocytic leukemia cells. BMC Cancer 2014; 14: 693.

31 

Guglas K, Kolenda T, Stasiak M, et al. YRNAs: New Insights and Potential Novel Approach in Head and Neck Squamous Cell Carcinoma. Cells 2020; 9: E1281.

32 

Kolenda T, Ryś M, Guglas K, et al. Quantification of long non-coding RNAs using qRT-PCR: comparison of different cDNA synthesis methods and RNA stability. Archives of Medical Science 2019. DOI: 10.5114/aoms.2019.82639

33 

Wu G, Haw R. Functional Interaction Network Construction and Analysis for Disease Discovery. Methods Mol Biol 2017; 1558: 235-253.

34 

Subramanian A, Tamayo P, Mootha VK, et al. Gene set enrichment analysis: A knowledge-based approach for interpreting genome-wide expression profiles. Proc Natl Acad Sci 2005; 102: 15545-15550.

35 

Mootha VK, Lindgren CM, Eriksson KF, et al. PGC-1α-responsive genes involved in oxidative phosphorylation are coordinately downregulated in human diabetes. Nat Genet 2003; 34: 267-273.

36 

Warde-Farley D, Donaldson SL, Comes O, et al. The GeneMANIA prediction server: biological network integration for gene prioritization and predicting gene function. Nucleic Acids Res 2010; 38: W214-W220.

37 

Liu Z, Chang Q, Yang F, et al. Long non-coding RNA NEAT1 overexpression is associated with unfavorable prognosis in patients with hepatocellular carcinoma after hepatectomy: a Chinese population-based study. Eur J Surg Oncol 2017; 43: 1697-1703.

38 

van Heesch S, van Iterson M, Jacobi J, et al., Extensive localization of long noncoding RNAs to the cytosol and mono-and polyribosomal complexes. Genome Biol 2014; 15: R6.

39 

Dong P, Xiong Y, Yue J, et al. Long Non-coding RNA NEAT1: A Novel Target for Diagnosis and Therapy in Human Tumors. Front Genet 2018; 9: 471.

40 

Wu Y, Yang L, Zhao J, et al. Nuclear-enriched abundant transcript 1 as a diagnostic and prognostic biomarker in colorectal cancer. Mol Cancer 2015; 14: 191.

41 

Nakagawa S, Shimada M, Yanaka K, et al. The lncRNA Neat1 is required for corpus luteum formation and the establishment of pregnancy in a subpopulation of mice. Development 2014; 141: 4618-4627.

42 

Vogelstein B, Lane D, Levine AJ. Surfing the p53 network. Nature 2000; 408: 307-310.

43 

Idogawa M, Nakase H, Sasaki Y, Tokino T. Prognostic effect of long noncoding RNA NEAT1 expression depends on p53 mutation status in cancer. J Oncol 2019; 2019: 7.

44 

Sano D, Xie TX, Ow TJ, et al. Disruptive TP53 mutation is associated with aggressive disease characteristics in an orthotopic murine model of oral tongue cancer. Clin Cancer Res 2011; 17: 6658-6670.

45 

Soussi T, Dehouche K, Beroud C. 2000. p53 website and analysis of p53 gene mutations in human cancer: forging a link between carcinogenesis and epidemiology. Hum Mutat 2000; 15: 105-113.

46 

CMRI. CellBank Australia [Internet]. Available from: http://www.cellbankaustralia.com/dok.html (access: 21 Jun 2020).

47 

Mello SS, Sinow C, Raj N, et al. Neat1 is a p53-inducible lincRNA essential for transformation suppression. Genes Dev 2017; 31: 1095-1108.

48 

Fajardo A, Piazza G, Tinsley H. The Role of Cyclic Nucleotide Signaling Pathways in Cancer: Targets for Prevention and Treatment. Cancers (Basel) 2014; 6: 436-458.

49 

Caretta A, Mucignat-Caretta C. Protein kinase a in Cancer. Cancers 2011; 3: 913-926.

50 

Borland G, Smith BO, Yarwood SJ. EPAC proteins transduce diverse cellular actions of cAMP. Br J Pharmacol 2009; 158: 70-86.

51 

Dang CV. MYC on the path to cancer. Cell 2012; 149: 22-35.

52 

Boxer LM, Dang CV. Translocations involving c-myc and c-myc function. Oncogene 2001; 20: 5595-5610.

53 

Beer S, Zetterberg A, Ihrie RA, et al. Developmental context determines latency of MYC-induced tumorigenesis. PLoS Biol 2004; 2: e332.

54 

Carrasco DR, Sukhdeo K, Protopopova M, et al. The differentiation and stress response factor XBP-1 drives multiple myeloma pathogenesis. Cancer Cell 2007; 11: 349-360.

55 

Papandreou I, Denko NC, Olson M, et al. Identification of an Ire1alpha endonuclease specific inhibitor with cytotoxic activity against human multiple myeloma. Blood 2011; 117: 1311-1314.

56 

Guertin DA, Sabatini DM. Defining the role of mTOR in cancer. Cancer Cell 2007; 12: 9-22.

57 

Sarbassov DD, Guertin DA, Ali SM, Sabatini DM. Phosphorylation and regulation of Akt/PKB by the rictor-mTOR complex. Science 2005; 307: 1098-1101.

58 

Zoncu R, Efeyan A, Sabatini DM. mTOR: from growth signal integration to cancer, diabetes and ageing. Nat Rev Mol Cell Biol 2011; 12: 21-35.

59 

Dhani N, Fyles A, Hedley D, Milosevic M. The Clinical Significance of Hypoxia in Human Cancers. Semin Nuc Med 2015; 45: 110-121.

60 

Ashton TM, McKenna WG, Kunz-Schughart LA, Higgins GS. Oxidative Phosphorylation as an Emerging Target in Cancer Therapy. Clin Cancer Res 2018; 24: 2482-2490.

61 

Bouwman P, Jonkers J. The effects of deregulated DNA damage signalling on cancer chemotherapy response and resistance. Nat Rev Cancer 2012; 12: 587-598.

62 

LaTulippe E, Satagopan J, Smith A, et al. Comprehensive gene expression analysis of prostate cancer reveals distinct transcriptional programs associated with metastatic disease. Cancer Res 2002; 62: 4499-4506.

Copyright: © 2020 Termedia Sp. z o. o. This is an Open Access article distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International (CC BY-NC-SA 4.0) License (http://creativecommons.org/licenses/by-nc-sa/4.0/), allowing third parties to copy and redistribute the material in any medium or format and to remix, transform, and build upon the material, provided the original work is properly cited and states its license.
  
Termedia
About us Contact
Copyright notice Privacy policy Advertising policy Contact us
Quick links
Journals Books eBooks Events
© 2024 Termedia Sp. z o.o.
Developed by Bentus.