Project description:The involvement of tRNA m1A modification in the anti-tumoral tumor-associated macrophages (TAMs) has been validated in our study that macrophage-specific knockout of m1A “writer” enzymes TRMT61A leads to increased infiltration of TAMs, impaired CD8+ T cell function, and enhanced tumor growth. Since TRMT61A-derived tRNA m1A modification mainly enhances translation efficiency, we reasoned that the loss of TRMT61A in macrophages would result in the downregulation of a group of protein levels without affecting their mRNA levels. To assess the impact of TRMT61A deficiency on mRNA transcript levels in macrophages, we collected TRMT61A-KO and WT BMDMs derived from Trmt61af/fLysmCre and Trmt61af/f mice to perform bulk RNA sequencing. Of total 22173 genes, the mRNA expression of 22054 genes remain unchanged in macrophages upon TRMT61A deletion, suggesting that TRMT61A did not contribute to mRNA transcriptional regulation in macrophages.

Project description:The involvement of tRNA m1A modification in the anti-tumoral tumor-associated macrophages (TAMs) has been validated in our study that macrophage-specific knockout of m1A “writer” enzymes TRMT61A leads to increased infiltration of TAMs, impaired CD8+ T cell function, and enhanced tumor growth. Since we observed that tumor-derived components suppresses tRNA m1A modification in macrophages, we sought to identify which component in the TME induces the down-regulation of tRNA m1A modification. Here, we performed bulk RNA-seq using TRMT61AOE-CAR-iMACs and CAR-iMACs to ensure the effect of human Trmt61a overexpression on CAR-iMACs. Kyoto encyclopedia of genes and genomes (KEGG) analysis showed that signal transduction is the most up-regulated pathway in CAR-iMACs after human Trmt61a overexpression.

Project description:Activation of CD8+ T cells necessitates rapid metabolic reprogramming to fulfill the substantial biosynthetic demands of their effector functions. However, the post-transcriptional mechanisms underpinning this process remain obscure. The tRNA N1-methyladenine (m1A) modification, which plays a role in maintaining tRNA stability and modulating protein translation, has an undefined physiological function in CD8+ T cells, particularly in antitumor responses. Here, we demonstrate that the tRNA m1A 'writer' gene Trmt61a enhances the tumor-killing capacity of CD8+ T cells by regulating cholesterol biosynthesis. We find that Trmt61a expression in CD8+ T cells is upregulated upon activation and correlates positively with T cell-mediated cytotoxicity within the tumor microenvironment of colorectal cancer (CRC) patients. Deletion of Trmt61a in CD8+ T cells leads to a compromised tumor-killing function in both in vivo and in vitro assays, which is dependent on the m1A catalytic activity of TRMT61A. Mechanistically, tRNA m1A promotes antitumor immunity in CD8+ T cells by enhancing the translation of ATP citrate lyase (ACLY), a key enzyme for cholesterol biosynthesis. Supplementation with cholesterol can rescue the impaired tumor-killing function and proliferation of TRMT61A-deficient CD8+ T cells. Our findings underscore the significance of tRNA m1A modification as a regulatory checkpoint in cholesterol metabolism in CD8+ T cells, suggesting potential novel strategies for cancer immunotherapy.

Project description:The role of N1-methyladenosine (m1A) in cancer remains poorly understood. Here we investigate the functional importance of RNA m1A methyltransferase TRMT61A in colorectal cancer (CRC) and assess its potential as a therapeutic target. Our findings demonstrate consistent elevation of TRMT61A expression and RNA m1A levels in primary CRC tissues, which correlate significantly with poor patient survival. Through CRISPR/Cas9 screenings, TRMT61A is the most essential gene among m1A regulators. We further elucidate that TRMT61A facilitates CRC tumorigenesis and progression by enhancing the stability of mRNA of crucial targets, including ONECUT2, thereby activating the MAPK/ERK signaling pathway in an m1A-dependent manner. Of note, we show promising anti-CRC effects by inhibiting TRMT61A using nanoparticleencapsulated siTRMT61A or our identified small molecule compound, PGG. Collectively, our study uncovers the essential role of TRMT61A-m1A in CRC by activating the ONECUT2-MAPK/ERK pathway. Targeting TRMT61A holds promise as a therapeutic approach for treating CRC.

Project description:The role of N1-methyladenosine (m1A) in cancer remains poorly understood. Here we investigate the functional importance of RNA m1A methyltransferase TRMT61A in colorectal cancer (CRC) and assess its potential as a therapeutic target. Our findings demonstrate consistent elevation of TRMT61A expression and RNA m1A levels in primary CRC tissues, which correlate significantly with poor patient survival. Through CRISPR/Cas9 screenings, TRMT61A is the most essential gene among m1A regulators. We further elucidate that TRMT61A facilitates CRC tumorigenesis and progression by enhancing the stability of mRNA of crucial targets, including ONECUT2, thereby activating the MAPK/ERK signaling pathway in an m1A-dependent manner. Of note, we show promising anti-CRC effects by inhibiting TRMT61A using nanoparticleencapsulated siTRMT61A or our identified small molecule compound, PGG. Collectively, our study uncovers the essential role of TRMT61A-m1A in CRC by activating the ONECUT2-MAPK/ERK pathway. Targeting TRMT61A holds promise as a therapeutic approach for treating CRC.

Project description:The role of N1-methyladenosine (m1A) in cancer remains poorly understood. Here we investigate the functional importance of RNA m1A methyltransferase TRMT61A in colorectal cancer (CRC) and assess its potential as a therapeutic target. Our findings demonstrate consistent elevation of TRMT61A expression and RNA m1A levels in primary CRC tissues, which correlate significantly with poor patient survival. Through CRISPR/Cas9 screenings, TRMT61A is the most essential gene among m1A regulators. We further elucidate that TRMT61A facilitates CRC tumorigenesis and progression by enhancing the stability of mRNA of crucial targets, including ONECUT2, thereby activating the MAPK/ERK signaling pathway in an m1A-dependent manner. Of note, we show promising anti-CRC effects by inhibiting TRMT61A using nanoparticleencapsulated siTRMT61A or our identified small molecule compound, PGG. Collectively, our study uncovers the essential role of TRMT61A-m1A in CRC by activating the ONECUT2-MAPK/ERK pathway. Targeting TRMT61A holds promise as a therapeutic approach for treating CRC.

Project description:The role of N1-methyladenosine (m1A) in cancer remains poorly understood. Here we investigate the functional importance of RNA m1A methyltransferase TRMT61A in colorectal cancer (CRC) and assess its potential as a therapeutic target. Our findings demonstrate consistent elevation of TRMT61A expression and RNA m1A levels in primary CRC tissues, which correlate significantly with poor patient survival. Through CRISPR/Cas9 screenings, TRMT61A is the most essential gene among m1A regulators. We further elucidate that TRMT61A facilitates CRC tumorigenesis and progression by enhancing the stability of mRNA of crucial targets, including ONECUT2, thereby activating the MAPK/ERK signaling pathway in an m1A-dependent manner. Of note, we show promising anti-CRC effects by inhibiting TRMT61A using nanoparticleencapsulated siTRMT61A or our identified small molecule compound, PGG. Collectively, our study uncovers the essential role of TRMT61A-m1A in CRC by activating the ONECUT2-MAPK/ERK pathway. Targeting TRMT61A holds promise as a therapeutic approach for treating CRC.

Project description:RNA N1-methyladenosine methylation (m1A) modification is critical in regulating mRNA translation and thus protein synthesis, but the role of m1A modification in the occurrence, progression, and immunotherapy of head and neck squamous cell cancer (HNSCC) remains largely unknown. In Tgfbr1/Pten 2cKO mice, we found that the spontaneous neoplastic transformation of oral mucosa is accompanied by elevated levels of m1A modification. Analysis of m1A-associated genes identified TRMT61A as the key m1A writer associated with cancer progression, and poor prognosis. Mechanically, TRMT61A-induced tRNA-m1A modification promotes MYC protein synthesis and subsequent programmed death-ligand 1 (PD-L1) expression. In Tgfbr1/Pten 2cKO mice, RNA-m1A modification levels are also elevated in tumors that developed resistance to oncolytic herpes simplex virus (oHSV) treatment. Therapeutic inhibition of m1A modification sustains oncolytic virus-induced antitumor immunity and reduces tumor growth, providing a promising strategy for alleviating resistance to oHSV therapy. These findings indicate that m1A inhibition can prevent immune escape after oHSV therapy by reducing the expression of PD-L1. Our results provide a mutually reinforcing strategy for clinical combination immunotherapy.

Project description:N1-methyl adenosine (m1A) is a wide-spread RNA modification present in tRNA, rRNA and mRNA. m1A modification sites in tRNAs are evolutionary conserved and its formation on tRNA is catalyzed by methyltransferase TRMT61A and TRMT6 complex. m1A promotes translation initiation and elongation. Due to its positive charge under physiological conditions, m1A can notably modulate RNA structure. It also blocks Watson-Crick base pairing and causes mutation and truncation during reverse transcription. Several misincorporation-based high throughput sequencing methods have been developed to sequence m1A. In this study, we introduce a reduction-based m1A sequencing (red-m1A-seq). We report that NaBH4 reduction of m1A can improve the mutation and readthrough rates using commercially available RT enzymes to give better positive signature, while alkaline-catalyzed Dimroth rearrangement can efficiently convert m1A to m6A to provide good controls, allowing the detection of m1A with higher sensitivity and accuracy. We applied red‑m1A-seq to sequence human small RNA and we not only detected all the previously reported tRNA m1A sites, but also new m1A sites in mt-tRNAAsn-ATT and 5.8S rRNA.

Project description:Group 3 innate lymphoid cells (ILC3s) play crucial roles in maintaining intestinal homeostasis and defending against bacterial infections. However, the epigenetic mechanisms that regulate ILC3 responses are not well understood. In this study, we show that Trmt61a, the methyltransferase responsible for the m1A58 tRNA modification, is predominantly expressed in ILC3s. We found that specific depletion of TRMT61A in ILC3s leads to dysregulated cell cycle and a reduction in cell numbers. Notably, mice with an ILC3-specific TRMT61A deficiency exhibit dysbiosis, but antibiotic treatment can restore colonic ILC3 levels. Furthermore, these mice exhibit increased susceptibility to experimental intestinal inflammation and enteric bacterial infection. Our findings uncover a previously unrecognized role for TRMT61A mediated m1A modification in the regulation of intestinal ILC3s, essential for protecting intestinal tissue during inflammation and enhancing innate immunity against enteric pathogens.