Project description:Lactylation, a metabolic stress-induced modification, plays a pivotal role in regulating diverse biological processes. Its involvement in perineural invasion (PNI) of pancreatic ductal adenocarcinoma (PDAC), however, has not been clearly defined. Our study demonstrates that patients with severe PNI exhibit significantly elevated levels of global lactylation and lactate, correlating with poorer prognosis. We identified NSUN2, a methyltransferase, as a crucial mediator of lactylation-driven PNI. Inhibition of lactylation or NSUN2 markedly reduced the neural infiltration capabilities of tumor cells. Mechanistically, lactate accumulation leads to the lactylation of NSUN2 at lysine 692 (K692), subsequently inhibiting its ubiquitination and degradation. lactylation of NSUN2 mediated m5C modification on CDCP1 and STC11 mRNA, enhanced their mRNA stability. Consistently, analyses using a KPC mouse model demonstrated that the lactylation of NSUN2/CDCP1/STC11 axis enhanced PNI through m5C modification. Our findings reveal that lactylation-driven NSUN2-mediated RNA m5C modification plays a pivotal role in promoting PNI and suggest that targeting NSUN2 could offer a promising therapeutic strategy for PDAC.

Project description:Perineural invasion (PNI) is a pivotal prognostic factor in pancreatic cancer, associated with aggressive tumor behavior and adverse patient outcomes. Despite its recognized clinical impact, the molecular mechanisms underlying PNI are not well understood. In this study, we isolated perineural invasion-associated cancer-associated fibroblasts (pCAFs), which demonstrated a markedly enhanced capacity to promote neural invasion in pancreatic cancer compared to non-perineural invasion-associated CAFs (npCAFs). Utilizing single-cell, high-throughput sequencing, and metabolomics, we identified a significant upregulation of glycolysis in pCAFs, fostering a high-lactate tumor microenvironment conducive to cancer progression. pCAFs-derived lactate is absorbed by tumor cells, facilitating histone H3K18 lactylation. This epigenetic modification activates the transcription of neural invasion-associated genes such as L1CAM and SLIT1, thereby driving PNI in pancreatic cancer. Further exploration of metabolic reprogramming in pCAFs revealed enhanced acetylation of the glycolytic enzyme GAPDH, correlated with increased enzymatic activity and glycolytic flux. Targeting of GAPDH and lactylation modifications significantly inhibits neural invasion in a KPC mouse model. Clinical data suggested that high levels of H3K18 lactylation correlate with severe PNI and poorer patient prognosis. Our findings provide critical insights into the role of pCAFs in the PNI of pancreatic cancer, highlighting glycolytic reprogramming and lactate-driven histone modifications as potential therapeutic targets for PDAC.

Project description:Perineural invasion (PNI) is a pivotal prognostic factor in pancreatic cancer, associated with aggressive tumor behavior and adverse patient outcomes. Despite its recognized clinical impact, the molecular mechanisms underlying PNI are not well understood. In this study, we isolated perineural invasion-associated cancer-associated fibroblasts (pCAFs), which demonstrated a markedly enhanced capacity to promote neural invasion in pancreatic cancer compared to non-perineural invasion-associated CAFs (npCAFs). Utilizing single-cell, high-throughput sequencing, and metabolomics, we identified a significant upregulation of glycolysis in pCAFs, fostering a high-lactate tumor microenvironment conducive to cancer progression. pCAFs-derived lactate is absorbed by tumor cells, facilitating histone H3K18 lactylation. This epigenetic modification activates the transcription of neural invasion-associated genes such as L1CAM and SLIT1, thereby driving PNI in pancreatic cancer. Further exploration of metabolic reprogramming in pCAFs revealed enhanced acetylation of the glycolytic enzyme GAPDH, correlated with increased enzymatic activity and glycolytic flux. Targeting of GAPDH and lactylation modifications significantly inhibits neural invasion in a KPC mouse model. Clinical data suggested that high levels of H3K18 lactylation correlate with severe PNI and poorer patient prognosis. Our findings provide critical insights into the role of pCAFs in the PNI of pancreatic cancer, highlighting glycolytic reprogramming and lactate-driven histone modifications as potential therapeutic targets for PDAC.

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.

Project description:Lactylation-driven NSUN2-mediated RNA m5C modification promotes perineural invasion in pancreatic cancer [mRNA-seq]

Project description:5-methylcytosine (m5C) RNA modification installed by methyltransferase NSUN2 regulates gene expression and cell fate. Retinoblastoma (RB) is the most common primary intraocular tumor in children. However, the functional role of m5C modification in retinoblastoma remains unclear. Here, we show that 5-methylcytosine significantly promotes the progression of retinoblastoma. Retinoblastoma samples showed increased m5C levels, indicating a poor prognosis. Changes in global m5C modification were highly associated with tumor progression in vitro and in vivo. Mechanistically, NSUN2 stabilized the methylated PFAS mRNA, a tumor promoter in retinoblastoma. Our work uncovers a critical function for m5C methylation in retinoblastoma and provides additional insight into the understanding of m5C modification.

Project description:5-methylcytosine (m5C) is emerging as an important epi-transcriptome modification involving RNA stability and translation efficiency in various biological processes. However, it remains unclear how m5C contributes to the dynamic regulation of transcriptome during the development of Plasmodium. Here, we identified the presence of 5-methylcytosine (m5C) modification in rodent (P. yoelii) and human (P. falciparum) malaria parasites transcriptome and depicted a comprehensive characterization landscape of m5C mRNA modification at single-nucleotide resolution (RNA-BisSeq) from asexual replicating stage to gametocyte development. Through transcriptome-wide profiling of mRNA m5C modification, we found that m5C modified mRNA displayed higher stability than non-m5C modified mRNA during the development of Plasmodium. We identified Plasmodium ortholog of NSUN2 as an mRNA m5C methyltransferase in malaria parasites. LC–MS/MS and RNA-BisSeq analysis revealed a large decrease in mRNA m5C modification at transcriptome-wide level upon Nsun2 knockout. Absence of Nsun2 severely reduced gametocyte production in either rodent (P. yoelii) or human (P. falciparum) malaria parasites. Meanwhile, some genes related to gametocytogenesis displayed a great reduction of m5C modification. Together, our data provides comprehensive mRNA m5C profiles in Plasmodium genus and reveals m5C modification-mediated mRNA stability as a novel mechanism regulating sexual differentiation of a unicellular eukaryote.

Project description:5-methylcytosine (m5C) is emerging as an important epi-transcriptome modification involving RNA stability and translation efficiency in various biological processes. However, it remains unclear how m5C contributes to the dynamic regulation of transcriptome during the development of Plasmodium. Here, we identified the presence of 5-methylcytosine (m5C) modification in rodent (P. yoelii) and human (P. falciparum) malaria parasites transcriptome and depicted a comprehensive characterization landscape of m5C mRNA modification at single-nucleotide resolution (RNA-BisSeq) from asexual replicating stage to gametocyte development. Through transcriptome-wide profiling of mRNA m5C modification, we found that m5C modified mRNA displayed higher stability than non-m5C modified mRNA during the development of Plasmodium. We identified Plasmodium ortholog of NSUN2 as an mRNA m5C methyltransferase in malaria parasites. LC–MS/MS and RNA-BisSeq analysis revealed a large decrease in mRNA m5C modification at transcriptome-wide level upon Nsun2 knockout. Absence of Nsun2 severely reduced gametocyte production in either rodent (P. yoelii) or human (P. falciparum) malaria parasites. Meanwhile, some genes related to gametocytogenesis displayed a great reduction of m5C modification. Together, our data provides comprehensive mRNA m5C profiles in Plasmodium genus and reveals m5C modification-mediated mRNA stability as a novel mechanism regulating sexual differentiation of a unicellular eukaryote.

Project description:5-methylcytosine (m5C) is emerging as an important epi-transcriptome modification involving RNA stability and translation efficiency in various biological processes. However, it remains unclear how m5C contributes to the dynamic regulation of transcriptome during the development of Plasmodium. Here, we identified the presence of 5-methylcytosine (m5C) modification in rodent (P. yoelii) and human (P. falciparum) malaria parasites transcriptome and depicted a comprehensive characterization landscape of m5C mRNA modification at single-nucleotide resolution (RNA-BisSeq) from asexual replicating stage to gametocyte development. Through transcriptome-wide profiling of mRNA m5C modification, we found that m5C modified mRNA displayed higher stability than non-m5C modified mRNA during the development of Plasmodium. We identified Plasmodium ortholog of NSUN2 as an mRNA m5C methyltransferase in malaria parasites. LC–MS/MS and RNA-BisSeq analysis revealed a large decrease in mRNA m5C modification at transcriptome-wide level upon Nsun2 knockout. Absence of Nsun2 severely reduced gametocyte production in either rodent (P. yoelii) or human (P. falciparum) malaria parasites. Meanwhile, some genes related to gametocytogenesis displayed a great reduction of m5C modification. Together, our data provides comprehensive mRNA m5C profiles in Plasmodium genus and reveals m5C modification-mediated mRNA stability as a novel mechanism regulating sexual differentiation of a unicellular eukaryote.