Project description:Studies on biological functions of RNA modifications such as N6-methyladenosine (m6A) in mRNA have sprung up in recent years, while the roles of N1-methyladenosine (m1A) in cancer progression remain largely unknown. We find m1A demethylase ALKBH3 can regulate the glycolysis of cancer cells via a demethylation activity dependent manner. Specifically, sequencing and functional studies confirm that ATP5D, one of the most important subunit of ATP synthase, is involved in m1A demethylase ALKBH3-regulated glycolysis of cancer cells. The m1A modified A71 at the Exon 1 of ATP5D negatively regulates its translation elongation via increasing the binding with YTHDF1/eRF1 complex, which facilitates the release of mRNA from ribosome complex. m1A also regulates mRNA stability of E2F1, which directly binds with ATP5D promoter to initiate its transcription. Targeted specific demethylation of ATP5D m1A by dm1ACRISPR system can significantly increase the expression of ATP5D and glycolysis of cancer cells. In vivo data confirm the roles of m1A/ATP5D in tumor growth and cancer progression. Our study for the first time reveals a crosstalk of mRNA m1A modification and cell metabolism, which expands the understanding of such interplays that are essential for cancer therapeutic application.

Project description:N1-methyladenosine (m1A) is an abundant post-transcriptional RNA modification, yet little is known about its prevalence, topology and dynamics in mRNA. Here, we show that m1A is abundant in human mRNA, with an m1A/A ratio of ~0.02%. We develop m1A-ID-Seq, based on m1A immunoprecipitation and the inherent property of m1A to stall reverse transcription, for the transcriptome-wide m1A analysis. m1A-ID-Seq identifies 901 m1A peaks (from 583 genes) in mRNA and ncRNA, and reveals a prominent feature of enrichment in the 5’-untranslated region of mRNA transcripts, distinct from that of N6-methyladenosine, the most abundant internal mammalian mRNA modification. m1A in mRNA is also reversible by ALKBH3, a known DNA/RNA demethylase. Lastly, m1A responds dynamically to stimuli and hundreds of stress-induced m1A sites are identified. Collectively, our approaches allow comprehensive analysis of m1A methylation and provide an important tool for functional studies of potential epigenetic regulation via the reversible and dynamic m1A methylation. Identification of m1A sites in human embryonic kidney cells. Comparisons of m1A profiles of wild type HEK293T with ALKBH3 knock out cell line reveals the ALKBH3 specific sites. Stress inducible m1A sites are also identified by comparing the profiles of untreated cells with stress treated cells.

Project description:N1-Methyladenosine (m1A) is a prevalent post-transcriptional RNA modification, yet little is known about its abundance, topol- ogy and dynamics in mRNA. Here, we show that m1A is prevalent in Homo sapiens mRNA, which shows an m1A/A ratio of ~0.02%. We develop the m1A-ID-seq technique, based on m1A immunoprecipitation and the inherent ability of m1A to stall reverse tran- scription, as a means for transcriptome-wide m1A profiling. m1A-ID-seq identifies 901 m1A peaks (from 600 genes) in mRNA and noncoding RNA and reveals a prominent feature, enrichment in the 5' untranslated region of mRNA transcripts, that is dis- tinct from the pattern for N6-methyladenosine, the most abundant internal mammalian mRNA modification. Moreover, m1A in mRNA is reversible by ALKBH3, a known DNA/RNA demethylase. Lastly, we show that m1A methylation responds dynamically to stimuli, and we identify hundreds of stress-induced m1A sites. Collectively, our approaches allow comprehensive analysis of m1A modification and provide tools for functional studies of potential epigenetic regulation via the reversible and dynamic m1A methylation.

Project description:To investigate the function of N1-methyladenosine methylome (m1A) in ocular melanoma, we analyzed m1A enrichment level in ocular melanoma and melanocyte cell lines and established ALKBH3 knock down cell lines in 92.1.

Project description:FTO, the first RNA demethylase discovered, mediates the demethylation of N6-methyladenosine (m6A), installed internally on messenger RNA, and N6,2′-O-dimethyladenosine (m6Am), occurring at the +1 position from the 5’ cap. Despite extensive recent research on FTO, its physiological impact on cellular processes has yet to be fully elucidated. Here, we demonstrate that the cellular distribution of FTO is distinct among different cell lines, which critically affects the access of FTO to different RNA substrates. FTO binds multiple RNA substrates, including mRNA, U6 RNA, and tRNA. It mainly targets internal m6A when located in the cell nucleus and preferentially demethylates m6Am when residing in the cytoplasm. The expression levels of transcripts containing internal m6A are associated with the alteration of the FTO more so than transcripts containing m6Am. We also discover that N1-methyladenosine (m1A) in tRNA is a main substrate of FTO, with the FTO-catalyzed demethylation of target tRNAs repressing protein synthesis. Collectively, FTO-mediated RNA demethylation affects both mRNA level and translation through distinct pathways.

Project description:Transfer RNA (tRNA) is a central component of protein synthesis and cell signaling network. One salient feature of tRNA is its heavily modified status, which can critically impact its function. Here we show that mammalian ALKBH1 is a tRNA demethylase. It mediates the demethylation of N1-methyladenosine (m1A) in tRNAs. The ALKBH1-catalyzed demethylation of the target tRNAs results in their reduced partition in polysomes and their decreased usage in protein synthesis. This process is dynamic and responds to glucose availability to affect translation. Our results uncover reversible methylation of tRNA as a new regulatory mechanism of post-transcriptional gene expression.

Project description:N1-methyladenosine (m1A) is one of messenger RNA modification in eukaryotes, but the potential roles of m1A methylated mRNA in trophoblast upon hypoxia remain elusive.

Project description:Background: The oxidative DNA demethylase ALKBH3 targets single-stranded DNA (ssDNA) in order to perform DNA alkylation damage repair. ALKBH3 becomes up-regulated during tumorigenesis and is necessary for proliferation. However, the underlying molecular mechanism remains to be understood. Methods: To further elucidate the function of ALKBH3 in cancer, we performed ChIP-seq to investigate the genomic binding pattern of endogenous ALKBH3 in PC3 prostate cancer cells coupled with microarray experiments to examine the expression effects of ALKBH3 depletion. Results: We demonstrate that ALKBH3 binds to transcription associated locations, such as places of promoter-proximal paused RNA polymerase II and enhancers. Strikingly, ALKBH3 strongly binds to the transcription initiation sites of a small number of highly active gene promoters. These promoters are characterized by high levels of transcriptional regulators, including transcription factors, the Mediator complex, cohesin, histone modifiers and active histone marks. Gene expression analysis showed that ALKBH3 does not directly influence the transcription of its target genes, but its depletion induces an up-regulation of ALKBH3 non-bound inflammatory genes. Conclusions: The genomic binding pattern of ALKBH3 revealed a putative novel hyperactive promoter type. Further, we propose that ALKBH3 is an intrinsic DNA repair protein that suppresses transcription associated DNA damage at highly expressed genes and thereby plays a role to maintain genomic integrity in ALKBH3-overexpressing cancer cells. These results raise the possibility that ALKBH3 may be a potential target for inhibiting cancer progression. PC3 cells were infected with ALKBH3 shRNA or Control shRNA for 48 hours and selected with puromycine. Cells were collected after 48h or 96h past selection.

Project description:N1-methyladenosine (m1A) was recently identified as a new mRNA modification based on its mapping to the 5’UTRs of thousands of mRNAs with an m1A-binding antibody. More recent studies have questioned the prevalence of m1A. To address this discrepancy, we mapped m1A using ultra-deep RNA-Seq datasets based on m1A-induced misincorporations during reverse transcription. Using this approach, we find m1A only in the mitochondrial MT-ND5 transcript. In contrast, m1A mapping using an m1A-binding antibody showed binding to transcription start nucleotides in mRNA 5’UTRs. Biochemical measurements indicate that m1A is not present at these sites. Instead, we find that the m1A antibody exhibits m1A-independent binding to mRNA cap structures. Our data demonstrate that high-stoichiometry m1A sites are rare in the transcriptome and that previous mapping of m1A to mRNA 5’UTRs reflect an unintended binding to mRNA caps.

Project description:Members of the mammalian AlkB family are known to mediate nucleic acid demethylation. ALKBH7, a mammalian AlkB homologue, localizes in mitochondria (mt) and affects metabolism, but its function and mechanism of action are unknown. Here, we report an approach to site-specifically detect m1A, m3C, m1G, and m22G modifications simultaneously within all cellular RNAs, and discovered that human ALKBH7 demethylates N2, N2-dimethylguanosine (m22G) and N1-methyladenosine (m1A) within mt-Ile and mt-Leu1 pre-tRNA regions, respectively, in nascent polycistronic mt-RNA. We further show that ALKBH7 regulates the processing and structural dynamics of polycistronic mt-RNAs. Depletion of ALKBH7 leads to increased polycistronic mt-RNA processing, reduced steady-state mitochondria-encoded tRNA levels and protein translation, as well as notably decreased mitochondrial activity. Thus, we identify ALKBH7 as an RNA demethylase that controls nascent mt-RNA processing and mitochondrial activity.