Project description:Aberrant post-transcriptional methylation is implicated in a wide range of human diseases, yet the specific enzymes responsible for site- and substrate-specific methylation remain largely unknown. Here, we use our recently developed catalysis-dependent RIP sequencing approach (miCLIP) and RNA bisulfite sequencing to map C5-methylcytosine (m5C) in the human transcriptome. We identified two novel m5C methylases NSun3 and NSun6, both of which have strong substrate specificity. In contrast to the previously characterized NSun2, which displays some preference to methylating transfer RNAs (tRNA), NSun6 predominantly targeted 3’ UTRs of messenger RNAs (mRNA), and NSun3 mainly methylated mitochondrial RNAs (mtRNA). Consistent with the miCLIP-predicted RNA target specificity, whole exome sequencing identified NSUN3 loss-of-function mutations in a patient presenting with combined respiratory chain complex deficiency. Functional studies of the patient fibroblast cell line revealed that loss of the NSun3 protein resulted in severe mitochondrial translation defects, which were rescued by expression of wild-type NSun3. In summary, our results reveal how highly conserved NSun m5C methylases partition their substrate specificities to remodel the sequences of particular ribonucleotide classes.

Project description:Aberrant post-transcriptional methylation is implicated in a wide range of human diseases, yet the specific enzymes responsible for site- and substrate-specific methylation remain largely unknown. Here, we use our recently developed catalysis-dependent RIP sequencing approach (miCLIP) and RNA bisulfite sequencing to map C5-methylcytosine (m5C) in the human transcriptome. We identified two novel m5C methylases NSun3 and NSun6, both of which have strong substrate specificity. In contrast to the previously characterized NSun2, which displays some preference to methylating transfer RNAs (tRNA), NSun6 predominantly targeted 3’ UTRs of messenger RNAs (mRNA), and NSun3 mainly methylated mitochondrial RNAs (mtRNA). Consistent with the miCLIP-predicted RNA target specificity, whole exome sequencing identified NSUN3 loss-of-function mutations in a patient presenting with combined respiratory chain complex deficiency. Functional studies of the patient fibroblast cell line revealed that loss of the NSun3 protein resulted in severe mitochondrial translation defects, which were rescued by expression of wild-type NSun3. In summary, our results reveal how highly conserved NSun m5C methylases partition their substrate specificities to remodel the sequences of particular ribonucleotide classes.

Project description:m5C accumulates on mRNAs in Nocodazole (Noc) treated cells. To figure out which m5C writer is responsible for these m5C sites, we generated three KO cell lines (NSUN2, NSUN5, and NSUN6) with CRISPR induced mutagenesis. We also used siRNA to suppress the expression of Nop2 (NSUN1) in wild-type HeLa cells. Then we performed mRNA BS-seq on the cells harvested after 48 hours Noc-treatment (for siRNA experiments, cells were treated with siRNA for 48 hours first).

Project description:5-methylcytosine (m5C) is a prevalent base modification in tRNA and rRNA but it also occurs more broadly in the transcriptome, including in mRNA. In pursuit of potential links of m5C with mRNA translation, we performed polysome profiling of human HeLa cell lysates and subjected RNA from resultant fractions to efficient bisulfite conversion followed by RNA sequencing (bsRNA-seq). Bioinformatic filters for rigorous site calling were devised to reduce technical noise. We obtained ~1,000 candidate m5C sites in the wider transcriptome, most of which were found in exonic regions of mRNA. Multiple novel sites were validated by amplicon-specific bsRNA-seq in independent samples of either human HeLa, LNCap and PrEC cells. Furthermore, RNAi-mediated depletion of either the NSUN2 or TRDMT1 m5C:RNA methyltransferases showed a clear dependence on NSUN2 for the majority of tested sites in mRNA and noncoding RNA. Candidate m5C sites in mRNAs are enriched in 5’UTRs and near start codons, and commonly embedded in a local context reminiscent of the NSUN2-dependent m5C sites found in the variable loop of tRNA. Analysing mRNA sites across the polysome profile revealed that non-conversion levels, at bulk and for many individual sites, were inversely correlated with ribosome association. Altogether, these findings emphasise the major role of NSUN2 in making this mark transcriptome-wide and further substantiate a functional interdependence of cytosine methylation level with mRNA translation

Project description:mRNA m5C, which has recently been implicated in the regulation of mRNA mobility, metabolism, and translation, plays important regulatory roles in various biological events. Two types of m5C sites are found in mRNAs. Type I m5C sites, which contain a 3’G-rich triplet motif and locate in the 5’ end of hairpin structures, are methylated by NSUN2. Type II m5C sites contain a 3’UCCA motif and locate in the loops of hairpin structures. However, their biogenesis remains unknown. Here we identified a novel mRNA methyltransferase that targets Type II m5C sites and generated BS-seq and RNA-seq data to verify our findings.

Project description:mRNA m5C, which has recently been implicated in the regulation of mRNA mobility, metabolism, and translation, plays important regulatory roles in various biological events. Two types of m5C sites are found in mRNAs. Type I m5C sites, which contain a 3’G-rich triplet motif and locate in the 5’ end of hairpin structures, are methylated by NSUN2. Type II m5C sites contain a 3’UCCA motif and locate in the loops of hairpin structures. However, their biogenesis remains unknown. Here we identified a novel mRNA methyltransferase that targets Type II m5C sites and generated BS-seq and RNA-seq data to verify our findings.

Project description:mRNA m5C, which has recently been implicated in the regulation of mRNA mobility, metabolism, and translation, plays important regulatory roles in various biological events. Two types of m5C sites are found in mRNAs. Type I m5C sites, which contain a 3’G-rich triplet motif and locate in the 5’ end of hairpin structures, are methylated by NSUN2. Type II m5C sites contain a 3’UCCA motif and locate in the loops of hairpin structures. However, their biogenesis remains unknown. Here we identified a novel mRNA methyltransferase that targets Type II m5C sites and generated BS-seq and RNA-seq data to verify our findings.

Project description:mRNA m5C, which has recently been implicated in the regulation of mRNA mobility, metabolism, and translation, plays important regulatory roles in various biological events. Two types of m5C sites are found in mRNAs. Type I m5C sites, which contain a 3’G-rich triplet motif and locate in the 5’ end of hairpin structures, are methylated by NSUN2. Type II m5C sites contain a 3’UCCA motif and locate in the loops of hairpin structures. However, their biogenesis remains unknown. Here we identified a novel mRNA methyltransferase that targets Type II m5C sites and generated BS-seq and RNA-seq data to verify our findings.

Project description:Background: As a widespread post-transcriptional RNA modification, N5-methylcytosine (m5C) is implicated in a variety of cellular responses and processes that regulate RNA metabolism. Despite this, a clear understanding of m5C modification’s role and mechanism in angiogenesis is still lacking. Methods: Single-cell RNA sequencing data was analyzed to determine expression of m5C methylase NSUN2. m5C levels were determined by mRNA isolation and anti-m5C dot blot in both hypoxia-induced endothelial cells (ECs) and laser-induced choroidal neovascularization (CNV). In addition, endothelial cell and endothelium‐specific NSUN2‐knockout mouse model were used to investigate the effect of NSUN2 silence on angiogenic phenotype. Genome-wide multiomics analyses were performed to identify the functional target of NSUN2, including proteomic analysis, transcriptome screening and m5C-methylated RNA immunoprecipitation sequencing (m5C-meRIP-seq). CUT&Tag sequencing was performed to test the histone lactylation signal in the promoter region of NSUN2. Finally, AAV-mediated short hairpin RNAi knockdown of NSUN2 gene expression (AAV-shNSUN2) was constructed to investigate the effect of inhibiting CNV. Results: First, we discovered that m5C methylase NSUN2 expression level and mRNA m5C level were significantly higher in CNV-ECs than in normal ECs. NSUN2 knockdown in ECs inhibited proliferative, migration, and tube formation activities of ECs. Moreover, compared with EC NSUN2flox/flox mice, EC-specific NSUN2-deficient (EC NSUN2-/-) mice displayed less retinal vascular leakage after laser induction. Through multiomics analyses, we subsequently identified A-kinase anchoring protein 2 (AKAP2), a scaffolding protein which isolate Protein kinase A (PKA) to specific subcellular locations through binding to its regulatory subunit, as a downstream candidate target of NSUN2 in ECs. Overexpression of exogenous AKAP2 markedly reversed the inhibitory phenotypes in NSUN2-deficient ECs. Interestingly, laser induced NSUN2 up-regulation was driven by lactate-mediated lactylation on histone H3K18. In CNV models, AAV-mediated repression of NSUN2 modulated highly retinal vascular leakage and choroidal thickness. Conclusion: Overall, our findings indicate that NSUN2 is a novel therapeutic target for choroidal neovascularization.

Project description:Background: As a widespread post-transcriptional RNA modification, N5-methylcytosine (m5C) is implicated in a variety of cellular responses and processes that regulate RNA metabolism. Despite this, a clear understanding of m5C modification’s role and mechanism in angiogenesis is still lacking. Methods: Single-cell RNA sequencing data was analyzed to determine expression of m5C methylase NSUN2. m5C levels were determined by mRNA isolation and anti-m5C dot blot in both hypoxia-induced endothelial cells (ECs) and laser-induced choroidal neovascularization (CNV). In addition, endothelial cell and endothelium‐specific NSUN2‐knockout mouse model were used to investigate the effect of NSUN2 silence on angiogenic phenotype. Genome-wide multiomics analyses were performed to identify the functional target of NSUN2, including proteomic analysis, transcriptome screening and m5C-methylated RNA immunoprecipitation sequencing (m5C-meRIP-seq). CUT&Tag sequencing was performed to test the histone lactylation signal in the promoter region of NSUN2. Finally, AAV-mediated short hairpin RNAi knockdown of NSUN2 gene expression (AAV-shNSUN2) was constructed to investigate the effect of inhibiting CNV. Results: First, we discovered that m5C methylase NSUN2 expression level and mRNA m5C level were significantly higher in CNV-ECs than in normal ECs. NSUN2 knockdown in ECs inhibited proliferative, migration, and tube formation activities of ECs. Moreover, compared with EC NSUN2flox/flox mice, EC-specific NSUN2-deficient (EC NSUN2-/-) mice displayed less retinal vascular leakage after laser induction. Through multiomics analyses, we subsequently identified A-kinase anchoring protein 2 (AKAP2), a scaffolding protein which isolate Protein kinase A (PKA) to specific subcellular locations through binding to its regulatory subunit, as a downstream candidate target of NSUN2 in ECs. Overexpression of exogenous AKAP2 markedly reversed the inhibitory phenotypes in NSUN2-deficient ECs. Interestingly, laser induced NSUN2 up-regulation was driven by lactate-mediated lactylation on histone H3K18. In CNV models, AAV-mediated repression of NSUN2 modulated highly retinal vascular leakage and choroidal thickness. Conclusion: Overall, our findings indicate that NSUN2 is a novel therapeutic target for choroidal neovascularization.