Project description:N6-methyladenosine (m6A) RNA methylation is the most abundant internal chemical modifications in eukaryotic messenger RNA (mRNA) as well as long non-coding RNA (lncRNA). Recently, m6A RNA methylation research was revived by the discovery of the fat mass- and obesity-associated protein (FTO) as the first RNA demethylase, implicating that m6A RNA methylation is a reversible and dynamic modification and may have critical biological functions. Emerging evidence has shown that m6A modifications in mRNAs and lncRNAs play crucial roles in regulating RNA fate and function in biological processes in the past several years. As the first identified RNA demethylase that regulates the demethylation of target mRNAs, FTO has been reported to play an oncogenic role in leukemia and glioblastoma stem cells. To identify the target genes of FTO in melanoma cells, we used m6A IP seq coupled with RNA seq to determine the potential demethylation and gene targets across the whole transcriptome for FTO, and identified more than 1,000 genes.

Project description:N6-methyladenosine (m6A) RNA methylation is the most abundant internal chemical modifications in eukaryotic messenger RNA (mRNA) as well as long non-coding RNA (lncRNA). Recently, m6A RNA methylation research was revived by the discovery of the fat mass- and obesity-associated protein (FTO) as the first RNA demethylase, implicating that m6A RNA methylation is a reversible and dynamic modification and may have critical biological functions. Emerging evidence has shown that m6A modifications in mRNAs and lncRNAs play crucial roles in regulating RNA fate and function in biological processes in the past several years. The goal is to determine the targets of arsenic damage including m6A RNA methylation in keratinocytes.

Project description:Here we use MeRIP-Seq to analyze global adenosine methylation (m6A) in mRNAs in the midbrain and striatum of Fto-deficient mice. We find that Fto deficiency leads to increased methylation within a subset of mRNAs important for neuronal signaling, including many within the dopaminergic signaling pathway. Collectively, our results show that Fto regulates demethylation of specific mRNAs in vivo, and this activity relates to control of dopaminergic transmission. Profiling of m6A in midbrain and striatum from FTO knockout mice

Project description:Here we use MeRIP-Seq to analyze global adenosine methylation (m6A) in mRNAs in the midbrain and striatum of Fto-deficient mice. We find that Fto deficiency leads to increased methylation within a subset of mRNAs important for neuronal signaling, including many within the dopaminergic signaling pathway. Collectively, our results show that Fto regulates demethylation of specific mRNAs in vivo, and this activity relates to control of dopaminergic transmission. Profiling of m6A in midbrain and striatum from wild type mice

Project description:The fat mass and obesity-associated (FTO) protein is a well-characterized demethylase that removes N6-methyladenosine (m6A) from animal mRNAs. However, it is unclear yet how the demethylation operates in living cells. In this study, we applied genome-wide approaches to study how FTO finds its demethylation targets in human cells. We overexpressed FTO in human HeLa cells, demonstrating that FTO effectively removes m6A from the RRACH motif enriched in the 3’UTR regions and leaves m6A at other motifs unaffected. RRACH elements are clearly enriched at FTO binding sites; however, m6A has a lower tendency to be removed from the FTO-bound RRACH. Taken together with the experimental validaton results, we propose a model in which FTO effectivly recognizes m6A-containing RRACH motifs in RNAs, leading to a faster demethylation and dissociation kinetic than the association, and consequently undectable FTO-mRNA association. However, when FTO binds to the non-m6A RRACH motif, the binding has a lower dissociation kinetics, yielding the detectable FTO binding signals which would enable FTO to have roles in regulating other mRNA processing events.

Project description:The fat mass and obesity-associated (FTO) protein is a well-characterized demethylase that removes N6-methyladenosine (m6A) from animal mRNAs. However, it is unclear yet how the demethylation operates in living cells. In this study, we applied genome-wide approaches to study how FTO finds its demethylation targets in human cells. We overexpressed FTO in human HeLa cells, demonstrating that FTO effectively removes m6A from the RRACH motif enriched in the 3’UTR regions and leaves m6A at other motifs unaffected. RRACH elements are clearly enriched at FTO binding sites; however, m6A has a lower tendency to be removed from the FTO-bound RRACH. Taken together with the experimental validaton results, we propose a model in which FTO effectivly recognizes m6A-containing RRACH motifs in RNAs, leading to a faster demethylation and dissociation kinetic than the association, and consequently undectable FTO-mRNA association. However, when FTO binds to the non-m6A RRACH motif, the binding has a lower dissociation kinetics, yielding the detectable FTO binding signals which would enable FTO to have roles in regulating other mRNA processing events.

Project description:The discovery of activating mutations in receptor tyrosine kinases (RTKs) leads to clinical testing of RTK inhibitors (TKIs). However, the rapid acquisition of resistance limits TKI effectiveness. Here we establish TKI-resistant cells that propagate in the absence of RTK signaling. Relative to sensitive cells, TKI-resistant cells display decreased N6-methyladenosine (m6A), a ubiquitous and reversible modification on RNA, but upregulated fat mass and obesity-associated gene (FTO), an m6A demethylase. Notably, the naïve leukemia cell populations are heterogeneous with respect to FTO levels. Cells with higher intrinsic and transient FTO expression demonstrate reduction of m6A methylation and TKI sensitivity with higher tumorigenic. Genetic or pharmacological dysfunction of FTO increases m6A abundance sensitizing resistant cells to TKIs. Mechanistically, FTO-mediated m6A demethylation promotes mRNA stability and protein translation rate, upregulating oncogenes that are indispensable for survival and proliferation. Our findings therefore establish a role of FTO-dependent m6A demethylation for TKI-resistance, offering a therapeutic window for incorporating m6A modulators in counteracting acquired TKI resistance.

Project description:Adenosine N6-methylation (m6A) is one of the most pervasive mRNA modifications, and yet the physiological significance of m6A removal (demethylation) remains elusive. Here we report the m6A demethylase FTO functions as a conserved regulator of motile ciliogenesis. Mechanistically, FTO demethylates and thereby stabilizes the mRNA encoding the master ciliary transcription factor FOXJ1. Depletion of Fto in Xenopus laevis embryos caused widespread motile cilia defects, and Foxj1 was identified as one of the major phenocritical targets. In primary human airway epithelium, FTO depletion also led to FOXJ1 mRNA destabilization and a severe loss of ciliated cells with an increase of neighboring goblet cells. Consistently, Fto knockout mice showed strong asthma-like phenotypes upon allergen challenge owing to defective ciliated cells in the airway epithelium. Altogether, our study reveals a conserved role of the FTO-FOXJ1 axis in embryonic and homeostatic motile ciliogenesis.

Project description:The post-transcriptional modification of mRNA and tRNA provides an additional layer of regulatory complexity during gene expression. TRMT10A is a tRNA methyltransferase that installs N1-methylguanosine (m1G), while FTO performs demethylation on N6-methyladenosine (m6A) and N6,2'-O-dimethyladenosine (m6Am) in mRNA. We find that this tRNA methyltransferase TRMT10A interacts with mRNA demethylase FTO (ALKBH9), both in vitro and inside cells. Strikingly, depletion of TRMT10A not only led to decreased m1G in tRNA but also significantly increased m6A levels in mRNA. CLIP-seq results showed that TRMT10A shares a significant overlap of associated mRNAs with FTO, and these mRNAs have accelerated decay rates potentially through the regulation by specific m6A reader. Furthermore, transcripts with increased m6A upon TRMT10A ablation contain an overrepresentation of m1G9-containing tRNAs codons read by tRNAGln(TTG), tRNAArg(CCG), and tRNAThr(CGT). These findings collectively reveal the presence of coordinated mRNA and tRNA modifications and demonstrate a mechanism for regulating gene expression through the interactions between mRNA and tRNA modifying enzymes.

Project description:N6-methyladenosine (m6A) is the most abundant post-transcriptional methylation of mature mRNA and plays a crucial regulatory role in various biological functions, involving development and cancer progression. m6A is deposited by methyltransferase complex composed of METTL3 and METTL14 cotranscriptionally, and removed by demethylase FTO or ALKBH5. m6A is highly enriched within the 3’ UTRs and in the vicinity of the stop codon of mature mRNA. However, the mechanism that causes this distribution pattern is still enigmatic. Here, we show that EJC packages mRNAs to shape mRNA m6A landscape. We first tested the possibility that demethylase removes m6A during spicing and found that ALKBH5 depletion had a minor effect on m6A levels. Thus, we ruled out the demethylation model. We then hypothesized that splicing factors inhibit the methylation process of internal exons, but not the 3’ UTR. Knockdown of EIF4A3, a core component of the exon junction complex, significantly increased m6A levels in mature mRNAs. The hypermethylated sites are enriched in short internal exons. Furthermore, EIF4A3 depletion upregulates METTL3 binding affinity to mRNA to deposit m6As. In conclusion, Our results demonstrate that EIF4A3 blocks METTL3 binding and methylating internal short exons of mRNA. These findings shed light on the fact that RNA packaging formed during splicing acts as a regulator that shapes mRNA modifications.