N6-methyladenosine (m6A) is identified as the most common, abundant and conserved internal transcriptional modification, especially within eukaryotic messenger RNAs (mRNAs). M6A modification is installed by the m6A methyltransferases (METTL3/14, WTAP, RBM15/15B and KIAA1429, termed as “writers”), reverted by the demethylases (FTO and ALKBH5, termed as “erasers”) and recognized by m6A binding proteins (YTHDF1/2/3, IGF2BP1 and HNRNPA2B1, termed as “readers”). Acumulating evidence shows that, m6A RNA methylation has an outsize effect on RNA production/metabolism and participates in the pathogenesis of multiple diseases including cancers. Until now, the molecular mechanisms underlying m6A RNA methylation in various tumors have not been comprehensively clarified. In this review, we mainly summarize the recent advances in biological function of m6A modifications in human cancer and discuss the potential therapeutic strategies.
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Abkürzungen
ALKBH5
Alkb homologue 5
AML
Acute myeloid leukemia
BCLAF1
BCL2-associated transcription factor 1
BCSCs
Breast cancer stem cells
CA4
Carbonic anhydrase IV
CEBP
CCAAT-enhancer binding protein
circRNAs
Circular RNAs
CRC
Colorectal cancer
D2-HG
D2-hydorxyglutarate
DAA
3-deazaadenosine
Dnmt1
DNA methyltransferase 1
eIF
eukaryotic initiation factor
FGF14
Fibroblast growth factor 14
FOXM1-AS
Antisense to FOXM1
FOXO1
Forkhead box protein O1
FTO
Fat mass and obesity-associated protein
GSCs
Glioblastoma stem-like cells
HBXIP
Hepatitis B X-interacting protein
HCC
Hepatocellular carcinoma
HNRNP
Heterogeneous nuclear ribonucleoprotein
HSP70
Heat-shock protein 70
HSPCs
Hematopoietic stem/progenitor cells
IDH
Isocitrate de-hydrogenases
IGF2BP
IGF2 mRNA binding proteins
lncRNAs
Long non-coding RNAs
LUSC
Lung squamous cell carcinoma
m6A
N6-methyladenosine
MA
Meclofenamic acid
METTL3
Methyltransferase-like 3
miRNAs
Micro RNAs
mRNAs
Messenger RNAs
ncRNAs
Noncoding RNAs
NSCLC
Non-small cell lung carcinoma
R-2HG
R-2-hydroxyglutarate
RUNX1T1
Runt-related transcription factor 1
SAH
S-adenosylhomocysteine
SAM
S-adenosylmethionine
SOCS2
Suppressor of cytokine signaling 2
SRSF
serine/arginine-rich splicing factor
T2DM
Type 2 diabetes mellitus
THRAP3
Thyroid hormone receptor-associated protein 3
Uhrf1
Ubiquitin-like with PHD and RING finger domains 1
UTR
Untranslated terminal region
WTAP
Wilms tumour 1-associated protein
YTHDF
YT521-B homology domain-containing protein family
ZNF750
Zinc finger protein 750
α-KG
Α-ketoglutarate
Introduction
According to MODOMICS, 163 different chemical modifications in RNA have been identified in all living organisms by the end of 2017 [1]. Among these modifications, N6-methyladenosine (m6A), methylated at the N6 position of adenosine, has been considered as the most pervasive, abundant and conserved internal transcriptional modification within eukaryotic messenger RNAs (mRNAs) [2], microRNAs (miRNAs) [3] and long non-coding RNAs (lncRNAs) [4]. RNA m6A is enriched near stop codon and 3′ untranslated terminal region (UTR) [5, 6] and translated near 5′ UTR in a cap-independent manner [7], thereby affecting RNA transcription, processing, translation and metabolism.
The deposition of m6A is encoded by a methyltransferase complex involving three homologous factors jargonized as ‘writers’, ‘erasers’ and ‘readers’ (Fig. 1). Methyltransferase-like 3 (METTL3) [8], METTL14 [9], Wilms tumor 1-associated protein (WTAP) [10], RBM15/15B [11] and KIAA1429 [12] are categorized as the components of ‘writers’ that catalyze the formation of m6A; ‘erasers’, fat mass and obesity-associated protein (FTO) [13] and alkB homologue 5 (ALKBH5) [14], selectively remove the methyl code from target mRNAs; ‘Readers’ are capable of decoding m6A methylation and generating a functional signal, including YT521-B homology (YTH) domain-containing protein [15], eukaryotic initiation factor (eIF) 3 [11], IGF2 mRNA binding proteins (IGF2BP) families [16] and heterogeneous nuclear ribonucleoprotein (HNRNP) protein families [17]. YTH domain can recognize m6A through a conserved aromatic cage [18] and another two proteins FMR1, LRPPRC “read” this modification [19, 20]. Contrary to the conventional ‘writer’-‘eraser’-‘reader’ paradigm, few studies reveal METTL3/16 as a m6A ‘writer’ or ‘reader’ [21].
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M6A RNA modification is a dynamic and reversible process which was corroborated by the discovery of ‘eraser’ in 2011 [13]. It is associated with multiple diseases such as obesity, infertility and cancer [22]. In this review, we summarize the function and therapeutic advances of m6A modifications in human cancer and provide their promising applications in the treatment of these malignant tumors (Table 1).
Table 1
Multiple functions exerted by m6A RNA methylation in various diseases
HSPCs hematopoietic stem/progenitor cells, AML acute myeloid leukemia, GBM Glioblastoma, GSC glioblastoma stem cell, HCC hepatocellular cancer, CRC colorectal cancer, BCSCs Breast cancer stem cells, NPC Nasopharyngeal carcinoma
Biological function of m6A modification in mammals
Recent years have witnessed a substantial progress of m6A post-transcriptional modification in regulating RNA transcription [23, 24], processing event [25‐27], splicing [28‐33], RNA stabilities [34‐40] and translation [42‐49] (Fig. 2).
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M6A modification in RNA transcript
METTL3 and FTO are implicated in regulating transcription of CCAAT-enhancer binding protein (CEBP) family. METTL3 is localized to the starting sites of CEBPZ, which is required for recruitment of METTL3 to chromatin [23]. CEBPA is identified as an exclusive transcription factor displaying a positive correlation with FTO and regulating its transcription in acute myeloid leukemia (AML) [24].
M6A modification in RNA processing
M6A modifications promote the initiation of miRNA biogenesis [3] and regulate nuclear mRNA processing events [25]. METTL3 recognizes the pri-miRNAs by microprocessor protein DGCR8 and causes the elevation of mature miRNAs and concomitant reduction of unprocessed pri-miRNAs in breast cancer [3]. METTL14 interacts with DGCR8 to modulate pri-miR-126 and suppresses the metastatic potential of hepatocellular carcinoma (HCC) [26]. FTO can regulate poly(A) site and 3′ UTR length by interacting with METTL3 [25]. YTHDC1 knockout in oocytes exhibits massive defects and contributes to extensive alternative polyadenylation and 3′ UTR length alterations [27].
M6A modification in RNA splicing
M6A RNA modifications that overlap in space with the splicing enhancer regions affect alternative RNA splicing by acting as key pre-mRNA splicing regulators [28]. Inhibiton of m6A methyltransferase impacts gene expression and alternative splicing patterns [29]. FTO regulates nuclear mRNA alternative splicing by binding with SRSF2 [25]. FTO and ALKBH5 regulate m6A around splice sites to control the splicing of Runt-related transcription factor 1 (RUNX1T1) in exon [28], and removal of m6A by FTO reduces the recruitment of SRSF2 and prompts the skipping of exon 6, leading to a short isoform of RUNX1T1 [30]. Depletion of METTL3 is associated with RNA splicing in pancreatic cancer [31]. WTAP is enriched in some proteins involved in pre-mRNA splicing [32]. But, some studies show that, M6A is not enriched at the ends of alternatively spliced exons and METTL3 unaffects pre-mRNA splicing in embryonic stem cells [33].
M6A modification in RNA degradation
M6A is a determinant of cytoplasmic mRNA stability [34], and reduces mRNA stability [35]. A RNA decay monitoring system is adopted to investigate the effects of m6A modifications on RNA degradation [36]. Knockdown of METTL3 abolishes SOCS2 m6A modification and augments SOCS2 expression [37]. M6A-mediated SOCS2 degradation also relies on m6A ‘reader’ YTHDFs [37], which accelerate the decay of m6A-modified transcripts [38] or target mRNA [39]. Knockout of m6A methyltransferase attenuates YTHDF2 specific binding with target mRNAs and increases their stability [40]. M6A RNA methylation also controls T cell homeostasis by targeting the IL-7/STAT5/SOCS pathways [41] and decreases the stability of MYC/CEBPA transcripts [24].
M6A modification in RNA translation
M6A modifications occur in mRNA and noncoding RNA (ncRNAs) to regulate gene expression in its 5′ or 3′ UTR [7, 42]. METTL3 enhances mRNA translation [8], while depletion of METTL3 selectively inhibits mRNAs translation in 5′UTR [43] and reduces AFF4 and MYC translation in bladder cancer [44] but increase that of zinc finger protein 750 and fibroblast growth factor 14 in nasopharyngeal carcinoma [45].
M6A modifications facilitate the initiated translation through interacting with the initiation factors eIF3, CBP80 and eIF4E in an RNA-independent manner [46]. Heat-shock-induced translation of heat-shock protein 70 (HSP70) alters the transcriptome-wide distribution of m6A [7] and affects DNA repair [47]. ABCF1-sensitive transcripts largely overlaps with METTL3-modified mRNAs and are critical for m6A-regulated mRNA translation [43]. In addition, FMR1 binds to hundreds of mRNAs to negatively regulate their translation [20]. YTHDF1 facilitates the translation of m6A-modified mRNAs in protein-synthesis and YTHDF3 acts in the initial stage of m6A-driven translation from circular RNAs (circRNAs) [38, 48, 49].
M6A RNA modification in metabolic and developmental diseases
The methyltransferases and demethylases of m6A are associated with a variety of diseases, such as obesity [13, 50], type 2 diabetes mellitus (T2DM) [51], growth retardation, developmental delay, facial dysmorphism [52]. Besides, m6A modification affects infertility [14], developmental arrest [22], neuronal disorder [53] and infectious diseases [54, 55].
M6A modification in metabolic and infectious diseases
M6A modification is involved in metabolic abnormalities in patients with T2DM and obesity [56]. FTO regulates the energy homeostasis and dopaminergic pathway through FTO-dependent m6A demethylation [50, 51], and it is ubiquitous in adipose and muscle tissues, influencing RUNX1T1 splicing in adipogenesis [28, 30]. METTL3/14 reduce the abundance of Hepatitis C virus replication, but FTO promotes its production through YTHDF proteins [54]. M6A is also identified as a conserved modulatory symbol across Flaviviridae genomes, including dengue, Zika virus and West Nile virus [55].
M6A modification in infertility
Deficiency of demethylase ALKBH5 leads to the aberrant spermatogenesis and apoptosis with impaired fertility in testes and striking changes in DNA methyltransferase 1 (Dnmt1) and ubiquitin-like with PHD and RING finger domains 1 (Uhrf1) [14]. YTHDF2 is required for maternal transcriptome during oocyte maturation [57]. YTHDC1/2 determine the germline development in mouse [58], and YTHDC1 is essential for spermatogonia in males and oocyte maturation in females [27].
M6A modification in nervous system development
M6A modification regulates the pace of cerebral cortex development [59] and m6A-regulated histone modifications enhances self-renewal of neural stem cells by METTL3/14 [60]. M6A has dual effects on delaying tempo of corticogenesis by two distinct pathways: increased cell-cycle length and decreased mRNA decay [59]. M6A depletion decreases the decay of radial glia cells associated with stem cell maintenance, neurogenesis and differentiation [61].
M6A modification in inflammation and metabolism-related cancer
Cacinogenesis is characterized by stepwise accumulation of genetic/epigenetic alterations of different proto-oncogenes and tumor-suppressor genes following other diseases including chronic inflammation and metabolic diseases. METTL3/14 and FTO influence Hepatitis C virus replication and production, and endogenous mediators of inflammatory responses (proinflammatory cytokines, reactive oxygen, et al) can promote genetic/epigenetic alterations [62]. FTO affects RUNX1T1 splicing in adipogenesis [28, 30], and RUNX1T1 is essential for pancreas development [63]. Transcription factor forkhead box protein O1 (FOXO1) as another direct substrate of FTO, regulates gluconeogenesis in liver [64] and promotes the growth of pancreatic ductal adenocarcinoma [65].
M6A RNA modification in human cancer
Emerging evidence suggests that, m6A modification is associated with the tumor proliferation, differentiation, tumorigenesis [46], proliferation [66], invasion [46] and metastasis [26] and functions as oncogenes or anti-oncogenes in malignant tumors (Table 1 and Fig. 3).
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Acute myeloid leukemia (AML)
FTO is highly expressed in AML with t(11q23)/MLL rearrangements, t(15;17)/PML-RARA, FLT3-ITD and/or NPM1 mutations and promotes leukemic cell transformation and tumorigenesis [67]. METTL3/14 are expressed in hematopoietic stem/progenitor cells (HSPCs) and AML cells with t(11q23), t(15;17), or t(8;21), control the terminal myeloid differentiation of HSPCs and promote the survival and proliferation of AML [68]. WTAP acts in cell proliferation and arrests the differentiation of leukemia [69].
M6A promotes the translation of c-MYC, BCL2 and PTEN in AML [70]. METTL14 acts an oncogenic role by regulating its targets MYB/MYC through m6A modification [68]. YTHDF2, responsible for the decay of m6A-modified mRNA transcripts [40], is also associated with MYC in leukemia [71]. Besides, YTHDF2 stabilizes Tal1 mRNAs and increases its expansion in AML [72].
Collectively, these studies corroborate the functional importance of m6A modifications in leukemia, such as METTL3 [23, 70], METTL14 [68], FTO [24, 67] and YTHDF2 [24, 40] and they provide profound insights into development and maintenance of AML and self-renewal of leukemia stem/initiation cells through the downstream MYC and Tal1 pathways.
Glioblastoma (GBM)
METTL3/14 inhibit GSC growth, self-renewal and tumorigenesis, but FTO and ALKBH5 indicate poor survival in GBM by regulating ADAM19 and transcription factor FOXM1 [73, 74]. LncRNA antisense to FOXM1 (FOXM1-AS) promotes the interaction of ALKBH5 with FOXM1 nascent transcripts in the tumorigenesis of GSCs [73].
Lung cancer
M6A demethylase FTO is identified as a prognostic factor in lung squamous cell carcinoma (LUSC) and facilitates cell proliferation and invasion, but inhibits cell apoptosis by regulating MZF1 expression [75]. METTL3 acts as a oncogene in lung cancer by increasing EGFR and TAZ expression and promoting cell growth, survival and invasion [46]. METTL3-eIF3 caused mRNA circularization promotes the translation and oncogenesis of lung adenocarcinoma [46]. Besides, SUMOylation of METTL3 is of importance for the promotion of tumor growth at lysine residues K177, K211, K212 and K215 in non-small cell lung carcinoma (NSCLC) [76]. These studies provide insights into the critical roles of METTL3 and FTO in lung carcinoma.
Hepatocellular carcinoma (HCC)
METTL3 is related to a poor prognosis in HCC patients and promotes HCC cell proliferation, migration and colony formation by YTHDF2-dependent posttranscriptional silencing of SOCS2 [37]. But, METTL14 is an anti-metastatic factor and serves as a favorable factor in HCC by regulating m6A-dependent miRNA processing [26]. MiR-145 down-regulates YTHDF2 through targeting its mRNA 3′ UTR [77]. In conclusion, METTL3 upregulation or METTL14 downregulation predicts poor prognosis in patients with HCC and contributes to HCC progression and metastasis [26, 37]. METTL3 suppresses SOCS2 expression in HCC via the miR-145/m6A/YTHDF2 dependent axis [37, 77]. Thus, these studies suggest a new dimension of epigenetic alteration in liver carcinogenesis.
Breast cancer and colorectal cancer (CRC)
METTL3 is associated with the expression of mammalian hepatitis B X-interacting protein (HBXIP), displaying an aggressiveness in breast cancer. HBXIP-induced METTL3 promotes the proliferation of breast cancer via inhibiting tumor suppressor let-7 g [78]. Besides, ALKBH5 decreases the levels of m6A in NANOG mRNA and enhances its stability, leading to an increase of NANOG mRNA and protein levels in breast cancer stem cells (BCSCs) [79]. Another m6A eraser ‘FTO’ polymorphism has no association with the risk of CRC [80], but the m6A ‘writer’ WTAP is associated with carbonic anhydrase IV (CA4), which inhibits the proliferation and induces apoptosis and cycle arrest by repressing the Wnt signaling through targeting the WTAP-WT1-TBL1 axis [81].
Brief summary of m6A modification-related carcinogenesis
M6A RNA modifications regulate RNA production/metabolism and take part in the carcinogenesis. On the one hand, m6A-modified genes usually act a oncogenic role in cancer, leading to alterations of mRNA translation and acceleration of tumor progression, and decreasing m6A modification results in tumor development. On the other hand, given that SUMOylation of METTL3 represses its m6A methyltransferase capacity and results in tumor growth of NSCLC, modification of m6A methylase can determine the tumor development.
M6A modification in cancer treatment
M6A modification indicates new directions for the treatment of various cancers. Regulators or inhibitors of m6A modifications may provide the potential therapeutic strategies for cancers, such as MA2 in GBM [74], R-2HG/SPI1/FB23–2 in AML [24, 68, 82] and CA4 in CRC [81]. Meclofenamic acid (MA) as one of the selective FTO inhibitors is a non-steroidal anti-inflammatory drug by competing with FTO binding sites [83]. MA2, the ethyl ester derivative of MA, increases m6A modification, leading to the suppression of tumor progression [74, 83]. The expression of ASB2 and RARA is increased in hematopoiesis and they act as key regulators of ATRA-induced differentiation of leukemia cells [84]. FTO enhances the leukemogenesis of AML by inhibition of the ASB2 and RARA expression [67]. FB23–2, as another inhibitor of m6A demethylase FTO suppresses AML cell proliferation and promotes the cell differentiation and apoptosis [82].
ALKBH5 and FTO are α-ketoglutarate (α-KG)-dependent dioxygenases [85], which are competitively inhibited by D2-hydorxyglutarate (D2-HG) and elevated in isocitrate de-hydrogenases (IDH)-mutant cancers for transferring isocitrate to α-KG [86]. R-2-hydroxyglutarate (R-2HG), an metabolite by mutating IDH1/2 enzyme, exhibits anti-leukemia effects through increasing m6A levels in R-2HG-sensitive AML [24].
S-adenosylmethionine (SAM) serves as a cofactor substrate in METTL3/14 complex and its product S-adenosylhomocysteine (SAH) inhibits the methyltransferases by competing with adenosylmethionine [87]. 3-deazaadenosine (DAA) inhibits SAH hydrolase and interrupts insertion of m6A into mRNA substrates [88] and its analogs suppress the replication of various viruses editing m6A- mRNA in cancers [89, 90].
METTL14 acts an oncogenic role by regulating MYB/MYC axis through m6A modification [68]. SPI1, a hematopoietic transcription factor, directly inhibits METTL14 expression in malignant hematopoietic cells [68] and may be a potential therapeutic target for AML. CA4 inhibits the tumorigenicity of CRC by suppressing the WTAP-WT1-TBL1 axis [81].
Future prospect
M6A RNA modifications act by regulating RNA transcript, splicing, processing, translation and decay and participate in the tumorigenesis and metastasis of multiple malignancies. However, the underlying mechanisms of m6A modifications in cancer should be further addressed.. Besides FMR1 and LRPPRC, the function of ALKBH family in m6A RNA methylation is undetermined. METTL14 has different expression levels in various tumor tissues. Given a dual role of METTL14 either as a tumor suppressor [26] or an oncogene in cancer [68], its role in other cancers need be further elucidated. Though some inhibitors of m6A methylation have shown promising effects on cancer development [68, 81], novel therapeutic strategies for m6A RNA methylation should be further explored in the treatment of cancer.
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