METTL3 and ALKBH5 oppositely regulate m<sup>6</sup>A modification of <i>TFEB</i> mRNA, which dictates the fate of hypoxia/reoxygenation-treated cardiomyocytes

CDC-like kinase 3 (CLK3) is a dual specificity kinase that functions on substrates containing serine/threonine and tyrosine. But its role in human cancer remains unknown. Herein, we demonstrated that CLK3 was significantly up-regulated in cholangiocarcinoma (CCA) and identified a recurrent Q607R somatic substitution that represented a gain-of-function mutation in the CLK3 kinase domain. Gene ontology term enrichment suggested that high CLK3 expression in CCA patients mainly was associated with nucleotide metabolism reprogramming, which was further confirmed by comparing metabolic profiling of CCA cells. CLK3 directly phosphorylated USP13 at Y708, which promoted its binding to c-Myc, thereby preventing Fbxl14-mediated c-Myc ubiquitination and activating the transcription of purine metabolic genes. Notably, the CCA-associated CLK3-Q607R mutant induced USP13-Y708 phosphorylation and enhanced the activity of c-Myc. In turn, c-Myc transcriptionally up-regulated CLK3. Finally, we identified tacrine hydrochloride as a potential drug to inhibit aberrant CLK3-induced CCA. These findings demonstrate that CLK3 plays a crucial role in CCA purine metabolism, suggesting a potential therapeutic utility.

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“…As described previously (Song et al, 2019), we cultured HEK293T cells to perform the dual-luciferase reporter assays.…”

Section: Luciferase Reporter Assaysmentioning

confidence: 99%

Targeting CLK3 inhibits the progression of cholangiocarcinoma by reprogramming nucleotide metabolism

Zhou

Lin

Feng

et al. 2020

Journal of Experimental Medicine

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“…Suppressing adipogenesis by promoting cell cycle transition in mitotic clonal expansion [89] YTHDF2 Inhibiting autophagy and adipogenesis by decreasing protein expression of ATG5 and ATG7 and shortening the lifespan of their m 6 A-modified mRNAs [87] Suppressing adipogenesis by increasing m 6 A methylation of CCNA2 and CDK2 and reversing the methylation effect of FTO on CCNA2 and CDK2 [90,91] Inhibiting adipogenesis via the downregulation of CCND1 [92] NAFLD FTO Down-regulating mitochondrial content and up-regulating TG deposition [101] Promoting hepatic fat accumulation by increasing the expression of lipogenic genes, including FASN, SCD and MOGAT1, and intracellular TG level in HepG2 cells [101] Increasing oxidative stress and lipid deposition [99] YTHDF2 Increasing lipid accumulation by decreasing both PPARα mRNA lifetime and expression [105] METTL3 Increasing lipid accumulation by decreasing both PPARα mRNA lifetime and expression [105] Hypertension m 6 A-SNPs EncodIing β1-adrenoreceptor, a hypertension-susceptibility candidate gene [108,109] Altering BP-related gene expression, mRNA stability and homeostasis [110] Cardiovascular diseases FTO Decreasing fibrosis and enhancing angiogenesis in mouse models of myocardial infarction [111] METTL3 Driving cardiomyocyte hypertrophy by catalyzing methylation of m 6 A on certain subsets of mRNAs [112] Decreasing eccentric cardiomyocyte remodeling and dysfunction [112] Inhibiting cellular autophagic flux and promoting apoptosis in hypoxia/reoxygenation-treated cardiomyocytes [113] Osteoporosis METTL3 Inhibiting adipogenesis and adipogenic differentiation via JAK1/STAT5/C/EBPβ pathway in bone marrow stem cells [119] Inhibiting osteoporosis pathological phenotypes, consisting of decreased bone mass and increased marrow adiposity via PTH/PTH1R signaling axis [118] FTO Promoting the differentiation of adipocyte and osteoblast by upregulating GDF11-FTO-PPARγ signalling way [116] Enhancing the stability of mRNA of proteins which function to protect osteoblasts from genotoxic damage through Hspa1a-NF-κB signaling way [120] Immune-related MDs ALKBH5 Expressing highly in organs enriched in immune cells with frequent immune reactions [10,123] METTL3 Stimulating T cell activation and the development of T lymphocytes in the thymus by regulating the translation of CD40, CD80 and TLR4 signaling adaptor TIRAP transcripts in den...…”

Section: Mettl14mentioning

confidence: 99%

“…Whereas, diminished METTL3 promotes eccentric cardiomyocyte remodeling and dysfunction [112]. Moreover, METTL3 upregulation inhibits cellular autophagic flux and promotes apoptosis in hypoxia/reoxygenation-treated cardiomyocytes [113].…”

Section: A Methylation In Hypertension and Cardiovascular Diseasesmentioning

confidence: 99%

RNA N6-methyladenosine: a promising molecular target in metabolic diseases

Wang

Huang

et al. 2020

Cell Biosci

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N6-methyladenosine is a prevalent and abundant transcriptome modification, and its methylation regulates the various aspects of RNAs, including transcription, translation, processing and metabolism. The methylation of N6-methyladenosine is highly associated with numerous cellular processes, which plays important roles in the development of physiological process and diseases. The high prevalence of metabolic diseases poses a serious threat to human health, but its pathological mechanisms remain poorly understood. Recent studies have reported that the progression of metabolic diseases is closely related to the expression of RNA N6-methyladenosine modification. In this review, we aim to summarize the biological and clinical significance of RNA N6-methyladenosine modification in metabolic diseases, including obesity, type 2 diabetes, non-alcoholic fatty liver disease, hypertension, cardiovascular diseases, osteoporosis and immune-related metabolic diseases.

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“…Up to now, no consistent conclusion was reached about the link between m 6 A and hypoxia. Previous reports found that the m 6 A abundance in mRNA was increased under hypoxia stress in HEK293T cells and cardiomyocytes (37, 38). The increased m 6 A level stabilized the mRNAs of Glucose Transporter 1 (Glut1), Myc proto-oncogene bHLH transcription factor (Myc), Dual Specificity Protein Phosphatase 1 (Dusp1), Hairy and Enhancer of Split 1 (Hes1), and Jun Proto-Oncogene AP-1 Transcription Factor Subunit (Jun) without influencing their protein level (37).…”

Section: Discussionmentioning

confidence: 79%

“…Hypoxia increased demethylation by stimulating hypoxia-inducible factor (HIF)-1α- and HIF-2α–dependent over-expression of ALKBH5 (26). In addition, transcription factor EB activates the transcription of ALKBH5 and downregulates the stability of METTL3 mRNA in hypoxia/reoxygenation (H/R)-induced autophagy in ischemic diseases (38). Our study found that m 6 A abundance in total circRNAs was decreased by hypoxia exposure.…”

Section: Discussionmentioning

confidence: 99%

Transcriptome-wide map of m⁶A circRNAs identified in hypoxic pulmonary hypertension rat model

Zhou

et al. 2019

Preprint

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32Hypoxic pulmonary hypertension (HPH) is a lethal disease. CircRNAs and m 6 A 33 circRNAs have been reported to be associated with cancer progression, but the 34 expression profiling of m 6 A circRNAs has not been identified in HPH. This study was 35 to investigate the transcriptome-wide map of m 6 A circRNAs in HPH. In this study, 36 hypoxia-induced PH rat model was established. Total RNA was extracted and purified 37 from lungs of rats, then circRNAs were detected and annotated by RNA-seq analysis. 38 m 6 A RNA Immunoprecipitation (MeRIP) was performed following rRNA depletion, 39 and RNA-seq library was constructed. CircRNA-miRNA-mRNA co-expression 40 network was also constructed. In vitro, total m 6 A was measured. m 6 A circXpo6 and 41 m 6 A circTmtc3 were detected in pulmonary artery smooth muscle cells (PASMCs) and 42 pulmonary artery endothelial cells (PAECs) exposed to 21% O 2 and 1% O 2 for 48 h, 43 respectively. m 6 A abundance in 166 circRNAs was significantly upregulated and m 6 A 44 abundance in 191 circRNAs was significantly downregulated in lungs of HPH rats. 45 m 6 A abundance in circRNAs was significantly reduced in hypoxia in vitro. m 6 A 46 circRNAs were mainly derived from single exons of protein-coding genes. m 6 A 47 influenced the circRNA-miRNA-mRNA co-expression network in hypoxia. m 6 A 48 circXpo6 and m 6 A circTmtc3 were downregulated in hypoxia. In general, our study 49 firstly identified the transcriptome-wide map of m 6 A circRNAs in HPH. m 6 A level in 50 circRNAs was decreased in lungs of HPH rats and in PASMCs and PAECs exposed to 51 hypoxia. Downregulated or upregulated m 6 A level influenced circRNA-miRNA-52 mRNA co-expression network in HPH. Moreover, we firstly identified two 53 downregulated m 6 A circRNAs in HPH: circXpo6 and circTmtc3. We suggested that 54 m 6 A circRNAs may be used as a potential diagnostic marker or therapy target in the 55 future.56 57 58 59 60 3 61 62 Author summary 63 HPH is a disease with great morbidity and mortality. It is often caused by chronic 64 hypoxic lung diseases, such as chronic obstructive pulmonary disease and interstitial 65 lung diseases. It lacks effective therapy methods so far. CircRNAs are a type of non-66 coding RNAs and can be used as biomarkers because they are differentially enriched in 67 specific cell types or tissues and not easily degraded. m 6 A is identified as the most 68 universal modification on non-coding RNAs in eukaryotes. CircRNAs can be modified 69 by m 6 A. m 6 A circRNAs in HPH is not well understood yet. Here we identify the 70 transcriptome-wide map of m 6 A circRNAs in HPH. We elucidate that m 6 A level in 71circRNAs is decreased in lungs of HPH rats and in PASMCs and PAECs exposed to 72 hypoxia. We find that downregulated or upregulated m 6 A level influences circRNA-73 miRNA-mRNA co-expression network in HPH. Moreover, we are the first to identify 74 two downregulated m 6 A circRNAs in HPH: circXpo6 and circTmtc3. We suggest that 75 m 6 A circRNAs may be used as a potential diagnostic marker or thera...

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METTL3 and ALKBH5 oppositely regulate m⁶A modification of TFEB mRNA, which dictates the fate of hypoxia/reoxygenation-treated cardiomyocytes

Cited by 361 publications

References 41 publications

Targeting CLK3 inhibits the progression of cholangiocarcinoma by reprogramming nucleotide metabolism

Targeting CLK3 inhibits the progression of cholangiocarcinoma by reprogramming nucleotide metabolism

RNA N6-methyladenosine: a promising molecular target in metabolic diseases

Transcriptome-wide map of m⁶A circRNAs identified in hypoxic pulmonary hypertension rat model

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METTL3 and ALKBH5 oppositely regulate m6A modification of TFEB mRNA, which dictates the fate of hypoxia/reoxygenation-treated cardiomyocytes

Cited by 361 publications

References 41 publications

Targeting CLK3 inhibits the progression of cholangiocarcinoma by reprogramming nucleotide metabolism

Targeting CLK3 inhibits the progression of cholangiocarcinoma by reprogramming nucleotide metabolism

RNA N6-methyladenosine: a promising molecular target in metabolic diseases

Transcriptome-wide map of m6A circRNAs identified in hypoxic pulmonary hypertension rat model

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Product

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METTL3 and ALKBH5 oppositely regulate m⁶A modification of TFEB mRNA, which dictates the fate of hypoxia/reoxygenation-treated cardiomyocytes

Transcriptome-wide map of m⁶A circRNAs identified in hypoxic pulmonary hypertension rat model