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. 2020 Oct 25;12(11):3118. doi: 10.3390/cancers12113118

MicroRNA in Papillary Thyroid Carcinoma: A Systematic Review from 2018 to June 2020

Liviu Hitu 1,*, Katalin Gabora 1, Eduard-Alexandru Bonci 1, Andra Piciu 2, Adriana-Cezara Hitu 3, Paul-Andrei Ștefan 1,4, Doina Piciu 1,5
PMCID: PMC7694051  PMID: 33113852

Abstract

Simple Summary

The most common form of endocrine cancer - papillary thyroid carcinoma, has an increasing incidence. Although this disease usually has an indolent behavior, there are cases when it can evolve more aggressively. It has been known for some time that it is possible to use microRNAs for the diagnosis, prognosis and even treatment monitoring of papillary thyroid cancer. The purpose of this study is to summarize the latest information provided by publications regarding the involvement of microRNAs in papillary thyroid cancer, underling the new clinical perspectives offered by these publications.

Abstract

The involvement of micro-ribonucleic acid (microRNAs) in metabolic pathways such as regulation, signal transduction, cell maintenance, and differentiation make them possible biomarkers and therapeutic targets. The purpose of this review is to summarize the information published in the last two and a half years about the involvement of microRNAs in papillary thyroid carcinoma (PTC). Another goal is to understand the perspective offered by the new findings. Main microRNA features such as origin, regulation, targeted genes, and metabolic pathways will be presented in this paper. We interrogated the PubMed database using several keywords: “microRNA” + “thyroid” + “papillary” + “carcinoma”. After applying search filters and inclusion criteria, a selection of 137 articles published between January 2018–June 2020 was made. Data regarding microRNA, metabolic pathways, gene/protein, and study utility were selected and included in the table and later discussed regarding the matter at hand. We found that most microRNAs regularly expressed in the normal thyroid gland are downregulated in PTC, indicating an important tumor-suppressor action by those microRNAs. Moreover, we showed that one gene can be targeted by several microRNAs and have nominally described these interactions. We have revealed which microRNAs can target several genes at once.

Keywords: microRNA, miRNA, papillary, thyroid, carcinoma, microcarcinoma

1. Introduction

Given that in the last two and a half years alone, more than 200 articles have been published on the involvement of microRNAs in the pathology of PTC, microRNAs are a hot topic. Several questions arise from the analysis of these studies, for example, how relevant is the information of these studies to daily medical practice; Will this information ever be beneficial for the patients with an aggressive form of papillary carcinoma? Or we design studies on the treadmill pursuing only scientific interest? During the 1970s, Francis Crick asserted what he believed to be the central dogma of molecular biology. Genetic information traveled from deoxyribonucleic acid (DNA) to ribonucleic acid (RNA) through transcription, then from RNA to proteins via translation, meaning proteins were the functional end products of genes. However, after the whole human genome sequencing, it was understood that genes that encoded proteins accounted for less than 2% of the genome. Given the intricacy of cellular processes, genetic information is most likely passed by additional regulatory elements and not only by coding genes [1]. MicroRNAs (miRNAs) are a class of endogenous non-coding RNA molecules ranging from 18 to 22 nucleotides in length. MicroRNA’s constitute only 3% of the human genome but it is believed that they regulate more than half of the protein-coding genes. Mature microRNA can promote or inhibit messenger ribonucleic acid (mRNA) translation and degradation by targeting with precision complementary sequences in 3′UnTranslated Regions (3′UTR). They act both as post-transcriptional regulators of gene expression and as messengers or intercellular signaling [2]. MicroRNAs are involved in central biological processes, including development, organogenesis, tissue differentiation, cell cycles, and metabolism. Alterations in the expression of microRNA contribute to the pathogenesis of the majority of human malignancies (PTC) [3,4]. The most striking evidence that links microRNAs with thyroid cancer is their large alteration in expression in malignant cells compared to benign cells. MicroRNA expression is dysregulated in human cancer through various mechanisms. The most important are amplification or deletion of microRNA genes, abnormal transcriptional control of microRNAs, and epigenetic changes [5]. PTC is the most common thyroid malignancy [6], and it is defined as a malignant epithelial tumor with evidence of follicular differentiation and a series of specific nuclear features [7]. The incidence of PTC is increasing mainly due to improved diagnostic methods such as ultrasound (US) with targeted fine-needle aspiration biopsy (FNAB) [8]. This increase has been predominantly an increase in diagnosing papillary thyroid microcarcinoma (PTMC). PTMC is defined as measuring 1.0 cm or less in the greatest dimension of the tumor [9]. Cervical lymph nodes, lungs, and bones are the most common metastatic sites, brain, liver, and skin involvement is less common. Distant metastases are usually diagnosed through clinical symptoms or suspicious imaging/laboratory findings (abnormal uptake on the post-ablation whole-body scan (WBS). Another diagnostic method can be a positive finding on an F18-fluorodeoxyglucose (F18-FDG) positron emission tomography/computed tomography (PET/CT) evaluation or cross-sectional study prompted by elevated thyroglobulin levels in patients whose post-ablation WBS is negative [10]. Usually, PTC has an excellent prognosis [11]. Therefore, what are the special situations in daily practice that make us need these new potential biological markers for PTC diagnosis, prognosis, and therapeutic targets? The purpose of this review is to summarize the information published in the last two and a half years about the involvement of microRNAs in PTC. It is also to understand the perspective offered by the new findings.

2. Materials and Methods

A literature analysis was performed in MEDLINE using PubMed for studies published from 2018 to June 2020. The following keywords were used: ”microRNA”+ ”papillary”+ “thyroid” + “carcinoma”, which resulted in 466 articles in English. All related abstracts were reviewed and relevant studies that were published in English were selected. We only included papers that had full text available and described the exact method and results regarding microRNA’s signatures in PTC epigenetic mechanism. A selection of 137 eligible articles was the result of our search (Figure 1).

Figure 1.

Figure 1

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Study selection summary.

3. Results

Data on microRNAs, the sample source, the regulatory mode of microRNAs, the target genes/proteins of microRNAs, and their effect on PTC cells from the 137 studies were selected and presented in Table 1 [12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,52,53,54,55,56,57,58,59,60,61,62,63,64,65,66,67,68,69,70,71,72,73,74,75,76,77,78,79,80,81,82,83,84,85,86,87,88,89,90,91,92,93,94,95,96,97,98,99,100,101,102,103,104,105,106,107,108,109,110,111,112,113,114,115,116,117,118,119,120,121,122,123,124,125,126,127,128,129,130,131,132,133,134,135,136,137,138,139,140,141,142,143,144,145,146,147,148].

Table 1.

Targets of epigenetic alterations in papillary thyroid carcinoma (PTC).

miRNA Sample Sources Up/Down-Regulated Targeted Gene miRNA Effect on PTC Cells Sponging/Sequestering Potential Utility References
miR-520a-3p tissue Down JAK1 prevented cell proliferation, migration, invasion, promoted apoptosis TT Bi. CL et al. [12]
miR-139-5p tissue Down LMO4 suppressed cell proliferation, migration, and tumor growth circBACH2 Pr, TT Cai. X et al. [13]
miR-128 tissue Down SPHK1 elevated apoptosis increased G0/G1 arrest, reduced Cyclin D1/ CDK4 expressions - TT Cao. XZ et al. [14]
miR-2861 tissue Up DGCR5 promoted cell proliferation and invasion lncRNA DGCR5 Pg Chen. F et al. [15]
miR-101 tissue Down CXCL12 repressed cell proliferation, migration, and invasion. Enhanced apoptosis - Pg, TT Chen. F et al. [16]
miR-135b-5p tissue Up CCNG2 modulated tumor cells proliferation, apoptosis, migration lncRNA GAS8-AS1 TT Chen. N et al. [17]
miR-202-3p tissue Down WNT suppressed the expression of β-catenin, cell migration, and invasion - TT Chen. J et al. [18]
miR-1271 tissue Up IRS1 suppressed migration, invasion, and proliferation of PTC cells - TT Chen. Y et al. [19]
miR-153-3p tissue Down ZNRF2 regulated cell proliferation, migration, and invasion lncRNA TTN-AS1 TT Cui. Z et al. [20]
miR-548c-3p tissue Down HIF1α reducted N-cadherin and vimentin expression - Pg, TT Du. Y et al. [21]
miR-150 tissue Down MUC4 suppressed PTC cell proliferation and metastasis - Dg, TT Fa. Z et al. [22]
Ex-miR-103 blood Up GPER1 influenced the differentiation of CD4 + T cell into Treg cells - TT Fang. T et al. [23]
miR-625-3p tissue Up AEG-1 promoted the proliferation, migration, and invasion of thyroid cancer cells - TT Fang. L et al. [24]
miR-141-3p tissue Down YY-1 inhibited cell growth, induced apoptosis, and suppressed invasion - Pg, TT Fang. M et al. [25]
miR-613 tissue Down SphK2 inhibited cell proliferation, migration, and invasion lncRNA LINC00460 TT Feng. L et al. [26]
miR-93-3p-660 tissue Up FOXO1 inhibited glycolysis that attenuated glucose uptake and lactate production lncRNA ASMTL-AS1 TT Feng. Z et al. [27]
miR-1266 tissue Down FGFR2 inhibited PTC cell proliferation, migration, and invasion - Dg, TT Fu. YT et al. [28]
miR-129 tissue Up MAL2 suppressed growth and invasion of PTC cells - Pv, TT Gao. X et al. [29]
miR-791 tissue Down - inhibited proliferation of PTC cells via blocking the G1 phase - Pg, TT Gao. XB et al. [30]
miR-429 tissue Down ZEB1 inhibited cell proliferation, migration, and invasion lncRNA SNHG22 Dg, TT Gao. H et al. [31]
miR-30a tissue Down E2F7 inhibited the proliferation, migration, and invasion of PTC cells - TT Guo. H et al. [32]
miR-9-5p tissue Down BRAF suppressed the viability of PTC cells by inducing apoptosis - TT Guo. F et al. [33]
miR-215 tissue Down ARFGEF1 inhibited proliferation and metastasis - Pg Han. J et al. [34]
Ex-miR-199 blood Down DLG1-AS1 suppressed proliferation of PTC cells - Dg He. T et al. [35]
miR-1252 tissue Up FSTL1 inhibited viability, proliferation, and stimulated apoptosis in PTC cells. hsa_circ_ 0011290 TT Hu. Z et al. [36]
miR-486-5p tissue Down KIAA1199 inhibited cell growth of PTC - TT Jiao. X et al. [37]
miR-885-5p tissue Down RAC1 suppressed PTC cell proliferation hsa_circ_ 0004458 TT Jin. X et al. [38]
miR-15a tissue Down RET/AKT inhibited PTC cell proliferation and invasion and enhanced the apoptosis - TT Jin. J et al. [39]
miR-381-3p tissue Down LRP6 inhibited the proliferation and metastasis of PTC cells - TT Kong. W et al. [40]
miR-485-5p tissue Down Raf1 inhibited PTC cell proliferation, migration and invasion LncRNA LINC00460 TT Li. G et al. [41]
miR-320a cell culture Up HMGB1 inhibited cell proliferation, migration and invasion rates lncRNA ANRIL Pv, TT Li. M et al. [42]
miR-369-3p cell culture Down TSPAN13 suppressed cell proliferation, colony formation, and induced apoptosis in PTC - Dg, Pv, TT Li. P et al. [43]
miR-205 tissue Down YAP1 inhibited proliferation and invasion of thyroid cancer cells - TT Li. D et al. [44]
miR-204-3p tissue Down CDC23 suppressed PTC proliferation, migration and invasion lncRNA LINC00514 TT Li. X et al. [45]
miR-361-5p tissue Down ROCK1 Inhibited proliferation, migration, and invasion - TT Li. R et al. [46]
miR-4500 cell culture Down PLXNC1 inhibited cell viability, colony formation, and cell apoptosis - Pg, TT Li. R et al. [47]
miR-211-5p tissue Down SPARC suppressed proliferation, migration, and invasion of thyroid tumor cells lncRNA MCM3AP-AS1 TT Liang. M et al. [48]
miR-101 tissue Down FN1 promoted the RAI-resistance in PTC lncRNA-NEAT1 TT Liu. C et al. [49]
miR-214 tissue Down PSMD10 suppressed proliferation, and induced cell apoptosis and cell cycle arrest in PTC cells - TT Liu. F et al. [50]
miR-744 tissue Down NOB1 attenuated the proliferation and invasion of PTC cells - TT Liu. H et al. [51]
miR-96-5p tissue Up CCDC67 accelerated the proliferation and metastasis of PTC cells - Dg, TT Liu. ZM et al. [52]
miR-4728 cell culture Down SOS1 repressed the PTC cell proliferation through MAPK - Dg, TT Liu. Z et al. [53]
miR-431 tissue Down Gli1 inhibited cell migration and invasion of PTC - TT Liu. Y et al. [54]
miR-524-5p tissue Down FOXE1, ITGA3 suppressed PTC progression by regulating tumor cell proliferation, migration, and invasion - TT Liu. H et al. [55]
miR-331-3p tissue Down SLC25A1 inhibited PTC cells proliferation, migration and invasion lncRNA-BRM TT Liu. S et al. [56]
miR-335-5p tissue Down ICAM1 reduced the proliferation, migration, invasion of PTC - TT Luo. L et al. [57]
miR-146a tissue - GABPA suppressed proliferation, migration, and invading capabilities of PTC cells TT Long. M et al. [58]
miR-29a-3p tissue Down OTUB2 suppressed growth, proliferation, invasion in PTC cells. - Pg, TT Ma. Y et al. [59]
miR-199a-5p tissue Down SNAI1 reduced migration and invasion of PTC cells - TT Ma. S et al. [60]
miR-363-3p tissue Down ITGA6 suppressed anoikis resistance in PTC cells - TT Pan. Y et al. [61]
miR-1231, miR-1304 tissue Down - inhibited proliferation and invasion of PTC cells circ_ 0025033 TT Pan. Y et al. [62]
miR-146b-5p tissue Up DNMT3A accelerated extra-glandular invasion and metastasis of PTC cells lncRNA-MALAT1 Dg, TT Peng. Y et al. [63]
miR-448 tissue Down KDM5B inhibited PTC cell progression and tumor growth via TGIF1 - TT Pu. Y et al. [64]
miR-199b-5p tissue Down STON2 inhibited PTC cell growth and metastasis - TT Ren. L et al. [65]
miR-26a-5p tissue Down Wnt5a inhibited proliferation, colony formation, invasion, and migration of PTC cells. - TT Shi. D et al. [66]
miR-564 tissue Down AEG-1 inhibited cell proliferation, migration, and invasion and induced cell apoptosis - TT Song. Z et al. [67]
miR-214-3p tissue Down PSMD10 impaired PTC cell proliferation and metastasis lncRNA-SNHG3 TT Sui. G et al. [68]
miR-144 tissue Down WWTR1 inhibited of PTC cell proliferation - Pg, TT Sun. W et al. [69]
miR-106b-5p tissue Down ATAD2 induced apoptosis and suppressed invasion of PTC cells lncRNA-NEAT1_2 TT Sun. W et al. [70]
miR-124-3p cell culture Down MAP2K4 inhibited the proliferation, induced apoptosis and cell cycle arrest in PTC cells - TT Sun. Y et al. [71]
miR-577 tissue Down Sphk2 inhibited PTC cell proliferation, migration, and invasion lncRNA-LINC00520 Dg, TT Sun. Y et al. [72]
miR-486 tissue Down TENM1 inhibited proliferation, invasion, and migration of PTC cell - TT Sun. YH et al. [73]
miR-497 tissue Down BDNF suppressed PTC cell proliferation, migration, and invasion lncRNA-LINC00152 TT Sun. Z et al. [74]
miR-22 tissue Up - promoted PTC cell metastasis and BRAFV600E mutation - Dg, Pg Wang. D et al. [75]
miR-599 tissue Down Hey2 diminished PTC cell proliferation, migration, invasion, while stimulating apoptosis - Pr, TT Wang. DP et al. [76]
miR-3619-5p cell culture Down FOXM1 regulated proliferation and apoptosis in PTC lncRNA-Linc01410 TT Wang. G et al. [77]
miR-675 tissue Down MAPK1 suppressed PTC cell proliferation, migration, and invasion lncRNA-RMRP TT Wang. J et al. [78]
miR-1258 cell culture Down TMPRSS4 inhibited cell viability, migration, and invasion - Dg, TT Wang. L et al. [79]
miR-451a tissue Down ZEB1 suppressed proliferation, mobility, and invasion of PTC cell - TT Wang. Q et al. [80]
miR-622 tissue Down VEGFA inhibited PTC cell proliferation, migration, and invasion - TT Wang. R et al. [81]
miR-212 tissue Down MIAT inhibited PTC cell proliferation, migration, and invasion. (possible) lncRNA-MIAT TT Wang. R et al. [82]
miR-718 tissue Down PDPK1 inhibited PTC cell growth, reduced cell invasion, repressed glucose metabolism - Dg, TT Wang. X et al. [83]
miR-31 tissue Down SOX11 repressed PTC cell proliferation, invasion, and migration - TT Wang. Y et al. [84]
miR-384 tissue Down PRKACB suppressed PTC cell proliferation and migration - TT Wang. Y et al. [85]
miR-873 tissue Down CXCL16 inhibited proliferation, migration, and invasion of the PTC cells - TT Wang. Z et al. [86]
miR-143-3p tissue Down MSI2 induced apoptosis, suppresses invasion and migration of PTC - TT Wang. ZL et al. [87]
miR-1261 tissue Down C8orf4 inhibited PTC cell proliferation, migration, and invasion circZFR TT Wei. H et al. [88]
miR-200a-3p tissue Down YAP1 inhibited PTC cell proliferation and promoted apoptosis lncRNA-SNHG15 TT Wu. DM et al.
[89]
miR-329 tissue Down WNT1 decreased PTC cell proliferation, colony formation, suppressed growth - TT Wu. L et al. [90]
miR-203 tissue Down Bcl-2 inhibited cell proliferation, induced apoptosis, and suppressed the motility of PTC cells - TT Wu. X et al. [91]
miR-26a tissue Down ROCK1 repressed PTC cell viability, invasion, and metastasis - Dg, TT Wu. YC et al. [92]
miR-222 tissue Up - correlated with capsular invasion, vascular invasion, tumor size and metastasis - Pg Xiang. D et al. [93]
miR-150-5p cell culture Up BRAF(V600E) promoted PTC cell proliferation, suppressed apoptosis - TT Yan. R et al. [94]
miR-423-5p cell culture Down SOX12 suppressed PTC cell proliferation and invasion lncRNA-NR2F1-AS1 TT Yang. C et al. [95]
miR-182 tissue Up CHL1 * correlated with extrathyroidal invasion, cervical lymph node metastasis, and TNM - Pg Yao. XG et al. [96]
miR-1179 tissue - HMGB1 - circFOXM1 TT Ye. M et al. [97]
miR-1270 cell culture Up SCAI promoted PTC cell proliferation, migration - TT Yi. T et al. [98]
miR-761 tissue Down TRIM29 inhibited cell proliferation, and cell cycle progression in PTC lncRNA- HOXA11-AS TT Yin. X et al. [99]
miR-23a- tissue Down CCNG1 decreased proliferation, induced cell cycle arrest, and promoted PTC cell apoptosis - Dg, TT Yin. JJ et al. [100]
miR-203 tissue Down AKT3 suppressed cell migration and invasion in the PTC cells and promoted cell apoptosis - TT You. A et al. [101]
miR-3619-3p tissue Up Wnt promoted PTC cell migration and invasion - TT Yu. S et al. [102]
miR-637 tissue Down Akt1 inhibit inhibited PTC cell proliferation, invasion, and migration lncRNA HOTTIP Dg, TT Yuan. Q et al. [103]
miR-21 tissue Up VHL promoted PTC cell proliferation and invasion - TT Zang. C et al. [104]
miR-224-5p tissue Up EGR2 promoted PTC cell
migration, invasion		 - Dg, TT Zang. CS et al. [105]
miR-509 tissue Down PAX9 inhibited cell proliferation and invasion in papillary thyroid carcinoma - TT Zhang. S et al. [106]
miR-766 tissue Down IRS2 inhibited proliferation of PTC cells - TT Zhao. J et al. [107]
miR-96-3p tissue Up SDHB increased the invasion and migration of PTC cells TT Zhao. X et al. [108]
miR-138-5p tissue Down LRRK2 inhibited PTC cell proliferation, apoptosis lncRNA RP11-476D10.1 TT Zhao. Y et al. [109]
miR-409-3p tissue Down CCND2 negatively regulated PTC cell proliferation and cell cycle progression - Pr, TT Zhao. Z et al. [110]
miR-200b/c tissue Down Rap1b inhibited PTC cell invasion, migration and growth - TT Zhou. B et al. [111]
miR-188-5p tissue Down FGF-5 * suppressed PTC cells growth - TT Zhou. P et al. [112]
miR-506 tissue Down IL17RD inhibited the proliferation, invasion, and migration capacities of PTC cells - Pg, TT Zhu. J et al. [113]
miR-146 tissue Up * KIT promoted PTC cell proliferation and invasion * lncRNA CTC TT Liao. B et al. [114]
miR-1178 tissue Up TLR4 promoted cell proliferation and suppressed cell apoptosis circ_FNDC3B TT Wu. G et al. [115]
miR-106a tissue Up PTEN/
SFR4		 enhanced PTC cell proliferative, migratory and invasive abilities lncRNA-HULC TT Yang. Z et al. [116]
miR-335 tissue Down SOX2 suppressed the proliferation, migration, and invasion of PTC cells lncRNA-LINC01510 TT Li. Q et al. [117]
miR-199a-5p tissue Down SLC1A5 attenuated proliferation, induced apoptosis, and arrested cells in the G0/G1 phase ABHD11-AS1 Dg, TT Zhuang. X et al. [118]
miR-145-5p tissue Down AKT3 inhibited proliferation, migration and invasion lncRNA-n384546 Dg, TT Feng. J et al. [119]
miR-211 tissue Up RECK promoted tumor growth and increased tumor volume in PTC cells - Dg, Pg Wei. ZL et al. [120]
miR-206 tissue Down MAP4K3 enhanced Euthyrox sensitivity in Euthyrox-resistant PTC cells - TT Liu. F et al. [121]
miR-21-5p cell culture Up TGFBI, COL4A1 secreted by hypoxic PTC cells is a potent pro-angiogenic factor - Dg, TT Wu. F et al. [122]
Ex-miR-423-5p blood Up - promoted PTC cell migration and invasion - Dg, TT Ye. W et al. [123]
miR-422a tissue Down SP1 suppressed PTC cells proliferation and metastasis lncRNA-LINC00313 TT Yan. D et al. [124]
miR-1301-3p tissue Down STAT3 inhibited PTC cell proliferation, cell apoptosis -accelerated lncRNA-ABDH11-AS1 TT Wen. J et al. [125]
miR-let-7a tissue Down c-Myc suppressed PTC cell proliferation, migration, and invasion - TT Huang. J et al. [126]
miR-let-7e tissue Down HMGB1 inhibited of PTC cell growth and metastasis - TT Ding. C et al. [127]
miR-146b-5p tissue Up CCDC6 promoted proliferation, migration, invasion, and cell cycle progression of PTC cells - Dg, TT Jia. M et al. [128]
miR-145 tissue Down ZEB2 inhibited the migration, invasion, and tumorigenesis of PTC cells circ_NUP214 TT Li. X et al. [129]
miR-520c-3p tissue Down S100A4 inhibited PTC cells proliferation lncRNA-HOXA-AS2 TT Xia. F et al. [130]
miR-15a-5p tissue Down - inhibited PTC cells growth lncRNA-HOXA-AS2 TT Jiang. L et al. [131]
miR-146b-3p tissue Up NF2 increased PTC cell migration and invasion - TT Yu. C et al. [132]
miR-22a-3p tissue Up CBL promoted PTC cell proliferation and invasion circ_ITCH TT Wang. M et al. [133]
miR-21 cell culture - PTEN matrine- induced apoptosis and G1 cell cycle arrest - TT Zhao. L et al. [134]
miR-204 tissue Down BRD4 inhibited of PTC cell proliferation lncRNA-UCA1 TT Li. D et al. [135]
miR-4429 tissue Down Bcl-2 suppressed PTC cell proliferation, promoted apoptosis, and induced cell cycle arrest in G2/M phase lncRNA-LINC00313 TT Wu. JW et al. [136]
miR-222 tissue Up * PPP2R2A promoted PTC cell migration and invasion - Dg, TT Huang. Y et al. [137]
miR-21-5p tissue Down Bcl-2 inhibited TPC cell
proliferation and invasion		 lncRNA-BISPR Dg, TT Zhang. H et al. [138]
miR-30a tissue Down IGF1R inhibited PTC cell proliferation, cycle progression, invasion, migration lncRNA-PVT1 TT Feng. K et al. [139]
miR-129-5p tissue Down KLK7 inhibited proliferation, cell survival, invasion, and migration lncRNA-NEAT1 TT Zhang. H et al. [140]
Ex-miR-146b-5p, Ex-miR-222-5p blood Down - enhanced the migration and invasion activity of PTC cells - Pg Jiang. K et al. [141]
miR-539 tissue Down SLPI inhibited PTC cell EMT and tumor growth - TT Xu. CB et al. [142]
miR-24-3p tissue Up p27kip1 regulated PTC cell proliferation, apoptosis migration and invasion ncRNA-MIR22HG TT Chen. ZB et al. [143]
miR-26a cell culture Down ARPP19 promoted proliferation of PTC cells - TT Gong. Y et al. [144]
Ex-miR-98-5p blood Down HMGA2 promoted PTC cell growth, inhibited apoptosis - Dg, Pg Qiu. K et al. [145]
miR-296-5p tissue Down PLK1 suppressed cell proliferation, inhibited cell clone formation, arrested the cell cycle in G2/M phase, and induced apoptosis - TT Zhou. SL et al. [146]
miR-451a cell culture Down * PSMB8 inhibited proliferation, EMT and induced apoptosis of PTC cells - TT Fan. X et al. [147]
miR-630 tissue Down JAK2/
STAT3		 suppressed migration and invasion of PTC cells - TT Pan. XM et al. [148]
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TT—therapeutic target, Dg-Diagnosis, Pg—Prognostic, Pr—Prevention, * The feature discovered in another study than the one cited.

3.1. Up- and Downregulated microRNAs in Papillary Thyroid Cancer

Out of 139 microRNAs, 106 are downregulated and 33 are upregulated (Table 1). This means that more than a quarter of the described microRNAs have an oncogenic role (oncomiR’s) and the rest of them have a tumor-suppressive role. The dysregulation of microRNA is an important event during the development of papillary thyroid carcinoma. Overexpression of certain microRNA can result in the tumor suppressor genes repression. Down-regulation of specific microRNA can lead to increased expression of oncogenes. Overexpression and downregulation induce malignant effects on cell cycle progression, proliferation, migration, and apoptosis, leading to tumor growth and progression in PTC and other types of malignancies [1].

3.2. One Gene Can Be Targeted by Several microRNAs

Analyzing, individually, in each study, the interaction between microRNAs and the genes targeted by them, we noticed that the same gene can be targeted by different microRNAs. For example, HMGB1 has been reported to play an important role in promoting both cell survival and death by regulating multiple signaling pathways, including proliferation, autophagy, inflammation, invasion, and metastasis. The study by Ding. C et al. [127] indicates that microRNA-let-7e downregulates HMGB1 expression by directly targeting the HMGB1 3′-UTR, downregulated HMGB1 inhibits PTC cell proliferation and metastasis [127]. MicroRNA-1179 interacted with the 3′ UTR of HMGB1 and suppressed HMGB1 expression at the post-transcriptional level and indicates that the microRNA-1179/MHGB1 pathway plays a tumor suppressor role in PTC [97]. The same gene-HMGB1 is involved in ANRIL/HMGB1/ microRNA-320a pathway. Propofol-mediated ANRIL downregulation competed with HMGB1 to bind microRNA-320a, thus inhibiting PTC cell malignant behaviors [42].

A study by Chen et al. [18] has shown that enforced expression of microRNA-202-3p inhibited WNT signaling by downregulating β-catenin expression in PTC. Again, the same gene is regulated by microRNA-3619-3p to promote cell migration and invasion in PTC [102]. WNT1 has been shown to promote cancer progression because it triggers cell proliferation and metastasis, microRNA-329 inhibits papillary thyroid cancer progression via direct targeting WNT1 [90]. WNT5a, an important signaling molecule in the non-canonical Wnt family, has been involved in nearly all parts of the non-canonical Wnt pathway. The invasion and metastasis of PTC cells were inhibited by microRNA-26a- 5p via Wnt5a [66].

B-cell lymphoma-2 (Bcl-2), an oncogene expressed in most thyroid carcinomas, is also found to be a target of several different microRNAs. MicroRNA-21-5p suppressed Bcl-2 expression [138], silencing LINC00313 led to down-regulation of anti-apoptotic Bcl-2 proteins [136]. Overexpression of miR microARN-203 may serve a role in PTC tumor cells by downregulating Bcl-2 expression [91].

One more targeted gene by multiple microRNAs in PTC is AKT, the human homolog of the viral oncogene v-Akt is related to protein kinases A (PKA) and C (PKC) in humans. The pathway that involves AKT inactivates several proapoptotic factors, AKT also activates transcription factors which promote anti-apoptotic genes. Overexpression of microRNA-15a inhibited the activation of the AKT pathway, which inhibited cell proliferation and promoted the process of apoptosis [39]. Upregulated microRNA-203 suppresses epithelial-mesenchymal transition (EMT), invasion, proliferation, and migration as well as induces apoptosis of PTC cells via downregulated AKT3 [101]. lncRNA n384546 could regulate the expression of AKT3 by sponging microRNA-145-5p [119]. lncRNA HOTTIP modulated Akt1 expression by regulating microRNA-637 in PTC cell lines [103].

Another example is the Sphingosine kinase (SPHK), an enzyme, catalyzing the formation of the prosurvival second messenger sphingosine-1-phosphate (S1P) from the pro-apoptotic lipid sphingosine. High SPHK expression is correlated with a significant decrease in survival rate in patients with several forms of cancer, including PTC. LncRNA LINC00460 promoted PTC progression via modulating SphK2 through sponging microRNA-613 in PTC [26]. lncRNA LINC00520 accelerates the progression of papillary thyroid carcinoma by serving as a competing endogenous RNA of microRNA-577 to increase SphK2 expression [72]. MicroRNA-128 targets SPHK1 to induce apoptosis and reduce cell proliferation, migration in thyroid cancer cell lines, and inhibits tumor growth [14].

PTEN (phosphatase with tensin homology), an upstream negative regulatory molecule of the PI3K/AKT pathway, is the direct target gene of microRNA-106 [116] and microRNA-21 [134]. MicroRNA-625-3p [24] and microRNA-564 [67] directly target the same gene, AEG-1 (astrocyte elevated gene 1), an important regulator of PTC genesis and development. Yes-associated protein 1 (YAP1) was identified as a target gene of microRNA -205 [44] and microRNA-200a-3p [89]. Both microRNA-361-5p [46] and microRNA-26a [92] target ROCK1 (Rho-associated coiled-coil kinase 1), which was closely associated with poor PTC prognosis [46]. Zinc Finger E-Box Binding Homeobox 1 (ZEB1) a gene that plays vital roles in the metastasis of cancer, is inhibited by microRNA-451a [80] and a direct target of microRNA-429 [31].

From the same families of genes discovered to be the target of several microRNAs we mention CXCL-12/16 [16,86], CCNG-1/2 [17,100], IRS-1/2 [19,107], FGF-2/FR [28,112], CCDC-6/67 [52,128], FOX-O1/E1/M1 [27,55,76], ITGA-3/6 [55,61], SL-1A5/25A1 [56,118], MAP-2K4/K1/4K3 [71,78,120], and SOX 11/12/2 [84,95,117].

3.3. One MicroRNA Can Target Several mRNAs/Genes

One microRNA does not target only one but several mRNA/genes, as it was stated before. In our study, we found several microRNAs with multiple genes targeted. For instance, microRNA-146b-5p, downregulated CCDC6 expression by binding to its 3′-UTR in the study by Jia et al. [128] and promoted the expression of MALAT1 by negatively regulating DNMT3A in the study by Peng et al. [63]. The same microRNA-146b, but with the 3p strand located in the reverse position compared to the 5p strand which is present in the forward (5′-3′) position, meaning microRNA-146b-3p, is targeting directly NF2 [132]. From the same family, microRNA-146a targets GABPA [58], and microRNA-146 targets KIT [114]. MicroRNA-199a-5p inhibited cell migration, invasion, and EMT by targeting SNAI in PTC [60] but also attenuated cell proliferation, induced apoptosis, and arrested cells in the G0/G1 phase through regulating the expression of SLC1A5 [118]. From the same family, microRNA-199b-5p suppressed PTC cell aggressiveness by targeting STON2 [65]. MicroRNA-101 suppresses the proliferation, apoptosis resistance, invasion, and migration of PTC cells by directly targeting CXCL12 [16]. MicroRNA-101-3p deficiency enhanced the expression level of FN1, which therefore promoted the RAI (radioactive iodine)-resistance of PTC [49]. Another example is microRNA-150 which serves a key function in suppressing the malignant growth and aggressive behavior of PTC cells through the downregulation of MUC4 [22]. Overexpression of microRNA-150-5p regulated cell proliferation, metastasis, and apoptosis by regulating BRAFV600E [94]. Both the IGF1R [139] and E2F7 [32] genes are targeted directly by the microRNA-30a. MicroRNA-203 inhibits proliferation and motility, and induces apoptosis of PTC cells via regulation of the expression of Bcl-2 [91], and suppresses EMT, invasion, proliferation, and migration of PTC cells via downregulated AKT3 [101]. Five more genes are found to be the target of the same microRNA in four different studies. VHL [104], Bcl-2 [138], PTEN [134], TGFBI [122], and COL4A1 [122] are all targeted genes by microRNA-21. There are still more examples of the same microRNA’s but with the 3p strand located in the reverse position compared to 5p strand which is present in the forward (5′-3′) position, that target different genes: [52,108], [119,129], [29,140], [37,73], [39,131], [45,135], [48,120], [50,68], [66,92], and [57,117].

4. Discussion

Each microRNA can regulate hundreds of messenger RNAs (mRNAs), while various microRNA can control the same mRNA. Additionally, many microRNAs regulate and are regulated by other species of non-coding RNAs, such as circular RNAs (circRNAs) and long non-coding RNAs (lncRNAs). For this reason, it is extremely difficult to predict, study, and analyze the precise role of a single microRNA involved in human cancer, considering the complexity of its connections. Focusing on a single microRNA molecule represents a limited approach. Additional information could come from network analysis, which has become a common tool in the biological field to better understand molecular interactions [1].

Most studies assess the level of expression of the microRNA in question, show the actions of its overexpression/silencing on cell lines, find the gene targeted by the microRNA, and how the metabolic pathway microRNA / target gene works. Although complex information is presented, at the end of the discussion chapter we find the same dry phrase “microRNA-X could be a potential therapeutic/diagnostic/prognostic target for PTC treatment”. Despite this, there are several articles with a different study design that offer something more than “could be”. One of them is the study of Zhao. L et al. [134] which finds Matrine, a traditional Chinese medicine, as an alternative drug for PTC treatment. Treatment with matrine at the concentrations of 1, 2, 5, 10, and 20 mg/ml inhibited TPC 1 cell proliferation by up to 95.8% (for 20 mg/ml matrine). Matrine induced apoptosis and G1 cell cycle arrest through downregulating microRNA-21 to affect the PTEN/Akt signaling in TPC 1 human thyroid cancer cells. Liu. F et al. [121] discovered that microRNA-206 contributed to euthyrox resistance in PTC cells through blockage p38 and JNK signaling pathway by targeting MAP4K3. Another study by Liu et al. [49], found the promoting gene and the signaling pathway regulating RAI-resistance in PTC. The results attested that NEAT1 was upregulated in RAI-resistant PTC accompanied microRNA-101-3p inhibition, FN1 overexpression, and PI3K/AKT signaling pathway abnormal activation. Fang. T et al. [23] discovered that Shenmai injection (SMI), a traditional Chinese formula mainly made up of Red Ginseng and Radix Ophiopogonis. SMI inhibits the differentiation of CD4 + T cells into Treg cells via the microRNA-103/GPER1 axis, which improves the immunological function of PTC patients with postoperative 131-Iodine ablation. Although few, these studies differ in the classical approach to the use of microRNAs in papillary thyroid carcinomas and should be recognized as at least promising.

Even if in the world of publications microRNA is a hot topic, when we talk about PTC, most international guidelines regarding thyroid cancer management, do not even mention microRNA. Here we refer to the NCCN 2018 [149], ETA 2019 [7], and ESMO 2019 [11] guidelines. The exception is the ATA 2015 guideline, which, although published several years before the above-listed guidelines, mentions microRNA as an additional diagnostic molecular marker strategy under development. microRNA markers have shown initial diagnostic utility in FNA samples with indeterminate cytological diagnoses, but they have not been thoroughly validated. It is also mentioned about microRNA, also in this guide, in the chapter “Directions for future research”, as possible progress in identifying markers of thyroid cancer. To result in a significantly improved accuracy of cancer detection in thyroid nodules as compared to the currently available clinical tests [8].

Hence, which are the most challenging parts in PTC management where we could use microRNA? After the clinical and ultrasound evaluation of a thyroid nodule, if malignancy criteria are present, a fine needle biopsy is performed for cytological examination. Some results of the cytological examination can be inconclusive. In such cases, there is a need to assess molecular markers to make a presurgical differentiation of benign and malign lesions. MicroRNAs are one of the novel classes of molecular markers that are being used to improve the diagnosis of thyroid cancer. Several studies have shown that a microRNA-based signature in FNABs can be used to discriminate benign from malignant thyroid nodules. MicroRNA profiling of thyroid cancers can also provide prognostic information useful for defining optimal management strategies. Expression levels of certain microRNA in thyroid tumor tissues are associated with clinicopathological characteristics, such as tumor size, multifocality, capsular invasion, extrathyroidal extension, and both lymph node and distant metastases [150]. Treatment options have been proposed and implemented based on the results obtained from research conducted on epigenetic alterations. Therefore, the development of new therapeutic strategies based on targeting epigenetic changes to restore the expression of tumor suppressor microRNAs or to blunt overexpressed oncogenic microRNAs may provide a new landscape for the treatment of aggressive PTC [151].

Although PTMC generally has an excellent prognosis, the long-term rate of recurrence of PTMC has been reported to be as high as 10% [9]. Currently, there are no reliable clinical features including molecular markers, that can differentiate PTMC in patients who develop progressive disease from indolent PTMC. Even so, searching the PubMed database, regarding microRNA signatures in PTMC, there is only one study by Zhang et al. which combines serum microRNA with ultrasound profile as predictive biomarkers of diagnosis and prognosis for PTMC. In this study, microRNAs were found to be significantly associated with a poor prognosis of patients with PTMC and could be used as prognostic molecular markers or patients with PTMC before and after surgery. These results suggest that circulating microRNAs may be useful as non-invasive molecular biomarkers of diagnosis and prognosis for PTMC [9], selecting those cases that need aggressive therapies, despite the histology of PTMC. Given the need for more studies in this field, this topic could be a research idea for the future, in the era of personalized medicine.

5. Conclusions

Research regarding microRNAs in PTC is undergoing a tremendous shift, suggesting rapid maturation of this field. In this review, we tried to represent as briefly as possible the interactions of microRNAs with target proteins. We also showed microRNAs regulation mode and its effect on PTC cells. Our results showed that a gene can target multiple microRNAs simultaneously, and vice versa. All this information can be used to find the most effective therapeutic targets/biomarkers in PTC. For future research, we indicated a possible niche, namely microRNA signatures in PTMC.

Author Contributions

Conceptualization, L.H., A.P., D.P. Data curation, L.H., A.-C.H., K.G.; Formal analysis, E.-A.B., A.P.; Investigation, L.H., D.P., P.-A.Ș.; Methodology, A.P., A.-C.H., D.P.; Supervision, D.P. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Conflicts of Interest

The authors declare no conflict of interest.

Footnotes

Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

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